rename to add files

2024-03-26 16:41:55 -07:00 · 2024-03-26 16:41:55 -07:00 · 2a1345eb23
commit 2a1345eb23
parent eaa0f3d065
12 changed files with 144791 additions and 1 deletions
--- a/examples/server/tree_sitter/tree-sitter-python
+++ b/examples/server/tree_sitter/tree-sitter-python
@ -1 +0,0 @@
 Subproject commit b8a4c64121ba66b460cb878e934e3157ecbfb124
--- a/examples/server/tree_sitter/tree-sitter-python1/.editorconfig
+++ b/examples/server/tree_sitter/tree-sitter-python1/.editorconfig
@ -0,0 +1,39 @@
 root = true
 [*]
 charset = utf-8
 end_of_line = lf
 insert_final_newline = true
 trim_trailing_whitespace = true
 [*.{json,toml,yml,gyp}]
 indent_style = space
 indent_size = 2
 [*.js]
 indent_style = space
 indent_size = 2
 [*.rs]
 indent_style = space
 indent_size = 4
 [*.{c,cc,h}]
 indent_style = space
 indent_size = 4
 [*.{py,pyi}]
 indent_style = space
 indent_size = 4
 [*.swift]
 indent_style = space
 indent_size = 4
 [*.go]
 indent_style = tab
 indent_size = 8
 [Makefile]
 indent_style = tab
 indent_size = 8
--- a/examples/server/tree_sitter/tree-sitter-python1/.eslintrc.js
+++ b/examples/server/tree_sitter/tree-sitter-python1/.eslintrc.js
@ -0,0 +1,20 @@
 module.exports = {
  'env': {
    'commonjs': true,
    'es2021': true,
  },
  'extends': 'google',
  'overrides': [
  ],
  'parserOptions': {
    'ecmaVersion': 'latest',
    'sourceType': 'module',
  },
  'rules': {
    'indent': ['error', 2, {'SwitchCase': 1}],
    'max-len': [
      'error',
      {'code': 120, 'ignoreComments': true, 'ignoreUrls': true, 'ignoreStrings': true},
    ],
  },
 };
--- a/examples/server/tree_sitter/tree-sitter-python1/.gitattributes
+++ b/examples/server/tree_sitter/tree-sitter-python1/.gitattributes
@ -0,0 +1,15 @@
 * text eol=lf
 examples/crlf-line-endings.py eol=crlf
 examples/python2-grammar-crlf.py eol=crlf
 examples/python3-grammar-crlf.py eol=crlf
 src/*.json linguist-generated
 src/parser.c linguist-generated
 src/tree_sitter/* linguist-generated
 bindings/** linguist-generated
 binding.gyp linguist-generated
 setup.py linguist-generated
 Makefile linguist-generated
 Package.swift linguist-generated
--- a/examples/server/tree_sitter/tree-sitter-python1/.npmignore
+++ b/examples/server/tree_sitter/tree-sitter-python1/.npmignore
@ -0,0 +1,17 @@
 bindings/c
 bindings/go
 bindings/python
 bindings/rust
 bindings/swift
 Cargo.toml
 Makefile
 examples
 pyproject.toml
 setup.py
 test
 .editorconfig
 .github
 .gitignore
 .gitattributes
 .gitmodules
 .npmignore
--- a/examples/server/tree_sitter/tree-sitter-python1/src/grammar.json
+++ b/examples/server/tree_sitter/tree-sitter-python1/src/grammar.json
--- a/examples/server/tree_sitter/tree-sitter-python1/src/node-types.json
+++ b/examples/server/tree_sitter/tree-sitter-python1/src/node-types.json
--- a/examples/server/tree_sitter/tree-sitter-python1/src/parser.c
+++ b/examples/server/tree_sitter/tree-sitter-python1/src/parser.c
--- a/examples/server/tree_sitter/tree-sitter-python1/src/scanner.c
+++ b/examples/server/tree_sitter/tree-sitter-python1/src/scanner.c
@ -0,0 +1,433 @@
 #include "tree_sitter/array.h"
 #include "tree_sitter/parser.h"
 #include <assert.h>
 #include <stdint.h>
 #include <stdio.h>
 #include <string.h>
 enum TokenType {
    NEWLINE,
    INDENT,
    DEDENT,
    STRING_START,
    STRING_CONTENT,
    ESCAPE_INTERPOLATION,
    STRING_END,
    COMMENT,
    CLOSE_PAREN,
    CLOSE_BRACKET,
    CLOSE_BRACE,
    EXCEPT,
 };
 typedef enum {
    SingleQuote = 1 << 0,
    DoubleQuote = 1 << 1,
    BackQuote = 1 << 2,
    Raw = 1 << 3,
    Format = 1 << 4,
    Triple = 1 << 5,
    Bytes = 1 << 6,
 } Flags;
 typedef struct {
    char flags;
 } Delimiter;
 static inline Delimiter new_delimiter() { return (Delimiter){0}; }
 static inline bool is_format(Delimiter *delimiter) { return delimiter->flags & Format; }
 static inline bool is_raw(Delimiter *delimiter) { return delimiter->flags & Raw; }
 static inline bool is_triple(Delimiter *delimiter) { return delimiter->flags & Triple; }
 static inline bool is_bytes(Delimiter *delimiter) { return delimiter->flags & Bytes; }
 static inline int32_t end_character(Delimiter *delimiter) {
    if (delimiter->flags & SingleQuote) {
        return '\'';
    }
    if (delimiter->flags & DoubleQuote) {
        return '"';
    }
    if (delimiter->flags & BackQuote) {
        return '`';
    }
    return 0;
 }
 static inline void set_format(Delimiter *delimiter) { delimiter->flags |= Format; }
 static inline void set_raw(Delimiter *delimiter) { delimiter->flags |= Raw; }
 static inline void set_triple(Delimiter *delimiter) { delimiter->flags |= Triple; }
 static inline void set_bytes(Delimiter *delimiter) { delimiter->flags |= Bytes; }
 static inline void set_end_character(Delimiter *delimiter, int32_t character) {
    switch (character) {
        case '\'':
            delimiter->flags |= SingleQuote;
            break;
        case '"':
            delimiter->flags |= DoubleQuote;
            break;
        case '`':
            delimiter->flags |= BackQuote;
            break;
        default:
            assert(false);
    }
 }
 typedef struct {
    Array(uint16_t) indents;
    Array(Delimiter) delimiters;
    bool inside_f_string;
 } Scanner;
 static inline void advance(TSLexer *lexer) { lexer->advance(lexer, false); }
 static inline void skip(TSLexer *lexer) { lexer->advance(lexer, true); }
 bool tree_sitter_python_external_scanner_scan(void *payload, TSLexer *lexer, const bool *valid_symbols) {
    Scanner *scanner = (Scanner *)payload;
    bool error_recovery_mode = valid_symbols[STRING_CONTENT] && valid_symbols[INDENT];
    bool within_brackets = valid_symbols[CLOSE_BRACE] || valid_symbols[CLOSE_PAREN] || valid_symbols[CLOSE_BRACKET];
    bool advanced_once = false;
    if (valid_symbols[ESCAPE_INTERPOLATION] && scanner->delimiters.size > 0 &&
        (lexer->lookahead == '{' || lexer->lookahead == '}') && !error_recovery_mode) {
        Delimiter *delimiter = array_back(&scanner->delimiters);
        if (is_format(delimiter)) {
            lexer->mark_end(lexer);
            bool is_left_brace = lexer->lookahead == '{';
            advance(lexer);
            advanced_once = true;
            if ((lexer->lookahead == '{' && is_left_brace) || (lexer->lookahead == '}' && !is_left_brace)) {
                advance(lexer);
                lexer->mark_end(lexer);
                lexer->result_symbol = ESCAPE_INTERPOLATION;
                return true;
            }
            return false;
        }
    }
    if (valid_symbols[STRING_CONTENT] && scanner->delimiters.size > 0 && !error_recovery_mode) {
        Delimiter *delimiter = array_back(&scanner->delimiters);
        int32_t end_char = end_character(delimiter);
        bool has_content = advanced_once;
        while (lexer->lookahead) {
            if ((advanced_once || lexer->lookahead == '{' || lexer->lookahead == '}') && is_format(delimiter)) {
                lexer->mark_end(lexer);
                lexer->result_symbol = STRING_CONTENT;
                return has_content;
            }
            if (lexer->lookahead == '\\') {
                if (is_raw(delimiter)) {
                    // Step over the backslash.
                    advance(lexer);
                    // Step over any escaped quotes.
                    if (lexer->lookahead == end_character(delimiter) || lexer->lookahead == '\\') {
                        advance(lexer);
                    }
                    // Step over newlines
                    if (lexer->lookahead == '\r') {
                        advance(lexer);
                        if (lexer->lookahead == '\n') {
                            advance(lexer);
                        }
                    } else if (lexer->lookahead == '\n') {
                        advance(lexer);
                    }
                    continue;
                }
                if (is_bytes(delimiter)) {
                    lexer->mark_end(lexer);
                    advance(lexer);
                    if (lexer->lookahead == 'N' || lexer->lookahead == 'u' || lexer->lookahead == 'U') {
                        // In bytes string, \N{...}, \uXXXX and \UXXXXXXXX are
                        // not escape sequences
                        // https://docs.python.org/3/reference/lexical_analysis.html#string-and-bytes-literals
                        advance(lexer);
                    } else {
                        lexer->result_symbol = STRING_CONTENT;
                        return has_content;
                    }
                } else {
                    lexer->mark_end(lexer);
                    lexer->result_symbol = STRING_CONTENT;
                    return has_content;
                }
            } else if (lexer->lookahead == end_char) {
                if (is_triple(delimiter)) {
                    lexer->mark_end(lexer);
                    advance(lexer);
                    if (lexer->lookahead == end_char) {
                        advance(lexer);
                        if (lexer->lookahead == end_char) {
                            if (has_content) {
                                lexer->result_symbol = STRING_CONTENT;
                            } else {
                                advance(lexer);
                                lexer->mark_end(lexer);
                                array_pop(&scanner->delimiters);
                                lexer->result_symbol = STRING_END;
                                scanner->inside_f_string = false;
                            }
                            return true;
                        }
                        lexer->mark_end(lexer);
                        lexer->result_symbol = STRING_CONTENT;
                        return true;
                    }
                    lexer->mark_end(lexer);
                    lexer->result_symbol = STRING_CONTENT;
                    return true;
                }
                if (has_content) {
                    lexer->result_symbol = STRING_CONTENT;
                } else {
                    advance(lexer);
                    array_pop(&scanner->delimiters);
                    lexer->result_symbol = STRING_END;
                    scanner->inside_f_string = false;
                }
                lexer->mark_end(lexer);
                return true;
            } else if (lexer->lookahead == '\n' && has_content && !is_triple(delimiter)) {
                return false;
            }
            advance(lexer);
            has_content = true;
        }
    }
    lexer->mark_end(lexer);
    bool found_end_of_line = false;
    uint32_t indent_length = 0;
    int32_t first_comment_indent_length = -1;
    for (;;) {
        if (lexer->lookahead == '\n') {
            found_end_of_line = true;
            indent_length = 0;
            skip(lexer);
        } else if (lexer->lookahead == ' ') {
            indent_length++;
            skip(lexer);
        } else if (lexer->lookahead == '\r' || lexer->lookahead == '\f') {
            indent_length = 0;
            skip(lexer);
        } else if (lexer->lookahead == '\t') {
            indent_length += 8;
            skip(lexer);
        } else if (lexer->lookahead == '#' && (valid_symbols[INDENT] || valid_symbols[DEDENT] ||
                                               valid_symbols[NEWLINE] || valid_symbols[EXCEPT])) {
            // If we haven't found an EOL yet,
            // then this is a comment after an expression:
            //   foo = bar # comment
            // Just return, since we don't want to generate an indent/dedent
            // token.
            if (!found_end_of_line) {
                return false;
            }
            if (first_comment_indent_length == -1) {
                first_comment_indent_length = (int32_t)indent_length;
            }
            while (lexer->lookahead && lexer->lookahead != '\n') {
                skip(lexer);
            }
            skip(lexer);
            indent_length = 0;
        } else if (lexer->lookahead == '\\') {
            skip(lexer);
            if (lexer->lookahead == '\r') {
                skip(lexer);
            }
            if (lexer->lookahead == '\n' || lexer->eof(lexer)) {
                skip(lexer);
            } else {
                return false;
            }
        } else if (lexer->eof(lexer)) {
            indent_length = 0;
            found_end_of_line = true;
            break;
        } else {
            break;
        }
    }
    if (found_end_of_line) {
        if (scanner->indents.size > 0) {
            uint16_t current_indent_length = *array_back(&scanner->indents);
            if (valid_symbols[INDENT] && indent_length > current_indent_length) {
                array_push(&scanner->indents, indent_length);
                lexer->result_symbol = INDENT;
                return true;
            }
            bool next_tok_is_string_start =
                lexer->lookahead == '\"' || lexer->lookahead == '\'' || lexer->lookahead == '`';
            if ((valid_symbols[DEDENT] ||
                 (!valid_symbols[NEWLINE] && !(valid_symbols[STRING_START] && next_tok_is_string_start) &&
                  !within_brackets)) &&
                indent_length < current_indent_length && !scanner->inside_f_string &&
                // Wait to create a dedent token until we've consumed any
                // comments
                // whose indentation matches the current block.
                first_comment_indent_length < (int32_t)current_indent_length) {
                array_pop(&scanner->indents);
                lexer->result_symbol = DEDENT;
                return true;
            }
        }
        if (valid_symbols[NEWLINE] && !error_recovery_mode) {
            lexer->result_symbol = NEWLINE;
            return true;
        }
    }
    if (first_comment_indent_length == -1 && valid_symbols[STRING_START]) {
        Delimiter delimiter = new_delimiter();
        bool has_flags = false;
        while (lexer->lookahead) {
            if (lexer->lookahead == 'f' || lexer->lookahead == 'F') {
                set_format(&delimiter);
            } else if (lexer->lookahead == 'r' || lexer->lookahead == 'R') {
                set_raw(&delimiter);
            } else if (lexer->lookahead == 'b' || lexer->lookahead == 'B') {
                set_bytes(&delimiter);
            } else if (lexer->lookahead != 'u' && lexer->lookahead != 'U') {
                break;
            }
            has_flags = true;
            advance(lexer);
        }
        if (lexer->lookahead == '`') {
            set_end_character(&delimiter, '`');
            advance(lexer);
            lexer->mark_end(lexer);
        } else if (lexer->lookahead == '\'') {
            set_end_character(&delimiter, '\'');
            advance(lexer);
            lexer->mark_end(lexer);
            if (lexer->lookahead == '\'') {
                advance(lexer);
                if (lexer->lookahead == '\'') {
                    advance(lexer);
                    lexer->mark_end(lexer);
                    set_triple(&delimiter);
                }
            }
        } else if (lexer->lookahead == '"') {
            set_end_character(&delimiter, '"');
            advance(lexer);
            lexer->mark_end(lexer);
            if (lexer->lookahead == '"') {
                advance(lexer);
                if (lexer->lookahead == '"') {
                    advance(lexer);
                    lexer->mark_end(lexer);
                    set_triple(&delimiter);
                }
            }
        }
        if (end_character(&delimiter)) {
            array_push(&scanner->delimiters, delimiter);
            lexer->result_symbol = STRING_START;
            scanner->inside_f_string = is_format(&delimiter);
            return true;
        }
        if (has_flags) {
            return false;
        }
    }
    return false;
 }
 unsigned tree_sitter_python_external_scanner_serialize(void *payload, char *buffer) {
    Scanner *scanner = (Scanner *)payload;
    size_t size = 0;
    buffer[size++] = (char)scanner->inside_f_string;
    size_t delimiter_count = scanner->delimiters.size;
    if (delimiter_count > UINT8_MAX) {
        delimiter_count = UINT8_MAX;
    }
    buffer[size++] = (char)delimiter_count;
    if (delimiter_count > 0) {
        memcpy(&buffer[size], scanner->delimiters.contents, delimiter_count);
    }
    size += delimiter_count;
    uint32_t iter = 1;
    for (; iter < scanner->indents.size && size < TREE_SITTER_SERIALIZATION_BUFFER_SIZE; ++iter) {
        buffer[size++] = (char)*array_get(&scanner->indents, iter);
    }
    return size;
 }
 void tree_sitter_python_external_scanner_deserialize(void *payload, const char *buffer, unsigned length) {
    Scanner *scanner = (Scanner *)payload;
    array_delete(&scanner->delimiters);
    array_delete(&scanner->indents);
    array_push(&scanner->indents, 0);
    if (length > 0) {
        size_t size = 0;
        scanner->inside_f_string = (bool)buffer[size++];
        size_t delimiter_count = (uint8_t)buffer[size++];
        if (delimiter_count > 0) {
            array_reserve(&scanner->delimiters, delimiter_count);
            scanner->delimiters.size = delimiter_count;
            memcpy(scanner->delimiters.contents, &buffer[size], delimiter_count);
            size += delimiter_count;
        }
        for (; size < length; size++) {
            array_push(&scanner->indents, (unsigned char)buffer[size]);
        }
    }
 }
 void *tree_sitter_python_external_scanner_create() {
 #if defined(__STDC_VERSION__) && (__STDC_VERSION__ >= 201112L)
    _Static_assert(sizeof(Delimiter) == sizeof(char), "");
 #else
    assert(sizeof(Delimiter) == sizeof(char));
 #endif
    Scanner *scanner = calloc(1, sizeof(Scanner));
    array_init(&scanner->indents);
    array_init(&scanner->delimiters);
    tree_sitter_python_external_scanner_deserialize(scanner, NULL, 0);
    return scanner;
 }
 void tree_sitter_python_external_scanner_destroy(void *payload) {
    Scanner *scanner = (Scanner *)payload;
    array_delete(&scanner->indents);
    array_delete(&scanner->delimiters);
    free(scanner);
 }
--- a/examples/server/tree_sitter/tree-sitter-python1/src/tree_sitter/alloc.h
+++ b/examples/server/tree_sitter/tree-sitter-python1/src/tree_sitter/alloc.h
@ -0,0 +1,54 @@
 #ifndef TREE_SITTER_ALLOC_H_
 #define TREE_SITTER_ALLOC_H_
 #ifdef __cplusplus
 extern "C" {
 #endif
 #include <stdbool.h>
 #include <stdio.h>
 #include <stdlib.h>
 // Allow clients to override allocation functions
 #ifdef TREE_SITTER_REUSE_ALLOCATOR
 extern void *(*ts_current_malloc)(size_t);
 extern void *(*ts_current_calloc)(size_t, size_t);
 extern void *(*ts_current_realloc)(void *, size_t);
 extern void (*ts_current_free)(void *);
 #ifndef ts_malloc
 #define ts_malloc  ts_current_malloc
 #endif
 #ifndef ts_calloc
 #define ts_calloc  ts_current_calloc
 #endif
 #ifndef ts_realloc
 #define ts_realloc ts_current_realloc
 #endif
 #ifndef ts_free
 #define ts_free    ts_current_free
 #endif
 #else
 #ifndef ts_malloc
 #define ts_malloc  malloc
 #endif
 #ifndef ts_calloc
 #define ts_calloc  calloc
 #endif
 #ifndef ts_realloc
 #define ts_realloc realloc
 #endif
 #ifndef ts_free
 #define ts_free    free
 #endif
 #endif
 #ifdef __cplusplus
 }
 #endif
 #endif // TREE_SITTER_ALLOC_H_
--- a/examples/server/tree_sitter/tree-sitter-python1/src/tree_sitter/array.h
+++ b/examples/server/tree_sitter/tree-sitter-python1/src/tree_sitter/array.h
@ -0,0 +1,287 @@
 #ifndef TREE_SITTER_ARRAY_H_
 #define TREE_SITTER_ARRAY_H_
 #ifdef __cplusplus
 extern "C" {
 #endif
 #include "./alloc.h"
 #include <assert.h>
 #include <stdbool.h>
 #include <stdint.h>
 #include <stdlib.h>
 #include <string.h>
 #ifdef _MSC_VER
 #pragma warning(disable : 4101)
 #elif defined(__GNUC__) || defined(__clang__)
 #pragma GCC diagnostic push
 #pragma GCC diagnostic ignored "-Wunused-variable"
 #endif
 #define Array(T)       \
  struct {             \
    T *contents;       \
    uint32_t size;     \
    uint32_t capacity; \
  }
 /// Initialize an array.
 #define array_init(self) \
  ((self)->size = 0, (self)->capacity = 0, (self)->contents = NULL)
 /// Create an empty array.
 #define array_new() \
  { NULL, 0, 0 }
 /// Get a pointer to the element at a given `index` in the array.
 #define array_get(self, _index) \
  (assert((uint32_t)(_index) < (self)->size), &(self)->contents[_index])
 /// Get a pointer to the first element in the array.
 #define array_front(self) array_get(self, 0)
 /// Get a pointer to the last element in the array.
 #define array_back(self) array_get(self, (self)->size - 1)
 /// Clear the array, setting its size to zero. Note that this does not free any
 /// memory allocated for the array's contents.
 #define array_clear(self) ((self)->size = 0)
 /// Reserve `new_capacity` elements of space in the array. If `new_capacity` is
 /// less than the array's current capacity, this function has no effect.
 #define array_reserve(self, new_capacity) \
  _array__reserve((Array *)(self), array_elem_size(self), new_capacity)
 /// Free any memory allocated for this array. Note that this does not free any
 /// memory allocated for the array's contents.
 #define array_delete(self) _array__delete((Array *)(self))
 /// Push a new `element` onto the end of the array.
 #define array_push(self, element)                            \
  (_array__grow((Array *)(self), 1, array_elem_size(self)), \
   (self)->contents[(self)->size++] = (element))
 /// Increase the array's size by `count` elements.
 /// New elements are zero-initialized.
 #define array_grow_by(self, count) \
  (_array__grow((Array *)(self), count, array_elem_size(self)), \
   memset((self)->contents + (self)->size, 0, (count) * array_elem_size(self)), \
   (self)->size += (count))
 /// Append all elements from one array to the end of another.
 #define array_push_all(self, other)                                       \
  array_extend((self), (other)->size, (other)->contents)
 /// Append `count` elements to the end of the array, reading their values from the
 /// `contents` pointer.
 #define array_extend(self, count, contents)                    \
  _array__splice(                                               \
    (Array *)(self), array_elem_size(self), (self)->size, \
    0, count,  contents                                        \
  )
 /// Remove `old_count` elements from the array starting at the given `index`. At
 /// the same index, insert `new_count` new elements, reading their values from the
 /// `new_contents` pointer.
 #define array_splice(self, _index, old_count, new_count, new_contents)  \
  _array__splice(                                                       \
    (Array *)(self), array_elem_size(self), _index,                \
    old_count, new_count, new_contents                                 \
  )
 /// Insert one `element` into the array at the given `index`.
 #define array_insert(self, _index, element) \
  _array__splice((Array *)(self), array_elem_size(self), _index, 0, 1, &(element))
 /// Remove one element from the array at the given `index`.
 #define array_erase(self, _index) \
  _array__erase((Array *)(self), array_elem_size(self), _index)
 /// Pop the last element off the array, returning the element by value.
 #define array_pop(self) ((self)->contents[--(self)->size])
 /// Assign the contents of one array to another, reallocating if necessary.
 #define array_assign(self, other) \
  _array__assign((Array *)(self), (const Array *)(other), array_elem_size(self))
 /// Swap one array with another
 #define array_swap(self, other) \
  _array__swap((Array *)(self), (Array *)(other))
 /// Get the size of the array contents
 #define array_elem_size(self) (sizeof *(self)->contents)
 /// Search a sorted array for a given `needle` value, using the given `compare`
 /// callback to determine the order.
 ///
 /// If an existing element is found to be equal to `needle`, then the `index`
 /// out-parameter is set to the existing value's index, and the `exists`
 /// out-parameter is set to true. Otherwise, `index` is set to an index where
 /// `needle` should be inserted in order to preserve the sorting, and `exists`
 /// is set to false.
 #define array_search_sorted_with(self, compare, needle, _index, _exists) \
  _array__search_sorted(self, 0, compare, , needle, _index, _exists)
 /// Search a sorted array for a given `needle` value, using integer comparisons
 /// of a given struct field (specified with a leading dot) to determine the order.
 ///
 /// See also `array_search_sorted_with`.
 #define array_search_sorted_by(self, field, needle, _index, _exists) \
  _array__search_sorted(self, 0, _compare_int, field, needle, _index, _exists)
 /// Insert a given `value` into a sorted array, using the given `compare`
 /// callback to determine the order.
 #define array_insert_sorted_with(self, compare, value) \
  do { \
    unsigned _index, _exists; \
    array_search_sorted_with(self, compare, &(value), &_index, &_exists); \
    if (!_exists) array_insert(self, _index, value); \
  } while (0)
 /// Insert a given `value` into a sorted array, using integer comparisons of
 /// a given struct field (specified with a leading dot) to determine the order.
 ///
 /// See also `array_search_sorted_by`.
 #define array_insert_sorted_by(self, field, value) \
  do { \
    unsigned _index, _exists; \
    array_search_sorted_by(self, field, (value) field, &_index, &_exists); \
    if (!_exists) array_insert(self, _index, value); \
  } while (0)
 // Private
 typedef Array(void) Array;
 /// This is not what you're looking for, see `array_delete`.
 static inline void _array__delete(Array *self) {
  if (self->contents) {
    ts_free(self->contents);
    self->contents = NULL;
    self->size = 0;
    self->capacity = 0;
  }
 }
 /// This is not what you're looking for, see `array_erase`.
 static inline void _array__erase(Array *self, size_t element_size,
                                uint32_t index) {
  assert(index < self->size);
  char *contents = (char *)self->contents;
  memmove(contents + index * element_size, contents + (index + 1) * element_size,
          (self->size - index - 1) * element_size);
  self->size--;
 }
 /// This is not what you're looking for, see `array_reserve`.
 static inline void _array__reserve(Array *self, size_t element_size, uint32_t new_capacity) {
  if (new_capacity > self->capacity) {
    if (self->contents) {
      self->contents = ts_realloc(self->contents, new_capacity * element_size);
    } else {
      self->contents = ts_malloc(new_capacity * element_size);
    }
    self->capacity = new_capacity;
  }
 }
 /// This is not what you're looking for, see `array_assign`.
 static inline void _array__assign(Array *self, const Array *other, size_t element_size) {
  _array__reserve(self, element_size, other->size);
  self->size = other->size;
  memcpy(self->contents, other->contents, self->size * element_size);
 }
 /// This is not what you're looking for, see `array_swap`.
 static inline void _array__swap(Array *self, Array *other) {
  Array swap = *other;
  *other = *self;
  *self = swap;
 }
 /// This is not what you're looking for, see `array_push` or `array_grow_by`.
 static inline void _array__grow(Array *self, uint32_t count, size_t element_size) {
  uint32_t new_size = self->size + count;
  if (new_size > self->capacity) {
    uint32_t new_capacity = self->capacity * 2;
    if (new_capacity < 8) new_capacity = 8;
    if (new_capacity < new_size) new_capacity = new_size;
    _array__reserve(self, element_size, new_capacity);
  }
 }
 /// This is not what you're looking for, see `array_splice`.
 static inline void _array__splice(Array *self, size_t element_size,
                                 uint32_t index, uint32_t old_count,
                                 uint32_t new_count, const void *elements) {
  uint32_t new_size = self->size + new_count - old_count;
  uint32_t old_end = index + old_count;
  uint32_t new_end = index + new_count;
  assert(old_end <= self->size);
  _array__reserve(self, element_size, new_size);
  char *contents = (char *)self->contents;
  if (self->size > old_end) {
    memmove(
      contents + new_end * element_size,
      contents + old_end * element_size,
      (self->size - old_end) * element_size
    );
  }
  if (new_count > 0) {
    if (elements) {
      memcpy(
        (contents + index * element_size),
        elements,
        new_count * element_size
      );
    } else {
      memset(
        (contents + index * element_size),
        0,
        new_count * element_size
      );
    }
  }
  self->size += new_count - old_count;
 }
 /// A binary search routine, based on Rust's `std::slice::binary_search_by`.
 /// This is not what you're looking for, see `array_search_sorted_with` or `array_search_sorted_by`.
 #define _array__search_sorted(self, start, compare, suffix, needle, _index, _exists) \
  do { \
    *(_index) = start; \
    *(_exists) = false; \
    uint32_t size = (self)->size - *(_index); \
    if (size == 0) break; \
    int comparison; \
    while (size > 1) { \
      uint32_t half_size = size / 2; \
      uint32_t mid_index = *(_index) + half_size; \
      comparison = compare(&((self)->contents[mid_index] suffix), (needle)); \
      if (comparison <= 0) *(_index) = mid_index; \
      size -= half_size; \
    } \
    comparison = compare(&((self)->contents[*(_index)] suffix), (needle)); \
    if (comparison == 0) *(_exists) = true; \
    else if (comparison < 0) *(_index) += 1; \
  } while (0)
 /// Helper macro for the `_sorted_by` routines below. This takes the left (existing)
 /// parameter by reference in order to work with the generic sorting function above.
 #define _compare_int(a, b) ((int)*(a) - (int)(b))
 #ifdef _MSC_VER
 #pragma warning(default : 4101)
 #elif defined(__GNUC__) || defined(__clang__)
 #pragma GCC diagnostic pop
 #endif
 #ifdef __cplusplus
 }
 #endif
 #endif  // TREE_SITTER_ARRAY_H_
--- a/examples/server/tree_sitter/tree-sitter-python1/src/tree_sitter/parser.h
+++ b/examples/server/tree_sitter/tree-sitter-python1/src/tree_sitter/parser.h
@ -0,0 +1,230 @@
 #ifndef TREE_SITTER_PARSER_H_
 #define TREE_SITTER_PARSER_H_
 #ifdef __cplusplus
 extern "C" {
 #endif
 #include <stdbool.h>
 #include <stdint.h>
 #include <stdlib.h>
 #define ts_builtin_sym_error ((TSSymbol)-1)
 #define ts_builtin_sym_end 0
 #define TREE_SITTER_SERIALIZATION_BUFFER_SIZE 1024
 #ifndef TREE_SITTER_API_H_
 typedef uint16_t TSStateId;
 typedef uint16_t TSSymbol;
 typedef uint16_t TSFieldId;
 typedef struct TSLanguage TSLanguage;
 #endif
 typedef struct {
  TSFieldId field_id;
  uint8_t child_index;
  bool inherited;
 } TSFieldMapEntry;
 typedef struct {
  uint16_t index;
  uint16_t length;
 } TSFieldMapSlice;
 typedef struct {
  bool visible;
  bool named;
  bool supertype;
 } TSSymbolMetadata;
 typedef struct TSLexer TSLexer;
 struct TSLexer {
  int32_t lookahead;
  TSSymbol result_symbol;
  void (*advance)(TSLexer *, bool);
  void (*mark_end)(TSLexer *);
  uint32_t (*get_column)(TSLexer *);
  bool (*is_at_included_range_start)(const TSLexer *);
  bool (*eof)(const TSLexer *);
 };
 typedef enum {
  TSParseActionTypeShift,
  TSParseActionTypeReduce,
  TSParseActionTypeAccept,
  TSParseActionTypeRecover,
 } TSParseActionType;
 typedef union {
  struct {
    uint8_t type;
    TSStateId state;
    bool extra;
    bool repetition;
  } shift;
  struct {
    uint8_t type;
    uint8_t child_count;
    TSSymbol symbol;
    int16_t dynamic_precedence;
    uint16_t production_id;
  } reduce;
  uint8_t type;
 } TSParseAction;
 typedef struct {
  uint16_t lex_state;
  uint16_t external_lex_state;
 } TSLexMode;
 typedef union {
  TSParseAction action;
  struct {
    uint8_t count;
    bool reusable;
  } entry;
 } TSParseActionEntry;
 struct TSLanguage {
  uint32_t version;
  uint32_t symbol_count;
  uint32_t alias_count;
  uint32_t token_count;
  uint32_t external_token_count;
  uint32_t state_count;
  uint32_t large_state_count;
  uint32_t production_id_count;
  uint32_t field_count;
  uint16_t max_alias_sequence_length;
  const uint16_t *parse_table;
  const uint16_t *small_parse_table;
  const uint32_t *small_parse_table_map;
  const TSParseActionEntry *parse_actions;
  const char * const *symbol_names;
  const char * const *field_names;
  const TSFieldMapSlice *field_map_slices;
  const TSFieldMapEntry *field_map_entries;
  const TSSymbolMetadata *symbol_metadata;
  const TSSymbol *public_symbol_map;
  const uint16_t *alias_map;
  const TSSymbol *alias_sequences;
  const TSLexMode *lex_modes;
  bool (*lex_fn)(TSLexer *, TSStateId);
  bool (*keyword_lex_fn)(TSLexer *, TSStateId);
  TSSymbol keyword_capture_token;
  struct {
    const bool *states;
    const TSSymbol *symbol_map;
    void *(*create)(void);
    void (*destroy)(void *);
    bool (*scan)(void *, TSLexer *, const bool *symbol_whitelist);
    unsigned (*serialize)(void *, char *);
    void (*deserialize)(void *, const char *, unsigned);
  } external_scanner;
  const TSStateId *primary_state_ids;
 };
 /*
 *  Lexer Macros
 */
 #ifdef _MSC_VER
 #define UNUSED __pragma(warning(suppress : 4101))
 #else
 #define UNUSED __attribute__((unused))
 #endif
 #define START_LEXER()           \
  bool result = false;          \
  bool skip = false;            \
  UNUSED                        \
  bool eof = false;             \
  int32_t lookahead;            \
  goto start;                   \
  next_state:                   \
  lexer->advance(lexer, skip);  \
  start:                        \
  skip = false;                 \
  lookahead = lexer->lookahead;
 #define ADVANCE(state_value) \
  {                          \
    state = state_value;     \
    goto next_state;         \
  }
 #define SKIP(state_value) \
  {                       \
    skip = true;          \
    state = state_value;  \
    goto next_state;      \
  }
 #define ACCEPT_TOKEN(symbol_value)     \
  result = true;                       \
  lexer->result_symbol = symbol_value; \
  lexer->mark_end(lexer);
 #define END_STATE() return result;
 /*
 *  Parse Table Macros
 */
 #define SMALL_STATE(id) ((id) - LARGE_STATE_COUNT)
 #define STATE(id) id
 #define ACTIONS(id) id
 #define SHIFT(state_value)            \
  {{                                  \
    .shift = {                        \
      .type = TSParseActionTypeShift, \
      .state = (state_value)          \
    }                                 \
  }}
 #define SHIFT_REPEAT(state_value)     \
  {{                                  \
    .shift = {                        \
      .type = TSParseActionTypeShift, \
      .state = (state_value),         \
      .repetition = true              \
    }                                 \
  }}
 #define SHIFT_EXTRA()                 \
  {{                                  \
    .shift = {                        \
      .type = TSParseActionTypeShift, \
      .extra = true                   \
    }                                 \
  }}
 #define REDUCE(symbol_val, child_count_val, ...) \
  {{                                             \
    .reduce = {                                  \
      .type = TSParseActionTypeReduce,           \
      .symbol = symbol_val,                      \
      .child_count = child_count_val,            \
      __VA_ARGS__                                \
    },                                           \
  }}
 #define RECOVER()                    \
  {{                                 \
    .type = TSParseActionTypeRecover \
  }}
 #define ACCEPT_INPUT()              \
  {{                                \
    .type = TSParseActionTypeAccept \
  }}
 #ifdef __cplusplus
 }
 #endif
 #endif  // TREE_SITTER_PARSER_H_
		`@ -1 +0,0 @@`
			`Subproject commit b8a4c64121ba66b460cb878e934e3157ecbfb124`