#include #include "./subtree.h" #include "./tree.h" #include "./language.h" typedef struct { Subtree parent; const TSTree *tree; Length position; uint32_t child_index; uint32_t structural_child_index; const TSSymbol *alias_sequence; } NodeChildIterator; // TSNode - constructors TSNode ts_node_new(const TSTree *tree, const Subtree *subtree, Length position, TSSymbol alias) { return (TSNode) { {position.bytes, position.extent.row, position.extent.column, alias}, subtree, tree, }; } static inline TSNode ts_node__null(void) { return ts_node_new(NULL, NULL, length_zero(), 0); } // TSNode - accessors uint32_t ts_node_start_byte(TSNode self) { return self.context[0]; } TSPoint ts_node_start_point(TSNode self) { return (TSPoint) {self.context[1], self.context[2]}; } static inline uint32_t ts_node__alias(const TSNode *self) { return self->context[3]; } static inline Subtree ts_node__subtree(TSNode self) { return *(const Subtree *)self.id; } // NodeChildIterator static inline NodeChildIterator ts_node_iterate_children(const TSNode *node) { Subtree subtree = ts_node__subtree(*node); if (ts_subtree_child_count(subtree) == 0) { return (NodeChildIterator) {NULL_SUBTREE, node->tree, length_zero(), 0, 0, NULL}; } const TSSymbol *alias_sequence = ts_language_alias_sequence( node->tree->language, subtree.ptr->production_id ); return (NodeChildIterator) { .tree = node->tree, .parent = subtree, .position = {ts_node_start_byte(*node), ts_node_start_point(*node)}, .child_index = 0, .structural_child_index = 0, .alias_sequence = alias_sequence, }; } static inline bool ts_node_child_iterator_done(NodeChildIterator *self) { return self->child_index == self->parent.ptr->child_count; } static inline bool ts_node_child_iterator_next(NodeChildIterator *self, TSNode *result) { if (!self->parent.ptr || ts_node_child_iterator_done(self)) return false; const Subtree *child = &self->parent.ptr->children[self->child_index]; TSSymbol alias_symbol = 0; if (!ts_subtree_extra(*child)) { if (self->alias_sequence) { alias_symbol = self->alias_sequence[self->structural_child_index]; } self->structural_child_index++; } if (self->child_index > 0) { self->position = length_add(self->position, ts_subtree_padding(*child)); } *result = ts_node_new( self->tree, child, self->position, alias_symbol ); self->position = length_add(self->position, ts_subtree_size(*child)); self->child_index++; return true; } // TSNode - private static inline bool ts_node__is_relevant(TSNode self, bool include_anonymous) { Subtree tree = ts_node__subtree(self); if (include_anonymous) { return ts_subtree_visible(tree) || ts_node__alias(&self); } else { return (ts_subtree_visible(tree) && ts_subtree_named(tree)) || (ts_node__alias(&self) && ts_language_symbol_metadata(self.tree->language, ts_node__alias(&self)).named); } } static inline uint32_t ts_node__relevant_child_count(TSNode self, bool include_anonymous) { Subtree tree = ts_node__subtree(self); if (ts_subtree_child_count(tree) > 0) { if (include_anonymous) { return tree.ptr->visible_child_count; } else { return tree.ptr->named_child_count; } } else { return 0; } } static inline TSNode ts_node__child(TSNode self, uint32_t child_index, bool include_anonymous) { TSNode result = self; bool did_descend = true; while (did_descend) { did_descend = false; TSNode child; uint32_t index = 0; NodeChildIterator iterator = ts_node_iterate_children(&result); while (ts_node_child_iterator_next(&iterator, &child)) { if (ts_node__is_relevant(child, include_anonymous)) { if (index == child_index) { ts_tree_set_cached_parent(self.tree, &child, &self); return child; } index++; } else { uint32_t grandchild_index = child_index - index; uint32_t grandchild_count = ts_node__relevant_child_count(child, include_anonymous); if (grandchild_index < grandchild_count) { did_descend = true; result = child; child_index = grandchild_index; break; } index += grandchild_count; } } } return ts_node__null(); } static bool ts_subtree_has_trailing_empty_descendant(Subtree self, Subtree other) { for (unsigned i = ts_subtree_child_count(self) - 1; i + 1 > 0; i--) { Subtree child = self.ptr->children[i]; if (ts_subtree_total_bytes(child) > 0) break; if (child.ptr == other.ptr || ts_subtree_has_trailing_empty_descendant(child, other)) { return true; } } return false; } static inline TSNode ts_node__prev_sibling(TSNode self, bool include_anonymous) { Subtree self_subtree = ts_node__subtree(self); bool self_is_empty = ts_subtree_total_bytes(self_subtree) == 0; uint32_t target_end_byte = ts_node_end_byte(self); TSNode node = ts_node_parent(self); TSNode earlier_node = ts_node__null(); bool earlier_node_is_relevant = false; while (!ts_node_is_null(node)) { TSNode earlier_child = ts_node__null(); bool earlier_child_is_relevant = false; bool found_child_containing_target = false; TSNode child; NodeChildIterator iterator = ts_node_iterate_children(&node); while (ts_node_child_iterator_next(&iterator, &child)) { if (child.id == self.id) break; if (iterator.position.bytes > target_end_byte) { found_child_containing_target = true; break; } if (iterator.position.bytes == target_end_byte && (!self_is_empty || ts_subtree_has_trailing_empty_descendant(ts_node__subtree(child), self_subtree))) { found_child_containing_target = true; break; } if (ts_node__is_relevant(child, include_anonymous)) { earlier_child = child; earlier_child_is_relevant = true; } else if (ts_node__relevant_child_count(child, include_anonymous) > 0) { earlier_child = child; earlier_child_is_relevant = false; } } if (found_child_containing_target) { if (!ts_node_is_null(earlier_child)) { earlier_node = earlier_child; earlier_node_is_relevant = earlier_child_is_relevant; } node = child; } else if (earlier_child_is_relevant) { return earlier_child; } else if (!ts_node_is_null(earlier_child)) { node = earlier_child; } else if (earlier_node_is_relevant) { return earlier_node; } else { node = earlier_node; } } return ts_node__null(); } static inline TSNode ts_node__next_sibling(TSNode self, bool include_anonymous) { uint32_t target_end_byte = ts_node_end_byte(self); TSNode node = ts_node_parent(self); TSNode later_node = ts_node__null(); bool later_node_is_relevant = false; while (!ts_node_is_null(node)) { TSNode later_child = ts_node__null(); bool later_child_is_relevant = false; TSNode child_containing_target = ts_node__null(); TSNode child; NodeChildIterator iterator = ts_node_iterate_children(&node); while (ts_node_child_iterator_next(&iterator, &child)) { if (iterator.position.bytes < target_end_byte) continue; if (ts_node_start_byte(child) <= ts_node_start_byte(self)) { if (ts_node__subtree(child).ptr != ts_node__subtree(self).ptr) { child_containing_target = child; } } else if (ts_node__is_relevant(child, include_anonymous)) { later_child = child; later_child_is_relevant = true; break; } else if (ts_node__relevant_child_count(child, include_anonymous) > 0) { later_child = child; later_child_is_relevant = false; break; } } if (!ts_node_is_null(child_containing_target)) { if (!ts_node_is_null(later_child)) { later_node = later_child; later_node_is_relevant = later_child_is_relevant; } node = child_containing_target; } else if (later_child_is_relevant) { return later_child; } else if (!ts_node_is_null(later_child)) { node = later_child; } else if (later_node_is_relevant) { return later_node; } else { node = later_node; } } return ts_node__null(); } static inline bool point_gt(TSPoint self, TSPoint other) { return self.row > other.row || (self.row == other.row && self.column > other.column); } static inline TSNode ts_node__first_child_for_byte(TSNode self, uint32_t goal, bool include_anonymous) { TSNode node = self; bool did_descend = true; while (did_descend) { did_descend = false; TSNode child; NodeChildIterator iterator = ts_node_iterate_children(&node); while (ts_node_child_iterator_next(&iterator, &child)) { if (ts_node_end_byte(child) > goal) { if (ts_node__is_relevant(child, include_anonymous)) { return child; } else if (ts_node_child_count(child) > 0) { did_descend = true; node = child; break; } } } } return ts_node__null(); } static inline TSNode ts_node__descendant_for_byte_range(TSNode self, uint32_t min, uint32_t max, bool include_anonymous) { TSNode node = self; TSNode last_visible_node = self; bool did_descend = true; while (did_descend) { did_descend = false; TSNode child; NodeChildIterator iterator = ts_node_iterate_children(&node); while (ts_node_child_iterator_next(&iterator, &child)) { if (max <= iterator.position.bytes) { if (ts_node_start_byte(child) > min) break; node = child; if (ts_node__is_relevant(node, include_anonymous)) { ts_tree_set_cached_parent(self.tree, &child, &last_visible_node); last_visible_node = node; } did_descend = true; break; } } } return last_visible_node; } static inline TSNode ts_node__descendant_for_point_range(TSNode self, TSPoint min, TSPoint max, bool include_anonymous) { TSNode node = self; TSNode last_visible_node = self; bool did_descend = true; while (did_descend) { did_descend = false; TSNode child; NodeChildIterator iterator = ts_node_iterate_children(&node); while (ts_node_child_iterator_next(&iterator, &child)) { if (point_lte(max, iterator.position.extent)) { if (point_gt(ts_node_start_point(child), min)) break; node = child; if (ts_node__is_relevant(node, include_anonymous)) { ts_tree_set_cached_parent(self.tree, &child, &last_visible_node); last_visible_node = node; } did_descend = true; break; } } } return last_visible_node; } // TSNode - public uint32_t ts_node_end_byte(TSNode self) { return ts_node_start_byte(self) + ts_subtree_size(ts_node__subtree(self)).bytes; } TSPoint ts_node_end_point(TSNode self) { return point_add(ts_node_start_point(self), ts_subtree_size(ts_node__subtree(self)).extent); } TSSymbol ts_node_symbol(TSNode self) { return ts_node__alias(&self) ? ts_node__alias(&self) : ts_subtree_symbol(ts_node__subtree(self)); } const char *ts_node_type(TSNode self) { return ts_language_symbol_name(self.tree->language, ts_node_symbol(self)); } char *ts_node_string(TSNode self) { return ts_subtree_string(ts_node__subtree(self), self.tree->language, false); } bool ts_node_eq(TSNode self, TSNode other) { return self.tree == other.tree && self.id == other.id; } bool ts_node_is_null(TSNode self) { return self.id == 0; } bool ts_node_is_named(TSNode self) { return ts_node__alias(&self) ? ts_language_symbol_metadata(self.tree->language, ts_node__alias(&self)).named : ts_subtree_named(ts_node__subtree(self)); } bool ts_node_is_missing(TSNode self) { return ts_subtree_missing(ts_node__subtree(self)); } bool ts_node_has_changes(TSNode self) { return ts_subtree_has_changes(ts_node__subtree(self)); } bool ts_node_has_error(TSNode self) { return ts_subtree_error_cost(ts_node__subtree(self)) > 0; } TSNode ts_node_parent(TSNode self) { TSNode node = ts_tree_get_cached_parent(self.tree, &self); if (node.id) return node; node = ts_tree_root_node(self.tree); uint32_t end_byte = ts_node_end_byte(self); if (node.id == self.id) return ts_node__null(); TSNode last_visible_node = node; bool did_descend = true; while (did_descend) { did_descend = false; TSNode child; NodeChildIterator iterator = ts_node_iterate_children(&node); while (ts_node_child_iterator_next(&iterator, &child)) { if ( ts_node_start_byte(child) > ts_node_start_byte(self) || child.id == self.id ) break; if (iterator.position.bytes >= end_byte) { node = child; if (ts_node__is_relevant(child, true)) { ts_tree_set_cached_parent(self.tree, &node, &last_visible_node); last_visible_node = node; } did_descend = true; break; } } } return last_visible_node; } TSNode ts_node_child(TSNode self, uint32_t child_index) { return ts_node__child(self, child_index, true); } TSNode ts_node_named_child(TSNode self, uint32_t child_index) { return ts_node__child(self, child_index, false); } TSNode ts_node_child_by_field_id(TSNode self, TSFieldId field_id) { recur: if (!field_id || ts_node_child_count(self) == 0) return ts_node__null(); const TSFieldMapEntry *field_map, *field_map_end; ts_language_field_map( self.tree->language, ts_node__subtree(self).ptr->production_id, &field_map, &field_map_end ); if (field_map == field_map_end) return ts_node__null(); // The field mappings are sorted by their field id. Scan all // the mappings to find the ones for the given field id. while (field_map->field_id < field_id) { field_map++; if (field_map == field_map_end) return ts_node__null(); } while (field_map_end[-1].field_id > field_id) { field_map_end--; if (field_map == field_map_end) return ts_node__null(); } TSNode child; NodeChildIterator iterator = ts_node_iterate_children(&self); while (ts_node_child_iterator_next(&iterator, &child)) { if (!ts_subtree_extra(ts_node__subtree(child))) { uint32_t index = iterator.structural_child_index - 1; if (index < field_map->child_index) continue; // Hidden nodes' fields are "inherited" by their visible parent. if (field_map->inherited) { // If this is the *last* possible child node for this field, // then perform a tail call to avoid recursion. if (field_map + 1 == field_map_end) { self = child; goto recur; } // Otherwise, descend into this child, but if it doesn't contain // the field, continue searching subsequent children. else { TSNode result = ts_node_child_by_field_id(child, field_id); if (result.id) return result; field_map++; if (field_map == field_map_end) return ts_node__null(); } } else if (ts_node__is_relevant(child, true)) { return child; } // If the field refers to a hidden node, return its first visible // child. else { return ts_node_child(child, 0); } } } return ts_node__null(); } TSNode ts_node_child_by_field_name( TSNode self, const char *name, uint32_t name_length ) { TSFieldId field_id = ts_language_field_id_for_name( self.tree->language, name, name_length ); return ts_node_child_by_field_id(self, field_id); } uint32_t ts_node_child_count(TSNode self) { Subtree tree = ts_node__subtree(self); if (ts_subtree_child_count(tree) > 0) { return tree.ptr->visible_child_count; } else { return 0; } } uint32_t ts_node_named_child_count(TSNode self) { Subtree tree = ts_node__subtree(self); if (ts_subtree_child_count(tree) > 0) { return tree.ptr->named_child_count; } else { return 0; } } TSNode ts_node_next_sibling(TSNode self) { return ts_node__next_sibling(self, true); } TSNode ts_node_next_named_sibling(TSNode self) { return ts_node__next_sibling(self, false); } TSNode ts_node_prev_sibling(TSNode self) { return ts_node__prev_sibling(self, true); } TSNode ts_node_prev_named_sibling(TSNode self) { return ts_node__prev_sibling(self, false); } TSNode ts_node_first_child_for_byte(TSNode self, uint32_t byte) { return ts_node__first_child_for_byte(self, byte, true); } TSNode ts_node_first_named_child_for_byte(TSNode self, uint32_t byte) { return ts_node__first_child_for_byte(self, byte, false); } TSNode ts_node_descendant_for_byte_range(TSNode self, uint32_t min, uint32_t max) { return ts_node__descendant_for_byte_range(self, min, max, true); } TSNode ts_node_named_descendant_for_byte_range(TSNode self, uint32_t min, uint32_t max) { return ts_node__descendant_for_byte_range(self, min, max, false); } TSNode ts_node_descendant_for_point_range(TSNode self, TSPoint min, TSPoint max) { return ts_node__descendant_for_point_range(self, min, max, true); } TSNode ts_node_named_descendant_for_point_range(TSNode self, TSPoint min, TSPoint max) { return ts_node__descendant_for_point_range(self, min, max, false); } void ts_node_edit(TSNode *self, const TSInputEdit *edit) { uint32_t start_byte = ts_node_start_byte(*self); TSPoint start_point = ts_node_start_point(*self); if (start_byte >= edit->old_end_byte) { start_byte = edit->new_end_byte + (start_byte - edit->old_end_byte); start_point = point_add(edit->new_end_point, point_sub(start_point, edit->old_end_point)); } else if (start_byte > edit->start_byte) { start_byte = edit->new_end_byte; start_point = edit->new_end_point; } self->context[0] = start_byte; self->context[1] = start_point.row; self->context[2] = start_point.column; }