minishell/parser/nsrc/get_changed_ranges.c

#include "./get_changed_ranges.h"
#include "./error_costs.h"
#include "./language.h"
#include "./subtree.h"
#include "./tree_cursor.h"
#include <assert.h>

// #define DEBUG_GET_CHANGED_RANGES

static void ts_range_array_add(TSRangeArray *self, Length start, Length end)
{
	if (self->size > 0)
	{
		TSRange *last_range = array_back(self);
		if (start.bytes <= last_range->end_byte)
		{
			last_range->end_byte = end.bytes;
			last_range->end_point = end.extent;
			return;
		}
	}

	if (start.bytes < end.bytes)
	{
		TSRange range = {start.extent, end.extent, start.bytes, end.bytes};
		array_push(self, range);
	}
}

bool ts_range_array_intersects(const TSRangeArray *self, unsigned start_index, uint32_t start_byte, uint32_t end_byte)
{
	for (unsigned i = start_index; i < self->size; i++)
	{
		TSRange *range = &self->contents[i];
		if (range->end_byte > start_byte)
		{
			if (range->start_byte >= end_byte)
				break;
			return true;
		}
	}
	return false;
}

void ts_range_array_get_changed_ranges(const TSRange *old_ranges, unsigned old_range_count, const TSRange *new_ranges,
									   unsigned new_range_count, TSRangeArray *differences)
{
	unsigned new_index = 0;
	unsigned old_index = 0;
	Length	 current_position = length_zero();
	bool	 in_old_range = false;
	bool	 in_new_range = false;

	while (old_index < old_range_count || new_index < new_range_count)
	{
		const TSRange *old_range = &old_ranges[old_index];
		const TSRange *new_range = &new_ranges[new_index];

		Length next_old_position;
		if (in_old_range)
		{
			next_old_position = (Length){old_range->end_byte, old_range->end_point};
		}
		else if (old_index < old_range_count)
		{
			next_old_position = (Length){old_range->start_byte, old_range->start_point};
		}
		else
		{
			next_old_position = LENGTH_MAX;
		}

		Length next_new_position;
		if (in_new_range)
		{
			next_new_position = (Length){new_range->end_byte, new_range->end_point};
		}
		else if (new_index < new_range_count)
		{
			next_new_position = (Length){new_range->start_byte, new_range->start_point};
		}
		else
		{
			next_new_position = LENGTH_MAX;
		}

		if (next_old_position.bytes < next_new_position.bytes)
		{
			if (in_old_range != in_new_range)
			{
				ts_range_array_add(differences, current_position, next_old_position);
			}
			if (in_old_range)
				old_index++;
			current_position = next_old_position;
			in_old_range = !in_old_range;
		}
		else if (next_new_position.bytes < next_old_position.bytes)
		{
			if (in_old_range != in_new_range)
			{
				ts_range_array_add(differences, current_position, next_new_position);
			}
			if (in_new_range)
				new_index++;
			current_position = next_new_position;
			in_new_range = !in_new_range;
		}
		else
		{
			if (in_old_range != in_new_range)
			{
				ts_range_array_add(differences, current_position, next_new_position);
			}
			if (in_old_range)
				old_index++;
			if (in_new_range)
				new_index++;
			in_old_range = !in_old_range;
			in_new_range = !in_new_range;
			current_position = next_new_position;
		}
	}
}

typedef struct Iterator
{
	TreeCursor		  cursor;
	const TSLanguage *language;
	unsigned		  visible_depth;
	bool			  in_padding;
} Iterator;

static Iterator iterator_new(TreeCursor *cursor, const Subtree *tree, const TSLanguage *language)
{
	array_clear(&cursor->stack);
	array_push(&cursor->stack, ((TreeCursorEntry){
								   .subtree = tree,
								   .position = length_zero(),
								   .child_index = 0,
								   .structural_child_index = 0,
							   }));
	return (Iterator){
		.cursor = *cursor,
		.language = language,
		.visible_depth = 1,
		.in_padding = false,
	};
}

static bool iterator_done(Iterator *self)
{
	return self->cursor.stack.size == 0;
}

static Length iterator_start_position(Iterator *self)
{
	TreeCursorEntry entry = *array_back(&self->cursor.stack);
	if (self->in_padding)
	{
		return entry.position;
	}
	else
	{
		return length_add(entry.position, ts_subtree_padding(*entry.subtree));
	}
}

static Length iterator_end_position(Iterator *self)
{
	TreeCursorEntry entry = *array_back(&self->cursor.stack);
	Length			result = length_add(entry.position, ts_subtree_padding(*entry.subtree));
	if (self->in_padding)
	{
		return result;
	}
	else
	{
		return length_add(result, ts_subtree_size(*entry.subtree));
	}
}

static bool iterator_tree_is_visible(const Iterator *self)
{
	TreeCursorEntry entry = *array_back(&self->cursor.stack);
	if (ts_subtree_visible(*entry.subtree))
		return true;
	if (self->cursor.stack.size > 1)
	{
		Subtree parent = *self->cursor.stack.contents[self->cursor.stack.size - 2].subtree;
		return ts_language_alias_at(self->language, parent.ptr->inner.non_terminal.production_id, entry.structural_child_index) != 0;
	}
	return false;
}

static void iterator_get_visible_state(const Iterator *self, Subtree *tree, TSSymbol *alias_symbol, uint32_t *start_byte)
{
	uint32_t i = self->cursor.stack.size - 1;

	if (self->in_padding)
	{
		if (i == 0)
			return;
		i--;
	}

	for (; i + 1 > 0; i--)
	{
		TreeCursorEntry entry = self->cursor.stack.contents[i];

		if (i > 0)
		{
			const Subtree *parent = self->cursor.stack.contents[i - 1].subtree;
			*alias_symbol = ts_language_alias_at(self->language, parent->ptr->inner.non_terminal.production_id, entry.structural_child_index);
		}

		if (ts_subtree_visible(*entry.subtree) || *alias_symbol)
		{
			*tree = *entry.subtree;
			*start_byte = entry.position.bytes;
			break;
		}
	}
}

static void iterator_ascend(Iterator *self)
{
	if (iterator_done(self))
		return;
	if (iterator_tree_is_visible(self) && !self->in_padding)
		self->visible_depth--;
	if (array_back(&self->cursor.stack)->child_index > 0)
		self->in_padding = false;
	self->cursor.stack.size--;
}

static bool iterator_descend(Iterator *self, uint32_t goal_position)
{
	if (self->in_padding)
		return false;

	bool did_descend = false;
	do
	{
		did_descend = false;
		TreeCursorEntry entry = *array_back(&self->cursor.stack);
		Length			position = entry.position;
		uint32_t		structural_child_index = 0;
		for (uint32_t i = 0, n = ts_subtree_child_count(*entry.subtree); i < n; i++)
		{
			const Subtree *child = &ts_subtree_children(*entry.subtree)[i];
			Length		   child_left = length_add(position, ts_subtree_padding(*child));
			Length		   child_right = length_add(child_left, ts_subtree_size(*child));

			if (child_right.bytes > goal_position)
			{
				array_push(&self->cursor.stack, ((TreeCursorEntry){
													.subtree = child,
													.position = position,
													.child_index = i,
													.structural_child_index = structural_child_index,
												}));

				if (iterator_tree_is_visible(self))
				{
					if (child_left.bytes > goal_position)
					{
						self->in_padding = true;
					}
					else
					{
						self->visible_depth++;
					}
					return true;
				}

				did_descend = true;
				break;
			}

			position = child_right;
			if (!ts_subtree_extra(*child))
				structural_child_index++;
		}
	} while (did_descend);

	return false;
}

static void iterator_advance(Iterator *self)
{
	if (self->in_padding)
	{
		self->in_padding = false;
		if (iterator_tree_is_visible(self))
		{
			self->visible_depth++;
		}
		else
		{
			iterator_descend(self, 0);
		}
		return;
	}

	for (;;)
	{
		if (iterator_tree_is_visible(self))
			self->visible_depth--;
		TreeCursorEntry entry = array_pop(&self->cursor.stack);
		if (iterator_done(self))
			return;

		const Subtree *parent = array_back(&self->cursor.stack)->subtree;
		uint32_t	   child_index = entry.child_index + 1;
		if (ts_subtree_child_count(*parent) > child_index)
		{
			Length	 position = length_add(entry.position, ts_subtree_total_size(*entry.subtree));
			uint32_t structural_child_index = entry.structural_child_index;
			if (!ts_subtree_extra(*entry.subtree))
				structural_child_index++;
			const Subtree *next_child = &ts_subtree_children(*parent)[child_index];

			array_push(&self->cursor.stack, ((TreeCursorEntry){
												.subtree = next_child,
												.position = position,
												.child_index = child_index,
												.structural_child_index = structural_child_index,
											}));

			if (iterator_tree_is_visible(self))
			{
				if (ts_subtree_padding(*next_child).bytes > 0)
				{
					self->in_padding = true;
				}
				else
				{
					self->visible_depth++;
				}
			}
			else
			{
				iterator_descend(self, 0);
			}
			break;
		}
	}
}

typedef enum IteratorComparison
{
	IteratorDiffers,
	IteratorMayDiffer,
	IteratorMatches,
} IteratorComparison;

static IteratorComparison iterator_compare(const Iterator *old_iter, const Iterator *new_iter)
{
	Subtree	 old_tree = NULL_SUBTREE;
	Subtree	 new_tree = NULL_SUBTREE;
	uint32_t old_start = 0;
	uint32_t new_start = 0;
	TSSymbol old_alias_symbol = 0;
	TSSymbol new_alias_symbol = 0;
	iterator_get_visible_state(old_iter, &old_tree, &old_alias_symbol, &old_start);
	iterator_get_visible_state(new_iter, &new_tree, &new_alias_symbol, &new_start);

	if (!old_tree.ptr && !new_tree.ptr)
		return IteratorMatches;
	if (!old_tree.ptr || !new_tree.ptr)
		return IteratorDiffers;

	if (old_alias_symbol == new_alias_symbol && ts_subtree_symbol(old_tree) == ts_subtree_symbol(new_tree))
	{
		if (old_start == new_start && !ts_subtree_has_changes(old_tree) && ts_subtree_symbol(old_tree) != ts_builtin_sym_error &&
			ts_subtree_size(old_tree).bytes == ts_subtree_size(new_tree).bytes && ts_subtree_parse_state(old_tree) != TS_TREE_STATE_NONE &&
			ts_subtree_parse_state(new_tree) != TS_TREE_STATE_NONE &&
			(ts_subtree_parse_state(old_tree) == ERROR_STATE) == (ts_subtree_parse_state(new_tree) == ERROR_STATE))
		{
			return IteratorMatches;
		}
		else
		{
			return IteratorMayDiffer;
		}
	}

	return IteratorDiffers;
}

#ifdef DEBUG_GET_CHANGED_RANGES
static inline void iterator_print_state(Iterator *self)
{
	TreeCursorEntry entry = *array_back(&self->cursor.stack);
	TSPoint			start = iterator_start_position(self).extent;
	TSPoint			end = iterator_end_position(self).extent;
	const char	   *name = ts_language_symbol_name(self->language, ts_subtree_symbol(*entry.subtree));
	printf("(%-25s %s\t depth:%u [%u, %u] - [%u, %u])", name, self->in_padding ? "(p)" : "   ", self->visible_depth, start.row + 1,
		   start.column, end.row + 1, end.column);
}
#endif

unsigned ts_subtree_get_changed_ranges(const Subtree *old_tree, const Subtree *new_tree, TreeCursor *cursor1, TreeCursor *cursor2,
									   const TSLanguage *language, const TSRangeArray *included_range_differences, TSRange **ranges)
{
	TSRangeArray results = array_new();

	Iterator old_iter = iterator_new(cursor1, old_tree, language);
	Iterator new_iter = iterator_new(cursor2, new_tree, language);

	unsigned included_range_difference_index = 0;

	Length position = iterator_start_position(&old_iter);
	Length next_position = iterator_start_position(&new_iter);
	if (position.bytes < next_position.bytes)
	{
		ts_range_array_add(&results, position, next_position);
		position = next_position;
	}
	else if (position.bytes > next_position.bytes)
	{
		ts_range_array_add(&results, next_position, position);
		next_position = position;
	}

	do
	{
#ifdef DEBUG_GET_CHANGED_RANGES
		printf("At [%-2u, %-2u] Compare ", position.extent.row + 1, position.extent.column);
		iterator_print_state(&old_iter);
		printf("\tvs\t");
		iterator_print_state(&new_iter);
		puts("");
#endif

		// Compare the old and new subtrees.
		IteratorComparison comparison = iterator_compare(&old_iter, &new_iter);

		// Even if the two subtrees appear to be identical, they could differ
		// internally if they contain a range of text that was previously
		// excluded from the parse, and is now included, or vice-versa.
		if (comparison == IteratorMatches && ts_range_array_intersects(included_range_differences, included_range_difference_index,
																	   position.bytes, iterator_end_position(&old_iter).bytes))
		{
			comparison = IteratorMayDiffer;
		}

		bool is_changed = false;
		switch (comparison)
		{
		// If the subtrees are definitely identical, move to the end
		// of both subtrees.
		case IteratorMatches:
			next_position = iterator_end_position(&old_iter);
			break;

		// If the subtrees might differ internally, descend into both
		// subtrees, finding the first child that spans the current position.
		case IteratorMayDiffer:
			if (iterator_descend(&old_iter, position.bytes))
			{
				if (!iterator_descend(&new_iter, position.bytes))
				{
					is_changed = true;
					next_position = iterator_end_position(&old_iter);
				}
			}
			else if (iterator_descend(&new_iter, position.bytes))
			{
				is_changed = true;
				next_position = iterator_end_position(&new_iter);
			}
			else
			{
				next_position = length_min(iterator_end_position(&old_iter), iterator_end_position(&new_iter));
			}
			break;

		// If the subtrees are different, record a change and then move
		// to the end of both subtrees.
		case IteratorDiffers:
			is_changed = true;
			next_position = length_min(iterator_end_position(&old_iter), iterator_end_position(&new_iter));
			break;
		}

		// Ensure that both iterators are caught up to the current position.
		while (!iterator_done(&old_iter) && iterator_end_position(&old_iter).bytes <= next_position.bytes)
			iterator_advance(&old_iter);
		while (!iterator_done(&new_iter) && iterator_end_position(&new_iter).bytes <= next_position.bytes)
			iterator_advance(&new_iter);

		// Ensure that both iterators are at the same depth in the tree.
		while (old_iter.visible_depth > new_iter.visible_depth)
		{
			iterator_ascend(&old_iter);
		}
		while (new_iter.visible_depth > old_iter.visible_depth)
		{
			iterator_ascend(&new_iter);
		}

		if (is_changed)
		{
#ifdef DEBUG_GET_CHANGED_RANGES
			printf("  change: [[%u, %u] - [%u, %u]]\n", position.extent.row + 1, position.extent.column, next_position.extent.row + 1,
				   next_position.extent.column);
#endif

			ts_range_array_add(&results, position, next_position);
		}

		position = next_position;

		// Keep track of the current position in the included range differences
		// array in order to avoid scanning the entire array on each iteration.
		while (included_range_difference_index < included_range_differences->size)
		{
			const TSRange *range = &included_range_differences->contents[included_range_difference_index];
			if (range->end_byte <= position.bytes)
			{
				included_range_difference_index++;
			}
			else
			{
				break;
			}
		}
	} while (!iterator_done(&old_iter) && !iterator_done(&new_iter));

	Length old_size = ts_subtree_total_size(*old_tree);
	Length new_size = ts_subtree_total_size(*new_tree);
	if (old_size.bytes < new_size.bytes)
	{
		ts_range_array_add(&results, old_size, new_size);
	}
	else if (new_size.bytes < old_size.bytes)
	{
		ts_range_array_add(&results, new_size, old_size);
	}

	*cursor1 = old_iter.cursor;
	*cursor2 = new_iter.cursor;
	*ranges = results.contents;
	return results.size;
}