import ast import os.path import re from dataclasses import dataclass, field from enum import Enum from typing import IO, Any, Dict, List, Optional, Set, Text, Tuple from pegen import grammar from pegen.grammar import ( Alt, Cut, Forced, Gather, GrammarVisitor, Group, Leaf, Lookahead, NamedItem, NameLeaf, NegativeLookahead, Opt, PositiveLookahead, Repeat0, Repeat1, Rhs, Rule, StringLeaf, ) from pegen.parser_generator import ParserGenerator EXTENSION_PREFIX = """\ #include "pegen.h" #if defined(Py_DEBUG) && defined(Py_BUILD_CORE) # define D(x) if (p->debug) { x; } #else # define D(x) #endif #ifdef __wasi__ # define MAXSTACK 4000 #else # define MAXSTACK 6000 #endif """ EXTENSION_SUFFIX = """ void * _PyPegen_parse(Parser *p) { // Initialize keywords p->keywords = reserved_keywords; p->n_keyword_lists = n_keyword_lists; p->soft_keywords = soft_keywords; return start_rule(p); } """ class NodeTypes(Enum): NAME_TOKEN = 0 NUMBER_TOKEN = 1 STRING_TOKEN = 2 GENERIC_TOKEN = 3 KEYWORD = 4 SOFT_KEYWORD = 5 CUT_OPERATOR = 6 BASE_NODETYPES = { "NAME": NodeTypes.NAME_TOKEN, "NUMBER": NodeTypes.NUMBER_TOKEN, "STRING": NodeTypes.STRING_TOKEN, "SOFT_KEYWORD": NodeTypes.SOFT_KEYWORD, } @dataclass class FunctionCall: function: str arguments: List[Any] = field(default_factory=list) assigned_variable: Optional[str] = None assigned_variable_type: Optional[str] = None return_type: Optional[str] = None nodetype: Optional[NodeTypes] = None force_true: bool = False comment: Optional[str] = None def __str__(self) -> str: parts = [] parts.append(self.function) if self.arguments: parts.append(f"({', '.join(map(str, self.arguments))})") if self.force_true: parts.append(", !p->error_indicator") if self.assigned_variable: if self.assigned_variable_type: parts = [ "(", self.assigned_variable, " = ", "(", self.assigned_variable_type, ")", *parts, ")", ] else: parts = ["(", self.assigned_variable, " = ", *parts, ")"] if self.comment: parts.append(f" // {self.comment}") return "".join(parts) class CCallMakerVisitor(GrammarVisitor): def __init__( self, parser_generator: ParserGenerator, exact_tokens: Dict[str, int], non_exact_tokens: Set[str], ): self.gen = parser_generator self.exact_tokens = exact_tokens self.non_exact_tokens = non_exact_tokens self.cache: Dict[Any, FunctionCall] = {} self.cleanup_statements: List[str] = [] def keyword_helper(self, keyword: str) -> FunctionCall: return FunctionCall( assigned_variable="_keyword", function="_PyPegen_expect_token", arguments=["p", self.gen.keywords[keyword]], return_type="Token *", nodetype=NodeTypes.KEYWORD, comment=f"token='{keyword}'", ) def soft_keyword_helper(self, value: str) -> FunctionCall: return FunctionCall( assigned_variable="_keyword", function="_PyPegen_expect_soft_keyword", arguments=["p", value], return_type="expr_ty", nodetype=NodeTypes.SOFT_KEYWORD, comment=f"soft_keyword='{value}'", ) def visit_NameLeaf(self, node: NameLeaf) -> FunctionCall: name = node.value if name in self.non_exact_tokens: if name in BASE_NODETYPES: return FunctionCall( assigned_variable=f"{name.lower()}_var", function=f"_PyPegen_{name.lower()}_token", arguments=["p"], nodetype=BASE_NODETYPES[name], return_type="expr_ty", comment=name, ) return FunctionCall( assigned_variable=f"{name.lower()}_var", function=f"_PyPegen_expect_token", arguments=["p", name], nodetype=NodeTypes.GENERIC_TOKEN, return_type="Token *", comment=f"token='{name}'", ) type = None rule = self.gen.all_rules.get(name.lower()) if rule is not None: type = "asdl_seq *" if rule.is_loop() or rule.is_gather() else rule.type return FunctionCall( assigned_variable=f"{name}_var", function=f"{name}_rule", arguments=["p"], return_type=type, comment=f"{node}", ) def visit_StringLeaf(self, node: StringLeaf) -> FunctionCall: val = ast.literal_eval(node.value) if re.match(r"[a-zA-Z_]\w*\Z", val): # This is a keyword if node.value.endswith("'"): return self.keyword_helper(val) else: return self.soft_keyword_helper(node.value) else: assert val in self.exact_tokens, f"{node.value} is not a known literal" type = self.exact_tokens[val] return FunctionCall( assigned_variable="_literal", function=f"_PyPegen_expect_token", arguments=["p", type], nodetype=NodeTypes.GENERIC_TOKEN, return_type="Token *", comment=f"token='{val}'", ) def visit_Rhs(self, node: Rhs) -> FunctionCall: if node in self.cache: return self.cache[node] if node.can_be_inlined: self.cache[node] = self.generate_call(node.alts[0].items[0]) else: name = self.gen.artifical_rule_from_rhs(node) self.cache[node] = FunctionCall( assigned_variable=f"{name}_var", function=f"{name}_rule", arguments=["p"], comment=f"{node}", ) return self.cache[node] def visit_NamedItem(self, node: NamedItem) -> FunctionCall: call = self.generate_call(node.item) if node.name: call.assigned_variable = node.name if node.type: call.assigned_variable_type = node.type return call def lookahead_call_helper(self, node: Lookahead, positive: int) -> FunctionCall: call = self.generate_call(node.node) if call.nodetype == NodeTypes.NAME_TOKEN: return FunctionCall( function=f"_PyPegen_lookahead_with_name", arguments=[positive, call.function, *call.arguments], return_type="int", ) elif call.nodetype == NodeTypes.SOFT_KEYWORD: return FunctionCall( function=f"_PyPegen_lookahead_with_string", arguments=[positive, call.function, *call.arguments], return_type="int", ) elif call.nodetype in {NodeTypes.GENERIC_TOKEN, NodeTypes.KEYWORD}: return FunctionCall( function=f"_PyPegen_lookahead_with_int", arguments=[positive, call.function, *call.arguments], return_type="int", comment=f"token={node.node}", ) else: return FunctionCall( function=f"_PyPegen_lookahead", arguments=[positive, call.function, *call.arguments], return_type="int", ) def visit_PositiveLookahead(self, node: PositiveLookahead) -> FunctionCall: return self.lookahead_call_helper(node, 1) def visit_NegativeLookahead(self, node: NegativeLookahead) -> FunctionCall: return self.lookahead_call_helper(node, 0) def visit_Forced(self, node: Forced) -> FunctionCall: call = self.generate_call(node.node) if isinstance(node.node, Leaf): assert isinstance(node.node, Leaf) val = ast.literal_eval(node.node.value) assert val in self.exact_tokens, f"{node.node.value} is not a known literal" type = self.exact_tokens[val] return FunctionCall( assigned_variable="_literal", function=f"_PyPegen_expect_forced_token", arguments=["p", type, f'"{val}"'], nodetype=NodeTypes.GENERIC_TOKEN, return_type="Token *", comment=f"forced_token='{val}'", ) if isinstance(node.node, Group): call = self.visit(node.node.rhs) call.assigned_variable = None call.comment = None return FunctionCall( assigned_variable="_literal", function=f"_PyPegen_expect_forced_result", arguments=["p", str(call), f'"{node.node.rhs!s}"'], return_type="void *", comment=f"forced_token=({node.node.rhs!s})", ) else: raise NotImplementedError(f"Forced tokens don't work with {node.node} nodes") def visit_Opt(self, node: Opt) -> FunctionCall: call = self.generate_call(node.node) return FunctionCall( assigned_variable="_opt_var", function=call.function, arguments=call.arguments, force_true=True, comment=f"{node}", ) def visit_Repeat0(self, node: Repeat0) -> FunctionCall: if node in self.cache: return self.cache[node] name = self.gen.artificial_rule_from_repeat(node.node, False) self.cache[node] = FunctionCall( assigned_variable=f"{name}_var", function=f"{name}_rule", arguments=["p"], return_type="asdl_seq *", comment=f"{node}", ) return self.cache[node] def visit_Repeat1(self, node: Repeat1) -> FunctionCall: if node in self.cache: return self.cache[node] name = self.gen.artificial_rule_from_repeat(node.node, True) self.cache[node] = FunctionCall( assigned_variable=f"{name}_var", function=f"{name}_rule", arguments=["p"], return_type="asdl_seq *", comment=f"{node}", ) return self.cache[node] def visit_Gather(self, node: Gather) -> FunctionCall: if node in self.cache: return self.cache[node] name = self.gen.artifical_rule_from_gather(node) self.cache[node] = FunctionCall( assigned_variable=f"{name}_var", function=f"{name}_rule", arguments=["p"], return_type="asdl_seq *", comment=f"{node}", ) return self.cache[node] def visit_Group(self, node: Group) -> FunctionCall: return self.generate_call(node.rhs) def visit_Cut(self, node: Cut) -> FunctionCall: return FunctionCall( assigned_variable="_cut_var", return_type="int", function="1", nodetype=NodeTypes.CUT_OPERATOR, ) def generate_call(self, node: Any) -> FunctionCall: return super().visit(node) class CParserGenerator(ParserGenerator, GrammarVisitor): def __init__( self, grammar: grammar.Grammar, tokens: Dict[int, str], exact_tokens: Dict[str, int], non_exact_tokens: Set[str], file: Optional[IO[Text]], debug: bool = False, skip_actions: bool = False, ): super().__init__(grammar, set(tokens.values()), file) self.callmakervisitor: CCallMakerVisitor = CCallMakerVisitor( self, exact_tokens, non_exact_tokens ) self._varname_counter = 0 self.debug = debug self.skip_actions = skip_actions self.cleanup_statements: List[str] = [] def add_level(self) -> None: self.print("if (p->level++ == MAXSTACK) {") with self.indent(): self.print("p->error_indicator = 1;") self.print("PyErr_NoMemory();") self.print("}") def remove_level(self) -> None: self.print("p->level--;") def add_return(self, ret_val: str) -> None: for stmt in self.cleanup_statements: self.print(stmt) self.remove_level() self.print(f"return {ret_val};") def unique_varname(self, name: str = "tmpvar") -> str: new_var = name + "_" + str(self._varname_counter) self._varname_counter += 1 return new_var def call_with_errorcheck_return(self, call_text: str, returnval: str) -> None: error_var = self.unique_varname() self.print(f"int {error_var} = {call_text};") self.print(f"if ({error_var}) {{") with self.indent(): self.add_return(returnval) self.print("}") def call_with_errorcheck_goto(self, call_text: str, goto_target: str) -> None: error_var = self.unique_varname() self.print(f"int {error_var} = {call_text};") self.print(f"if ({error_var}) {{") with self.indent(): self.print(f"goto {goto_target};") self.print(f"}}") def out_of_memory_return( self, expr: str, cleanup_code: Optional[str] = None, ) -> None: self.print(f"if ({expr}) {{") with self.indent(): if cleanup_code is not None: self.print(cleanup_code) self.print("p->error_indicator = 1;") self.print("PyErr_NoMemory();") self.add_return("NULL") self.print(f"}}") def out_of_memory_goto(self, expr: str, goto_target: str) -> None: self.print(f"if ({expr}) {{") with self.indent(): self.print("PyErr_NoMemory();") self.print(f"goto {goto_target};") self.print(f"}}") def generate(self, filename: str) -> None: self.collect_rules() basename = os.path.basename(filename) self.print(f"// @generated by pegen from {basename}") header = self.grammar.metas.get("header", EXTENSION_PREFIX) if header: self.print(header.rstrip("\n")) subheader = self.grammar.metas.get("subheader", "") if subheader: self.print(subheader) self._setup_keywords() self._setup_soft_keywords() for i, (rulename, rule) in enumerate(self.all_rules.items(), 1000): comment = " // Left-recursive" if rule.left_recursive else "" self.print(f"#define {rulename}_type {i}{comment}") self.print() for rulename, rule in self.all_rules.items(): if rule.is_loop() or rule.is_gather(): type = "asdl_seq *" elif rule.type: type = rule.type + " " else: type = "void *" self.print(f"static {type}{rulename}_rule(Parser *p);") self.print() for rulename, rule in list(self.all_rules.items()): self.print() if rule.left_recursive: self.print("// Left-recursive") self.visit(rule) if self.skip_actions: mode = 0 else: mode = int(self.rules["start"].type == "mod_ty") if "start" in self.rules else 1 if mode == 1 and self.grammar.metas.get("bytecode"): mode += 1 modulename = self.grammar.metas.get("modulename", "parse") trailer = self.grammar.metas.get("trailer", EXTENSION_SUFFIX) if trailer: self.print(trailer.rstrip("\n") % dict(mode=mode, modulename=modulename)) def _group_keywords_by_length(self) -> Dict[int, List[Tuple[str, int]]]: groups: Dict[int, List[Tuple[str, int]]] = {} for keyword_str, keyword_type in self.keywords.items(): length = len(keyword_str) if length in groups: groups[length].append((keyword_str, keyword_type)) else: groups[length] = [(keyword_str, keyword_type)] return groups def _setup_keywords(self) -> None: n_keyword_lists = ( len(max(self.keywords.keys(), key=len)) + 1 if len(self.keywords) > 0 else 0 ) self.print(f"static const int n_keyword_lists = {n_keyword_lists};") groups = self._group_keywords_by_length() self.print("static KeywordToken *reserved_keywords[] = {") with self.indent(): num_groups = max(groups) + 1 if groups else 1 for keywords_length in range(num_groups): if keywords_length not in groups.keys(): self.print("(KeywordToken[]) {{NULL, -1}},") else: self.print("(KeywordToken[]) {") with self.indent(): for keyword_str, keyword_type in groups[keywords_length]: self.print(f'{{"{keyword_str}", {keyword_type}}},') self.print("{NULL, -1},") self.print("},") self.print("};") def _setup_soft_keywords(self) -> None: soft_keywords = sorted(self.soft_keywords) self.print("static char *soft_keywords[] = {") with self.indent(): for keyword in soft_keywords: self.print(f'"{keyword}",') self.print("NULL,") self.print("};") def _set_up_token_start_metadata_extraction(self) -> None: self.print("if (p->mark == p->fill && _PyPegen_fill_token(p) < 0) {") with self.indent(): self.print("p->error_indicator = 1;") self.add_return("NULL") self.print("}") self.print("int _start_lineno = p->tokens[_mark]->lineno;") self.print("UNUSED(_start_lineno); // Only used by EXTRA macro") self.print("int _start_col_offset = p->tokens[_mark]->col_offset;") self.print("UNUSED(_start_col_offset); // Only used by EXTRA macro") def _set_up_token_end_metadata_extraction(self) -> None: self.print("Token *_token = _PyPegen_get_last_nonnwhitespace_token(p);") self.print("if (_token == NULL) {") with self.indent(): self.add_return("NULL") self.print("}") self.print("int _end_lineno = _token->end_lineno;") self.print("UNUSED(_end_lineno); // Only used by EXTRA macro") self.print("int _end_col_offset = _token->end_col_offset;") self.print("UNUSED(_end_col_offset); // Only used by EXTRA macro") def _check_for_errors(self) -> None: self.print("if (p->error_indicator) {") with self.indent(): self.add_return("NULL") self.print("}") def _set_up_rule_memoization(self, node: Rule, result_type: str) -> None: self.print("{") with self.indent(): self.add_level() self.print(f"{result_type} _res = NULL;") self.print(f"if (_PyPegen_is_memoized(p, {node.name}_type, &_res)) {{") with self.indent(): self.add_return("_res") self.print("}") self.print("int _mark = p->mark;") self.print("int _resmark = p->mark;") self.print("while (1) {") with self.indent(): self.call_with_errorcheck_return( f"_PyPegen_update_memo(p, _mark, {node.name}_type, _res)", "_res" ) self.print("p->mark = _mark;") self.print(f"void *_raw = {node.name}_raw(p);") self.print("if (p->error_indicator) {") with self.indent(): self.add_return("NULL") self.print("}") self.print("if (_raw == NULL || p->mark <= _resmark)") with self.indent(): self.print("break;") self.print(f"_resmark = p->mark;") self.print("_res = _raw;") self.print("}") self.print(f"p->mark = _resmark;") self.add_return("_res") self.print("}") self.print(f"static {result_type}") self.print(f"{node.name}_raw(Parser *p)") def _should_memoize(self, node: Rule) -> bool: return node.memo and not node.left_recursive def _handle_default_rule_body(self, node: Rule, rhs: Rhs, result_type: str) -> None: memoize = self._should_memoize(node) with self.indent(): self.add_level() self._check_for_errors() self.print(f"{result_type} _res = NULL;") if memoize: self.print(f"if (_PyPegen_is_memoized(p, {node.name}_type, &_res)) {{") with self.indent(): self.add_return("_res") self.print("}") self.print("int _mark = p->mark;") if any(alt.action and "EXTRA" in alt.action for alt in rhs.alts): self._set_up_token_start_metadata_extraction() self.visit( rhs, is_loop=False, is_gather=node.is_gather(), rulename=node.name, ) if self.debug: self.print(f'D(fprintf(stderr, "Fail at %d: {node.name}\\n", p->mark));') self.print("_res = NULL;") self.print(" done:") with self.indent(): if memoize: self.print(f"_PyPegen_insert_memo(p, _mark, {node.name}_type, _res);") self.add_return("_res") def _handle_loop_rule_body(self, node: Rule, rhs: Rhs) -> None: memoize = self._should_memoize(node) is_repeat1 = node.name.startswith("_loop1") with self.indent(): self.add_level() self._check_for_errors() self.print("void *_res = NULL;") if memoize: self.print(f"if (_PyPegen_is_memoized(p, {node.name}_type, &_res)) {{") with self.indent(): self.add_return("_res") self.print("}") self.print("int _mark = p->mark;") self.print("int _start_mark = p->mark;") self.print("void **_children = PyMem_Malloc(sizeof(void *));") self.out_of_memory_return(f"!_children") self.print("Py_ssize_t _children_capacity = 1;") self.print("Py_ssize_t _n = 0;") if any(alt.action and "EXTRA" in alt.action for alt in rhs.alts): self._set_up_token_start_metadata_extraction() self.visit( rhs, is_loop=True, is_gather=node.is_gather(), rulename=node.name, ) if is_repeat1: self.print("if (_n == 0 || p->error_indicator) {") with self.indent(): self.print("PyMem_Free(_children);") self.add_return("NULL") self.print("}") self.print("asdl_seq *_seq = (asdl_seq*)_Py_asdl_generic_seq_new(_n, p->arena);") self.out_of_memory_return(f"!_seq", cleanup_code="PyMem_Free(_children);") self.print("for (int i = 0; i < _n; i++) asdl_seq_SET_UNTYPED(_seq, i, _children[i]);") self.print("PyMem_Free(_children);") if node.name: self.print(f"_PyPegen_insert_memo(p, _start_mark, {node.name}_type, _seq);") self.add_return("_seq") def visit_Rule(self, node: Rule) -> None: is_loop = node.is_loop() is_gather = node.is_gather() rhs = node.flatten() if is_loop or is_gather: result_type = "asdl_seq *" elif node.type: result_type = node.type else: result_type = "void *" for line in str(node).splitlines(): self.print(f"// {line}") if node.left_recursive and node.leader: self.print(f"static {result_type} {node.name}_raw(Parser *);") self.print(f"static {result_type}") self.print(f"{node.name}_rule(Parser *p)") if node.left_recursive and node.leader: self._set_up_rule_memoization(node, result_type) self.print("{") if node.name.endswith("without_invalid"): with self.indent(): self.print("int _prev_call_invalid = p->call_invalid_rules;") self.print("p->call_invalid_rules = 0;") self.cleanup_statements.append("p->call_invalid_rules = _prev_call_invalid;") if is_loop: self._handle_loop_rule_body(node, rhs) else: self._handle_default_rule_body(node, rhs, result_type) if node.name.endswith("without_invalid"): self.cleanup_statements.pop() self.print("}") def visit_NamedItem(self, node: NamedItem) -> None: call = self.callmakervisitor.generate_call(node) if call.assigned_variable: call.assigned_variable = self.dedupe(call.assigned_variable) self.print(call) def visit_Rhs( self, node: Rhs, is_loop: bool, is_gather: bool, rulename: Optional[str] ) -> None: if is_loop: assert len(node.alts) == 1 for alt in node.alts: self.visit(alt, is_loop=is_loop, is_gather=is_gather, rulename=rulename) def join_conditions(self, keyword: str, node: Any) -> None: self.print(f"{keyword} (") with self.indent(): first = True for item in node.items: if first: first = False else: self.print("&&") self.visit(item) self.print(")") def emit_action(self, node: Alt, cleanup_code: Optional[str] = None) -> None: self.print(f"_res = {node.action};") self.print("if (_res == NULL && PyErr_Occurred()) {") with self.indent(): self.print("p->error_indicator = 1;") if cleanup_code: self.print(cleanup_code) self.add_return("NULL") self.print("}") if self.debug: self.print( f'D(fprintf(stderr, "Hit with action [%d-%d]: %s\\n", _mark, p->mark, "{node}"));' ) def emit_default_action(self, is_gather: bool, node: Alt) -> None: if len(self.local_variable_names) > 1: if is_gather: assert len(self.local_variable_names) == 2 self.print( f"_res = _PyPegen_seq_insert_in_front(p, " f"{self.local_variable_names[0]}, {self.local_variable_names[1]});" ) else: if self.debug: self.print( f'D(fprintf(stderr, "Hit without action [%d:%d]: %s\\n", _mark, p->mark, "{node}"));' ) self.print( f"_res = _PyPegen_dummy_name(p, {', '.join(self.local_variable_names)});" ) else: if self.debug: self.print( f'D(fprintf(stderr, "Hit with default action [%d:%d]: %s\\n", _mark, p->mark, "{node}"));' ) self.print(f"_res = {self.local_variable_names[0]};") def emit_dummy_action(self) -> None: self.print("_res = _PyPegen_dummy_name(p);") def handle_alt_normal(self, node: Alt, is_gather: bool, rulename: Optional[str]) -> None: self.join_conditions(keyword="if", node=node) self.print("{") # We have parsed successfully all the conditions for the option. with self.indent(): node_str = str(node).replace('"', '\\"') self.print( f'D(fprintf(stderr, "%*c+ {rulename}[%d-%d]: %s succeeded!\\n", p->level, \' \', _mark, p->mark, "{node_str}"));' ) # Prepare to emit the rule action and do so if node.action and "EXTRA" in node.action: self._set_up_token_end_metadata_extraction() if self.skip_actions: self.emit_dummy_action() elif node.action: self.emit_action(node) else: self.emit_default_action(is_gather, node) # As the current option has parsed correctly, do not continue with the rest. self.print(f"goto done;") self.print("}") def handle_alt_loop(self, node: Alt, is_gather: bool, rulename: Optional[str]) -> None: # Condition of the main body of the alternative self.join_conditions(keyword="while", node=node) self.print("{") # We have parsed successfully one item! with self.indent(): # Prepare to emit the rule action and do so if node.action and "EXTRA" in node.action: self._set_up_token_end_metadata_extraction() if self.skip_actions: self.emit_dummy_action() elif node.action: self.emit_action(node, cleanup_code="PyMem_Free(_children);") else: self.emit_default_action(is_gather, node) # Add the result of rule to the temporary buffer of children. This buffer # will populate later an asdl_seq with all elements to return. self.print("if (_n == _children_capacity) {") with self.indent(): self.print("_children_capacity *= 2;") self.print( "void **_new_children = PyMem_Realloc(_children, _children_capacity*sizeof(void *));" ) self.out_of_memory_return(f"!_new_children") self.print("_children = _new_children;") self.print("}") self.print("_children[_n++] = _res;") self.print("_mark = p->mark;") self.print("}") def visit_Alt( self, node: Alt, is_loop: bool, is_gather: bool, rulename: Optional[str] ) -> None: if len(node.items) == 1 and str(node.items[0]).startswith("invalid_"): self.print(f"if (p->call_invalid_rules) {{ // {node}") else: self.print(f"{{ // {node}") with self.indent(): self._check_for_errors() node_str = str(node).replace('"', '\\"') self.print( f'D(fprintf(stderr, "%*c> {rulename}[%d-%d]: %s\\n", p->level, \' \', _mark, p->mark, "{node_str}"));' ) # Prepare variable declarations for the alternative vars = self.collect_vars(node) for v, var_type in sorted(item for item in vars.items() if item[0] is not None): if not var_type: var_type = "void *" else: var_type += " " if v == "_cut_var": v += " = 0" # cut_var must be initialized self.print(f"{var_type}{v};") if v and v.startswith("_opt_var"): self.print(f"UNUSED({v}); // Silence compiler warnings") with self.local_variable_context(): if is_loop: self.handle_alt_loop(node, is_gather, rulename) else: self.handle_alt_normal(node, is_gather, rulename) self.print("p->mark = _mark;") node_str = str(node).replace('"', '\\"') self.print( f"D(fprintf(stderr, \"%*c%s {rulename}[%d-%d]: %s failed!\\n\", p->level, ' ',\n" f' p->error_indicator ? "ERROR!" : "-", _mark, p->mark, "{node_str}"));' ) if "_cut_var" in vars: self.print("if (_cut_var) {") with self.indent(): self.add_return("NULL") self.print("}") self.print("}") def collect_vars(self, node: Alt) -> Dict[Optional[str], Optional[str]]: types = {} with self.local_variable_context(): for item in node.items: name, type = self.add_var(item) types[name] = type return types def add_var(self, node: NamedItem) -> Tuple[Optional[str], Optional[str]]: call = self.callmakervisitor.generate_call(node.item) name = node.name if node.name else call.assigned_variable if name is not None: name = self.dedupe(name) return_type = call.return_type if node.type is None else node.type return name, return_type