from mypy.util import unnamed_function import copy import re import sys import warnings import typing # for typing.Type, which conflicts with types.Type from typing import ( Tuple, Union, TypeVar, Callable, Sequence, Optional, Any, Dict, cast, List ) from typing_extensions import Final, Literal, overload from mypy.sharedparse import ( special_function_elide_names, argument_elide_name, ) from mypy.nodes import ( MypyFile, Node, ImportBase, Import, ImportAll, ImportFrom, FuncDef, OverloadedFuncDef, OverloadPart, ClassDef, Decorator, Block, Var, OperatorAssignmentStmt, ExpressionStmt, AssignmentStmt, ReturnStmt, RaiseStmt, AssertStmt, DelStmt, BreakStmt, ContinueStmt, PassStmt, GlobalDecl, WhileStmt, ForStmt, IfStmt, TryStmt, WithStmt, MatchStmt, TupleExpr, GeneratorExpr, ListComprehension, ListExpr, ConditionalExpr, DictExpr, SetExpr, NameExpr, IntExpr, StrExpr, BytesExpr, UnicodeExpr, FloatExpr, CallExpr, SuperExpr, MemberExpr, IndexExpr, SliceExpr, OpExpr, UnaryExpr, LambdaExpr, ComparisonExpr, AssignmentExpr, StarExpr, YieldFromExpr, NonlocalDecl, DictionaryComprehension, SetComprehension, ComplexExpr, EllipsisExpr, YieldExpr, Argument, AwaitExpr, TempNode, RefExpr, Expression, Statement, ArgKind, ARG_POS, ARG_OPT, ARG_STAR, ARG_NAMED, ARG_NAMED_OPT, ARG_STAR2, check_arg_names, FakeInfo, ) from mypy.patterns import ( AsPattern, OrPattern, ValuePattern, SequencePattern, StarredPattern, MappingPattern, ClassPattern, SingletonPattern ) from mypy.types import ( Type, CallableType, AnyType, UnboundType, TupleType, TypeList, EllipsisType, CallableArgument, TypeOfAny, Instance, RawExpressionType, ProperType, UnionType, ) from mypy import defaults from mypy import message_registry, errorcodes as codes from mypy.errors import Errors from mypy.options import Options from mypy.reachability import infer_reachability_of_if_statement, mark_block_unreachable from mypy.util import bytes_to_human_readable_repr try: # pull this into a final variable to make mypyc be quiet about the # the default argument warning PY_MINOR_VERSION: Final = sys.version_info[1] # Check if we can use the stdlib ast module instead of typed_ast. if sys.version_info >= (3, 8): import ast as ast3 assert 'kind' in ast3.Constant._fields, \ f"This 3.8.0 alpha ({sys.version.split()[0]}) is too old; 3.8.0a3 required" # TODO: Num, Str, Bytes, NameConstant, Ellipsis are deprecated in 3.8. # TODO: Index, ExtSlice are deprecated in 3.9. from ast import ( AST, Call, FunctionType, Name, Attribute, Ellipsis as ast3_Ellipsis, Starred, NameConstant, Expression as ast3_Expression, Str, Bytes, Index, Num, UnaryOp, USub, ) def ast3_parse(source: Union[str, bytes], filename: str, mode: str, feature_version: int = PY_MINOR_VERSION) -> AST: return ast3.parse(source, filename, mode, type_comments=True, # This works the magic feature_version=feature_version) NamedExpr = ast3.NamedExpr Constant = ast3.Constant else: from typed_ast import ast3 from typed_ast.ast3 import ( AST, Call, FunctionType, Name, Attribute, Ellipsis as ast3_Ellipsis, Starred, NameConstant, Expression as ast3_Expression, Str, Bytes, Index, Num, UnaryOp, USub, ) def ast3_parse(source: Union[str, bytes], filename: str, mode: str, feature_version: int = PY_MINOR_VERSION) -> AST: return ast3.parse(source, filename, mode, feature_version=feature_version) # These don't exist before 3.8 NamedExpr = Any Constant = Any if sys.version_info >= (3, 10): Match = ast3.Match MatchValue = ast3.MatchValue MatchSingleton = ast3.MatchSingleton MatchSequence = ast3.MatchSequence MatchStar = ast3.MatchStar MatchMapping = ast3.MatchMapping MatchClass = ast3.MatchClass MatchAs = ast3.MatchAs MatchOr = ast3.MatchOr AstNode = Union[ast3.expr, ast3.stmt, ast3.pattern, ast3.ExceptHandler] else: Match = Any MatchValue = Any MatchSingleton = Any MatchSequence = Any MatchStar = Any MatchMapping = Any MatchClass = Any MatchAs = Any MatchOr = Any AstNode = Union[ast3.expr, ast3.stmt, ast3.ExceptHandler] except ImportError: try: from typed_ast import ast35 # type: ignore[attr-defined] # noqa: F401 except ImportError: print('The typed_ast package is not installed.\n' 'You can install it with `python3 -m pip install typed-ast`.', file=sys.stderr) else: print('You need a more recent version of the typed_ast package.\n' 'You can update to the latest version with ' '`python3 -m pip install -U typed-ast`.', file=sys.stderr) sys.exit(1) N = TypeVar('N', bound=Node) # There is no way to create reasonable fallbacks at this stage, # they must be patched later. MISSING_FALLBACK: Final = FakeInfo("fallback can't be filled out until semanal") _dummy_fallback: Final = Instance(MISSING_FALLBACK, [], -1) TYPE_COMMENT_SYNTAX_ERROR: Final = "syntax error in type comment" INVALID_TYPE_IGNORE: Final = 'Invalid "type: ignore" comment' TYPE_IGNORE_PATTERN: Final = re.compile(r'[^#]*#\s*type:\s*ignore\s*(.*)') def parse(source: Union[str, bytes], fnam: str, module: Optional[str], errors: Optional[Errors] = None, options: Optional[Options] = None) -> MypyFile: """Parse a source file, without doing any semantic analysis. Return the parse tree. If errors is not provided, raise ParseError on failure. Otherwise, use the errors object to report parse errors. """ raise_on_error = False if errors is None: errors = Errors() raise_on_error = True if options is None: options = Options() errors.set_file(fnam, module) is_stub_file = fnam.endswith('.pyi') try: if is_stub_file: feature_version = defaults.PYTHON3_VERSION[1] else: assert options.python_version[0] >= 3 feature_version = options.python_version[1] # Disable deprecation warnings about \u with warnings.catch_warnings(): warnings.filterwarnings("ignore", category=DeprecationWarning) ast = ast3_parse(source, fnam, 'exec', feature_version=feature_version) tree = ASTConverter(options=options, is_stub=is_stub_file, errors=errors, ).visit(ast) tree.path = fnam tree.is_stub = is_stub_file except SyntaxError as e: # alias to please mypyc is_py38_or_earlier = sys.version_info < (3, 9) if is_py38_or_earlier and e.filename == "": # In Python 3.8 and earlier, syntax errors in f-strings have lineno relative to the # start of the f-string. This would be misleading, as mypy will report the error as the # lineno within the file. e.lineno = None errors.report(e.lineno if e.lineno is not None else -1, e.offset, e.msg, blocker=True, code=codes.SYNTAX) tree = MypyFile([], [], False, {}) if raise_on_error and errors.is_errors(): errors.raise_error() return tree def parse_type_ignore_tag(tag: Optional[str]) -> Optional[List[str]]: """Parse optional "[code, ...]" tag after "# type: ignore". Return: * [] if no tag was found (ignore all errors) * list of ignored error codes if a tag was found * None if the tag was invalid. """ if not tag or tag.strip() == '' or tag.strip().startswith('#'): # No tag -- ignore all errors. return [] m = re.match(r'\s*\[([^]#]*)\]\s*(#.*)?$', tag) if m is None: # Invalid "# type: ignore" comment. return None return [code.strip() for code in m.group(1).split(',')] def parse_type_comment(type_comment: str, line: int, column: int, errors: Optional[Errors], assume_str_is_unicode: bool = True, ) -> Tuple[Optional[List[str]], Optional[ProperType]]: """Parse type portion of a type comment (+ optional type ignore). Return (ignore info, parsed type). """ try: typ = ast3_parse(type_comment, '', 'eval') except SyntaxError: if errors is not None: stripped_type = type_comment.split("#", 2)[0].strip() err_msg = f'{TYPE_COMMENT_SYNTAX_ERROR} "{stripped_type}"' errors.report(line, column, err_msg, blocker=True, code=codes.SYNTAX) return None, None else: raise else: extra_ignore = TYPE_IGNORE_PATTERN.match(type_comment) if extra_ignore: # Typeshed has a non-optional return type for group! tag: Optional[str] = cast(Any, extra_ignore).group(1) ignored: Optional[List[str]] = parse_type_ignore_tag(tag) if ignored is None: if errors is not None: errors.report(line, column, INVALID_TYPE_IGNORE, code=codes.SYNTAX) else: raise SyntaxError else: ignored = None assert isinstance(typ, ast3_Expression) converted = TypeConverter(errors, line=line, override_column=column, assume_str_is_unicode=assume_str_is_unicode, is_evaluated=False).visit(typ.body) return ignored, converted def parse_type_string(expr_string: str, expr_fallback_name: str, line: int, column: int, assume_str_is_unicode: bool = True) -> ProperType: """Parses a type that was originally present inside of an explicit string, byte string, or unicode string. For example, suppose we have the type `Foo["blah"]`. We should parse the string expression "blah" using this function. If `assume_str_is_unicode` is set to true, this function will assume that `Foo["blah"]` is equivalent to `Foo[u"blah"]`. Otherwise, it assumes it's equivalent to `Foo[b"blah"]`. The caller is responsible for keeping track of the context in which the type string was encountered (e.g. in Python 3 code, Python 2 code, Python 2 code with unicode_literals...) and setting `assume_str_is_unicode` accordingly. """ try: _, node = parse_type_comment(expr_string.strip(), line=line, column=column, errors=None, assume_str_is_unicode=assume_str_is_unicode) if isinstance(node, UnboundType) and node.original_str_expr is None: node.original_str_expr = expr_string node.original_str_fallback = expr_fallback_name return node elif isinstance(node, UnionType): return node else: return RawExpressionType(expr_string, expr_fallback_name, line, column) except (SyntaxError, ValueError): # Note: the parser will raise a `ValueError` instead of a SyntaxError if # the string happens to contain things like \x00. return RawExpressionType(expr_string, expr_fallback_name, line, column) def is_no_type_check_decorator(expr: ast3.expr) -> bool: if isinstance(expr, Name): return expr.id == 'no_type_check' elif isinstance(expr, Attribute): if isinstance(expr.value, Name): return expr.value.id == 'typing' and expr.attr == 'no_type_check' return False class ASTConverter: def __init__(self, options: Options, is_stub: bool, errors: Errors) -> None: # 'C' for class, 'F' for function self.class_and_function_stack: List[Literal["C", "F"]] = [] self.imports: List[ImportBase] = [] self.options = options self.is_stub = is_stub self.errors = errors self.type_ignores: Dict[int, List[str]] = {} # Cache of visit_X methods keyed by type of visited object self.visitor_cache: Dict[type, Callable[[Optional[AST]], Any]] = {} def note(self, msg: str, line: int, column: int) -> None: self.errors.report(line, column, msg, severity='note', code=codes.SYNTAX) def fail(self, msg: str, line: int, column: int, blocker: bool = True, code: codes.ErrorCode = codes.SYNTAX) -> None: if blocker or not self.options.ignore_errors: self.errors.report(line, column, msg, blocker=blocker, code=code) def fail_merge_overload(self, node: IfStmt) -> None: self.fail( "Condition can't be inferred, unable to merge overloads", line=node.line, column=node.column, blocker=False, code=codes.MISC, ) def visit(self, node: Optional[AST]) -> Any: if node is None: return None typeobj = type(node) visitor = self.visitor_cache.get(typeobj) if visitor is None: method = 'visit_' + node.__class__.__name__ visitor = getattr(self, method) self.visitor_cache[typeobj] = visitor return visitor(node) def set_line(self, node: N, n: AstNode) -> N: node.line = n.lineno node.column = n.col_offset node.end_line = getattr(n, "end_lineno", None) if isinstance(n, ast3.expr) else None node.end_column = getattr(n, "end_col_offset", None) if isinstance(n, ast3.expr) else None return node def translate_opt_expr_list(self, l: Sequence[Optional[AST]]) -> List[Optional[Expression]]: res: List[Optional[Expression]] = [] for e in l: exp = self.visit(e) res.append(exp) return res def translate_expr_list(self, l: Sequence[AST]) -> List[Expression]: return cast(List[Expression], self.translate_opt_expr_list(l)) def get_lineno(self, node: Union[ast3.expr, ast3.stmt]) -> int: if (isinstance(node, (ast3.AsyncFunctionDef, ast3.ClassDef, ast3.FunctionDef)) and node.decorator_list): return node.decorator_list[0].lineno return node.lineno def translate_stmt_list(self, stmts: Sequence[ast3.stmt], ismodule: bool = False) -> List[Statement]: # A "# type: ignore" comment before the first statement of a module # ignores the whole module: if (ismodule and stmts and self.type_ignores and min(self.type_ignores) < self.get_lineno(stmts[0])): self.errors.used_ignored_lines[self.errors.file][min(self.type_ignores)].append( codes.FILE.code) block = Block(self.fix_function_overloads(self.translate_stmt_list(stmts))) mark_block_unreachable(block) return [block] res: List[Statement] = [] for stmt in stmts: node = self.visit(stmt) res.append(node) return res def translate_type_comment(self, n: Union[ast3.stmt, ast3.arg], type_comment: Optional[str]) -> Optional[ProperType]: if type_comment is None: return None else: lineno = n.lineno extra_ignore, typ = parse_type_comment(type_comment, lineno, n.col_offset, self.errors) if extra_ignore is not None: self.type_ignores[lineno] = extra_ignore return typ op_map: Final[Dict[typing.Type[AST], str]] = { ast3.Add: '+', ast3.Sub: '-', ast3.Mult: '*', ast3.MatMult: '@', ast3.Div: '/', ast3.Mod: '%', ast3.Pow: '**', ast3.LShift: '<<', ast3.RShift: '>>', ast3.BitOr: '|', ast3.BitXor: '^', ast3.BitAnd: '&', ast3.FloorDiv: '//' } def from_operator(self, op: ast3.operator) -> str: op_name = ASTConverter.op_map.get(type(op)) if op_name is None: raise RuntimeError('Unknown operator ' + str(type(op))) else: return op_name comp_op_map: Final[Dict[typing.Type[AST], str]] = { ast3.Gt: '>', ast3.Lt: '<', ast3.Eq: '==', ast3.GtE: '>=', ast3.LtE: '<=', ast3.NotEq: '!=', ast3.Is: 'is', ast3.IsNot: 'is not', ast3.In: 'in', ast3.NotIn: 'not in' } def from_comp_operator(self, op: ast3.cmpop) -> str: op_name = ASTConverter.comp_op_map.get(type(op)) if op_name is None: raise RuntimeError('Unknown comparison operator ' + str(type(op))) else: return op_name def as_block(self, stmts: List[ast3.stmt], lineno: int) -> Optional[Block]: b = None if stmts: b = Block(self.fix_function_overloads(self.translate_stmt_list(stmts))) b.set_line(lineno) return b def as_required_block(self, stmts: List[ast3.stmt], lineno: int) -> Block: assert stmts # must be non-empty b = Block(self.fix_function_overloads(self.translate_stmt_list(stmts))) b.set_line(lineno) return b def fix_function_overloads(self, stmts: List[Statement]) -> List[Statement]: ret: List[Statement] = [] current_overload: List[OverloadPart] = [] current_overload_name: Optional[str] = None seen_unconditional_func_def = False last_if_stmt: Optional[IfStmt] = None last_if_overload: Optional[Union[Decorator, FuncDef, OverloadedFuncDef]] = None last_if_stmt_overload_name: Optional[str] = None last_if_unknown_truth_value: Optional[IfStmt] = None skipped_if_stmts: List[IfStmt] = [] for stmt in stmts: if_overload_name: Optional[str] = None if_block_with_overload: Optional[Block] = None if_unknown_truth_value: Optional[IfStmt] = None if isinstance(stmt, IfStmt) and seen_unconditional_func_def is False: # Check IfStmt block to determine if function overloads can be merged if_overload_name = self._check_ifstmt_for_overloads(stmt, current_overload_name) if if_overload_name is not None: if_block_with_overload, if_unknown_truth_value = \ self._get_executable_if_block_with_overloads(stmt) if (current_overload_name is not None and isinstance(stmt, (Decorator, FuncDef)) and stmt.name == current_overload_name): if last_if_stmt is not None: skipped_if_stmts.append(last_if_stmt) if last_if_overload is not None: # Last stmt was an IfStmt with same overload name # Add overloads to current_overload if isinstance(last_if_overload, OverloadedFuncDef): current_overload.extend(last_if_overload.items) else: current_overload.append(last_if_overload) last_if_stmt, last_if_overload = None, None if last_if_unknown_truth_value: self.fail_merge_overload(last_if_unknown_truth_value) last_if_unknown_truth_value = None current_overload.append(stmt) if isinstance(stmt, FuncDef): seen_unconditional_func_def = True elif ( current_overload_name is not None and isinstance(stmt, IfStmt) and if_overload_name == current_overload_name ): # IfStmt only contains stmts relevant to current_overload. # Check if stmts are reachable and add them to current_overload, # otherwise skip IfStmt to allow subsequent overload # or function definitions. skipped_if_stmts.append(stmt) if if_block_with_overload is None: if if_unknown_truth_value is not None: self.fail_merge_overload(if_unknown_truth_value) continue if last_if_overload is not None: # Last stmt was an IfStmt with same overload name # Add overloads to current_overload if isinstance(last_if_overload, OverloadedFuncDef): current_overload.extend(last_if_overload.items) else: current_overload.append(last_if_overload) last_if_stmt, last_if_overload = None, None if isinstance(if_block_with_overload.body[-1], OverloadedFuncDef): skipped_if_stmts.extend( cast(List[IfStmt], if_block_with_overload.body[:-1]) ) current_overload.extend(if_block_with_overload.body[-1].items) else: current_overload.append( cast(Union[Decorator, FuncDef], if_block_with_overload.body[0]) ) else: if last_if_stmt is not None: ret.append(last_if_stmt) last_if_stmt_overload_name = current_overload_name last_if_stmt, last_if_overload = None, None last_if_unknown_truth_value = None if current_overload and current_overload_name == last_if_stmt_overload_name: # Remove last stmt (IfStmt) from ret if the overload names matched # Only happens if no executable block had been found in IfStmt skipped_if_stmts.append(cast(IfStmt, ret.pop())) if current_overload and skipped_if_stmts: # Add bare IfStmt (without overloads) to ret # Required for mypy to be able to still check conditions for if_stmt in skipped_if_stmts: self._strip_contents_from_if_stmt(if_stmt) ret.append(if_stmt) skipped_if_stmts = [] if len(current_overload) == 1: ret.append(current_overload[0]) elif len(current_overload) > 1: ret.append(OverloadedFuncDef(current_overload)) # If we have multiple decorated functions named "_" next to each, we want to treat # them as a series of regular FuncDefs instead of one OverloadedFuncDef because # most of mypy/mypyc assumes that all the functions in an OverloadedFuncDef are # related, but multiple underscore functions next to each other aren't necessarily # related seen_unconditional_func_def = False if isinstance(stmt, Decorator) and not unnamed_function(stmt.name): current_overload = [stmt] current_overload_name = stmt.name elif ( isinstance(stmt, IfStmt) and if_overload_name is not None ): current_overload = [] current_overload_name = if_overload_name last_if_stmt = stmt last_if_stmt_overload_name = None if if_block_with_overload is not None: skipped_if_stmts.extend( cast(List[IfStmt], if_block_with_overload.body[:-1]) ) last_if_overload = cast( Union[Decorator, FuncDef, OverloadedFuncDef], if_block_with_overload.body[-1] ) last_if_unknown_truth_value = if_unknown_truth_value else: current_overload = [] current_overload_name = None ret.append(stmt) if current_overload and skipped_if_stmts: # Add bare IfStmt (without overloads) to ret # Required for mypy to be able to still check conditions for if_stmt in skipped_if_stmts: self._strip_contents_from_if_stmt(if_stmt) ret.append(if_stmt) if len(current_overload) == 1: ret.append(current_overload[0]) elif len(current_overload) > 1: ret.append(OverloadedFuncDef(current_overload)) elif last_if_overload is not None: ret.append(last_if_overload) elif last_if_stmt is not None: ret.append(last_if_stmt) return ret def _check_ifstmt_for_overloads( self, stmt: IfStmt, current_overload_name: Optional[str] = None ) -> Optional[str]: """Check if IfStmt contains only overloads with the same name. Return overload_name if found, None otherwise. """ # Check that block only contains a single Decorator, FuncDef, or OverloadedFuncDef. # Multiple overloads have already been merged as OverloadedFuncDef. if not ( len(stmt.body[0].body) == 1 and ( isinstance(stmt.body[0].body[0], (Decorator, OverloadedFuncDef)) or current_overload_name is not None and isinstance(stmt.body[0].body[0], FuncDef) ) or len(stmt.body[0].body) > 1 and isinstance(stmt.body[0].body[-1], OverloadedFuncDef) and all( self._is_stripped_if_stmt(if_stmt) for if_stmt in stmt.body[0].body[:-1] ) ): return None overload_name = cast( Union[Decorator, FuncDef, OverloadedFuncDef], stmt.body[0].body[-1]).name if stmt.else_body is None: return overload_name if isinstance(stmt.else_body, Block) and len(stmt.else_body.body) == 1: # For elif: else_body contains an IfStmt itself -> do a recursive check. if ( isinstance(stmt.else_body.body[0], (Decorator, FuncDef, OverloadedFuncDef)) and stmt.else_body.body[0].name == overload_name ): return overload_name if ( isinstance(stmt.else_body.body[0], IfStmt) and self._check_ifstmt_for_overloads( stmt.else_body.body[0], current_overload_name ) == overload_name ): return overload_name return None def _get_executable_if_block_with_overloads( self, stmt: IfStmt ) -> Tuple[Optional[Block], Optional[IfStmt]]: """Return block from IfStmt that will get executed. Return 0 -> A block if sure that alternative blocks are unreachable. 1 -> An IfStmt if the reachability of it can't be inferred, i.e. the truth value is unknown. """ infer_reachability_of_if_statement(stmt, self.options) if ( stmt.else_body is None and stmt.body[0].is_unreachable is True ): # always False condition with no else return None, None if ( stmt.else_body is None or stmt.body[0].is_unreachable is False and stmt.else_body.is_unreachable is False ): # The truth value is unknown, thus not conclusive return None, stmt if stmt.else_body.is_unreachable is True: # else_body will be set unreachable if condition is always True return stmt.body[0], None if stmt.body[0].is_unreachable is True: # body will be set unreachable if condition is always False # else_body can contain an IfStmt itself (for elif) -> do a recursive check if isinstance(stmt.else_body.body[0], IfStmt): return self._get_executable_if_block_with_overloads(stmt.else_body.body[0]) return stmt.else_body, None return None, stmt def _strip_contents_from_if_stmt(self, stmt: IfStmt) -> None: """Remove contents from IfStmt. Needed to still be able to check the conditions after the contents have been merged with the surrounding function overloads. """ if len(stmt.body) == 1: stmt.body[0].body = [] if stmt.else_body and len(stmt.else_body.body) == 1: if isinstance(stmt.else_body.body[0], IfStmt): self._strip_contents_from_if_stmt(stmt.else_body.body[0]) else: stmt.else_body.body = [] def _is_stripped_if_stmt(self, stmt: Statement) -> bool: """Check stmt to make sure it is a stripped IfStmt. See also: _strip_contents_from_if_stmt """ if not isinstance(stmt, IfStmt): return False if not (len(stmt.body) == 1 and len(stmt.body[0].body) == 0): # Body not empty return False if not stmt.else_body or len(stmt.else_body.body) == 0: # No or empty else_body return True # For elif, IfStmt are stored recursively in else_body return self._is_stripped_if_stmt(stmt.else_body.body[0]) def in_method_scope(self) -> bool: return self.class_and_function_stack[-2:] == ['C', 'F'] def translate_module_id(self, id: str) -> str: """Return the actual, internal module id for a source text id. For example, translate '__builtin__' in Python 2 to 'builtins'. """ if id == self.options.custom_typing_module: return 'typing' elif id == '__builtin__' and self.options.python_version[0] == 2: # HACK: __builtin__ in Python 2 is aliases to builtins. However, the implementation # is named __builtin__.py (there is another layer of translation elsewhere). return 'builtins' return id def visit_Module(self, mod: ast3.Module) -> MypyFile: self.type_ignores = {} for ti in mod.type_ignores: parsed = parse_type_ignore_tag(ti.tag) # type: ignore[attr-defined] if parsed is not None: self.type_ignores[ti.lineno] = parsed else: self.fail(INVALID_TYPE_IGNORE, ti.lineno, -1) body = self.fix_function_overloads(self.translate_stmt_list(mod.body, ismodule=True)) return MypyFile(body, self.imports, False, self.type_ignores, ) # --- stmt --- # FunctionDef(identifier name, arguments args, # stmt* body, expr* decorator_list, expr? returns, string? type_comment) # arguments = (arg* args, arg? vararg, arg* kwonlyargs, expr* kw_defaults, # arg? kwarg, expr* defaults) def visit_FunctionDef(self, n: ast3.FunctionDef) -> Union[FuncDef, Decorator]: return self.do_func_def(n) # AsyncFunctionDef(identifier name, arguments args, # stmt* body, expr* decorator_list, expr? returns, string? type_comment) def visit_AsyncFunctionDef(self, n: ast3.AsyncFunctionDef) -> Union[FuncDef, Decorator]: return self.do_func_def(n, is_coroutine=True) def do_func_def(self, n: Union[ast3.FunctionDef, ast3.AsyncFunctionDef], is_coroutine: bool = False) -> Union[FuncDef, Decorator]: """Helper shared between visit_FunctionDef and visit_AsyncFunctionDef.""" self.class_and_function_stack.append('F') no_type_check = bool(n.decorator_list and any(is_no_type_check_decorator(d) for d in n.decorator_list)) lineno = n.lineno args = self.transform_args(n.args, lineno, no_type_check=no_type_check) if special_function_elide_names(n.name): for arg in args: arg.pos_only = True arg_kinds = [arg.kind for arg in args] arg_names = [None if arg.pos_only else arg.variable.name for arg in args] arg_types: List[Optional[Type]] = [] if no_type_check: arg_types = [None] * len(args) return_type = None elif n.type_comment is not None: try: func_type_ast = ast3_parse(n.type_comment, '', 'func_type') assert isinstance(func_type_ast, FunctionType) # for ellipsis arg if (len(func_type_ast.argtypes) == 1 and isinstance(func_type_ast.argtypes[0], ast3_Ellipsis)): if n.returns: # PEP 484 disallows both type annotations and type comments self.fail(message_registry.DUPLICATE_TYPE_SIGNATURES, lineno, n.col_offset) arg_types = [a.type_annotation if a.type_annotation is not None else AnyType(TypeOfAny.unannotated) for a in args] else: # PEP 484 disallows both type annotations and type comments if n.returns or any(a.type_annotation is not None for a in args): self.fail(message_registry.DUPLICATE_TYPE_SIGNATURES, lineno, n.col_offset) translated_args = (TypeConverter(self.errors, line=lineno, override_column=n.col_offset) .translate_expr_list(func_type_ast.argtypes)) arg_types = [a if a is not None else AnyType(TypeOfAny.unannotated) for a in translated_args] return_type = TypeConverter(self.errors, line=lineno).visit(func_type_ast.returns) # add implicit self type if self.in_method_scope() and len(arg_types) < len(args): arg_types.insert(0, AnyType(TypeOfAny.special_form)) except SyntaxError: stripped_type = n.type_comment.split("#", 2)[0].strip() err_msg = f'{TYPE_COMMENT_SYNTAX_ERROR} "{stripped_type}"' self.fail(err_msg, lineno, n.col_offset) if n.type_comment and n.type_comment[0] not in ["(", "#"]: self.note('Suggestion: wrap argument types in parentheses', lineno, n.col_offset) arg_types = [AnyType(TypeOfAny.from_error)] * len(args) return_type = AnyType(TypeOfAny.from_error) else: arg_types = [a.type_annotation for a in args] return_type = TypeConverter(self.errors, line=n.returns.lineno if n.returns else lineno).visit(n.returns) for arg, arg_type in zip(args, arg_types): self.set_type_optional(arg_type, arg.initializer) func_type = None if any(arg_types) or return_type: if len(arg_types) != 1 and any(isinstance(t, EllipsisType) for t in arg_types): self.fail("Ellipses cannot accompany other argument types " "in function type signature", lineno, n.col_offset) elif len(arg_types) > len(arg_kinds): self.fail('Type signature has too many arguments', lineno, n.col_offset, blocker=False) elif len(arg_types) < len(arg_kinds): self.fail('Type signature has too few arguments', lineno, n.col_offset, blocker=False) else: func_type = CallableType([a if a is not None else AnyType(TypeOfAny.unannotated) for a in arg_types], arg_kinds, arg_names, return_type if return_type is not None else AnyType(TypeOfAny.unannotated), _dummy_fallback) func_def = FuncDef( n.name, args, self.as_required_block(n.body, lineno), func_type) if isinstance(func_def.type, CallableType): # semanal.py does some in-place modifications we want to avoid func_def.unanalyzed_type = func_def.type.copy_modified() if is_coroutine: func_def.is_coroutine = True if func_type is not None: func_type.definition = func_def func_type.line = lineno if n.decorator_list: if sys.version_info < (3, 8): # Before 3.8, [typed_]ast the line number points to the first decorator. # In 3.8, it points to the 'def' line, where we want it. lineno += len(n.decorator_list) end_lineno: Optional[int] = None else: # Set end_lineno to the old pre-3.8 lineno, in order to keep # existing "# type: ignore" comments working: end_lineno = n.decorator_list[0].lineno + len(n.decorator_list) var = Var(func_def.name) var.is_ready = False var.set_line(lineno) func_def.is_decorated = True func_def.set_line(lineno, n.col_offset, end_lineno) func_def.body.set_line(lineno) # TODO: Why? deco = Decorator(func_def, self.translate_expr_list(n.decorator_list), var) first = n.decorator_list[0] deco.set_line(first.lineno, first.col_offset) retval: Union[FuncDef, Decorator] = deco else: # FuncDef overrides set_line -- can't use self.set_line func_def.set_line(lineno, n.col_offset) retval = func_def self.class_and_function_stack.pop() return retval def set_type_optional(self, type: Optional[Type], initializer: Optional[Expression]) -> None: if self.options.no_implicit_optional: return # Indicate that type should be wrapped in an Optional if arg is initialized to None. optional = isinstance(initializer, NameExpr) and initializer.name == 'None' if isinstance(type, UnboundType): type.optional = optional def transform_args(self, args: ast3.arguments, line: int, no_type_check: bool = False, ) -> List[Argument]: new_args = [] names: List[ast3.arg] = [] posonlyargs = getattr(args, "posonlyargs", cast(List[ast3.arg], [])) args_args = posonlyargs + args.args args_defaults = args.defaults num_no_defaults = len(args_args) - len(args_defaults) # positional arguments without defaults for i, a in enumerate(args_args[:num_no_defaults]): pos_only = i < len(posonlyargs) new_args.append(self.make_argument(a, None, ARG_POS, no_type_check, pos_only)) names.append(a) # positional arguments with defaults for i, (a, d) in enumerate(zip(args_args[num_no_defaults:], args_defaults)): pos_only = num_no_defaults + i < len(posonlyargs) new_args.append(self.make_argument(a, d, ARG_OPT, no_type_check, pos_only)) names.append(a) # *arg if args.vararg is not None: new_args.append(self.make_argument(args.vararg, None, ARG_STAR, no_type_check)) names.append(args.vararg) # keyword-only arguments with defaults for a, kd in zip(args.kwonlyargs, args.kw_defaults): new_args.append(self.make_argument( a, kd, ARG_NAMED if kd is None else ARG_NAMED_OPT, no_type_check)) names.append(a) # **kwarg if args.kwarg is not None: new_args.append(self.make_argument(args.kwarg, None, ARG_STAR2, no_type_check)) names.append(args.kwarg) check_arg_names([arg.variable.name for arg in new_args], names, self.fail_arg) return new_args def make_argument(self, arg: ast3.arg, default: Optional[ast3.expr], kind: ArgKind, no_type_check: bool, pos_only: bool = False) -> Argument: if no_type_check: arg_type = None else: annotation = arg.annotation type_comment = arg.type_comment if annotation is not None and type_comment is not None: self.fail(message_registry.DUPLICATE_TYPE_SIGNATURES, arg.lineno, arg.col_offset) arg_type = None if annotation is not None: arg_type = TypeConverter(self.errors, line=arg.lineno).visit(annotation) else: arg_type = self.translate_type_comment(arg, type_comment) if argument_elide_name(arg.arg): pos_only = True return Argument(Var(arg.arg), arg_type, self.visit(default), kind, pos_only) def fail_arg(self, msg: str, arg: ast3.arg) -> None: self.fail(msg, arg.lineno, arg.col_offset) # ClassDef(identifier name, # expr* bases, # keyword* keywords, # stmt* body, # expr* decorator_list) def visit_ClassDef(self, n: ast3.ClassDef) -> ClassDef: self.class_and_function_stack.append('C') keywords = [(kw.arg, self.visit(kw.value)) for kw in n.keywords if kw.arg] cdef = ClassDef(n.name, self.as_required_block(n.body, n.lineno), None, self.translate_expr_list(n.bases), metaclass=dict(keywords).get('metaclass'), keywords=keywords) cdef.decorators = self.translate_expr_list(n.decorator_list) # Set end_lineno to the old mypy 0.700 lineno, in order to keep # existing "# type: ignore" comments working: if sys.version_info < (3, 8): cdef.line = n.lineno + len(n.decorator_list) cdef.end_line = n.lineno else: cdef.line = n.lineno cdef.end_line = n.decorator_list[0].lineno if n.decorator_list else None cdef.column = n.col_offset self.class_and_function_stack.pop() return cdef # Return(expr? value) def visit_Return(self, n: ast3.Return) -> ReturnStmt: node = ReturnStmt(self.visit(n.value)) return self.set_line(node, n) # Delete(expr* targets) def visit_Delete(self, n: ast3.Delete) -> DelStmt: if len(n.targets) > 1: tup = TupleExpr(self.translate_expr_list(n.targets)) tup.set_line(n.lineno) node = DelStmt(tup) else: node = DelStmt(self.visit(n.targets[0])) return self.set_line(node, n) # Assign(expr* targets, expr? value, string? type_comment, expr? annotation) def visit_Assign(self, n: ast3.Assign) -> AssignmentStmt: lvalues = self.translate_expr_list(n.targets) rvalue = self.visit(n.value) typ = self.translate_type_comment(n, n.type_comment) s = AssignmentStmt(lvalues, rvalue, type=typ, new_syntax=False) return self.set_line(s, n) # AnnAssign(expr target, expr annotation, expr? value, int simple) def visit_AnnAssign(self, n: ast3.AnnAssign) -> AssignmentStmt: line = n.lineno if n.value is None: # always allow 'x: int' rvalue: Expression = TempNode(AnyType(TypeOfAny.special_form), no_rhs=True) rvalue.line = line rvalue.column = n.col_offset else: rvalue = self.visit(n.value) typ = TypeConverter(self.errors, line=line).visit(n.annotation) assert typ is not None typ.column = n.annotation.col_offset s = AssignmentStmt([self.visit(n.target)], rvalue, type=typ, new_syntax=True) return self.set_line(s, n) # AugAssign(expr target, operator op, expr value) def visit_AugAssign(self, n: ast3.AugAssign) -> OperatorAssignmentStmt: s = OperatorAssignmentStmt(self.from_operator(n.op), self.visit(n.target), self.visit(n.value)) return self.set_line(s, n) # For(expr target, expr iter, stmt* body, stmt* orelse, string? type_comment) def visit_For(self, n: ast3.For) -> ForStmt: target_type = self.translate_type_comment(n, n.type_comment) node = ForStmt(self.visit(n.target), self.visit(n.iter), self.as_required_block(n.body, n.lineno), self.as_block(n.orelse, n.lineno), target_type) return self.set_line(node, n) # AsyncFor(expr target, expr iter, stmt* body, stmt* orelse, string? type_comment) def visit_AsyncFor(self, n: ast3.AsyncFor) -> ForStmt: target_type = self.translate_type_comment(n, n.type_comment) node = ForStmt(self.visit(n.target), self.visit(n.iter), self.as_required_block(n.body, n.lineno), self.as_block(n.orelse, n.lineno), target_type) node.is_async = True return self.set_line(node, n) # While(expr test, stmt* body, stmt* orelse) def visit_While(self, n: ast3.While) -> WhileStmt: node = WhileStmt(self.visit(n.test), self.as_required_block(n.body, n.lineno), self.as_block(n.orelse, n.lineno)) return self.set_line(node, n) # If(expr test, stmt* body, stmt* orelse) def visit_If(self, n: ast3.If) -> IfStmt: lineno = n.lineno node = IfStmt([self.visit(n.test)], [self.as_required_block(n.body, lineno)], self.as_block(n.orelse, lineno)) return self.set_line(node, n) # With(withitem* items, stmt* body, string? type_comment) def visit_With(self, n: ast3.With) -> WithStmt: target_type = self.translate_type_comment(n, n.type_comment) node = WithStmt([self.visit(i.context_expr) for i in n.items], [self.visit(i.optional_vars) for i in n.items], self.as_required_block(n.body, n.lineno), target_type) return self.set_line(node, n) # AsyncWith(withitem* items, stmt* body, string? type_comment) def visit_AsyncWith(self, n: ast3.AsyncWith) -> WithStmt: target_type = self.translate_type_comment(n, n.type_comment) s = WithStmt([self.visit(i.context_expr) for i in n.items], [self.visit(i.optional_vars) for i in n.items], self.as_required_block(n.body, n.lineno), target_type) s.is_async = True return self.set_line(s, n) # Raise(expr? exc, expr? cause) def visit_Raise(self, n: ast3.Raise) -> RaiseStmt: node = RaiseStmt(self.visit(n.exc), self.visit(n.cause)) return self.set_line(node, n) # Try(stmt* body, excepthandler* handlers, stmt* orelse, stmt* finalbody) def visit_Try(self, n: ast3.Try) -> TryStmt: vs = [ self.set_line(NameExpr(h.name), h) if h.name is not None else None for h in n.handlers ] types = [self.visit(h.type) for h in n.handlers] handlers = [self.as_required_block(h.body, h.lineno) for h in n.handlers] node = TryStmt(self.as_required_block(n.body, n.lineno), vs, types, handlers, self.as_block(n.orelse, n.lineno), self.as_block(n.finalbody, n.lineno)) return self.set_line(node, n) # Assert(expr test, expr? msg) def visit_Assert(self, n: ast3.Assert) -> AssertStmt: node = AssertStmt(self.visit(n.test), self.visit(n.msg)) return self.set_line(node, n) # Import(alias* names) def visit_Import(self, n: ast3.Import) -> Import: names: List[Tuple[str, Optional[str]]] = [] for alias in n.names: name = self.translate_module_id(alias.name) asname = alias.asname if asname is None and name != alias.name: # if the module name has been translated (and it's not already # an explicit import-as), make it an implicit import-as the # original name asname = alias.name names.append((name, asname)) i = Import(names) self.imports.append(i) return self.set_line(i, n) # ImportFrom(identifier? module, alias* names, int? level) def visit_ImportFrom(self, n: ast3.ImportFrom) -> ImportBase: assert n.level is not None if len(n.names) == 1 and n.names[0].name == '*': mod = n.module if n.module is not None else '' i: ImportBase = ImportAll(mod, n.level) else: i = ImportFrom(self.translate_module_id(n.module) if n.module is not None else '', n.level, [(a.name, a.asname) for a in n.names]) self.imports.append(i) return self.set_line(i, n) # Global(identifier* names) def visit_Global(self, n: ast3.Global) -> GlobalDecl: g = GlobalDecl(n.names) return self.set_line(g, n) # Nonlocal(identifier* names) def visit_Nonlocal(self, n: ast3.Nonlocal) -> NonlocalDecl: d = NonlocalDecl(n.names) return self.set_line(d, n) # Expr(expr value) def visit_Expr(self, n: ast3.Expr) -> ExpressionStmt: value = self.visit(n.value) node = ExpressionStmt(value) return self.set_line(node, n) # Pass def visit_Pass(self, n: ast3.Pass) -> PassStmt: s = PassStmt() return self.set_line(s, n) # Break def visit_Break(self, n: ast3.Break) -> BreakStmt: s = BreakStmt() return self.set_line(s, n) # Continue def visit_Continue(self, n: ast3.Continue) -> ContinueStmt: s = ContinueStmt() return self.set_line(s, n) # --- expr --- def visit_NamedExpr(self, n: NamedExpr) -> AssignmentExpr: s = AssignmentExpr(self.visit(n.target), self.visit(n.value)) return self.set_line(s, n) # BoolOp(boolop op, expr* values) def visit_BoolOp(self, n: ast3.BoolOp) -> OpExpr: # mypy translates (1 and 2 and 3) as (1 and (2 and 3)) assert len(n.values) >= 2 op_node = n.op if isinstance(op_node, ast3.And): op = 'and' elif isinstance(op_node, ast3.Or): op = 'or' else: raise RuntimeError('unknown BoolOp ' + str(type(n))) # potentially inefficient! return self.group(op, self.translate_expr_list(n.values), n) def group(self, op: str, vals: List[Expression], n: ast3.expr) -> OpExpr: if len(vals) == 2: e = OpExpr(op, vals[0], vals[1]) else: e = OpExpr(op, vals[0], self.group(op, vals[1:], n)) return self.set_line(e, n) # BinOp(expr left, operator op, expr right) def visit_BinOp(self, n: ast3.BinOp) -> OpExpr: op = self.from_operator(n.op) if op is None: raise RuntimeError('cannot translate BinOp ' + str(type(n.op))) e = OpExpr(op, self.visit(n.left), self.visit(n.right)) return self.set_line(e, n) # UnaryOp(unaryop op, expr operand) def visit_UnaryOp(self, n: ast3.UnaryOp) -> UnaryExpr: op = None if isinstance(n.op, ast3.Invert): op = '~' elif isinstance(n.op, ast3.Not): op = 'not' elif isinstance(n.op, ast3.UAdd): op = '+' elif isinstance(n.op, ast3.USub): op = '-' if op is None: raise RuntimeError('cannot translate UnaryOp ' + str(type(n.op))) e = UnaryExpr(op, self.visit(n.operand)) return self.set_line(e, n) # Lambda(arguments args, expr body) def visit_Lambda(self, n: ast3.Lambda) -> LambdaExpr: body = ast3.Return(n.body) body.lineno = n.body.lineno body.col_offset = n.body.col_offset e = LambdaExpr(self.transform_args(n.args, n.lineno), self.as_required_block([body], n.lineno)) e.set_line(n.lineno, n.col_offset) # Overrides set_line -- can't use self.set_line return e # IfExp(expr test, expr body, expr orelse) def visit_IfExp(self, n: ast3.IfExp) -> ConditionalExpr: e = ConditionalExpr(self.visit(n.test), self.visit(n.body), self.visit(n.orelse)) return self.set_line(e, n) # Dict(expr* keys, expr* values) def visit_Dict(self, n: ast3.Dict) -> DictExpr: e = DictExpr(list(zip(self.translate_opt_expr_list(n.keys), self.translate_expr_list(n.values)))) return self.set_line(e, n) # Set(expr* elts) def visit_Set(self, n: ast3.Set) -> SetExpr: e = SetExpr(self.translate_expr_list(n.elts)) return self.set_line(e, n) # ListComp(expr elt, comprehension* generators) def visit_ListComp(self, n: ast3.ListComp) -> ListComprehension: e = ListComprehension(self.visit_GeneratorExp(cast(ast3.GeneratorExp, n))) return self.set_line(e, n) # SetComp(expr elt, comprehension* generators) def visit_SetComp(self, n: ast3.SetComp) -> SetComprehension: e = SetComprehension(self.visit_GeneratorExp(cast(ast3.GeneratorExp, n))) return self.set_line(e, n) # DictComp(expr key, expr value, comprehension* generators) def visit_DictComp(self, n: ast3.DictComp) -> DictionaryComprehension: targets = [self.visit(c.target) for c in n.generators] iters = [self.visit(c.iter) for c in n.generators] ifs_list = [self.translate_expr_list(c.ifs) for c in n.generators] is_async = [bool(c.is_async) for c in n.generators] e = DictionaryComprehension(self.visit(n.key), self.visit(n.value), targets, iters, ifs_list, is_async) return self.set_line(e, n) # GeneratorExp(expr elt, comprehension* generators) def visit_GeneratorExp(self, n: ast3.GeneratorExp) -> GeneratorExpr: targets = [self.visit(c.target) for c in n.generators] iters = [self.visit(c.iter) for c in n.generators] ifs_list = [self.translate_expr_list(c.ifs) for c in n.generators] is_async = [bool(c.is_async) for c in n.generators] e = GeneratorExpr(self.visit(n.elt), targets, iters, ifs_list, is_async) return self.set_line(e, n) # Await(expr value) def visit_Await(self, n: ast3.Await) -> AwaitExpr: v = self.visit(n.value) e = AwaitExpr(v) return self.set_line(e, n) # Yield(expr? value) def visit_Yield(self, n: ast3.Yield) -> YieldExpr: e = YieldExpr(self.visit(n.value)) return self.set_line(e, n) # YieldFrom(expr value) def visit_YieldFrom(self, n: ast3.YieldFrom) -> YieldFromExpr: e = YieldFromExpr(self.visit(n.value)) return self.set_line(e, n) # Compare(expr left, cmpop* ops, expr* comparators) def visit_Compare(self, n: ast3.Compare) -> ComparisonExpr: operators = [self.from_comp_operator(o) for o in n.ops] operands = self.translate_expr_list([n.left] + n.comparators) e = ComparisonExpr(operators, operands) return self.set_line(e, n) # Call(expr func, expr* args, keyword* keywords) # keyword = (identifier? arg, expr value) def visit_Call(self, n: Call) -> CallExpr: args = n.args keywords = n.keywords keyword_names = [k.arg for k in keywords] arg_types = self.translate_expr_list( [a.value if isinstance(a, Starred) else a for a in args] + [k.value for k in keywords]) arg_kinds = ([ARG_STAR if type(a) is Starred else ARG_POS for a in args] + [ARG_STAR2 if arg is None else ARG_NAMED for arg in keyword_names]) e = CallExpr(self.visit(n.func), arg_types, arg_kinds, cast('List[Optional[str]]', [None] * len(args)) + keyword_names) return self.set_line(e, n) # Constant(object value) -- a constant, in Python 3.8. def visit_Constant(self, n: Constant) -> Any: val = n.value e: Any = None if val is None: e = NameExpr('None') elif isinstance(val, str): e = StrExpr(n.s) elif isinstance(val, bytes): e = BytesExpr(bytes_to_human_readable_repr(n.s)) elif isinstance(val, bool): # Must check before int! e = NameExpr(str(val)) elif isinstance(val, int): e = IntExpr(val) elif isinstance(val, float): e = FloatExpr(val) elif isinstance(val, complex): e = ComplexExpr(val) elif val is Ellipsis: e = EllipsisExpr() else: raise RuntimeError('Constant not implemented for ' + str(type(val))) return self.set_line(e, n) # Num(object n) -- a number as a PyObject. def visit_Num(self, n: ast3.Num) -> Union[IntExpr, FloatExpr, ComplexExpr]: # The n field has the type complex, but complex isn't *really* # a parent of int and float, and this causes isinstance below # to think that the complex branch is always picked. Avoid # this by throwing away the type. val: object = n.n if isinstance(val, int): e: Union[IntExpr, FloatExpr, ComplexExpr] = IntExpr(val) elif isinstance(val, float): e = FloatExpr(val) elif isinstance(val, complex): e = ComplexExpr(val) else: raise RuntimeError('num not implemented for ' + str(type(val))) return self.set_line(e, n) # Str(string s) def visit_Str(self, n: Str) -> Union[UnicodeExpr, StrExpr]: # Hack: assume all string literals in Python 2 stubs are normal # strs (i.e. not unicode). All stubs are parsed with the Python 3 # parser, which causes unprefixed string literals to be interpreted # as unicode instead of bytes. This hack is generally okay, # because mypy considers str literals to be compatible with # unicode. e = StrExpr(n.s) return self.set_line(e, n) # JoinedStr(expr* values) def visit_JoinedStr(self, n: ast3.JoinedStr) -> Expression: # Each of n.values is a str or FormattedValue; we just concatenate # them all using ''.join. empty_string = StrExpr('') empty_string.set_line(n.lineno, n.col_offset) strs_to_join = ListExpr(self.translate_expr_list(n.values)) strs_to_join.set_line(empty_string) # Don't make unnecessary join call if there is only one str to join if len(strs_to_join.items) == 1: return self.set_line(strs_to_join.items[0], n) join_method = MemberExpr(empty_string, 'join') join_method.set_line(empty_string) result_expression = CallExpr(join_method, [strs_to_join], [ARG_POS], [None]) return self.set_line(result_expression, n) # FormattedValue(expr value) def visit_FormattedValue(self, n: ast3.FormattedValue) -> Expression: # A FormattedValue is a component of a JoinedStr, or it can exist # on its own. We translate them to individual '{}'.format(value) # calls. Format specifier and conversion information is passed along # to allow mypyc to support f-strings with format specifiers and conversions. val_exp = self.visit(n.value) val_exp.set_line(n.lineno, n.col_offset) conv_str = '' if n.conversion is None or n.conversion < 0 else '!' + chr(n.conversion) format_string = StrExpr('{' + conv_str + ':{}}') format_spec_exp = self.visit(n.format_spec) if n.format_spec is not None else StrExpr('') format_string.set_line(n.lineno, n.col_offset) format_method = MemberExpr(format_string, 'format') format_method.set_line(format_string) result_expression = CallExpr(format_method, [val_exp, format_spec_exp], [ARG_POS, ARG_POS], [None, None]) return self.set_line(result_expression, n) # Bytes(bytes s) def visit_Bytes(self, n: ast3.Bytes) -> Union[BytesExpr, StrExpr]: e = BytesExpr(bytes_to_human_readable_repr(n.s)) return self.set_line(e, n) # NameConstant(singleton value) def visit_NameConstant(self, n: NameConstant) -> NameExpr: e = NameExpr(str(n.value)) return self.set_line(e, n) # Ellipsis def visit_Ellipsis(self, n: ast3_Ellipsis) -> EllipsisExpr: e = EllipsisExpr() return self.set_line(e, n) # Attribute(expr value, identifier attr, expr_context ctx) def visit_Attribute(self, n: Attribute) -> Union[MemberExpr, SuperExpr]: value = n.value member_expr = MemberExpr(self.visit(value), n.attr) obj = member_expr.expr if (isinstance(obj, CallExpr) and isinstance(obj.callee, NameExpr) and obj.callee.name == 'super'): e: Union[MemberExpr, SuperExpr] = SuperExpr(member_expr.name, obj) else: e = member_expr return self.set_line(e, n) # Subscript(expr value, slice slice, expr_context ctx) def visit_Subscript(self, n: ast3.Subscript) -> IndexExpr: e = IndexExpr(self.visit(n.value), self.visit(n.slice)) self.set_line(e, n) # alias to please mypyc is_py38_or_earlier = sys.version_info < (3, 9) if ( isinstance(n.slice, ast3.Slice) or (is_py38_or_earlier and isinstance(n.slice, ast3.ExtSlice)) ): # Before Python 3.9, Slice has no line/column in the raw ast. To avoid incompatibility # visit_Slice doesn't set_line, even in Python 3.9 on. # ExtSlice also has no line/column info. In Python 3.9 on, line/column is set for # e.index when visiting n.slice. e.index.line = e.line e.index.column = e.column return e # Starred(expr value, expr_context ctx) def visit_Starred(self, n: Starred) -> StarExpr: e = StarExpr(self.visit(n.value)) return self.set_line(e, n) # Name(identifier id, expr_context ctx) def visit_Name(self, n: Name) -> NameExpr: e = NameExpr(n.id) return self.set_line(e, n) # List(expr* elts, expr_context ctx) def visit_List(self, n: ast3.List) -> Union[ListExpr, TupleExpr]: expr_list: List[Expression] = [self.visit(e) for e in n.elts] if isinstance(n.ctx, ast3.Store): # [x, y] = z and (x, y) = z means exactly the same thing e: Union[ListExpr, TupleExpr] = TupleExpr(expr_list) else: e = ListExpr(expr_list) return self.set_line(e, n) # Tuple(expr* elts, expr_context ctx) def visit_Tuple(self, n: ast3.Tuple) -> TupleExpr: e = TupleExpr(self.translate_expr_list(n.elts)) return self.set_line(e, n) # --- slice --- # Slice(expr? lower, expr? upper, expr? step) def visit_Slice(self, n: ast3.Slice) -> SliceExpr: return SliceExpr(self.visit(n.lower), self.visit(n.upper), self.visit(n.step)) # ExtSlice(slice* dims) def visit_ExtSlice(self, n: ast3.ExtSlice) -> TupleExpr: # cast for mypyc's benefit on Python 3.9 return TupleExpr(self.translate_expr_list(cast(Any, n).dims)) # Index(expr value) def visit_Index(self, n: Index) -> Node: # cast for mypyc's benefit on Python 3.9 return self.visit(cast(Any, n).value) # Match(expr subject, match_case* cases) # python 3.10 and later def visit_Match(self, n: Match) -> MatchStmt: node = MatchStmt(self.visit(n.subject), [self.visit(c.pattern) for c in n.cases], [self.visit(c.guard) for c in n.cases], [self.as_required_block(c.body, n.lineno) for c in n.cases]) return self.set_line(node, n) def visit_MatchValue(self, n: MatchValue) -> ValuePattern: node = ValuePattern(self.visit(n.value)) return self.set_line(node, n) def visit_MatchSingleton(self, n: MatchSingleton) -> SingletonPattern: node = SingletonPattern(n.value) return self.set_line(node, n) def visit_MatchSequence(self, n: MatchSequence) -> SequencePattern: patterns = [self.visit(p) for p in n.patterns] stars = [p for p in patterns if isinstance(p, StarredPattern)] assert len(stars) < 2 node = SequencePattern(patterns) return self.set_line(node, n) def visit_MatchStar(self, n: MatchStar) -> StarredPattern: if n.name is None: node = StarredPattern(None) else: node = StarredPattern(NameExpr(n.name)) return self.set_line(node, n) def visit_MatchMapping(self, n: MatchMapping) -> MappingPattern: keys = [self.visit(k) for k in n.keys] values = [self.visit(v) for v in n.patterns] if n.rest is None: rest = None else: rest = NameExpr(n.rest) node = MappingPattern(keys, values, rest) return self.set_line(node, n) def visit_MatchClass(self, n: MatchClass) -> ClassPattern: class_ref = self.visit(n.cls) assert isinstance(class_ref, RefExpr) positionals = [self.visit(p) for p in n.patterns] keyword_keys = n.kwd_attrs keyword_values = [self.visit(p) for p in n.kwd_patterns] node = ClassPattern(class_ref, positionals, keyword_keys, keyword_values) return self.set_line(node, n) # MatchAs(expr pattern, identifier name) def visit_MatchAs(self, n: MatchAs) -> AsPattern: if n.name is None: name = None else: name = NameExpr(n.name) name = self.set_line(name, n) node = AsPattern(self.visit(n.pattern), name) return self.set_line(node, n) # MatchOr(expr* pattern) def visit_MatchOr(self, n: MatchOr) -> OrPattern: node = OrPattern([self.visit(pattern) for pattern in n.patterns]) return self.set_line(node, n) class TypeConverter: def __init__(self, errors: Optional[Errors], line: int = -1, override_column: int = -1, assume_str_is_unicode: bool = True, is_evaluated: bool = True, ) -> None: self.errors = errors self.line = line self.override_column = override_column self.node_stack: List[AST] = [] self.assume_str_is_unicode = assume_str_is_unicode self.is_evaluated = is_evaluated def convert_column(self, column: int) -> int: """Apply column override if defined; otherwise return column. Column numbers are sometimes incorrect in the AST and the column override can be used to work around that. """ if self.override_column < 0: return column else: return self.override_column def invalid_type(self, node: AST, note: Optional[str] = None) -> RawExpressionType: """Constructs a type representing some expression that normally forms an invalid type. For example, if we see a type hint that says "3 + 4", we would transform that expression into a RawExpressionType. The semantic analysis layer will report an "Invalid type" error when it encounters this type, along with the given note if one is provided. See RawExpressionType's docstring for more details on how it's used. """ return RawExpressionType( None, 'typing.Any', line=self.line, column=getattr(node, 'col_offset', -1), note=note, ) @overload def visit(self, node: ast3.expr) -> ProperType: ... @overload def visit(self, node: Optional[AST]) -> Optional[ProperType]: ... def visit(self, node: Optional[AST]) -> Optional[ProperType]: """Modified visit -- keep track of the stack of nodes""" if node is None: return None self.node_stack.append(node) try: method = 'visit_' + node.__class__.__name__ visitor = getattr(self, method, None) if visitor is not None: return visitor(node) else: return self.invalid_type(node) finally: self.node_stack.pop() def parent(self) -> Optional[AST]: """Return the AST node above the one we are processing""" if len(self.node_stack) < 2: return None return self.node_stack[-2] def fail(self, msg: str, line: int, column: int) -> None: if self.errors: self.errors.report(line, column, msg, blocker=True, code=codes.SYNTAX) def note(self, msg: str, line: int, column: int) -> None: if self.errors: self.errors.report(line, column, msg, severity='note', code=codes.SYNTAX) def translate_expr_list(self, l: Sequence[ast3.expr]) -> List[Type]: return [self.visit(e) for e in l] def visit_raw_str(self, s: str) -> Type: # An escape hatch that allows the AST walker in fastparse2 to # directly hook into the Python 3 type converter in some cases # without needing to create an intermediary `Str` object. _, typ = parse_type_comment(s.strip(), self.line, -1, self.errors, self.assume_str_is_unicode) return typ or AnyType(TypeOfAny.from_error) def visit_Call(self, e: Call) -> Type: # Parse the arg constructor f = e.func constructor = stringify_name(f) if not isinstance(self.parent(), ast3.List): note = None if constructor: note = "Suggestion: use {0}[...] instead of {0}(...)".format(constructor) return self.invalid_type(e, note=note) if not constructor: self.fail("Expected arg constructor name", e.lineno, e.col_offset) name: Optional[str] = None default_type = AnyType(TypeOfAny.special_form) typ: Type = default_type for i, arg in enumerate(e.args): if i == 0: converted = self.visit(arg) assert converted is not None typ = converted elif i == 1: name = self._extract_argument_name(arg) else: self.fail("Too many arguments for argument constructor", f.lineno, f.col_offset) for k in e.keywords: value = k.value if k.arg == "name": if name is not None: self.fail('"{}" gets multiple values for keyword argument "name"'.format( constructor), f.lineno, f.col_offset) name = self._extract_argument_name(value) elif k.arg == "type": if typ is not default_type: self.fail('"{}" gets multiple values for keyword argument "type"'.format( constructor), f.lineno, f.col_offset) converted = self.visit(value) assert converted is not None typ = converted else: self.fail( f'Unexpected argument "{k.arg}" for argument constructor', value.lineno, value.col_offset) return CallableArgument(typ, name, constructor, e.lineno, e.col_offset) def translate_argument_list(self, l: Sequence[ast3.expr]) -> TypeList: return TypeList([self.visit(e) for e in l], line=self.line) def _extract_argument_name(self, n: ast3.expr) -> Optional[str]: if isinstance(n, Str): return n.s.strip() elif isinstance(n, NameConstant) and str(n.value) == 'None': return None self.fail('Expected string literal for argument name, got {}'.format( type(n).__name__), self.line, 0) return None def visit_Name(self, n: Name) -> Type: return UnboundType(n.id, line=self.line, column=self.convert_column(n.col_offset)) def visit_BinOp(self, n: ast3.BinOp) -> Type: if not isinstance(n.op, ast3.BitOr): return self.invalid_type(n) left = self.visit(n.left) right = self.visit(n.right) return UnionType([left, right], line=self.line, column=self.convert_column(n.col_offset), is_evaluated=self.is_evaluated, uses_pep604_syntax=True) def visit_NameConstant(self, n: NameConstant) -> Type: if isinstance(n.value, bool): return RawExpressionType(n.value, 'builtins.bool', line=self.line) else: return UnboundType(str(n.value), line=self.line, column=n.col_offset) # Only for 3.8 and newer def visit_Constant(self, n: Constant) -> Type: val = n.value if val is None: # None is a type. return UnboundType('None', line=self.line) if isinstance(val, str): # Parse forward reference. if (n.kind and 'u' in n.kind) or self.assume_str_is_unicode: return parse_type_string(n.s, 'builtins.unicode', self.line, n.col_offset, assume_str_is_unicode=self.assume_str_is_unicode) else: return parse_type_string(n.s, 'builtins.str', self.line, n.col_offset, assume_str_is_unicode=self.assume_str_is_unicode) if val is Ellipsis: # '...' is valid in some types. return EllipsisType(line=self.line) if isinstance(val, bool): # Special case for True/False. return RawExpressionType(val, 'builtins.bool', line=self.line) if isinstance(val, (int, float, complex)): return self.numeric_type(val, n) if isinstance(val, bytes): contents = bytes_to_human_readable_repr(val) return RawExpressionType(contents, 'builtins.bytes', self.line, column=n.col_offset) # Everything else is invalid. return self.invalid_type(n) # UnaryOp(op, operand) def visit_UnaryOp(self, n: UnaryOp) -> Type: # We support specifically Literal[-4] and nothing else. # For example, Literal[+4] or Literal[~6] is not supported. typ = self.visit(n.operand) if isinstance(typ, RawExpressionType) and isinstance(n.op, USub): if isinstance(typ.literal_value, int): typ.literal_value *= -1 return typ return self.invalid_type(n) def numeric_type(self, value: object, n: AST) -> Type: # The node's field has the type complex, but complex isn't *really* # a parent of int and float, and this causes isinstance below # to think that the complex branch is always picked. Avoid # this by throwing away the type. if isinstance(value, int): numeric_value: Optional[int] = value type_name = 'builtins.int' else: # Other kinds of numbers (floats, complex) are not valid parameters for # RawExpressionType so we just pass in 'None' for now. We'll report the # appropriate error at a later stage. numeric_value = None type_name = f'builtins.{type(value).__name__}' return RawExpressionType( numeric_value, type_name, line=self.line, column=getattr(n, 'col_offset', -1), ) # These next three methods are only used if we are on python < # 3.8, using typed_ast. They are defined unconditionally because # mypyc can't handle conditional method definitions. # Num(number n) def visit_Num(self, n: Num) -> Type: return self.numeric_type(n.n, n) # Str(string s) def visit_Str(self, n: Str) -> Type: # Note: we transform these fallback types into the correct types in # 'typeanal.py' -- specifically in the named_type_with_normalized_str method. # If we're analyzing Python 3, that function will translate 'builtins.unicode' # into 'builtins.str'. In contrast, if we're analyzing Python 2 code, we'll # translate 'builtins.bytes' in the method below into 'builtins.str'. # Do a getattr because the field doesn't exist in 3.8 (where # this method doesn't actually ever run.) We can't just do # an attribute access with a `# type: ignore` because it would be # unused on < 3.8. kind: str = getattr(n, "kind") # noqa if 'u' in kind or self.assume_str_is_unicode: return parse_type_string(n.s, 'builtins.unicode', self.line, n.col_offset, assume_str_is_unicode=self.assume_str_is_unicode) else: return parse_type_string(n.s, 'builtins.str', self.line, n.col_offset, assume_str_is_unicode=self.assume_str_is_unicode) # Bytes(bytes s) def visit_Bytes(self, n: Bytes) -> Type: contents = bytes_to_human_readable_repr(n.s) return RawExpressionType(contents, 'builtins.bytes', self.line, column=n.col_offset) def visit_Index(self, n: ast3.Index) -> Type: # cast for mypyc's benefit on Python 3.9 return self.visit(cast(Any, n).value) def visit_Slice(self, n: ast3.Slice) -> Type: return self.invalid_type( n, note="did you mean to use ',' instead of ':' ?" ) # Subscript(expr value, slice slice, expr_context ctx) # Python 3.8 and before # Subscript(expr value, expr slice, expr_context ctx) # Python 3.9 and later def visit_Subscript(self, n: ast3.Subscript) -> Type: if sys.version_info >= (3, 9): # Really 3.9a5 or later sliceval: Any = n.slice # Python 3.8 or earlier use a different AST structure for subscripts elif isinstance(n.slice, ast3.Index): sliceval: Any = n.slice.value elif isinstance(n.slice, ast3.Slice): sliceval = copy.deepcopy(n.slice) # so we don't mutate passed AST if getattr(sliceval, "col_offset", None) is None: # Fix column information so that we get Python 3.9+ message order sliceval.col_offset = sliceval.lower.col_offset else: assert isinstance(n.slice, ast3.ExtSlice) dims = copy.deepcopy(n.slice.dims) for s in dims: if getattr(s, "col_offset", None) is None: if isinstance(s, ast3.Index): s.col_offset = s.value.col_offset # type: ignore elif isinstance(s, ast3.Slice): s.col_offset = s.lower.col_offset # type: ignore sliceval = ast3.Tuple(dims, n.ctx) empty_tuple_index = False if isinstance(sliceval, ast3.Tuple): params = self.translate_expr_list(sliceval.elts) if len(sliceval.elts) == 0: empty_tuple_index = True else: params = [self.visit(sliceval)] value = self.visit(n.value) if isinstance(value, UnboundType) and not value.args: return UnboundType(value.name, params, line=self.line, column=value.column, empty_tuple_index=empty_tuple_index) else: return self.invalid_type(n) def visit_Tuple(self, n: ast3.Tuple) -> Type: return TupleType(self.translate_expr_list(n.elts), _dummy_fallback, implicit=True, line=self.line, column=self.convert_column(n.col_offset)) # Attribute(expr value, identifier attr, expr_context ctx) def visit_Attribute(self, n: Attribute) -> Type: before_dot = self.visit(n.value) if isinstance(before_dot, UnboundType) and not before_dot.args: return UnboundType(f"{before_dot.name}.{n.attr}", line=self.line) else: return self.invalid_type(n) # Ellipsis def visit_Ellipsis(self, n: ast3_Ellipsis) -> Type: return EllipsisType(line=self.line) # List(expr* elts, expr_context ctx) def visit_List(self, n: ast3.List) -> Type: assert isinstance(n.ctx, ast3.Load) return self.translate_argument_list(n.elts) def stringify_name(n: AST) -> Optional[str]: if isinstance(n, Name): return n.id elif isinstance(n, Attribute): sv = stringify_name(n.value) if sv is not None: return f"{sv}.{n.attr}" return None # Can't do it.