#include #include #include #include #include #include "tree_sitter/parser.h" #include "runtime/alloc.h" #include "runtime/tree.h" #include "runtime/length.h" #include "runtime/error_costs.h" TSStateId TS_TREE_STATE_NONE = USHRT_MAX; TSTree *ts_tree_make_leaf(TSSymbol sym, TSLength padding, TSLength size, TSSymbolMetadata metadata) { TSTree *result = ts_malloc(sizeof(TSTree)); if (!result) return NULL; *result = (TSTree){ .ref_count = 1, .symbol = sym, .size = size, .child_count = 0, .visible_child_count = 0, .named_child_count = 0, .children = NULL, .padding = padding, .visible = metadata.visible, .named = metadata.named, .first_leaf.symbol = sym, }; return result; } bool ts_tree_array_copy(TreeArray self, TreeArray *dest) { TSTree **contents = NULL; if (self.capacity > 0) { contents = ts_calloc(self.capacity, sizeof(TSTree *)); if (!contents) return false; memcpy(contents, self.contents, self.size * sizeof(TSTree *)); for (size_t i = 0; i < self.size; i++) ts_tree_retain(contents[i]); } dest->size = self.size; dest->capacity = self.capacity; dest->contents = contents; return true; } void ts_tree_array_delete(TreeArray *self) { for (size_t i = 0; i < self->size; i++) ts_tree_release(self->contents[i]); array_delete(self); } size_t ts_tree_array_essential_count(const TreeArray *self) { size_t result = 0; for (size_t i = 0; i < self->size; i++) { TSTree *tree = self->contents[i]; if (!tree->extra && tree->symbol != ts_builtin_sym_error) result++; } return result; } TSTree *ts_tree_make_error(TSLength size, TSLength padding, char lookahead_char) { TSTree *result = ts_tree_make_leaf(ts_builtin_sym_error, padding, size, (TSSymbolMetadata){ .visible = true, .named = true, }); if (!result) return NULL; result->fragile_left = true; result->fragile_right = true; result->lookahead_char = lookahead_char; return result; } TSTree *ts_tree_make_copy(TSTree *self) { TSTree *result = ts_malloc(sizeof(TSTree)); if (!result) return NULL; *result = *self; result->ref_count = 1; return result; } void ts_tree_assign_parents(TSTree *self) { TSLength offset; recur: offset = ts_length_zero(); for (size_t i = 0; i < self->child_count; i++) { TSTree *child = self->children[i]; if (child->context.parent != self || child->context.index != i) { child->context.parent = self; child->context.index = i; child->context.offset = offset; if (i == self->child_count - 1) { self = child; goto recur; } ts_tree_assign_parents(child); } offset = ts_length_add(offset, ts_tree_total_size(child)); } } void ts_tree_set_children(TSTree *self, size_t child_count, TSTree **children) { if (self->child_count > 0) ts_free(self->children); self->children = children; self->child_count = child_count; self->named_child_count = 0; self->visible_child_count = 0; self->error_cost = 0; for (size_t i = 0; i < child_count; i++) { TSTree *child = children[i]; if (i == 0) { self->padding = child->padding; self->size = child->size; } else { self->size = ts_length_add(self->size, ts_tree_total_size(child)); } self->error_cost += child->error_cost; if (child->visible) { self->visible_child_count++; if (child->named) self->named_child_count++; } else { self->visible_child_count += child->visible_child_count; self->named_child_count += child->named_child_count; } if (child->symbol == ts_builtin_sym_error) { self->fragile_left = self->fragile_right = true; self->parse_state = TS_TREE_STATE_NONE; } } if (self->symbol == ts_builtin_sym_error) { self->error_cost += ERROR_COST_PER_SKIPPED_CHAR * self->size.chars + ERROR_COST_PER_SKIPPED_LINE * self->size.extent.row; for (size_t i = 0; i < child_count; i++) if (!self->children[i]->extra) self->error_cost += ERROR_COST_PER_SKIPPED_TREE; } if (child_count > 0) { self->first_leaf = children[0]->first_leaf; if (children[0]->fragile_left) self->fragile_left = true; if (children[child_count - 1]->fragile_right) self->fragile_right = true; } } TSTree *ts_tree_make_node(TSSymbol symbol, size_t child_count, TSTree **children, TSSymbolMetadata metadata) { TSTree *result = ts_tree_make_leaf(symbol, ts_length_zero(), ts_length_zero(), metadata); if (!result) return NULL; ts_tree_set_children(result, child_count, children); return result; } TSTree *ts_tree_make_error_node(TreeArray *children) { for (size_t i = 0; i < children->size; i++) { TSTree *child = children->contents[i]; if (child->symbol == ts_builtin_sym_error && child->child_count > 0) { if (!array_splice(children, i, 1, child->child_count, child->children)) return NULL; i += child->child_count - 1; for (size_t j = 0; j < child->child_count; j++) ts_tree_retain(child->children[j]); ts_tree_release(child); } } TSTree *result = ts_tree_make_node( ts_builtin_sym_error, children->size, children->contents, (TSSymbolMetadata){.extra = false, .visible = true, .named = true }); if (!result) return NULL; result->fragile_left = true; result->fragile_right = true; return result; } void ts_tree_retain(TSTree *self) { assert(self->ref_count > 0); self->ref_count++; } void ts_tree_release(TSTree *self) { if (!self) return; recur: assert(self->ref_count > 0); self->ref_count--; if (self->ref_count == 0) { if (self->child_count > 0) { for (size_t i = 0; i < self->child_count - 1; i++) ts_tree_release(self->children[i]); TSTree *last_child = self->children[self->child_count - 1]; ts_free(self->children); ts_free(self); self = last_child; goto recur; } ts_free(self); } } size_t ts_tree_start_column(const TSTree *self) { size_t column = self->padding.extent.column; if (self->padding.extent.row > 0) return column; for (const TSTree *tree = self; tree != NULL; tree = tree->context.parent) { column += tree->context.offset.extent.column; if (tree->context.offset.extent.row > 0) break; } return column; } size_t ts_tree_end_column(const TSTree *self) { size_t result = self->size.extent.column; if (self->size.extent.row == 0) result += ts_tree_start_column(self); return result; } bool ts_tree_eq(const TSTree *self, const TSTree *other) { if (self) { if (!other) return false; } else { return !other; } if (self->symbol != other->symbol) return false; if (self->visible != other->visible) return false; if (self->named != other->named) return false; if (self->symbol == ts_builtin_sym_error) return self->lookahead_char == other->lookahead_char; if (self->child_count != other->child_count) return false; if (self->visible_child_count != other->visible_child_count) return false; if (self->named_child_count != other->named_child_count) return false; for (size_t i = 0; i < self->child_count; i++) if (!ts_tree_eq(self->children[i], other->children[i])) return false; return true; } int ts_tree_compare(const TSTree *left, const TSTree *right) { if (left->symbol < right->symbol) return -1; if (right->symbol < left->symbol) return 1; if (left->child_count < right->child_count) return -1; if (right->child_count < left->child_count) return 1; for (size_t i = 0; i < left->child_count; i++) { TSTree *left_child = left->children[i]; TSTree *right_child = right->children[i]; switch (ts_tree_compare(left_child, right_child)) { case -1: return -1; case 1: return 1; default: break; } } return 0; } static inline long min(long a, long b) { return a <= b ? a : b; } void ts_tree_edit(TSTree *self, const TSInputEdit *edit) { size_t old_end_byte = edit->start_byte + edit->bytes_removed; size_t new_end_byte = edit->start_byte + edit->bytes_added; TSPoint old_end_point = ts_point_add(edit->start_point, edit->extent_removed); TSPoint new_end_point = ts_point_add(edit->start_point, edit->extent_added); assert(old_end_byte <= ts_tree_total_bytes(self)); self->has_changes = true; if (edit->start_byte < self->padding.bytes) { ts_length_set_unknown(&self->padding); if (self->padding.bytes >= old_end_byte) { size_t trailing_padding_bytes = self->padding.bytes - old_end_byte; TSPoint trailing_padding_extent = ts_point_sub(self->padding.extent, old_end_point); self->padding.bytes = new_end_byte + trailing_padding_bytes; self->padding.extent = ts_point_add(new_end_point, trailing_padding_extent); } else { ts_length_set_unknown(&self->size); size_t removed_content_bytes = old_end_byte - self->padding.bytes; TSPoint removed_content_extent = ts_point_sub(old_end_point, self->padding.extent); self->size.bytes = self->size.bytes - removed_content_bytes; self->size.extent = ts_point_sub(self->size.extent, removed_content_extent); self->padding.bytes = new_end_byte; self->padding.extent = new_end_point; } } else if (edit->start_byte == self->padding.bytes && edit->bytes_removed == 0) { ts_length_set_unknown(&self->padding); self->padding.bytes = self->padding.bytes + edit->bytes_added; self->padding.extent = ts_point_add(self->padding.extent, edit->extent_added); } else { ts_length_set_unknown(&self->size); size_t trailing_content_bytes = ts_tree_total_bytes(self) - old_end_byte; TSPoint trailing_content_extent = ts_point_sub(ts_tree_total_extent(self), old_end_point); self->size.bytes = new_end_byte + trailing_content_bytes - self->padding.bytes; self->size.extent = ts_point_sub(ts_point_add(new_end_point, trailing_content_extent), self->padding.extent); } bool found_first_child = false; long remaining_bytes_to_delete = 0; TSPoint remaining_extent_to_delete = {0, 0}; TSLength child_left, child_right = ts_length_zero(); for (size_t i = 0; i < self->child_count; i++) { TSTree *child = self->children[i]; child_left = child_right; if (!found_first_child) { child_right = ts_length_add(child_left, ts_tree_total_size(child)); if (child_right.bytes >= edit->start_byte) { found_first_child = true; TSInputEdit child_edit = { .start_byte = edit->start_byte - child_left.bytes, .bytes_added = edit->bytes_added, .bytes_removed = edit->bytes_removed, .start_point = ts_point_sub(edit->start_point, child_left.extent), .extent_added = edit->extent_added, .extent_removed = edit->extent_removed, }; if (old_end_byte > child_right.bytes) { child_edit.bytes_removed = child_right.bytes - edit->start_byte; child_edit.extent_removed = ts_point_sub(child_right.extent, edit->start_point); remaining_bytes_to_delete = old_end_byte - child_right.bytes; remaining_extent_to_delete = ts_point_sub(old_end_point, child_right.extent); } ts_tree_edit(child, &child_edit); } } else if (remaining_bytes_to_delete > 0) { TSInputEdit child_edit = { .start_byte = 0, .bytes_added = 0, .bytes_removed = min(remaining_bytes_to_delete, ts_tree_total_bytes(child)), .start_point = {0, 0}, .extent_added = {0, 0}, .extent_removed = ts_point_min(remaining_extent_to_delete, ts_tree_total_size(child).extent), }; remaining_bytes_to_delete -= child_edit.bytes_removed; remaining_extent_to_delete = ts_point_sub(remaining_extent_to_delete, child_edit.extent_removed); ts_tree_edit(child, &child_edit); } child_right = ts_length_add(child_left, ts_tree_total_size(child)); child->context.offset = child_left; } } static size_t ts_tree__write_char_to_string(char *s, size_t n, int32_t c) { if (c == 0) return snprintf(s, n, "EOF"); else if (c < 128) return snprintf(s, n, "'%c'", c); else return snprintf(s, n, "%d", c); } static size_t ts_tree__write_to_string(const TSTree *self, const TSLanguage *language, char *string, size_t limit, bool is_root, bool include_all) { if (!self) return snprintf(string, limit, "(NULL)"); char *cursor = string; char **writer = (limit > 0) ? &cursor : &string; bool visible = include_all || is_root || (self->visible && self->named); if (visible && !is_root) cursor += snprintf(*writer, limit, " "); if (visible) { if (self->symbol == ts_builtin_sym_error && self->child_count == 0 && self->size.chars > 0) { cursor += snprintf(*writer, limit, "(UNEXPECTED "); cursor += ts_tree__write_char_to_string(*writer, limit, self->lookahead_char); } else { cursor += snprintf(*writer, limit, "(%s", ts_language_symbol_name(language, self->symbol)); } } for (size_t i = 0; i < self->child_count; i++) { TSTree *child = self->children[i]; cursor += ts_tree__write_to_string(child, language, *writer, limit, false, include_all); } if (visible) cursor += snprintf(*writer, limit, ")"); return cursor - string; } char *ts_tree_string(const TSTree *self, const TSLanguage *language, bool include_all) { static char SCRATCH[1]; size_t size = ts_tree__write_to_string(self, language, SCRATCH, 0, true, include_all) + 1; char *result = ts_malloc(size * sizeof(char)); ts_tree__write_to_string(self, language, result, size, true, include_all); return result; } void ts_tree__print_dot_graph(const TSTree *self, size_t offset, const TSLanguage *language, FILE *f) { fprintf(f, "tree_%p [label=\"%s\"", self, ts_language_symbol_name(language, self->symbol)); if (self->child_count == 0) fprintf(f, ", shape=plaintext"); if (self->extra) fprintf(f, ", fontcolor=gray"); fprintf(f, ", tooltip=\"range:%lu - %lu\nstate:%d\nerror-cost:%u\"]\n", offset, offset + ts_tree_total_chars(self), self->parse_state, self->error_cost); for (size_t i = 0; i < self->child_count; i++) { const TSTree *child = self->children[i]; ts_tree__print_dot_graph(child, offset, language, f); fprintf(f, "tree_%p -> tree_%p [tooltip=%lu]\n", self, child, i); offset += ts_tree_total_chars(child); } } void ts_tree_print_dot_graph(const TSTree *self, const TSLanguage *language, FILE *f) { fprintf(f, "digraph tree {\n"); fprintf(f, "edge [arrowhead=none]\n"); ts_tree__print_dot_graph(self, 0, language, f); fprintf(f, "}\n"); }