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sqlparser/parser/
mod.rs

1// Licensed under the Apache License, Version 2.0 (the "License");
2// you may not use this file except in compliance with the License.
3// You may obtain a copy of the License at
4//
5// http://www.apache.org/licenses/LICENSE-2.0
6//
7// Unless required by applicable law or agreed to in writing, software
8// distributed under the License is distributed on an "AS IS" BASIS,
9// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
10// See the License for the specific language governing permissions and
11// limitations under the License.
12
13//! SQL Parser
14
15#[cfg(not(feature = "std"))]
16use alloc::{
17    boxed::Box,
18    format,
19    string::{String, ToString},
20    vec,
21    vec::Vec,
22};
23use core::{
24    fmt::{self, Display},
25    str::FromStr,
26};
27use helpers::attached_token::AttachedToken;
28
29use log::debug;
30
31use recursion::RecursionCounter;
32use IsLateral::*;
33use IsOptional::*;
34
35use crate::ast::*;
36use crate::ast::{
37    comments,
38    helpers::{
39        key_value_options::{
40            KeyValueOption, KeyValueOptionKind, KeyValueOptions, KeyValueOptionsDelimiter,
41        },
42        stmt_create_table::{CreateTableBuilder, CreateTableConfiguration},
43    },
44};
45use crate::dialect::*;
46use crate::keywords::{Keyword, ALL_KEYWORDS};
47use crate::tokenizer::*;
48use sqlparser::parser::ParserState::ColumnDefinition;
49
50/// Errors produced by the SQL parser.
51#[derive(Debug, Clone, PartialEq, Eq)]
52pub enum ParserError {
53    /// Error originating from the tokenizer with a message.
54    TokenizerError(String),
55    /// Generic parser error with a message.
56    ParserError(String),
57    /// Raised when a recursion depth limit is exceeded.
58    RecursionLimitExceeded,
59}
60
61// Use `Parser::expected` instead, if possible
62macro_rules! parser_err {
63    ($MSG:expr, $loc:expr) => {
64        Err(ParserError::ParserError(format!("{}{}", $MSG, $loc)))
65    };
66}
67
68mod alter;
69mod merge;
70
71#[cfg(feature = "std")]
72/// Implementation [`RecursionCounter`] if std is available
73mod recursion {
74    use std::cell::Cell;
75    use std::rc::Rc;
76
77    use super::ParserError;
78
79    /// Tracks remaining recursion depth. This value is decremented on
80    /// each call to [`RecursionCounter::try_decrease()`], when it reaches 0 an error will
81    /// be returned.
82    ///
83    /// Note: Uses an [`std::rc::Rc`] and [`std::cell::Cell`] in order to satisfy the Rust
84    /// borrow checker so the automatic [`DepthGuard`] decrement a
85    /// reference to the counter.
86    ///
87    /// Note: when "recursive-protection" feature is enabled, this crate uses additional stack overflow protection
88    /// for some of its recursive methods. See [`recursive::recursive`] for more information.
89    pub(crate) struct RecursionCounter {
90        remaining_depth: Rc<Cell<usize>>,
91    }
92
93    impl RecursionCounter {
94        /// Creates a [`RecursionCounter`] with the specified maximum
95        /// depth
96        pub fn new(remaining_depth: usize) -> Self {
97            Self {
98                remaining_depth: Rc::new(remaining_depth.into()),
99            }
100        }
101
102        /// Decreases the remaining depth by 1.
103        ///
104        /// Returns [`Err`] if the remaining depth falls to 0.
105        ///
106        /// Returns a [`DepthGuard`] which will adds 1 to the
107        /// remaining depth upon drop;
108        pub fn try_decrease(&self) -> Result<DepthGuard, ParserError> {
109            let old_value = self.remaining_depth.get();
110            // ran out of space
111            if old_value == 0 {
112                Err(ParserError::RecursionLimitExceeded)
113            } else {
114                self.remaining_depth.set(old_value - 1);
115                Ok(DepthGuard::new(Rc::clone(&self.remaining_depth)))
116            }
117        }
118    }
119
120    /// Guard that increases the remaining depth by 1 on drop
121    pub struct DepthGuard {
122        remaining_depth: Rc<Cell<usize>>,
123    }
124
125    impl DepthGuard {
126        fn new(remaining_depth: Rc<Cell<usize>>) -> Self {
127            Self { remaining_depth }
128        }
129    }
130    impl Drop for DepthGuard {
131        fn drop(&mut self) {
132            let old_value = self.remaining_depth.get();
133            self.remaining_depth.set(old_value + 1);
134        }
135    }
136}
137
138#[cfg(not(feature = "std"))]
139mod recursion {
140    /// Implementation [`RecursionCounter`] if std is NOT available (and does not
141    /// guard against stack overflow).
142    ///
143    /// Has the same API as the std [`RecursionCounter`] implementation
144    /// but does not actually limit stack depth.
145    pub(crate) struct RecursionCounter {}
146
147    impl RecursionCounter {
148        pub fn new(_remaining_depth: usize) -> Self {
149            Self {}
150        }
151        pub fn try_decrease(&self) -> Result<DepthGuard, super::ParserError> {
152            Ok(DepthGuard {})
153        }
154    }
155
156    pub struct DepthGuard {}
157}
158
159#[derive(PartialEq, Eq)]
160/// Indicates whether a parser element is optional or mandatory.
161pub enum IsOptional {
162    /// The element is optional.
163    Optional,
164    /// The element is mandatory.
165    Mandatory,
166}
167
168/// Indicates if a table expression is lateral.
169pub enum IsLateral {
170    /// The expression is lateral.
171    Lateral,
172    /// The expression is not lateral.
173    NotLateral,
174}
175
176/// Represents a wildcard expression used in SELECT lists.
177pub enum WildcardExpr {
178    /// A specific expression used instead of a wildcard.
179    Expr(Expr),
180    /// A qualified wildcard like `table.*`.
181    QualifiedWildcard(ObjectName),
182    /// An unqualified `*` wildcard.
183    Wildcard,
184}
185
186impl From<TokenizerError> for ParserError {
187    fn from(e: TokenizerError) -> Self {
188        ParserError::TokenizerError(e.to_string())
189    }
190}
191
192impl fmt::Display for ParserError {
193    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
194        write!(
195            f,
196            "sql parser error: {}",
197            match self {
198                ParserError::TokenizerError(s) => s,
199                ParserError::ParserError(s) => s,
200                ParserError::RecursionLimitExceeded => "recursion limit exceeded",
201            }
202        )
203    }
204}
205
206impl core::error::Error for ParserError {}
207
208// By default, allow expressions up to this deep before erroring
209const DEFAULT_REMAINING_DEPTH: usize = 50;
210
211// A constant EOF token that can be referenced.
212const EOF_TOKEN: TokenWithSpan = TokenWithSpan {
213    token: Token::EOF,
214    span: Span {
215        start: Location { line: 0, column: 0 },
216        end: Location { line: 0, column: 0 },
217    },
218};
219
220/// Composite types declarations using angle brackets syntax can be arbitrary
221/// nested such that the following declaration is possible:
222///      `ARRAY<ARRAY<INT>>`
223/// But the tokenizer recognizes the `>>` as a ShiftRight token.
224/// We work around that limitation when parsing a data type by accepting
225/// either a `>` or `>>` token in such cases, remembering which variant we
226/// matched.
227/// In the latter case having matched a `>>`, the parent type will not look to
228/// match its closing `>` as a result since that will have taken place at the
229/// child type.
230///
231/// See [Parser::parse_data_type] for details
232struct MatchedTrailingBracket(bool);
233
234impl From<bool> for MatchedTrailingBracket {
235    fn from(value: bool) -> Self {
236        Self(value)
237    }
238}
239
240/// Options that control how the [`Parser`] parses SQL text
241#[derive(Debug, Clone, PartialEq, Eq)]
242pub struct ParserOptions {
243    /// Allow trailing commas in lists (e.g. `a, b,`).
244    pub trailing_commas: bool,
245    /// Controls how literal values are unescaped. See
246    /// [`Tokenizer::with_unescape`] for more details.
247    pub unescape: bool,
248    /// Controls if the parser expects a semi-colon token
249    /// between statements. Default is `true`.
250    pub require_semicolon_stmt_delimiter: bool,
251}
252
253impl Default for ParserOptions {
254    fn default() -> Self {
255        Self {
256            trailing_commas: false,
257            unescape: true,
258            require_semicolon_stmt_delimiter: true,
259        }
260    }
261}
262
263impl ParserOptions {
264    /// Create a new [`ParserOptions`]
265    pub fn new() -> Self {
266        Default::default()
267    }
268
269    /// Set if trailing commas are allowed.
270    ///
271    /// If this option is `false` (the default), the following SQL will
272    /// not parse. If the option is `true`, the SQL will parse.
273    ///
274    /// ```sql
275    ///  SELECT
276    ///   foo,
277    ///   bar,
278    ///  FROM baz
279    /// ```
280    pub fn with_trailing_commas(mut self, trailing_commas: bool) -> Self {
281        self.trailing_commas = trailing_commas;
282        self
283    }
284
285    /// Set if literal values are unescaped. Defaults to true. See
286    /// [`Tokenizer::with_unescape`] for more details.
287    pub fn with_unescape(mut self, unescape: bool) -> Self {
288        self.unescape = unescape;
289        self
290    }
291}
292
293#[derive(Copy, Clone)]
294enum ParserState {
295    /// The default state of the parser.
296    Normal,
297    /// The state when parsing a CONNECT BY expression. This allows parsing
298    /// PRIOR expressions while still allowing prior as an identifier name
299    /// in other contexts.
300    ConnectBy,
301    /// The state when parsing column definitions.  This state prohibits
302    /// NOT NULL as an alias for IS NOT NULL.  For example:
303    /// ```sql
304    /// CREATE TABLE foo (abc BIGINT NOT NULL);
305    /// ```
306    ColumnDefinition,
307}
308
309/// A SQL Parser
310///
311/// This struct is the main entry point for parsing SQL queries.
312///
313/// # Functionality:
314/// * Parsing SQL: see examples on [`Parser::new`] and [`Parser::parse_sql`]
315/// * Controlling recursion: See [`Parser::with_recursion_limit`]
316/// * Controlling parser options: See [`Parser::with_options`]
317/// * Providing your own tokens: See [`Parser::with_tokens`]
318///
319/// # Internals
320///
321/// The parser uses a [`Tokenizer`] to tokenize the input SQL string into a
322/// `Vec` of [`TokenWithSpan`]s and maintains an `index` to the current token
323/// being processed. The token vec may contain multiple SQL statements.
324///
325/// * The "current" token is the token at `index - 1`
326/// * The "next" token is the token at `index`
327/// * The "previous" token is the token at `index - 2`
328///
329/// If `index` is equal to the length of the token stream, the 'next' token is
330/// [`Token::EOF`].
331///
332/// For example, the SQL string "SELECT * FROM foo" will be tokenized into
333/// following tokens:
334/// ```text
335///  [
336///    "SELECT", // token index 0
337///    " ",      // whitespace
338///    "*",
339///    " ",
340///    "FROM",
341///    " ",
342///    "foo"
343///   ]
344/// ```
345///
346///
347pub struct Parser<'a> {
348    /// The tokens
349    tokens: Vec<TokenWithSpan>,
350    /// The index of the first unprocessed token in [`Parser::tokens`].
351    index: usize,
352    /// The current state of the parser.
353    state: ParserState,
354    /// The SQL dialect to use.
355    dialect: &'a dyn Dialect,
356    /// Additional options that allow you to mix & match behavior
357    /// otherwise constrained to certain dialects (e.g. trailing
358    /// commas) and/or format of parse (e.g. unescaping).
359    options: ParserOptions,
360    /// Ensures the stack does not overflow by limiting recursion depth.
361    recursion_counter: RecursionCounter,
362}
363
364impl<'a> Parser<'a> {
365    /// Create a parser for a [`Dialect`]
366    ///
367    /// See also [`Parser::parse_sql`]
368    ///
369    /// Example:
370    /// ```
371    /// # use sqlparser::{parser::{Parser, ParserError}, dialect::GenericDialect};
372    /// # fn main() -> Result<(), ParserError> {
373    /// let dialect = GenericDialect{};
374    /// let statements = Parser::new(&dialect)
375    ///   .try_with_sql("SELECT * FROM foo")?
376    ///   .parse_statements()?;
377    /// # Ok(())
378    /// # }
379    /// ```
380    pub fn new(dialect: &'a dyn Dialect) -> Self {
381        Self {
382            tokens: vec![],
383            index: 0,
384            state: ParserState::Normal,
385            dialect,
386            recursion_counter: RecursionCounter::new(DEFAULT_REMAINING_DEPTH),
387            options: ParserOptions::new().with_trailing_commas(dialect.supports_trailing_commas()),
388        }
389    }
390
391    /// Specify the maximum recursion limit while parsing.
392    ///
393    /// [`Parser`] prevents stack overflows by returning
394    /// [`ParserError::RecursionLimitExceeded`] if the parser exceeds
395    /// this depth while processing the query.
396    ///
397    /// Example:
398    /// ```
399    /// # use sqlparser::{parser::{Parser, ParserError}, dialect::GenericDialect};
400    /// # fn main() -> Result<(), ParserError> {
401    /// let dialect = GenericDialect{};
402    /// let result = Parser::new(&dialect)
403    ///   .with_recursion_limit(1)
404    ///   .try_with_sql("SELECT * FROM foo WHERE (a OR (b OR (c OR d)))")?
405    ///   .parse_statements();
406    ///   assert_eq!(result, Err(ParserError::RecursionLimitExceeded));
407    /// # Ok(())
408    /// # }
409    /// ```
410    ///
411    /// Note: when "recursive-protection" feature is enabled, this crate uses additional stack overflow protection
412    //  for some of its recursive methods. See [`recursive::recursive`] for more information.
413    pub fn with_recursion_limit(mut self, recursion_limit: usize) -> Self {
414        self.recursion_counter = RecursionCounter::new(recursion_limit);
415        self
416    }
417
418    /// Specify additional parser options
419    ///
420    /// [`Parser`] supports additional options ([`ParserOptions`])
421    /// that allow you to mix & match behavior otherwise constrained
422    /// to certain dialects (e.g. trailing commas).
423    ///
424    /// Example:
425    /// ```
426    /// # use sqlparser::{parser::{Parser, ParserError, ParserOptions}, dialect::GenericDialect};
427    /// # fn main() -> Result<(), ParserError> {
428    /// let dialect = GenericDialect{};
429    /// let options = ParserOptions::new()
430    ///    .with_trailing_commas(true)
431    ///    .with_unescape(false);
432    /// let result = Parser::new(&dialect)
433    ///   .with_options(options)
434    ///   .try_with_sql("SELECT a, b, COUNT(*), FROM foo GROUP BY a, b,")?
435    ///   .parse_statements();
436    ///   assert!(matches!(result, Ok(_)));
437    /// # Ok(())
438    /// # }
439    /// ```
440    pub fn with_options(mut self, options: ParserOptions) -> Self {
441        self.options = options;
442        self
443    }
444
445    /// Reset this parser to parse the specified token stream
446    pub fn with_tokens_with_locations(mut self, tokens: Vec<TokenWithSpan>) -> Self {
447        self.tokens = tokens;
448        self.index = 0;
449        self
450    }
451
452    /// Reset this parser state to parse the specified tokens
453    pub fn with_tokens(self, tokens: Vec<Token>) -> Self {
454        // Put in dummy locations
455        let tokens_with_locations: Vec<TokenWithSpan> = tokens
456            .into_iter()
457            .map(|token| TokenWithSpan {
458                token,
459                span: Span::empty(),
460            })
461            .collect();
462        self.with_tokens_with_locations(tokens_with_locations)
463    }
464
465    /// Tokenize the sql string and sets this [`Parser`]'s state to
466    /// parse the resulting tokens
467    ///
468    /// Returns an error if there was an error tokenizing the SQL string.
469    ///
470    /// See example on [`Parser::new()`] for an example
471    pub fn try_with_sql(self, sql: &str) -> Result<Self, ParserError> {
472        debug!("Parsing sql '{sql}'...");
473        let tokens = Tokenizer::new(self.dialect, sql)
474            .with_unescape(self.options.unescape)
475            .tokenize_with_location()?;
476        Ok(self.with_tokens_with_locations(tokens))
477    }
478
479    /// Parse potentially multiple statements
480    ///
481    /// Example
482    /// ```
483    /// # use sqlparser::{parser::{Parser, ParserError}, dialect::GenericDialect};
484    /// # fn main() -> Result<(), ParserError> {
485    /// let dialect = GenericDialect{};
486    /// let statements = Parser::new(&dialect)
487    ///   // Parse a SQL string with 2 separate statements
488    ///   .try_with_sql("SELECT * FROM foo; SELECT * FROM bar;")?
489    ///   .parse_statements()?;
490    /// assert_eq!(statements.len(), 2);
491    /// # Ok(())
492    /// # }
493    /// ```
494    pub fn parse_statements(&mut self) -> Result<Vec<Statement>, ParserError> {
495        let mut stmts = Vec::new();
496        let mut expecting_statement_delimiter = false;
497        loop {
498            // ignore empty statements (between successive statement delimiters)
499            while self.consume_token(&Token::SemiColon) {
500                expecting_statement_delimiter = false;
501            }
502
503            if !self.options.require_semicolon_stmt_delimiter {
504                expecting_statement_delimiter = false;
505            }
506
507            match &self.peek_token_ref().token {
508                Token::EOF => break,
509
510                // end of statement
511                Token::Word(word)
512                    if expecting_statement_delimiter && word.keyword == Keyword::END =>
513                {
514                    break;
515                }
516                _ => {}
517            }
518
519            if expecting_statement_delimiter {
520                return self.expected_ref("end of statement", self.peek_token_ref());
521            }
522
523            let statement = self.parse_statement()?;
524            stmts.push(statement);
525            expecting_statement_delimiter = true;
526        }
527        Ok(stmts)
528    }
529
530    /// Convenience method to parse a string with one or more SQL
531    /// statements into produce an Abstract Syntax Tree (AST).
532    ///
533    /// Example
534    /// ```
535    /// # use sqlparser::{parser::{Parser, ParserError}, dialect::GenericDialect};
536    /// # fn main() -> Result<(), ParserError> {
537    /// let dialect = GenericDialect{};
538    /// let statements = Parser::parse_sql(
539    ///   &dialect, "SELECT * FROM foo"
540    /// )?;
541    /// assert_eq!(statements.len(), 1);
542    /// # Ok(())
543    /// # }
544    /// ```
545    pub fn parse_sql(dialect: &dyn Dialect, sql: &str) -> Result<Vec<Statement>, ParserError> {
546        Parser::new(dialect).try_with_sql(sql)?.parse_statements()
547    }
548
549    /// Parses the given `sql` into an Abstract Syntax Tree (AST), returning
550    /// also encountered source code comments.
551    ///
552    /// See [Parser::parse_sql].
553    pub fn parse_sql_with_comments(
554        dialect: &'a dyn Dialect,
555        sql: &str,
556    ) -> Result<(Vec<Statement>, comments::Comments), ParserError> {
557        let mut p = Parser::new(dialect).try_with_sql(sql)?;
558        p.parse_statements().map(|stmts| (stmts, p.into_comments()))
559    }
560
561    /// Consumes this parser returning comments from the parsed token stream.
562    fn into_comments(self) -> comments::Comments {
563        let mut comments = comments::Comments::default();
564        for t in self.tokens.into_iter() {
565            match t.token {
566                Token::Whitespace(Whitespace::SingleLineComment { comment, prefix }) => {
567                    comments.offer(comments::CommentWithSpan {
568                        comment: comments::Comment::SingleLine {
569                            content: comment,
570                            prefix,
571                        },
572                        span: t.span,
573                    });
574                }
575                Token::Whitespace(Whitespace::MultiLineComment(comment)) => {
576                    comments.offer(comments::CommentWithSpan {
577                        comment: comments::Comment::MultiLine(comment),
578                        span: t.span,
579                    });
580                }
581                _ => {}
582            }
583        }
584        comments
585    }
586
587    /// Parse a single top-level statement (such as SELECT, INSERT, CREATE, etc.),
588    /// stopping before the statement separator, if any.
589    pub fn parse_statement(&mut self) -> Result<Statement, ParserError> {
590        let _guard = self.recursion_counter.try_decrease()?;
591
592        // allow the dialect to override statement parsing
593        if let Some(statement) = self.dialect.parse_statement(self) {
594            return statement;
595        }
596
597        let next_token = self.next_token();
598        match &next_token.token {
599            Token::Word(w) => match w.keyword {
600                Keyword::KILL => self.parse_kill(),
601                Keyword::FLUSH => self.parse_flush(),
602                Keyword::DESC => self.parse_explain(DescribeAlias::Desc),
603                Keyword::DESCRIBE => self.parse_explain(DescribeAlias::Describe),
604                Keyword::EXPLAIN => self.parse_explain(DescribeAlias::Explain),
605                Keyword::ANALYZE => self.parse_analyze().map(Into::into),
606                Keyword::CASE => {
607                    self.prev_token();
608                    self.parse_case_stmt().map(Into::into)
609                }
610                Keyword::IF => {
611                    self.prev_token();
612                    self.parse_if_stmt().map(Into::into)
613                }
614                Keyword::WHILE => {
615                    self.prev_token();
616                    self.parse_while().map(Into::into)
617                }
618                Keyword::RAISE => {
619                    self.prev_token();
620                    self.parse_raise_stmt().map(Into::into)
621                }
622                Keyword::SELECT | Keyword::WITH | Keyword::VALUES | Keyword::FROM => {
623                    self.prev_token();
624                    self.parse_query().map(Into::into)
625                }
626                Keyword::TRUNCATE => self.parse_truncate().map(Into::into),
627                Keyword::ATTACH => {
628                    if dialect_of!(self is DuckDbDialect) {
629                        self.parse_attach_duckdb_database()
630                    } else {
631                        self.parse_attach_database()
632                    }
633                }
634                Keyword::DETACH if self.dialect.supports_detach() => {
635                    self.parse_detach_duckdb_database()
636                }
637                Keyword::MSCK => self.parse_msck().map(Into::into),
638                Keyword::CREATE => self.parse_create(),
639                Keyword::CACHE => self.parse_cache_table(),
640                Keyword::DROP => self.parse_drop(),
641                Keyword::DISCARD => self.parse_discard(),
642                Keyword::DECLARE => self.parse_declare(),
643                Keyword::FETCH => self.parse_fetch_statement(),
644                Keyword::DELETE => self.parse_delete(next_token),
645                Keyword::INSERT => self.parse_insert(next_token),
646                Keyword::REPLACE => self.parse_replace(next_token),
647                Keyword::UNCACHE => self.parse_uncache_table(),
648                Keyword::UPDATE => self.parse_update(next_token),
649                Keyword::ALTER => self.parse_alter(),
650                Keyword::CALL => self.parse_call(),
651                Keyword::COPY => self.parse_copy(),
652                Keyword::OPEN => {
653                    self.prev_token();
654                    self.parse_open()
655                }
656                Keyword::CLOSE => self.parse_close(),
657                Keyword::SET => self.parse_set(),
658                Keyword::SHOW => self.parse_show(),
659                Keyword::USE => self.parse_use(),
660                Keyword::GRANT => self.parse_grant().map(Into::into),
661                Keyword::DENY => {
662                    self.prev_token();
663                    self.parse_deny()
664                }
665                Keyword::REVOKE => self.parse_revoke().map(Into::into),
666                Keyword::START => self.parse_start_transaction(),
667                Keyword::BEGIN => self.parse_begin(),
668                Keyword::END => self.parse_end(),
669                Keyword::SAVEPOINT => self.parse_savepoint(),
670                Keyword::RELEASE => self.parse_release(),
671                Keyword::COMMIT => self.parse_commit(),
672                Keyword::RAISERROR => Ok(self.parse_raiserror()?),
673                Keyword::THROW => {
674                    self.prev_token();
675                    self.parse_throw().map(Into::into)
676                }
677                Keyword::ROLLBACK => self.parse_rollback(),
678                Keyword::ASSERT => self.parse_assert(),
679                // `PREPARE`, `EXECUTE` and `DEALLOCATE` are Postgres-specific
680                // syntaxes. They are used for Postgres prepared statement.
681                Keyword::DEALLOCATE => self.parse_deallocate(),
682                Keyword::EXECUTE | Keyword::EXEC => self.parse_execute(),
683                Keyword::PREPARE => self.parse_prepare(),
684                Keyword::MERGE => self.parse_merge(next_token).map(Into::into),
685                // `LISTEN`, `UNLISTEN` and `NOTIFY` are Postgres-specific
686                // syntaxes. They are used for Postgres statement.
687                Keyword::LISTEN if self.dialect.supports_listen_notify() => self.parse_listen(),
688                Keyword::UNLISTEN if self.dialect.supports_listen_notify() => self.parse_unlisten(),
689                Keyword::NOTIFY if self.dialect.supports_listen_notify() => self.parse_notify(),
690                // `PRAGMA` is sqlite specific https://www.sqlite.org/pragma.html
691                Keyword::PRAGMA => self.parse_pragma(),
692                Keyword::UNLOAD => {
693                    self.prev_token();
694                    self.parse_unload()
695                }
696                Keyword::RENAME => self.parse_rename(),
697                // `INSTALL` is duckdb specific https://duckdb.org/docs/extensions/overview
698                Keyword::INSTALL if self.dialect.supports_install() => self.parse_install(),
699                Keyword::LOAD => self.parse_load(),
700                Keyword::LOCK => {
701                    self.prev_token();
702                    self.parse_lock_statement().map(Into::into)
703                }
704                Keyword::OPTIMIZE if self.dialect.supports_optimize_table() => {
705                    self.parse_optimize_table()
706                }
707                // `COMMENT` is snowflake specific https://docs.snowflake.com/en/sql-reference/sql/comment
708                Keyword::COMMENT if self.dialect.supports_comment_on() => self.parse_comment(),
709                Keyword::PRINT => self.parse_print(),
710                // `WAITFOR` is MSSQL specific https://learn.microsoft.com/en-us/sql/t-sql/language-elements/waitfor-transact-sql
711                Keyword::WAITFOR => self.parse_waitfor(),
712                Keyword::RETURN => self.parse_return(),
713                Keyword::EXPORT => {
714                    self.prev_token();
715                    self.parse_export_data()
716                }
717                Keyword::VACUUM => {
718                    self.prev_token();
719                    self.parse_vacuum()
720                }
721                Keyword::RESET => self.parse_reset().map(Into::into),
722                _ => self.expected("an SQL statement", next_token),
723            },
724            Token::LParen => {
725                self.prev_token();
726                self.parse_query().map(Into::into)
727            }
728            _ => self.expected("an SQL statement", next_token),
729        }
730    }
731
732    /// Parse a `CASE` statement.
733    ///
734    /// See [Statement::Case]
735    pub fn parse_case_stmt(&mut self) -> Result<CaseStatement, ParserError> {
736        let case_token = self.expect_keyword(Keyword::CASE)?;
737
738        let match_expr = if self.peek_keyword(Keyword::WHEN) {
739            None
740        } else {
741            Some(self.parse_expr()?)
742        };
743
744        self.expect_keyword_is(Keyword::WHEN)?;
745        let when_blocks = self.parse_keyword_separated(Keyword::WHEN, |parser| {
746            parser.parse_conditional_statement_block(&[Keyword::WHEN, Keyword::ELSE, Keyword::END])
747        })?;
748
749        let else_block = if self.parse_keyword(Keyword::ELSE) {
750            Some(self.parse_conditional_statement_block(&[Keyword::END])?)
751        } else {
752            None
753        };
754
755        let mut end_case_token = self.expect_keyword(Keyword::END)?;
756        if self.peek_keyword(Keyword::CASE) {
757            end_case_token = self.expect_keyword(Keyword::CASE)?;
758        }
759
760        Ok(CaseStatement {
761            case_token: AttachedToken(case_token),
762            match_expr,
763            when_blocks,
764            else_block,
765            end_case_token: AttachedToken(end_case_token),
766        })
767    }
768
769    /// Parse an `IF` statement.
770    ///
771    /// See [Statement::If]
772    pub fn parse_if_stmt(&mut self) -> Result<IfStatement, ParserError> {
773        self.expect_keyword_is(Keyword::IF)?;
774        let if_block = self.parse_conditional_statement_block(&[
775            Keyword::ELSE,
776            Keyword::ELSEIF,
777            Keyword::END,
778        ])?;
779
780        let elseif_blocks = if self.parse_keyword(Keyword::ELSEIF) {
781            self.parse_keyword_separated(Keyword::ELSEIF, |parser| {
782                parser.parse_conditional_statement_block(&[
783                    Keyword::ELSEIF,
784                    Keyword::ELSE,
785                    Keyword::END,
786                ])
787            })?
788        } else {
789            vec![]
790        };
791
792        let else_block = if self.parse_keyword(Keyword::ELSE) {
793            Some(self.parse_conditional_statement_block(&[Keyword::END])?)
794        } else {
795            None
796        };
797
798        self.expect_keyword_is(Keyword::END)?;
799        let end_token = self.expect_keyword(Keyword::IF)?;
800
801        Ok(IfStatement {
802            if_block,
803            elseif_blocks,
804            else_block,
805            end_token: Some(AttachedToken(end_token)),
806        })
807    }
808
809    /// Parse a `WHILE` statement.
810    ///
811    /// See [Statement::While]
812    fn parse_while(&mut self) -> Result<WhileStatement, ParserError> {
813        self.expect_keyword_is(Keyword::WHILE)?;
814        let while_block = self.parse_conditional_statement_block(&[Keyword::END])?;
815
816        Ok(WhileStatement { while_block })
817    }
818
819    /// Parses an expression and associated list of statements
820    /// belonging to a conditional statement like `IF` or `WHEN` or `WHILE`.
821    ///
822    /// Example:
823    /// ```sql
824    /// IF condition THEN statement1; statement2;
825    /// ```
826    fn parse_conditional_statement_block(
827        &mut self,
828        terminal_keywords: &[Keyword],
829    ) -> Result<ConditionalStatementBlock, ParserError> {
830        let start_token = self.get_current_token().clone(); // self.expect_keyword(keyword)?;
831        let mut then_token = None;
832
833        let condition = match &start_token.token {
834            Token::Word(w) if w.keyword == Keyword::ELSE => None,
835            Token::Word(w) if w.keyword == Keyword::WHILE => {
836                let expr = self.parse_expr()?;
837                Some(expr)
838            }
839            _ => {
840                let expr = self.parse_expr()?;
841                then_token = Some(AttachedToken(self.expect_keyword(Keyword::THEN)?));
842                Some(expr)
843            }
844        };
845
846        let conditional_statements = self.parse_conditional_statements(terminal_keywords)?;
847
848        Ok(ConditionalStatementBlock {
849            start_token: AttachedToken(start_token),
850            condition,
851            then_token,
852            conditional_statements,
853        })
854    }
855
856    /// Parse a BEGIN/END block or a sequence of statements
857    /// This could be inside of a conditional (IF, CASE, WHILE etc.) or an object body defined optionally BEGIN/END and one or more statements.
858    pub(crate) fn parse_conditional_statements(
859        &mut self,
860        terminal_keywords: &[Keyword],
861    ) -> Result<ConditionalStatements, ParserError> {
862        let conditional_statements = if self.peek_keyword(Keyword::BEGIN) {
863            let begin_token = self.expect_keyword(Keyword::BEGIN)?;
864            let statements = self.parse_statement_list(terminal_keywords)?;
865            let end_token = self.expect_keyword(Keyword::END)?;
866
867            ConditionalStatements::BeginEnd(BeginEndStatements {
868                begin_token: AttachedToken(begin_token),
869                statements,
870                end_token: AttachedToken(end_token),
871            })
872        } else {
873            ConditionalStatements::Sequence {
874                statements: self.parse_statement_list(terminal_keywords)?,
875            }
876        };
877        Ok(conditional_statements)
878    }
879
880    /// Parse a `RAISE` statement.
881    ///
882    /// See [Statement::Raise]
883    pub fn parse_raise_stmt(&mut self) -> Result<RaiseStatement, ParserError> {
884        self.expect_keyword_is(Keyword::RAISE)?;
885
886        let value = if self.parse_keywords(&[Keyword::USING, Keyword::MESSAGE]) {
887            self.expect_token(&Token::Eq)?;
888            Some(RaiseStatementValue::UsingMessage(self.parse_expr()?))
889        } else {
890            self.maybe_parse(|parser| parser.parse_expr().map(RaiseStatementValue::Expr))?
891        };
892
893        Ok(RaiseStatement { value })
894    }
895    /// Parse a COMMENT statement.
896    ///
897    /// See [Statement::Comment]
898    pub fn parse_comment(&mut self) -> Result<Statement, ParserError> {
899        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
900
901        self.expect_keyword_is(Keyword::ON)?;
902        let token = self.next_token();
903
904        let (object_type, object_name) = match token.token {
905            Token::Word(w) if w.keyword == Keyword::COLLATION => {
906                (CommentObject::Collation, self.parse_object_name(false)?)
907            }
908            Token::Word(w) if w.keyword == Keyword::COLUMN => {
909                (CommentObject::Column, self.parse_object_name(false)?)
910            }
911            Token::Word(w) if w.keyword == Keyword::DATABASE => {
912                (CommentObject::Database, self.parse_object_name(false)?)
913            }
914            Token::Word(w) if w.keyword == Keyword::DOMAIN => {
915                (CommentObject::Domain, self.parse_object_name(false)?)
916            }
917            Token::Word(w) if w.keyword == Keyword::EXTENSION => {
918                (CommentObject::Extension, self.parse_object_name(false)?)
919            }
920            Token::Word(w) if w.keyword == Keyword::FUNCTION => {
921                (CommentObject::Function, self.parse_object_name(false)?)
922            }
923            Token::Word(w) if w.keyword == Keyword::INDEX => {
924                (CommentObject::Index, self.parse_object_name(false)?)
925            }
926            Token::Word(w) if w.keyword == Keyword::MATERIALIZED => {
927                self.expect_keyword_is(Keyword::VIEW)?;
928                (
929                    CommentObject::MaterializedView,
930                    self.parse_object_name(false)?,
931                )
932            }
933            Token::Word(w) if w.keyword == Keyword::PROCEDURE => {
934                (CommentObject::Procedure, self.parse_object_name(false)?)
935            }
936            Token::Word(w) if w.keyword == Keyword::ROLE => {
937                (CommentObject::Role, self.parse_object_name(false)?)
938            }
939            Token::Word(w) if w.keyword == Keyword::SCHEMA => {
940                (CommentObject::Schema, self.parse_object_name(false)?)
941            }
942            Token::Word(w) if w.keyword == Keyword::SEQUENCE => {
943                (CommentObject::Sequence, self.parse_object_name(false)?)
944            }
945            Token::Word(w) if w.keyword == Keyword::TABLE => {
946                (CommentObject::Table, self.parse_object_name(false)?)
947            }
948            Token::Word(w) if w.keyword == Keyword::TYPE => {
949                (CommentObject::Type, self.parse_object_name(false)?)
950            }
951            Token::Word(w) if w.keyword == Keyword::USER => {
952                (CommentObject::User, self.parse_object_name(false)?)
953            }
954            Token::Word(w) if w.keyword == Keyword::VIEW => {
955                (CommentObject::View, self.parse_object_name(false)?)
956            }
957            _ => self.expected("comment object_type", token)?,
958        };
959
960        self.expect_keyword_is(Keyword::IS)?;
961        let comment = if self.parse_keyword(Keyword::NULL) {
962            None
963        } else {
964            Some(self.parse_literal_string()?)
965        };
966        Ok(Statement::Comment {
967            object_type,
968            object_name,
969            comment,
970            if_exists,
971        })
972    }
973
974    /// Parse `FLUSH` statement.
975    pub fn parse_flush(&mut self) -> Result<Statement, ParserError> {
976        let mut channel = None;
977        let mut tables: Vec<ObjectName> = vec![];
978        let mut read_lock = false;
979        let mut export = false;
980
981        if !dialect_of!(self is MySqlDialect | GenericDialect) {
982            return parser_err!(
983                "Unsupported statement FLUSH",
984                self.peek_token_ref().span.start
985            );
986        }
987
988        let location = if self.parse_keyword(Keyword::NO_WRITE_TO_BINLOG) {
989            Some(FlushLocation::NoWriteToBinlog)
990        } else if self.parse_keyword(Keyword::LOCAL) {
991            Some(FlushLocation::Local)
992        } else {
993            None
994        };
995
996        let object_type = if self.parse_keywords(&[Keyword::BINARY, Keyword::LOGS]) {
997            FlushType::BinaryLogs
998        } else if self.parse_keywords(&[Keyword::ENGINE, Keyword::LOGS]) {
999            FlushType::EngineLogs
1000        } else if self.parse_keywords(&[Keyword::ERROR, Keyword::LOGS]) {
1001            FlushType::ErrorLogs
1002        } else if self.parse_keywords(&[Keyword::GENERAL, Keyword::LOGS]) {
1003            FlushType::GeneralLogs
1004        } else if self.parse_keywords(&[Keyword::HOSTS]) {
1005            FlushType::Hosts
1006        } else if self.parse_keyword(Keyword::PRIVILEGES) {
1007            FlushType::Privileges
1008        } else if self.parse_keyword(Keyword::OPTIMIZER_COSTS) {
1009            FlushType::OptimizerCosts
1010        } else if self.parse_keywords(&[Keyword::RELAY, Keyword::LOGS]) {
1011            if self.parse_keywords(&[Keyword::FOR, Keyword::CHANNEL]) {
1012                channel = Some(self.parse_object_name(false)?.to_string());
1013            }
1014            FlushType::RelayLogs
1015        } else if self.parse_keywords(&[Keyword::SLOW, Keyword::LOGS]) {
1016            FlushType::SlowLogs
1017        } else if self.parse_keyword(Keyword::STATUS) {
1018            FlushType::Status
1019        } else if self.parse_keyword(Keyword::USER_RESOURCES) {
1020            FlushType::UserResources
1021        } else if self.parse_keywords(&[Keyword::LOGS]) {
1022            FlushType::Logs
1023        } else if self.parse_keywords(&[Keyword::TABLES]) {
1024            loop {
1025                let next_token = self.next_token();
1026                match &next_token.token {
1027                    Token::Word(w) => match w.keyword {
1028                        Keyword::WITH => {
1029                            read_lock = self.parse_keywords(&[Keyword::READ, Keyword::LOCK]);
1030                        }
1031                        Keyword::FOR => {
1032                            export = self.parse_keyword(Keyword::EXPORT);
1033                        }
1034                        Keyword::NoKeyword => {
1035                            self.prev_token();
1036                            tables = self.parse_comma_separated(|p| p.parse_object_name(false))?;
1037                        }
1038                        _ => {}
1039                    },
1040                    _ => {
1041                        break;
1042                    }
1043                }
1044            }
1045
1046            FlushType::Tables
1047        } else {
1048            return self.expected_ref(
1049                "BINARY LOGS, ENGINE LOGS, ERROR LOGS, GENERAL LOGS, HOSTS, LOGS, PRIVILEGES, OPTIMIZER_COSTS,\
1050                 RELAY LOGS [FOR CHANNEL channel], SLOW LOGS, STATUS, USER_RESOURCES",
1051                self.peek_token_ref(),
1052            );
1053        };
1054
1055        Ok(Statement::Flush {
1056            object_type,
1057            location,
1058            channel,
1059            read_lock,
1060            export,
1061            tables,
1062        })
1063    }
1064
1065    /// Parse `MSCK` statement.
1066    pub fn parse_msck(&mut self) -> Result<Msck, ParserError> {
1067        let repair = self.parse_keyword(Keyword::REPAIR);
1068        self.expect_keyword_is(Keyword::TABLE)?;
1069        let table_name = self.parse_object_name(false)?;
1070        let partition_action = self
1071            .maybe_parse(|parser| {
1072                let pa = match parser.parse_one_of_keywords(&[
1073                    Keyword::ADD,
1074                    Keyword::DROP,
1075                    Keyword::SYNC,
1076                ]) {
1077                    Some(Keyword::ADD) => Some(AddDropSync::ADD),
1078                    Some(Keyword::DROP) => Some(AddDropSync::DROP),
1079                    Some(Keyword::SYNC) => Some(AddDropSync::SYNC),
1080                    _ => None,
1081                };
1082                parser.expect_keyword_is(Keyword::PARTITIONS)?;
1083                Ok(pa)
1084            })?
1085            .unwrap_or_default();
1086        Ok(Msck {
1087            repair,
1088            table_name,
1089            partition_action,
1090        })
1091    }
1092
1093    /// Parse `TRUNCATE` statement.
1094    pub fn parse_truncate(&mut self) -> Result<Truncate, ParserError> {
1095        let table = self.parse_keyword(Keyword::TABLE);
1096        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
1097
1098        let table_names = self.parse_comma_separated(|p| {
1099            let only = p.parse_keyword(Keyword::ONLY);
1100            let name = p.parse_object_name(false)?;
1101            let has_asterisk = p.consume_token(&Token::Mul);
1102            Ok(TruncateTableTarget {
1103                name,
1104                only,
1105                has_asterisk,
1106            })
1107        })?;
1108
1109        let mut partitions = None;
1110        if self.parse_keyword(Keyword::PARTITION) {
1111            self.expect_token(&Token::LParen)?;
1112            partitions = Some(self.parse_comma_separated(Parser::parse_expr)?);
1113            self.expect_token(&Token::RParen)?;
1114        }
1115
1116        let mut identity = None;
1117        let mut cascade = None;
1118
1119        if dialect_of!(self is PostgreSqlDialect | GenericDialect) {
1120            identity = if self.parse_keywords(&[Keyword::RESTART, Keyword::IDENTITY]) {
1121                Some(TruncateIdentityOption::Restart)
1122            } else if self.parse_keywords(&[Keyword::CONTINUE, Keyword::IDENTITY]) {
1123                Some(TruncateIdentityOption::Continue)
1124            } else {
1125                None
1126            };
1127
1128            cascade = self.parse_cascade_option();
1129        };
1130
1131        let on_cluster = self.parse_optional_on_cluster()?;
1132
1133        Ok(Truncate {
1134            table_names,
1135            partitions,
1136            table,
1137            if_exists,
1138            identity,
1139            cascade,
1140            on_cluster,
1141        })
1142    }
1143
1144    fn parse_cascade_option(&mut self) -> Option<CascadeOption> {
1145        if self.parse_keyword(Keyword::CASCADE) {
1146            Some(CascadeOption::Cascade)
1147        } else if self.parse_keyword(Keyword::RESTRICT) {
1148            Some(CascadeOption::Restrict)
1149        } else {
1150            None
1151        }
1152    }
1153
1154    /// Parse options for `ATTACH DUCKDB DATABASE` statement.
1155    pub fn parse_attach_duckdb_database_options(
1156        &mut self,
1157    ) -> Result<Vec<AttachDuckDBDatabaseOption>, ParserError> {
1158        if !self.consume_token(&Token::LParen) {
1159            return Ok(vec![]);
1160        }
1161
1162        let mut options = vec![];
1163        loop {
1164            if self.parse_keyword(Keyword::READ_ONLY) {
1165                let boolean = if self.parse_keyword(Keyword::TRUE) {
1166                    Some(true)
1167                } else if self.parse_keyword(Keyword::FALSE) {
1168                    Some(false)
1169                } else {
1170                    None
1171                };
1172                options.push(AttachDuckDBDatabaseOption::ReadOnly(boolean));
1173            } else if self.parse_keyword(Keyword::TYPE) {
1174                let ident = self.parse_identifier()?;
1175                options.push(AttachDuckDBDatabaseOption::Type(ident));
1176            } else {
1177                return self
1178                    .expected_ref("expected one of: ), READ_ONLY, TYPE", self.peek_token_ref());
1179            };
1180
1181            if self.consume_token(&Token::RParen) {
1182                return Ok(options);
1183            } else if self.consume_token(&Token::Comma) {
1184                continue;
1185            } else {
1186                return self.expected_ref("expected one of: ')', ','", self.peek_token_ref());
1187            }
1188        }
1189    }
1190
1191    /// Parse `ATTACH DUCKDB DATABASE` statement.
1192    pub fn parse_attach_duckdb_database(&mut self) -> Result<Statement, ParserError> {
1193        let database = self.parse_keyword(Keyword::DATABASE);
1194        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
1195        let database_path = self.parse_identifier()?;
1196        let database_alias = if self.parse_keyword(Keyword::AS) {
1197            Some(self.parse_identifier()?)
1198        } else {
1199            None
1200        };
1201
1202        let attach_options = self.parse_attach_duckdb_database_options()?;
1203        Ok(Statement::AttachDuckDBDatabase {
1204            if_not_exists,
1205            database,
1206            database_path,
1207            database_alias,
1208            attach_options,
1209        })
1210    }
1211
1212    /// Parse `DETACH DUCKDB DATABASE` statement.
1213    pub fn parse_detach_duckdb_database(&mut self) -> Result<Statement, ParserError> {
1214        let database = self.parse_keyword(Keyword::DATABASE);
1215        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
1216        let database_alias = self.parse_identifier()?;
1217        Ok(Statement::DetachDuckDBDatabase {
1218            if_exists,
1219            database,
1220            database_alias,
1221        })
1222    }
1223
1224    /// Parse `ATTACH DATABASE` statement.
1225    pub fn parse_attach_database(&mut self) -> Result<Statement, ParserError> {
1226        let database = self.parse_keyword(Keyword::DATABASE);
1227        let database_file_name = self.parse_expr()?;
1228        self.expect_keyword_is(Keyword::AS)?;
1229        let schema_name = self.parse_identifier()?;
1230        Ok(Statement::AttachDatabase {
1231            database,
1232            schema_name,
1233            database_file_name,
1234        })
1235    }
1236
1237    /// Parse `ANALYZE` statement.
1238    pub fn parse_analyze(&mut self) -> Result<Analyze, ParserError> {
1239        let has_table_keyword = self.parse_keyword(Keyword::TABLE);
1240        let table_name = self.maybe_parse(|parser| parser.parse_object_name(false))?;
1241        let mut for_columns = false;
1242        let mut cache_metadata = false;
1243        let mut noscan = false;
1244        let mut partitions = None;
1245        let mut compute_statistics = false;
1246        let mut columns = vec![];
1247
1248        // PostgreSQL syntax: ANALYZE t (col1, col2)
1249        if table_name.is_some() && self.consume_token(&Token::LParen) {
1250            columns = self.parse_comma_separated(|p| p.parse_identifier())?;
1251            self.expect_token(&Token::RParen)?;
1252        }
1253
1254        loop {
1255            match self.parse_one_of_keywords(&[
1256                Keyword::PARTITION,
1257                Keyword::FOR,
1258                Keyword::CACHE,
1259                Keyword::NOSCAN,
1260                Keyword::COMPUTE,
1261            ]) {
1262                Some(Keyword::PARTITION) => {
1263                    self.expect_token(&Token::LParen)?;
1264                    partitions = Some(self.parse_comma_separated(Parser::parse_expr)?);
1265                    self.expect_token(&Token::RParen)?;
1266                }
1267                Some(Keyword::NOSCAN) => noscan = true,
1268                Some(Keyword::FOR) => {
1269                    self.expect_keyword_is(Keyword::COLUMNS)?;
1270
1271                    columns = self
1272                        .maybe_parse(|parser| {
1273                            parser.parse_comma_separated(|p| p.parse_identifier())
1274                        })?
1275                        .unwrap_or_default();
1276                    for_columns = true
1277                }
1278                Some(Keyword::CACHE) => {
1279                    self.expect_keyword_is(Keyword::METADATA)?;
1280                    cache_metadata = true
1281                }
1282                Some(Keyword::COMPUTE) => {
1283                    self.expect_keyword_is(Keyword::STATISTICS)?;
1284                    compute_statistics = true
1285                }
1286                _ => break,
1287            }
1288        }
1289
1290        Ok(Analyze {
1291            has_table_keyword,
1292            table_name,
1293            for_columns,
1294            columns,
1295            partitions,
1296            cache_metadata,
1297            noscan,
1298            compute_statistics,
1299        })
1300    }
1301
1302    /// Parse a new expression including wildcard & qualified wildcard.
1303    pub fn parse_wildcard_expr(&mut self) -> Result<Expr, ParserError> {
1304        let index = self.index;
1305
1306        let next_token = self.next_token();
1307        match next_token.token {
1308            t @ (Token::Word(_) | Token::SingleQuotedString(_))
1309                if self.peek_token_ref().token == Token::Period =>
1310            {
1311                let mut id_parts: Vec<Ident> = vec![match t {
1312                    Token::Word(w) => w.into_ident(next_token.span),
1313                    Token::SingleQuotedString(s) => Ident::with_quote('\'', s),
1314                    _ => {
1315                        return Err(ParserError::ParserError(
1316                            "Internal parser error: unexpected token type".to_string(),
1317                        ))
1318                    }
1319                }];
1320
1321                while self.consume_token(&Token::Period) {
1322                    let next_token = self.next_token();
1323                    match next_token.token {
1324                        Token::Word(w) => id_parts.push(w.into_ident(next_token.span)),
1325                        Token::SingleQuotedString(s) => {
1326                            // SQLite has single-quoted identifiers
1327                            id_parts.push(Ident::with_quote('\'', s))
1328                        }
1329                        Token::Placeholder(s) => {
1330                            // Snowflake uses $1, $2, etc. for positional column references
1331                            // in staged data queries like: SELECT t.$1 FROM @stage t
1332                            id_parts.push(Ident::new(s))
1333                        }
1334                        Token::Mul => {
1335                            return Ok(Expr::QualifiedWildcard(
1336                                ObjectName::from(id_parts),
1337                                AttachedToken(next_token),
1338                            ));
1339                        }
1340                        _ => {
1341                            return self.expected("an identifier or a '*' after '.'", next_token);
1342                        }
1343                    }
1344                }
1345            }
1346            Token::Mul => {
1347                return Ok(Expr::Wildcard(AttachedToken(next_token)));
1348            }
1349            // Handle parenthesized wildcard: (*)
1350            Token::LParen => {
1351                let [maybe_mul, maybe_rparen] = self.peek_tokens_ref();
1352                if maybe_mul.token == Token::Mul && maybe_rparen.token == Token::RParen {
1353                    let mul_token = self.next_token(); // consume Mul
1354                    self.next_token(); // consume RParen
1355                    return Ok(Expr::Wildcard(AttachedToken(mul_token)));
1356                }
1357            }
1358            _ => (),
1359        };
1360
1361        self.index = index;
1362        self.parse_expr()
1363    }
1364
1365    /// Parse a new expression.
1366    pub fn parse_expr(&mut self) -> Result<Expr, ParserError> {
1367        self.parse_subexpr(self.dialect.prec_unknown())
1368    }
1369
1370    /// Parse expression with optional alias and order by.
1371    pub fn parse_expr_with_alias_and_order_by(
1372        &mut self,
1373    ) -> Result<ExprWithAliasAndOrderBy, ParserError> {
1374        let expr = self.parse_expr()?;
1375
1376        fn validator(explicit: bool, kw: &Keyword, _parser: &mut Parser) -> bool {
1377            explicit || !&[Keyword::ASC, Keyword::DESC, Keyword::GROUP].contains(kw)
1378        }
1379        let alias = self.parse_optional_alias_inner(None, validator)?;
1380        let order_by = OrderByOptions {
1381            sort: self.parse_optional_order_by_sort(),
1382            nulls_first: None,
1383        };
1384        Ok(ExprWithAliasAndOrderBy {
1385            expr: ExprWithAlias { expr, alias },
1386            order_by,
1387        })
1388    }
1389
1390    /// Parse tokens until the precedence changes.
1391    #[cfg_attr(feature = "recursive-protection", recursive::recursive)]
1392    pub fn parse_subexpr(&mut self, precedence: u8) -> Result<Expr, ParserError> {
1393        let _guard = self.recursion_counter.try_decrease()?;
1394        debug!("parsing expr");
1395        let mut expr = self.parse_prefix()?;
1396
1397        expr = self.parse_compound_expr(expr, vec![])?;
1398
1399        // Parse an optional collation cast operator following `expr`.
1400        //
1401        // For example (MSSQL): t1.a COLLATE Latin1_General_CI_AS
1402        if !self.in_column_definition_state() && self.parse_keyword(Keyword::COLLATE) {
1403            expr = Expr::Collate {
1404                expr: Box::new(expr),
1405                collation: self.parse_object_name(false)?,
1406            };
1407        }
1408
1409        debug!("prefix: {expr:?}");
1410        loop {
1411            let next_precedence = self.get_next_precedence()?;
1412            debug!("next precedence: {next_precedence:?}");
1413
1414            if precedence >= next_precedence {
1415                break;
1416            }
1417
1418            // The period operator is handled exclusively by the
1419            // compound field access parsing.
1420            if Token::Period == self.peek_token_ref().token {
1421                break;
1422            }
1423
1424            expr = self.parse_infix(expr, next_precedence)?;
1425        }
1426        Ok(expr)
1427    }
1428
1429    /// Parse `ASSERT` statement.
1430    pub fn parse_assert(&mut self) -> Result<Statement, ParserError> {
1431        let condition = self.parse_expr()?;
1432        let message = if self.parse_keyword(Keyword::AS) {
1433            Some(self.parse_expr()?)
1434        } else {
1435            None
1436        };
1437
1438        Ok(Statement::Assert { condition, message })
1439    }
1440
1441    /// Parse `SAVEPOINT` statement.
1442    pub fn parse_savepoint(&mut self) -> Result<Statement, ParserError> {
1443        let name = self.parse_identifier()?;
1444        Ok(Statement::Savepoint { name })
1445    }
1446
1447    /// Parse `RELEASE` statement.
1448    pub fn parse_release(&mut self) -> Result<Statement, ParserError> {
1449        let _ = self.parse_keyword(Keyword::SAVEPOINT);
1450        let name = self.parse_identifier()?;
1451
1452        Ok(Statement::ReleaseSavepoint { name })
1453    }
1454
1455    /// Parse `LISTEN` statement.
1456    pub fn parse_listen(&mut self) -> Result<Statement, ParserError> {
1457        let channel = self.parse_identifier()?;
1458        Ok(Statement::LISTEN { channel })
1459    }
1460
1461    /// Parse `UNLISTEN` statement.
1462    pub fn parse_unlisten(&mut self) -> Result<Statement, ParserError> {
1463        let channel = if self.consume_token(&Token::Mul) {
1464            Ident::new(Expr::Wildcard(AttachedToken::empty()).to_string())
1465        } else {
1466            match self.parse_identifier() {
1467                Ok(expr) => expr,
1468                _ => {
1469                    self.prev_token();
1470                    return self.expected_ref("wildcard or identifier", self.peek_token_ref());
1471                }
1472            }
1473        };
1474        Ok(Statement::UNLISTEN { channel })
1475    }
1476
1477    /// Parse `NOTIFY` statement.
1478    pub fn parse_notify(&mut self) -> Result<Statement, ParserError> {
1479        let channel = self.parse_identifier()?;
1480        let payload = if self.consume_token(&Token::Comma) {
1481            Some(self.parse_literal_string()?)
1482        } else {
1483            None
1484        };
1485        Ok(Statement::NOTIFY { channel, payload })
1486    }
1487
1488    /// Parses a `RENAME TABLE` statement. See [Statement::RenameTable]
1489    pub fn parse_rename(&mut self) -> Result<Statement, ParserError> {
1490        if self.peek_keyword(Keyword::TABLE) {
1491            self.expect_keyword(Keyword::TABLE)?;
1492            let rename_tables = self.parse_comma_separated(|parser| {
1493                let old_name = parser.parse_object_name(false)?;
1494                parser.expect_keyword(Keyword::TO)?;
1495                let new_name = parser.parse_object_name(false)?;
1496
1497                Ok(RenameTable { old_name, new_name })
1498            })?;
1499            Ok(rename_tables.into())
1500        } else {
1501            self.expected_ref("KEYWORD `TABLE` after RENAME", self.peek_token_ref())
1502        }
1503    }
1504
1505    /// Tries to parse an expression by matching the specified word to known keywords that have a special meaning in the dialect.
1506    /// Returns `None if no match is found.
1507    fn parse_expr_prefix_by_reserved_word(
1508        &mut self,
1509        w: &Word,
1510        w_span: Span,
1511    ) -> Result<Option<Expr>, ParserError> {
1512        match w.keyword {
1513            Keyword::TRUE | Keyword::FALSE if self.dialect.supports_boolean_literals() => {
1514                self.prev_token();
1515                Ok(Some(Expr::Value(self.parse_value()?)))
1516            }
1517            Keyword::NULL => {
1518                self.prev_token();
1519                Ok(Some(Expr::Value(self.parse_value()?)))
1520            }
1521            Keyword::CURRENT_CATALOG
1522            | Keyword::CURRENT_USER
1523            | Keyword::SESSION_USER
1524            | Keyword::USER
1525            if dialect_of!(self is PostgreSqlDialect | GenericDialect) =>
1526                {
1527                    Ok(Some(Expr::Function(Function {
1528                        name: ObjectName::from(vec![w.to_ident(w_span)]),
1529                        uses_odbc_syntax: false,
1530                        parameters: FunctionArguments::None,
1531                        args: FunctionArguments::None,
1532                        null_treatment: None,
1533                        filter: None,
1534                        over: None,
1535                        within_group: vec![],
1536                    })))
1537                }
1538            Keyword::CURRENT_TIMESTAMP
1539            | Keyword::CURRENT_TIME
1540            | Keyword::CURRENT_DATE
1541            | Keyword::LOCALTIME
1542            | Keyword::LOCALTIMESTAMP => {
1543                Ok(Some(self.parse_time_functions(ObjectName::from(vec![w.to_ident(w_span)]))?))
1544            }
1545            Keyword::CASE => Ok(Some(self.parse_case_expr()?)),
1546            Keyword::CONVERT => Ok(Some(self.parse_convert_expr(false)?)),
1547            Keyword::TRY_CONVERT if self.dialect.supports_try_convert() => Ok(Some(self.parse_convert_expr(true)?)),
1548            Keyword::CAST => Ok(Some(self.parse_cast_expr(CastKind::Cast)?)),
1549            Keyword::TRY_CAST => Ok(Some(self.parse_cast_expr(CastKind::TryCast)?)),
1550            Keyword::SAFE_CAST => Ok(Some(self.parse_cast_expr(CastKind::SafeCast)?)),
1551            Keyword::EXISTS
1552            // Support parsing Databricks has a function named `exists`.
1553            if !dialect_of!(self is DatabricksDialect)
1554                || matches!(
1555                        self.peek_nth_token_ref(1).token,
1556                        Token::Word(Word {
1557                            keyword: Keyword::SELECT | Keyword::WITH,
1558                            ..
1559                        })
1560                    ) =>
1561                {
1562                    Ok(Some(self.parse_exists_expr(false)?))
1563                }
1564            Keyword::EXTRACT => Ok(Some(self.parse_extract_expr()?)),
1565            Keyword::CEIL => Ok(Some(self.parse_ceil_floor_expr(true)?)),
1566            Keyword::FLOOR => Ok(Some(self.parse_ceil_floor_expr(false)?)),
1567            Keyword::POSITION if self.peek_token_ref().token == Token::LParen => {
1568                Ok(Some(self.parse_position_expr(w.to_ident(w_span))?))
1569            }
1570            Keyword::SUBSTR | Keyword::SUBSTRING => {
1571                self.prev_token();
1572                Ok(Some(self.parse_substring()?))
1573            }
1574            Keyword::OVERLAY => Ok(Some(self.parse_overlay_expr()?)),
1575            Keyword::TRIM => Ok(Some(self.parse_trim_expr()?)),
1576            Keyword::INTERVAL => Ok(Some(self.parse_interval()?)),
1577            // Treat ARRAY[1,2,3] as an array [1,2,3], otherwise try as subquery or a function call
1578            Keyword::ARRAY if *self.peek_token_ref() == Token::LBracket => {
1579                self.expect_token(&Token::LBracket)?;
1580                Ok(Some(self.parse_array_expr(true)?))
1581            }
1582            Keyword::ARRAY
1583            if self.peek_token_ref().token == Token::LParen
1584                && !dialect_of!(self is ClickHouseDialect | DatabricksDialect) =>
1585                {
1586                    self.expect_token(&Token::LParen)?;
1587                    let query = self.parse_query()?;
1588                    self.expect_token(&Token::RParen)?;
1589                    Ok(Some(Expr::Function(Function {
1590                        name: ObjectName::from(vec![w.to_ident(w_span)]),
1591                        uses_odbc_syntax: false,
1592                        parameters: FunctionArguments::None,
1593                        args: FunctionArguments::Subquery(query),
1594                        filter: None,
1595                        null_treatment: None,
1596                        over: None,
1597                        within_group: vec![],
1598                    })))
1599                }
1600            Keyword::NOT => Ok(Some(self.parse_not()?)),
1601            Keyword::MATCH if self.dialect.supports_match_against() => {
1602                Ok(Some(self.parse_match_against()?))
1603            }
1604            Keyword::STRUCT if self.dialect.supports_struct_literal() => {
1605                let struct_expr = self.parse_struct_literal()?;
1606                Ok(Some(struct_expr))
1607            }
1608            Keyword::PRIOR if matches!(self.state, ParserState::ConnectBy) => {
1609                let expr = self.parse_subexpr(self.dialect.prec_value(Precedence::PlusMinus))?;
1610                Ok(Some(Expr::Prior(Box::new(expr))))
1611            }
1612            Keyword::MAP if *self.peek_token_ref() == Token::LBrace && self.dialect.support_map_literal_syntax() => {
1613                Ok(Some(self.parse_duckdb_map_literal()?))
1614            }
1615            Keyword::LAMBDA if self.dialect.supports_lambda_functions() => {
1616                Ok(Some(self.parse_lambda_expr()?))
1617            }
1618            _ if self.dialect.supports_geometric_types() => match w.keyword {
1619                Keyword::CIRCLE => Ok(Some(self.parse_geometric_type(GeometricTypeKind::Circle)?)),
1620                Keyword::BOX => Ok(Some(self.parse_geometric_type(GeometricTypeKind::GeometricBox)?)),
1621                Keyword::PATH => Ok(Some(self.parse_geometric_type(GeometricTypeKind::GeometricPath)?)),
1622                Keyword::LINE => Ok(Some(self.parse_geometric_type(GeometricTypeKind::Line)?)),
1623                Keyword::LSEG => Ok(Some(self.parse_geometric_type(GeometricTypeKind::LineSegment)?)),
1624                Keyword::POINT => Ok(Some(self.parse_geometric_type(GeometricTypeKind::Point)?)),
1625                Keyword::POLYGON => Ok(Some(self.parse_geometric_type(GeometricTypeKind::Polygon)?)),
1626                _ => Ok(None),
1627            },
1628            _ => Ok(None),
1629        }
1630    }
1631
1632    /// Tries to parse an expression by a word that is not known to have a special meaning in the dialect.
1633    fn parse_expr_prefix_by_unreserved_word(
1634        &mut self,
1635        w: &Word,
1636        w_span: Span,
1637    ) -> Result<Expr, ParserError> {
1638        let is_outer_join = self.peek_outer_join_operator();
1639        match &self.peek_token_ref().token {
1640            Token::LParen if !is_outer_join => {
1641                let id_parts = vec![w.to_ident(w_span)];
1642                self.parse_function(ObjectName::from(id_parts))
1643            }
1644            // string introducer https://dev.mysql.com/doc/refman/8.0/en/charset-introducer.html
1645            Token::SingleQuotedString(_)
1646            | Token::DoubleQuotedString(_)
1647            | Token::HexStringLiteral(_)
1648                if w.value.starts_with('_') =>
1649            {
1650                Ok(Expr::Prefixed {
1651                    prefix: w.to_ident(w_span),
1652                    value: self.parse_introduced_string_expr()?.into(),
1653                })
1654            }
1655            // string introducer https://dev.mysql.com/doc/refman/8.0/en/charset-introducer.html
1656            Token::SingleQuotedString(_)
1657            | Token::DoubleQuotedString(_)
1658            | Token::HexStringLiteral(_)
1659                if w.value.starts_with('_') =>
1660            {
1661                Ok(Expr::Prefixed {
1662                    prefix: w.to_ident(w_span),
1663                    value: self.parse_introduced_string_expr()?.into(),
1664                })
1665            }
1666            // An unreserved word (likely an identifier) is followed by an arrow,
1667            // which indicates a lambda function with a single, untyped parameter.
1668            // For example: `a -> a * 2`.
1669            Token::Arrow if self.dialect.supports_lambda_functions() => {
1670                self.expect_token(&Token::Arrow)?;
1671                Ok(Expr::Lambda(LambdaFunction {
1672                    params: OneOrManyWithParens::One(LambdaFunctionParameter {
1673                        name: w.to_ident(w_span),
1674                        data_type: None,
1675                    }),
1676                    body: Box::new(self.parse_expr()?),
1677                    syntax: LambdaSyntax::Arrow,
1678                }))
1679            }
1680            // An unreserved word (likely an identifier) that is followed by another word (likley a data type)
1681            // which is then followed by an arrow, which indicates a lambda function with a single, typed parameter.
1682            // For example: `a INT -> a * 2`.
1683            Token::Word(_)
1684                if self.dialect.supports_lambda_functions()
1685                    && self.peek_nth_token_ref(1).token == Token::Arrow =>
1686            {
1687                let data_type = self.parse_data_type()?;
1688                self.expect_token(&Token::Arrow)?;
1689                Ok(Expr::Lambda(LambdaFunction {
1690                    params: OneOrManyWithParens::One(LambdaFunctionParameter {
1691                        name: w.to_ident(w_span),
1692                        data_type: Some(data_type),
1693                    }),
1694                    body: Box::new(self.parse_expr()?),
1695                    syntax: LambdaSyntax::Arrow,
1696                }))
1697            }
1698            _ => Ok(Expr::Identifier(w.to_ident(w_span))),
1699        }
1700    }
1701
1702    /// Returns true if the given [ObjectName] is a single unquoted
1703    /// identifier matching `expected` (case-insensitive).
1704    fn is_simple_unquoted_object_name(name: &ObjectName, expected: &str) -> bool {
1705        if let [ObjectNamePart::Identifier(ident)] = name.0.as_slice() {
1706            ident.quote_style.is_none() && ident.value.eq_ignore_ascii_case(expected)
1707        } else {
1708            false
1709        }
1710    }
1711
1712    /// Parse an expression prefix.
1713    pub fn parse_prefix(&mut self) -> Result<Expr, ParserError> {
1714        // allow the dialect to override prefix parsing
1715        if let Some(prefix) = self.dialect.parse_prefix(self) {
1716            return prefix;
1717        }
1718
1719        // PostgreSQL allows any string literal to be preceded by a type name, indicating that the
1720        // string literal represents a literal of that type. Some examples:
1721        //
1722        //      DATE '2020-05-20'
1723        //      TIMESTAMP WITH TIME ZONE '2020-05-20 7:43:54'
1724        //      BOOL 'true'
1725        //
1726        // The first two are standard SQL, while the latter is a PostgreSQL extension. Complicating
1727        // matters is the fact that INTERVAL string literals may optionally be followed by special
1728        // keywords, e.g.:
1729        //
1730        //      INTERVAL '7' DAY
1731        //
1732        // Note also that naively `SELECT date` looks like a syntax error because the `date` type
1733        // name is not followed by a string literal, but in fact in PostgreSQL it is a valid
1734        // expression that should parse as the column name "date".
1735        let loc = self.peek_token_ref().span.start;
1736        let opt_expr = self.maybe_parse(|parser| {
1737            match parser.parse_data_type()? {
1738                DataType::Interval { .. } => parser.parse_interval(),
1739                // PostgreSQL allows almost any identifier to be used as custom data type name,
1740                // and we support that in `parse_data_type()`. But unlike Postgres we don't
1741                // have a list of globally reserved keywords (since they vary across dialects),
1742                // so given `NOT 'a' LIKE 'b'`, we'd accept `NOT` as a possible custom data type
1743                // name, resulting in `NOT 'a'` being recognized as a `TypedString` instead of
1744                // an unary negation `NOT ('a' LIKE 'b')`. To solve this, we don't accept the
1745                // `type 'string'` syntax for the custom data types at all ...
1746                //
1747                // ... with the exception of `xml '...'` on dialects that support XML
1748                // expressions, which is a valid PostgreSQL typed string literal.
1749                DataType::Custom(ref name, ref modifiers)
1750                    if modifiers.is_empty()
1751                        && Self::is_simple_unquoted_object_name(name, "xml")
1752                        && parser.dialect.supports_xml_expressions() =>
1753                {
1754                    Ok(Expr::TypedString(TypedString {
1755                        data_type: DataType::Custom(name.clone(), modifiers.clone()),
1756                        value: parser.parse_value()?,
1757                        uses_odbc_syntax: false,
1758                    }))
1759                }
1760                DataType::Custom(..) => parser_err!("dummy", loc),
1761                // MySQL supports using the `BINARY` keyword as a cast to binary type.
1762                DataType::Binary(..) if self.dialect.supports_binary_kw_as_cast() => {
1763                    Ok(Expr::Cast {
1764                        kind: CastKind::Cast,
1765                        expr: Box::new(parser.parse_expr()?),
1766                        data_type: DataType::Binary(None),
1767                        array: false,
1768                        format: None,
1769                    })
1770                }
1771                data_type => Ok(Expr::TypedString(TypedString {
1772                    data_type,
1773                    value: parser.parse_value()?,
1774                    uses_odbc_syntax: false,
1775                })),
1776            }
1777        })?;
1778
1779        if let Some(expr) = opt_expr {
1780            return Ok(expr);
1781        }
1782
1783        // Cache some dialect properties to avoid lifetime issues with the
1784        // next_token reference.
1785
1786        let dialect = self.dialect;
1787
1788        self.advance_token();
1789        let next_token_index = self.get_current_index();
1790        let next_token = self.get_current_token();
1791        let span = next_token.span;
1792        let expr = match &next_token.token {
1793            Token::Word(w) => {
1794                // The word we consumed may fall into one of two cases: it has a special meaning, or not.
1795                // For example, in Snowflake, the word `interval` may have two meanings depending on the context:
1796                // `SELECT CURRENT_DATE() + INTERVAL '1 DAY', MAX(interval) FROM tbl;`
1797                //                          ^^^^^^^^^^^^^^^^      ^^^^^^^^
1798                //                         interval expression   identifier
1799                //
1800                // We first try to parse the word and following tokens as a special expression, and if that fails,
1801                // we rollback and try to parse it as an identifier.
1802                let w = w.clone();
1803                match self.try_parse(|parser| parser.parse_expr_prefix_by_reserved_word(&w, span)) {
1804                    // This word indicated an expression prefix and parsing was successful
1805                    Ok(Some(expr)) => Ok(expr),
1806
1807                    // No expression prefix associated with this word
1808                    Ok(None) => Ok(self.parse_expr_prefix_by_unreserved_word(&w, span)?),
1809
1810                    // If parsing of the word as a special expression failed, we are facing two options:
1811                    // 1. The statement is malformed, e.g. `SELECT INTERVAL '1 DAI` (`DAI` instead of `DAY`)
1812                    // 2. The word is used as an identifier, e.g. `SELECT MAX(interval) FROM tbl`
1813                    // We first try to parse the word as an identifier and if that fails
1814                    // we rollback and return the parsing error we got from trying to parse a
1815                    // special expression (to maintain backwards compatibility of parsing errors).
1816                    Err(e) => {
1817                        if !self.dialect.is_reserved_for_identifier(w.keyword) {
1818                            if let Ok(Some(expr)) = self.maybe_parse(|parser| {
1819                                parser.parse_expr_prefix_by_unreserved_word(&w, span)
1820                            }) {
1821                                return Ok(expr);
1822                            }
1823                        }
1824                        return Err(e);
1825                    }
1826                }
1827            } // End of Token::Word
1828            // array `[1, 2, 3]`
1829            Token::LBracket => self.parse_array_expr(false),
1830            tok @ Token::Minus | tok @ Token::Plus => {
1831                let op = if *tok == Token::Plus {
1832                    UnaryOperator::Plus
1833                } else {
1834                    UnaryOperator::Minus
1835                };
1836                Ok(Expr::UnaryOp {
1837                    op,
1838                    expr: Box::new(
1839                        self.parse_subexpr(self.dialect.prec_value(Precedence::MulDivModOp))?,
1840                    ),
1841                })
1842            }
1843            Token::ExclamationMark if dialect.supports_bang_not_operator() => Ok(Expr::UnaryOp {
1844                op: UnaryOperator::BangNot,
1845                expr: Box::new(self.parse_subexpr(self.dialect.prec_value(Precedence::UnaryNot))?),
1846            }),
1847            tok @ Token::DoubleExclamationMark
1848            | tok @ Token::PGSquareRoot
1849            | tok @ Token::PGCubeRoot
1850            | tok @ Token::AtSign
1851                if dialect_is!(dialect is PostgreSqlDialect) =>
1852            {
1853                let op = match tok {
1854                    Token::DoubleExclamationMark => UnaryOperator::PGPrefixFactorial,
1855                    Token::PGSquareRoot => UnaryOperator::PGSquareRoot,
1856                    Token::PGCubeRoot => UnaryOperator::PGCubeRoot,
1857                    Token::AtSign => UnaryOperator::PGAbs,
1858                    _ => {
1859                        return Err(ParserError::ParserError(
1860                            "Internal parser error: unexpected unary operator token".to_string(),
1861                        ))
1862                    }
1863                };
1864                Ok(Expr::UnaryOp {
1865                    op,
1866                    expr: Box::new(
1867                        self.parse_subexpr(self.dialect.prec_value(Precedence::PlusMinus))?,
1868                    ),
1869                })
1870            }
1871            Token::Tilde => Ok(Expr::UnaryOp {
1872                op: UnaryOperator::BitwiseNot,
1873                expr: Box::new(self.parse_subexpr(self.dialect.prec_value(Precedence::PlusMinus))?),
1874            }),
1875            tok @ Token::Sharp
1876            | tok @ Token::AtDashAt
1877            | tok @ Token::AtAt
1878            | tok @ Token::QuestionMarkDash
1879            | tok @ Token::QuestionPipe
1880                if self.dialect.supports_geometric_types() =>
1881            {
1882                let op = match tok {
1883                    Token::Sharp => UnaryOperator::Hash,
1884                    Token::AtDashAt => UnaryOperator::AtDashAt,
1885                    Token::AtAt => UnaryOperator::DoubleAt,
1886                    Token::QuestionMarkDash => UnaryOperator::QuestionDash,
1887                    Token::QuestionPipe => UnaryOperator::QuestionPipe,
1888                    _ => {
1889                        return Err(ParserError::ParserError(format!(
1890                            "Unexpected token in unary operator parsing: {tok:?}"
1891                        )))
1892                    }
1893                };
1894                Ok(Expr::UnaryOp {
1895                    op,
1896                    expr: Box::new(
1897                        self.parse_subexpr(self.dialect.prec_value(Precedence::PlusMinus))?,
1898                    ),
1899                })
1900            }
1901            Token::EscapedStringLiteral(_) if dialect_is!(dialect is PostgreSqlDialect | GenericDialect) =>
1902            {
1903                self.prev_token();
1904                Ok(Expr::Value(self.parse_value()?))
1905            }
1906            Token::UnicodeStringLiteral(_) => {
1907                self.prev_token();
1908                Ok(Expr::Value(self.parse_value()?))
1909            }
1910            Token::Number(_, _)
1911            | Token::SingleQuotedString(_)
1912            | Token::DoubleQuotedString(_)
1913            | Token::TripleSingleQuotedString(_)
1914            | Token::TripleDoubleQuotedString(_)
1915            | Token::DollarQuotedString(_)
1916            | Token::SingleQuotedByteStringLiteral(_)
1917            | Token::DoubleQuotedByteStringLiteral(_)
1918            | Token::TripleSingleQuotedByteStringLiteral(_)
1919            | Token::TripleDoubleQuotedByteStringLiteral(_)
1920            | Token::SingleQuotedRawStringLiteral(_)
1921            | Token::DoubleQuotedRawStringLiteral(_)
1922            | Token::TripleSingleQuotedRawStringLiteral(_)
1923            | Token::TripleDoubleQuotedRawStringLiteral(_)
1924            | Token::NationalStringLiteral(_)
1925            | Token::QuoteDelimitedStringLiteral(_)
1926            | Token::NationalQuoteDelimitedStringLiteral(_)
1927            | Token::HexStringLiteral(_) => {
1928                self.prev_token();
1929                Ok(Expr::Value(self.parse_value()?))
1930            }
1931            Token::LParen => {
1932                let expr =
1933                    if let Some(expr) = self.try_parse_expr_sub_query()? {
1934                        expr
1935                    } else if let Some(lambda) = self.try_parse_lambda()? {
1936                        return Ok(lambda);
1937                    } else {
1938                        // Parentheses in expressions switch to "normal" parsing state.
1939                        // This matters for dialects (SQLite, DuckDB) where `NOT NULL` can
1940                        // be an alias for `IS NOT NULL`. In column definitions like:
1941                        //
1942                        //   CREATE TABLE t (c INT DEFAULT (42 NOT NULL) NOT NULL)
1943                        //
1944                        // The `(42 NOT NULL)` is an expression with parens, so it parses
1945                        // as `IsNotNull(42)`. The trailing `NOT NULL` is outside those
1946                        // expression parens (the outer parens are CREATE TABLE syntax),
1947                        // so it remains a column constraint.
1948                        let exprs = self.with_state(ParserState::Normal, |p| {
1949                            p.parse_comma_separated(Parser::parse_expr)
1950                        })?;
1951                        match exprs.len() {
1952                            0 => return Err(ParserError::ParserError(
1953                                "Internal parser error: parse_comma_separated returned empty list"
1954                                    .to_string(),
1955                            )),
1956                            1 => Expr::Nested(Box::new(exprs.into_iter().next().unwrap())),
1957                            _ => Expr::Tuple(exprs),
1958                        }
1959                    };
1960                self.expect_token(&Token::RParen)?;
1961                Ok(expr)
1962            }
1963            Token::Placeholder(_) | Token::Colon | Token::AtSign => {
1964                self.prev_token();
1965                Ok(Expr::Value(self.parse_value()?))
1966            }
1967            Token::LBrace => {
1968                self.prev_token();
1969                self.parse_lbrace_expr()
1970            }
1971            _ => self.expected_at("an expression", next_token_index),
1972        }?;
1973
1974        Ok(expr)
1975    }
1976
1977    fn parse_geometric_type(&mut self, kind: GeometricTypeKind) -> Result<Expr, ParserError> {
1978        Ok(Expr::TypedString(TypedString {
1979            data_type: DataType::GeometricType(kind),
1980            value: self.parse_value()?,
1981            uses_odbc_syntax: false,
1982        }))
1983    }
1984
1985    /// Try to parse an [Expr::CompoundFieldAccess] like `a.b.c` or `a.b[1].c`.
1986    /// If all the fields are `Expr::Identifier`s, return an [Expr::CompoundIdentifier] instead.
1987    /// If only the root exists, return the root.
1988    /// Parses compound expressions which may be delimited by period
1989    /// or bracket notation.
1990    /// For example: `a.b.c`, `a.b[1]`.
1991    pub fn parse_compound_expr(
1992        &mut self,
1993        root: Expr,
1994        mut chain: Vec<AccessExpr>,
1995    ) -> Result<Expr, ParserError> {
1996        let mut ending_wildcard: Option<TokenWithSpan> = None;
1997        loop {
1998            if self.consume_token(&Token::Period) {
1999                let next_token = self.peek_token_ref();
2000                match &next_token.token {
2001                    Token::Mul => {
2002                        // Postgres explicitly allows funcnm(tablenm.*) and the
2003                        // function array_agg traverses this control flow
2004                        if dialect_of!(self is PostgreSqlDialect) {
2005                            ending_wildcard = Some(self.next_token());
2006                        } else {
2007                            // Put back the consumed `.` tokens before exiting.
2008                            // If this expression is being parsed in the
2009                            // context of a projection, then the `.*` could imply
2010                            // a wildcard expansion. For example:
2011                            // `SELECT STRUCT('foo').* FROM T`
2012                            self.prev_token(); // .
2013                        }
2014
2015                        break;
2016                    }
2017                    Token::SingleQuotedString(s) => {
2018                        let expr =
2019                            Expr::Identifier(Ident::with_quote_and_span('\'', next_token.span, s));
2020                        chain.push(AccessExpr::Dot(expr));
2021                        self.advance_token(); // The consumed string
2022                    }
2023                    Token::Placeholder(s) => {
2024                        // Snowflake uses $1, $2, etc. for positional column references
2025                        // in staged data queries like: SELECT t.$1 FROM @stage t
2026                        let expr = Expr::Identifier(Ident::with_span(next_token.span, s));
2027                        chain.push(AccessExpr::Dot(expr));
2028                        self.advance_token(); // The consumed placeholder
2029                    }
2030                    // Fallback to parsing an arbitrary expression, but restrict to expression
2031                    // types that are valid after the dot operator. This ensures that e.g.
2032                    // `T.interval` is parsed as a compound identifier, not as an interval
2033                    // expression.
2034                    _ => {
2035                        let expr = self.maybe_parse(|parser| {
2036                            let expr = parser
2037                                .parse_subexpr(parser.dialect.prec_value(Precedence::Period))?;
2038                            match &expr {
2039                                Expr::CompoundFieldAccess { .. }
2040                                | Expr::CompoundIdentifier(_)
2041                                | Expr::Identifier(_)
2042                                | Expr::Value(_)
2043                                | Expr::Function(_) => Ok(expr),
2044                                _ => parser.expected_ref(
2045                                    "an identifier or value",
2046                                    parser.peek_token_ref(),
2047                                ),
2048                            }
2049                        })?;
2050
2051                        match expr {
2052                            // If we get back a compound field access or identifier,
2053                            // we flatten the nested expression.
2054                            // For example if the current root is `foo`
2055                            // and we get back a compound identifier expression `bar.baz`
2056                            // The full expression should be `foo.bar.baz` (i.e.
2057                            // a root with an access chain with 2 entries) and not
2058                            // `foo.(bar.baz)` (i.e. a root with an access chain with
2059                            // 1 entry`).
2060                            Some(Expr::CompoundFieldAccess { root, access_chain }) => {
2061                                chain.push(AccessExpr::Dot(*root));
2062                                chain.extend(access_chain);
2063                            }
2064                            Some(Expr::CompoundIdentifier(parts)) => chain.extend(
2065                                parts.into_iter().map(Expr::Identifier).map(AccessExpr::Dot),
2066                            ),
2067                            Some(expr) => {
2068                                chain.push(AccessExpr::Dot(expr));
2069                            }
2070                            // If the expression is not a valid suffix, fall back to
2071                            // parsing as an identifier. This handles cases like `T.interval`
2072                            // where `interval` is a keyword but should be treated as an identifier.
2073                            None => {
2074                                chain.push(AccessExpr::Dot(Expr::Identifier(
2075                                    self.parse_identifier()?,
2076                                )));
2077                            }
2078                        }
2079                    }
2080                }
2081            } else if !self.dialect.supports_partiql()
2082                && self.peek_token_ref().token == Token::LBracket
2083            {
2084                self.parse_multi_dim_subscript(&mut chain)?;
2085            } else {
2086                break;
2087            }
2088        }
2089
2090        let tok_index = self.get_current_index();
2091        if let Some(wildcard_token) = ending_wildcard {
2092            if !Self::is_all_ident(&root, &chain) {
2093                return self
2094                    .expected_ref("an identifier or a '*' after '.'", self.peek_token_ref());
2095            };
2096            Ok(Expr::QualifiedWildcard(
2097                ObjectName::from(Self::exprs_to_idents(root, chain)?),
2098                AttachedToken(wildcard_token),
2099            ))
2100        } else if self.maybe_parse_outer_join_operator() {
2101            if !Self::is_all_ident(&root, &chain) {
2102                return self.expected_at("column identifier before (+)", tok_index);
2103            };
2104            let expr = if chain.is_empty() {
2105                root
2106            } else {
2107                Expr::CompoundIdentifier(Self::exprs_to_idents(root, chain)?)
2108            };
2109            Ok(Expr::OuterJoin(expr.into()))
2110        } else {
2111            Self::build_compound_expr(root, chain)
2112        }
2113    }
2114
2115    /// Combines a root expression and access chain to form
2116    /// a compound expression. Which may be a [Expr::CompoundFieldAccess]
2117    /// or other special cased expressions like [Expr::CompoundIdentifier],
2118    /// [Expr::OuterJoin].
2119    fn build_compound_expr(
2120        root: Expr,
2121        mut access_chain: Vec<AccessExpr>,
2122    ) -> Result<Expr, ParserError> {
2123        if access_chain.is_empty() {
2124            return Ok(root);
2125        }
2126
2127        if Self::is_all_ident(&root, &access_chain) {
2128            return Ok(Expr::CompoundIdentifier(Self::exprs_to_idents(
2129                root,
2130                access_chain,
2131            )?));
2132        }
2133
2134        // Flatten qualified function calls.
2135        // For example, the expression `a.b.c.foo(1,2,3)` should
2136        // represent a function called `a.b.c.foo`, rather than
2137        // a composite expression.
2138        if matches!(root, Expr::Identifier(_))
2139            && matches!(
2140                access_chain.last(),
2141                Some(AccessExpr::Dot(Expr::Function(_)))
2142            )
2143            && access_chain
2144                .iter()
2145                .rev()
2146                .skip(1) // All except the Function
2147                .all(|access| matches!(access, AccessExpr::Dot(Expr::Identifier(_))))
2148        {
2149            let Some(AccessExpr::Dot(Expr::Function(mut func))) = access_chain.pop() else {
2150                return parser_err!("expected function expression", root.span().start);
2151            };
2152
2153            let compound_func_name = [root]
2154                .into_iter()
2155                .chain(access_chain.into_iter().flat_map(|access| match access {
2156                    AccessExpr::Dot(expr) => Some(expr),
2157                    _ => None,
2158                }))
2159                .flat_map(|expr| match expr {
2160                    Expr::Identifier(ident) => Some(ident),
2161                    _ => None,
2162                })
2163                .map(ObjectNamePart::Identifier)
2164                .chain(func.name.0)
2165                .collect::<Vec<_>>();
2166            func.name = ObjectName(compound_func_name);
2167
2168            return Ok(Expr::Function(func));
2169        }
2170
2171        // Flatten qualified outer join expressions.
2172        // For example, the expression `T.foo(+)` should
2173        // represent an outer join on the column name `T.foo`
2174        // rather than a composite expression.
2175        if access_chain.len() == 1
2176            && matches!(
2177                access_chain.last(),
2178                Some(AccessExpr::Dot(Expr::OuterJoin(_)))
2179            )
2180        {
2181            let Some(AccessExpr::Dot(Expr::OuterJoin(inner_expr))) = access_chain.pop() else {
2182                return parser_err!("expected (+) expression", root.span().start);
2183            };
2184
2185            if !Self::is_all_ident(&root, &[]) {
2186                return parser_err!("column identifier before (+)", root.span().start);
2187            };
2188
2189            let token_start = root.span().start;
2190            let mut idents = Self::exprs_to_idents(root, vec![])?;
2191            match *inner_expr {
2192                Expr::CompoundIdentifier(suffix) => idents.extend(suffix),
2193                Expr::Identifier(suffix) => idents.push(suffix),
2194                _ => {
2195                    return parser_err!("column identifier before (+)", token_start);
2196                }
2197            }
2198
2199            return Ok(Expr::OuterJoin(Expr::CompoundIdentifier(idents).into()));
2200        }
2201
2202        Ok(Expr::CompoundFieldAccess {
2203            root: Box::new(root),
2204            access_chain,
2205        })
2206    }
2207
2208    fn keyword_to_modifier(k: Keyword) -> Option<ContextModifier> {
2209        match k {
2210            Keyword::LOCAL => Some(ContextModifier::Local),
2211            Keyword::GLOBAL => Some(ContextModifier::Global),
2212            Keyword::SESSION => Some(ContextModifier::Session),
2213            _ => None,
2214        }
2215    }
2216
2217    /// Check if the root is an identifier and all fields are identifiers.
2218    fn is_all_ident(root: &Expr, fields: &[AccessExpr]) -> bool {
2219        if !matches!(root, Expr::Identifier(_)) {
2220            return false;
2221        }
2222        fields
2223            .iter()
2224            .all(|x| matches!(x, AccessExpr::Dot(Expr::Identifier(_))))
2225    }
2226
2227    /// Convert a root and a list of fields to a list of identifiers.
2228    fn exprs_to_idents(root: Expr, fields: Vec<AccessExpr>) -> Result<Vec<Ident>, ParserError> {
2229        let mut idents = vec![];
2230        if let Expr::Identifier(root) = root {
2231            idents.push(root);
2232            for x in fields {
2233                if let AccessExpr::Dot(Expr::Identifier(ident)) = x {
2234                    idents.push(ident);
2235                } else {
2236                    return parser_err!(
2237                        format!("Expected identifier, found: {}", x),
2238                        x.span().start
2239                    );
2240                }
2241            }
2242            Ok(idents)
2243        } else {
2244            parser_err!(
2245                format!("Expected identifier, found: {}", root),
2246                root.span().start
2247            )
2248        }
2249    }
2250
2251    /// Returns true if the next tokens indicate the outer join operator `(+)`.
2252    fn peek_outer_join_operator(&mut self) -> bool {
2253        if !self.dialect.supports_outer_join_operator() {
2254            return false;
2255        }
2256
2257        let [maybe_lparen, maybe_plus, maybe_rparen] = self.peek_tokens_ref();
2258        Token::LParen == maybe_lparen.token
2259            && Token::Plus == maybe_plus.token
2260            && Token::RParen == maybe_rparen.token
2261    }
2262
2263    /// If the next tokens indicates the outer join operator `(+)`, consume
2264    /// the tokens and return true.
2265    fn maybe_parse_outer_join_operator(&mut self) -> bool {
2266        self.dialect.supports_outer_join_operator()
2267            && self.consume_tokens(&[Token::LParen, Token::Plus, Token::RParen])
2268    }
2269
2270    /// Parse utility options in the form of `(option1, option2 arg2, option3 arg3, ...)`
2271    pub fn parse_utility_options(&mut self) -> Result<Vec<UtilityOption>, ParserError> {
2272        self.expect_token(&Token::LParen)?;
2273        let options = self.parse_comma_separated(Self::parse_utility_option)?;
2274        self.expect_token(&Token::RParen)?;
2275
2276        Ok(options)
2277    }
2278
2279    fn parse_utility_option(&mut self) -> Result<UtilityOption, ParserError> {
2280        let name = self.parse_identifier()?;
2281
2282        let next_token = self.peek_token_ref();
2283        if next_token == &Token::Comma || next_token == &Token::RParen {
2284            return Ok(UtilityOption { name, arg: None });
2285        }
2286        let arg = self.parse_expr()?;
2287
2288        Ok(UtilityOption {
2289            name,
2290            arg: Some(arg),
2291        })
2292    }
2293
2294    fn try_parse_expr_sub_query(&mut self) -> Result<Option<Expr>, ParserError> {
2295        if !self.peek_sub_query() {
2296            return Ok(None);
2297        }
2298
2299        Ok(Some(Expr::Subquery(self.parse_query()?)))
2300    }
2301
2302    fn try_parse_lambda(&mut self) -> Result<Option<Expr>, ParserError> {
2303        if !self.dialect.supports_lambda_functions() {
2304            return Ok(None);
2305        }
2306        self.maybe_parse(|p| {
2307            let params = p.parse_comma_separated(|p| p.parse_lambda_function_parameter())?;
2308            p.expect_token(&Token::RParen)?;
2309            p.expect_token(&Token::Arrow)?;
2310            let expr = p.parse_expr()?;
2311            Ok(Expr::Lambda(LambdaFunction {
2312                params: OneOrManyWithParens::Many(params),
2313                body: Box::new(expr),
2314                syntax: LambdaSyntax::Arrow,
2315            }))
2316        })
2317    }
2318
2319    /// Parses a lambda expression following the `LAMBDA` keyword syntax.
2320    ///
2321    /// Syntax: `LAMBDA <params> : <expr>`
2322    ///
2323    /// Examples:
2324    /// - `LAMBDA x : x + 1`
2325    /// - `LAMBDA x, i : x > i`
2326    ///
2327    /// See <https://duckdb.org/docs/stable/sql/functions/lambda>
2328    fn parse_lambda_expr(&mut self) -> Result<Expr, ParserError> {
2329        // Parse the parameters: either a single identifier or comma-separated identifiers
2330        let params = self.parse_lambda_function_parameters()?;
2331        // Expect the colon separator
2332        self.expect_token(&Token::Colon)?;
2333        // Parse the body expression
2334        let body = self.parse_expr()?;
2335        Ok(Expr::Lambda(LambdaFunction {
2336            params,
2337            body: Box::new(body),
2338            syntax: LambdaSyntax::LambdaKeyword,
2339        }))
2340    }
2341
2342    /// Parses the parameters of a lambda function with optional typing.
2343    fn parse_lambda_function_parameters(
2344        &mut self,
2345    ) -> Result<OneOrManyWithParens<LambdaFunctionParameter>, ParserError> {
2346        // Parse the parameters: either a single identifier or comma-separated identifiers
2347        let params = if self.consume_token(&Token::LParen) {
2348            // Parenthesized parameters: (x, y)
2349            let params = self.parse_comma_separated(|p| p.parse_lambda_function_parameter())?;
2350            self.expect_token(&Token::RParen)?;
2351            OneOrManyWithParens::Many(params)
2352        } else {
2353            // Unparenthesized parameters: x or x, y
2354            let params = self.parse_comma_separated(|p| p.parse_lambda_function_parameter())?;
2355            if params.len() == 1 {
2356                OneOrManyWithParens::One(params.into_iter().next().unwrap())
2357            } else {
2358                OneOrManyWithParens::Many(params)
2359            }
2360        };
2361        Ok(params)
2362    }
2363
2364    /// Parses a single parameter of a lambda function, with optional typing.
2365    fn parse_lambda_function_parameter(&mut self) -> Result<LambdaFunctionParameter, ParserError> {
2366        let name = self.parse_identifier()?;
2367        let data_type = match &self.peek_token_ref().token {
2368            Token::Word(_) => self.maybe_parse(|p| p.parse_data_type())?,
2369            _ => None,
2370        };
2371        Ok(LambdaFunctionParameter { name, data_type })
2372    }
2373
2374    /// Tries to parse the body of an [ODBC escaping sequence]
2375    /// i.e. without the enclosing braces
2376    /// Currently implemented:
2377    /// Scalar Function Calls
2378    /// Date, Time, and Timestamp Literals
2379    /// See <https://learn.microsoft.com/en-us/sql/odbc/reference/develop-app/escape-sequences-in-odbc?view=sql-server-2017>
2380    fn maybe_parse_odbc_body(&mut self) -> Result<Option<Expr>, ParserError> {
2381        // Attempt 1: Try to parse it as a function.
2382        if let Some(expr) = self.maybe_parse_odbc_fn_body()? {
2383            return Ok(Some(expr));
2384        }
2385        // Attempt 2: Try to parse it as a Date, Time or Timestamp Literal
2386        self.maybe_parse_odbc_body_datetime()
2387    }
2388
2389    /// Tries to parse the body of an [ODBC Date, Time, and Timestamp Literals] call.
2390    ///
2391    /// ```sql
2392    /// {d '2025-07-17'}
2393    /// {t '14:12:01'}
2394    /// {ts '2025-07-17 14:12:01'}
2395    /// ```
2396    ///
2397    /// [ODBC Date, Time, and Timestamp Literals]:
2398    /// https://learn.microsoft.com/en-us/sql/odbc/reference/develop-app/date-time-and-timestamp-literals?view=sql-server-2017
2399    fn maybe_parse_odbc_body_datetime(&mut self) -> Result<Option<Expr>, ParserError> {
2400        self.maybe_parse(|p| {
2401            let token = p.next_token().clone();
2402            let word_string = token.token.to_string();
2403            let data_type = match word_string.as_str() {
2404                "t" => DataType::Time(None, TimezoneInfo::None),
2405                "d" => DataType::Date,
2406                "ts" => DataType::Timestamp(None, TimezoneInfo::None),
2407                _ => return p.expected("ODBC datetime keyword (t, d, or ts)", token),
2408            };
2409            let value = p.parse_value()?;
2410            Ok(Expr::TypedString(TypedString {
2411                data_type,
2412                value,
2413                uses_odbc_syntax: true,
2414            }))
2415        })
2416    }
2417
2418    /// Tries to parse the body of an [ODBC function] call.
2419    /// i.e. without the enclosing braces
2420    ///
2421    /// ```sql
2422    /// fn myfunc(1,2,3)
2423    /// ```
2424    ///
2425    /// [ODBC function]: https://learn.microsoft.com/en-us/sql/odbc/reference/develop-app/scalar-function-calls?view=sql-server-2017
2426    fn maybe_parse_odbc_fn_body(&mut self) -> Result<Option<Expr>, ParserError> {
2427        self.maybe_parse(|p| {
2428            p.expect_keyword(Keyword::FN)?;
2429            let fn_name = p.parse_object_name(false)?;
2430            let mut fn_call = p.parse_function_call(fn_name)?;
2431            fn_call.uses_odbc_syntax = true;
2432            Ok(Expr::Function(fn_call))
2433        })
2434    }
2435
2436    /// Parse a function call expression named by `name` and return it as an `Expr`.
2437    pub fn parse_function(&mut self, name: ObjectName) -> Result<Expr, ParserError> {
2438        self.parse_function_call(name).map(Expr::Function)
2439    }
2440
2441    fn parse_function_call(&mut self, name: ObjectName) -> Result<Function, ParserError> {
2442        self.expect_token(&Token::LParen)?;
2443
2444        // Snowflake permits a subquery to be passed as an argument without
2445        // an enclosing set of parens if it's the only argument.
2446        if self.dialect.supports_subquery_as_function_arg() && self.peek_sub_query() {
2447            let subquery = self.parse_query()?;
2448            self.expect_token(&Token::RParen)?;
2449            return Ok(Function {
2450                name,
2451                uses_odbc_syntax: false,
2452                parameters: FunctionArguments::None,
2453                args: FunctionArguments::Subquery(subquery),
2454                filter: None,
2455                null_treatment: None,
2456                over: None,
2457                within_group: vec![],
2458            });
2459        }
2460
2461        let mut args = self.parse_function_argument_list()?;
2462        let mut parameters = FunctionArguments::None;
2463        // ClickHouse aggregations support parametric functions like `HISTOGRAM(0.5, 0.6)(x, y)`
2464        // which (0.5, 0.6) is a parameter to the function.
2465        if dialect_of!(self is ClickHouseDialect | GenericDialect)
2466            && self.consume_token(&Token::LParen)
2467        {
2468            parameters = FunctionArguments::List(args);
2469            args = self.parse_function_argument_list()?;
2470        }
2471
2472        let within_group = if self.parse_keywords(&[Keyword::WITHIN, Keyword::GROUP]) {
2473            self.expect_token(&Token::LParen)?;
2474            self.expect_keywords(&[Keyword::ORDER, Keyword::BY])?;
2475            let order_by = self.parse_comma_separated(Parser::parse_order_by_expr)?;
2476            self.expect_token(&Token::RParen)?;
2477            order_by
2478        } else {
2479            vec![]
2480        };
2481
2482        let filter = if self.dialect.supports_filter_during_aggregation()
2483            && self.parse_keyword(Keyword::FILTER)
2484            && self.consume_token(&Token::LParen)
2485            && self.parse_keyword(Keyword::WHERE)
2486        {
2487            let filter = Some(Box::new(self.parse_expr()?));
2488            self.expect_token(&Token::RParen)?;
2489            filter
2490        } else {
2491            None
2492        };
2493
2494        // Syntax for null treatment shows up either in the args list
2495        // or after the function call, but not both.
2496        let null_treatment = if args
2497            .clauses
2498            .iter()
2499            .all(|clause| !matches!(clause, FunctionArgumentClause::IgnoreOrRespectNulls(_)))
2500        {
2501            self.parse_null_treatment()?
2502        } else {
2503            None
2504        };
2505
2506        let over = if self.parse_keyword(Keyword::OVER) {
2507            if self.consume_token(&Token::LParen) {
2508                let window_spec = self.parse_window_spec()?;
2509                Some(WindowType::WindowSpec(window_spec))
2510            } else {
2511                Some(WindowType::NamedWindow(self.parse_identifier()?))
2512            }
2513        } else {
2514            None
2515        };
2516
2517        Ok(Function {
2518            name,
2519            uses_odbc_syntax: false,
2520            parameters,
2521            args: FunctionArguments::List(args),
2522            null_treatment,
2523            filter,
2524            over,
2525            within_group,
2526        })
2527    }
2528
2529    /// Optionally parses a null treatment clause.
2530    fn parse_null_treatment(&mut self) -> Result<Option<NullTreatment>, ParserError> {
2531        match self.parse_one_of_keywords(&[Keyword::RESPECT, Keyword::IGNORE]) {
2532            Some(keyword) => {
2533                self.expect_keyword_is(Keyword::NULLS)?;
2534
2535                Ok(match keyword {
2536                    Keyword::RESPECT => Some(NullTreatment::RespectNulls),
2537                    Keyword::IGNORE => Some(NullTreatment::IgnoreNulls),
2538                    _ => None,
2539                })
2540            }
2541            None => Ok(None),
2542        }
2543    }
2544
2545    /// Parse time-related function `name` possibly followed by `(...)` arguments.
2546    pub fn parse_time_functions(&mut self, name: ObjectName) -> Result<Expr, ParserError> {
2547        let args = if self.consume_token(&Token::LParen) {
2548            FunctionArguments::List(self.parse_function_argument_list()?)
2549        } else {
2550            FunctionArguments::None
2551        };
2552        Ok(Expr::Function(Function {
2553            name,
2554            uses_odbc_syntax: false,
2555            parameters: FunctionArguments::None,
2556            args,
2557            filter: None,
2558            over: None,
2559            null_treatment: None,
2560            within_group: vec![],
2561        }))
2562    }
2563
2564    /// Parse window frame `UNITS` clause: `ROWS`, `RANGE`, or `GROUPS`.
2565    pub fn parse_window_frame_units(&mut self) -> Result<WindowFrameUnits, ParserError> {
2566        let next_token = self.next_token();
2567        match &next_token.token {
2568            Token::Word(w) => match w.keyword {
2569                Keyword::ROWS => Ok(WindowFrameUnits::Rows),
2570                Keyword::RANGE => Ok(WindowFrameUnits::Range),
2571                Keyword::GROUPS => Ok(WindowFrameUnits::Groups),
2572                _ => self.expected("ROWS, RANGE, GROUPS", next_token)?,
2573            },
2574            _ => self.expected("ROWS, RANGE, GROUPS", next_token),
2575        }
2576    }
2577
2578    /// Parse a `WINDOW` frame definition (units and bounds).
2579    pub fn parse_window_frame(&mut self) -> Result<WindowFrame, ParserError> {
2580        let units = self.parse_window_frame_units()?;
2581        let (start_bound, end_bound) = if self.parse_keyword(Keyword::BETWEEN) {
2582            let start_bound = self.parse_window_frame_bound()?;
2583            self.expect_keyword_is(Keyword::AND)?;
2584            let end_bound = Some(self.parse_window_frame_bound()?);
2585            (start_bound, end_bound)
2586        } else {
2587            (self.parse_window_frame_bound()?, None)
2588        };
2589        Ok(WindowFrame {
2590            units,
2591            start_bound,
2592            end_bound,
2593        })
2594    }
2595
2596    /// Parse a window frame bound: `CURRENT ROW` or `<n> PRECEDING|FOLLOWING`.
2597    pub fn parse_window_frame_bound(&mut self) -> Result<WindowFrameBound, ParserError> {
2598        if self.parse_keywords(&[Keyword::CURRENT, Keyword::ROW]) {
2599            Ok(WindowFrameBound::CurrentRow)
2600        } else {
2601            let rows = if self.parse_keyword(Keyword::UNBOUNDED) {
2602                None
2603            } else {
2604                Some(Box::new(match &self.peek_token_ref().token {
2605                    Token::SingleQuotedString(_) => self.parse_interval()?,
2606                    _ => self.parse_expr()?,
2607                }))
2608            };
2609            if self.parse_keyword(Keyword::PRECEDING) {
2610                Ok(WindowFrameBound::Preceding(rows))
2611            } else if self.parse_keyword(Keyword::FOLLOWING) {
2612                Ok(WindowFrameBound::Following(rows))
2613            } else {
2614                self.expected_ref("PRECEDING or FOLLOWING", self.peek_token_ref())
2615            }
2616        }
2617    }
2618
2619    /// Parse a group by expr. Group by expr can be one of group sets, roll up, cube, or simple expr.
2620    fn parse_group_by_expr(&mut self) -> Result<Expr, ParserError> {
2621        if self.dialect.supports_group_by_expr() {
2622            if self.parse_keywords(&[Keyword::GROUPING, Keyword::SETS]) {
2623                self.expect_token(&Token::LParen)?;
2624                let result = self.parse_comma_separated(|p| p.parse_tuple(true, true))?;
2625                self.expect_token(&Token::RParen)?;
2626                Ok(Expr::GroupingSets(result))
2627            } else if self.parse_keyword(Keyword::CUBE) {
2628                self.expect_token(&Token::LParen)?;
2629                let result = self.parse_comma_separated(|p| p.parse_tuple(true, true))?;
2630                self.expect_token(&Token::RParen)?;
2631                Ok(Expr::Cube(result))
2632            } else if self.parse_keyword(Keyword::ROLLUP) {
2633                self.expect_token(&Token::LParen)?;
2634                let result = self.parse_comma_separated(|p| p.parse_tuple(true, true))?;
2635                self.expect_token(&Token::RParen)?;
2636                Ok(Expr::Rollup(result))
2637            } else if self.consume_tokens(&[Token::LParen, Token::RParen]) {
2638                // PostgreSQL allow to use empty tuple as a group by expression,
2639                // e.g. `GROUP BY (), name`. Please refer to GROUP BY Clause section in
2640                // [PostgreSQL](https://www.postgresql.org/docs/16/sql-select.html)
2641                Ok(Expr::Tuple(vec![]))
2642            } else {
2643                self.parse_expr()
2644            }
2645        } else {
2646            // TODO parse rollup for other dialects
2647            self.parse_expr()
2648        }
2649    }
2650
2651    /// Parse a tuple with `(` and `)`.
2652    /// If `lift_singleton` is true, then a singleton tuple is lifted to a tuple of length 1, otherwise it will fail.
2653    /// If `allow_empty` is true, then an empty tuple is allowed.
2654    fn parse_tuple(
2655        &mut self,
2656        lift_singleton: bool,
2657        allow_empty: bool,
2658    ) -> Result<Vec<Expr>, ParserError> {
2659        if lift_singleton {
2660            if self.consume_token(&Token::LParen) {
2661                let result = if allow_empty && self.consume_token(&Token::RParen) {
2662                    vec![]
2663                } else {
2664                    let result = self.parse_comma_separated(Parser::parse_expr)?;
2665                    self.expect_token(&Token::RParen)?;
2666                    result
2667                };
2668                Ok(result)
2669            } else {
2670                Ok(vec![self.parse_expr()?])
2671            }
2672        } else {
2673            self.expect_token(&Token::LParen)?;
2674            let result = if allow_empty && self.consume_token(&Token::RParen) {
2675                vec![]
2676            } else {
2677                let result = self.parse_comma_separated(Parser::parse_expr)?;
2678                self.expect_token(&Token::RParen)?;
2679                result
2680            };
2681            Ok(result)
2682        }
2683    }
2684
2685    /// Parse a `CASE` expression and return an [`Expr::Case`].
2686    pub fn parse_case_expr(&mut self) -> Result<Expr, ParserError> {
2687        let case_token = AttachedToken(self.get_current_token().clone());
2688        let mut operand = None;
2689        if !self.parse_keyword(Keyword::WHEN) {
2690            operand = Some(Box::new(self.parse_expr()?));
2691            self.expect_keyword_is(Keyword::WHEN)?;
2692        }
2693        let mut conditions = vec![];
2694        loop {
2695            let condition = self.parse_expr()?;
2696            self.expect_keyword_is(Keyword::THEN)?;
2697            let result = self.parse_expr()?;
2698            conditions.push(CaseWhen { condition, result });
2699            if !self.parse_keyword(Keyword::WHEN) {
2700                break;
2701            }
2702        }
2703        let else_result = if self.parse_keyword(Keyword::ELSE) {
2704            Some(Box::new(self.parse_expr()?))
2705        } else {
2706            None
2707        };
2708        let end_token = AttachedToken(self.expect_keyword(Keyword::END)?);
2709        Ok(Expr::Case {
2710            case_token,
2711            end_token,
2712            operand,
2713            conditions,
2714            else_result,
2715        })
2716    }
2717
2718    /// Parse an optional `FORMAT` clause for `CAST` expressions.
2719    pub fn parse_optional_cast_format(&mut self) -> Result<Option<CastFormat>, ParserError> {
2720        if self.parse_keyword(Keyword::FORMAT) {
2721            let value = self.parse_value()?;
2722            match self.parse_optional_time_zone()? {
2723                Some(tz) => Ok(Some(CastFormat::ValueAtTimeZone(value, tz))),
2724                None => Ok(Some(CastFormat::Value(value))),
2725            }
2726        } else {
2727            Ok(None)
2728        }
2729    }
2730
2731    /// Parse an optional `AT TIME ZONE` clause.
2732    pub fn parse_optional_time_zone(&mut self) -> Result<Option<ValueWithSpan>, ParserError> {
2733        if self.parse_keywords(&[Keyword::AT, Keyword::TIME, Keyword::ZONE]) {
2734            self.parse_value().map(Some)
2735        } else {
2736            Ok(None)
2737        }
2738    }
2739
2740    /// mssql-like convert function
2741    fn parse_mssql_convert(&mut self, is_try: bool) -> Result<Expr, ParserError> {
2742        self.expect_token(&Token::LParen)?;
2743        let data_type = self.parse_data_type()?;
2744        self.expect_token(&Token::Comma)?;
2745        let expr = self.parse_expr()?;
2746        let styles = if self.consume_token(&Token::Comma) {
2747            self.parse_comma_separated(Parser::parse_expr)?
2748        } else {
2749            Default::default()
2750        };
2751        self.expect_token(&Token::RParen)?;
2752        Ok(Expr::Convert {
2753            is_try,
2754            expr: Box::new(expr),
2755            data_type: Some(data_type),
2756            charset: None,
2757            target_before_value: true,
2758            styles,
2759        })
2760    }
2761
2762    /// Parse a SQL CONVERT function:
2763    ///  - `CONVERT('héhé' USING utf8mb4)` (MySQL)
2764    ///  - `CONVERT('héhé', CHAR CHARACTER SET utf8mb4)` (MySQL)
2765    ///  - `CONVERT(DECIMAL(10, 5), 42)` (MSSQL) - the type comes first
2766    pub fn parse_convert_expr(&mut self, is_try: bool) -> Result<Expr, ParserError> {
2767        if self.dialect.convert_type_before_value() {
2768            return self.parse_mssql_convert(is_try);
2769        }
2770        self.expect_token(&Token::LParen)?;
2771        let expr = self.parse_expr()?;
2772        if self.parse_keyword(Keyword::USING) {
2773            let charset = self.parse_object_name(false)?;
2774            self.expect_token(&Token::RParen)?;
2775            return Ok(Expr::Convert {
2776                is_try,
2777                expr: Box::new(expr),
2778                data_type: None,
2779                charset: Some(charset),
2780                target_before_value: false,
2781                styles: vec![],
2782            });
2783        }
2784        self.expect_token(&Token::Comma)?;
2785        let data_type = self.parse_data_type()?;
2786        let charset = if self.parse_keywords(&[Keyword::CHARACTER, Keyword::SET]) {
2787            Some(self.parse_object_name(false)?)
2788        } else {
2789            None
2790        };
2791        self.expect_token(&Token::RParen)?;
2792        Ok(Expr::Convert {
2793            is_try,
2794            expr: Box::new(expr),
2795            data_type: Some(data_type),
2796            charset,
2797            target_before_value: false,
2798            styles: vec![],
2799        })
2800    }
2801
2802    /// Parse a SQL CAST function e.g. `CAST(expr AS FLOAT)`
2803    pub fn parse_cast_expr(&mut self, kind: CastKind) -> Result<Expr, ParserError> {
2804        self.expect_token(&Token::LParen)?;
2805        let expr = self.parse_expr()?;
2806        self.expect_keyword_is(Keyword::AS)?;
2807        let data_type = self.parse_data_type()?;
2808        let array = self.parse_keyword(Keyword::ARRAY);
2809        let format = self.parse_optional_cast_format()?;
2810        self.expect_token(&Token::RParen)?;
2811        Ok(Expr::Cast {
2812            kind,
2813            expr: Box::new(expr),
2814            data_type,
2815            array,
2816            format,
2817        })
2818    }
2819
2820    /// Parse a SQL EXISTS expression e.g. `WHERE EXISTS(SELECT ...)`.
2821    pub fn parse_exists_expr(&mut self, negated: bool) -> Result<Expr, ParserError> {
2822        self.expect_token(&Token::LParen)?;
2823        let exists_node = Expr::Exists {
2824            negated,
2825            subquery: self.parse_query()?,
2826        };
2827        self.expect_token(&Token::RParen)?;
2828        Ok(exists_node)
2829    }
2830
2831    /// Parse a SQL `EXTRACT` expression e.g. `EXTRACT(YEAR FROM date)`.
2832    pub fn parse_extract_expr(&mut self) -> Result<Expr, ParserError> {
2833        self.expect_token(&Token::LParen)?;
2834        let field = self.parse_date_time_field()?;
2835
2836        let syntax = if self.parse_keyword(Keyword::FROM) {
2837            ExtractSyntax::From
2838        } else if self.dialect.supports_extract_comma_syntax() && self.consume_token(&Token::Comma)
2839        {
2840            ExtractSyntax::Comma
2841        } else {
2842            return Err(ParserError::ParserError(
2843                "Expected 'FROM' or ','".to_string(),
2844            ));
2845        };
2846
2847        let expr = self.parse_expr()?;
2848        self.expect_token(&Token::RParen)?;
2849        Ok(Expr::Extract {
2850            field,
2851            expr: Box::new(expr),
2852            syntax,
2853        })
2854    }
2855
2856    /// Parse a `CEIL` or `FLOOR` expression.
2857    pub fn parse_ceil_floor_expr(&mut self, is_ceil: bool) -> Result<Expr, ParserError> {
2858        self.expect_token(&Token::LParen)?;
2859        let expr = self.parse_expr()?;
2860        // Parse `CEIL/FLOOR(expr)`
2861        let field = if self.parse_keyword(Keyword::TO) {
2862            // Parse `CEIL/FLOOR(expr TO DateTimeField)`
2863            CeilFloorKind::DateTimeField(self.parse_date_time_field()?)
2864        } else if self.consume_token(&Token::Comma) {
2865            // Parse `CEIL/FLOOR(expr, scale)`
2866            let v = self.parse_value()?;
2867            if matches!(v.value, Value::Number(_, _)) {
2868                CeilFloorKind::Scale(v)
2869            } else {
2870                return Err(ParserError::ParserError(
2871                    "Scale field can only be of number type".to_string(),
2872                ));
2873            }
2874        } else {
2875            CeilFloorKind::DateTimeField(DateTimeField::NoDateTime)
2876        };
2877        self.expect_token(&Token::RParen)?;
2878        if is_ceil {
2879            Ok(Expr::Ceil {
2880                expr: Box::new(expr),
2881                field,
2882            })
2883        } else {
2884            Ok(Expr::Floor {
2885                expr: Box::new(expr),
2886                field,
2887            })
2888        }
2889    }
2890
2891    /// Parse a `POSITION` expression.
2892    pub fn parse_position_expr(&mut self, ident: Ident) -> Result<Expr, ParserError> {
2893        let between_prec = self.dialect.prec_value(Precedence::Between);
2894        let position_expr = self.maybe_parse(|p| {
2895            // PARSE SELECT POSITION('@' in field)
2896            p.expect_token(&Token::LParen)?;
2897
2898            // Parse the subexpr till the IN keyword
2899            let expr = p.parse_subexpr(between_prec)?;
2900            p.expect_keyword_is(Keyword::IN)?;
2901            let from = p.parse_expr()?;
2902            p.expect_token(&Token::RParen)?;
2903            Ok(Expr::Position {
2904                expr: Box::new(expr),
2905                r#in: Box::new(from),
2906            })
2907        })?;
2908        match position_expr {
2909            Some(expr) => Ok(expr),
2910            // Snowflake supports `position` as an ordinary function call
2911            // without the special `IN` syntax.
2912            None => self.parse_function(ObjectName::from(vec![ident])),
2913        }
2914    }
2915
2916    /// Parse `SUBSTRING`/`SUBSTR` expressions: `SUBSTRING(expr FROM start FOR length)` or `SUBSTR(expr, start, length)`.
2917    pub fn parse_substring(&mut self) -> Result<Expr, ParserError> {
2918        let shorthand = match self.expect_one_of_keywords(&[Keyword::SUBSTR, Keyword::SUBSTRING])? {
2919            Keyword::SUBSTR => true,
2920            Keyword::SUBSTRING => false,
2921            _ => {
2922                self.prev_token();
2923                return self.expected_ref("SUBSTR or SUBSTRING", self.peek_token_ref());
2924            }
2925        };
2926        self.expect_token(&Token::LParen)?;
2927        let expr = self.parse_expr()?;
2928        let mut from_expr = None;
2929        let special = self.consume_token(&Token::Comma);
2930        if special || self.parse_keyword(Keyword::FROM) {
2931            from_expr = Some(self.parse_expr()?);
2932        }
2933
2934        let mut to_expr = None;
2935        if self.parse_keyword(Keyword::FOR) || self.consume_token(&Token::Comma) {
2936            to_expr = Some(self.parse_expr()?);
2937        }
2938        self.expect_token(&Token::RParen)?;
2939
2940        Ok(Expr::Substring {
2941            expr: Box::new(expr),
2942            substring_from: from_expr.map(Box::new),
2943            substring_for: to_expr.map(Box::new),
2944            special,
2945            shorthand,
2946        })
2947    }
2948
2949    /// Parse an OVERLAY expression.
2950    ///
2951    /// See [Expr::Overlay]
2952    pub fn parse_overlay_expr(&mut self) -> Result<Expr, ParserError> {
2953        // PARSE OVERLAY (EXPR PLACING EXPR FROM 1 [FOR 3])
2954        self.expect_token(&Token::LParen)?;
2955        let expr = self.parse_expr()?;
2956        self.expect_keyword_is(Keyword::PLACING)?;
2957        let what_expr = self.parse_expr()?;
2958        self.expect_keyword_is(Keyword::FROM)?;
2959        let from_expr = self.parse_expr()?;
2960        let mut for_expr = None;
2961        if self.parse_keyword(Keyword::FOR) {
2962            for_expr = Some(self.parse_expr()?);
2963        }
2964        self.expect_token(&Token::RParen)?;
2965
2966        Ok(Expr::Overlay {
2967            expr: Box::new(expr),
2968            overlay_what: Box::new(what_expr),
2969            overlay_from: Box::new(from_expr),
2970            overlay_for: for_expr.map(Box::new),
2971        })
2972    }
2973
2974    /// ```sql
2975    /// TRIM ([WHERE] ['text' FROM] 'text')
2976    /// TRIM ('text')
2977    /// TRIM(<expr>, [, characters]) -- PostgreSQL, DuckDB, Snowflake, BigQuery, Generic
2978    /// ```
2979    pub fn parse_trim_expr(&mut self) -> Result<Expr, ParserError> {
2980        self.expect_token(&Token::LParen)?;
2981        let mut trim_where = None;
2982        if let Token::Word(word) = &self.peek_token_ref().token {
2983            if [Keyword::BOTH, Keyword::LEADING, Keyword::TRAILING].contains(&word.keyword) {
2984                trim_where = Some(self.parse_trim_where()?);
2985            }
2986        }
2987        let expr = self.parse_expr()?;
2988        if self.parse_keyword(Keyword::FROM) {
2989            let trim_what = Box::new(expr);
2990            let expr = self.parse_expr()?;
2991            self.expect_token(&Token::RParen)?;
2992            Ok(Expr::Trim {
2993                expr: Box::new(expr),
2994                trim_where,
2995                trim_what: Some(trim_what),
2996                trim_characters: None,
2997            })
2998        } else if self.dialect.supports_comma_separated_trim() && self.consume_token(&Token::Comma)
2999        {
3000            let characters = self.parse_comma_separated(Parser::parse_expr)?;
3001            self.expect_token(&Token::RParen)?;
3002            Ok(Expr::Trim {
3003                expr: Box::new(expr),
3004                trim_where: None,
3005                trim_what: None,
3006                trim_characters: Some(characters),
3007            })
3008        } else {
3009            self.expect_token(&Token::RParen)?;
3010            Ok(Expr::Trim {
3011                expr: Box::new(expr),
3012                trim_where,
3013                trim_what: None,
3014                trim_characters: None,
3015            })
3016        }
3017    }
3018
3019    /// Parse the `WHERE` field for a `TRIM` expression.
3020    ///
3021    /// See [TrimWhereField]
3022    pub fn parse_trim_where(&mut self) -> Result<TrimWhereField, ParserError> {
3023        let next_token = self.next_token();
3024        match &next_token.token {
3025            Token::Word(w) => match w.keyword {
3026                Keyword::BOTH => Ok(TrimWhereField::Both),
3027                Keyword::LEADING => Ok(TrimWhereField::Leading),
3028                Keyword::TRAILING => Ok(TrimWhereField::Trailing),
3029                _ => self.expected("trim_where field", next_token)?,
3030            },
3031            _ => self.expected("trim_where field", next_token),
3032        }
3033    }
3034
3035    /// Parses an array expression `[ex1, ex2, ..]`
3036    /// if `named` is `true`, came from an expression like  `ARRAY[ex1, ex2]`
3037    pub fn parse_array_expr(&mut self, named: bool) -> Result<Expr, ParserError> {
3038        let exprs = self.parse_comma_separated0(Parser::parse_expr, Token::RBracket)?;
3039        self.expect_token(&Token::RBracket)?;
3040        Ok(Expr::Array(Array { elem: exprs, named }))
3041    }
3042
3043    /// Parse the `ON OVERFLOW` clause for `LISTAGG`.
3044    ///
3045    /// See [`ListAggOnOverflow`]
3046    pub fn parse_listagg_on_overflow(&mut self) -> Result<Option<ListAggOnOverflow>, ParserError> {
3047        if self.parse_keywords(&[Keyword::ON, Keyword::OVERFLOW]) {
3048            if self.parse_keyword(Keyword::ERROR) {
3049                Ok(Some(ListAggOnOverflow::Error))
3050            } else {
3051                self.expect_keyword_is(Keyword::TRUNCATE)?;
3052                let filler = match &self.peek_token_ref().token {
3053                    Token::Word(w)
3054                        if w.keyword == Keyword::WITH || w.keyword == Keyword::WITHOUT =>
3055                    {
3056                        None
3057                    }
3058                    Token::SingleQuotedString(_)
3059                    | Token::EscapedStringLiteral(_)
3060                    | Token::UnicodeStringLiteral(_)
3061                    | Token::NationalStringLiteral(_)
3062                    | Token::QuoteDelimitedStringLiteral(_)
3063                    | Token::NationalQuoteDelimitedStringLiteral(_)
3064                    | Token::HexStringLiteral(_) => Some(Box::new(self.parse_expr()?)),
3065                    _ => self.expected_ref(
3066                        "either filler, WITH, or WITHOUT in LISTAGG",
3067                        self.peek_token_ref(),
3068                    )?,
3069                };
3070                let with_count = self.parse_keyword(Keyword::WITH);
3071                if !with_count && !self.parse_keyword(Keyword::WITHOUT) {
3072                    self.expected_ref("either WITH or WITHOUT in LISTAGG", self.peek_token_ref())?;
3073                }
3074                self.expect_keyword_is(Keyword::COUNT)?;
3075                Ok(Some(ListAggOnOverflow::Truncate { filler, with_count }))
3076            }
3077        } else {
3078            Ok(None)
3079        }
3080    }
3081
3082    /// Parse a date/time field for `EXTRACT`, interval qualifiers, and ceil/floor operations.
3083    ///
3084    /// `EXTRACT` supports a wider set of date/time fields than interval qualifiers,
3085    /// so this function may need to be split in two.
3086    ///
3087    /// See [`DateTimeField`]
3088    pub fn parse_date_time_field(&mut self) -> Result<DateTimeField, ParserError> {
3089        let next_token = self.next_token();
3090        match &next_token.token {
3091            Token::Word(w) => match w.keyword {
3092                Keyword::YEAR => Ok(DateTimeField::Year),
3093                Keyword::YEARS => Ok(DateTimeField::Years),
3094                Keyword::MONTH => Ok(DateTimeField::Month),
3095                Keyword::MONTHS => Ok(DateTimeField::Months),
3096                Keyword::WEEK => {
3097                    let week_day = if dialect_of!(self is BigQueryDialect | GenericDialect)
3098                        && self.consume_token(&Token::LParen)
3099                    {
3100                        let week_day = self.parse_identifier()?;
3101                        self.expect_token(&Token::RParen)?;
3102                        Some(week_day)
3103                    } else {
3104                        None
3105                    };
3106                    Ok(DateTimeField::Week(week_day))
3107                }
3108                Keyword::WEEKS => Ok(DateTimeField::Weeks),
3109                Keyword::DAY => Ok(DateTimeField::Day),
3110                Keyword::DAYOFWEEK => Ok(DateTimeField::DayOfWeek),
3111                Keyword::DAYOFYEAR => Ok(DateTimeField::DayOfYear),
3112                Keyword::DAYS => Ok(DateTimeField::Days),
3113                Keyword::DATE => Ok(DateTimeField::Date),
3114                Keyword::DATETIME => Ok(DateTimeField::Datetime),
3115                Keyword::HOUR => Ok(DateTimeField::Hour),
3116                Keyword::HOURS => Ok(DateTimeField::Hours),
3117                Keyword::MINUTE => Ok(DateTimeField::Minute),
3118                Keyword::MINUTES => Ok(DateTimeField::Minutes),
3119                Keyword::SECOND => Ok(DateTimeField::Second),
3120                Keyword::SECONDS => Ok(DateTimeField::Seconds),
3121                Keyword::CENTURY => Ok(DateTimeField::Century),
3122                Keyword::DECADE => Ok(DateTimeField::Decade),
3123                Keyword::DOY => Ok(DateTimeField::Doy),
3124                Keyword::DOW => Ok(DateTimeField::Dow),
3125                Keyword::EPOCH => Ok(DateTimeField::Epoch),
3126                Keyword::ISODOW => Ok(DateTimeField::Isodow),
3127                Keyword::ISOYEAR => Ok(DateTimeField::Isoyear),
3128                Keyword::ISOWEEK => Ok(DateTimeField::IsoWeek),
3129                Keyword::JULIAN => Ok(DateTimeField::Julian),
3130                Keyword::MICROSECOND => Ok(DateTimeField::Microsecond),
3131                Keyword::MICROSECONDS => Ok(DateTimeField::Microseconds),
3132                Keyword::MILLENIUM => Ok(DateTimeField::Millenium),
3133                Keyword::MILLENNIUM => Ok(DateTimeField::Millennium),
3134                Keyword::MILLISECOND => Ok(DateTimeField::Millisecond),
3135                Keyword::MILLISECONDS => Ok(DateTimeField::Milliseconds),
3136                Keyword::NANOSECOND => Ok(DateTimeField::Nanosecond),
3137                Keyword::NANOSECONDS => Ok(DateTimeField::Nanoseconds),
3138                Keyword::QUARTER => Ok(DateTimeField::Quarter),
3139                Keyword::TIME => Ok(DateTimeField::Time),
3140                Keyword::TIMEZONE => Ok(DateTimeField::Timezone),
3141                Keyword::TIMEZONE_ABBR => Ok(DateTimeField::TimezoneAbbr),
3142                Keyword::TIMEZONE_HOUR => Ok(DateTimeField::TimezoneHour),
3143                Keyword::TIMEZONE_MINUTE => Ok(DateTimeField::TimezoneMinute),
3144                Keyword::TIMEZONE_REGION => Ok(DateTimeField::TimezoneRegion),
3145                _ if self.dialect.allow_extract_custom() => {
3146                    self.prev_token();
3147                    let custom = self.parse_identifier()?;
3148                    Ok(DateTimeField::Custom(custom))
3149                }
3150                _ => self.expected("date/time field", next_token),
3151            },
3152            Token::SingleQuotedString(_) if self.dialect.allow_extract_single_quotes() => {
3153                self.prev_token();
3154                let custom = self.parse_identifier()?;
3155                Ok(DateTimeField::Custom(custom))
3156            }
3157            _ => self.expected("date/time field", next_token),
3158        }
3159    }
3160
3161    /// Parse a `NOT` expression.
3162    ///
3163    /// Represented in the AST as `Expr::UnaryOp` with `UnaryOperator::Not`.
3164    pub fn parse_not(&mut self) -> Result<Expr, ParserError> {
3165        match &self.peek_token_ref().token {
3166            Token::Word(w) => match w.keyword {
3167                Keyword::EXISTS => {
3168                    let negated = true;
3169                    let _ = self.parse_keyword(Keyword::EXISTS);
3170                    self.parse_exists_expr(negated)
3171                }
3172                _ => Ok(Expr::UnaryOp {
3173                    op: UnaryOperator::Not,
3174                    expr: Box::new(
3175                        self.parse_subexpr(self.dialect.prec_value(Precedence::UnaryNot))?,
3176                    ),
3177                }),
3178            },
3179            _ => Ok(Expr::UnaryOp {
3180                op: UnaryOperator::Not,
3181                expr: Box::new(self.parse_subexpr(self.dialect.prec_value(Precedence::UnaryNot))?),
3182            }),
3183        }
3184    }
3185
3186    /// Parse expression types that start with a left brace '{'.
3187    /// Examples:
3188    /// ```sql
3189    /// -- Dictionary expr.
3190    /// {'key1': 'value1', 'key2': 'value2'}
3191    ///
3192    /// -- Function call using the ODBC syntax.
3193    /// { fn CONCAT('foo', 'bar') }
3194    /// ```
3195    fn parse_lbrace_expr(&mut self) -> Result<Expr, ParserError> {
3196        let token = self.expect_token(&Token::LBrace)?;
3197
3198        if let Some(fn_expr) = self.maybe_parse_odbc_body()? {
3199            self.expect_token(&Token::RBrace)?;
3200            return Ok(fn_expr);
3201        }
3202
3203        if self.dialect.supports_dictionary_syntax() {
3204            self.prev_token(); // Put back the '{'
3205            return self.parse_dictionary();
3206        }
3207
3208        self.expected("an expression", token)
3209    }
3210
3211    /// Parses fulltext expressions [`sqlparser::ast::Expr::MatchAgainst`]
3212    ///
3213    /// # Errors
3214    /// This method will raise an error if the column list is empty or with invalid identifiers,
3215    /// the match expression is not a literal string, or if the search modifier is not valid.
3216    pub fn parse_match_against(&mut self) -> Result<Expr, ParserError> {
3217        let columns = self.parse_parenthesized_qualified_column_list(Mandatory, false)?;
3218
3219        self.expect_keyword_is(Keyword::AGAINST)?;
3220
3221        self.expect_token(&Token::LParen)?;
3222
3223        // MySQL is too permissive about the value, IMO we can't validate it perfectly on syntax level.
3224        let match_value = self.parse_value()?;
3225
3226        let in_natural_language_mode_keywords = &[
3227            Keyword::IN,
3228            Keyword::NATURAL,
3229            Keyword::LANGUAGE,
3230            Keyword::MODE,
3231        ];
3232
3233        let with_query_expansion_keywords = &[Keyword::WITH, Keyword::QUERY, Keyword::EXPANSION];
3234
3235        let in_boolean_mode_keywords = &[Keyword::IN, Keyword::BOOLEAN, Keyword::MODE];
3236
3237        let opt_search_modifier = if self.parse_keywords(in_natural_language_mode_keywords) {
3238            if self.parse_keywords(with_query_expansion_keywords) {
3239                Some(SearchModifier::InNaturalLanguageModeWithQueryExpansion)
3240            } else {
3241                Some(SearchModifier::InNaturalLanguageMode)
3242            }
3243        } else if self.parse_keywords(in_boolean_mode_keywords) {
3244            Some(SearchModifier::InBooleanMode)
3245        } else if self.parse_keywords(with_query_expansion_keywords) {
3246            Some(SearchModifier::WithQueryExpansion)
3247        } else {
3248            None
3249        };
3250
3251        self.expect_token(&Token::RParen)?;
3252
3253        Ok(Expr::MatchAgainst {
3254            columns,
3255            match_value,
3256            opt_search_modifier,
3257        })
3258    }
3259
3260    /// Parse an `INTERVAL` expression.
3261    ///
3262    /// Some syntactically valid intervals:
3263    ///
3264    /// ```sql
3265    ///   1. INTERVAL '1' DAY
3266    ///   2. INTERVAL '1-1' YEAR TO MONTH
3267    ///   3. INTERVAL '1' SECOND
3268    ///   4. INTERVAL '1:1:1.1' HOUR (5) TO SECOND (5)
3269    ///   5. INTERVAL '1.1' SECOND (2, 2)
3270    ///   6. INTERVAL '1:1' HOUR (5) TO MINUTE (5)
3271    ///   7. (MySql & BigQuery only): INTERVAL 1 DAY
3272    /// ```
3273    ///
3274    /// Note that we do not currently attempt to parse the quoted value.
3275    pub fn parse_interval(&mut self) -> Result<Expr, ParserError> {
3276        // The SQL standard allows an optional sign before the value string, but
3277        // it is not clear if any implementations support that syntax, so we
3278        // don't currently try to parse it. (The sign can instead be included
3279        // inside the value string.)
3280
3281        // to match the different flavours of INTERVAL syntax, we only allow expressions
3282        // if the dialect requires an interval qualifier,
3283        // see https://github.com/sqlparser-rs/sqlparser-rs/pull/1398 for more details
3284        let value = if self.dialect.require_interval_qualifier() {
3285            // parse a whole expression so `INTERVAL 1 + 1 DAY` is valid
3286            self.parse_expr()?
3287        } else {
3288            // parse a prefix expression so `INTERVAL 1 DAY` is valid, but `INTERVAL 1 + 1 DAY` is not
3289            // this also means that `INTERVAL '5 days' > INTERVAL '1 day'` treated properly
3290            self.parse_prefix()?
3291        };
3292
3293        // Following the string literal is a qualifier which indicates the units
3294        // of the duration specified in the string literal.
3295        //
3296        // Note that PostgreSQL allows omitting the qualifier, so we provide
3297        // this more general implementation.
3298        let leading_field = if self.next_token_is_temporal_unit() {
3299            Some(self.parse_date_time_field()?)
3300        } else if self.dialect.require_interval_qualifier() {
3301            return parser_err!(
3302                "INTERVAL requires a unit after the literal value",
3303                self.peek_token_ref().span.start
3304            );
3305        } else {
3306            None
3307        };
3308
3309        let (leading_precision, last_field, fsec_precision) =
3310            if leading_field == Some(DateTimeField::Second) {
3311                // SQL mandates special syntax for `SECOND TO SECOND` literals.
3312                // Instead of
3313                //     `SECOND [(<leading precision>)] TO SECOND[(<fractional seconds precision>)]`
3314                // one must use the special format:
3315                //     `SECOND [( <leading precision> [ , <fractional seconds precision>] )]`
3316                let last_field = None;
3317                let (leading_precision, fsec_precision) = self.parse_optional_precision_scale()?;
3318                (leading_precision, last_field, fsec_precision)
3319            } else {
3320                let leading_precision = self.parse_optional_precision()?;
3321                if self.parse_keyword(Keyword::TO) {
3322                    let last_field = Some(self.parse_date_time_field()?);
3323                    let fsec_precision = if last_field == Some(DateTimeField::Second) {
3324                        self.parse_optional_precision()?
3325                    } else {
3326                        None
3327                    };
3328                    (leading_precision, last_field, fsec_precision)
3329                } else {
3330                    (leading_precision, None, None)
3331                }
3332            };
3333
3334        Ok(Expr::Interval(Interval {
3335            value: Box::new(value),
3336            leading_field,
3337            leading_precision,
3338            last_field,
3339            fractional_seconds_precision: fsec_precision,
3340        }))
3341    }
3342
3343    /// Peek at the next token and determine if it is a temporal unit
3344    /// like `second`.
3345    pub fn next_token_is_temporal_unit(&mut self) -> bool {
3346        if let Token::Word(word) = &self.peek_token_ref().token {
3347            matches!(
3348                word.keyword,
3349                Keyword::YEAR
3350                    | Keyword::YEARS
3351                    | Keyword::MONTH
3352                    | Keyword::MONTHS
3353                    | Keyword::WEEK
3354                    | Keyword::WEEKS
3355                    | Keyword::DAY
3356                    | Keyword::DAYS
3357                    | Keyword::HOUR
3358                    | Keyword::HOURS
3359                    | Keyword::MINUTE
3360                    | Keyword::MINUTES
3361                    | Keyword::SECOND
3362                    | Keyword::SECONDS
3363                    | Keyword::CENTURY
3364                    | Keyword::DECADE
3365                    | Keyword::DOW
3366                    | Keyword::DOY
3367                    | Keyword::EPOCH
3368                    | Keyword::ISODOW
3369                    | Keyword::ISOYEAR
3370                    | Keyword::JULIAN
3371                    | Keyword::MICROSECOND
3372                    | Keyword::MICROSECONDS
3373                    | Keyword::MILLENIUM
3374                    | Keyword::MILLENNIUM
3375                    | Keyword::MILLISECOND
3376                    | Keyword::MILLISECONDS
3377                    | Keyword::NANOSECOND
3378                    | Keyword::NANOSECONDS
3379                    | Keyword::QUARTER
3380                    | Keyword::TIMEZONE
3381                    | Keyword::TIMEZONE_HOUR
3382                    | Keyword::TIMEZONE_MINUTE
3383            )
3384        } else {
3385            false
3386        }
3387    }
3388
3389    /// Syntax
3390    /// ```sql
3391    /// -- typed
3392    /// STRUCT<[field_name] field_type, ...>( expr1 [, ... ])
3393    /// -- typeless
3394    /// STRUCT( expr1 [AS field_name] [, ... ])
3395    /// ```
3396    fn parse_struct_literal(&mut self) -> Result<Expr, ParserError> {
3397        // Parse the fields definition if exist `<[field_name] field_type, ...>`
3398        self.prev_token();
3399        let (fields, trailing_bracket) =
3400            self.parse_struct_type_def(Self::parse_struct_field_def)?;
3401        if trailing_bracket.0 {
3402            return parser_err!(
3403                "unmatched > in STRUCT literal",
3404                self.peek_token_ref().span.start
3405            );
3406        }
3407
3408        // Parse the struct values `(expr1 [, ... ])`
3409        self.expect_token(&Token::LParen)?;
3410        let values = self
3411            .parse_comma_separated(|parser| parser.parse_struct_field_expr(!fields.is_empty()))?;
3412        self.expect_token(&Token::RParen)?;
3413
3414        Ok(Expr::Struct { values, fields })
3415    }
3416
3417    /// Parse an expression value for a struct literal
3418    /// Syntax
3419    /// ```sql
3420    /// expr [AS name]
3421    /// ```
3422    ///
3423    /// For biquery [1], Parameter typed_syntax is set to true if the expression
3424    /// is to be parsed as a field expression declared using typed
3425    /// struct syntax [2], and false if using typeless struct syntax [3].
3426    ///
3427    /// [1]: https://cloud.google.com/bigquery/docs/reference/standard-sql/data-types#constructing_a_struct
3428    /// [2]: https://cloud.google.com/bigquery/docs/reference/standard-sql/data-types#typed_struct_syntax
3429    /// [3]: https://cloud.google.com/bigquery/docs/reference/standard-sql/data-types#typeless_struct_syntax
3430    fn parse_struct_field_expr(&mut self, typed_syntax: bool) -> Result<Expr, ParserError> {
3431        let expr = self.parse_expr()?;
3432        if self.parse_keyword(Keyword::AS) {
3433            if typed_syntax {
3434                return parser_err!("Typed syntax does not allow AS", {
3435                    self.prev_token();
3436                    self.peek_token_ref().span.start
3437                });
3438            }
3439            let field_name = self.parse_identifier()?;
3440            Ok(Expr::Named {
3441                expr: expr.into(),
3442                name: field_name,
3443            })
3444        } else {
3445            Ok(expr)
3446        }
3447    }
3448
3449    /// Parse a Struct type definition as a sequence of field-value pairs.
3450    /// The syntax of the Struct elem differs by dialect so it is customised
3451    /// by the `elem_parser` argument.
3452    ///
3453    /// Syntax
3454    /// ```sql
3455    /// Hive:
3456    /// STRUCT<field_name: field_type>
3457    ///
3458    /// BigQuery:
3459    /// STRUCT<[field_name] field_type>
3460    /// ```
3461    fn parse_struct_type_def<F>(
3462        &mut self,
3463        mut elem_parser: F,
3464    ) -> Result<(Vec<StructField>, MatchedTrailingBracket), ParserError>
3465    where
3466        F: FnMut(&mut Parser<'a>) -> Result<(StructField, MatchedTrailingBracket), ParserError>,
3467    {
3468        self.expect_keyword_is(Keyword::STRUCT)?;
3469
3470        // Nothing to do if we have no type information.
3471        if self.peek_token_ref().token != Token::Lt {
3472            return Ok((Default::default(), false.into()));
3473        }
3474        self.next_token();
3475
3476        let mut field_defs = vec![];
3477        let trailing_bracket = loop {
3478            let (def, trailing_bracket) = elem_parser(self)?;
3479            field_defs.push(def);
3480            // The struct field definition is finished if it occurs `>>` or comma.
3481            if trailing_bracket.0 || !self.consume_token(&Token::Comma) {
3482                break trailing_bracket;
3483            }
3484        };
3485
3486        Ok((
3487            field_defs,
3488            self.expect_closing_angle_bracket(trailing_bracket)?,
3489        ))
3490    }
3491
3492    /// Duckdb Struct Data Type <https://duckdb.org/docs/sql/data_types/struct.html#retrieving-from-structs>
3493    fn parse_duckdb_struct_type_def(&mut self) -> Result<Vec<StructField>, ParserError> {
3494        self.expect_keyword_is(Keyword::STRUCT)?;
3495        self.expect_token(&Token::LParen)?;
3496        let struct_body = self.parse_comma_separated(|parser| {
3497            let field_name = parser.parse_identifier()?;
3498            let field_type = parser.parse_data_type()?;
3499
3500            Ok(StructField {
3501                field_name: Some(field_name),
3502                field_type,
3503                options: None,
3504            })
3505        });
3506        self.expect_token(&Token::RParen)?;
3507        struct_body
3508    }
3509
3510    /// Parse a field definition in a [struct] or [tuple].
3511    /// Syntax:
3512    ///
3513    /// ```sql
3514    /// [field_name] field_type
3515    /// field_name: field_type
3516    /// ```
3517    ///
3518    /// [struct]: https://cloud.google.com/bigquery/docs/reference/standard-sql/data-types#declaring_a_struct_type
3519    /// [tuple]: https://clickhouse.com/docs/en/sql-reference/data-types/tuple
3520    /// [databricks]: https://docs.databricks.com/en/sql/language-manual/data-types/struct-type.html
3521    fn parse_struct_field_def(
3522        &mut self,
3523    ) -> Result<(StructField, MatchedTrailingBracket), ParserError> {
3524        // Look beyond the next item to infer whether both field name
3525        // and type are specified.
3526        let is_named_field = matches!(
3527            (self.peek_nth_token(0).token, self.peek_nth_token(1).token),
3528            (Token::Word(_), Token::Word(_)) | (Token::Word(_), Token::Colon)
3529        );
3530
3531        let field_name = if is_named_field {
3532            let name = self.parse_identifier()?;
3533            let _ = self.consume_token(&Token::Colon);
3534            Some(name)
3535        } else {
3536            None
3537        };
3538
3539        let (field_type, trailing_bracket) = self.parse_data_type_helper()?;
3540
3541        let options = self.maybe_parse_options(Keyword::OPTIONS)?;
3542        Ok((
3543            StructField {
3544                field_name,
3545                field_type,
3546                options,
3547            },
3548            trailing_bracket,
3549        ))
3550    }
3551
3552    /// DuckDB specific: Parse a Union type definition as a sequence of field-value pairs.
3553    ///
3554    /// Syntax:
3555    ///
3556    /// ```sql
3557    /// UNION(field_name field_type[,...])
3558    /// ```
3559    ///
3560    /// [1]: https://duckdb.org/docs/sql/data_types/union.html
3561    fn parse_union_type_def(&mut self) -> Result<Vec<UnionField>, ParserError> {
3562        self.expect_keyword_is(Keyword::UNION)?;
3563
3564        self.expect_token(&Token::LParen)?;
3565
3566        let fields = self.parse_comma_separated(|p| {
3567            Ok(UnionField {
3568                field_name: p.parse_identifier()?,
3569                field_type: p.parse_data_type()?,
3570            })
3571        })?;
3572
3573        self.expect_token(&Token::RParen)?;
3574
3575        Ok(fields)
3576    }
3577
3578    /// DuckDB and ClickHouse specific: Parse a duckdb [dictionary] or a clickhouse [map] setting
3579    ///
3580    /// Syntax:
3581    ///
3582    /// ```sql
3583    /// {'field_name': expr1[, ... ]}
3584    /// ```
3585    ///
3586    /// [dictionary]: https://duckdb.org/docs/sql/data_types/struct#creating-structs
3587    /// [map]: https://clickhouse.com/docs/operations/settings/settings#additional_table_filters
3588    fn parse_dictionary(&mut self) -> Result<Expr, ParserError> {
3589        self.expect_token(&Token::LBrace)?;
3590
3591        let fields = self.parse_comma_separated0(Self::parse_dictionary_field, Token::RBrace)?;
3592
3593        self.expect_token(&Token::RBrace)?;
3594
3595        Ok(Expr::Dictionary(fields))
3596    }
3597
3598    /// Parse a field for a duckdb [dictionary] or a clickhouse [map] setting
3599    ///
3600    /// Syntax
3601    ///
3602    /// ```sql
3603    /// 'name': expr
3604    /// ```
3605    ///
3606    /// [dictionary]: https://duckdb.org/docs/sql/data_types/struct#creating-structs
3607    /// [map]: https://clickhouse.com/docs/operations/settings/settings#additional_table_filters
3608    fn parse_dictionary_field(&mut self) -> Result<DictionaryField, ParserError> {
3609        let key = self.parse_identifier()?;
3610
3611        self.expect_token(&Token::Colon)?;
3612
3613        let expr = self.parse_expr()?;
3614
3615        Ok(DictionaryField {
3616            key,
3617            value: Box::new(expr),
3618        })
3619    }
3620
3621    /// DuckDB specific: Parse a duckdb [map]
3622    ///
3623    /// Syntax:
3624    ///
3625    /// ```sql
3626    /// Map {key1: value1[, ... ]}
3627    /// ```
3628    ///
3629    /// [map]: https://duckdb.org/docs/sql/data_types/map.html#creating-maps
3630    fn parse_duckdb_map_literal(&mut self) -> Result<Expr, ParserError> {
3631        self.expect_token(&Token::LBrace)?;
3632        let fields = self.parse_comma_separated0(Self::parse_duckdb_map_field, Token::RBrace)?;
3633        self.expect_token(&Token::RBrace)?;
3634        Ok(Expr::Map(Map { entries: fields }))
3635    }
3636
3637    /// Parse a field for a duckdb [map]
3638    ///
3639    /// Syntax
3640    ///
3641    /// ```sql
3642    /// key: value
3643    /// ```
3644    ///
3645    /// [map]: https://duckdb.org/docs/sql/data_types/map.html#creating-maps
3646    fn parse_duckdb_map_field(&mut self) -> Result<MapEntry, ParserError> {
3647        // Stop before `:` so it can act as a key/value separator
3648        let key = self.parse_subexpr(self.dialect.prec_value(Precedence::Colon))?;
3649
3650        self.expect_token(&Token::Colon)?;
3651
3652        let value = self.parse_expr()?;
3653
3654        Ok(MapEntry {
3655            key: Box::new(key),
3656            value: Box::new(value),
3657        })
3658    }
3659
3660    /// Parse clickhouse [map]
3661    ///
3662    /// Syntax
3663    ///
3664    /// ```sql
3665    /// Map(key_data_type, value_data_type)
3666    /// ```
3667    ///
3668    /// [map]: https://clickhouse.com/docs/en/sql-reference/data-types/map
3669    fn parse_click_house_map_def(&mut self) -> Result<(DataType, DataType), ParserError> {
3670        self.expect_keyword_is(Keyword::MAP)?;
3671        self.expect_token(&Token::LParen)?;
3672        let key_data_type = self.parse_data_type()?;
3673        self.expect_token(&Token::Comma)?;
3674        let value_data_type = self.parse_data_type()?;
3675        self.expect_token(&Token::RParen)?;
3676
3677        Ok((key_data_type, value_data_type))
3678    }
3679
3680    /// Parse clickhouse [tuple]
3681    ///
3682    /// Syntax
3683    ///
3684    /// ```sql
3685    /// Tuple([field_name] field_type, ...)
3686    /// ```
3687    ///
3688    /// [tuple]: https://clickhouse.com/docs/en/sql-reference/data-types/tuple
3689    fn parse_click_house_tuple_def(&mut self) -> Result<Vec<StructField>, ParserError> {
3690        self.expect_keyword_is(Keyword::TUPLE)?;
3691        self.expect_token(&Token::LParen)?;
3692        let mut field_defs = vec![];
3693        loop {
3694            let (def, _) = self.parse_struct_field_def()?;
3695            field_defs.push(def);
3696            if !self.consume_token(&Token::Comma) {
3697                break;
3698            }
3699        }
3700        self.expect_token(&Token::RParen)?;
3701
3702        Ok(field_defs)
3703    }
3704
3705    /// For nested types that use the angle bracket syntax, this matches either
3706    /// `>`, `>>` or nothing depending on which variant is expected (specified by the previously
3707    /// matched `trailing_bracket` argument). It returns whether there is a trailing
3708    /// left to be matched - (i.e. if '>>' was matched).
3709    fn expect_closing_angle_bracket(
3710        &mut self,
3711        trailing_bracket: MatchedTrailingBracket,
3712    ) -> Result<MatchedTrailingBracket, ParserError> {
3713        let trailing_bracket = if !trailing_bracket.0 {
3714            match &self.peek_token_ref().token {
3715                Token::Gt => {
3716                    self.next_token();
3717                    false.into()
3718                }
3719                Token::ShiftRight => {
3720                    self.next_token();
3721                    true.into()
3722                }
3723                _ => return self.expected_ref(">", self.peek_token_ref()),
3724            }
3725        } else {
3726            false.into()
3727        };
3728
3729        Ok(trailing_bracket)
3730    }
3731
3732    /// Parse an operator following an expression
3733    pub fn parse_infix(&mut self, expr: Expr, precedence: u8) -> Result<Expr, ParserError> {
3734        // allow the dialect to override infix parsing
3735        if let Some(infix) = self.dialect.parse_infix(self, &expr, precedence) {
3736            return infix;
3737        }
3738
3739        let dialect = self.dialect;
3740
3741        self.advance_token();
3742        let tok = self.get_current_token();
3743        debug!("infix: {tok:?}");
3744        let tok_index = self.get_current_index();
3745        let span = tok.span;
3746        let regular_binary_operator = match &tok.token {
3747            Token::Spaceship => Some(BinaryOperator::Spaceship),
3748            Token::DoubleEq => Some(BinaryOperator::Eq),
3749            Token::Assignment => Some(BinaryOperator::Assignment),
3750            Token::Eq => Some(BinaryOperator::Eq),
3751            Token::Neq => Some(BinaryOperator::NotEq),
3752            Token::Gt => Some(BinaryOperator::Gt),
3753            Token::GtEq => Some(BinaryOperator::GtEq),
3754            Token::Lt => Some(BinaryOperator::Lt),
3755            Token::LtEq => Some(BinaryOperator::LtEq),
3756            Token::Plus => Some(BinaryOperator::Plus),
3757            Token::Minus => Some(BinaryOperator::Minus),
3758            Token::Mul => Some(BinaryOperator::Multiply),
3759            Token::Mod => Some(BinaryOperator::Modulo),
3760            Token::StringConcat => Some(BinaryOperator::StringConcat),
3761            Token::Pipe => Some(BinaryOperator::BitwiseOr),
3762            Token::Caret => {
3763                // In PostgreSQL, ^ stands for the exponentiation operation,
3764                // and # stands for XOR. See https://www.postgresql.org/docs/current/functions-math.html
3765                if dialect_is!(dialect is PostgreSqlDialect) {
3766                    Some(BinaryOperator::PGExp)
3767                } else {
3768                    Some(BinaryOperator::BitwiseXor)
3769                }
3770            }
3771            Token::Ampersand => Some(BinaryOperator::BitwiseAnd),
3772            Token::Div => Some(BinaryOperator::Divide),
3773            Token::DuckIntDiv if dialect_is!(dialect is DuckDbDialect | GenericDialect) => {
3774                Some(BinaryOperator::DuckIntegerDivide)
3775            }
3776            Token::ShiftLeft if dialect.supports_bitwise_shift_operators() => {
3777                Some(BinaryOperator::PGBitwiseShiftLeft)
3778            }
3779            Token::ShiftRight if dialect.supports_bitwise_shift_operators() => {
3780                Some(BinaryOperator::PGBitwiseShiftRight)
3781            }
3782            Token::Sharp if dialect_is!(dialect is PostgreSqlDialect | RedshiftSqlDialect) => {
3783                Some(BinaryOperator::PGBitwiseXor)
3784            }
3785            Token::Overlap if dialect_is!(dialect is PostgreSqlDialect | RedshiftSqlDialect) => {
3786                Some(BinaryOperator::PGOverlap)
3787            }
3788            Token::Overlap if dialect_is!(dialect is PostgreSqlDialect | GenericDialect) => {
3789                Some(BinaryOperator::PGOverlap)
3790            }
3791            Token::Overlap if dialect.supports_double_ampersand_operator() => {
3792                Some(BinaryOperator::And)
3793            }
3794            Token::CaretAt if dialect_is!(dialect is PostgreSqlDialect | GenericDialect) => {
3795                Some(BinaryOperator::PGStartsWith)
3796            }
3797            Token::Tilde => Some(BinaryOperator::PGRegexMatch),
3798            Token::TildeAsterisk => Some(BinaryOperator::PGRegexIMatch),
3799            Token::ExclamationMarkTilde => Some(BinaryOperator::PGRegexNotMatch),
3800            Token::ExclamationMarkTildeAsterisk => Some(BinaryOperator::PGRegexNotIMatch),
3801            Token::DoubleTilde => Some(BinaryOperator::PGLikeMatch),
3802            Token::DoubleTildeAsterisk => Some(BinaryOperator::PGILikeMatch),
3803            Token::ExclamationMarkDoubleTilde => Some(BinaryOperator::PGNotLikeMatch),
3804            Token::ExclamationMarkDoubleTildeAsterisk => Some(BinaryOperator::PGNotILikeMatch),
3805            Token::Arrow => Some(BinaryOperator::Arrow),
3806            Token::LongArrow => Some(BinaryOperator::LongArrow),
3807            Token::HashArrow => Some(BinaryOperator::HashArrow),
3808            Token::HashLongArrow => Some(BinaryOperator::HashLongArrow),
3809            Token::AtArrow => Some(BinaryOperator::AtArrow),
3810            Token::ArrowAt => Some(BinaryOperator::ArrowAt),
3811            Token::HashMinus => Some(BinaryOperator::HashMinus),
3812            Token::AtQuestion => Some(BinaryOperator::AtQuestion),
3813            Token::AtAt => Some(BinaryOperator::AtAt),
3814            Token::Question => Some(BinaryOperator::Question),
3815            Token::QuestionAnd => Some(BinaryOperator::QuestionAnd),
3816            Token::QuestionPipe => Some(BinaryOperator::QuestionPipe),
3817            Token::CustomBinaryOperator(s) => Some(BinaryOperator::Custom(s.clone())),
3818            Token::DoubleSharp if self.dialect.supports_geometric_types() => {
3819                Some(BinaryOperator::DoubleHash)
3820            }
3821
3822            Token::AmpersandLeftAngleBracket if self.dialect.supports_geometric_types() => {
3823                Some(BinaryOperator::AndLt)
3824            }
3825            Token::AmpersandRightAngleBracket if self.dialect.supports_geometric_types() => {
3826                Some(BinaryOperator::AndGt)
3827            }
3828            Token::QuestionMarkDash if self.dialect.supports_geometric_types() => {
3829                Some(BinaryOperator::QuestionDash)
3830            }
3831            Token::AmpersandLeftAngleBracketVerticalBar
3832                if self.dialect.supports_geometric_types() =>
3833            {
3834                Some(BinaryOperator::AndLtPipe)
3835            }
3836            Token::VerticalBarAmpersandRightAngleBracket
3837                if self.dialect.supports_geometric_types() =>
3838            {
3839                Some(BinaryOperator::PipeAndGt)
3840            }
3841            Token::TwoWayArrow if self.dialect.supports_geometric_types() => {
3842                Some(BinaryOperator::LtDashGt)
3843            }
3844            Token::LeftAngleBracketCaret if self.dialect.supports_geometric_types() => {
3845                Some(BinaryOperator::LtCaret)
3846            }
3847            Token::RightAngleBracketCaret if self.dialect.supports_geometric_types() => {
3848                Some(BinaryOperator::GtCaret)
3849            }
3850            Token::QuestionMarkSharp if self.dialect.supports_geometric_types() => {
3851                Some(BinaryOperator::QuestionHash)
3852            }
3853            Token::QuestionMarkDoubleVerticalBar if self.dialect.supports_geometric_types() => {
3854                Some(BinaryOperator::QuestionDoublePipe)
3855            }
3856            Token::QuestionMarkDashVerticalBar if self.dialect.supports_geometric_types() => {
3857                Some(BinaryOperator::QuestionDashPipe)
3858            }
3859            Token::TildeEqual if self.dialect.supports_geometric_types() => {
3860                Some(BinaryOperator::TildeEq)
3861            }
3862            Token::ShiftLeftVerticalBar if self.dialect.supports_geometric_types() => {
3863                Some(BinaryOperator::LtLtPipe)
3864            }
3865            Token::VerticalBarShiftRight if self.dialect.supports_geometric_types() => {
3866                Some(BinaryOperator::PipeGtGt)
3867            }
3868            Token::AtSign if self.dialect.supports_geometric_types() => Some(BinaryOperator::At),
3869
3870            Token::Word(w) => match w.keyword {
3871                Keyword::AND => Some(BinaryOperator::And),
3872                Keyword::OR => Some(BinaryOperator::Or),
3873                Keyword::XOR => Some(BinaryOperator::Xor),
3874                Keyword::OVERLAPS => Some(BinaryOperator::Overlaps),
3875                Keyword::OPERATOR if dialect_is!(dialect is PostgreSqlDialect | GenericDialect) => {
3876                    self.expect_token(&Token::LParen)?;
3877                    // there are special rules for operator names in
3878                    // postgres so we can not use 'parse_object'
3879                    // or similar.
3880                    // See https://www.postgresql.org/docs/current/sql-createoperator.html
3881                    let mut idents = vec![];
3882                    loop {
3883                        self.advance_token();
3884                        idents.push(self.get_current_token().to_string());
3885                        if !self.consume_token(&Token::Period) {
3886                            break;
3887                        }
3888                    }
3889                    self.expect_token(&Token::RParen)?;
3890                    Some(BinaryOperator::PGCustomBinaryOperator(idents))
3891                }
3892                _ => None,
3893            },
3894            _ => None,
3895        };
3896
3897        let tok = self.token_at(tok_index);
3898        if let Some(op) = regular_binary_operator {
3899            if let Some(keyword) =
3900                self.parse_one_of_keywords(&[Keyword::ANY, Keyword::ALL, Keyword::SOME])
3901            {
3902                self.expect_token(&Token::LParen)?;
3903                let right = if self.peek_sub_query() {
3904                    // We have a subquery ahead (SELECT\WITH ...) need to rewind and
3905                    // use the parenthesis for parsing the subquery as an expression.
3906                    self.prev_token(); // LParen
3907                    self.parse_subexpr(precedence)?
3908                } else {
3909                    // Non-subquery expression
3910                    let right = self.parse_subexpr(precedence)?;
3911                    self.expect_token(&Token::RParen)?;
3912                    right
3913                };
3914
3915                if !matches!(
3916                    op,
3917                    BinaryOperator::Gt
3918                        | BinaryOperator::Lt
3919                        | BinaryOperator::GtEq
3920                        | BinaryOperator::LtEq
3921                        | BinaryOperator::Eq
3922                        | BinaryOperator::NotEq
3923                        | BinaryOperator::PGRegexMatch
3924                        | BinaryOperator::PGRegexIMatch
3925                        | BinaryOperator::PGRegexNotMatch
3926                        | BinaryOperator::PGRegexNotIMatch
3927                        | BinaryOperator::PGLikeMatch
3928                        | BinaryOperator::PGILikeMatch
3929                        | BinaryOperator::PGNotLikeMatch
3930                        | BinaryOperator::PGNotILikeMatch
3931                ) {
3932                    return parser_err!(
3933                        format!(
3934                        "Expected one of [=, >, <, =>, =<, !=, ~, ~*, !~, !~*, ~~, ~~*, !~~, !~~*] as comparison operator, found: {op}"
3935                    ),
3936                        span.start
3937                    );
3938                };
3939
3940                Ok(match keyword {
3941                    Keyword::ALL => Expr::AllOp {
3942                        left: Box::new(expr),
3943                        compare_op: op,
3944                        right: Box::new(right),
3945                    },
3946                    Keyword::ANY | Keyword::SOME => Expr::AnyOp {
3947                        left: Box::new(expr),
3948                        compare_op: op,
3949                        right: Box::new(right),
3950                        is_some: keyword == Keyword::SOME,
3951                    },
3952                    unexpected_keyword => return Err(ParserError::ParserError(
3953                        format!("Internal parser error: expected any of {{ALL, ANY, SOME}}, got {unexpected_keyword:?}"),
3954                    )),
3955                })
3956            } else {
3957                Ok(Expr::BinaryOp {
3958                    left: Box::new(expr),
3959                    op,
3960                    right: Box::new(self.parse_subexpr(precedence)?),
3961                })
3962            }
3963        } else if let Token::Word(w) = &tok.token {
3964            match w.keyword {
3965                Keyword::IS => {
3966                    if self.parse_keyword(Keyword::NULL) {
3967                        Ok(Expr::IsNull(Box::new(expr)))
3968                    } else if self.parse_keywords(&[Keyword::NOT, Keyword::NULL]) {
3969                        Ok(Expr::IsNotNull(Box::new(expr)))
3970                    } else if self.parse_keywords(&[Keyword::TRUE]) {
3971                        Ok(Expr::IsTrue(Box::new(expr)))
3972                    } else if self.parse_keywords(&[Keyword::NOT, Keyword::TRUE]) {
3973                        Ok(Expr::IsNotTrue(Box::new(expr)))
3974                    } else if self.parse_keywords(&[Keyword::FALSE]) {
3975                        Ok(Expr::IsFalse(Box::new(expr)))
3976                    } else if self.parse_keywords(&[Keyword::NOT, Keyword::FALSE]) {
3977                        Ok(Expr::IsNotFalse(Box::new(expr)))
3978                    } else if self.parse_keywords(&[Keyword::UNKNOWN]) {
3979                        Ok(Expr::IsUnknown(Box::new(expr)))
3980                    } else if self.parse_keywords(&[Keyword::NOT, Keyword::UNKNOWN]) {
3981                        Ok(Expr::IsNotUnknown(Box::new(expr)))
3982                    } else if self.parse_keywords(&[Keyword::DISTINCT, Keyword::FROM]) {
3983                        let expr2 = self.parse_expr()?;
3984                        Ok(Expr::IsDistinctFrom(Box::new(expr), Box::new(expr2)))
3985                    } else if self.parse_keywords(&[Keyword::NOT, Keyword::DISTINCT, Keyword::FROM])
3986                    {
3987                        let expr2 = self.parse_expr()?;
3988                        Ok(Expr::IsNotDistinctFrom(Box::new(expr), Box::new(expr2)))
3989                    } else if let Ok(is_normalized) = self.parse_unicode_is_normalized(expr) {
3990                        Ok(is_normalized)
3991                    } else {
3992                        self.expected_ref(
3993                            "[NOT] NULL | TRUE | FALSE | DISTINCT | [form] NORMALIZED FROM after IS",
3994                            self.peek_token_ref(),
3995                        )
3996                    }
3997                }
3998                Keyword::AT => {
3999                    self.expect_keywords(&[Keyword::TIME, Keyword::ZONE])?;
4000                    Ok(Expr::AtTimeZone {
4001                        timestamp: Box::new(expr),
4002                        time_zone: Box::new(self.parse_subexpr(precedence)?),
4003                    })
4004                }
4005                Keyword::NOT
4006                | Keyword::IN
4007                | Keyword::BETWEEN
4008                | Keyword::LIKE
4009                | Keyword::ILIKE
4010                | Keyword::SIMILAR
4011                | Keyword::REGEXP
4012                | Keyword::RLIKE => {
4013                    self.prev_token();
4014                    let negated = self.parse_keyword(Keyword::NOT);
4015                    let regexp = self.parse_keyword(Keyword::REGEXP);
4016                    let rlike = self.parse_keyword(Keyword::RLIKE);
4017                    let null = if !self.in_column_definition_state() {
4018                        self.parse_keyword(Keyword::NULL)
4019                    } else {
4020                        false
4021                    };
4022                    if regexp || rlike {
4023                        Ok(Expr::RLike {
4024                            negated,
4025                            expr: Box::new(expr),
4026                            pattern: Box::new(
4027                                self.parse_subexpr(self.dialect.prec_value(Precedence::Like))?,
4028                            ),
4029                            regexp,
4030                        })
4031                    } else if negated && null {
4032                        Ok(Expr::IsNotNull(Box::new(expr)))
4033                    } else if self.parse_keyword(Keyword::IN) {
4034                        self.parse_in(expr, negated)
4035                    } else if self.parse_keyword(Keyword::BETWEEN) {
4036                        self.parse_between(expr, negated)
4037                    } else if self.parse_keyword(Keyword::LIKE) {
4038                        Ok(Expr::Like {
4039                            negated,
4040                            any: self.parse_keyword(Keyword::ANY),
4041                            expr: Box::new(expr),
4042                            pattern: Box::new(
4043                                self.parse_subexpr(self.dialect.prec_value(Precedence::Like))?,
4044                            ),
4045                            escape_char: self.parse_escape_char()?,
4046                        })
4047                    } else if self.parse_keyword(Keyword::ILIKE) {
4048                        Ok(Expr::ILike {
4049                            negated,
4050                            any: self.parse_keyword(Keyword::ANY),
4051                            expr: Box::new(expr),
4052                            pattern: Box::new(
4053                                self.parse_subexpr(self.dialect.prec_value(Precedence::Like))?,
4054                            ),
4055                            escape_char: self.parse_escape_char()?,
4056                        })
4057                    } else if self.parse_keywords(&[Keyword::SIMILAR, Keyword::TO]) {
4058                        Ok(Expr::SimilarTo {
4059                            negated,
4060                            expr: Box::new(expr),
4061                            pattern: Box::new(
4062                                self.parse_subexpr(self.dialect.prec_value(Precedence::Like))?,
4063                            ),
4064                            escape_char: self.parse_escape_char()?,
4065                        })
4066                    } else {
4067                        self.expected_ref("IN or BETWEEN after NOT", self.peek_token_ref())
4068                    }
4069                }
4070                Keyword::NOTNULL if dialect.supports_notnull_operator() => {
4071                    Ok(Expr::IsNotNull(Box::new(expr)))
4072                }
4073                Keyword::MEMBER => {
4074                    if self.parse_keyword(Keyword::OF) {
4075                        self.expect_token(&Token::LParen)?;
4076                        let array = self.parse_expr()?;
4077                        self.expect_token(&Token::RParen)?;
4078                        Ok(Expr::MemberOf(MemberOf {
4079                            value: Box::new(expr),
4080                            array: Box::new(array),
4081                        }))
4082                    } else {
4083                        self.expected_ref("OF after MEMBER", self.peek_token_ref())
4084                    }
4085                }
4086                // Can only happen if `get_next_precedence` got out of sync with this function
4087                _ => parser_err!(
4088                    format!("No infix parser for token {:?}", tok.token),
4089                    tok.span.start
4090                ),
4091            }
4092        } else if Token::DoubleColon == *tok {
4093            Ok(Expr::Cast {
4094                kind: CastKind::DoubleColon,
4095                expr: Box::new(expr),
4096                data_type: self.parse_data_type()?,
4097                array: false,
4098                format: None,
4099            })
4100        } else if Token::ExclamationMark == *tok && self.dialect.supports_factorial_operator() {
4101            Ok(Expr::UnaryOp {
4102                op: UnaryOperator::PGPostfixFactorial,
4103                expr: Box::new(expr),
4104            })
4105        } else if Token::LBracket == *tok && self.dialect.supports_partiql()
4106            || (Token::Colon == *tok)
4107        {
4108            self.prev_token();
4109            self.parse_json_access(expr)
4110        } else {
4111            // Can only happen if `get_next_precedence` got out of sync with this function
4112            parser_err!(
4113                format!("No infix parser for token {:?}", tok.token),
4114                tok.span.start
4115            )
4116        }
4117    }
4118
4119    /// Parse the `ESCAPE CHAR` portion of `LIKE`, `ILIKE`, and `SIMILAR TO`
4120    pub fn parse_escape_char(&mut self) -> Result<Option<ValueWithSpan>, ParserError> {
4121        if self.parse_keyword(Keyword::ESCAPE) {
4122            Ok(Some(self.parse_value()?))
4123        } else {
4124            Ok(None)
4125        }
4126    }
4127
4128    /// Parses an array subscript like
4129    /// * `[:]`
4130    /// * `[l]`
4131    /// * `[l:]`
4132    /// * `[:u]`
4133    /// * `[l:u]`
4134    /// * `[l:u:s]`
4135    ///
4136    /// Parser is right after `[`
4137    fn parse_subscript_inner(&mut self) -> Result<Subscript, ParserError> {
4138        // at either `<lower>:(rest)` or `:(rest)]`
4139        let lower_bound = if self.consume_token(&Token::Colon) {
4140            None
4141        } else {
4142            // parse expr until we hit a colon (or any token with lower precedence)
4143            Some(self.parse_subexpr(self.dialect.prec_value(Precedence::Colon))?)
4144        };
4145
4146        // check for end
4147        if self.consume_token(&Token::RBracket) {
4148            if let Some(lower_bound) = lower_bound {
4149                return Ok(Subscript::Index { index: lower_bound });
4150            };
4151            return Ok(Subscript::Slice {
4152                lower_bound,
4153                upper_bound: None,
4154                stride: None,
4155            });
4156        }
4157
4158        // consume the `:`
4159        if lower_bound.is_some() {
4160            self.expect_token(&Token::Colon)?;
4161        }
4162
4163        // we are now at either `]`, `<upper>(rest)]`
4164        let upper_bound = if self.consume_token(&Token::RBracket) {
4165            return Ok(Subscript::Slice {
4166                lower_bound,
4167                upper_bound: None,
4168                stride: None,
4169            });
4170        } else {
4171            // parse expr until we hit a colon (or any token with lower precedence)
4172            Some(self.parse_subexpr(self.dialect.prec_value(Precedence::Colon))?)
4173        };
4174
4175        // check for end
4176        if self.consume_token(&Token::RBracket) {
4177            return Ok(Subscript::Slice {
4178                lower_bound,
4179                upper_bound,
4180                stride: None,
4181            });
4182        }
4183
4184        // we are now at `:]` or `:stride]`
4185        self.expect_token(&Token::Colon)?;
4186        let stride = if self.consume_token(&Token::RBracket) {
4187            None
4188        } else {
4189            Some(self.parse_expr()?)
4190        };
4191
4192        if stride.is_some() {
4193            self.expect_token(&Token::RBracket)?;
4194        }
4195
4196        Ok(Subscript::Slice {
4197            lower_bound,
4198            upper_bound,
4199            stride,
4200        })
4201    }
4202
4203    /// Parse a multi-dimension array accessing like `[1:3][1][1]`
4204    pub fn parse_multi_dim_subscript(
4205        &mut self,
4206        chain: &mut Vec<AccessExpr>,
4207    ) -> Result<(), ParserError> {
4208        while self.consume_token(&Token::LBracket) {
4209            self.parse_subscript(chain)?;
4210        }
4211        Ok(())
4212    }
4213
4214    /// Parses an array subscript like `[1:3]`
4215    ///
4216    /// Parser is right after `[`
4217    fn parse_subscript(&mut self, chain: &mut Vec<AccessExpr>) -> Result<(), ParserError> {
4218        let subscript = self.parse_subscript_inner()?;
4219        chain.push(AccessExpr::Subscript(subscript));
4220        Ok(())
4221    }
4222
4223    fn parse_json_path_object_key(&mut self) -> Result<JsonPathElem, ParserError> {
4224        let token = self.next_token();
4225        match token.token {
4226            Token::Word(Word {
4227                value,
4228                // path segments in SF dot notation can be unquoted or double-quoted;
4229                // Databricks also supports backtick-quoted identifiers
4230                quote_style: quote_style @ (Some('"') | Some('`') | None),
4231                // some experimentation suggests that snowflake permits
4232                // any keyword here unquoted.
4233                keyword: _,
4234            }) => Ok(JsonPathElem::Dot {
4235                key: value,
4236                quoted: quote_style.is_some(),
4237            }),
4238
4239            // This token should never be generated on snowflake or generic
4240            // dialects, but we handle it just in case this is used on future
4241            // dialects.
4242            Token::DoubleQuotedString(key) => Ok(JsonPathElem::Dot { key, quoted: true }),
4243
4244            _ => self.expected("variant object key name", token),
4245        }
4246    }
4247
4248    fn parse_json_access(&mut self, expr: Expr) -> Result<Expr, ParserError> {
4249        let path = self.parse_json_path()?;
4250        Ok(Expr::JsonAccess {
4251            value: Box::new(expr),
4252            path,
4253        })
4254    }
4255
4256    fn parse_json_path(&mut self) -> Result<JsonPath, ParserError> {
4257        let mut path = Vec::new();
4258        loop {
4259            match self.next_token().token {
4260                Token::Colon if path.is_empty() && self.peek_token_ref() == &Token::LBracket => {
4261                    self.next_token();
4262                    let key = self.parse_wildcard_expr()?;
4263                    self.expect_token(&Token::RBracket)?;
4264                    path.push(JsonPathElem::ColonBracket { key });
4265                }
4266                Token::Colon if path.is_empty() => {
4267                    path.push(self.parse_json_path_object_key()?);
4268                }
4269                Token::Period if !path.is_empty() => {
4270                    path.push(self.parse_json_path_object_key()?);
4271                }
4272                Token::LBracket => {
4273                    let key = self.parse_wildcard_expr()?;
4274                    self.expect_token(&Token::RBracket)?;
4275
4276                    path.push(JsonPathElem::Bracket { key });
4277                }
4278                _ => {
4279                    self.prev_token();
4280                    break;
4281                }
4282            };
4283        }
4284
4285        debug_assert!(!path.is_empty());
4286        Ok(JsonPath { path })
4287    }
4288
4289    /// Parses the parens following the `[ NOT ] IN` operator.
4290    pub fn parse_in(&mut self, expr: Expr, negated: bool) -> Result<Expr, ParserError> {
4291        // BigQuery allows `IN UNNEST(array_expression)`
4292        // https://cloud.google.com/bigquery/docs/reference/standard-sql/operators#in_operators
4293        if self.parse_keyword(Keyword::UNNEST) {
4294            self.expect_token(&Token::LParen)?;
4295            let array_expr = self.parse_expr()?;
4296            self.expect_token(&Token::RParen)?;
4297            return Ok(Expr::InUnnest {
4298                expr: Box::new(expr),
4299                array_expr: Box::new(array_expr),
4300                negated,
4301            });
4302        }
4303        self.expect_token(&Token::LParen)?;
4304        let in_op = match self.maybe_parse(|p| p.parse_query())? {
4305            Some(subquery) => Expr::InSubquery {
4306                expr: Box::new(expr),
4307                subquery,
4308                negated,
4309            },
4310            None => Expr::InList {
4311                expr: Box::new(expr),
4312                list: if self.dialect.supports_in_empty_list() {
4313                    self.parse_comma_separated0(Parser::parse_expr, Token::RParen)?
4314                } else {
4315                    self.parse_comma_separated(Parser::parse_expr)?
4316                },
4317                negated,
4318            },
4319        };
4320        self.expect_token(&Token::RParen)?;
4321        Ok(in_op)
4322    }
4323
4324    /// Parses `BETWEEN <low> AND <high>`, assuming the `BETWEEN` keyword was already consumed.
4325    pub fn parse_between(&mut self, expr: Expr, negated: bool) -> Result<Expr, ParserError> {
4326        // Stop parsing subexpressions for <low> and <high> on tokens with
4327        // precedence lower than that of `BETWEEN`, such as `AND`, `IS`, etc.
4328        let low = self.parse_subexpr(self.dialect.prec_value(Precedence::Between))?;
4329        self.expect_keyword_is(Keyword::AND)?;
4330        let high = self.parse_subexpr(self.dialect.prec_value(Precedence::Between))?;
4331        Ok(Expr::Between {
4332            expr: Box::new(expr),
4333            negated,
4334            low: Box::new(low),
4335            high: Box::new(high),
4336        })
4337    }
4338
4339    /// Parse a PostgreSQL casting style which is in the form of `expr::datatype`.
4340    pub fn parse_pg_cast(&mut self, expr: Expr) -> Result<Expr, ParserError> {
4341        Ok(Expr::Cast {
4342            kind: CastKind::DoubleColon,
4343            expr: Box::new(expr),
4344            data_type: self.parse_data_type()?,
4345            array: false,
4346            format: None,
4347        })
4348    }
4349
4350    /// Get the precedence of the next token
4351    pub fn get_next_precedence(&self) -> Result<u8, ParserError> {
4352        self.dialect.get_next_precedence_default(self)
4353    }
4354
4355    /// Return the token at the given location, or EOF if the index is beyond
4356    /// the length of the current set of tokens.
4357    pub fn token_at(&self, index: usize) -> &TokenWithSpan {
4358        self.tokens.get(index).unwrap_or(&EOF_TOKEN)
4359    }
4360
4361    /// Return the first non-whitespace token that has not yet been processed
4362    /// or Token::EOF
4363    ///
4364    /// See [`Self::peek_token_ref`] to avoid the copy.
4365    pub fn peek_token(&self) -> TokenWithSpan {
4366        self.peek_nth_token(0)
4367    }
4368
4369    /// Return a reference to the first non-whitespace token that has not yet
4370    /// been processed or Token::EOF
4371    pub fn peek_token_ref(&self) -> &TokenWithSpan {
4372        self.peek_nth_token_ref(0)
4373    }
4374
4375    /// Returns the `N` next non-whitespace tokens that have not yet been
4376    /// processed.
4377    ///
4378    /// Example:
4379    /// ```rust
4380    /// # use sqlparser::dialect::GenericDialect;
4381    /// # use sqlparser::parser::Parser;
4382    /// # use sqlparser::keywords::Keyword;
4383    /// # use sqlparser::tokenizer::{Token, Word};
4384    /// let dialect = GenericDialect {};
4385    /// let mut parser = Parser::new(&dialect).try_with_sql("ORDER BY foo, bar").unwrap();
4386    ///
4387    /// // Note that Rust infers the number of tokens to peek based on the
4388    /// // length of the slice pattern!
4389    /// assert!(matches!(
4390    ///     parser.peek_tokens(),
4391    ///     [
4392    ///         Token::Word(Word { keyword: Keyword::ORDER, .. }),
4393    ///         Token::Word(Word { keyword: Keyword::BY, .. }),
4394    ///     ]
4395    /// ));
4396    /// ```
4397    pub fn peek_tokens<const N: usize>(&self) -> [Token; N] {
4398        self.peek_tokens_with_location()
4399            .map(|with_loc| with_loc.token)
4400    }
4401
4402    /// Returns the `N` next non-whitespace tokens with locations that have not
4403    /// yet been processed.
4404    ///
4405    /// See [`Self::peek_token`] for an example.
4406    pub fn peek_tokens_with_location<const N: usize>(&self) -> [TokenWithSpan; N] {
4407        let mut index = self.index;
4408        core::array::from_fn(|_| loop {
4409            let token = self.tokens.get(index);
4410            index += 1;
4411            if let Some(TokenWithSpan {
4412                token: Token::Whitespace(_),
4413                span: _,
4414            }) = token
4415            {
4416                continue;
4417            }
4418            break token.cloned().unwrap_or(TokenWithSpan {
4419                token: Token::EOF,
4420                span: Span::empty(),
4421            });
4422        })
4423    }
4424
4425    /// Returns references to the `N` next non-whitespace tokens
4426    /// that have not yet been processed.
4427    ///
4428    /// See [`Self::peek_tokens`] for an example.
4429    pub fn peek_tokens_ref<const N: usize>(&self) -> [&TokenWithSpan; N] {
4430        let mut index = self.index;
4431        core::array::from_fn(|_| loop {
4432            let token = self.tokens.get(index);
4433            index += 1;
4434            if let Some(TokenWithSpan {
4435                token: Token::Whitespace(_),
4436                span: _,
4437            }) = token
4438            {
4439                continue;
4440            }
4441            break token.unwrap_or(&EOF_TOKEN);
4442        })
4443    }
4444
4445    /// Return nth non-whitespace token that has not yet been processed
4446    pub fn peek_nth_token(&self, n: usize) -> TokenWithSpan {
4447        self.peek_nth_token_ref(n).clone()
4448    }
4449
4450    /// Return nth non-whitespace token that has not yet been processed
4451    pub fn peek_nth_token_ref(&self, mut n: usize) -> &TokenWithSpan {
4452        let mut index = self.index;
4453        loop {
4454            index += 1;
4455            match self.tokens.get(index - 1) {
4456                Some(TokenWithSpan {
4457                    token: Token::Whitespace(_),
4458                    span: _,
4459                }) => continue,
4460                non_whitespace => {
4461                    if n == 0 {
4462                        return non_whitespace.unwrap_or(&EOF_TOKEN);
4463                    }
4464                    n -= 1;
4465                }
4466            }
4467        }
4468    }
4469
4470    /// Return the first token, possibly whitespace, that has not yet been processed
4471    /// (or None if reached end-of-file).
4472    pub fn peek_token_no_skip(&self) -> TokenWithSpan {
4473        self.peek_nth_token_no_skip(0)
4474    }
4475
4476    /// Return nth token, possibly whitespace, that has not yet been processed.
4477    pub fn peek_nth_token_no_skip(&self, n: usize) -> TokenWithSpan {
4478        self.tokens
4479            .get(self.index + n)
4480            .cloned()
4481            .unwrap_or(TokenWithSpan {
4482                token: Token::EOF,
4483                span: Span::empty(),
4484            })
4485    }
4486
4487    /// Return nth token, possibly whitespace, that has not yet been processed.
4488    fn peek_nth_token_no_skip_ref(&self, n: usize) -> &TokenWithSpan {
4489        self.tokens.get(self.index + n).unwrap_or(&EOF_TOKEN)
4490    }
4491
4492    /// Return true if the next tokens exactly `expected`
4493    ///
4494    /// Does not advance the current token.
4495    fn peek_keywords(&mut self, expected: &[Keyword]) -> bool {
4496        let index = self.index;
4497        let matched = self.parse_keywords(expected);
4498        self.index = index;
4499        matched
4500    }
4501
4502    /// Advances to the next non-whitespace token and returns a copy.
4503    ///
4504    /// Please use [`Self::advance_token`] and [`Self::get_current_token`] to
4505    /// avoid the copy.
4506    pub fn next_token(&mut self) -> TokenWithSpan {
4507        self.advance_token();
4508        self.get_current_token().clone()
4509    }
4510
4511    /// Returns the index of the current token
4512    ///
4513    /// This can be used with APIs that expect an index, such as
4514    /// [`Self::token_at`]
4515    pub fn get_current_index(&self) -> usize {
4516        self.index.saturating_sub(1)
4517    }
4518
4519    /// Return the next unprocessed token, possibly whitespace.
4520    pub fn next_token_no_skip(&mut self) -> Option<&TokenWithSpan> {
4521        self.index += 1;
4522        self.tokens.get(self.index - 1)
4523    }
4524
4525    /// Advances the current token to the next non-whitespace token
4526    ///
4527    /// See [`Self::get_current_token`] to get the current token after advancing
4528    pub fn advance_token(&mut self) {
4529        loop {
4530            self.index += 1;
4531            match self.tokens.get(self.index - 1) {
4532                Some(TokenWithSpan {
4533                    token: Token::Whitespace(_),
4534                    span: _,
4535                }) => continue,
4536                _ => break,
4537            }
4538        }
4539    }
4540
4541    /// Returns a reference to the current token
4542    ///
4543    /// Does not advance the current token.
4544    pub fn get_current_token(&self) -> &TokenWithSpan {
4545        self.token_at(self.index.saturating_sub(1))
4546    }
4547
4548    /// Returns a reference to the previous token
4549    ///
4550    /// Does not advance the current token.
4551    pub fn get_previous_token(&self) -> &TokenWithSpan {
4552        self.token_at(self.index.saturating_sub(2))
4553    }
4554
4555    /// Returns a reference to the next token
4556    ///
4557    /// Does not advance the current token.
4558    pub fn get_next_token(&self) -> &TokenWithSpan {
4559        self.token_at(self.index)
4560    }
4561
4562    /// Seek back the last one non-whitespace token.
4563    ///
4564    /// Must be called after `next_token()`, otherwise might panic. OK to call
4565    /// after `next_token()` indicates an EOF.
4566    ///
4567    // TODO rename to backup_token and deprecate prev_token?
4568    pub fn prev_token(&mut self) {
4569        loop {
4570            assert!(self.index > 0);
4571            self.index -= 1;
4572            if let Some(TokenWithSpan {
4573                token: Token::Whitespace(_),
4574                span: _,
4575            }) = self.tokens.get(self.index)
4576            {
4577                continue;
4578            }
4579            return;
4580        }
4581    }
4582
4583    /// Report `found` was encountered instead of `expected`
4584    pub fn expected<T>(&self, expected: &str, found: TokenWithSpan) -> Result<T, ParserError> {
4585        parser_err!(
4586            format!("Expected: {expected}, found: {found}"),
4587            found.span.start
4588        )
4589    }
4590
4591    /// report `found` was encountered instead of `expected`
4592    pub fn expected_ref<T>(&self, expected: &str, found: &TokenWithSpan) -> Result<T, ParserError> {
4593        parser_err!(
4594            format!("Expected: {expected}, found: {found}"),
4595            found.span.start
4596        )
4597    }
4598
4599    /// Report that the token at `index` was found instead of `expected`.
4600    pub fn expected_at<T>(&self, expected: &str, index: usize) -> Result<T, ParserError> {
4601        let found = self.tokens.get(index).unwrap_or(&EOF_TOKEN);
4602        parser_err!(
4603            format!("Expected: {expected}, found: {found}"),
4604            found.span.start
4605        )
4606    }
4607
4608    /// If the current token is the `expected` keyword, consume it and returns
4609    /// true. Otherwise, no tokens are consumed and returns false.
4610    #[must_use]
4611    pub fn parse_keyword(&mut self, expected: Keyword) -> bool {
4612        if self.peek_keyword(expected) {
4613            self.advance_token();
4614            true
4615        } else {
4616            false
4617        }
4618    }
4619
4620    #[must_use]
4621    /// Check if the current token is the expected keyword without consuming it.
4622    ///
4623    /// Returns true if the current token matches the expected keyword.
4624    pub fn peek_keyword(&self, expected: Keyword) -> bool {
4625        matches!(&self.peek_token_ref().token, Token::Word(w) if expected == w.keyword)
4626    }
4627
4628    /// If the current token is the `expected` keyword followed by
4629    /// specified tokens, consume them and returns true.
4630    /// Otherwise, no tokens are consumed and returns false.
4631    ///
4632    /// Note that if the length of `tokens` is too long, this function will
4633    /// not be efficient as it does a loop on the tokens with `peek_nth_token`
4634    /// each time.
4635    pub fn parse_keyword_with_tokens(&mut self, expected: Keyword, tokens: &[Token]) -> bool {
4636        self.keyword_with_tokens(expected, tokens, true)
4637    }
4638
4639    /// Peeks to see if the current token is the `expected` keyword followed by specified tokens
4640    /// without consuming them.
4641    ///
4642    /// See [Self::parse_keyword_with_tokens] for details.
4643    pub(crate) fn peek_keyword_with_tokens(&mut self, expected: Keyword, tokens: &[Token]) -> bool {
4644        self.keyword_with_tokens(expected, tokens, false)
4645    }
4646
4647    fn keyword_with_tokens(&mut self, expected: Keyword, tokens: &[Token], consume: bool) -> bool {
4648        match &self.peek_token_ref().token {
4649            Token::Word(w) if expected == w.keyword => {
4650                for (idx, token) in tokens.iter().enumerate() {
4651                    if self.peek_nth_token_ref(idx + 1).token != *token {
4652                        return false;
4653                    }
4654                }
4655
4656                if consume {
4657                    for _ in 0..(tokens.len() + 1) {
4658                        self.advance_token();
4659                    }
4660                }
4661
4662                true
4663            }
4664            _ => false,
4665        }
4666    }
4667
4668    /// If the current and subsequent tokens exactly match the `keywords`
4669    /// sequence, consume them and returns true. Otherwise, no tokens are
4670    /// consumed and returns false
4671    #[must_use]
4672    pub fn parse_keywords(&mut self, keywords: &[Keyword]) -> bool {
4673        self.parse_keywords_indexed(keywords).is_some()
4674    }
4675
4676    /// Just like [Self::parse_keywords], but - upon success - returns the
4677    /// token index of the first keyword.
4678    #[must_use]
4679    fn parse_keywords_indexed(&mut self, keywords: &[Keyword]) -> Option<usize> {
4680        let start_index = self.index;
4681        let mut first_keyword_index = None;
4682        for &keyword in keywords {
4683            if !self.parse_keyword(keyword) {
4684                self.index = start_index;
4685                return None;
4686            }
4687            if first_keyword_index.is_none() {
4688                first_keyword_index = Some(self.index.saturating_sub(1));
4689            }
4690        }
4691        first_keyword_index
4692    }
4693
4694    /// If the current token is one of the given `keywords`, returns the keyword
4695    /// that matches, without consuming the token. Otherwise, returns [`None`].
4696    #[must_use]
4697    pub fn peek_one_of_keywords(&self, keywords: &[Keyword]) -> Option<Keyword> {
4698        for keyword in keywords {
4699            if self.peek_keyword(*keyword) {
4700                return Some(*keyword);
4701            }
4702        }
4703        None
4704    }
4705
4706    /// If the current token is one of the given `keywords`, consume the token
4707    /// and return the keyword that matches. Otherwise, no tokens are consumed
4708    /// and returns [`None`].
4709    #[must_use]
4710    pub fn parse_one_of_keywords(&mut self, keywords: &[Keyword]) -> Option<Keyword> {
4711        match &self.peek_token_ref().token {
4712            Token::Word(w) => {
4713                keywords
4714                    .iter()
4715                    .find(|keyword| **keyword == w.keyword)
4716                    .map(|keyword| {
4717                        self.advance_token();
4718                        *keyword
4719                    })
4720            }
4721            _ => None,
4722        }
4723    }
4724
4725    /// If the current token is one of the expected keywords, consume the token
4726    /// and return the keyword that matches. Otherwise, return an error.
4727    pub fn expect_one_of_keywords(&mut self, keywords: &[Keyword]) -> Result<Keyword, ParserError> {
4728        if let Some(keyword) = self.parse_one_of_keywords(keywords) {
4729            Ok(keyword)
4730        } else {
4731            let keywords: Vec<String> = keywords.iter().map(|x| format!("{x:?}")).collect();
4732            self.expected_ref(
4733                &format!("one of {}", keywords.join(" or ")),
4734                self.peek_token_ref(),
4735            )
4736        }
4737    }
4738
4739    /// If the current token is the `expected` keyword, consume the token.
4740    /// Otherwise, return an error.
4741    ///
4742    // todo deprecate in favor of expected_keyword_is
4743    pub fn expect_keyword(&mut self, expected: Keyword) -> Result<TokenWithSpan, ParserError> {
4744        if self.parse_keyword(expected) {
4745            Ok(self.get_current_token().clone())
4746        } else {
4747            self.expected_ref(format!("{:?}", &expected).as_str(), self.peek_token_ref())
4748        }
4749    }
4750
4751    /// If the current token is the `expected` keyword, consume the token.
4752    /// Otherwise, return an error.
4753    ///
4754    /// This differs from expect_keyword only in that the matched keyword
4755    /// token is not returned.
4756    pub fn expect_keyword_is(&mut self, expected: Keyword) -> Result<(), ParserError> {
4757        if self.parse_keyword(expected) {
4758            Ok(())
4759        } else {
4760            self.expected_ref(format!("{:?}", &expected).as_str(), self.peek_token_ref())
4761        }
4762    }
4763
4764    /// If the current and subsequent tokens exactly match the `keywords`
4765    /// sequence, consume them and returns Ok. Otherwise, return an Error.
4766    pub fn expect_keywords(&mut self, expected: &[Keyword]) -> Result<(), ParserError> {
4767        for &kw in expected {
4768            self.expect_keyword_is(kw)?;
4769        }
4770        Ok(())
4771    }
4772
4773    /// Consume the next token if it matches the expected token, otherwise return false
4774    ///
4775    /// See [Self::advance_token] to consume the token unconditionally
4776    #[must_use]
4777    pub fn consume_token(&mut self, expected: &Token) -> bool {
4778        if self.peek_token_ref() == expected {
4779            self.advance_token();
4780            true
4781        } else {
4782            false
4783        }
4784    }
4785
4786    /// If the current and subsequent tokens exactly match the `tokens`
4787    /// sequence, consume them and returns true. Otherwise, no tokens are
4788    /// consumed and returns false
4789    #[must_use]
4790    pub fn consume_tokens(&mut self, tokens: &[Token]) -> bool {
4791        let index = self.index;
4792        for token in tokens {
4793            if !self.consume_token(token) {
4794                self.index = index;
4795                return false;
4796            }
4797        }
4798        true
4799    }
4800
4801    /// Bail out if the current token is not an expected keyword, or consume it if it is
4802    pub fn expect_token(&mut self, expected: &Token) -> Result<TokenWithSpan, ParserError> {
4803        if self.peek_token_ref() == expected {
4804            Ok(self.next_token())
4805        } else {
4806            self.expected_ref(&expected.to_string(), self.peek_token_ref())
4807        }
4808    }
4809
4810    fn parse<T: FromStr>(s: String, loc: Location) -> Result<T, ParserError>
4811    where
4812        <T as FromStr>::Err: Display,
4813    {
4814        s.parse::<T>().map_err(|e| {
4815            ParserError::ParserError(format!(
4816                "Could not parse '{s}' as {}: {e}{loc}",
4817                core::any::type_name::<T>()
4818            ))
4819        })
4820    }
4821
4822    /// Parse a comma-separated list of 1+ SelectItem
4823    pub fn parse_projection(&mut self) -> Result<Vec<SelectItem>, ParserError> {
4824        // BigQuery and Snowflake allow trailing commas, but only in project lists
4825        // e.g. `SELECT 1, 2, FROM t`
4826        // https://cloud.google.com/bigquery/docs/reference/standard-sql/lexical#trailing_commas
4827        // https://docs.snowflake.com/en/release-notes/2024/8_11#select-supports-trailing-commas
4828
4829        let trailing_commas =
4830            self.options.trailing_commas | self.dialect.supports_projection_trailing_commas();
4831
4832        self.parse_comma_separated_with_trailing_commas(
4833            |p| p.parse_select_item(),
4834            trailing_commas,
4835            Self::is_reserved_for_column_alias,
4836        )
4837    }
4838
4839    /// Parse a list of actions for `GRANT` statements.
4840    pub fn parse_actions_list(&mut self) -> Result<Vec<Action>, ParserError> {
4841        let mut values = vec![];
4842        loop {
4843            values.push(self.parse_grant_permission()?);
4844            if !self.consume_token(&Token::Comma) {
4845                break;
4846            } else if self.options.trailing_commas {
4847                match &self.peek_token_ref().token {
4848                    Token::Word(kw) if kw.keyword == Keyword::ON => {
4849                        break;
4850                    }
4851                    Token::RParen
4852                    | Token::SemiColon
4853                    | Token::EOF
4854                    | Token::RBracket
4855                    | Token::RBrace => break,
4856                    _ => continue,
4857                }
4858            }
4859        }
4860        Ok(values)
4861    }
4862
4863    /// Parse a list of [TableWithJoins]
4864    fn parse_table_with_joins(&mut self) -> Result<Vec<TableWithJoins>, ParserError> {
4865        let trailing_commas = self.dialect.supports_from_trailing_commas();
4866
4867        self.parse_comma_separated_with_trailing_commas(
4868            Parser::parse_table_and_joins,
4869            trailing_commas,
4870            |kw, parser| !self.dialect.is_table_factor(kw, parser),
4871        )
4872    }
4873
4874    /// Parse the comma of a comma-separated syntax element.
4875    /// `R` is a predicate that should return true if the next
4876    /// keyword is a reserved keyword.
4877    /// Allows for control over trailing commas
4878    ///
4879    /// Returns true if there is a next element
4880    fn is_parse_comma_separated_end_with_trailing_commas<R>(
4881        &mut self,
4882        trailing_commas: bool,
4883        is_reserved_keyword: &R,
4884    ) -> bool
4885    where
4886        R: Fn(&Keyword, &mut Parser) -> bool,
4887    {
4888        if !self.consume_token(&Token::Comma) {
4889            true
4890        } else if trailing_commas {
4891            let token = self.next_token().token;
4892            let is_end = match token {
4893                Token::Word(ref kw) if is_reserved_keyword(&kw.keyword, self) => true,
4894                Token::RParen | Token::SemiColon | Token::EOF | Token::RBracket | Token::RBrace => {
4895                    true
4896                }
4897                _ => false,
4898            };
4899            self.prev_token();
4900
4901            is_end
4902        } else {
4903            false
4904        }
4905    }
4906
4907    /// Parse the comma of a comma-separated syntax element.
4908    /// Returns true if there is a next element
4909    fn is_parse_comma_separated_end(&mut self) -> bool {
4910        self.is_parse_comma_separated_end_with_trailing_commas(
4911            self.options.trailing_commas,
4912            &Self::is_reserved_for_column_alias,
4913        )
4914    }
4915
4916    /// Parse a comma-separated list of 1+ items accepted by `F`
4917    pub fn parse_comma_separated<T, F>(&mut self, f: F) -> Result<Vec<T>, ParserError>
4918    where
4919        F: FnMut(&mut Parser<'a>) -> Result<T, ParserError>,
4920    {
4921        self.parse_comma_separated_with_trailing_commas(
4922            f,
4923            self.options.trailing_commas,
4924            Self::is_reserved_for_column_alias,
4925        )
4926    }
4927
4928    /// Parse a comma-separated list of 1+ items accepted by `F`.
4929    /// `R` is a predicate that should return true if the next
4930    /// keyword is a reserved keyword.
4931    /// Allows for control over trailing commas.
4932    fn parse_comma_separated_with_trailing_commas<T, F, R>(
4933        &mut self,
4934        mut f: F,
4935        trailing_commas: bool,
4936        is_reserved_keyword: R,
4937    ) -> Result<Vec<T>, ParserError>
4938    where
4939        F: FnMut(&mut Parser<'a>) -> Result<T, ParserError>,
4940        R: Fn(&Keyword, &mut Parser) -> bool,
4941    {
4942        let mut values = vec![];
4943        loop {
4944            values.push(f(self)?);
4945            if self.is_parse_comma_separated_end_with_trailing_commas(
4946                trailing_commas,
4947                &is_reserved_keyword,
4948            ) {
4949                break;
4950            }
4951        }
4952        Ok(values)
4953    }
4954
4955    /// Parse a period-separated list of 1+ items accepted by `F`
4956    fn parse_period_separated<T, F>(&mut self, mut f: F) -> Result<Vec<T>, ParserError>
4957    where
4958        F: FnMut(&mut Parser<'a>) -> Result<T, ParserError>,
4959    {
4960        let mut values = vec![];
4961        loop {
4962            values.push(f(self)?);
4963            if !self.consume_token(&Token::Period) {
4964                break;
4965            }
4966        }
4967        Ok(values)
4968    }
4969
4970    /// Parse a keyword-separated list of 1+ items accepted by `F`
4971    pub fn parse_keyword_separated<T, F>(
4972        &mut self,
4973        keyword: Keyword,
4974        mut f: F,
4975    ) -> Result<Vec<T>, ParserError>
4976    where
4977        F: FnMut(&mut Parser<'a>) -> Result<T, ParserError>,
4978    {
4979        let mut values = vec![];
4980        loop {
4981            values.push(f(self)?);
4982            if !self.parse_keyword(keyword) {
4983                break;
4984            }
4985        }
4986        Ok(values)
4987    }
4988
4989    /// Parse an expression enclosed in parentheses.
4990    pub fn parse_parenthesized<T, F>(&mut self, mut f: F) -> Result<T, ParserError>
4991    where
4992        F: FnMut(&mut Parser<'a>) -> Result<T, ParserError>,
4993    {
4994        self.expect_token(&Token::LParen)?;
4995        let res = f(self)?;
4996        self.expect_token(&Token::RParen)?;
4997        Ok(res)
4998    }
4999
5000    /// Parse a comma-separated list of 0+ items accepted by `F`
5001    /// * `end_token` - expected end token for the closure (e.g. [Token::RParen], [Token::RBrace] ...)
5002    pub fn parse_comma_separated0<T, F>(
5003        &mut self,
5004        f: F,
5005        end_token: Token,
5006    ) -> Result<Vec<T>, ParserError>
5007    where
5008        F: FnMut(&mut Parser<'a>) -> Result<T, ParserError>,
5009    {
5010        if self.peek_token_ref().token == end_token {
5011            return Ok(vec![]);
5012        }
5013
5014        if self.options.trailing_commas && self.peek_tokens() == [Token::Comma, end_token] {
5015            let _ = self.consume_token(&Token::Comma);
5016            return Ok(vec![]);
5017        }
5018
5019        self.parse_comma_separated(f)
5020    }
5021
5022    /// Parses 0 or more statements, each followed by a semicolon.
5023    /// If the next token is any of `terminal_keywords` then no more
5024    /// statements will be parsed.
5025    pub(crate) fn parse_statement_list(
5026        &mut self,
5027        terminal_keywords: &[Keyword],
5028    ) -> Result<Vec<Statement>, ParserError> {
5029        let mut values = vec![];
5030        loop {
5031            match &self.peek_nth_token_ref(0).token {
5032                Token::EOF => break,
5033                Token::Word(w)
5034                    if w.quote_style.is_none() && terminal_keywords.contains(&w.keyword) =>
5035                {
5036                    break;
5037                }
5038                _ => {}
5039            }
5040
5041            values.push(self.parse_statement()?);
5042            self.expect_token(&Token::SemiColon)?;
5043        }
5044        Ok(values)
5045    }
5046
5047    /// Default implementation of a predicate that returns true if
5048    /// the specified keyword is reserved for column alias.
5049    /// See [Dialect::is_column_alias]
5050    fn is_reserved_for_column_alias(kw: &Keyword, parser: &mut Parser) -> bool {
5051        !parser.dialect.is_column_alias(kw, parser)
5052    }
5053
5054    /// Run a parser method `f`, reverting back to the current position if unsuccessful.
5055    /// Returns `ParserError::RecursionLimitExceeded` if `f` returns a `RecursionLimitExceeded`.
5056    /// Returns `Ok(None)` if `f` returns any other error.
5057    pub fn maybe_parse<T, F>(&mut self, f: F) -> Result<Option<T>, ParserError>
5058    where
5059        F: FnMut(&mut Parser) -> Result<T, ParserError>,
5060    {
5061        match self.try_parse(f) {
5062            Ok(t) => Ok(Some(t)),
5063            Err(ParserError::RecursionLimitExceeded) => Err(ParserError::RecursionLimitExceeded),
5064            _ => Ok(None),
5065        }
5066    }
5067
5068    /// Run a parser method `f`, reverting back to the current position if unsuccessful.
5069    pub fn try_parse<T, F>(&mut self, mut f: F) -> Result<T, ParserError>
5070    where
5071        F: FnMut(&mut Parser) -> Result<T, ParserError>,
5072    {
5073        let index = self.index;
5074        match f(self) {
5075            Ok(t) => Ok(t),
5076            Err(e) => {
5077                // Unwind stack if limit exceeded
5078                self.index = index;
5079                Err(e)
5080            }
5081        }
5082    }
5083
5084    /// Parse either `ALL`, `DISTINCT` or `DISTINCT ON (...)`. Returns [`None`] if `ALL` is parsed
5085    /// and results in a [`ParserError`] if both `ALL` and `DISTINCT` are found.
5086    pub fn parse_all_or_distinct(&mut self) -> Result<Option<Distinct>, ParserError> {
5087        let loc = self.peek_token_ref().span.start;
5088        let distinct = match self.parse_one_of_keywords(&[Keyword::ALL, Keyword::DISTINCT]) {
5089            Some(Keyword::ALL) => {
5090                if self.peek_keyword(Keyword::DISTINCT) {
5091                    return parser_err!("Cannot specify ALL then DISTINCT".to_string(), loc);
5092                }
5093                Some(Distinct::All)
5094            }
5095            Some(Keyword::DISTINCT) => {
5096                if self.peek_keyword(Keyword::ALL) {
5097                    return parser_err!("Cannot specify DISTINCT then ALL".to_string(), loc);
5098                }
5099                Some(Distinct::Distinct)
5100            }
5101            None => return Ok(None),
5102            _ => return parser_err!("ALL or DISTINCT", loc),
5103        };
5104
5105        let Some(Distinct::Distinct) = distinct else {
5106            return Ok(distinct);
5107        };
5108        if !self.parse_keyword(Keyword::ON) {
5109            return Ok(Some(Distinct::Distinct));
5110        }
5111
5112        self.expect_token(&Token::LParen)?;
5113        let col_names = if self.consume_token(&Token::RParen) {
5114            self.prev_token();
5115            Vec::new()
5116        } else {
5117            self.parse_comma_separated(Parser::parse_expr)?
5118        };
5119        self.expect_token(&Token::RParen)?;
5120        Ok(Some(Distinct::On(col_names)))
5121    }
5122
5123    /// Parse a SQL CREATE statement
5124    pub fn parse_create(&mut self) -> Result<Statement, ParserError> {
5125        let or_replace = self.parse_keywords(&[Keyword::OR, Keyword::REPLACE]);
5126        let or_alter = self.parse_keywords(&[Keyword::OR, Keyword::ALTER]);
5127        let multiset = self.maybe_parse_multiset();
5128        let local = self.parse_one_of_keywords(&[Keyword::LOCAL]).is_some();
5129        let global = self.parse_one_of_keywords(&[Keyword::GLOBAL]).is_some();
5130        let transient = self.parse_one_of_keywords(&[Keyword::TRANSIENT]).is_some();
5131        let global: Option<bool> = if global {
5132            Some(true)
5133        } else if local {
5134            Some(false)
5135        } else {
5136            None
5137        };
5138        let temporary = self
5139            .parse_one_of_keywords(&[Keyword::TEMP, Keyword::TEMPORARY])
5140            .is_some();
5141        let volatile = self.parse_keyword(Keyword::VOLATILE);
5142        let persistent = dialect_of!(self is DuckDbDialect)
5143            && self.parse_one_of_keywords(&[Keyword::PERSISTENT]).is_some();
5144        let create_view_params = self.parse_create_view_params()?;
5145        if self.peek_keywords(&[Keyword::SNAPSHOT, Keyword::TABLE]) {
5146            self.parse_create_snapshot_table().map(Into::into)
5147        } else if self.parse_keyword(Keyword::TABLE) {
5148            self.parse_create_table(or_replace, temporary, global, transient, volatile, multiset)
5149                .map(Into::into)
5150        } else if self.peek_keyword(Keyword::MATERIALIZED)
5151            || self.peek_keyword(Keyword::VIEW)
5152            || self.peek_keywords(&[Keyword::SECURE, Keyword::MATERIALIZED, Keyword::VIEW])
5153            || self.peek_keywords(&[Keyword::SECURE, Keyword::VIEW])
5154        {
5155            self.parse_create_view(or_alter, or_replace, temporary, create_view_params)
5156                .map(Into::into)
5157        } else if self.parse_keyword(Keyword::POLICY) {
5158            self.parse_create_policy().map(Into::into)
5159        } else if self.parse_keyword(Keyword::EXTERNAL) {
5160            self.parse_create_external_table(or_replace).map(Into::into)
5161        } else if self.parse_keyword(Keyword::FUNCTION) {
5162            self.parse_create_function(or_alter, or_replace, temporary)
5163        } else if self.parse_keyword(Keyword::DOMAIN) {
5164            self.parse_create_domain().map(Into::into)
5165        } else if self.parse_keyword(Keyword::TRIGGER) {
5166            self.parse_create_trigger(temporary, or_alter, or_replace, false)
5167                .map(Into::into)
5168        } else if self.parse_keywords(&[Keyword::CONSTRAINT, Keyword::TRIGGER]) {
5169            self.parse_create_trigger(temporary, or_alter, or_replace, true)
5170                .map(Into::into)
5171        } else if self.parse_keyword(Keyword::MACRO) {
5172            self.parse_create_macro(or_replace, temporary)
5173        } else if self.parse_keyword(Keyword::SECRET) {
5174            self.parse_create_secret(or_replace, temporary, persistent)
5175        } else if self.parse_keyword(Keyword::USER) {
5176            self.parse_create_user(or_replace).map(Into::into)
5177        } else if or_replace {
5178            self.expected_ref(
5179                "[EXTERNAL] TABLE or [MATERIALIZED] VIEW or FUNCTION after CREATE OR REPLACE",
5180                self.peek_token_ref(),
5181            )
5182        } else if self.parse_keyword(Keyword::EXTENSION) {
5183            self.parse_create_extension().map(Into::into)
5184        } else if self.parse_keyword(Keyword::INDEX) {
5185            self.parse_create_index(false).map(Into::into)
5186        } else if self.parse_keywords(&[Keyword::UNIQUE, Keyword::INDEX]) {
5187            self.parse_create_index(true).map(Into::into)
5188        } else if self.parse_keyword(Keyword::VIRTUAL) {
5189            self.parse_create_virtual_table()
5190        } else if self.parse_keyword(Keyword::SCHEMA) {
5191            self.parse_create_schema()
5192        } else if self.parse_keyword(Keyword::DATABASE) {
5193            self.parse_create_database()
5194        } else if self.parse_keyword(Keyword::ROLE) {
5195            self.parse_create_role().map(Into::into)
5196        } else if self.parse_keyword(Keyword::SEQUENCE) {
5197            self.parse_create_sequence(temporary)
5198        } else if self.parse_keyword(Keyword::COLLATION) {
5199            self.parse_create_collation().map(Into::into)
5200        } else if self.parse_keyword(Keyword::TYPE) {
5201            self.parse_create_type()
5202        } else if self.parse_keyword(Keyword::PROCEDURE) {
5203            self.parse_create_procedure(or_alter)
5204        } else if self.parse_keyword(Keyword::CONNECTOR) {
5205            self.parse_create_connector().map(Into::into)
5206        } else if self.parse_keyword(Keyword::OPERATOR) {
5207            // Check if this is CREATE OPERATOR FAMILY or CREATE OPERATOR CLASS
5208            if self.parse_keyword(Keyword::FAMILY) {
5209                self.parse_create_operator_family().map(Into::into)
5210            } else if self.parse_keyword(Keyword::CLASS) {
5211                self.parse_create_operator_class().map(Into::into)
5212            } else {
5213                self.parse_create_operator().map(Into::into)
5214            }
5215        } else if self.parse_keyword(Keyword::SERVER) {
5216            self.parse_pg_create_server()
5217        } else {
5218            self.expected_ref("an object type after CREATE", self.peek_token_ref())
5219        }
5220    }
5221
5222    fn parse_create_user(&mut self, or_replace: bool) -> Result<CreateUser, ParserError> {
5223        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
5224        let name = self.parse_identifier()?;
5225        let options = self
5226            .parse_key_value_options(false, &[Keyword::WITH, Keyword::TAG])?
5227            .options;
5228        let with_tags = self.parse_keyword(Keyword::WITH);
5229        let tags = if self.parse_keyword(Keyword::TAG) {
5230            self.parse_key_value_options(true, &[])?.options
5231        } else {
5232            vec![]
5233        };
5234        Ok(CreateUser {
5235            or_replace,
5236            if_not_exists,
5237            name,
5238            options: KeyValueOptions {
5239                options,
5240                delimiter: KeyValueOptionsDelimiter::Space,
5241            },
5242            with_tags,
5243            tags: KeyValueOptions {
5244                options: tags,
5245                delimiter: KeyValueOptionsDelimiter::Comma,
5246            },
5247        })
5248    }
5249
5250    /// See [DuckDB Docs](https://duckdb.org/docs/sql/statements/create_secret.html) for more details.
5251    pub fn parse_create_secret(
5252        &mut self,
5253        or_replace: bool,
5254        temporary: bool,
5255        persistent: bool,
5256    ) -> Result<Statement, ParserError> {
5257        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
5258
5259        let mut storage_specifier = None;
5260        let mut name = None;
5261        if self.peek_token_ref().token != Token::LParen {
5262            if self.parse_keyword(Keyword::IN) {
5263                storage_specifier = self.parse_identifier().ok()
5264            } else {
5265                name = self.parse_identifier().ok();
5266            }
5267
5268            // Storage specifier may follow the name
5269            if storage_specifier.is_none()
5270                && self.peek_token_ref().token != Token::LParen
5271                && self.parse_keyword(Keyword::IN)
5272            {
5273                storage_specifier = self.parse_identifier().ok();
5274            }
5275        }
5276
5277        self.expect_token(&Token::LParen)?;
5278        self.expect_keyword_is(Keyword::TYPE)?;
5279        let secret_type = self.parse_identifier()?;
5280
5281        let mut options = Vec::new();
5282        if self.consume_token(&Token::Comma) {
5283            options.append(&mut self.parse_comma_separated(|p| {
5284                let key = p.parse_identifier()?;
5285                let value = p.parse_identifier()?;
5286                Ok(SecretOption { key, value })
5287            })?);
5288        }
5289        self.expect_token(&Token::RParen)?;
5290
5291        let temp = match (temporary, persistent) {
5292            (true, false) => Some(true),
5293            (false, true) => Some(false),
5294            (false, false) => None,
5295            _ => self.expected_ref("TEMPORARY or PERSISTENT", self.peek_token_ref())?,
5296        };
5297
5298        Ok(Statement::CreateSecret {
5299            or_replace,
5300            temporary: temp,
5301            if_not_exists,
5302            name,
5303            storage_specifier,
5304            secret_type,
5305            options,
5306        })
5307    }
5308
5309    /// Parse a CACHE TABLE statement
5310    pub fn parse_cache_table(&mut self) -> Result<Statement, ParserError> {
5311        let (mut table_flag, mut options, mut has_as, mut query) = (None, vec![], false, None);
5312        if self.parse_keyword(Keyword::TABLE) {
5313            let table_name = self.parse_object_name(false)?;
5314            if self.peek_token_ref().token != Token::EOF {
5315                if let Token::Word(word) = &self.peek_token_ref().token {
5316                    if word.keyword == Keyword::OPTIONS {
5317                        options = self.parse_options(Keyword::OPTIONS)?
5318                    }
5319                };
5320
5321                if self.peek_token_ref().token != Token::EOF {
5322                    let (a, q) = self.parse_as_query()?;
5323                    has_as = a;
5324                    query = Some(q);
5325                }
5326
5327                Ok(Statement::Cache {
5328                    table_flag,
5329                    table_name,
5330                    has_as,
5331                    options,
5332                    query,
5333                })
5334            } else {
5335                Ok(Statement::Cache {
5336                    table_flag,
5337                    table_name,
5338                    has_as,
5339                    options,
5340                    query,
5341                })
5342            }
5343        } else {
5344            table_flag = Some(self.parse_object_name(false)?);
5345            if self.parse_keyword(Keyword::TABLE) {
5346                let table_name = self.parse_object_name(false)?;
5347                if self.peek_token_ref().token != Token::EOF {
5348                    if let Token::Word(word) = &self.peek_token_ref().token {
5349                        if word.keyword == Keyword::OPTIONS {
5350                            options = self.parse_options(Keyword::OPTIONS)?
5351                        }
5352                    };
5353
5354                    if self.peek_token_ref().token != Token::EOF {
5355                        let (a, q) = self.parse_as_query()?;
5356                        has_as = a;
5357                        query = Some(q);
5358                    }
5359
5360                    Ok(Statement::Cache {
5361                        table_flag,
5362                        table_name,
5363                        has_as,
5364                        options,
5365                        query,
5366                    })
5367                } else {
5368                    Ok(Statement::Cache {
5369                        table_flag,
5370                        table_name,
5371                        has_as,
5372                        options,
5373                        query,
5374                    })
5375                }
5376            } else {
5377                if self.peek_token_ref().token == Token::EOF {
5378                    self.prev_token();
5379                }
5380                self.expected_ref("a `TABLE` keyword", self.peek_token_ref())
5381            }
5382        }
5383    }
5384
5385    /// Parse 'AS' before as query,such as `WITH XXX AS SELECT XXX` oer `CACHE TABLE AS SELECT XXX`
5386    pub fn parse_as_query(&mut self) -> Result<(bool, Box<Query>), ParserError> {
5387        match &self.peek_token_ref().token {
5388            Token::Word(word) => match word.keyword {
5389                Keyword::AS => {
5390                    self.next_token();
5391                    Ok((true, self.parse_query()?))
5392                }
5393                _ => Ok((false, self.parse_query()?)),
5394            },
5395            _ => self.expected_ref("a QUERY statement", self.peek_token_ref()),
5396        }
5397    }
5398
5399    /// Parse a UNCACHE TABLE statement
5400    pub fn parse_uncache_table(&mut self) -> Result<Statement, ParserError> {
5401        self.expect_keyword_is(Keyword::TABLE)?;
5402        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
5403        let table_name = self.parse_object_name(false)?;
5404        Ok(Statement::UNCache {
5405            table_name,
5406            if_exists,
5407        })
5408    }
5409
5410    /// SQLite-specific `CREATE VIRTUAL TABLE`
5411    pub fn parse_create_virtual_table(&mut self) -> Result<Statement, ParserError> {
5412        self.expect_keyword_is(Keyword::TABLE)?;
5413        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
5414        let table_name = self.parse_object_name(false)?;
5415        self.expect_keyword_is(Keyword::USING)?;
5416        let module_name = self.parse_identifier()?;
5417        // SQLite docs note that module "arguments syntax is sufficiently
5418        // general that the arguments can be made to appear as column
5419        // definitions in a traditional CREATE TABLE statement", but
5420        // we don't implement that.
5421        let module_args = self.parse_parenthesized_column_list(Optional, false)?;
5422        Ok(Statement::CreateVirtualTable {
5423            name: table_name,
5424            if_not_exists,
5425            module_name,
5426            module_args,
5427        })
5428    }
5429
5430    /// Parse a `CREATE SCHEMA` statement.
5431    pub fn parse_create_schema(&mut self) -> Result<Statement, ParserError> {
5432        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
5433
5434        let schema_name = self.parse_schema_name()?;
5435
5436        let default_collate_spec = if self.parse_keywords(&[Keyword::DEFAULT, Keyword::COLLATE]) {
5437            Some(self.parse_expr()?)
5438        } else {
5439            None
5440        };
5441
5442        let with = if self.peek_keyword(Keyword::WITH) {
5443            Some(self.parse_options(Keyword::WITH)?)
5444        } else {
5445            None
5446        };
5447
5448        let options = if self.peek_keyword(Keyword::OPTIONS) {
5449            Some(self.parse_options(Keyword::OPTIONS)?)
5450        } else {
5451            None
5452        };
5453
5454        let clone = if self.parse_keyword(Keyword::CLONE) {
5455            Some(self.parse_object_name(false)?)
5456        } else {
5457            None
5458        };
5459
5460        Ok(Statement::CreateSchema {
5461            schema_name,
5462            if_not_exists,
5463            with,
5464            options,
5465            default_collate_spec,
5466            clone,
5467        })
5468    }
5469
5470    fn parse_schema_name(&mut self) -> Result<SchemaName, ParserError> {
5471        if self.parse_keyword(Keyword::AUTHORIZATION) {
5472            Ok(SchemaName::UnnamedAuthorization(self.parse_identifier()?))
5473        } else {
5474            let name = self.parse_object_name(false)?;
5475
5476            if self.parse_keyword(Keyword::AUTHORIZATION) {
5477                Ok(SchemaName::NamedAuthorization(
5478                    name,
5479                    self.parse_identifier()?,
5480                ))
5481            } else {
5482                Ok(SchemaName::Simple(name))
5483            }
5484        }
5485    }
5486
5487    /// Parse a `CREATE DATABASE` statement.
5488    pub fn parse_create_database(&mut self) -> Result<Statement, ParserError> {
5489        let ine = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
5490        let db_name = self.parse_object_name(false)?;
5491        let mut location = None;
5492        let mut managed_location = None;
5493        loop {
5494            match self.parse_one_of_keywords(&[Keyword::LOCATION, Keyword::MANAGEDLOCATION]) {
5495                Some(Keyword::LOCATION) => location = Some(self.parse_literal_string()?),
5496                Some(Keyword::MANAGEDLOCATION) => {
5497                    managed_location = Some(self.parse_literal_string()?)
5498                }
5499                _ => break,
5500            }
5501        }
5502        let clone = if self.parse_keyword(Keyword::CLONE) {
5503            Some(self.parse_object_name(false)?)
5504        } else {
5505            None
5506        };
5507
5508        // Parse MySQL-style [DEFAULT] CHARACTER SET and [DEFAULT] COLLATE options
5509        //
5510        // Note: The docs only mention `CHARACTER SET`, but `CHARSET` is also supported.
5511        // Furthermore, MySQL will only accept one character set, raising an error if there is more
5512        // than one, but will accept multiple collations and use the last one.
5513        //
5514        // <https://dev.mysql.com/doc/refman/8.4/en/create-database.html>
5515        let mut default_charset = None;
5516        let mut default_collation = None;
5517        loop {
5518            let has_default = self.parse_keyword(Keyword::DEFAULT);
5519            if default_charset.is_none() && self.parse_keywords(&[Keyword::CHARACTER, Keyword::SET])
5520                || self.parse_keyword(Keyword::CHARSET)
5521            {
5522                let _ = self.consume_token(&Token::Eq);
5523                default_charset = Some(self.parse_identifier()?.value);
5524            } else if self.parse_keyword(Keyword::COLLATE) {
5525                let _ = self.consume_token(&Token::Eq);
5526                default_collation = Some(self.parse_identifier()?.value);
5527            } else if has_default {
5528                // DEFAULT keyword not followed by CHARACTER SET, CHARSET, or COLLATE
5529                self.prev_token();
5530                break;
5531            } else {
5532                break;
5533            }
5534        }
5535
5536        Ok(Statement::CreateDatabase {
5537            db_name,
5538            if_not_exists: ine,
5539            location,
5540            managed_location,
5541            or_replace: false,
5542            transient: false,
5543            clone,
5544            data_retention_time_in_days: None,
5545            max_data_extension_time_in_days: None,
5546            external_volume: None,
5547            catalog: None,
5548            replace_invalid_characters: None,
5549            default_ddl_collation: None,
5550            storage_serialization_policy: None,
5551            comment: None,
5552            default_charset,
5553            default_collation,
5554            catalog_sync: None,
5555            catalog_sync_namespace_mode: None,
5556            catalog_sync_namespace_flatten_delimiter: None,
5557            with_tags: None,
5558            with_contacts: None,
5559        })
5560    }
5561
5562    /// Parse an optional `USING` clause for `CREATE FUNCTION`.
5563    pub fn parse_optional_create_function_using(
5564        &mut self,
5565    ) -> Result<Option<CreateFunctionUsing>, ParserError> {
5566        if !self.parse_keyword(Keyword::USING) {
5567            return Ok(None);
5568        };
5569        let keyword =
5570            self.expect_one_of_keywords(&[Keyword::JAR, Keyword::FILE, Keyword::ARCHIVE])?;
5571
5572        let uri = self.parse_literal_string()?;
5573
5574        match keyword {
5575            Keyword::JAR => Ok(Some(CreateFunctionUsing::Jar(uri))),
5576            Keyword::FILE => Ok(Some(CreateFunctionUsing::File(uri))),
5577            Keyword::ARCHIVE => Ok(Some(CreateFunctionUsing::Archive(uri))),
5578            _ => self.expected(
5579                "JAR, FILE or ARCHIVE, got {:?}",
5580                TokenWithSpan::wrap(Token::make_keyword(format!("{keyword:?}").as_str())),
5581            ),
5582        }
5583    }
5584
5585    /// Parse a `CREATE FUNCTION` statement.
5586    pub fn parse_create_function(
5587        &mut self,
5588        or_alter: bool,
5589        or_replace: bool,
5590        temporary: bool,
5591    ) -> Result<Statement, ParserError> {
5592        if dialect_of!(self is HiveDialect) {
5593            self.parse_hive_create_function(or_replace, temporary)
5594                .map(Into::into)
5595        } else if dialect_of!(self is PostgreSqlDialect | GenericDialect) {
5596            self.parse_postgres_create_function(or_replace, temporary)
5597                .map(Into::into)
5598        } else if dialect_of!(self is DuckDbDialect) {
5599            self.parse_create_macro(or_replace, temporary)
5600        } else if dialect_of!(self is BigQueryDialect) {
5601            self.parse_bigquery_create_function(or_replace, temporary)
5602                .map(Into::into)
5603        } else if dialect_of!(self is MsSqlDialect) {
5604            self.parse_mssql_create_function(or_alter, or_replace, temporary)
5605                .map(Into::into)
5606        } else {
5607            self.prev_token();
5608            self.expected_ref("an object type after CREATE", self.peek_token_ref())
5609        }
5610    }
5611
5612    /// Parse `CREATE FUNCTION` for [PostgreSQL]
5613    ///
5614    /// [PostgreSQL]: https://www.postgresql.org/docs/15/sql-createfunction.html
5615    fn parse_postgres_create_function(
5616        &mut self,
5617        or_replace: bool,
5618        temporary: bool,
5619    ) -> Result<CreateFunction, ParserError> {
5620        let name = self.parse_object_name(false)?;
5621
5622        self.expect_token(&Token::LParen)?;
5623        let args = if Token::RParen != self.peek_token_ref().token {
5624            self.parse_comma_separated(Parser::parse_function_arg)?
5625        } else {
5626            vec![]
5627        };
5628        self.expect_token(&Token::RParen)?;
5629
5630        let return_type = if self.parse_keyword(Keyword::RETURNS) {
5631            Some(self.parse_function_return_type()?)
5632        } else {
5633            None
5634        };
5635
5636        #[derive(Default)]
5637        struct Body {
5638            language: Option<Ident>,
5639            behavior: Option<FunctionBehavior>,
5640            function_body: Option<CreateFunctionBody>,
5641            called_on_null: Option<FunctionCalledOnNull>,
5642            parallel: Option<FunctionParallel>,
5643            security: Option<FunctionSecurity>,
5644        }
5645        let mut body = Body::default();
5646        let mut set_params: Vec<FunctionDefinitionSetParam> = Vec::new();
5647        loop {
5648            fn ensure_not_set<T>(field: &Option<T>, name: &str) -> Result<(), ParserError> {
5649                if field.is_some() {
5650                    return Err(ParserError::ParserError(format!(
5651                        "{name} specified more than once",
5652                    )));
5653                }
5654                Ok(())
5655            }
5656            if self.parse_keyword(Keyword::AS) {
5657                ensure_not_set(&body.function_body, "AS")?;
5658                body.function_body = Some(self.parse_create_function_body_string()?);
5659            } else if self.parse_keyword(Keyword::LANGUAGE) {
5660                ensure_not_set(&body.language, "LANGUAGE")?;
5661                body.language = Some(self.parse_identifier()?);
5662            } else if self.parse_keyword(Keyword::IMMUTABLE) {
5663                ensure_not_set(&body.behavior, "IMMUTABLE | STABLE | VOLATILE")?;
5664                body.behavior = Some(FunctionBehavior::Immutable);
5665            } else if self.parse_keyword(Keyword::STABLE) {
5666                ensure_not_set(&body.behavior, "IMMUTABLE | STABLE | VOLATILE")?;
5667                body.behavior = Some(FunctionBehavior::Stable);
5668            } else if self.parse_keyword(Keyword::VOLATILE) {
5669                ensure_not_set(&body.behavior, "IMMUTABLE | STABLE | VOLATILE")?;
5670                body.behavior = Some(FunctionBehavior::Volatile);
5671            } else if self.parse_keywords(&[
5672                Keyword::CALLED,
5673                Keyword::ON,
5674                Keyword::NULL,
5675                Keyword::INPUT,
5676            ]) {
5677                ensure_not_set(
5678                    &body.called_on_null,
5679                    "CALLED ON NULL INPUT | RETURNS NULL ON NULL INPUT | STRICT",
5680                )?;
5681                body.called_on_null = Some(FunctionCalledOnNull::CalledOnNullInput);
5682            } else if self.parse_keywords(&[
5683                Keyword::RETURNS,
5684                Keyword::NULL,
5685                Keyword::ON,
5686                Keyword::NULL,
5687                Keyword::INPUT,
5688            ]) {
5689                ensure_not_set(
5690                    &body.called_on_null,
5691                    "CALLED ON NULL INPUT | RETURNS NULL ON NULL INPUT | STRICT",
5692                )?;
5693                body.called_on_null = Some(FunctionCalledOnNull::ReturnsNullOnNullInput);
5694            } else if self.parse_keyword(Keyword::STRICT) {
5695                ensure_not_set(
5696                    &body.called_on_null,
5697                    "CALLED ON NULL INPUT | RETURNS NULL ON NULL INPUT | STRICT",
5698                )?;
5699                body.called_on_null = Some(FunctionCalledOnNull::Strict);
5700            } else if self.parse_keyword(Keyword::PARALLEL) {
5701                ensure_not_set(&body.parallel, "PARALLEL { UNSAFE | RESTRICTED | SAFE }")?;
5702                if self.parse_keyword(Keyword::UNSAFE) {
5703                    body.parallel = Some(FunctionParallel::Unsafe);
5704                } else if self.parse_keyword(Keyword::RESTRICTED) {
5705                    body.parallel = Some(FunctionParallel::Restricted);
5706                } else if self.parse_keyword(Keyword::SAFE) {
5707                    body.parallel = Some(FunctionParallel::Safe);
5708                } else {
5709                    return self
5710                        .expected_ref("one of UNSAFE | RESTRICTED | SAFE", self.peek_token_ref());
5711                }
5712            } else if self.parse_keyword(Keyword::SECURITY) {
5713                ensure_not_set(&body.security, "SECURITY { DEFINER | INVOKER }")?;
5714                if self.parse_keyword(Keyword::DEFINER) {
5715                    body.security = Some(FunctionSecurity::Definer);
5716                } else if self.parse_keyword(Keyword::INVOKER) {
5717                    body.security = Some(FunctionSecurity::Invoker);
5718                } else {
5719                    return self.expected_ref("DEFINER or INVOKER", self.peek_token_ref());
5720                }
5721            } else if self.parse_keyword(Keyword::SET) {
5722                let name = self.parse_object_name(false)?;
5723                let value = if self.parse_keywords(&[Keyword::FROM, Keyword::CURRENT]) {
5724                    FunctionSetValue::FromCurrent
5725                } else {
5726                    if !self.consume_token(&Token::Eq) && !self.parse_keyword(Keyword::TO) {
5727                        return self.expected_ref("= or TO", self.peek_token_ref());
5728                    }
5729                    if self.parse_keyword(Keyword::DEFAULT) {
5730                        FunctionSetValue::Default
5731                    } else {
5732                        let values = self.parse_comma_separated(Parser::parse_expr)?;
5733                        FunctionSetValue::Values(values)
5734                    }
5735                };
5736                set_params.push(FunctionDefinitionSetParam { name, value });
5737            } else if self.parse_keyword(Keyword::RETURN) {
5738                ensure_not_set(&body.function_body, "RETURN")?;
5739                body.function_body = Some(CreateFunctionBody::Return(self.parse_expr()?));
5740            } else {
5741                break;
5742            }
5743        }
5744
5745        Ok(CreateFunction {
5746            or_alter: false,
5747            or_replace,
5748            temporary,
5749            name,
5750            args: Some(args),
5751            return_type,
5752            behavior: body.behavior,
5753            called_on_null: body.called_on_null,
5754            parallel: body.parallel,
5755            security: body.security,
5756            set_params,
5757            language: body.language,
5758            function_body: body.function_body,
5759            if_not_exists: false,
5760            using: None,
5761            determinism_specifier: None,
5762            options: None,
5763            remote_connection: None,
5764        })
5765    }
5766
5767    /// Parse `CREATE FUNCTION` for [Hive]
5768    ///
5769    /// [Hive]: https://cwiki.apache.org/confluence/display/hive/languagemanual+ddl#LanguageManualDDL-Create/Drop/ReloadFunction
5770    fn parse_hive_create_function(
5771        &mut self,
5772        or_replace: bool,
5773        temporary: bool,
5774    ) -> Result<CreateFunction, ParserError> {
5775        let name = self.parse_object_name(false)?;
5776        self.expect_keyword_is(Keyword::AS)?;
5777
5778        let body = self.parse_create_function_body_string()?;
5779        let using = self.parse_optional_create_function_using()?;
5780
5781        Ok(CreateFunction {
5782            or_alter: false,
5783            or_replace,
5784            temporary,
5785            name,
5786            function_body: Some(body),
5787            using,
5788            if_not_exists: false,
5789            args: None,
5790            return_type: None,
5791            behavior: None,
5792            called_on_null: None,
5793            parallel: None,
5794            security: None,
5795            set_params: vec![],
5796            language: None,
5797            determinism_specifier: None,
5798            options: None,
5799            remote_connection: None,
5800        })
5801    }
5802
5803    /// Parse `CREATE FUNCTION` for [BigQuery]
5804    ///
5805    /// [BigQuery]: https://cloud.google.com/bigquery/docs/reference/standard-sql/data-definition-language#create_function_statement
5806    fn parse_bigquery_create_function(
5807        &mut self,
5808        or_replace: bool,
5809        temporary: bool,
5810    ) -> Result<CreateFunction, ParserError> {
5811        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
5812        let (name, args) = self.parse_create_function_name_and_params()?;
5813
5814        let return_type = if self.parse_keyword(Keyword::RETURNS) {
5815            Some(self.parse_function_return_type()?)
5816        } else {
5817            None
5818        };
5819
5820        let determinism_specifier = if self.parse_keyword(Keyword::DETERMINISTIC) {
5821            Some(FunctionDeterminismSpecifier::Deterministic)
5822        } else if self.parse_keywords(&[Keyword::NOT, Keyword::DETERMINISTIC]) {
5823            Some(FunctionDeterminismSpecifier::NotDeterministic)
5824        } else {
5825            None
5826        };
5827
5828        let language = if self.parse_keyword(Keyword::LANGUAGE) {
5829            Some(self.parse_identifier()?)
5830        } else {
5831            None
5832        };
5833
5834        let remote_connection =
5835            if self.parse_keywords(&[Keyword::REMOTE, Keyword::WITH, Keyword::CONNECTION]) {
5836                Some(self.parse_object_name(false)?)
5837            } else {
5838                None
5839            };
5840
5841        // `OPTIONS` may come before of after the function body but
5842        // may be specified at most once.
5843        let mut options = self.maybe_parse_options(Keyword::OPTIONS)?;
5844
5845        let function_body = if remote_connection.is_none() {
5846            self.expect_keyword_is(Keyword::AS)?;
5847            let expr = self.parse_expr()?;
5848            if options.is_none() {
5849                options = self.maybe_parse_options(Keyword::OPTIONS)?;
5850                Some(CreateFunctionBody::AsBeforeOptions {
5851                    body: expr,
5852                    link_symbol: None,
5853                })
5854            } else {
5855                Some(CreateFunctionBody::AsAfterOptions(expr))
5856            }
5857        } else {
5858            None
5859        };
5860
5861        Ok(CreateFunction {
5862            or_alter: false,
5863            or_replace,
5864            temporary,
5865            if_not_exists,
5866            name,
5867            args: Some(args),
5868            return_type,
5869            function_body,
5870            language,
5871            determinism_specifier,
5872            options,
5873            remote_connection,
5874            using: None,
5875            behavior: None,
5876            called_on_null: None,
5877            parallel: None,
5878            security: None,
5879            set_params: vec![],
5880        })
5881    }
5882
5883    /// Parse `CREATE FUNCTION` for [MsSql]
5884    ///
5885    /// [MsSql]: https://learn.microsoft.com/en-us/sql/t-sql/statements/create-function-transact-sql
5886    fn parse_mssql_create_function(
5887        &mut self,
5888        or_alter: bool,
5889        or_replace: bool,
5890        temporary: bool,
5891    ) -> Result<CreateFunction, ParserError> {
5892        let (name, args) = self.parse_create_function_name_and_params()?;
5893
5894        self.expect_keyword(Keyword::RETURNS)?;
5895
5896        let return_table = self.maybe_parse(|p| {
5897            let return_table_name = p.parse_identifier()?;
5898
5899            p.expect_keyword_is(Keyword::TABLE)?;
5900            p.prev_token();
5901
5902            let table_column_defs = match p.parse_data_type()? {
5903                DataType::Table(Some(table_column_defs)) if !table_column_defs.is_empty() => {
5904                    table_column_defs
5905                }
5906                _ => parser_err!(
5907                    "Expected table column definitions after TABLE keyword",
5908                    p.peek_token_ref().span.start
5909                )?,
5910            };
5911
5912            Ok(DataType::NamedTable {
5913                name: ObjectName(vec![ObjectNamePart::Identifier(return_table_name)]),
5914                columns: table_column_defs,
5915            })
5916        })?;
5917
5918        let data_type = match return_table {
5919            Some(table_type) => table_type,
5920            None => self.parse_data_type()?,
5921        };
5922        let return_type = Some(FunctionReturnType::DataType(data_type));
5923
5924        let _ = self.parse_keyword(Keyword::AS);
5925
5926        let function_body = if self.peek_keyword(Keyword::BEGIN) {
5927            let begin_token = self.expect_keyword(Keyword::BEGIN)?;
5928            let statements = self.parse_statement_list(&[Keyword::END])?;
5929            let end_token = self.expect_keyword(Keyword::END)?;
5930
5931            Some(CreateFunctionBody::AsBeginEnd(BeginEndStatements {
5932                begin_token: AttachedToken(begin_token),
5933                statements,
5934                end_token: AttachedToken(end_token),
5935            }))
5936        } else if self.parse_keyword(Keyword::RETURN) {
5937            if self.peek_token_ref().token == Token::LParen {
5938                Some(CreateFunctionBody::AsReturnExpr(self.parse_expr()?))
5939            } else if self.peek_keyword(Keyword::SELECT) {
5940                let select = self.parse_select()?;
5941                Some(CreateFunctionBody::AsReturnSelect(select))
5942            } else {
5943                parser_err!(
5944                    "Expected a subquery (or bare SELECT statement) after RETURN",
5945                    self.peek_token_ref().span.start
5946                )?
5947            }
5948        } else {
5949            parser_err!("Unparsable function body", self.peek_token_ref().span.start)?
5950        };
5951
5952        Ok(CreateFunction {
5953            or_alter,
5954            or_replace,
5955            temporary,
5956            if_not_exists: false,
5957            name,
5958            args: Some(args),
5959            return_type,
5960            function_body,
5961            language: None,
5962            determinism_specifier: None,
5963            options: None,
5964            remote_connection: None,
5965            using: None,
5966            behavior: None,
5967            called_on_null: None,
5968            parallel: None,
5969            security: None,
5970            set_params: vec![],
5971        })
5972    }
5973
5974    fn parse_function_return_type(&mut self) -> Result<FunctionReturnType, ParserError> {
5975        if self.parse_keyword(Keyword::SETOF) {
5976            Ok(FunctionReturnType::SetOf(self.parse_data_type()?))
5977        } else {
5978            Ok(FunctionReturnType::DataType(self.parse_data_type()?))
5979        }
5980    }
5981
5982    fn parse_create_function_name_and_params(
5983        &mut self,
5984    ) -> Result<(ObjectName, Vec<OperateFunctionArg>), ParserError> {
5985        let name = self.parse_object_name(false)?;
5986        let parse_function_param =
5987            |parser: &mut Parser| -> Result<OperateFunctionArg, ParserError> {
5988                let name = parser.parse_identifier()?;
5989                let data_type = parser.parse_data_type()?;
5990                let default_expr = if parser.consume_token(&Token::Eq) {
5991                    Some(parser.parse_expr()?)
5992                } else {
5993                    None
5994                };
5995
5996                Ok(OperateFunctionArg {
5997                    mode: None,
5998                    name: Some(name),
5999                    data_type,
6000                    default_expr,
6001                })
6002            };
6003        self.expect_token(&Token::LParen)?;
6004        let args = self.parse_comma_separated0(parse_function_param, Token::RParen)?;
6005        self.expect_token(&Token::RParen)?;
6006        Ok((name, args))
6007    }
6008
6009    fn parse_function_arg(&mut self) -> Result<OperateFunctionArg, ParserError> {
6010        let mode = if self.parse_keyword(Keyword::IN) {
6011            Some(ArgMode::In)
6012        } else if self.parse_keyword(Keyword::OUT) {
6013            Some(ArgMode::Out)
6014        } else if self.parse_keyword(Keyword::INOUT) {
6015            Some(ArgMode::InOut)
6016        } else if self.parse_keyword(Keyword::VARIADIC) {
6017            Some(ArgMode::Variadic)
6018        } else {
6019            None
6020        };
6021
6022        // parse: [ argname ] argtype
6023        let mut name = None;
6024        let mut data_type = self.parse_data_type()?;
6025
6026        // To check whether the first token is a name or a type, we need to
6027        // peek the next token, which if it is another type keyword, then the
6028        // first token is a name and not a type in itself.
6029        let data_type_idx = self.get_current_index();
6030
6031        // DEFAULT will be parsed as `DataType::Custom`, which is undesirable in this context
6032        fn parse_data_type_no_default(parser: &mut Parser) -> Result<DataType, ParserError> {
6033            if parser.peek_keyword(Keyword::DEFAULT) {
6034                // This dummy error is ignored in `maybe_parse`
6035                parser_err!(
6036                    "The DEFAULT keyword is not a type",
6037                    parser.peek_token_ref().span.start
6038                )
6039            } else {
6040                parser.parse_data_type()
6041            }
6042        }
6043
6044        if let Some(next_data_type) = self.maybe_parse(parse_data_type_no_default)? {
6045            let token = self.token_at(data_type_idx);
6046
6047            // We ensure that the token is a `Word` token, and not other special tokens.
6048            if !matches!(token.token, Token::Word(_)) {
6049                return self.expected("a name or type", token.clone());
6050            }
6051
6052            name = Some(Ident::new(token.to_string()));
6053            data_type = next_data_type;
6054        }
6055
6056        let default_expr = if self.parse_keyword(Keyword::DEFAULT) || self.consume_token(&Token::Eq)
6057        {
6058            Some(self.parse_expr()?)
6059        } else {
6060            None
6061        };
6062        Ok(OperateFunctionArg {
6063            mode,
6064            name,
6065            data_type,
6066            default_expr,
6067        })
6068    }
6069
6070    fn parse_aggregate_function_arg(&mut self) -> Result<OperateFunctionArg, ParserError> {
6071        let mode = if self.parse_keyword(Keyword::IN) {
6072            Some(ArgMode::In)
6073        } else {
6074            if self
6075                .peek_one_of_keywords(&[Keyword::OUT, Keyword::INOUT, Keyword::VARIADIC])
6076                .is_some()
6077            {
6078                return self.expected_ref(
6079                    "IN or argument type in aggregate signature",
6080                    self.peek_token_ref(),
6081                );
6082            }
6083            None
6084        };
6085
6086        // Parse: [ argname ] argtype, but do not consume ORDER from
6087        // `... argtype ORDER BY ...` as a type-name disambiguator.
6088        let mut name = None;
6089        let mut data_type = self.parse_data_type()?;
6090        let data_type_idx = self.get_current_index();
6091
6092        fn parse_data_type_for_aggregate_arg(parser: &mut Parser) -> Result<DataType, ParserError> {
6093            if parser.peek_keyword(Keyword::DEFAULT)
6094                || parser.peek_keyword(Keyword::ORDER)
6095                || parser.peek_token_ref().token == Token::Comma
6096                || parser.peek_token_ref().token == Token::RParen
6097            {
6098                // Dummy error ignored by maybe_parse
6099                parser_err!(
6100                    "The current token cannot start an aggregate argument type",
6101                    parser.peek_token_ref().span.start
6102                )
6103            } else {
6104                parser.parse_data_type()
6105            }
6106        }
6107
6108        if let Some(next_data_type) = self.maybe_parse(parse_data_type_for_aggregate_arg)? {
6109            let token = self.token_at(data_type_idx);
6110            if !matches!(token.token, Token::Word(_)) {
6111                return self.expected("a name or type", token.clone());
6112            }
6113
6114            name = Some(Ident::new(token.to_string()));
6115            data_type = next_data_type;
6116        }
6117
6118        if self.peek_keyword(Keyword::DEFAULT) || self.peek_token_ref().token == Token::Eq {
6119            return self.expected_ref(
6120                "',' or ')' or ORDER BY after aggregate argument type",
6121                self.peek_token_ref(),
6122            );
6123        }
6124
6125        Ok(OperateFunctionArg {
6126            mode,
6127            name,
6128            data_type,
6129            default_expr: None,
6130        })
6131    }
6132
6133    /// Parse statements of the DropTrigger type such as:
6134    ///
6135    /// ```sql
6136    /// DROP TRIGGER [ IF EXISTS ] name ON table_name [ CASCADE | RESTRICT ]
6137    /// ```
6138    pub fn parse_drop_trigger(&mut self) -> Result<DropTrigger, ParserError> {
6139        if !dialect_of!(self is PostgreSqlDialect | SQLiteDialect | GenericDialect | MySqlDialect | MsSqlDialect)
6140        {
6141            self.prev_token();
6142            return self.expected_ref("an object type after DROP", self.peek_token_ref());
6143        }
6144        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
6145        let trigger_name = self.parse_object_name(false)?;
6146        let table_name = if self.parse_keyword(Keyword::ON) {
6147            Some(self.parse_object_name(false)?)
6148        } else {
6149            None
6150        };
6151        let option = match self.parse_one_of_keywords(&[Keyword::CASCADE, Keyword::RESTRICT]) {
6152            Some(Keyword::CASCADE) => Some(ReferentialAction::Cascade),
6153            Some(Keyword::RESTRICT) => Some(ReferentialAction::Restrict),
6154            Some(unexpected_keyword) => return Err(ParserError::ParserError(
6155                format!("Internal parser error: expected any of {{CASCADE, RESTRICT}}, got {unexpected_keyword:?}"),
6156            )),
6157            None => None,
6158        };
6159        Ok(DropTrigger {
6160            if_exists,
6161            trigger_name,
6162            table_name,
6163            option,
6164        })
6165    }
6166
6167    /// Parse a `CREATE TRIGGER` statement.
6168    pub fn parse_create_trigger(
6169        &mut self,
6170        temporary: bool,
6171        or_alter: bool,
6172        or_replace: bool,
6173        is_constraint: bool,
6174    ) -> Result<CreateTrigger, ParserError> {
6175        if !dialect_of!(self is PostgreSqlDialect | SQLiteDialect | GenericDialect | MySqlDialect | MsSqlDialect)
6176        {
6177            self.prev_token();
6178            return self.expected_ref("an object type after CREATE", self.peek_token_ref());
6179        }
6180
6181        let name = self.parse_object_name(false)?;
6182        let period = self.maybe_parse(|parser| parser.parse_trigger_period())?;
6183
6184        let events = self.parse_keyword_separated(Keyword::OR, Parser::parse_trigger_event)?;
6185        self.expect_keyword_is(Keyword::ON)?;
6186        let table_name = self.parse_object_name(false)?;
6187
6188        let referenced_table_name = if self.parse_keyword(Keyword::FROM) {
6189            self.parse_object_name(true).ok()
6190        } else {
6191            None
6192        };
6193
6194        let characteristics = self.parse_constraint_characteristics()?;
6195
6196        let mut referencing = vec![];
6197        if self.parse_keyword(Keyword::REFERENCING) {
6198            while let Some(refer) = self.parse_trigger_referencing()? {
6199                referencing.push(refer);
6200            }
6201        }
6202
6203        let trigger_object = if self.parse_keyword(Keyword::FOR) {
6204            let include_each = self.parse_keyword(Keyword::EACH);
6205            let trigger_object =
6206                match self.expect_one_of_keywords(&[Keyword::ROW, Keyword::STATEMENT])? {
6207                    Keyword::ROW => TriggerObject::Row,
6208                    Keyword::STATEMENT => TriggerObject::Statement,
6209                    unexpected_keyword => return Err(ParserError::ParserError(
6210                        format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in ROW/STATEMENT"),
6211                    )),
6212                };
6213
6214            Some(if include_each {
6215                TriggerObjectKind::ForEach(trigger_object)
6216            } else {
6217                TriggerObjectKind::For(trigger_object)
6218            })
6219        } else {
6220            let _ = self.parse_keyword(Keyword::FOR);
6221
6222            None
6223        };
6224
6225        let condition = self
6226            .parse_keyword(Keyword::WHEN)
6227            .then(|| self.parse_expr())
6228            .transpose()?;
6229
6230        let mut exec_body = None;
6231        let mut statements = None;
6232        if self.parse_keyword(Keyword::EXECUTE) {
6233            exec_body = Some(self.parse_trigger_exec_body()?);
6234        } else {
6235            statements = Some(self.parse_conditional_statements(&[Keyword::END])?);
6236        }
6237
6238        Ok(CreateTrigger {
6239            or_alter,
6240            temporary,
6241            or_replace,
6242            is_constraint,
6243            name,
6244            period,
6245            period_before_table: true,
6246            events,
6247            table_name,
6248            referenced_table_name,
6249            referencing,
6250            trigger_object,
6251            condition,
6252            exec_body,
6253            statements_as: false,
6254            statements,
6255            characteristics,
6256        })
6257    }
6258
6259    /// Parse the period part of a trigger (`BEFORE`, `AFTER`, etc.).
6260    pub fn parse_trigger_period(&mut self) -> Result<TriggerPeriod, ParserError> {
6261        Ok(
6262            match self.expect_one_of_keywords(&[
6263                Keyword::FOR,
6264                Keyword::BEFORE,
6265                Keyword::AFTER,
6266                Keyword::INSTEAD,
6267            ])? {
6268                Keyword::FOR => TriggerPeriod::For,
6269                Keyword::BEFORE => TriggerPeriod::Before,
6270                Keyword::AFTER => TriggerPeriod::After,
6271                Keyword::INSTEAD => self
6272                    .expect_keyword_is(Keyword::OF)
6273                    .map(|_| TriggerPeriod::InsteadOf)?,
6274                unexpected_keyword => return Err(ParserError::ParserError(
6275                    format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in trigger period"),
6276                )),
6277            },
6278        )
6279    }
6280
6281    /// Parse the event part of a trigger (`INSERT`, `UPDATE`, etc.).
6282    pub fn parse_trigger_event(&mut self) -> Result<TriggerEvent, ParserError> {
6283        Ok(
6284            match self.expect_one_of_keywords(&[
6285                Keyword::INSERT,
6286                Keyword::UPDATE,
6287                Keyword::DELETE,
6288                Keyword::TRUNCATE,
6289            ])? {
6290                Keyword::INSERT => TriggerEvent::Insert,
6291                Keyword::UPDATE => {
6292                    if self.parse_keyword(Keyword::OF) {
6293                        let cols = self.parse_comma_separated(Parser::parse_identifier)?;
6294                        TriggerEvent::Update(cols)
6295                    } else {
6296                        TriggerEvent::Update(vec![])
6297                    }
6298                }
6299                Keyword::DELETE => TriggerEvent::Delete,
6300                Keyword::TRUNCATE => TriggerEvent::Truncate,
6301                unexpected_keyword => return Err(ParserError::ParserError(
6302                    format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in trigger event"),
6303                )),
6304            },
6305        )
6306    }
6307
6308    /// Parse the `REFERENCING` clause of a trigger.
6309    pub fn parse_trigger_referencing(&mut self) -> Result<Option<TriggerReferencing>, ParserError> {
6310        let refer_type = match self.parse_one_of_keywords(&[Keyword::OLD, Keyword::NEW]) {
6311            Some(Keyword::OLD) if self.parse_keyword(Keyword::TABLE) => {
6312                TriggerReferencingType::OldTable
6313            }
6314            Some(Keyword::NEW) if self.parse_keyword(Keyword::TABLE) => {
6315                TriggerReferencingType::NewTable
6316            }
6317            _ => {
6318                return Ok(None);
6319            }
6320        };
6321
6322        let is_as = self.parse_keyword(Keyword::AS);
6323        let transition_relation_name = self.parse_object_name(false)?;
6324        Ok(Some(TriggerReferencing {
6325            refer_type,
6326            is_as,
6327            transition_relation_name,
6328        }))
6329    }
6330
6331    /// Parse the execution body of a trigger (`FUNCTION` or `PROCEDURE`).
6332    pub fn parse_trigger_exec_body(&mut self) -> Result<TriggerExecBody, ParserError> {
6333        Ok(TriggerExecBody {
6334            exec_type: match self
6335                .expect_one_of_keywords(&[Keyword::FUNCTION, Keyword::PROCEDURE])?
6336            {
6337                Keyword::FUNCTION => TriggerExecBodyType::Function,
6338                Keyword::PROCEDURE => TriggerExecBodyType::Procedure,
6339                unexpected_keyword => return Err(ParserError::ParserError(
6340                    format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in trigger exec body"),
6341                )),
6342            },
6343            func_desc: self.parse_function_desc()?,
6344        })
6345    }
6346
6347    /// Parse a `CREATE MACRO` statement.
6348    pub fn parse_create_macro(
6349        &mut self,
6350        or_replace: bool,
6351        temporary: bool,
6352    ) -> Result<Statement, ParserError> {
6353        if dialect_of!(self is DuckDbDialect |  GenericDialect) {
6354            let name = self.parse_object_name(false)?;
6355            self.expect_token(&Token::LParen)?;
6356            let args = if self.consume_token(&Token::RParen) {
6357                self.prev_token();
6358                None
6359            } else {
6360                Some(self.parse_comma_separated(Parser::parse_macro_arg)?)
6361            };
6362
6363            self.expect_token(&Token::RParen)?;
6364            self.expect_keyword_is(Keyword::AS)?;
6365
6366            Ok(Statement::CreateMacro {
6367                or_replace,
6368                temporary,
6369                name,
6370                args,
6371                definition: if self.parse_keyword(Keyword::TABLE) {
6372                    MacroDefinition::Table(self.parse_query()?)
6373                } else {
6374                    MacroDefinition::Expr(self.parse_expr()?)
6375                },
6376            })
6377        } else {
6378            self.prev_token();
6379            self.expected_ref("an object type after CREATE", self.peek_token_ref())
6380        }
6381    }
6382
6383    fn parse_macro_arg(&mut self) -> Result<MacroArg, ParserError> {
6384        let name = self.parse_identifier()?;
6385
6386        let default_expr =
6387            if self.consume_token(&Token::Assignment) || self.consume_token(&Token::RArrow) {
6388                Some(self.parse_expr()?)
6389            } else {
6390                None
6391            };
6392        Ok(MacroArg { name, default_expr })
6393    }
6394
6395    /// Parse a `CREATE EXTERNAL TABLE` statement.
6396    pub fn parse_create_external_table(
6397        &mut self,
6398        or_replace: bool,
6399    ) -> Result<CreateTable, ParserError> {
6400        self.expect_keyword_is(Keyword::TABLE)?;
6401        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
6402        let table_name = self.parse_object_name(false)?;
6403        let (columns, constraints) = self.parse_columns()?;
6404
6405        let hive_distribution = self.parse_hive_distribution()?;
6406        let hive_formats = self.parse_hive_formats()?;
6407
6408        let file_format = if let Some(ref hf) = hive_formats {
6409            if let Some(ref ff) = hf.storage {
6410                match ff {
6411                    HiveIOFormat::FileFormat { format } => Some(*format),
6412                    _ => None,
6413                }
6414            } else {
6415                None
6416            }
6417        } else {
6418            None
6419        };
6420        let location = hive_formats.as_ref().and_then(|hf| hf.location.clone());
6421
6422        let with_connection = if self.parse_keywords(&[Keyword::WITH, Keyword::CONNECTION]) {
6423            Some(self.parse_object_name(false)?)
6424        } else {
6425            None
6426        };
6427        let table_properties = self.parse_options(Keyword::TBLPROPERTIES)?;
6428        let table_options = if !table_properties.is_empty() {
6429            CreateTableOptions::TableProperties(table_properties)
6430        } else if let Some(options) = self.maybe_parse_options(Keyword::OPTIONS)? {
6431            CreateTableOptions::Options(options)
6432        } else {
6433            CreateTableOptions::None
6434        };
6435        Ok(CreateTableBuilder::new(table_name)
6436            .columns(columns)
6437            .constraints(constraints)
6438            .hive_distribution(hive_distribution)
6439            .hive_formats(hive_formats)
6440            .table_options(table_options)
6441            .with_connection(with_connection)
6442            .or_replace(or_replace)
6443            .if_not_exists(if_not_exists)
6444            .external(true)
6445            .file_format(file_format)
6446            .location(location)
6447            .build())
6448    }
6449
6450    /// Parse `CREATE SNAPSHOT TABLE` statement.
6451    ///
6452    /// <https://cloud.google.com/bigquery/docs/reference/standard-sql/data-definition-language#create_snapshot_table_statement>
6453    pub fn parse_create_snapshot_table(&mut self) -> Result<CreateTable, ParserError> {
6454        self.expect_keywords(&[Keyword::SNAPSHOT, Keyword::TABLE])?;
6455        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
6456        let table_name = self.parse_object_name(true)?;
6457
6458        self.expect_keyword_is(Keyword::CLONE)?;
6459        let clone = Some(self.parse_object_name(true)?);
6460
6461        let version =
6462            if self.parse_keywords(&[Keyword::FOR, Keyword::SYSTEM_TIME, Keyword::AS, Keyword::OF])
6463            {
6464                Some(TableVersion::ForSystemTimeAsOf(self.parse_expr()?))
6465            } else {
6466                None
6467            };
6468
6469        let table_options = if let Some(options) = self.maybe_parse_options(Keyword::OPTIONS)? {
6470            CreateTableOptions::Options(options)
6471        } else {
6472            CreateTableOptions::None
6473        };
6474
6475        Ok(CreateTableBuilder::new(table_name)
6476            .snapshot(true)
6477            .if_not_exists(if_not_exists)
6478            .clone_clause(clone)
6479            .version(version)
6480            .table_options(table_options)
6481            .build())
6482    }
6483
6484    /// Parse a file format for external tables.
6485    pub fn parse_file_format(&mut self) -> Result<FileFormat, ParserError> {
6486        let next_token = self.next_token();
6487        match &next_token.token {
6488            Token::Word(w) => match w.keyword {
6489                Keyword::AVRO => Ok(FileFormat::AVRO),
6490                Keyword::JSONFILE => Ok(FileFormat::JSONFILE),
6491                Keyword::ORC => Ok(FileFormat::ORC),
6492                Keyword::PARQUET => Ok(FileFormat::PARQUET),
6493                Keyword::RCFILE => Ok(FileFormat::RCFILE),
6494                Keyword::SEQUENCEFILE => Ok(FileFormat::SEQUENCEFILE),
6495                Keyword::TEXTFILE => Ok(FileFormat::TEXTFILE),
6496                _ => self.expected("fileformat", next_token),
6497            },
6498            _ => self.expected("fileformat", next_token),
6499        }
6500    }
6501
6502    fn parse_analyze_format_kind(&mut self) -> Result<AnalyzeFormatKind, ParserError> {
6503        if self.consume_token(&Token::Eq) {
6504            Ok(AnalyzeFormatKind::Assignment(self.parse_analyze_format()?))
6505        } else {
6506            Ok(AnalyzeFormatKind::Keyword(self.parse_analyze_format()?))
6507        }
6508    }
6509
6510    /// Parse an `ANALYZE FORMAT`.
6511    pub fn parse_analyze_format(&mut self) -> Result<AnalyzeFormat, ParserError> {
6512        let next_token = self.next_token();
6513        match &next_token.token {
6514            Token::Word(w) => match w.keyword {
6515                Keyword::TEXT => Ok(AnalyzeFormat::TEXT),
6516                Keyword::GRAPHVIZ => Ok(AnalyzeFormat::GRAPHVIZ),
6517                Keyword::JSON => Ok(AnalyzeFormat::JSON),
6518                Keyword::TREE => Ok(AnalyzeFormat::TREE),
6519                _ => self.expected("fileformat", next_token),
6520            },
6521            _ => self.expected("fileformat", next_token),
6522        }
6523    }
6524
6525    /// Parse a `CREATE VIEW` statement.
6526    pub fn parse_create_view(
6527        &mut self,
6528        or_alter: bool,
6529        or_replace: bool,
6530        temporary: bool,
6531        create_view_params: Option<CreateViewParams>,
6532    ) -> Result<CreateView, ParserError> {
6533        let secure = self.parse_keyword(Keyword::SECURE);
6534        let materialized = self.parse_keyword(Keyword::MATERIALIZED);
6535        self.expect_keyword_is(Keyword::VIEW)?;
6536        let allow_unquoted_hyphen = dialect_of!(self is BigQueryDialect);
6537        // Tries to parse IF NOT EXISTS either before name or after name
6538        // Name before IF NOT EXISTS is supported by snowflake but undocumented
6539        let if_not_exists_first =
6540            self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
6541        let name = self.parse_object_name(allow_unquoted_hyphen)?;
6542        let name_before_not_exists = !if_not_exists_first
6543            && self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
6544        let if_not_exists = if_not_exists_first || name_before_not_exists;
6545        let mut copy_grants = self.parse_keywords(&[Keyword::COPY, Keyword::GRANTS]);
6546        // Many dialects support `OR ALTER` right after `CREATE`, but we don't (yet).
6547        // ANSI SQL and Postgres support RECURSIVE here, but we don't support it either.
6548        let columns = self.parse_view_columns()?;
6549        // Snowflake also documents `COPY GRANTS` *after* the column list; accept
6550        // either position, but not both.
6551        // <https://docs.snowflake.com/en/sql-reference/sql/create-view#syntax>
6552        if !copy_grants {
6553            copy_grants = self.parse_keywords(&[Keyword::COPY, Keyword::GRANTS]);
6554        }
6555        let mut options = CreateTableOptions::None;
6556        let with_options = self.parse_options(Keyword::WITH)?;
6557        if !with_options.is_empty() {
6558            options = CreateTableOptions::With(with_options);
6559        }
6560
6561        let cluster_by = if self.parse_keyword(Keyword::CLUSTER) {
6562            self.expect_keyword_is(Keyword::BY)?;
6563            self.parse_parenthesized_column_list(Optional, false)?
6564        } else {
6565            vec![]
6566        };
6567
6568        if dialect_of!(self is BigQueryDialect | GenericDialect) {
6569            if let Some(opts) = self.maybe_parse_options(Keyword::OPTIONS)? {
6570                if !opts.is_empty() {
6571                    options = CreateTableOptions::Options(opts);
6572                }
6573            };
6574        }
6575
6576        let to = if dialect_of!(self is ClickHouseDialect | GenericDialect)
6577            && self.parse_keyword(Keyword::TO)
6578        {
6579            Some(self.parse_object_name(false)?)
6580        } else {
6581            None
6582        };
6583
6584        let comment = if self.dialect.supports_create_view_comment_syntax()
6585            && self.parse_keyword(Keyword::COMMENT)
6586        {
6587            self.expect_token(&Token::Eq)?;
6588            Some(self.parse_comment_value()?)
6589        } else {
6590            None
6591        };
6592
6593        self.expect_keyword_is(Keyword::AS)?;
6594        let query = self.parse_query()?;
6595        // Optional `WITH [ CASCADED | LOCAL ] CHECK OPTION` is widely supported here.
6596
6597        let with_no_schema_binding = dialect_of!(self is RedshiftSqlDialect | GenericDialect)
6598            && self.parse_keywords(&[
6599                Keyword::WITH,
6600                Keyword::NO,
6601                Keyword::SCHEMA,
6602                Keyword::BINDING,
6603            ]);
6604
6605        Ok(CreateView {
6606            or_alter,
6607            name,
6608            columns,
6609            query,
6610            materialized,
6611            secure,
6612            or_replace,
6613            options,
6614            cluster_by,
6615            comment,
6616            with_no_schema_binding,
6617            if_not_exists,
6618            temporary,
6619            copy_grants,
6620            to,
6621            params: create_view_params,
6622            name_before_not_exists,
6623        })
6624    }
6625
6626    /// Parse optional parameters for the `CREATE VIEW` statement supported by [MySQL].
6627    ///
6628    /// [MySQL]: https://dev.mysql.com/doc/refman/9.1/en/create-view.html
6629    fn parse_create_view_params(&mut self) -> Result<Option<CreateViewParams>, ParserError> {
6630        let algorithm = if self.parse_keyword(Keyword::ALGORITHM) {
6631            self.expect_token(&Token::Eq)?;
6632            Some(
6633                match self.expect_one_of_keywords(&[
6634                    Keyword::UNDEFINED,
6635                    Keyword::MERGE,
6636                    Keyword::TEMPTABLE,
6637                ])? {
6638                    Keyword::UNDEFINED => CreateViewAlgorithm::Undefined,
6639                    Keyword::MERGE => CreateViewAlgorithm::Merge,
6640                    Keyword::TEMPTABLE => CreateViewAlgorithm::TempTable,
6641                    _ => {
6642                        self.prev_token();
6643                        let found = self.next_token();
6644                        return self
6645                            .expected("UNDEFINED or MERGE or TEMPTABLE after ALGORITHM =", found);
6646                    }
6647                },
6648            )
6649        } else {
6650            None
6651        };
6652        let definer = if self.parse_keyword(Keyword::DEFINER) {
6653            self.expect_token(&Token::Eq)?;
6654            Some(self.parse_grantee_name()?)
6655        } else {
6656            None
6657        };
6658        let security = if self.parse_keywords(&[Keyword::SQL, Keyword::SECURITY]) {
6659            Some(
6660                match self.expect_one_of_keywords(&[Keyword::DEFINER, Keyword::INVOKER])? {
6661                    Keyword::DEFINER => CreateViewSecurity::Definer,
6662                    Keyword::INVOKER => CreateViewSecurity::Invoker,
6663                    _ => {
6664                        self.prev_token();
6665                        let found = self.next_token();
6666                        return self.expected("DEFINER or INVOKER after SQL SECURITY", found);
6667                    }
6668                },
6669            )
6670        } else {
6671            None
6672        };
6673        if algorithm.is_some() || definer.is_some() || security.is_some() {
6674            Ok(Some(CreateViewParams {
6675                algorithm,
6676                definer,
6677                security,
6678            }))
6679        } else {
6680            Ok(None)
6681        }
6682    }
6683
6684    /// Parse a `CREATE ROLE` statement.
6685    pub fn parse_create_role(&mut self) -> Result<CreateRole, ParserError> {
6686        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
6687        let names = self.parse_comma_separated(|p| p.parse_object_name(false))?;
6688
6689        let _ = self.parse_keyword(Keyword::WITH); // [ WITH ]
6690
6691        let optional_keywords = if dialect_of!(self is MsSqlDialect) {
6692            vec![Keyword::AUTHORIZATION]
6693        } else if dialect_of!(self is PostgreSqlDialect) {
6694            vec![
6695                Keyword::LOGIN,
6696                Keyword::NOLOGIN,
6697                Keyword::INHERIT,
6698                Keyword::NOINHERIT,
6699                Keyword::BYPASSRLS,
6700                Keyword::NOBYPASSRLS,
6701                Keyword::PASSWORD,
6702                Keyword::CREATEDB,
6703                Keyword::NOCREATEDB,
6704                Keyword::CREATEROLE,
6705                Keyword::NOCREATEROLE,
6706                Keyword::SUPERUSER,
6707                Keyword::NOSUPERUSER,
6708                Keyword::REPLICATION,
6709                Keyword::NOREPLICATION,
6710                Keyword::CONNECTION,
6711                Keyword::VALID,
6712                Keyword::IN,
6713                Keyword::ROLE,
6714                Keyword::ADMIN,
6715                Keyword::USER,
6716            ]
6717        } else {
6718            vec![]
6719        };
6720
6721        // MSSQL
6722        let mut authorization_owner = None;
6723        // Postgres
6724        let mut login = None;
6725        let mut inherit = None;
6726        let mut bypassrls = None;
6727        let mut password = None;
6728        let mut create_db = None;
6729        let mut create_role = None;
6730        let mut superuser = None;
6731        let mut replication = None;
6732        let mut connection_limit = None;
6733        let mut valid_until = None;
6734        let mut in_role = vec![];
6735        let mut in_group = vec![];
6736        let mut role = vec![];
6737        let mut user = vec![];
6738        let mut admin = vec![];
6739
6740        while let Some(keyword) = self.parse_one_of_keywords(&optional_keywords) {
6741            let loc = self
6742                .tokens
6743                .get(self.index - 1)
6744                .map_or(Location { line: 0, column: 0 }, |t| t.span.start);
6745            match keyword {
6746                Keyword::AUTHORIZATION => {
6747                    if authorization_owner.is_some() {
6748                        parser_err!("Found multiple AUTHORIZATION", loc)
6749                    } else {
6750                        authorization_owner = Some(self.parse_object_name(false)?);
6751                        Ok(())
6752                    }
6753                }
6754                Keyword::LOGIN | Keyword::NOLOGIN => {
6755                    if login.is_some() {
6756                        parser_err!("Found multiple LOGIN or NOLOGIN", loc)
6757                    } else {
6758                        login = Some(keyword == Keyword::LOGIN);
6759                        Ok(())
6760                    }
6761                }
6762                Keyword::INHERIT | Keyword::NOINHERIT => {
6763                    if inherit.is_some() {
6764                        parser_err!("Found multiple INHERIT or NOINHERIT", loc)
6765                    } else {
6766                        inherit = Some(keyword == Keyword::INHERIT);
6767                        Ok(())
6768                    }
6769                }
6770                Keyword::BYPASSRLS | Keyword::NOBYPASSRLS => {
6771                    if bypassrls.is_some() {
6772                        parser_err!("Found multiple BYPASSRLS or NOBYPASSRLS", loc)
6773                    } else {
6774                        bypassrls = Some(keyword == Keyword::BYPASSRLS);
6775                        Ok(())
6776                    }
6777                }
6778                Keyword::CREATEDB | Keyword::NOCREATEDB => {
6779                    if create_db.is_some() {
6780                        parser_err!("Found multiple CREATEDB or NOCREATEDB", loc)
6781                    } else {
6782                        create_db = Some(keyword == Keyword::CREATEDB);
6783                        Ok(())
6784                    }
6785                }
6786                Keyword::CREATEROLE | Keyword::NOCREATEROLE => {
6787                    if create_role.is_some() {
6788                        parser_err!("Found multiple CREATEROLE or NOCREATEROLE", loc)
6789                    } else {
6790                        create_role = Some(keyword == Keyword::CREATEROLE);
6791                        Ok(())
6792                    }
6793                }
6794                Keyword::SUPERUSER | Keyword::NOSUPERUSER => {
6795                    if superuser.is_some() {
6796                        parser_err!("Found multiple SUPERUSER or NOSUPERUSER", loc)
6797                    } else {
6798                        superuser = Some(keyword == Keyword::SUPERUSER);
6799                        Ok(())
6800                    }
6801                }
6802                Keyword::REPLICATION | Keyword::NOREPLICATION => {
6803                    if replication.is_some() {
6804                        parser_err!("Found multiple REPLICATION or NOREPLICATION", loc)
6805                    } else {
6806                        replication = Some(keyword == Keyword::REPLICATION);
6807                        Ok(())
6808                    }
6809                }
6810                Keyword::PASSWORD => {
6811                    if password.is_some() {
6812                        parser_err!("Found multiple PASSWORD", loc)
6813                    } else {
6814                        password = if self.parse_keyword(Keyword::NULL) {
6815                            Some(Password::NullPassword)
6816                        } else {
6817                            Some(Password::Password(Expr::Value(self.parse_value()?)))
6818                        };
6819                        Ok(())
6820                    }
6821                }
6822                Keyword::CONNECTION => {
6823                    self.expect_keyword_is(Keyword::LIMIT)?;
6824                    if connection_limit.is_some() {
6825                        parser_err!("Found multiple CONNECTION LIMIT", loc)
6826                    } else {
6827                        connection_limit = Some(Expr::Value(self.parse_number_value()?));
6828                        Ok(())
6829                    }
6830                }
6831                Keyword::VALID => {
6832                    self.expect_keyword_is(Keyword::UNTIL)?;
6833                    if valid_until.is_some() {
6834                        parser_err!("Found multiple VALID UNTIL", loc)
6835                    } else {
6836                        valid_until = Some(Expr::Value(self.parse_value()?));
6837                        Ok(())
6838                    }
6839                }
6840                Keyword::IN => {
6841                    if self.parse_keyword(Keyword::ROLE) {
6842                        if !in_role.is_empty() {
6843                            parser_err!("Found multiple IN ROLE", loc)
6844                        } else {
6845                            in_role = self.parse_comma_separated(|p| p.parse_identifier())?;
6846                            Ok(())
6847                        }
6848                    } else if self.parse_keyword(Keyword::GROUP) {
6849                        if !in_group.is_empty() {
6850                            parser_err!("Found multiple IN GROUP", loc)
6851                        } else {
6852                            in_group = self.parse_comma_separated(|p| p.parse_identifier())?;
6853                            Ok(())
6854                        }
6855                    } else {
6856                        self.expected_ref("ROLE or GROUP after IN", self.peek_token_ref())
6857                    }
6858                }
6859                Keyword::ROLE => {
6860                    if !role.is_empty() {
6861                        parser_err!("Found multiple ROLE", loc)
6862                    } else {
6863                        role = self.parse_comma_separated(|p| p.parse_identifier())?;
6864                        Ok(())
6865                    }
6866                }
6867                Keyword::USER => {
6868                    if !user.is_empty() {
6869                        parser_err!("Found multiple USER", loc)
6870                    } else {
6871                        user = self.parse_comma_separated(|p| p.parse_identifier())?;
6872                        Ok(())
6873                    }
6874                }
6875                Keyword::ADMIN => {
6876                    if !admin.is_empty() {
6877                        parser_err!("Found multiple ADMIN", loc)
6878                    } else {
6879                        admin = self.parse_comma_separated(|p| p.parse_identifier())?;
6880                        Ok(())
6881                    }
6882                }
6883                _ => break,
6884            }?
6885        }
6886
6887        Ok(CreateRole {
6888            names,
6889            if_not_exists,
6890            login,
6891            inherit,
6892            bypassrls,
6893            password,
6894            create_db,
6895            create_role,
6896            replication,
6897            superuser,
6898            connection_limit,
6899            valid_until,
6900            in_role,
6901            in_group,
6902            role,
6903            user,
6904            admin,
6905            authorization_owner,
6906        })
6907    }
6908
6909    /// Parse an `OWNER` clause.
6910    pub fn parse_owner(&mut self) -> Result<Owner, ParserError> {
6911        let owner = match self.parse_one_of_keywords(&[Keyword::CURRENT_USER, Keyword::CURRENT_ROLE, Keyword::SESSION_USER]) {
6912            Some(Keyword::CURRENT_USER) => Owner::CurrentUser,
6913            Some(Keyword::CURRENT_ROLE) => Owner::CurrentRole,
6914            Some(Keyword::SESSION_USER) => Owner::SessionUser,
6915            Some(unexpected_keyword) => return Err(ParserError::ParserError(
6916                format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in owner"),
6917            )),
6918            None => {
6919                match self.parse_identifier() {
6920                    Ok(ident) => Owner::Ident(ident),
6921                    Err(e) => {
6922                        return Err(ParserError::ParserError(format!("Expected: CURRENT_USER, CURRENT_ROLE, SESSION_USER or identifier after OWNER TO. {e}")))
6923                    }
6924                }
6925            }
6926        };
6927        Ok(owner)
6928    }
6929
6930    /// Parses a [Statement::CreateDomain] statement.
6931    fn parse_create_domain(&mut self) -> Result<CreateDomain, ParserError> {
6932        let name = self.parse_object_name(false)?;
6933        self.expect_keyword_is(Keyword::AS)?;
6934        let data_type = self.parse_data_type()?;
6935        let collation = if self.parse_keyword(Keyword::COLLATE) {
6936            Some(self.parse_identifier()?)
6937        } else {
6938            None
6939        };
6940        let default = if self.parse_keyword(Keyword::DEFAULT) {
6941            Some(self.parse_expr()?)
6942        } else {
6943            None
6944        };
6945        let mut constraints = Vec::new();
6946        while let Some(constraint) = self.parse_optional_table_constraint()? {
6947            constraints.push(constraint);
6948        }
6949
6950        Ok(CreateDomain {
6951            name,
6952            data_type,
6953            collation,
6954            default,
6955            constraints,
6956        })
6957    }
6958
6959    /// ```sql
6960    ///     CREATE POLICY name ON table_name [ AS { PERMISSIVE | RESTRICTIVE } ]
6961    ///     [ FOR { ALL | SELECT | INSERT | UPDATE | DELETE } ]
6962    ///     [ TO { role_name | PUBLIC | CURRENT_USER | CURRENT_ROLE | SESSION_USER } [, ...] ]
6963    ///     [ USING ( using_expression ) ]
6964    ///     [ WITH CHECK ( with_check_expression ) ]
6965    /// ```
6966    ///
6967    /// [PostgreSQL Documentation](https://www.postgresql.org/docs/current/sql-createpolicy.html)
6968    pub fn parse_create_policy(&mut self) -> Result<CreatePolicy, ParserError> {
6969        let name = self.parse_identifier()?;
6970        self.expect_keyword_is(Keyword::ON)?;
6971        let table_name = self.parse_object_name(false)?;
6972
6973        let policy_type = if self.parse_keyword(Keyword::AS) {
6974            let keyword =
6975                self.expect_one_of_keywords(&[Keyword::PERMISSIVE, Keyword::RESTRICTIVE])?;
6976            Some(match keyword {
6977                Keyword::PERMISSIVE => CreatePolicyType::Permissive,
6978                Keyword::RESTRICTIVE => CreatePolicyType::Restrictive,
6979                unexpected_keyword => return Err(ParserError::ParserError(
6980                    format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in policy type"),
6981                )),
6982            })
6983        } else {
6984            None
6985        };
6986
6987        let command = if self.parse_keyword(Keyword::FOR) {
6988            let keyword = self.expect_one_of_keywords(&[
6989                Keyword::ALL,
6990                Keyword::SELECT,
6991                Keyword::INSERT,
6992                Keyword::UPDATE,
6993                Keyword::DELETE,
6994            ])?;
6995            Some(match keyword {
6996                Keyword::ALL => CreatePolicyCommand::All,
6997                Keyword::SELECT => CreatePolicyCommand::Select,
6998                Keyword::INSERT => CreatePolicyCommand::Insert,
6999                Keyword::UPDATE => CreatePolicyCommand::Update,
7000                Keyword::DELETE => CreatePolicyCommand::Delete,
7001                unexpected_keyword => return Err(ParserError::ParserError(
7002                    format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in policy command"),
7003                )),
7004            })
7005        } else {
7006            None
7007        };
7008
7009        let to = if self.parse_keyword(Keyword::TO) {
7010            Some(self.parse_comma_separated(|p| p.parse_owner())?)
7011        } else {
7012            None
7013        };
7014
7015        let using = if self.parse_keyword(Keyword::USING) {
7016            self.expect_token(&Token::LParen)?;
7017            let expr = self.parse_expr()?;
7018            self.expect_token(&Token::RParen)?;
7019            Some(expr)
7020        } else {
7021            None
7022        };
7023
7024        let with_check = if self.parse_keywords(&[Keyword::WITH, Keyword::CHECK]) {
7025            self.expect_token(&Token::LParen)?;
7026            let expr = self.parse_expr()?;
7027            self.expect_token(&Token::RParen)?;
7028            Some(expr)
7029        } else {
7030            None
7031        };
7032
7033        Ok(CreatePolicy {
7034            name,
7035            table_name,
7036            policy_type,
7037            command,
7038            to,
7039            using,
7040            with_check,
7041        })
7042    }
7043
7044    /// ```sql
7045    /// CREATE CONNECTOR [IF NOT EXISTS] connector_name
7046    /// [TYPE datasource_type]
7047    /// [URL datasource_url]
7048    /// [COMMENT connector_comment]
7049    /// [WITH DCPROPERTIES(property_name=property_value, ...)]
7050    /// ```
7051    ///
7052    /// [Hive Documentation](https://cwiki.apache.org/confluence/pages/viewpage.action?pageId=27362034#LanguageManualDDL-CreateDataConnectorCreateConnector)
7053    pub fn parse_create_connector(&mut self) -> Result<CreateConnector, ParserError> {
7054        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
7055        let name = self.parse_identifier()?;
7056
7057        let connector_type = if self.parse_keyword(Keyword::TYPE) {
7058            Some(self.parse_literal_string()?)
7059        } else {
7060            None
7061        };
7062
7063        let url = if self.parse_keyword(Keyword::URL) {
7064            Some(self.parse_literal_string()?)
7065        } else {
7066            None
7067        };
7068
7069        let comment = self.parse_optional_inline_comment()?;
7070
7071        let with_dcproperties =
7072            match self.parse_options_with_keywords(&[Keyword::WITH, Keyword::DCPROPERTIES])? {
7073                properties if !properties.is_empty() => Some(properties),
7074                _ => None,
7075            };
7076
7077        Ok(CreateConnector {
7078            name,
7079            if_not_exists,
7080            connector_type,
7081            url,
7082            comment,
7083            with_dcproperties,
7084        })
7085    }
7086
7087    /// Parse an operator name, which can contain special characters like +, -, <, >, =
7088    /// that are tokenized as operator tokens rather than identifiers.
7089    /// This is used for PostgreSQL CREATE OPERATOR statements.
7090    ///
7091    /// Examples: `+`, `myschema.+`, `pg_catalog.<=`
7092    fn parse_operator_name(&mut self) -> Result<ObjectName, ParserError> {
7093        let mut parts = vec![];
7094        loop {
7095            parts.push(ObjectNamePart::Identifier(Ident::new(
7096                self.next_token().to_string(),
7097            )));
7098            if !self.consume_token(&Token::Period) {
7099                break;
7100            }
7101        }
7102        Ok(ObjectName(parts))
7103    }
7104
7105    /// Parse a [Statement::CreateOperator]
7106    ///
7107    /// [PostgreSQL Documentation](https://www.postgresql.org/docs/current/sql-createoperator.html)
7108    pub fn parse_create_operator(&mut self) -> Result<CreateOperator, ParserError> {
7109        let name = self.parse_operator_name()?;
7110        self.expect_token(&Token::LParen)?;
7111
7112        let mut function: Option<ObjectName> = None;
7113        let mut is_procedure = false;
7114        let mut left_arg: Option<DataType> = None;
7115        let mut right_arg: Option<DataType> = None;
7116        let mut options: Vec<OperatorOption> = Vec::new();
7117
7118        loop {
7119            let keyword = self.expect_one_of_keywords(&[
7120                Keyword::FUNCTION,
7121                Keyword::PROCEDURE,
7122                Keyword::LEFTARG,
7123                Keyword::RIGHTARG,
7124                Keyword::COMMUTATOR,
7125                Keyword::NEGATOR,
7126                Keyword::RESTRICT,
7127                Keyword::JOIN,
7128                Keyword::HASHES,
7129                Keyword::MERGES,
7130            ])?;
7131
7132            match keyword {
7133                Keyword::HASHES if !options.iter().any(|o| matches!(o, OperatorOption::Hashes)) => {
7134                    options.push(OperatorOption::Hashes);
7135                }
7136                Keyword::MERGES if !options.iter().any(|o| matches!(o, OperatorOption::Merges)) => {
7137                    options.push(OperatorOption::Merges);
7138                }
7139                Keyword::FUNCTION | Keyword::PROCEDURE if function.is_none() => {
7140                    self.expect_token(&Token::Eq)?;
7141                    function = Some(self.parse_object_name(false)?);
7142                    is_procedure = keyword == Keyword::PROCEDURE;
7143                }
7144                Keyword::LEFTARG if left_arg.is_none() => {
7145                    self.expect_token(&Token::Eq)?;
7146                    left_arg = Some(self.parse_data_type()?);
7147                }
7148                Keyword::RIGHTARG if right_arg.is_none() => {
7149                    self.expect_token(&Token::Eq)?;
7150                    right_arg = Some(self.parse_data_type()?);
7151                }
7152                Keyword::COMMUTATOR
7153                    if !options
7154                        .iter()
7155                        .any(|o| matches!(o, OperatorOption::Commutator(_))) =>
7156                {
7157                    self.expect_token(&Token::Eq)?;
7158                    if self.parse_keyword(Keyword::OPERATOR) {
7159                        self.expect_token(&Token::LParen)?;
7160                        let op = self.parse_operator_name()?;
7161                        self.expect_token(&Token::RParen)?;
7162                        options.push(OperatorOption::Commutator(op));
7163                    } else {
7164                        options.push(OperatorOption::Commutator(self.parse_operator_name()?));
7165                    }
7166                }
7167                Keyword::NEGATOR
7168                    if !options
7169                        .iter()
7170                        .any(|o| matches!(o, OperatorOption::Negator(_))) =>
7171                {
7172                    self.expect_token(&Token::Eq)?;
7173                    if self.parse_keyword(Keyword::OPERATOR) {
7174                        self.expect_token(&Token::LParen)?;
7175                        let op = self.parse_operator_name()?;
7176                        self.expect_token(&Token::RParen)?;
7177                        options.push(OperatorOption::Negator(op));
7178                    } else {
7179                        options.push(OperatorOption::Negator(self.parse_operator_name()?));
7180                    }
7181                }
7182                Keyword::RESTRICT
7183                    if !options
7184                        .iter()
7185                        .any(|o| matches!(o, OperatorOption::Restrict(_))) =>
7186                {
7187                    self.expect_token(&Token::Eq)?;
7188                    options.push(OperatorOption::Restrict(Some(
7189                        self.parse_object_name(false)?,
7190                    )));
7191                }
7192                Keyword::JOIN if !options.iter().any(|o| matches!(o, OperatorOption::Join(_))) => {
7193                    self.expect_token(&Token::Eq)?;
7194                    options.push(OperatorOption::Join(Some(self.parse_object_name(false)?)));
7195                }
7196                _ => {
7197                    return Err(ParserError::ParserError(format!(
7198                        "Duplicate or unexpected keyword {:?} in CREATE OPERATOR",
7199                        keyword
7200                    )))
7201                }
7202            }
7203
7204            if !self.consume_token(&Token::Comma) {
7205                break;
7206            }
7207        }
7208
7209        // Expect closing parenthesis
7210        self.expect_token(&Token::RParen)?;
7211
7212        // FUNCTION is required
7213        let function = function.ok_or_else(|| {
7214            ParserError::ParserError("CREATE OPERATOR requires FUNCTION parameter".to_string())
7215        })?;
7216
7217        Ok(CreateOperator {
7218            name,
7219            function,
7220            is_procedure,
7221            left_arg,
7222            right_arg,
7223            options,
7224        })
7225    }
7226
7227    /// Parse a [Statement::CreateOperatorFamily]
7228    ///
7229    /// [PostgreSQL Documentation](https://www.postgresql.org/docs/current/sql-createopfamily.html)
7230    pub fn parse_create_operator_family(&mut self) -> Result<CreateOperatorFamily, ParserError> {
7231        let name = self.parse_object_name(false)?;
7232        self.expect_keyword(Keyword::USING)?;
7233        let using = self.parse_identifier()?;
7234
7235        Ok(CreateOperatorFamily { name, using })
7236    }
7237
7238    /// Parse a [Statement::CreateOperatorClass]
7239    ///
7240    /// [PostgreSQL Documentation](https://www.postgresql.org/docs/current/sql-createopclass.html)
7241    pub fn parse_create_operator_class(&mut self) -> Result<CreateOperatorClass, ParserError> {
7242        let name = self.parse_object_name(false)?;
7243        let default = self.parse_keyword(Keyword::DEFAULT);
7244        self.expect_keywords(&[Keyword::FOR, Keyword::TYPE])?;
7245        let for_type = self.parse_data_type()?;
7246        self.expect_keyword(Keyword::USING)?;
7247        let using = self.parse_identifier()?;
7248
7249        let family = if self.parse_keyword(Keyword::FAMILY) {
7250            Some(self.parse_object_name(false)?)
7251        } else {
7252            None
7253        };
7254
7255        self.expect_keyword(Keyword::AS)?;
7256
7257        let mut items = vec![];
7258        loop {
7259            if self.parse_keyword(Keyword::OPERATOR) {
7260                let strategy_number = self.parse_literal_uint()?;
7261                let operator_name = self.parse_operator_name()?;
7262
7263                // Optional operator argument types
7264                let op_types = if self.consume_token(&Token::LParen) {
7265                    let left = self.parse_data_type()?;
7266                    self.expect_token(&Token::Comma)?;
7267                    let right = self.parse_data_type()?;
7268                    self.expect_token(&Token::RParen)?;
7269                    Some(OperatorArgTypes { left, right })
7270                } else {
7271                    None
7272                };
7273
7274                // Optional purpose
7275                let purpose = if self.parse_keyword(Keyword::FOR) {
7276                    if self.parse_keyword(Keyword::SEARCH) {
7277                        Some(OperatorPurpose::ForSearch)
7278                    } else if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
7279                        let sort_family = self.parse_object_name(false)?;
7280                        Some(OperatorPurpose::ForOrderBy { sort_family })
7281                    } else {
7282                        return self
7283                            .expected_ref("SEARCH or ORDER BY after FOR", self.peek_token_ref());
7284                    }
7285                } else {
7286                    None
7287                };
7288
7289                items.push(OperatorClassItem::Operator {
7290                    strategy_number,
7291                    operator_name,
7292                    op_types,
7293                    purpose,
7294                });
7295            } else if self.parse_keyword(Keyword::FUNCTION) {
7296                let support_number = self.parse_literal_uint()?;
7297
7298                // Optional operator types
7299                let op_types = if self.consume_token(&Token::LParen)
7300                    && self.peek_token_ref().token != Token::RParen
7301                {
7302                    let mut types = vec![];
7303                    loop {
7304                        types.push(self.parse_data_type()?);
7305                        if !self.consume_token(&Token::Comma) {
7306                            break;
7307                        }
7308                    }
7309                    self.expect_token(&Token::RParen)?;
7310                    Some(types)
7311                } else if self.consume_token(&Token::LParen) {
7312                    self.expect_token(&Token::RParen)?;
7313                    Some(vec![])
7314                } else {
7315                    None
7316                };
7317
7318                let function_name = self.parse_object_name(false)?;
7319
7320                // Function argument types
7321                let argument_types = if self.consume_token(&Token::LParen) {
7322                    let mut types = vec![];
7323                    loop {
7324                        if self.peek_token_ref().token == Token::RParen {
7325                            break;
7326                        }
7327                        types.push(self.parse_data_type()?);
7328                        if !self.consume_token(&Token::Comma) {
7329                            break;
7330                        }
7331                    }
7332                    self.expect_token(&Token::RParen)?;
7333                    types
7334                } else {
7335                    vec![]
7336                };
7337
7338                items.push(OperatorClassItem::Function {
7339                    support_number,
7340                    op_types,
7341                    function_name,
7342                    argument_types,
7343                });
7344            } else if self.parse_keyword(Keyword::STORAGE) {
7345                let storage_type = self.parse_data_type()?;
7346                items.push(OperatorClassItem::Storage { storage_type });
7347            } else {
7348                break;
7349            }
7350
7351            // Check for comma separator
7352            if !self.consume_token(&Token::Comma) {
7353                break;
7354            }
7355        }
7356
7357        Ok(CreateOperatorClass {
7358            name,
7359            default,
7360            for_type,
7361            using,
7362            family,
7363            items,
7364        })
7365    }
7366
7367    /// Parse a `DROP` statement.
7368    pub fn parse_drop(&mut self) -> Result<Statement, ParserError> {
7369        // MySQL dialect supports `TEMPORARY`
7370        let temporary = dialect_of!(self is MySqlDialect | GenericDialect | DuckDbDialect)
7371            && self.parse_keyword(Keyword::TEMPORARY);
7372        let persistent = dialect_of!(self is DuckDbDialect)
7373            && self.parse_one_of_keywords(&[Keyword::PERSISTENT]).is_some();
7374
7375        let object_type = if self.parse_keyword(Keyword::TABLE) {
7376            ObjectType::Table
7377        } else if self.parse_keyword(Keyword::COLLATION) {
7378            ObjectType::Collation
7379        } else if self.parse_keyword(Keyword::VIEW) {
7380            ObjectType::View
7381        } else if self.parse_keywords(&[Keyword::MATERIALIZED, Keyword::VIEW]) {
7382            ObjectType::MaterializedView
7383        } else if self.parse_keyword(Keyword::INDEX) {
7384            ObjectType::Index
7385        } else if self.parse_keyword(Keyword::ROLE) {
7386            ObjectType::Role
7387        } else if self.parse_keyword(Keyword::SCHEMA) {
7388            ObjectType::Schema
7389        } else if self.parse_keyword(Keyword::DATABASE) {
7390            ObjectType::Database
7391        } else if self.parse_keyword(Keyword::SEQUENCE) {
7392            ObjectType::Sequence
7393        } else if self.parse_keyword(Keyword::STAGE) {
7394            ObjectType::Stage
7395        } else if self.parse_keyword(Keyword::TYPE) {
7396            ObjectType::Type
7397        } else if self.parse_keyword(Keyword::USER) {
7398            ObjectType::User
7399        } else if self.parse_keyword(Keyword::STREAM) {
7400            ObjectType::Stream
7401        } else if self.parse_keyword(Keyword::FUNCTION) {
7402            return self.parse_drop_function().map(Into::into);
7403        } else if self.parse_keyword(Keyword::POLICY) {
7404            return self.parse_drop_policy().map(Into::into);
7405        } else if self.parse_keyword(Keyword::CONNECTOR) {
7406            return self.parse_drop_connector();
7407        } else if self.parse_keyword(Keyword::DOMAIN) {
7408            return self.parse_drop_domain().map(Into::into);
7409        } else if self.parse_keyword(Keyword::PROCEDURE) {
7410            return self.parse_drop_procedure();
7411        } else if self.parse_keyword(Keyword::SECRET) {
7412            return self.parse_drop_secret(temporary, persistent);
7413        } else if self.parse_keyword(Keyword::TRIGGER) {
7414            return self.parse_drop_trigger().map(Into::into);
7415        } else if self.parse_keyword(Keyword::EXTENSION) {
7416            return self.parse_drop_extension();
7417        } else if self.parse_keyword(Keyword::OPERATOR) {
7418            // Check if this is DROP OPERATOR FAMILY or DROP OPERATOR CLASS
7419            return if self.parse_keyword(Keyword::FAMILY) {
7420                self.parse_drop_operator_family()
7421            } else if self.parse_keyword(Keyword::CLASS) {
7422                self.parse_drop_operator_class()
7423            } else {
7424                self.parse_drop_operator()
7425            };
7426        } else {
7427            return self.expected_ref(
7428                "COLLATION, CONNECTOR, DATABASE, EXTENSION, FUNCTION, INDEX, OPERATOR, POLICY, PROCEDURE, ROLE, SCHEMA, SECRET, SEQUENCE, STAGE, TABLE, TRIGGER, TYPE, VIEW, MATERIALIZED VIEW or USER after DROP",
7429                self.peek_token_ref(),
7430            );
7431        };
7432        // Many dialects support the non-standard `IF EXISTS` clause and allow
7433        // specifying multiple objects to delete in a single statement
7434        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
7435        let names = self.parse_comma_separated(|p| p.parse_object_name(false))?;
7436
7437        let loc = self.peek_token_ref().span.start;
7438        let cascade = self.parse_keyword(Keyword::CASCADE);
7439        let restrict = self.parse_keyword(Keyword::RESTRICT);
7440        let purge = self.parse_keyword(Keyword::PURGE);
7441        if cascade && restrict {
7442            return parser_err!("Cannot specify both CASCADE and RESTRICT in DROP", loc);
7443        }
7444        if object_type == ObjectType::Role && (cascade || restrict || purge) {
7445            return parser_err!(
7446                "Cannot specify CASCADE, RESTRICT, or PURGE in DROP ROLE",
7447                loc
7448            );
7449        }
7450        let table = if self.parse_keyword(Keyword::ON) {
7451            Some(self.parse_object_name(false)?)
7452        } else {
7453            None
7454        };
7455        Ok(Statement::Drop {
7456            object_type,
7457            if_exists,
7458            names,
7459            cascade,
7460            restrict,
7461            purge,
7462            temporary,
7463            table,
7464        })
7465    }
7466
7467    fn parse_optional_drop_behavior(&mut self) -> Option<DropBehavior> {
7468        match self.parse_one_of_keywords(&[Keyword::CASCADE, Keyword::RESTRICT]) {
7469            Some(Keyword::CASCADE) => Some(DropBehavior::Cascade),
7470            Some(Keyword::RESTRICT) => Some(DropBehavior::Restrict),
7471            _ => None,
7472        }
7473    }
7474
7475    /// ```sql
7476    /// DROP FUNCTION [ IF EXISTS ] name [ ( [ [ argmode ] [ argname ] argtype [, ...] ] ) ] [, ...]
7477    /// [ CASCADE | RESTRICT ]
7478    /// ```
7479    fn parse_drop_function(&mut self) -> Result<DropFunction, ParserError> {
7480        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
7481        let func_desc = self.parse_comma_separated(Parser::parse_function_desc)?;
7482        let drop_behavior = self.parse_optional_drop_behavior();
7483        Ok(DropFunction {
7484            if_exists,
7485            func_desc,
7486            drop_behavior,
7487        })
7488    }
7489
7490    /// ```sql
7491    /// DROP POLICY [ IF EXISTS ] name ON table_name [ CASCADE | RESTRICT ]
7492    /// ```
7493    ///
7494    /// [PostgreSQL Documentation](https://www.postgresql.org/docs/current/sql-droppolicy.html)
7495    fn parse_drop_policy(&mut self) -> Result<DropPolicy, ParserError> {
7496        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
7497        let name = self.parse_identifier()?;
7498        self.expect_keyword_is(Keyword::ON)?;
7499        let table_name = self.parse_object_name(false)?;
7500        let drop_behavior = self.parse_optional_drop_behavior();
7501        Ok(DropPolicy {
7502            if_exists,
7503            name,
7504            table_name,
7505            drop_behavior,
7506        })
7507    }
7508    /// ```sql
7509    /// DROP CONNECTOR [IF EXISTS] name
7510    /// ```
7511    ///
7512    /// See [Hive](https://cwiki.apache.org/confluence/pages/viewpage.action?pageId=27362034#LanguageManualDDL-DropConnector)
7513    fn parse_drop_connector(&mut self) -> Result<Statement, ParserError> {
7514        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
7515        let name = self.parse_identifier()?;
7516        Ok(Statement::DropConnector { if_exists, name })
7517    }
7518
7519    /// ```sql
7520    /// DROP DOMAIN [ IF EXISTS ] name [ CASCADE | RESTRICT ]
7521    /// ```
7522    fn parse_drop_domain(&mut self) -> Result<DropDomain, ParserError> {
7523        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
7524        let name = self.parse_object_name(false)?;
7525        let drop_behavior = self.parse_optional_drop_behavior();
7526        Ok(DropDomain {
7527            if_exists,
7528            name,
7529            drop_behavior,
7530        })
7531    }
7532
7533    /// ```sql
7534    /// DROP PROCEDURE [ IF EXISTS ] name [ ( [ [ argmode ] [ argname ] argtype [, ...] ] ) ] [, ...]
7535    /// [ CASCADE | RESTRICT ]
7536    /// ```
7537    fn parse_drop_procedure(&mut self) -> Result<Statement, ParserError> {
7538        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
7539        let proc_desc = self.parse_comma_separated(Parser::parse_function_desc)?;
7540        let drop_behavior = self.parse_optional_drop_behavior();
7541        Ok(Statement::DropProcedure {
7542            if_exists,
7543            proc_desc,
7544            drop_behavior,
7545        })
7546    }
7547
7548    fn parse_function_desc(&mut self) -> Result<FunctionDesc, ParserError> {
7549        let name = self.parse_object_name(false)?;
7550
7551        let args = if self.consume_token(&Token::LParen) {
7552            if self.consume_token(&Token::RParen) {
7553                Some(vec![])
7554            } else {
7555                let args = self.parse_comma_separated(Parser::parse_function_arg)?;
7556                self.expect_token(&Token::RParen)?;
7557                Some(args)
7558            }
7559        } else {
7560            None
7561        };
7562
7563        Ok(FunctionDesc { name, args })
7564    }
7565
7566    /// See [DuckDB Docs](https://duckdb.org/docs/sql/statements/create_secret.html) for more details.
7567    fn parse_drop_secret(
7568        &mut self,
7569        temporary: bool,
7570        persistent: bool,
7571    ) -> Result<Statement, ParserError> {
7572        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
7573        let name = self.parse_identifier()?;
7574        let storage_specifier = if self.parse_keyword(Keyword::FROM) {
7575            self.parse_identifier().ok()
7576        } else {
7577            None
7578        };
7579        let temp = match (temporary, persistent) {
7580            (true, false) => Some(true),
7581            (false, true) => Some(false),
7582            (false, false) => None,
7583            _ => self.expected_ref("TEMPORARY or PERSISTENT", self.peek_token_ref())?,
7584        };
7585
7586        Ok(Statement::DropSecret {
7587            if_exists,
7588            temporary: temp,
7589            name,
7590            storage_specifier,
7591        })
7592    }
7593
7594    /// Parse a `DECLARE` statement.
7595    ///
7596    /// ```sql
7597    /// DECLARE name [ BINARY ] [ ASENSITIVE | INSENSITIVE ] [ [ NO ] SCROLL ]
7598    ///     CURSOR [ { WITH | WITHOUT } HOLD ] FOR query
7599    /// ```
7600    ///
7601    /// The syntax can vary significantly between warehouses. See the grammar
7602    /// on the warehouse specific function in such cases.
7603    pub fn parse_declare(&mut self) -> Result<Statement, ParserError> {
7604        if dialect_of!(self is BigQueryDialect) {
7605            return self.parse_big_query_declare();
7606        }
7607        if dialect_of!(self is SnowflakeDialect) {
7608            return self.parse_snowflake_declare();
7609        }
7610        if dialect_of!(self is MsSqlDialect) {
7611            return self.parse_mssql_declare();
7612        }
7613
7614        let name = self.parse_identifier()?;
7615
7616        let binary = Some(self.parse_keyword(Keyword::BINARY));
7617        let sensitive = if self.parse_keyword(Keyword::INSENSITIVE) {
7618            Some(true)
7619        } else if self.parse_keyword(Keyword::ASENSITIVE) {
7620            Some(false)
7621        } else {
7622            None
7623        };
7624        let scroll = if self.parse_keyword(Keyword::SCROLL) {
7625            Some(true)
7626        } else if self.parse_keywords(&[Keyword::NO, Keyword::SCROLL]) {
7627            Some(false)
7628        } else {
7629            None
7630        };
7631
7632        self.expect_keyword_is(Keyword::CURSOR)?;
7633        let declare_type = Some(DeclareType::Cursor);
7634
7635        let hold = match self.parse_one_of_keywords(&[Keyword::WITH, Keyword::WITHOUT]) {
7636            Some(keyword) => {
7637                self.expect_keyword_is(Keyword::HOLD)?;
7638
7639                match keyword {
7640                    Keyword::WITH => Some(true),
7641                    Keyword::WITHOUT => Some(false),
7642                    unexpected_keyword => return Err(ParserError::ParserError(
7643                        format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in cursor hold"),
7644                    )),
7645                }
7646            }
7647            None => None,
7648        };
7649
7650        self.expect_keyword_is(Keyword::FOR)?;
7651
7652        let query = Some(self.parse_query()?);
7653
7654        Ok(Statement::Declare {
7655            stmts: vec![Declare {
7656                names: vec![name],
7657                data_type: None,
7658                assignment: None,
7659                declare_type,
7660                binary,
7661                sensitive,
7662                scroll,
7663                hold,
7664                for_query: query,
7665            }],
7666        })
7667    }
7668
7669    /// Parse a [BigQuery] `DECLARE` statement.
7670    ///
7671    /// Syntax:
7672    /// ```text
7673    /// DECLARE variable_name[, ...] [{ <variable_type> | <DEFAULT expression> }];
7674    /// ```
7675    /// [BigQuery]: https://cloud.google.com/bigquery/docs/reference/standard-sql/procedural-language#declare
7676    pub fn parse_big_query_declare(&mut self) -> Result<Statement, ParserError> {
7677        let names = self.parse_comma_separated(Parser::parse_identifier)?;
7678
7679        let data_type = match &self.peek_token_ref().token {
7680            Token::Word(w) if w.keyword == Keyword::DEFAULT => None,
7681            _ => Some(self.parse_data_type()?),
7682        };
7683
7684        let expr = if data_type.is_some() {
7685            if self.parse_keyword(Keyword::DEFAULT) {
7686                Some(self.parse_expr()?)
7687            } else {
7688                None
7689            }
7690        } else {
7691            // If no variable type - default expression must be specified, per BQ docs.
7692            // i.e `DECLARE foo;` is invalid.
7693            self.expect_keyword_is(Keyword::DEFAULT)?;
7694            Some(self.parse_expr()?)
7695        };
7696
7697        Ok(Statement::Declare {
7698            stmts: vec![Declare {
7699                names,
7700                data_type,
7701                assignment: expr.map(|expr| DeclareAssignment::Default(Box::new(expr))),
7702                declare_type: None,
7703                binary: None,
7704                sensitive: None,
7705                scroll: None,
7706                hold: None,
7707                for_query: None,
7708            }],
7709        })
7710    }
7711
7712    /// Parse a [Snowflake] `DECLARE` statement.
7713    ///
7714    /// Syntax:
7715    /// ```text
7716    /// DECLARE
7717    ///   [{ <variable_declaration>
7718    ///      | <cursor_declaration>
7719    ///      | <resultset_declaration>
7720    ///      | <exception_declaration> }; ... ]
7721    ///
7722    /// <variable_declaration>
7723    /// <variable_name> [<type>] [ { DEFAULT | := } <expression>]
7724    ///
7725    /// <cursor_declaration>
7726    /// <cursor_name> CURSOR FOR <query>
7727    ///
7728    /// <resultset_declaration>
7729    /// <resultset_name> RESULTSET [ { DEFAULT | := } ( <query> ) ] ;
7730    ///
7731    /// <exception_declaration>
7732    /// <exception_name> EXCEPTION [ ( <exception_number> , '<exception_message>' ) ] ;
7733    /// ```
7734    ///
7735    /// [Snowflake]: https://docs.snowflake.com/en/sql-reference/snowflake-scripting/declare
7736    pub fn parse_snowflake_declare(&mut self) -> Result<Statement, ParserError> {
7737        let mut stmts = vec![];
7738        loop {
7739            let name = self.parse_identifier()?;
7740            let (declare_type, for_query, assigned_expr, data_type) =
7741                if self.parse_keyword(Keyword::CURSOR) {
7742                    self.expect_keyword_is(Keyword::FOR)?;
7743                    match &self.peek_token_ref().token {
7744                        Token::Word(w) if w.keyword == Keyword::SELECT => (
7745                            Some(DeclareType::Cursor),
7746                            Some(self.parse_query()?),
7747                            None,
7748                            None,
7749                        ),
7750                        _ => (
7751                            Some(DeclareType::Cursor),
7752                            None,
7753                            Some(DeclareAssignment::For(Box::new(self.parse_expr()?))),
7754                            None,
7755                        ),
7756                    }
7757                } else if self.parse_keyword(Keyword::RESULTSET) {
7758                    let assigned_expr = if self.peek_token_ref().token != Token::SemiColon {
7759                        self.parse_snowflake_variable_declaration_expression()?
7760                    } else {
7761                        // Nothing more to do. The statement has no further parameters.
7762                        None
7763                    };
7764
7765                    (Some(DeclareType::ResultSet), None, assigned_expr, None)
7766                } else if self.parse_keyword(Keyword::EXCEPTION) {
7767                    let assigned_expr = if self.peek_token_ref().token == Token::LParen {
7768                        Some(DeclareAssignment::Expr(Box::new(self.parse_expr()?)))
7769                    } else {
7770                        // Nothing more to do. The statement has no further parameters.
7771                        None
7772                    };
7773
7774                    (Some(DeclareType::Exception), None, assigned_expr, None)
7775                } else {
7776                    // Without an explicit keyword, the only valid option is variable declaration.
7777                    let (assigned_expr, data_type) = if let Some(assigned_expr) =
7778                        self.parse_snowflake_variable_declaration_expression()?
7779                    {
7780                        (Some(assigned_expr), None)
7781                    } else if let Token::Word(_) = &self.peek_token_ref().token {
7782                        let data_type = self.parse_data_type()?;
7783                        (
7784                            self.parse_snowflake_variable_declaration_expression()?,
7785                            Some(data_type),
7786                        )
7787                    } else {
7788                        (None, None)
7789                    };
7790                    (None, None, assigned_expr, data_type)
7791                };
7792            let stmt = Declare {
7793                names: vec![name],
7794                data_type,
7795                assignment: assigned_expr,
7796                declare_type,
7797                binary: None,
7798                sensitive: None,
7799                scroll: None,
7800                hold: None,
7801                for_query,
7802            };
7803
7804            stmts.push(stmt);
7805            if self.consume_token(&Token::SemiColon) {
7806                match &self.peek_token_ref().token {
7807                    Token::Word(w)
7808                        if ALL_KEYWORDS
7809                            .binary_search(&w.value.to_uppercase().as_str())
7810                            .is_err() =>
7811                    {
7812                        // Not a keyword - start of a new declaration.
7813                        continue;
7814                    }
7815                    _ => {
7816                        // Put back the semicolon, this is the end of the DECLARE statement.
7817                        self.prev_token();
7818                    }
7819                }
7820            }
7821
7822            break;
7823        }
7824
7825        Ok(Statement::Declare { stmts })
7826    }
7827
7828    /// Parse a [MsSql] `DECLARE` statement.
7829    ///
7830    /// Syntax:
7831    /// ```text
7832    /// DECLARE
7833    // {
7834    //   { @local_variable [AS] data_type [ = value ] }
7835    //   | { @cursor_variable_name CURSOR [ FOR ] }
7836    // } [ ,...n ]
7837    /// ```
7838    /// [MsSql]: https://learn.microsoft.com/en-us/sql/t-sql/language-elements/declare-local-variable-transact-sql?view=sql-server-ver16
7839    pub fn parse_mssql_declare(&mut self) -> Result<Statement, ParserError> {
7840        let stmts = self.parse_comma_separated(Parser::parse_mssql_declare_stmt)?;
7841
7842        Ok(Statement::Declare { stmts })
7843    }
7844
7845    /// Parse the body of a [MsSql] `DECLARE`statement.
7846    ///
7847    /// Syntax:
7848    /// ```text
7849    // {
7850    //   { @local_variable [AS] data_type [ = value ] }
7851    //   | { @cursor_variable_name CURSOR [ FOR ]}
7852    // } [ ,...n ]
7853    /// ```
7854    /// [MsSql]: https://learn.microsoft.com/en-us/sql/t-sql/language-elements/declare-local-variable-transact-sql?view=sql-server-ver16
7855    pub fn parse_mssql_declare_stmt(&mut self) -> Result<Declare, ParserError> {
7856        let name = {
7857            let ident = self.parse_identifier()?;
7858            if !ident.value.starts_with('@')
7859                && !matches!(
7860                    &self.peek_token_ref().token,
7861                    Token::Word(w) if w.keyword == Keyword::CURSOR
7862                )
7863            {
7864                Err(ParserError::TokenizerError(
7865                    "Invalid MsSql variable declaration.".to_string(),
7866                ))
7867            } else {
7868                Ok(ident)
7869            }
7870        }?;
7871
7872        let (declare_type, data_type) = match &self.peek_token_ref().token {
7873            Token::Word(w) => match w.keyword {
7874                Keyword::CURSOR => {
7875                    self.next_token();
7876                    (Some(DeclareType::Cursor), None)
7877                }
7878                Keyword::AS => {
7879                    self.next_token();
7880                    (None, Some(self.parse_data_type()?))
7881                }
7882                _ => (None, Some(self.parse_data_type()?)),
7883            },
7884            _ => (None, Some(self.parse_data_type()?)),
7885        };
7886
7887        let (for_query, assignment) = if self.peek_keyword(Keyword::FOR) {
7888            self.next_token();
7889            let query = Some(self.parse_query()?);
7890            (query, None)
7891        } else {
7892            let assignment = self.parse_mssql_variable_declaration_expression()?;
7893            (None, assignment)
7894        };
7895
7896        Ok(Declare {
7897            names: vec![name],
7898            data_type,
7899            assignment,
7900            declare_type,
7901            binary: None,
7902            sensitive: None,
7903            scroll: None,
7904            hold: None,
7905            for_query,
7906        })
7907    }
7908
7909    /// Parses the assigned expression in a variable declaration.
7910    ///
7911    /// Syntax:
7912    /// ```text
7913    /// [ { DEFAULT | := } <expression>]
7914    /// ```
7915    /// <https://docs.snowflake.com/en/sql-reference/snowflake-scripting/declare#variable-declaration-syntax>
7916    pub fn parse_snowflake_variable_declaration_expression(
7917        &mut self,
7918    ) -> Result<Option<DeclareAssignment>, ParserError> {
7919        Ok(match &self.peek_token_ref().token {
7920            Token::Word(w) if w.keyword == Keyword::DEFAULT => {
7921                self.next_token(); // Skip `DEFAULT`
7922                Some(DeclareAssignment::Default(Box::new(self.parse_expr()?)))
7923            }
7924            Token::Assignment => {
7925                self.next_token(); // Skip `:=`
7926                Some(DeclareAssignment::DuckAssignment(Box::new(
7927                    self.parse_expr()?,
7928                )))
7929            }
7930            _ => None,
7931        })
7932    }
7933
7934    /// Parses the assigned expression in a variable declaration.
7935    ///
7936    /// Syntax:
7937    /// ```text
7938    /// [ = <expression>]
7939    /// ```
7940    pub fn parse_mssql_variable_declaration_expression(
7941        &mut self,
7942    ) -> Result<Option<DeclareAssignment>, ParserError> {
7943        Ok(match &self.peek_token_ref().token {
7944            Token::Eq => {
7945                self.next_token(); // Skip `=`
7946                Some(DeclareAssignment::MsSqlAssignment(Box::new(
7947                    self.parse_expr()?,
7948                )))
7949            }
7950            _ => None,
7951        })
7952    }
7953
7954    /// Parse `FETCH [direction] { FROM | IN } cursor INTO target;` statement.
7955    pub fn parse_fetch_statement(&mut self) -> Result<Statement, ParserError> {
7956        let direction = if self.parse_keyword(Keyword::NEXT) {
7957            FetchDirection::Next
7958        } else if self.parse_keyword(Keyword::PRIOR) {
7959            FetchDirection::Prior
7960        } else if self.parse_keyword(Keyword::FIRST) {
7961            FetchDirection::First
7962        } else if self.parse_keyword(Keyword::LAST) {
7963            FetchDirection::Last
7964        } else if self.parse_keyword(Keyword::ABSOLUTE) {
7965            FetchDirection::Absolute {
7966                limit: self.parse_number_value()?,
7967            }
7968        } else if self.parse_keyword(Keyword::RELATIVE) {
7969            FetchDirection::Relative {
7970                limit: self.parse_number_value()?,
7971            }
7972        } else if self.parse_keyword(Keyword::FORWARD) {
7973            if self.parse_keyword(Keyword::ALL) {
7974                FetchDirection::ForwardAll
7975            } else {
7976                FetchDirection::Forward {
7977                    // TODO: Support optional
7978                    limit: Some(self.parse_number_value()?),
7979                }
7980            }
7981        } else if self.parse_keyword(Keyword::BACKWARD) {
7982            if self.parse_keyword(Keyword::ALL) {
7983                FetchDirection::BackwardAll
7984            } else {
7985                FetchDirection::Backward {
7986                    // TODO: Support optional
7987                    limit: Some(self.parse_number_value()?),
7988                }
7989            }
7990        } else if self.parse_keyword(Keyword::ALL) {
7991            FetchDirection::All
7992        } else {
7993            FetchDirection::Count {
7994                limit: self.parse_number_value()?,
7995            }
7996        };
7997
7998        let position = if self.peek_keyword(Keyword::FROM) {
7999            self.expect_keyword(Keyword::FROM)?;
8000            FetchPosition::From
8001        } else if self.peek_keyword(Keyword::IN) {
8002            self.expect_keyword(Keyword::IN)?;
8003            FetchPosition::In
8004        } else {
8005            return parser_err!("Expected FROM or IN", self.peek_token_ref().span.start);
8006        };
8007
8008        let name = self.parse_identifier()?;
8009
8010        let into = if self.parse_keyword(Keyword::INTO) {
8011            Some(self.parse_object_name(false)?)
8012        } else {
8013            None
8014        };
8015
8016        Ok(Statement::Fetch {
8017            name,
8018            direction,
8019            position,
8020            into,
8021        })
8022    }
8023
8024    /// Parse a `DISCARD` statement.
8025    pub fn parse_discard(&mut self) -> Result<Statement, ParserError> {
8026        let object_type = if self.parse_keyword(Keyword::ALL) {
8027            DiscardObject::ALL
8028        } else if self.parse_keyword(Keyword::PLANS) {
8029            DiscardObject::PLANS
8030        } else if self.parse_keyword(Keyword::SEQUENCES) {
8031            DiscardObject::SEQUENCES
8032        } else if self.parse_keyword(Keyword::TEMP) || self.parse_keyword(Keyword::TEMPORARY) {
8033            DiscardObject::TEMP
8034        } else {
8035            return self.expected_ref(
8036                "ALL, PLANS, SEQUENCES, TEMP or TEMPORARY after DISCARD",
8037                self.peek_token_ref(),
8038            );
8039        };
8040        Ok(Statement::Discard { object_type })
8041    }
8042
8043    /// Parse a `CREATE INDEX` statement.
8044    pub fn parse_create_index(&mut self, unique: bool) -> Result<CreateIndex, ParserError> {
8045        let concurrently = self.parse_keyword(Keyword::CONCURRENTLY);
8046        let r#async = self.parse_keyword(Keyword::ASYNC);
8047        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
8048
8049        let mut using = None;
8050
8051        let index_name = if if_not_exists || !self.parse_keyword(Keyword::ON) {
8052            let index_name = self.parse_object_name(false)?;
8053            // MySQL allows `USING index_type` either before or after `ON table_name`
8054            using = self.parse_optional_using_then_index_type()?;
8055            self.expect_keyword_is(Keyword::ON)?;
8056            Some(index_name)
8057        } else {
8058            None
8059        };
8060
8061        let table_name = self.parse_object_name(false)?;
8062
8063        // MySQL allows having two `USING` clauses.
8064        // In that case, the second clause overwrites the first.
8065        using = self.parse_optional_using_then_index_type()?.or(using);
8066
8067        let columns = self.parse_parenthesized_index_column_list()?;
8068
8069        let include = if self.parse_keyword(Keyword::INCLUDE) {
8070            self.expect_token(&Token::LParen)?;
8071            let columns = self.parse_comma_separated(|p| p.parse_identifier())?;
8072            self.expect_token(&Token::RParen)?;
8073            columns
8074        } else {
8075            vec![]
8076        };
8077
8078        let nulls_distinct = if self.parse_keyword(Keyword::NULLS) {
8079            let not = self.parse_keyword(Keyword::NOT);
8080            self.expect_keyword_is(Keyword::DISTINCT)?;
8081            Some(!not)
8082        } else {
8083            None
8084        };
8085
8086        let with = if self.dialect.supports_create_index_with_clause()
8087            && self.parse_keyword(Keyword::WITH)
8088        {
8089            self.expect_token(&Token::LParen)?;
8090            let with_params = self.parse_comma_separated(Parser::parse_expr)?;
8091            self.expect_token(&Token::RParen)?;
8092            with_params
8093        } else {
8094            Vec::new()
8095        };
8096
8097        let predicate = if self.parse_keyword(Keyword::WHERE) {
8098            Some(self.parse_expr()?)
8099        } else {
8100            None
8101        };
8102
8103        // MySQL options (including the modern style of `USING` after the column list instead of
8104        // before, which is deprecated) shouldn't conflict with other preceding options (e.g. `WITH
8105        // PARSER` won't be caught by the above `WITH` clause parsing because MySQL doesn't set that
8106        // support flag). This is probably invalid syntax for other dialects, but it is simpler to
8107        // parse it anyway (as we do inside `ALTER TABLE` and `CREATE TABLE` parsing).
8108        let index_options = self.parse_index_options()?;
8109
8110        // MySQL allows `ALGORITHM` and `LOCK` options. Unlike in `ALTER TABLE`, they need not be comma separated.
8111        let mut alter_options = Vec::new();
8112        while self
8113            .peek_one_of_keywords(&[Keyword::ALGORITHM, Keyword::LOCK])
8114            .is_some()
8115        {
8116            alter_options.push(self.parse_alter_table_operation()?)
8117        }
8118
8119        Ok(CreateIndex {
8120            name: index_name,
8121            table_name,
8122            using,
8123            columns,
8124            unique,
8125            concurrently,
8126            r#async,
8127            if_not_exists,
8128            include,
8129            nulls_distinct,
8130            with,
8131            predicate,
8132            index_options,
8133            alter_options,
8134        })
8135    }
8136
8137    /// Parse a `CREATE EXTENSION` statement.
8138    pub fn parse_create_extension(&mut self) -> Result<CreateExtension, ParserError> {
8139        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
8140        let name = self.parse_identifier()?;
8141
8142        let (schema, version, cascade) = if self.parse_keyword(Keyword::WITH) {
8143            let schema = if self.parse_keyword(Keyword::SCHEMA) {
8144                Some(self.parse_identifier()?)
8145            } else {
8146                None
8147            };
8148
8149            let version = if self.parse_keyword(Keyword::VERSION) {
8150                Some(self.parse_identifier()?)
8151            } else {
8152                None
8153            };
8154
8155            let cascade = self.parse_keyword(Keyword::CASCADE);
8156
8157            (schema, version, cascade)
8158        } else {
8159            (None, None, false)
8160        };
8161
8162        Ok(CreateExtension {
8163            name,
8164            if_not_exists,
8165            schema,
8166            version,
8167            cascade,
8168        })
8169    }
8170
8171    /// Parse a PostgreSQL-specific [Statement::CreateCollation] statement.
8172    pub fn parse_create_collation(&mut self) -> Result<CreateCollation, ParserError> {
8173        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
8174        let name = self.parse_object_name(false)?;
8175
8176        let definition = if self.parse_keyword(Keyword::FROM) {
8177            CreateCollationDefinition::From(self.parse_object_name(false)?)
8178        } else if self.consume_token(&Token::LParen) {
8179            let options = self.parse_comma_separated(Parser::parse_sql_option)?;
8180            self.expect_token(&Token::RParen)?;
8181            CreateCollationDefinition::Options(options)
8182        } else {
8183            return self.expected_ref(
8184                "FROM or parenthesized option list after CREATE COLLATION name",
8185                self.peek_token_ref(),
8186            );
8187        };
8188
8189        Ok(CreateCollation {
8190            if_not_exists,
8191            name,
8192            definition,
8193        })
8194    }
8195
8196    /// Parse a PostgreSQL-specific [Statement::DropExtension] statement.
8197    pub fn parse_drop_extension(&mut self) -> Result<Statement, ParserError> {
8198        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
8199        let names = self.parse_comma_separated(|p| p.parse_identifier())?;
8200        let cascade_or_restrict =
8201            self.parse_one_of_keywords(&[Keyword::CASCADE, Keyword::RESTRICT]);
8202        Ok(Statement::DropExtension(DropExtension {
8203            names,
8204            if_exists,
8205            cascade_or_restrict: cascade_or_restrict
8206                .map(|k| match k {
8207                    Keyword::CASCADE => Ok(ReferentialAction::Cascade),
8208                    Keyword::RESTRICT => Ok(ReferentialAction::Restrict),
8209                    _ => self.expected_ref("CASCADE or RESTRICT", self.peek_token_ref()),
8210                })
8211                .transpose()?,
8212        }))
8213    }
8214
8215    /// Parse a[Statement::DropOperator] statement.
8216    ///
8217    pub fn parse_drop_operator(&mut self) -> Result<Statement, ParserError> {
8218        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
8219        let operators = self.parse_comma_separated(|p| p.parse_drop_operator_signature())?;
8220        let drop_behavior = self.parse_optional_drop_behavior();
8221        Ok(Statement::DropOperator(DropOperator {
8222            if_exists,
8223            operators,
8224            drop_behavior,
8225        }))
8226    }
8227
8228    /// Parse an operator signature for a [Statement::DropOperator]
8229    /// Format: `name ( { left_type | NONE } , right_type )`
8230    fn parse_drop_operator_signature(&mut self) -> Result<DropOperatorSignature, ParserError> {
8231        let name = self.parse_operator_name()?;
8232        self.expect_token(&Token::LParen)?;
8233
8234        // Parse left operand type (or NONE for prefix operators)
8235        let left_type = if self.parse_keyword(Keyword::NONE) {
8236            None
8237        } else {
8238            Some(self.parse_data_type()?)
8239        };
8240
8241        self.expect_token(&Token::Comma)?;
8242
8243        // Parse right operand type (always required)
8244        let right_type = self.parse_data_type()?;
8245
8246        self.expect_token(&Token::RParen)?;
8247
8248        Ok(DropOperatorSignature {
8249            name,
8250            left_type,
8251            right_type,
8252        })
8253    }
8254
8255    /// Parse a [Statement::DropOperatorFamily]
8256    ///
8257    /// [PostgreSQL Documentation](https://www.postgresql.org/docs/current/sql-dropopfamily.html)
8258    pub fn parse_drop_operator_family(&mut self) -> Result<Statement, ParserError> {
8259        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
8260        let names = self.parse_comma_separated(|p| p.parse_object_name(false))?;
8261        self.expect_keyword(Keyword::USING)?;
8262        let using = self.parse_identifier()?;
8263        let drop_behavior = self.parse_optional_drop_behavior();
8264        Ok(Statement::DropOperatorFamily(DropOperatorFamily {
8265            if_exists,
8266            names,
8267            using,
8268            drop_behavior,
8269        }))
8270    }
8271
8272    /// Parse a [Statement::DropOperatorClass]
8273    ///
8274    /// [PostgreSQL Documentation](https://www.postgresql.org/docs/current/sql-dropopclass.html)
8275    pub fn parse_drop_operator_class(&mut self) -> Result<Statement, ParserError> {
8276        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
8277        let names = self.parse_comma_separated(|p| p.parse_object_name(false))?;
8278        self.expect_keyword(Keyword::USING)?;
8279        let using = self.parse_identifier()?;
8280        let drop_behavior = self.parse_optional_drop_behavior();
8281        Ok(Statement::DropOperatorClass(DropOperatorClass {
8282            if_exists,
8283            names,
8284            using,
8285            drop_behavior,
8286        }))
8287    }
8288
8289    /// Parse Hive distribution style.
8290    ///
8291    /// TODO: Support parsing for `SKEWED` distribution style.
8292    pub fn parse_hive_distribution(&mut self) -> Result<HiveDistributionStyle, ParserError> {
8293        if self.parse_keywords(&[Keyword::PARTITIONED, Keyword::BY]) {
8294            self.expect_token(&Token::LParen)?;
8295            let columns =
8296                self.parse_comma_separated(|parser| parser.parse_column_def_inner(true))?;
8297            self.expect_token(&Token::RParen)?;
8298            Ok(HiveDistributionStyle::PARTITIONED { columns })
8299        } else {
8300            Ok(HiveDistributionStyle::NONE)
8301        }
8302    }
8303
8304    /// Parse Redshift `DISTSTYLE { AUTO | EVEN | KEY | ALL }`.
8305    ///
8306    /// See <https://docs.aws.amazon.com/redshift/latest/dg/r_CREATE_TABLE_NEW.html>
8307    fn parse_dist_style(&mut self) -> Result<DistStyle, ParserError> {
8308        let token = self.next_token();
8309        match &token.token {
8310            Token::Word(w) => match w.keyword {
8311                Keyword::AUTO => Ok(DistStyle::Auto),
8312                Keyword::EVEN => Ok(DistStyle::Even),
8313                Keyword::KEY => Ok(DistStyle::Key),
8314                Keyword::ALL => Ok(DistStyle::All),
8315                _ => self.expected("AUTO, EVEN, KEY, or ALL", token),
8316            },
8317            _ => self.expected("AUTO, EVEN, KEY, or ALL", token),
8318        }
8319    }
8320
8321    /// Parse Hive formats.
8322    pub fn parse_hive_formats(&mut self) -> Result<Option<HiveFormat>, ParserError> {
8323        let mut hive_format: Option<HiveFormat> = None;
8324        loop {
8325            match self.parse_one_of_keywords(&[
8326                Keyword::ROW,
8327                Keyword::STORED,
8328                Keyword::LOCATION,
8329                Keyword::WITH,
8330                Keyword::USING,
8331            ]) {
8332                Some(Keyword::ROW) => {
8333                    hive_format
8334                        .get_or_insert_with(HiveFormat::default)
8335                        .row_format = Some(self.parse_row_format()?);
8336                }
8337                Some(Keyword::STORED) => {
8338                    self.expect_keyword_is(Keyword::AS)?;
8339                    if self.parse_keyword(Keyword::INPUTFORMAT) {
8340                        let input_format = self.parse_expr()?;
8341                        self.expect_keyword_is(Keyword::OUTPUTFORMAT)?;
8342                        let output_format = self.parse_expr()?;
8343                        hive_format.get_or_insert_with(HiveFormat::default).storage =
8344                            Some(HiveIOFormat::IOF {
8345                                input_format,
8346                                output_format,
8347                            });
8348                    } else {
8349                        let format = self.parse_file_format()?;
8350                        hive_format.get_or_insert_with(HiveFormat::default).storage =
8351                            Some(HiveIOFormat::FileFormat { format });
8352                    }
8353                }
8354                Some(Keyword::LOCATION) => {
8355                    hive_format.get_or_insert_with(HiveFormat::default).location =
8356                        Some(self.parse_literal_string()?);
8357                }
8358                Some(Keyword::WITH) => {
8359                    self.prev_token();
8360                    let properties = self
8361                        .parse_options_with_keywords(&[Keyword::WITH, Keyword::SERDEPROPERTIES])?;
8362                    if !properties.is_empty() {
8363                        hive_format
8364                            .get_or_insert_with(HiveFormat::default)
8365                            .serde_properties = Some(properties);
8366                    } else {
8367                        break;
8368                    }
8369                }
8370                Some(Keyword::USING) if self.dialect.supports_create_table_using() => {
8371                    let format = self.parse_identifier()?;
8372                    hive_format.get_or_insert_with(HiveFormat::default).storage =
8373                        Some(HiveIOFormat::Using { format });
8374                }
8375                Some(Keyword::USING) => {
8376                    // USING is not a table format keyword in this dialect; put it back
8377                    self.prev_token();
8378                    break;
8379                }
8380                None => break,
8381                _ => break,
8382            }
8383        }
8384
8385        Ok(hive_format)
8386    }
8387
8388    /// Parse Hive row format.
8389    pub fn parse_row_format(&mut self) -> Result<HiveRowFormat, ParserError> {
8390        self.expect_keyword_is(Keyword::FORMAT)?;
8391        match self.parse_one_of_keywords(&[Keyword::SERDE, Keyword::DELIMITED]) {
8392            Some(Keyword::SERDE) => {
8393                let class = self.parse_literal_string()?;
8394                Ok(HiveRowFormat::SERDE { class })
8395            }
8396            _ => {
8397                let mut row_delimiters = vec![];
8398
8399                loop {
8400                    match self.parse_one_of_keywords(&[
8401                        Keyword::FIELDS,
8402                        Keyword::COLLECTION,
8403                        Keyword::MAP,
8404                        Keyword::LINES,
8405                        Keyword::NULL,
8406                    ]) {
8407                        Some(Keyword::FIELDS)
8408                            if self.parse_keywords(&[Keyword::TERMINATED, Keyword::BY]) =>
8409                        {
8410                            row_delimiters.push(HiveRowDelimiter {
8411                                delimiter: HiveDelimiter::FieldsTerminatedBy,
8412                                char: self.parse_identifier()?,
8413                            });
8414
8415                            if self.parse_keywords(&[Keyword::ESCAPED, Keyword::BY]) {
8416                                row_delimiters.push(HiveRowDelimiter {
8417                                    delimiter: HiveDelimiter::FieldsEscapedBy,
8418                                    char: self.parse_identifier()?,
8419                                });
8420                            }
8421                        }
8422                        Some(Keyword::COLLECTION)
8423                            if self.parse_keywords(&[
8424                                Keyword::ITEMS,
8425                                Keyword::TERMINATED,
8426                                Keyword::BY,
8427                            ]) =>
8428                        {
8429                            row_delimiters.push(HiveRowDelimiter {
8430                                delimiter: HiveDelimiter::CollectionItemsTerminatedBy,
8431                                char: self.parse_identifier()?,
8432                            });
8433                        }
8434                        Some(Keyword::MAP)
8435                            if self.parse_keywords(&[
8436                                Keyword::KEYS,
8437                                Keyword::TERMINATED,
8438                                Keyword::BY,
8439                            ]) =>
8440                        {
8441                            row_delimiters.push(HiveRowDelimiter {
8442                                delimiter: HiveDelimiter::MapKeysTerminatedBy,
8443                                char: self.parse_identifier()?,
8444                            });
8445                        }
8446                        Some(Keyword::LINES)
8447                            if self.parse_keywords(&[Keyword::TERMINATED, Keyword::BY]) =>
8448                        {
8449                            row_delimiters.push(HiveRowDelimiter {
8450                                delimiter: HiveDelimiter::LinesTerminatedBy,
8451                                char: self.parse_identifier()?,
8452                            });
8453                        }
8454                        Some(Keyword::NULL)
8455                            if self.parse_keywords(&[Keyword::DEFINED, Keyword::AS]) =>
8456                        {
8457                            row_delimiters.push(HiveRowDelimiter {
8458                                delimiter: HiveDelimiter::NullDefinedAs,
8459                                char: self.parse_identifier()?,
8460                            });
8461                        }
8462                        _ => {
8463                            break;
8464                        }
8465                    }
8466                }
8467
8468                Ok(HiveRowFormat::DELIMITED {
8469                    delimiters: row_delimiters,
8470                })
8471            }
8472        }
8473    }
8474
8475    fn parse_optional_on_cluster(&mut self) -> Result<Option<Ident>, ParserError> {
8476        if self.parse_keywords(&[Keyword::ON, Keyword::CLUSTER]) {
8477            Ok(Some(self.parse_identifier()?))
8478        } else {
8479            Ok(None)
8480        }
8481    }
8482
8483    /// Parse `CREATE TABLE` statement.
8484    pub fn parse_create_table(
8485        &mut self,
8486        or_replace: bool,
8487        temporary: bool,
8488        global: Option<bool>,
8489        transient: bool,
8490        volatile: bool,
8491        multiset: Option<bool>,
8492    ) -> Result<CreateTable, ParserError> {
8493        let allow_unquoted_hyphen = dialect_of!(self is BigQueryDialect);
8494        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
8495        let table_name = self.parse_object_name(allow_unquoted_hyphen)?;
8496
8497        let fallback = if self.dialect.supports_leading_comma_before_table_options()
8498            && self.consume_token(&Token::Comma)
8499        {
8500            let fallback = self.maybe_parse_fallback()?;
8501            if fallback.is_none() {
8502                self.prev_token(); // Put back comma.
8503            }
8504            fallback
8505        } else {
8506            None
8507        };
8508
8509        // PostgreSQL PARTITION OF for child partition tables
8510        // Note: This is a PostgreSQL-specific feature, but the dialect check was intentionally
8511        // removed to allow GenericDialect and other dialects to parse this syntax. This enables
8512        // multi-dialect SQL tools to work with PostgreSQL-specific DDL statements.
8513        //
8514        // PARTITION OF can be combined with other table definition clauses in the AST,
8515        // though PostgreSQL itself prohibits PARTITION OF with AS SELECT or LIKE clauses.
8516        // The parser accepts these combinations for flexibility; semantic validation
8517        // is left to downstream tools.
8518        // Child partitions can have their own constraints and indexes.
8519        let partition_of = if self.parse_keywords(&[Keyword::PARTITION, Keyword::OF]) {
8520            Some(self.parse_object_name(allow_unquoted_hyphen)?)
8521        } else {
8522            None
8523        };
8524
8525        // Clickhouse has `ON CLUSTER 'cluster'` syntax for DDLs
8526        let on_cluster = self.parse_optional_on_cluster()?;
8527
8528        let like = self.maybe_parse_create_table_like(allow_unquoted_hyphen)?;
8529
8530        let clone = if self.parse_keyword(Keyword::CLONE) {
8531            self.parse_object_name(allow_unquoted_hyphen).ok()
8532        } else {
8533            None
8534        };
8535
8536        // parse optional column list (schema)
8537        let (columns, constraints) = self.parse_columns()?;
8538        let comment_after_column_def =
8539            if dialect_of!(self is HiveDialect) && self.parse_keyword(Keyword::COMMENT) {
8540                let next_token = self.next_token();
8541                match next_token.token {
8542                    Token::SingleQuotedString(str) => Some(CommentDef::WithoutEq(str)),
8543                    _ => self.expected("comment", next_token)?,
8544                }
8545            } else {
8546                None
8547            };
8548
8549        // PostgreSQL PARTITION OF: partition bound specification
8550        let for_values = if partition_of.is_some() {
8551            if self.peek_keyword(Keyword::FOR) || self.peek_keyword(Keyword::DEFAULT) {
8552                Some(self.parse_partition_for_values()?)
8553            } else {
8554                return self.expected_ref(
8555                    "FOR VALUES or DEFAULT after PARTITION OF",
8556                    self.peek_token_ref(),
8557                );
8558            }
8559        } else {
8560            None
8561        };
8562
8563        // SQLite supports `WITHOUT ROWID` at the end of `CREATE TABLE`
8564        let without_rowid = self.parse_keywords(&[Keyword::WITHOUT, Keyword::ROWID]);
8565
8566        let hive_distribution = self.parse_hive_distribution()?;
8567        let clustered_by = self.parse_optional_clustered_by()?;
8568        let hive_formats = self.parse_hive_formats()?;
8569
8570        let create_table_config = self.parse_optional_create_table_config()?;
8571
8572        // ClickHouse supports `PRIMARY KEY`, before `ORDER BY`
8573        // https://clickhouse.com/docs/en/sql-reference/statements/create/table#primary-key
8574        let primary_key = if dialect_of!(self is ClickHouseDialect | GenericDialect)
8575            && self.parse_keywords(&[Keyword::PRIMARY, Keyword::KEY])
8576        {
8577            Some(Box::new(self.parse_expr()?))
8578        } else {
8579            None
8580        };
8581
8582        let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
8583            if self.consume_token(&Token::LParen) {
8584                let columns = if self.peek_token_ref().token != Token::RParen {
8585                    self.parse_comma_separated(|p| p.parse_expr())?
8586                } else {
8587                    vec![]
8588                };
8589                self.expect_token(&Token::RParen)?;
8590                Some(OneOrManyWithParens::Many(columns))
8591            } else {
8592                Some(OneOrManyWithParens::One(self.parse_expr()?))
8593            }
8594        } else {
8595            None
8596        };
8597
8598        // ClickHouse allows PARTITION BY after ORDER BY
8599        // https://clickhouse.com/docs/en/sql-reference/statements/create/table#partition-by
8600        let partition_by = if create_table_config.partition_by.is_none()
8601            && self.dialect.supports_partition_by_after_order_by()
8602            && self.parse_keywords(&[Keyword::PARTITION, Keyword::BY])
8603        {
8604            Some(Box::new(self.parse_expr()?))
8605        } else {
8606            create_table_config.partition_by
8607        };
8608
8609        let on_commit = if self.parse_keywords(&[Keyword::ON, Keyword::COMMIT]) {
8610            Some(self.parse_create_table_on_commit()?)
8611        } else {
8612            None
8613        };
8614
8615        let strict = self.parse_keyword(Keyword::STRICT);
8616
8617        // Redshift: BACKUP YES|NO
8618        let backup = if self.parse_keyword(Keyword::BACKUP) {
8619            let keyword = self.expect_one_of_keywords(&[Keyword::YES, Keyword::NO])?;
8620            Some(keyword == Keyword::YES)
8621        } else {
8622            None
8623        };
8624
8625        // Redshift: DISTSTYLE, DISTKEY, SORTKEY
8626        let diststyle = if self.parse_keyword(Keyword::DISTSTYLE) {
8627            Some(self.parse_dist_style()?)
8628        } else {
8629            None
8630        };
8631        let distkey = if self.parse_keyword(Keyword::DISTKEY) {
8632            self.expect_token(&Token::LParen)?;
8633            let expr = self.parse_expr()?;
8634            self.expect_token(&Token::RParen)?;
8635            Some(expr)
8636        } else {
8637            None
8638        };
8639        let sortkey = if self.parse_keyword(Keyword::SORTKEY) {
8640            self.expect_token(&Token::LParen)?;
8641            let columns = self.parse_comma_separated(|p| p.parse_expr())?;
8642            self.expect_token(&Token::RParen)?;
8643            Some(columns)
8644        } else {
8645            None
8646        };
8647
8648        // Parse optional `AS ( query )`
8649        let query = if self.parse_keyword(Keyword::AS) {
8650            Some(self.parse_query()?)
8651        } else if self.dialect.supports_create_table_select() && self.parse_keyword(Keyword::SELECT)
8652        {
8653            // rewind the SELECT keyword
8654            self.prev_token();
8655            Some(self.parse_query()?)
8656        } else {
8657            None
8658        };
8659
8660        // `WITH DATA` clause only applies if there is a query body.
8661        let with_data = if query.is_some() {
8662            self.maybe_parse_with_data()?
8663        } else {
8664            None
8665        };
8666
8667        Ok(CreateTableBuilder::new(table_name)
8668            .temporary(temporary)
8669            .columns(columns)
8670            .constraints(constraints)
8671            .or_replace(or_replace)
8672            .if_not_exists(if_not_exists)
8673            .transient(transient)
8674            .volatile(volatile)
8675            .multiset(multiset)
8676            .fallback(fallback)
8677            .hive_distribution(hive_distribution)
8678            .hive_formats(hive_formats)
8679            .global(global)
8680            .query(query)
8681            .without_rowid(without_rowid)
8682            .like(like)
8683            .clone_clause(clone)
8684            .comment_after_column_def(comment_after_column_def)
8685            .order_by(order_by)
8686            .on_commit(on_commit)
8687            .on_cluster(on_cluster)
8688            .clustered_by(clustered_by)
8689            .partition_by(partition_by)
8690            .cluster_by(create_table_config.cluster_by)
8691            .inherits(create_table_config.inherits)
8692            .partition_of(partition_of)
8693            .for_values(for_values)
8694            .table_options(create_table_config.table_options)
8695            .primary_key(primary_key)
8696            .with_data(with_data)
8697            .strict(strict)
8698            .backup(backup)
8699            .diststyle(diststyle)
8700            .distkey(distkey)
8701            .sortkey(sortkey)
8702            .build())
8703    }
8704
8705    /// Parse `MULTISET` table-kind prefix on `CREATE TABLE`.
8706    fn maybe_parse_multiset(&mut self) -> Option<bool> {
8707        match self.parse_one_of_keywords(&[Keyword::SET, Keyword::MULTISET]) {
8708            Some(Keyword::MULTISET) => Some(true),
8709            Some(Keyword::SET) => Some(false),
8710            _ => None,
8711        }
8712    }
8713
8714    /// Parse `FALLBACK` option on a `CREATE TABLE` statement,
8715    fn maybe_parse_fallback(&mut self) -> Result<Option<bool>, ParserError> {
8716        if self.parse_keywords(&[Keyword::NO, Keyword::FALLBACK]) {
8717            Ok(Some(false))
8718        } else if self.parse_keyword(Keyword::FALLBACK) {
8719            Ok(Some(true))
8720        } else {
8721            Ok(None)
8722        }
8723    }
8724
8725    /// Parse [`WithData`] clause on `CREATE TABLE ... AS` statement.
8726    fn maybe_parse_with_data(&mut self) -> Result<Option<WithData>, ParserError> {
8727        let data = if self.parse_keywords(&[Keyword::WITH, Keyword::DATA]) {
8728            true
8729        } else if self.parse_keywords(&[Keyword::WITH, Keyword::NO, Keyword::DATA]) {
8730            false
8731        } else {
8732            return Ok(None);
8733        };
8734
8735        let statistics = if self.parse_keywords(&[Keyword::AND, Keyword::STATISTICS]) {
8736            Some(true)
8737        } else if self.parse_keywords(&[Keyword::AND, Keyword::NO, Keyword::STATISTICS]) {
8738            Some(false)
8739        } else {
8740            None
8741        };
8742
8743        Ok(Some(WithData { data, statistics }))
8744    }
8745
8746    fn maybe_parse_create_table_like(
8747        &mut self,
8748        allow_unquoted_hyphen: bool,
8749    ) -> Result<Option<CreateTableLikeKind>, ParserError> {
8750        let like = if self.dialect.supports_create_table_like_parenthesized()
8751            && self.consume_token(&Token::LParen)
8752        {
8753            if self.parse_keyword(Keyword::LIKE) {
8754                let name = self.parse_object_name(allow_unquoted_hyphen)?;
8755                let defaults = if self.parse_keywords(&[Keyword::INCLUDING, Keyword::DEFAULTS]) {
8756                    Some(CreateTableLikeDefaults::Including)
8757                } else if self.parse_keywords(&[Keyword::EXCLUDING, Keyword::DEFAULTS]) {
8758                    Some(CreateTableLikeDefaults::Excluding)
8759                } else {
8760                    None
8761                };
8762                self.expect_token(&Token::RParen)?;
8763                Some(CreateTableLikeKind::Parenthesized(CreateTableLike {
8764                    name,
8765                    defaults,
8766                }))
8767            } else {
8768                // Rollback the '(' it's probably the columns list
8769                self.prev_token();
8770                None
8771            }
8772        } else if self.parse_keyword(Keyword::LIKE) || self.parse_keyword(Keyword::ILIKE) {
8773            let name = self.parse_object_name(allow_unquoted_hyphen)?;
8774            Some(CreateTableLikeKind::Plain(CreateTableLike {
8775                name,
8776                defaults: None,
8777            }))
8778        } else {
8779            None
8780        };
8781        Ok(like)
8782    }
8783
8784    pub(crate) fn parse_create_table_on_commit(&mut self) -> Result<OnCommit, ParserError> {
8785        if self.parse_keywords(&[Keyword::DELETE, Keyword::ROWS]) {
8786            Ok(OnCommit::DeleteRows)
8787        } else if self.parse_keywords(&[Keyword::PRESERVE, Keyword::ROWS]) {
8788            Ok(OnCommit::PreserveRows)
8789        } else if self.parse_keywords(&[Keyword::DROP]) {
8790            Ok(OnCommit::Drop)
8791        } else {
8792            parser_err!(
8793                "Expecting DELETE ROWS, PRESERVE ROWS or DROP",
8794                self.peek_token_ref()
8795            )
8796        }
8797    }
8798
8799    /// Parse [ForValues] of a `PARTITION OF` clause.
8800    ///
8801    /// Parses: `FOR VALUES partition_bound_spec | DEFAULT`
8802    ///
8803    /// [PostgreSQL](https://www.postgresql.org/docs/current/sql-createtable.html)
8804    fn parse_partition_for_values(&mut self) -> Result<ForValues, ParserError> {
8805        if self.parse_keyword(Keyword::DEFAULT) {
8806            return Ok(ForValues::Default);
8807        }
8808
8809        self.expect_keywords(&[Keyword::FOR, Keyword::VALUES])?;
8810
8811        if self.parse_keyword(Keyword::IN) {
8812            // FOR VALUES IN (expr, ...)
8813            self.expect_token(&Token::LParen)?;
8814            if self.peek_token_ref().token == Token::RParen {
8815                return self.expected_ref("at least one value", self.peek_token_ref());
8816            }
8817            let values = self.parse_comma_separated(Parser::parse_expr)?;
8818            self.expect_token(&Token::RParen)?;
8819            Ok(ForValues::In(values))
8820        } else if self.parse_keyword(Keyword::FROM) {
8821            // FOR VALUES FROM (...) TO (...)
8822            self.expect_token(&Token::LParen)?;
8823            if self.peek_token_ref().token == Token::RParen {
8824                return self.expected_ref("at least one value", self.peek_token_ref());
8825            }
8826            let from = self.parse_comma_separated(Parser::parse_partition_bound_value)?;
8827            self.expect_token(&Token::RParen)?;
8828            self.expect_keyword(Keyword::TO)?;
8829            self.expect_token(&Token::LParen)?;
8830            if self.peek_token_ref().token == Token::RParen {
8831                return self.expected_ref("at least one value", self.peek_token_ref());
8832            }
8833            let to = self.parse_comma_separated(Parser::parse_partition_bound_value)?;
8834            self.expect_token(&Token::RParen)?;
8835            Ok(ForValues::From { from, to })
8836        } else if self.parse_keyword(Keyword::WITH) {
8837            // FOR VALUES WITH (MODULUS n, REMAINDER r)
8838            self.expect_token(&Token::LParen)?;
8839            self.expect_keyword(Keyword::MODULUS)?;
8840            let modulus = self.parse_literal_uint()?;
8841            self.expect_token(&Token::Comma)?;
8842            self.expect_keyword(Keyword::REMAINDER)?;
8843            let remainder = self.parse_literal_uint()?;
8844            self.expect_token(&Token::RParen)?;
8845            Ok(ForValues::With { modulus, remainder })
8846        } else {
8847            self.expected_ref("IN, FROM, or WITH after FOR VALUES", self.peek_token_ref())
8848        }
8849    }
8850
8851    /// Parse a single partition bound value (MINVALUE, MAXVALUE, or expression).
8852    fn parse_partition_bound_value(&mut self) -> Result<PartitionBoundValue, ParserError> {
8853        if self.parse_keyword(Keyword::MINVALUE) {
8854            Ok(PartitionBoundValue::MinValue)
8855        } else if self.parse_keyword(Keyword::MAXVALUE) {
8856            Ok(PartitionBoundValue::MaxValue)
8857        } else {
8858            Ok(PartitionBoundValue::Expr(self.parse_expr()?))
8859        }
8860    }
8861
8862    /// Parse configuration like inheritance, partitioning, clustering information during the table creation.
8863    ///
8864    /// [BigQuery](https://cloud.google.com/bigquery/docs/reference/standard-sql/data-definition-language#syntax_2)
8865    /// [PostgreSQL](https://www.postgresql.org/docs/current/ddl-partitioning.html)
8866    /// [MySql](https://dev.mysql.com/doc/refman/8.4/en/create-table.html)
8867    fn parse_optional_create_table_config(
8868        &mut self,
8869    ) -> Result<CreateTableConfiguration, ParserError> {
8870        let mut table_options = CreateTableOptions::None;
8871
8872        let inherits = if self.parse_keyword(Keyword::INHERITS) {
8873            Some(self.parse_parenthesized_qualified_column_list(IsOptional::Mandatory, false)?)
8874        } else {
8875            None
8876        };
8877
8878        // PostgreSQL supports `WITH ( options )`, before `AS`
8879        let with_options = self.parse_options(Keyword::WITH)?;
8880        if !with_options.is_empty() {
8881            table_options = CreateTableOptions::With(with_options)
8882        }
8883
8884        let table_properties = self.parse_options(Keyword::TBLPROPERTIES)?;
8885        if !table_properties.is_empty() {
8886            table_options = CreateTableOptions::TableProperties(table_properties);
8887        }
8888        let partition_by = if dialect_of!(self is BigQueryDialect | PostgreSqlDialect | GenericDialect)
8889            && self.parse_keywords(&[Keyword::PARTITION, Keyword::BY])
8890        {
8891            Some(Box::new(self.parse_expr()?))
8892        } else {
8893            None
8894        };
8895
8896        let mut cluster_by = None;
8897        if dialect_of!(self is BigQueryDialect | GenericDialect) {
8898            if self.parse_keywords(&[Keyword::CLUSTER, Keyword::BY]) {
8899                cluster_by = Some(WrappedCollection::NoWrapping(
8900                    self.parse_comma_separated(|p| p.parse_expr())?,
8901                ));
8902            };
8903
8904            if let Token::Word(word) = &self.peek_token_ref().token {
8905                if word.keyword == Keyword::OPTIONS {
8906                    table_options =
8907                        CreateTableOptions::Options(self.parse_options(Keyword::OPTIONS)?)
8908                }
8909            };
8910        }
8911
8912        if !dialect_of!(self is HiveDialect) && table_options == CreateTableOptions::None {
8913            let plain_options = self.parse_plain_options()?;
8914            if !plain_options.is_empty() {
8915                table_options = CreateTableOptions::Plain(plain_options)
8916            }
8917        };
8918
8919        Ok(CreateTableConfiguration {
8920            partition_by,
8921            cluster_by,
8922            inherits,
8923            table_options,
8924        })
8925    }
8926
8927    fn parse_plain_option(&mut self) -> Result<Option<SqlOption>, ParserError> {
8928        // Single parameter option
8929        // <https://dev.mysql.com/doc/refman/8.4/en/create-table.html>
8930        if self.parse_keywords(&[Keyword::START, Keyword::TRANSACTION]) {
8931            return Ok(Some(SqlOption::Ident(Ident::new("START TRANSACTION"))));
8932        }
8933
8934        // Custom option
8935        // <https://dev.mysql.com/doc/refman/8.4/en/create-table.html>
8936        if self.parse_keywords(&[Keyword::COMMENT]) {
8937            let has_eq = self.consume_token(&Token::Eq);
8938            let value = self.next_token();
8939
8940            let comment = match (has_eq, value.token) {
8941                (true, Token::SingleQuotedString(s)) => {
8942                    Ok(Some(SqlOption::Comment(CommentDef::WithEq(s))))
8943                }
8944                (false, Token::SingleQuotedString(s)) => {
8945                    Ok(Some(SqlOption::Comment(CommentDef::WithoutEq(s))))
8946                }
8947                (_, token) => {
8948                    self.expected("Token::SingleQuotedString", TokenWithSpan::wrap(token))
8949                }
8950            };
8951            return comment;
8952        }
8953
8954        // <https://dev.mysql.com/doc/refman/8.4/en/create-table.html>
8955        // <https://clickhouse.com/docs/sql-reference/statements/create/table>
8956        if self.parse_keywords(&[Keyword::ENGINE]) {
8957            let _ = self.consume_token(&Token::Eq);
8958            let value = self.next_token();
8959
8960            let engine = match value.token {
8961                Token::Word(w) => {
8962                    let parameters = if self.peek_token_ref().token == Token::LParen {
8963                        self.parse_parenthesized_identifiers()?
8964                    } else {
8965                        vec![]
8966                    };
8967
8968                    Ok(Some(SqlOption::NamedParenthesizedList(
8969                        NamedParenthesizedList {
8970                            key: Ident::new("ENGINE"),
8971                            name: Some(Ident::new(w.value)),
8972                            values: parameters,
8973                        },
8974                    )))
8975                }
8976                _ => {
8977                    return self.expected("Token::Word", value)?;
8978                }
8979            };
8980
8981            return engine;
8982        }
8983
8984        // <https://dev.mysql.com/doc/refman/8.4/en/create-table.html>
8985        if self.parse_keywords(&[Keyword::TABLESPACE]) {
8986            let _ = self.consume_token(&Token::Eq);
8987            let value = self.next_token();
8988
8989            let tablespace = match value.token {
8990                Token::Word(Word { value: name, .. }) | Token::SingleQuotedString(name) => {
8991                    let storage = match self.parse_keyword(Keyword::STORAGE) {
8992                        true => {
8993                            let _ = self.consume_token(&Token::Eq);
8994                            let storage_token = self.next_token();
8995                            match &storage_token.token {
8996                                Token::Word(w) => match w.value.to_uppercase().as_str() {
8997                                    "DISK" => Some(StorageType::Disk),
8998                                    "MEMORY" => Some(StorageType::Memory),
8999                                    _ => self
9000                                        .expected("Storage type (DISK or MEMORY)", storage_token)?,
9001                                },
9002                                _ => self.expected("Token::Word", storage_token)?,
9003                            }
9004                        }
9005                        false => None,
9006                    };
9007
9008                    Ok(Some(SqlOption::TableSpace(TablespaceOption {
9009                        name,
9010                        storage,
9011                    })))
9012                }
9013                _ => {
9014                    return self.expected("Token::Word", value)?;
9015                }
9016            };
9017
9018            return tablespace;
9019        }
9020
9021        // <https://dev.mysql.com/doc/refman/8.4/en/create-table.html>
9022        if self.parse_keyword(Keyword::UNION) {
9023            let _ = self.consume_token(&Token::Eq);
9024            let value = self.next_token();
9025
9026            match value.token {
9027                Token::LParen => {
9028                    let tables: Vec<Ident> =
9029                        self.parse_comma_separated0(Parser::parse_identifier, Token::RParen)?;
9030                    self.expect_token(&Token::RParen)?;
9031
9032                    return Ok(Some(SqlOption::NamedParenthesizedList(
9033                        NamedParenthesizedList {
9034                            key: Ident::new("UNION"),
9035                            name: None,
9036                            values: tables,
9037                        },
9038                    )));
9039                }
9040                _ => {
9041                    return self.expected("Token::LParen", value)?;
9042                }
9043            }
9044        }
9045
9046        // Key/Value parameter option
9047        let key = if self.parse_keywords(&[Keyword::DEFAULT, Keyword::CHARSET]) {
9048            Ident::new("DEFAULT CHARSET")
9049        } else if self.parse_keyword(Keyword::CHARSET) {
9050            Ident::new("CHARSET")
9051        } else if self.parse_keywords(&[Keyword::DEFAULT, Keyword::CHARACTER, Keyword::SET]) {
9052            Ident::new("DEFAULT CHARACTER SET")
9053        } else if self.parse_keywords(&[Keyword::CHARACTER, Keyword::SET]) {
9054            Ident::new("CHARACTER SET")
9055        } else if self.parse_keywords(&[Keyword::DEFAULT, Keyword::COLLATE]) {
9056            Ident::new("DEFAULT COLLATE")
9057        } else if self.parse_keyword(Keyword::COLLATE) {
9058            Ident::new("COLLATE")
9059        } else if self.parse_keywords(&[Keyword::DATA, Keyword::DIRECTORY]) {
9060            Ident::new("DATA DIRECTORY")
9061        } else if self.parse_keywords(&[Keyword::INDEX, Keyword::DIRECTORY]) {
9062            Ident::new("INDEX DIRECTORY")
9063        } else if self.parse_keyword(Keyword::KEY_BLOCK_SIZE) {
9064            Ident::new("KEY_BLOCK_SIZE")
9065        } else if self.parse_keyword(Keyword::ROW_FORMAT) {
9066            Ident::new("ROW_FORMAT")
9067        } else if self.parse_keyword(Keyword::PACK_KEYS) {
9068            Ident::new("PACK_KEYS")
9069        } else if self.parse_keyword(Keyword::STATS_AUTO_RECALC) {
9070            Ident::new("STATS_AUTO_RECALC")
9071        } else if self.parse_keyword(Keyword::STATS_PERSISTENT) {
9072            Ident::new("STATS_PERSISTENT")
9073        } else if self.parse_keyword(Keyword::STATS_SAMPLE_PAGES) {
9074            Ident::new("STATS_SAMPLE_PAGES")
9075        } else if self.parse_keyword(Keyword::DELAY_KEY_WRITE) {
9076            Ident::new("DELAY_KEY_WRITE")
9077        } else if self.parse_keyword(Keyword::COMPRESSION) {
9078            Ident::new("COMPRESSION")
9079        } else if self.parse_keyword(Keyword::ENCRYPTION) {
9080            Ident::new("ENCRYPTION")
9081        } else if self.parse_keyword(Keyword::MAX_ROWS) {
9082            Ident::new("MAX_ROWS")
9083        } else if self.parse_keyword(Keyword::MIN_ROWS) {
9084            Ident::new("MIN_ROWS")
9085        } else if self.parse_keyword(Keyword::AUTOEXTEND_SIZE) {
9086            Ident::new("AUTOEXTEND_SIZE")
9087        } else if self.parse_keyword(Keyword::AVG_ROW_LENGTH) {
9088            Ident::new("AVG_ROW_LENGTH")
9089        } else if self.parse_keyword(Keyword::CHECKSUM) {
9090            Ident::new("CHECKSUM")
9091        } else if self.parse_keyword(Keyword::CONNECTION) {
9092            Ident::new("CONNECTION")
9093        } else if self.parse_keyword(Keyword::ENGINE_ATTRIBUTE) {
9094            Ident::new("ENGINE_ATTRIBUTE")
9095        } else if self.parse_keyword(Keyword::PASSWORD) {
9096            Ident::new("PASSWORD")
9097        } else if self.parse_keyword(Keyword::SECONDARY_ENGINE_ATTRIBUTE) {
9098            Ident::new("SECONDARY_ENGINE_ATTRIBUTE")
9099        } else if self.parse_keyword(Keyword::INSERT_METHOD) {
9100            Ident::new("INSERT_METHOD")
9101        } else if self.parse_keyword(Keyword::AUTO_INCREMENT) {
9102            Ident::new("AUTO_INCREMENT")
9103        } else {
9104            return Ok(None);
9105        };
9106
9107        let _ = self.consume_token(&Token::Eq);
9108
9109        let value = match self
9110            .maybe_parse(|parser| parser.parse_value())?
9111            .map(Expr::Value)
9112        {
9113            Some(expr) => expr,
9114            None => Expr::Identifier(self.parse_identifier()?),
9115        };
9116
9117        Ok(Some(SqlOption::KeyValue { key, value }))
9118    }
9119
9120    /// Parse plain options.
9121    pub fn parse_plain_options(&mut self) -> Result<Vec<SqlOption>, ParserError> {
9122        let mut options = Vec::new();
9123
9124        while let Some(option) = self.parse_plain_option()? {
9125            options.push(option);
9126            // Some dialects support comma-separated options; it shouldn't introduce ambiguity to
9127            // consume it for all dialects.
9128            let _ = self.consume_token(&Token::Comma);
9129        }
9130
9131        Ok(options)
9132    }
9133
9134    /// Parse optional inline comment.
9135    pub fn parse_optional_inline_comment(&mut self) -> Result<Option<CommentDef>, ParserError> {
9136        let comment = if self.parse_keyword(Keyword::COMMENT) {
9137            let has_eq = self.consume_token(&Token::Eq);
9138            let comment = self.parse_comment_value()?;
9139            Some(if has_eq {
9140                CommentDef::WithEq(comment)
9141            } else {
9142                CommentDef::WithoutEq(comment)
9143            })
9144        } else {
9145            None
9146        };
9147        Ok(comment)
9148    }
9149
9150    /// Parse comment value.
9151    pub fn parse_comment_value(&mut self) -> Result<String, ParserError> {
9152        let next_token = self.next_token();
9153        let value = match next_token.token {
9154            Token::SingleQuotedString(str) => str,
9155            Token::DollarQuotedString(str) => str.value,
9156            _ => self.expected("string literal", next_token)?,
9157        };
9158        Ok(value)
9159    }
9160
9161    /// Parse optional procedure parameters.
9162    pub fn parse_optional_procedure_parameters(
9163        &mut self,
9164    ) -> Result<Option<Vec<ProcedureParam>>, ParserError> {
9165        let mut params = vec![];
9166        if !self.consume_token(&Token::LParen) || self.consume_token(&Token::RParen) {
9167            return Ok(Some(params));
9168        }
9169        loop {
9170            if let Token::Word(_) = &self.peek_token_ref().token {
9171                params.push(self.parse_procedure_param()?)
9172            }
9173            let comma = self.consume_token(&Token::Comma);
9174            if self.consume_token(&Token::RParen) {
9175                // allow a trailing comma, even though it's not in standard
9176                break;
9177            } else if !comma {
9178                return self.expected_ref(
9179                    "',' or ')' after parameter definition",
9180                    self.peek_token_ref(),
9181                );
9182            }
9183        }
9184        Ok(Some(params))
9185    }
9186
9187    /// Parse columns and constraints.
9188    pub fn parse_columns(&mut self) -> Result<(Vec<ColumnDef>, Vec<TableConstraint>), ParserError> {
9189        let mut columns = vec![];
9190        let mut constraints = vec![];
9191        if !self.consume_token(&Token::LParen) || self.consume_token(&Token::RParen) {
9192            return Ok((columns, constraints));
9193        }
9194
9195        loop {
9196            if let Some(constraint) = self.parse_optional_table_constraint()? {
9197                constraints.push(constraint);
9198            } else if let Token::Word(_) = &self.peek_token_ref().token {
9199                columns.push(self.parse_column_def()?);
9200            } else {
9201                return self.expected_ref(
9202                    "column name or constraint definition",
9203                    self.peek_token_ref(),
9204                );
9205            }
9206
9207            let comma = self.consume_token(&Token::Comma);
9208            let rparen = self.peek_token_ref().token == Token::RParen;
9209
9210            if !comma && !rparen {
9211                return self
9212                    .expected_ref("',' or ')' after column definition", self.peek_token_ref());
9213            };
9214
9215            if rparen
9216                && (!comma
9217                    || self.dialect.supports_column_definition_trailing_commas()
9218                    || self.options.trailing_commas)
9219            {
9220                let _ = self.consume_token(&Token::RParen);
9221                break;
9222            }
9223        }
9224
9225        Ok((columns, constraints))
9226    }
9227
9228    /// Parse procedure parameter.
9229    pub fn parse_procedure_param(&mut self) -> Result<ProcedureParam, ParserError> {
9230        let mode = if self.parse_keyword(Keyword::IN) {
9231            Some(ArgMode::In)
9232        } else if self.parse_keyword(Keyword::OUT) {
9233            Some(ArgMode::Out)
9234        } else if self.parse_keyword(Keyword::INOUT) {
9235            Some(ArgMode::InOut)
9236        } else {
9237            None
9238        };
9239        let name = self.parse_identifier()?;
9240        let data_type = self.parse_data_type()?;
9241        let default = if self.consume_token(&Token::Eq) {
9242            Some(self.parse_expr()?)
9243        } else {
9244            None
9245        };
9246
9247        Ok(ProcedureParam {
9248            name,
9249            data_type,
9250            mode,
9251            default,
9252        })
9253    }
9254
9255    /// Parse column definition.
9256    pub fn parse_column_def(&mut self) -> Result<ColumnDef, ParserError> {
9257        self.parse_column_def_inner(false)
9258    }
9259
9260    fn parse_column_def_inner(
9261        &mut self,
9262        optional_data_type: bool,
9263    ) -> Result<ColumnDef, ParserError> {
9264        let col_name = self.parse_identifier()?;
9265        let data_type = if self.is_column_type_sqlite_unspecified() {
9266            DataType::Unspecified
9267        } else if optional_data_type {
9268            self.maybe_parse(|parser| parser.parse_data_type())?
9269                .unwrap_or(DataType::Unspecified)
9270        } else {
9271            self.parse_data_type()?
9272        };
9273        let mut options = vec![];
9274        loop {
9275            if self.parse_keyword(Keyword::CONSTRAINT) {
9276                let name = Some(self.parse_identifier()?);
9277                if let Some(option) = self.parse_optional_column_option()? {
9278                    options.push(ColumnOptionDef { name, option });
9279                } else {
9280                    return self.expected_ref(
9281                        "constraint details after CONSTRAINT <name>",
9282                        self.peek_token_ref(),
9283                    );
9284                }
9285            } else if let Some(option) = self.parse_optional_column_option()? {
9286                options.push(ColumnOptionDef { name: None, option });
9287            } else {
9288                break;
9289            };
9290        }
9291        Ok(ColumnDef {
9292            name: col_name,
9293            data_type,
9294            options,
9295        })
9296    }
9297
9298    fn is_column_type_sqlite_unspecified(&mut self) -> bool {
9299        if dialect_of!(self is SQLiteDialect) {
9300            match &self.peek_token_ref().token {
9301                Token::Word(word) => matches!(
9302                    word.keyword,
9303                    Keyword::CONSTRAINT
9304                        | Keyword::PRIMARY
9305                        | Keyword::NOT
9306                        | Keyword::UNIQUE
9307                        | Keyword::CHECK
9308                        | Keyword::DEFAULT
9309                        | Keyword::COLLATE
9310                        | Keyword::REFERENCES
9311                        | Keyword::GENERATED
9312                        | Keyword::AS
9313                ),
9314                _ => true, // e.g. comma immediately after column name
9315            }
9316        } else {
9317            false
9318        }
9319    }
9320
9321    /// Parse optional column option.
9322    pub fn parse_optional_column_option(&mut self) -> Result<Option<ColumnOption>, ParserError> {
9323        if let Some(option) = self.dialect.parse_column_option(self)? {
9324            return option;
9325        }
9326
9327        self.with_state(
9328            ColumnDefinition,
9329            |parser| -> Result<Option<ColumnOption>, ParserError> {
9330                parser.parse_optional_column_option_inner()
9331            },
9332        )
9333    }
9334
9335    fn parse_optional_column_option_inner(&mut self) -> Result<Option<ColumnOption>, ParserError> {
9336        if self.parse_keywords(&[Keyword::CHARACTER, Keyword::SET]) {
9337            Ok(Some(ColumnOption::CharacterSet(
9338                self.parse_object_name(false)?,
9339            )))
9340        } else if self.parse_keywords(&[Keyword::COLLATE]) {
9341            Ok(Some(ColumnOption::Collation(
9342                self.parse_object_name(false)?,
9343            )))
9344        } else if self.parse_keywords(&[Keyword::NOT, Keyword::NULL]) {
9345            Ok(Some(ColumnOption::NotNull))
9346        } else if self.parse_keywords(&[Keyword::COMMENT]) {
9347            Ok(Some(ColumnOption::Comment(self.parse_comment_value()?)))
9348        } else if self.parse_keyword(Keyword::NULL) {
9349            Ok(Some(ColumnOption::Null))
9350        } else if self.parse_keyword(Keyword::DEFAULT) {
9351            Ok(Some(ColumnOption::Default(self.parse_expr()?)))
9352        } else if dialect_of!(self is ClickHouseDialect| GenericDialect)
9353            && self.parse_keyword(Keyword::MATERIALIZED)
9354        {
9355            Ok(Some(ColumnOption::Materialized(self.parse_expr()?)))
9356        } else if dialect_of!(self is ClickHouseDialect| GenericDialect)
9357            && self.parse_keyword(Keyword::ALIAS)
9358        {
9359            Ok(Some(ColumnOption::Alias(self.parse_expr()?)))
9360        } else if dialect_of!(self is ClickHouseDialect| GenericDialect)
9361            && self.parse_keyword(Keyword::EPHEMERAL)
9362        {
9363            // The expression is optional for the EPHEMERAL syntax, so we need to check
9364            // if the column definition has remaining tokens before parsing the expression.
9365            if matches!(self.peek_token_ref().token, Token::Comma | Token::RParen) {
9366                Ok(Some(ColumnOption::Ephemeral(None)))
9367            } else {
9368                Ok(Some(ColumnOption::Ephemeral(Some(self.parse_expr()?))))
9369            }
9370        } else if self.parse_keywords(&[Keyword::PRIMARY, Keyword::KEY]) {
9371            let characteristics = self.parse_constraint_characteristics()?;
9372            Ok(Some(
9373                PrimaryKeyConstraint {
9374                    name: None,
9375                    index_name: None,
9376                    index_type: None,
9377                    columns: vec![],
9378                    index_options: vec![],
9379                    characteristics,
9380                }
9381                .into(),
9382            ))
9383        } else if self.parse_keyword(Keyword::UNIQUE) {
9384            let index_type_display =
9385                if self.dialect.supports_key_column_option() && self.parse_keyword(Keyword::KEY) {
9386                    KeyOrIndexDisplay::Key
9387                } else {
9388                    KeyOrIndexDisplay::None
9389                };
9390            let characteristics = self.parse_constraint_characteristics()?;
9391            Ok(Some(
9392                UniqueConstraint {
9393                    name: None,
9394                    index_name: None,
9395                    index_type_display,
9396                    index_type: None,
9397                    columns: vec![],
9398                    index_options: vec![],
9399                    characteristics,
9400                    nulls_distinct: NullsDistinctOption::None,
9401                }
9402                .into(),
9403            ))
9404        } else if self.dialect.supports_key_column_option() && self.parse_keyword(Keyword::KEY) {
9405            // In MySQL, `KEY` in a column definition is shorthand for `PRIMARY KEY`.
9406            // See: https://dev.mysql.com/doc/refman/8.4/en/create-table.html
9407            let characteristics = self.parse_constraint_characteristics()?;
9408            Ok(Some(
9409                PrimaryKeyConstraint {
9410                    name: None,
9411                    index_name: None,
9412                    index_type: None,
9413                    columns: vec![],
9414                    index_options: vec![],
9415                    characteristics,
9416                }
9417                .into(),
9418            ))
9419        } else if self.parse_keyword(Keyword::REFERENCES) {
9420            let foreign_table = self.parse_object_name(false)?;
9421            // PostgreSQL allows omitting the column list and
9422            // uses the primary key column of the foreign table by default
9423            let referred_columns = self.parse_parenthesized_column_list(Optional, false)?;
9424            let mut match_kind = None;
9425            let mut on_delete = None;
9426            let mut on_update = None;
9427            loop {
9428                if match_kind.is_none() && self.parse_keyword(Keyword::MATCH) {
9429                    match_kind = Some(self.parse_match_kind()?);
9430                } else if on_delete.is_none()
9431                    && self.parse_keywords(&[Keyword::ON, Keyword::DELETE])
9432                {
9433                    on_delete = Some(self.parse_referential_action()?);
9434                } else if on_update.is_none()
9435                    && self.parse_keywords(&[Keyword::ON, Keyword::UPDATE])
9436                {
9437                    on_update = Some(self.parse_referential_action()?);
9438                } else {
9439                    break;
9440                }
9441            }
9442            let characteristics = self.parse_constraint_characteristics()?;
9443
9444            Ok(Some(
9445                ForeignKeyConstraint {
9446                    name: None,       // Column-level constraints don't have names
9447                    index_name: None, // Not applicable for column-level constraints
9448                    columns: vec![],  // Not applicable for column-level constraints
9449                    foreign_table,
9450                    referred_columns,
9451                    on_delete,
9452                    on_update,
9453                    match_kind,
9454                    characteristics,
9455                }
9456                .into(),
9457            ))
9458        } else if self.parse_keyword(Keyword::CHECK) {
9459            self.expect_token(&Token::LParen)?;
9460            // since `CHECK` requires parentheses, we can parse the inner expression in ParserState::Normal
9461            let expr: Expr = self.with_state(ParserState::Normal, |p| p.parse_expr())?;
9462            self.expect_token(&Token::RParen)?;
9463
9464            let enforced = if self.parse_keyword(Keyword::ENFORCED) {
9465                Some(true)
9466            } else if self.parse_keywords(&[Keyword::NOT, Keyword::ENFORCED]) {
9467                Some(false)
9468            } else {
9469                None
9470            };
9471
9472            Ok(Some(
9473                CheckConstraint {
9474                    name: None, // Column-level check constraints don't have names
9475                    expr: Box::new(expr),
9476                    enforced,
9477                }
9478                .into(),
9479            ))
9480        } else if self.parse_keyword(Keyword::AUTO_INCREMENT)
9481            && dialect_of!(self is MySqlDialect | GenericDialect)
9482        {
9483            // Support AUTO_INCREMENT for MySQL
9484            Ok(Some(ColumnOption::DialectSpecific(vec![
9485                Token::make_keyword("AUTO_INCREMENT"),
9486            ])))
9487        } else if self.parse_keyword(Keyword::AUTOINCREMENT)
9488            && dialect_of!(self is SQLiteDialect |  GenericDialect)
9489        {
9490            // Support AUTOINCREMENT for SQLite
9491            Ok(Some(ColumnOption::DialectSpecific(vec![
9492                Token::make_keyword("AUTOINCREMENT"),
9493            ])))
9494        } else if self.parse_keyword(Keyword::ASC)
9495            && self.dialect.supports_asc_desc_in_column_definition()
9496        {
9497            // Support ASC for SQLite
9498            Ok(Some(ColumnOption::DialectSpecific(vec![
9499                Token::make_keyword("ASC"),
9500            ])))
9501        } else if self.parse_keyword(Keyword::DESC)
9502            && self.dialect.supports_asc_desc_in_column_definition()
9503        {
9504            // Support DESC for SQLite
9505            Ok(Some(ColumnOption::DialectSpecific(vec![
9506                Token::make_keyword("DESC"),
9507            ])))
9508        } else if self.parse_keywords(&[Keyword::ON, Keyword::UPDATE])
9509            && dialect_of!(self is MySqlDialect | GenericDialect)
9510        {
9511            let expr = self.parse_expr()?;
9512            Ok(Some(ColumnOption::OnUpdate(expr)))
9513        } else if self.parse_keyword(Keyword::GENERATED) {
9514            self.parse_optional_column_option_generated()
9515        } else if dialect_of!(self is BigQueryDialect | GenericDialect)
9516            && self.parse_keyword(Keyword::OPTIONS)
9517        {
9518            self.prev_token();
9519            Ok(Some(ColumnOption::Options(
9520                self.parse_options(Keyword::OPTIONS)?,
9521            )))
9522        } else if self.parse_keyword(Keyword::AS)
9523            && dialect_of!(self is MySqlDialect | SQLiteDialect | DuckDbDialect | GenericDialect)
9524        {
9525            self.parse_optional_column_option_as()
9526        } else if self.parse_keyword(Keyword::SRID)
9527            && dialect_of!(self is MySqlDialect | GenericDialect)
9528        {
9529            Ok(Some(ColumnOption::Srid(Box::new(self.parse_expr()?))))
9530        } else if self.parse_keyword(Keyword::IDENTITY)
9531            && dialect_of!(self is MsSqlDialect | GenericDialect)
9532        {
9533            let parameters = if self.consume_token(&Token::LParen) {
9534                let seed = self.parse_number()?;
9535                self.expect_token(&Token::Comma)?;
9536                let increment = self.parse_number()?;
9537                self.expect_token(&Token::RParen)?;
9538
9539                Some(IdentityPropertyFormatKind::FunctionCall(
9540                    IdentityParameters { seed, increment },
9541                ))
9542            } else {
9543                None
9544            };
9545            Ok(Some(ColumnOption::Identity(
9546                IdentityPropertyKind::Identity(IdentityProperty {
9547                    parameters,
9548                    order: None,
9549                }),
9550            )))
9551        } else if dialect_of!(self is SQLiteDialect | GenericDialect)
9552            && self.parse_keywords(&[Keyword::ON, Keyword::CONFLICT])
9553        {
9554            // Support ON CONFLICT for SQLite
9555            Ok(Some(ColumnOption::OnConflict(
9556                self.expect_one_of_keywords(&[
9557                    Keyword::ROLLBACK,
9558                    Keyword::ABORT,
9559                    Keyword::FAIL,
9560                    Keyword::IGNORE,
9561                    Keyword::REPLACE,
9562                ])?,
9563            )))
9564        } else if self.parse_keyword(Keyword::INVISIBLE) {
9565            Ok(Some(ColumnOption::Invisible))
9566        } else {
9567            Ok(None)
9568        }
9569    }
9570
9571    pub(crate) fn parse_tag(&mut self) -> Result<Tag, ParserError> {
9572        let name = self.parse_object_name(false)?;
9573        self.expect_token(&Token::Eq)?;
9574        let value = self.parse_literal_string()?;
9575
9576        Ok(Tag::new(name, value))
9577    }
9578
9579    fn parse_optional_column_option_generated(
9580        &mut self,
9581    ) -> Result<Option<ColumnOption>, ParserError> {
9582        if self.parse_keywords(&[Keyword::ALWAYS, Keyword::AS, Keyword::IDENTITY]) {
9583            let mut sequence_options = vec![];
9584            if self.expect_token(&Token::LParen).is_ok() {
9585                sequence_options = self.parse_create_sequence_options()?;
9586                self.expect_token(&Token::RParen)?;
9587            }
9588            Ok(Some(ColumnOption::Generated {
9589                generated_as: GeneratedAs::Always,
9590                sequence_options: Some(sequence_options),
9591                generation_expr: None,
9592                generation_expr_mode: None,
9593                generated_keyword: true,
9594            }))
9595        } else if self.parse_keywords(&[
9596            Keyword::BY,
9597            Keyword::DEFAULT,
9598            Keyword::AS,
9599            Keyword::IDENTITY,
9600        ]) {
9601            let mut sequence_options = vec![];
9602            if self.expect_token(&Token::LParen).is_ok() {
9603                sequence_options = self.parse_create_sequence_options()?;
9604                self.expect_token(&Token::RParen)?;
9605            }
9606            Ok(Some(ColumnOption::Generated {
9607                generated_as: GeneratedAs::ByDefault,
9608                sequence_options: Some(sequence_options),
9609                generation_expr: None,
9610                generation_expr_mode: None,
9611                generated_keyword: true,
9612            }))
9613        } else if self.parse_keywords(&[Keyword::ALWAYS, Keyword::AS]) {
9614            if self.expect_token(&Token::LParen).is_ok() {
9615                let expr: Expr = self.with_state(ParserState::Normal, |p| p.parse_expr())?;
9616                self.expect_token(&Token::RParen)?;
9617                let (gen_as, expr_mode) = if self.parse_keywords(&[Keyword::STORED]) {
9618                    Ok((
9619                        GeneratedAs::ExpStored,
9620                        Some(GeneratedExpressionMode::Stored),
9621                    ))
9622                } else if dialect_of!(self is PostgreSqlDialect) {
9623                    // Postgres' AS IDENTITY branches are above, this one needs STORED
9624                    self.expected_ref("STORED", self.peek_token_ref())
9625                } else if self.parse_keywords(&[Keyword::VIRTUAL]) {
9626                    Ok((GeneratedAs::Always, Some(GeneratedExpressionMode::Virtual)))
9627                } else {
9628                    Ok((GeneratedAs::Always, None))
9629                }?;
9630
9631                Ok(Some(ColumnOption::Generated {
9632                    generated_as: gen_as,
9633                    sequence_options: None,
9634                    generation_expr: Some(expr),
9635                    generation_expr_mode: expr_mode,
9636                    generated_keyword: true,
9637                }))
9638            } else {
9639                Ok(None)
9640            }
9641        } else {
9642            Ok(None)
9643        }
9644    }
9645
9646    fn parse_optional_column_option_as(&mut self) -> Result<Option<ColumnOption>, ParserError> {
9647        // Some DBs allow 'AS (expr)', shorthand for GENERATED ALWAYS AS
9648        self.expect_token(&Token::LParen)?;
9649        let expr = self.parse_expr()?;
9650        self.expect_token(&Token::RParen)?;
9651
9652        let (gen_as, expr_mode) = if self.parse_keywords(&[Keyword::STORED]) {
9653            (
9654                GeneratedAs::ExpStored,
9655                Some(GeneratedExpressionMode::Stored),
9656            )
9657        } else if self.parse_keywords(&[Keyword::VIRTUAL]) {
9658            (GeneratedAs::Always, Some(GeneratedExpressionMode::Virtual))
9659        } else {
9660            (GeneratedAs::Always, None)
9661        };
9662
9663        Ok(Some(ColumnOption::Generated {
9664            generated_as: gen_as,
9665            sequence_options: None,
9666            generation_expr: Some(expr),
9667            generation_expr_mode: expr_mode,
9668            generated_keyword: false,
9669        }))
9670    }
9671
9672    /// Parse optional `CLUSTERED BY` clause for Hive/Generic dialects.
9673    pub fn parse_optional_clustered_by(&mut self) -> Result<Option<ClusteredBy>, ParserError> {
9674        let clustered_by = if dialect_of!(self is HiveDialect|GenericDialect)
9675            && self.parse_keywords(&[Keyword::CLUSTERED, Keyword::BY])
9676        {
9677            let columns = self.parse_parenthesized_column_list(Mandatory, false)?;
9678
9679            let sorted_by = if self.parse_keywords(&[Keyword::SORTED, Keyword::BY]) {
9680                self.expect_token(&Token::LParen)?;
9681                let sorted_by_columns = self.parse_comma_separated(|p| p.parse_order_by_expr())?;
9682                self.expect_token(&Token::RParen)?;
9683                Some(sorted_by_columns)
9684            } else {
9685                None
9686            };
9687
9688            self.expect_keyword_is(Keyword::INTO)?;
9689            let num_buckets = self.parse_number_value()?.value;
9690            self.expect_keyword_is(Keyword::BUCKETS)?;
9691            Some(ClusteredBy {
9692                columns,
9693                sorted_by,
9694                num_buckets,
9695            })
9696        } else {
9697            None
9698        };
9699        Ok(clustered_by)
9700    }
9701
9702    /// Parse a referential action used in foreign key clauses.
9703    ///
9704    /// Recognized forms: `RESTRICT`, `CASCADE`, `SET NULL`, `NO ACTION`, `SET DEFAULT`.
9705    pub fn parse_referential_action(&mut self) -> Result<ReferentialAction, ParserError> {
9706        if self.parse_keyword(Keyword::RESTRICT) {
9707            Ok(ReferentialAction::Restrict)
9708        } else if self.parse_keyword(Keyword::CASCADE) {
9709            Ok(ReferentialAction::Cascade)
9710        } else if self.parse_keywords(&[Keyword::SET, Keyword::NULL]) {
9711            Ok(ReferentialAction::SetNull)
9712        } else if self.parse_keywords(&[Keyword::NO, Keyword::ACTION]) {
9713            Ok(ReferentialAction::NoAction)
9714        } else if self.parse_keywords(&[Keyword::SET, Keyword::DEFAULT]) {
9715            Ok(ReferentialAction::SetDefault)
9716        } else {
9717            self.expected_ref(
9718                "one of RESTRICT, CASCADE, SET NULL, NO ACTION or SET DEFAULT",
9719                self.peek_token_ref(),
9720            )
9721        }
9722    }
9723
9724    /// Parse a `MATCH` kind for constraint references: `FULL`, `PARTIAL`, or `SIMPLE`.
9725    pub fn parse_match_kind(&mut self) -> Result<ConstraintReferenceMatchKind, ParserError> {
9726        if self.parse_keyword(Keyword::FULL) {
9727            Ok(ConstraintReferenceMatchKind::Full)
9728        } else if self.parse_keyword(Keyword::PARTIAL) {
9729            Ok(ConstraintReferenceMatchKind::Partial)
9730        } else if self.parse_keyword(Keyword::SIMPLE) {
9731            Ok(ConstraintReferenceMatchKind::Simple)
9732        } else {
9733            self.expected_ref("one of FULL, PARTIAL or SIMPLE", self.peek_token_ref())
9734        }
9735    }
9736
9737    /// Parse `index_name [ DEFERRABLE | NOT DEFERRABLE ] [ INITIALLY DEFERRED | INITIALLY IMMEDIATE ]`
9738    /// after `{ PRIMARY KEY | UNIQUE } USING INDEX`.
9739    fn parse_constraint_using_index(
9740        &mut self,
9741        name: Option<Ident>,
9742    ) -> Result<ConstraintUsingIndex, ParserError> {
9743        let index_name = self.parse_identifier()?;
9744        let characteristics = self.parse_constraint_characteristics()?;
9745        Ok(ConstraintUsingIndex {
9746            name,
9747            index_name,
9748            characteristics,
9749        })
9750    }
9751
9752    /// Parse optional constraint characteristics such as `DEFERRABLE`, `INITIALLY` and `ENFORCED`.
9753    pub fn parse_constraint_characteristics(
9754        &mut self,
9755    ) -> Result<Option<ConstraintCharacteristics>, ParserError> {
9756        let mut cc = ConstraintCharacteristics::default();
9757
9758        loop {
9759            if cc.deferrable.is_none() && self.parse_keywords(&[Keyword::NOT, Keyword::DEFERRABLE])
9760            {
9761                cc.deferrable = Some(false);
9762            } else if cc.deferrable.is_none() && self.parse_keyword(Keyword::DEFERRABLE) {
9763                cc.deferrable = Some(true);
9764            } else if cc.initially.is_none() && self.parse_keyword(Keyword::INITIALLY) {
9765                if self.parse_keyword(Keyword::DEFERRED) {
9766                    cc.initially = Some(DeferrableInitial::Deferred);
9767                } else if self.parse_keyword(Keyword::IMMEDIATE) {
9768                    cc.initially = Some(DeferrableInitial::Immediate);
9769                } else {
9770                    self.expected_ref("one of DEFERRED or IMMEDIATE", self.peek_token_ref())?;
9771                }
9772            } else if cc.enforced.is_none() && self.parse_keyword(Keyword::ENFORCED) {
9773                cc.enforced = Some(true);
9774            } else if cc.enforced.is_none()
9775                && self.parse_keywords(&[Keyword::NOT, Keyword::ENFORCED])
9776            {
9777                cc.enforced = Some(false);
9778            } else {
9779                break;
9780            }
9781        }
9782
9783        if cc.deferrable.is_some() || cc.initially.is_some() || cc.enforced.is_some() {
9784            Ok(Some(cc))
9785        } else {
9786            Ok(None)
9787        }
9788    }
9789
9790    /// Parse an optional table constraint (e.g. `PRIMARY KEY`, `UNIQUE`, `FOREIGN KEY`, `CHECK`).
9791    pub fn parse_optional_table_constraint(
9792        &mut self,
9793    ) -> Result<Option<TableConstraint>, ParserError> {
9794        let name = if self.parse_keyword(Keyword::CONSTRAINT) {
9795            if self.dialect.supports_constraint_keyword_without_name()
9796                && self
9797                    .peek_one_of_keywords(&[
9798                        Keyword::CHECK,
9799                        Keyword::PRIMARY,
9800                        Keyword::UNIQUE,
9801                        Keyword::FOREIGN,
9802                    ])
9803                    .is_some()
9804            {
9805                None
9806            } else {
9807                Some(self.parse_identifier()?)
9808            }
9809        } else {
9810            None
9811        };
9812
9813        let next_token = self.next_token();
9814        match next_token.token {
9815            Token::Word(w) if w.keyword == Keyword::UNIQUE => {
9816                // PostgreSQL: UNIQUE USING INDEX index_name
9817                // https://www.postgresql.org/docs/current/sql-altertable.html
9818                if self.parse_keywords(&[Keyword::USING, Keyword::INDEX]) {
9819                    return Ok(Some(TableConstraint::UniqueUsingIndex(
9820                        self.parse_constraint_using_index(name)?,
9821                    )));
9822                }
9823
9824                let index_type_display = self.parse_index_type_display();
9825                if !dialect_of!(self is GenericDialect | MySqlDialect)
9826                    && !index_type_display.is_none()
9827                {
9828                    return self.expected_ref(
9829                        "`index_name` or `(column_name [, ...])`",
9830                        self.peek_token_ref(),
9831                    );
9832                }
9833
9834                let nulls_distinct = self.parse_optional_nulls_distinct()?;
9835
9836                // optional index name
9837                let index_name = self.parse_optional_ident()?;
9838                let index_type = self.parse_optional_using_then_index_type()?;
9839
9840                let columns = self.parse_parenthesized_index_column_list()?;
9841                let index_options = self.parse_index_options()?;
9842                let characteristics = self.parse_constraint_characteristics()?;
9843                Ok(Some(
9844                    UniqueConstraint {
9845                        name,
9846                        index_name,
9847                        index_type_display,
9848                        index_type,
9849                        columns,
9850                        index_options,
9851                        characteristics,
9852                        nulls_distinct,
9853                    }
9854                    .into(),
9855                ))
9856            }
9857            Token::Word(w) if w.keyword == Keyword::PRIMARY => {
9858                // after `PRIMARY` always stay `KEY`
9859                self.expect_keyword_is(Keyword::KEY)?;
9860
9861                // PostgreSQL: PRIMARY KEY USING INDEX index_name
9862                // https://www.postgresql.org/docs/current/sql-altertable.html
9863                if self.parse_keywords(&[Keyword::USING, Keyword::INDEX]) {
9864                    return Ok(Some(TableConstraint::PrimaryKeyUsingIndex(
9865                        self.parse_constraint_using_index(name)?,
9866                    )));
9867                }
9868
9869                // optional index name
9870                let index_name = self.parse_optional_ident()?;
9871                let index_type = self.parse_optional_using_then_index_type()?;
9872
9873                let columns = self.parse_parenthesized_index_column_list()?;
9874                let index_options = self.parse_index_options()?;
9875                let characteristics = self.parse_constraint_characteristics()?;
9876                Ok(Some(
9877                    PrimaryKeyConstraint {
9878                        name,
9879                        index_name,
9880                        index_type,
9881                        columns,
9882                        index_options,
9883                        characteristics,
9884                    }
9885                    .into(),
9886                ))
9887            }
9888            Token::Word(w) if w.keyword == Keyword::FOREIGN => {
9889                self.expect_keyword_is(Keyword::KEY)?;
9890                let index_name = self.parse_optional_ident()?;
9891                let columns = self.parse_parenthesized_column_list(Mandatory, false)?;
9892                self.expect_keyword_is(Keyword::REFERENCES)?;
9893                let foreign_table = self.parse_object_name(false)?;
9894                let referred_columns = self.parse_parenthesized_column_list(Optional, false)?;
9895                let mut match_kind = None;
9896                let mut on_delete = None;
9897                let mut on_update = None;
9898                loop {
9899                    if match_kind.is_none() && self.parse_keyword(Keyword::MATCH) {
9900                        match_kind = Some(self.parse_match_kind()?);
9901                    } else if on_delete.is_none()
9902                        && self.parse_keywords(&[Keyword::ON, Keyword::DELETE])
9903                    {
9904                        on_delete = Some(self.parse_referential_action()?);
9905                    } else if on_update.is_none()
9906                        && self.parse_keywords(&[Keyword::ON, Keyword::UPDATE])
9907                    {
9908                        on_update = Some(self.parse_referential_action()?);
9909                    } else {
9910                        break;
9911                    }
9912                }
9913
9914                let characteristics = self.parse_constraint_characteristics()?;
9915
9916                Ok(Some(
9917                    ForeignKeyConstraint {
9918                        name,
9919                        index_name,
9920                        columns,
9921                        foreign_table,
9922                        referred_columns,
9923                        on_delete,
9924                        on_update,
9925                        match_kind,
9926                        characteristics,
9927                    }
9928                    .into(),
9929                ))
9930            }
9931            Token::Word(w) if w.keyword == Keyword::CHECK => {
9932                self.expect_token(&Token::LParen)?;
9933                let expr = Box::new(self.parse_expr()?);
9934                self.expect_token(&Token::RParen)?;
9935
9936                let enforced = if self.parse_keyword(Keyword::ENFORCED) {
9937                    Some(true)
9938                } else if self.parse_keywords(&[Keyword::NOT, Keyword::ENFORCED]) {
9939                    Some(false)
9940                } else {
9941                    None
9942                };
9943
9944                Ok(Some(
9945                    CheckConstraint {
9946                        name,
9947                        expr,
9948                        enforced,
9949                    }
9950                    .into(),
9951                ))
9952            }
9953            Token::Word(w)
9954                if (w.keyword == Keyword::INDEX || w.keyword == Keyword::KEY)
9955                    && dialect_of!(self is GenericDialect | MySqlDialect)
9956                    && name.is_none() =>
9957            {
9958                let display_as_key = w.keyword == Keyword::KEY;
9959
9960                let name = match &self.peek_token_ref().token {
9961                    Token::Word(word) if word.keyword == Keyword::USING => None,
9962                    _ => self.parse_optional_ident()?,
9963                };
9964
9965                let index_type = self.parse_optional_using_then_index_type()?;
9966                let columns = self.parse_parenthesized_index_column_list()?;
9967                let index_options = self.parse_index_options()?;
9968
9969                Ok(Some(
9970                    IndexConstraint {
9971                        display_as_key,
9972                        name,
9973                        index_type,
9974                        columns,
9975                        index_options,
9976                    }
9977                    .into(),
9978                ))
9979            }
9980            Token::Word(w)
9981                if (w.keyword == Keyword::FULLTEXT || w.keyword == Keyword::SPATIAL)
9982                    && dialect_of!(self is GenericDialect | MySqlDialect) =>
9983            {
9984                if let Some(name) = name {
9985                    return self.expected(
9986                        "FULLTEXT or SPATIAL option without constraint name",
9987                        TokenWithSpan {
9988                            token: Token::make_keyword(&name.to_string()),
9989                            span: next_token.span,
9990                        },
9991                    );
9992                }
9993
9994                let fulltext = w.keyword == Keyword::FULLTEXT;
9995
9996                let index_type_display = self.parse_index_type_display();
9997
9998                let opt_index_name = self.parse_optional_ident()?;
9999
10000                let columns = self.parse_parenthesized_index_column_list()?;
10001
10002                Ok(Some(
10003                    FullTextOrSpatialConstraint {
10004                        fulltext,
10005                        index_type_display,
10006                        opt_index_name,
10007                        columns,
10008                    }
10009                    .into(),
10010                ))
10011            }
10012            _ => {
10013                if name.is_some() {
10014                    self.expected("PRIMARY, UNIQUE, FOREIGN, or CHECK", next_token)
10015                } else {
10016                    self.prev_token();
10017                    Ok(None)
10018                }
10019            }
10020        }
10021    }
10022
10023    fn parse_optional_nulls_distinct(&mut self) -> Result<NullsDistinctOption, ParserError> {
10024        Ok(if self.parse_keyword(Keyword::NULLS) {
10025            let not = self.parse_keyword(Keyword::NOT);
10026            self.expect_keyword_is(Keyword::DISTINCT)?;
10027            if not {
10028                NullsDistinctOption::NotDistinct
10029            } else {
10030                NullsDistinctOption::Distinct
10031            }
10032        } else {
10033            NullsDistinctOption::None
10034        })
10035    }
10036
10037    /// Optionally parse a parenthesized list of `SqlOption`s introduced by `keyword`.
10038    pub fn maybe_parse_options(
10039        &mut self,
10040        keyword: Keyword,
10041    ) -> Result<Option<Vec<SqlOption>>, ParserError> {
10042        if let Token::Word(word) = &self.peek_token_ref().token {
10043            if word.keyword == keyword {
10044                return Ok(Some(self.parse_options(keyword)?));
10045            }
10046        };
10047        Ok(None)
10048    }
10049
10050    /// Parse a parenthesized list of `SqlOption`s following `keyword`, or return an empty vec.
10051    pub fn parse_options(&mut self, keyword: Keyword) -> Result<Vec<SqlOption>, ParserError> {
10052        if self.parse_keyword(keyword) {
10053            self.expect_token(&Token::LParen)?;
10054            let options = self.parse_comma_separated0(Parser::parse_sql_option, Token::RParen)?;
10055            self.expect_token(&Token::RParen)?;
10056            Ok(options)
10057        } else {
10058            Ok(vec![])
10059        }
10060    }
10061
10062    /// Parse options introduced by one of `keywords` followed by a parenthesized list.
10063    pub fn parse_options_with_keywords(
10064        &mut self,
10065        keywords: &[Keyword],
10066    ) -> Result<Vec<SqlOption>, ParserError> {
10067        if self.parse_keywords(keywords) {
10068            self.expect_token(&Token::LParen)?;
10069            let options = self.parse_comma_separated(Parser::parse_sql_option)?;
10070            self.expect_token(&Token::RParen)?;
10071            Ok(options)
10072        } else {
10073            Ok(vec![])
10074        }
10075    }
10076
10077    /// Parse an index type token (e.g. `BTREE`, `HASH`, or a custom identifier).
10078    pub fn parse_index_type(&mut self) -> Result<IndexType, ParserError> {
10079        Ok(if self.parse_keyword(Keyword::BTREE) {
10080            IndexType::BTree
10081        } else if self.parse_keyword(Keyword::HASH) {
10082            IndexType::Hash
10083        } else if self.parse_keyword(Keyword::GIN) {
10084            IndexType::GIN
10085        } else if self.parse_keyword(Keyword::GIST) {
10086            IndexType::GiST
10087        } else if self.parse_keyword(Keyword::SPGIST) {
10088            IndexType::SPGiST
10089        } else if self.parse_keyword(Keyword::BRIN) {
10090            IndexType::BRIN
10091        } else if self.parse_keyword(Keyword::BLOOM) {
10092            IndexType::Bloom
10093        } else {
10094            IndexType::Custom(self.parse_identifier()?)
10095        })
10096    }
10097
10098    /// Optionally parse the `USING` keyword, followed by an [IndexType]
10099    /// Example:
10100    /// ```sql
10101    //// USING BTREE (name, age DESC)
10102    /// ```
10103    /// Optionally parse `USING <index_type>` and return the parsed `IndexType` if present.
10104    pub fn parse_optional_using_then_index_type(
10105        &mut self,
10106    ) -> Result<Option<IndexType>, ParserError> {
10107        if self.parse_keyword(Keyword::USING) {
10108            Ok(Some(self.parse_index_type()?))
10109        } else {
10110            Ok(None)
10111        }
10112    }
10113
10114    /// Parse `[ident]`, mostly `ident` is name, like:
10115    /// `window_name`, `index_name`, ...
10116    /// Parse an optional identifier, returning `Some(Ident)` if present.
10117    pub fn parse_optional_ident(&mut self) -> Result<Option<Ident>, ParserError> {
10118        self.maybe_parse(|parser| parser.parse_identifier())
10119    }
10120
10121    #[must_use]
10122    /// Parse optional `KEY` or `INDEX` display tokens used in index/constraint declarations.
10123    pub fn parse_index_type_display(&mut self) -> KeyOrIndexDisplay {
10124        if self.parse_keyword(Keyword::KEY) {
10125            KeyOrIndexDisplay::Key
10126        } else if self.parse_keyword(Keyword::INDEX) {
10127            KeyOrIndexDisplay::Index
10128        } else {
10129            KeyOrIndexDisplay::None
10130        }
10131    }
10132
10133    /// Parse an optional index option such as `USING <type>` or `COMMENT <string>`.
10134    pub fn parse_optional_index_option(&mut self) -> Result<Option<IndexOption>, ParserError> {
10135        if let Some(index_type) = self.parse_optional_using_then_index_type()? {
10136            Ok(Some(IndexOption::Using(index_type)))
10137        } else if self.parse_keyword(Keyword::COMMENT) {
10138            let s = self.parse_literal_string()?;
10139            Ok(Some(IndexOption::Comment(s)))
10140        } else {
10141            Ok(None)
10142        }
10143    }
10144
10145    /// Parse zero or more index options and return them as a vector.
10146    pub fn parse_index_options(&mut self) -> Result<Vec<IndexOption>, ParserError> {
10147        let mut options = Vec::new();
10148
10149        loop {
10150            match self.parse_optional_index_option()? {
10151                Some(index_option) => options.push(index_option),
10152                None => return Ok(options),
10153            }
10154        }
10155    }
10156
10157    /// Parse a single `SqlOption` used by various dialect-specific DDL statements.
10158    pub fn parse_sql_option(&mut self) -> Result<SqlOption, ParserError> {
10159        let is_mssql = dialect_of!(self is MsSqlDialect|GenericDialect);
10160
10161        match &self.peek_token_ref().token {
10162            Token::Word(w) if w.keyword == Keyword::HEAP && is_mssql => {
10163                Ok(SqlOption::Ident(self.parse_identifier()?))
10164            }
10165            Token::Word(w) if w.keyword == Keyword::PARTITION && is_mssql => {
10166                self.parse_option_partition()
10167            }
10168            Token::Word(w) if w.keyword == Keyword::CLUSTERED && is_mssql => {
10169                self.parse_option_clustered()
10170            }
10171            _ => {
10172                let name = self.parse_identifier()?;
10173                self.expect_token(&Token::Eq)?;
10174                let value = self.parse_expr()?;
10175
10176                Ok(SqlOption::KeyValue { key: name, value })
10177            }
10178        }
10179    }
10180
10181    /// Parse a `CLUSTERED` table option (MSSQL-specific syntaxes supported).
10182    pub fn parse_option_clustered(&mut self) -> Result<SqlOption, ParserError> {
10183        if self.parse_keywords(&[
10184            Keyword::CLUSTERED,
10185            Keyword::COLUMNSTORE,
10186            Keyword::INDEX,
10187            Keyword::ORDER,
10188        ]) {
10189            Ok(SqlOption::Clustered(
10190                TableOptionsClustered::ColumnstoreIndexOrder(
10191                    self.parse_parenthesized_column_list(IsOptional::Mandatory, false)?,
10192                ),
10193            ))
10194        } else if self.parse_keywords(&[Keyword::CLUSTERED, Keyword::COLUMNSTORE, Keyword::INDEX]) {
10195            Ok(SqlOption::Clustered(
10196                TableOptionsClustered::ColumnstoreIndex,
10197            ))
10198        } else if self.parse_keywords(&[Keyword::CLUSTERED, Keyword::INDEX]) {
10199            self.expect_token(&Token::LParen)?;
10200
10201            let columns = self.parse_comma_separated(|p| {
10202                let name = p.parse_identifier()?;
10203                let asc = p.parse_asc_desc();
10204
10205                Ok(ClusteredIndex { name, asc })
10206            })?;
10207
10208            self.expect_token(&Token::RParen)?;
10209
10210            Ok(SqlOption::Clustered(TableOptionsClustered::Index(columns)))
10211        } else {
10212            Err(ParserError::ParserError(
10213                "invalid CLUSTERED sequence".to_string(),
10214            ))
10215        }
10216    }
10217
10218    /// Parse a `PARTITION(...) FOR VALUES(...)` table option.
10219    pub fn parse_option_partition(&mut self) -> Result<SqlOption, ParserError> {
10220        self.expect_keyword_is(Keyword::PARTITION)?;
10221        self.expect_token(&Token::LParen)?;
10222        let column_name = self.parse_identifier()?;
10223
10224        self.expect_keyword_is(Keyword::RANGE)?;
10225        let range_direction = if self.parse_keyword(Keyword::LEFT) {
10226            Some(PartitionRangeDirection::Left)
10227        } else if self.parse_keyword(Keyword::RIGHT) {
10228            Some(PartitionRangeDirection::Right)
10229        } else {
10230            None
10231        };
10232
10233        self.expect_keywords(&[Keyword::FOR, Keyword::VALUES])?;
10234        self.expect_token(&Token::LParen)?;
10235
10236        let for_values = self.parse_comma_separated(Parser::parse_expr)?;
10237
10238        self.expect_token(&Token::RParen)?;
10239        self.expect_token(&Token::RParen)?;
10240
10241        Ok(SqlOption::Partition {
10242            column_name,
10243            range_direction,
10244            for_values,
10245        })
10246    }
10247
10248    /// Parse a parenthesized list of partition expressions and return a `Partition` value.
10249    pub fn parse_partition(&mut self) -> Result<Partition, ParserError> {
10250        self.expect_token(&Token::LParen)?;
10251        let partitions = self.parse_comma_separated(Parser::parse_expr)?;
10252        self.expect_token(&Token::RParen)?;
10253        Ok(Partition::Partitions(partitions))
10254    }
10255
10256    /// Parse a parenthesized `SELECT` projection used for projection-based operations.
10257    pub fn parse_projection_select(&mut self) -> Result<ProjectionSelect, ParserError> {
10258        self.expect_token(&Token::LParen)?;
10259        self.expect_keyword_is(Keyword::SELECT)?;
10260        let projection = self.parse_projection()?;
10261        let group_by = self.parse_optional_group_by()?;
10262        let order_by = self.parse_optional_order_by()?;
10263        self.expect_token(&Token::RParen)?;
10264        Ok(ProjectionSelect {
10265            projection,
10266            group_by,
10267            order_by,
10268        })
10269    }
10270    /// Parse `ALTER TABLE ... ADD PROJECTION ...` operation.
10271    pub fn parse_alter_table_add_projection(&mut self) -> Result<AlterTableOperation, ParserError> {
10272        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
10273        let name = self.parse_identifier()?;
10274        let query = self.parse_projection_select()?;
10275        Ok(AlterTableOperation::AddProjection {
10276            if_not_exists,
10277            name,
10278            select: query,
10279        })
10280    }
10281
10282    /// Parse Redshift `ALTER SORTKEY (column_list)`.
10283    ///
10284    /// See <https://docs.aws.amazon.com/redshift/latest/dg/r_ALTER_TABLE.html>
10285    fn parse_alter_sort_key(&mut self) -> Result<AlterTableOperation, ParserError> {
10286        self.expect_keyword_is(Keyword::ALTER)?;
10287        self.expect_keyword_is(Keyword::SORTKEY)?;
10288        self.expect_token(&Token::LParen)?;
10289        let columns = self.parse_comma_separated(|p| p.parse_expr())?;
10290        self.expect_token(&Token::RParen)?;
10291        Ok(AlterTableOperation::AlterSortKey { columns })
10292    }
10293
10294    /// Parse a single `ALTER TABLE` operation and return an `AlterTableOperation`.
10295    pub fn parse_alter_table_operation(&mut self) -> Result<AlterTableOperation, ParserError> {
10296        let operation = if self.parse_keyword(Keyword::ADD) {
10297            if let Some(constraint) = self.parse_optional_table_constraint()? {
10298                let not_valid = self.parse_keywords(&[Keyword::NOT, Keyword::VALID]);
10299                AlterTableOperation::AddConstraint {
10300                    constraint,
10301                    not_valid,
10302                }
10303            } else if dialect_of!(self is ClickHouseDialect|GenericDialect)
10304                && self.parse_keyword(Keyword::PROJECTION)
10305            {
10306                return self.parse_alter_table_add_projection();
10307            } else {
10308                let if_not_exists =
10309                    self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
10310                let mut new_partitions = vec![];
10311                loop {
10312                    if self.parse_keyword(Keyword::PARTITION) {
10313                        new_partitions.push(self.parse_partition()?);
10314                    } else {
10315                        break;
10316                    }
10317                }
10318                if !new_partitions.is_empty() {
10319                    AlterTableOperation::AddPartitions {
10320                        if_not_exists,
10321                        new_partitions,
10322                    }
10323                } else {
10324                    let column_keyword = self.parse_keyword(Keyword::COLUMN);
10325
10326                    let if_not_exists = if dialect_of!(self is PostgreSqlDialect | BigQueryDialect | DuckDbDialect | GenericDialect)
10327                    {
10328                        self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS])
10329                            || if_not_exists
10330                    } else {
10331                        false
10332                    };
10333
10334                    let column_def = self.parse_column_def()?;
10335
10336                    let column_position = self.parse_column_position()?;
10337
10338                    AlterTableOperation::AddColumn {
10339                        column_keyword,
10340                        if_not_exists,
10341                        column_def,
10342                        column_position,
10343                    }
10344                }
10345            }
10346        } else if self.parse_keyword(Keyword::RENAME) {
10347            if dialect_of!(self is PostgreSqlDialect) && self.parse_keyword(Keyword::CONSTRAINT) {
10348                let old_name = self.parse_identifier()?;
10349                self.expect_keyword_is(Keyword::TO)?;
10350                let new_name = self.parse_identifier()?;
10351                AlterTableOperation::RenameConstraint { old_name, new_name }
10352            } else if self.parse_keyword(Keyword::TO) {
10353                let table_name = self.parse_object_name(false)?;
10354                AlterTableOperation::RenameTable {
10355                    table_name: RenameTableNameKind::To(table_name),
10356                }
10357            } else if self.parse_keyword(Keyword::AS) {
10358                let table_name = self.parse_object_name(false)?;
10359                AlterTableOperation::RenameTable {
10360                    table_name: RenameTableNameKind::As(table_name),
10361                }
10362            } else {
10363                let _ = self.parse_keyword(Keyword::COLUMN); // [ COLUMN ]
10364                let old_column_name = self.parse_identifier()?;
10365                self.expect_keyword_is(Keyword::TO)?;
10366                let new_column_name = self.parse_identifier()?;
10367                AlterTableOperation::RenameColumn {
10368                    old_column_name,
10369                    new_column_name,
10370                }
10371            }
10372        } else if self.parse_keyword(Keyword::DISABLE) {
10373            if self.parse_keywords(&[Keyword::ROW, Keyword::LEVEL, Keyword::SECURITY]) {
10374                AlterTableOperation::DisableRowLevelSecurity {}
10375            } else if self.parse_keyword(Keyword::RULE) {
10376                let name = self.parse_identifier()?;
10377                AlterTableOperation::DisableRule { name }
10378            } else if self.parse_keyword(Keyword::TRIGGER) {
10379                let name = self.parse_identifier()?;
10380                AlterTableOperation::DisableTrigger { name }
10381            } else {
10382                return self.expected_ref(
10383                    "ROW LEVEL SECURITY, RULE, or TRIGGER after DISABLE",
10384                    self.peek_token_ref(),
10385                );
10386            }
10387        } else if self.parse_keyword(Keyword::ENABLE) {
10388            if self.parse_keywords(&[Keyword::ALWAYS, Keyword::RULE]) {
10389                let name = self.parse_identifier()?;
10390                AlterTableOperation::EnableAlwaysRule { name }
10391            } else if self.parse_keywords(&[Keyword::ALWAYS, Keyword::TRIGGER]) {
10392                let name = self.parse_identifier()?;
10393                AlterTableOperation::EnableAlwaysTrigger { name }
10394            } else if self.parse_keywords(&[Keyword::ROW, Keyword::LEVEL, Keyword::SECURITY]) {
10395                AlterTableOperation::EnableRowLevelSecurity {}
10396            } else if self.parse_keywords(&[Keyword::REPLICA, Keyword::RULE]) {
10397                let name = self.parse_identifier()?;
10398                AlterTableOperation::EnableReplicaRule { name }
10399            } else if self.parse_keywords(&[Keyword::REPLICA, Keyword::TRIGGER]) {
10400                let name = self.parse_identifier()?;
10401                AlterTableOperation::EnableReplicaTrigger { name }
10402            } else if self.parse_keyword(Keyword::RULE) {
10403                let name = self.parse_identifier()?;
10404                AlterTableOperation::EnableRule { name }
10405            } else if self.parse_keyword(Keyword::TRIGGER) {
10406                let name = self.parse_identifier()?;
10407                AlterTableOperation::EnableTrigger { name }
10408            } else {
10409                return self.expected_ref(
10410                    "ALWAYS, REPLICA, ROW LEVEL SECURITY, RULE, or TRIGGER after ENABLE",
10411                    self.peek_token_ref(),
10412                );
10413            }
10414        } else if self.parse_keywords(&[
10415            Keyword::FORCE,
10416            Keyword::ROW,
10417            Keyword::LEVEL,
10418            Keyword::SECURITY,
10419        ]) {
10420            AlterTableOperation::ForceRowLevelSecurity
10421        } else if self.parse_keywords(&[
10422            Keyword::NO,
10423            Keyword::FORCE,
10424            Keyword::ROW,
10425            Keyword::LEVEL,
10426            Keyword::SECURITY,
10427        ]) {
10428            AlterTableOperation::NoForceRowLevelSecurity
10429        } else if self.parse_keywords(&[Keyword::CLEAR, Keyword::PROJECTION])
10430            && dialect_of!(self is ClickHouseDialect|GenericDialect)
10431        {
10432            let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
10433            let name = self.parse_identifier()?;
10434            let partition = if self.parse_keywords(&[Keyword::IN, Keyword::PARTITION]) {
10435                Some(self.parse_identifier()?)
10436            } else {
10437                None
10438            };
10439            AlterTableOperation::ClearProjection {
10440                if_exists,
10441                name,
10442                partition,
10443            }
10444        } else if self.parse_keywords(&[Keyword::MATERIALIZE, Keyword::PROJECTION])
10445            && dialect_of!(self is ClickHouseDialect|GenericDialect)
10446        {
10447            let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
10448            let name = self.parse_identifier()?;
10449            let partition = if self.parse_keywords(&[Keyword::IN, Keyword::PARTITION]) {
10450                Some(self.parse_identifier()?)
10451            } else {
10452                None
10453            };
10454            AlterTableOperation::MaterializeProjection {
10455                if_exists,
10456                name,
10457                partition,
10458            }
10459        } else if self.parse_keyword(Keyword::DROP) {
10460            if self.parse_keywords(&[Keyword::IF, Keyword::EXISTS, Keyword::PARTITION]) {
10461                self.expect_token(&Token::LParen)?;
10462                let partitions = self.parse_comma_separated(Parser::parse_expr)?;
10463                self.expect_token(&Token::RParen)?;
10464                AlterTableOperation::DropPartitions {
10465                    partitions,
10466                    if_exists: true,
10467                }
10468            } else if self.parse_keyword(Keyword::PARTITION) {
10469                self.expect_token(&Token::LParen)?;
10470                let partitions = self.parse_comma_separated(Parser::parse_expr)?;
10471                self.expect_token(&Token::RParen)?;
10472                AlterTableOperation::DropPartitions {
10473                    partitions,
10474                    if_exists: false,
10475                }
10476            } else if self.parse_keyword(Keyword::CONSTRAINT) {
10477                let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
10478                let name = self.parse_identifier()?;
10479                let drop_behavior = self.parse_optional_drop_behavior();
10480                AlterTableOperation::DropConstraint {
10481                    if_exists,
10482                    name,
10483                    drop_behavior,
10484                }
10485            } else if self.parse_keywords(&[Keyword::PRIMARY, Keyword::KEY]) {
10486                let drop_behavior = self.parse_optional_drop_behavior();
10487                AlterTableOperation::DropPrimaryKey { drop_behavior }
10488            } else if self.parse_keywords(&[Keyword::FOREIGN, Keyword::KEY]) {
10489                let name = self.parse_identifier()?;
10490                let drop_behavior = self.parse_optional_drop_behavior();
10491                AlterTableOperation::DropForeignKey {
10492                    name,
10493                    drop_behavior,
10494                }
10495            } else if self.parse_keyword(Keyword::INDEX) {
10496                let name = self.parse_identifier()?;
10497                AlterTableOperation::DropIndex { name }
10498            } else if self.parse_keyword(Keyword::PROJECTION)
10499                && dialect_of!(self is ClickHouseDialect|GenericDialect)
10500            {
10501                let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
10502                let name = self.parse_identifier()?;
10503                AlterTableOperation::DropProjection { if_exists, name }
10504            } else if self.parse_keywords(&[Keyword::CLUSTERING, Keyword::KEY]) {
10505                AlterTableOperation::DropClusteringKey
10506            } else {
10507                let has_column_keyword = self.parse_keyword(Keyword::COLUMN); // [ COLUMN ]
10508                let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
10509                let column_names = if self.dialect.supports_comma_separated_drop_column_list() {
10510                    self.parse_comma_separated(Parser::parse_identifier)?
10511                } else {
10512                    vec![self.parse_identifier()?]
10513                };
10514                let drop_behavior = self.parse_optional_drop_behavior();
10515                AlterTableOperation::DropColumn {
10516                    has_column_keyword,
10517                    column_names,
10518                    if_exists,
10519                    drop_behavior,
10520                }
10521            }
10522        } else if self.parse_keyword(Keyword::PARTITION) {
10523            self.expect_token(&Token::LParen)?;
10524            let before = self.parse_comma_separated(Parser::parse_expr)?;
10525            self.expect_token(&Token::RParen)?;
10526            self.expect_keyword_is(Keyword::RENAME)?;
10527            self.expect_keywords(&[Keyword::TO, Keyword::PARTITION])?;
10528            self.expect_token(&Token::LParen)?;
10529            let renames = self.parse_comma_separated(Parser::parse_expr)?;
10530            self.expect_token(&Token::RParen)?;
10531            AlterTableOperation::RenamePartitions {
10532                old_partitions: before,
10533                new_partitions: renames,
10534            }
10535        } else if self.parse_keyword(Keyword::CHANGE) {
10536            let _ = self.parse_keyword(Keyword::COLUMN); // [ COLUMN ]
10537            let old_name = self.parse_identifier()?;
10538            let new_name = self.parse_identifier()?;
10539            let data_type = self.parse_data_type()?;
10540            let mut options = vec![];
10541            while let Some(option) = self.parse_optional_column_option()? {
10542                options.push(option);
10543            }
10544
10545            let column_position = self.parse_column_position()?;
10546
10547            AlterTableOperation::ChangeColumn {
10548                old_name,
10549                new_name,
10550                data_type,
10551                options,
10552                column_position,
10553            }
10554        } else if self.parse_keyword(Keyword::MODIFY) {
10555            let _ = self.parse_keyword(Keyword::COLUMN); // [ COLUMN ]
10556            let col_name = self.parse_identifier()?;
10557            let data_type = self.parse_data_type()?;
10558            let mut options = vec![];
10559            while let Some(option) = self.parse_optional_column_option()? {
10560                options.push(option);
10561            }
10562
10563            let column_position = self.parse_column_position()?;
10564
10565            AlterTableOperation::ModifyColumn {
10566                col_name,
10567                data_type,
10568                options,
10569                column_position,
10570            }
10571        } else if self.parse_keyword(Keyword::ALTER) {
10572            if self.peek_keyword(Keyword::SORTKEY) {
10573                self.prev_token();
10574                return self.parse_alter_sort_key();
10575            }
10576
10577            let _ = self.parse_keyword(Keyword::COLUMN); // [ COLUMN ]
10578            let column_name = self.parse_identifier()?;
10579            let is_postgresql = dialect_of!(self is PostgreSqlDialect);
10580
10581            let op: AlterColumnOperation = if self.parse_keywords(&[
10582                Keyword::SET,
10583                Keyword::NOT,
10584                Keyword::NULL,
10585            ]) {
10586                AlterColumnOperation::SetNotNull {}
10587            } else if self.parse_keywords(&[Keyword::DROP, Keyword::NOT, Keyword::NULL]) {
10588                AlterColumnOperation::DropNotNull {}
10589            } else if self.parse_keywords(&[Keyword::SET, Keyword::DEFAULT]) {
10590                AlterColumnOperation::SetDefault {
10591                    value: self.parse_expr()?,
10592                }
10593            } else if self.parse_keywords(&[Keyword::DROP, Keyword::DEFAULT]) {
10594                AlterColumnOperation::DropDefault {}
10595            } else if self.parse_keywords(&[Keyword::SET, Keyword::DATA, Keyword::TYPE]) {
10596                self.parse_set_data_type(true)?
10597            } else if self.parse_keyword(Keyword::TYPE) {
10598                self.parse_set_data_type(false)?
10599            } else if self.parse_keywords(&[Keyword::ADD, Keyword::GENERATED]) {
10600                let generated_as = if self.parse_keyword(Keyword::ALWAYS) {
10601                    Some(GeneratedAs::Always)
10602                } else if self.parse_keywords(&[Keyword::BY, Keyword::DEFAULT]) {
10603                    Some(GeneratedAs::ByDefault)
10604                } else {
10605                    None
10606                };
10607
10608                self.expect_keywords(&[Keyword::AS, Keyword::IDENTITY])?;
10609
10610                let mut sequence_options: Option<Vec<SequenceOptions>> = None;
10611
10612                if self.peek_token_ref().token == Token::LParen {
10613                    self.expect_token(&Token::LParen)?;
10614                    sequence_options = Some(self.parse_create_sequence_options()?);
10615                    self.expect_token(&Token::RParen)?;
10616                }
10617
10618                AlterColumnOperation::AddGenerated {
10619                    generated_as,
10620                    sequence_options,
10621                }
10622            } else {
10623                let message = if is_postgresql {
10624                    "SET/DROP NOT NULL, SET DEFAULT, SET DATA TYPE, or ADD GENERATED after ALTER COLUMN"
10625                } else {
10626                    "SET/DROP NOT NULL, SET DEFAULT, or SET DATA TYPE after ALTER COLUMN"
10627                };
10628
10629                return self.expected_ref(message, self.peek_token_ref());
10630            };
10631            AlterTableOperation::AlterColumn { column_name, op }
10632        } else if self.parse_keyword(Keyword::SWAP) {
10633            self.expect_keyword_is(Keyword::WITH)?;
10634            let table_name = self.parse_object_name(false)?;
10635            AlterTableOperation::SwapWith { table_name }
10636        } else if dialect_of!(self is PostgreSqlDialect | GenericDialect)
10637            && self.parse_keywords(&[Keyword::OWNER, Keyword::TO])
10638        {
10639            let new_owner = self.parse_owner()?;
10640            AlterTableOperation::OwnerTo { new_owner }
10641        } else if dialect_of!(self is ClickHouseDialect|GenericDialect)
10642            && self.parse_keyword(Keyword::ATTACH)
10643        {
10644            AlterTableOperation::AttachPartition {
10645                partition: self.parse_part_or_partition()?,
10646            }
10647        } else if dialect_of!(self is ClickHouseDialect|GenericDialect)
10648            && self.parse_keyword(Keyword::DETACH)
10649        {
10650            AlterTableOperation::DetachPartition {
10651                partition: self.parse_part_or_partition()?,
10652            }
10653        } else if dialect_of!(self is ClickHouseDialect|GenericDialect)
10654            && self.parse_keyword(Keyword::FREEZE)
10655        {
10656            let partition = self.parse_part_or_partition()?;
10657            let with_name = if self.parse_keyword(Keyword::WITH) {
10658                self.expect_keyword_is(Keyword::NAME)?;
10659                Some(self.parse_identifier()?)
10660            } else {
10661                None
10662            };
10663            AlterTableOperation::FreezePartition {
10664                partition,
10665                with_name,
10666            }
10667        } else if dialect_of!(self is ClickHouseDialect|GenericDialect)
10668            && self.parse_keyword(Keyword::UNFREEZE)
10669        {
10670            let partition = self.parse_part_or_partition()?;
10671            let with_name = if self.parse_keyword(Keyword::WITH) {
10672                self.expect_keyword_is(Keyword::NAME)?;
10673                Some(self.parse_identifier()?)
10674            } else {
10675                None
10676            };
10677            AlterTableOperation::UnfreezePartition {
10678                partition,
10679                with_name,
10680            }
10681        } else if self.parse_keywords(&[Keyword::CLUSTER, Keyword::BY]) {
10682            self.expect_token(&Token::LParen)?;
10683            let exprs = self.parse_comma_separated(|parser| parser.parse_expr())?;
10684            self.expect_token(&Token::RParen)?;
10685            AlterTableOperation::ClusterBy { exprs }
10686        } else if self.parse_keywords(&[Keyword::SUSPEND, Keyword::RECLUSTER]) {
10687            AlterTableOperation::SuspendRecluster
10688        } else if self.parse_keywords(&[Keyword::RESUME, Keyword::RECLUSTER]) {
10689            AlterTableOperation::ResumeRecluster
10690        } else if self.parse_keyword(Keyword::LOCK) {
10691            let equals = self.consume_token(&Token::Eq);
10692            let lock = match self.parse_one_of_keywords(&[
10693                Keyword::DEFAULT,
10694                Keyword::EXCLUSIVE,
10695                Keyword::NONE,
10696                Keyword::SHARED,
10697            ]) {
10698                Some(Keyword::DEFAULT) => AlterTableLock::Default,
10699                Some(Keyword::EXCLUSIVE) => AlterTableLock::Exclusive,
10700                Some(Keyword::NONE) => AlterTableLock::None,
10701                Some(Keyword::SHARED) => AlterTableLock::Shared,
10702                _ => self.expected_ref(
10703                    "DEFAULT, EXCLUSIVE, NONE or SHARED after LOCK [=]",
10704                    self.peek_token_ref(),
10705                )?,
10706            };
10707            AlterTableOperation::Lock { equals, lock }
10708        } else if self.parse_keyword(Keyword::ALGORITHM) {
10709            let equals = self.consume_token(&Token::Eq);
10710            let algorithm = match self.parse_one_of_keywords(&[
10711                Keyword::DEFAULT,
10712                Keyword::INSTANT,
10713                Keyword::INPLACE,
10714                Keyword::COPY,
10715            ]) {
10716                Some(Keyword::DEFAULT) => AlterTableAlgorithm::Default,
10717                Some(Keyword::INSTANT) => AlterTableAlgorithm::Instant,
10718                Some(Keyword::INPLACE) => AlterTableAlgorithm::Inplace,
10719                Some(Keyword::COPY) => AlterTableAlgorithm::Copy,
10720                _ => self.expected_ref(
10721                    "DEFAULT, INSTANT, INPLACE, or COPY after ALGORITHM [=]",
10722                    self.peek_token_ref(),
10723                )?,
10724            };
10725            AlterTableOperation::Algorithm { equals, algorithm }
10726        } else if self.parse_keyword(Keyword::AUTO_INCREMENT) {
10727            let equals = self.consume_token(&Token::Eq);
10728            let value = self.parse_number_value()?;
10729            AlterTableOperation::AutoIncrement { equals, value }
10730        } else if self.parse_keywords(&[Keyword::REPLICA, Keyword::IDENTITY]) {
10731            let identity = if self.parse_keyword(Keyword::NOTHING) {
10732                ReplicaIdentity::Nothing
10733            } else if self.parse_keyword(Keyword::FULL) {
10734                ReplicaIdentity::Full
10735            } else if self.parse_keyword(Keyword::DEFAULT) {
10736                ReplicaIdentity::Default
10737            } else if self.parse_keywords(&[Keyword::USING, Keyword::INDEX]) {
10738                ReplicaIdentity::Index(self.parse_identifier()?)
10739            } else {
10740                return self.expected_ref(
10741                    "NOTHING, FULL, DEFAULT, or USING INDEX index_name after REPLICA IDENTITY",
10742                    self.peek_token_ref(),
10743                );
10744            };
10745
10746            AlterTableOperation::ReplicaIdentity { identity }
10747        } else if self.parse_keywords(&[Keyword::VALIDATE, Keyword::CONSTRAINT]) {
10748            let name = self.parse_identifier()?;
10749            AlterTableOperation::ValidateConstraint { name }
10750        } else {
10751            let mut options =
10752                self.parse_options_with_keywords(&[Keyword::SET, Keyword::TBLPROPERTIES])?;
10753            if !options.is_empty() {
10754                AlterTableOperation::SetTblProperties {
10755                    table_properties: options,
10756                }
10757            } else {
10758                options = self.parse_options(Keyword::SET)?;
10759                if !options.is_empty() {
10760                    AlterTableOperation::SetOptionsParens { options }
10761                } else {
10762                    return self.expected_ref(
10763                    "ADD, RENAME, PARTITION, SWAP, DROP, REPLICA IDENTITY, SET, or SET TBLPROPERTIES after ALTER TABLE",
10764                    self.peek_token_ref(),
10765                  );
10766                }
10767            }
10768        };
10769        Ok(operation)
10770    }
10771
10772    fn parse_set_data_type(&mut self, had_set: bool) -> Result<AlterColumnOperation, ParserError> {
10773        let data_type = self.parse_data_type()?;
10774        let using = if self.dialect.supports_alter_column_type_using()
10775            && self.parse_keyword(Keyword::USING)
10776        {
10777            Some(self.parse_expr()?)
10778        } else {
10779            None
10780        };
10781        Ok(AlterColumnOperation::SetDataType {
10782            data_type,
10783            using,
10784            had_set,
10785        })
10786    }
10787
10788    fn parse_part_or_partition(&mut self) -> Result<Partition, ParserError> {
10789        let keyword = self.expect_one_of_keywords(&[Keyword::PART, Keyword::PARTITION])?;
10790        match keyword {
10791            Keyword::PART => Ok(Partition::Part(self.parse_expr()?)),
10792            Keyword::PARTITION => Ok(Partition::Expr(self.parse_expr()?)),
10793            // unreachable because expect_one_of_keywords used above
10794            unexpected_keyword => Err(ParserError::ParserError(
10795                format!("Internal parser error: expected any of {{PART, PARTITION}}, got {unexpected_keyword:?}"),
10796            )),
10797        }
10798    }
10799
10800    /// Parse an `ALTER <object>` statement and dispatch to the appropriate alter handler.
10801    pub fn parse_alter(&mut self) -> Result<Statement, ParserError> {
10802        let object_type = self.expect_one_of_keywords(&[
10803            Keyword::VIEW,
10804            Keyword::TYPE,
10805            Keyword::COLLATION,
10806            Keyword::TABLE,
10807            Keyword::INDEX,
10808            Keyword::FUNCTION,
10809            Keyword::AGGREGATE,
10810            Keyword::ROLE,
10811            Keyword::POLICY,
10812            Keyword::CONNECTOR,
10813            Keyword::ICEBERG,
10814            Keyword::SCHEMA,
10815            Keyword::USER,
10816            Keyword::OPERATOR,
10817        ])?;
10818        match object_type {
10819            Keyword::SCHEMA => {
10820                self.prev_token();
10821                self.prev_token();
10822                self.parse_alter_schema()
10823            }
10824            Keyword::VIEW => self.parse_alter_view(),
10825            Keyword::TYPE => self.parse_alter_type(),
10826            Keyword::COLLATION => self.parse_alter_collation().map(Into::into),
10827            Keyword::TABLE => self.parse_alter_table(false),
10828            Keyword::ICEBERG => {
10829                self.expect_keyword(Keyword::TABLE)?;
10830                self.parse_alter_table(true)
10831            }
10832            Keyword::INDEX => {
10833                let index_name = self.parse_object_name(false)?;
10834                let operation = if self.parse_keyword(Keyword::RENAME) {
10835                    if self.parse_keyword(Keyword::TO) {
10836                        let index_name = self.parse_object_name(false)?;
10837                        AlterIndexOperation::RenameIndex { index_name }
10838                    } else {
10839                        return self.expected_ref("TO after RENAME", self.peek_token_ref());
10840                    }
10841                } else {
10842                    return self.expected_ref("RENAME after ALTER INDEX", self.peek_token_ref());
10843                };
10844
10845                Ok(Statement::AlterIndex {
10846                    name: index_name,
10847                    operation,
10848                })
10849            }
10850            Keyword::FUNCTION => self.parse_alter_function(AlterFunctionKind::Function),
10851            Keyword::AGGREGATE => self.parse_alter_function(AlterFunctionKind::Aggregate),
10852            Keyword::OPERATOR => {
10853                if self.parse_keyword(Keyword::FAMILY) {
10854                    self.parse_alter_operator_family().map(Into::into)
10855                } else if self.parse_keyword(Keyword::CLASS) {
10856                    self.parse_alter_operator_class().map(Into::into)
10857                } else {
10858                    self.parse_alter_operator().map(Into::into)
10859                }
10860            }
10861            Keyword::ROLE => self.parse_alter_role(),
10862            Keyword::POLICY => self.parse_alter_policy().map(Into::into),
10863            Keyword::CONNECTOR => self.parse_alter_connector(),
10864            Keyword::USER => self.parse_alter_user().map(Into::into),
10865            // unreachable because expect_one_of_keywords used above
10866            unexpected_keyword => Err(ParserError::ParserError(
10867                format!("Internal parser error: expected any of {{VIEW, TYPE, COLLATION, TABLE, INDEX, FUNCTION, AGGREGATE, ROLE, POLICY, CONNECTOR, ICEBERG, SCHEMA, USER, OPERATOR}}, got {unexpected_keyword:?}"),
10868            )),
10869        }
10870    }
10871
10872    fn parse_alter_aggregate_signature(
10873        &mut self,
10874    ) -> Result<(FunctionDesc, bool, Option<Vec<OperateFunctionArg>>), ParserError> {
10875        let name = self.parse_object_name(false)?;
10876        self.expect_token(&Token::LParen)?;
10877
10878        if self.consume_token(&Token::Mul) {
10879            self.expect_token(&Token::RParen)?;
10880            return Ok((
10881                FunctionDesc {
10882                    name,
10883                    args: Some(vec![]),
10884                },
10885                true,
10886                None,
10887            ));
10888        }
10889
10890        let args =
10891            if self.peek_keyword(Keyword::ORDER) || self.peek_token_ref().token == Token::RParen {
10892                vec![]
10893            } else {
10894                self.parse_comma_separated(Parser::parse_aggregate_function_arg)?
10895            };
10896
10897        let aggregate_order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
10898            Some(self.parse_comma_separated(Parser::parse_aggregate_function_arg)?)
10899        } else {
10900            None
10901        };
10902
10903        self.expect_token(&Token::RParen)?;
10904        Ok((
10905            FunctionDesc {
10906                name,
10907                args: Some(args),
10908            },
10909            false,
10910            aggregate_order_by,
10911        ))
10912    }
10913
10914    fn parse_alter_function_action(&mut self) -> Result<Option<AlterFunctionAction>, ParserError> {
10915        let action = if self.parse_keywords(&[
10916            Keyword::CALLED,
10917            Keyword::ON,
10918            Keyword::NULL,
10919            Keyword::INPUT,
10920        ]) {
10921            Some(AlterFunctionAction::CalledOnNull(
10922                FunctionCalledOnNull::CalledOnNullInput,
10923            ))
10924        } else if self.parse_keywords(&[
10925            Keyword::RETURNS,
10926            Keyword::NULL,
10927            Keyword::ON,
10928            Keyword::NULL,
10929            Keyword::INPUT,
10930        ]) {
10931            Some(AlterFunctionAction::CalledOnNull(
10932                FunctionCalledOnNull::ReturnsNullOnNullInput,
10933            ))
10934        } else if self.parse_keyword(Keyword::STRICT) {
10935            Some(AlterFunctionAction::CalledOnNull(
10936                FunctionCalledOnNull::Strict,
10937            ))
10938        } else if self.parse_keyword(Keyword::IMMUTABLE) {
10939            Some(AlterFunctionAction::Behavior(FunctionBehavior::Immutable))
10940        } else if self.parse_keyword(Keyword::STABLE) {
10941            Some(AlterFunctionAction::Behavior(FunctionBehavior::Stable))
10942        } else if self.parse_keyword(Keyword::VOLATILE) {
10943            Some(AlterFunctionAction::Behavior(FunctionBehavior::Volatile))
10944        } else if self.parse_keyword(Keyword::NOT) {
10945            self.expect_keyword(Keyword::LEAKPROOF)?;
10946            Some(AlterFunctionAction::Leakproof(false))
10947        } else if self.parse_keyword(Keyword::LEAKPROOF) {
10948            Some(AlterFunctionAction::Leakproof(true))
10949        } else if self.parse_keyword(Keyword::EXTERNAL) {
10950            self.expect_keyword(Keyword::SECURITY)?;
10951            let security = if self.parse_keyword(Keyword::DEFINER) {
10952                FunctionSecurity::Definer
10953            } else if self.parse_keyword(Keyword::INVOKER) {
10954                FunctionSecurity::Invoker
10955            } else {
10956                return self.expected_ref("DEFINER or INVOKER", self.peek_token_ref());
10957            };
10958            Some(AlterFunctionAction::Security {
10959                external: true,
10960                security,
10961            })
10962        } else if self.parse_keyword(Keyword::SECURITY) {
10963            let security = if self.parse_keyword(Keyword::DEFINER) {
10964                FunctionSecurity::Definer
10965            } else if self.parse_keyword(Keyword::INVOKER) {
10966                FunctionSecurity::Invoker
10967            } else {
10968                return self.expected_ref("DEFINER or INVOKER", self.peek_token_ref());
10969            };
10970            Some(AlterFunctionAction::Security {
10971                external: false,
10972                security,
10973            })
10974        } else if self.parse_keyword(Keyword::PARALLEL) {
10975            let parallel = if self.parse_keyword(Keyword::UNSAFE) {
10976                FunctionParallel::Unsafe
10977            } else if self.parse_keyword(Keyword::RESTRICTED) {
10978                FunctionParallel::Restricted
10979            } else if self.parse_keyword(Keyword::SAFE) {
10980                FunctionParallel::Safe
10981            } else {
10982                return self
10983                    .expected_ref("one of UNSAFE | RESTRICTED | SAFE", self.peek_token_ref());
10984            };
10985            Some(AlterFunctionAction::Parallel(parallel))
10986        } else if self.parse_keyword(Keyword::COST) {
10987            Some(AlterFunctionAction::Cost(self.parse_number()?))
10988        } else if self.parse_keyword(Keyword::ROWS) {
10989            Some(AlterFunctionAction::Rows(self.parse_number()?))
10990        } else if self.parse_keyword(Keyword::SUPPORT) {
10991            Some(AlterFunctionAction::Support(self.parse_object_name(false)?))
10992        } else if self.parse_keyword(Keyword::SET) {
10993            let name = self.parse_object_name(false)?;
10994            let value = if self.parse_keywords(&[Keyword::FROM, Keyword::CURRENT]) {
10995                FunctionSetValue::FromCurrent
10996            } else {
10997                if !self.consume_token(&Token::Eq) && !self.parse_keyword(Keyword::TO) {
10998                    return self.expected_ref("= or TO", self.peek_token_ref());
10999                }
11000                if self.parse_keyword(Keyword::DEFAULT) {
11001                    FunctionSetValue::Default
11002                } else {
11003                    FunctionSetValue::Values(self.parse_comma_separated(Parser::parse_expr)?)
11004                }
11005            };
11006            Some(AlterFunctionAction::Set(FunctionDefinitionSetParam {
11007                name,
11008                value,
11009            }))
11010        } else if self.parse_keyword(Keyword::RESET) {
11011            let reset_config = if self.parse_keyword(Keyword::ALL) {
11012                ResetConfig::ALL
11013            } else {
11014                ResetConfig::ConfigName(self.parse_object_name(false)?)
11015            };
11016            Some(AlterFunctionAction::Reset(reset_config))
11017        } else {
11018            None
11019        };
11020
11021        Ok(action)
11022    }
11023
11024    fn parse_alter_function_actions(
11025        &mut self,
11026    ) -> Result<(Vec<AlterFunctionAction>, bool), ParserError> {
11027        let mut actions = vec![];
11028        while let Some(action) = self.parse_alter_function_action()? {
11029            actions.push(action);
11030        }
11031        if actions.is_empty() {
11032            return self.expected_ref("at least one ALTER FUNCTION action", self.peek_token_ref());
11033        }
11034        let restrict = self.parse_keyword(Keyword::RESTRICT);
11035        Ok((actions, restrict))
11036    }
11037
11038    /// Parse an `ALTER FUNCTION` or `ALTER AGGREGATE` statement.
11039    pub fn parse_alter_function(
11040        &mut self,
11041        kind: AlterFunctionKind,
11042    ) -> Result<Statement, ParserError> {
11043        let (function, aggregate_star, aggregate_order_by) = match kind {
11044            AlterFunctionKind::Function => (self.parse_function_desc()?, false, None),
11045            AlterFunctionKind::Aggregate => self.parse_alter_aggregate_signature()?,
11046        };
11047
11048        let operation = if self.parse_keywords(&[Keyword::RENAME, Keyword::TO]) {
11049            let new_name = self.parse_identifier()?;
11050            AlterFunctionOperation::RenameTo { new_name }
11051        } else if self.parse_keywords(&[Keyword::OWNER, Keyword::TO]) {
11052            AlterFunctionOperation::OwnerTo(self.parse_owner()?)
11053        } else if self.parse_keywords(&[Keyword::SET, Keyword::SCHEMA]) {
11054            AlterFunctionOperation::SetSchema {
11055                schema_name: self.parse_object_name(false)?,
11056            }
11057        } else if matches!(kind, AlterFunctionKind::Function) && self.parse_keyword(Keyword::NO) {
11058            if !self.parse_keyword(Keyword::DEPENDS) {
11059                return self.expected_ref("DEPENDS after NO", self.peek_token_ref());
11060            }
11061            self.expect_keywords(&[Keyword::ON, Keyword::EXTENSION])?;
11062            AlterFunctionOperation::DependsOnExtension {
11063                no: true,
11064                extension_name: self.parse_object_name(false)?,
11065            }
11066        } else if matches!(kind, AlterFunctionKind::Function)
11067            && self.parse_keyword(Keyword::DEPENDS)
11068        {
11069            self.expect_keywords(&[Keyword::ON, Keyword::EXTENSION])?;
11070            AlterFunctionOperation::DependsOnExtension {
11071                no: false,
11072                extension_name: self.parse_object_name(false)?,
11073            }
11074        } else if matches!(kind, AlterFunctionKind::Function) {
11075            let (actions, restrict) = self.parse_alter_function_actions()?;
11076            AlterFunctionOperation::Actions { actions, restrict }
11077        } else {
11078            return self.expected_ref(
11079                "RENAME TO, OWNER TO, or SET SCHEMA after ALTER AGGREGATE",
11080                self.peek_token_ref(),
11081            );
11082        };
11083
11084        Ok(Statement::AlterFunction(AlterFunction {
11085            kind,
11086            function,
11087            aggregate_order_by,
11088            aggregate_star,
11089            operation,
11090        }))
11091    }
11092
11093    /// Parse a [Statement::AlterTable]
11094    pub fn parse_alter_table(&mut self, iceberg: bool) -> Result<Statement, ParserError> {
11095        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
11096        let only = self.parse_keyword(Keyword::ONLY); // [ ONLY ]
11097        let table_name = self.parse_object_name(false)?;
11098        let on_cluster = self.parse_optional_on_cluster()?;
11099        let operations = self.parse_comma_separated(Parser::parse_alter_table_operation)?;
11100
11101        let mut location = None;
11102        if self.parse_keyword(Keyword::LOCATION) {
11103            location = Some(HiveSetLocation {
11104                has_set: false,
11105                location: self.parse_identifier()?,
11106            });
11107        } else if self.parse_keywords(&[Keyword::SET, Keyword::LOCATION]) {
11108            location = Some(HiveSetLocation {
11109                has_set: true,
11110                location: self.parse_identifier()?,
11111            });
11112        }
11113
11114        let end_token = if self.peek_token_ref().token == Token::SemiColon {
11115            self.peek_token_ref().clone()
11116        } else {
11117            self.get_current_token().clone()
11118        };
11119
11120        Ok(AlterTable {
11121            name: table_name,
11122            if_exists,
11123            only,
11124            operations,
11125            location,
11126            on_cluster,
11127            table_type: if iceberg {
11128                Some(AlterTableType::Iceberg)
11129            } else {
11130                None
11131            },
11132            end_token: AttachedToken(end_token),
11133        }
11134        .into())
11135    }
11136
11137    /// Parse an `ALTER VIEW` statement.
11138    pub fn parse_alter_view(&mut self) -> Result<Statement, ParserError> {
11139        let name = self.parse_object_name(false)?;
11140        let columns = self.parse_parenthesized_column_list(Optional, false)?;
11141
11142        let with_options = self.parse_options(Keyword::WITH)?;
11143
11144        self.expect_keyword_is(Keyword::AS)?;
11145        let query = self.parse_query()?;
11146
11147        Ok(Statement::AlterView {
11148            name,
11149            columns,
11150            query,
11151            with_options,
11152        })
11153    }
11154
11155    /// Parse a [Statement::AlterType]
11156    pub fn parse_alter_type(&mut self) -> Result<Statement, ParserError> {
11157        let name = self.parse_object_name(false)?;
11158
11159        if self.parse_keywords(&[Keyword::RENAME, Keyword::TO]) {
11160            let new_name = self.parse_identifier()?;
11161            Ok(Statement::AlterType(AlterType {
11162                name,
11163                operation: AlterTypeOperation::Rename(AlterTypeRename { new_name }),
11164            }))
11165        } else if self.parse_keywords(&[Keyword::ADD, Keyword::VALUE]) {
11166            let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
11167            let new_enum_value = self.parse_identifier()?;
11168            let position = if self.parse_keyword(Keyword::BEFORE) {
11169                Some(AlterTypeAddValuePosition::Before(self.parse_identifier()?))
11170            } else if self.parse_keyword(Keyword::AFTER) {
11171                Some(AlterTypeAddValuePosition::After(self.parse_identifier()?))
11172            } else {
11173                None
11174            };
11175
11176            Ok(Statement::AlterType(AlterType {
11177                name,
11178                operation: AlterTypeOperation::AddValue(AlterTypeAddValue {
11179                    if_not_exists,
11180                    value: new_enum_value,
11181                    position,
11182                }),
11183            }))
11184        } else if self.parse_keywords(&[Keyword::RENAME, Keyword::VALUE]) {
11185            let existing_enum_value = self.parse_identifier()?;
11186            self.expect_keyword(Keyword::TO)?;
11187            let new_enum_value = self.parse_identifier()?;
11188
11189            Ok(Statement::AlterType(AlterType {
11190                name,
11191                operation: AlterTypeOperation::RenameValue(AlterTypeRenameValue {
11192                    from: existing_enum_value,
11193                    to: new_enum_value,
11194                }),
11195            }))
11196        } else {
11197            self.expected_ref(
11198                "{RENAME TO | { RENAME | ADD } VALUE}",
11199                self.peek_token_ref(),
11200            )
11201        }
11202    }
11203
11204    /// Parse a [Statement::AlterCollation].
11205    ///
11206    /// [PostgreSQL Documentation](https://www.postgresql.org/docs/current/sql-altercollation.html)
11207    pub fn parse_alter_collation(&mut self) -> Result<AlterCollation, ParserError> {
11208        let name = self.parse_object_name(false)?;
11209        let operation = if self.parse_keywords(&[Keyword::RENAME, Keyword::TO]) {
11210            AlterCollationOperation::RenameTo {
11211                new_name: self.parse_identifier()?,
11212            }
11213        } else if self.parse_keywords(&[Keyword::OWNER, Keyword::TO]) {
11214            AlterCollationOperation::OwnerTo(self.parse_owner()?)
11215        } else if self.parse_keywords(&[Keyword::SET, Keyword::SCHEMA]) {
11216            AlterCollationOperation::SetSchema {
11217                schema_name: self.parse_object_name(false)?,
11218            }
11219        } else if self.parse_keywords(&[Keyword::REFRESH, Keyword::VERSION]) {
11220            AlterCollationOperation::RefreshVersion
11221        } else {
11222            return self.expected_ref(
11223                "RENAME TO, OWNER TO, SET SCHEMA, or REFRESH VERSION after ALTER COLLATION",
11224                self.peek_token_ref(),
11225            );
11226        };
11227
11228        Ok(AlterCollation { name, operation })
11229    }
11230
11231    /// Parse a [Statement::AlterOperator]
11232    ///
11233    /// [PostgreSQL Documentation](https://www.postgresql.org/docs/current/sql-alteroperator.html)
11234    pub fn parse_alter_operator(&mut self) -> Result<AlterOperator, ParserError> {
11235        let name = self.parse_operator_name()?;
11236
11237        // Parse (left_type, right_type)
11238        self.expect_token(&Token::LParen)?;
11239
11240        let left_type = if self.parse_keyword(Keyword::NONE) {
11241            None
11242        } else {
11243            Some(self.parse_data_type()?)
11244        };
11245
11246        self.expect_token(&Token::Comma)?;
11247        let right_type = self.parse_data_type()?;
11248        self.expect_token(&Token::RParen)?;
11249
11250        // Parse the operation
11251        let operation = if self.parse_keywords(&[Keyword::OWNER, Keyword::TO]) {
11252            let owner = if self.parse_keyword(Keyword::CURRENT_ROLE) {
11253                Owner::CurrentRole
11254            } else if self.parse_keyword(Keyword::CURRENT_USER) {
11255                Owner::CurrentUser
11256            } else if self.parse_keyword(Keyword::SESSION_USER) {
11257                Owner::SessionUser
11258            } else {
11259                Owner::Ident(self.parse_identifier()?)
11260            };
11261            AlterOperatorOperation::OwnerTo(owner)
11262        } else if self.parse_keywords(&[Keyword::SET, Keyword::SCHEMA]) {
11263            let schema_name = self.parse_object_name(false)?;
11264            AlterOperatorOperation::SetSchema { schema_name }
11265        } else if self.parse_keyword(Keyword::SET) {
11266            self.expect_token(&Token::LParen)?;
11267
11268            let mut options = Vec::new();
11269            loop {
11270                let keyword = self.expect_one_of_keywords(&[
11271                    Keyword::RESTRICT,
11272                    Keyword::JOIN,
11273                    Keyword::COMMUTATOR,
11274                    Keyword::NEGATOR,
11275                    Keyword::HASHES,
11276                    Keyword::MERGES,
11277                ])?;
11278
11279                match keyword {
11280                    Keyword::RESTRICT => {
11281                        self.expect_token(&Token::Eq)?;
11282                        let proc_name = if self.parse_keyword(Keyword::NONE) {
11283                            None
11284                        } else {
11285                            Some(self.parse_object_name(false)?)
11286                        };
11287                        options.push(OperatorOption::Restrict(proc_name));
11288                    }
11289                    Keyword::JOIN => {
11290                        self.expect_token(&Token::Eq)?;
11291                        let proc_name = if self.parse_keyword(Keyword::NONE) {
11292                            None
11293                        } else {
11294                            Some(self.parse_object_name(false)?)
11295                        };
11296                        options.push(OperatorOption::Join(proc_name));
11297                    }
11298                    Keyword::COMMUTATOR => {
11299                        self.expect_token(&Token::Eq)?;
11300                        let op_name = self.parse_operator_name()?;
11301                        options.push(OperatorOption::Commutator(op_name));
11302                    }
11303                    Keyword::NEGATOR => {
11304                        self.expect_token(&Token::Eq)?;
11305                        let op_name = self.parse_operator_name()?;
11306                        options.push(OperatorOption::Negator(op_name));
11307                    }
11308                    Keyword::HASHES => {
11309                        options.push(OperatorOption::Hashes);
11310                    }
11311                    Keyword::MERGES => {
11312                        options.push(OperatorOption::Merges);
11313                    }
11314                    unexpected_keyword => return Err(ParserError::ParserError(
11315                        format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in operator option"),
11316                    )),
11317                }
11318
11319                if !self.consume_token(&Token::Comma) {
11320                    break;
11321                }
11322            }
11323
11324            self.expect_token(&Token::RParen)?;
11325            AlterOperatorOperation::Set { options }
11326        } else {
11327            return self.expected_ref(
11328                "OWNER TO, SET SCHEMA, or SET after ALTER OPERATOR",
11329                self.peek_token_ref(),
11330            );
11331        };
11332
11333        Ok(AlterOperator {
11334            name,
11335            left_type,
11336            right_type,
11337            operation,
11338        })
11339    }
11340
11341    /// Parse an operator item for ALTER OPERATOR FAMILY ADD operations
11342    fn parse_operator_family_add_operator(&mut self) -> Result<OperatorFamilyItem, ParserError> {
11343        let strategy_number = self.parse_literal_uint()?;
11344        let operator_name = self.parse_operator_name()?;
11345
11346        // Operator argument types (required for ALTER OPERATOR FAMILY)
11347        self.expect_token(&Token::LParen)?;
11348        let op_types = self.parse_comma_separated(Parser::parse_data_type)?;
11349        self.expect_token(&Token::RParen)?;
11350
11351        // Optional purpose
11352        let purpose = if self.parse_keyword(Keyword::FOR) {
11353            if self.parse_keyword(Keyword::SEARCH) {
11354                Some(OperatorPurpose::ForSearch)
11355            } else if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
11356                let sort_family = self.parse_object_name(false)?;
11357                Some(OperatorPurpose::ForOrderBy { sort_family })
11358            } else {
11359                return self.expected_ref("SEARCH or ORDER BY after FOR", self.peek_token_ref());
11360            }
11361        } else {
11362            None
11363        };
11364
11365        Ok(OperatorFamilyItem::Operator {
11366            strategy_number,
11367            operator_name,
11368            op_types,
11369            purpose,
11370        })
11371    }
11372
11373    /// Parse a function item for ALTER OPERATOR FAMILY ADD operations
11374    fn parse_operator_family_add_function(&mut self) -> Result<OperatorFamilyItem, ParserError> {
11375        let support_number = self.parse_literal_uint()?;
11376
11377        // Optional operator types
11378        let op_types =
11379            if self.consume_token(&Token::LParen) && self.peek_token_ref().token != Token::RParen {
11380                let types = self.parse_comma_separated(Parser::parse_data_type)?;
11381                self.expect_token(&Token::RParen)?;
11382                Some(types)
11383            } else if self.consume_token(&Token::LParen) {
11384                self.expect_token(&Token::RParen)?;
11385                Some(vec![])
11386            } else {
11387                None
11388            };
11389
11390        let function_name = self.parse_object_name(false)?;
11391
11392        // Function argument types
11393        let argument_types = if self.consume_token(&Token::LParen) {
11394            if self.peek_token_ref().token == Token::RParen {
11395                self.expect_token(&Token::RParen)?;
11396                vec![]
11397            } else {
11398                let types = self.parse_comma_separated(Parser::parse_data_type)?;
11399                self.expect_token(&Token::RParen)?;
11400                types
11401            }
11402        } else {
11403            vec![]
11404        };
11405
11406        Ok(OperatorFamilyItem::Function {
11407            support_number,
11408            op_types,
11409            function_name,
11410            argument_types,
11411        })
11412    }
11413
11414    /// Parse an operator item for ALTER OPERATOR FAMILY DROP operations
11415    fn parse_operator_family_drop_operator(
11416        &mut self,
11417    ) -> Result<OperatorFamilyDropItem, ParserError> {
11418        let strategy_number = self.parse_literal_uint()?;
11419
11420        // Operator argument types (required for DROP)
11421        self.expect_token(&Token::LParen)?;
11422        let op_types = self.parse_comma_separated(Parser::parse_data_type)?;
11423        self.expect_token(&Token::RParen)?;
11424
11425        Ok(OperatorFamilyDropItem::Operator {
11426            strategy_number,
11427            op_types,
11428        })
11429    }
11430
11431    /// Parse a function item for ALTER OPERATOR FAMILY DROP operations
11432    fn parse_operator_family_drop_function(
11433        &mut self,
11434    ) -> Result<OperatorFamilyDropItem, ParserError> {
11435        let support_number = self.parse_literal_uint()?;
11436
11437        // Operator types (required for DROP)
11438        self.expect_token(&Token::LParen)?;
11439        let op_types = self.parse_comma_separated(Parser::parse_data_type)?;
11440        self.expect_token(&Token::RParen)?;
11441
11442        Ok(OperatorFamilyDropItem::Function {
11443            support_number,
11444            op_types,
11445        })
11446    }
11447
11448    /// Parse an operator family item for ADD operations (dispatches to operator or function parsing)
11449    fn parse_operator_family_add_item(&mut self) -> Result<OperatorFamilyItem, ParserError> {
11450        if self.parse_keyword(Keyword::OPERATOR) {
11451            self.parse_operator_family_add_operator()
11452        } else if self.parse_keyword(Keyword::FUNCTION) {
11453            self.parse_operator_family_add_function()
11454        } else {
11455            self.expected_ref("OPERATOR or FUNCTION", self.peek_token_ref())
11456        }
11457    }
11458
11459    /// Parse an operator family item for DROP operations (dispatches to operator or function parsing)
11460    fn parse_operator_family_drop_item(&mut self) -> Result<OperatorFamilyDropItem, ParserError> {
11461        if self.parse_keyword(Keyword::OPERATOR) {
11462            self.parse_operator_family_drop_operator()
11463        } else if self.parse_keyword(Keyword::FUNCTION) {
11464            self.parse_operator_family_drop_function()
11465        } else {
11466            self.expected_ref("OPERATOR or FUNCTION", self.peek_token_ref())
11467        }
11468    }
11469
11470    /// Parse a [Statement::AlterOperatorFamily]
11471    /// See <https://www.postgresql.org/docs/current/sql-alteropfamily.html>
11472    pub fn parse_alter_operator_family(&mut self) -> Result<AlterOperatorFamily, ParserError> {
11473        let name = self.parse_object_name(false)?;
11474        self.expect_keyword(Keyword::USING)?;
11475        let using = self.parse_identifier()?;
11476
11477        let operation = if self.parse_keyword(Keyword::ADD) {
11478            let items = self.parse_comma_separated(Parser::parse_operator_family_add_item)?;
11479            AlterOperatorFamilyOperation::Add { items }
11480        } else if self.parse_keyword(Keyword::DROP) {
11481            let items = self.parse_comma_separated(Parser::parse_operator_family_drop_item)?;
11482            AlterOperatorFamilyOperation::Drop { items }
11483        } else if self.parse_keywords(&[Keyword::RENAME, Keyword::TO]) {
11484            let new_name = self.parse_object_name(false)?;
11485            AlterOperatorFamilyOperation::RenameTo { new_name }
11486        } else if self.parse_keywords(&[Keyword::OWNER, Keyword::TO]) {
11487            let owner = self.parse_owner()?;
11488            AlterOperatorFamilyOperation::OwnerTo(owner)
11489        } else if self.parse_keywords(&[Keyword::SET, Keyword::SCHEMA]) {
11490            let schema_name = self.parse_object_name(false)?;
11491            AlterOperatorFamilyOperation::SetSchema { schema_name }
11492        } else {
11493            return self.expected_ref(
11494                "ADD, DROP, RENAME TO, OWNER TO, or SET SCHEMA after ALTER OPERATOR FAMILY",
11495                self.peek_token_ref(),
11496            );
11497        };
11498
11499        Ok(AlterOperatorFamily {
11500            name,
11501            using,
11502            operation,
11503        })
11504    }
11505
11506    /// Parse an `ALTER OPERATOR CLASS` statement.
11507    ///
11508    /// Handles operations like `RENAME TO`, `OWNER TO`, and `SET SCHEMA`.
11509    pub fn parse_alter_operator_class(&mut self) -> Result<AlterOperatorClass, ParserError> {
11510        let name = self.parse_object_name(false)?;
11511        self.expect_keyword(Keyword::USING)?;
11512        let using = self.parse_identifier()?;
11513
11514        let operation = if self.parse_keywords(&[Keyword::RENAME, Keyword::TO]) {
11515            let new_name = self.parse_object_name(false)?;
11516            AlterOperatorClassOperation::RenameTo { new_name }
11517        } else if self.parse_keywords(&[Keyword::OWNER, Keyword::TO]) {
11518            let owner = self.parse_owner()?;
11519            AlterOperatorClassOperation::OwnerTo(owner)
11520        } else if self.parse_keywords(&[Keyword::SET, Keyword::SCHEMA]) {
11521            let schema_name = self.parse_object_name(false)?;
11522            AlterOperatorClassOperation::SetSchema { schema_name }
11523        } else {
11524            return self.expected_ref(
11525                "RENAME TO, OWNER TO, or SET SCHEMA after ALTER OPERATOR CLASS",
11526                self.peek_token_ref(),
11527            );
11528        };
11529
11530        Ok(AlterOperatorClass {
11531            name,
11532            using,
11533            operation,
11534        })
11535    }
11536
11537    /// Parse an `ALTER SCHEMA` statement.
11538    ///
11539    /// Supports operations such as setting options, renaming, adding/dropping replicas, and changing owner.
11540    pub fn parse_alter_schema(&mut self) -> Result<Statement, ParserError> {
11541        self.expect_keywords(&[Keyword::ALTER, Keyword::SCHEMA])?;
11542        let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
11543        let name = self.parse_object_name(false)?;
11544        let operation = if self.parse_keywords(&[Keyword::SET, Keyword::OPTIONS]) {
11545            self.prev_token();
11546            let options = self.parse_options(Keyword::OPTIONS)?;
11547            AlterSchemaOperation::SetOptionsParens { options }
11548        } else if self.parse_keywords(&[Keyword::SET, Keyword::DEFAULT, Keyword::COLLATE]) {
11549            let collate = self.parse_expr()?;
11550            AlterSchemaOperation::SetDefaultCollate { collate }
11551        } else if self.parse_keywords(&[Keyword::ADD, Keyword::REPLICA]) {
11552            let replica = self.parse_identifier()?;
11553            let options = if self.peek_keyword(Keyword::OPTIONS) {
11554                Some(self.parse_options(Keyword::OPTIONS)?)
11555            } else {
11556                None
11557            };
11558            AlterSchemaOperation::AddReplica { replica, options }
11559        } else if self.parse_keywords(&[Keyword::DROP, Keyword::REPLICA]) {
11560            let replica = self.parse_identifier()?;
11561            AlterSchemaOperation::DropReplica { replica }
11562        } else if self.parse_keywords(&[Keyword::RENAME, Keyword::TO]) {
11563            let new_name = self.parse_object_name(false)?;
11564            AlterSchemaOperation::Rename { name: new_name }
11565        } else if self.parse_keywords(&[Keyword::OWNER, Keyword::TO]) {
11566            let owner = self.parse_owner()?;
11567            AlterSchemaOperation::OwnerTo { owner }
11568        } else {
11569            return self.expected_ref("ALTER SCHEMA operation", self.peek_token_ref());
11570        };
11571        Ok(Statement::AlterSchema(AlterSchema {
11572            name,
11573            if_exists,
11574            operations: vec![operation],
11575        }))
11576    }
11577
11578    /// Parse a `CALL procedure_name(arg1, arg2, ...)`
11579    /// or `CALL procedure_name` statement
11580    pub fn parse_call(&mut self) -> Result<Statement, ParserError> {
11581        let object_name = self.parse_object_name(false)?;
11582        if self.peek_token_ref().token == Token::LParen {
11583            match self.parse_function(object_name)? {
11584                Expr::Function(f) => Ok(Statement::Call(f)),
11585                other => parser_err!(
11586                    format!("Expected a simple procedure call but found: {other}"),
11587                    self.peek_token_ref().span.start
11588                ),
11589            }
11590        } else {
11591            Ok(Statement::Call(Function {
11592                name: object_name,
11593                uses_odbc_syntax: false,
11594                parameters: FunctionArguments::None,
11595                args: FunctionArguments::None,
11596                over: None,
11597                filter: None,
11598                null_treatment: None,
11599                within_group: vec![],
11600            }))
11601        }
11602    }
11603
11604    /// Parse a copy statement
11605    pub fn parse_copy(&mut self) -> Result<Statement, ParserError> {
11606        let source;
11607        if self.consume_token(&Token::LParen) {
11608            source = CopySource::Query(self.parse_query()?);
11609            self.expect_token(&Token::RParen)?;
11610        } else {
11611            let table_name = self.parse_object_name(false)?;
11612            let columns = self.parse_parenthesized_column_list(Optional, false)?;
11613            source = CopySource::Table {
11614                table_name,
11615                columns,
11616            };
11617        }
11618        let to = match self.parse_one_of_keywords(&[Keyword::FROM, Keyword::TO]) {
11619            Some(Keyword::FROM) => false,
11620            Some(Keyword::TO) => true,
11621            _ => self.expected_ref("FROM or TO", self.peek_token_ref())?,
11622        };
11623        if !to {
11624            // Use a separate if statement to prevent Rust compiler from complaining about
11625            // "if statement in this position is unstable: https://github.com/rust-lang/rust/issues/53667"
11626            if let CopySource::Query(_) = source {
11627                return Err(ParserError::ParserError(
11628                    "COPY ... FROM does not support query as a source".to_string(),
11629                ));
11630            }
11631        }
11632        let target = if self.parse_keyword(Keyword::STDIN) {
11633            CopyTarget::Stdin
11634        } else if self.parse_keyword(Keyword::STDOUT) {
11635            CopyTarget::Stdout
11636        } else if self.parse_keyword(Keyword::PROGRAM) {
11637            CopyTarget::Program {
11638                command: self.parse_literal_string()?,
11639            }
11640        } else {
11641            CopyTarget::File {
11642                filename: self.parse_literal_string()?,
11643            }
11644        };
11645        let _ = self.parse_keyword(Keyword::WITH); // [ WITH ]
11646        let mut options = vec![];
11647        if self.consume_token(&Token::LParen) {
11648            options = self.parse_comma_separated(Parser::parse_copy_option)?;
11649            self.expect_token(&Token::RParen)?;
11650        }
11651        let mut legacy_options = vec![];
11652        while let Some(opt) = self.maybe_parse(|parser| parser.parse_copy_legacy_option())? {
11653            legacy_options.push(opt);
11654        }
11655        let values =
11656            if matches!(target, CopyTarget::Stdin) && self.peek_token_ref().token != Token::EOF {
11657                self.expect_token(&Token::SemiColon)?;
11658                self.parse_tsv()
11659            } else {
11660                vec![]
11661            };
11662        Ok(Statement::Copy {
11663            source,
11664            to,
11665            target,
11666            options,
11667            legacy_options,
11668            values,
11669        })
11670    }
11671
11672    /// Parse [Statement::Open]
11673    fn parse_open(&mut self) -> Result<Statement, ParserError> {
11674        self.expect_keyword(Keyword::OPEN)?;
11675        Ok(Statement::Open(OpenStatement {
11676            cursor_name: self.parse_identifier()?,
11677        }))
11678    }
11679
11680    /// Parse a `CLOSE` cursor statement.
11681    pub fn parse_close(&mut self) -> Result<Statement, ParserError> {
11682        let cursor = if self.parse_keyword(Keyword::ALL) {
11683            CloseCursor::All
11684        } else {
11685            let name = self.parse_identifier()?;
11686
11687            CloseCursor::Specific { name }
11688        };
11689
11690        Ok(Statement::Close { cursor })
11691    }
11692
11693    fn parse_copy_option(&mut self) -> Result<CopyOption, ParserError> {
11694        let ret = match self.parse_one_of_keywords(&[
11695            Keyword::FORMAT,
11696            Keyword::FREEZE,
11697            Keyword::DELIMITER,
11698            Keyword::NULL,
11699            Keyword::HEADER,
11700            Keyword::QUOTE,
11701            Keyword::ESCAPE,
11702            Keyword::FORCE_QUOTE,
11703            Keyword::FORCE_NOT_NULL,
11704            Keyword::FORCE_NULL,
11705            Keyword::ENCODING,
11706        ]) {
11707            Some(Keyword::FORMAT) => CopyOption::Format(self.parse_identifier()?),
11708            Some(Keyword::FREEZE) => CopyOption::Freeze(!matches!(
11709                self.parse_one_of_keywords(&[Keyword::TRUE, Keyword::FALSE]),
11710                Some(Keyword::FALSE)
11711            )),
11712            Some(Keyword::DELIMITER) => CopyOption::Delimiter(self.parse_literal_char()?),
11713            Some(Keyword::NULL) => CopyOption::Null(self.parse_literal_string()?),
11714            Some(Keyword::HEADER) => CopyOption::Header(!matches!(
11715                self.parse_one_of_keywords(&[Keyword::TRUE, Keyword::FALSE]),
11716                Some(Keyword::FALSE)
11717            )),
11718            Some(Keyword::QUOTE) => CopyOption::Quote(self.parse_literal_char()?),
11719            Some(Keyword::ESCAPE) => CopyOption::Escape(self.parse_literal_char()?),
11720            Some(Keyword::FORCE_QUOTE) => {
11721                CopyOption::ForceQuote(self.parse_parenthesized_column_list(Mandatory, false)?)
11722            }
11723            Some(Keyword::FORCE_NOT_NULL) => {
11724                CopyOption::ForceNotNull(self.parse_parenthesized_column_list(Mandatory, false)?)
11725            }
11726            Some(Keyword::FORCE_NULL) => {
11727                CopyOption::ForceNull(self.parse_parenthesized_column_list(Mandatory, false)?)
11728            }
11729            Some(Keyword::ENCODING) => CopyOption::Encoding(self.parse_literal_string()?),
11730            _ => self.expected_ref("option", self.peek_token_ref())?,
11731        };
11732        Ok(ret)
11733    }
11734
11735    fn parse_copy_legacy_option(&mut self) -> Result<CopyLegacyOption, ParserError> {
11736        // FORMAT \[ AS \] is optional
11737        if self.parse_keyword(Keyword::FORMAT) {
11738            let _ = self.parse_keyword(Keyword::AS);
11739        }
11740
11741        let ret = match self.parse_one_of_keywords(&[
11742            Keyword::ACCEPTANYDATE,
11743            Keyword::ACCEPTINVCHARS,
11744            Keyword::ADDQUOTES,
11745            Keyword::ALLOWOVERWRITE,
11746            Keyword::BINARY,
11747            Keyword::BLANKSASNULL,
11748            Keyword::BZIP2,
11749            Keyword::CLEANPATH,
11750            Keyword::COMPUPDATE,
11751            Keyword::CREDENTIALS,
11752            Keyword::CSV,
11753            Keyword::DATEFORMAT,
11754            Keyword::DELIMITER,
11755            Keyword::EMPTYASNULL,
11756            Keyword::ENCRYPTED,
11757            Keyword::ESCAPE,
11758            Keyword::EXTENSION,
11759            Keyword::FIXEDWIDTH,
11760            Keyword::GZIP,
11761            Keyword::HEADER,
11762            Keyword::IAM_ROLE,
11763            Keyword::IGNOREHEADER,
11764            Keyword::JSON,
11765            Keyword::MANIFEST,
11766            Keyword::MAXFILESIZE,
11767            Keyword::NULL,
11768            Keyword::PARALLEL,
11769            Keyword::PARQUET,
11770            Keyword::PARTITION,
11771            Keyword::REGION,
11772            Keyword::REMOVEQUOTES,
11773            Keyword::ROWGROUPSIZE,
11774            Keyword::STATUPDATE,
11775            Keyword::TIMEFORMAT,
11776            Keyword::TRUNCATECOLUMNS,
11777            Keyword::ZSTD,
11778        ]) {
11779            Some(Keyword::ACCEPTANYDATE) => CopyLegacyOption::AcceptAnyDate,
11780            Some(Keyword::ACCEPTINVCHARS) => {
11781                let _ = self.parse_keyword(Keyword::AS); // [ AS ]
11782                let ch = if matches!(self.peek_token_ref().token, Token::SingleQuotedString(_)) {
11783                    Some(self.parse_literal_string()?)
11784                } else {
11785                    None
11786                };
11787                CopyLegacyOption::AcceptInvChars(ch)
11788            }
11789            Some(Keyword::ADDQUOTES) => CopyLegacyOption::AddQuotes,
11790            Some(Keyword::ALLOWOVERWRITE) => CopyLegacyOption::AllowOverwrite,
11791            Some(Keyword::BINARY) => CopyLegacyOption::Binary,
11792            Some(Keyword::BLANKSASNULL) => CopyLegacyOption::BlankAsNull,
11793            Some(Keyword::BZIP2) => CopyLegacyOption::Bzip2,
11794            Some(Keyword::CLEANPATH) => CopyLegacyOption::CleanPath,
11795            Some(Keyword::COMPUPDATE) => {
11796                let preset = self.parse_keyword(Keyword::PRESET);
11797                let enabled = match self.parse_one_of_keywords(&[
11798                    Keyword::TRUE,
11799                    Keyword::FALSE,
11800                    Keyword::ON,
11801                    Keyword::OFF,
11802                ]) {
11803                    Some(Keyword::TRUE) | Some(Keyword::ON) => Some(true),
11804                    Some(Keyword::FALSE) | Some(Keyword::OFF) => Some(false),
11805                    _ => None,
11806                };
11807                CopyLegacyOption::CompUpdate { preset, enabled }
11808            }
11809            Some(Keyword::CREDENTIALS) => {
11810                CopyLegacyOption::Credentials(self.parse_literal_string()?)
11811            }
11812            Some(Keyword::CSV) => CopyLegacyOption::Csv({
11813                let mut opts = vec![];
11814                while let Some(opt) =
11815                    self.maybe_parse(|parser| parser.parse_copy_legacy_csv_option())?
11816                {
11817                    opts.push(opt);
11818                }
11819                opts
11820            }),
11821            Some(Keyword::DATEFORMAT) => {
11822                let _ = self.parse_keyword(Keyword::AS);
11823                let fmt = if matches!(self.peek_token_ref().token, Token::SingleQuotedString(_)) {
11824                    Some(self.parse_literal_string()?)
11825                } else {
11826                    None
11827                };
11828                CopyLegacyOption::DateFormat(fmt)
11829            }
11830            Some(Keyword::DELIMITER) => {
11831                let _ = self.parse_keyword(Keyword::AS);
11832                CopyLegacyOption::Delimiter(self.parse_literal_char()?)
11833            }
11834            Some(Keyword::EMPTYASNULL) => CopyLegacyOption::EmptyAsNull,
11835            Some(Keyword::ENCRYPTED) => {
11836                let auto = self.parse_keyword(Keyword::AUTO);
11837                CopyLegacyOption::Encrypted { auto }
11838            }
11839            Some(Keyword::ESCAPE) => CopyLegacyOption::Escape,
11840            Some(Keyword::EXTENSION) => {
11841                let ext = self.parse_literal_string()?;
11842                CopyLegacyOption::Extension(ext)
11843            }
11844            Some(Keyword::FIXEDWIDTH) => {
11845                let spec = self.parse_literal_string()?;
11846                CopyLegacyOption::FixedWidth(spec)
11847            }
11848            Some(Keyword::GZIP) => CopyLegacyOption::Gzip,
11849            Some(Keyword::HEADER) => CopyLegacyOption::Header,
11850            Some(Keyword::IAM_ROLE) => CopyLegacyOption::IamRole(self.parse_iam_role_kind()?),
11851            Some(Keyword::IGNOREHEADER) => {
11852                let _ = self.parse_keyword(Keyword::AS);
11853                let num_rows = self.parse_literal_uint()?;
11854                CopyLegacyOption::IgnoreHeader(num_rows)
11855            }
11856            Some(Keyword::JSON) => {
11857                let _ = self.parse_keyword(Keyword::AS);
11858                let fmt = if matches!(self.peek_token_ref().token, Token::SingleQuotedString(_)) {
11859                    Some(self.parse_literal_string()?)
11860                } else {
11861                    None
11862                };
11863                CopyLegacyOption::Json(fmt)
11864            }
11865            Some(Keyword::MANIFEST) => {
11866                let verbose = self.parse_keyword(Keyword::VERBOSE);
11867                CopyLegacyOption::Manifest { verbose }
11868            }
11869            Some(Keyword::MAXFILESIZE) => {
11870                let _ = self.parse_keyword(Keyword::AS);
11871                let size = self.parse_number_value()?;
11872                let unit = match self.parse_one_of_keywords(&[Keyword::MB, Keyword::GB]) {
11873                    Some(Keyword::MB) => Some(FileSizeUnit::MB),
11874                    Some(Keyword::GB) => Some(FileSizeUnit::GB),
11875                    _ => None,
11876                };
11877                CopyLegacyOption::MaxFileSize(FileSize { size, unit })
11878            }
11879            Some(Keyword::NULL) => {
11880                let _ = self.parse_keyword(Keyword::AS);
11881                CopyLegacyOption::Null(self.parse_literal_string()?)
11882            }
11883            Some(Keyword::PARALLEL) => {
11884                let enabled = match self.parse_one_of_keywords(&[
11885                    Keyword::TRUE,
11886                    Keyword::FALSE,
11887                    Keyword::ON,
11888                    Keyword::OFF,
11889                ]) {
11890                    Some(Keyword::TRUE) | Some(Keyword::ON) => Some(true),
11891                    Some(Keyword::FALSE) | Some(Keyword::OFF) => Some(false),
11892                    _ => None,
11893                };
11894                CopyLegacyOption::Parallel(enabled)
11895            }
11896            Some(Keyword::PARQUET) => CopyLegacyOption::Parquet,
11897            Some(Keyword::PARTITION) => {
11898                self.expect_keyword(Keyword::BY)?;
11899                let columns = self.parse_parenthesized_column_list(IsOptional::Mandatory, false)?;
11900                let include = self.parse_keyword(Keyword::INCLUDE);
11901                CopyLegacyOption::PartitionBy(UnloadPartitionBy { columns, include })
11902            }
11903            Some(Keyword::REGION) => {
11904                let _ = self.parse_keyword(Keyword::AS);
11905                let region = self.parse_literal_string()?;
11906                CopyLegacyOption::Region(region)
11907            }
11908            Some(Keyword::REMOVEQUOTES) => CopyLegacyOption::RemoveQuotes,
11909            Some(Keyword::ROWGROUPSIZE) => {
11910                let _ = self.parse_keyword(Keyword::AS);
11911                let file_size = self.parse_file_size()?;
11912                CopyLegacyOption::RowGroupSize(file_size)
11913            }
11914            Some(Keyword::STATUPDATE) => {
11915                let enabled = match self.parse_one_of_keywords(&[
11916                    Keyword::TRUE,
11917                    Keyword::FALSE,
11918                    Keyword::ON,
11919                    Keyword::OFF,
11920                ]) {
11921                    Some(Keyword::TRUE) | Some(Keyword::ON) => Some(true),
11922                    Some(Keyword::FALSE) | Some(Keyword::OFF) => Some(false),
11923                    _ => None,
11924                };
11925                CopyLegacyOption::StatUpdate(enabled)
11926            }
11927            Some(Keyword::TIMEFORMAT) => {
11928                let _ = self.parse_keyword(Keyword::AS);
11929                let fmt = if matches!(self.peek_token_ref().token, Token::SingleQuotedString(_)) {
11930                    Some(self.parse_literal_string()?)
11931                } else {
11932                    None
11933                };
11934                CopyLegacyOption::TimeFormat(fmt)
11935            }
11936            Some(Keyword::TRUNCATECOLUMNS) => CopyLegacyOption::TruncateColumns,
11937            Some(Keyword::ZSTD) => CopyLegacyOption::Zstd,
11938            _ => self.expected_ref("option", self.peek_token_ref())?,
11939        };
11940        Ok(ret)
11941    }
11942
11943    fn parse_file_size(&mut self) -> Result<FileSize, ParserError> {
11944        let size = self.parse_number_value()?;
11945        let unit = self.maybe_parse_file_size_unit();
11946        Ok(FileSize { size, unit })
11947    }
11948
11949    fn maybe_parse_file_size_unit(&mut self) -> Option<FileSizeUnit> {
11950        match self.parse_one_of_keywords(&[Keyword::MB, Keyword::GB]) {
11951            Some(Keyword::MB) => Some(FileSizeUnit::MB),
11952            Some(Keyword::GB) => Some(FileSizeUnit::GB),
11953            _ => None,
11954        }
11955    }
11956
11957    fn parse_iam_role_kind(&mut self) -> Result<IamRoleKind, ParserError> {
11958        if self.parse_keyword(Keyword::DEFAULT) {
11959            Ok(IamRoleKind::Default)
11960        } else {
11961            let arn = self.parse_literal_string()?;
11962            Ok(IamRoleKind::Arn(arn))
11963        }
11964    }
11965
11966    fn parse_copy_legacy_csv_option(&mut self) -> Result<CopyLegacyCsvOption, ParserError> {
11967        let ret = match self.parse_one_of_keywords(&[
11968            Keyword::HEADER,
11969            Keyword::QUOTE,
11970            Keyword::ESCAPE,
11971            Keyword::FORCE,
11972        ]) {
11973            Some(Keyword::HEADER) => CopyLegacyCsvOption::Header,
11974            Some(Keyword::QUOTE) => {
11975                let _ = self.parse_keyword(Keyword::AS); // [ AS ]
11976                CopyLegacyCsvOption::Quote(self.parse_literal_char()?)
11977            }
11978            Some(Keyword::ESCAPE) => {
11979                let _ = self.parse_keyword(Keyword::AS); // [ AS ]
11980                CopyLegacyCsvOption::Escape(self.parse_literal_char()?)
11981            }
11982            Some(Keyword::FORCE) if self.parse_keywords(&[Keyword::NOT, Keyword::NULL]) => {
11983                CopyLegacyCsvOption::ForceNotNull(
11984                    self.parse_comma_separated(|p| p.parse_identifier())?,
11985                )
11986            }
11987            Some(Keyword::FORCE) if self.parse_keywords(&[Keyword::QUOTE]) => {
11988                CopyLegacyCsvOption::ForceQuote(
11989                    self.parse_comma_separated(|p| p.parse_identifier())?,
11990                )
11991            }
11992            _ => self.expected_ref("csv option", self.peek_token_ref())?,
11993        };
11994        Ok(ret)
11995    }
11996
11997    fn parse_literal_char(&mut self) -> Result<char, ParserError> {
11998        let s = self.parse_literal_string()?;
11999        if s.len() != 1 {
12000            let loc = self
12001                .tokens
12002                .get(self.index - 1)
12003                .map_or(Location { line: 0, column: 0 }, |t| t.span.start);
12004            return parser_err!(format!("Expect a char, found {s:?}"), loc);
12005        }
12006        Ok(s.chars().next().unwrap())
12007    }
12008
12009    /// Parse a tab separated values in
12010    /// COPY payload
12011    pub fn parse_tsv(&mut self) -> Vec<Option<String>> {
12012        self.parse_tab_value()
12013    }
12014
12015    /// Parse a single tab-separated value row used by `COPY` payload parsing.
12016    pub fn parse_tab_value(&mut self) -> Vec<Option<String>> {
12017        let mut values = vec![];
12018        let mut content = String::new();
12019        while let Some(t) = self.next_token_no_skip().map(|t| &t.token) {
12020            match t {
12021                Token::Whitespace(Whitespace::Tab) => {
12022                    values.push(Some(core::mem::take(&mut content)));
12023                }
12024                Token::Whitespace(Whitespace::Newline) => {
12025                    values.push(Some(core::mem::take(&mut content)));
12026                }
12027                Token::Backslash => {
12028                    if self.consume_token(&Token::Period) {
12029                        return values;
12030                    }
12031                    if let Token::Word(w) = self.next_token().token {
12032                        if w.value == "N" {
12033                            values.push(None);
12034                        }
12035                    }
12036                }
12037                _ => {
12038                    content.push_str(&t.to_string());
12039                }
12040            }
12041        }
12042        values
12043    }
12044
12045    /// Parse a literal value (numbers, strings, date/time, booleans)
12046    pub fn parse_value(&mut self) -> Result<ValueWithSpan, ParserError> {
12047        let next_token = self.next_token();
12048        let span = next_token.span;
12049        let ok_value = |value: Value| Ok(value.with_span(span));
12050        match next_token.token {
12051            Token::Word(w) => match w.keyword {
12052                Keyword::TRUE if self.dialect.supports_boolean_literals() => {
12053                    ok_value(Value::Boolean(true))
12054                }
12055                Keyword::FALSE if self.dialect.supports_boolean_literals() => {
12056                    ok_value(Value::Boolean(false))
12057                }
12058                Keyword::NULL => ok_value(Value::Null),
12059                Keyword::NoKeyword if w.quote_style.is_some() => match w.quote_style {
12060                    Some('"') => ok_value(Value::DoubleQuotedString(w.value)),
12061                    Some('\'') => ok_value(Value::SingleQuotedString(w.value)),
12062                    _ => self.expected(
12063                        "A value?",
12064                        TokenWithSpan {
12065                            token: Token::Word(w),
12066                            span,
12067                        },
12068                    )?,
12069                },
12070                _ => self.expected(
12071                    "a concrete value",
12072                    TokenWithSpan {
12073                        token: Token::Word(w),
12074                        span,
12075                    },
12076                ),
12077            },
12078            // The call to n.parse() returns a bigdecimal when the
12079            // bigdecimal feature is enabled, and is otherwise a no-op
12080            // (i.e., it returns the input string).
12081            Token::Number(n, l) => ok_value(Value::Number(Self::parse(n, span.start)?, l)),
12082            Token::SingleQuotedString(ref s) => ok_value(Value::SingleQuotedString(
12083                self.maybe_concat_string_literal(s.to_string()),
12084            )),
12085            Token::DoubleQuotedString(ref s) => ok_value(Value::DoubleQuotedString(
12086                self.maybe_concat_string_literal(s.to_string()),
12087            )),
12088            Token::TripleSingleQuotedString(ref s) => {
12089                ok_value(Value::TripleSingleQuotedString(s.to_string()))
12090            }
12091            Token::TripleDoubleQuotedString(ref s) => {
12092                ok_value(Value::TripleDoubleQuotedString(s.to_string()))
12093            }
12094            Token::DollarQuotedString(ref s) => ok_value(Value::DollarQuotedString(s.clone())),
12095            Token::SingleQuotedByteStringLiteral(ref s) => {
12096                ok_value(Value::SingleQuotedByteStringLiteral(s.clone()))
12097            }
12098            Token::DoubleQuotedByteStringLiteral(ref s) => {
12099                ok_value(Value::DoubleQuotedByteStringLiteral(s.clone()))
12100            }
12101            Token::TripleSingleQuotedByteStringLiteral(ref s) => {
12102                ok_value(Value::TripleSingleQuotedByteStringLiteral(s.clone()))
12103            }
12104            Token::TripleDoubleQuotedByteStringLiteral(ref s) => {
12105                ok_value(Value::TripleDoubleQuotedByteStringLiteral(s.clone()))
12106            }
12107            Token::SingleQuotedRawStringLiteral(ref s) => {
12108                ok_value(Value::SingleQuotedRawStringLiteral(s.clone()))
12109            }
12110            Token::DoubleQuotedRawStringLiteral(ref s) => {
12111                ok_value(Value::DoubleQuotedRawStringLiteral(s.clone()))
12112            }
12113            Token::TripleSingleQuotedRawStringLiteral(ref s) => {
12114                ok_value(Value::TripleSingleQuotedRawStringLiteral(s.clone()))
12115            }
12116            Token::TripleDoubleQuotedRawStringLiteral(ref s) => {
12117                ok_value(Value::TripleDoubleQuotedRawStringLiteral(s.clone()))
12118            }
12119            Token::NationalStringLiteral(ref s) => {
12120                ok_value(Value::NationalStringLiteral(s.to_string()))
12121            }
12122            Token::QuoteDelimitedStringLiteral(v) => {
12123                ok_value(Value::QuoteDelimitedStringLiteral(v))
12124            }
12125            Token::NationalQuoteDelimitedStringLiteral(v) => {
12126                ok_value(Value::NationalQuoteDelimitedStringLiteral(v))
12127            }
12128            Token::EscapedStringLiteral(ref s) => {
12129                ok_value(Value::EscapedStringLiteral(s.to_string()))
12130            }
12131            Token::UnicodeStringLiteral(ref s) => {
12132                ok_value(Value::UnicodeStringLiteral(s.to_string()))
12133            }
12134            Token::HexStringLiteral(ref s) => ok_value(Value::HexStringLiteral(s.to_string())),
12135            Token::Placeholder(ref s) => ok_value(Value::Placeholder(s.to_string())),
12136            tok @ Token::Colon | tok @ Token::AtSign => {
12137                // 1. Not calling self.parse_identifier(false)?
12138                //    because only in placeholder we want to check
12139                //    numbers as idfentifies.  This because snowflake
12140                //    allows numbers as placeholders
12141                // 2. Not calling self.next_token() to enforce `tok`
12142                //    be followed immediately by a word/number, ie.
12143                //    without any whitespace in between
12144                let next_token = self.next_token_no_skip().unwrap_or(&EOF_TOKEN).clone();
12145                let ident = match next_token.token {
12146                    Token::Word(w) => Ok(w.into_ident(next_token.span)),
12147                    Token::Number(w, false) => Ok(Ident::with_span(next_token.span, w)),
12148                    _ => self.expected("placeholder", next_token),
12149                }?;
12150                Ok(Value::Placeholder(format!("{tok}{}", ident.value))
12151                    .with_span(Span::new(span.start, ident.span.end)))
12152            }
12153            unexpected => self.expected(
12154                "a value",
12155                TokenWithSpan {
12156                    token: unexpected,
12157                    span,
12158                },
12159            ),
12160        }
12161    }
12162
12163    fn maybe_concat_string_literal(&mut self, mut str: String) -> String {
12164        if self.dialect.supports_string_literal_concatenation() {
12165            while let Token::SingleQuotedString(ref s) | Token::DoubleQuotedString(ref s) =
12166                self.peek_token_ref().token
12167            {
12168                str.push_str(s);
12169                self.advance_token();
12170            }
12171        } else if self
12172            .dialect
12173            .supports_string_literal_concatenation_with_newline()
12174        {
12175            // We are iterating over tokens including whitespaces, to identify
12176            // string literals separated by newlines so we can concatenate them.
12177            let mut after_newline = false;
12178            loop {
12179                match self.peek_token_no_skip().token {
12180                    Token::Whitespace(Whitespace::Newline) => {
12181                        after_newline = true;
12182                        self.next_token_no_skip();
12183                    }
12184                    Token::Whitespace(_) => {
12185                        self.next_token_no_skip();
12186                    }
12187                    Token::SingleQuotedString(ref s) | Token::DoubleQuotedString(ref s)
12188                        if after_newline =>
12189                    {
12190                        str.push_str(s.clone().as_str());
12191                        self.next_token_no_skip();
12192                        after_newline = false;
12193                    }
12194                    _ => break,
12195                }
12196            }
12197        }
12198
12199        str
12200    }
12201
12202    /// Parse an unsigned numeric literal
12203    pub fn parse_number_value(&mut self) -> Result<ValueWithSpan, ParserError> {
12204        let value_wrapper = self.parse_value()?;
12205        match &value_wrapper.value {
12206            Value::Number(_, _) => Ok(value_wrapper),
12207            Value::Placeholder(_) => Ok(value_wrapper),
12208            _ => {
12209                self.prev_token();
12210                self.expected_ref("literal number", self.peek_token_ref())
12211            }
12212        }
12213    }
12214
12215    /// Parse a numeric literal as an expression. Returns a [`Expr::UnaryOp`] if the number is signed,
12216    /// otherwise returns a [`Expr::Value`]
12217    pub fn parse_number(&mut self) -> Result<Expr, ParserError> {
12218        let next_token = self.next_token();
12219        match next_token.token {
12220            Token::Plus => Ok(Expr::UnaryOp {
12221                op: UnaryOperator::Plus,
12222                expr: Box::new(Expr::Value(self.parse_number_value()?)),
12223            }),
12224            Token::Minus => Ok(Expr::UnaryOp {
12225                op: UnaryOperator::Minus,
12226                expr: Box::new(Expr::Value(self.parse_number_value()?)),
12227            }),
12228            _ => {
12229                self.prev_token();
12230                Ok(Expr::Value(self.parse_number_value()?))
12231            }
12232        }
12233    }
12234
12235    fn parse_introduced_string_expr(&mut self) -> Result<Expr, ParserError> {
12236        let next_token = self.next_token();
12237        let span = next_token.span;
12238        match next_token.token {
12239            Token::SingleQuotedString(ref s) => Ok(Expr::Value(
12240                Value::SingleQuotedString(s.to_string()).with_span(span),
12241            )),
12242            Token::DoubleQuotedString(ref s) => Ok(Expr::Value(
12243                Value::DoubleQuotedString(s.to_string()).with_span(span),
12244            )),
12245            Token::HexStringLiteral(ref s) => Ok(Expr::Value(
12246                Value::HexStringLiteral(s.to_string()).with_span(span),
12247            )),
12248            unexpected => self.expected(
12249                "a string value",
12250                TokenWithSpan {
12251                    token: unexpected,
12252                    span,
12253                },
12254            ),
12255        }
12256    }
12257
12258    /// Parse an unsigned literal integer/long
12259    pub fn parse_literal_uint(&mut self) -> Result<u64, ParserError> {
12260        let next_token = self.next_token();
12261        match next_token.token {
12262            Token::Number(s, _) => Self::parse::<u64>(s, next_token.span.start),
12263            _ => self.expected("literal int", next_token),
12264        }
12265    }
12266
12267    /// Parse the body of a `CREATE FUNCTION` specified as a string.
12268    /// e.g. `CREATE FUNCTION ... AS $$ body $$`.
12269    fn parse_create_function_body_string(&mut self) -> Result<CreateFunctionBody, ParserError> {
12270        let parse_string_expr = |parser: &mut Parser| -> Result<Expr, ParserError> {
12271            let peek_token = parser.peek_token();
12272            let span = peek_token.span;
12273            match peek_token.token {
12274                Token::DollarQuotedString(s) if dialect_of!(parser is PostgreSqlDialect | GenericDialect) =>
12275                {
12276                    parser.next_token();
12277                    Ok(Expr::Value(Value::DollarQuotedString(s).with_span(span)))
12278                }
12279                _ => Ok(Expr::Value(
12280                    Value::SingleQuotedString(parser.parse_literal_string()?).with_span(span),
12281                )),
12282            }
12283        };
12284
12285        Ok(CreateFunctionBody::AsBeforeOptions {
12286            body: parse_string_expr(self)?,
12287            link_symbol: if self.consume_token(&Token::Comma) {
12288                Some(parse_string_expr(self)?)
12289            } else {
12290                None
12291            },
12292        })
12293    }
12294
12295    /// Parse a literal string
12296    pub fn parse_literal_string(&mut self) -> Result<String, ParserError> {
12297        let next_token = self.next_token();
12298        match next_token.token {
12299            Token::Word(Word {
12300                value,
12301                keyword: Keyword::NoKeyword,
12302                ..
12303            }) => Ok(value),
12304            Token::SingleQuotedString(s) => Ok(s),
12305            Token::DoubleQuotedString(s) => Ok(s),
12306            Token::EscapedStringLiteral(s) if dialect_of!(self is PostgreSqlDialect | GenericDialect) => {
12307                Ok(s)
12308            }
12309            Token::UnicodeStringLiteral(s) => Ok(s),
12310            _ => self.expected("literal string", next_token),
12311        }
12312    }
12313
12314    /// Parse a boolean string
12315    pub(crate) fn parse_boolean_string(&mut self) -> Result<bool, ParserError> {
12316        match self.parse_one_of_keywords(&[Keyword::TRUE, Keyword::FALSE]) {
12317            Some(Keyword::TRUE) => Ok(true),
12318            Some(Keyword::FALSE) => Ok(false),
12319            _ => self.expected_ref("TRUE or FALSE", self.peek_token_ref()),
12320        }
12321    }
12322
12323    /// Parse a literal unicode normalization clause
12324    pub fn parse_unicode_is_normalized(&mut self, expr: Expr) -> Result<Expr, ParserError> {
12325        let neg = self.parse_keyword(Keyword::NOT);
12326        let normalized_form = self.maybe_parse(|parser| {
12327            match parser.parse_one_of_keywords(&[
12328                Keyword::NFC,
12329                Keyword::NFD,
12330                Keyword::NFKC,
12331                Keyword::NFKD,
12332            ]) {
12333                Some(Keyword::NFC) => Ok(NormalizationForm::NFC),
12334                Some(Keyword::NFD) => Ok(NormalizationForm::NFD),
12335                Some(Keyword::NFKC) => Ok(NormalizationForm::NFKC),
12336                Some(Keyword::NFKD) => Ok(NormalizationForm::NFKD),
12337                _ => parser.expected_ref("unicode normalization form", parser.peek_token_ref()),
12338            }
12339        })?;
12340        if self.parse_keyword(Keyword::NORMALIZED) {
12341            return Ok(Expr::IsNormalized {
12342                expr: Box::new(expr),
12343                form: normalized_form,
12344                negated: neg,
12345            });
12346        }
12347        self.expected_ref("unicode normalization form", self.peek_token_ref())
12348    }
12349
12350    /// Parse parenthesized enum members, used with `ENUM(...)` type definitions.
12351    pub fn parse_enum_values(&mut self) -> Result<Vec<EnumMember>, ParserError> {
12352        self.expect_token(&Token::LParen)?;
12353        let values = self.parse_comma_separated(|parser| {
12354            let name = parser.parse_literal_string()?;
12355            let e = if parser.consume_token(&Token::Eq) {
12356                let value = parser.parse_number()?;
12357                EnumMember::NamedValue(name, value)
12358            } else {
12359                EnumMember::Name(name)
12360            };
12361            Ok(e)
12362        })?;
12363        self.expect_token(&Token::RParen)?;
12364
12365        Ok(values)
12366    }
12367
12368    /// Parse a SQL datatype (in the context of a CREATE TABLE statement for example)
12369    pub fn parse_data_type(&mut self) -> Result<DataType, ParserError> {
12370        let (ty, trailing_bracket) = self.parse_data_type_helper()?;
12371        if trailing_bracket.0 {
12372            return parser_err!(
12373                format!("unmatched > after parsing data type {ty}"),
12374                self.peek_token_ref()
12375            );
12376        }
12377
12378        Ok(ty)
12379    }
12380
12381    fn parse_data_type_helper(
12382        &mut self,
12383    ) -> Result<(DataType, MatchedTrailingBracket), ParserError> {
12384        let dialect = self.dialect;
12385        self.advance_token();
12386        let next_token = self.get_current_token();
12387        let next_token_index = self.get_current_index();
12388
12389        let mut trailing_bracket: MatchedTrailingBracket = false.into();
12390        let mut data = match &next_token.token {
12391            Token::Word(w) => match w.keyword {
12392                Keyword::BOOLEAN => Ok(DataType::Boolean),
12393                Keyword::BOOL => Ok(DataType::Bool),
12394                Keyword::FLOAT => {
12395                    let precision = self.parse_exact_number_optional_precision_scale()?;
12396
12397                    if self.parse_keyword(Keyword::UNSIGNED) {
12398                        Ok(DataType::FloatUnsigned(precision))
12399                    } else {
12400                        Ok(DataType::Float(precision))
12401                    }
12402                }
12403                Keyword::REAL => {
12404                    if self.parse_keyword(Keyword::UNSIGNED) {
12405                        Ok(DataType::RealUnsigned)
12406                    } else {
12407                        Ok(DataType::Real)
12408                    }
12409                }
12410                Keyword::FLOAT4 => Ok(DataType::Float4),
12411                Keyword::FLOAT32 => Ok(DataType::Float32),
12412                Keyword::FLOAT64 => Ok(DataType::Float64),
12413                Keyword::FLOAT8 => Ok(DataType::Float8),
12414                Keyword::DOUBLE => {
12415                    if self.parse_keyword(Keyword::PRECISION) {
12416                        if self.parse_keyword(Keyword::UNSIGNED) {
12417                            Ok(DataType::DoublePrecisionUnsigned)
12418                        } else {
12419                            Ok(DataType::DoublePrecision)
12420                        }
12421                    } else {
12422                        let precision = self.parse_exact_number_optional_precision_scale()?;
12423
12424                        if self.parse_keyword(Keyword::UNSIGNED) {
12425                            Ok(DataType::DoubleUnsigned(precision))
12426                        } else {
12427                            Ok(DataType::Double(precision))
12428                        }
12429                    }
12430                }
12431                Keyword::TINYINT => {
12432                    let optional_precision = self.parse_optional_precision();
12433                    if self.parse_keyword(Keyword::UNSIGNED) {
12434                        Ok(DataType::TinyIntUnsigned(optional_precision?))
12435                    } else {
12436                        if dialect.supports_data_type_signed_suffix() {
12437                            let _ = self.parse_keyword(Keyword::SIGNED);
12438                        }
12439                        Ok(DataType::TinyInt(optional_precision?))
12440                    }
12441                }
12442                Keyword::INT2 => {
12443                    let optional_precision = self.parse_optional_precision();
12444                    if self.parse_keyword(Keyword::UNSIGNED) {
12445                        Ok(DataType::Int2Unsigned(optional_precision?))
12446                    } else {
12447                        Ok(DataType::Int2(optional_precision?))
12448                    }
12449                }
12450                Keyword::SMALLINT => {
12451                    let optional_precision = self.parse_optional_precision();
12452                    if self.parse_keyword(Keyword::UNSIGNED) {
12453                        Ok(DataType::SmallIntUnsigned(optional_precision?))
12454                    } else {
12455                        if dialect.supports_data_type_signed_suffix() {
12456                            let _ = self.parse_keyword(Keyword::SIGNED);
12457                        }
12458                        Ok(DataType::SmallInt(optional_precision?))
12459                    }
12460                }
12461                Keyword::MEDIUMINT => {
12462                    let optional_precision = self.parse_optional_precision();
12463                    if self.parse_keyword(Keyword::UNSIGNED) {
12464                        Ok(DataType::MediumIntUnsigned(optional_precision?))
12465                    } else {
12466                        if dialect.supports_data_type_signed_suffix() {
12467                            let _ = self.parse_keyword(Keyword::SIGNED);
12468                        }
12469                        Ok(DataType::MediumInt(optional_precision?))
12470                    }
12471                }
12472                Keyword::INT => {
12473                    let optional_precision = self.parse_optional_precision();
12474                    if self.parse_keyword(Keyword::UNSIGNED) {
12475                        Ok(DataType::IntUnsigned(optional_precision?))
12476                    } else {
12477                        if dialect.supports_data_type_signed_suffix() {
12478                            let _ = self.parse_keyword(Keyword::SIGNED);
12479                        }
12480                        Ok(DataType::Int(optional_precision?))
12481                    }
12482                }
12483                Keyword::INT4 => {
12484                    let optional_precision = self.parse_optional_precision();
12485                    if self.parse_keyword(Keyword::UNSIGNED) {
12486                        Ok(DataType::Int4Unsigned(optional_precision?))
12487                    } else {
12488                        Ok(DataType::Int4(optional_precision?))
12489                    }
12490                }
12491                Keyword::INT8 => {
12492                    let optional_precision = self.parse_optional_precision();
12493                    if self.parse_keyword(Keyword::UNSIGNED) {
12494                        Ok(DataType::Int8Unsigned(optional_precision?))
12495                    } else {
12496                        Ok(DataType::Int8(optional_precision?))
12497                    }
12498                }
12499                Keyword::INT16 => Ok(DataType::Int16),
12500                Keyword::INT32 => Ok(DataType::Int32),
12501                Keyword::INT64 => Ok(DataType::Int64),
12502                Keyword::INT128 => Ok(DataType::Int128),
12503                Keyword::INT256 => Ok(DataType::Int256),
12504                Keyword::INTEGER => {
12505                    let optional_precision = self.parse_optional_precision();
12506                    if self.parse_keyword(Keyword::UNSIGNED) {
12507                        Ok(DataType::IntegerUnsigned(optional_precision?))
12508                    } else {
12509                        if dialect.supports_data_type_signed_suffix() {
12510                            let _ = self.parse_keyword(Keyword::SIGNED);
12511                        }
12512                        Ok(DataType::Integer(optional_precision?))
12513                    }
12514                }
12515                Keyword::BIGINT => {
12516                    let optional_precision = self.parse_optional_precision();
12517                    if self.parse_keyword(Keyword::UNSIGNED) {
12518                        Ok(DataType::BigIntUnsigned(optional_precision?))
12519                    } else {
12520                        if dialect.supports_data_type_signed_suffix() {
12521                            let _ = self.parse_keyword(Keyword::SIGNED);
12522                        }
12523                        Ok(DataType::BigInt(optional_precision?))
12524                    }
12525                }
12526                Keyword::HUGEINT => Ok(DataType::HugeInt),
12527                Keyword::UBIGINT => Ok(DataType::UBigInt),
12528                Keyword::UHUGEINT => Ok(DataType::UHugeInt),
12529                Keyword::USMALLINT => Ok(DataType::USmallInt),
12530                Keyword::UTINYINT => Ok(DataType::UTinyInt),
12531                Keyword::UINT8 => Ok(DataType::UInt8),
12532                Keyword::UINT16 => Ok(DataType::UInt16),
12533                Keyword::UINT32 => Ok(DataType::UInt32),
12534                Keyword::UINT64 => Ok(DataType::UInt64),
12535                Keyword::UINT128 => Ok(DataType::UInt128),
12536                Keyword::UINT256 => Ok(DataType::UInt256),
12537                Keyword::VARCHAR => Ok(DataType::Varchar(self.parse_optional_character_length()?)),
12538                Keyword::NVARCHAR => {
12539                    Ok(DataType::Nvarchar(self.parse_optional_character_length()?))
12540                }
12541                Keyword::CHARACTER => {
12542                    if self.parse_keyword(Keyword::VARYING) {
12543                        Ok(DataType::CharacterVarying(
12544                            self.parse_optional_character_length()?,
12545                        ))
12546                    } else if self.parse_keywords(&[Keyword::LARGE, Keyword::OBJECT]) {
12547                        Ok(DataType::CharacterLargeObject(
12548                            self.parse_optional_precision()?,
12549                        ))
12550                    } else {
12551                        Ok(DataType::Character(self.parse_optional_character_length()?))
12552                    }
12553                }
12554                Keyword::CHAR => {
12555                    if self.parse_keyword(Keyword::VARYING) {
12556                        Ok(DataType::CharVarying(
12557                            self.parse_optional_character_length()?,
12558                        ))
12559                    } else if self.parse_keywords(&[Keyword::LARGE, Keyword::OBJECT]) {
12560                        Ok(DataType::CharLargeObject(self.parse_optional_precision()?))
12561                    } else {
12562                        Ok(DataType::Char(self.parse_optional_character_length()?))
12563                    }
12564                }
12565                Keyword::CLOB => Ok(DataType::Clob(self.parse_optional_precision()?)),
12566                Keyword::BINARY => Ok(DataType::Binary(self.parse_optional_precision()?)),
12567                Keyword::VARBINARY => Ok(DataType::Varbinary(self.parse_optional_binary_length()?)),
12568                Keyword::BLOB => Ok(DataType::Blob(self.parse_optional_precision()?)),
12569                Keyword::TINYBLOB => Ok(DataType::TinyBlob),
12570                Keyword::MEDIUMBLOB => Ok(DataType::MediumBlob),
12571                Keyword::LONGBLOB => Ok(DataType::LongBlob),
12572                Keyword::LONG if self.dialect.supports_long_type_as_bigint() => {
12573                    Ok(DataType::BigInt(None))
12574                }
12575                Keyword::BYTES => Ok(DataType::Bytes(self.parse_optional_precision()?)),
12576                Keyword::BIT => {
12577                    if self.parse_keyword(Keyword::VARYING) {
12578                        Ok(DataType::BitVarying(self.parse_optional_precision()?))
12579                    } else {
12580                        Ok(DataType::Bit(self.parse_optional_precision()?))
12581                    }
12582                }
12583                Keyword::VARBIT => Ok(DataType::VarBit(self.parse_optional_precision()?)),
12584                Keyword::UUID => Ok(DataType::Uuid),
12585                Keyword::DATE => Ok(DataType::Date),
12586                Keyword::DATE32 => Ok(DataType::Date32),
12587                Keyword::DATETIME => Ok(DataType::Datetime(self.parse_optional_precision()?)),
12588                Keyword::DATETIME64 => {
12589                    self.prev_token();
12590                    let (precision, time_zone) = self.parse_datetime_64()?;
12591                    Ok(DataType::Datetime64(precision, time_zone))
12592                }
12593                Keyword::TIMESTAMP => {
12594                    let precision = self.parse_optional_precision()?;
12595                    let tz = if self.parse_keyword(Keyword::WITH) {
12596                        self.expect_keywords(&[Keyword::TIME, Keyword::ZONE])?;
12597                        TimezoneInfo::WithTimeZone
12598                    } else if self.parse_keyword(Keyword::WITHOUT) {
12599                        self.expect_keywords(&[Keyword::TIME, Keyword::ZONE])?;
12600                        TimezoneInfo::WithoutTimeZone
12601                    } else {
12602                        TimezoneInfo::None
12603                    };
12604                    Ok(DataType::Timestamp(precision, tz))
12605                }
12606                Keyword::TIMESTAMPTZ => Ok(DataType::Timestamp(
12607                    self.parse_optional_precision()?,
12608                    TimezoneInfo::Tz,
12609                )),
12610                Keyword::TIMESTAMP_NTZ => {
12611                    Ok(DataType::TimestampNtz(self.parse_optional_precision()?))
12612                }
12613                Keyword::TIME => {
12614                    let precision = self.parse_optional_precision()?;
12615                    let tz = if self.parse_keyword(Keyword::WITH) {
12616                        self.expect_keywords(&[Keyword::TIME, Keyword::ZONE])?;
12617                        TimezoneInfo::WithTimeZone
12618                    } else if self.parse_keyword(Keyword::WITHOUT) {
12619                        self.expect_keywords(&[Keyword::TIME, Keyword::ZONE])?;
12620                        TimezoneInfo::WithoutTimeZone
12621                    } else {
12622                        TimezoneInfo::None
12623                    };
12624                    Ok(DataType::Time(precision, tz))
12625                }
12626                Keyword::TIMETZ => Ok(DataType::Time(
12627                    self.parse_optional_precision()?,
12628                    TimezoneInfo::Tz,
12629                )),
12630                Keyword::INTERVAL => {
12631                    if self.dialect.supports_interval_options() {
12632                        let fields = self.maybe_parse_optional_interval_fields()?;
12633                        let precision = self.parse_optional_precision()?;
12634                        Ok(DataType::Interval { fields, precision })
12635                    } else {
12636                        Ok(DataType::Interval {
12637                            fields: None,
12638                            precision: None,
12639                        })
12640                    }
12641                }
12642                Keyword::JSON => Ok(DataType::JSON),
12643                Keyword::JSONB => Ok(DataType::JSONB),
12644                Keyword::REGCLASS => Ok(DataType::Regclass),
12645                Keyword::STRING => Ok(DataType::String(self.parse_optional_precision()?)),
12646                Keyword::FIXEDSTRING => {
12647                    self.expect_token(&Token::LParen)?;
12648                    let character_length = self.parse_literal_uint()?;
12649                    self.expect_token(&Token::RParen)?;
12650                    Ok(DataType::FixedString(character_length))
12651                }
12652                Keyword::TEXT => {
12653                    if let Some(modifiers) = self.parse_optional_type_modifiers()? {
12654                        Ok(DataType::Custom(
12655                            ObjectName::from(vec![Ident::new("TEXT")]),
12656                            modifiers,
12657                        ))
12658                    } else {
12659                        Ok(DataType::Text)
12660                    }
12661                }
12662                Keyword::TINYTEXT => Ok(DataType::TinyText),
12663                Keyword::MEDIUMTEXT => Ok(DataType::MediumText),
12664                Keyword::LONGTEXT => Ok(DataType::LongText),
12665                Keyword::BYTEA => Ok(DataType::Bytea),
12666                Keyword::NUMERIC => Ok(DataType::Numeric(
12667                    self.parse_exact_number_optional_precision_scale()?,
12668                )),
12669                Keyword::DECIMAL => {
12670                    let precision = self.parse_exact_number_optional_precision_scale()?;
12671
12672                    if self.parse_keyword(Keyword::UNSIGNED) {
12673                        Ok(DataType::DecimalUnsigned(precision))
12674                    } else {
12675                        Ok(DataType::Decimal(precision))
12676                    }
12677                }
12678                Keyword::DEC => {
12679                    let precision = self.parse_exact_number_optional_precision_scale()?;
12680
12681                    if self.parse_keyword(Keyword::UNSIGNED) {
12682                        Ok(DataType::DecUnsigned(precision))
12683                    } else {
12684                        Ok(DataType::Dec(precision))
12685                    }
12686                }
12687                Keyword::BIGNUMERIC => Ok(DataType::BigNumeric(
12688                    self.parse_exact_number_optional_precision_scale()?,
12689                )),
12690                Keyword::BIGDECIMAL => Ok(DataType::BigDecimal(
12691                    self.parse_exact_number_optional_precision_scale()?,
12692                )),
12693                Keyword::ENUM => Ok(DataType::Enum(self.parse_enum_values()?, None)),
12694                Keyword::ENUM8 => Ok(DataType::Enum(self.parse_enum_values()?, Some(8))),
12695                Keyword::ENUM16 => Ok(DataType::Enum(self.parse_enum_values()?, Some(16))),
12696                Keyword::SET => Ok(DataType::Set(self.parse_string_values()?)),
12697                Keyword::ARRAY => {
12698                    if self.dialect.supports_array_typedef_without_element_type() {
12699                        Ok(DataType::Array(ArrayElemTypeDef::None))
12700                    } else if dialect_of!(self is ClickHouseDialect) {
12701                        Ok(self.parse_sub_type(|internal_type| {
12702                            DataType::Array(ArrayElemTypeDef::Parenthesis(internal_type))
12703                        })?)
12704                    } else {
12705                        self.expect_token(&Token::Lt)?;
12706                        let (inside_type, _trailing_bracket) = self.parse_data_type_helper()?;
12707                        trailing_bracket = self.expect_closing_angle_bracket(_trailing_bracket)?;
12708                        Ok(DataType::Array(ArrayElemTypeDef::AngleBracket(Box::new(
12709                            inside_type,
12710                        ))))
12711                    }
12712                }
12713                Keyword::STRUCT if dialect_is!(dialect is DuckDbDialect) => {
12714                    self.prev_token();
12715                    let field_defs = self.parse_duckdb_struct_type_def()?;
12716                    Ok(DataType::Struct(field_defs, StructBracketKind::Parentheses))
12717                }
12718                Keyword::STRUCT if self.dialect.supports_struct_literal() => {
12719                    self.prev_token();
12720                    let (field_defs, _trailing_bracket) =
12721                        self.parse_struct_type_def(Self::parse_struct_field_def)?;
12722                    trailing_bracket = _trailing_bracket;
12723                    Ok(DataType::Struct(
12724                        field_defs,
12725                        StructBracketKind::AngleBrackets,
12726                    ))
12727                }
12728                Keyword::UNION if dialect_is!(dialect is DuckDbDialect | GenericDialect) => {
12729                    self.prev_token();
12730                    let fields = self.parse_union_type_def()?;
12731                    Ok(DataType::Union(fields))
12732                }
12733                Keyword::NULLABLE if dialect_is!(dialect is ClickHouseDialect | GenericDialect) => {
12734                    Ok(self.parse_sub_type(DataType::Nullable)?)
12735                }
12736                Keyword::LOWCARDINALITY if dialect_is!(dialect is ClickHouseDialect | GenericDialect) => {
12737                    Ok(self.parse_sub_type(DataType::LowCardinality)?)
12738                }
12739                Keyword::MAP if self.dialect.supports_map_literal_with_angle_brackets() => {
12740                    self.expect_token(&Token::Lt)?;
12741                    let key_data_type = self.parse_data_type()?;
12742                    self.expect_token(&Token::Comma)?;
12743                    let (value_data_type, _trailing_bracket) = self.parse_data_type_helper()?;
12744                    trailing_bracket = self.expect_closing_angle_bracket(_trailing_bracket)?;
12745                    Ok(DataType::Map(
12746                        Box::new(key_data_type),
12747                        Box::new(value_data_type),
12748                    ))
12749                }
12750                Keyword::MAP if dialect_is!(dialect is ClickHouseDialect | GenericDialect) => {
12751                    self.prev_token();
12752                    let (key_data_type, value_data_type) = self.parse_click_house_map_def()?;
12753                    Ok(DataType::Map(
12754                        Box::new(key_data_type),
12755                        Box::new(value_data_type),
12756                    ))
12757                }
12758                Keyword::NESTED if dialect_is!(dialect is ClickHouseDialect | GenericDialect) => {
12759                    self.expect_token(&Token::LParen)?;
12760                    let field_defs = self.parse_comma_separated(Parser::parse_column_def)?;
12761                    self.expect_token(&Token::RParen)?;
12762                    Ok(DataType::Nested(field_defs))
12763                }
12764                Keyword::TUPLE if dialect_is!(dialect is ClickHouseDialect | GenericDialect) => {
12765                    self.prev_token();
12766                    let field_defs = self.parse_click_house_tuple_def()?;
12767                    Ok(DataType::Tuple(field_defs))
12768                }
12769                Keyword::TRIGGER => Ok(DataType::Trigger),
12770                Keyword::ANY if self.peek_keyword(Keyword::TYPE) => {
12771                    let _ = self.parse_keyword(Keyword::TYPE);
12772                    Ok(DataType::AnyType)
12773                }
12774                Keyword::TABLE => {
12775                    // an LParen after the TABLE keyword indicates that table columns are being defined
12776                    // whereas no LParen indicates an anonymous table expression will be returned
12777                    if self.peek_token_ref().token == Token::LParen {
12778                        let columns = self.parse_returns_table_columns()?;
12779                        Ok(DataType::Table(Some(columns)))
12780                    } else {
12781                        Ok(DataType::Table(None))
12782                    }
12783                }
12784                Keyword::SIGNED => {
12785                    if self.parse_keyword(Keyword::INTEGER) {
12786                        Ok(DataType::SignedInteger)
12787                    } else {
12788                        Ok(DataType::Signed)
12789                    }
12790                }
12791                Keyword::UNSIGNED => {
12792                    if self.parse_keyword(Keyword::INTEGER) {
12793                        Ok(DataType::UnsignedInteger)
12794                    } else {
12795                        Ok(DataType::Unsigned)
12796                    }
12797                }
12798                Keyword::TSVECTOR if dialect_is!(dialect is PostgreSqlDialect | GenericDialect) => {
12799                    Ok(DataType::TsVector)
12800                }
12801                Keyword::TSQUERY if dialect_is!(dialect is PostgreSqlDialect | GenericDialect) => {
12802                    Ok(DataType::TsQuery)
12803                }
12804                _ => {
12805                    self.prev_token();
12806                    let type_name = self.parse_object_name(false)?;
12807                    if let Some(modifiers) = self.parse_optional_type_modifiers()? {
12808                        Ok(DataType::Custom(type_name, modifiers))
12809                    } else {
12810                        Ok(DataType::Custom(type_name, vec![]))
12811                    }
12812                }
12813            },
12814            _ => self.expected_at("a data type name", next_token_index),
12815        }?;
12816
12817        if self.dialect.supports_array_typedef_with_brackets() {
12818            while self.consume_token(&Token::LBracket) {
12819                // Parse optional array data type size
12820                let size = self.maybe_parse(|p| p.parse_literal_uint())?;
12821                self.expect_token(&Token::RBracket)?;
12822                data = DataType::Array(ArrayElemTypeDef::SquareBracket(Box::new(data), size))
12823            }
12824        }
12825        Ok((data, trailing_bracket))
12826    }
12827
12828    fn parse_returns_table_column(&mut self) -> Result<ColumnDef, ParserError> {
12829        self.parse_column_def()
12830    }
12831
12832    fn parse_returns_table_columns(&mut self) -> Result<Vec<ColumnDef>, ParserError> {
12833        self.expect_token(&Token::LParen)?;
12834        let columns = self.parse_comma_separated(Parser::parse_returns_table_column)?;
12835        self.expect_token(&Token::RParen)?;
12836        Ok(columns)
12837    }
12838
12839    /// Parse a parenthesized, comma-separated list of single-quoted strings.
12840    pub fn parse_string_values(&mut self) -> Result<Vec<String>, ParserError> {
12841        self.expect_token(&Token::LParen)?;
12842        let mut values = Vec::new();
12843        loop {
12844            let next_token = self.next_token();
12845            match next_token.token {
12846                Token::SingleQuotedString(value) => values.push(value),
12847                _ => self.expected("a string", next_token)?,
12848            }
12849            let next_token = self.next_token();
12850            match next_token.token {
12851                Token::Comma => (),
12852                Token::RParen => break,
12853                _ => self.expected(", or }", next_token)?,
12854            }
12855        }
12856        Ok(values)
12857    }
12858
12859    /// Strictly parse `identifier AS identifier`
12860    pub fn parse_identifier_with_alias(&mut self) -> Result<IdentWithAlias, ParserError> {
12861        let ident = self.parse_identifier()?;
12862        self.expect_keyword_is(Keyword::AS)?;
12863        let alias = self.parse_identifier()?;
12864        Ok(IdentWithAlias { ident, alias })
12865    }
12866
12867    /// Parse `identifier [AS] identifier` where the AS keyword is optional
12868    fn parse_identifier_with_optional_alias(&mut self) -> Result<IdentWithAlias, ParserError> {
12869        let ident = self.parse_identifier()?;
12870        let _after_as = self.parse_keyword(Keyword::AS);
12871        let alias = self.parse_identifier()?;
12872        Ok(IdentWithAlias { ident, alias })
12873    }
12874
12875    /// Parse comma-separated list of parenthesized queries for pipe operators
12876    fn parse_pipe_operator_queries(&mut self) -> Result<Vec<Query>, ParserError> {
12877        self.parse_comma_separated(|parser| {
12878            parser.expect_token(&Token::LParen)?;
12879            let query = parser.parse_query()?;
12880            parser.expect_token(&Token::RParen)?;
12881            Ok(*query)
12882        })
12883    }
12884
12885    /// Parse set quantifier for pipe operators that require DISTINCT. E.g. INTERSECT and EXCEPT
12886    fn parse_distinct_required_set_quantifier(
12887        &mut self,
12888        operator_name: &str,
12889    ) -> Result<SetQuantifier, ParserError> {
12890        let quantifier = self.parse_set_quantifier(&Some(SetOperator::Intersect));
12891        match quantifier {
12892            SetQuantifier::Distinct | SetQuantifier::DistinctByName => Ok(quantifier),
12893            _ => Err(ParserError::ParserError(format!(
12894                "{operator_name} pipe operator requires DISTINCT modifier",
12895            ))),
12896        }
12897    }
12898
12899    /// Parse optional identifier alias (with or without AS keyword)
12900    fn parse_identifier_optional_alias(&mut self) -> Result<Option<Ident>, ParserError> {
12901        if self.parse_keyword(Keyword::AS) {
12902            Ok(Some(self.parse_identifier()?))
12903        } else {
12904            // Check if the next token is an identifier (implicit alias)
12905            self.maybe_parse(|parser| parser.parse_identifier())
12906        }
12907    }
12908
12909    /// Optionally parses an alias for a select list item
12910    fn maybe_parse_select_item_alias(&mut self) -> Result<Option<Ident>, ParserError> {
12911        fn validator(explicit: bool, kw: &Keyword, parser: &mut Parser) -> bool {
12912            parser.dialect.is_select_item_alias(explicit, kw, parser)
12913        }
12914        self.parse_optional_alias_inner(None, validator)
12915    }
12916
12917    /// Optionally parses an alias for a table like in `... FROM generate_series(1, 10) AS t (col)`.
12918    /// In this case, the alias is allowed to optionally name the columns in the table, in
12919    /// addition to the table itself.
12920    pub fn maybe_parse_table_alias(&mut self) -> Result<Option<TableAlias>, ParserError> {
12921        fn validator(explicit: bool, kw: &Keyword, parser: &mut Parser) -> bool {
12922            parser.dialect.is_table_factor_alias(explicit, kw, parser)
12923        }
12924        let explicit = self.peek_keyword(Keyword::AS);
12925        match self.parse_optional_alias_inner(None, validator)? {
12926            Some(name) => {
12927                let columns = self.parse_table_alias_column_defs()?;
12928                let at = if self.dialect.supports_partiql() && self.parse_keyword(Keyword::AT) {
12929                    Some(self.parse_identifier()?)
12930                } else {
12931                    None
12932                };
12933                Ok(Some(TableAlias {
12934                    explicit,
12935                    name,
12936                    columns,
12937                    at,
12938                }))
12939            }
12940            None => Ok(None),
12941        }
12942    }
12943
12944    fn parse_table_index_hints(&mut self) -> Result<Vec<TableIndexHints>, ParserError> {
12945        let mut hints = vec![];
12946        while let Some(hint_type) =
12947            self.parse_one_of_keywords(&[Keyword::USE, Keyword::IGNORE, Keyword::FORCE])
12948        {
12949            let hint_type = match hint_type {
12950                Keyword::USE => TableIndexHintType::Use,
12951                Keyword::IGNORE => TableIndexHintType::Ignore,
12952                Keyword::FORCE => TableIndexHintType::Force,
12953                _ => {
12954                    return self.expected_ref(
12955                        "expected to match USE/IGNORE/FORCE keyword",
12956                        self.peek_token_ref(),
12957                    )
12958                }
12959            };
12960            let index_type = match self.parse_one_of_keywords(&[Keyword::INDEX, Keyword::KEY]) {
12961                Some(Keyword::INDEX) => TableIndexType::Index,
12962                Some(Keyword::KEY) => TableIndexType::Key,
12963                _ => {
12964                    return self
12965                        .expected_ref("expected to match INDEX/KEY keyword", self.peek_token_ref())
12966                }
12967            };
12968            let for_clause = if self.parse_keyword(Keyword::FOR) {
12969                let clause = if self.parse_keyword(Keyword::JOIN) {
12970                    TableIndexHintForClause::Join
12971                } else if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
12972                    TableIndexHintForClause::OrderBy
12973                } else if self.parse_keywords(&[Keyword::GROUP, Keyword::BY]) {
12974                    TableIndexHintForClause::GroupBy
12975                } else {
12976                    return self.expected_ref(
12977                        "expected to match FOR/ORDER BY/GROUP BY table hint in for clause",
12978                        self.peek_token_ref(),
12979                    );
12980                };
12981                Some(clause)
12982            } else {
12983                None
12984            };
12985
12986            self.expect_token(&Token::LParen)?;
12987            let index_names = if self.peek_token_ref().token != Token::RParen {
12988                self.parse_comma_separated(Parser::parse_identifier)?
12989            } else {
12990                vec![]
12991            };
12992            self.expect_token(&Token::RParen)?;
12993            hints.push(TableIndexHints {
12994                hint_type,
12995                index_type,
12996                for_clause,
12997                index_names,
12998            });
12999        }
13000        Ok(hints)
13001    }
13002
13003    /// Wrapper for parse_optional_alias_inner, left for backwards-compatibility
13004    /// but new flows should use the context-specific methods such as `maybe_parse_select_item_alias`
13005    /// and `maybe_parse_table_alias`.
13006    pub fn parse_optional_alias(
13007        &mut self,
13008        reserved_kwds: &[Keyword],
13009    ) -> Result<Option<Ident>, ParserError> {
13010        fn validator(_explicit: bool, _kw: &Keyword, _parser: &mut Parser) -> bool {
13011            false
13012        }
13013        self.parse_optional_alias_inner(Some(reserved_kwds), validator)
13014    }
13015
13016    /// Parses an optional alias after a SQL element such as a select list item
13017    /// or a table name.
13018    ///
13019    /// This method accepts an optional list of reserved keywords or a function
13020    /// to call to validate if a keyword should be parsed as an alias, to allow
13021    /// callers to customize the parsing logic based on their context.
13022    fn parse_optional_alias_inner<F>(
13023        &mut self,
13024        reserved_kwds: Option<&[Keyword]>,
13025        validator: F,
13026    ) -> Result<Option<Ident>, ParserError>
13027    where
13028        F: Fn(bool, &Keyword, &mut Parser) -> bool,
13029    {
13030        let after_as = self.parse_keyword(Keyword::AS);
13031
13032        let next_token = self.next_token();
13033        match next_token.token {
13034            // Accepts a keyword as an alias if the AS keyword explicitly indicate an alias or if the
13035            // caller provided a list of reserved keywords and the keyword is not on that list.
13036            Token::Word(w)
13037                if reserved_kwds.is_some()
13038                    && (after_as || reserved_kwds.is_some_and(|x| !x.contains(&w.keyword))) =>
13039            {
13040                Ok(Some(w.into_ident(next_token.span)))
13041            }
13042            // Accepts a keyword as alias based on the caller's context, such as to what SQL element
13043            // this word is a potential alias of using the validator call-back. This allows for
13044            // dialect-specific logic.
13045            Token::Word(w) if validator(after_as, &w.keyword, self) => {
13046                Ok(Some(w.into_ident(next_token.span)))
13047            }
13048            // For backwards-compatibility, we accept quoted strings as aliases regardless of the context.
13049            Token::SingleQuotedString(s) => Ok(Some(Ident::with_quote('\'', s))),
13050            Token::DoubleQuotedString(s) => Ok(Some(Ident::with_quote('\"', s))),
13051            _ => {
13052                if after_as {
13053                    return self.expected("an identifier after AS", next_token);
13054                }
13055                self.prev_token();
13056                Ok(None) // no alias found
13057            }
13058        }
13059    }
13060
13061    /// Parse an optional `GROUP BY` clause, returning `Some(GroupByExpr)` when present.
13062    pub fn parse_optional_group_by(&mut self) -> Result<Option<GroupByExpr>, ParserError> {
13063        if self.parse_keywords(&[Keyword::GROUP, Keyword::BY]) {
13064            let expressions = if self.parse_keyword(Keyword::ALL) {
13065                None
13066            } else {
13067                Some(self.parse_comma_separated(Parser::parse_group_by_expr)?)
13068            };
13069
13070            let mut modifiers = vec![];
13071            if self.dialect.supports_group_by_with_modifier() {
13072                loop {
13073                    if !self.parse_keyword(Keyword::WITH) {
13074                        break;
13075                    }
13076                    let keyword = self.expect_one_of_keywords(&[
13077                        Keyword::ROLLUP,
13078                        Keyword::CUBE,
13079                        Keyword::TOTALS,
13080                    ])?;
13081                    modifiers.push(match keyword {
13082                        Keyword::ROLLUP => GroupByWithModifier::Rollup,
13083                        Keyword::CUBE => GroupByWithModifier::Cube,
13084                        Keyword::TOTALS => GroupByWithModifier::Totals,
13085                        _ => {
13086                            return parser_err!(
13087                                "BUG: expected to match GroupBy modifier keyword",
13088                                self.peek_token_ref().span.start
13089                            )
13090                        }
13091                    });
13092                }
13093            }
13094            if self.parse_keywords(&[Keyword::GROUPING, Keyword::SETS]) {
13095                self.expect_token(&Token::LParen)?;
13096                let result = self.parse_comma_separated(|p| {
13097                    if p.peek_token_ref().token == Token::LParen {
13098                        p.parse_tuple(true, true)
13099                    } else {
13100                        Ok(vec![p.parse_expr()?])
13101                    }
13102                })?;
13103                self.expect_token(&Token::RParen)?;
13104                modifiers.push(GroupByWithModifier::GroupingSets(Expr::GroupingSets(
13105                    result,
13106                )));
13107            };
13108            let group_by = match expressions {
13109                None => GroupByExpr::All(modifiers),
13110                Some(exprs) => GroupByExpr::Expressions(exprs, modifiers),
13111            };
13112            Ok(Some(group_by))
13113        } else {
13114            Ok(None)
13115        }
13116    }
13117
13118    /// Parse an optional `ORDER BY` clause, returning `Some(OrderBy)` when present.
13119    pub fn parse_optional_order_by(&mut self) -> Result<Option<OrderBy>, ParserError> {
13120        if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
13121            let order_by =
13122                if self.dialect.supports_order_by_all() && self.parse_keyword(Keyword::ALL) {
13123                    let order_by_options = self.parse_order_by_options()?;
13124                    OrderBy {
13125                        kind: OrderByKind::All(order_by_options),
13126                        interpolate: None,
13127                    }
13128                } else {
13129                    let exprs = self.parse_comma_separated(Parser::parse_order_by_expr)?;
13130                    let interpolate = if self.dialect.supports_interpolate() {
13131                        self.parse_interpolations()?
13132                    } else {
13133                        None
13134                    };
13135                    OrderBy {
13136                        kind: OrderByKind::Expressions(exprs),
13137                        interpolate,
13138                    }
13139                };
13140            Ok(Some(order_by))
13141        } else {
13142            Ok(None)
13143        }
13144    }
13145
13146    fn parse_optional_limit_clause(&mut self) -> Result<Option<LimitClause>, ParserError> {
13147        let mut offset = if self.parse_keyword(Keyword::OFFSET) {
13148            Some(self.parse_offset()?)
13149        } else {
13150            None
13151        };
13152
13153        let (limit, limit_by) = if self.parse_keyword(Keyword::LIMIT) {
13154            let expr = self.parse_limit()?;
13155
13156            if self.dialect.supports_limit_comma()
13157                && offset.is_none()
13158                && expr.is_some() // ALL not supported with comma
13159                && self.consume_token(&Token::Comma)
13160            {
13161                let offset = expr.ok_or_else(|| {
13162                    ParserError::ParserError(
13163                        "Missing offset for LIMIT <offset>, <limit>".to_string(),
13164                    )
13165                })?;
13166                return Ok(Some(LimitClause::OffsetCommaLimit {
13167                    offset,
13168                    limit: self.parse_expr()?,
13169                }));
13170            }
13171
13172            let limit_by = if self.dialect.supports_limit_by() && self.parse_keyword(Keyword::BY) {
13173                Some(self.parse_comma_separated(Parser::parse_expr)?)
13174            } else {
13175                None
13176            };
13177
13178            (Some(expr), limit_by)
13179        } else {
13180            (None, None)
13181        };
13182
13183        if offset.is_none() && limit.is_some() && self.parse_keyword(Keyword::OFFSET) {
13184            offset = Some(self.parse_offset()?);
13185        }
13186
13187        if offset.is_some() || (limit.is_some() && limit != Some(None)) || limit_by.is_some() {
13188            Ok(Some(LimitClause::LimitOffset {
13189                limit: limit.unwrap_or_default(),
13190                offset,
13191                limit_by: limit_by.unwrap_or_default(),
13192            }))
13193        } else {
13194            Ok(None)
13195        }
13196    }
13197
13198    /// Parse a table object for insertion
13199    /// e.g. `some_database.some_table` or `FUNCTION some_table_func(...)`
13200    pub fn parse_table_object(&mut self) -> Result<TableObject, ParserError> {
13201        if self.dialect.supports_insert_table_function() && self.parse_keyword(Keyword::FUNCTION) {
13202            let fn_name = self.parse_object_name(false)?;
13203            self.parse_function_call(fn_name)
13204                .map(TableObject::TableFunction)
13205        } else if self.dialect.supports_insert_table_query() && self.peek_subquery_or_cte_start() {
13206            self.parse_parenthesized(|p| p.parse_query())
13207                .map(TableObject::TableQuery)
13208        } else {
13209            self.parse_object_name(false).map(TableObject::TableName)
13210        }
13211    }
13212
13213    /// Parse a possibly qualified, possibly quoted identifier, e.g.
13214    /// `foo` or `myschema."table"
13215    ///
13216    /// The `in_table_clause` parameter indicates whether the object name is a table in a FROM, JOIN,
13217    /// or similar table clause. Currently, this is used only to support unquoted hyphenated identifiers
13218    /// in this context on BigQuery.
13219    pub fn parse_object_name(&mut self, in_table_clause: bool) -> Result<ObjectName, ParserError> {
13220        self.parse_object_name_inner(in_table_clause, false)
13221    }
13222
13223    /// Parse a possibly qualified, possibly quoted identifier, e.g.
13224    /// `foo` or `myschema."table"
13225    ///
13226    /// The `in_table_clause` parameter indicates whether the object name is a table in a FROM, JOIN,
13227    /// or similar table clause. Currently, this is used only to support unquoted hyphenated identifiers
13228    /// in this context on BigQuery.
13229    ///
13230    /// The `allow_wildcards` parameter indicates whether to allow for wildcards in the object name
13231    /// e.g. *, *.*, `foo`.*, or "foo"."bar"
13232    fn parse_object_name_inner(
13233        &mut self,
13234        in_table_clause: bool,
13235        allow_wildcards: bool,
13236    ) -> Result<ObjectName, ParserError> {
13237        let mut parts = vec![];
13238        if dialect_of!(self is BigQueryDialect) && in_table_clause {
13239            loop {
13240                let (ident, end_with_period) = self.parse_unquoted_hyphenated_identifier()?;
13241                parts.push(ObjectNamePart::Identifier(ident));
13242                if !self.consume_token(&Token::Period) && !end_with_period {
13243                    break;
13244                }
13245            }
13246        } else {
13247            loop {
13248                if allow_wildcards && self.peek_token_ref().token == Token::Mul {
13249                    let span = self.next_token().span;
13250                    parts.push(ObjectNamePart::Identifier(Ident {
13251                        value: Token::Mul.to_string(),
13252                        quote_style: None,
13253                        span,
13254                    }));
13255                } else if dialect_of!(self is BigQueryDialect) && in_table_clause {
13256                    let (ident, end_with_period) = self.parse_unquoted_hyphenated_identifier()?;
13257                    parts.push(ObjectNamePart::Identifier(ident));
13258                    if !self.consume_token(&Token::Period) && !end_with_period {
13259                        break;
13260                    }
13261                } else if self.dialect.supports_object_name_double_dot_notation()
13262                    && parts.len() == 1
13263                    && matches!(self.peek_token_ref().token, Token::Period)
13264                {
13265                    // Empty string here means default schema
13266                    parts.push(ObjectNamePart::Identifier(Ident::new("")));
13267                } else {
13268                    let ident = self.parse_identifier()?;
13269                    let part = if self
13270                        .dialect
13271                        .is_identifier_generating_function_name(&ident, &parts)
13272                    {
13273                        self.expect_token(&Token::LParen)?;
13274                        let args: Vec<FunctionArg> =
13275                            self.parse_comma_separated0(Self::parse_function_args, Token::RParen)?;
13276                        self.expect_token(&Token::RParen)?;
13277                        ObjectNamePart::Function(ObjectNamePartFunction { name: ident, args })
13278                    } else {
13279                        ObjectNamePart::Identifier(ident)
13280                    };
13281                    parts.push(part);
13282                }
13283
13284                if !self.consume_token(&Token::Period) {
13285                    break;
13286                }
13287            }
13288        }
13289
13290        // BigQuery accepts any number of quoted identifiers of a table name.
13291        // https://cloud.google.com/bigquery/docs/reference/standard-sql/lexical#quoted_identifiers
13292        if dialect_of!(self is BigQueryDialect)
13293            && parts.iter().any(|part| {
13294                part.as_ident()
13295                    .is_some_and(|ident| ident.value.contains('.'))
13296            })
13297        {
13298            parts = parts
13299                .into_iter()
13300                .flat_map(|part| match part.as_ident() {
13301                    Some(ident) => ident
13302                        .value
13303                        .split('.')
13304                        .map(|value| {
13305                            ObjectNamePart::Identifier(Ident {
13306                                value: value.into(),
13307                                quote_style: ident.quote_style,
13308                                span: ident.span,
13309                            })
13310                        })
13311                        .collect::<Vec<_>>(),
13312                    None => vec![part],
13313                })
13314                .collect()
13315        }
13316
13317        Ok(ObjectName(parts))
13318    }
13319
13320    /// Parse identifiers
13321    pub fn parse_identifiers(&mut self) -> Result<Vec<Ident>, ParserError> {
13322        let mut idents = vec![];
13323        loop {
13324            let token = self.peek_token_ref();
13325            match &token.token {
13326                Token::Word(w) => {
13327                    idents.push(w.to_ident(token.span));
13328                }
13329                Token::EOF | Token::Eq | Token::SemiColon | Token::VerticalBarRightAngleBracket => {
13330                    break
13331                }
13332                _ => {}
13333            }
13334            self.advance_token();
13335        }
13336        Ok(idents)
13337    }
13338
13339    /// Parse identifiers of form ident1[.identN]*
13340    ///
13341    /// Similar in functionality to [parse_identifiers], with difference
13342    /// being this function is much more strict about parsing a valid multipart identifier, not
13343    /// allowing extraneous tokens to be parsed, otherwise it fails.
13344    ///
13345    /// For example:
13346    ///
13347    /// ```rust
13348    /// use sqlparser::ast::Ident;
13349    /// use sqlparser::dialect::GenericDialect;
13350    /// use sqlparser::parser::Parser;
13351    ///
13352    /// let dialect = GenericDialect {};
13353    /// let expected = vec![Ident::new("one"), Ident::new("two")];
13354    ///
13355    /// // expected usage
13356    /// let sql = "one.two";
13357    /// let mut parser = Parser::new(&dialect).try_with_sql(sql).unwrap();
13358    /// let actual = parser.parse_multipart_identifier().unwrap();
13359    /// assert_eq!(&actual, &expected);
13360    ///
13361    /// // parse_identifiers is more loose on what it allows, parsing successfully
13362    /// let sql = "one + two";
13363    /// let mut parser = Parser::new(&dialect).try_with_sql(sql).unwrap();
13364    /// let actual = parser.parse_identifiers().unwrap();
13365    /// assert_eq!(&actual, &expected);
13366    ///
13367    /// // expected to strictly fail due to + separator
13368    /// let sql = "one + two";
13369    /// let mut parser = Parser::new(&dialect).try_with_sql(sql).unwrap();
13370    /// let actual = parser.parse_multipart_identifier().unwrap_err();
13371    /// assert_eq!(
13372    ///     actual.to_string(),
13373    ///     "sql parser error: Unexpected token in identifier: +"
13374    /// );
13375    /// ```
13376    ///
13377    /// [parse_identifiers]: Parser::parse_identifiers
13378    pub fn parse_multipart_identifier(&mut self) -> Result<Vec<Ident>, ParserError> {
13379        let mut idents = vec![];
13380
13381        // expecting at least one word for identifier
13382        let next_token = self.next_token();
13383        match next_token.token {
13384            Token::Word(w) => idents.push(w.into_ident(next_token.span)),
13385            Token::EOF => {
13386                return Err(ParserError::ParserError(
13387                    "Empty input when parsing identifier".to_string(),
13388                ))?
13389            }
13390            token => {
13391                return Err(ParserError::ParserError(format!(
13392                    "Unexpected token in identifier: {token}"
13393                )))?
13394            }
13395        };
13396
13397        // parse optional next parts if exist
13398        loop {
13399            match self.next_token().token {
13400                // ensure that optional period is succeeded by another identifier
13401                Token::Period => {
13402                    let next_token = self.next_token();
13403                    match next_token.token {
13404                        Token::Word(w) => idents.push(w.into_ident(next_token.span)),
13405                        Token::EOF => {
13406                            return Err(ParserError::ParserError(
13407                                "Trailing period in identifier".to_string(),
13408                            ))?
13409                        }
13410                        token => {
13411                            return Err(ParserError::ParserError(format!(
13412                                "Unexpected token following period in identifier: {token}"
13413                            )))?
13414                        }
13415                    }
13416                }
13417                Token::EOF => break,
13418                token => {
13419                    return Err(ParserError::ParserError(format!(
13420                        "Unexpected token in identifier: {token}"
13421                    )))?;
13422                }
13423            }
13424        }
13425
13426        Ok(idents)
13427    }
13428
13429    /// Parse a simple one-word identifier (possibly quoted, possibly a keyword)
13430    pub fn parse_identifier(&mut self) -> Result<Ident, ParserError> {
13431        let next_token = self.next_token();
13432        match next_token.token {
13433            Token::Word(w) => Ok(w.into_ident(next_token.span)),
13434            Token::SingleQuotedString(s) => Ok(Ident::with_quote('\'', s)),
13435            Token::DoubleQuotedString(s) => Ok(Ident::with_quote('\"', s)),
13436            _ => self.expected("identifier", next_token),
13437        }
13438    }
13439
13440    /// On BigQuery, hyphens are permitted in unquoted identifiers inside of a FROM or
13441    /// TABLE clause.
13442    ///
13443    /// The first segment must be an ordinary unquoted identifier, e.g. it must not start
13444    /// with a digit. Subsequent segments are either must either be valid identifiers or
13445    /// integers, e.g. foo-123 is allowed, but foo-123a is not.
13446    ///
13447    /// [BigQuery-lexical](https://cloud.google.com/bigquery/docs/reference/standard-sql/lexical)
13448    ///
13449    /// Return a tuple of the identifier and a boolean indicating it ends with a period.
13450    fn parse_unquoted_hyphenated_identifier(&mut self) -> Result<(Ident, bool), ParserError> {
13451        match self.peek_token().token {
13452            Token::Word(w) => {
13453                let quote_style_is_none = w.quote_style.is_none();
13454                let mut requires_whitespace = false;
13455                let mut ident = w.into_ident(self.next_token().span);
13456                if quote_style_is_none {
13457                    while matches!(self.peek_token_no_skip().token, Token::Minus) {
13458                        self.next_token();
13459                        ident.value.push('-');
13460
13461                        let token = self
13462                            .next_token_no_skip()
13463                            .cloned()
13464                            .unwrap_or(TokenWithSpan::wrap(Token::EOF));
13465                        requires_whitespace = match token.token {
13466                            Token::Word(next_word) if next_word.quote_style.is_none() => {
13467                                ident.value.push_str(&next_word.value);
13468                                false
13469                            }
13470                            Token::Number(s, false) => {
13471                                // A number token can represent a decimal value ending with a period, e.g., `Number('123.')`.
13472                                // However, for an [ObjectName], it is part of a hyphenated identifier, e.g., `foo-123.bar`.
13473                                //
13474                                // If a number token is followed by a period, it is part of an [ObjectName].
13475                                // Return the identifier with `true` if the number token is followed by a period, indicating that
13476                                // parsing should continue for the next part of the hyphenated identifier.
13477                                if s.ends_with('.') {
13478                                    let Some(s) = s.split('.').next().filter(|s| {
13479                                        !s.is_empty() && s.chars().all(|c| c.is_ascii_digit())
13480                                    }) else {
13481                                        return self.expected(
13482                                            "continuation of hyphenated identifier",
13483                                            TokenWithSpan::new(Token::Number(s, false), token.span),
13484                                        );
13485                                    };
13486                                    ident.value.push_str(s);
13487                                    return Ok((ident, true));
13488                                } else {
13489                                    ident.value.push_str(&s);
13490                                }
13491                                // If next token is period, then it is part of an ObjectName and we don't expect whitespace
13492                                // after the number.
13493                                !matches!(self.peek_token_ref().token, Token::Period)
13494                            }
13495                            _ => {
13496                                return self
13497                                    .expected("continuation of hyphenated identifier", token);
13498                            }
13499                        }
13500                    }
13501
13502                    // If the last segment was a number, we must check that it's followed by whitespace,
13503                    // otherwise foo-123a will be parsed as `foo-123` with the alias `a`.
13504                    if requires_whitespace {
13505                        let token = self.next_token();
13506                        if !matches!(token.token, Token::EOF | Token::Whitespace(_)) {
13507                            return self
13508                                .expected("whitespace following hyphenated identifier", token);
13509                        }
13510                    }
13511                }
13512                Ok((ident, false))
13513            }
13514            _ => Ok((self.parse_identifier()?, false)),
13515        }
13516    }
13517
13518    /// Parses a parenthesized, comma-separated list of column definitions within a view.
13519    fn parse_view_columns(&mut self) -> Result<Vec<ViewColumnDef>, ParserError> {
13520        if self.consume_token(&Token::LParen) {
13521            if self.peek_token_ref().token == Token::RParen {
13522                self.next_token();
13523                Ok(vec![])
13524            } else {
13525                let cols = self.parse_comma_separated_with_trailing_commas(
13526                    Parser::parse_view_column,
13527                    self.dialect.supports_column_definition_trailing_commas(),
13528                    Self::is_reserved_for_column_alias,
13529                )?;
13530                self.expect_token(&Token::RParen)?;
13531                Ok(cols)
13532            }
13533        } else {
13534            Ok(vec![])
13535        }
13536    }
13537
13538    /// Parses a column definition within a view.
13539    fn parse_view_column(&mut self) -> Result<ViewColumnDef, ParserError> {
13540        let name = self.parse_identifier()?;
13541        let options = self.parse_view_column_options()?;
13542        let data_type = if dialect_of!(self is ClickHouseDialect) {
13543            Some(self.parse_data_type()?)
13544        } else {
13545            None
13546        };
13547        Ok(ViewColumnDef {
13548            name,
13549            data_type,
13550            options,
13551        })
13552    }
13553
13554    fn parse_view_column_options(&mut self) -> Result<Option<ColumnOptions>, ParserError> {
13555        let mut options = Vec::new();
13556        loop {
13557            let option = self.parse_optional_column_option()?;
13558            if let Some(option) = option {
13559                options.push(option);
13560            } else {
13561                break;
13562            }
13563        }
13564        if options.is_empty() {
13565            Ok(None)
13566        } else if self.dialect.supports_space_separated_column_options() {
13567            Ok(Some(ColumnOptions::SpaceSeparated(options)))
13568        } else {
13569            Ok(Some(ColumnOptions::CommaSeparated(options)))
13570        }
13571    }
13572
13573    /// Parses a parenthesized comma-separated list of unqualified, possibly quoted identifiers.
13574    /// For example: `(col1, "col 2", ...)`
13575    pub fn parse_parenthesized_column_list(
13576        &mut self,
13577        optional: IsOptional,
13578        allow_empty: bool,
13579    ) -> Result<Vec<Ident>, ParserError> {
13580        self.parse_parenthesized_column_list_inner(optional, allow_empty, |p| p.parse_identifier())
13581    }
13582
13583    /// Parse a parenthesized list of compound identifiers as expressions.
13584    pub fn parse_parenthesized_compound_identifier_list(
13585        &mut self,
13586        optional: IsOptional,
13587        allow_empty: bool,
13588    ) -> Result<Vec<Expr>, ParserError> {
13589        self.parse_parenthesized_column_list_inner(optional, allow_empty, |p| {
13590            Ok(Expr::CompoundIdentifier(
13591                p.parse_period_separated(|p| p.parse_identifier())?,
13592            ))
13593        })
13594    }
13595
13596    /// Parses a parenthesized comma-separated list of index columns, which can be arbitrary
13597    /// expressions with ordering information (and an opclass in some dialects).
13598    fn parse_parenthesized_index_column_list(&mut self) -> Result<Vec<IndexColumn>, ParserError> {
13599        self.parse_parenthesized_column_list_inner(Mandatory, false, |p| {
13600            p.parse_create_index_expr()
13601        })
13602    }
13603
13604    /// Parses a parenthesized comma-separated list of qualified, possibly quoted identifiers.
13605    /// For example: `(db1.sc1.tbl1.col1, db1.sc1.tbl1."col 2", ...)`
13606    pub fn parse_parenthesized_qualified_column_list(
13607        &mut self,
13608        optional: IsOptional,
13609        allow_empty: bool,
13610    ) -> Result<Vec<ObjectName>, ParserError> {
13611        self.parse_parenthesized_column_list_inner(optional, allow_empty, |p| {
13612            p.parse_object_name(true)
13613        })
13614    }
13615
13616    /// Parses a parenthesized comma-separated list of columns using
13617    /// the provided function to parse each element.
13618    fn parse_parenthesized_column_list_inner<F, T>(
13619        &mut self,
13620        optional: IsOptional,
13621        allow_empty: bool,
13622        mut f: F,
13623    ) -> Result<Vec<T>, ParserError>
13624    where
13625        F: FnMut(&mut Parser) -> Result<T, ParserError>,
13626    {
13627        if self.consume_token(&Token::LParen) {
13628            if allow_empty && self.peek_token_ref().token == Token::RParen {
13629                self.next_token();
13630                Ok(vec![])
13631            } else {
13632                let cols = self.parse_comma_separated(|p| f(p))?;
13633                self.expect_token(&Token::RParen)?;
13634                Ok(cols)
13635            }
13636        } else if optional == Optional {
13637            Ok(vec![])
13638        } else {
13639            self.expected_ref("a list of columns in parentheses", self.peek_token_ref())
13640        }
13641    }
13642
13643    /// Parses a parenthesized comma-separated list of table alias column definitions.
13644    fn parse_table_alias_column_defs(&mut self) -> Result<Vec<TableAliasColumnDef>, ParserError> {
13645        if self.consume_token(&Token::LParen) {
13646            let cols = self.parse_comma_separated(|p| {
13647                let name = p.parse_identifier()?;
13648                let data_type = p.maybe_parse(|p| p.parse_data_type())?;
13649                Ok(TableAliasColumnDef { name, data_type })
13650            })?;
13651            self.expect_token(&Token::RParen)?;
13652            Ok(cols)
13653        } else {
13654            Ok(vec![])
13655        }
13656    }
13657
13658    /// Parse an unsigned precision value enclosed in parentheses, e.g. `(10)`.
13659    pub fn parse_precision(&mut self) -> Result<u64, ParserError> {
13660        self.expect_token(&Token::LParen)?;
13661        let n = self.parse_literal_uint()?;
13662        self.expect_token(&Token::RParen)?;
13663        Ok(n)
13664    }
13665
13666    /// Parse an optional precision `(n)` and return it as `Some(n)` when present.
13667    pub fn parse_optional_precision(&mut self) -> Result<Option<u64>, ParserError> {
13668        if self.consume_token(&Token::LParen) {
13669            let n = self.parse_literal_uint()?;
13670            self.expect_token(&Token::RParen)?;
13671            Ok(Some(n))
13672        } else {
13673            Ok(None)
13674        }
13675    }
13676
13677    fn maybe_parse_optional_interval_fields(
13678        &mut self,
13679    ) -> Result<Option<IntervalFields>, ParserError> {
13680        match self.parse_one_of_keywords(&[
13681            // Can be followed by `TO` option
13682            Keyword::YEAR,
13683            Keyword::DAY,
13684            Keyword::HOUR,
13685            Keyword::MINUTE,
13686            // No `TO` option
13687            Keyword::MONTH,
13688            Keyword::SECOND,
13689        ]) {
13690            Some(Keyword::YEAR) => {
13691                if self.peek_keyword(Keyword::TO) {
13692                    self.expect_keyword(Keyword::TO)?;
13693                    self.expect_keyword(Keyword::MONTH)?;
13694                    Ok(Some(IntervalFields::YearToMonth))
13695                } else {
13696                    Ok(Some(IntervalFields::Year))
13697                }
13698            }
13699            Some(Keyword::DAY) => {
13700                if self.peek_keyword(Keyword::TO) {
13701                    self.expect_keyword(Keyword::TO)?;
13702                    match self.expect_one_of_keywords(&[
13703                        Keyword::HOUR,
13704                        Keyword::MINUTE,
13705                        Keyword::SECOND,
13706                    ])? {
13707                        Keyword::HOUR => Ok(Some(IntervalFields::DayToHour)),
13708                        Keyword::MINUTE => Ok(Some(IntervalFields::DayToMinute)),
13709                        Keyword::SECOND => Ok(Some(IntervalFields::DayToSecond)),
13710                        _ => {
13711                            self.prev_token();
13712                            self.expected_ref("HOUR, MINUTE, or SECOND", self.peek_token_ref())
13713                        }
13714                    }
13715                } else {
13716                    Ok(Some(IntervalFields::Day))
13717                }
13718            }
13719            Some(Keyword::HOUR) => {
13720                if self.peek_keyword(Keyword::TO) {
13721                    self.expect_keyword(Keyword::TO)?;
13722                    match self.expect_one_of_keywords(&[Keyword::MINUTE, Keyword::SECOND])? {
13723                        Keyword::MINUTE => Ok(Some(IntervalFields::HourToMinute)),
13724                        Keyword::SECOND => Ok(Some(IntervalFields::HourToSecond)),
13725                        _ => {
13726                            self.prev_token();
13727                            self.expected_ref("MINUTE or SECOND", self.peek_token_ref())
13728                        }
13729                    }
13730                } else {
13731                    Ok(Some(IntervalFields::Hour))
13732                }
13733            }
13734            Some(Keyword::MINUTE) => {
13735                if self.peek_keyword(Keyword::TO) {
13736                    self.expect_keyword(Keyword::TO)?;
13737                    self.expect_keyword(Keyword::SECOND)?;
13738                    Ok(Some(IntervalFields::MinuteToSecond))
13739                } else {
13740                    Ok(Some(IntervalFields::Minute))
13741                }
13742            }
13743            Some(Keyword::MONTH) => Ok(Some(IntervalFields::Month)),
13744            Some(Keyword::SECOND) => Ok(Some(IntervalFields::Second)),
13745            Some(_) => {
13746                self.prev_token();
13747                self.expected_ref(
13748                    "YEAR, MONTH, DAY, HOUR, MINUTE, or SECOND",
13749                    self.peek_token_ref(),
13750                )
13751            }
13752            None => Ok(None),
13753        }
13754    }
13755
13756    /// Parse datetime64 [1]
13757    /// Syntax
13758    /// ```sql
13759    /// DateTime64(precision[, timezone])
13760    /// ```
13761    ///
13762    /// [1]: https://clickhouse.com/docs/en/sql-reference/data-types/datetime64
13763    pub fn parse_datetime_64(&mut self) -> Result<(u64, Option<String>), ParserError> {
13764        self.expect_keyword_is(Keyword::DATETIME64)?;
13765        self.expect_token(&Token::LParen)?;
13766        let precision = self.parse_literal_uint()?;
13767        let time_zone = if self.consume_token(&Token::Comma) {
13768            Some(self.parse_literal_string()?)
13769        } else {
13770            None
13771        };
13772        self.expect_token(&Token::RParen)?;
13773        Ok((precision, time_zone))
13774    }
13775
13776    /// Parse an optional character length specification `(n | MAX [CHARACTERS|OCTETS])`.
13777    pub fn parse_optional_character_length(
13778        &mut self,
13779    ) -> Result<Option<CharacterLength>, ParserError> {
13780        if self.consume_token(&Token::LParen) {
13781            let character_length = self.parse_character_length()?;
13782            self.expect_token(&Token::RParen)?;
13783            Ok(Some(character_length))
13784        } else {
13785            Ok(None)
13786        }
13787    }
13788
13789    /// Parse an optional binary length specification like `(n)`.
13790    pub fn parse_optional_binary_length(&mut self) -> Result<Option<BinaryLength>, ParserError> {
13791        if self.consume_token(&Token::LParen) {
13792            let binary_length = self.parse_binary_length()?;
13793            self.expect_token(&Token::RParen)?;
13794            Ok(Some(binary_length))
13795        } else {
13796            Ok(None)
13797        }
13798    }
13799
13800    /// Parse a character length, handling `MAX` or integer lengths with optional units.
13801    pub fn parse_character_length(&mut self) -> Result<CharacterLength, ParserError> {
13802        if self.parse_keyword(Keyword::MAX) {
13803            return Ok(CharacterLength::Max);
13804        }
13805        let length = self.parse_literal_uint()?;
13806        let unit = if self.parse_keyword(Keyword::CHARACTERS) {
13807            Some(CharLengthUnits::Characters)
13808        } else if self.parse_keyword(Keyword::OCTETS) {
13809            Some(CharLengthUnits::Octets)
13810        } else {
13811            None
13812        };
13813        Ok(CharacterLength::IntegerLength { length, unit })
13814    }
13815
13816    /// Parse a binary length specification, returning `BinaryLength`.
13817    pub fn parse_binary_length(&mut self) -> Result<BinaryLength, ParserError> {
13818        if self.parse_keyword(Keyword::MAX) {
13819            return Ok(BinaryLength::Max);
13820        }
13821        let length = self.parse_literal_uint()?;
13822        Ok(BinaryLength::IntegerLength { length })
13823    }
13824
13825    /// Parse an optional `(precision[, scale])` and return `(Option<precision>, Option<scale>)`.
13826    pub fn parse_optional_precision_scale(
13827        &mut self,
13828    ) -> Result<(Option<u64>, Option<u64>), ParserError> {
13829        if self.consume_token(&Token::LParen) {
13830            let n = self.parse_literal_uint()?;
13831            let scale = if self.consume_token(&Token::Comma) {
13832                Some(self.parse_literal_uint()?)
13833            } else {
13834                None
13835            };
13836            self.expect_token(&Token::RParen)?;
13837            Ok((Some(n), scale))
13838        } else {
13839            Ok((None, None))
13840        }
13841    }
13842
13843    /// Parse exact-number precision/scale info like `(precision[, scale])` for decimal types.
13844    pub fn parse_exact_number_optional_precision_scale(
13845        &mut self,
13846    ) -> Result<ExactNumberInfo, ParserError> {
13847        if self.consume_token(&Token::LParen) {
13848            let precision = self.parse_literal_uint()?;
13849            let scale = if self.consume_token(&Token::Comma) {
13850                Some(self.parse_signed_integer()?)
13851            } else {
13852                None
13853            };
13854
13855            self.expect_token(&Token::RParen)?;
13856
13857            match scale {
13858                None => Ok(ExactNumberInfo::Precision(precision)),
13859                Some(scale) => Ok(ExactNumberInfo::PrecisionAndScale(precision, scale)),
13860            }
13861        } else {
13862            Ok(ExactNumberInfo::None)
13863        }
13864    }
13865
13866    /// Parse an optionally signed integer literal.
13867    fn parse_signed_integer(&mut self) -> Result<i64, ParserError> {
13868        let is_negative = self.consume_token(&Token::Minus);
13869
13870        if !is_negative {
13871            let _ = self.consume_token(&Token::Plus);
13872        }
13873
13874        let current_token = self.peek_token_ref();
13875        match &current_token.token {
13876            Token::Number(s, _) => {
13877                let s = s.clone();
13878                let span_start = current_token.span.start;
13879                self.advance_token();
13880                let value = Self::parse::<i64>(s, span_start)?;
13881                Ok(if is_negative { -value } else { value })
13882            }
13883            _ => self.expected_ref("number", current_token),
13884        }
13885    }
13886
13887    /// Parse optional type modifiers appearing in parentheses e.g. `(UNSIGNED, ZEROFILL)`.
13888    pub fn parse_optional_type_modifiers(&mut self) -> Result<Option<Vec<String>>, ParserError> {
13889        if self.consume_token(&Token::LParen) {
13890            let mut modifiers = Vec::new();
13891            loop {
13892                let next_token = self.next_token();
13893                match next_token.token {
13894                    Token::Word(w) => modifiers.push(w.to_string()),
13895                    Token::Number(n, _) => modifiers.push(n),
13896                    Token::SingleQuotedString(s) => modifiers.push(s),
13897
13898                    Token::Comma => {
13899                        continue;
13900                    }
13901                    Token::RParen => {
13902                        break;
13903                    }
13904                    _ => self.expected("type modifiers", next_token)?,
13905                }
13906            }
13907
13908            Ok(Some(modifiers))
13909        } else {
13910            Ok(None)
13911        }
13912    }
13913
13914    /// Parse a parenthesized sub data type
13915    fn parse_sub_type<F>(&mut self, parent_type: F) -> Result<DataType, ParserError>
13916    where
13917        F: FnOnce(Box<DataType>) -> DataType,
13918    {
13919        self.expect_token(&Token::LParen)?;
13920        let inside_type = self.parse_data_type()?;
13921        self.expect_token(&Token::RParen)?;
13922        Ok(parent_type(inside_type.into()))
13923    }
13924
13925    /// Parse a DELETE statement, returning a `Box`ed SetExpr
13926    ///
13927    /// This is used to reduce the size of the stack frames in debug builds
13928    fn parse_delete_setexpr_boxed(
13929        &mut self,
13930        delete_token: TokenWithSpan,
13931    ) -> Result<Box<SetExpr>, ParserError> {
13932        Ok(Box::new(SetExpr::Delete(self.parse_delete(delete_token)?)))
13933    }
13934
13935    /// Parse a `DELETE` statement and return `Statement::Delete`.
13936    pub fn parse_delete(&mut self, delete_token: TokenWithSpan) -> Result<Statement, ParserError> {
13937        let optimizer_hints = self.maybe_parse_optimizer_hints()?;
13938        let (tables, with_from_keyword) = if !self.parse_keyword(Keyword::FROM) {
13939            // `FROM` keyword is optional in BigQuery SQL.
13940            // https://cloud.google.com/bigquery/docs/reference/standard-sql/dml-syntax#delete_statement
13941            if dialect_of!(self is BigQueryDialect | OracleDialect | GenericDialect) {
13942                (vec![], false)
13943            } else {
13944                let tables = self.parse_comma_separated(|p| p.parse_object_name(false))?;
13945                self.expect_keyword_is(Keyword::FROM)?;
13946                (tables, true)
13947            }
13948        } else {
13949            (vec![], true)
13950        };
13951
13952        let from = self.parse_comma_separated(Parser::parse_table_and_joins)?;
13953
13954        let output = self.maybe_parse_output_clause()?;
13955
13956        let using = if self.parse_keyword(Keyword::USING) {
13957            Some(self.parse_comma_separated(Parser::parse_table_and_joins)?)
13958        } else {
13959            None
13960        };
13961        let selection = if self.parse_keyword(Keyword::WHERE) {
13962            Some(self.parse_expr()?)
13963        } else {
13964            None
13965        };
13966        let returning = if self.parse_keyword(Keyword::RETURNING) {
13967            Some(self.parse_comma_separated(Parser::parse_select_item)?)
13968        } else {
13969            None
13970        };
13971        let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
13972            self.parse_comma_separated(Parser::parse_order_by_expr)?
13973        } else {
13974            vec![]
13975        };
13976        let limit = if self.parse_keyword(Keyword::LIMIT) {
13977            self.parse_limit()?
13978        } else {
13979            None
13980        };
13981
13982        Ok(Statement::Delete(Delete {
13983            delete_token: delete_token.into(),
13984            optimizer_hints,
13985            tables,
13986            from: if with_from_keyword {
13987                FromTable::WithFromKeyword(from)
13988            } else {
13989                FromTable::WithoutKeyword(from)
13990            },
13991            using,
13992            selection,
13993            returning,
13994            output,
13995            order_by,
13996            limit,
13997        }))
13998    }
13999
14000    /// Parse a `KILL` statement, optionally specifying `CONNECTION`, `QUERY`, or `MUTATION`.
14001    /// KILL [CONNECTION | QUERY | MUTATION] processlist_id
14002    pub fn parse_kill(&mut self) -> Result<Statement, ParserError> {
14003        let modifier_keyword =
14004            self.parse_one_of_keywords(&[Keyword::CONNECTION, Keyword::QUERY, Keyword::MUTATION]);
14005
14006        let id = self.parse_literal_uint()?;
14007
14008        let modifier = match modifier_keyword {
14009            Some(Keyword::CONNECTION) => Some(KillType::Connection),
14010            Some(Keyword::QUERY) => Some(KillType::Query),
14011            Some(Keyword::MUTATION) => {
14012                if dialect_of!(self is ClickHouseDialect | GenericDialect) {
14013                    Some(KillType::Mutation)
14014                } else {
14015                    self.expected_ref(
14016                        "Unsupported type for KILL, allowed: CONNECTION | QUERY",
14017                        self.peek_token_ref(),
14018                    )?
14019                }
14020            }
14021            _ => None,
14022        };
14023
14024        Ok(Statement::Kill { modifier, id })
14025    }
14026
14027    /// Parse an `EXPLAIN` statement, handling dialect-specific options and modifiers.
14028    pub fn parse_explain(
14029        &mut self,
14030        describe_alias: DescribeAlias,
14031    ) -> Result<Statement, ParserError> {
14032        let mut analyze = false;
14033        let mut verbose = false;
14034        let mut query_plan = false;
14035        let mut estimate = false;
14036        let mut format = None;
14037        let mut options = None;
14038
14039        // Note: DuckDB is compatible with PostgreSQL syntax for this statement,
14040        // although not all features may be implemented.
14041        if describe_alias == DescribeAlias::Explain
14042            && self.dialect.supports_explain_with_utility_options()
14043            && self.peek_token_ref().token == Token::LParen
14044        {
14045            options = Some(self.parse_utility_options()?)
14046        } else if self.parse_keywords(&[Keyword::QUERY, Keyword::PLAN]) {
14047            query_plan = true;
14048        } else if self.parse_keyword(Keyword::ESTIMATE) {
14049            estimate = true;
14050        } else {
14051            analyze = self.parse_keyword(Keyword::ANALYZE);
14052            verbose = self.parse_keyword(Keyword::VERBOSE);
14053            if self.parse_keyword(Keyword::FORMAT) {
14054                format = Some(self.parse_analyze_format_kind()?);
14055            }
14056        }
14057
14058        match self.maybe_parse(|parser| parser.parse_statement())? {
14059            Some(Statement::Explain { .. }) | Some(Statement::ExplainTable { .. }) => Err(
14060                ParserError::ParserError("Explain must be root of the plan".to_string()),
14061            ),
14062            Some(statement) => Ok(Statement::Explain {
14063                describe_alias,
14064                analyze,
14065                verbose,
14066                query_plan,
14067                estimate,
14068                statement: Box::new(statement),
14069                format,
14070                options,
14071            }),
14072            _ => {
14073                let hive_format =
14074                    match self.parse_one_of_keywords(&[Keyword::EXTENDED, Keyword::FORMATTED]) {
14075                        Some(Keyword::EXTENDED) => Some(HiveDescribeFormat::Extended),
14076                        Some(Keyword::FORMATTED) => Some(HiveDescribeFormat::Formatted),
14077                        _ => None,
14078                    };
14079
14080                let has_table_keyword = if self.dialect.describe_requires_table_keyword() {
14081                    // only allow to use TABLE keyword for DESC|DESCRIBE statement
14082                    self.parse_keyword(Keyword::TABLE)
14083                } else {
14084                    false
14085                };
14086
14087                let table_name = self.parse_object_name(false)?;
14088                Ok(Statement::ExplainTable {
14089                    describe_alias,
14090                    hive_format,
14091                    has_table_keyword,
14092                    table_name,
14093                })
14094            }
14095        }
14096    }
14097
14098    /// Parse a query expression, i.e. a `SELECT` statement optionally
14099    /// preceded with some `WITH` CTE declarations and optionally followed
14100    /// by `ORDER BY`. Unlike some other parse_... methods, this one doesn't
14101    /// expect the initial keyword to be already consumed
14102    #[cfg_attr(feature = "recursive-protection", recursive::recursive)]
14103    pub fn parse_query(&mut self) -> Result<Box<Query>, ParserError> {
14104        let _guard = self.recursion_counter.try_decrease()?;
14105        let with = if self.parse_keyword(Keyword::WITH) {
14106            let with_token = self.get_current_token();
14107            Some(With {
14108                with_token: with_token.clone().into(),
14109                recursive: self.parse_keyword(Keyword::RECURSIVE),
14110                cte_tables: self.parse_comma_separated(Parser::parse_cte)?,
14111            })
14112        } else {
14113            None
14114        };
14115        if self.parse_keyword(Keyword::INSERT) {
14116            Ok(Query {
14117                with,
14118                body: self.parse_insert_setexpr_boxed(self.get_current_token().clone())?,
14119                order_by: None,
14120                limit_clause: None,
14121                fetch: None,
14122                locks: vec![],
14123                for_clause: None,
14124                settings: None,
14125                format_clause: None,
14126                pipe_operators: vec![],
14127            }
14128            .into())
14129        } else if self.parse_keyword(Keyword::UPDATE) {
14130            Ok(Query {
14131                with,
14132                body: self.parse_update_setexpr_boxed(self.get_current_token().clone())?,
14133                order_by: None,
14134                limit_clause: None,
14135                fetch: None,
14136                locks: vec![],
14137                for_clause: None,
14138                settings: None,
14139                format_clause: None,
14140                pipe_operators: vec![],
14141            }
14142            .into())
14143        } else if self.parse_keyword(Keyword::DELETE) {
14144            Ok(Query {
14145                with,
14146                body: self.parse_delete_setexpr_boxed(self.get_current_token().clone())?,
14147                limit_clause: None,
14148                order_by: None,
14149                fetch: None,
14150                locks: vec![],
14151                for_clause: None,
14152                settings: None,
14153                format_clause: None,
14154                pipe_operators: vec![],
14155            }
14156            .into())
14157        } else if self.parse_keyword(Keyword::MERGE) {
14158            Ok(Query {
14159                with,
14160                body: self.parse_merge_setexpr_boxed(self.get_current_token().clone())?,
14161                limit_clause: None,
14162                order_by: None,
14163                fetch: None,
14164                locks: vec![],
14165                for_clause: None,
14166                settings: None,
14167                format_clause: None,
14168                pipe_operators: vec![],
14169            }
14170            .into())
14171        } else {
14172            let body = self.parse_query_body(self.dialect.prec_unknown())?;
14173
14174            let order_by = self.parse_optional_order_by()?;
14175
14176            let limit_clause = self.parse_optional_limit_clause()?;
14177
14178            let settings = self.parse_settings()?;
14179
14180            let fetch = if self.parse_keyword(Keyword::FETCH) {
14181                Some(self.parse_fetch()?)
14182            } else {
14183                None
14184            };
14185
14186            let mut for_clause = None;
14187            let mut locks = Vec::new();
14188            while self.parse_keyword(Keyword::FOR) {
14189                if let Some(parsed_for_clause) = self.parse_for_clause()? {
14190                    for_clause = Some(parsed_for_clause);
14191                    break;
14192                } else {
14193                    locks.push(self.parse_lock()?);
14194                }
14195            }
14196            let format_clause =
14197                if self.dialect.supports_select_format() && self.parse_keyword(Keyword::FORMAT) {
14198                    if self.parse_keyword(Keyword::NULL) {
14199                        Some(FormatClause::Null)
14200                    } else {
14201                        let ident = self.parse_identifier()?;
14202                        Some(FormatClause::Identifier(ident))
14203                    }
14204                } else {
14205                    None
14206                };
14207
14208            let pipe_operators = if self.dialect.supports_pipe_operator() {
14209                self.parse_pipe_operators()?
14210            } else {
14211                Vec::new()
14212            };
14213
14214            Ok(Query {
14215                with,
14216                body,
14217                order_by,
14218                limit_clause,
14219                fetch,
14220                locks,
14221                for_clause,
14222                settings,
14223                format_clause,
14224                pipe_operators,
14225            }
14226            .into())
14227        }
14228    }
14229
14230    fn parse_pipe_operators(&mut self) -> Result<Vec<PipeOperator>, ParserError> {
14231        let mut pipe_operators = Vec::new();
14232
14233        while self.consume_token(&Token::VerticalBarRightAngleBracket) {
14234            let kw = self.expect_one_of_keywords(&[
14235                Keyword::SELECT,
14236                Keyword::EXTEND,
14237                Keyword::SET,
14238                Keyword::DROP,
14239                Keyword::AS,
14240                Keyword::WHERE,
14241                Keyword::LIMIT,
14242                Keyword::AGGREGATE,
14243                Keyword::ORDER,
14244                Keyword::TABLESAMPLE,
14245                Keyword::RENAME,
14246                Keyword::UNION,
14247                Keyword::INTERSECT,
14248                Keyword::EXCEPT,
14249                Keyword::CALL,
14250                Keyword::PIVOT,
14251                Keyword::UNPIVOT,
14252                Keyword::JOIN,
14253                Keyword::INNER,
14254                Keyword::LEFT,
14255                Keyword::RIGHT,
14256                Keyword::FULL,
14257                Keyword::CROSS,
14258            ])?;
14259            match kw {
14260                Keyword::SELECT => {
14261                    let exprs = self.parse_comma_separated(Parser::parse_select_item)?;
14262                    pipe_operators.push(PipeOperator::Select { exprs })
14263                }
14264                Keyword::EXTEND => {
14265                    let exprs = self.parse_comma_separated(Parser::parse_select_item)?;
14266                    pipe_operators.push(PipeOperator::Extend { exprs })
14267                }
14268                Keyword::SET => {
14269                    let assignments = self.parse_comma_separated(Parser::parse_assignment)?;
14270                    pipe_operators.push(PipeOperator::Set { assignments })
14271                }
14272                Keyword::DROP => {
14273                    let columns = self.parse_identifiers()?;
14274                    pipe_operators.push(PipeOperator::Drop { columns })
14275                }
14276                Keyword::AS => {
14277                    let alias = self.parse_identifier()?;
14278                    pipe_operators.push(PipeOperator::As { alias })
14279                }
14280                Keyword::WHERE => {
14281                    let expr = self.parse_expr()?;
14282                    pipe_operators.push(PipeOperator::Where { expr })
14283                }
14284                Keyword::LIMIT => {
14285                    let expr = self.parse_expr()?;
14286                    let offset = if self.parse_keyword(Keyword::OFFSET) {
14287                        Some(self.parse_expr()?)
14288                    } else {
14289                        None
14290                    };
14291                    pipe_operators.push(PipeOperator::Limit { expr, offset })
14292                }
14293                Keyword::AGGREGATE => {
14294                    let full_table_exprs = if self.peek_keyword(Keyword::GROUP) {
14295                        vec![]
14296                    } else {
14297                        self.parse_comma_separated(|parser| {
14298                            parser.parse_expr_with_alias_and_order_by()
14299                        })?
14300                    };
14301
14302                    let group_by_expr = if self.parse_keywords(&[Keyword::GROUP, Keyword::BY]) {
14303                        self.parse_comma_separated(|parser| {
14304                            parser.parse_expr_with_alias_and_order_by()
14305                        })?
14306                    } else {
14307                        vec![]
14308                    };
14309
14310                    pipe_operators.push(PipeOperator::Aggregate {
14311                        full_table_exprs,
14312                        group_by_expr,
14313                    })
14314                }
14315                Keyword::ORDER => {
14316                    self.expect_one_of_keywords(&[Keyword::BY])?;
14317                    let exprs = self.parse_comma_separated(Parser::parse_order_by_expr)?;
14318                    pipe_operators.push(PipeOperator::OrderBy { exprs })
14319                }
14320                Keyword::TABLESAMPLE => {
14321                    let sample = self.parse_table_sample(TableSampleModifier::TableSample)?;
14322                    pipe_operators.push(PipeOperator::TableSample { sample });
14323                }
14324                Keyword::RENAME => {
14325                    let mappings =
14326                        self.parse_comma_separated(Parser::parse_identifier_with_optional_alias)?;
14327                    pipe_operators.push(PipeOperator::Rename { mappings });
14328                }
14329                Keyword::UNION => {
14330                    let set_quantifier = self.parse_set_quantifier(&Some(SetOperator::Union));
14331                    let queries = self.parse_pipe_operator_queries()?;
14332                    pipe_operators.push(PipeOperator::Union {
14333                        set_quantifier,
14334                        queries,
14335                    });
14336                }
14337                Keyword::INTERSECT => {
14338                    let set_quantifier =
14339                        self.parse_distinct_required_set_quantifier("INTERSECT")?;
14340                    let queries = self.parse_pipe_operator_queries()?;
14341                    pipe_operators.push(PipeOperator::Intersect {
14342                        set_quantifier,
14343                        queries,
14344                    });
14345                }
14346                Keyword::EXCEPT => {
14347                    let set_quantifier = self.parse_distinct_required_set_quantifier("EXCEPT")?;
14348                    let queries = self.parse_pipe_operator_queries()?;
14349                    pipe_operators.push(PipeOperator::Except {
14350                        set_quantifier,
14351                        queries,
14352                    });
14353                }
14354                Keyword::CALL => {
14355                    let function_name = self.parse_object_name(false)?;
14356                    let function_expr = self.parse_function(function_name)?;
14357                    if let Expr::Function(function) = function_expr {
14358                        let alias = self.parse_identifier_optional_alias()?;
14359                        pipe_operators.push(PipeOperator::Call { function, alias });
14360                    } else {
14361                        return Err(ParserError::ParserError(
14362                            "Expected function call after CALL".to_string(),
14363                        ));
14364                    }
14365                }
14366                Keyword::PIVOT => {
14367                    self.expect_token(&Token::LParen)?;
14368                    let aggregate_functions =
14369                        self.parse_comma_separated(Self::parse_pivot_aggregate_function)?;
14370                    self.expect_keyword_is(Keyword::FOR)?;
14371                    let value_column = self.parse_period_separated(|p| p.parse_identifier())?;
14372                    self.expect_keyword_is(Keyword::IN)?;
14373
14374                    self.expect_token(&Token::LParen)?;
14375                    let value_source = if self.parse_keyword(Keyword::ANY) {
14376                        let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
14377                            self.parse_comma_separated(Parser::parse_order_by_expr)?
14378                        } else {
14379                            vec![]
14380                        };
14381                        PivotValueSource::Any(order_by)
14382                    } else if self.peek_sub_query() {
14383                        PivotValueSource::Subquery(self.parse_query()?)
14384                    } else {
14385                        PivotValueSource::List(
14386                            self.parse_comma_separated(Self::parse_expr_with_alias)?,
14387                        )
14388                    };
14389                    self.expect_token(&Token::RParen)?;
14390                    self.expect_token(&Token::RParen)?;
14391
14392                    let alias = self.parse_identifier_optional_alias()?;
14393
14394                    pipe_operators.push(PipeOperator::Pivot {
14395                        aggregate_functions,
14396                        value_column,
14397                        value_source,
14398                        alias,
14399                    });
14400                }
14401                Keyword::UNPIVOT => {
14402                    self.expect_token(&Token::LParen)?;
14403                    let value_column = self.parse_identifier()?;
14404                    self.expect_keyword(Keyword::FOR)?;
14405                    let name_column = self.parse_identifier()?;
14406                    self.expect_keyword(Keyword::IN)?;
14407
14408                    self.expect_token(&Token::LParen)?;
14409                    let unpivot_columns = self.parse_comma_separated(Parser::parse_identifier)?;
14410                    self.expect_token(&Token::RParen)?;
14411
14412                    self.expect_token(&Token::RParen)?;
14413
14414                    let alias = self.parse_identifier_optional_alias()?;
14415
14416                    pipe_operators.push(PipeOperator::Unpivot {
14417                        value_column,
14418                        name_column,
14419                        unpivot_columns,
14420                        alias,
14421                    });
14422                }
14423                Keyword::JOIN
14424                | Keyword::INNER
14425                | Keyword::LEFT
14426                | Keyword::RIGHT
14427                | Keyword::FULL
14428                | Keyword::CROSS => {
14429                    self.prev_token();
14430                    let mut joins = self.parse_joins()?;
14431                    if joins.len() != 1 {
14432                        return Err(ParserError::ParserError(
14433                            "Join pipe operator must have a single join".to_string(),
14434                        ));
14435                    }
14436                    let join = joins.swap_remove(0);
14437                    pipe_operators.push(PipeOperator::Join(join))
14438                }
14439                unhandled => {
14440                    return Err(ParserError::ParserError(format!(
14441                    "`expect_one_of_keywords` further up allowed unhandled keyword: {unhandled:?}"
14442                )))
14443                }
14444            }
14445        }
14446        Ok(pipe_operators)
14447    }
14448
14449    fn parse_settings(&mut self) -> Result<Option<Vec<Setting>>, ParserError> {
14450        let settings = if self.dialect.supports_settings() && self.parse_keyword(Keyword::SETTINGS)
14451        {
14452            let key_values = self.parse_comma_separated(|p| {
14453                let key = p.parse_identifier()?;
14454                p.expect_token(&Token::Eq)?;
14455                let value = p.parse_expr()?;
14456                Ok(Setting { key, value })
14457            })?;
14458            Some(key_values)
14459        } else {
14460            None
14461        };
14462        Ok(settings)
14463    }
14464
14465    /// Parse a mssql `FOR [XML | JSON | BROWSE]` clause
14466    pub fn parse_for_clause(&mut self) -> Result<Option<ForClause>, ParserError> {
14467        if self.parse_keyword(Keyword::XML) {
14468            Ok(Some(self.parse_for_xml()?))
14469        } else if self.parse_keyword(Keyword::JSON) {
14470            Ok(Some(self.parse_for_json()?))
14471        } else if self.parse_keyword(Keyword::BROWSE) {
14472            Ok(Some(ForClause::Browse))
14473        } else {
14474            Ok(None)
14475        }
14476    }
14477
14478    /// Parse a mssql `FOR XML` clause
14479    pub fn parse_for_xml(&mut self) -> Result<ForClause, ParserError> {
14480        let for_xml = if self.parse_keyword(Keyword::RAW) {
14481            let mut element_name = None;
14482            if self.peek_token_ref().token == Token::LParen {
14483                self.expect_token(&Token::LParen)?;
14484                element_name = Some(self.parse_literal_string()?);
14485                self.expect_token(&Token::RParen)?;
14486            }
14487            ForXml::Raw(element_name)
14488        } else if self.parse_keyword(Keyword::AUTO) {
14489            ForXml::Auto
14490        } else if self.parse_keyword(Keyword::EXPLICIT) {
14491            ForXml::Explicit
14492        } else if self.parse_keyword(Keyword::PATH) {
14493            let mut element_name = None;
14494            if self.peek_token_ref().token == Token::LParen {
14495                self.expect_token(&Token::LParen)?;
14496                element_name = Some(self.parse_literal_string()?);
14497                self.expect_token(&Token::RParen)?;
14498            }
14499            ForXml::Path(element_name)
14500        } else {
14501            return Err(ParserError::ParserError(
14502                "Expected FOR XML [RAW | AUTO | EXPLICIT | PATH ]".to_string(),
14503            ));
14504        };
14505        let mut elements = false;
14506        let mut binary_base64 = false;
14507        let mut root = None;
14508        let mut r#type = false;
14509        while self.peek_token_ref().token == Token::Comma {
14510            self.next_token();
14511            if self.parse_keyword(Keyword::ELEMENTS) {
14512                elements = true;
14513            } else if self.parse_keyword(Keyword::BINARY) {
14514                self.expect_keyword_is(Keyword::BASE64)?;
14515                binary_base64 = true;
14516            } else if self.parse_keyword(Keyword::ROOT) {
14517                self.expect_token(&Token::LParen)?;
14518                root = Some(self.parse_literal_string()?);
14519                self.expect_token(&Token::RParen)?;
14520            } else if self.parse_keyword(Keyword::TYPE) {
14521                r#type = true;
14522            }
14523        }
14524        Ok(ForClause::Xml {
14525            for_xml,
14526            elements,
14527            binary_base64,
14528            root,
14529            r#type,
14530        })
14531    }
14532
14533    /// Parse a mssql `FOR JSON` clause
14534    pub fn parse_for_json(&mut self) -> Result<ForClause, ParserError> {
14535        let for_json = if self.parse_keyword(Keyword::AUTO) {
14536            ForJson::Auto
14537        } else if self.parse_keyword(Keyword::PATH) {
14538            ForJson::Path
14539        } else {
14540            return Err(ParserError::ParserError(
14541                "Expected FOR JSON [AUTO | PATH ]".to_string(),
14542            ));
14543        };
14544        let mut root = None;
14545        let mut include_null_values = false;
14546        let mut without_array_wrapper = false;
14547        while self.peek_token_ref().token == Token::Comma {
14548            self.next_token();
14549            if self.parse_keyword(Keyword::ROOT) {
14550                self.expect_token(&Token::LParen)?;
14551                root = Some(self.parse_literal_string()?);
14552                self.expect_token(&Token::RParen)?;
14553            } else if self.parse_keyword(Keyword::INCLUDE_NULL_VALUES) {
14554                include_null_values = true;
14555            } else if self.parse_keyword(Keyword::WITHOUT_ARRAY_WRAPPER) {
14556                without_array_wrapper = true;
14557            }
14558        }
14559        Ok(ForClause::Json {
14560            for_json,
14561            root,
14562            include_null_values,
14563            without_array_wrapper,
14564        })
14565    }
14566
14567    /// Parse a CTE (`alias [( col1, col2, ... )] [AS] (subquery)`)
14568    pub fn parse_cte(&mut self) -> Result<Cte, ParserError> {
14569        let name = self.parse_identifier()?;
14570
14571        let as_optional = self.dialect.supports_cte_without_as();
14572
14573        // If AS is optional, first try to parse `name (query)` directly
14574        if as_optional && !self.peek_keyword(Keyword::AS) {
14575            if let Some((query, closing_paren_token)) = self.maybe_parse(|p| {
14576                p.expect_token(&Token::LParen)?;
14577                let query = p.parse_query()?;
14578                let closing_paren_token = p.expect_token(&Token::RParen)?;
14579                Ok((query, closing_paren_token))
14580            })? {
14581                let mut cte = Cte {
14582                    alias: TableAlias {
14583                        explicit: false,
14584                        name,
14585                        columns: vec![],
14586                        at: None,
14587                    },
14588                    query,
14589                    from: None,
14590                    materialized: None,
14591                    closing_paren_token: closing_paren_token.into(),
14592                };
14593                if self.parse_keyword(Keyword::FROM) {
14594                    cte.from = Some(self.parse_identifier()?);
14595                }
14596                return Ok(cte);
14597            }
14598        }
14599
14600        // Determine column definitions and consume AS
14601        let columns = if self.parse_keyword(Keyword::AS) {
14602            vec![]
14603        } else {
14604            let columns = self.parse_table_alias_column_defs()?;
14605            if as_optional {
14606                let _ = self.parse_keyword(Keyword::AS);
14607            } else {
14608                self.expect_keyword_is(Keyword::AS)?;
14609            }
14610            columns
14611        };
14612
14613        let mut is_materialized = None;
14614        if dialect_of!(self is PostgreSqlDialect) {
14615            if self.parse_keyword(Keyword::MATERIALIZED) {
14616                is_materialized = Some(CteAsMaterialized::Materialized);
14617            } else if self.parse_keywords(&[Keyword::NOT, Keyword::MATERIALIZED]) {
14618                is_materialized = Some(CteAsMaterialized::NotMaterialized);
14619            }
14620        }
14621
14622        self.expect_token(&Token::LParen)?;
14623        let query = self.parse_query()?;
14624        let closing_paren_token = self.expect_token(&Token::RParen)?;
14625
14626        let mut cte = Cte {
14627            alias: TableAlias {
14628                explicit: false,
14629                name,
14630                columns,
14631                at: None,
14632            },
14633            query,
14634            from: None,
14635            materialized: is_materialized,
14636            closing_paren_token: closing_paren_token.into(),
14637        };
14638        if self.dialect.supports_from_first_insert() && self.parse_keyword(Keyword::FROM) {
14639            cte.from = Some(self.parse_identifier()?);
14640        }
14641        Ok(cte)
14642    }
14643
14644    /// Parse a "query body", which is an expression with roughly the
14645    /// following grammar:
14646    /// ```sql
14647    ///   query_body ::= restricted_select | '(' subquery ')' | set_operation
14648    ///   restricted_select ::= 'SELECT' [expr_list] [ from ] [ where ] [ groupby_having ]
14649    ///   subquery ::= query_body [ order_by_limit ]
14650    ///   set_operation ::= query_body { 'UNION' | 'EXCEPT' | 'INTERSECT' } [ 'ALL' ] query_body
14651    /// ```
14652    pub fn parse_query_body(&mut self, precedence: u8) -> Result<Box<SetExpr>, ParserError> {
14653        // We parse the expression using a Pratt parser, as in `parse_expr()`.
14654        // Start by parsing a restricted SELECT or a `(subquery)`:
14655        let expr = if self.peek_keyword(Keyword::SELECT)
14656            || (self.peek_keyword(Keyword::FROM) && self.dialect.supports_from_first_select())
14657        {
14658            SetExpr::Select(self.parse_select().map(Box::new)?)
14659        } else if self.consume_token(&Token::LParen) {
14660            // CTEs are not allowed here, but the parser currently accepts them
14661            let subquery = self.parse_query()?;
14662            self.expect_token(&Token::RParen)?;
14663            SetExpr::Query(subquery)
14664        } else if self.parse_keyword(Keyword::VALUES) {
14665            let is_mysql = dialect_of!(self is MySqlDialect);
14666            SetExpr::Values(self.parse_values(is_mysql, false)?)
14667        } else if self.parse_keyword(Keyword::VALUE) {
14668            let is_mysql = dialect_of!(self is MySqlDialect);
14669            SetExpr::Values(self.parse_values(is_mysql, true)?)
14670        } else if self.parse_keyword(Keyword::TABLE) {
14671            SetExpr::Table(Box::new(self.parse_as_table()?))
14672        } else {
14673            return self.expected_ref(
14674                "SELECT, VALUES, or a subquery in the query body",
14675                self.peek_token_ref(),
14676            );
14677        };
14678
14679        self.parse_remaining_set_exprs(expr, precedence)
14680    }
14681
14682    /// Parse any extra set expressions that may be present in a query body
14683    ///
14684    /// (this is its own function to reduce required stack size in debug builds)
14685    fn parse_remaining_set_exprs(
14686        &mut self,
14687        mut expr: SetExpr,
14688        precedence: u8,
14689    ) -> Result<Box<SetExpr>, ParserError> {
14690        loop {
14691            // The query can be optionally followed by a set operator:
14692            let op = self.parse_set_operator(&self.peek_token().token);
14693            let next_precedence = match op {
14694                // UNION and EXCEPT have the same binding power and evaluate left-to-right
14695                Some(SetOperator::Union) | Some(SetOperator::Except) | Some(SetOperator::Minus) => {
14696                    10
14697                }
14698                // INTERSECT has higher precedence than UNION/EXCEPT
14699                Some(SetOperator::Intersect) => 20,
14700                // Unexpected token or EOF => stop parsing the query body
14701                None => break,
14702            };
14703            if precedence >= next_precedence {
14704                break;
14705            }
14706            self.next_token(); // skip past the set operator
14707            let set_quantifier = self.parse_set_quantifier(&op);
14708            expr = SetExpr::SetOperation {
14709                left: Box::new(expr),
14710                op: op.unwrap(),
14711                set_quantifier,
14712                right: self.parse_query_body(next_precedence)?,
14713            };
14714        }
14715
14716        Ok(expr.into())
14717    }
14718
14719    /// Parse a set operator token into its `SetOperator` variant.
14720    pub fn parse_set_operator(&mut self, token: &Token) -> Option<SetOperator> {
14721        match token {
14722            Token::Word(w) if w.keyword == Keyword::UNION => Some(SetOperator::Union),
14723            Token::Word(w) if w.keyword == Keyword::EXCEPT => Some(SetOperator::Except),
14724            Token::Word(w) if w.keyword == Keyword::INTERSECT => Some(SetOperator::Intersect),
14725            Token::Word(w) if w.keyword == Keyword::MINUS => Some(SetOperator::Minus),
14726            _ => None,
14727        }
14728    }
14729
14730    /// Parse a set quantifier (e.g., `ALL`, `DISTINCT BY NAME`) for the given set operator.
14731    pub fn parse_set_quantifier(&mut self, op: &Option<SetOperator>) -> SetQuantifier {
14732        match op {
14733            Some(
14734                SetOperator::Except
14735                | SetOperator::Intersect
14736                | SetOperator::Union
14737                | SetOperator::Minus,
14738            ) => {
14739                if self.parse_keywords(&[Keyword::DISTINCT, Keyword::BY, Keyword::NAME]) {
14740                    SetQuantifier::DistinctByName
14741                } else if self.parse_keywords(&[Keyword::BY, Keyword::NAME]) {
14742                    SetQuantifier::ByName
14743                } else if self.parse_keyword(Keyword::ALL) {
14744                    if self.parse_keywords(&[Keyword::BY, Keyword::NAME]) {
14745                        SetQuantifier::AllByName
14746                    } else {
14747                        SetQuantifier::All
14748                    }
14749                } else if self.parse_keyword(Keyword::DISTINCT) {
14750                    SetQuantifier::Distinct
14751                } else {
14752                    SetQuantifier::None
14753                }
14754            }
14755            _ => SetQuantifier::None,
14756        }
14757    }
14758
14759    /// Parse a restricted `SELECT` statement (no CTEs / `UNION` / `ORDER BY`)
14760    pub fn parse_select(&mut self) -> Result<Select, ParserError> {
14761        let mut from_first = None;
14762
14763        if self.dialect.supports_from_first_select() && self.peek_keyword(Keyword::FROM) {
14764            let from_token = self.expect_keyword(Keyword::FROM)?;
14765            let from = self.parse_table_with_joins()?;
14766            if !self.peek_keyword(Keyword::SELECT) {
14767                return Ok(Select {
14768                    select_token: AttachedToken(from_token),
14769                    optimizer_hints: vec![],
14770                    distinct: None,
14771                    select_modifiers: None,
14772                    top: None,
14773                    top_before_distinct: false,
14774                    projection: vec![],
14775                    exclude: None,
14776                    into: None,
14777                    from,
14778                    lateral_views: vec![],
14779                    prewhere: None,
14780                    selection: None,
14781                    group_by: GroupByExpr::Expressions(vec![], vec![]),
14782                    cluster_by: vec![],
14783                    distribute_by: vec![],
14784                    sort_by: vec![],
14785                    having: None,
14786                    named_window: vec![],
14787                    window_before_qualify: false,
14788                    qualify: None,
14789                    value_table_mode: None,
14790                    connect_by: vec![],
14791                    flavor: SelectFlavor::FromFirstNoSelect,
14792                });
14793            }
14794            from_first = Some(from);
14795        }
14796
14797        let select_token = self.expect_keyword(Keyword::SELECT)?;
14798        let optimizer_hints = self.maybe_parse_optimizer_hints()?;
14799        let value_table_mode = self.parse_value_table_mode()?;
14800
14801        let (select_modifiers, distinct_select_modifier) =
14802            if self.dialect.supports_select_modifiers() {
14803                self.parse_select_modifiers()?
14804            } else {
14805                (None, None)
14806            };
14807
14808        let mut top_before_distinct = false;
14809        let mut top = None;
14810        if self.dialect.supports_top_before_distinct() && self.parse_keyword(Keyword::TOP) {
14811            top = Some(self.parse_top()?);
14812            top_before_distinct = true;
14813        }
14814
14815        let distinct = if distinct_select_modifier.is_some() {
14816            distinct_select_modifier
14817        } else {
14818            self.parse_all_or_distinct()?
14819        };
14820
14821        if !self.dialect.supports_top_before_distinct() && self.parse_keyword(Keyword::TOP) {
14822            top = Some(self.parse_top()?);
14823        }
14824
14825        let projection =
14826            if self.dialect.supports_empty_projections() && self.peek_keyword(Keyword::FROM) {
14827                vec![]
14828            } else {
14829                self.parse_projection()?
14830            };
14831
14832        let exclude = if self.dialect.supports_select_exclude() {
14833            self.parse_optional_select_item_exclude()?
14834        } else {
14835            None
14836        };
14837
14838        let into = if self.parse_keyword(Keyword::INTO) {
14839            Some(self.parse_select_into()?)
14840        } else {
14841            None
14842        };
14843
14844        // Note that for keywords to be properly handled here, they need to be
14845        // added to `RESERVED_FOR_COLUMN_ALIAS` / `RESERVED_FOR_TABLE_ALIAS`,
14846        // otherwise they may be parsed as an alias as part of the `projection`
14847        // or `from`.
14848
14849        let (from, from_first) = if let Some(from) = from_first.take() {
14850            (from, true)
14851        } else if self.parse_keyword(Keyword::FROM) {
14852            (self.parse_table_with_joins()?, false)
14853        } else {
14854            (vec![], false)
14855        };
14856
14857        let mut lateral_views = vec![];
14858        loop {
14859            if self.parse_keywords(&[Keyword::LATERAL, Keyword::VIEW]) {
14860                let outer = self.parse_keyword(Keyword::OUTER);
14861                let lateral_view = self.parse_expr()?;
14862                let lateral_view_name = self.parse_object_name(false)?;
14863                let lateral_col_alias = self
14864                    .parse_comma_separated(|parser| {
14865                        parser.parse_optional_alias(&[
14866                            Keyword::WHERE,
14867                            Keyword::GROUP,
14868                            Keyword::CLUSTER,
14869                            Keyword::HAVING,
14870                            Keyword::LATERAL,
14871                        ]) // This couldn't possibly be a bad idea
14872                    })?
14873                    .into_iter()
14874                    .flatten()
14875                    .collect();
14876
14877                lateral_views.push(LateralView {
14878                    lateral_view,
14879                    lateral_view_name,
14880                    lateral_col_alias,
14881                    outer,
14882                });
14883            } else {
14884                break;
14885            }
14886        }
14887
14888        let prewhere = if self.dialect.supports_prewhere() && self.parse_keyword(Keyword::PREWHERE)
14889        {
14890            Some(self.parse_expr()?)
14891        } else {
14892            None
14893        };
14894
14895        let selection = if self.parse_keyword(Keyword::WHERE) {
14896            Some(self.parse_expr()?)
14897        } else {
14898            None
14899        };
14900
14901        let connect_by = self.maybe_parse_connect_by()?;
14902
14903        let group_by = self
14904            .parse_optional_group_by()?
14905            .unwrap_or_else(|| GroupByExpr::Expressions(vec![], vec![]));
14906
14907        let cluster_by = if self.parse_keywords(&[Keyword::CLUSTER, Keyword::BY]) {
14908            self.parse_comma_separated(Parser::parse_expr)?
14909        } else {
14910            vec![]
14911        };
14912
14913        let distribute_by = if self.parse_keywords(&[Keyword::DISTRIBUTE, Keyword::BY]) {
14914            self.parse_comma_separated(Parser::parse_expr)?
14915        } else {
14916            vec![]
14917        };
14918
14919        let sort_by = if self.parse_keywords(&[Keyword::SORT, Keyword::BY]) {
14920            self.parse_comma_separated(Parser::parse_order_by_expr)?
14921        } else {
14922            vec![]
14923        };
14924
14925        let having = if self.parse_keyword(Keyword::HAVING) {
14926            Some(self.parse_expr()?)
14927        } else {
14928            None
14929        };
14930
14931        // Accept QUALIFY and WINDOW in any order and flag accordingly.
14932        let (named_windows, qualify, window_before_qualify) = if self.parse_keyword(Keyword::WINDOW)
14933        {
14934            let named_windows = self.parse_comma_separated(Parser::parse_named_window)?;
14935            if self.parse_keyword(Keyword::QUALIFY) {
14936                (named_windows, Some(self.parse_expr()?), true)
14937            } else {
14938                (named_windows, None, true)
14939            }
14940        } else if self.parse_keyword(Keyword::QUALIFY) {
14941            let qualify = Some(self.parse_expr()?);
14942            if self.parse_keyword(Keyword::WINDOW) {
14943                (
14944                    self.parse_comma_separated(Parser::parse_named_window)?,
14945                    qualify,
14946                    false,
14947                )
14948            } else {
14949                (Default::default(), qualify, false)
14950            }
14951        } else {
14952            Default::default()
14953        };
14954
14955        Ok(Select {
14956            select_token: AttachedToken(select_token),
14957            optimizer_hints,
14958            distinct,
14959            select_modifiers,
14960            top,
14961            top_before_distinct,
14962            projection,
14963            exclude,
14964            into,
14965            from,
14966            lateral_views,
14967            prewhere,
14968            selection,
14969            group_by,
14970            cluster_by,
14971            distribute_by,
14972            sort_by,
14973            having,
14974            named_window: named_windows,
14975            window_before_qualify,
14976            qualify,
14977            value_table_mode,
14978            connect_by,
14979            flavor: if from_first {
14980                SelectFlavor::FromFirst
14981            } else {
14982                SelectFlavor::Standard
14983            },
14984        })
14985    }
14986
14987    /// Parses optimizer hints at the current token position.
14988    ///
14989    /// Collects all `/*prefix+...*/` and `--prefix+...` patterns.
14990    /// The `prefix` is any run of ASCII alphanumeric characters between the
14991    /// comment marker and `+` (e.g. `""` for `/*+...*/`, `"abc"` for `/*abc+...*/`).
14992    ///
14993    /// [MySQL](https://dev.mysql.com/doc/refman/8.4/en/optimizer-hints.html#optimizer-hints-overview)
14994    /// [Oracle](https://docs.oracle.com/en/database/oracle/oracle-database/21/sqlrf/Comments.html#GUID-D316D545-89E2-4D54-977F-FC97815CD62E)
14995    fn maybe_parse_optimizer_hints(&mut self) -> Result<Vec<OptimizerHint>, ParserError> {
14996        let supports_hints = self.dialect.supports_comment_optimizer_hint();
14997        if !supports_hints {
14998            return Ok(vec![]);
14999        }
15000        let mut hints = vec![];
15001        loop {
15002            let t = self.peek_nth_token_no_skip_ref(0);
15003            let Token::Whitespace(ws) = &t.token else {
15004                break;
15005            };
15006            match ws {
15007                Whitespace::SingleLineComment { comment, prefix } => {
15008                    if let Some((hint_prefix, text)) = Self::extract_hint_prefix_and_text(comment) {
15009                        hints.push(OptimizerHint {
15010                            prefix: hint_prefix,
15011                            text,
15012                            style: OptimizerHintStyle::SingleLine {
15013                                prefix: prefix.clone(),
15014                            },
15015                        });
15016                    }
15017                    self.next_token_no_skip();
15018                }
15019                Whitespace::MultiLineComment(comment) => {
15020                    if let Some((hint_prefix, text)) = Self::extract_hint_prefix_and_text(comment) {
15021                        hints.push(OptimizerHint {
15022                            prefix: hint_prefix,
15023                            text,
15024                            style: OptimizerHintStyle::MultiLine,
15025                        });
15026                    }
15027                    self.next_token_no_skip();
15028                }
15029                Whitespace::Space | Whitespace::Tab | Whitespace::Newline => {
15030                    self.next_token_no_skip();
15031                }
15032            }
15033        }
15034        Ok(hints)
15035    }
15036
15037    /// Checks if a comment's content starts with `[ASCII-alphanumeric]*+`
15038    /// and returns `(prefix, text_after_plus)` if so.
15039    fn extract_hint_prefix_and_text(comment: &str) -> Option<(String, String)> {
15040        let (before_plus, text) = comment.split_once('+')?;
15041        if before_plus.chars().all(|c| c.is_ascii_alphanumeric()) {
15042            Some((before_plus.to_string(), text.to_string()))
15043        } else {
15044            None
15045        }
15046    }
15047
15048    /// Parses MySQL SELECT modifiers and DISTINCT/ALL in any order.
15049    ///
15050    /// Manual testing shows odifiers can appear in any order, and modifiers other than DISTINCT/ALL
15051    /// can be repeated.
15052    ///
15053    /// <https://dev.mysql.com/doc/refman/8.4/en/select.html>
15054    fn parse_select_modifiers(
15055        &mut self,
15056    ) -> Result<(Option<SelectModifiers>, Option<Distinct>), ParserError> {
15057        let mut modifiers = SelectModifiers::default();
15058        let mut distinct = None;
15059
15060        let keywords = &[
15061            Keyword::ALL,
15062            Keyword::DISTINCT,
15063            Keyword::DISTINCTROW,
15064            Keyword::HIGH_PRIORITY,
15065            Keyword::STRAIGHT_JOIN,
15066            Keyword::SQL_SMALL_RESULT,
15067            Keyword::SQL_BIG_RESULT,
15068            Keyword::SQL_BUFFER_RESULT,
15069            Keyword::SQL_NO_CACHE,
15070            Keyword::SQL_CALC_FOUND_ROWS,
15071        ];
15072
15073        while let Some(keyword) = self.parse_one_of_keywords(keywords) {
15074            match keyword {
15075                Keyword::ALL | Keyword::DISTINCT if distinct.is_none() => {
15076                    self.prev_token();
15077                    distinct = self.parse_all_or_distinct()?;
15078                }
15079                // DISTINCTROW is a MySQL-specific legacy (but not deprecated) alias for DISTINCT
15080                Keyword::DISTINCTROW if distinct.is_none() => {
15081                    distinct = Some(Distinct::Distinct);
15082                }
15083                Keyword::HIGH_PRIORITY => modifiers.high_priority = true,
15084                Keyword::STRAIGHT_JOIN => modifiers.straight_join = true,
15085                Keyword::SQL_SMALL_RESULT => modifiers.sql_small_result = true,
15086                Keyword::SQL_BIG_RESULT => modifiers.sql_big_result = true,
15087                Keyword::SQL_BUFFER_RESULT => modifiers.sql_buffer_result = true,
15088                Keyword::SQL_NO_CACHE => modifiers.sql_no_cache = true,
15089                Keyword::SQL_CALC_FOUND_ROWS => modifiers.sql_calc_found_rows = true,
15090                _ => {
15091                    self.prev_token();
15092                    return self.expected_ref(
15093                        "HIGH_PRIORITY, STRAIGHT_JOIN, or other MySQL select modifier",
15094                        self.peek_token_ref(),
15095                    );
15096                }
15097            }
15098        }
15099
15100        // Avoid polluting the AST with `Some(SelectModifiers::default())` empty value unless there
15101        // actually were some modifiers set.
15102        let select_modifiers = if modifiers.is_any_set() {
15103            Some(modifiers)
15104        } else {
15105            None
15106        };
15107        Ok((select_modifiers, distinct))
15108    }
15109
15110    fn parse_value_table_mode(&mut self) -> Result<Option<ValueTableMode>, ParserError> {
15111        if !dialect_of!(self is BigQueryDialect) {
15112            return Ok(None);
15113        }
15114
15115        let mode = if self.parse_keywords(&[Keyword::DISTINCT, Keyword::AS, Keyword::VALUE]) {
15116            Some(ValueTableMode::DistinctAsValue)
15117        } else if self.parse_keywords(&[Keyword::DISTINCT, Keyword::AS, Keyword::STRUCT]) {
15118            Some(ValueTableMode::DistinctAsStruct)
15119        } else if self.parse_keywords(&[Keyword::AS, Keyword::VALUE])
15120            || self.parse_keywords(&[Keyword::ALL, Keyword::AS, Keyword::VALUE])
15121        {
15122            Some(ValueTableMode::AsValue)
15123        } else if self.parse_keywords(&[Keyword::AS, Keyword::STRUCT])
15124            || self.parse_keywords(&[Keyword::ALL, Keyword::AS, Keyword::STRUCT])
15125        {
15126            Some(ValueTableMode::AsStruct)
15127        } else if self.parse_keyword(Keyword::AS) {
15128            self.expected_ref("VALUE or STRUCT", self.peek_token_ref())?
15129        } else {
15130            None
15131        };
15132
15133        Ok(mode)
15134    }
15135
15136    /// Invoke `f` after first setting the parser's `ParserState` to `state`.
15137    ///
15138    /// Upon return, restores the parser's state to what it started at.
15139    fn with_state<T, F>(&mut self, state: ParserState, mut f: F) -> Result<T, ParserError>
15140    where
15141        F: FnMut(&mut Parser) -> Result<T, ParserError>,
15142    {
15143        let current_state = self.state;
15144        self.state = state;
15145        let res = f(self);
15146        self.state = current_state;
15147        res
15148    }
15149
15150    /// Parse a `CONNECT BY` clause (Oracle-style hierarchical query support).
15151    pub fn maybe_parse_connect_by(&mut self) -> Result<Vec<ConnectByKind>, ParserError> {
15152        let mut clauses = Vec::with_capacity(2);
15153        loop {
15154            if let Some(idx) = self.parse_keywords_indexed(&[Keyword::START, Keyword::WITH]) {
15155                clauses.push(ConnectByKind::StartWith {
15156                    start_token: self.token_at(idx).clone().into(),
15157                    condition: self.parse_expr()?.into(),
15158                });
15159            } else if let Some(idx) = self.parse_keywords_indexed(&[Keyword::CONNECT, Keyword::BY])
15160            {
15161                clauses.push(ConnectByKind::ConnectBy {
15162                    connect_token: self.token_at(idx).clone().into(),
15163                    nocycle: self.parse_keyword(Keyword::NOCYCLE),
15164                    relationships: self.with_state(ParserState::ConnectBy, |parser| {
15165                        parser.parse_comma_separated(Parser::parse_expr)
15166                    })?,
15167                });
15168            } else {
15169                break;
15170            }
15171        }
15172        Ok(clauses)
15173    }
15174
15175    /// Parse `CREATE TABLE x AS TABLE y`
15176    pub fn parse_as_table(&mut self) -> Result<Table, ParserError> {
15177        let token1 = self.next_token();
15178        let token2 = self.next_token();
15179        let token3 = self.next_token();
15180
15181        let table_name;
15182        let schema_name;
15183        if token2 == Token::Period {
15184            match token1.token {
15185                Token::Word(w) => {
15186                    schema_name = w.value;
15187                }
15188                _ => {
15189                    return self.expected("Schema name", token1);
15190                }
15191            }
15192            match token3.token {
15193                Token::Word(w) => {
15194                    table_name = w.value;
15195                }
15196                _ => {
15197                    return self.expected("Table name", token3);
15198                }
15199            }
15200            Ok(Table {
15201                table_name: Some(table_name),
15202                schema_name: Some(schema_name),
15203            })
15204        } else {
15205            match token1.token {
15206                Token::Word(w) => {
15207                    table_name = w.value;
15208                }
15209                _ => {
15210                    return self.expected("Table name", token1);
15211                }
15212            }
15213            Ok(Table {
15214                table_name: Some(table_name),
15215                schema_name: None,
15216            })
15217        }
15218    }
15219
15220    /// Parse a `SET ROLE` statement. Expects SET to be consumed already.
15221    fn parse_set_role(
15222        &mut self,
15223        modifier: Option<ContextModifier>,
15224    ) -> Result<Statement, ParserError> {
15225        self.expect_keyword_is(Keyword::ROLE)?;
15226
15227        let role_name = if self.parse_keyword(Keyword::NONE) {
15228            None
15229        } else {
15230            Some(self.parse_identifier()?)
15231        };
15232        Ok(Statement::Set(Set::SetRole {
15233            context_modifier: modifier,
15234            role_name,
15235        }))
15236    }
15237
15238    fn parse_set_values(
15239        &mut self,
15240        parenthesized_assignment: bool,
15241    ) -> Result<Vec<Expr>, ParserError> {
15242        let mut values = vec![];
15243
15244        if parenthesized_assignment {
15245            self.expect_token(&Token::LParen)?;
15246        }
15247
15248        loop {
15249            let value = if let Some(expr) = self.try_parse_expr_sub_query()? {
15250                expr
15251            } else if let Ok(expr) = self.parse_expr() {
15252                expr
15253            } else {
15254                self.expected_ref("variable value", self.peek_token_ref())?
15255            };
15256
15257            values.push(value);
15258            if self.consume_token(&Token::Comma) {
15259                continue;
15260            }
15261
15262            if parenthesized_assignment {
15263                self.expect_token(&Token::RParen)?;
15264            }
15265            return Ok(values);
15266        }
15267    }
15268
15269    fn parse_context_modifier(&mut self) -> Option<ContextModifier> {
15270        let modifier =
15271            self.parse_one_of_keywords(&[Keyword::SESSION, Keyword::LOCAL, Keyword::GLOBAL])?;
15272
15273        Self::keyword_to_modifier(modifier)
15274    }
15275
15276    /// Parse a single SET statement assignment `var = expr`.
15277    fn parse_set_assignment(&mut self) -> Result<SetAssignment, ParserError> {
15278        let scope = self.parse_context_modifier();
15279
15280        let name = if self.dialect.supports_parenthesized_set_variables()
15281            && self.consume_token(&Token::LParen)
15282        {
15283            // Parenthesized assignments are handled in the `parse_set` function after
15284            // trying to parse list of assignments using this function.
15285            // If a dialect supports both, and we find a LParen, we early exit from this function.
15286            self.expected_ref("Unparenthesized assignment", self.peek_token_ref())?
15287        } else {
15288            self.parse_object_name(false)?
15289        };
15290
15291        if !(self.consume_token(&Token::Eq) || self.parse_keyword(Keyword::TO)) {
15292            return self.expected_ref("assignment operator", self.peek_token_ref());
15293        }
15294
15295        let value = self.parse_expr()?;
15296
15297        Ok(SetAssignment { scope, name, value })
15298    }
15299
15300    fn parse_set(&mut self) -> Result<Statement, ParserError> {
15301        let hivevar = self.parse_keyword(Keyword::HIVEVAR);
15302
15303        // Modifier is either HIVEVAR: or a ContextModifier (LOCAL, SESSION, etc), not both
15304        let scope = if !hivevar {
15305            self.parse_context_modifier()
15306        } else {
15307            None
15308        };
15309
15310        if hivevar {
15311            self.expect_token(&Token::Colon)?;
15312        }
15313
15314        if let Some(set_role_stmt) = self.maybe_parse(|parser| parser.parse_set_role(scope))? {
15315            return Ok(set_role_stmt);
15316        }
15317
15318        // Handle special cases first
15319        if self.parse_keywords(&[Keyword::TIME, Keyword::ZONE])
15320            || self.parse_keyword(Keyword::TIMEZONE)
15321        {
15322            if self.consume_token(&Token::Eq) || self.parse_keyword(Keyword::TO) {
15323                return Ok(Set::SingleAssignment {
15324                    scope,
15325                    hivevar,
15326                    variable: ObjectName::from(vec!["TIMEZONE".into()]),
15327                    values: self.parse_set_values(false)?,
15328                }
15329                .into());
15330            } else {
15331                // A shorthand alias for SET TIME ZONE that doesn't require
15332                // the assignment operator. It's originally PostgreSQL specific,
15333                // but we allow it for all the dialects
15334                return Ok(Set::SetTimeZone {
15335                    local: scope == Some(ContextModifier::Local),
15336                    value: self.parse_expr()?,
15337                }
15338                .into());
15339            }
15340        } else if self.dialect.supports_set_names() && self.parse_keyword(Keyword::NAMES) {
15341            if self.parse_keyword(Keyword::DEFAULT) {
15342                return Ok(Set::SetNamesDefault {}.into());
15343            }
15344            let charset_name = self.parse_identifier()?;
15345            let collation_name = if self.parse_one_of_keywords(&[Keyword::COLLATE]).is_some() {
15346                Some(self.parse_literal_string()?)
15347            } else {
15348                None
15349            };
15350
15351            return Ok(Set::SetNames {
15352                charset_name,
15353                collation_name,
15354            }
15355            .into());
15356        } else if self.parse_keyword(Keyword::CHARACTERISTICS) {
15357            self.expect_keywords(&[Keyword::AS, Keyword::TRANSACTION])?;
15358            return Ok(Set::SetTransaction {
15359                modes: self.parse_transaction_modes()?,
15360                snapshot: None,
15361                session: true,
15362            }
15363            .into());
15364        } else if self.parse_keyword(Keyword::TRANSACTION) {
15365            if self.parse_keyword(Keyword::SNAPSHOT) {
15366                let snapshot_id = self.parse_value()?;
15367                return Ok(Set::SetTransaction {
15368                    modes: vec![],
15369                    snapshot: Some(snapshot_id),
15370                    session: false,
15371                }
15372                .into());
15373            }
15374            return Ok(Set::SetTransaction {
15375                modes: self.parse_transaction_modes()?,
15376                snapshot: None,
15377                session: false,
15378            }
15379            .into());
15380        } else if self.parse_keyword(Keyword::AUTHORIZATION) {
15381            let scope = match scope {
15382                Some(s) => s,
15383                None => {
15384                    return self.expected_at(
15385                        "SESSION, LOCAL, or other scope modifier before AUTHORIZATION",
15386                        self.get_current_index(),
15387                    )
15388                }
15389            };
15390            let auth_value = if self.parse_keyword(Keyword::DEFAULT) {
15391                SetSessionAuthorizationParamKind::Default
15392            } else {
15393                let value = self.parse_identifier()?;
15394                SetSessionAuthorizationParamKind::User(value)
15395            };
15396            return Ok(Set::SetSessionAuthorization(SetSessionAuthorizationParam {
15397                scope,
15398                kind: auth_value,
15399            })
15400            .into());
15401        }
15402
15403        if self.dialect.supports_comma_separated_set_assignments() {
15404            if scope.is_some() {
15405                self.prev_token();
15406            }
15407
15408            if let Some(assignments) = self
15409                .maybe_parse(|parser| parser.parse_comma_separated(Parser::parse_set_assignment))?
15410            {
15411                return if assignments.len() > 1 {
15412                    Ok(Set::MultipleAssignments { assignments }.into())
15413                } else {
15414                    let SetAssignment { scope, name, value } =
15415                        assignments.into_iter().next().ok_or_else(|| {
15416                            ParserError::ParserError("Expected at least one assignment".to_string())
15417                        })?;
15418
15419                    Ok(Set::SingleAssignment {
15420                        scope,
15421                        hivevar,
15422                        variable: name,
15423                        values: vec![value],
15424                    }
15425                    .into())
15426                };
15427            }
15428        }
15429
15430        let variables = if self.dialect.supports_parenthesized_set_variables()
15431            && self.consume_token(&Token::LParen)
15432        {
15433            let vars = OneOrManyWithParens::Many(
15434                self.parse_comma_separated(|parser: &mut Parser<'a>| parser.parse_identifier())?
15435                    .into_iter()
15436                    .map(|ident| ObjectName::from(vec![ident]))
15437                    .collect(),
15438            );
15439            self.expect_token(&Token::RParen)?;
15440            vars
15441        } else {
15442            OneOrManyWithParens::One(self.parse_object_name(false)?)
15443        };
15444
15445        if self.consume_token(&Token::Eq) || self.parse_keyword(Keyword::TO) {
15446            let stmt = match variables {
15447                OneOrManyWithParens::One(var) => Set::SingleAssignment {
15448                    scope,
15449                    hivevar,
15450                    variable: var,
15451                    values: self.parse_set_values(false)?,
15452                },
15453                OneOrManyWithParens::Many(vars) => Set::ParenthesizedAssignments {
15454                    variables: vars,
15455                    values: self.parse_set_values(true)?,
15456                },
15457            };
15458
15459            return Ok(stmt.into());
15460        }
15461
15462        if self.dialect.supports_set_stmt_without_operator() {
15463            self.prev_token();
15464            return self.parse_set_session_params();
15465        };
15466
15467        self.expected_ref("equals sign or TO", self.peek_token_ref())
15468    }
15469
15470    /// Parse session parameter assignments after `SET` when no `=` or `TO` is present.
15471    pub fn parse_set_session_params(&mut self) -> Result<Statement, ParserError> {
15472        if self.parse_keyword(Keyword::STATISTICS) {
15473            let topic = match self.parse_one_of_keywords(&[
15474                Keyword::IO,
15475                Keyword::PROFILE,
15476                Keyword::TIME,
15477                Keyword::XML,
15478            ]) {
15479                Some(Keyword::IO) => SessionParamStatsTopic::IO,
15480                Some(Keyword::PROFILE) => SessionParamStatsTopic::Profile,
15481                Some(Keyword::TIME) => SessionParamStatsTopic::Time,
15482                Some(Keyword::XML) => SessionParamStatsTopic::Xml,
15483                _ => return self.expected_ref("IO, PROFILE, TIME or XML", self.peek_token_ref()),
15484            };
15485            let value = self.parse_session_param_value()?;
15486            Ok(
15487                Set::SetSessionParam(SetSessionParamKind::Statistics(SetSessionParamStatistics {
15488                    topic,
15489                    value,
15490                }))
15491                .into(),
15492            )
15493        } else if self.parse_keyword(Keyword::IDENTITY_INSERT) {
15494            let obj = self.parse_object_name(false)?;
15495            let value = self.parse_session_param_value()?;
15496            Ok(Set::SetSessionParam(SetSessionParamKind::IdentityInsert(
15497                SetSessionParamIdentityInsert { obj, value },
15498            ))
15499            .into())
15500        } else if self.parse_keyword(Keyword::OFFSETS) {
15501            let keywords = self.parse_comma_separated(|parser| {
15502                let next_token = parser.next_token();
15503                match &next_token.token {
15504                    Token::Word(w) => Ok(w.to_string()),
15505                    _ => parser.expected("SQL keyword", next_token),
15506                }
15507            })?;
15508            let value = self.parse_session_param_value()?;
15509            Ok(
15510                Set::SetSessionParam(SetSessionParamKind::Offsets(SetSessionParamOffsets {
15511                    keywords,
15512                    value,
15513                }))
15514                .into(),
15515            )
15516        } else {
15517            let names = self.parse_comma_separated(|parser| {
15518                let next_token = parser.next_token();
15519                match next_token.token {
15520                    Token::Word(w) => Ok(w.to_string()),
15521                    _ => parser.expected("Session param name", next_token),
15522                }
15523            })?;
15524            let value = self.parse_expr()?.to_string();
15525            Ok(
15526                Set::SetSessionParam(SetSessionParamKind::Generic(SetSessionParamGeneric {
15527                    names,
15528                    value,
15529                }))
15530                .into(),
15531            )
15532        }
15533    }
15534
15535    fn parse_session_param_value(&mut self) -> Result<SessionParamValue, ParserError> {
15536        if self.parse_keyword(Keyword::ON) {
15537            Ok(SessionParamValue::On)
15538        } else if self.parse_keyword(Keyword::OFF) {
15539            Ok(SessionParamValue::Off)
15540        } else {
15541            self.expected_ref("ON or OFF", self.peek_token_ref())
15542        }
15543    }
15544
15545    /// Parse a `SHOW` statement and dispatch to specific SHOW handlers.
15546    pub fn parse_show(&mut self) -> Result<Statement, ParserError> {
15547        let terse = self.parse_keyword(Keyword::TERSE);
15548        let extended = self.parse_keyword(Keyword::EXTENDED);
15549        let full = self.parse_keyword(Keyword::FULL);
15550        let session = self.parse_keyword(Keyword::SESSION);
15551        let global = self.parse_keyword(Keyword::GLOBAL);
15552        let external = self.parse_keyword(Keyword::EXTERNAL);
15553        if self
15554            .parse_one_of_keywords(&[Keyword::COLUMNS, Keyword::FIELDS])
15555            .is_some()
15556        {
15557            Ok(self.parse_show_columns(extended, full)?)
15558        } else if self.parse_keyword(Keyword::TABLES) {
15559            Ok(self.parse_show_tables(terse, extended, full, external)?)
15560        } else if self.parse_keywords(&[Keyword::MATERIALIZED, Keyword::VIEWS]) {
15561            Ok(self.parse_show_views(terse, true)?)
15562        } else if self.parse_keyword(Keyword::VIEWS) {
15563            Ok(self.parse_show_views(terse, false)?)
15564        } else if self.parse_keyword(Keyword::FUNCTIONS) {
15565            Ok(self.parse_show_functions()?)
15566        } else if self.parse_keyword(Keyword::PROCESSLIST) {
15567            Ok(Statement::ShowProcessList { full })
15568        } else if extended || full {
15569            Err(ParserError::ParserError(
15570                "EXTENDED/FULL are not supported with this type of SHOW query".to_string(),
15571            ))
15572        } else if self.parse_one_of_keywords(&[Keyword::CREATE]).is_some() {
15573            Ok(self.parse_show_create()?)
15574        } else if self.parse_keyword(Keyword::COLLATION) {
15575            Ok(self.parse_show_collation()?)
15576        } else if self.parse_keyword(Keyword::VARIABLES)
15577            && dialect_of!(self is MySqlDialect | GenericDialect)
15578        {
15579            Ok(Statement::ShowVariables {
15580                filter: self.parse_show_statement_filter()?,
15581                session,
15582                global,
15583            })
15584        } else if self.parse_keyword(Keyword::STATUS)
15585            && dialect_of!(self is MySqlDialect | GenericDialect)
15586        {
15587            Ok(Statement::ShowStatus {
15588                filter: self.parse_show_statement_filter()?,
15589                session,
15590                global,
15591            })
15592        } else if self.parse_keyword(Keyword::CATALOGS) {
15593            self.parse_show_catalogs(terse)
15594        } else if self.parse_keyword(Keyword::DATABASES) {
15595            self.parse_show_databases(terse)
15596        } else if self.parse_keyword(Keyword::SCHEMAS) {
15597            self.parse_show_schemas(terse)
15598        } else if self.parse_keywords(&[Keyword::CHARACTER, Keyword::SET]) {
15599            self.parse_show_charset(false)
15600        } else if self.parse_keyword(Keyword::CHARSET) {
15601            self.parse_show_charset(true)
15602        } else {
15603            Ok(Statement::ShowVariable {
15604                variable: self.parse_identifiers()?,
15605            })
15606        }
15607    }
15608
15609    fn parse_show_charset(&mut self, is_shorthand: bool) -> Result<Statement, ParserError> {
15610        // parse one of keywords
15611        Ok(Statement::ShowCharset(ShowCharset {
15612            is_shorthand,
15613            filter: self.parse_show_statement_filter()?,
15614        }))
15615    }
15616
15617    fn parse_show_catalogs(&mut self, terse: bool) -> Result<Statement, ParserError> {
15618        let history = self.parse_keyword(Keyword::HISTORY);
15619        let show_options = self.parse_show_stmt_options()?;
15620        Ok(Statement::ShowCatalogs {
15621            terse,
15622            history,
15623            show_options,
15624        })
15625    }
15626
15627    fn parse_show_databases(&mut self, terse: bool) -> Result<Statement, ParserError> {
15628        let history = self.parse_keyword(Keyword::HISTORY);
15629        let show_options = self.parse_show_stmt_options()?;
15630        Ok(Statement::ShowDatabases {
15631            terse,
15632            history,
15633            show_options,
15634        })
15635    }
15636
15637    fn parse_show_schemas(&mut self, terse: bool) -> Result<Statement, ParserError> {
15638        let history = self.parse_keyword(Keyword::HISTORY);
15639        let show_options = self.parse_show_stmt_options()?;
15640        Ok(Statement::ShowSchemas {
15641            terse,
15642            history,
15643            show_options,
15644        })
15645    }
15646
15647    /// Parse `SHOW CREATE <object>` returning the corresponding `ShowCreate` statement.
15648    pub fn parse_show_create(&mut self) -> Result<Statement, ParserError> {
15649        let obj_type = match self.expect_one_of_keywords(&[
15650            Keyword::TABLE,
15651            Keyword::TRIGGER,
15652            Keyword::FUNCTION,
15653            Keyword::PROCEDURE,
15654            Keyword::EVENT,
15655            Keyword::VIEW,
15656        ])? {
15657            Keyword::TABLE => Ok(ShowCreateObject::Table),
15658            Keyword::TRIGGER => Ok(ShowCreateObject::Trigger),
15659            Keyword::FUNCTION => Ok(ShowCreateObject::Function),
15660            Keyword::PROCEDURE => Ok(ShowCreateObject::Procedure),
15661            Keyword::EVENT => Ok(ShowCreateObject::Event),
15662            Keyword::VIEW => Ok(ShowCreateObject::View),
15663            keyword => Err(ParserError::ParserError(format!(
15664                "Unable to map keyword to ShowCreateObject: {keyword:?}"
15665            ))),
15666        }?;
15667
15668        let obj_name = self.parse_object_name(false)?;
15669
15670        Ok(Statement::ShowCreate { obj_type, obj_name })
15671    }
15672
15673    /// Parse `SHOW COLUMNS`/`SHOW FIELDS` and return a `ShowColumns` statement.
15674    pub fn parse_show_columns(
15675        &mut self,
15676        extended: bool,
15677        full: bool,
15678    ) -> Result<Statement, ParserError> {
15679        let show_options = self.parse_show_stmt_options()?;
15680        Ok(Statement::ShowColumns {
15681            extended,
15682            full,
15683            show_options,
15684        })
15685    }
15686
15687    fn parse_show_tables(
15688        &mut self,
15689        terse: bool,
15690        extended: bool,
15691        full: bool,
15692        external: bool,
15693    ) -> Result<Statement, ParserError> {
15694        let history = !external && self.parse_keyword(Keyword::HISTORY);
15695        let show_options = self.parse_show_stmt_options()?;
15696        Ok(Statement::ShowTables {
15697            terse,
15698            history,
15699            extended,
15700            full,
15701            external,
15702            show_options,
15703        })
15704    }
15705
15706    fn parse_show_views(
15707        &mut self,
15708        terse: bool,
15709        materialized: bool,
15710    ) -> Result<Statement, ParserError> {
15711        let show_options = self.parse_show_stmt_options()?;
15712        Ok(Statement::ShowViews {
15713            materialized,
15714            terse,
15715            show_options,
15716        })
15717    }
15718
15719    /// Parse `SHOW FUNCTIONS` and optional filter.
15720    pub fn parse_show_functions(&mut self) -> Result<Statement, ParserError> {
15721        let filter = self.parse_show_statement_filter()?;
15722        Ok(Statement::ShowFunctions { filter })
15723    }
15724
15725    /// Parse `SHOW COLLATION` and optional filter.
15726    pub fn parse_show_collation(&mut self) -> Result<Statement, ParserError> {
15727        let filter = self.parse_show_statement_filter()?;
15728        Ok(Statement::ShowCollation { filter })
15729    }
15730
15731    /// Parse an optional filter used by `SHOW` statements (LIKE, ILIKE, WHERE, or literal).
15732    pub fn parse_show_statement_filter(
15733        &mut self,
15734    ) -> Result<Option<ShowStatementFilter>, ParserError> {
15735        if self.parse_keyword(Keyword::LIKE) {
15736            Ok(Some(ShowStatementFilter::Like(
15737                self.parse_literal_string()?,
15738            )))
15739        } else if self.parse_keyword(Keyword::ILIKE) {
15740            Ok(Some(ShowStatementFilter::ILike(
15741                self.parse_literal_string()?,
15742            )))
15743        } else if self.parse_keyword(Keyword::WHERE) {
15744            Ok(Some(ShowStatementFilter::Where(self.parse_expr()?)))
15745        } else {
15746            self.maybe_parse(|parser| -> Result<String, ParserError> {
15747                parser.parse_literal_string()
15748            })?
15749            .map_or(Ok(None), |filter| {
15750                Ok(Some(ShowStatementFilter::NoKeyword(filter)))
15751            })
15752        }
15753    }
15754
15755    /// Parse a `USE` statement (database/catalog/schema/warehouse/role selection).
15756    pub fn parse_use(&mut self) -> Result<Statement, ParserError> {
15757        // Determine which keywords are recognized by the current dialect
15758        let parsed_keyword = if dialect_of!(self is HiveDialect) {
15759            // HiveDialect accepts USE DEFAULT; statement without any db specified
15760            if self.parse_keyword(Keyword::DEFAULT) {
15761                return Ok(Statement::Use(Use::Default));
15762            }
15763            None // HiveDialect doesn't expect any other specific keyword after `USE`
15764        } else if dialect_of!(self is DatabricksDialect) {
15765            self.parse_one_of_keywords(&[Keyword::CATALOG, Keyword::DATABASE, Keyword::SCHEMA])
15766        } else if dialect_of!(self is SnowflakeDialect) {
15767            self.parse_one_of_keywords(&[
15768                Keyword::DATABASE,
15769                Keyword::SCHEMA,
15770                Keyword::WAREHOUSE,
15771                Keyword::ROLE,
15772                Keyword::SECONDARY,
15773            ])
15774        } else {
15775            None // No specific keywords for other dialects, including GenericDialect
15776        };
15777
15778        let result = if matches!(parsed_keyword, Some(Keyword::SECONDARY)) {
15779            self.parse_secondary_roles()?
15780        } else {
15781            let obj_name = self.parse_object_name(false)?;
15782            match parsed_keyword {
15783                Some(Keyword::CATALOG) => Use::Catalog(obj_name),
15784                Some(Keyword::DATABASE) => Use::Database(obj_name),
15785                Some(Keyword::SCHEMA) => Use::Schema(obj_name),
15786                Some(Keyword::WAREHOUSE) => Use::Warehouse(obj_name),
15787                Some(Keyword::ROLE) => Use::Role(obj_name),
15788                _ => Use::Object(obj_name),
15789            }
15790        };
15791
15792        Ok(Statement::Use(result))
15793    }
15794
15795    fn parse_secondary_roles(&mut self) -> Result<Use, ParserError> {
15796        self.expect_one_of_keywords(&[Keyword::ROLES, Keyword::ROLE])?;
15797        if self.parse_keyword(Keyword::NONE) {
15798            Ok(Use::SecondaryRoles(SecondaryRoles::None))
15799        } else if self.parse_keyword(Keyword::ALL) {
15800            Ok(Use::SecondaryRoles(SecondaryRoles::All))
15801        } else {
15802            let roles = self.parse_comma_separated(|parser| parser.parse_identifier())?;
15803            Ok(Use::SecondaryRoles(SecondaryRoles::List(roles)))
15804        }
15805    }
15806
15807    /// Parse a table factor followed by any join clauses, returning `TableWithJoins`.
15808    pub fn parse_table_and_joins(&mut self) -> Result<TableWithJoins, ParserError> {
15809        let relation = self.parse_table_factor()?;
15810        // Note that for keywords to be properly handled here, they need to be
15811        // added to `RESERVED_FOR_TABLE_ALIAS`, otherwise they may be parsed as
15812        // a table alias.
15813        let joins = self.parse_joins()?;
15814        Ok(TableWithJoins { relation, joins })
15815    }
15816
15817    fn parse_joins(&mut self) -> Result<Vec<Join>, ParserError> {
15818        let mut joins = vec![];
15819        loop {
15820            let global = self.parse_keyword(Keyword::GLOBAL);
15821            let join = if self.parse_keyword(Keyword::CROSS) {
15822                let join_operator = if self.parse_keyword(Keyword::JOIN) {
15823                    JoinOperator::CrossJoin(JoinConstraint::None)
15824                } else if self.parse_keyword(Keyword::APPLY) {
15825                    // MSSQL extension, similar to CROSS JOIN LATERAL
15826                    JoinOperator::CrossApply
15827                } else {
15828                    return self.expected_ref("JOIN or APPLY after CROSS", self.peek_token_ref());
15829                };
15830                let relation = self.parse_table_factor()?;
15831                let join_operator = if matches!(join_operator, JoinOperator::CrossJoin(_))
15832                    && self.dialect.supports_cross_join_constraint()
15833                {
15834                    let constraint = self.parse_join_constraint(false)?;
15835                    JoinOperator::CrossJoin(constraint)
15836                } else {
15837                    join_operator
15838                };
15839                Join {
15840                    relation,
15841                    global,
15842                    join_operator,
15843                }
15844            } else if self.parse_keyword(Keyword::OUTER) {
15845                // MSSQL extension, similar to LEFT JOIN LATERAL .. ON 1=1
15846                self.expect_keyword_is(Keyword::APPLY)?;
15847                Join {
15848                    relation: self.parse_table_factor()?,
15849                    global,
15850                    join_operator: JoinOperator::OuterApply,
15851                }
15852            } else if self.parse_keyword(Keyword::ASOF) {
15853                self.expect_keyword_is(Keyword::JOIN)?;
15854                let relation = self.parse_table_factor()?;
15855                self.expect_keyword_is(Keyword::MATCH_CONDITION)?;
15856                let match_condition = self.parse_parenthesized(Self::parse_expr)?;
15857                Join {
15858                    relation,
15859                    global,
15860                    join_operator: JoinOperator::AsOf {
15861                        match_condition,
15862                        constraint: self.parse_join_constraint(false)?,
15863                    },
15864                }
15865            } else if self.dialect.supports_array_join_syntax()
15866                && self.parse_keywords(&[Keyword::INNER, Keyword::ARRAY, Keyword::JOIN])
15867            {
15868                // ClickHouse: INNER ARRAY JOIN
15869                Join {
15870                    relation: self.parse_table_factor()?,
15871                    global,
15872                    join_operator: JoinOperator::InnerArrayJoin,
15873                }
15874            } else if self.dialect.supports_array_join_syntax()
15875                && self.parse_keywords(&[Keyword::LEFT, Keyword::ARRAY, Keyword::JOIN])
15876            {
15877                // ClickHouse: LEFT ARRAY JOIN
15878                Join {
15879                    relation: self.parse_table_factor()?,
15880                    global,
15881                    join_operator: JoinOperator::LeftArrayJoin,
15882                }
15883            } else if self.dialect.supports_array_join_syntax()
15884                && self.parse_keywords(&[Keyword::ARRAY, Keyword::JOIN])
15885            {
15886                // ClickHouse: ARRAY JOIN
15887                Join {
15888                    relation: self.parse_table_factor()?,
15889                    global,
15890                    join_operator: JoinOperator::ArrayJoin,
15891                }
15892            } else {
15893                let natural = self.parse_keyword(Keyword::NATURAL);
15894                let peek_keyword = if let Token::Word(w) = &self.peek_token_ref().token {
15895                    w.keyword
15896                } else {
15897                    Keyword::NoKeyword
15898                };
15899
15900                let join_operator_type = match peek_keyword {
15901                    Keyword::INNER | Keyword::JOIN => {
15902                        let inner = self.parse_keyword(Keyword::INNER); // [ INNER ]
15903                        self.expect_keyword_is(Keyword::JOIN)?;
15904                        if inner {
15905                            JoinOperator::Inner
15906                        } else {
15907                            JoinOperator::Join
15908                        }
15909                    }
15910                    kw @ Keyword::LEFT | kw @ Keyword::RIGHT => {
15911                        let _ = self.next_token(); // consume LEFT/RIGHT
15912                        let is_left = kw == Keyword::LEFT;
15913                        let join_type = self.parse_one_of_keywords(&[
15914                            Keyword::OUTER,
15915                            Keyword::SEMI,
15916                            Keyword::ANTI,
15917                            Keyword::JOIN,
15918                        ]);
15919                        match join_type {
15920                            Some(Keyword::OUTER) => {
15921                                self.expect_keyword_is(Keyword::JOIN)?;
15922                                if is_left {
15923                                    JoinOperator::LeftOuter
15924                                } else {
15925                                    JoinOperator::RightOuter
15926                                }
15927                            }
15928                            Some(Keyword::SEMI) => {
15929                                self.expect_keyword_is(Keyword::JOIN)?;
15930                                if is_left {
15931                                    JoinOperator::LeftSemi
15932                                } else {
15933                                    JoinOperator::RightSemi
15934                                }
15935                            }
15936                            Some(Keyword::ANTI) => {
15937                                self.expect_keyword_is(Keyword::JOIN)?;
15938                                if is_left {
15939                                    JoinOperator::LeftAnti
15940                                } else {
15941                                    JoinOperator::RightAnti
15942                                }
15943                            }
15944                            Some(Keyword::JOIN) => {
15945                                if is_left {
15946                                    JoinOperator::Left
15947                                } else {
15948                                    JoinOperator::Right
15949                                }
15950                            }
15951                            _ => {
15952                                return Err(ParserError::ParserError(format!(
15953                                    "expected OUTER, SEMI, ANTI or JOIN after {kw:?}"
15954                                )))
15955                            }
15956                        }
15957                    }
15958                    Keyword::ANTI => {
15959                        let _ = self.next_token(); // consume ANTI
15960                        self.expect_keyword_is(Keyword::JOIN)?;
15961                        JoinOperator::Anti
15962                    }
15963                    Keyword::SEMI => {
15964                        let _ = self.next_token(); // consume SEMI
15965                        self.expect_keyword_is(Keyword::JOIN)?;
15966                        JoinOperator::Semi
15967                    }
15968                    Keyword::FULL => {
15969                        let _ = self.next_token(); // consume FULL
15970                        let _ = self.parse_keyword(Keyword::OUTER); // [ OUTER ]
15971                        self.expect_keyword_is(Keyword::JOIN)?;
15972                        JoinOperator::FullOuter
15973                    }
15974                    Keyword::OUTER => {
15975                        return self.expected_ref("LEFT, RIGHT, or FULL", self.peek_token_ref());
15976                    }
15977                    Keyword::STRAIGHT_JOIN => {
15978                        let _ = self.next_token(); // consume STRAIGHT_JOIN
15979                        JoinOperator::StraightJoin
15980                    }
15981                    _ if natural => {
15982                        return self
15983                            .expected_ref("a join type after NATURAL", self.peek_token_ref());
15984                    }
15985                    _ => break,
15986                };
15987                let mut relation = self.parse_table_factor()?;
15988
15989                if !self
15990                    .dialect
15991                    .supports_left_associative_joins_without_parens()
15992                    && self.peek_parens_less_nested_join()
15993                {
15994                    let joins = self.parse_joins()?;
15995                    relation = TableFactor::NestedJoin {
15996                        table_with_joins: Box::new(TableWithJoins { relation, joins }),
15997                        alias: None,
15998                    };
15999                }
16000
16001                let join_constraint = self.parse_join_constraint(natural)?;
16002                Join {
16003                    relation,
16004                    global,
16005                    join_operator: join_operator_type(join_constraint),
16006                }
16007            };
16008            joins.push(join);
16009        }
16010        Ok(joins)
16011    }
16012
16013    fn peek_parens_less_nested_join(&self) -> bool {
16014        matches!(
16015            self.peek_token_ref().token,
16016            Token::Word(Word {
16017                keyword: Keyword::JOIN
16018                    | Keyword::INNER
16019                    | Keyword::LEFT
16020                    | Keyword::RIGHT
16021                    | Keyword::FULL,
16022                ..
16023            })
16024        )
16025    }
16026
16027    /// A table name or a parenthesized subquery, followed by optional `[AS] alias`
16028    #[cfg_attr(feature = "recursive-protection", recursive::recursive)]
16029    pub fn parse_table_factor(&mut self) -> Result<TableFactor, ParserError> {
16030        let _guard = self.recursion_counter.try_decrease()?;
16031        if self.parse_keyword(Keyword::LATERAL) {
16032            // LATERAL must always be followed by a subquery or table function.
16033            if self.consume_token(&Token::LParen) {
16034                self.parse_derived_table_factor(Lateral)
16035            } else {
16036                let name = self.parse_object_name(false)?;
16037                self.expect_token(&Token::LParen)?;
16038                let args = self.parse_optional_args()?;
16039                let with_ordinality = self.parse_keywords(&[Keyword::WITH, Keyword::ORDINALITY]);
16040                let alias = self.maybe_parse_table_alias()?;
16041                Ok(TableFactor::Function {
16042                    lateral: true,
16043                    name,
16044                    args,
16045                    with_ordinality,
16046                    alias,
16047                })
16048            }
16049        } else if self.parse_keyword(Keyword::TABLE) {
16050            // parse table function (SELECT * FROM TABLE (<expr>) [ AS <alias> ])
16051            self.expect_token(&Token::LParen)?;
16052            let expr = self.parse_expr()?;
16053            self.expect_token(&Token::RParen)?;
16054            let alias = self.maybe_parse_table_alias()?;
16055            Ok(TableFactor::TableFunction { expr, alias })
16056        } else if self.consume_token(&Token::LParen) {
16057            // A left paren introduces either a derived table (i.e., a subquery)
16058            // or a nested join. It's nearly impossible to determine ahead of
16059            // time which it is... so we just try to parse both.
16060            //
16061            // Here's an example that demonstrates the complexity:
16062            //                     /-------------------------------------------------------\
16063            //                     | /-----------------------------------\                 |
16064            //     SELECT * FROM ( ( ( (SELECT 1) UNION (SELECT 2) ) AS t1 NATURAL JOIN t2 ) )
16065            //                   ^ ^ ^ ^
16066            //                   | | | |
16067            //                   | | | |
16068            //                   | | | (4) belongs to a SetExpr::Query inside the subquery
16069            //                   | | (3) starts a derived table (subquery)
16070            //                   | (2) starts a nested join
16071            //                   (1) an additional set of parens around a nested join
16072            //
16073
16074            // If the recently consumed '(' starts a derived table, the call to
16075            // `parse_derived_table_factor` below will return success after parsing the
16076            // subquery, followed by the closing ')', and the alias of the derived table.
16077            // In the example above this is case (3).
16078            if let Some(mut table) =
16079                self.maybe_parse(|parser| parser.parse_derived_table_factor(NotLateral))?
16080            {
16081                while let Some(kw) = self.parse_one_of_keywords(&[Keyword::PIVOT, Keyword::UNPIVOT])
16082                {
16083                    table = match kw {
16084                        Keyword::PIVOT => self.parse_pivot_table_factor(table)?,
16085                        Keyword::UNPIVOT => self.parse_unpivot_table_factor(table)?,
16086                        unexpected_keyword => return Err(ParserError::ParserError(
16087                            format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in pivot/unpivot"),
16088                        )),
16089                    }
16090                }
16091                return Ok(table);
16092            }
16093
16094            // A parsing error from `parse_derived_table_factor` indicates that the '(' we've
16095            // recently consumed does not start a derived table (cases 1, 2, or 4).
16096            // `maybe_parse` will ignore such an error and rewind to be after the opening '('.
16097
16098            // Inside the parentheses we expect to find an (A) table factor
16099            // followed by some joins or (B) another level of nesting.
16100            let mut table_and_joins = self.parse_table_and_joins()?;
16101
16102            #[allow(clippy::if_same_then_else)]
16103            if !table_and_joins.joins.is_empty() {
16104                self.expect_token(&Token::RParen)?;
16105                let alias = self.maybe_parse_table_alias()?;
16106                Ok(TableFactor::NestedJoin {
16107                    table_with_joins: Box::new(table_and_joins),
16108                    alias,
16109                }) // (A)
16110            } else if let TableFactor::NestedJoin {
16111                table_with_joins: _,
16112                alias: _,
16113            } = &table_and_joins.relation
16114            {
16115                // (B): `table_and_joins` (what we found inside the parentheses)
16116                // is a nested join `(foo JOIN bar)`, not followed by other joins.
16117                self.expect_token(&Token::RParen)?;
16118                let alias = self.maybe_parse_table_alias()?;
16119                Ok(TableFactor::NestedJoin {
16120                    table_with_joins: Box::new(table_and_joins),
16121                    alias,
16122                })
16123            } else if self.dialect.supports_parens_around_table_factor() {
16124                // Dialect-specific behavior: Snowflake diverges from the
16125                // standard and from most of the other implementations by
16126                // allowing extra parentheses not only around a join (B), but
16127                // around lone table names (e.g. `FROM (mytable [AS alias])`)
16128                // and around derived tables (e.g. `FROM ((SELECT ...)
16129                // [AS alias])`) as well.
16130                self.expect_token(&Token::RParen)?;
16131
16132                if let Some(outer_alias) = self.maybe_parse_table_alias()? {
16133                    // Snowflake also allows specifying an alias *after* parens
16134                    // e.g. `FROM (mytable) AS alias`
16135                    match &mut table_and_joins.relation {
16136                        TableFactor::Derived { alias, .. }
16137                        | TableFactor::Table { alias, .. }
16138                        | TableFactor::Function { alias, .. }
16139                        | TableFactor::UNNEST { alias, .. }
16140                        | TableFactor::JsonTable { alias, .. }
16141                        | TableFactor::XmlTable { alias, .. }
16142                        | TableFactor::OpenJsonTable { alias, .. }
16143                        | TableFactor::TableFunction { alias, .. }
16144                        | TableFactor::Pivot { alias, .. }
16145                        | TableFactor::Unpivot { alias, .. }
16146                        | TableFactor::MatchRecognize { alias, .. }
16147                        | TableFactor::SemanticView { alias, .. }
16148                        | TableFactor::NestedJoin { alias, .. } => {
16149                            // but not `FROM (mytable AS alias1) AS alias2`.
16150                            if let Some(inner_alias) = alias {
16151                                return Err(ParserError::ParserError(format!(
16152                                    "duplicate alias {inner_alias}"
16153                                )));
16154                            }
16155                            // Act as if the alias was specified normally next
16156                            // to the table name: `(mytable) AS alias` ->
16157                            // `(mytable AS alias)`
16158                            alias.replace(outer_alias);
16159                        }
16160                    };
16161                }
16162                // Do not store the extra set of parens in the AST
16163                Ok(table_and_joins.relation)
16164            } else {
16165                // The SQL spec prohibits derived tables and bare tables from
16166                // appearing alone in parentheses (e.g. `FROM (mytable)`)
16167                self.expected_ref("joined table", self.peek_token_ref())
16168            }
16169        } else if self.dialect.supports_values_as_table_factor()
16170            && matches!(
16171                self.peek_tokens(),
16172                [
16173                    Token::Word(Word {
16174                        keyword: Keyword::VALUES,
16175                        ..
16176                    }),
16177                    Token::LParen
16178                ]
16179            )
16180        {
16181            self.expect_keyword_is(Keyword::VALUES)?;
16182
16183            // Snowflake and Databricks allow syntax like below:
16184            // SELECT * FROM VALUES (1, 'a'), (2, 'b') AS t (col1, col2)
16185            // where there are no parentheses around the VALUES clause.
16186            let values = SetExpr::Values(self.parse_values(false, false)?);
16187            let alias = self.maybe_parse_table_alias()?;
16188            Ok(TableFactor::Derived {
16189                lateral: false,
16190                subquery: Box::new(Query {
16191                    with: None,
16192                    body: Box::new(values),
16193                    order_by: None,
16194                    limit_clause: None,
16195                    fetch: None,
16196                    locks: vec![],
16197                    for_clause: None,
16198                    settings: None,
16199                    format_clause: None,
16200                    pipe_operators: vec![],
16201                }),
16202                alias,
16203                sample: None,
16204            })
16205        } else if dialect_of!(self is BigQueryDialect | PostgreSqlDialect | GenericDialect)
16206            && self.parse_keyword(Keyword::UNNEST)
16207        {
16208            self.expect_token(&Token::LParen)?;
16209            let array_exprs = self.parse_comma_separated(Parser::parse_expr)?;
16210            self.expect_token(&Token::RParen)?;
16211
16212            let with_ordinality = self.parse_keywords(&[Keyword::WITH, Keyword::ORDINALITY]);
16213            let alias = match self.maybe_parse_table_alias() {
16214                Ok(Some(alias)) => Some(alias),
16215                Ok(None) => None,
16216                Err(e) => return Err(e),
16217            };
16218
16219            let with_offset = match self.expect_keywords(&[Keyword::WITH, Keyword::OFFSET]) {
16220                Ok(()) => true,
16221                Err(_) => false,
16222            };
16223
16224            let with_offset_alias = if with_offset {
16225                match self.parse_optional_alias(keywords::RESERVED_FOR_COLUMN_ALIAS) {
16226                    Ok(Some(alias)) => Some(alias),
16227                    Ok(None) => None,
16228                    Err(e) => return Err(e),
16229                }
16230            } else {
16231                None
16232            };
16233
16234            Ok(TableFactor::UNNEST {
16235                alias,
16236                array_exprs,
16237                with_offset,
16238                with_offset_alias,
16239                with_ordinality,
16240            })
16241        } else if self.parse_keyword_with_tokens(Keyword::JSON_TABLE, &[Token::LParen]) {
16242            let json_expr = self.parse_expr()?;
16243            self.expect_token(&Token::Comma)?;
16244            let json_path = self.parse_value()?;
16245            self.expect_keyword_is(Keyword::COLUMNS)?;
16246            self.expect_token(&Token::LParen)?;
16247            let columns = self.parse_comma_separated(Parser::parse_json_table_column_def)?;
16248            self.expect_token(&Token::RParen)?;
16249            self.expect_token(&Token::RParen)?;
16250            let alias = self.maybe_parse_table_alias()?;
16251            Ok(TableFactor::JsonTable {
16252                json_expr,
16253                json_path,
16254                columns,
16255                alias,
16256            })
16257        } else if self.parse_keyword_with_tokens(Keyword::OPENJSON, &[Token::LParen]) {
16258            self.prev_token();
16259            self.parse_open_json_table_factor()
16260        } else if self.parse_keyword_with_tokens(Keyword::XMLTABLE, &[Token::LParen]) {
16261            self.prev_token();
16262            self.parse_xml_table_factor()
16263        } else if self.dialect.supports_semantic_view_table_factor()
16264            && self.peek_keyword_with_tokens(Keyword::SEMANTIC_VIEW, &[Token::LParen])
16265        {
16266            self.parse_semantic_view_table_factor()
16267        } else if self.peek_token_ref().token == Token::AtSign {
16268            // Stage reference: @mystage or @namespace.stage (e.g. Snowflake)
16269            self.parse_snowflake_stage_table_factor()
16270        } else {
16271            let name = self.parse_object_name(true)?;
16272
16273            let json_path = match &self.peek_token_ref().token {
16274                Token::LBracket if self.dialect.supports_partiql() => Some(self.parse_json_path()?),
16275                _ => None,
16276            };
16277
16278            let partitions: Vec<Ident> = if dialect_of!(self is MySqlDialect | GenericDialect)
16279                && self.parse_keyword(Keyword::PARTITION)
16280            {
16281                self.parse_parenthesized_identifiers()?
16282            } else {
16283                vec![]
16284            };
16285
16286            // Parse potential version qualifier
16287            let version = self.maybe_parse_table_version()?;
16288
16289            // Postgres, MSSQL, ClickHouse: table-valued functions:
16290            let args = if self.consume_token(&Token::LParen) {
16291                Some(self.parse_table_function_args()?)
16292            } else {
16293                None
16294            };
16295
16296            let with_ordinality = self.parse_keywords(&[Keyword::WITH, Keyword::ORDINALITY]);
16297
16298            let mut sample = None;
16299            if self.dialect.supports_table_sample_before_alias() {
16300                if let Some(parsed_sample) = self.maybe_parse_table_sample()? {
16301                    sample = Some(TableSampleKind::BeforeTableAlias(parsed_sample));
16302                }
16303            }
16304
16305            let alias = self.maybe_parse_table_alias()?;
16306
16307            // MYSQL-specific table hints:
16308            let index_hints = if self.dialect.supports_table_hints() {
16309                self.maybe_parse(|p| p.parse_table_index_hints())?
16310                    .unwrap_or(vec![])
16311            } else {
16312                vec![]
16313            };
16314
16315            // MSSQL-specific table hints:
16316            let mut with_hints = vec![];
16317            if self.parse_keyword(Keyword::WITH) {
16318                if self.consume_token(&Token::LParen) {
16319                    with_hints = self.parse_comma_separated(Parser::parse_expr)?;
16320                    self.expect_token(&Token::RParen)?;
16321                } else {
16322                    // rewind, as WITH may belong to the next statement's CTE
16323                    self.prev_token();
16324                }
16325            };
16326
16327            if !self.dialect.supports_table_sample_before_alias() {
16328                if let Some(parsed_sample) = self.maybe_parse_table_sample()? {
16329                    sample = Some(TableSampleKind::AfterTableAlias(parsed_sample));
16330                }
16331            }
16332
16333            let mut table = TableFactor::Table {
16334                name,
16335                alias,
16336                args,
16337                with_hints,
16338                version,
16339                partitions,
16340                with_ordinality,
16341                json_path,
16342                sample,
16343                index_hints,
16344            };
16345
16346            while let Some(kw) = self.parse_one_of_keywords(&[Keyword::PIVOT, Keyword::UNPIVOT]) {
16347                table = match kw {
16348                    Keyword::PIVOT => self.parse_pivot_table_factor(table)?,
16349                    Keyword::UNPIVOT => self.parse_unpivot_table_factor(table)?,
16350                    unexpected_keyword => return Err(ParserError::ParserError(
16351                        format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in pivot/unpivot"),
16352                    )),
16353                }
16354            }
16355
16356            if self.dialect.supports_match_recognize()
16357                && self.parse_keyword(Keyword::MATCH_RECOGNIZE)
16358            {
16359                table = self.parse_match_recognize(table)?;
16360            }
16361
16362            Ok(table)
16363        }
16364    }
16365
16366    /// Parse a Snowflake stage reference as a table factor.
16367    /// Handles syntax like: `@mystage1 (file_format => 'myformat', pattern => '...')`
16368    ///
16369    /// See: <https://docs.snowflake.com/en/user-guide/querying-stage>
16370    fn parse_snowflake_stage_table_factor(&mut self) -> Result<TableFactor, ParserError> {
16371        // Parse the stage name starting with @
16372        let name = crate::dialect::parse_snowflake_stage_name(self)?;
16373
16374        // Parse optional stage options like (file_format => 'myformat', pattern => '...')
16375        let args = if self.consume_token(&Token::LParen) {
16376            Some(self.parse_table_function_args()?)
16377        } else {
16378            None
16379        };
16380
16381        let alias = self.maybe_parse_table_alias()?;
16382
16383        Ok(TableFactor::Table {
16384            name,
16385            alias,
16386            args,
16387            with_hints: vec![],
16388            version: None,
16389            partitions: vec![],
16390            with_ordinality: false,
16391            json_path: None,
16392            sample: None,
16393            index_hints: vec![],
16394        })
16395    }
16396
16397    fn maybe_parse_table_sample(&mut self) -> Result<Option<Box<TableSample>>, ParserError> {
16398        let modifier = if self.parse_keyword(Keyword::TABLESAMPLE) {
16399            TableSampleModifier::TableSample
16400        } else if self.parse_keyword(Keyword::SAMPLE) {
16401            TableSampleModifier::Sample
16402        } else {
16403            return Ok(None);
16404        };
16405        self.parse_table_sample(modifier).map(Some)
16406    }
16407
16408    fn parse_table_sample(
16409        &mut self,
16410        modifier: TableSampleModifier,
16411    ) -> Result<Box<TableSample>, ParserError> {
16412        let name = match self.parse_one_of_keywords(&[
16413            Keyword::BERNOULLI,
16414            Keyword::ROW,
16415            Keyword::SYSTEM,
16416            Keyword::BLOCK,
16417        ]) {
16418            Some(Keyword::BERNOULLI) => Some(TableSampleMethod::Bernoulli),
16419            Some(Keyword::ROW) => Some(TableSampleMethod::Row),
16420            Some(Keyword::SYSTEM) => Some(TableSampleMethod::System),
16421            Some(Keyword::BLOCK) => Some(TableSampleMethod::Block),
16422            _ => None,
16423        };
16424
16425        let parenthesized = self.consume_token(&Token::LParen);
16426
16427        let (quantity, bucket) = if parenthesized && self.parse_keyword(Keyword::BUCKET) {
16428            let selected_bucket = self.parse_number_value()?;
16429            self.expect_keywords(&[Keyword::OUT, Keyword::OF])?;
16430            let total = self.parse_number_value()?;
16431            let on = if self.parse_keyword(Keyword::ON) {
16432                Some(self.parse_expr()?)
16433            } else {
16434                None
16435            };
16436            (
16437                None,
16438                Some(TableSampleBucket {
16439                    bucket: selected_bucket,
16440                    total,
16441                    on,
16442                }),
16443            )
16444        } else {
16445            let value = match self.maybe_parse(|p| p.parse_expr())? {
16446                Some(num) => num,
16447                None => {
16448                    let next_token = self.next_token();
16449                    if let Token::Word(w) = next_token.token {
16450                        Expr::Value(Value::Placeholder(w.value).with_span(next_token.span))
16451                    } else {
16452                        return parser_err!(
16453                            "Expecting number or byte length e.g. 100M",
16454                            self.peek_token_ref().span.start
16455                        );
16456                    }
16457                }
16458            };
16459            let unit = if self.parse_keyword(Keyword::ROWS) {
16460                Some(TableSampleUnit::Rows)
16461            } else if self.parse_keyword(Keyword::PERCENT) {
16462                Some(TableSampleUnit::Percent)
16463            } else {
16464                None
16465            };
16466            (
16467                Some(TableSampleQuantity {
16468                    parenthesized,
16469                    value,
16470                    unit,
16471                }),
16472                None,
16473            )
16474        };
16475        if parenthesized {
16476            self.expect_token(&Token::RParen)?;
16477        }
16478
16479        let seed = if self.parse_keyword(Keyword::REPEATABLE) {
16480            Some(self.parse_table_sample_seed(TableSampleSeedModifier::Repeatable)?)
16481        } else if self.parse_keyword(Keyword::SEED) {
16482            Some(self.parse_table_sample_seed(TableSampleSeedModifier::Seed)?)
16483        } else {
16484            None
16485        };
16486
16487        let offset = if self.parse_keyword(Keyword::OFFSET) {
16488            Some(self.parse_expr()?)
16489        } else {
16490            None
16491        };
16492
16493        Ok(Box::new(TableSample {
16494            modifier,
16495            name,
16496            quantity,
16497            seed,
16498            bucket,
16499            offset,
16500        }))
16501    }
16502
16503    fn parse_table_sample_seed(
16504        &mut self,
16505        modifier: TableSampleSeedModifier,
16506    ) -> Result<TableSampleSeed, ParserError> {
16507        self.expect_token(&Token::LParen)?;
16508        let value = self.parse_number_value()?;
16509        self.expect_token(&Token::RParen)?;
16510        Ok(TableSampleSeed { modifier, value })
16511    }
16512
16513    /// Parses `OPENJSON( jsonExpression [ , path ] )  [ <with_clause> ]` clause,
16514    /// assuming the `OPENJSON` keyword was already consumed.
16515    fn parse_open_json_table_factor(&mut self) -> Result<TableFactor, ParserError> {
16516        self.expect_token(&Token::LParen)?;
16517        let json_expr = self.parse_expr()?;
16518        let json_path = if self.consume_token(&Token::Comma) {
16519            Some(self.parse_value()?)
16520        } else {
16521            None
16522        };
16523        self.expect_token(&Token::RParen)?;
16524        let columns = if self.parse_keyword(Keyword::WITH) {
16525            self.expect_token(&Token::LParen)?;
16526            let columns = self.parse_comma_separated(Parser::parse_openjson_table_column_def)?;
16527            self.expect_token(&Token::RParen)?;
16528            columns
16529        } else {
16530            Vec::new()
16531        };
16532        let alias = self.maybe_parse_table_alias()?;
16533        Ok(TableFactor::OpenJsonTable {
16534            json_expr,
16535            json_path,
16536            columns,
16537            alias,
16538        })
16539    }
16540
16541    fn parse_xml_table_factor(&mut self) -> Result<TableFactor, ParserError> {
16542        self.expect_token(&Token::LParen)?;
16543        let namespaces = if self.parse_keyword(Keyword::XMLNAMESPACES) {
16544            self.expect_token(&Token::LParen)?;
16545            let namespaces = self.parse_comma_separated(Parser::parse_xml_namespace_definition)?;
16546            self.expect_token(&Token::RParen)?;
16547            self.expect_token(&Token::Comma)?;
16548            namespaces
16549        } else {
16550            vec![]
16551        };
16552        let row_expression = self.parse_expr()?;
16553        let passing = self.parse_xml_passing_clause()?;
16554        self.expect_keyword_is(Keyword::COLUMNS)?;
16555        let columns = self.parse_comma_separated(Parser::parse_xml_table_column)?;
16556        self.expect_token(&Token::RParen)?;
16557        let alias = self.maybe_parse_table_alias()?;
16558        Ok(TableFactor::XmlTable {
16559            namespaces,
16560            row_expression,
16561            passing,
16562            columns,
16563            alias,
16564        })
16565    }
16566
16567    fn parse_xml_namespace_definition(&mut self) -> Result<XmlNamespaceDefinition, ParserError> {
16568        let uri = self.parse_expr()?;
16569        self.expect_keyword_is(Keyword::AS)?;
16570        let name = self.parse_identifier()?;
16571        Ok(XmlNamespaceDefinition { uri, name })
16572    }
16573
16574    fn parse_xml_table_column(&mut self) -> Result<XmlTableColumn, ParserError> {
16575        let name = self.parse_identifier()?;
16576
16577        let option = if self.parse_keyword(Keyword::FOR) {
16578            self.expect_keyword(Keyword::ORDINALITY)?;
16579            XmlTableColumnOption::ForOrdinality
16580        } else {
16581            let r#type = self.parse_data_type()?;
16582            let mut path = None;
16583            let mut default = None;
16584
16585            if self.parse_keyword(Keyword::PATH) {
16586                path = Some(self.parse_expr()?);
16587            }
16588
16589            if self.parse_keyword(Keyword::DEFAULT) {
16590                default = Some(self.parse_expr()?);
16591            }
16592
16593            let not_null = self.parse_keywords(&[Keyword::NOT, Keyword::NULL]);
16594            if !not_null {
16595                // NULL is the default but can be specified explicitly
16596                let _ = self.parse_keyword(Keyword::NULL);
16597            }
16598
16599            XmlTableColumnOption::NamedInfo {
16600                r#type,
16601                path,
16602                default,
16603                nullable: !not_null,
16604            }
16605        };
16606        Ok(XmlTableColumn { name, option })
16607    }
16608
16609    fn parse_xml_passing_clause(&mut self) -> Result<XmlPassingClause, ParserError> {
16610        let mut arguments = vec![];
16611        if self.parse_keyword(Keyword::PASSING) {
16612            loop {
16613                let by_value =
16614                    self.parse_keyword(Keyword::BY) && self.expect_keyword(Keyword::VALUE).is_ok();
16615                let expr = self.parse_expr()?;
16616                let alias = if self.parse_keyword(Keyword::AS) {
16617                    Some(self.parse_identifier()?)
16618                } else {
16619                    None
16620                };
16621                arguments.push(XmlPassingArgument {
16622                    expr,
16623                    alias,
16624                    by_value,
16625                });
16626                if !self.consume_token(&Token::Comma) {
16627                    break;
16628                }
16629            }
16630        }
16631        Ok(XmlPassingClause { arguments })
16632    }
16633
16634    /// Parse a [TableFactor::SemanticView]
16635    fn parse_semantic_view_table_factor(&mut self) -> Result<TableFactor, ParserError> {
16636        self.expect_keyword(Keyword::SEMANTIC_VIEW)?;
16637        self.expect_token(&Token::LParen)?;
16638
16639        let name = self.parse_object_name(true)?;
16640
16641        // Parse DIMENSIONS, METRICS, FACTS and WHERE clauses in flexible order
16642        let mut dimensions = Vec::new();
16643        let mut metrics = Vec::new();
16644        let mut facts = Vec::new();
16645        let mut where_clause = None;
16646
16647        while self.peek_token_ref().token != Token::RParen {
16648            if self.parse_keyword(Keyword::DIMENSIONS) {
16649                if !dimensions.is_empty() {
16650                    return Err(ParserError::ParserError(
16651                        "DIMENSIONS clause can only be specified once".to_string(),
16652                    ));
16653                }
16654                dimensions = self.parse_comma_separated(Parser::parse_wildcard_expr)?;
16655            } else if self.parse_keyword(Keyword::METRICS) {
16656                if !metrics.is_empty() {
16657                    return Err(ParserError::ParserError(
16658                        "METRICS clause can only be specified once".to_string(),
16659                    ));
16660                }
16661                metrics = self.parse_comma_separated(Parser::parse_wildcard_expr)?;
16662            } else if self.parse_keyword(Keyword::FACTS) {
16663                if !facts.is_empty() {
16664                    return Err(ParserError::ParserError(
16665                        "FACTS clause can only be specified once".to_string(),
16666                    ));
16667                }
16668                facts = self.parse_comma_separated(Parser::parse_wildcard_expr)?;
16669            } else if self.parse_keyword(Keyword::WHERE) {
16670                if where_clause.is_some() {
16671                    return Err(ParserError::ParserError(
16672                        "WHERE clause can only be specified once".to_string(),
16673                    ));
16674                }
16675                where_clause = Some(self.parse_expr()?);
16676            } else {
16677                let tok = self.peek_token_ref();
16678                return parser_err!(
16679                    format!(
16680                        "Expected one of DIMENSIONS, METRICS, FACTS or WHERE, got {}",
16681                        tok.token
16682                    ),
16683                    tok.span.start
16684                )?;
16685            }
16686        }
16687
16688        self.expect_token(&Token::RParen)?;
16689
16690        let alias = self.maybe_parse_table_alias()?;
16691
16692        Ok(TableFactor::SemanticView {
16693            name,
16694            dimensions,
16695            metrics,
16696            facts,
16697            where_clause,
16698            alias,
16699        })
16700    }
16701
16702    fn parse_match_recognize(&mut self, table: TableFactor) -> Result<TableFactor, ParserError> {
16703        self.expect_token(&Token::LParen)?;
16704
16705        let partition_by = if self.parse_keywords(&[Keyword::PARTITION, Keyword::BY]) {
16706            self.parse_comma_separated(Parser::parse_expr)?
16707        } else {
16708            vec![]
16709        };
16710
16711        let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
16712            self.parse_comma_separated(Parser::parse_order_by_expr)?
16713        } else {
16714            vec![]
16715        };
16716
16717        let measures = if self.parse_keyword(Keyword::MEASURES) {
16718            self.parse_comma_separated(|p| {
16719                let expr = p.parse_expr()?;
16720                let _ = p.parse_keyword(Keyword::AS);
16721                let alias = p.parse_identifier()?;
16722                Ok(Measure { expr, alias })
16723            })?
16724        } else {
16725            vec![]
16726        };
16727
16728        let rows_per_match =
16729            if self.parse_keywords(&[Keyword::ONE, Keyword::ROW, Keyword::PER, Keyword::MATCH]) {
16730                Some(RowsPerMatch::OneRow)
16731            } else if self.parse_keywords(&[
16732                Keyword::ALL,
16733                Keyword::ROWS,
16734                Keyword::PER,
16735                Keyword::MATCH,
16736            ]) {
16737                Some(RowsPerMatch::AllRows(
16738                    if self.parse_keywords(&[Keyword::SHOW, Keyword::EMPTY, Keyword::MATCHES]) {
16739                        Some(EmptyMatchesMode::Show)
16740                    } else if self.parse_keywords(&[
16741                        Keyword::OMIT,
16742                        Keyword::EMPTY,
16743                        Keyword::MATCHES,
16744                    ]) {
16745                        Some(EmptyMatchesMode::Omit)
16746                    } else if self.parse_keywords(&[
16747                        Keyword::WITH,
16748                        Keyword::UNMATCHED,
16749                        Keyword::ROWS,
16750                    ]) {
16751                        Some(EmptyMatchesMode::WithUnmatched)
16752                    } else {
16753                        None
16754                    },
16755                ))
16756            } else {
16757                None
16758            };
16759
16760        let after_match_skip =
16761            if self.parse_keywords(&[Keyword::AFTER, Keyword::MATCH, Keyword::SKIP]) {
16762                if self.parse_keywords(&[Keyword::PAST, Keyword::LAST, Keyword::ROW]) {
16763                    Some(AfterMatchSkip::PastLastRow)
16764                } else if self.parse_keywords(&[Keyword::TO, Keyword::NEXT, Keyword::ROW]) {
16765                    Some(AfterMatchSkip::ToNextRow)
16766                } else if self.parse_keywords(&[Keyword::TO, Keyword::FIRST]) {
16767                    Some(AfterMatchSkip::ToFirst(self.parse_identifier()?))
16768                } else if self.parse_keywords(&[Keyword::TO, Keyword::LAST]) {
16769                    Some(AfterMatchSkip::ToLast(self.parse_identifier()?))
16770                } else {
16771                    let found = self.next_token();
16772                    return self.expected("after match skip option", found);
16773                }
16774            } else {
16775                None
16776            };
16777
16778        self.expect_keyword_is(Keyword::PATTERN)?;
16779        let pattern = self.parse_parenthesized(Self::parse_pattern)?;
16780
16781        self.expect_keyword_is(Keyword::DEFINE)?;
16782
16783        let symbols = self.parse_comma_separated(|p| {
16784            let symbol = p.parse_identifier()?;
16785            p.expect_keyword_is(Keyword::AS)?;
16786            let definition = p.parse_expr()?;
16787            Ok(SymbolDefinition { symbol, definition })
16788        })?;
16789
16790        self.expect_token(&Token::RParen)?;
16791
16792        let alias = self.maybe_parse_table_alias()?;
16793
16794        Ok(TableFactor::MatchRecognize {
16795            table: Box::new(table),
16796            partition_by,
16797            order_by,
16798            measures,
16799            rows_per_match,
16800            after_match_skip,
16801            pattern,
16802            symbols,
16803            alias,
16804        })
16805    }
16806
16807    fn parse_base_pattern(&mut self) -> Result<MatchRecognizePattern, ParserError> {
16808        match self.next_token().token {
16809            Token::Caret => Ok(MatchRecognizePattern::Symbol(MatchRecognizeSymbol::Start)),
16810            Token::Placeholder(s) if s == "$" => {
16811                Ok(MatchRecognizePattern::Symbol(MatchRecognizeSymbol::End))
16812            }
16813            Token::LBrace => {
16814                self.expect_token(&Token::Minus)?;
16815                let symbol = self.parse_identifier().map(MatchRecognizeSymbol::Named)?;
16816                self.expect_token(&Token::Minus)?;
16817                self.expect_token(&Token::RBrace)?;
16818                Ok(MatchRecognizePattern::Exclude(symbol))
16819            }
16820            Token::Word(Word {
16821                value,
16822                quote_style: None,
16823                ..
16824            }) if value == "PERMUTE" => {
16825                self.expect_token(&Token::LParen)?;
16826                let symbols = self.parse_comma_separated(|p| {
16827                    p.parse_identifier().map(MatchRecognizeSymbol::Named)
16828                })?;
16829                self.expect_token(&Token::RParen)?;
16830                Ok(MatchRecognizePattern::Permute(symbols))
16831            }
16832            Token::LParen => {
16833                let pattern = self.parse_pattern()?;
16834                self.expect_token(&Token::RParen)?;
16835                Ok(MatchRecognizePattern::Group(Box::new(pattern)))
16836            }
16837            _ => {
16838                self.prev_token();
16839                self.parse_identifier()
16840                    .map(MatchRecognizeSymbol::Named)
16841                    .map(MatchRecognizePattern::Symbol)
16842            }
16843        }
16844    }
16845
16846    fn parse_repetition_pattern(&mut self) -> Result<MatchRecognizePattern, ParserError> {
16847        let mut pattern = self.parse_base_pattern()?;
16848        loop {
16849            let token = self.next_token();
16850            let quantifier = match token.token {
16851                Token::Mul => RepetitionQuantifier::ZeroOrMore,
16852                Token::Plus => RepetitionQuantifier::OneOrMore,
16853                Token::Placeholder(s) if s == "?" => RepetitionQuantifier::AtMostOne,
16854                Token::LBrace => {
16855                    // quantifier is a range like {n} or {n,} or {,m} or {n,m}
16856                    let token = self.next_token();
16857                    match token.token {
16858                        Token::Comma => {
16859                            let next_token = self.next_token();
16860                            let Token::Number(n, _) = next_token.token else {
16861                                return self.expected("literal number", next_token);
16862                            };
16863                            self.expect_token(&Token::RBrace)?;
16864                            RepetitionQuantifier::AtMost(Self::parse(n, token.span.start)?)
16865                        }
16866                        Token::Number(n, _) if self.consume_token(&Token::Comma) => {
16867                            let next_token = self.next_token();
16868                            match next_token.token {
16869                                Token::Number(m, _) => {
16870                                    self.expect_token(&Token::RBrace)?;
16871                                    RepetitionQuantifier::Range(
16872                                        Self::parse(n, token.span.start)?,
16873                                        Self::parse(m, token.span.start)?,
16874                                    )
16875                                }
16876                                Token::RBrace => {
16877                                    RepetitionQuantifier::AtLeast(Self::parse(n, token.span.start)?)
16878                                }
16879                                _ => {
16880                                    return self.expected("} or upper bound", next_token);
16881                                }
16882                            }
16883                        }
16884                        Token::Number(n, _) => {
16885                            self.expect_token(&Token::RBrace)?;
16886                            RepetitionQuantifier::Exactly(Self::parse(n, token.span.start)?)
16887                        }
16888                        _ => return self.expected("quantifier range", token),
16889                    }
16890                }
16891                _ => {
16892                    self.prev_token();
16893                    break;
16894                }
16895            };
16896            pattern = MatchRecognizePattern::Repetition(Box::new(pattern), quantifier);
16897        }
16898        Ok(pattern)
16899    }
16900
16901    fn parse_concat_pattern(&mut self) -> Result<MatchRecognizePattern, ParserError> {
16902        let mut patterns = vec![self.parse_repetition_pattern()?];
16903        while !matches!(self.peek_token_ref().token, Token::RParen | Token::Pipe) {
16904            patterns.push(self.parse_repetition_pattern()?);
16905        }
16906        match <[MatchRecognizePattern; 1]>::try_from(patterns) {
16907            Ok([pattern]) => Ok(pattern),
16908            Err(patterns) => Ok(MatchRecognizePattern::Concat(patterns)),
16909        }
16910    }
16911
16912    fn parse_pattern(&mut self) -> Result<MatchRecognizePattern, ParserError> {
16913        let pattern = self.parse_concat_pattern()?;
16914        if self.consume_token(&Token::Pipe) {
16915            match self.parse_pattern()? {
16916                // flatten nested alternations
16917                MatchRecognizePattern::Alternation(mut patterns) => {
16918                    patterns.insert(0, pattern);
16919                    Ok(MatchRecognizePattern::Alternation(patterns))
16920                }
16921                next => Ok(MatchRecognizePattern::Alternation(vec![pattern, next])),
16922            }
16923        } else {
16924            Ok(pattern)
16925        }
16926    }
16927
16928    /// Parses a the timestamp version specifier (i.e. query historical data)
16929    pub fn maybe_parse_table_version(&mut self) -> Result<Option<TableVersion>, ParserError> {
16930        if self.dialect.supports_table_versioning() {
16931            if self.parse_keywords(&[Keyword::FOR, Keyword::SYSTEM_TIME, Keyword::AS, Keyword::OF])
16932            {
16933                let expr = self.parse_expr()?;
16934                return Ok(Some(TableVersion::ForSystemTimeAsOf(expr)));
16935            } else if self.peek_keyword(Keyword::CHANGES) {
16936                return self.parse_table_version_changes().map(Some);
16937            } else if self.peek_keyword(Keyword::AT) || self.peek_keyword(Keyword::BEFORE) {
16938                let func_name = self.parse_object_name(true)?;
16939                let func = self.parse_function(func_name)?;
16940                return Ok(Some(TableVersion::Function(func)));
16941            } else if self.parse_keywords(&[Keyword::TIMESTAMP, Keyword::AS, Keyword::OF]) {
16942                let expr = self.parse_expr()?;
16943                return Ok(Some(TableVersion::TimestampAsOf(expr)));
16944            } else if self.parse_keywords(&[Keyword::VERSION, Keyword::AS, Keyword::OF]) {
16945                let expr = Expr::Value(self.parse_number_value()?);
16946                return Ok(Some(TableVersion::VersionAsOf(expr)));
16947            }
16948        }
16949        Ok(None)
16950    }
16951
16952    /// Parses the Snowflake `CHANGES` clause for change tracking queries.
16953    ///
16954    /// Syntax:
16955    /// ```sql
16956    /// CHANGES (INFORMATION => DEFAULT)
16957    ///   AT (TIMESTAMP => <expr>)
16958    ///   [END (TIMESTAMP => <expr>)]
16959    /// ```
16960    ///
16961    /// <https://docs.snowflake.com/en/sql-reference/constructs/changes>
16962    fn parse_table_version_changes(&mut self) -> Result<TableVersion, ParserError> {
16963        let changes_name = self.parse_object_name(true)?;
16964        let changes = self.parse_function(changes_name)?;
16965        let at_name = self.parse_object_name(true)?;
16966        let at = self.parse_function(at_name)?;
16967        let end = if self.peek_keyword(Keyword::END) {
16968            let end_name = self.parse_object_name(true)?;
16969            Some(self.parse_function(end_name)?)
16970        } else {
16971            None
16972        };
16973        Ok(TableVersion::Changes { changes, at, end })
16974    }
16975
16976    /// Parses MySQL's JSON_TABLE column definition.
16977    /// For example: `id INT EXISTS PATH '$' DEFAULT '0' ON EMPTY ERROR ON ERROR`
16978    pub fn parse_json_table_column_def(&mut self) -> Result<JsonTableColumn, ParserError> {
16979        if self.parse_keyword(Keyword::NESTED) {
16980            let _has_path_keyword = self.parse_keyword(Keyword::PATH);
16981            let path = self.parse_value()?;
16982            self.expect_keyword_is(Keyword::COLUMNS)?;
16983            let columns = self.parse_parenthesized(|p| {
16984                p.parse_comma_separated(Self::parse_json_table_column_def)
16985            })?;
16986            return Ok(JsonTableColumn::Nested(JsonTableNestedColumn {
16987                path,
16988                columns,
16989            }));
16990        }
16991        let name = self.parse_identifier()?;
16992        if self.parse_keyword(Keyword::FOR) {
16993            self.expect_keyword_is(Keyword::ORDINALITY)?;
16994            return Ok(JsonTableColumn::ForOrdinality(name));
16995        }
16996        let r#type = self.parse_data_type()?;
16997        let exists = self.parse_keyword(Keyword::EXISTS);
16998        self.expect_keyword_is(Keyword::PATH)?;
16999        let path = self.parse_value()?;
17000        let mut on_empty = None;
17001        let mut on_error = None;
17002        while let Some(error_handling) = self.parse_json_table_column_error_handling()? {
17003            if self.parse_keyword(Keyword::EMPTY) {
17004                on_empty = Some(error_handling);
17005            } else {
17006                self.expect_keyword_is(Keyword::ERROR)?;
17007                on_error = Some(error_handling);
17008            }
17009        }
17010        Ok(JsonTableColumn::Named(JsonTableNamedColumn {
17011            name,
17012            r#type,
17013            path,
17014            exists,
17015            on_empty,
17016            on_error,
17017        }))
17018    }
17019
17020    /// Parses MSSQL's `OPENJSON WITH` column definition.
17021    ///
17022    /// ```sql
17023    /// colName type [ column_path ] [ AS JSON ]
17024    /// ```
17025    ///
17026    /// Reference: <https://learn.microsoft.com/en-us/sql/t-sql/functions/openjson-transact-sql?view=sql-server-ver16#syntax>
17027    pub fn parse_openjson_table_column_def(&mut self) -> Result<OpenJsonTableColumn, ParserError> {
17028        let name = self.parse_identifier()?;
17029        let r#type = self.parse_data_type()?;
17030        let path = if let Token::SingleQuotedString(path) = self.peek_token().token {
17031            self.next_token();
17032            Some(path)
17033        } else {
17034            None
17035        };
17036        let as_json = self.parse_keyword(Keyword::AS);
17037        if as_json {
17038            self.expect_keyword_is(Keyword::JSON)?;
17039        }
17040        Ok(OpenJsonTableColumn {
17041            name,
17042            r#type,
17043            path,
17044            as_json,
17045        })
17046    }
17047
17048    fn parse_json_table_column_error_handling(
17049        &mut self,
17050    ) -> Result<Option<JsonTableColumnErrorHandling>, ParserError> {
17051        let res = if self.parse_keyword(Keyword::NULL) {
17052            JsonTableColumnErrorHandling::Null
17053        } else if self.parse_keyword(Keyword::ERROR) {
17054            JsonTableColumnErrorHandling::Error
17055        } else if self.parse_keyword(Keyword::DEFAULT) {
17056            JsonTableColumnErrorHandling::Default(self.parse_value()?)
17057        } else {
17058            return Ok(None);
17059        };
17060        self.expect_keyword_is(Keyword::ON)?;
17061        Ok(Some(res))
17062    }
17063
17064    /// Parse a derived table factor (a parenthesized subquery), handling optional LATERAL.
17065    pub fn parse_derived_table_factor(
17066        &mut self,
17067        lateral: IsLateral,
17068    ) -> Result<TableFactor, ParserError> {
17069        let subquery = self.parse_query()?;
17070        self.expect_token(&Token::RParen)?;
17071        let alias = self.maybe_parse_table_alias()?;
17072
17073        // Parse optional SAMPLE clause after alias
17074        let sample = self
17075            .maybe_parse_table_sample()?
17076            .map(TableSampleKind::AfterTableAlias);
17077
17078        Ok(TableFactor::Derived {
17079            lateral: match lateral {
17080                Lateral => true,
17081                NotLateral => false,
17082            },
17083            subquery,
17084            alias,
17085            sample,
17086        })
17087    }
17088
17089    /// Parses an expression with an optional alias
17090    ///
17091    /// Examples:
17092    ///
17093    /// ```sql
17094    /// SUM(price) AS total_price
17095    /// ```
17096    /// ```sql
17097    /// SUM(price)
17098    /// ```
17099    ///
17100    /// Example
17101    /// ```
17102    /// # use sqlparser::parser::{Parser, ParserError};
17103    /// # use sqlparser::dialect::GenericDialect;
17104    /// # fn main() ->Result<(), ParserError> {
17105    /// let sql = r#"SUM("a") as "b""#;
17106    /// let mut parser = Parser::new(&GenericDialect).try_with_sql(sql)?;
17107    /// let expr_with_alias = parser.parse_expr_with_alias()?;
17108    /// assert_eq!(Some("b".to_string()), expr_with_alias.alias.map(|x|x.value));
17109    /// # Ok(())
17110    /// # }
17111    pub fn parse_expr_with_alias(&mut self) -> Result<ExprWithAlias, ParserError> {
17112        let expr = self.parse_expr()?;
17113        let alias = if self.parse_keyword(Keyword::AS) {
17114            Some(self.parse_identifier()?)
17115        } else {
17116            None
17117        };
17118
17119        Ok(ExprWithAlias { expr, alias })
17120    }
17121
17122    /// Parse an expression followed by an optional alias; Unlike
17123    /// [Self::parse_expr_with_alias] the "AS" keyword between the expression
17124    /// and the alias is optional.
17125    fn parse_expr_with_alias_optional_as_keyword(&mut self) -> Result<ExprWithAlias, ParserError> {
17126        let expr = self.parse_expr()?;
17127        let alias = self.parse_identifier_optional_alias()?;
17128        Ok(ExprWithAlias { expr, alias })
17129    }
17130
17131    /// Parses a plain function call with an optional alias for the `PIVOT` clause
17132    fn parse_pivot_aggregate_function(&mut self) -> Result<ExprWithAlias, ParserError> {
17133        let function_name = match self.next_token().token {
17134            Token::Word(w) => Ok(w.value),
17135            _ => self.expected_ref("a function identifier", self.peek_token_ref()),
17136        }?;
17137        let expr = self.parse_function(ObjectName::from(vec![Ident::new(function_name)]))?;
17138        let alias = {
17139            fn validator(explicit: bool, kw: &Keyword, parser: &mut Parser) -> bool {
17140                // ~ for a PIVOT aggregate function the alias must not be a "FOR"; in any dialect
17141                kw != &Keyword::FOR && parser.dialect.is_select_item_alias(explicit, kw, parser)
17142            }
17143            self.parse_optional_alias_inner(None, validator)?
17144        };
17145        Ok(ExprWithAlias { expr, alias })
17146    }
17147
17148    /// Parse a PIVOT table factor (ClickHouse/Oracle style pivot), returning a TableFactor.
17149    pub fn parse_pivot_table_factor(
17150        &mut self,
17151        table: TableFactor,
17152    ) -> Result<TableFactor, ParserError> {
17153        self.expect_token(&Token::LParen)?;
17154        let aggregate_functions =
17155            self.parse_comma_separated(Self::parse_pivot_aggregate_function)?;
17156        self.expect_keyword_is(Keyword::FOR)?;
17157        let value_column = if self.peek_token_ref().token == Token::LParen {
17158            self.parse_parenthesized_column_list_inner(Mandatory, false, |p| {
17159                p.parse_subexpr(self.dialect.prec_value(Precedence::Between))
17160            })?
17161        } else {
17162            vec![self.parse_subexpr(self.dialect.prec_value(Precedence::Between))?]
17163        };
17164        self.expect_keyword_is(Keyword::IN)?;
17165
17166        self.expect_token(&Token::LParen)?;
17167        let value_source = if self.parse_keyword(Keyword::ANY) {
17168            let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
17169                self.parse_comma_separated(Parser::parse_order_by_expr)?
17170            } else {
17171                vec![]
17172            };
17173            PivotValueSource::Any(order_by)
17174        } else if self.peek_sub_query() {
17175            PivotValueSource::Subquery(self.parse_query()?)
17176        } else {
17177            PivotValueSource::List(
17178                self.parse_comma_separated(Self::parse_expr_with_alias_optional_as_keyword)?,
17179            )
17180        };
17181        self.expect_token(&Token::RParen)?;
17182
17183        let default_on_null =
17184            if self.parse_keywords(&[Keyword::DEFAULT, Keyword::ON, Keyword::NULL]) {
17185                self.expect_token(&Token::LParen)?;
17186                let expr = self.parse_expr()?;
17187                self.expect_token(&Token::RParen)?;
17188                Some(expr)
17189            } else {
17190                None
17191            };
17192
17193        self.expect_token(&Token::RParen)?;
17194        let alias = self.maybe_parse_table_alias()?;
17195        Ok(TableFactor::Pivot {
17196            table: Box::new(table),
17197            aggregate_functions,
17198            value_column,
17199            value_source,
17200            default_on_null,
17201            alias,
17202        })
17203    }
17204
17205    /// Parse an UNPIVOT table factor, returning a TableFactor.
17206    pub fn parse_unpivot_table_factor(
17207        &mut self,
17208        table: TableFactor,
17209    ) -> Result<TableFactor, ParserError> {
17210        let null_inclusion = if self.parse_keyword(Keyword::INCLUDE) {
17211            self.expect_keyword_is(Keyword::NULLS)?;
17212            Some(NullInclusion::IncludeNulls)
17213        } else if self.parse_keyword(Keyword::EXCLUDE) {
17214            self.expect_keyword_is(Keyword::NULLS)?;
17215            Some(NullInclusion::ExcludeNulls)
17216        } else {
17217            None
17218        };
17219        self.expect_token(&Token::LParen)?;
17220        let value = self.parse_expr()?;
17221        self.expect_keyword_is(Keyword::FOR)?;
17222        let name = self.parse_identifier()?;
17223        self.expect_keyword_is(Keyword::IN)?;
17224        let columns = self.parse_parenthesized_column_list_inner(Mandatory, false, |p| {
17225            p.parse_expr_with_alias()
17226        })?;
17227        self.expect_token(&Token::RParen)?;
17228        let alias = self.maybe_parse_table_alias()?;
17229        Ok(TableFactor::Unpivot {
17230            table: Box::new(table),
17231            value,
17232            null_inclusion,
17233            name,
17234            columns,
17235            alias,
17236        })
17237    }
17238
17239    /// Parse a JOIN constraint (`NATURAL`, `ON <expr>`, `USING (...)`, or no constraint).
17240    pub fn parse_join_constraint(&mut self, natural: bool) -> Result<JoinConstraint, ParserError> {
17241        if natural {
17242            Ok(JoinConstraint::Natural)
17243        } else if self.parse_keyword(Keyword::ON) {
17244            let constraint = self.parse_expr()?;
17245            Ok(JoinConstraint::On(constraint))
17246        } else if self.parse_keyword(Keyword::USING) {
17247            let columns = self.parse_parenthesized_qualified_column_list(Mandatory, false)?;
17248            Ok(JoinConstraint::Using(columns))
17249        } else {
17250            Ok(JoinConstraint::None)
17251            //self.expected_ref("ON, or USING after JOIN", self.peek_token_ref())
17252        }
17253    }
17254
17255    /// Parse a GRANT statement.
17256    pub fn parse_grant(&mut self) -> Result<Grant, ParserError> {
17257        let (privileges, objects) = self.parse_grant_deny_revoke_privileges_objects()?;
17258
17259        self.expect_keyword_is(Keyword::TO)?;
17260        let grantees = self.parse_grantees()?;
17261
17262        let with_grant_option =
17263            self.parse_keywords(&[Keyword::WITH, Keyword::GRANT, Keyword::OPTION]);
17264
17265        let current_grants =
17266            if self.parse_keywords(&[Keyword::COPY, Keyword::CURRENT, Keyword::GRANTS]) {
17267                Some(CurrentGrantsKind::CopyCurrentGrants)
17268            } else if self.parse_keywords(&[Keyword::REVOKE, Keyword::CURRENT, Keyword::GRANTS]) {
17269                Some(CurrentGrantsKind::RevokeCurrentGrants)
17270            } else {
17271                None
17272            };
17273
17274        let as_grantor = if self.parse_keywords(&[Keyword::AS]) {
17275            Some(self.parse_identifier()?)
17276        } else {
17277            None
17278        };
17279
17280        let granted_by = if self.parse_keywords(&[Keyword::GRANTED, Keyword::BY]) {
17281            Some(self.parse_identifier()?)
17282        } else {
17283            None
17284        };
17285
17286        Ok(Grant {
17287            privileges,
17288            objects,
17289            grantees,
17290            with_grant_option,
17291            as_grantor,
17292            granted_by,
17293            current_grants,
17294        })
17295    }
17296
17297    fn parse_grantees(&mut self) -> Result<Vec<Grantee>, ParserError> {
17298        let mut values = vec![];
17299        let mut grantee_type = GranteesType::None;
17300        loop {
17301            let new_grantee_type = if self.parse_keyword(Keyword::ROLE) {
17302                GranteesType::Role
17303            } else if self.parse_keyword(Keyword::USER) {
17304                GranteesType::User
17305            } else if self.parse_keyword(Keyword::SHARE) {
17306                GranteesType::Share
17307            } else if self.parse_keyword(Keyword::GROUP) {
17308                GranteesType::Group
17309            } else if self.parse_keyword(Keyword::PUBLIC) {
17310                GranteesType::Public
17311            } else if self.parse_keywords(&[Keyword::DATABASE, Keyword::ROLE]) {
17312                GranteesType::DatabaseRole
17313            } else if self.parse_keywords(&[Keyword::APPLICATION, Keyword::ROLE]) {
17314                GranteesType::ApplicationRole
17315            } else if self.parse_keyword(Keyword::APPLICATION) {
17316                GranteesType::Application
17317            } else {
17318                grantee_type.clone() // keep from previous iteraton, if not specified
17319            };
17320
17321            if self
17322                .dialect
17323                .get_reserved_grantees_types()
17324                .contains(&new_grantee_type)
17325            {
17326                self.prev_token();
17327            } else {
17328                grantee_type = new_grantee_type;
17329            }
17330
17331            let grantee = if grantee_type == GranteesType::Public {
17332                Grantee {
17333                    grantee_type: grantee_type.clone(),
17334                    name: None,
17335                }
17336            } else {
17337                let mut name = self.parse_grantee_name()?;
17338                if self.consume_token(&Token::Colon) {
17339                    // Redshift supports namespace prefix for external users and groups:
17340                    // <Namespace>:<GroupName> or <Namespace>:<UserName>
17341                    // https://docs.aws.amazon.com/redshift/latest/mgmt/redshift-iam-access-control-native-idp.html
17342                    let ident = self.parse_identifier()?;
17343                    if let GranteeName::ObjectName(namespace) = name {
17344                        name = GranteeName::ObjectName(ObjectName::from(vec![Ident::new(
17345                            format!("{namespace}:{ident}"),
17346                        )]));
17347                    };
17348                }
17349                Grantee {
17350                    grantee_type: grantee_type.clone(),
17351                    name: Some(name),
17352                }
17353            };
17354
17355            values.push(grantee);
17356
17357            if !self.consume_token(&Token::Comma) {
17358                break;
17359            }
17360        }
17361
17362        Ok(values)
17363    }
17364
17365    /// Parse privileges and optional target objects for GRANT/DENY/REVOKE statements.
17366    pub fn parse_grant_deny_revoke_privileges_objects(
17367        &mut self,
17368    ) -> Result<(Privileges, Option<GrantObjects>), ParserError> {
17369        let privileges = if self.parse_keyword(Keyword::ALL) {
17370            Privileges::All {
17371                with_privileges_keyword: self.parse_keyword(Keyword::PRIVILEGES),
17372            }
17373        } else {
17374            let actions = self.parse_actions_list()?;
17375            Privileges::Actions(actions)
17376        };
17377
17378        let objects = if self.parse_keyword(Keyword::ON) {
17379            if self.parse_keywords(&[Keyword::ALL, Keyword::TABLES, Keyword::IN, Keyword::SCHEMA]) {
17380                Some(GrantObjects::AllTablesInSchema {
17381                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17382                })
17383            } else if self.parse_keywords(&[
17384                Keyword::ALL,
17385                Keyword::EXTERNAL,
17386                Keyword::TABLES,
17387                Keyword::IN,
17388                Keyword::SCHEMA,
17389            ]) {
17390                Some(GrantObjects::AllExternalTablesInSchema {
17391                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17392                })
17393            } else if self.parse_keywords(&[
17394                Keyword::ALL,
17395                Keyword::VIEWS,
17396                Keyword::IN,
17397                Keyword::SCHEMA,
17398            ]) {
17399                Some(GrantObjects::AllViewsInSchema {
17400                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17401                })
17402            } else if self.parse_keywords(&[
17403                Keyword::ALL,
17404                Keyword::MATERIALIZED,
17405                Keyword::VIEWS,
17406                Keyword::IN,
17407                Keyword::SCHEMA,
17408            ]) {
17409                Some(GrantObjects::AllMaterializedViewsInSchema {
17410                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17411                })
17412            } else if self.parse_keywords(&[
17413                Keyword::ALL,
17414                Keyword::FUNCTIONS,
17415                Keyword::IN,
17416                Keyword::SCHEMA,
17417            ]) {
17418                Some(GrantObjects::AllFunctionsInSchema {
17419                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17420                })
17421            } else if self.parse_keywords(&[
17422                Keyword::FUTURE,
17423                Keyword::SCHEMAS,
17424                Keyword::IN,
17425                Keyword::DATABASE,
17426            ]) {
17427                Some(GrantObjects::FutureSchemasInDatabase {
17428                    databases: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17429                })
17430            } else if self.parse_keywords(&[
17431                Keyword::FUTURE,
17432                Keyword::TABLES,
17433                Keyword::IN,
17434                Keyword::SCHEMA,
17435            ]) {
17436                Some(GrantObjects::FutureTablesInSchema {
17437                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17438                })
17439            } else if self.parse_keywords(&[
17440                Keyword::FUTURE,
17441                Keyword::EXTERNAL,
17442                Keyword::TABLES,
17443                Keyword::IN,
17444                Keyword::SCHEMA,
17445            ]) {
17446                Some(GrantObjects::FutureExternalTablesInSchema {
17447                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17448                })
17449            } else if self.parse_keywords(&[
17450                Keyword::FUTURE,
17451                Keyword::VIEWS,
17452                Keyword::IN,
17453                Keyword::SCHEMA,
17454            ]) {
17455                Some(GrantObjects::FutureViewsInSchema {
17456                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17457                })
17458            } else if self.parse_keywords(&[
17459                Keyword::FUTURE,
17460                Keyword::MATERIALIZED,
17461                Keyword::VIEWS,
17462                Keyword::IN,
17463                Keyword::SCHEMA,
17464            ]) {
17465                Some(GrantObjects::FutureMaterializedViewsInSchema {
17466                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17467                })
17468            } else if self.parse_keywords(&[
17469                Keyword::ALL,
17470                Keyword::SEQUENCES,
17471                Keyword::IN,
17472                Keyword::SCHEMA,
17473            ]) {
17474                Some(GrantObjects::AllSequencesInSchema {
17475                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17476                })
17477            } else if self.parse_keywords(&[
17478                Keyword::FUTURE,
17479                Keyword::SEQUENCES,
17480                Keyword::IN,
17481                Keyword::SCHEMA,
17482            ]) {
17483                Some(GrantObjects::FutureSequencesInSchema {
17484                    schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
17485                })
17486            } else if self.parse_keywords(&[Keyword::RESOURCE, Keyword::MONITOR]) {
17487                Some(GrantObjects::ResourceMonitors(
17488                    self.parse_comma_separated(|p| p.parse_object_name(false))?,
17489                ))
17490            } else if self.parse_keywords(&[Keyword::COMPUTE, Keyword::POOL]) {
17491                Some(GrantObjects::ComputePools(
17492                    self.parse_comma_separated(|p| p.parse_object_name(false))?,
17493                ))
17494            } else if self.parse_keywords(&[Keyword::FAILOVER, Keyword::GROUP]) {
17495                Some(GrantObjects::FailoverGroup(
17496                    self.parse_comma_separated(|p| p.parse_object_name(false))?,
17497                ))
17498            } else if self.parse_keywords(&[Keyword::REPLICATION, Keyword::GROUP]) {
17499                Some(GrantObjects::ReplicationGroup(
17500                    self.parse_comma_separated(|p| p.parse_object_name(false))?,
17501                ))
17502            } else if self.parse_keywords(&[Keyword::EXTERNAL, Keyword::VOLUME]) {
17503                Some(GrantObjects::ExternalVolumes(
17504                    self.parse_comma_separated(|p| p.parse_object_name(false))?,
17505                ))
17506            } else {
17507                let object_type = self.parse_one_of_keywords(&[
17508                    Keyword::SEQUENCE,
17509                    Keyword::DATABASE,
17510                    Keyword::SCHEMA,
17511                    Keyword::TABLE,
17512                    Keyword::VIEW,
17513                    Keyword::WAREHOUSE,
17514                    Keyword::INTEGRATION,
17515                    Keyword::VIEW,
17516                    Keyword::WAREHOUSE,
17517                    Keyword::INTEGRATION,
17518                    Keyword::USER,
17519                    Keyword::CONNECTION,
17520                    Keyword::PROCEDURE,
17521                    Keyword::FUNCTION,
17522                ]);
17523                let objects =
17524                    self.parse_comma_separated(|p| p.parse_object_name_inner(false, true));
17525                match object_type {
17526                    Some(Keyword::DATABASE) => Some(GrantObjects::Databases(objects?)),
17527                    Some(Keyword::SCHEMA) => Some(GrantObjects::Schemas(objects?)),
17528                    Some(Keyword::SEQUENCE) => Some(GrantObjects::Sequences(objects?)),
17529                    Some(Keyword::WAREHOUSE) => Some(GrantObjects::Warehouses(objects?)),
17530                    Some(Keyword::INTEGRATION) => Some(GrantObjects::Integrations(objects?)),
17531                    Some(Keyword::VIEW) => Some(GrantObjects::Views(objects?)),
17532                    Some(Keyword::USER) => Some(GrantObjects::Users(objects?)),
17533                    Some(Keyword::CONNECTION) => Some(GrantObjects::Connections(objects?)),
17534                    kw @ (Some(Keyword::PROCEDURE) | Some(Keyword::FUNCTION)) => {
17535                        if let Some(name) = objects?.first() {
17536                            self.parse_grant_procedure_or_function(name, &kw)?
17537                        } else {
17538                            self.expected_ref("procedure or function name", self.peek_token_ref())?
17539                        }
17540                    }
17541                    Some(Keyword::TABLE) | None => Some(GrantObjects::Tables(objects?)),
17542                    Some(unexpected_keyword) => return Err(ParserError::ParserError(
17543                        format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in grant objects"),
17544                    )),
17545                }
17546            }
17547        } else {
17548            None
17549        };
17550
17551        Ok((privileges, objects))
17552    }
17553
17554    fn parse_grant_procedure_or_function(
17555        &mut self,
17556        name: &ObjectName,
17557        kw: &Option<Keyword>,
17558    ) -> Result<Option<GrantObjects>, ParserError> {
17559        let arg_types = if self.consume_token(&Token::LParen) {
17560            let list = self.parse_comma_separated0(Self::parse_data_type, Token::RParen)?;
17561            self.expect_token(&Token::RParen)?;
17562            list
17563        } else {
17564            vec![]
17565        };
17566        match kw {
17567            Some(Keyword::PROCEDURE) => Ok(Some(GrantObjects::Procedure {
17568                name: name.clone(),
17569                arg_types,
17570            })),
17571            Some(Keyword::FUNCTION) => Ok(Some(GrantObjects::Function {
17572                name: name.clone(),
17573                arg_types,
17574            })),
17575            _ => self.expected_ref("procedure or function keywords", self.peek_token_ref())?,
17576        }
17577    }
17578
17579    /// Parse a single grantable permission/action (used within GRANT statements).
17580    pub fn parse_grant_permission(&mut self) -> Result<Action, ParserError> {
17581        fn parse_columns(parser: &mut Parser) -> Result<Option<Vec<Ident>>, ParserError> {
17582            let columns = parser.parse_parenthesized_column_list(Optional, false)?;
17583            if columns.is_empty() {
17584                Ok(None)
17585            } else {
17586                Ok(Some(columns))
17587            }
17588        }
17589
17590        // Multi-word privileges
17591        if self.parse_keywords(&[Keyword::IMPORTED, Keyword::PRIVILEGES]) {
17592            Ok(Action::ImportedPrivileges)
17593        } else if self.parse_keywords(&[Keyword::ADD, Keyword::SEARCH, Keyword::OPTIMIZATION]) {
17594            Ok(Action::AddSearchOptimization)
17595        } else if self.parse_keywords(&[Keyword::ATTACH, Keyword::LISTING]) {
17596            Ok(Action::AttachListing)
17597        } else if self.parse_keywords(&[Keyword::ATTACH, Keyword::POLICY]) {
17598            Ok(Action::AttachPolicy)
17599        } else if self.parse_keywords(&[Keyword::BIND, Keyword::SERVICE, Keyword::ENDPOINT]) {
17600            Ok(Action::BindServiceEndpoint)
17601        } else if self.parse_keywords(&[Keyword::DATABASE, Keyword::ROLE]) {
17602            let role = self.parse_object_name(false)?;
17603            Ok(Action::DatabaseRole { role })
17604        } else if self.parse_keywords(&[Keyword::EVOLVE, Keyword::SCHEMA]) {
17605            Ok(Action::EvolveSchema)
17606        } else if self.parse_keywords(&[Keyword::IMPORT, Keyword::SHARE]) {
17607            Ok(Action::ImportShare)
17608        } else if self.parse_keywords(&[Keyword::MANAGE, Keyword::VERSIONS]) {
17609            Ok(Action::ManageVersions)
17610        } else if self.parse_keywords(&[Keyword::MANAGE, Keyword::RELEASES]) {
17611            Ok(Action::ManageReleases)
17612        } else if self.parse_keywords(&[Keyword::OVERRIDE, Keyword::SHARE, Keyword::RESTRICTIONS]) {
17613            Ok(Action::OverrideShareRestrictions)
17614        } else if self.parse_keywords(&[
17615            Keyword::PURCHASE,
17616            Keyword::DATA,
17617            Keyword::EXCHANGE,
17618            Keyword::LISTING,
17619        ]) {
17620            Ok(Action::PurchaseDataExchangeListing)
17621        } else if self.parse_keywords(&[Keyword::RESOLVE, Keyword::ALL]) {
17622            Ok(Action::ResolveAll)
17623        } else if self.parse_keywords(&[Keyword::READ, Keyword::SESSION]) {
17624            Ok(Action::ReadSession)
17625
17626        // Single-word privileges
17627        } else if self.parse_keyword(Keyword::APPLY) {
17628            let apply_type = self.parse_action_apply_type()?;
17629            Ok(Action::Apply { apply_type })
17630        } else if self.parse_keyword(Keyword::APPLYBUDGET) {
17631            Ok(Action::ApplyBudget)
17632        } else if self.parse_keyword(Keyword::AUDIT) {
17633            Ok(Action::Audit)
17634        } else if self.parse_keyword(Keyword::CONNECT) {
17635            Ok(Action::Connect)
17636        } else if self.parse_keyword(Keyword::CREATE) {
17637            let obj_type = self.maybe_parse_action_create_object_type();
17638            Ok(Action::Create { obj_type })
17639        } else if self.parse_keyword(Keyword::DELETE) {
17640            Ok(Action::Delete)
17641        } else if self.parse_keyword(Keyword::EXEC) {
17642            let obj_type = self.maybe_parse_action_execute_obj_type();
17643            Ok(Action::Exec { obj_type })
17644        } else if self.parse_keyword(Keyword::EXECUTE) {
17645            let obj_type = self.maybe_parse_action_execute_obj_type();
17646            Ok(Action::Execute { obj_type })
17647        } else if self.parse_keyword(Keyword::FAILOVER) {
17648            Ok(Action::Failover)
17649        } else if self.parse_keyword(Keyword::INSERT) {
17650            Ok(Action::Insert {
17651                columns: parse_columns(self)?,
17652            })
17653        } else if self.parse_keyword(Keyword::MANAGE) {
17654            let manage_type = self.parse_action_manage_type()?;
17655            Ok(Action::Manage { manage_type })
17656        } else if self.parse_keyword(Keyword::MODIFY) {
17657            let modify_type = self.parse_action_modify_type();
17658            Ok(Action::Modify { modify_type })
17659        } else if self.parse_keyword(Keyword::MONITOR) {
17660            let monitor_type = self.parse_action_monitor_type();
17661            Ok(Action::Monitor { monitor_type })
17662        } else if self.parse_keyword(Keyword::OPERATE) {
17663            Ok(Action::Operate)
17664        } else if self.parse_keyword(Keyword::REFERENCES) {
17665            Ok(Action::References {
17666                columns: parse_columns(self)?,
17667            })
17668        } else if self.parse_keyword(Keyword::READ) {
17669            Ok(Action::Read)
17670        } else if self.parse_keyword(Keyword::REPLICATE) {
17671            Ok(Action::Replicate)
17672        } else if self.parse_keyword(Keyword::ROLE) {
17673            let role = self.parse_object_name(false)?;
17674            Ok(Action::Role { role })
17675        } else if self.parse_keyword(Keyword::SELECT) {
17676            Ok(Action::Select {
17677                columns: parse_columns(self)?,
17678            })
17679        } else if self.parse_keyword(Keyword::TEMPORARY) {
17680            Ok(Action::Temporary)
17681        } else if self.parse_keyword(Keyword::TRIGGER) {
17682            Ok(Action::Trigger)
17683        } else if self.parse_keyword(Keyword::TRUNCATE) {
17684            Ok(Action::Truncate)
17685        } else if self.parse_keyword(Keyword::UPDATE) {
17686            Ok(Action::Update {
17687                columns: parse_columns(self)?,
17688            })
17689        } else if self.parse_keyword(Keyword::USAGE) {
17690            Ok(Action::Usage)
17691        } else if self.parse_keyword(Keyword::OWNERSHIP) {
17692            Ok(Action::Ownership)
17693        } else if self.parse_keyword(Keyword::DROP) {
17694            Ok(Action::Drop)
17695        } else {
17696            self.expected_ref("a privilege keyword", self.peek_token_ref())?
17697        }
17698    }
17699
17700    fn maybe_parse_action_create_object_type(&mut self) -> Option<ActionCreateObjectType> {
17701        // Multi-word object types
17702        if self.parse_keywords(&[Keyword::APPLICATION, Keyword::PACKAGE]) {
17703            Some(ActionCreateObjectType::ApplicationPackage)
17704        } else if self.parse_keywords(&[Keyword::COMPUTE, Keyword::POOL]) {
17705            Some(ActionCreateObjectType::ComputePool)
17706        } else if self.parse_keywords(&[Keyword::DATA, Keyword::EXCHANGE, Keyword::LISTING]) {
17707            Some(ActionCreateObjectType::DataExchangeListing)
17708        } else if self.parse_keywords(&[Keyword::EXTERNAL, Keyword::VOLUME]) {
17709            Some(ActionCreateObjectType::ExternalVolume)
17710        } else if self.parse_keywords(&[Keyword::FAILOVER, Keyword::GROUP]) {
17711            Some(ActionCreateObjectType::FailoverGroup)
17712        } else if self.parse_keywords(&[Keyword::NETWORK, Keyword::POLICY]) {
17713            Some(ActionCreateObjectType::NetworkPolicy)
17714        } else if self.parse_keywords(&[Keyword::ORGANIZATION, Keyword::LISTING]) {
17715            Some(ActionCreateObjectType::OrganiationListing)
17716        } else if self.parse_keywords(&[Keyword::REPLICATION, Keyword::GROUP]) {
17717            Some(ActionCreateObjectType::ReplicationGroup)
17718        }
17719        // Single-word object types
17720        else if self.parse_keyword(Keyword::ACCOUNT) {
17721            Some(ActionCreateObjectType::Account)
17722        } else if self.parse_keyword(Keyword::APPLICATION) {
17723            Some(ActionCreateObjectType::Application)
17724        } else if self.parse_keyword(Keyword::DATABASE) {
17725            Some(ActionCreateObjectType::Database)
17726        } else if self.parse_keyword(Keyword::INTEGRATION) {
17727            Some(ActionCreateObjectType::Integration)
17728        } else if self.parse_keyword(Keyword::ROLE) {
17729            Some(ActionCreateObjectType::Role)
17730        } else if self.parse_keyword(Keyword::SCHEMA) {
17731            Some(ActionCreateObjectType::Schema)
17732        } else if self.parse_keyword(Keyword::SHARE) {
17733            Some(ActionCreateObjectType::Share)
17734        } else if self.parse_keyword(Keyword::USER) {
17735            Some(ActionCreateObjectType::User)
17736        } else if self.parse_keyword(Keyword::WAREHOUSE) {
17737            Some(ActionCreateObjectType::Warehouse)
17738        } else {
17739            None
17740        }
17741    }
17742
17743    fn parse_action_apply_type(&mut self) -> Result<ActionApplyType, ParserError> {
17744        if self.parse_keywords(&[Keyword::AGGREGATION, Keyword::POLICY]) {
17745            Ok(ActionApplyType::AggregationPolicy)
17746        } else if self.parse_keywords(&[Keyword::AUTHENTICATION, Keyword::POLICY]) {
17747            Ok(ActionApplyType::AuthenticationPolicy)
17748        } else if self.parse_keywords(&[Keyword::JOIN, Keyword::POLICY]) {
17749            Ok(ActionApplyType::JoinPolicy)
17750        } else if self.parse_keywords(&[Keyword::MASKING, Keyword::POLICY]) {
17751            Ok(ActionApplyType::MaskingPolicy)
17752        } else if self.parse_keywords(&[Keyword::PACKAGES, Keyword::POLICY]) {
17753            Ok(ActionApplyType::PackagesPolicy)
17754        } else if self.parse_keywords(&[Keyword::PASSWORD, Keyword::POLICY]) {
17755            Ok(ActionApplyType::PasswordPolicy)
17756        } else if self.parse_keywords(&[Keyword::PROJECTION, Keyword::POLICY]) {
17757            Ok(ActionApplyType::ProjectionPolicy)
17758        } else if self.parse_keywords(&[Keyword::ROW, Keyword::ACCESS, Keyword::POLICY]) {
17759            Ok(ActionApplyType::RowAccessPolicy)
17760        } else if self.parse_keywords(&[Keyword::SESSION, Keyword::POLICY]) {
17761            Ok(ActionApplyType::SessionPolicy)
17762        } else if self.parse_keyword(Keyword::TAG) {
17763            Ok(ActionApplyType::Tag)
17764        } else {
17765            self.expected_ref("GRANT APPLY type", self.peek_token_ref())
17766        }
17767    }
17768
17769    fn maybe_parse_action_execute_obj_type(&mut self) -> Option<ActionExecuteObjectType> {
17770        if self.parse_keywords(&[Keyword::DATA, Keyword::METRIC, Keyword::FUNCTION]) {
17771            Some(ActionExecuteObjectType::DataMetricFunction)
17772        } else if self.parse_keywords(&[Keyword::MANAGED, Keyword::ALERT]) {
17773            Some(ActionExecuteObjectType::ManagedAlert)
17774        } else if self.parse_keywords(&[Keyword::MANAGED, Keyword::TASK]) {
17775            Some(ActionExecuteObjectType::ManagedTask)
17776        } else if self.parse_keyword(Keyword::ALERT) {
17777            Some(ActionExecuteObjectType::Alert)
17778        } else if self.parse_keyword(Keyword::TASK) {
17779            Some(ActionExecuteObjectType::Task)
17780        } else {
17781            None
17782        }
17783    }
17784
17785    fn parse_action_manage_type(&mut self) -> Result<ActionManageType, ParserError> {
17786        if self.parse_keywords(&[Keyword::ACCOUNT, Keyword::SUPPORT, Keyword::CASES]) {
17787            Ok(ActionManageType::AccountSupportCases)
17788        } else if self.parse_keywords(&[Keyword::EVENT, Keyword::SHARING]) {
17789            Ok(ActionManageType::EventSharing)
17790        } else if self.parse_keywords(&[Keyword::LISTING, Keyword::AUTO, Keyword::FULFILLMENT]) {
17791            Ok(ActionManageType::ListingAutoFulfillment)
17792        } else if self.parse_keywords(&[Keyword::ORGANIZATION, Keyword::SUPPORT, Keyword::CASES]) {
17793            Ok(ActionManageType::OrganizationSupportCases)
17794        } else if self.parse_keywords(&[Keyword::USER, Keyword::SUPPORT, Keyword::CASES]) {
17795            Ok(ActionManageType::UserSupportCases)
17796        } else if self.parse_keyword(Keyword::GRANTS) {
17797            Ok(ActionManageType::Grants)
17798        } else if self.parse_keyword(Keyword::WAREHOUSES) {
17799            Ok(ActionManageType::Warehouses)
17800        } else {
17801            self.expected_ref("GRANT MANAGE type", self.peek_token_ref())
17802        }
17803    }
17804
17805    fn parse_action_modify_type(&mut self) -> Option<ActionModifyType> {
17806        if self.parse_keywords(&[Keyword::LOG, Keyword::LEVEL]) {
17807            Some(ActionModifyType::LogLevel)
17808        } else if self.parse_keywords(&[Keyword::TRACE, Keyword::LEVEL]) {
17809            Some(ActionModifyType::TraceLevel)
17810        } else if self.parse_keywords(&[Keyword::SESSION, Keyword::LOG, Keyword::LEVEL]) {
17811            Some(ActionModifyType::SessionLogLevel)
17812        } else if self.parse_keywords(&[Keyword::SESSION, Keyword::TRACE, Keyword::LEVEL]) {
17813            Some(ActionModifyType::SessionTraceLevel)
17814        } else {
17815            None
17816        }
17817    }
17818
17819    fn parse_action_monitor_type(&mut self) -> Option<ActionMonitorType> {
17820        if self.parse_keyword(Keyword::EXECUTION) {
17821            Some(ActionMonitorType::Execution)
17822        } else if self.parse_keyword(Keyword::SECURITY) {
17823            Some(ActionMonitorType::Security)
17824        } else if self.parse_keyword(Keyword::USAGE) {
17825            Some(ActionMonitorType::Usage)
17826        } else {
17827            None
17828        }
17829    }
17830
17831    /// Parse a grantee name, possibly with a host qualifier (user@host).
17832    pub fn parse_grantee_name(&mut self) -> Result<GranteeName, ParserError> {
17833        let mut name = self.parse_object_name(false)?;
17834        if self.dialect.supports_user_host_grantee()
17835            && name.0.len() == 1
17836            && name.0[0].as_ident().is_some()
17837            && self.consume_token(&Token::AtSign)
17838        {
17839            let user = name.0.pop().unwrap().as_ident().unwrap().clone();
17840            let host = self.parse_identifier()?;
17841            Ok(GranteeName::UserHost { user, host })
17842        } else {
17843            Ok(GranteeName::ObjectName(name))
17844        }
17845    }
17846
17847    /// Parse [`Statement::Deny`]
17848    pub fn parse_deny(&mut self) -> Result<Statement, ParserError> {
17849        self.expect_keyword(Keyword::DENY)?;
17850
17851        let (privileges, objects) = self.parse_grant_deny_revoke_privileges_objects()?;
17852        let objects = match objects {
17853            Some(o) => o,
17854            None => {
17855                return parser_err!(
17856                    "DENY statements must specify an object",
17857                    self.peek_token_ref().span.start
17858                )
17859            }
17860        };
17861
17862        self.expect_keyword_is(Keyword::TO)?;
17863        let grantees = self.parse_grantees()?;
17864        let cascade = self.parse_cascade_option();
17865        let granted_by = if self.parse_keywords(&[Keyword::AS]) {
17866            Some(self.parse_identifier()?)
17867        } else {
17868            None
17869        };
17870
17871        Ok(Statement::Deny(DenyStatement {
17872            privileges,
17873            objects,
17874            grantees,
17875            cascade,
17876            granted_by,
17877        }))
17878    }
17879
17880    /// Parse a REVOKE statement
17881    pub fn parse_revoke(&mut self) -> Result<Revoke, ParserError> {
17882        let (privileges, objects) = self.parse_grant_deny_revoke_privileges_objects()?;
17883
17884        self.expect_keyword_is(Keyword::FROM)?;
17885        let grantees = self.parse_grantees()?;
17886
17887        let granted_by = if self.parse_keywords(&[Keyword::GRANTED, Keyword::BY]) {
17888            Some(self.parse_identifier()?)
17889        } else {
17890            None
17891        };
17892
17893        let cascade = self.parse_cascade_option();
17894
17895        Ok(Revoke {
17896            privileges,
17897            objects,
17898            grantees,
17899            granted_by,
17900            cascade,
17901        })
17902    }
17903
17904    /// Parse an REPLACE statement
17905    pub fn parse_replace(
17906        &mut self,
17907        replace_token: TokenWithSpan,
17908    ) -> Result<Statement, ParserError> {
17909        if !dialect_of!(self is MySqlDialect | GenericDialect) {
17910            return parser_err!(
17911                "Unsupported statement REPLACE",
17912                self.peek_token_ref().span.start
17913            );
17914        }
17915
17916        let mut insert = self.parse_insert(replace_token)?;
17917        if let Statement::Insert(Insert { replace_into, .. }) = &mut insert {
17918            *replace_into = true;
17919        }
17920
17921        Ok(insert)
17922    }
17923
17924    /// Parse an INSERT statement, returning a `Box`ed SetExpr
17925    ///
17926    /// This is used to reduce the size of the stack frames in debug builds
17927    fn parse_insert_setexpr_boxed(
17928        &mut self,
17929        insert_token: TokenWithSpan,
17930    ) -> Result<Box<SetExpr>, ParserError> {
17931        Ok(Box::new(SetExpr::Insert(self.parse_insert(insert_token)?)))
17932    }
17933
17934    /// Parse an INSERT statement
17935    pub fn parse_insert(&mut self, insert_token: TokenWithSpan) -> Result<Statement, ParserError> {
17936        let optimizer_hints = self.maybe_parse_optimizer_hints()?;
17937        let or = self.parse_conflict_clause();
17938        let priority = if !dialect_of!(self is MySqlDialect | GenericDialect) {
17939            None
17940        } else if self.parse_keyword(Keyword::LOW_PRIORITY) {
17941            Some(MysqlInsertPriority::LowPriority)
17942        } else if self.parse_keyword(Keyword::DELAYED) {
17943            Some(MysqlInsertPriority::Delayed)
17944        } else if self.parse_keyword(Keyword::HIGH_PRIORITY) {
17945            Some(MysqlInsertPriority::HighPriority)
17946        } else {
17947            None
17948        };
17949
17950        let ignore = dialect_of!(self is MySqlDialect | GenericDialect)
17951            && self.parse_keyword(Keyword::IGNORE);
17952
17953        let replace_into = false;
17954
17955        let overwrite = self.parse_keyword(Keyword::OVERWRITE);
17956        let into = self.parse_keyword(Keyword::INTO);
17957
17958        let local = self.parse_keyword(Keyword::LOCAL);
17959
17960        if self.parse_keyword(Keyword::DIRECTORY) {
17961            let path = self.parse_literal_string()?;
17962            let file_format = if self.parse_keywords(&[Keyword::STORED, Keyword::AS]) {
17963                Some(self.parse_file_format()?)
17964            } else {
17965                None
17966            };
17967            let source = self.parse_query()?;
17968            Ok(Statement::Directory {
17969                local,
17970                path,
17971                overwrite,
17972                file_format,
17973                source,
17974            })
17975        } else {
17976            // Hive lets you put table here regardless
17977            let table = self.parse_keyword(Keyword::TABLE);
17978            let table_object = self.parse_table_object()?;
17979
17980            let table_alias = if self.dialect.supports_insert_table_alias()
17981                && !self.peek_sub_query()
17982                && self
17983                    .peek_one_of_keywords(&[Keyword::DEFAULT, Keyword::VALUES])
17984                    .is_none()
17985            {
17986                if self.parse_keyword(Keyword::AS) {
17987                    Some(TableAliasWithoutColumns {
17988                        explicit: true,
17989                        alias: self.parse_identifier()?,
17990                    })
17991                } else {
17992                    self.maybe_parse(|parser| parser.parse_identifier())?
17993                        .map(|alias| TableAliasWithoutColumns {
17994                            explicit: false,
17995                            alias,
17996                        })
17997                }
17998            } else {
17999                None
18000            };
18001
18002            let is_mysql = dialect_of!(self is MySqlDialect);
18003
18004            let (columns, partitioned, after_columns, output, source, assignments) = if self
18005                .parse_keywords(&[Keyword::DEFAULT, Keyword::VALUES])
18006            {
18007                (vec![], None, vec![], None, None, vec![])
18008            } else {
18009                let (columns, partitioned, after_columns) = if !self.peek_subquery_start() {
18010                    let columns =
18011                        self.parse_parenthesized_qualified_column_list(Optional, is_mysql)?;
18012
18013                    let partitioned = self.parse_insert_partition()?;
18014                    // Hive allows you to specify columns after partitions as well if you want.
18015                    let after_columns = if dialect_of!(self is HiveDialect) {
18016                        self.parse_parenthesized_column_list(Optional, false)?
18017                    } else {
18018                        vec![]
18019                    };
18020                    (columns, partitioned, after_columns)
18021                } else {
18022                    Default::default()
18023                };
18024
18025                let output = self.maybe_parse_output_clause()?;
18026
18027                let (source, assignments) = if self.peek_keyword(Keyword::FORMAT)
18028                    || self.peek_keyword(Keyword::SETTINGS)
18029                {
18030                    (None, vec![])
18031                } else if self.dialect.supports_insert_set() && self.parse_keyword(Keyword::SET) {
18032                    (None, self.parse_comma_separated(Parser::parse_assignment)?)
18033                } else {
18034                    (Some(self.parse_query()?), vec![])
18035                };
18036
18037                (
18038                    columns,
18039                    partitioned,
18040                    after_columns,
18041                    output,
18042                    source,
18043                    assignments,
18044                )
18045            };
18046
18047            let (format_clause, settings) = if self.dialect.supports_insert_format() {
18048                // Settings always comes before `FORMAT` for ClickHouse:
18049                // <https://clickhouse.com/docs/en/sql-reference/statements/insert-into>
18050                let settings = self.parse_settings()?;
18051
18052                let format = if self.parse_keyword(Keyword::FORMAT) {
18053                    Some(self.parse_input_format_clause()?)
18054                } else {
18055                    None
18056                };
18057
18058                (format, settings)
18059            } else {
18060                Default::default()
18061            };
18062
18063            let insert_alias = if dialect_of!(self is MySqlDialect | GenericDialect)
18064                && self.parse_keyword(Keyword::AS)
18065            {
18066                let row_alias = self.parse_object_name(false)?;
18067                let col_aliases = Some(self.parse_parenthesized_column_list(Optional, false)?);
18068                Some(InsertAliases {
18069                    row_alias,
18070                    col_aliases,
18071                })
18072            } else {
18073                None
18074            };
18075
18076            let on = if self.parse_keyword(Keyword::ON) {
18077                if self.parse_keyword(Keyword::CONFLICT) {
18078                    let conflict_target =
18079                        if self.parse_keywords(&[Keyword::ON, Keyword::CONSTRAINT]) {
18080                            Some(ConflictTarget::OnConstraint(self.parse_object_name(false)?))
18081                        } else if self.peek_token_ref().token == Token::LParen {
18082                            Some(ConflictTarget::Columns(
18083                                self.parse_parenthesized_column_list(IsOptional::Mandatory, false)?,
18084                            ))
18085                        } else {
18086                            None
18087                        };
18088
18089                    self.expect_keyword_is(Keyword::DO)?;
18090                    let action = if self.parse_keyword(Keyword::NOTHING) {
18091                        OnConflictAction::DoNothing
18092                    } else {
18093                        self.expect_keyword_is(Keyword::UPDATE)?;
18094                        self.expect_keyword_is(Keyword::SET)?;
18095                        let assignments = self.parse_comma_separated(Parser::parse_assignment)?;
18096                        let selection = if self.parse_keyword(Keyword::WHERE) {
18097                            Some(self.parse_expr()?)
18098                        } else {
18099                            None
18100                        };
18101                        OnConflictAction::DoUpdate(DoUpdate {
18102                            assignments,
18103                            selection,
18104                        })
18105                    };
18106
18107                    Some(OnInsert::OnConflict(OnConflict {
18108                        conflict_target,
18109                        action,
18110                    }))
18111                } else {
18112                    self.expect_keyword_is(Keyword::DUPLICATE)?;
18113                    self.expect_keyword_is(Keyword::KEY)?;
18114                    self.expect_keyword_is(Keyword::UPDATE)?;
18115                    let l = self.parse_comma_separated(Parser::parse_assignment)?;
18116
18117                    Some(OnInsert::DuplicateKeyUpdate(l))
18118                }
18119            } else {
18120                None
18121            };
18122
18123            let returning = if self.parse_keyword(Keyword::RETURNING) {
18124                Some(self.parse_comma_separated(Parser::parse_select_item)?)
18125            } else {
18126                None
18127            };
18128
18129            Ok(Insert {
18130                insert_token: insert_token.into(),
18131                optimizer_hints,
18132                or,
18133                table: table_object,
18134                table_alias,
18135                ignore,
18136                into,
18137                overwrite,
18138                partitioned,
18139                columns,
18140                after_columns,
18141                source,
18142                assignments,
18143                has_table_keyword: table,
18144                on,
18145                returning,
18146                output,
18147                replace_into,
18148                priority,
18149                insert_alias,
18150                settings,
18151                format_clause,
18152                multi_table_insert_type: None,
18153                multi_table_into_clauses: vec![],
18154                multi_table_when_clauses: vec![],
18155                multi_table_else_clause: None,
18156            }
18157            .into())
18158        }
18159    }
18160
18161    /// Parses input format clause used for ClickHouse.
18162    ///
18163    /// <https://clickhouse.com/docs/en/interfaces/formats>
18164    pub fn parse_input_format_clause(&mut self) -> Result<InputFormatClause, ParserError> {
18165        let ident = self.parse_identifier()?;
18166        let values = self
18167            .maybe_parse(|p| p.parse_comma_separated(|p| p.parse_expr()))?
18168            .unwrap_or_default();
18169
18170        Ok(InputFormatClause { ident, values })
18171    }
18172
18173    /// Returns true if the immediate tokens look like the
18174    /// beginning of a subquery. `(SELECT ...`
18175    fn peek_subquery_start(&mut self) -> bool {
18176        matches!(
18177            self.peek_tokens_ref(),
18178            [
18179                TokenWithSpan {
18180                    token: Token::LParen,
18181                    ..
18182                },
18183                TokenWithSpan {
18184                    token: Token::Word(Word {
18185                        keyword: Keyword::SELECT,
18186                        ..
18187                    }),
18188                    ..
18189                },
18190            ]
18191        )
18192    }
18193
18194    /// Returns true if the immediate tokens look like the
18195    /// beginning of a subquery possibly preceded by CTEs;
18196    /// i.e. `(WITH ...` or `(SELECT ...`.
18197    fn peek_subquery_or_cte_start(&mut self) -> bool {
18198        matches!(
18199            self.peek_tokens_ref(),
18200            [
18201                TokenWithSpan {
18202                    token: Token::LParen,
18203                    ..
18204                },
18205                TokenWithSpan {
18206                    token: Token::Word(Word {
18207                        keyword: Keyword::SELECT | Keyword::WITH,
18208                        ..
18209                    }),
18210                    ..
18211                },
18212            ]
18213        )
18214    }
18215
18216    fn parse_conflict_clause(&mut self) -> Option<SqliteOnConflict> {
18217        if self.parse_keywords(&[Keyword::OR, Keyword::REPLACE]) {
18218            Some(SqliteOnConflict::Replace)
18219        } else if self.parse_keywords(&[Keyword::OR, Keyword::ROLLBACK]) {
18220            Some(SqliteOnConflict::Rollback)
18221        } else if self.parse_keywords(&[Keyword::OR, Keyword::ABORT]) {
18222            Some(SqliteOnConflict::Abort)
18223        } else if self.parse_keywords(&[Keyword::OR, Keyword::FAIL]) {
18224            Some(SqliteOnConflict::Fail)
18225        } else if self.parse_keywords(&[Keyword::OR, Keyword::IGNORE]) {
18226            Some(SqliteOnConflict::Ignore)
18227        } else if self.parse_keyword(Keyword::REPLACE) {
18228            Some(SqliteOnConflict::Replace)
18229        } else {
18230            None
18231        }
18232    }
18233
18234    /// Parse an optional `PARTITION (...)` clause for INSERT statements.
18235    pub fn parse_insert_partition(&mut self) -> Result<Option<Vec<Expr>>, ParserError> {
18236        if self.parse_keyword(Keyword::PARTITION) {
18237            self.expect_token(&Token::LParen)?;
18238            let partition_cols = Some(self.parse_comma_separated(Parser::parse_expr)?);
18239            self.expect_token(&Token::RParen)?;
18240            Ok(partition_cols)
18241        } else {
18242            Ok(None)
18243        }
18244    }
18245
18246    /// Parse optional Hive `INPUTFORMAT ... SERDE ...` clause used by LOAD DATA.
18247    pub fn parse_load_data_table_format(
18248        &mut self,
18249    ) -> Result<Option<HiveLoadDataFormat>, ParserError> {
18250        if self.parse_keyword(Keyword::INPUTFORMAT) {
18251            let input_format = self.parse_expr()?;
18252            self.expect_keyword_is(Keyword::SERDE)?;
18253            let serde = self.parse_expr()?;
18254            Ok(Some(HiveLoadDataFormat {
18255                input_format,
18256                serde,
18257            }))
18258        } else {
18259            Ok(None)
18260        }
18261    }
18262
18263    /// Parse an UPDATE statement, returning a `Box`ed SetExpr
18264    ///
18265    /// This is used to reduce the size of the stack frames in debug builds
18266    fn parse_update_setexpr_boxed(
18267        &mut self,
18268        update_token: TokenWithSpan,
18269    ) -> Result<Box<SetExpr>, ParserError> {
18270        Ok(Box::new(SetExpr::Update(self.parse_update(update_token)?)))
18271    }
18272
18273    /// Parse an `UPDATE` statement and return `Statement::Update`.
18274    pub fn parse_update(&mut self, update_token: TokenWithSpan) -> Result<Statement, ParserError> {
18275        let optimizer_hints = self.maybe_parse_optimizer_hints()?;
18276        let or = self.parse_conflict_clause();
18277        let table = self.parse_table_and_joins()?;
18278        let from_before_set = if self.parse_keyword(Keyword::FROM) {
18279            Some(UpdateTableFromKind::BeforeSet(
18280                self.parse_table_with_joins()?,
18281            ))
18282        } else {
18283            None
18284        };
18285        self.expect_keyword(Keyword::SET)?;
18286        let assignments = self.parse_comma_separated(Parser::parse_assignment)?;
18287
18288        let output = self.maybe_parse_output_clause()?;
18289
18290        let from = if from_before_set.is_none() && self.parse_keyword(Keyword::FROM) {
18291            Some(UpdateTableFromKind::AfterSet(
18292                self.parse_table_with_joins()?,
18293            ))
18294        } else {
18295            from_before_set
18296        };
18297        let selection = if self.parse_keyword(Keyword::WHERE) {
18298            Some(self.parse_expr()?)
18299        } else {
18300            None
18301        };
18302        let returning = if self.parse_keyword(Keyword::RETURNING) {
18303            Some(self.parse_comma_separated(Parser::parse_select_item)?)
18304        } else {
18305            None
18306        };
18307        let order_by = if self.dialect.supports_update_order_by()
18308            && self.parse_keywords(&[Keyword::ORDER, Keyword::BY])
18309        {
18310            self.parse_comma_separated(Parser::parse_order_by_expr)?
18311        } else {
18312            vec![]
18313        };
18314        let limit = if self.parse_keyword(Keyword::LIMIT) {
18315            Some(self.parse_expr()?)
18316        } else {
18317            None
18318        };
18319        Ok(Update {
18320            update_token: update_token.into(),
18321            optimizer_hints,
18322            table,
18323            assignments,
18324            from,
18325            selection,
18326            returning,
18327            output,
18328            or,
18329            order_by,
18330            limit,
18331        }
18332        .into())
18333    }
18334
18335    /// Parse a `var = expr` assignment, used in an UPDATE statement
18336    pub fn parse_assignment(&mut self) -> Result<Assignment, ParserError> {
18337        let target = self.parse_assignment_target()?;
18338        self.expect_token(&Token::Eq)?;
18339        let value = self.parse_expr()?;
18340        Ok(Assignment { target, value })
18341    }
18342
18343    /// Parse the left-hand side of an assignment, used in an UPDATE statement
18344    pub fn parse_assignment_target(&mut self) -> Result<AssignmentTarget, ParserError> {
18345        if self.consume_token(&Token::LParen) {
18346            let columns = self.parse_comma_separated(|p| p.parse_object_name(false))?;
18347            self.expect_token(&Token::RParen)?;
18348            Ok(AssignmentTarget::Tuple(columns))
18349        } else {
18350            let column = self.parse_object_name(false)?;
18351            Ok(AssignmentTarget::ColumnName(column))
18352        }
18353    }
18354
18355    /// Parse a single function argument, handling named and unnamed variants.
18356    pub fn parse_function_args(&mut self) -> Result<FunctionArg, ParserError> {
18357        let arg = if self.dialect.supports_named_fn_args_with_expr_name() {
18358            self.maybe_parse(|p| {
18359                let name = p.parse_expr()?;
18360                let operator = p.parse_function_named_arg_operator()?;
18361                let arg = p.parse_wildcard_expr()?.into();
18362                Ok(FunctionArg::ExprNamed {
18363                    name,
18364                    arg,
18365                    operator,
18366                })
18367            })?
18368        } else {
18369            self.maybe_parse(|p| {
18370                let name = p.parse_identifier()?;
18371                let operator = p.parse_function_named_arg_operator()?;
18372                let arg = p.parse_wildcard_expr()?.into();
18373                Ok(FunctionArg::Named {
18374                    name,
18375                    arg,
18376                    operator,
18377                })
18378            })?
18379        };
18380        if let Some(arg) = arg {
18381            return Ok(arg);
18382        }
18383        let wildcard_expr = self.parse_wildcard_expr()?;
18384        let arg_expr: FunctionArgExpr = match wildcard_expr {
18385            Expr::Wildcard(ref token) if self.dialect.supports_select_wildcard_exclude() => {
18386                // Support `* EXCLUDE(col1, col2, ...)` inside function calls (e.g. Snowflake's
18387                // `HASH(* EXCLUDE(col))`).  Parse the options the same way SELECT items do.
18388                let opts = self.parse_wildcard_additional_options(token.0.clone())?;
18389                if opts.opt_exclude.is_some()
18390                    || opts.opt_except.is_some()
18391                    || opts.opt_replace.is_some()
18392                    || opts.opt_rename.is_some()
18393                    || opts.opt_ilike.is_some()
18394                {
18395                    FunctionArgExpr::WildcardWithOptions(opts)
18396                } else {
18397                    wildcard_expr.into()
18398                }
18399            }
18400            other => other.into(),
18401        };
18402        Ok(FunctionArg::Unnamed(arg_expr))
18403    }
18404
18405    fn parse_function_named_arg_operator(&mut self) -> Result<FunctionArgOperator, ParserError> {
18406        if self.parse_keyword(Keyword::VALUE) {
18407            return Ok(FunctionArgOperator::Value);
18408        }
18409        let tok = self.next_token();
18410        match tok.token {
18411            Token::RArrow if self.dialect.supports_named_fn_args_with_rarrow_operator() => {
18412                Ok(FunctionArgOperator::RightArrow)
18413            }
18414            Token::Eq if self.dialect.supports_named_fn_args_with_eq_operator() => {
18415                Ok(FunctionArgOperator::Equals)
18416            }
18417            Token::Assignment
18418                if self
18419                    .dialect
18420                    .supports_named_fn_args_with_assignment_operator() =>
18421            {
18422                Ok(FunctionArgOperator::Assignment)
18423            }
18424            Token::Colon if self.dialect.supports_named_fn_args_with_colon_operator() => {
18425                Ok(FunctionArgOperator::Colon)
18426            }
18427            _ => {
18428                self.prev_token();
18429                self.expected("argument operator", tok)
18430            }
18431        }
18432    }
18433
18434    /// Parse an optional, comma-separated list of function arguments (consumes closing paren).
18435    pub fn parse_optional_args(&mut self) -> Result<Vec<FunctionArg>, ParserError> {
18436        if self.consume_token(&Token::RParen) {
18437            Ok(vec![])
18438        } else {
18439            let args = self.parse_comma_separated(Parser::parse_function_args)?;
18440            self.expect_token(&Token::RParen)?;
18441            Ok(args)
18442        }
18443    }
18444
18445    fn parse_table_function_args(&mut self) -> Result<TableFunctionArgs, ParserError> {
18446        if self.consume_token(&Token::RParen) {
18447            return Ok(TableFunctionArgs {
18448                args: vec![],
18449                settings: None,
18450            });
18451        }
18452        let mut args = vec![];
18453        let settings = loop {
18454            if let Some(settings) = self.parse_settings()? {
18455                break Some(settings);
18456            }
18457            args.push(self.parse_function_args()?);
18458            if self.is_parse_comma_separated_end() {
18459                break None;
18460            }
18461        };
18462        self.expect_token(&Token::RParen)?;
18463        Ok(TableFunctionArgs { args, settings })
18464    }
18465
18466    /// Parses a potentially empty list of arguments to a function
18467    /// (including the closing parenthesis).
18468    ///
18469    /// Examples:
18470    /// ```sql
18471    /// FIRST_VALUE(x ORDER BY 1,2,3);
18472    /// FIRST_VALUE(x IGNORE NULL);
18473    /// ```
18474    fn parse_function_argument_list(&mut self) -> Result<FunctionArgumentList, ParserError> {
18475        let mut clauses = vec![];
18476
18477        // Handle clauses that may exist with an empty argument list
18478
18479        if let Some(null_clause) = self.parse_json_null_clause() {
18480            clauses.push(FunctionArgumentClause::JsonNullClause(null_clause));
18481        }
18482
18483        if let Some(json_returning_clause) = self.maybe_parse_json_returning_clause()? {
18484            clauses.push(FunctionArgumentClause::JsonReturningClause(
18485                json_returning_clause,
18486            ));
18487        }
18488
18489        if self.consume_token(&Token::RParen) {
18490            return Ok(FunctionArgumentList {
18491                duplicate_treatment: None,
18492                args: vec![],
18493                clauses,
18494            });
18495        }
18496
18497        let duplicate_treatment = self.parse_duplicate_treatment()?;
18498        let args = self.parse_comma_separated(Parser::parse_function_args)?;
18499
18500        if self.dialect.supports_window_function_null_treatment_arg() {
18501            if let Some(null_treatment) = self.parse_null_treatment()? {
18502                clauses.push(FunctionArgumentClause::IgnoreOrRespectNulls(null_treatment));
18503            }
18504        }
18505
18506        if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
18507            clauses.push(FunctionArgumentClause::OrderBy(
18508                self.parse_comma_separated(Parser::parse_order_by_expr)?,
18509            ));
18510        }
18511
18512        if self.parse_keyword(Keyword::LIMIT) {
18513            clauses.push(FunctionArgumentClause::Limit(self.parse_expr()?));
18514        }
18515
18516        if dialect_of!(self is GenericDialect | BigQueryDialect)
18517            && self.parse_keyword(Keyword::HAVING)
18518        {
18519            let kind = match self.expect_one_of_keywords(&[Keyword::MIN, Keyword::MAX])? {
18520                Keyword::MIN => HavingBoundKind::Min,
18521                Keyword::MAX => HavingBoundKind::Max,
18522                unexpected_keyword => return Err(ParserError::ParserError(
18523                    format!("Internal parser error: unexpected keyword `{unexpected_keyword}` in having bound"),
18524                )),
18525            };
18526            clauses.push(FunctionArgumentClause::Having(HavingBound(
18527                kind,
18528                self.parse_expr()?,
18529            )))
18530        }
18531
18532        if dialect_of!(self is GenericDialect | MySqlDialect)
18533            && self.parse_keyword(Keyword::SEPARATOR)
18534        {
18535            clauses.push(FunctionArgumentClause::Separator(self.parse_value()?));
18536        }
18537
18538        if let Some(on_overflow) = self.parse_listagg_on_overflow()? {
18539            clauses.push(FunctionArgumentClause::OnOverflow(on_overflow));
18540        }
18541
18542        if let Some(null_clause) = self.parse_json_null_clause() {
18543            clauses.push(FunctionArgumentClause::JsonNullClause(null_clause));
18544        }
18545
18546        if let Some(json_returning_clause) = self.maybe_parse_json_returning_clause()? {
18547            clauses.push(FunctionArgumentClause::JsonReturningClause(
18548                json_returning_clause,
18549            ));
18550        }
18551
18552        self.expect_token(&Token::RParen)?;
18553        Ok(FunctionArgumentList {
18554            duplicate_treatment,
18555            args,
18556            clauses,
18557        })
18558    }
18559
18560    fn parse_json_null_clause(&mut self) -> Option<JsonNullClause> {
18561        if self.parse_keywords(&[Keyword::ABSENT, Keyword::ON, Keyword::NULL]) {
18562            Some(JsonNullClause::AbsentOnNull)
18563        } else if self.parse_keywords(&[Keyword::NULL, Keyword::ON, Keyword::NULL]) {
18564            Some(JsonNullClause::NullOnNull)
18565        } else {
18566            None
18567        }
18568    }
18569
18570    fn maybe_parse_json_returning_clause(
18571        &mut self,
18572    ) -> Result<Option<JsonReturningClause>, ParserError> {
18573        if self.parse_keyword(Keyword::RETURNING) {
18574            let data_type = self.parse_data_type()?;
18575            Ok(Some(JsonReturningClause { data_type }))
18576        } else {
18577            Ok(None)
18578        }
18579    }
18580
18581    fn parse_duplicate_treatment(&mut self) -> Result<Option<DuplicateTreatment>, ParserError> {
18582        let loc = self.peek_token_ref().span.start;
18583        match (
18584            self.parse_keyword(Keyword::ALL),
18585            self.parse_keyword(Keyword::DISTINCT),
18586        ) {
18587            (true, false) => Ok(Some(DuplicateTreatment::All)),
18588            (false, true) => Ok(Some(DuplicateTreatment::Distinct)),
18589            (false, false) => Ok(None),
18590            (true, true) => parser_err!("Cannot specify both ALL and DISTINCT".to_string(), loc),
18591        }
18592    }
18593
18594    /// Parse a comma-delimited list of projections after SELECT
18595    pub fn parse_select_item(&mut self) -> Result<SelectItem, ParserError> {
18596        let prefix = self
18597            .parse_one_of_keywords(
18598                self.dialect
18599                    .get_reserved_keywords_for_select_item_operator(),
18600            )
18601            .map(|keyword| Ident::new(format!("{keyword:?}")));
18602
18603        match self.parse_wildcard_expr()? {
18604            Expr::QualifiedWildcard(prefix, token) => Ok(SelectItem::QualifiedWildcard(
18605                SelectItemQualifiedWildcardKind::ObjectName(prefix),
18606                self.parse_wildcard_additional_options(token.0)?,
18607            )),
18608            Expr::Wildcard(token) => Ok(SelectItem::Wildcard(
18609                self.parse_wildcard_additional_options(token.0)?,
18610            )),
18611            Expr::Identifier(v) if v.value.to_lowercase() == "from" && v.quote_style.is_none() => {
18612                parser_err!(
18613                    format!("Expected an expression, found: {}", v),
18614                    self.peek_token_ref().span.start
18615                )
18616            }
18617            Expr::BinaryOp {
18618                left,
18619                op: BinaryOperator::Eq,
18620                right,
18621            } if self.dialect.supports_eq_alias_assignment()
18622                && matches!(left.as_ref(), Expr::Identifier(_)) =>
18623            {
18624                let Expr::Identifier(alias) = *left else {
18625                    return parser_err!(
18626                        "BUG: expected identifier expression as alias",
18627                        self.peek_token_ref().span.start
18628                    );
18629                };
18630                Ok(SelectItem::ExprWithAlias {
18631                    expr: *right,
18632                    alias,
18633                })
18634            }
18635            expr if self.dialect.supports_select_expr_star()
18636                && self.consume_tokens(&[Token::Period, Token::Mul]) =>
18637            {
18638                let wildcard_token = self.get_previous_token().clone();
18639                Ok(SelectItem::QualifiedWildcard(
18640                    SelectItemQualifiedWildcardKind::Expr(expr),
18641                    self.parse_wildcard_additional_options(wildcard_token)?,
18642                ))
18643            }
18644            expr if self.dialect.supports_select_item_multi_column_alias()
18645                && self.peek_keyword(Keyword::AS)
18646                && self.peek_nth_token(1).token == Token::LParen =>
18647            {
18648                self.expect_keyword(Keyword::AS)?;
18649                self.expect_token(&Token::LParen)?;
18650                let aliases = self.parse_comma_separated(|p| p.parse_identifier())?;
18651                self.expect_token(&Token::RParen)?;
18652                Ok(SelectItem::ExprWithAliases {
18653                    expr: maybe_prefixed_expr(expr, prefix),
18654                    aliases,
18655                })
18656            }
18657            expr => self
18658                .maybe_parse_select_item_alias()
18659                .map(|alias| match alias {
18660                    Some(alias) => SelectItem::ExprWithAlias {
18661                        expr: maybe_prefixed_expr(expr, prefix),
18662                        alias,
18663                    },
18664                    None => SelectItem::UnnamedExpr(maybe_prefixed_expr(expr, prefix)),
18665                }),
18666        }
18667    }
18668
18669    /// Parse an [`WildcardAdditionalOptions`] information for wildcard select items.
18670    ///
18671    /// If it is not possible to parse it, will return an option.
18672    pub fn parse_wildcard_additional_options(
18673        &mut self,
18674        wildcard_token: TokenWithSpan,
18675    ) -> Result<WildcardAdditionalOptions, ParserError> {
18676        let opt_ilike = if self.dialect.supports_select_wildcard_ilike() {
18677            self.parse_optional_select_item_ilike()?
18678        } else {
18679            None
18680        };
18681        let opt_exclude = if opt_ilike.is_none() && self.dialect.supports_select_wildcard_exclude()
18682        {
18683            self.parse_optional_select_item_exclude()?
18684        } else {
18685            None
18686        };
18687        let opt_except = if self.dialect.supports_select_wildcard_except() {
18688            self.parse_optional_select_item_except()?
18689        } else {
18690            None
18691        };
18692        let opt_replace = if self.dialect.supports_select_wildcard_replace() {
18693            self.parse_optional_select_item_replace()?
18694        } else {
18695            None
18696        };
18697        let opt_rename = if self.dialect.supports_select_wildcard_rename() {
18698            self.parse_optional_select_item_rename()?
18699        } else {
18700            None
18701        };
18702
18703        let opt_alias = if self.dialect.supports_select_wildcard_with_alias() {
18704            self.maybe_parse_select_item_alias()?
18705        } else {
18706            None
18707        };
18708
18709        Ok(WildcardAdditionalOptions {
18710            wildcard_token: wildcard_token.into(),
18711            opt_ilike,
18712            opt_exclude,
18713            opt_except,
18714            opt_rename,
18715            opt_replace,
18716            opt_alias,
18717        })
18718    }
18719
18720    /// Parse an [`Ilike`](IlikeSelectItem) information for wildcard select items.
18721    ///
18722    /// If it is not possible to parse it, will return an option.
18723    pub fn parse_optional_select_item_ilike(
18724        &mut self,
18725    ) -> Result<Option<IlikeSelectItem>, ParserError> {
18726        let opt_ilike = if self.parse_keyword(Keyword::ILIKE) {
18727            let next_token = self.next_token();
18728            let pattern = match next_token.token {
18729                Token::SingleQuotedString(s) => s,
18730                _ => return self.expected("ilike pattern", next_token),
18731            };
18732            Some(IlikeSelectItem { pattern })
18733        } else {
18734            None
18735        };
18736        Ok(opt_ilike)
18737    }
18738
18739    /// Parse an [`Exclude`](ExcludeSelectItem) information for wildcard select items.
18740    ///
18741    /// If it is not possible to parse it, will return an option.
18742    pub fn parse_optional_select_item_exclude(
18743        &mut self,
18744    ) -> Result<Option<ExcludeSelectItem>, ParserError> {
18745        let opt_exclude = if self.parse_keyword(Keyword::EXCLUDE) {
18746            if self.consume_token(&Token::LParen) {
18747                let columns =
18748                    self.parse_comma_separated(|parser| parser.parse_object_name(false))?;
18749                self.expect_token(&Token::RParen)?;
18750                Some(ExcludeSelectItem::Multiple(columns))
18751            } else {
18752                let column = self.parse_object_name(false)?;
18753                Some(ExcludeSelectItem::Single(column))
18754            }
18755        } else {
18756            None
18757        };
18758
18759        Ok(opt_exclude)
18760    }
18761
18762    /// Parse an [`Except`](ExceptSelectItem) information for wildcard select items.
18763    ///
18764    /// If it is not possible to parse it, will return an option.
18765    pub fn parse_optional_select_item_except(
18766        &mut self,
18767    ) -> Result<Option<ExceptSelectItem>, ParserError> {
18768        let opt_except = if self.parse_keyword(Keyword::EXCEPT) {
18769            if self.peek_token_ref().token == Token::LParen {
18770                let idents = self.parse_parenthesized_column_list(Mandatory, false)?;
18771                match &idents[..] {
18772                    [] => {
18773                        return self.expected_ref(
18774                            "at least one column should be parsed by the expect clause",
18775                            self.peek_token_ref(),
18776                        )?;
18777                    }
18778                    [first, idents @ ..] => Some(ExceptSelectItem {
18779                        first_element: first.clone(),
18780                        additional_elements: idents.to_vec(),
18781                    }),
18782                }
18783            } else {
18784                // Clickhouse allows EXCEPT column_name
18785                let ident = self.parse_identifier()?;
18786                Some(ExceptSelectItem {
18787                    first_element: ident,
18788                    additional_elements: vec![],
18789                })
18790            }
18791        } else {
18792            None
18793        };
18794
18795        Ok(opt_except)
18796    }
18797
18798    /// Parse a [`Rename`](RenameSelectItem) information for wildcard select items.
18799    pub fn parse_optional_select_item_rename(
18800        &mut self,
18801    ) -> Result<Option<RenameSelectItem>, ParserError> {
18802        let opt_rename = if self.parse_keyword(Keyword::RENAME) {
18803            if self.consume_token(&Token::LParen) {
18804                let idents =
18805                    self.parse_comma_separated(|parser| parser.parse_identifier_with_alias())?;
18806                self.expect_token(&Token::RParen)?;
18807                Some(RenameSelectItem::Multiple(idents))
18808            } else {
18809                let ident = self.parse_identifier_with_alias()?;
18810                Some(RenameSelectItem::Single(ident))
18811            }
18812        } else {
18813            None
18814        };
18815
18816        Ok(opt_rename)
18817    }
18818
18819    /// Parse a [`Replace`](ReplaceSelectItem) information for wildcard select items.
18820    pub fn parse_optional_select_item_replace(
18821        &mut self,
18822    ) -> Result<Option<ReplaceSelectItem>, ParserError> {
18823        let opt_replace = if self.parse_keyword(Keyword::REPLACE) {
18824            if self.consume_token(&Token::LParen) {
18825                let items = self.parse_comma_separated(|parser| {
18826                    Ok(Box::new(parser.parse_replace_elements()?))
18827                })?;
18828                self.expect_token(&Token::RParen)?;
18829                Some(ReplaceSelectItem { items })
18830            } else {
18831                let tok = self.next_token();
18832                return self.expected("( after REPLACE but", tok);
18833            }
18834        } else {
18835            None
18836        };
18837
18838        Ok(opt_replace)
18839    }
18840    /// Parse a single element of a `REPLACE (...)` select-item clause.
18841    pub fn parse_replace_elements(&mut self) -> Result<ReplaceSelectElement, ParserError> {
18842        let expr = self.parse_expr()?;
18843        let as_keyword = self.parse_keyword(Keyword::AS);
18844        let ident = self.parse_identifier()?;
18845        Ok(ReplaceSelectElement {
18846            expr,
18847            column_name: ident,
18848            as_keyword,
18849        })
18850    }
18851
18852    /// Parse ASC or DESC, returns an Option with true if ASC, false of DESC or `None` if none of
18853    /// them.
18854    pub fn parse_asc_desc(&mut self) -> Option<bool> {
18855        if self.parse_keyword(Keyword::ASC) {
18856            Some(true)
18857        } else if self.parse_keyword(Keyword::DESC) {
18858            Some(false)
18859        } else {
18860            None
18861        }
18862    }
18863
18864    /// Parse ASC or DESC and map to [OrderBySort].
18865    fn parse_optional_order_by_sort(&mut self) -> Option<OrderBySort> {
18866        match self.parse_asc_desc() {
18867            Some(true) => Some(OrderBySort::Asc),
18868            Some(false) => Some(OrderBySort::Desc),
18869            None => None,
18870        }
18871    }
18872
18873    /// Parse an [OrderByExpr] expression.
18874    pub fn parse_order_by_expr(&mut self) -> Result<OrderByExpr, ParserError> {
18875        self.parse_order_by_expr_inner(false)
18876            .map(|(order_by, _)| order_by)
18877    }
18878
18879    /// Parse an [IndexColumn].
18880    pub fn parse_create_index_expr(&mut self) -> Result<IndexColumn, ParserError> {
18881        self.parse_order_by_expr_inner(true)
18882            .map(|(column, operator_class)| IndexColumn {
18883                column,
18884                operator_class,
18885            })
18886    }
18887
18888    fn parse_order_by_expr_inner(
18889        &mut self,
18890        with_operator_class: bool,
18891    ) -> Result<(OrderByExpr, Option<ObjectName>), ParserError> {
18892        let expr = self.parse_expr()?;
18893
18894        let operator_class: Option<ObjectName> = if with_operator_class {
18895            // We check that if non of the following keywords are present, then we parse an
18896            // identifier as operator class.
18897            if self
18898                .peek_one_of_keywords(&[Keyword::ASC, Keyword::DESC, Keyword::NULLS, Keyword::WITH])
18899                .is_some()
18900            {
18901                None
18902            } else {
18903                self.maybe_parse(|parser| parser.parse_object_name(false))?
18904            }
18905        } else {
18906            None
18907        };
18908
18909        let options = if !with_operator_class
18910            && self.dialect.supports_order_by_using_operator()
18911            && self.parse_keyword(Keyword::USING)
18912        {
18913            let op = self.parse_order_by_using_operator()?;
18914            OrderByOptions {
18915                sort: Some(OrderBySort::Using(op)),
18916                nulls_first: self.parse_null_ordering_modifier(),
18917            }
18918        } else {
18919            self.parse_order_by_options()?
18920        };
18921
18922        let with_fill = if self.dialect.supports_with_fill()
18923            && self.parse_keywords(&[Keyword::WITH, Keyword::FILL])
18924        {
18925            Some(self.parse_with_fill()?)
18926        } else {
18927            None
18928        };
18929
18930        Ok((
18931            OrderByExpr {
18932                expr,
18933                options,
18934                with_fill,
18935            },
18936            operator_class,
18937        ))
18938    }
18939
18940    fn parse_order_by_using_operator(&mut self) -> Result<ObjectName, ParserError> {
18941        if self.parse_keyword(Keyword::OPERATOR) {
18942            self.expect_token(&Token::LParen)?;
18943            let operator_name = self.parse_operator_name()?;
18944            self.expect_token(&Token::RParen)?;
18945            return Ok(operator_name);
18946        }
18947
18948        let token = self.next_token();
18949        Ok(ObjectName::from(vec![Ident::new(token.token.to_string())]))
18950    }
18951
18952    fn parse_null_ordering_modifier(&mut self) -> Option<bool> {
18953        if self.parse_keywords(&[Keyword::NULLS, Keyword::FIRST]) {
18954            Some(true)
18955        } else if self.parse_keywords(&[Keyword::NULLS, Keyword::LAST]) {
18956            Some(false)
18957        } else {
18958            None
18959        }
18960    }
18961
18962    fn parse_order_by_options(&mut self) -> Result<OrderByOptions, ParserError> {
18963        let sort = self.parse_optional_order_by_sort();
18964        let nulls_first = self.parse_null_ordering_modifier();
18965
18966        Ok(OrderByOptions { sort, nulls_first })
18967    }
18968
18969    // Parse a WITH FILL clause (ClickHouse dialect)
18970    // that follow the WITH FILL keywords in a ORDER BY clause
18971    /// Parse a `WITH FILL` clause used in ORDER BY (ClickHouse dialect).
18972    pub fn parse_with_fill(&mut self) -> Result<WithFill, ParserError> {
18973        let from = if self.parse_keyword(Keyword::FROM) {
18974            Some(self.parse_expr()?)
18975        } else {
18976            None
18977        };
18978
18979        let to = if self.parse_keyword(Keyword::TO) {
18980            Some(self.parse_expr()?)
18981        } else {
18982            None
18983        };
18984
18985        let step = if self.parse_keyword(Keyword::STEP) {
18986            Some(self.parse_expr()?)
18987        } else {
18988            None
18989        };
18990
18991        Ok(WithFill { from, to, step })
18992    }
18993
18994    /// Parse a set of comma separated INTERPOLATE expressions (ClickHouse dialect)
18995    /// that follow the INTERPOLATE keyword in an ORDER BY clause with the WITH FILL modifier
18996    pub fn parse_interpolations(&mut self) -> Result<Option<Interpolate>, ParserError> {
18997        if !self.parse_keyword(Keyword::INTERPOLATE) {
18998            return Ok(None);
18999        }
19000
19001        if self.consume_token(&Token::LParen) {
19002            let interpolations =
19003                self.parse_comma_separated0(|p| p.parse_interpolation(), Token::RParen)?;
19004            self.expect_token(&Token::RParen)?;
19005            // INTERPOLATE () and INTERPOLATE ( ... ) variants
19006            return Ok(Some(Interpolate {
19007                exprs: Some(interpolations),
19008            }));
19009        }
19010
19011        // INTERPOLATE
19012        Ok(Some(Interpolate { exprs: None }))
19013    }
19014
19015    /// Parse a INTERPOLATE expression (ClickHouse dialect)
19016    pub fn parse_interpolation(&mut self) -> Result<InterpolateExpr, ParserError> {
19017        let column = self.parse_identifier()?;
19018        let expr = if self.parse_keyword(Keyword::AS) {
19019            Some(self.parse_expr()?)
19020        } else {
19021            None
19022        };
19023        Ok(InterpolateExpr { column, expr })
19024    }
19025
19026    /// Parse a TOP clause, MSSQL equivalent of LIMIT,
19027    /// that follows after `SELECT [DISTINCT]`.
19028    pub fn parse_top(&mut self) -> Result<Top, ParserError> {
19029        let quantity = if self.consume_token(&Token::LParen) {
19030            let quantity = self.parse_expr()?;
19031            self.expect_token(&Token::RParen)?;
19032            Some(TopQuantity::Expr(quantity))
19033        } else {
19034            let next_token = self.next_token();
19035            let quantity = match next_token.token {
19036                Token::Number(s, _) => Self::parse::<u64>(s, next_token.span.start)?,
19037                _ => self.expected("literal int", next_token)?,
19038            };
19039            Some(TopQuantity::Constant(quantity))
19040        };
19041
19042        let percent = self.parse_keyword(Keyword::PERCENT);
19043
19044        let with_ties = self.parse_keywords(&[Keyword::WITH, Keyword::TIES]);
19045
19046        Ok(Top {
19047            with_ties,
19048            percent,
19049            quantity,
19050        })
19051    }
19052
19053    /// Parse a LIMIT clause
19054    pub fn parse_limit(&mut self) -> Result<Option<Expr>, ParserError> {
19055        if self.parse_keyword(Keyword::ALL) {
19056            Ok(None)
19057        } else {
19058            Ok(Some(self.parse_expr()?))
19059        }
19060    }
19061
19062    /// Parse an OFFSET clause
19063    pub fn parse_offset(&mut self) -> Result<Offset, ParserError> {
19064        let value = self.parse_expr()?;
19065        let rows = if self.parse_keyword(Keyword::ROW) {
19066            OffsetRows::Row
19067        } else if self.parse_keyword(Keyword::ROWS) {
19068            OffsetRows::Rows
19069        } else {
19070            OffsetRows::None
19071        };
19072        Ok(Offset { value, rows })
19073    }
19074
19075    /// Parse a FETCH clause
19076    pub fn parse_fetch(&mut self) -> Result<Fetch, ParserError> {
19077        let _ = self.parse_one_of_keywords(&[Keyword::FIRST, Keyword::NEXT]);
19078
19079        let (quantity, percent) = if self
19080            .parse_one_of_keywords(&[Keyword::ROW, Keyword::ROWS])
19081            .is_some()
19082        {
19083            (None, false)
19084        } else {
19085            let quantity = Expr::Value(self.parse_value()?);
19086            let percent = self.parse_keyword(Keyword::PERCENT);
19087            let _ = self.parse_one_of_keywords(&[Keyword::ROW, Keyword::ROWS]);
19088            (Some(quantity), percent)
19089        };
19090
19091        let with_ties = if self.parse_keyword(Keyword::ONLY) {
19092            false
19093        } else {
19094            self.parse_keywords(&[Keyword::WITH, Keyword::TIES])
19095        };
19096
19097        Ok(Fetch {
19098            with_ties,
19099            percent,
19100            quantity,
19101        })
19102    }
19103
19104    /// Parse a FOR UPDATE/FOR SHARE clause
19105    pub fn parse_lock(&mut self) -> Result<LockClause, ParserError> {
19106        let lock_type = match self.expect_one_of_keywords(&[Keyword::UPDATE, Keyword::SHARE])? {
19107            Keyword::UPDATE => LockType::Update,
19108            Keyword::SHARE => LockType::Share,
19109            unexpected_keyword => return Err(ParserError::ParserError(
19110                format!("Internal parser error: expected any of {{UPDATE, SHARE}}, got {unexpected_keyword:?}"),
19111            )),
19112        };
19113        let of = if self.parse_keyword(Keyword::OF) {
19114            Some(self.parse_object_name(false)?)
19115        } else {
19116            None
19117        };
19118        let nonblock = if self.parse_keyword(Keyword::NOWAIT) {
19119            Some(NonBlock::Nowait)
19120        } else if self.parse_keywords(&[Keyword::SKIP, Keyword::LOCKED]) {
19121            Some(NonBlock::SkipLocked)
19122        } else {
19123            None
19124        };
19125        Ok(LockClause {
19126            lock_type,
19127            of,
19128            nonblock,
19129        })
19130    }
19131
19132    /// Parse a PostgreSQL `LOCK` statement.
19133    pub fn parse_lock_statement(&mut self) -> Result<Lock, ParserError> {
19134        self.expect_keyword(Keyword::LOCK)?;
19135
19136        if self.peek_keyword(Keyword::TABLES) {
19137            return self.expected_ref("TABLE or a table name", self.peek_token_ref());
19138        }
19139
19140        let _ = self.parse_keyword(Keyword::TABLE);
19141        let tables = self.parse_comma_separated(Parser::parse_lock_table_target)?;
19142        let lock_mode = if self.parse_keyword(Keyword::IN) {
19143            let lock_mode = self.parse_lock_table_mode()?;
19144            self.expect_keyword(Keyword::MODE)?;
19145            Some(lock_mode)
19146        } else {
19147            None
19148        };
19149        let nowait = self.parse_keyword(Keyword::NOWAIT);
19150
19151        Ok(Lock {
19152            tables,
19153            lock_mode,
19154            nowait,
19155        })
19156    }
19157
19158    fn parse_lock_table_target(&mut self) -> Result<LockTableTarget, ParserError> {
19159        let only = self.parse_keyword(Keyword::ONLY);
19160        let name = self.parse_object_name(false)?;
19161        let has_asterisk = self.consume_token(&Token::Mul);
19162
19163        Ok(LockTableTarget {
19164            name,
19165            only,
19166            has_asterisk,
19167        })
19168    }
19169
19170    fn parse_lock_table_mode(&mut self) -> Result<LockTableMode, ParserError> {
19171        if self.parse_keywords(&[Keyword::ACCESS, Keyword::SHARE]) {
19172            Ok(LockTableMode::AccessShare)
19173        } else if self.parse_keywords(&[Keyword::ACCESS, Keyword::EXCLUSIVE]) {
19174            Ok(LockTableMode::AccessExclusive)
19175        } else if self.parse_keywords(&[Keyword::ROW, Keyword::SHARE]) {
19176            Ok(LockTableMode::RowShare)
19177        } else if self.parse_keywords(&[Keyword::ROW, Keyword::EXCLUSIVE]) {
19178            Ok(LockTableMode::RowExclusive)
19179        } else if self.parse_keywords(&[Keyword::SHARE, Keyword::UPDATE, Keyword::EXCLUSIVE]) {
19180            Ok(LockTableMode::ShareUpdateExclusive)
19181        } else if self.parse_keywords(&[Keyword::SHARE, Keyword::ROW, Keyword::EXCLUSIVE]) {
19182            Ok(LockTableMode::ShareRowExclusive)
19183        } else if self.parse_keyword(Keyword::SHARE) {
19184            Ok(LockTableMode::Share)
19185        } else if self.parse_keyword(Keyword::EXCLUSIVE) {
19186            Ok(LockTableMode::Exclusive)
19187        } else {
19188            self.expected_ref("a PostgreSQL LOCK TABLE mode", self.peek_token_ref())
19189        }
19190    }
19191
19192    /// Parse a VALUES clause
19193    pub fn parse_values(
19194        &mut self,
19195        allow_empty: bool,
19196        value_keyword: bool,
19197    ) -> Result<Values, ParserError> {
19198        let mut explicit_row = false;
19199
19200        let rows = self.parse_comma_separated(|parser| {
19201            if parser.parse_keyword(Keyword::ROW) {
19202                explicit_row = true;
19203            }
19204            Ok(Parens {
19205                opening_token: parser.expect_token(&Token::LParen)?.into(),
19206                content: if allow_empty && parser.peek_token_ref().token == Token::RParen {
19207                    vec![]
19208                } else {
19209                    parser.parse_comma_separated(Parser::parse_expr)?
19210                },
19211                closing_token: parser.expect_token(&Token::RParen)?.into(),
19212            })
19213        })?;
19214        Ok(Values {
19215            explicit_row,
19216            rows,
19217            value_keyword,
19218        })
19219    }
19220
19221    /// Parse a 'START TRANSACTION' statement
19222    pub fn parse_start_transaction(&mut self) -> Result<Statement, ParserError> {
19223        self.expect_keyword_is(Keyword::TRANSACTION)?;
19224        Ok(Statement::StartTransaction {
19225            modes: self.parse_transaction_modes()?,
19226            begin: false,
19227            transaction: Some(BeginTransactionKind::Transaction),
19228            modifier: None,
19229            statements: vec![],
19230            exception: None,
19231            has_end_keyword: false,
19232        })
19233    }
19234
19235    /// Parse a transaction modifier keyword that can follow a `BEGIN` statement.
19236    pub(crate) fn parse_transaction_modifier(&mut self) -> Option<TransactionModifier> {
19237        if !self.dialect.supports_start_transaction_modifier() {
19238            None
19239        } else if self.parse_keyword(Keyword::DEFERRED) {
19240            Some(TransactionModifier::Deferred)
19241        } else if self.parse_keyword(Keyword::IMMEDIATE) {
19242            Some(TransactionModifier::Immediate)
19243        } else if self.parse_keyword(Keyword::EXCLUSIVE) {
19244            Some(TransactionModifier::Exclusive)
19245        } else if self.parse_keyword(Keyword::TRY) {
19246            Some(TransactionModifier::Try)
19247        } else if self.parse_keyword(Keyword::CATCH) {
19248            Some(TransactionModifier::Catch)
19249        } else {
19250            None
19251        }
19252    }
19253
19254    /// Parse a 'BEGIN' statement
19255    pub fn parse_begin(&mut self) -> Result<Statement, ParserError> {
19256        let modifier = self.parse_transaction_modifier();
19257        let transaction =
19258            match self.parse_one_of_keywords(&[Keyword::TRANSACTION, Keyword::WORK, Keyword::TRAN])
19259            {
19260                Some(Keyword::TRANSACTION) => Some(BeginTransactionKind::Transaction),
19261                Some(Keyword::WORK) => Some(BeginTransactionKind::Work),
19262                Some(Keyword::TRAN) => Some(BeginTransactionKind::Tran),
19263                _ => None,
19264            };
19265        Ok(Statement::StartTransaction {
19266            modes: self.parse_transaction_modes()?,
19267            begin: true,
19268            transaction,
19269            modifier,
19270            statements: vec![],
19271            exception: None,
19272            has_end_keyword: false,
19273        })
19274    }
19275
19276    /// Parse a 'BEGIN ... EXCEPTION ... END' block
19277    pub fn parse_begin_exception_end(&mut self) -> Result<Statement, ParserError> {
19278        let statements = self.parse_statement_list(&[Keyword::EXCEPTION, Keyword::END])?;
19279
19280        let exception = if self.parse_keyword(Keyword::EXCEPTION) {
19281            let mut when = Vec::new();
19282
19283            // We can have multiple `WHEN` arms so we consume all cases until `END`
19284            while !self.peek_keyword(Keyword::END) {
19285                self.expect_keyword(Keyword::WHEN)?;
19286
19287                // Each `WHEN` case can have one or more conditions, e.g.
19288                // WHEN EXCEPTION_1 [OR EXCEPTION_2] THEN
19289                // So we parse identifiers until the `THEN` keyword.
19290                let mut idents = Vec::new();
19291
19292                while !self.parse_keyword(Keyword::THEN) {
19293                    let ident = self.parse_identifier()?;
19294                    idents.push(ident);
19295
19296                    self.maybe_parse(|p| p.expect_keyword(Keyword::OR))?;
19297                }
19298
19299                let statements = self.parse_statement_list(&[Keyword::WHEN, Keyword::END])?;
19300
19301                when.push(ExceptionWhen { idents, statements });
19302            }
19303
19304            Some(when)
19305        } else {
19306            None
19307        };
19308
19309        self.expect_keyword(Keyword::END)?;
19310
19311        Ok(Statement::StartTransaction {
19312            begin: true,
19313            statements,
19314            exception,
19315            has_end_keyword: true,
19316            transaction: None,
19317            modifier: None,
19318            modes: Default::default(),
19319        })
19320    }
19321
19322    /// Parse an 'END' statement
19323    pub fn parse_end(&mut self) -> Result<Statement, ParserError> {
19324        let modifier = if !self.dialect.supports_end_transaction_modifier() {
19325            None
19326        } else if self.parse_keyword(Keyword::TRY) {
19327            Some(TransactionModifier::Try)
19328        } else if self.parse_keyword(Keyword::CATCH) {
19329            Some(TransactionModifier::Catch)
19330        } else {
19331            None
19332        };
19333        Ok(Statement::Commit {
19334            chain: self.parse_commit_rollback_chain()?,
19335            end: true,
19336            modifier,
19337        })
19338    }
19339
19340    /// Parse a list of transaction modes
19341    pub fn parse_transaction_modes(&mut self) -> Result<Vec<TransactionMode>, ParserError> {
19342        let mut modes = vec![];
19343        let mut required = false;
19344        loop {
19345            let mode = if self.parse_keywords(&[Keyword::ISOLATION, Keyword::LEVEL]) {
19346                let iso_level = if self.parse_keywords(&[Keyword::READ, Keyword::UNCOMMITTED]) {
19347                    TransactionIsolationLevel::ReadUncommitted
19348                } else if self.parse_keywords(&[Keyword::READ, Keyword::COMMITTED]) {
19349                    TransactionIsolationLevel::ReadCommitted
19350                } else if self.parse_keywords(&[Keyword::REPEATABLE, Keyword::READ]) {
19351                    TransactionIsolationLevel::RepeatableRead
19352                } else if self.parse_keyword(Keyword::SERIALIZABLE) {
19353                    TransactionIsolationLevel::Serializable
19354                } else if self.parse_keyword(Keyword::SNAPSHOT) {
19355                    TransactionIsolationLevel::Snapshot
19356                } else {
19357                    self.expected_ref("isolation level", self.peek_token_ref())?
19358                };
19359                TransactionMode::IsolationLevel(iso_level)
19360            } else if self.parse_keywords(&[Keyword::READ, Keyword::ONLY]) {
19361                TransactionMode::AccessMode(TransactionAccessMode::ReadOnly)
19362            } else if self.parse_keywords(&[Keyword::READ, Keyword::WRITE]) {
19363                TransactionMode::AccessMode(TransactionAccessMode::ReadWrite)
19364            } else if required {
19365                self.expected_ref("transaction mode", self.peek_token_ref())?
19366            } else {
19367                break;
19368            };
19369            modes.push(mode);
19370            // ANSI requires a comma after each transaction mode, but
19371            // PostgreSQL, for historical reasons, does not. We follow
19372            // PostgreSQL in making the comma optional, since that is strictly
19373            // more general.
19374            required = self.consume_token(&Token::Comma);
19375        }
19376        Ok(modes)
19377    }
19378
19379    /// Parse a 'COMMIT' statement
19380    pub fn parse_commit(&mut self) -> Result<Statement, ParserError> {
19381        Ok(Statement::Commit {
19382            chain: self.parse_commit_rollback_chain()?,
19383            end: false,
19384            modifier: None,
19385        })
19386    }
19387
19388    /// Parse a 'ROLLBACK' statement
19389    pub fn parse_rollback(&mut self) -> Result<Statement, ParserError> {
19390        let chain = self.parse_commit_rollback_chain()?;
19391        let savepoint = self.parse_rollback_savepoint()?;
19392
19393        Ok(Statement::Rollback { chain, savepoint })
19394    }
19395
19396    /// Parse an optional `AND [NO] CHAIN` clause for `COMMIT` and `ROLLBACK` statements
19397    pub fn parse_commit_rollback_chain(&mut self) -> Result<bool, ParserError> {
19398        let _ = self.parse_one_of_keywords(&[Keyword::TRANSACTION, Keyword::WORK, Keyword::TRAN]);
19399        if self.parse_keyword(Keyword::AND) {
19400            let chain = !self.parse_keyword(Keyword::NO);
19401            self.expect_keyword_is(Keyword::CHAIN)?;
19402            Ok(chain)
19403        } else {
19404            Ok(false)
19405        }
19406    }
19407
19408    /// Parse an optional 'TO SAVEPOINT savepoint_name' clause for ROLLBACK statements
19409    pub fn parse_rollback_savepoint(&mut self) -> Result<Option<Ident>, ParserError> {
19410        if self.parse_keyword(Keyword::TO) {
19411            let _ = self.parse_keyword(Keyword::SAVEPOINT);
19412            let savepoint = self.parse_identifier()?;
19413
19414            Ok(Some(savepoint))
19415        } else {
19416            Ok(None)
19417        }
19418    }
19419
19420    /// Parse a 'RAISERROR' statement
19421    pub fn parse_raiserror(&mut self) -> Result<Statement, ParserError> {
19422        self.expect_token(&Token::LParen)?;
19423        let message = Box::new(self.parse_expr()?);
19424        self.expect_token(&Token::Comma)?;
19425        let severity = Box::new(self.parse_expr()?);
19426        self.expect_token(&Token::Comma)?;
19427        let state = Box::new(self.parse_expr()?);
19428        let arguments = if self.consume_token(&Token::Comma) {
19429            self.parse_comma_separated(Parser::parse_expr)?
19430        } else {
19431            vec![]
19432        };
19433        self.expect_token(&Token::RParen)?;
19434        let options = if self.parse_keyword(Keyword::WITH) {
19435            self.parse_comma_separated(Parser::parse_raiserror_option)?
19436        } else {
19437            vec![]
19438        };
19439        Ok(Statement::RaisError {
19440            message,
19441            severity,
19442            state,
19443            arguments,
19444            options,
19445        })
19446    }
19447
19448    /// Parse a single `RAISERROR` option
19449    pub fn parse_raiserror_option(&mut self) -> Result<RaisErrorOption, ParserError> {
19450        match self.expect_one_of_keywords(&[Keyword::LOG, Keyword::NOWAIT, Keyword::SETERROR])? {
19451            Keyword::LOG => Ok(RaisErrorOption::Log),
19452            Keyword::NOWAIT => Ok(RaisErrorOption::NoWait),
19453            Keyword::SETERROR => Ok(RaisErrorOption::SetError),
19454            _ => self.expected_ref(
19455                "LOG, NOWAIT OR SETERROR raiserror option",
19456                self.peek_token_ref(),
19457            ),
19458        }
19459    }
19460
19461    /// Parse a MSSQL `THROW` statement.
19462    ///
19463    /// See [Statement::Throw]
19464    pub fn parse_throw(&mut self) -> Result<ThrowStatement, ParserError> {
19465        self.expect_keyword_is(Keyword::THROW)?;
19466
19467        let error_number = self.maybe_parse(|p| p.parse_expr().map(Box::new))?;
19468        let (message, state) = if error_number.is_some() {
19469            self.expect_token(&Token::Comma)?;
19470            let message = Box::new(self.parse_expr()?);
19471            self.expect_token(&Token::Comma)?;
19472            let state = Box::new(self.parse_expr()?);
19473            (Some(message), Some(state))
19474        } else {
19475            (None, None)
19476        };
19477
19478        Ok(ThrowStatement {
19479            error_number,
19480            message,
19481            state,
19482        })
19483    }
19484
19485    /// Parse a SQL `DEALLOCATE` statement
19486    pub fn parse_deallocate(&mut self) -> Result<Statement, ParserError> {
19487        let prepare = self.parse_keyword(Keyword::PREPARE);
19488        let name = self.parse_identifier()?;
19489        Ok(Statement::Deallocate { name, prepare })
19490    }
19491
19492    /// Parse a SQL `EXECUTE` statement
19493    pub fn parse_execute(&mut self) -> Result<Statement, ParserError> {
19494        let immediate =
19495            self.dialect.supports_execute_immediate() && self.parse_keyword(Keyword::IMMEDIATE);
19496
19497        // When `EXEC` is immediately followed by `(`, the content is a dynamic-SQL
19498        // expression — e.g. `EXEC (@sql)`, `EXEC ('SELECT ...')`, or
19499        // `EXEC ('SELECT ... FROM ' + @tbl + ' WHERE ...')`.
19500        // Skip name parsing; the expression ends up in `parameters` via the
19501        // `has_parentheses` path below, consistent with `EXECUTE IMMEDIATE <expr>`.
19502        let name = if immediate || matches!(self.peek_token_ref().token, Token::LParen) {
19503            None
19504        } else {
19505            Some(self.parse_object_name(false)?)
19506        };
19507
19508        let has_parentheses = self.consume_token(&Token::LParen);
19509
19510        let end_kws = &[Keyword::USING, Keyword::OUTPUT, Keyword::DEFAULT];
19511        let end_token = match (has_parentheses, self.peek_token().token) {
19512            (true, _) => Token::RParen,
19513            (false, Token::EOF) => Token::EOF,
19514            (false, Token::Word(w)) if end_kws.contains(&w.keyword) => Token::Word(w),
19515            (false, _) => Token::SemiColon,
19516        };
19517
19518        let parameters = self.parse_comma_separated0(Parser::parse_expr, end_token)?;
19519
19520        if has_parentheses {
19521            self.expect_token(&Token::RParen)?;
19522        }
19523
19524        let into = if self.parse_keyword(Keyword::INTO) {
19525            self.parse_comma_separated(Self::parse_identifier)?
19526        } else {
19527            vec![]
19528        };
19529
19530        let using = if self.parse_keyword(Keyword::USING) {
19531            self.parse_comma_separated(Self::parse_expr_with_alias)?
19532        } else {
19533            vec![]
19534        };
19535
19536        let output = self.parse_keyword(Keyword::OUTPUT);
19537
19538        let default = self.parse_keyword(Keyword::DEFAULT);
19539
19540        Ok(Statement::Execute {
19541            immediate,
19542            name,
19543            parameters,
19544            has_parentheses,
19545            into,
19546            using,
19547            output,
19548            default,
19549        })
19550    }
19551
19552    /// Parse a SQL `PREPARE` statement
19553    pub fn parse_prepare(&mut self) -> Result<Statement, ParserError> {
19554        let name = self.parse_identifier()?;
19555
19556        let mut data_types = vec![];
19557        if self.consume_token(&Token::LParen) {
19558            data_types = self.parse_comma_separated(Parser::parse_data_type)?;
19559            self.expect_token(&Token::RParen)?;
19560        }
19561
19562        self.expect_keyword_is(Keyword::AS)?;
19563        let statement = Box::new(self.parse_statement()?);
19564        Ok(Statement::Prepare {
19565            name,
19566            data_types,
19567            statement,
19568        })
19569    }
19570
19571    /// Parse a SQL `UNLOAD` statement
19572    pub fn parse_unload(&mut self) -> Result<Statement, ParserError> {
19573        self.expect_keyword(Keyword::UNLOAD)?;
19574        self.expect_token(&Token::LParen)?;
19575        let (query, query_text) =
19576            if matches!(self.peek_token_ref().token, Token::SingleQuotedString(_)) {
19577                (None, Some(self.parse_literal_string()?))
19578            } else {
19579                (Some(self.parse_query()?), None)
19580            };
19581        self.expect_token(&Token::RParen)?;
19582
19583        self.expect_keyword_is(Keyword::TO)?;
19584        let to = self.parse_identifier()?;
19585        let auth = if self.parse_keyword(Keyword::IAM_ROLE) {
19586            Some(self.parse_iam_role_kind()?)
19587        } else {
19588            None
19589        };
19590        let with = self.parse_options(Keyword::WITH)?;
19591        let mut options = vec![];
19592        while let Some(opt) = self.maybe_parse(|parser| parser.parse_copy_legacy_option())? {
19593            options.push(opt);
19594        }
19595        Ok(Statement::Unload {
19596            query,
19597            query_text,
19598            to,
19599            auth,
19600            with,
19601            options,
19602        })
19603    }
19604
19605    fn parse_select_into(&mut self) -> Result<SelectInto, ParserError> {
19606        let temporary = self
19607            .parse_one_of_keywords(&[Keyword::TEMP, Keyword::TEMPORARY])
19608            .is_some();
19609        let unlogged = self.parse_keyword(Keyword::UNLOGGED);
19610        let table = self.parse_keyword(Keyword::TABLE);
19611        let name = self.parse_object_name(false)?;
19612
19613        Ok(SelectInto {
19614            temporary,
19615            unlogged,
19616            table,
19617            name,
19618        })
19619    }
19620
19621    fn parse_pragma_value(&mut self) -> Result<ValueWithSpan, ParserError> {
19622        let v = self.parse_value()?;
19623        match &v.value {
19624            Value::SingleQuotedString(_) => Ok(v),
19625            Value::DoubleQuotedString(_) => Ok(v),
19626            Value::Number(_, _) => Ok(v),
19627            Value::Placeholder(_) => Ok(v),
19628            _ => {
19629                self.prev_token();
19630                self.expected_ref("number or string or ? placeholder", self.peek_token_ref())
19631            }
19632        }
19633    }
19634
19635    /// PRAGMA [schema-name '.'] pragma-name [('=' pragma-value) | '(' pragma-value ')']
19636    pub fn parse_pragma(&mut self) -> Result<Statement, ParserError> {
19637        let name = self.parse_object_name(false)?;
19638        if self.consume_token(&Token::LParen) {
19639            let value = self.parse_pragma_value()?;
19640            self.expect_token(&Token::RParen)?;
19641            Ok(Statement::Pragma {
19642                name,
19643                value: Some(value),
19644                is_eq: false,
19645            })
19646        } else if self.consume_token(&Token::Eq) {
19647            Ok(Statement::Pragma {
19648                name,
19649                value: Some(self.parse_pragma_value()?),
19650                is_eq: true,
19651            })
19652        } else {
19653            Ok(Statement::Pragma {
19654                name,
19655                value: None,
19656                is_eq: false,
19657            })
19658        }
19659    }
19660
19661    /// `INSTALL [extension_name]`
19662    pub fn parse_install(&mut self) -> Result<Statement, ParserError> {
19663        let extension_name = self.parse_identifier()?;
19664
19665        Ok(Statement::Install { extension_name })
19666    }
19667
19668    /// Parse a SQL LOAD statement
19669    pub fn parse_load(&mut self) -> Result<Statement, ParserError> {
19670        if self.dialect.supports_load_extension() {
19671            let extension_name = self.parse_identifier()?;
19672            Ok(Statement::Load { extension_name })
19673        } else if self.parse_keyword(Keyword::DATA) && self.dialect.supports_load_data() {
19674            let local = self.parse_one_of_keywords(&[Keyword::LOCAL]).is_some();
19675            self.expect_keyword_is(Keyword::INPATH)?;
19676            let inpath = self.parse_literal_string()?;
19677            let overwrite = self.parse_one_of_keywords(&[Keyword::OVERWRITE]).is_some();
19678            self.expect_keyword_is(Keyword::INTO)?;
19679            self.expect_keyword_is(Keyword::TABLE)?;
19680            let table_name = self.parse_object_name(false)?;
19681            let partitioned = self.parse_insert_partition()?;
19682            let table_format = self.parse_load_data_table_format()?;
19683            Ok(Statement::LoadData {
19684                local,
19685                inpath,
19686                overwrite,
19687                table_name,
19688                partitioned,
19689                table_format,
19690            })
19691        } else {
19692            self.expected_ref(
19693                "`DATA` or an extension name after `LOAD`",
19694                self.peek_token_ref(),
19695            )
19696        }
19697    }
19698
19699    /// ClickHouse:
19700    /// ```sql
19701    /// OPTIMIZE TABLE [db.]name [ON CLUSTER cluster] [PARTITION partition | PARTITION ID 'partition_id'] [FINAL] [DEDUPLICATE [BY expression]]
19702    /// ```
19703    /// [ClickHouse](https://clickhouse.com/docs/en/sql-reference/statements/optimize)
19704    ///
19705    /// Databricks:
19706    /// ```sql
19707    /// OPTIMIZE table_name [WHERE predicate] [ZORDER BY (col_name1 [, ...])]
19708    /// ```
19709    /// [Databricks](https://docs.databricks.com/en/sql/language-manual/delta-optimize.html)
19710    pub fn parse_optimize_table(&mut self) -> Result<Statement, ParserError> {
19711        let has_table_keyword = self.parse_keyword(Keyword::TABLE);
19712
19713        let name = self.parse_object_name(false)?;
19714
19715        // ClickHouse-specific options
19716        let on_cluster = self.parse_optional_on_cluster()?;
19717
19718        let partition = if self.parse_keyword(Keyword::PARTITION) {
19719            if self.parse_keyword(Keyword::ID) {
19720                Some(Partition::Identifier(self.parse_identifier()?))
19721            } else {
19722                Some(Partition::Expr(self.parse_expr()?))
19723            }
19724        } else {
19725            None
19726        };
19727
19728        let include_final = self.parse_keyword(Keyword::FINAL);
19729
19730        let deduplicate = if self.parse_keyword(Keyword::DEDUPLICATE) {
19731            if self.parse_keyword(Keyword::BY) {
19732                Some(Deduplicate::ByExpression(self.parse_expr()?))
19733            } else {
19734                Some(Deduplicate::All)
19735            }
19736        } else {
19737            None
19738        };
19739
19740        // Databricks-specific options
19741        let predicate = if self.parse_keyword(Keyword::WHERE) {
19742            Some(self.parse_expr()?)
19743        } else {
19744            None
19745        };
19746
19747        let zorder = if self.parse_keywords(&[Keyword::ZORDER, Keyword::BY]) {
19748            self.expect_token(&Token::LParen)?;
19749            let columns = self.parse_comma_separated(|p| p.parse_expr())?;
19750            self.expect_token(&Token::RParen)?;
19751            Some(columns)
19752        } else {
19753            None
19754        };
19755
19756        Ok(Statement::OptimizeTable {
19757            name,
19758            has_table_keyword,
19759            on_cluster,
19760            partition,
19761            include_final,
19762            deduplicate,
19763            predicate,
19764            zorder,
19765        })
19766    }
19767
19768    /// ```sql
19769    /// CREATE [ { TEMPORARY | TEMP } ] SEQUENCE [ IF NOT EXISTS ] <sequence_name>
19770    /// ```
19771    ///
19772    /// See [Postgres docs](https://www.postgresql.org/docs/current/sql-createsequence.html) for more details.
19773    pub fn parse_create_sequence(&mut self, temporary: bool) -> Result<Statement, ParserError> {
19774        //[ IF NOT EXISTS ]
19775        let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
19776        //name
19777        let name = self.parse_object_name(false)?;
19778        //[ AS data_type ]
19779        let mut data_type: Option<DataType> = None;
19780        if self.parse_keywords(&[Keyword::AS]) {
19781            data_type = Some(self.parse_data_type()?)
19782        }
19783        let sequence_options = self.parse_create_sequence_options()?;
19784        // [ OWNED BY { table_name.column_name | NONE } ]
19785        let owned_by = if self.parse_keywords(&[Keyword::OWNED, Keyword::BY]) {
19786            if self.parse_keywords(&[Keyword::NONE]) {
19787                Some(ObjectName::from(vec![Ident::new("NONE")]))
19788            } else {
19789                Some(self.parse_object_name(false)?)
19790            }
19791        } else {
19792            None
19793        };
19794        Ok(Statement::CreateSequence {
19795            temporary,
19796            if_not_exists,
19797            name,
19798            data_type,
19799            sequence_options,
19800            owned_by,
19801        })
19802    }
19803
19804    fn parse_create_sequence_options(&mut self) -> Result<Vec<SequenceOptions>, ParserError> {
19805        let mut sequence_options = vec![];
19806        // PostgreSQL allows these clauses in any order (e.g. pg_dump emits
19807        // `START` before `INCREMENT`), so loop until no clause matches.
19808        // https://www.postgresql.org/docs/current/sql-createsequence.html
19809        loop {
19810            //[ INCREMENT [ BY ] increment ]
19811            if self.parse_keywords(&[Keyword::INCREMENT]) {
19812                if self.parse_keywords(&[Keyword::BY]) {
19813                    sequence_options.push(SequenceOptions::IncrementBy(self.parse_number()?, true));
19814                } else {
19815                    sequence_options
19816                        .push(SequenceOptions::IncrementBy(self.parse_number()?, false));
19817                }
19818            }
19819            //[ MINVALUE minvalue | NO MINVALUE ]
19820            else if self.parse_keyword(Keyword::MINVALUE) {
19821                sequence_options.push(SequenceOptions::MinValue(Some(self.parse_number()?)));
19822            } else if self.parse_keywords(&[Keyword::NO, Keyword::MINVALUE]) {
19823                sequence_options.push(SequenceOptions::MinValue(None));
19824            }
19825            //[ MAXVALUE maxvalue | NO MAXVALUE ]
19826            else if self.parse_keywords(&[Keyword::MAXVALUE]) {
19827                sequence_options.push(SequenceOptions::MaxValue(Some(self.parse_number()?)));
19828            } else if self.parse_keywords(&[Keyword::NO, Keyword::MAXVALUE]) {
19829                sequence_options.push(SequenceOptions::MaxValue(None));
19830            }
19831            //[ START [ WITH ] start ]
19832            else if self.parse_keywords(&[Keyword::START]) {
19833                if self.parse_keywords(&[Keyword::WITH]) {
19834                    sequence_options.push(SequenceOptions::StartWith(self.parse_number()?, true));
19835                } else {
19836                    sequence_options.push(SequenceOptions::StartWith(self.parse_number()?, false));
19837                }
19838            }
19839            //[ CACHE cache ]
19840            else if self.parse_keywords(&[Keyword::CACHE]) {
19841                sequence_options.push(SequenceOptions::Cache(self.parse_number()?));
19842            }
19843            // [ [ NO ] CYCLE ]
19844            else if self.parse_keywords(&[Keyword::NO, Keyword::CYCLE]) {
19845                sequence_options.push(SequenceOptions::Cycle(true));
19846            } else if self.parse_keywords(&[Keyword::CYCLE]) {
19847                sequence_options.push(SequenceOptions::Cycle(false));
19848            } else {
19849                break;
19850            }
19851        }
19852
19853        Ok(sequence_options)
19854    }
19855
19856    ///   Parse a `CREATE SERVER` statement.
19857    ///
19858    ///  See [Statement::CreateServer]
19859    pub fn parse_pg_create_server(&mut self) -> Result<Statement, ParserError> {
19860        let ine = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
19861        let name = self.parse_object_name(false)?;
19862
19863        let server_type = if self.parse_keyword(Keyword::TYPE) {
19864            Some(self.parse_identifier()?)
19865        } else {
19866            None
19867        };
19868
19869        let version = if self.parse_keyword(Keyword::VERSION) {
19870            Some(self.parse_identifier()?)
19871        } else {
19872            None
19873        };
19874
19875        self.expect_keywords(&[Keyword::FOREIGN, Keyword::DATA, Keyword::WRAPPER])?;
19876        let foreign_data_wrapper = self.parse_object_name(false)?;
19877
19878        let mut options = None;
19879        if self.parse_keyword(Keyword::OPTIONS) {
19880            self.expect_token(&Token::LParen)?;
19881            options = Some(self.parse_comma_separated(|p| {
19882                let key = p.parse_identifier()?;
19883                let value = p.parse_identifier()?;
19884                Ok(CreateServerOption { key, value })
19885            })?);
19886            self.expect_token(&Token::RParen)?;
19887        }
19888
19889        Ok(Statement::CreateServer(CreateServerStatement {
19890            name,
19891            if_not_exists: ine,
19892            server_type,
19893            version,
19894            foreign_data_wrapper,
19895            options,
19896        }))
19897    }
19898
19899    /// The index of the first unprocessed token.
19900    pub fn index(&self) -> usize {
19901        self.index
19902    }
19903
19904    /// Parse a named window definition.
19905    pub fn parse_named_window(&mut self) -> Result<NamedWindowDefinition, ParserError> {
19906        let ident = self.parse_identifier()?;
19907        self.expect_keyword_is(Keyword::AS)?;
19908
19909        let window_expr = if self.consume_token(&Token::LParen) {
19910            NamedWindowExpr::WindowSpec(self.parse_window_spec()?)
19911        } else if self.dialect.supports_window_clause_named_window_reference() {
19912            NamedWindowExpr::NamedWindow(self.parse_identifier()?)
19913        } else {
19914            return self.expected_ref("(", self.peek_token_ref());
19915        };
19916
19917        Ok(NamedWindowDefinition(ident, window_expr))
19918    }
19919
19920    /// Parse `CREATE PROCEDURE` statement.
19921    pub fn parse_create_procedure(&mut self, or_alter: bool) -> Result<Statement, ParserError> {
19922        let name = self.parse_object_name(false)?;
19923        let params = self.parse_optional_procedure_parameters()?;
19924
19925        let language = if self.parse_keyword(Keyword::LANGUAGE) {
19926            Some(self.parse_identifier()?)
19927        } else {
19928            None
19929        };
19930
19931        self.expect_keyword_is(Keyword::AS)?;
19932
19933        let body = self.parse_conditional_statements(&[Keyword::END])?;
19934
19935        Ok(Statement::CreateProcedure {
19936            name,
19937            or_alter,
19938            params,
19939            language,
19940            body,
19941        })
19942    }
19943
19944    /// Parse a window specification.
19945    pub fn parse_window_spec(&mut self) -> Result<WindowSpec, ParserError> {
19946        let window_name = match &self.peek_token_ref().token {
19947            Token::Word(word) if word.keyword == Keyword::NoKeyword => {
19948                self.parse_optional_ident()?
19949            }
19950            _ => None,
19951        };
19952
19953        let partition_by = if self.parse_keywords(&[Keyword::PARTITION, Keyword::BY]) {
19954            self.parse_comma_separated(Parser::parse_expr)?
19955        } else {
19956            vec![]
19957        };
19958        let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
19959            self.parse_comma_separated(Parser::parse_order_by_expr)?
19960        } else {
19961            vec![]
19962        };
19963
19964        let window_frame = if !self.consume_token(&Token::RParen) {
19965            let window_frame = self.parse_window_frame()?;
19966            self.expect_token(&Token::RParen)?;
19967            Some(window_frame)
19968        } else {
19969            None
19970        };
19971        Ok(WindowSpec {
19972            window_name,
19973            partition_by,
19974            order_by,
19975            window_frame,
19976        })
19977    }
19978
19979    /// Parse `CREATE TYPE` statement.
19980    pub fn parse_create_type(&mut self) -> Result<Statement, ParserError> {
19981        let name = self.parse_object_name(false)?;
19982
19983        // Check if we have AS keyword
19984        let has_as = self.parse_keyword(Keyword::AS);
19985
19986        if !has_as {
19987            // Two cases: CREATE TYPE name; or CREATE TYPE name (options);
19988            if self.consume_token(&Token::LParen) {
19989                // CREATE TYPE name (options) - SQL definition without AS
19990                let options = self.parse_create_type_sql_definition_options()?;
19991                self.expect_token(&Token::RParen)?;
19992                return Ok(Statement::CreateType {
19993                    name,
19994                    representation: Some(UserDefinedTypeRepresentation::SqlDefinition { options }),
19995                });
19996            }
19997
19998            // CREATE TYPE name; - no representation
19999            return Ok(Statement::CreateType {
20000                name,
20001                representation: None,
20002            });
20003        }
20004
20005        // We have AS keyword
20006        if self.parse_keyword(Keyword::ENUM) {
20007            // CREATE TYPE name AS ENUM (labels)
20008            self.parse_create_type_enum(name)
20009        } else if self.parse_keyword(Keyword::RANGE) {
20010            // CREATE TYPE name AS RANGE (options)
20011            self.parse_create_type_range(name)
20012        } else if self.consume_token(&Token::LParen) {
20013            // CREATE TYPE name AS (attributes) - Composite
20014            self.parse_create_type_composite(name)
20015        } else {
20016            self.expected_ref("ENUM, RANGE, or '(' after AS", self.peek_token_ref())
20017        }
20018    }
20019
20020    /// Parse remainder of `CREATE TYPE AS (attributes)` statement (composite type)
20021    ///
20022    /// See [PostgreSQL](https://www.postgresql.org/docs/current/sql-createtype.html)
20023    fn parse_create_type_composite(&mut self, name: ObjectName) -> Result<Statement, ParserError> {
20024        if self.consume_token(&Token::RParen) {
20025            // Empty composite type
20026            return Ok(Statement::CreateType {
20027                name,
20028                representation: Some(UserDefinedTypeRepresentation::Composite {
20029                    attributes: vec![],
20030                }),
20031            });
20032        }
20033
20034        let mut attributes = vec![];
20035        loop {
20036            let attr_name = self.parse_identifier()?;
20037            let attr_data_type = self.parse_data_type()?;
20038            let attr_collation = if self.parse_keyword(Keyword::COLLATE) {
20039                Some(self.parse_object_name(false)?)
20040            } else {
20041                None
20042            };
20043            attributes.push(UserDefinedTypeCompositeAttributeDef {
20044                name: attr_name,
20045                data_type: attr_data_type,
20046                collation: attr_collation,
20047            });
20048
20049            if !self.consume_token(&Token::Comma) {
20050                break;
20051            }
20052        }
20053        self.expect_token(&Token::RParen)?;
20054
20055        Ok(Statement::CreateType {
20056            name,
20057            representation: Some(UserDefinedTypeRepresentation::Composite { attributes }),
20058        })
20059    }
20060
20061    /// Parse remainder of `CREATE TYPE AS ENUM` statement (see [Statement::CreateType] and [Self::parse_create_type])
20062    ///
20063    /// See [PostgreSQL](https://www.postgresql.org/docs/current/sql-createtype.html)
20064    pub fn parse_create_type_enum(&mut self, name: ObjectName) -> Result<Statement, ParserError> {
20065        self.expect_token(&Token::LParen)?;
20066        let labels = self.parse_comma_separated0(|p| p.parse_identifier(), Token::RParen)?;
20067        self.expect_token(&Token::RParen)?;
20068
20069        Ok(Statement::CreateType {
20070            name,
20071            representation: Some(UserDefinedTypeRepresentation::Enum { labels }),
20072        })
20073    }
20074
20075    /// Parse remainder of `CREATE TYPE AS RANGE` statement
20076    ///
20077    /// See [PostgreSQL](https://www.postgresql.org/docs/current/sql-createtype.html)
20078    fn parse_create_type_range(&mut self, name: ObjectName) -> Result<Statement, ParserError> {
20079        self.expect_token(&Token::LParen)?;
20080        let options = self.parse_comma_separated0(|p| p.parse_range_option(), Token::RParen)?;
20081        self.expect_token(&Token::RParen)?;
20082
20083        Ok(Statement::CreateType {
20084            name,
20085            representation: Some(UserDefinedTypeRepresentation::Range { options }),
20086        })
20087    }
20088
20089    /// Parse a single range option for a `CREATE TYPE AS RANGE` statement
20090    fn parse_range_option(&mut self) -> Result<UserDefinedTypeRangeOption, ParserError> {
20091        let keyword = self.parse_one_of_keywords(&[
20092            Keyword::SUBTYPE,
20093            Keyword::SUBTYPE_OPCLASS,
20094            Keyword::COLLATION,
20095            Keyword::CANONICAL,
20096            Keyword::SUBTYPE_DIFF,
20097            Keyword::MULTIRANGE_TYPE_NAME,
20098        ]);
20099
20100        match keyword {
20101            Some(Keyword::SUBTYPE) => {
20102                self.expect_token(&Token::Eq)?;
20103                let data_type = self.parse_data_type()?;
20104                Ok(UserDefinedTypeRangeOption::Subtype(data_type))
20105            }
20106            Some(Keyword::SUBTYPE_OPCLASS) => {
20107                self.expect_token(&Token::Eq)?;
20108                let name = self.parse_object_name(false)?;
20109                Ok(UserDefinedTypeRangeOption::SubtypeOpClass(name))
20110            }
20111            Some(Keyword::COLLATION) => {
20112                self.expect_token(&Token::Eq)?;
20113                let name = self.parse_object_name(false)?;
20114                Ok(UserDefinedTypeRangeOption::Collation(name))
20115            }
20116            Some(Keyword::CANONICAL) => {
20117                self.expect_token(&Token::Eq)?;
20118                let name = self.parse_object_name(false)?;
20119                Ok(UserDefinedTypeRangeOption::Canonical(name))
20120            }
20121            Some(Keyword::SUBTYPE_DIFF) => {
20122                self.expect_token(&Token::Eq)?;
20123                let name = self.parse_object_name(false)?;
20124                Ok(UserDefinedTypeRangeOption::SubtypeDiff(name))
20125            }
20126            Some(Keyword::MULTIRANGE_TYPE_NAME) => {
20127                self.expect_token(&Token::Eq)?;
20128                let name = self.parse_object_name(false)?;
20129                Ok(UserDefinedTypeRangeOption::MultirangeTypeName(name))
20130            }
20131            _ => self.expected_ref("range option keyword", self.peek_token_ref()),
20132        }
20133    }
20134
20135    /// Parse SQL definition options for CREATE TYPE (options)
20136    fn parse_create_type_sql_definition_options(
20137        &mut self,
20138    ) -> Result<Vec<UserDefinedTypeSqlDefinitionOption>, ParserError> {
20139        self.parse_comma_separated0(|p| p.parse_sql_definition_option(), Token::RParen)
20140    }
20141
20142    /// Parse a single SQL definition option for CREATE TYPE (options)
20143    fn parse_sql_definition_option(
20144        &mut self,
20145    ) -> Result<UserDefinedTypeSqlDefinitionOption, ParserError> {
20146        let keyword = self.parse_one_of_keywords(&[
20147            Keyword::INPUT,
20148            Keyword::OUTPUT,
20149            Keyword::RECEIVE,
20150            Keyword::SEND,
20151            Keyword::TYPMOD_IN,
20152            Keyword::TYPMOD_OUT,
20153            Keyword::ANALYZE,
20154            Keyword::SUBSCRIPT,
20155            Keyword::INTERNALLENGTH,
20156            Keyword::PASSEDBYVALUE,
20157            Keyword::ALIGNMENT,
20158            Keyword::STORAGE,
20159            Keyword::LIKE,
20160            Keyword::CATEGORY,
20161            Keyword::PREFERRED,
20162            Keyword::DEFAULT,
20163            Keyword::ELEMENT,
20164            Keyword::DELIMITER,
20165            Keyword::COLLATABLE,
20166        ]);
20167
20168        match keyword {
20169            Some(Keyword::INPUT) => {
20170                self.expect_token(&Token::Eq)?;
20171                let name = self.parse_object_name(false)?;
20172                Ok(UserDefinedTypeSqlDefinitionOption::Input(name))
20173            }
20174            Some(Keyword::OUTPUT) => {
20175                self.expect_token(&Token::Eq)?;
20176                let name = self.parse_object_name(false)?;
20177                Ok(UserDefinedTypeSqlDefinitionOption::Output(name))
20178            }
20179            Some(Keyword::RECEIVE) => {
20180                self.expect_token(&Token::Eq)?;
20181                let name = self.parse_object_name(false)?;
20182                Ok(UserDefinedTypeSqlDefinitionOption::Receive(name))
20183            }
20184            Some(Keyword::SEND) => {
20185                self.expect_token(&Token::Eq)?;
20186                let name = self.parse_object_name(false)?;
20187                Ok(UserDefinedTypeSqlDefinitionOption::Send(name))
20188            }
20189            Some(Keyword::TYPMOD_IN) => {
20190                self.expect_token(&Token::Eq)?;
20191                let name = self.parse_object_name(false)?;
20192                Ok(UserDefinedTypeSqlDefinitionOption::TypmodIn(name))
20193            }
20194            Some(Keyword::TYPMOD_OUT) => {
20195                self.expect_token(&Token::Eq)?;
20196                let name = self.parse_object_name(false)?;
20197                Ok(UserDefinedTypeSqlDefinitionOption::TypmodOut(name))
20198            }
20199            Some(Keyword::ANALYZE) => {
20200                self.expect_token(&Token::Eq)?;
20201                let name = self.parse_object_name(false)?;
20202                Ok(UserDefinedTypeSqlDefinitionOption::Analyze(name))
20203            }
20204            Some(Keyword::SUBSCRIPT) => {
20205                self.expect_token(&Token::Eq)?;
20206                let name = self.parse_object_name(false)?;
20207                Ok(UserDefinedTypeSqlDefinitionOption::Subscript(name))
20208            }
20209            Some(Keyword::INTERNALLENGTH) => {
20210                self.expect_token(&Token::Eq)?;
20211                if self.parse_keyword(Keyword::VARIABLE) {
20212                    Ok(UserDefinedTypeSqlDefinitionOption::InternalLength(
20213                        UserDefinedTypeInternalLength::Variable,
20214                    ))
20215                } else {
20216                    let value = self.parse_literal_uint()?;
20217                    Ok(UserDefinedTypeSqlDefinitionOption::InternalLength(
20218                        UserDefinedTypeInternalLength::Fixed(value),
20219                    ))
20220                }
20221            }
20222            Some(Keyword::PASSEDBYVALUE) => Ok(UserDefinedTypeSqlDefinitionOption::PassedByValue),
20223            Some(Keyword::ALIGNMENT) => {
20224                self.expect_token(&Token::Eq)?;
20225                let align_keyword = self.parse_one_of_keywords(&[
20226                    Keyword::CHAR,
20227                    Keyword::INT2,
20228                    Keyword::INT4,
20229                    Keyword::DOUBLE,
20230                ]);
20231                match align_keyword {
20232                    Some(Keyword::CHAR) => Ok(UserDefinedTypeSqlDefinitionOption::Alignment(
20233                        Alignment::Char,
20234                    )),
20235                    Some(Keyword::INT2) => Ok(UserDefinedTypeSqlDefinitionOption::Alignment(
20236                        Alignment::Int2,
20237                    )),
20238                    Some(Keyword::INT4) => Ok(UserDefinedTypeSqlDefinitionOption::Alignment(
20239                        Alignment::Int4,
20240                    )),
20241                    Some(Keyword::DOUBLE) => Ok(UserDefinedTypeSqlDefinitionOption::Alignment(
20242                        Alignment::Double,
20243                    )),
20244                    _ => self.expected_ref(
20245                        "alignment value (char, int2, int4, or double)",
20246                        self.peek_token_ref(),
20247                    ),
20248                }
20249            }
20250            Some(Keyword::STORAGE) => {
20251                self.expect_token(&Token::Eq)?;
20252                let storage_keyword = self.parse_one_of_keywords(&[
20253                    Keyword::PLAIN,
20254                    Keyword::EXTERNAL,
20255                    Keyword::EXTENDED,
20256                    Keyword::MAIN,
20257                ]);
20258                match storage_keyword {
20259                    Some(Keyword::PLAIN) => Ok(UserDefinedTypeSqlDefinitionOption::Storage(
20260                        UserDefinedTypeStorage::Plain,
20261                    )),
20262                    Some(Keyword::EXTERNAL) => Ok(UserDefinedTypeSqlDefinitionOption::Storage(
20263                        UserDefinedTypeStorage::External,
20264                    )),
20265                    Some(Keyword::EXTENDED) => Ok(UserDefinedTypeSqlDefinitionOption::Storage(
20266                        UserDefinedTypeStorage::Extended,
20267                    )),
20268                    Some(Keyword::MAIN) => Ok(UserDefinedTypeSqlDefinitionOption::Storage(
20269                        UserDefinedTypeStorage::Main,
20270                    )),
20271                    _ => self.expected_ref(
20272                        "storage value (plain, external, extended, or main)",
20273                        self.peek_token_ref(),
20274                    ),
20275                }
20276            }
20277            Some(Keyword::LIKE) => {
20278                self.expect_token(&Token::Eq)?;
20279                let name = self.parse_object_name(false)?;
20280                Ok(UserDefinedTypeSqlDefinitionOption::Like(name))
20281            }
20282            Some(Keyword::CATEGORY) => {
20283                self.expect_token(&Token::Eq)?;
20284                let category_str = self.parse_literal_string()?;
20285                let category_char = category_str.chars().next().ok_or_else(|| {
20286                    ParserError::ParserError(
20287                        "CATEGORY value must be a single character".to_string(),
20288                    )
20289                })?;
20290                Ok(UserDefinedTypeSqlDefinitionOption::Category(category_char))
20291            }
20292            Some(Keyword::PREFERRED) => {
20293                self.expect_token(&Token::Eq)?;
20294                let value =
20295                    self.parse_keyword(Keyword::TRUE) || !self.parse_keyword(Keyword::FALSE);
20296                Ok(UserDefinedTypeSqlDefinitionOption::Preferred(value))
20297            }
20298            Some(Keyword::DEFAULT) => {
20299                self.expect_token(&Token::Eq)?;
20300                let expr = self.parse_expr()?;
20301                Ok(UserDefinedTypeSqlDefinitionOption::Default(expr))
20302            }
20303            Some(Keyword::ELEMENT) => {
20304                self.expect_token(&Token::Eq)?;
20305                let data_type = self.parse_data_type()?;
20306                Ok(UserDefinedTypeSqlDefinitionOption::Element(data_type))
20307            }
20308            Some(Keyword::DELIMITER) => {
20309                self.expect_token(&Token::Eq)?;
20310                let delimiter = self.parse_literal_string()?;
20311                Ok(UserDefinedTypeSqlDefinitionOption::Delimiter(delimiter))
20312            }
20313            Some(Keyword::COLLATABLE) => {
20314                self.expect_token(&Token::Eq)?;
20315                let value =
20316                    self.parse_keyword(Keyword::TRUE) || !self.parse_keyword(Keyword::FALSE);
20317                Ok(UserDefinedTypeSqlDefinitionOption::Collatable(value))
20318            }
20319            _ => self.expected_ref("SQL definition option keyword", self.peek_token_ref()),
20320        }
20321    }
20322
20323    fn parse_parenthesized_identifiers(&mut self) -> Result<Vec<Ident>, ParserError> {
20324        self.expect_token(&Token::LParen)?;
20325        let idents = self.parse_comma_separated0(|p| p.parse_identifier(), Token::RParen)?;
20326        self.expect_token(&Token::RParen)?;
20327        Ok(idents)
20328    }
20329
20330    fn parse_column_position(&mut self) -> Result<Option<MySQLColumnPosition>, ParserError> {
20331        if dialect_of!(self is MySqlDialect | GenericDialect) {
20332            if self.parse_keyword(Keyword::FIRST) {
20333                Ok(Some(MySQLColumnPosition::First))
20334            } else if self.parse_keyword(Keyword::AFTER) {
20335                let ident = self.parse_identifier()?;
20336                Ok(Some(MySQLColumnPosition::After(ident)))
20337            } else {
20338                Ok(None)
20339            }
20340        } else {
20341            Ok(None)
20342        }
20343    }
20344
20345    /// Parse [Statement::Print]
20346    fn parse_print(&mut self) -> Result<Statement, ParserError> {
20347        Ok(Statement::Print(PrintStatement {
20348            message: Box::new(self.parse_expr()?),
20349        }))
20350    }
20351
20352    /// Parse [Statement::WaitFor]
20353    ///
20354    /// See: <https://learn.microsoft.com/en-us/sql/t-sql/language-elements/waitfor-transact-sql>
20355    fn parse_waitfor(&mut self) -> Result<Statement, ParserError> {
20356        let wait_type = if self.parse_keyword(Keyword::DELAY) {
20357            WaitForType::Delay
20358        } else if self.parse_keyword(Keyword::TIME) {
20359            WaitForType::Time
20360        } else {
20361            return self.expected_ref("DELAY or TIME", self.peek_token_ref());
20362        };
20363        let expr = self.parse_expr()?;
20364        Ok(Statement::WaitFor(WaitForStatement { wait_type, expr }))
20365    }
20366
20367    /// Parse [Statement::Return]
20368    fn parse_return(&mut self) -> Result<Statement, ParserError> {
20369        match self.maybe_parse(|p| p.parse_expr())? {
20370            Some(expr) => Ok(Statement::Return(ReturnStatement {
20371                value: Some(ReturnStatementValue::Expr(expr)),
20372            })),
20373            None => Ok(Statement::Return(ReturnStatement { value: None })),
20374        }
20375    }
20376
20377    /// /// Parse a `EXPORT DATA` statement.
20378    ///
20379    /// See [Statement::ExportData]
20380    fn parse_export_data(&mut self) -> Result<Statement, ParserError> {
20381        self.expect_keywords(&[Keyword::EXPORT, Keyword::DATA])?;
20382
20383        let connection = if self.parse_keywords(&[Keyword::WITH, Keyword::CONNECTION]) {
20384            Some(self.parse_object_name(false)?)
20385        } else {
20386            None
20387        };
20388        self.expect_keyword(Keyword::OPTIONS)?;
20389        self.expect_token(&Token::LParen)?;
20390        let options = self.parse_comma_separated(|p| p.parse_sql_option())?;
20391        self.expect_token(&Token::RParen)?;
20392        self.expect_keyword(Keyword::AS)?;
20393        let query = self.parse_query()?;
20394        Ok(Statement::ExportData(ExportData {
20395            options,
20396            query,
20397            connection,
20398        }))
20399    }
20400
20401    fn parse_vacuum(&mut self) -> Result<Statement, ParserError> {
20402        self.expect_keyword(Keyword::VACUUM)?;
20403        let full = self.parse_keyword(Keyword::FULL);
20404        let sort_only = self.parse_keywords(&[Keyword::SORT, Keyword::ONLY]);
20405        let delete_only = self.parse_keywords(&[Keyword::DELETE, Keyword::ONLY]);
20406        let reindex = self.parse_keyword(Keyword::REINDEX);
20407        let recluster = self.parse_keyword(Keyword::RECLUSTER);
20408        let (table_name, threshold, boost) =
20409            match self.maybe_parse(|p| p.parse_object_name(false))? {
20410                Some(table_name) => {
20411                    let threshold = if self.parse_keyword(Keyword::TO) {
20412                        let value = self.parse_value()?;
20413                        self.expect_keyword(Keyword::PERCENT)?;
20414                        Some(value)
20415                    } else {
20416                        None
20417                    };
20418                    let boost = self.parse_keyword(Keyword::BOOST);
20419                    (Some(table_name), threshold, boost)
20420                }
20421                _ => (None, None, false),
20422            };
20423        Ok(Statement::Vacuum(VacuumStatement {
20424            full,
20425            sort_only,
20426            delete_only,
20427            reindex,
20428            recluster,
20429            table_name,
20430            threshold,
20431            boost,
20432        }))
20433    }
20434
20435    /// Consume the parser and return its underlying token buffer
20436    pub fn into_tokens(self) -> Vec<TokenWithSpan> {
20437        self.tokens
20438    }
20439
20440    /// Returns true if the next keyword indicates a sub query, i.e. SELECT or WITH
20441    fn peek_sub_query(&mut self) -> bool {
20442        self.peek_one_of_keywords(&[Keyword::SELECT, Keyword::WITH])
20443            .is_some()
20444    }
20445
20446    pub(crate) fn parse_show_stmt_options(&mut self) -> Result<ShowStatementOptions, ParserError> {
20447        let show_in;
20448        let mut filter_position = None;
20449        if self.dialect.supports_show_like_before_in() {
20450            if let Some(filter) = self.parse_show_statement_filter()? {
20451                filter_position = Some(ShowStatementFilterPosition::Infix(filter));
20452            }
20453            show_in = self.maybe_parse_show_stmt_in()?;
20454        } else {
20455            show_in = self.maybe_parse_show_stmt_in()?;
20456            if let Some(filter) = self.parse_show_statement_filter()? {
20457                filter_position = Some(ShowStatementFilterPosition::Suffix(filter));
20458            }
20459        }
20460        let starts_with = self.maybe_parse_show_stmt_starts_with()?;
20461        let limit = self.maybe_parse_show_stmt_limit()?;
20462        let from = self.maybe_parse_show_stmt_from()?;
20463        Ok(ShowStatementOptions {
20464            filter_position,
20465            show_in,
20466            starts_with,
20467            limit,
20468            limit_from: from,
20469        })
20470    }
20471
20472    fn maybe_parse_show_stmt_in(&mut self) -> Result<Option<ShowStatementIn>, ParserError> {
20473        let clause = match self.parse_one_of_keywords(&[Keyword::FROM, Keyword::IN]) {
20474            Some(Keyword::FROM) => ShowStatementInClause::FROM,
20475            Some(Keyword::IN) => ShowStatementInClause::IN,
20476            None => return Ok(None),
20477            _ => return self.expected_ref("FROM or IN", self.peek_token_ref()),
20478        };
20479
20480        let (parent_type, parent_name) = match self.parse_one_of_keywords(&[
20481            Keyword::ACCOUNT,
20482            Keyword::DATABASE,
20483            Keyword::SCHEMA,
20484            Keyword::TABLE,
20485            Keyword::VIEW,
20486        ]) {
20487            // If we see these next keywords it means we don't have a parent name
20488            Some(Keyword::DATABASE)
20489                if self.peek_keywords(&[Keyword::STARTS, Keyword::WITH])
20490                    | self.peek_keyword(Keyword::LIMIT) =>
20491            {
20492                (Some(ShowStatementInParentType::Database), None)
20493            }
20494            Some(Keyword::SCHEMA)
20495                if self.peek_keywords(&[Keyword::STARTS, Keyword::WITH])
20496                    | self.peek_keyword(Keyword::LIMIT) =>
20497            {
20498                (Some(ShowStatementInParentType::Schema), None)
20499            }
20500            Some(parent_kw) => {
20501                // The parent name here is still optional, for example:
20502                // SHOW TABLES IN ACCOUNT, so parsing the object name
20503                // may fail because the statement ends.
20504                let parent_name = self.maybe_parse(|p| p.parse_object_name(false))?;
20505                match parent_kw {
20506                    Keyword::ACCOUNT => (Some(ShowStatementInParentType::Account), parent_name),
20507                    Keyword::DATABASE => (Some(ShowStatementInParentType::Database), parent_name),
20508                    Keyword::SCHEMA => (Some(ShowStatementInParentType::Schema), parent_name),
20509                    Keyword::TABLE => (Some(ShowStatementInParentType::Table), parent_name),
20510                    Keyword::VIEW => (Some(ShowStatementInParentType::View), parent_name),
20511                    _ => {
20512                        return self.expected_ref(
20513                            "one of ACCOUNT, DATABASE, SCHEMA, TABLE or VIEW",
20514                            self.peek_token_ref(),
20515                        )
20516                    }
20517                }
20518            }
20519            None => {
20520                // Parsing MySQL style FROM tbl_name FROM db_name
20521                // which is equivalent to FROM tbl_name.db_name
20522                let mut parent_name = self.parse_object_name(false)?;
20523                if self
20524                    .parse_one_of_keywords(&[Keyword::FROM, Keyword::IN])
20525                    .is_some()
20526                {
20527                    parent_name
20528                        .0
20529                        .insert(0, ObjectNamePart::Identifier(self.parse_identifier()?));
20530                }
20531                (None, Some(parent_name))
20532            }
20533        };
20534
20535        Ok(Some(ShowStatementIn {
20536            clause,
20537            parent_type,
20538            parent_name,
20539        }))
20540    }
20541
20542    fn maybe_parse_show_stmt_starts_with(&mut self) -> Result<Option<ValueWithSpan>, ParserError> {
20543        if self.parse_keywords(&[Keyword::STARTS, Keyword::WITH]) {
20544            Ok(Some(self.parse_value()?))
20545        } else {
20546            Ok(None)
20547        }
20548    }
20549
20550    fn maybe_parse_show_stmt_limit(&mut self) -> Result<Option<Expr>, ParserError> {
20551        if self.parse_keyword(Keyword::LIMIT) {
20552            Ok(self.parse_limit()?)
20553        } else {
20554            Ok(None)
20555        }
20556    }
20557
20558    fn maybe_parse_show_stmt_from(&mut self) -> Result<Option<ValueWithSpan>, ParserError> {
20559        if self.parse_keyword(Keyword::FROM) {
20560            Ok(Some(self.parse_value()?))
20561        } else {
20562            Ok(None)
20563        }
20564    }
20565
20566    pub(crate) fn in_column_definition_state(&self) -> bool {
20567        matches!(self.state, ColumnDefinition)
20568    }
20569
20570    /// Parses options provided in key-value format.
20571    ///
20572    /// * `parenthesized` - true if the options are enclosed in parenthesis
20573    /// * `end_words` - a list of keywords that any of them indicates the end of the options section
20574    pub(crate) fn parse_key_value_options(
20575        &mut self,
20576        parenthesized: bool,
20577        end_words: &[Keyword],
20578    ) -> Result<KeyValueOptions, ParserError> {
20579        let mut options: Vec<KeyValueOption> = Vec::new();
20580        let mut delimiter = KeyValueOptionsDelimiter::Space;
20581        if parenthesized {
20582            self.expect_token(&Token::LParen)?;
20583        }
20584        loop {
20585            match self.next_token().token {
20586                Token::RParen => {
20587                    if parenthesized {
20588                        break;
20589                    } else {
20590                        return self.expected_ref(" another option or EOF", self.peek_token_ref());
20591                    }
20592                }
20593                Token::EOF | Token::SemiColon => break,
20594                Token::Comma => {
20595                    delimiter = KeyValueOptionsDelimiter::Comma;
20596                    continue;
20597                }
20598                Token::Word(w) if !end_words.contains(&w.keyword) => {
20599                    options.push(self.parse_key_value_option(&w)?)
20600                }
20601                Token::Word(w) if end_words.contains(&w.keyword) => {
20602                    self.prev_token();
20603                    break;
20604                }
20605                _ => {
20606                    return self.expected_ref(
20607                        "another option, EOF, SemiColon, Comma or ')'",
20608                        self.peek_token_ref(),
20609                    )
20610                }
20611            };
20612        }
20613
20614        Ok(KeyValueOptions { delimiter, options })
20615    }
20616
20617    /// Parses a `KEY = VALUE` construct based on the specified key
20618    pub(crate) fn parse_key_value_option(
20619        &mut self,
20620        key: &Word,
20621    ) -> Result<KeyValueOption, ParserError> {
20622        self.expect_token(&Token::Eq)?;
20623        let peeked_token = self.peek_token();
20624        match peeked_token.token {
20625            Token::SingleQuotedString(_) => Ok(KeyValueOption {
20626                option_name: key.value.clone(),
20627                option_value: KeyValueOptionKind::Single(self.parse_value()?),
20628            }),
20629            Token::Word(word)
20630                if word.keyword == Keyword::TRUE || word.keyword == Keyword::FALSE =>
20631            {
20632                Ok(KeyValueOption {
20633                    option_name: key.value.clone(),
20634                    option_value: KeyValueOptionKind::Single(self.parse_value()?),
20635                })
20636            }
20637            Token::Number(..) => Ok(KeyValueOption {
20638                option_name: key.value.clone(),
20639                option_value: KeyValueOptionKind::Single(self.parse_value()?),
20640            }),
20641            Token::Word(word) => {
20642                self.next_token();
20643                Ok(KeyValueOption {
20644                    option_name: key.value.clone(),
20645                    option_value: KeyValueOptionKind::Single(
20646                        Value::Placeholder(word.value.clone()).with_span(peeked_token.span),
20647                    ),
20648                })
20649            }
20650            Token::LParen => {
20651                // Can be a list of values or a list of key value properties.
20652                // Try to parse a list of values and if that fails, try to parse
20653                // a list of key-value properties.
20654                match self.maybe_parse(|parser| {
20655                    parser.expect_token(&Token::LParen)?;
20656                    let values = parser.parse_comma_separated0(|p| p.parse_value(), Token::RParen);
20657                    parser.expect_token(&Token::RParen)?;
20658                    values
20659                })? {
20660                    Some(values) => Ok(KeyValueOption {
20661                        option_name: key.value.clone(),
20662                        option_value: KeyValueOptionKind::Multi(values),
20663                    }),
20664                    None => Ok(KeyValueOption {
20665                        option_name: key.value.clone(),
20666                        option_value: KeyValueOptionKind::KeyValueOptions(Box::new(
20667                            self.parse_key_value_options(true, &[])?,
20668                        )),
20669                    }),
20670                }
20671            }
20672            _ => self.expected_ref("expected option value", self.peek_token_ref()),
20673        }
20674    }
20675
20676    /// Parses a RESET statement
20677    fn parse_reset(&mut self) -> Result<ResetStatement, ParserError> {
20678        if self.parse_keyword(Keyword::ALL) {
20679            return Ok(ResetStatement { reset: Reset::ALL });
20680        }
20681
20682        let obj = self.parse_object_name(false)?;
20683        Ok(ResetStatement {
20684            reset: Reset::ConfigurationParameter(obj),
20685        })
20686    }
20687}
20688
20689fn maybe_prefixed_expr(expr: Expr, prefix: Option<Ident>) -> Expr {
20690    if let Some(prefix) = prefix {
20691        Expr::Prefixed {
20692            prefix,
20693            value: Box::new(expr),
20694        }
20695    } else {
20696        expr
20697    }
20698}
20699
20700impl Word {
20701    /// Convert a reference to this word into an [`Ident`] by cloning the value.
20702    ///
20703    /// Use this method when you need to keep the original `Word` around.
20704    /// If you can consume the `Word`, prefer [`into_ident`](Self::into_ident) instead
20705    /// to avoid cloning.
20706    pub fn to_ident(&self, span: Span) -> Ident {
20707        Ident {
20708            value: self.value.clone(),
20709            quote_style: self.quote_style,
20710            span,
20711        }
20712    }
20713
20714    /// Convert this word into an [`Ident`] identifier, consuming the `Word`.
20715    ///
20716    /// This avoids cloning the string value. If you need to keep the original
20717    /// `Word`, use [`to_ident`](Self::to_ident) instead.
20718    pub fn into_ident(self, span: Span) -> Ident {
20719        Ident {
20720            value: self.value,
20721            quote_style: self.quote_style,
20722            span,
20723        }
20724    }
20725}
20726
20727#[cfg(test)]
20728mod tests {
20729    use crate::test_utils::{all_dialects, TestedDialects};
20730
20731    use super::*;
20732
20733    #[test]
20734    fn test_prev_index() {
20735        let sql = "SELECT version";
20736        all_dialects().run_parser_method(sql, |parser| {
20737            assert_eq!(parser.peek_token(), Token::make_keyword("SELECT"));
20738            assert_eq!(parser.next_token(), Token::make_keyword("SELECT"));
20739            parser.prev_token();
20740            assert_eq!(parser.next_token(), Token::make_keyword("SELECT"));
20741            assert_eq!(parser.next_token(), Token::make_word("version", None));
20742            parser.prev_token();
20743            assert_eq!(parser.peek_token(), Token::make_word("version", None));
20744            assert_eq!(parser.next_token(), Token::make_word("version", None));
20745            assert_eq!(parser.peek_token(), Token::EOF);
20746            parser.prev_token();
20747            assert_eq!(parser.next_token(), Token::make_word("version", None));
20748            assert_eq!(parser.next_token(), Token::EOF);
20749            assert_eq!(parser.next_token(), Token::EOF);
20750            parser.prev_token();
20751        });
20752    }
20753
20754    #[test]
20755    fn test_peek_tokens() {
20756        all_dialects().run_parser_method("SELECT foo AS bar FROM baz", |parser| {
20757            assert!(matches!(
20758                parser.peek_tokens(),
20759                [Token::Word(Word {
20760                    keyword: Keyword::SELECT,
20761                    ..
20762                })]
20763            ));
20764
20765            assert!(matches!(
20766                parser.peek_tokens(),
20767                [
20768                    Token::Word(Word {
20769                        keyword: Keyword::SELECT,
20770                        ..
20771                    }),
20772                    Token::Word(_),
20773                    Token::Word(Word {
20774                        keyword: Keyword::AS,
20775                        ..
20776                    }),
20777                ]
20778            ));
20779
20780            for _ in 0..4 {
20781                parser.next_token();
20782            }
20783
20784            assert!(matches!(
20785                parser.peek_tokens(),
20786                [
20787                    Token::Word(Word {
20788                        keyword: Keyword::FROM,
20789                        ..
20790                    }),
20791                    Token::Word(_),
20792                    Token::EOF,
20793                    Token::EOF,
20794                ]
20795            ))
20796        })
20797    }
20798
20799    #[cfg(test)]
20800    mod test_parse_data_type {
20801        use crate::ast::{
20802            CharLengthUnits, CharacterLength, DataType, ExactNumberInfo, ObjectName, TimezoneInfo,
20803        };
20804        use crate::dialect::{AnsiDialect, GenericDialect, PostgreSqlDialect};
20805        use crate::test_utils::TestedDialects;
20806
20807        macro_rules! test_parse_data_type {
20808            ($dialect:expr, $input:expr, $expected_type:expr $(,)?) => {{
20809                $dialect.run_parser_method(&*$input, |parser| {
20810                    let data_type = parser.parse_data_type().unwrap();
20811                    assert_eq!($expected_type, data_type);
20812                    assert_eq!($input.to_string(), data_type.to_string());
20813                });
20814            }};
20815        }
20816
20817        #[test]
20818        fn test_ansii_character_string_types() {
20819            // Character string types: <https://jakewheat.github.io/sql-overview/sql-2016-foundation-grammar.html#character-string-type>
20820            let dialect =
20821                TestedDialects::new(vec![Box::new(GenericDialect {}), Box::new(AnsiDialect {})]);
20822
20823            test_parse_data_type!(dialect, "CHARACTER", DataType::Character(None));
20824
20825            test_parse_data_type!(
20826                dialect,
20827                "CHARACTER(20)",
20828                DataType::Character(Some(CharacterLength::IntegerLength {
20829                    length: 20,
20830                    unit: None
20831                }))
20832            );
20833
20834            test_parse_data_type!(
20835                dialect,
20836                "CHARACTER(20 CHARACTERS)",
20837                DataType::Character(Some(CharacterLength::IntegerLength {
20838                    length: 20,
20839                    unit: Some(CharLengthUnits::Characters)
20840                }))
20841            );
20842
20843            test_parse_data_type!(
20844                dialect,
20845                "CHARACTER(20 OCTETS)",
20846                DataType::Character(Some(CharacterLength::IntegerLength {
20847                    length: 20,
20848                    unit: Some(CharLengthUnits::Octets)
20849                }))
20850            );
20851
20852            test_parse_data_type!(dialect, "CHAR", DataType::Char(None));
20853
20854            test_parse_data_type!(
20855                dialect,
20856                "CHAR(20)",
20857                DataType::Char(Some(CharacterLength::IntegerLength {
20858                    length: 20,
20859                    unit: None
20860                }))
20861            );
20862
20863            test_parse_data_type!(
20864                dialect,
20865                "CHAR(20 CHARACTERS)",
20866                DataType::Char(Some(CharacterLength::IntegerLength {
20867                    length: 20,
20868                    unit: Some(CharLengthUnits::Characters)
20869                }))
20870            );
20871
20872            test_parse_data_type!(
20873                dialect,
20874                "CHAR(20 OCTETS)",
20875                DataType::Char(Some(CharacterLength::IntegerLength {
20876                    length: 20,
20877                    unit: Some(CharLengthUnits::Octets)
20878                }))
20879            );
20880
20881            test_parse_data_type!(
20882                dialect,
20883                "CHARACTER VARYING(20)",
20884                DataType::CharacterVarying(Some(CharacterLength::IntegerLength {
20885                    length: 20,
20886                    unit: None
20887                }))
20888            );
20889
20890            test_parse_data_type!(
20891                dialect,
20892                "CHARACTER VARYING(20 CHARACTERS)",
20893                DataType::CharacterVarying(Some(CharacterLength::IntegerLength {
20894                    length: 20,
20895                    unit: Some(CharLengthUnits::Characters)
20896                }))
20897            );
20898
20899            test_parse_data_type!(
20900                dialect,
20901                "CHARACTER VARYING(20 OCTETS)",
20902                DataType::CharacterVarying(Some(CharacterLength::IntegerLength {
20903                    length: 20,
20904                    unit: Some(CharLengthUnits::Octets)
20905                }))
20906            );
20907
20908            test_parse_data_type!(
20909                dialect,
20910                "CHAR VARYING(20)",
20911                DataType::CharVarying(Some(CharacterLength::IntegerLength {
20912                    length: 20,
20913                    unit: None
20914                }))
20915            );
20916
20917            test_parse_data_type!(
20918                dialect,
20919                "CHAR VARYING(20 CHARACTERS)",
20920                DataType::CharVarying(Some(CharacterLength::IntegerLength {
20921                    length: 20,
20922                    unit: Some(CharLengthUnits::Characters)
20923                }))
20924            );
20925
20926            test_parse_data_type!(
20927                dialect,
20928                "CHAR VARYING(20 OCTETS)",
20929                DataType::CharVarying(Some(CharacterLength::IntegerLength {
20930                    length: 20,
20931                    unit: Some(CharLengthUnits::Octets)
20932                }))
20933            );
20934
20935            test_parse_data_type!(
20936                dialect,
20937                "VARCHAR(20)",
20938                DataType::Varchar(Some(CharacterLength::IntegerLength {
20939                    length: 20,
20940                    unit: None
20941                }))
20942            );
20943        }
20944
20945        #[test]
20946        fn test_ansii_character_large_object_types() {
20947            // Character large object types: <https://jakewheat.github.io/sql-overview/sql-2016-foundation-grammar.html#character-large-object-length>
20948            let dialect =
20949                TestedDialects::new(vec![Box::new(GenericDialect {}), Box::new(AnsiDialect {})]);
20950
20951            test_parse_data_type!(
20952                dialect,
20953                "CHARACTER LARGE OBJECT",
20954                DataType::CharacterLargeObject(None)
20955            );
20956            test_parse_data_type!(
20957                dialect,
20958                "CHARACTER LARGE OBJECT(20)",
20959                DataType::CharacterLargeObject(Some(20))
20960            );
20961
20962            test_parse_data_type!(
20963                dialect,
20964                "CHAR LARGE OBJECT",
20965                DataType::CharLargeObject(None)
20966            );
20967            test_parse_data_type!(
20968                dialect,
20969                "CHAR LARGE OBJECT(20)",
20970                DataType::CharLargeObject(Some(20))
20971            );
20972
20973            test_parse_data_type!(dialect, "CLOB", DataType::Clob(None));
20974            test_parse_data_type!(dialect, "CLOB(20)", DataType::Clob(Some(20)));
20975        }
20976
20977        #[test]
20978        fn test_parse_custom_types() {
20979            let dialect =
20980                TestedDialects::new(vec![Box::new(GenericDialect {}), Box::new(AnsiDialect {})]);
20981
20982            test_parse_data_type!(
20983                dialect,
20984                "GEOMETRY",
20985                DataType::Custom(ObjectName::from(vec!["GEOMETRY".into()]), vec![])
20986            );
20987
20988            test_parse_data_type!(
20989                dialect,
20990                "GEOMETRY(POINT)",
20991                DataType::Custom(
20992                    ObjectName::from(vec!["GEOMETRY".into()]),
20993                    vec!["POINT".to_string()]
20994                )
20995            );
20996
20997            test_parse_data_type!(
20998                dialect,
20999                "GEOMETRY(POINT, 4326)",
21000                DataType::Custom(
21001                    ObjectName::from(vec!["GEOMETRY".into()]),
21002                    vec!["POINT".to_string(), "4326".to_string()]
21003                )
21004            );
21005        }
21006
21007        #[test]
21008        fn test_ansii_exact_numeric_types() {
21009            // Exact numeric types: <https://jakewheat.github.io/sql-overview/sql-2016-foundation-grammar.html#exact-numeric-type>
21010            let dialect = TestedDialects::new(vec![
21011                Box::new(GenericDialect {}),
21012                Box::new(AnsiDialect {}),
21013                Box::new(PostgreSqlDialect {}),
21014            ]);
21015
21016            test_parse_data_type!(dialect, "NUMERIC", DataType::Numeric(ExactNumberInfo::None));
21017
21018            test_parse_data_type!(
21019                dialect,
21020                "NUMERIC(2)",
21021                DataType::Numeric(ExactNumberInfo::Precision(2))
21022            );
21023
21024            test_parse_data_type!(
21025                dialect,
21026                "NUMERIC(2,10)",
21027                DataType::Numeric(ExactNumberInfo::PrecisionAndScale(2, 10))
21028            );
21029
21030            test_parse_data_type!(dialect, "DECIMAL", DataType::Decimal(ExactNumberInfo::None));
21031
21032            test_parse_data_type!(
21033                dialect,
21034                "DECIMAL(2)",
21035                DataType::Decimal(ExactNumberInfo::Precision(2))
21036            );
21037
21038            test_parse_data_type!(
21039                dialect,
21040                "DECIMAL(2,10)",
21041                DataType::Decimal(ExactNumberInfo::PrecisionAndScale(2, 10))
21042            );
21043
21044            test_parse_data_type!(dialect, "DEC", DataType::Dec(ExactNumberInfo::None));
21045
21046            test_parse_data_type!(
21047                dialect,
21048                "DEC(2)",
21049                DataType::Dec(ExactNumberInfo::Precision(2))
21050            );
21051
21052            test_parse_data_type!(
21053                dialect,
21054                "DEC(2,10)",
21055                DataType::Dec(ExactNumberInfo::PrecisionAndScale(2, 10))
21056            );
21057
21058            // Test negative scale values.
21059            test_parse_data_type!(
21060                dialect,
21061                "NUMERIC(10,-2)",
21062                DataType::Numeric(ExactNumberInfo::PrecisionAndScale(10, -2))
21063            );
21064
21065            test_parse_data_type!(
21066                dialect,
21067                "DECIMAL(1000,-10)",
21068                DataType::Decimal(ExactNumberInfo::PrecisionAndScale(1000, -10))
21069            );
21070
21071            test_parse_data_type!(
21072                dialect,
21073                "DEC(5,-1000)",
21074                DataType::Dec(ExactNumberInfo::PrecisionAndScale(5, -1000))
21075            );
21076
21077            test_parse_data_type!(
21078                dialect,
21079                "NUMERIC(10,-5)",
21080                DataType::Numeric(ExactNumberInfo::PrecisionAndScale(10, -5))
21081            );
21082
21083            test_parse_data_type!(
21084                dialect,
21085                "DECIMAL(20,-10)",
21086                DataType::Decimal(ExactNumberInfo::PrecisionAndScale(20, -10))
21087            );
21088
21089            test_parse_data_type!(
21090                dialect,
21091                "DEC(5,-2)",
21092                DataType::Dec(ExactNumberInfo::PrecisionAndScale(5, -2))
21093            );
21094
21095            dialect.run_parser_method("NUMERIC(10,+5)", |parser| {
21096                let data_type = parser.parse_data_type().unwrap();
21097                assert_eq!(
21098                    DataType::Numeric(ExactNumberInfo::PrecisionAndScale(10, 5)),
21099                    data_type
21100                );
21101                // Note: Explicit '+' sign is not preserved in output, which is correct
21102                assert_eq!("NUMERIC(10,5)", data_type.to_string());
21103            });
21104        }
21105
21106        #[test]
21107        fn test_ansii_date_type() {
21108            // Datetime types: <https://jakewheat.github.io/sql-overview/sql-2016-foundation-grammar.html#datetime-type>
21109            let dialect =
21110                TestedDialects::new(vec![Box::new(GenericDialect {}), Box::new(AnsiDialect {})]);
21111
21112            test_parse_data_type!(dialect, "DATE", DataType::Date);
21113
21114            test_parse_data_type!(dialect, "TIME", DataType::Time(None, TimezoneInfo::None));
21115
21116            test_parse_data_type!(
21117                dialect,
21118                "TIME(6)",
21119                DataType::Time(Some(6), TimezoneInfo::None)
21120            );
21121
21122            test_parse_data_type!(
21123                dialect,
21124                "TIME WITH TIME ZONE",
21125                DataType::Time(None, TimezoneInfo::WithTimeZone)
21126            );
21127
21128            test_parse_data_type!(
21129                dialect,
21130                "TIME(6) WITH TIME ZONE",
21131                DataType::Time(Some(6), TimezoneInfo::WithTimeZone)
21132            );
21133
21134            test_parse_data_type!(
21135                dialect,
21136                "TIME WITHOUT TIME ZONE",
21137                DataType::Time(None, TimezoneInfo::WithoutTimeZone)
21138            );
21139
21140            test_parse_data_type!(
21141                dialect,
21142                "TIME(6) WITHOUT TIME ZONE",
21143                DataType::Time(Some(6), TimezoneInfo::WithoutTimeZone)
21144            );
21145
21146            test_parse_data_type!(
21147                dialect,
21148                "TIMESTAMP",
21149                DataType::Timestamp(None, TimezoneInfo::None)
21150            );
21151
21152            test_parse_data_type!(
21153                dialect,
21154                "TIMESTAMP(22)",
21155                DataType::Timestamp(Some(22), TimezoneInfo::None)
21156            );
21157
21158            test_parse_data_type!(
21159                dialect,
21160                "TIMESTAMP(22) WITH TIME ZONE",
21161                DataType::Timestamp(Some(22), TimezoneInfo::WithTimeZone)
21162            );
21163
21164            test_parse_data_type!(
21165                dialect,
21166                "TIMESTAMP(33) WITHOUT TIME ZONE",
21167                DataType::Timestamp(Some(33), TimezoneInfo::WithoutTimeZone)
21168            );
21169        }
21170    }
21171
21172    #[test]
21173    fn test_parse_schema_name() {
21174        // The expected name should be identical as the input name, that's why I don't receive both
21175        macro_rules! test_parse_schema_name {
21176            ($input:expr, $expected_name:expr $(,)?) => {{
21177                all_dialects().run_parser_method(&*$input, |parser| {
21178                    let schema_name = parser.parse_schema_name().unwrap();
21179                    // Validate that the structure is the same as expected
21180                    assert_eq!(schema_name, $expected_name);
21181                    // Validate that the input and the expected structure serialization are the same
21182                    assert_eq!(schema_name.to_string(), $input.to_string());
21183                });
21184            }};
21185        }
21186
21187        let dummy_name = ObjectName::from(vec![Ident::new("dummy_name")]);
21188        let dummy_authorization = Ident::new("dummy_authorization");
21189
21190        test_parse_schema_name!(
21191            format!("{dummy_name}"),
21192            SchemaName::Simple(dummy_name.clone())
21193        );
21194
21195        test_parse_schema_name!(
21196            format!("AUTHORIZATION {dummy_authorization}"),
21197            SchemaName::UnnamedAuthorization(dummy_authorization.clone()),
21198        );
21199        test_parse_schema_name!(
21200            format!("{dummy_name} AUTHORIZATION {dummy_authorization}"),
21201            SchemaName::NamedAuthorization(dummy_name.clone(), dummy_authorization.clone()),
21202        );
21203    }
21204
21205    #[test]
21206    fn mysql_parse_index_table_constraint() {
21207        macro_rules! test_parse_table_constraint {
21208            ($dialect:expr, $input:expr, $expected:expr $(,)?) => {{
21209                $dialect.run_parser_method(&*$input, |parser| {
21210                    let constraint = parser.parse_optional_table_constraint().unwrap().unwrap();
21211                    // Validate that the structure is the same as expected
21212                    assert_eq!(constraint, $expected);
21213                    // Validate that the input and the expected structure serialization are the same
21214                    assert_eq!(constraint.to_string(), $input.to_string());
21215                });
21216            }};
21217        }
21218
21219        fn mk_expected_col(name: &str) -> IndexColumn {
21220            IndexColumn {
21221                column: OrderByExpr {
21222                    expr: Expr::Identifier(name.into()),
21223                    options: OrderByOptions {
21224                        sort: None,
21225                        nulls_first: None,
21226                    },
21227                    with_fill: None,
21228                },
21229                operator_class: None,
21230            }
21231        }
21232
21233        let dialect =
21234            TestedDialects::new(vec![Box::new(GenericDialect {}), Box::new(MySqlDialect {})]);
21235
21236        test_parse_table_constraint!(
21237            dialect,
21238            "INDEX (c1)",
21239            IndexConstraint {
21240                display_as_key: false,
21241                name: None,
21242                index_type: None,
21243                columns: vec![mk_expected_col("c1")],
21244                index_options: vec![],
21245            }
21246            .into()
21247        );
21248
21249        test_parse_table_constraint!(
21250            dialect,
21251            "KEY (c1)",
21252            IndexConstraint {
21253                display_as_key: true,
21254                name: None,
21255                index_type: None,
21256                columns: vec![mk_expected_col("c1")],
21257                index_options: vec![],
21258            }
21259            .into()
21260        );
21261
21262        test_parse_table_constraint!(
21263            dialect,
21264            "INDEX 'index' (c1, c2)",
21265            TableConstraint::Index(IndexConstraint {
21266                display_as_key: false,
21267                name: Some(Ident::with_quote('\'', "index")),
21268                index_type: None,
21269                columns: vec![mk_expected_col("c1"), mk_expected_col("c2")],
21270                index_options: vec![],
21271            })
21272        );
21273
21274        test_parse_table_constraint!(
21275            dialect,
21276            "INDEX USING BTREE (c1)",
21277            IndexConstraint {
21278                display_as_key: false,
21279                name: None,
21280                index_type: Some(IndexType::BTree),
21281                columns: vec![mk_expected_col("c1")],
21282                index_options: vec![],
21283            }
21284            .into()
21285        );
21286
21287        test_parse_table_constraint!(
21288            dialect,
21289            "INDEX USING HASH (c1)",
21290            IndexConstraint {
21291                display_as_key: false,
21292                name: None,
21293                index_type: Some(IndexType::Hash),
21294                columns: vec![mk_expected_col("c1")],
21295                index_options: vec![],
21296            }
21297            .into()
21298        );
21299
21300        test_parse_table_constraint!(
21301            dialect,
21302            "INDEX idx_name USING BTREE (c1)",
21303            IndexConstraint {
21304                display_as_key: false,
21305                name: Some(Ident::new("idx_name")),
21306                index_type: Some(IndexType::BTree),
21307                columns: vec![mk_expected_col("c1")],
21308                index_options: vec![],
21309            }
21310            .into()
21311        );
21312
21313        test_parse_table_constraint!(
21314            dialect,
21315            "INDEX idx_name USING HASH (c1)",
21316            IndexConstraint {
21317                display_as_key: false,
21318                name: Some(Ident::new("idx_name")),
21319                index_type: Some(IndexType::Hash),
21320                columns: vec![mk_expected_col("c1")],
21321                index_options: vec![],
21322            }
21323            .into()
21324        );
21325    }
21326
21327    #[test]
21328    fn test_tokenizer_error_loc() {
21329        let sql = "foo '";
21330        let ast = Parser::parse_sql(&GenericDialect, sql);
21331        assert_eq!(
21332            ast,
21333            Err(ParserError::TokenizerError(
21334                "Unterminated string literal at Line: 1, Column: 5".to_string()
21335            ))
21336        );
21337    }
21338
21339    #[test]
21340    fn test_parser_error_loc() {
21341        let sql = "SELECT this is a syntax error";
21342        let ast = Parser::parse_sql(&GenericDialect, sql);
21343        assert_eq!(
21344            ast,
21345            Err(ParserError::ParserError(
21346                "Expected: [NOT] NULL | TRUE | FALSE | DISTINCT | [form] NORMALIZED FROM after IS, found: a at Line: 1, Column: 16"
21347                    .to_string()
21348            ))
21349        );
21350    }
21351
21352    #[test]
21353    fn test_nested_explain_error() {
21354        let sql = "EXPLAIN EXPLAIN SELECT 1";
21355        let ast = Parser::parse_sql(&GenericDialect, sql);
21356        assert_eq!(
21357            ast,
21358            Err(ParserError::ParserError(
21359                "Explain must be root of the plan".to_string()
21360            ))
21361        );
21362    }
21363
21364    #[test]
21365    fn test_parse_multipart_identifier_positive() {
21366        let dialect = TestedDialects::new(vec![Box::new(GenericDialect {})]);
21367
21368        // parse multipart with quotes
21369        let expected = vec![
21370            Ident {
21371                value: "CATALOG".to_string(),
21372                quote_style: None,
21373                span: Span::empty(),
21374            },
21375            Ident {
21376                value: "F(o)o. \"bar".to_string(),
21377                quote_style: Some('"'),
21378                span: Span::empty(),
21379            },
21380            Ident {
21381                value: "table".to_string(),
21382                quote_style: None,
21383                span: Span::empty(),
21384            },
21385        ];
21386        dialect.run_parser_method(r#"CATALOG."F(o)o. ""bar".table"#, |parser| {
21387            let actual = parser.parse_multipart_identifier().unwrap();
21388            assert_eq!(expected, actual);
21389        });
21390
21391        // allow whitespace between ident parts
21392        let expected = vec![
21393            Ident {
21394                value: "CATALOG".to_string(),
21395                quote_style: None,
21396                span: Span::empty(),
21397            },
21398            Ident {
21399                value: "table".to_string(),
21400                quote_style: None,
21401                span: Span::empty(),
21402            },
21403        ];
21404        dialect.run_parser_method("CATALOG . table", |parser| {
21405            let actual = parser.parse_multipart_identifier().unwrap();
21406            assert_eq!(expected, actual);
21407        });
21408    }
21409
21410    #[test]
21411    fn test_parse_multipart_identifier_negative() {
21412        macro_rules! test_parse_multipart_identifier_error {
21413            ($input:expr, $expected_err:expr $(,)?) => {{
21414                all_dialects().run_parser_method(&*$input, |parser| {
21415                    let actual_err = parser.parse_multipart_identifier().unwrap_err();
21416                    assert_eq!(actual_err.to_string(), $expected_err);
21417                });
21418            }};
21419        }
21420
21421        test_parse_multipart_identifier_error!(
21422            "",
21423            "sql parser error: Empty input when parsing identifier",
21424        );
21425
21426        test_parse_multipart_identifier_error!(
21427            "*schema.table",
21428            "sql parser error: Unexpected token in identifier: *",
21429        );
21430
21431        test_parse_multipart_identifier_error!(
21432            "schema.table*",
21433            "sql parser error: Unexpected token in identifier: *",
21434        );
21435
21436        test_parse_multipart_identifier_error!(
21437            "schema.table.",
21438            "sql parser error: Trailing period in identifier",
21439        );
21440
21441        test_parse_multipart_identifier_error!(
21442            "schema.*",
21443            "sql parser error: Unexpected token following period in identifier: *",
21444        );
21445    }
21446
21447    #[test]
21448    fn test_mysql_partition_selection() {
21449        let sql = "SELECT * FROM employees PARTITION (p0, p2)";
21450        let expected = vec!["p0", "p2"];
21451
21452        let ast: Vec<Statement> = Parser::parse_sql(&MySqlDialect {}, sql).unwrap();
21453        assert_eq!(ast.len(), 1);
21454        if let Statement::Query(v) = &ast[0] {
21455            if let SetExpr::Select(select) = &*v.body {
21456                assert_eq!(select.from.len(), 1);
21457                let from: &TableWithJoins = &select.from[0];
21458                let table_factor = &from.relation;
21459                if let TableFactor::Table { partitions, .. } = table_factor {
21460                    let actual: Vec<&str> = partitions
21461                        .iter()
21462                        .map(|ident| ident.value.as_str())
21463                        .collect();
21464                    assert_eq!(expected, actual);
21465                }
21466            }
21467        } else {
21468            panic!("fail to parse mysql partition selection");
21469        }
21470    }
21471
21472    #[test]
21473    fn test_replace_into_placeholders() {
21474        let sql = "REPLACE INTO t (a) VALUES (&a)";
21475
21476        assert!(Parser::parse_sql(&GenericDialect {}, sql).is_err());
21477    }
21478
21479    #[test]
21480    fn test_replace_into_set_placeholder() {
21481        let sql = "REPLACE INTO t SET ?";
21482
21483        assert!(Parser::parse_sql(&GenericDialect {}, sql).is_err());
21484    }
21485
21486    #[test]
21487    fn test_replace_incomplete() {
21488        let sql = r#"REPLACE"#;
21489
21490        assert!(Parser::parse_sql(&MySqlDialect {}, sql).is_err());
21491    }
21492
21493    #[test]
21494    fn test_placeholder_invalid_whitespace() {
21495        for w in ["  ", "/*invalid*/"] {
21496            let sql = format!("\nSELECT\n  :{w}fooBar");
21497            assert!(Parser::parse_sql(&GenericDialect, &sql).is_err());
21498        }
21499    }
21500}