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powdb_query/executor/
prepared.rs

1//! PreparedQuery struct and related Engine methods.
2
3use crate::ast::*;
4use crate::plan::*;
5use crate::planner;
6use crate::result::{QueryError, QueryResult};
7use powdb_storage::catalog::Catalog;
8use powdb_storage::row::{ROW_MAGIC, ROW_PREFIX_SIZE};
9use powdb_storage::types::*;
10
11use super::compiled::*;
12use super::eval::*;
13use super::Engine;
14
15pub struct PreparedQuery {
16    plan_template: PlanNode,
17    /// Total number of `Expr::Literal` slots reachable from the plan.
18    /// Callers must supply exactly this many literals per execution.
19    pub param_count: usize,
20    /// Fast-path metadata for `PlanNode::Insert`. `Some` when:
21    ///   * the template is an Insert, and
22    ///   * every assignment RHS is `Expr::Literal(_)` (no computed exprs),
23    ///     which means param_count == assignments.len() and the caller's
24    ///     literal slice maps 1:1 to schema column indices.
25    ///
26    /// Mission C Phase 15: upgraded from a bare `Vec<usize>` to a
27    /// dedicated [`InsertFast`] struct so the execute path can skip the
28    /// second `catalog.schema(table)` HashMap lookup just to read
29    /// `n_cols`, and can dispatch through `get_table_mut` + `tbl.insert`
30    /// instead of going via the generic `catalog.insert` wrapper.
31    insert_fast: Option<InsertFast>,
32    /// Mission C Phase 14: fast-path metadata for point updates by primary
33    /// key — `T filter .pk = <lit> update { col := <lit> }` where `pk` is
34    /// an indexed column and `col` is fixed-size and not indexed. At
35    /// execute time we skip plan clone, substitute walk, schema re-lookup,
36    /// `resolved_assignments` + `FastPatch` + `matching_rids` Vec allocs,
37    /// and the whole `PlanNode::Update` arm. Just a btree lookup and a
38    /// byte patch.
39    update_pk_fast: Option<UpdatePkFast>,
40}
41
42/// Mission C Phase 15: precomputed insert fast-path metadata. Built once
43/// in [`Engine::prepare`] from a `PlanNode::Insert` template whose every
44/// assignment RHS is a raw literal. The execute path reads `n_cols` and
45/// `col_indices` directly — no catalog schema lookup needed.
46#[derive(Clone)]
47struct InsertFast {
48    /// Mission C Phase 18: cached slot index into `Catalog::tables`.
49    /// DROP/ALTER/index DDL can invalidate the slot or row contract, so every
50    /// execution compares the O(1) catalog structure generation below.
51    table_slot: usize,
52    structure_generation: u64,
53    /// Schema column index for each positional literal, in the order the
54    /// caller passes them.
55    col_indices: Vec<usize>,
56    /// Total number of schema columns — the size `insert_values_scratch`
57    /// must be resized to before filling positions via `col_indices`.
58    /// Cached here so the hot loop skips `catalog.schema(table)` entirely.
59    n_cols: usize,
60    /// Schema slots omitted by this prepared INSERT. The scratch row is shared
61    /// by all prepared inserts on an engine, so these positions must be reset
62    /// to NULL before each execution. Precomputing the complement avoids an
63    /// O(columns × assignments) membership scan on the write hot path.
64    omitted_col_indices: Vec<usize>,
65    /// Assigned column definitions in parameter order. Runtime literals still
66    /// pass through the same coercion rules as the generic INSERT executor;
67    /// preparing with an integer placeholder must not permit a later string to
68    /// be stored in an integer column.
69    assigned_columns: Vec<ColumnDef>,
70    /// Required slots are checked after coercion so a bound NULL cannot bypass
71    /// the generic INSERT required-column contract.
72    required_col_indices: Vec<usize>,
73    /// Needed to mark dependent materialized views dirty in both prepared
74    /// execution variants.
75    table_name: String,
76    /// Prepare-time schema names used only to preserve canonical required-field
77    /// errors. Structural validity is the O(1) generation check above.
78    schema_columns: Vec<ColumnDef>,
79}
80
81/// Mission C Phase 14: precomputed fast-path for `update_by_pk` shaped
82/// prepared queries. Built once in [`Engine::prepare`] and reused on every
83/// `execute_prepared` call.
84#[derive(Clone)]
85struct UpdatePkFast {
86    /// Mission C Phase 18: cached slot index into `Catalog::tables`, guarded
87    /// by the O(1) catalog structure generation on every execution.
88    table_slot: usize,
89    structure_generation: u64,
90    /// Name of the key column (the `.id = ?` side). We look this up in
91    /// the owning table's `indexed_cols` at execute time rather than
92    /// caching a raw `&BTree` — the engine owns the catalog and can't
93    /// hand out long-lived borrows anyway, and the n≤5 linear scan is
94    /// a handful of ns.
95    key_col: String,
96    /// Target column position. A later ALTER ADD INDEX on this column must
97    /// disable the raw byte-patch path so live secondary indexes and unique
98    /// constraints are maintained by the generic update executor.
99    target_col_idx: usize,
100    /// Byte offset of the target fixed column in the row encoding:
101    /// `2 + bitmap_size + layout.fixed_offsets[target_col]`.
102    field_off: usize,
103    /// Byte offset of the bitmap byte containing the target column's null
104    /// bit (`2 + target_col / 8`).
105    bitmap_byte_off: usize,
106    /// Bit mask for the target column's null bit.
107    bit_mask: u8,
108    /// Type of the target fixed column — drives the literal-to-bytes
109    /// encoding at execute time.
110    target_type: TypeId,
111    /// Index into the caller's `literals` slice that holds the filter key.
112    /// Always 0 today (filter literal is visited before the assignment
113    /// RHS), but stored explicitly so the contract is obvious.
114    key_literal_idx: usize,
115    /// Index into the caller's `literals` slice that holds the new value.
116    value_literal_idx: usize,
117}
118
119fn cached_table_matches(catalog: &Catalog, structure_generation: u64) -> bool {
120    catalog.structure_generation() == structure_generation
121}
122
123fn literal_can_take_without_error(literal: &Literal, column: &ColumnDef) -> bool {
124    matches!(
125        (literal, column.type_id),
126        (
127            Literal::Int(_),
128            TypeId::Int | TypeId::Float | TypeId::DateTime
129        ) | (Literal::Float(_), TypeId::Float | TypeId::Int)
130            | (Literal::String(_), TypeId::Str)
131            | (Literal::Bool(_), TypeId::Bool)
132    )
133}
134
135fn restore_taken_strings(fast: &InsertFast, literals: &mut [Literal], values: &mut [Value]) {
136    for (position, literal) in literals.iter_mut().enumerate() {
137        if let Literal::String(destination) = literal {
138            if let Value::Str(source) = &mut values[fast.col_indices[position]] {
139                *destination = std::mem::take(source);
140            }
141        }
142    }
143}
144
145impl Engine {
146    pub fn prepare(&mut self, query: &str) -> Result<PreparedQuery, QueryError> {
147        let plan = planner::plan(query).map_err(|e| QueryError::Parse(e.to_string()))?;
148        let param_count = crate::plan_cache::count_literal_slots(&plan);
149
150        // Insert fast path: if the template is Insert and every assignment
151        // RHS is a literal, resolve column indices once here and store
152        // them. execute_prepared will skip the plan-clone + substitute
153        // walk on this path.
154        //
155        // Mission C Phase 15: also cache `n_cols` and the target table
156        // name so execute_prepared doesn't need a second HashMap lookup
157        // on `self.catalog.schema(table)` just to size the scratch Vec.
158        let insert_fast = match &plan {
159            // Single-row inserts only: the byte-level fast path patches one
160            // row's worth of scratch. Multi-row `insert T {..},{..}` falls
161            // through to the generic plan path (always correct).
162            PlanNode::Insert {
163                table,
164                rows,
165                returning,
166            } if !returning
167                && rows.len() == 1
168                && rows[0].iter().all(|a| matches!(a.value, Expr::Literal(_)))
169                && param_count == rows[0].len() =>
170            {
171                let assignments = &rows[0];
172                let table_slot = self
173                    .catalog
174                    .table_slot(table)
175                    .ok_or_else(|| QueryError::TableNotFound(table.clone()))?;
176                let schema = self.catalog.table_by_slot(table_slot).schema();
177                let n_cols = schema.columns.len();
178                let indices: Result<Vec<usize>, QueryError> = assignments
179                    .iter()
180                    .map(|a| {
181                        schema
182                            .column_index(&a.field)
183                            .ok_or_else(|| QueryError::ColumnNotFound {
184                                table: table.clone(),
185                                column: a.field.clone(),
186                            })
187                    })
188                    .collect();
189                let indices = indices?;
190                let defaults = self.catalog.column_defaults(table).unwrap_or(&[]);
191                let auto = self.catalog.auto_columns(table).unwrap_or(&[]);
192                let omitted_required = schema
193                    .columns
194                    .iter()
195                    .enumerate()
196                    .any(|(index, column)| column.required && !indices.contains(&index));
197                // Defaults and auto columns require table-owned state updates.
198                // Keep those shapes on the generic executor, which applies the
199                // full schema contract. An omitted required column must also
200                // take the generic path so it returns the canonical error.
201                if defaults.iter().any(Option::is_some)
202                    || auto.iter().any(|is_auto| *is_auto)
203                    || omitted_required
204                {
205                    None
206                } else {
207                    let omitted_col_indices = (0..n_cols)
208                        .filter(|index| !indices.contains(index))
209                        .collect();
210                    let assigned_columns = indices
211                        .iter()
212                        .map(|&index| schema.columns[index].clone())
213                        .collect();
214                    let required_col_indices = schema
215                        .columns
216                        .iter()
217                        .enumerate()
218                        .filter_map(|(index, column)| column.required.then_some(index))
219                        .collect();
220                    Some(InsertFast {
221                        table_slot,
222                        structure_generation: self.catalog.structure_generation(),
223                        col_indices: indices,
224                        n_cols,
225                        omitted_col_indices,
226                        assigned_columns,
227                        required_col_indices,
228                        table_name: table.clone(),
229                        schema_columns: schema.columns.clone(),
230                    })
231                }
232            }
233            _ => None,
234        };
235
236        // Mission C Phase 14: update-by-pk fast path. Match on the shape
237        // planner::plan_update builds for `T filter .pk = ? update
238        // { col := ? }` — `Update { input: IndexScan(pk), assignments:
239        // [{col, Literal}] }` — and only if every precondition holds:
240        //   * `pk` is an indexed column (so the executor would take the
241        //     btree.lookup path at run time regardless)
242        //   * there's exactly one assignment
243        //   * the assigned column is fixed-size and *not* indexed (so we
244        //     don't have to maintain any secondary index on write)
245        //   * both literal slots are already `Expr::Literal` (no computed
246        //     expressions)
247        // If any of these fail we fall through to the standard substitute
248        // + execute path.
249        let update_pk_fast = Self::try_build_update_pk_fast(&self.catalog, &plan);
250
251        Ok(PreparedQuery {
252            plan_template: plan,
253            param_count,
254            insert_fast,
255            update_pk_fast,
256        })
257    }
258
259    /// Mission C Phase 14: inspect a planned tree and, if it matches the
260    /// `update_by_pk` fast-path shape, return the precomputed byte-patch
261    /// metadata. Returns `None` on any mismatch — the caller falls through
262    /// to the substitute-and-execute path, which is always correct.
263    fn try_build_update_pk_fast(catalog: &Catalog, plan: &PlanNode) -> Option<UpdatePkFast> {
264        // Top level must be `Update { input: IndexScan(...), ... }`.
265        let (table, input, assignments) = match plan {
266            // `returning` must materialize the post-update row image, which the
267            // byte-patch fast path can't produce — fall through to the generic
268            // executor arm.
269            PlanNode::Update {
270                table,
271                input,
272                assignments,
273                returning: false,
274            } => (table, input.as_ref(), assignments),
275            _ => return None,
276        };
277        // Exactly one assignment — the bench hot path and the only case
278        // where a single byte-patch covers the whole mutation.
279        if assignments.len() != 1 {
280            return None;
281        }
282        let assn = &assignments[0];
283        // Assignment RHS must be a raw literal, not a computed expr.
284        if !matches!(assn.value, Expr::Literal(_)) {
285            return None;
286        }
287        // Input must be an IndexScan on the same table with a literal key.
288        let (key_col, key_table) = match input {
289            PlanNode::IndexScan {
290                table: t,
291                column,
292                key: Expr::Literal(_),
293            } => (column.clone(), t.clone()),
294            _ => return None,
295        };
296        if &key_table != table {
297            return None;
298        }
299
300        // Look up schema + index state from the live catalog, caching
301        // the slot so the execute path skips the name probe.
302        let table_slot = catalog.table_slot(table)?;
303        let tbl = catalog.table_by_slot(table_slot);
304        let schema = tbl.schema();
305
306        // Key column must have an index (the btree.lookup path is what
307        // makes the fast path worth building).
308        if !tbl.has_index(&key_col) {
309            return None;
310        }
311
312        // Target column must exist, be fixed-size, and NOT be indexed (so
313        // we don't have to maintain any secondary index here).
314        let target_col_idx = schema.column_index(&assn.field)?;
315        let target_type = schema.columns[target_col_idx].type_id;
316        if !is_fixed_size(target_type) {
317            return None;
318        }
319        if tbl.has_indexed_col(target_col_idx) {
320            return None;
321        }
322
323        // Precompute byte offsets from the cached row layout.
324        let layout = tbl.row_layout();
325        let fixed_off = layout.fixed_offset(target_col_idx)?;
326        let bitmap_size = layout.bitmap_size();
327        let field_off = 2 + bitmap_size + fixed_off;
328        let bitmap_byte_off = 2 + target_col_idx / 8;
329        let bit_mask = 1u8 << (target_col_idx % 8);
330
331        // Literal walk order for `Update { IndexScan(key), [{value}] }`
332        // (see `plan_cache::substitute_plan` — input first, then the
333        // assignments). The filter key is literal 0, the assignment RHS
334        // is literal 1.
335        Some(UpdatePkFast {
336            table_slot,
337            structure_generation: catalog.structure_generation(),
338            key_col,
339            target_col_idx,
340            field_off,
341            bitmap_byte_off,
342            bit_mask,
343            target_type,
344            key_literal_idx: 0,
345            value_literal_idx: 1,
346        })
347    }
348
349    /// Execute a [`PreparedQuery`] with the given literal values.
350    ///
351    /// The literals are substituted into a clone of the template plan in
352    /// the same deterministic walk order that [`crate::canonicalize`]
353    /// produces (filter predicate first, then projection, then assignment
354    /// RHS, and so on). Substitution errors here mean the caller passed
355    /// the wrong number of literals for this query shape.
356    pub fn execute_prepared(
357        &mut self,
358        prep: &PreparedQuery,
359        literals: &[Literal],
360    ) -> Result<QueryResult, QueryError> {
361        if literals.len() != prep.param_count {
362            return Err(QueryError::Execution(format!(
363                "prepared query expects {} literal(s), got {}",
364                prep.param_count,
365                literals.len(),
366            )));
367        }
368
369        // Mission C Phase 14: update-by-pk fast path. Skip plan clone,
370        // substitute walk, resolved_assignments, FastPatch, Vec<RowId>,
371        // RowLayout::new — straight to btree.lookup_int + byte patch.
372        // On rare mismatches (wrong literal type, index dropped after
373        // prepare) the helper returns `Ok(None)` and we fall through to
374        // the generic substitute-and-execute path below.
375        if let Some(fast) = &prep.update_pk_fast {
376            if let Some(result) = self.try_execute_update_pk_fast(fast, literals)? {
377                // Mark dependent views dirty for prepared update fast path.
378                if let PlanNode::Update { table, .. } = &prep.plan_template {
379                    self.view_registry.mark_dependents_dirty(table);
380                }
381                // Mission B (post-review): statement-boundary WAL group
382                // commit. The fast path appended an Update record but did
383                // not flush — flush it now so the executor's contract is
384                // "WAL is on disk before this returns".
385                self.catalog
386                    .commit_autocommit()
387                    .map_err(|e| QueryError::StorageError(e.to_string()))?;
388                return Ok(result);
389            }
390        }
391
392        // Insert fast path: skip plan-clone + substitute walk + PlanNode::Insert
393        // arm's column-index resolution. Build the Row directly from the
394        // caller's literal slice using indices we resolved at prepare time.
395        // Saves ~300-500ns per insert on the bench.
396        //
397        // Mission C Phase 13: the scratch `Vec<Value>` is reused across
398        // calls — no fresh allocation per insert. We split the borrow
399        // between `self.catalog` and `self.insert_values_scratch` by
400        // moving the scratch into a local, filling it, passing to the
401        // catalog, and putting it back.
402        //
403        // Mission C Phase 15: the cached `InsertFast` carries `n_cols`
404        // and the table name, so the hot path makes exactly one catalog
405        // HashMap lookup (`get_table_mut`) and dispatches straight into
406        // `tbl.insert` — no intermediate schema lookup, no generic
407        // `Catalog::insert` wrapper.
408        if let Some(fast) = prep
409            .insert_fast
410            .as_ref()
411            .filter(|fast| cached_table_matches(&self.catalog, fast.structure_generation))
412        {
413            let mut values = std::mem::take(&mut self.insert_values_scratch);
414            values.resize(fast.n_cols, Value::Empty);
415            // Columns omitted by the prepared INSERT must return to NULL on
416            // every execution. Assigned string slots keep their allocation so
417            // repeated prepared inserts copy into stable buffers instead of
418            // allocating one String per field per row.
419            for &index in &fast.omitted_col_indices {
420                values[index] = Value::Empty;
421            }
422            for (pos, lit) in literals.iter().enumerate() {
423                let value = &mut values[fast.col_indices[pos]];
424                let column = &fast.assigned_columns[pos];
425                match (value, lit, column.type_id) {
426                    (Value::Str(buffer), Literal::String(text), TypeId::Str) => {
427                        buffer.clear();
428                        buffer.push_str(text);
429                    }
430                    (value, literal, _) => {
431                        let raw = literal_value_from(literal);
432                        match coerce_value(raw, column) {
433                            Ok(coerced) => *value = coerced,
434                            Err(error) => {
435                                self.insert_values_scratch = values;
436                                return Err(QueryError::Execution(error));
437                            }
438                        }
439                    }
440                }
441            }
442            for &index in &fast.required_col_indices {
443                if matches!(values[index], Value::Empty) {
444                    let column = &fast.schema_columns[index];
445                    self.insert_values_scratch = values;
446                    return Err(QueryError::Execution(format!(
447                        "column '{}' is required but no value was provided",
448                        column.name
449                    )));
450                }
451            }
452            // Mission C Phase 18: direct O(1) slot index — no
453            // catalog hash probe. Slot was resolved at prepare time.
454            // Durability fix: route through the WAL-logging `insert_by_slot`
455            // (was the raw `Table::insert`, which bypassed the WAL and lost
456            // every prepared insert on a crash).
457            let res = self
458                .catalog
459                .insert_by_slot(fast.table_slot, &values)
460                .map_err(|e| e.to_string());
461            // Retain ordinary row buffers, but do not pin an overflow-sized
462            // client string in the engine forever after one prepared insert.
463            for value in &mut values {
464                if matches!(value, Value::Str(buffer) if buffer.capacity() > powdb_storage::page::MAX_ROW_DATA_SIZE)
465                {
466                    *value = Value::Empty;
467                }
468            }
469            // Keep one row's string buffers for the next prepared execution.
470            // This is bounded by the prepared row width and never escapes the
471            // engine; the catalog has already encoded/copied the values.
472            self.insert_values_scratch = values;
473            res?;
474            // Mark dependent views dirty for prepared insert fast path.
475            self.view_registry.mark_dependents_dirty(&fast.table_name);
476            // Mission B (post-review): statement-boundary WAL group commit.
477            self.catalog
478                .commit_autocommit()
479                .map_err(|e| QueryError::StorageError(e.to_string()))?;
480            return Ok(QueryResult::Modified(1));
481        }
482
483        let mut plan = prep.plan_template.clone();
484        let mut idx = 0usize;
485        crate::plan_cache::substitute_plan(&mut plan, literals, &mut idx);
486        debug_assert_eq!(idx, literals.len());
487        let result = self.execute_plan(&plan);
488        // Mission B (post-review): statement-boundary WAL group commit.
489        // No-op when nothing was buffered (read-only plans).
490        self.catalog
491            .commit_autocommit()
492            .map_err(|e| QueryError::StorageError(e.to_string()))?;
493        result
494    }
495
496    /// Mission C Phase 14: point-update fast path for prepared
497    /// `T filter .pk = ? update { col := ? }` queries. The caller has
498    /// already verified this is an int-indexed pk with a fixed-size,
499    /// non-indexed target column; all we do here is pluck the two
500    /// literals out of the caller's slice, run one `btree.lookup_int`,
501    /// and patch 1–8 bytes of the row. No plan clone, no allocations.
502    ///
503    /// Returns:
504    ///   * `Ok(Some(result))` — fast path took the mutation.
505    ///   * `Ok(None)` — can't take the fast path this call (wrong
506    ///     literal type, index dropped since prepare, etc.). Caller
507    ///     falls through to the generic substitute-and-execute path.
508    ///   * `Err(_)` — real error (table gone, I/O, etc.).
509    #[inline]
510    fn try_execute_update_pk_fast(
511        &mut self,
512        fast: &UpdatePkFast,
513        literals: &[Literal],
514    ) -> Result<Option<QueryResult>, QueryError> {
515        if !cached_table_matches(&self.catalog, fast.structure_generation) {
516            return Ok(None);
517        }
518        let current_table = self.catalog.table_by_slot(fast.table_slot);
519        if current_table.has_indexed_col(fast.target_col_idx)
520            || !current_table.has_index(&fast.key_col)
521        {
522            return Ok(None);
523        }
524        // 1) Extract the key literal. The fast path is only built for
525        //    int key columns; any other literal type means the caller
526        //    is violating the prepared-query contract or the schema
527        //    changed — either way, fall back.
528        let key_int = match &literals[fast.key_literal_idx] {
529            Literal::Int(v) => *v,
530            _ => return Ok(None),
531        };
532
533        // 2) Encode the new value as little-endian bytes matching the
534        //    target column's fixed encoding.
535        let bytes: FixedBytes = match (fast.target_type, &literals[fast.value_literal_idx]) {
536            (TypeId::Int, Literal::Int(v)) => FixedBytes::I64(v.to_le_bytes()),
537            (TypeId::DateTime, Literal::Int(v)) => FixedBytes::I64(v.to_le_bytes()),
538            (TypeId::Float, Literal::Float(v)) => FixedBytes::F64(v.to_le_bytes()),
539            (TypeId::Bool, Literal::Bool(v)) => FixedBytes::Bool(if *v { 1 } else { 0 }),
540            // Type mismatch — fall back to the generic path for a
541            // consistent error shape.
542            _ => return Ok(None),
543        };
544
545        // 3) Look up the table + btree, do the int lookup, patch the row
546        //    in place. Phase 18: table dispatch is a direct slot index;
547        //    the btree lookup is the linear scan over `indexed_cols`.
548        //    Single btree.lookup_int + one `with_row_bytes_mut` call.
549        //    No Vec allocations at all.
550        //
551        // Mission B2: route the in-place patch through the catalog's
552        // WAL-logged wrapper so crash recovery sees the update. The
553        // extra cost is one WAL append + fsync per query — the hot
554        // loop structure is unchanged.
555        let tbl = self.catalog.table_by_slot_mut(fast.table_slot);
556        let btree = tbl
557            .index(&fast.key_col)
558            .expect("prepared update index was revalidated above");
559        let Some(rid) = btree.lookup_int(key_int) else {
560            return Ok(Some(QueryResult::Modified(0)));
561        };
562
563        let fast_table_slot = fast.table_slot;
564        let bitmap_byte_off = fast.bitmap_byte_off;
565        let bit_mask = fast.bit_mask;
566        let field_off = fast.field_off;
567        let ok = self
568            .catalog
569            .update_row_bytes_logged_by_slot(fast_table_slot, rid, |row| {
570                let base = if row.len() >= ROW_PREFIX_SIZE && &row[0..4] == ROW_MAGIC {
571                    ROW_PREFIX_SIZE
572                } else {
573                    0
574                };
575                // Idempotent null-bit clear — safe even when the column was
576                // already non-null (the overwhelmingly common case).
577                row[base + bitmap_byte_off] &= !bit_mask;
578                let field_bytes = bytes.as_slice();
579                row[base + field_off..base + field_off + field_bytes.len()]
580                    .copy_from_slice(field_bytes);
581            })
582            .map_err(|e| QueryError::StorageError(e.to_string()))?;
583
584        Ok(Some(QueryResult::Modified(if ok { 1 } else { 0 })))
585    }
586
587    /// Mission C Phase 13: moving variant of [`Engine::execute_prepared`]
588    /// for the insert fast path. Takes `literals` by mutable reference
589    /// so that each `Literal::String` can be consumed via `mem::take`
590    /// instead of cloned into a `Value::Str`. On `insert_batch_1k` that
591    /// removes three per-row heap allocations (name, status, email),
592    /// bringing the workload over the line vs SQLite's amortized
593    /// prepare+execute loop.
594    ///
595    /// The caller's `Literal::String` entries are replaced with empty
596    /// strings on successful inserts — the `literals` slice is *not*
597    /// left in a valid-for-reuse state except for `Int`/`Float`/`Bool`
598    /// values. Non-insert templates fall through to the standard
599    /// substitute-and-execute path.
600    pub fn execute_prepared_take(
601        &mut self,
602        prep: &PreparedQuery,
603        literals: &mut [Literal],
604    ) -> Result<QueryResult, QueryError> {
605        if literals.len() != prep.param_count {
606            return Err(QueryError::Execution(format!(
607                "prepared query expects {} literal(s), got {}",
608                prep.param_count,
609                literals.len(),
610            )));
611        }
612
613        if let Some(fast) = prep
614            .insert_fast
615            .as_ref()
616            .filter(|fast| cached_table_matches(&self.catalog, fast.structure_generation))
617        {
618            // Moving strings is only safe when coercion cannot fail or replace
619            // the string with another representation. Complex/coercing shapes
620            // use the borrowed path; on success we still honor this method's
621            // consume-on-success contract.
622            if !literals
623                .iter()
624                .zip(&fast.assigned_columns)
625                .all(|(literal, column)| literal_can_take_without_error(literal, column))
626            {
627                let result = self.execute_prepared(prep, literals);
628                if result.is_ok() {
629                    for literal in literals {
630                        if let Literal::String(value) = literal {
631                            value.clear();
632                        }
633                    }
634                }
635                return result;
636            }
637            let mut values = std::mem::take(&mut self.insert_values_scratch);
638            values.clear();
639            values.resize(fast.n_cols, Value::Empty);
640            for (pos, lit) in literals.iter_mut().enumerate() {
641                let raw = literal_value_take(lit);
642                match coerce_value(raw, &fast.assigned_columns[pos]) {
643                    Ok(coerced) => values[fast.col_indices[pos]] = coerced,
644                    Err(error) => {
645                        restore_taken_strings(fast, literals, &mut values);
646                        values.clear();
647                        self.insert_values_scratch = values;
648                        return Err(QueryError::Execution(error));
649                    }
650                }
651            }
652            for &index in &fast.required_col_indices {
653                if matches!(values[index], Value::Empty) {
654                    let column = &fast.schema_columns[index];
655                    let error = format!(
656                        "column '{}' is required but no value was provided",
657                        column.name
658                    );
659                    restore_taken_strings(fast, literals, &mut values);
660                    values.clear();
661                    self.insert_values_scratch = values;
662                    return Err(QueryError::Execution(error));
663                }
664            }
665            // Mission C Phase 18: direct O(1) slot index — see
666            // `execute_prepared` for rationale. This is the hot path
667            // for `insert_batch_1k`. Durability fix: WAL-logging
668            // `insert_by_slot` (was the raw `Table::insert`).
669            if let Err(error) = self.catalog.insert_by_slot(fast.table_slot, &values) {
670                restore_taken_strings(fast, literals, &mut values);
671                values.clear();
672                self.insert_values_scratch = values;
673                return Err(QueryError::StorageError(error.to_string()));
674            }
675            self.view_registry.mark_dependents_dirty(&fast.table_name);
676            // Mission B (post-review): statement-boundary WAL group commit.
677            if let Err(error) = self.catalog.commit_autocommit() {
678                restore_taken_strings(fast, literals, &mut values);
679                values.clear();
680                self.insert_values_scratch = values;
681                return Err(QueryError::StorageError(error.to_string()));
682            }
683            values.clear();
684            self.insert_values_scratch = values;
685            return Ok(QueryResult::Modified(1));
686        }
687
688        // Non-insert templates — fall back to the standard path. We
689        // can't usefully move the literals because `substitute_plan`
690        // still expects an immutable slice, and the non-insert hot
691        // paths are dominated by plan walks anyway.
692        let result = self.execute_prepared(prep, literals);
693        if result.is_ok() && matches!(prep.plan_template, PlanNode::Insert { .. }) {
694            for literal in literals {
695                if let Literal::String(value) = literal {
696                    value.clear();
697                }
698            }
699        }
700        result
701    }
702
703    /// Walk an expression tree and replace every `InSubquery` node with
704    /// an `InList` by executing the subquery and collecting its first
705    /// column as literal values. This must be called before entering
706    /// the row-by-row scan loop because the scan closure can't call back
707    /// into the engine.
708    pub(super) fn materialize_subqueries(&mut self, expr: &Expr) -> Result<Expr, QueryError> {
709        match expr {
710            Expr::InSubquery {
711                expr: inner,
712                subquery,
713                negated,
714            } => {
715                if is_correlated_subquery(subquery, &self.catalog) {
716                    let inner = self.materialize_subqueries(inner)?;
717                    return Ok(Expr::InSubquery {
718                        expr: Box::new(inner),
719                        subquery: subquery.clone(),
720                        negated: *negated,
721                    });
722                }
723                let inner = self.materialize_subqueries(inner)?;
724                // Plan and execute the subquery.
725                let sub_plan = crate::planner::plan_statement(Statement::Query(*subquery.clone()))
726                    .map_err(|e| QueryError::StorageError(e.to_string()))?;
727                let result = self.execute_plan(&sub_plan)?;
728                let values = match result {
729                    QueryResult::Rows { rows, .. } => {
730                        let mut values = Vec::with_capacity(rows.len());
731                        let mut cancel = crate::cancel::CancelCheck::new();
732                        for mut row in rows {
733                            cancel.tick()?;
734                            if !row.is_empty() {
735                                values.push(value_to_expr(row.swap_remove(0)));
736                            }
737                        }
738                        values
739                    }
740                    _ => Vec::new(),
741                };
742                // WS2: byte-budget guard on the materialized IN-list.
743                self.charge_in_list(&values)?;
744                Ok(Expr::InList {
745                    expr: Box::new(inner),
746                    list: values,
747                    negated: *negated,
748                })
749            }
750            Expr::ExistsSubquery { subquery, negated } => {
751                if is_correlated_subquery(subquery, &self.catalog) {
752                    return Ok(expr.clone());
753                }
754                // Uncorrelated EXISTS: run the subquery once and collapse
755                // into a Bool literal.
756                let sub_plan = crate::planner::plan_statement(Statement::Query(*subquery.clone()))
757                    .map_err(|e| QueryError::StorageError(e.to_string()))?;
758                let result = self.execute_plan(&sub_plan)?;
759                let has_rows = match result {
760                    QueryResult::Rows { rows, .. } => !rows.is_empty(),
761                    _ => false,
762                };
763                let truth = if *negated { !has_rows } else { has_rows };
764                Ok(Expr::Literal(Literal::Bool(truth)))
765            }
766            Expr::BinaryOp(l, op, r) => {
767                let l = self.materialize_subqueries(l)?;
768                let r = self.materialize_subqueries(r)?;
769                Ok(Expr::BinaryOp(Box::new(l), *op, Box::new(r)))
770            }
771            Expr::UnaryOp(op, inner) => {
772                let inner = self.materialize_subqueries(inner)?;
773                Ok(Expr::UnaryOp(*op, Box::new(inner)))
774            }
775            Expr::Case { whens, else_expr } => {
776                let whens = whens
777                    .iter()
778                    .map(|(c, r)| {
779                        let c = self.materialize_subqueries(c)?;
780                        let r = self.materialize_subqueries(r)?;
781                        Ok((Box::new(c), Box::new(r)))
782                    })
783                    .collect::<Result<Vec<_>, QueryError>>()?;
784                let else_expr = match else_expr {
785                    Some(e) => Some(Box::new(self.materialize_subqueries(e)?)),
786                    None => None,
787                };
788                Ok(Expr::Case { whens, else_expr })
789            }
790            // Leaf nodes: no subqueries possible.
791            other => Ok(other.clone()),
792        }
793    }
794
795    /// Write-path per-row materialisation of correlated subqueries.
796    pub(super) fn materialize_correlated_for_row(
797        &mut self,
798        expr: &Expr,
799        outer_row: &[Value],
800        outer_columns: &[String],
801    ) -> Result<Expr, QueryError> {
802        match expr {
803            Expr::InSubquery {
804                expr: inner,
805                subquery,
806                negated,
807            } => {
808                let inner = self.materialize_correlated_for_row(inner, outer_row, outer_columns)?;
809                let mut sub = *subquery.clone();
810                if let Some(ref filter) = sub.filter {
811                    sub.filter = Some(substitute_outer_refs(
812                        filter,
813                        &sub.source,
814                        &self.catalog,
815                        outer_row,
816                        outer_columns,
817                    ));
818                }
819                let sub_plan = crate::planner::plan_statement(Statement::Query(sub))
820                    .map_err(|e| QueryError::StorageError(e.to_string()))?;
821                let result = self.execute_plan(&sub_plan)?;
822                let values = match result {
823                    QueryResult::Rows { rows, .. } => {
824                        let mut values = Vec::with_capacity(rows.len());
825                        let mut cancel = crate::cancel::CancelCheck::new();
826                        for mut row in rows {
827                            cancel.tick()?;
828                            if !row.is_empty() {
829                                values.push(value_to_expr(row.swap_remove(0)));
830                            }
831                        }
832                        values
833                    }
834                    _ => Vec::new(),
835                };
836                Ok(Expr::InList {
837                    expr: Box::new(inner),
838                    list: values,
839                    negated: *negated,
840                })
841            }
842            Expr::ExistsSubquery { subquery, negated } => {
843                let mut sub = *subquery.clone();
844                if let Some(ref filter) = sub.filter {
845                    sub.filter = Some(substitute_outer_refs(
846                        filter,
847                        &sub.source,
848                        &self.catalog,
849                        outer_row,
850                        outer_columns,
851                    ));
852                }
853                let sub_plan = crate::planner::plan_statement(Statement::Query(sub))
854                    .map_err(|e| QueryError::StorageError(e.to_string()))?;
855                let result = self.execute_plan(&sub_plan)?;
856                let has_rows = match result {
857                    QueryResult::Rows { rows, .. } => !rows.is_empty(),
858                    _ => false,
859                };
860                let truth = if *negated { !has_rows } else { has_rows };
861                Ok(Expr::Literal(Literal::Bool(truth)))
862            }
863            Expr::BinaryOp(l, op, r) => {
864                let l = self.materialize_correlated_for_row(l, outer_row, outer_columns)?;
865                let r = self.materialize_correlated_for_row(r, outer_row, outer_columns)?;
866                Ok(Expr::BinaryOp(Box::new(l), *op, Box::new(r)))
867            }
868            Expr::UnaryOp(op, inner) => {
869                let inner = self.materialize_correlated_for_row(inner, outer_row, outer_columns)?;
870                Ok(Expr::UnaryOp(*op, Box::new(inner)))
871            }
872            other => Ok(other.clone()),
873        }
874    }
875}