# Owner(s): ["module: unknown"] import torch from torch._C import parse_schema from torch.testing._internal.common_utils import run_tests, TestCase class TestFunctionSchema(TestCase): def test_serialize_and_deserialize(self): schemas = torch._C._jit_get_all_schemas() # so far we have around 1700 registered schemas self.assertGreater(len(schemas), 1000) for schema in schemas: parsed_schema = parse_schema(str(schema)) self.assertEqual(parsed_schema, schema) self.assertTrue(parsed_schema.is_backward_compatible_with(schema)) def test_out_schema(self): schema_with_out = parse_schema( "any.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!)" ) self.assertTrue(schema_with_out.arguments[-1].is_out) schema_without_out = parse_schema( "any.not_out(Tensor self, Tensor b) -> Tensor" ) self.assertFalse(schema_without_out.arguments[-1].is_out) def test_hash_schema(self): schema1 = parse_schema("any.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!)") schema2 = parse_schema("any.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!)") self.assertEqual(hash(schema1), hash(schema2)) schema3 = parse_schema( "any.not_out(Tensor self, *, Tensor(a!) out) -> Tensor(a!)" ) self.assertNotEqual(hash(schema2), hash(schema3)) schema4 = parse_schema( "foo(Tensor self, *, int a, Tensor(a!) out) -> Tensor(a!)" ) self.assertNotEqual(hash(schema2), hash(schema4)) # schemas with different default value, or different kw-only arg, should have different hash default_val_schema0 = parse_schema("foo(Tensor self, int a = 2) -> Tensor(a!)") default_val_schema1 = parse_schema("foo(Tensor self, int a = 3) -> Tensor(a!)") default_val_schema2 = parse_schema( "foo(Tensor self, *, int a = 2) -> Tensor(a!)" ) self.assertNotEqual(hash(default_val_schema0), hash(default_val_schema1)) self.assertNotEqual(hash(default_val_schema0), hash(default_val_schema2)) # schema with different alias annotation should have different hash alias_schema = parse_schema("foo(Tensor(a!) self, int a = 2) -> Tensor(a!)") self.assertNotEqual(hash(default_val_schema0), hash(alias_schema)) alias_schema2 = parse_schema("foo(Tensor(b!) self, int a = 2) -> Tensor(a!)") self.assertNotEqual(hash(alias_schema), hash(alias_schema2)) # schema with different alias infos alias_schema3 = parse_schema( "foo(Tensor self, *, int a, int b=1, Tensor(a!) out, Tensor(b!) b) -> Tensor(a!)" ) alias_schema4 = parse_schema( "foo(Tensor self, *, int a, int b=1, Tensor(a!) out, Tensor(b!) b) -> Tensor(b!)" ) alias_schema5 = parse_schema( "foo(Tensor self, *, int a, int b=1, Tensor(b!) out, Tensor(a!) b) -> Tensor(a!)" ) self.assertNotEqual(hash(alias_schema3), hash(alias_schema4)) self.assertNotEqual(hash(alias_schema3), hash(alias_schema5)) def test_backward_compatible_structure(self): old_schema = parse_schema("any.over(Tensor self, *, Tensor b) -> Tensor") # BC: A new schema without changes. new_schema = parse_schema("any.over(Tensor self, *, Tensor b) -> Tensor") self.assertTrue(new_schema.is_backward_compatible_with(old_schema)) # No-BC: A new schema with different name. new_schema = parse_schema("any_.over(Tensor self, *, Tensor b) -> Tensor") self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) # No-BC: A new schema with different overload name. new_schema = parse_schema("any.other(Tensor self, *, Tensor b) -> Tensor") self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) # No-BC: A new schema that adds vararg. new_schema = parse_schema("any.over(Tensor self, *, Tensor b, ...) -> Tensor") self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) # No-BC: A new schema with different number of outputs. new_schema = parse_schema( "any.over(Tensor self, *, Tensor b) -> (Tensor, Tensor)" ) self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) def test_backward_compatible_outputs(self): old_schema = parse_schema("any.over(Tensor self, *, Tensor b) -> Tensor") # No-BC: A new schema with output becoming of optional type. new_schema = parse_schema("any.over(Tensor self, *, Tensor b) -> Tensor?") self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) # BC: (the opposite case) An schema where the output is not of optional type anymore. self.assertTrue(old_schema.is_backward_compatible_with(new_schema)) # No-BC: A new schema with a different output type. new_schema = parse_schema("any.over(Tensor self, *, Tensor b) -> int") self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) # No-BC: A new schema with a different output type. new_schema = parse_schema("any.over(Tensor self, *, Tensor b) -> Tensor out") self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) def test_backward_compatible_arguments(self): old_schema = parse_schema("any(Tensor self, *, Tensor b, int c) -> Tensor") # No-BC: A new schema with less arguments. new_schema = parse_schema("any(Tensor self, *, Tensor b) -> Tensor") self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) # No-BC: A new schema with more arguments, appended, but no default value. new_schema = parse_schema( "any(Tensor self, *, Tensor b, int c, int d) -> Tensor" ) self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) # BC: A new schema with more arguments, appended, that have a default value. new_schema = parse_schema( "any(Tensor self, *, Tensor b, int c, int d=1) -> Tensor" ) self.assertTrue(new_schema.is_backward_compatible_with(old_schema)) # No-BC: A new schema with more arguments, not-appended, that have a default value. new_schema = parse_schema( "any(Tensor self, int d=1, *, Tensor b, int c) -> Tensor" ) self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) # BC: A new schema where old kwargs becomes positional. new_schema = parse_schema("any(Tensor self, Tensor b, *, int c) -> Tensor") self.assertTrue(new_schema.is_backward_compatible_with(old_schema)) # BC: (the opposite case) A new schema where an old positional argument becomes kwarg. self.assertFalse(old_schema.is_backward_compatible_with(new_schema)) # BC: A new schema where all old kwargs become positional. new_schema = parse_schema("any(Tensor self, Tensor b, int c) -> Tensor") self.assertTrue(new_schema.is_backward_compatible_with(old_schema)) # BC: (the opposite case) A new schema where all old positional arguments become kwarg. self.assertFalse(old_schema.is_backward_compatible_with(new_schema)) # No-BC: A new schema where old kwargs appear in different order. new_schema = parse_schema("any(Tensor self, *, int c, Tensor b) -> Tensor") self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) # BC: A new schema where argument becomes of type optional. new_schema = parse_schema("any(Tensor self, *, Tensor b, int? c) -> Tensor") self.assertTrue(new_schema.is_backward_compatible_with(old_schema)) # BC: A new schema where argument gains a default value. new_schema = parse_schema("any(Tensor self, *, Tensor b, int c=1) -> Tensor") self.assertTrue(new_schema.is_backward_compatible_with(old_schema)) # No-BC: A new schema where argument is "renamed". new_schema = parse_schema( "any(Tensor self, *, Tensor b, int renamed) -> Tensor" ) self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) # No-BC: A new schema where argument type changes to an incompatible type. new_schema = parse_schema("any(Tensor self, *, Tensor b, int[] c) -> Tensor") self.assertFalse(new_schema.is_backward_compatible_with(old_schema)) def test_backward_compatible_with_smart_serialization(self): # cases where out arg is provided old_schema = parse_schema( "foo(Tensor self, *, int a, Tensor(a!) out) -> Tensor(a!)" ) new_schema_same_out = parse_schema( "foo(Tensor self, *, int a, int b=1, Tensor(a!) out) -> Tensor(a!)" ) new_schema_wrong_default = parse_schema( "foo(Tensor self, *, int b=1, int a, Tensor(a!) out) -> Tensor(a!)" ) new_schema_more_out = parse_schema( "foo(Tensor self, *, int a, int b=1, Tensor(a!) out, Tensor(b!) b) -> Tensor(a!)" ) new_schema_wrong_pos = parse_schema( "foo(Tensor self, *, int a, int b=1, Tensor(b!) b, Tensor(a!) out) -> Tensor(a!)" ) self.assertTrue(new_schema_same_out.is_backward_compatible_with(old_schema)) self.assertTrue(new_schema_more_out.is_backward_compatible_with(old_schema)) self.assertFalse( new_schema_wrong_default.is_backward_compatible_with(old_schema) ) self.assertFalse(new_schema_wrong_pos.is_backward_compatible_with(old_schema)) # cases where out arg is not provided old_schema_without_arg = parse_schema("foo(Tensor self, int a, int b=1) -> int") new_schema_without_arg = parse_schema( "foo(Tensor self, int a, int b=1, int c=2) -> int" ) new_schema_without_arg_multiple_default = parse_schema( "foo(Tensor self, int a, int b=1, int c=2, int d=3) -> int" ) new_schema_without_arg_wrong_pos = parse_schema( "foo(Tensor self, int a, int c=2, int b=1) -> int" ) self.assertTrue( new_schema_without_arg.is_backward_compatible_with(old_schema_without_arg) ) self.assertTrue( new_schema_without_arg_multiple_default.is_backward_compatible_with( old_schema_without_arg ) ) self.assertFalse( new_schema_without_arg_wrong_pos.is_backward_compatible_with( old_schema_without_arg ) ) def test_string_optional_parameter_default_value(self): schema_a = parse_schema('example::op(str? order="NCHW") -> (Tensor)') schema_b = parse_schema(str(schema_a)) self.assertEqual(schema_a, schema_b) def test_forward_compatible_arguments_without_out(self): old_schema = parse_schema("any(Tensor self, int a, int b=1) -> Tensor") # deleting default arg is FC compatible new_schema = parse_schema("any(Tensor self, int a) -> Tensor") is_fc, _ = new_schema.check_forward_compatible_with(old_schema) self.assertTrue(is_fc) # adding default arg is FC compatible new_schema = parse_schema("any(Tensor self, int a, int b=1, int c=1) -> Tensor") is_fc, _ = new_schema.check_forward_compatible_with(old_schema) self.assertTrue(is_fc) # adding default arg with container type is NOT FC compatible new_schema = parse_schema( "any(Tensor self, int a, int b=1, int[2] c=1) -> Tensor" ) is_fc, reason = new_schema.check_forward_compatible_with(old_schema) self.assertFalse(is_fc) self.assertEqual( reason, "Function schema is not forward compatible since the new argument" " 'c' of type int[] has a container type as its default value.", ) # updating the default value of a default arg is NOT FC compatible new_schema = parse_schema("any(Tensor self, int a, int b=4) -> Tensor") is_fc, reason = new_schema.check_forward_compatible_with(old_schema) self.assertFalse(is_fc) self.assertEqual( reason, "'b' is not forward compatible with the older version of the schema" ) # updating the arg name of a default arg is NOT FC compatible new_schema = parse_schema("any(Tensor self, int a, int c=1) -> Tensor") is_fc, reason = new_schema.check_forward_compatible_with(old_schema) self.assertFalse(is_fc) self.assertEqual( reason, "'c' is not forward compatible with the older version of the schema" ) # not adding default arg in the end is NOT FC compatible new_schema = parse_schema("any(Tensor self, int a, int c=1, int b=1) -> Tensor") is_fc, reason = new_schema.check_forward_compatible_with(old_schema) self.assertFalse(is_fc) self.assertEqual( reason, "'c' is not forward compatible with the older version of the schema" ) # making default arg into positional arg is NOT FC compatible new_schema = parse_schema("any(Tensor self, int a, int b) -> Tensor") is_fc, reason = new_schema.check_forward_compatible_with(old_schema) self.assertFalse(is_fc) self.assertEqual( reason, "'b' is not forward compatible with the older version of the schema" ) # making positional arg into default arg is NOT FC compatible new_schema = parse_schema("any(Tensor self, int a=1, int b=1) -> Tensor") is_fc, reason = new_schema.check_forward_compatible_with(old_schema) self.assertFalse(is_fc) self.assertEqual( reason, "'a' is not forward compatible with the older version of the schema" ) def test_forward_compatible_arguments_real_use_case(self): # this change introduced forward incompatibility in the past old_slice_schema = parse_schema( "slice(Tensor(a) self, int dim=0, int start=0, int end=0, int step=1) -> Tensor(a)" ) new_slice_schema = parse_schema( "slice(Tensor(a) self, int dim=0, int? start=None, int? end=None, int step=1) -> Tensor(a)" ) is_fc, reason = new_slice_schema.check_forward_compatible_with(old_slice_schema) self.assertFalse(is_fc) self.assertEqual( reason, "'start' is not forward compatible with the older version of the schema", ) def test_forward_compatible_arguments_with_out(self): old_schema = parse_schema( "any(Tensor self, *, int a, int b=1, Tensor(a!) out) -> Tensor(a!)" ) new_schema = parse_schema( "any(Tensor self, *, int a, Tensor(a!) out) -> Tensor(a!)" ) is_fc, _ = new_schema.check_forward_compatible_with(old_schema) self.assertTrue(is_fc) new_schema = parse_schema( "any(Tensor self, *, int a, int b=1, int c=1, Tensor(a!) out) -> Tensor(a!)" ) is_fc, _ = new_schema.check_forward_compatible_with(old_schema) self.assertTrue(is_fc) new_schema = parse_schema( "any(Tensor self, *, int a, Tensor(d!) d, int b=1, Tensor(a!) out) -> Tensor(a!)" ) is_fc, reason = new_schema.check_forward_compatible_with(old_schema) self.assertFalse(is_fc) self.assertEqual( reason, "Function schema should have the same number of out arguments" ) def test_schema_error(self): with self.assertRaisesRegex( RuntimeError, r"schemas with vararg \(...\) can't have default value args" ): schema = parse_schema("any.foo(int arg1, int arg2=0, ...)") def test_tensor_list_alias_annotation_properly_parsed(self): schema_str = "foo(Tensor self, *, Tensor(a!)[] out) -> ()" schema = parse_schema(schema_str) self.assertTrue(schema.arguments[-1].alias_info.is_write) self.assertEqual(str(schema), schema_str) def test_tensor_option_arguments_properly_parsed(self): schema_str = ( "_to_copy(Tensor self, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None, " "bool? pin_memory=None, bool non_blocking=False, MemoryFormat? memory_format=None) -> Tensor" ) schema = parse_schema(schema_str) # fake type of MemoryFormat? is int? self.assertEqual(schema.arguments[-1].type.str(), "int?") # fake type of Layout? is int? self.assertEqual(schema.arguments[2].type.str(), "int?") # fake type of Device? is Device? self.assertEqual(schema.arguments[3].type.str(), "Device?") # print real types in FunctionSchema self.assertEqual(str(schema), schema_str) def test_sym_int_argument_properly_parsed(self): schema_str = "sym_size.int(Tensor self, int dim) -> SymInt" schema = parse_schema(schema_str) # fake type of SymInt is int self.assertEqual(schema.returns[-1].type.str(), "int") # real type of SymInt is SymInt self.assertEqual(schema.returns[-1].real_type.str(), "SymInt") # print real types in FunctionSchema self.assertEqual(str(schema), schema_str) if __name__ == "__main__": run_tests()