#include "./alloc.h" #include "./language.h" #include "./subtree.h" #include "./array.h" #include "./stack.h" #include "./length.h" #include #include #define MAX_LINK_COUNT 8 #define MAX_NODE_POOL_SIZE 50 #define MAX_ITERATOR_COUNT 64 #ifdef _WIN32 #define inline __forceinline #else #define inline static inline __attribute__((always_inline)) #endif typedef struct StackNode StackNode; typedef struct { StackNode *node; Subtree subtree; bool is_pending; } StackLink; struct StackNode { TSStateId state; Length position; StackLink links[MAX_LINK_COUNT]; short unsigned int link_count; uint32_t ref_count; unsigned error_cost; unsigned node_count; int dynamic_precedence; }; typedef struct { StackNode *node; SubtreeArray subtrees; uint32_t subtree_count; bool is_pending; } StackIterator; typedef struct { void *payload; StackIterateCallback callback; } StackIterateSession; typedef Array(StackNode *) StackNodeArray; typedef enum { StackStatusActive, StackStatusPaused, StackStatusHalted, } StackStatus; typedef struct { StackNode *node; Subtree last_external_token; StackSummary *summary; unsigned node_count_at_last_error; TSSymbol lookahead_when_paused; StackStatus status; } StackHead; struct Stack { Array(StackHead) heads; StackSliceArray slices; Array(StackIterator) iterators; StackNodeArray node_pool; StackNode *base_node; SubtreePool *subtree_pool; }; typedef unsigned StackAction; enum { StackActionNone, StackActionStop = 1, StackActionPop = 2, }; typedef StackAction (*StackCallback)(void *, const StackIterator *); static void stack_node_retain(StackNode *self) { if (!self) return; assert(self->ref_count > 0); self->ref_count++; assert(self->ref_count != 0); } static void stack_node_release(StackNode *self, StackNodeArray *pool, SubtreePool *subtree_pool) { recur: assert(self->ref_count != 0); self->ref_count--; if (self->ref_count > 0) return; StackNode *first_predecessor = NULL; if (self->link_count > 0) { for (unsigned i = self->link_count - 1; i > 0; i--) { StackLink link = self->links[i]; if (link.subtree.ptr) ts_subtree_release(subtree_pool, link.subtree); stack_node_release(link.node, pool, subtree_pool); } StackLink link = self->links[0]; if (link.subtree.ptr) ts_subtree_release(subtree_pool, link.subtree); first_predecessor = self->links[0].node; } if (pool->size < MAX_NODE_POOL_SIZE) { array_push(pool, self); } else { ts_free(self); } if (first_predecessor) { self = first_predecessor; goto recur; } } static StackNode *stack_node_new(StackNode *previous_node, Subtree subtree, bool is_pending, TSStateId state, StackNodeArray *pool) { StackNode *node = pool->size > 0 ? array_pop(pool) : ts_malloc(sizeof(StackNode)); *node = (StackNode){.ref_count = 1, .link_count = 0, .state = state}; if (previous_node) { node->link_count = 1; node->links[0] = (StackLink){ .node = previous_node, .subtree = subtree, .is_pending = is_pending, }; node->position = previous_node->position; node->error_cost = previous_node->error_cost; node->dynamic_precedence = previous_node->dynamic_precedence; node->node_count = previous_node->node_count; if (subtree.ptr) { node->error_cost += ts_subtree_error_cost(subtree); node->position = length_add(node->position, ts_subtree_total_size(subtree)); node->node_count += ts_subtree_node_count(subtree); node->dynamic_precedence += ts_subtree_dynamic_precedence(subtree); } } else { node->position = length_zero(); node->error_cost = 0; } return node; } static bool stack__subtree_is_equivalent(Subtree left, Subtree right) { return left.ptr == right.ptr || (left.ptr && right.ptr && ts_subtree_symbol(left) == ts_subtree_symbol(right) && ((ts_subtree_error_cost(left) > 0 && ts_subtree_error_cost(right) > 0) || (ts_subtree_padding(left).bytes == ts_subtree_padding(right).bytes && ts_subtree_size(left).bytes == ts_subtree_size(right).bytes && ts_subtree_child_count(left) == ts_subtree_child_count(right) && ts_subtree_extra(left) == ts_subtree_extra(right) && ts_subtree_external_scanner_state_eq(left, right)))); } static void stack_node_add_link(StackNode *self, StackLink link, SubtreePool *subtree_pool) { if (link.node == self) return; for (int i = 0; i < self->link_count; i++) { StackLink *existing_link = &self->links[i]; if (stack__subtree_is_equivalent(existing_link->subtree, link.subtree)) { // In general, we preserve ambiguities until they are removed from the stack // during a pop operation where multiple paths lead to the same node. But in // the special case where two links directly connect the same pair of nodes, // we can safely remove the ambiguity ahead of time without changing behavior. if (existing_link->node == link.node) { if ( ts_subtree_dynamic_precedence(link.subtree) > ts_subtree_dynamic_precedence(existing_link->subtree) ) { ts_subtree_retain(link.subtree); ts_subtree_release(subtree_pool, existing_link->subtree); existing_link->subtree = link.subtree; self->dynamic_precedence = link.node->dynamic_precedence + ts_subtree_dynamic_precedence(link.subtree); } return; } // If the previous nodes are mergeable, merge them recursively. if (existing_link->node->state == link.node->state && existing_link->node->position.bytes == link.node->position.bytes) { for (int j = 0; j < link.node->link_count; j++) { stack_node_add_link(existing_link->node, link.node->links[j], subtree_pool); } int32_t dynamic_precedence = link.node->dynamic_precedence; if (link.subtree.ptr) { dynamic_precedence += ts_subtree_dynamic_precedence(link.subtree); } if (dynamic_precedence > self->dynamic_precedence) { self->dynamic_precedence = dynamic_precedence; } return; } } } if (self->link_count == MAX_LINK_COUNT) return; stack_node_retain(link.node); unsigned node_count = link.node->node_count; int dynamic_precedence = link.node->dynamic_precedence; self->links[self->link_count++] = link; if (link.subtree.ptr) { ts_subtree_retain(link.subtree); node_count += ts_subtree_node_count(link.subtree); dynamic_precedence += ts_subtree_dynamic_precedence(link.subtree); } if (node_count > self->node_count) self->node_count = node_count; if (dynamic_precedence > self->dynamic_precedence) self->dynamic_precedence = dynamic_precedence; } static void stack_head_delete(StackHead *self, StackNodeArray *pool, SubtreePool *subtree_pool) { if (self->node) { if (self->last_external_token.ptr) { ts_subtree_release(subtree_pool, self->last_external_token); } if (self->summary) { array_delete(self->summary); ts_free(self->summary); } stack_node_release(self->node, pool, subtree_pool); } } static StackVersion ts_stack__add_version(Stack *self, StackVersion original_version, StackNode *node) { StackHead head = { .node = node, .node_count_at_last_error = self->heads.contents[original_version].node_count_at_last_error, .last_external_token = self->heads.contents[original_version].last_external_token, .status = StackStatusActive, .lookahead_when_paused = 0, }; array_push(&self->heads, head); stack_node_retain(node); if (head.last_external_token.ptr) ts_subtree_retain(head.last_external_token); return (StackVersion)(self->heads.size - 1); } static void ts_stack__add_slice(Stack *self, StackVersion original_version, StackNode *node, SubtreeArray *subtrees) { for (uint32_t i = self->slices.size - 1; i + 1 > 0; i--) { StackVersion version = self->slices.contents[i].version; if (self->heads.contents[version].node == node) { StackSlice slice = {*subtrees, version}; array_insert(&self->slices, i + 1, slice); return; } } StackVersion version = ts_stack__add_version(self, original_version, node); StackSlice slice = { *subtrees, version }; array_push(&self->slices, slice); } inline StackSliceArray stack__iter(Stack *self, StackVersion version, StackCallback callback, void *payload, int goal_subtree_count) { array_clear(&self->slices); array_clear(&self->iterators); StackHead *head = array_get(&self->heads, version); StackIterator iterator = { .node = head->node, .subtrees = array_new(), .subtree_count = 0, .is_pending = true, }; bool include_subtrees = false; if (goal_subtree_count >= 0) { include_subtrees = true; array_reserve(&iterator.subtrees, goal_subtree_count); } array_push(&self->iterators, iterator); while (self->iterators.size > 0) { for (uint32_t i = 0, size = self->iterators.size; i < size; i++) { StackIterator *iterator = &self->iterators.contents[i]; StackNode *node = iterator->node; StackAction action = callback(payload, iterator); bool should_pop = action & StackActionPop; bool should_stop = action & StackActionStop || node->link_count == 0; if (should_pop) { SubtreeArray subtrees = iterator->subtrees; if (!should_stop) ts_subtree_array_copy(subtrees, &subtrees); ts_subtree_array_reverse(&subtrees); ts_stack__add_slice( self, version, node, &subtrees ); } if (should_stop) { if (!should_pop) ts_subtree_array_delete(self->subtree_pool, &iterator->subtrees); array_erase(&self->iterators, i); i--, size--; continue; } for (uint32_t j = 1; j <= node->link_count; j++) { StackIterator *next_iterator; StackLink link; if (j == node->link_count) { link = node->links[0]; next_iterator = &self->iterators.contents[i]; } else { if (self->iterators.size >= MAX_ITERATOR_COUNT) continue; link = node->links[j]; StackIterator current_iterator = self->iterators.contents[i]; array_push(&self->iterators, current_iterator); next_iterator = array_back(&self->iterators); ts_subtree_array_copy(next_iterator->subtrees, &next_iterator->subtrees); } next_iterator->node = link.node; if (link.subtree.ptr) { if (include_subtrees) { array_push(&next_iterator->subtrees, link.subtree); ts_subtree_retain(link.subtree); } if (!ts_subtree_extra(link.subtree)) { next_iterator->subtree_count++; if (!link.is_pending) { next_iterator->is_pending = false; } } } else { next_iterator->subtree_count++; next_iterator->is_pending = false; } } } } return self->slices; } Stack *ts_stack_new(SubtreePool *subtree_pool) { Stack *self = ts_calloc(1, sizeof(Stack)); array_init(&self->heads); array_init(&self->slices); array_init(&self->iterators); array_init(&self->node_pool); array_reserve(&self->heads, 4); array_reserve(&self->slices, 4); array_reserve(&self->iterators, 4); array_reserve(&self->node_pool, MAX_NODE_POOL_SIZE); self->subtree_pool = subtree_pool; self->base_node = stack_node_new(NULL, NULL_SUBTREE, false, 1, &self->node_pool); ts_stack_clear(self); return self; } void ts_stack_delete(Stack *self) { if (self->slices.contents) array_delete(&self->slices); if (self->iterators.contents) array_delete(&self->iterators); stack_node_release(self->base_node, &self->node_pool, self->subtree_pool); for (uint32_t i = 0; i < self->heads.size; i++) { stack_head_delete(&self->heads.contents[i], &self->node_pool, self->subtree_pool); } array_clear(&self->heads); if (self->node_pool.contents) { for (uint32_t i = 0; i < self->node_pool.size; i++) ts_free(self->node_pool.contents[i]); array_delete(&self->node_pool); } array_delete(&self->heads); ts_free(self); } uint32_t ts_stack_version_count(const Stack *self) { return self->heads.size; } TSStateId ts_stack_state(const Stack *self, StackVersion version) { return array_get(&self->heads, version)->node->state; } Length ts_stack_position(const Stack *self, StackVersion version) { return array_get(&self->heads, version)->node->position; } Subtree ts_stack_last_external_token(const Stack *self, StackVersion version) { return array_get(&self->heads, version)->last_external_token; } void ts_stack_set_last_external_token(Stack *self, StackVersion version, Subtree token) { StackHead *head = array_get(&self->heads, version); if (token.ptr) ts_subtree_retain(token); if (head->last_external_token.ptr) ts_subtree_release(self->subtree_pool, head->last_external_token); head->last_external_token = token; } unsigned ts_stack_error_cost(const Stack *self, StackVersion version) { StackHead *head = array_get(&self->heads, version); unsigned result = head->node->error_cost; if ( head->status == StackStatusPaused || (head->node->state == ERROR_STATE && !head->node->links[0].subtree.ptr)) { result += ERROR_COST_PER_RECOVERY; } return result; } unsigned ts_stack_node_count_since_error(const Stack *self, StackVersion version) { StackHead *head = array_get(&self->heads, version); if (head->node->node_count < head->node_count_at_last_error) { head->node_count_at_last_error = head->node->node_count; } return head->node->node_count - head->node_count_at_last_error; } void ts_stack_push(Stack *self, StackVersion version, Subtree subtree, bool pending, TSStateId state) { StackHead *head = array_get(&self->heads, version); StackNode *new_node = stack_node_new(head->node, subtree, pending, state, &self->node_pool); if (!subtree.ptr) head->node_count_at_last_error = new_node->node_count; head->node = new_node; } inline StackAction iterate_callback(void *payload, const StackIterator *iterator) { StackIterateSession *session = payload; session->callback( session->payload, iterator->node->state, iterator->subtree_count ); return StackActionNone; } void ts_stack_iterate(Stack *self, StackVersion version, StackIterateCallback callback, void *payload) { StackIterateSession session = {payload, callback}; stack__iter(self, version, iterate_callback, &session, -1); } inline StackAction pop_count_callback(void *payload, const StackIterator *iterator) { unsigned *goal_subtree_count = payload; if (iterator->subtree_count == *goal_subtree_count) { return StackActionPop | StackActionStop; } else { return StackActionNone; } } StackSliceArray ts_stack_pop_count(Stack *self, StackVersion version, uint32_t count) { return stack__iter(self, version, pop_count_callback, &count, count); } inline StackAction pop_pending_callback(void *payload, const StackIterator *iterator) { if (iterator->subtree_count >= 1) { if (iterator->is_pending) { return StackActionPop | StackActionStop; } else { return StackActionStop; } } else { return StackActionNone; } } StackSliceArray ts_stack_pop_pending(Stack *self, StackVersion version) { StackSliceArray pop = stack__iter(self, version, pop_pending_callback, NULL, 0); if (pop.size > 0) { ts_stack_renumber_version(self, pop.contents[0].version, version); pop.contents[0].version = version; } return pop; } inline StackAction pop_error_callback(void *payload, const StackIterator *iterator) { if (iterator->subtrees.size > 0) { bool *found_error = payload; if (!*found_error && ts_subtree_is_error(iterator->subtrees.contents[0])) { *found_error = true; return StackActionPop | StackActionStop; } else { return StackActionStop; } } else { return StackActionNone; } } SubtreeArray ts_stack_pop_error(Stack *self, StackVersion version) { StackNode *node = array_get(&self->heads, version)->node; for (unsigned i = 0; i < node->link_count; i++) { if (node->links[i].subtree.ptr && ts_subtree_is_error(node->links[i].subtree)) { bool found_error = false; StackSliceArray pop = stack__iter(self, version, pop_error_callback, &found_error, 1); if (pop.size > 0) { assert(pop.size == 1); ts_stack_renumber_version(self, pop.contents[0].version, version); return pop.contents[0].subtrees; } break; } } return (SubtreeArray){.size = 0}; } inline StackAction pop_all_callback(void *payload, const StackIterator *iterator) { return iterator->node->link_count == 0 ? StackActionPop : StackActionNone; } StackSliceArray ts_stack_pop_all(Stack *self, StackVersion version) { return stack__iter(self, version, pop_all_callback, NULL, 0); } typedef struct { StackSummary *summary; unsigned max_depth; } SummarizeStackSession; inline StackAction summarize_stack_callback(void *payload, const StackIterator *iterator) { SummarizeStackSession *session = payload; TSStateId state = iterator->node->state; unsigned depth = iterator->subtree_count; if (depth > session->max_depth) return StackActionStop; for (unsigned i = session->summary->size - 1; i + 1 > 0; i--) { StackSummaryEntry entry = session->summary->contents[i]; if (entry.depth < depth) break; if (entry.depth == depth && entry.state == state) return StackActionNone; } array_push(session->summary, ((StackSummaryEntry){ .position = iterator->node->position, .depth = depth, .state = state, })); return StackActionNone; } void ts_stack_record_summary(Stack *self, StackVersion version, unsigned max_depth) { SummarizeStackSession session = { .summary = ts_malloc(sizeof(StackSummary)), .max_depth = max_depth }; array_init(session.summary); stack__iter(self, version, summarize_stack_callback, &session, -1); self->heads.contents[version].summary = session.summary; } StackSummary *ts_stack_get_summary(Stack *self, StackVersion version) { return array_get(&self->heads, version)->summary; } int ts_stack_dynamic_precedence(Stack *self, StackVersion version) { return array_get(&self->heads, version)->node->dynamic_precedence; } bool ts_stack_has_advanced_since_error(const Stack *self, StackVersion version) { const StackHead *head = array_get(&self->heads, version); const StackNode *node = head->node; if (node->error_cost == 0) return true; while (node) { if (node->link_count > 0) { Subtree subtree = node->links[0].subtree; if (subtree.ptr) { if (ts_subtree_total_bytes(subtree) > 0) { return true; } else if ( node->node_count > head->node_count_at_last_error && ts_subtree_error_cost(subtree) == 0 ) { node = node->links[0].node; continue; } } } break; } return false; } void ts_stack_remove_version(Stack *self, StackVersion version) { stack_head_delete(array_get(&self->heads, version), &self->node_pool, self->subtree_pool); array_erase(&self->heads, version); } void ts_stack_renumber_version(Stack *self, StackVersion v1, StackVersion v2) { if (v1 == v2) return; assert(v2 < v1); assert((uint32_t)v1 < self->heads.size); StackHead *source_head = &self->heads.contents[v1]; StackHead *target_head = &self->heads.contents[v2]; if (target_head->summary && !source_head->summary) { source_head->summary = target_head->summary; target_head->summary = NULL; } stack_head_delete(target_head, &self->node_pool, self->subtree_pool); *target_head = *source_head; array_erase(&self->heads, v1); } void ts_stack_swap_versions(Stack *self, StackVersion v1, StackVersion v2) { StackHead temporary_head = self->heads.contents[v1]; self->heads.contents[v1] = self->heads.contents[v2]; self->heads.contents[v2] = temporary_head; } StackVersion ts_stack_copy_version(Stack *self, StackVersion version) { assert(version < self->heads.size); array_push(&self->heads, self->heads.contents[version]); StackHead *head = array_back(&self->heads); stack_node_retain(head->node); if (head->last_external_token.ptr) ts_subtree_retain(head->last_external_token); head->summary = NULL; return self->heads.size - 1; } bool ts_stack_merge(Stack *self, StackVersion version1, StackVersion version2) { if (!ts_stack_can_merge(self, version1, version2)) return false; StackHead *head1 = &self->heads.contents[version1]; StackHead *head2 = &self->heads.contents[version2]; for (uint32_t i = 0; i < head2->node->link_count; i++) { stack_node_add_link(head1->node, head2->node->links[i], self->subtree_pool); } if (head1->node->state == ERROR_STATE) { head1->node_count_at_last_error = head1->node->node_count; } ts_stack_remove_version(self, version2); return true; } bool ts_stack_can_merge(Stack *self, StackVersion version1, StackVersion version2) { StackHead *head1 = &self->heads.contents[version1]; StackHead *head2 = &self->heads.contents[version2]; return head1->status == StackStatusActive && head2->status == StackStatusActive && head1->node->state == head2->node->state && head1->node->position.bytes == head2->node->position.bytes && head1->node->error_cost == head2->node->error_cost && ts_subtree_external_scanner_state_eq(head1->last_external_token, head2->last_external_token); } void ts_stack_halt(Stack *self, StackVersion version) { array_get(&self->heads, version)->status = StackStatusHalted; } void ts_stack_pause(Stack *self, StackVersion version, TSSymbol lookahead) { StackHead *head = array_get(&self->heads, version); head->status = StackStatusPaused; head->lookahead_when_paused = lookahead; head->node_count_at_last_error = head->node->node_count; } bool ts_stack_is_active(const Stack *self, StackVersion version) { return array_get(&self->heads, version)->status == StackStatusActive; } bool ts_stack_is_halted(const Stack *self, StackVersion version) { return array_get(&self->heads, version)->status == StackStatusHalted; } bool ts_stack_is_paused(const Stack *self, StackVersion version) { return array_get(&self->heads, version)->status == StackStatusPaused; } TSSymbol ts_stack_resume(Stack *self, StackVersion version) { StackHead *head = array_get(&self->heads, version); assert(head->status == StackStatusPaused); TSSymbol result = head->lookahead_when_paused; head->status = StackStatusActive; head->lookahead_when_paused = 0; return result; } void ts_stack_clear(Stack *self) { stack_node_retain(self->base_node); for (uint32_t i = 0; i < self->heads.size; i++) { stack_head_delete(&self->heads.contents[i], &self->node_pool, self->subtree_pool); } array_clear(&self->heads); array_push(&self->heads, ((StackHead){ .node = self->base_node, .last_external_token = NULL_SUBTREE, .status = StackStatusActive, .lookahead_when_paused = 0, })); } bool ts_stack_print_dot_graph(Stack *self, const TSLanguage *language, FILE *f) { array_reserve(&self->iterators, 32); bool was_recording_allocations = ts_toggle_allocation_recording(false); if (!f) f = stderr; fprintf(f, "digraph stack {\n"); fprintf(f, "rankdir=\"RL\";\n"); fprintf(f, "edge [arrowhead=none]\n"); Array(StackNode *) visited_nodes = array_new(); array_clear(&self->iterators); for (uint32_t i = 0; i < self->heads.size; i++) { StackHead *head = &self->heads.contents[i]; if (head->status == StackStatusHalted) continue; fprintf(f, "node_head_%u [shape=none, label=\"\"]\n", i); fprintf(f, "node_head_%u -> node_%p [", i, head->node); if (head->status == StackStatusPaused) { fprintf(f, "color=red "); } fprintf(f, "label=%u, fontcolor=blue, weight=10000, labeltooltip=\"node_count: %u\nerror_cost: %u", i, ts_stack_node_count_since_error(self, i), ts_stack_error_cost(self, i) ); if (head->last_external_token.ptr) { const ExternalScannerState *state = &head->last_external_token.ptr->external_scanner_state; const char *data = ts_external_scanner_state_data(state); fprintf(f, "\nexternal_scanner_state:"); for (uint32_t j = 0; j < state->length; j++) fprintf(f, " %2X", data[j]); } fprintf(f, "\"]\n"); array_push(&self->iterators, ((StackIterator){.node = head->node })); } bool all_iterators_done = false; while (!all_iterators_done) { all_iterators_done = true; for (uint32_t i = 0; i < self->iterators.size; i++) { StackIterator iterator = self->iterators.contents[i]; StackNode *node = iterator.node; for (uint32_t j = 0; j < visited_nodes.size; j++) { if (visited_nodes.contents[j] == node) { node = NULL; break; } } if (!node) continue; all_iterators_done = false; fprintf(f, "node_%p [", node); if (node->state == ERROR_STATE) { fprintf(f, "label=\"?\""); } else if ( node->link_count == 1 && node->links[0].subtree.ptr && ts_subtree_extra(node->links[0].subtree) ) { fprintf(f, "shape=point margin=0 label=\"\""); } else { fprintf(f, "label=\"%d\"", node->state); } fprintf( f, " tooltip=\"position: %u,%u\nnode_count:%u\nerror_cost: %u\ndynamic_precedence: %d\"];\n", node->position.extent.row + 1, node->position.extent.column, node->node_count, node->error_cost, node->dynamic_precedence ); for (int j = 0; j < node->link_count; j++) { StackLink link = node->links[j]; fprintf(f, "node_%p -> node_%p [", node, link.node); if (link.is_pending) fprintf(f, "style=dashed "); if (link.subtree.ptr && ts_subtree_extra(link.subtree)) fprintf(f, "fontcolor=gray "); if (!link.subtree.ptr) { fprintf(f, "color=red"); } else { fprintf(f, "label=\""); bool quoted = ts_subtree_visible(link.subtree) && !ts_subtree_named(link.subtree); if (quoted) fprintf(f, "'"); const char *name = ts_language_symbol_name(language, ts_subtree_symbol(link.subtree)); for (const char *c = name; *c; c++) { if (*c == '\"' || *c == '\\') fprintf(f, "\\"); fprintf(f, "%c", *c); } if (quoted) fprintf(f, "'"); fprintf(f, "\""); fprintf( f, "labeltooltip=\"error_cost: %u\ndynamic_precedence: %u\"", ts_subtree_error_cost(link.subtree), ts_subtree_dynamic_precedence(link.subtree) ); } fprintf(f, "];\n"); StackIterator *next_iterator; if (j == 0) { next_iterator = &self->iterators.contents[i]; } else { array_push(&self->iterators, iterator); next_iterator = array_back(&self->iterators); } next_iterator->node = link.node; } array_push(&visited_nodes, node); } } fprintf(f, "}\n"); array_delete(&visited_nodes); ts_toggle_allocation_recording(was_recording_allocations); return true; } #undef inline