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@ -75,60 +75,64 @@ fn find_pair(
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) -> Option<usize> {
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let pos = doc.char_to_byte(pos_);
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let root = syntax.tree_for_byte_range(pos, pos + 1).root_node();
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let mut node = root.descendant_for_byte_range(pos, pos + 1)?;
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let root = syntax.tree_for_byte_range(pos, pos).root_node();
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let mut node = root.descendant_for_byte_range(pos, pos)?;
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loop {
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if node.is_named() {
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let (start_byte, end_byte) = surrounding_bytes(doc, &node)?;
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let (start_char, end_char) = (doc.byte_to_char(start_byte), doc.byte_to_char(end_byte));
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if node.is_named() && node.child_count() >= 2 {
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let open = node.child(0).unwrap();
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let close = node.child(node.child_count() - 1).unwrap();
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if is_valid_pair_on_pos(doc, start_char, end_char) {
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if end_byte == pos {
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return Some(start_char);
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if let (Some((start_pos, open)), Some((end_pos, close))) =
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(as_char(doc, &open), as_char(doc, &close))
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{
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if PAIRS.contains(&(open, close)) {
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if start_pos == pos_ {
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return Some(start_pos);
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}
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// We return the end char if the cursor is either on the start char
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// or at some arbitrary position between start and end char.
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if traverse_parents || start_byte == pos {
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return Some(end_char);
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if traverse_parents || end_pos == pos_ {
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return Some(end_pos);
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}
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}
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}
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}
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// this node itselt wasn't a pair but maybe its siblings are
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// check if we are *on* the pair (special cased so we don't look
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// at the current node twice and to jump to the start on that case)
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if let Some(open) = as_close_pair(doc, &node) {
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if let Some(pair_start) = find_pair_end(doc, node.prev_sibling(), open, Backward) {
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if let Some((start_char, end_char)) = as_close_pair(doc, &node) {
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if let Some(pair_start) =
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find_pair_end(doc, node.prev_sibling(), start_char, end_char, Backward)
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{
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return Some(pair_start);
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}
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}
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if !traverse_parents {
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// check if we are *on* the opening pair (special cased here as
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// an opptimization since we only care about bracket on the cursor
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// here)
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if let Some(close) = as_open_pair(doc, &node) {
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if let Some(pair_end) = find_pair_end(doc, node.next_sibling(), close, Forward) {
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if let Some((start_char, end_char)) = as_open_pair(doc, &node) {
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if let Some(pair_end) =
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find_pair_end(doc, node.next_sibling(), start_char, end_char, Forward)
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{
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return Some(pair_end);
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}
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}
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if node.is_named() {
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break;
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}
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}
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for close in
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if traverse_parents {
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for sibling in
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iter::successors(node.next_sibling(), |node| node.next_sibling()).take(MATCH_LIMIT)
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{
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let Some(open) = as_close_pair(doc, &close) else {
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let Some((start_char, end_char)) = as_close_pair(doc, &sibling) else {
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continue;
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};
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if find_pair_end(doc, Some(node), open, Backward).is_some() {
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return doc.try_byte_to_char(close.start_byte()).ok();
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if find_pair_end(doc, sibling.prev_sibling(), start_char, end_char, Backward)
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.is_some()
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{
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return doc.try_byte_to_char(sibling.start_byte()).ok();
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}
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}
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} else if node.is_named() {
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break;
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}
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let Some(parent) = node.parent() else {
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break;
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};
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@ -241,29 +245,13 @@ pub fn is_valid_pair(ch: char) -> bool {
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PAIRS.iter().any(|(l, r)| *l == ch || *r == ch)
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}
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fn is_valid_pair_on_pos(doc: RopeSlice, start_char: usize, end_char: usize) -> bool {
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PAIRS.contains(&(doc.char(start_char), doc.char(end_char)))
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}
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fn surrounding_bytes(doc: RopeSlice, node: &Node) -> Option<(usize, usize)> {
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let len = doc.len_bytes();
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let start_byte = node.start_byte();
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let end_byte = node.end_byte().saturating_sub(1);
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if start_byte >= len || end_byte >= len {
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return None;
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}
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Some((start_byte, end_byte))
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}
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/// Tests if this node is a pair close char and returns the expected open char
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fn as_close_pair(doc: RopeSlice, node: &Node) -> Option<char> {
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/// and close char contained in this node
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fn as_close_pair(doc: RopeSlice, node: &Node) -> Option<(char, char)> {
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let close = as_char(doc, node)?.1;
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PAIRS
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.iter()
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.find_map(|&(open, close_)| (close_ == close).then_some(open))
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.find_map(|&(open, close_)| (close_ == close).then_some((close, open)))
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}
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/// Checks if `node` or its siblings (at most MATCH_LIMIT nodes) is the specified closing char
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@ -274,6 +262,7 @@ fn as_close_pair(doc: RopeSlice, node: &Node) -> Option<char> {
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fn find_pair_end(
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doc: RopeSlice,
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node: Option<Node>,
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start_char: char,
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end_char: char,
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direction: Direction,
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) -> Option<usize> {
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@ -281,20 +270,30 @@ fn find_pair_end(
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Forward => Node::next_sibling,
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Backward => Node::prev_sibling,
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};
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let mut depth = 0;
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iter::successors(node, advance)
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.take(MATCH_LIMIT)
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.find_map(|node| {
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let (pos, c) = as_char(doc, &node)?;
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(end_char == c).then_some(pos)
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if c == end_char {
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if depth == 0 {
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return Some(pos);
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}
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depth -= 1;
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} else if c == start_char {
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depth += 1;
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}
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None
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})
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}
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/// Tests if this node is a pair close char and returns the expected open char
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fn as_open_pair(doc: RopeSlice, node: &Node) -> Option<char> {
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/// Tests if this node is a pair open char and returns the expected close char
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/// and open char contained in this node
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fn as_open_pair(doc: RopeSlice, node: &Node) -> Option<(char, char)> {
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let open = as_char(doc, node)?.1;
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PAIRS
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.iter()
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.find_map(|&(open_, close)| (open_ == open).then_some(close))
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.find_map(|&(open_, close)| (open_ == open).then_some((open, close)))
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}
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/// If node is a single char return it (and its char position)
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