mod ffi;
mod util;

extern crate regex;
extern crate serde;
extern crate serde_derive;
extern crate serde_json;

#[cfg(unix)]
use std::os::unix::io::AsRawFd;

use std::ffi::CStr;
use std::marker::PhantomData;
use std::mem::MaybeUninit;
use std::os::raw::{c_char, c_void};
use std::ptr::NonNull;
use std::sync::atomic::AtomicUsize;
use std::{char, fmt, iter, ptr, slice, str, u16};

/// The latest ABI version that is supported by the current version of the
/// library.
///
/// When Languages are generated by the Tree-sitter CLI, they are
/// assigned an ABI version number that corresponds to the current CLI version.
/// The Tree-sitter library is generally backwards-compatible with languages
/// generated using older CLI versions, but is not forwards-compatible.
pub const LANGUAGE_VERSION: usize = ffi::TREE_SITTER_LANGUAGE_VERSION;

/// The earliest ABI version that is supported by the current version of the
/// library.
pub const MIN_COMPATIBLE_LANGUAGE_VERSION: usize = ffi::TREE_SITTER_MIN_COMPATIBLE_LANGUAGE_VERSION;

pub const PARSER_HEADER: &'static str = include_str!("../include/tree_sitter/parser.h");

/// An opaque object that defines how to parse a particular language. The code for each
/// `Language` is generated by the Tree-sitter CLI.
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
#[repr(transparent)]
pub struct Language(*const ffi::TSLanguage);

/// A tree that represents the syntactic structure of a source code file.
pub struct Tree(NonNull<ffi::TSTree>);

/// A position in a multi-line text document, in terms of rows and columns.
///
/// Rows and columns are zero-based.
#[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord)]
pub struct Point {
    pub row: usize,
    pub column: usize,
}

/// A range of positions in a multi-line text document, both in terms of bytes and of
/// rows and columns.
#[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord)]
pub struct Range {
    pub start_byte: usize,
    pub end_byte: usize,
    pub start_point: Point,
    pub end_point: Point,
}

/// A summary of a change to a text document.
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub struct InputEdit {
    pub start_byte: usize,
    pub old_end_byte: usize,
    pub new_end_byte: usize,
    pub start_position: Point,
    pub old_end_position: Point,
    pub new_end_position: Point,
}

/// A single node within a syntax `Tree`.
#[derive(Clone, Copy)]
#[repr(transparent)]
pub struct Node<'a>(ffi::TSNode, PhantomData<&'a ()>);

/// A stateful object that this is used to produce a `Tree` based on some source code.
pub struct Parser(NonNull<ffi::TSParser>);

/// A type of log message.
#[derive(Debug, PartialEq, Eq)]
pub enum LogType {
    Parse,
    Lex,
}

/// A callback that receives log messages during parser.
type Logger<'a> = Box<dyn FnMut(LogType, &str) + 'a>;

/// A stateful object for walking a syntax `Tree` efficiently.
pub struct TreeCursor<'a>(ffi::TSTreeCursor, PhantomData<&'a ()>);

/// A set of patterns that match nodes in a syntax tree.
#[derive(Debug)]
pub struct Query {
    ptr: NonNull<ffi::TSQuery>,
    capture_names: Vec<String>,
    text_predicates: Vec<Box<[TextPredicate]>>,
    property_settings: Vec<Box<[QueryProperty]>>,
    property_predicates: Vec<Box<[(QueryProperty, bool)]>>,
}

/// A stateful object for executing a `Query` on a syntax `Tree`.
pub struct QueryCursor(NonNull<ffi::TSQueryCursor>);

/// A key-value pair associated with a particular pattern in a `Query`.
#[derive(Debug, PartialEq, Eq)]
pub struct QueryProperty {
    pub key: Box<str>,
    pub value: Option<Box<str>>,
    pub capture_id: Option<usize>,
}

/// A match of a `Query` to a particular set of `Node`s.
pub struct QueryMatch<'a> {
    pub pattern_index: usize,
    pub captures: &'a [QueryCapture<'a>],
    id: u32,
    cursor: *mut ffi::TSQueryCursor,
}

/// A sequence of `QueryCapture`s within a `QueryMatch`.
pub struct QueryCaptures<'a, T: AsRef<[u8]>> {
    ptr: *mut ffi::TSQueryCursor,
    query: &'a Query,
    text_callback: Box<dyn FnMut(Node<'a>) -> T + 'a>,
}

/// A particular `Node` that has been captured with a particular name within a `Query`.
#[derive(Clone, Copy)]
#[repr(C)]
pub struct QueryCapture<'a> {
    pub node: Node<'a>,
    pub index: u32,
}

/// An error that occurred when trying to assign an incompatible `Language` to a `Parser`.
#[derive(Debug, PartialEq, Eq)]
pub struct LanguageError {
    version: usize,
}

/// An error that occurred when trying to create a `Query`.
#[derive(Debug, PartialEq, Eq)]
pub enum QueryError {
    Syntax(usize, String),
    NodeType(usize, String),
    Field(usize, String),
    Capture(usize, String),
    Predicate(String),
}

#[derive(Debug)]
enum TextPredicate {
    CaptureEqString(u32, String),
    CaptureEqCapture(u32, u32),
    CaptureMatchString(u32, regex::bytes::Regex),
}

impl Language {
    /// Get the ABI version number that indicates which version of the Tree-sitter CLI
    /// that was used to generate this `Language`.
    pub fn version(&self) -> usize {
        unsafe { ffi::ts_language_version(self.0) as usize }
    }

    /// Get the number of distinct node types in this language.
    pub fn node_kind_count(&self) -> usize {
        unsafe { ffi::ts_language_symbol_count(self.0) as usize }
    }

    /// Get the name of the node kind for the given numerical id.
    pub fn node_kind_for_id(&self, id: u16) -> &'static str {
        unsafe { CStr::from_ptr(ffi::ts_language_symbol_name(self.0, id)) }
            .to_str()
            .unwrap()
    }

    /// Check if the node type for the given numerical id is named (as opposed
    /// to an anonymous node type).
    pub fn node_kind_is_named(&self, id: u16) -> bool {
        unsafe { ffi::ts_language_symbol_type(self.0, id) == ffi::TSSymbolType_TSSymbolTypeRegular }
    }

    /// Get the number of distinct field names in this language.
    pub fn field_count(&self) -> usize {
        unsafe { ffi::ts_language_field_count(self.0) as usize }
    }

    /// Get the field names for the given numerical id.
    pub fn field_name_for_id(&self, field_id: u16) -> &'static str {
        unsafe { CStr::from_ptr(ffi::ts_language_field_name_for_id(self.0, field_id)) }
            .to_str()
            .unwrap()
    }

    /// Get the numerical id for the given field name.
    pub fn field_id_for_name(&self, field_name: impl AsRef<[u8]>) -> Option<u16> {
        let field_name = field_name.as_ref();
        let id = unsafe {
            ffi::ts_language_field_id_for_name(
                self.0,
                field_name.as_ptr() as *const c_char,
                field_name.len() as u32,
            )
        };
        if id == 0 {
            None
        } else {
            Some(id)
        }
    }
}

impl fmt::Display for LanguageError {
    fn fmt(&self, f: &mut fmt::Formatter) -> Result<(), fmt::Error> {
        write!(
            f,
            "Incompatible language version {}. Expected minimum {}, maximum {}",
            self.version, MIN_COMPATIBLE_LANGUAGE_VERSION, LANGUAGE_VERSION,
        )
    }
}

impl Parser {
    /// Create a new parser.
    pub fn new() -> Parser {
        unsafe {
            let parser = ffi::ts_parser_new();
            Parser(NonNull::new_unchecked(parser))
        }
    }

    /// Set the language that the parser should use for parsing.
    ///
    /// Returns a Result indicating whether or not the language was successfully
    /// assigned. True means assignment succeeded. False means there was a version
    /// mismatch: the language was generated with an incompatible version of the
    /// Tree-sitter CLI. Check the language's version using [Language::version]
    /// and compare it to this library's [LANGUAGE_VERSION](LANGUAGE_VERSION) and
    /// [MIN_COMPATIBLE_LANGUAGE_VERSION](MIN_COMPATIBLE_LANGUAGE_VERSION) constants.
    pub fn set_language(&mut self, language: Language) -> Result<(), LanguageError> {
        let version = language.version();
        if version < MIN_COMPATIBLE_LANGUAGE_VERSION || version > LANGUAGE_VERSION {
            Err(LanguageError { version })
        } else {
            unsafe {
                ffi::ts_parser_set_language(self.0.as_ptr(), language.0);
            }
            Ok(())
        }
    }

    /// Get the parser's current language.
    pub fn language(&self) -> Option<Language> {
        let ptr = unsafe { ffi::ts_parser_language(self.0.as_ptr()) };
        if ptr.is_null() {
            None
        } else {
            Some(Language(ptr))
        }
    }

    /// Get the parser's current logger.
    pub fn logger(&self) -> Option<&Logger> {
        let logger = unsafe { ffi::ts_parser_logger(self.0.as_ptr()) };
        unsafe { (logger.payload as *mut Logger).as_ref() }
    }

    /// Set the logging callback that a parser should use during parsing.
    pub fn set_logger(&mut self, logger: Option<Logger>) {
        let prev_logger = unsafe { ffi::ts_parser_logger(self.0.as_ptr()) };
        if !prev_logger.payload.is_null() {
            drop(unsafe { Box::from_raw(prev_logger.payload as *mut Logger) });
        }

        let c_logger;
        if let Some(logger) = logger {
            let container = Box::new(logger);

            unsafe extern "C" fn log(
                payload: *mut c_void,
                c_log_type: ffi::TSLogType,
                c_message: *const c_char,
            ) {
                let callback = (payload as *mut Logger).as_mut().unwrap();
                if let Ok(message) = CStr::from_ptr(c_message).to_str() {
                    let log_type = if c_log_type == ffi::TSLogType_TSLogTypeParse {
                        LogType::Parse
                    } else {
                        LogType::Lex
                    };
                    callback(log_type, message);
                }
            };

            let raw_container = Box::into_raw(container);

            c_logger = ffi::TSLogger {
                payload: raw_container as *mut c_void,
                log: Some(log),
            };
        } else {
            c_logger = ffi::TSLogger {
                payload: ptr::null_mut(),
                log: None,
            };
        }

        unsafe { ffi::ts_parser_set_logger(self.0.as_ptr(), c_logger) };
    }

    /// Set the destination to which the parser should write debugging graphs
    /// during parsing. The graphs are formatted in the DOT language. You may want
    /// to pipe these graphs directly to a `dot(1)` process in order to generate
    /// SVG output.
    #[cfg(unix)]
    pub fn print_dot_graphs(&mut self, file: &impl AsRawFd) {
        let fd = file.as_raw_fd();
        unsafe { ffi::ts_parser_print_dot_graphs(self.0.as_ptr(), ffi::dup(fd)) }
    }

    /// Stop the parser from printing debugging graphs while parsing.
    pub fn stop_printing_dot_graphs(&mut self) {
        unsafe { ffi::ts_parser_print_dot_graphs(self.0.as_ptr(), -1) }
    }

    /// Parse a slice of UTF8 text.
    ///
    /// # Arguments:
    /// * `text` The UTF8-encoded text to parse.
    /// * `old_tree` A previous syntax tree parsed from the same document.
    ///   If the text of the document has changed since `old_tree` was
    ///   created, then you must edit `old_tree` to match the new text using
    ///   [Tree::edit].
    ///
    /// Returns a [Tree] if parsing succeeded, or `None` if:
    ///  * The parser has not yet had a language assigned with [Parser::set_language]
    ///  * The timeout set with [Parser::set_timeout_micros] expired
    ///  * The cancellation flag set with [Parser::set_cancellation_flag] was flipped
    pub fn parse(&mut self, text: impl AsRef<[u8]>, old_tree: Option<&Tree>) -> Option<Tree> {
        let bytes = text.as_ref();
        let len = bytes.len();
        self.parse_with(
            &mut |i, _| if i < len { &bytes[i..] } else { &[] },
            old_tree,
        )
    }

    /// Parse a slice of UTF16 text.
    ///
    /// # Arguments:
    /// * `text` The UTF16-encoded text to parse.
    /// * `old_tree` A previous syntax tree parsed from the same document.
    ///   If the text of the document has changed since `old_tree` was
    ///   created, then you must edit `old_tree` to match the new text using
    ///   [Tree::edit].
    pub fn parse_utf16(
        &mut self,
        input: impl AsRef<[u16]>,
        old_tree: Option<&Tree>,
    ) -> Option<Tree> {
        let code_points = input.as_ref();
        let len = code_points.len();
        self.parse_utf16_with(
            &mut |i, _| if i < len { &code_points[i..] } else { &[] },
            old_tree,
        )
    }

    /// Parse UTF8 text provided in chunks by a callback.
    ///
    /// # Arguments:
    /// * `callback` A function that takes a byte offset and position and
    ///   returns a slice of UTF8-encoded text starting at that byte offset
    ///   and position. The slices can be of any length. If the given position
    ///   is at the end of the text, the callback should return an empty slice.
    /// * `old_tree` A previous syntax tree parsed from the same document.
    ///   If the text of the document has changed since `old_tree` was
    ///   created, then you must edit `old_tree` to match the new text using
    ///   [Tree::edit].
    pub fn parse_with<'a, T: AsRef<[u8]>, F: FnMut(usize, Point) -> T>(
        &mut self,
        callback: &mut F,
        old_tree: Option<&Tree>,
    ) -> Option<Tree> {
        // A pointer to this payload is passed on every call to the `read` C function.
        // The payload contains two things:
        // 1. A reference to the rust `callback`.
        // 2. The text that was returned from the previous call to `callback`.
        //    This allows the callback to return owned values like vectors.
        let mut payload: (&mut F, Option<T>) = (callback, None);

        // This C function is passed to Tree-sitter as the input callback.
        unsafe extern "C" fn read<'a, T: AsRef<[u8]>, F: FnMut(usize, Point) -> T>(
            payload: *mut c_void,
            byte_offset: u32,
            position: ffi::TSPoint,
            bytes_read: *mut u32,
        ) -> *const c_char {
            let (callback, text) = (payload as *mut (&mut F, Option<T>)).as_mut().unwrap();
            *text = Some(callback(byte_offset as usize, position.into()));
            let slice = text.as_ref().unwrap().as_ref();
            *bytes_read = slice.len() as u32;
            return slice.as_ptr() as *const c_char;
        };

        let c_input = ffi::TSInput {
            payload: &mut payload as *mut (&mut F, Option<T>) as *mut c_void,
            read: Some(read::<T, F>),
            encoding: ffi::TSInputEncoding_TSInputEncodingUTF8,
        };

        let c_old_tree = old_tree.map_or(ptr::null_mut(), |t| t.0.as_ptr());
        unsafe {
            let c_new_tree = ffi::ts_parser_parse(self.0.as_ptr(), c_old_tree, c_input);
            NonNull::new(c_new_tree).map(Tree)
        }
    }

    /// Parse UTF16 text provided in chunks by a callback.
    ///
    /// # Arguments:
    /// * `callback` A function that takes a code point offset and position and
    ///   returns a slice of UTF16-encoded text starting at that byte offset
    ///   and position. The slices can be of any length. If the given position
    ///   is at the end of the text, the callback should return an empty slice.
    /// * `old_tree` A previous syntax tree parsed from the same document.
    ///   If the text of the document has changed since `old_tree` was
    ///   created, then you must edit `old_tree` to match the new text using
    ///   [Tree::edit].
    pub fn parse_utf16_with<'a, T: AsRef<[u16]>, F: FnMut(usize, Point) -> T>(
        &mut self,
        callback: &mut F,
        old_tree: Option<&Tree>,
    ) -> Option<Tree> {
        // A pointer to this payload is passed on every call to the `read` C function.
        // The payload contains two things:
        // 1. A reference to the rust `callback`.
        // 2. The text that was returned from the previous call to `callback`.
        //    This allows the callback to return owned values like vectors.
        let mut payload: (&mut F, Option<T>) = (callback, None);

        // This C function is passed to Tree-sitter as the input callback.
        unsafe extern "C" fn read<'a, T: AsRef<[u16]>, F: FnMut(usize, Point) -> T>(
            payload: *mut c_void,
            byte_offset: u32,
            position: ffi::TSPoint,
            bytes_read: *mut u32,
        ) -> *const c_char {
            let (callback, text) = (payload as *mut (&mut F, Option<T>)).as_mut().unwrap();
            *text = Some(callback(
                (byte_offset / 2) as usize,
                Point {
                    row: position.row as usize,
                    column: position.column as usize / 2,
                },
            ));
            let slice = text.as_ref().unwrap().as_ref();
            *bytes_read = slice.len() as u32 * 2;
            slice.as_ptr() as *const c_char
        };

        let c_input = ffi::TSInput {
            payload: &mut payload as *mut (&mut F, Option<T>) as *mut c_void,
            read: Some(read::<T, F>),
            encoding: ffi::TSInputEncoding_TSInputEncodingUTF16,
        };

        let c_old_tree = old_tree.map_or(ptr::null_mut(), |t| t.0.as_ptr());
        unsafe {
            let c_new_tree = ffi::ts_parser_parse(self.0.as_ptr(), c_old_tree, c_input);
            NonNull::new(c_new_tree).map(Tree)
        }
    }

    /// Instruct the parser to start the next parse from the beginning.
    ///
    /// If the parser previously failed because of a timeout or a cancellation, then
    /// by default, it will resume where it left off on the next call to `parse` or
    /// other parsing functions. If you don't want to resume, and instead intend to
    /// use this parser to parse some other document, you must call `reset` first.
    pub fn reset(&mut self) {
        unsafe { ffi::ts_parser_reset(self.0.as_ptr()) }
    }

    /// Get the duration in microseconds that parsing is allowed to take.
    ///
    /// This is set via [set_timeout_micros](Parser::set_timeout_micros).
    pub fn timeout_micros(&self) -> u64 {
        unsafe { ffi::ts_parser_timeout_micros(self.0.as_ptr()) }
    }

    /// Set the maximum duration in microseconds that parsing should be allowed to
    /// take before halting.
    ///
    /// If parsing takes longer than this, it will halt early, returning `None`.
    /// See `parse` for more information.
    pub fn set_timeout_micros(&mut self, timeout_micros: u64) {
        unsafe { ffi::ts_parser_set_timeout_micros(self.0.as_ptr(), timeout_micros) }
    }

    /// Set the ranges of text that the parser should include when parsing.
    ///
    /// By default, the parser will always include entire documents. This function
    /// allows you to parse only a *portion* of a document but still return a syntax
    /// tree whose ranges match up with the document as a whole. You can also pass
    /// multiple disjoint ranges.
    pub fn set_included_ranges(&mut self, ranges: &[Range]) {
        let ts_ranges: Vec<ffi::TSRange> =
            ranges.iter().cloned().map(|range| range.into()).collect();
        unsafe {
            ffi::ts_parser_set_included_ranges(
                self.0.as_ptr(),
                ts_ranges.as_ptr(),
                ts_ranges.len() as u32,
            )
        };
    }

    /// Get the parser's current cancellation flag pointer.
    pub unsafe fn cancellation_flag(&self) -> Option<&AtomicUsize> {
        (ffi::ts_parser_cancellation_flag(self.0.as_ptr()) as *const AtomicUsize).as_ref()
    }

    /// Set the parser's current cancellation flag pointer.
    ///
    /// If a pointer is assigned, then the parser will periodically read from
    /// this pointer during parsing. If it reads a non-zero value, it will halt early,
    /// returning `None`. See [parse](Parser::parse) for more information.
    pub unsafe fn set_cancellation_flag(&self, flag: Option<&AtomicUsize>) {
        if let Some(flag) = flag {
            ffi::ts_parser_set_cancellation_flag(
                self.0.as_ptr(),
                flag as *const AtomicUsize as *const usize,
            );
        } else {
            ffi::ts_parser_set_cancellation_flag(self.0.as_ptr(), ptr::null());
        }
    }
}

impl Drop for Parser {
    fn drop(&mut self) {
        self.stop_printing_dot_graphs();
        self.set_logger(None);
        unsafe { ffi::ts_parser_delete(self.0.as_ptr()) }
    }
}

impl Tree {
    /// Get the root node of the syntax tree.
    pub fn root_node(&self) -> Node {
        Node::new(unsafe { ffi::ts_tree_root_node(self.0.as_ptr()) }).unwrap()
    }

    /// Get the language that was used to parse the syntax tree.
    pub fn language(&self) -> Language {
        Language(unsafe { ffi::ts_tree_language(self.0.as_ptr()) })
    }

    /// Edit the syntax tree to keep it in sync with source code that has been
    /// edited.
    ///
    /// You must describe the edit both in terms of byte offsets and in terms of
    /// row/column coordinates.
    pub fn edit(&mut self, edit: &InputEdit) {
        let edit = edit.into();
        unsafe { ffi::ts_tree_edit(self.0.as_ptr(), &edit) };
    }

    /// Create a new [TreeCursor] starting from the root of the tree.
    pub fn walk(&self) -> TreeCursor {
        self.root_node().walk()
    }

    /// Compare this old edited syntax tree to a new syntax tree representing the same
    /// document, returning a sequence of ranges whose syntactic structure has changed.
    ///
    /// For this to work correctly, this syntax tree must have been edited such that its
    /// ranges match up to the new tree. Generally, you'll want to call this method right
    /// after calling one of the [Parser::parse] functions. Call it on the old tree that
    /// was passed to parse, and pass the new tree that was returned from `parse`.
    pub fn changed_ranges(&self, other: &Tree) -> impl ExactSizeIterator<Item = Range> {
        let mut count = 0;
        unsafe {
            let ptr = ffi::ts_tree_get_changed_ranges(
                self.0.as_ptr(),
                other.0.as_ptr(),
                &mut count as *mut _ as *mut u32,
            );
            util::CBufferIter::new(ptr, count).map(|r| r.into())
        }
    }
}

impl fmt::Debug for Tree {
    fn fmt(&self, f: &mut fmt::Formatter) -> Result<(), fmt::Error> {
        write!(f, "{{Tree {:?}}}", self.root_node())
    }
}

impl Drop for Tree {
    fn drop(&mut self) {
        unsafe { ffi::ts_tree_delete(self.0.as_ptr()) }
    }
}

impl Clone for Tree {
    fn clone(&self) -> Tree {
        unsafe { Tree(NonNull::new_unchecked(ffi::ts_tree_copy(self.0.as_ptr()))) }
    }
}

impl<'tree> Node<'tree> {
    fn new(node: ffi::TSNode) -> Option<Self> {
        if node.id.is_null() {
            None
        } else {
            Some(Node(node, PhantomData))
        }
    }

    /// Get this node's type as a numerical id.
    pub fn kind_id(&self) -> u16 {
        unsafe { ffi::ts_node_symbol(self.0) }
    }

    /// Get this node's type as a string.
    pub fn kind(&self) -> &'static str {
        unsafe { CStr::from_ptr(ffi::ts_node_type(self.0)) }
            .to_str()
            .unwrap()
    }

    /// Get the [Language] that was used to parse this node's syntax tree.
    pub fn language(&self) -> Language {
        Language(unsafe { ffi::ts_tree_language(self.0.tree) })
    }

    /// Check if this node is *named*.
    ///
    /// Named nodes correspond to named rules in the grammar, whereas *anonymous* nodes
    /// correspond to string literals in the grammar.
    pub fn is_named(&self) -> bool {
        unsafe { ffi::ts_node_is_named(self.0) }
    }

    /// Check if this node is *extra*.
    ///
    /// Extra nodes represent things like comments, which are not required the grammar,
    /// but can appear anywhere.
    pub fn is_extra(&self) -> bool {
        unsafe { ffi::ts_node_is_extra(self.0) }
    }

    /// Check if this node has been edited.
    pub fn has_changes(&self) -> bool {
        unsafe { ffi::ts_node_has_changes(self.0) }
    }

    /// Check if this node represents a syntax error or contains any syntax errors anywhere
    /// within it.
    pub fn has_error(&self) -> bool {
        unsafe { ffi::ts_node_has_error(self.0) }
    }

    /// Check if this node represents a syntax error.
    ///
    /// Syntax errors represent parts of the code that could not be incorporated into a
    /// valid syntax tree.
    pub fn is_error(&self) -> bool {
        self.kind_id() == u16::MAX
    }

    /// Check if this node is *missing*.
    ///
    /// Missing nodes are inserted by the parser in order to recover from certain kinds of
    /// syntax errors.
    pub fn is_missing(&self) -> bool {
        unsafe { ffi::ts_node_is_missing(self.0) }
    }

    /// Get the byte offsets where this node starts.
    pub fn start_byte(&self) -> usize {
        unsafe { ffi::ts_node_start_byte(self.0) as usize }
    }

    /// Get the byte offsets where this node end.
    pub fn end_byte(&self) -> usize {
        unsafe { ffi::ts_node_end_byte(self.0) as usize }
    }

    /// Get the byte range of source code that this node represents.
    pub fn byte_range(&self) -> std::ops::Range<usize> {
        self.start_byte()..self.end_byte()
    }

    /// Get the range of source code that this node represents, both in terms of raw bytes
    /// and of row/column coordinates.
    pub fn range(&self) -> Range {
        Range {
            start_byte: self.start_byte(),
            end_byte: self.end_byte(),
            start_point: self.start_position(),
            end_point: self.end_position(),
        }
    }

    /// Get this node's start position in terms of rows and columns.
    pub fn start_position(&self) -> Point {
        let result = unsafe { ffi::ts_node_start_point(self.0) };
        result.into()
    }

    /// Get this node's end position in terms of rows and columns.
    pub fn end_position(&self) -> Point {
        let result = unsafe { ffi::ts_node_end_point(self.0) };
        result.into()
    }

    /// Get the node's child at the given index, where zero represents the first
    /// child.
    ///
    /// This method is fairly fast, but its cost is technically log(i), so you
    /// if you might be iterating over a long list of children, you should use
    /// [Node::children] instead.
    pub fn child(&self, i: usize) -> Option<Self> {
        Self::new(unsafe { ffi::ts_node_child(self.0, i as u32) })
    }

    /// Get this node's number of children.
    pub fn child_count(&self) -> usize {
        unsafe { ffi::ts_node_child_count(self.0) as usize }
    }

    /// Get this node's *named* child at the given index.
    ///
    /// See also [Node::is_named].
    /// This method is fairly fast, but its cost is technically log(i), so you
    /// if you might be iterating over a long list of children, you should use
    /// [Node::named_children] instead.
    pub fn named_child<'a>(&'a self, i: usize) -> Option<Self> {
        Self::new(unsafe { ffi::ts_node_named_child(self.0, i as u32) })
    }

    /// Get this node's number of *named* children.
    ///
    /// See also [Node::is_named].
    pub fn named_child_count(&self) -> usize {
        unsafe { ffi::ts_node_named_child_count(self.0) as usize }
    }

    /// Get the first child with the given field name.
    ///
    /// If multiple children may have the same field name, access them using
    /// [children_by_field_name](Node::children_by_field_name)
    pub fn child_by_field_name(&self, field_name: impl AsRef<[u8]>) -> Option<Self> {
        let field_name = field_name.as_ref();
        Self::new(unsafe {
            ffi::ts_node_child_by_field_name(
                self.0,
                field_name.as_ptr() as *const c_char,
                field_name.len() as u32,
            )
        })
    }

    /// Get this node's child with the given numerical field id.
    ///
    /// See also [child_by_field_name](Node::child_by_field_name). You can convert a field name to
    /// an id using [Language::field_id_for_name].
    pub fn child_by_field_id(&self, field_id: u16) -> Option<Self> {
        Self::new(unsafe { ffi::ts_node_child_by_field_id(self.0, field_id) })
    }

    /// Iterate over this node's children.
    ///
    /// A [TreeCursor] is used to retrieve the children efficiently. Obtain
    /// a [TreeCursor] by calling [Tree::walk] or [Node::walk]. To avoid unnecessary
    /// allocations, you should reuse the same cursor for subsequent calls to
    /// this method.
    ///
    /// If you're walking the tree recursively, you may want to use the `TreeCursor`
    /// APIs directly instead.
    pub fn children<'a>(
        &self,
        cursor: &'a mut TreeCursor<'tree>,
    ) -> impl ExactSizeIterator<Item = Node<'tree>> + 'a {
        cursor.reset(*self);
        cursor.goto_first_child();
        (0..self.child_count()).into_iter().map(move |_| {
            let result = cursor.node();
            cursor.goto_next_sibling();
            result
        })
    }

    /// Iterate over this node's named children.
    ///
    /// See also [Node::children].
    pub fn named_children<'a>(
        &self,
        cursor: &'a mut TreeCursor<'tree>,
    ) -> impl ExactSizeIterator<Item = Node<'tree>> + 'a {
        cursor.reset(*self);
        cursor.goto_first_child();
        (0..self.named_child_count()).into_iter().map(move |_| {
            while !cursor.node().is_named() {
                if !cursor.goto_next_sibling() {
                    break;
                }
            }
            let result = cursor.node();
            cursor.goto_next_sibling();
            result
        })
    }

    /// Iterate over this node's children with a given field name.
    ///
    /// See also [Node::children].
    pub fn children_by_field_name<'a>(
        &self,
        field_name: &str,
        cursor: &'a mut TreeCursor<'tree>,
    ) -> impl Iterator<Item = Node<'tree>> + 'a {
        let field_id = self.language().field_id_for_name(field_name);
        self.children_by_field_id(field_id.unwrap_or(0), cursor)
    }

    /// Iterate over this node's children with a given field id.
    ///
    /// See also [Node::children_by_field_name].
    pub fn children_by_field_id<'a>(
        &self,
        field_id: u16,
        cursor: &'a mut TreeCursor<'tree>,
    ) -> impl Iterator<Item = Node<'tree>> + 'a {
        cursor.reset(*self);
        cursor.goto_first_child();
        let mut done = false;
        iter::from_fn(move || {
            while !done {
                while cursor.field_id() != Some(field_id) {
                    if !cursor.goto_next_sibling() {
                        return None;
                    }
                }
                let result = cursor.node();
                if !cursor.goto_next_sibling() {
                    done = true;
                }
                return Some(result);
            }
            None
        })
    }

    /// Get this node's immediate parent.
    pub fn parent(&self) -> Option<Self> {
        Self::new(unsafe { ffi::ts_node_parent(self.0) })
    }

    /// Get this node's next sibling.
    pub fn next_sibling(&self) -> Option<Self> {
        Self::new(unsafe { ffi::ts_node_next_sibling(self.0) })
    }

    /// Get this node's previous sibling.
    pub fn prev_sibling(&self) -> Option<Self> {
        Self::new(unsafe { ffi::ts_node_prev_sibling(self.0) })
    }

    /// Get this node's next named sibling.
    pub fn next_named_sibling(&self) -> Option<Self> {
        Self::new(unsafe { ffi::ts_node_next_named_sibling(self.0) })
    }

    /// Get this node's previous named sibling.
    pub fn prev_named_sibling(&self) -> Option<Self> {
        Self::new(unsafe { ffi::ts_node_prev_named_sibling(self.0) })
    }

    /// Get the smallest node within this node that spans the given range.
    pub fn descendant_for_byte_range(&self, start: usize, end: usize) -> Option<Self> {
        Self::new(unsafe {
            ffi::ts_node_descendant_for_byte_range(self.0, start as u32, end as u32)
        })
    }

    /// Get the smallest named node within this node that spans the given range.
    pub fn named_descendant_for_byte_range(&self, start: usize, end: usize) -> Option<Self> {
        Self::new(unsafe {
            ffi::ts_node_named_descendant_for_byte_range(self.0, start as u32, end as u32)
        })
    }

    /// Get the smallest node within this node that spans the given range.
    pub fn descendant_for_point_range(&self, start: Point, end: Point) -> Option<Self> {
        Self::new(unsafe {
            ffi::ts_node_descendant_for_point_range(self.0, start.into(), end.into())
        })
    }

    /// Get the smallest named node within this node that spans the given range.
    pub fn named_descendant_for_point_range(&self, start: Point, end: Point) -> Option<Self> {
        Self::new(unsafe {
            ffi::ts_node_named_descendant_for_point_range(self.0, start.into(), end.into())
        })
    }

    pub fn to_sexp(&self) -> String {
        let c_string = unsafe { ffi::ts_node_string(self.0) };
        let result = unsafe { CStr::from_ptr(c_string) }
            .to_str()
            .unwrap()
            .to_string();
        unsafe { util::free_ptr(c_string as *mut c_void) };
        result
    }

    pub fn utf8_text<'a>(&self, source: &'a [u8]) -> Result<&'a str, str::Utf8Error> {
        str::from_utf8(&source[self.start_byte()..self.end_byte()])
    }

    pub fn utf16_text<'a>(&self, source: &'a [u16]) -> &'a [u16] {
        &source.as_ref()[self.start_byte()..self.end_byte()]
    }

    /// Create a new [TreeCursor] starting from this node.
    pub fn walk(&self) -> TreeCursor<'tree> {
        TreeCursor(unsafe { ffi::ts_tree_cursor_new(self.0) }, PhantomData)
    }

    /// Edit this node to keep it in-sync with source code that has been edited.
    ///
    /// This function is only rarely needed. When you edit a syntax tree with the
    /// [Tree::edit] method, all of the nodes that you retrieve from the tree
    /// afterward will already reflect the edit. You only need to use [Node::edit]
    /// when you have a specific [Node] instance that you want to keep and continue
    /// to use after an edit.
    pub fn edit(&mut self, edit: &InputEdit) {
        let edit = edit.into();
        unsafe { ffi::ts_node_edit(&mut self.0 as *mut ffi::TSNode, &edit) }
    }
}

impl<'a> PartialEq for Node<'a> {
    fn eq(&self, other: &Self) -> bool {
        self.0.id == other.0.id
    }
}

impl<'a> fmt::Debug for Node<'a> {
    fn fmt(&self, f: &mut fmt::Formatter) -> Result<(), fmt::Error> {
        write!(
            f,
            "{{Node {} {} - {}}}",
            self.kind(),
            self.start_position(),
            self.end_position()
        )
    }
}

impl<'a> TreeCursor<'a> {
    /// Get the tree cursor's current [Node].
    pub fn node(&self) -> Node<'a> {
        Node(
            unsafe { ffi::ts_tree_cursor_current_node(&self.0) },
            PhantomData,
        )
    }

    /// Get the numerical field id of this tree cursor's current node.
    ///
    /// See also [field_name](TreeCursor::field_name).
    pub fn field_id(&self) -> Option<u16> {
        unsafe {
            let id = ffi::ts_tree_cursor_current_field_id(&self.0);
            if id == 0 {
                None
            } else {
                Some(id)
            }
        }
    }

    /// Get the field name of this tree cursor's current node.
    pub fn field_name(&self) -> Option<&str> {
        unsafe {
            let ptr = ffi::ts_tree_cursor_current_field_name(&self.0);
            if ptr.is_null() {
                None
            } else {
                Some(CStr::from_ptr(ptr).to_str().unwrap())
            }
        }
    }

    /// Move this cursor to the first child of its current node.
    ///
    /// This returns `true` if the cursor successfully moved, and returns `false`
    /// if there were no children.
    pub fn goto_first_child(&mut self) -> bool {
        return unsafe { ffi::ts_tree_cursor_goto_first_child(&mut self.0) };
    }

    /// Move this cursor to the parent of its current node.
    ///
    /// This returns `true` if the cursor successfully moved, and returns `false`
    /// if there was no parent node (the cursor was already on the root node).
    pub fn goto_parent(&mut self) -> bool {
        return unsafe { ffi::ts_tree_cursor_goto_parent(&mut self.0) };
    }

    /// Move this cursor to the next sibling of its current node.
    ///
    /// This returns `true` if the cursor successfully moved, and returns `false`
    /// if there was no next sibling node.
    pub fn goto_next_sibling(&mut self) -> bool {
        return unsafe { ffi::ts_tree_cursor_goto_next_sibling(&mut self.0) };
    }

    /// Move this cursor to the first child of its current node that extends beyond
    /// the given byte offset.
    ///
    /// This returns the index of the child node if one was found, and returns `None`
    /// if no such child was found.
    pub fn goto_first_child_for_byte(&mut self, index: usize) -> Option<usize> {
        let result =
            unsafe { ffi::ts_tree_cursor_goto_first_child_for_byte(&mut self.0, index as u32) };
        if result < 0 {
            None
        } else {
            Some(result as usize)
        }
    }

    /// Re-initialize this tree cursor to start at a different node.
    pub fn reset(&mut self, node: Node<'a>) {
        unsafe { ffi::ts_tree_cursor_reset(&mut self.0, node.0) };
    }
}

impl<'a> Drop for TreeCursor<'a> {
    fn drop(&mut self) {
        unsafe { ffi::ts_tree_cursor_delete(&mut self.0) }
    }
}

impl Query {
    /// Create a new query from a string containing one or more S-expression
    /// patterns.
    ///
    /// The query is associated with a particular language, and can only be run
    /// on syntax nodes parsed with that language. References to Queries can be
    /// shared between multiple threads.
    pub fn new(language: Language, source: &str) -> Result<Self, QueryError> {
        let mut error_offset = 0u32;
        let mut error_type: ffi::TSQueryError = 0;
        let bytes = source.as_bytes();

        // Compile the query.
        let ptr = unsafe {
            ffi::ts_query_new(
                language.0,
                bytes.as_ptr() as *const c_char,
                bytes.len() as u32,
                &mut error_offset as *mut u32,
                &mut error_type as *mut ffi::TSQueryError,
            )
        };

        // On failure, build an error based on the error code and offset.
        if ptr.is_null() {
            let offset = error_offset as usize;
            let mut line_start = 0;
            let mut row = 0;
            let line_containing_error = source.split("\n").find_map(|line| {
                row += 1;
                let line_end = line_start + line.len() + 1;
                if line_end > offset {
                    Some(line)
                } else {
                    line_start = line_end;
                    None
                }
            });

            let message = if let Some(line) = line_containing_error {
                line.to_string() + "\n" + &" ".repeat(offset - line_start) + "^"
            } else {
                "Unexpected EOF".to_string()
            };

            // if line_containing_error
            return if error_type != ffi::TSQueryError_TSQueryErrorSyntax {
                let suffix = source.split_at(offset).1;
                let end_offset = suffix
                    .find(|c| !char::is_alphanumeric(c) && c != '_' && c != '-')
                    .unwrap_or(source.len());
                let name = suffix.split_at(end_offset).0.to_string();
                match error_type {
                    ffi::TSQueryError_TSQueryErrorNodeType => Err(QueryError::NodeType(row, name)),
                    ffi::TSQueryError_TSQueryErrorField => Err(QueryError::Field(row, name)),
                    ffi::TSQueryError_TSQueryErrorCapture => Err(QueryError::Capture(row, name)),
                    _ => Err(QueryError::Syntax(row, message)),
                }
            } else {
                Err(QueryError::Syntax(row, message))
            };
        }

        let string_count = unsafe { ffi::ts_query_string_count(ptr) };
        let capture_count = unsafe { ffi::ts_query_capture_count(ptr) };
        let pattern_count = unsafe { ffi::ts_query_pattern_count(ptr) as usize };
        let mut result = Query {
            ptr: unsafe { NonNull::new_unchecked(ptr) },
            capture_names: Vec::with_capacity(capture_count as usize),
            text_predicates: Vec::with_capacity(pattern_count),
            property_predicates: Vec::with_capacity(pattern_count),
            property_settings: Vec::with_capacity(pattern_count),
        };

        // Build a vector of strings to store the capture names.
        for i in 0..capture_count {
            unsafe {
                let mut length = 0u32;
                let name =
                    ffi::ts_query_capture_name_for_id(ptr, i, &mut length as *mut u32) as *const u8;
                let name = slice::from_raw_parts(name, length as usize);
                let name = str::from_utf8_unchecked(name);
                result.capture_names.push(name.to_string());
            }
        }

        // Build a vector of strings to represent literal values used in predicates.
        let string_values = (0..string_count)
            .map(|i| unsafe {
                let mut length = 0u32;
                let value =
                    ffi::ts_query_string_value_for_id(ptr, i as u32, &mut length as *mut u32)
                        as *const u8;
                let value = slice::from_raw_parts(value, length as usize);
                let value = str::from_utf8_unchecked(value);
                value.to_string()
            })
            .collect::<Vec<_>>();

        // Build a vector of predicates for each pattern.
        for i in 0..pattern_count {
            let predicate_steps = unsafe {
                let mut length = 0u32;
                let raw_predicates =
                    ffi::ts_query_predicates_for_pattern(ptr, i as u32, &mut length as *mut u32);
                slice::from_raw_parts(raw_predicates, length as usize)
            };

            let type_done = ffi::TSQueryPredicateStepType_TSQueryPredicateStepTypeDone;
            let type_capture = ffi::TSQueryPredicateStepType_TSQueryPredicateStepTypeCapture;
            let type_string = ffi::TSQueryPredicateStepType_TSQueryPredicateStepTypeString;

            let mut text_predicates = Vec::new();
            let mut property_predicates = Vec::new();
            let mut property_settings = Vec::new();
            for p in predicate_steps.split(|s| s.type_ == type_done) {
                if p.is_empty() {
                    continue;
                }

                if p[0].type_ != type_string {
                    return Err(QueryError::Predicate(format!(
                        "Expected predicate to start with a function name. Got @{}.",
                        result.capture_names[p[0].value_id as usize],
                    )));
                }

                // Build a predicate for each of the known predicate function names.
                let operator_name = &string_values[p[0].value_id as usize];
                match operator_name.as_str() {
                    "eq?" => {
                        if p.len() != 3 {
                            return Err(QueryError::Predicate(format!(
                                "Wrong number of arguments to eq? predicate. Expected 2, got {}.",
                                p.len() - 1
                            )));
                        }
                        if p[1].type_ != type_capture {
                            return Err(QueryError::Predicate(format!(
                                "First argument to eq? predicate must be a capture name. Got literal \"{}\".",
                                string_values[p[1].value_id as usize],
                            )));
                        }

                        text_predicates.push(if p[2].type_ == type_capture {
                            TextPredicate::CaptureEqCapture(p[1].value_id, p[2].value_id)
                        } else {
                            TextPredicate::CaptureEqString(
                                p[1].value_id,
                                string_values[p[2].value_id as usize].clone(),
                            )
                        });
                    }

                    "match?" => {
                        if p.len() != 3 {
                            return Err(QueryError::Predicate(format!(
                                "Wrong number of arguments to match? predicate. Expected 2, got {}.",
                                p.len() - 1
                            )));
                        }
                        if p[1].type_ != type_capture {
                            return Err(QueryError::Predicate(format!(
                                "First argument to match? predicate must be a capture name. Got literal \"{}\".",
                                string_values[p[1].value_id as usize],
                            )));
                        }
                        if p[2].type_ == type_capture {
                            return Err(QueryError::Predicate(format!(
                                "Second argument to match? predicate must be a literal. Got capture @{}.",
                                result.capture_names[p[2].value_id as usize],
                            )));
                        }

                        let regex = &string_values[p[2].value_id as usize];
                        text_predicates.push(TextPredicate::CaptureMatchString(
                            p[1].value_id,
                            regex::bytes::Regex::new(regex).map_err(|_| {
                                QueryError::Predicate(format!("Invalid regex '{}'", regex))
                            })?,
                        ));
                    }

                    "set!" => property_settings.push(Self::parse_property(
                        "set!",
                        &result.capture_names,
                        &string_values,
                        &p[1..],
                    )?),

                    "is?" | "is-not?" => property_predicates.push((
                        Self::parse_property(
                            &operator_name,
                            &result.capture_names,
                            &string_values,
                            &p[1..],
                        )?,
                        operator_name == "is?",
                    )),

                    _ => {
                        return Err(QueryError::Predicate(format!(
                            "Unknown query predicate function {}",
                            operator_name,
                        )))
                    }
                }
            }

            result
                .text_predicates
                .push(text_predicates.into_boxed_slice());
            result
                .property_predicates
                .push(property_predicates.into_boxed_slice());
            result
                .property_settings
                .push(property_settings.into_boxed_slice());
        }
        Ok(result)
    }

    /// Get the byte offset where the given pattern starts in the query's source.
    pub fn start_byte_for_pattern(&self, pattern_index: usize) -> usize {
        if pattern_index >= self.text_predicates.len() {
            panic!(
                "Pattern index is {} but the pattern count is {}",
                pattern_index,
                self.text_predicates.len(),
            );
        }
        unsafe {
            ffi::ts_query_start_byte_for_pattern(self.ptr.as_ptr(), pattern_index as u32) as usize
        }
    }

    /// Get the number of patterns in the query.
    pub fn pattern_count(&self) -> usize {
        unsafe { ffi::ts_query_pattern_count(self.ptr.as_ptr()) as usize }
    }

    /// Get the names of the captures used in the query.
    pub fn capture_names(&self) -> &[String] {
        &self.capture_names
    }

    /// Get the properties that are checked for the given pattern index.
    pub fn property_predicates(&self, index: usize) -> &[(QueryProperty, bool)] {
        &self.property_predicates[index]
    }

    /// Get the properties that are set for the given pattern index.
    pub fn property_settings(&self, index: usize) -> &[QueryProperty] {
        &self.property_settings[index]
    }

    /// Disable a certain capture within a query.
    ///
    /// This prevents the capture from being returned in matches, and also avoids any
    /// resource usage associated with recording the capture.
    pub fn disable_capture(&mut self, name: &str) {
        unsafe {
            ffi::ts_query_disable_capture(
                self.ptr.as_ptr(),
                name.as_bytes().as_ptr() as *const c_char,
                name.len() as u32,
            );
        }
    }

    fn parse_property(
        function_name: &str,
        capture_names: &[String],
        string_values: &[String],
        args: &[ffi::TSQueryPredicateStep],
    ) -> Result<QueryProperty, QueryError> {
        if args.len() == 0 || args.len() > 3 {
            return Err(QueryError::Predicate(format!(
                "Wrong number of arguments to {} predicate. Expected 1 to 3, got {}.",
                function_name,
                args.len(),
            )));
        }

        let mut i = 0;
        let mut capture_id = None;
        if args[i].type_ == ffi::TSQueryPredicateStepType_TSQueryPredicateStepTypeCapture {
            capture_id = Some(args[i].value_id as usize);
            i += 1;

            if i == args.len() {
                return Err(QueryError::Predicate(format!(
                    "No key specified for {} predicate.",
                    function_name,
                )));
            }
            if args[i].type_ == ffi::TSQueryPredicateStepType_TSQueryPredicateStepTypeCapture {
                return Err(QueryError::Predicate(format!(
                    "Invalid arguments to {} predicate. Expected string, got @{}",
                    function_name, capture_names[args[i].value_id as usize]
                )));
            }
        }

        let key = &string_values[args[i].value_id as usize];
        i += 1;

        let mut value = None;
        if i < args.len() {
            if args[i].type_ == ffi::TSQueryPredicateStepType_TSQueryPredicateStepTypeCapture {
                return Err(QueryError::Predicate(format!(
                    "Invalid arguments to {} predicate. Expected string, got @{}",
                    function_name, capture_names[args[i].value_id as usize]
                )));
            }
            value = Some(string_values[args[i].value_id as usize].as_str());
        }

        Ok(QueryProperty::new(key, value, capture_id))
    }
}

impl QueryCursor {
    /// Create a new cursor for executing a given query.
    ///
    /// The cursor stores the state that is needed to iteratively search for matches.
    pub fn new() -> Self {
        QueryCursor(unsafe { NonNull::new_unchecked(ffi::ts_query_cursor_new()) })
    }

    /// Iterate over all of the matches in the order that they were found.
    ///
    /// Each match contains the index of the pattern that matched, and a list of captures.
    /// Because multiple patterns can match the same set of nodes, one match may contain
    /// captures that appear *before* some of the captures from a previous match.
    pub fn matches<'a>(
        &mut self,
        query: &'a Query,
        node: Node<'a>,
        mut text_callback: impl FnMut(Node<'a>) -> &[u8] + 'a,
    ) -> impl Iterator<Item = QueryMatch<'a>> + 'a {
        let ptr = self.0.as_ptr();
        unsafe { ffi::ts_query_cursor_exec(ptr, query.ptr.as_ptr(), node.0) };
        std::iter::from_fn(move || loop {
            unsafe {
                let mut m = MaybeUninit::<ffi::TSQueryMatch>::uninit();
                if ffi::ts_query_cursor_next_match(ptr, m.as_mut_ptr()) {
                    let result = QueryMatch::new(m.assume_init(), ptr);
                    if result.satisfies_text_predicates(query, &mut text_callback) {
                        return Some(result);
                    }
                } else {
                    return None;
                }
            }
        })
    }

    /// Iterate over all of the individual captures in the order that they appear.
    ///
    /// This is useful if don't care about which pattern matched, and just want a single,
    /// ordered sequence of captures.
    pub fn captures<'a, T: AsRef<[u8]>>(
        &mut self,
        query: &'a Query,
        node: Node<'a>,
        text_callback: impl FnMut(Node<'a>) -> T + 'a,
    ) -> QueryCaptures<'a, T> {
        let ptr = self.0.as_ptr();
        unsafe { ffi::ts_query_cursor_exec(ptr, query.ptr.as_ptr(), node.0) };
        QueryCaptures {
            ptr,
            query,
            text_callback: Box::new(text_callback),
        }
    }

    /// Set the range in which the query will be executed, in terms of byte offsets.
    pub fn set_byte_range(&mut self, start: usize, end: usize) -> &mut Self {
        unsafe {
            ffi::ts_query_cursor_set_byte_range(self.0.as_ptr(), start as u32, end as u32);
        }
        self
    }

    /// Set the range in which the query will be executed, in terms of rows and columns.
    pub fn set_point_range(&mut self, start: Point, end: Point) -> &mut Self {
        unsafe {
            ffi::ts_query_cursor_set_point_range(self.0.as_ptr(), start.into(), end.into());
        }
        self
    }
}

impl<'a> QueryMatch<'a> {
    pub fn remove(self) {
        unsafe { ffi::ts_query_cursor_remove_match(self.cursor, self.id) }
    }

    fn new(m: ffi::TSQueryMatch, cursor: *mut ffi::TSQueryCursor) -> Self {
        QueryMatch {
            cursor,
            id: m.id,
            pattern_index: m.pattern_index as usize,
            captures: unsafe {
                slice::from_raw_parts(
                    m.captures as *const QueryCapture<'a>,
                    m.capture_count as usize,
                )
            },
        }
    }

    fn satisfies_text_predicates<T: AsRef<[u8]>>(
        &self,
        query: &Query,
        text_callback: &mut impl FnMut(Node<'a>) -> T,
    ) -> bool {
        query.text_predicates[self.pattern_index]
            .iter()
            .all(|predicate| match predicate {
                TextPredicate::CaptureEqCapture(i, j) => {
                    let node1 = self.capture_for_index(*i).unwrap();
                    let node2 = self.capture_for_index(*j).unwrap();
                    text_callback(node1).as_ref() == text_callback(node2).as_ref()
                }
                TextPredicate::CaptureEqString(i, s) => {
                    let node = self.capture_for_index(*i).unwrap();
                    text_callback(node).as_ref() == s.as_bytes()
                }
                TextPredicate::CaptureMatchString(i, r) => {
                    let node = self.capture_for_index(*i).unwrap();
                    r.is_match(text_callback(node).as_ref())
                }
            })
    }

    fn capture_for_index(&self, capture_index: u32) -> Option<Node<'a>> {
        for c in self.captures {
            if c.index == capture_index {
                return Some(c.node);
            }
        }
        None
    }
}

impl QueryProperty {
    pub fn new(key: &str, value: Option<&str>, capture_id: Option<usize>) -> Self {
        QueryProperty {
            capture_id,
            key: key.to_string().into_boxed_str(),
            value: value.map(|s| s.to_string().into_boxed_str()),
        }
    }
}

impl<'a, T: AsRef<[u8]>> Iterator for QueryCaptures<'a, T> {
    type Item = (QueryMatch<'a>, usize);

    fn next(&mut self) -> Option<Self::Item> {
        loop {
            unsafe {
                let mut capture_index = 0u32;
                let mut m = MaybeUninit::<ffi::TSQueryMatch>::uninit();
                if ffi::ts_query_cursor_next_capture(
                    self.ptr,
                    m.as_mut_ptr(),
                    &mut capture_index as *mut u32,
                ) {
                    let result = QueryMatch::new(m.assume_init(), self.ptr);
                    if result.satisfies_text_predicates(self.query, &mut self.text_callback) {
                        return Some((result, capture_index as usize));
                    } else {
                        result.remove();
                    }
                } else {
                    return None;
                }
            }
        }
    }
}

impl PartialEq for Query {
    fn eq(&self, other: &Self) -> bool {
        self.ptr == other.ptr
    }
}

impl Drop for Query {
    fn drop(&mut self) {
        unsafe { ffi::ts_query_delete(self.ptr.as_ptr()) }
    }
}

impl Drop for QueryCursor {
    fn drop(&mut self) {
        unsafe { ffi::ts_query_cursor_delete(self.0.as_ptr()) }
    }
}

impl Point {
    pub fn new(row: usize, column: usize) -> Self {
        Point { row, column }
    }
}

impl fmt::Display for Point {
    fn fmt(&self, f: &mut fmt::Formatter) -> Result<(), fmt::Error> {
        write!(f, "({}, {})", self.row, self.column)
    }
}

impl Into<ffi::TSPoint> for Point {
    fn into(self) -> ffi::TSPoint {
        ffi::TSPoint {
            row: self.row as u32,
            column: self.column as u32,
        }
    }
}

impl From<ffi::TSPoint> for Point {
    fn from(point: ffi::TSPoint) -> Self {
        Self {
            row: point.row as usize,
            column: point.column as usize,
        }
    }
}

impl Into<ffi::TSRange> for Range {
    fn into(self) -> ffi::TSRange {
        ffi::TSRange {
            start_byte: self.start_byte as u32,
            end_byte: self.end_byte as u32,
            start_point: self.start_point.into(),
            end_point: self.end_point.into(),
        }
    }
}

impl From<ffi::TSRange> for Range {
    fn from(range: ffi::TSRange) -> Self {
        Self {
            start_byte: range.start_byte as usize,
            end_byte: range.end_byte as usize,
            start_point: range.start_point.into(),
            end_point: range.end_point.into(),
        }
    }
}

impl<'a> Into<ffi::TSInputEdit> for &'a InputEdit {
    fn into(self) -> ffi::TSInputEdit {
        ffi::TSInputEdit {
            start_byte: self.start_byte as u32,
            old_end_byte: self.old_end_byte as u32,
            new_end_byte: self.new_end_byte as u32,
            start_point: self.start_position.into(),
            old_end_point: self.old_end_position.into(),
            new_end_point: self.new_end_position.into(),
        }
    }
}

unsafe impl Send for Language {}
unsafe impl Send for Parser {}
unsafe impl Send for Query {}
unsafe impl Send for Tree {}
unsafe impl Sync for Language {}
unsafe impl Sync for Query {}