# ext/mypy/infer.py # Copyright (C) 2021 the SQLAlchemy authors and contributors # # # This module is part of SQLAlchemy and is released under # the MIT License: https://www.opensource.org/licenses/mit-license.php from typing import Optional from typing import Sequence from mypy.maptype import map_instance_to_supertype from mypy.messages import format_type from mypy.nodes import AssignmentStmt from mypy.nodes import CallExpr from mypy.nodes import Expression from mypy.nodes import FuncDef from mypy.nodes import MemberExpr from mypy.nodes import NameExpr from mypy.nodes import RefExpr from mypy.nodes import StrExpr from mypy.nodes import TypeInfo from mypy.nodes import Var from mypy.plugin import SemanticAnalyzerPluginInterface from mypy.subtypes import is_subtype from mypy.types import AnyType from mypy.types import CallableType from mypy.types import get_proper_type from mypy.types import Instance from mypy.types import NoneType from mypy.types import ProperType from mypy.types import TypeOfAny from mypy.types import UnionType from . import names from . import util def infer_type_from_right_hand_nameexpr( api: SemanticAnalyzerPluginInterface, stmt: AssignmentStmt, node: Var, left_hand_explicit_type: Optional[ProperType], infer_from_right_side: RefExpr, ) -> Optional[ProperType]: type_id = names.type_id_for_callee(infer_from_right_side) if type_id is None: return None elif type_id is names.COLUMN: python_type_for_type = _infer_type_from_decl_column( api, stmt, node, left_hand_explicit_type ) elif type_id is names.RELATIONSHIP: python_type_for_type = _infer_type_from_relationship( api, stmt, node, left_hand_explicit_type ) elif type_id is names.COLUMN_PROPERTY: python_type_for_type = _infer_type_from_decl_column_property( api, stmt, node, left_hand_explicit_type ) elif type_id is names.SYNONYM_PROPERTY: python_type_for_type = infer_type_from_left_hand_type_only( api, node, left_hand_explicit_type ) elif type_id is names.COMPOSITE_PROPERTY: python_type_for_type = _infer_type_from_decl_composite_property( api, stmt, node, left_hand_explicit_type ) else: return None return python_type_for_type def _infer_type_from_relationship( api: SemanticAnalyzerPluginInterface, stmt: AssignmentStmt, node: Var, left_hand_explicit_type: Optional[ProperType], ) -> Optional[ProperType]: """Infer the type of mapping from a relationship. E.g.:: @reg.mapped class MyClass: # ... addresses = relationship(Address, uselist=True) order: Mapped["Order"] = relationship("Order") Will resolve in mypy as:: @reg.mapped class MyClass: # ... addresses: Mapped[List[Address]] order: Mapped["Order"] """ assert isinstance(stmt.rvalue, CallExpr) target_cls_arg = stmt.rvalue.args[0] python_type_for_type: Optional[ProperType] = None if isinstance(target_cls_arg, NameExpr) and isinstance( target_cls_arg.node, TypeInfo ): # type related_object_type = target_cls_arg.node python_type_for_type = Instance(related_object_type, []) # other cases not covered - an error message directs the user # to set an explicit type annotation # # node.type == str, it's a string # if isinstance(target_cls_arg, NameExpr) and isinstance( # target_cls_arg.node, Var # ) # points to a type # isinstance(target_cls_arg, NameExpr) and isinstance( # target_cls_arg.node, TypeAlias # ) # string expression # isinstance(target_cls_arg, StrExpr) uselist_arg = util.get_callexpr_kwarg(stmt.rvalue, "uselist") collection_cls_arg: Optional[Expression] = util.get_callexpr_kwarg( stmt.rvalue, "collection_class" ) type_is_a_collection = False # this can be used to determine Optional for a many-to-one # in the same way nullable=False could be used, if we start supporting # that. # innerjoin_arg = util.get_callexpr_kwarg(stmt.rvalue, "innerjoin") if ( uselist_arg is not None and api.parse_bool(uselist_arg) is True and collection_cls_arg is None ): type_is_a_collection = True if python_type_for_type is not None: python_type_for_type = api.named_type( names.NAMED_TYPE_BUILTINS_LIST, [python_type_for_type] ) elif ( uselist_arg is None or api.parse_bool(uselist_arg) is True ) and collection_cls_arg is not None: type_is_a_collection = True if isinstance(collection_cls_arg, CallExpr): collection_cls_arg = collection_cls_arg.callee if isinstance(collection_cls_arg, NameExpr) and isinstance( collection_cls_arg.node, TypeInfo ): if python_type_for_type is not None: # this can still be overridden by the left hand side # within _infer_Type_from_left_and_inferred_right python_type_for_type = Instance( collection_cls_arg.node, [python_type_for_type] ) elif ( isinstance(collection_cls_arg, NameExpr) and isinstance(collection_cls_arg.node, FuncDef) and collection_cls_arg.node.type is not None ): if python_type_for_type is not None: # this can still be overridden by the left hand side # within _infer_Type_from_left_and_inferred_right # TODO: handle mypy.types.Overloaded if isinstance(collection_cls_arg.node.type, CallableType): rt = get_proper_type(collection_cls_arg.node.type.ret_type) if isinstance(rt, CallableType): callable_ret_type = get_proper_type(rt.ret_type) if isinstance(callable_ret_type, Instance): python_type_for_type = Instance( callable_ret_type.type, [python_type_for_type], ) else: util.fail( api, "Expected Python collection type for " "collection_class parameter", stmt.rvalue, ) python_type_for_type = None elif uselist_arg is not None and api.parse_bool(uselist_arg) is False: if collection_cls_arg is not None: util.fail( api, "Sending uselist=False and collection_class at the same time " "does not make sense", stmt.rvalue, ) if python_type_for_type is not None: python_type_for_type = UnionType( [python_type_for_type, NoneType()] ) else: if left_hand_explicit_type is None: msg = ( "Can't infer scalar or collection for ORM mapped expression " "assigned to attribute '{}' if both 'uselist' and " "'collection_class' arguments are absent from the " "relationship(); please specify a " "type annotation on the left hand side." ) util.fail(api, msg.format(node.name), node) if python_type_for_type is None: return infer_type_from_left_hand_type_only( api, node, left_hand_explicit_type ) elif left_hand_explicit_type is not None: if type_is_a_collection: assert isinstance(left_hand_explicit_type, Instance) assert isinstance(python_type_for_type, Instance) return _infer_collection_type_from_left_and_inferred_right( api, node, left_hand_explicit_type, python_type_for_type ) else: return _infer_type_from_left_and_inferred_right( api, node, left_hand_explicit_type, python_type_for_type, ) else: return python_type_for_type def _infer_type_from_decl_composite_property( api: SemanticAnalyzerPluginInterface, stmt: AssignmentStmt, node: Var, left_hand_explicit_type: Optional[ProperType], ) -> Optional[ProperType]: """Infer the type of mapping from a CompositeProperty.""" assert isinstance(stmt.rvalue, CallExpr) target_cls_arg = stmt.rvalue.args[0] python_type_for_type = None if isinstance(target_cls_arg, NameExpr) and isinstance( target_cls_arg.node, TypeInfo ): related_object_type = target_cls_arg.node python_type_for_type = Instance(related_object_type, []) else: python_type_for_type = None if python_type_for_type is None: return infer_type_from_left_hand_type_only( api, node, left_hand_explicit_type ) elif left_hand_explicit_type is not None: return _infer_type_from_left_and_inferred_right( api, node, left_hand_explicit_type, python_type_for_type ) else: return python_type_for_type def _infer_type_from_decl_column_property( api: SemanticAnalyzerPluginInterface, stmt: AssignmentStmt, node: Var, left_hand_explicit_type: Optional[ProperType], ) -> Optional[ProperType]: """Infer the type of mapping from a ColumnProperty. This includes mappings against ``column_property()`` as well as the ``deferred()`` function. """ assert isinstance(stmt.rvalue, CallExpr) if stmt.rvalue.args: first_prop_arg = stmt.rvalue.args[0] if isinstance(first_prop_arg, CallExpr): type_id = names.type_id_for_callee(first_prop_arg.callee) # look for column_property() / deferred() etc with Column as first # argument if type_id is names.COLUMN: return _infer_type_from_decl_column( api, stmt, node, left_hand_explicit_type, right_hand_expression=first_prop_arg, ) if isinstance(stmt.rvalue, CallExpr): type_id = names.type_id_for_callee(stmt.rvalue.callee) # this is probably not strictly necessary as we have to use the left # hand type for query expression in any case. any other no-arg # column prop objects would go here also if type_id is names.QUERY_EXPRESSION: return _infer_type_from_decl_column( api, stmt, node, left_hand_explicit_type, ) return infer_type_from_left_hand_type_only( api, node, left_hand_explicit_type ) def _infer_type_from_decl_column( api: SemanticAnalyzerPluginInterface, stmt: AssignmentStmt, node: Var, left_hand_explicit_type: Optional[ProperType], right_hand_expression: Optional[CallExpr] = None, ) -> Optional[ProperType]: """Infer the type of mapping from a Column. E.g.:: @reg.mapped class MyClass: # ... a = Column(Integer) b = Column("b", String) c: Mapped[int] = Column(Integer) d: bool = Column(Boolean) Will resolve in MyPy as:: @reg.mapped class MyClass: # ... a : Mapped[int] b : Mapped[str] c: Mapped[int] d: Mapped[bool] """ assert isinstance(node, Var) callee = None if right_hand_expression is None: if not isinstance(stmt.rvalue, CallExpr): return None right_hand_expression = stmt.rvalue for column_arg in right_hand_expression.args[0:2]: if isinstance(column_arg, CallExpr): if isinstance(column_arg.callee, RefExpr): # x = Column(String(50)) callee = column_arg.callee type_args: Sequence[Expression] = column_arg.args break elif isinstance(column_arg, (NameExpr, MemberExpr)): if isinstance(column_arg.node, TypeInfo): # x = Column(String) callee = column_arg type_args = () break else: # x = Column(some_name, String), go to next argument continue elif isinstance(column_arg, (StrExpr,)): # x = Column("name", String), go to next argument continue else: assert False if callee is None: return None if isinstance(callee.node, TypeInfo) and names.mro_has_id( callee.node.mro, names.TYPEENGINE ): python_type_for_type = extract_python_type_from_typeengine( api, callee.node, type_args ) if left_hand_explicit_type is not None: return _infer_type_from_left_and_inferred_right( api, node, left_hand_explicit_type, python_type_for_type ) else: return UnionType([python_type_for_type, NoneType()]) else: # it's not TypeEngine, it's typically implicitly typed # like ForeignKey. we can't infer from the right side. return infer_type_from_left_hand_type_only( api, node, left_hand_explicit_type ) def _infer_type_from_left_and_inferred_right( api: SemanticAnalyzerPluginInterface, node: Var, left_hand_explicit_type: ProperType, python_type_for_type: ProperType, orig_left_hand_type: Optional[ProperType] = None, orig_python_type_for_type: Optional[ProperType] = None, ) -> Optional[ProperType]: """Validate type when a left hand annotation is present and we also could infer the right hand side:: attrname: SomeType = Column(SomeDBType) """ if orig_left_hand_type is None: orig_left_hand_type = left_hand_explicit_type if orig_python_type_for_type is None: orig_python_type_for_type = python_type_for_type if not is_subtype(left_hand_explicit_type, python_type_for_type): effective_type = api.named_type( names.NAMED_TYPE_SQLA_MAPPED, [orig_python_type_for_type] ) msg = ( "Left hand assignment '{}: {}' not compatible " "with ORM mapped expression of type {}" ) util.fail( api, msg.format( node.name, format_type(orig_left_hand_type), format_type(effective_type), ), node, ) return orig_left_hand_type def _infer_collection_type_from_left_and_inferred_right( api: SemanticAnalyzerPluginInterface, node: Var, left_hand_explicit_type: Instance, python_type_for_type: Instance, ) -> Optional[ProperType]: orig_left_hand_type = left_hand_explicit_type orig_python_type_for_type = python_type_for_type if left_hand_explicit_type.args: left_hand_arg = get_proper_type(left_hand_explicit_type.args[0]) python_type_arg = get_proper_type(python_type_for_type.args[0]) else: left_hand_arg = left_hand_explicit_type python_type_arg = python_type_for_type assert isinstance(left_hand_arg, (Instance, UnionType)) assert isinstance(python_type_arg, (Instance, UnionType)) return _infer_type_from_left_and_inferred_right( api, node, left_hand_arg, python_type_arg, orig_left_hand_type=orig_left_hand_type, orig_python_type_for_type=orig_python_type_for_type, ) def infer_type_from_left_hand_type_only( api: SemanticAnalyzerPluginInterface, node: Var, left_hand_explicit_type: Optional[ProperType], ) -> Optional[ProperType]: """Determine the type based on explicit annotation only. if no annotation were present, note that we need one there to know the type. """ if left_hand_explicit_type is None: msg = ( "Can't infer type from ORM mapped expression " "assigned to attribute '{}'; please specify a " "Python type or " "Mapped[] on the left hand side." ) util.fail(api, msg.format(node.name), node) return api.named_type( names.NAMED_TYPE_SQLA_MAPPED, [AnyType(TypeOfAny.special_form)] ) else: # use type from the left hand side return left_hand_explicit_type def extract_python_type_from_typeengine( api: SemanticAnalyzerPluginInterface, node: TypeInfo, type_args: Sequence[Expression], ) -> ProperType: if node.fullname == "sqlalchemy.sql.sqltypes.Enum" and type_args: first_arg = type_args[0] if isinstance(first_arg, RefExpr) and isinstance( first_arg.node, TypeInfo ): for base_ in first_arg.node.mro: if base_.fullname == "enum.Enum": return Instance(first_arg.node, []) # TODO: support other pep-435 types here else: return api.named_type(names.NAMED_TYPE_BUILTINS_STR, []) assert node.has_base("sqlalchemy.sql.type_api.TypeEngine"), ( "could not extract Python type from node: %s" % node ) type_engine_sym = api.lookup_fully_qualified_or_none( "sqlalchemy.sql.type_api.TypeEngine" ) assert type_engine_sym is not None and isinstance( type_engine_sym.node, TypeInfo ) type_engine = map_instance_to_supertype( Instance(node, []), type_engine_sym.node, ) return get_proper_type(type_engine.args[-1])