def add_method(funcname: str, ret: Type, args: List[Argument], name: Optional[str] = None, is_classmethod: bool = False, is_new: bool = False, ) -> None: if is_classmethod or is_new: first = [Argument(Var('cls'), TypeType.make_normalized(selftype), None, ARG_POS)] else: first = [Argument(Var('self'), selftype, None, ARG_POS)] args = first + args types = [arg.type_annotation for arg in args] items = [arg.variable.name() for arg in args] arg_kinds = [arg.kind for arg in args] assert None not in types signature = CallableType(cast(List[Type], types), arg_kinds, items, ret, function_type) signature.variables = [tvd] func = FuncDef(funcname, args, Block([])) func.info = info func.is_class = is_classmethod func.type = set_callable_name(signature, func) func._fullname = info.fullname() + '.' + funcname if is_classmethod: v = Var(funcname, func.type) v.is_classmethod = True v.info = info v._fullname = func._fullname dec = Decorator(func, [NameExpr('classmethod')], v) info.names[funcname] = SymbolTableNode(MDEF, dec) else: info.names[funcname] = SymbolTableNode(MDEF, func)
def add_method(funcname: str, ret: Type, args: List[Argument], name: Optional[str] = None, is_classmethod: bool = False, is_new: bool = False, ) -> None: if is_classmethod or is_new: first = [Argument(Var('cls'), TypeType.make_normalized(selftype), None, ARG_POS)] else: first = [Argument(Var('self'), selftype, None, ARG_POS)] args = first + args types = [arg.type_annotation for arg in args] items = [arg.variable.name() for arg in args] arg_kinds = [arg.kind for arg in args] assert None not in types signature = CallableType(cast(List[Type], types), arg_kinds, items, ret, function_type) signature.variables = [tvd] func = FuncDef(funcname, args, Block([])) func.info = info func.is_class = is_classmethod func.type = set_callable_name(signature, func) func._fullname = info.fullname() + '.' + funcname if is_classmethod: v = Var(funcname, func.type) v.is_classmethod = True v.info = info v._fullname = func._fullname dec = Decorator(func, [NameExpr('classmethod')], v) info.names[funcname] = SymbolTableNode(MDEF, dec) else: info.names[funcname] = SymbolTableNode(MDEF, func)
def add_classmethod_to_class(api, cls, name, args, return_type, self_type=None, tvar_def=None): """Adds a new classmethod to a class definition.""" info = cls.info # First remove any previously generated methods with the same name # to avoid clashes and problems in the semantic analyzer. if name in info.names: sym = info.names[name] if sym.plugin_generated and isinstance(sym.node, Decorator): cls.defs.body.remove(sym.node) self_type = self_type or fill_typevars(info) class_type = api.class_type(self_type) function_type = builtin_type(api, 'function') args = [Argument(Var('cls'), class_type, None, ARG_POS)] + args arg_types, arg_names, arg_kinds = [], [], [] for arg in args: assert arg.type_annotation, 'All arguments must be fully typed.' arg_types.append(arg.type_annotation) arg_names.append(arg.variable.name) arg_kinds.append(arg.kind) signature = CallableType(arg_types, arg_kinds, arg_names, return_type, function_type) if tvar_def: signature.variables = [tvar_def] func = FuncDef(name, args, Block([PassStmt()])) func.type = set_callable_name(signature, func) func._fullname = info.fullname + '.' + name func.line = info.line func.is_class = True var = Var(name) var.line = info.line var.info = info var.is_classmethod = True # should we have a NameExpr in the decorator list? dec = Decorator(func, [], var) dec.line = info.line # NOTE: we would like the plugin generated node to dominate, but we still # need to keep any existing definitions so they get semantically analyzed. if name in info.names: # Get a nice unique name instead. r_name = get_unique_redefinition_name(name, info.names) info.names[r_name] = info.names[name] info.names[name] = SymbolTableNode(MDEF, dec, plugin_generated=True) info.defn.defs.body.append(dec)
def visit_func_def(self, node: FuncDef) -> FuncDef: # Note that a FuncDef must be transformed to a FuncDef. new = FuncDef(node.name(), [self.visit_var(var) for var in node.args], node.arg_kinds[:], [None] * len(node.init), self.block(node.body), self.optional_type(node.type)) self.copy_function_attributes(new, node) new._fullname = node._fullname new.is_decorated = node.is_decorated new.is_conditional = node.is_conditional new.is_abstract = node.is_abstract new.is_static = node.is_static new.is_class = node.is_class new.is_property = node.is_property new.original_def = node.original_def return new
def visit_func_def(self, node: FuncDef) -> FuncDef: # Note that a FuncDef must be transformed to a FuncDef. new = FuncDef(node.name(), [self.copy_argument(arg) for arg in node.arguments], self.block(node.body), cast(FunctionLike, self.optional_type(node.type))) self.copy_function_attributes(new, node) new._fullname = node._fullname new.is_decorated = node.is_decorated new.is_conditional = node.is_conditional new.is_abstract = node.is_abstract new.is_static = node.is_static new.is_class = node.is_class new.is_property = node.is_property new.original_def = node.original_def return new
def visit_func_def(self, node: FuncDef) -> FuncDef: # Note that a FuncDef must be transformed to a FuncDef. new = FuncDef(node.name(), [self.copy_argument(arg) for arg in node.arguments], self.block(node.body), cast(FunctionLike, self.optional_type(node.type))) self.copy_function_attributes(new, node) new._fullname = node._fullname new.is_decorated = node.is_decorated new.is_conditional = node.is_conditional new.is_abstract = node.is_abstract new.is_static = node.is_static new.is_class = node.is_class new.is_property = node.is_property new.original_def = node.original_def return new
def visit_func_def(self, node: FuncDef) -> FuncDef: # Note that a FuncDef must be transformed to a FuncDef. new = FuncDef(node.name(), [self.visit_var(var) for var in node.args], node.arg_kinds[:], [None] * len(node.init), self.block(node.body), self.optional_type(node.type)) self.copy_function_attributes(new, node) new._fullname = node._fullname new.is_decorated = node.is_decorated new.is_conditional = node.is_conditional new.is_abstract = node.is_abstract new.is_static = node.is_static new.is_class = node.is_class new.is_property = node.is_property new.original_def = node.original_def return new
def visit_func_def(self, node: FuncDef) -> FuncDef: # Note that a FuncDef must be transformed to a FuncDef. # These contortions are needed to handle the case of recursive # references inside the function being transformed. # Set up placeholder nodes for references within this function # to other functions defined inside it. # Don't create an entry for this function itself though, # since we want self-references to point to the original # function if this is the top-level node we are transforming. init = FuncMapInitializer(self) for stmt in node.body.body: stmt.accept(init) new = FuncDef(node.name, [self.copy_argument(arg) for arg in node.arguments], self.block(node.body), cast(Optional[FunctionLike], self.optional_type(node.type))) self.copy_function_attributes(new, node) new._fullname = node._fullname new.is_decorated = node.is_decorated new.is_conditional = node.is_conditional new.is_abstract = node.is_abstract new.is_static = node.is_static new.is_class = node.is_class new.is_property = node.is_property new.is_final = node.is_final new.original_def = node.original_def if node in self.func_placeholder_map: # There is a placeholder definition for this function. Replace # the attributes of the placeholder with those form the transformed # function. We know that the classes will be identical (otherwise # this wouldn't work). result = self.func_placeholder_map[node] replace_object_state(result, new) return result else: return new
def visit_func_def(self, node: FuncDef) -> FuncDef: # Note that a FuncDef must be transformed to a FuncDef. # These contortions are needed to handle the case of recursive # references inside the function being transformed. # Set up placeholder nodes for references within this function # to other functions defined inside it. # Don't create an entry for this function itself though, # since we want self-references to point to the original # function if this is the top-level node we are transforming. init = FuncMapInitializer(self) for stmt in node.body.body: stmt.accept(init) new = FuncDef(node.name(), [self.copy_argument(arg) for arg in node.arguments], self.block(node.body), cast(Optional[FunctionLike], self.optional_type(node.type))) self.copy_function_attributes(new, node) new._fullname = node._fullname new.is_decorated = node.is_decorated new.is_conditional = node.is_conditional new.is_abstract = node.is_abstract new.is_static = node.is_static new.is_class = node.is_class new.is_property = node.is_property new.is_final = node.is_final new.original_def = node.original_def if node in self.func_placeholder_map: # There is a placeholder definition for this function. Replace # the attributes of the placeholder with those form the transformed # function. We know that the classes will be identical (otherwise # this wouldn't work). result = self.func_placeholder_map[node] replace_object_state(result, new) return result else: return new
def add_method( ctx: ClassDefContext, name: str, args: List[Argument], return_type: Type, self_type: Optional[Type] = None, tvar_def: Optional[TypeVarDef] = None, is_classmethod: bool = False, is_new: bool = False, # is_staticmethod: bool = False, ) -> None: """ Adds a new method to a class. This can be dropped if/when https://github.com/python/mypy/issues/7301 is merged """ info = ctx.cls.info # First remove any previously generated methods with the same name # to avoid clashes and problems in the semantic analyzer. if name in info.names: sym = info.names[name] if sym.plugin_generated and isinstance(sym.node, FuncDef): ctx.cls.defs.body.remove(sym.node) self_type = self_type or fill_typevars(info) if is_classmethod or is_new: first = [ Argument(Var("_cls"), TypeType.make_normalized(self_type), None, ARG_POS) ] # elif is_staticmethod: # first = [] else: self_type = self_type or fill_typevars(info) first = [Argument(Var("self"), self_type, None, ARG_POS)] args = first + args arg_types, arg_names, arg_kinds = [], [], [] for arg in args: assert arg.type_annotation, "All arguments must be fully typed." arg_types.append(arg.type_annotation) arg_names.append(get_name(arg.variable)) arg_kinds.append(arg.kind) function_type = ctx.api.named_type("__builtins__.function") signature = CallableType(arg_types, arg_kinds, arg_names, return_type, function_type) if tvar_def: signature.variables = [tvar_def] func = FuncDef(name, args, Block([PassStmt()])) func.info = info func.type = set_callable_name(signature, func) func.is_class = is_classmethod # func.is_static = is_staticmethod func._fullname = get_fullname(info) + "." + name func.line = info.line # NOTE: we would like the plugin generated node to dominate, but we still # need to keep any existing definitions so they get semantically analyzed. if name in info.names: # Get a nice unique name instead. r_name = get_unique_redefinition_name(name, info.names) info.names[r_name] = info.names[name] if is_classmethod: # or is_staticmethod: func.is_decorated = True v = Var(name, func.type) v.info = info v._fullname = func._fullname # if is_classmethod: v.is_classmethod = True dec = Decorator(func, [NameExpr("classmethod")], v) # else: # v.is_staticmethod = True # dec = Decorator(func, [NameExpr('staticmethod')], v) dec.line = info.line sym = SymbolTableNode(MDEF, dec) else: sym = SymbolTableNode(MDEF, func) sym.plugin_generated = True info.names[name] = sym info.defn.defs.body.append(func)
def _add_method( ctx: ClassDefContext, name: str, args: List[Argument], return_type: mypy.types.Type, self_type: Optional[mypy.types.Type] = None, tvar_def: Optional[mypy.types.TypeVarDef] = None, is_classmethod: bool = False, ) -> None: """Adds a new method to a class. """ info = ctx.cls.info # First remove any previously generated methods with the same name # to avoid clashes and problems in new semantic analyzer. if name in info.names: sym = info.names[name] if sym.plugin_generated and isinstance(sym.node, FuncDef): ctx.cls.defs.body.remove(sym.node) if is_classmethod: first = Argument( Var('cls'), # Working around python/mypy#5416. # This should be: mypy.types.TypeType.make_normalized(self_type) mypy.types.AnyType(mypy.types.TypeOfAny.implementation_artifact), None, ARG_POS) else: self_type = self_type or fill_typevars(info) first = Argument(Var('self'), self_type, None, ARG_POS) args = [first] + args function_type = ctx.api.named_type('__builtins__.function') arg_types, arg_names, arg_kinds = [], [], [] for arg in args: assert arg.type_annotation, 'All arguments must be fully typed.' arg_types.append(arg.type_annotation) arg_names.append(get_name(arg.variable)) arg_kinds.append(arg.kind) signature = mypy.types.CallableType(arg_types, arg_kinds, arg_names, return_type, function_type) if tvar_def: signature.variables = [tvar_def] func = FuncDef(name, args, Block([PassStmt()])) func.info = info func.is_class = is_classmethod func.type = set_callable_name(signature, func) func._fullname = get_fullname(info) + '.' + name func.line = info.line # NOTE: we would like the plugin generated node to dominate, but we still # need to keep any existing definitions so they get semantically analyzed. if name in info.names: # Get a nice unique name instead. r_name = get_unique_redefinition_name(name, info.names) info.names[r_name] = info.names[name] info.defn.defs.body.append(func) info.names[name] = SymbolTableNode(MDEF, func, plugin_generated=True)
def add_method_to_class( api: SemanticAnalyzerPluginInterface, cls: ClassDef, name: str, args: List[Argument], return_type: Type, self_type: Optional[Type] = None, tvar_def: Optional[TypeVarDef] = None, is_classmethod: bool = False, ) -> None: """ Adds a new method to a class definition. NOTE: Copied from mypy/plugins/common.py and extended with support for adding classmethods based on https://github.com/python/mypy/pull/7796 """ info = cls.info # First remove any previously generated methods with the same name # to avoid clashes and problems in the semantic analyzer. if name in info.names: sym = info.names[name] if sym.plugin_generated and isinstance(sym.node, FuncDef): cls.defs.body.remove(sym.node) self_type = self_type or fill_typevars(info) # Add either self or cls as the first argument if is_classmethod: first = Argument(Var("cls"), TypeType.make_normalized(self_type), None, ARG_POS) else: first = Argument(Var("self"), self_type, None, ARG_POS) args = [first] + args arg_types, arg_names, arg_kinds = [], [], [] for arg in args: assert arg.type_annotation, "All arguments must be fully typed." arg_types.append(arg.type_annotation) arg_names.append(arg.variable.name) arg_kinds.append(arg.kind) function_type = api.named_type("__builtins__.function") signature = CallableType(arg_types, arg_kinds, arg_names, return_type, function_type) if tvar_def: signature.variables = [tvar_def] func = FuncDef(name, args, Block([PassStmt()])) func.info = info func.type = set_callable_name(signature, func) func._fullname = info.fullname + "." + name # pylint: disable=protected-access func.line = info.line func.is_class = is_classmethod # NOTE: we would like the plugin generated node to dominate, but we still # need to keep any existing definitions so they get semantically analyzed. if name in info.names: # Get a nice unique name instead. r_name = get_unique_redefinition_name(name, info.names) info.names[r_name] = info.names[name] if is_classmethod: func.is_decorated = True v = Var(name, func.type) v.info = info v._fullname = func._fullname # pylint: disable=protected-access v.is_classmethod = True dec = Decorator(func, [NameExpr("classmethod")], v) dec.line = info.line sym = SymbolTableNode(MDEF, dec) else: sym = SymbolTableNode(MDEF, func) sym.plugin_generated = True info.names[name] = sym info.defn.defs.body.append(func)
def add_class_method( ctx: ClassDefContext, name: str, args: List[Argument], return_type: Type, self_type: Optional[Type] = None, tvar_def: Optional[TypeVarDef] = None, ) -> None: """Adds a new class method to a class. """ info = ctx.cls.info # First remove any previously generated methods with the same name # to avoid clashes and problems in the semantic analyzer. if name in info.names: sym = info.names[name] if sym.plugin_generated and isinstance(sym.node, FuncDef): ctx.cls.defs.body.remove(sym.node) self_type = self_type or fill_typevars(info) function_type = ctx.api.named_type('__builtins__.function') args = [ Argument(Var('_cls'), TypeType.make_normalized(self_type), None, ARG_POS) ] + args arg_types, arg_names, arg_kinds = [], [], [] for arg in args: assert arg.type_annotation, 'All arguments must be fully typed.' arg_types.append(arg.type_annotation) arg_names.append(arg.variable.name) arg_kinds.append(arg.kind) signature = CallableType(arg_types, arg_kinds, arg_names, return_type, function_type) if tvar_def: signature.variables = [tvar_def] func = FuncDef(name, args, Block([PassStmt()])) func.info = info func.type = set_callable_name(signature, func) func.is_class = True func._fullname = info.fullname + '.' + name func.line = info.line # NOTE: we would like the plugin generated node to dominate, but we still # need to keep any existing definitions so they get semantically analyzed. if name in info.names: # Get a nice unique name instead. r_name = get_unique_redefinition_name(name, info.names) info.names[r_name] = info.names[name] func.is_decorated = True v = Var(name, func.type) v.info = info v._fullname = func._fullname v.is_classmethod = True dec = Decorator(func, [NameExpr('classmethod')], v) dec.line = info.line sym = SymbolTableNode(MDEF, dec) sym.plugin_generated = True info.names[name] = sym info.defn.defs.body.append(func)
def add_classmethod_to_class( api: SemanticAnalyzerPluginInterface, cls: ClassDef, name: str, args: List[Argument], return_type: Type, cls_type: Optional[Type] = None, tvar_def: Optional[Any] = None, ) -> None: """ Adds a new classmethod to a class definition. :param api: :param cls: :param name: :param args: :param return_type: :param cls_type: :param tvar_def: """ info = cls.info # First remove any previously generated methods with the same name # to avoid clashes and problems in the semantic analyzer. if name in info.names: sym = info.names[name] if sym.plugin_generated and isinstance(sym.node, FuncDef): cls.defs.body.remove(sym.node) cls_type = cls_type or fill_typevars(info) function_type = api.named_type(f"{_builtins}.function") args = [Argument(Var("cls"), cls_type, None, ARG_POS)] + args arg_types, arg_names, arg_kinds = [], [], [] for arg in args: assert arg.type_annotation, "All arguments must be fully typed." arg_types.append(arg.type_annotation) arg_names.append(arg.variable.name) arg_kinds.append(arg.kind) signature = CallableType(arg_types, arg_kinds, arg_names, return_type, function_type) if tvar_def: signature.variables = [tvar_def] func = FuncDef(name, args, Block([PassStmt()])) func.is_class = True func.info = info func.type = set_callable_name(signature, func) func._fullname = info.fullname + '.' + name func.line = info.line # NOTE: we would like the plugin generated node to dominate, but we still # need to keep any existing definitions so they get semantically analyzed. if name in info.names: # Get a nice unique name instead. r_name = get_unique_redefinition_name(name, info.names) info.names[r_name] = info.names[name] info.names[name] = SymbolTableNode(MDEF, func, plugin_generated=True) info.defn.defs.body.append(func)