#!/usr/bin/env python3 # Copyright 2016 Google Inc. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS-IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import pytest from absl.testing import parameterized from fruit_test_common import * from fruit_test_config import CXX_COMPILER_NAME COMMON_DEFINITIONS = ''' #include "test_common.h" struct Scaler; struct ScalerImpl; struct Annotation1 {}; using ScalerAnnot1 = fruit::Annotated; using ScalerImplAnnot1 = fruit::Annotated; struct Annotation2 {}; using ScalerAnnot2 = fruit::Annotated; using ScalerImplAnnot2 = fruit::Annotated; template using WithNoAnnotation = T; template using WithAnnotation1 = fruit::Annotated; ''' class TestRegisterFactory(parameterized.TestCase): @parameterized.parameters([ 'std::function', 'fruit::Annotated>', ]) def test_register_factory_success_no_params_autoinject(self, XFactoryAnnot): source = ''' struct X { INJECT(X()) = default; }; fruit::Component getComponent() { return fruit::createComponent(); } int main() { fruit::Injector injector(getComponent); injector.get()(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ ('X()', 'X', 'std::function'), ('X()', 'fruit::Annotated', 'fruit::Annotated>'), ('std::unique_ptr()', 'std::unique_ptr', 'std::function()>'), ('std::unique_ptr()', 'fruit::Annotated>', 'fruit::Annotated()>>'), ]) def test_register_factory_success_no_params(self, ConstructX, XPtrAnnot, XPtrFactoryAnnot): source = ''' struct X {}; fruit::Component getComponent() { return fruit::createComponent() .registerFactory([](){return ConstructX;}); } int main() { fruit::Injector injector(getComponent); injector.get()(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ '', 'const', ]) def test_register_factory_autoinject_success(self, MaybeConst): source = ''' struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: INJECT(ScalerImpl(ASSISTED(double) factor)) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind(); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) def test_register_factory_autoinject_abstract_class_with_no_virtual_destructor_error(self): source = ''' struct Scaler { virtual double scale(double x) = 0; }; struct ScalerImpl : public Scaler { public: INJECT(ScalerImpl(ASSISTED(double))) { } double scale(double x) override { return x; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind(); } ''' expect_compile_error( r'FactoryBindingForUniquePtrOfClassWithNoVirtualDestructorError)?>\(double\)>,std::function)?>\(double\)>>', r'Fruit was trying to bind BaseFactory to DerivedFactory but the return type of BaseFactory is a std::unique_ptr of a class with no virtual destructor', COMMON_DEFINITIONS, source, locals()) def test_register_factory_autoinject_non_abstract_class_with_no_virtual_destructor_error(self): source = ''' struct Scaler { }; struct ScalerImpl : public Scaler { public: INJECT(ScalerImpl(ASSISTED(double))) { } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind(); } ''' expect_compile_error( r'FactoryBindingForUniquePtrOfClassWithNoVirtualDestructorError)?>\(double\)>,std::function)?>\(double\)>>', r'Fruit was trying to bind BaseFactory to DerivedFactory but the return type of BaseFactory is a std::unique_ptr of a class with no virtual destructor', COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ ('Scaler', 'std::function(double)>', 'std::function(double)>'), ('Scaler', 'std::function(double)>', 'const std::function(double)>'), ('fruit::Annotated', 'fruit::Annotated(double)>>', 'fruit::Annotated(double)>>'), ('fruit::Annotated', 'fruit::Annotated(double)>>', 'fruit::Annotated(double)>>'), ]) def test_autoinject(self, ScalerAnnot, ScalerFactoryAnnot, MaybeConstScalerFactoryAnnot): source = ''' struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: INJECT(ScalerImpl(ASSISTED(double) factor)) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind(); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ '', 'const', ]) def test_autoinject_returning_value(self, MaybeConst): source = ''' struct X { INJECT(X()) = default; }; struct Scaler { private: double factor; public: INJECT(Scaler(ASSISTED(double) factor, X)) : factor(factor) { } double scale(double x) { return x * factor; } }; using ScalerFactory = std::function; fruit::Component getScalerComponent() { return fruit::createComponent(); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); Scaler scaler = scalerFactory(12.1); std::cout << scaler.scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ ('Scaler', 'ScalerImpl', 'std::function(double)>', r'std::function)?>\(double\)>', ), ('fruit::Annotated', 'fruit::Annotated', 'fruit::Annotated(double)>>', r'fruit::Annotated)?>\(double\)>>', ), ]) def test_autoinject_error_abstract_class(self, ScalerAnnot, ScalerImplAnnot, ScalerFactoryAnnot, ScalerImplFactoryAnnotRegex): source = ''' struct Scaler { virtual double scale(double x) = 0; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } // Note: here we "forgot" to implement scale() (on purpose, for this test) so ScalerImpl is an abstract class. }; fruit::Component getScalerComponent() { return fruit::createComponent() .bind(); } ''' expect_compile_error( 'NoBindingFoundForAbstractClassError', 'No explicit binding was found for T, and note that C is an abstract class', COMMON_DEFINITIONS, source, locals()) def test_autoinject_nonmovable_ok(self): source = ''' struct I { virtual ~I() = default; }; struct C : public I { INJECT(C()) = default; C(const C&) = delete; C(C&&) = delete; C& operator=(const C&) = delete; C& operator=(C&&) = delete; }; using IFactory = std::function()>; fruit::Component getIFactory() { return fruit::createComponent() .bind(); } int main() { fruit::Injector injector(getIFactory); IFactory iFactory(injector); std::unique_ptr i = iFactory(); (void)i; } ''' expect_success( COMMON_DEFINITIONS, source) def test_autoinject_2_assisted_params(self): source = ''' struct Foo { Foo(int x, float y) { (void)x; (void)y; } }; using FooFactory = std::function; fruit::Component getComponent() { return fruit::createComponent() .registerFactory, fruit::Assisted)>( [](int x, float y) { return Foo(x, y); }); } int main() { fruit::Injector injector(getComponent); FooFactory fooFactory(injector); Foo foo = fooFactory(1, 2.3f); (void)foo; } ''' expect_success( COMMON_DEFINITIONS, source) def test_autoinject_2_assisted_params_returning_value(self): source = ''' struct Foo { Foo(int x, float y) { (void)x; (void)y; } }; using FooFactory = std::function; fruit::Component getComponent() { return fruit::createComponent() .registerFactory, fruit::Assisted)>( [](int x, float y) { return Foo(x, y); }); } int main() { fruit::Injector injector(getComponent); FooFactory fooFactory(injector); Foo foo = fooFactory(1, 2.3f); (void)foo; } ''' expect_success( COMMON_DEFINITIONS, source) def test_autoinject_instances_bound_to_assisted_params(self): source = ''' struct X {}; struct Y {}; struct Foo { Foo(X x, Y y) { (void)x; (void)y; } }; using FooFactory = std::function; fruit::Component getComponent() { static X x = X(); static Y y = Y(); return fruit::createComponent() .bindInstance(x) .bindInstance(y) .registerFactory( [](X x, Y y) { return Foo(x, y); }); } int main() { fruit::Injector injector(getComponent); FooFactory fooFactory(injector); Foo foo = fooFactory(); (void)foo; } ''' expect_success( COMMON_DEFINITIONS, source) def test_autoinject_2_assisted_params_plus_nonassisted_params(self): source = ''' struct X {}; struct Y {}; struct Z {}; struct Foo { Foo(X, Y, int, float, Z) { } }; using FooPtrFactory = std::function(int, float)>; fruit::Component getComponent() { static X x = X(); static Y y = Y(); static Z z = Z(); return fruit::createComponent() .bindInstance(x) .bindInstance(y) .bindInstance(z) .registerFactory(X, Y, fruit::Assisted, fruit::Assisted, Z)>( [](X x, Y y, int n, float a, Z z) { return std::unique_ptr(new Foo(x, y, n, a, z)); }); } int main() { fruit::Injector injector(getComponent); FooPtrFactory fooPtrFactory(injector); std::unique_ptr foo = fooPtrFactory(1, 3.4f); (void)foo; } ''' expect_success( COMMON_DEFINITIONS, source) def test_autoinject_2_assisted_params_plus_nonassisted_params_returning_value(self): source = ''' struct X {}; struct Y {}; struct Z {}; struct Foo { Foo(X, Y, int, float, Z) { } }; using FooFactory = std::function; fruit::Component getComponent() { static X x = X(); static Y y = Y(); static Z z = Z(); return fruit::createComponent() .bindInstance(x) .bindInstance(y) .bindInstance(z) .registerFactory, fruit::Assisted, Z)>( [](X x, Y y, int n, float a, Z z) { return Foo(x, y, n, a, z); }); } int main() { fruit::Injector injector(getComponent); FooFactory fooFactory(injector); Foo foo = fooFactory(1, 3.4f); (void)foo; } ''' expect_success( COMMON_DEFINITIONS, source) def test_autoinject_mixed_assisted_and_injected_params(self): source = ''' struct X {}; struct Y {}; struct Foo { Foo(int, float, X, Y, double) { } }; using FooFactory = std::function; fruit::Component getComponent() { static X x = X(); static Y y = Y(); return fruit::createComponent() .bindInstance(x) .bindInstance(y) .registerFactory, fruit::Assisted, X, Y, fruit::Assisted)>( [](int n, float a, X x, Y y, double d) { return Foo(n, a, x, y, d); }); } int main() { fruit::Injector injector(getComponent); FooFactory fooFactory(injector); Foo foo = fooFactory(1, 3.4f, 3.456); (void)foo; } ''' expect_success( COMMON_DEFINITIONS, source) def test_autoinject_annotation_in_signature_return_type(self): source = ''' struct X { using Inject = fruit::Annotated(); }; fruit::Component()>>> getComponent() { return fruit::createComponent(); } ''' expect_compile_error( 'InjectTypedefWithAnnotationError', 'C::Inject is a signature that returns an annotated type', COMMON_DEFINITIONS, source) def test_autoinject_annotation_in_signature_return_type_returning_value(self): source = ''' struct X { using Inject = fruit::Annotated(); }; fruit::Component>> getComponent() { return fruit::createComponent(); } ''' expect_compile_error( 'InjectTypedefWithAnnotationError', 'C::Inject is a signature that returns an annotated type', COMMON_DEFINITIONS, source) def test_autoinject_from_provider_simple(self): source = ''' struct X { INJECT(X()) = default; }; struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor, X) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .registerProvider([](X x) { return std::function(double)>([x](double n){ return std::unique_ptr(new ScalerImpl(n, x)); }); }) .bind(); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source) @parameterized.parameters([ ('Scaler', 'std::function(double)>', 'std::function(double)>', 'ScalerImpl', 'std::function(double)>'), ('Scaler', 'std::function(double)>', 'const std::function(double)>', 'ScalerImpl', 'std::function(double)>'), ('fruit::Annotated', 'fruit::Annotated(double)>>', 'fruit::Annotated(double)>>', 'fruit::Annotated', 'fruit::Annotated(double)>>'), ('fruit::Annotated', 'fruit::Annotated(double)>>', 'fruit::Annotated(double)>>', 'fruit::Annotated', 'fruit::Annotated(double)>>'), ]) def test_autoinject_from_provider(self, ScalerAnnot, ScalerFactoryAnnot, MaybeConstScalerFactoryAnnot, ScalerImplAnnot, ScalerImplFactoryAnnot): source = ''' struct X { INJECT(X()) = default; }; struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor, X) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; using ScalerImplFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .registerProvider([](X x) { return std::function(double)>([x](double n){ return std::unique_ptr(new ScalerImpl(n, x)); }); }) .bind(); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ 'ScalerFactory', 'fruit::Annotated', ]) def test_autoinject_from_provider_returning_value(self, ScalerFactoryAnnot): source = ''' struct X { INJECT(X()) = default; }; struct Scaler { private: double factor; public: Scaler(double factor, X) : factor(factor) { } double scale(double x) { return x * factor; } }; using ScalerFactory = std::function; fruit::Component getScalerComponent() { return fruit::createComponent() .registerProvider([](X x) { return std::function([x](double n){ return Scaler(n, x); }); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); Scaler scaler = scalerFactory(12.1); std::cout << scaler.scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @multiple_parameters([ '', 'const', ], [ 'X', 'ANNOTATED(Annotation1, X)', ]) def test_autoinject_with_binding(self, MaybeConst, X_ANNOT): source = ''' struct X { using Inject = X(); }; struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: INJECT(ScalerImpl(ASSISTED(double) factor, X_ANNOT x)) : factor(factor) { (void)x; } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind(); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @multiple_parameters([ '', 'const', ], [ 'X', 'ANNOTATED(Annotation1, X)', ]) def test_autoinject_with_binding_returning_value(self, MaybeConst, X_ANNOT): source = ''' struct X { using Inject = X(); }; struct Scaler { private: double factor; public: INJECT(Scaler(ASSISTED(double) factor, X_ANNOT x)) : factor(factor) { (void)x; } double scale(double x) { return x * factor; } }; using ScalerFactory = std::function; fruit::Component getScalerComponent() { return fruit::createComponent(); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); Scaler scaler = scalerFactory(12.1); std::cout << scaler.scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) def test_autoinject_with_binding_variant(self): source = ''' struct X { INJECT(X()) = default; }; struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: INJECT(ScalerImpl(X, ASSISTED(double) factor)) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind(); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source) def test_autoinject_with_binding_variant_returning_value(self): source = ''' struct X { INJECT(X()) = default; }; struct Scaler { private: double factor; public: INJECT(Scaler(X, ASSISTED(double) factor)) : factor(factor) { } double scale(double x) { return x * factor; } }; using ScalerFactory = std::function; fruit::Component getScalerComponent() { return fruit::createComponent(); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); Scaler scaler = scalerFactory(12.1); std::cout << scaler.scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source) @parameterized.parameters([ ('Scaler', 'ScalerImpl', 'std::function(double)>'), ('fruit::Annotated', 'fruit::Annotated', 'fruit::Annotated(double)>>'), ]) def test_register_factory_success(self, ScalerAnnot, ScalerImplAnnot, ScalerFactoryAnnot): source = ''' struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind() .registerFactory)>([](double factor) { return ScalerImpl(factor); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) def test_register_factory_with_annotation_returning_value(self): source = ''' struct Scaler { private: double factor; public: Scaler(double factor) : factor(factor) { } double scale(double x) { return x * factor; } }; using ScalerFactory = std::function; using ScalerFactoryAnnot1 = fruit::Annotated; fruit::Component getScalerComponent() { return fruit::createComponent() .registerFactory)>( [](double factor) { return Scaler(factor); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); Scaler scaler = scalerFactory(12.1); std::cout << scaler.scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source) def test_register_factory_with_different_annotation(self): source = ''' struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; using ScalerFactoryAnnot1 = fruit::Annotated; fruit::Component getScalerComponent() { return fruit::createComponent() .bind() .registerFactory)>( [](double factor) { return ScalerImpl(factor); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source) @parameterized.parameters([ ('Scaler', 'ScalerImpl', 'std::function(double, double)>'), ('fruit::Annotated', 'fruit::Annotated', 'fruit::Annotated(double, double)>>'), ]) def test_register_factory_2arg_success(self, ScalerAnnot, ScalerImplAnnot, ScalerFactoryAnnot): source = ''' struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double, double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind() .registerFactory, fruit::Assisted)>( [](double factor, double) { return ScalerImpl(factor); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); std::unique_ptr scaler = scalerFactory(12.1, 34.2); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) def test_register_factory_with_different_annotation_error(self): source = ''' struct Scaler { virtual double scale(double x) = 0; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; using ScalerFactoryAnnot1 = fruit::Annotated; fruit::Component getScalerComponent() { return fruit::createComponent() .bind() .registerFactory)>([](double factor) { return ScalerImpl(factor); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_compile_error( r'NoBindingFoundError)?>\(double\)>>>', r'', COMMON_DEFINITIONS, source) def test_register_factory_dep_on_provider(self): source = ''' struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind() .registerProvider([](){return 23;}) .registerFactory, fruit::Provider)>( [](double factor, fruit::Provider provider) { return ScalerImpl(factor * provider.get()); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source) def test_register_factory_dep_on_provider_returning_value(self): source = ''' struct Scaler { private: double factor; public: Scaler(double factor) : factor(factor) { } double scale(double x) { return x * factor; } }; using ScalerFactory = std::function; fruit::Component getScalerComponent() { return fruit::createComponent() .registerProvider([](){return 23;}) .registerFactory, fruit::Provider)>( [](double factor, fruit::Provider provider) { return Scaler(factor * provider.get()); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); Scaler scaler = scalerFactory(12.1); std::cout << scaler.scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source) def test_register_factory_error_abstract_class(self): source = ''' struct Scaler { virtual double scale(double x) = 0; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } // Note: here we "forgot" to implement scale() (on purpose, for this test) so ScalerImpl is an abstract class. }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind() .registerFactory(fruit::Assisted)>([](double) { return (ScalerImpl*)nullptr; }); } ''' expect_compile_error( 'CannotConstructAbstractClassError', 'The specified class can.t be constructed because it.s an abstract class.', COMMON_DEFINITIONS, source) def test_register_factory_error_not_function(self): source = ''' struct X { X(int) {} }; fruit::Component> getComponent() { int n = 3; return fruit::createComponent() .registerFactory([=]{return X(n);}); } ''' expect_compile_error( 'LambdaWithCapturesError<.*>', 'Only lambdas with no captures are supported', COMMON_DEFINITIONS, source) @parameterized.parameters([ ('Scaler', 'ScalerImpl', 'ScalerImpl*', 'std::function(double)>', r'ScalerImpl\*\(fruit::Assisted\)'), ('fruit::Annotated', 'fruit::Annotated', 'fruit::Annotated', 'fruit::Annotated(double)>>', r'fruit::Annotated\(fruit::Assisted\)') ]) def test_register_factory_for_pointer(self, ScalerAnnot, ScalerImplAnnot, ScalerImplPtrAnnot, ScalerFactoryAnnot, ScalerImplFactorySignatureAnnotRegex): source = ''' struct Scaler { virtual double scale(double x) = 0; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind() .registerFactory)>([](double factor) { return new ScalerImpl(factor); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_compile_error( 'FactoryReturningPointerError', 'The specified factory returns a pointer. This is not supported', COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ ('Scaler*', 'std::function', r'Scaler\*\(fruit::Assisted\)'), ('fruit::Annotated', 'fruit::Annotated>', r'fruit::Annotated\(fruit::Assisted\)'), ]) def test_register_factory_for_pointer_returning_value(self, ScalerPtrAnnot, ScalerFactoryAnnot, ScalerFactorySignatureAnnotRegex): source = ''' struct Scaler { private: double factor; public: Scaler(double factor) : factor(factor) { } double scale(double x) { return x * factor; } }; using ScalerFactory = std::function; fruit::Component getScalerComponent() { return fruit::createComponent() .registerFactory)>([](double factor) { return new Scaler(factor); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); Scaler scaler = scalerFactory(12.1); std::cout << scaler.scale(3) << std::endl; } ''' expect_compile_error( 'FactoryReturningPointerError', 'The specified factory returns a pointer. This is not supported', COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ ('Scaler', 'ScalerImpl', 'std::unique_ptr', 'std::function(double)>'), ('fruit::Annotated', 'fruit::Annotated', 'fruit::Annotated>', 'fruit::Annotated(double)>>'), ]) def test_register_factory_for_unique_pointer(self, ScalerAnnot, ScalerImplAnnot, ScalerImplPtrAnnot, ScalerFactoryAnnot): source = ''' struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind() .registerFactory)>( [](double factor) { return std::unique_ptr(new ScalerImpl(factor)); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ ('Scaler', 'ScalerImpl', 'std::unique_ptr', 'std::function(double)>'), ('fruit::Annotated', 'fruit::Annotated', 'fruit::Annotated>', 'fruit::Annotated(double)>>'), ]) def test_register_factory_for_unique_pointer_returning_invalid_unique_ptr_ok(self, ScalerAnnot, ScalerImplAnnot, ScalerImplPtrAnnot, ScalerFactoryAnnot): source = ''' struct Scaler { virtual double scale(double x) = 0; virtual ~Scaler() = default; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind() .registerFactory)>( [](double) { return std::unique_ptr(nullptr); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); std::unique_ptr scaler = scalerFactory(12.1); Assert(scaler.get() == nullptr); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ ('Scaler', 'std::function'), ('fruit::Annotated', 'fruit::Annotated>'), ]) def test_register_factory_for_unique_pointer_returning_value(self, ScalerAnnot, ScalerFactoryAnnot): source = ''' struct Scaler { private: double factor; public: Scaler(double factor) : factor(factor) { } double scale(double x) { return x * factor; } }; using ScalerFactory = std::function; fruit::Component getScalerComponent() { return fruit::createComponent() .registerFactory)>( [](double factor) { return Scaler(factor); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory = injector.get(); Scaler scaler = scalerFactory(12.1); std::cout << scaler.scale(3) << std::endl; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ 'ScalerImpl', 'fruit::Annotated', ]) def test_register_factory_inconsistent_signature(self, ScalerImplAnnot): source = ''' struct Scaler { virtual double scale(double x) = 0; }; struct ScalerImpl : public Scaler { private: double factor; public: ScalerImpl(double factor) : factor(factor) { } double scale(double x) override { return x * factor; } }; using ScalerFactory = std::function(double)>; fruit::Component getScalerComponent() { return fruit::createComponent() .bind() .registerFactory)>([](float factor) { return ScalerImpl(factor); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); std::unique_ptr scaler = scalerFactory(12.1); std::cout << scaler->scale(3) << std::endl; } ''' expect_compile_error( r'FunctorSignatureDoesNotMatchError', r'Unexpected functor signature', COMMON_DEFINITIONS, source, locals()) def test_register_factory_inconsistent_signature_returning_value(self): source = ''' struct Scaler { private: double factor; public: Scaler(double factor) : factor(factor) { } double scale(double x) { return x * factor; } }; using ScalerFactory = std::function; fruit::Component getScalerComponent() { return fruit::createComponent() .registerFactory)>([](float factor) { return Scaler(factor); }); } int main() { fruit::Injector injector(getScalerComponent); ScalerFactory scalerFactory(injector); Scaler scaler = scalerFactory(12.1); std::cout << scaler.scale(3) << std::endl; } ''' expect_compile_error( r'FunctorSignatureDoesNotMatchError', r'Unexpected functor signature', COMMON_DEFINITIONS, source) def test_register_factory_nonmovable_ok(self): source = ''' struct C { INJECT(C()) = default; C(const C&) = delete; C(C&&) = delete; C& operator=(const C&) = delete; C& operator=(C&&) = delete; }; using CFactory = std::function()>; fruit::Component getCFactory() { return fruit::createComponent(); } int main() { fruit::Injector injector(getCFactory); CFactory cFactory(injector); std::unique_ptr c = cFactory(); (void)c; } ''' expect_success( COMMON_DEFINITIONS, source) # TODO: this might not be the best error message, maybe we should ignore the constructor entirely in the message, # or mention that there are other ways to satisfy that dependency. @parameterized.parameters([ ('X', 'std::function'), ('fruit::Annotated', 'fruit::Annotated>'), ]) def test_register_factory_not_existing_constructor1(self, XAnnot, XFactoryAnnot): source = ''' struct X { INJECT(X()) = default; }; fruit::Component getComponent() { return fruit::createComponent(); } ''' expect_compile_error( r'FunctorSignatureDoesNotMatchError', r'Unexpected functor signature', COMMON_DEFINITIONS, source, locals()) # TODO: this might not be the best error message, maybe we should ignore the constructor entirely in the message, # or mention that there are other ways to satisfy that dependency. @parameterized.parameters([ ('std::function(int)>', r'std::unique_ptr)?>\(int\)', r'std::unique_ptr)?>\((void)?\)'), ('fruit::Annotated(int)>>', r'fruit::Annotated)?>>\(int\)', r'fruit::Annotated)?>>\((void)?\)') ]) def test_register_factory_not_existing_constructor2(self, XIntFactoryAnnot, XIntFactoryAnnotRegex, XVoidFactoryAnnotRegex): source = ''' struct X { using Inject = X(); }; fruit::Component getComponent() { return fruit::createComponent(); } ''' expect_compile_error( 'FunctorSignatureDoesNotMatchError', 'Unexpected functor signature', COMMON_DEFINITIONS, source, locals()) # TODO: this might not be the best error message, maybe we should ignore the constructor entirely in the message, # or mention that there are other ways to satisfy that dependency. @parameterized.parameters([ ('X', 'std::function'), ('fruit::Annotated', 'fruit::Annotated>'), ]) def test_register_factory_not_existing_constructor2_returning_value(self, XAnnot, XFactoryAnnot): source = ''' struct X { using Inject = X(); }; fruit::Component getComponent() { return fruit::createComponent(); } ''' expect_compile_error( r'FunctorSignatureDoesNotMatchError', r'Unexpected functor signature', COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ 'std::function', 'fruit::Annotated>', ]) def test_register_factory_success_factory_movable_only_implicit(self, XFactoryAnnot): source = ''' struct X { INJECT(X()) = default; X(X&&) = default; X(const X&) = delete; }; fruit::Component getComponent() { return fruit::createComponent(); } int main() { fruit::Injector injector(getComponent); injector.get()(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ ('X', 'X()', 'std::function'), ('fruit::Annotated', 'X()', 'fruit::Annotated>'), ('std::unique_ptr', 'std::unique_ptr(new X())', 'std::function()>'), ('fruit::Annotated>', 'std::unique_ptr(new X())', 'fruit::Annotated()>>'), ]) def test_register_factory_success_factory_movable_only_explicit(self, XPtrAnnot, ConstructX, XPtrFactoryAnnot): source = ''' struct X { X() = default; X(X&&) = default; X(const X&) = delete; }; fruit::Component getComponent() { return fruit::createComponent() .registerFactory([](){return ConstructX;}); } int main() { fruit::Injector injector(getComponent); injector.get()(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ 'std::function()>', 'fruit::Annotated()>>', ]) def test_register_factory_success_factory_not_movable_implicit(self, XPtrFactoryAnnot): source = ''' struct X { INJECT(X()) = default; X(X&&) = delete; X(const X&) = delete; }; fruit::Component getComponent() { return fruit::createComponent(); } int main() { fruit::Injector injector(getComponent); injector.get()(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ ('std::unique_ptr', 'std::function()>'), ('fruit::Annotated>', 'fruit::Annotated()>>'), ]) def test_register_factory_success_factory_not_movable_explicit_returning_pointer(self, XPtrAnnot, XPtrFactoryAnnot): source = ''' struct X { X() = default; X(X&&) = delete; X(const X&) = delete; }; fruit::Component getComponent() { return fruit::createComponent() .registerFactory([](){return std::unique_ptr(new X());}); } int main() { fruit::Injector injector(getComponent); injector.get()(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @multiple_parameters([ ('X()', 'X'), ('std::unique_ptr(new X())', 'std::unique_ptr'), ], [ 'WithNoAnnotation', 'WithAnnotation1', ], [ 'Y', 'Y*', 'const Y*', 'Y&', 'const Y&', 'std::shared_ptr', 'fruit::Provider', 'fruit::Provider', ]) def test_register_factory_with_param_success(self, ConstructX, XPtr, WithAnnot, YVariant): source = ''' struct Y {}; struct X {}; fruit::Component> getYComponent() { return fruit::createComponent() .registerConstructor()>(); } fruit::Component> getComponent() { return fruit::createComponent() .install(getYComponent) .registerFactory)>([](YVariant){ return ConstructX; }); } int main() { fruit::Injector> injector(getComponent); XPtr x = injector.get>()(); (void) x; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @multiple_parameters([ ('X()', 'X'), ('std::unique_ptr(new X())', 'std::unique_ptr'), ], [ 'WithNoAnnotation', 'WithAnnotation1', ], [ 'Y', 'const Y*', 'const Y&', 'fruit::Provider', ]) def test_register_factory_with_param_const_binding_success(self, ConstructX, XPtr, WithAnnot, YVariant): source = ''' struct Y {}; struct X {}; const Y y{}; fruit::Component> getYComponent() { return fruit::createComponent() .bindInstance, Y>(y); } fruit::Component> getComponent() { return fruit::createComponent() .install(getYComponent) .registerFactory)>([](YVariant){ return ConstructX; }); } int main() { fruit::Injector> injector(getComponent); XPtr x = injector.get>()(); (void) x; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @multiple_parameters([ ('X()', 'X'), ('std::unique_ptr(new X())', 'std::unique_ptr'), ], [ ('WithNoAnnotation', 'Y'), ('WithAnnotation1', 'fruit::Annotated'), ], [ 'X', 'std::unique_ptr', ], [ 'Y*', 'Y&', 'std::shared_ptr', 'fruit::Provider', ]) def test_register_factory_with_param_error_nonconst_param_required(self, ConstructX, XPtr, WithAnnot, YAnnotRegex, XFactoryResult, YVariant): source = ''' struct Y {}; struct X {}; fruit::Component> getYComponent(); fruit::Component> getComponent() { return fruit::createComponent() .install(getYComponent) .registerFactory)>([](YVariant){ return ConstructX; }); } ''' expect_compile_error( 'NonConstBindingRequiredButConstBindingProvidedError', 'The type T was provided as constant, however one of the constructors/providers/factories in this component', COMMON_DEFINITIONS, source, locals()) @multiple_parameters([ ('X()', 'X'), ('std::unique_ptr(new X())', 'std::unique_ptr'), ], [ 'X', 'std::unique_ptr', ], [ ('WithNoAnnotation', 'Y'), ('WithAnnotation1', 'fruit::Annotated'), ], [ 'Y*', 'Y&', 'std::shared_ptr', 'fruit::Provider', ]) def test_register_factory_with_param_error_nonconst_param_required_install_after(self, ConstructX, XPtr, XFactoryResult, WithAnnot, YAnnotRegex, YVariant): source = ''' struct Y {}; struct X {}; fruit::Component> getYComponent(); fruit::Component> getComponent() { return fruit::createComponent() .registerFactory)>([](YVariant){ return ConstructX; }) .install(getYComponent); } ''' expect_compile_error( 'NonConstBindingRequiredButConstBindingProvidedError', 'The type T was provided as constant, however one of the constructors/providers/factories in this component', COMMON_DEFINITIONS, source, locals()) @multiple_parameters([ ('X()', 'X'), ('std::unique_ptr(new X())', 'std::unique_ptr'), ], [ 'WithNoAnnotation', 'WithAnnotation1', ]) def test_register_factory_with_non_assignable_injected_param_success(self, ConstructX, XPtr, WithAnnot): source = ''' struct Y { Y(const Y&) = delete; Y& operator=(const Y&) = delete; Y() = default; Y(Y&&) = default; Y& operator=(Y&&) = default; }; struct X {}; fruit::Component> getYComponent() { return fruit::createComponent() .registerConstructor()>(); } fruit::Component> getComponent() { return fruit::createComponent() .install(getYComponent) .registerFactory)>([](Y&){ return ConstructX; }); } int main() { fruit::Injector> injector(getComponent); XPtr x = injector.get>()(); (void) x; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @multiple_parameters([ ('X()', 'X'), ('std::unique_ptr(new X())', 'std::unique_ptr'), ]) def test_register_factory_with_non_assignable_assisted_param_success(self, ConstructX, XPtr): source = ''' struct Y { Y(const Y&) = delete; Y& operator=(const Y&) = delete; Y() = default; Y(Y&&) = default; Y& operator=(Y&&) = default; }; struct X {}; fruit::Component> getComponent() { return fruit::createComponent() .registerFactory)>([](Y){ return ConstructX; }); } int main() { fruit::Injector> injector(getComponent); XPtr x = injector.get>()(Y()); (void) x; } ''' expect_success( COMMON_DEFINITIONS, source, locals()) def test_register_factory_requiring_nonconst_then_requiring_const_ok(self): source = ''' struct X {}; struct Y {}; struct Z {}; fruit::Component, std::function> getRootComponent() { return fruit::createComponent() .registerFactory([](X&) { return Y();}) .registerFactory([](const X&) { return Z();}) .registerConstructor(); } int main() { fruit::Injector, std::function> injector(getRootComponent); std::function yFactory = injector.get>(); yFactory(); std::function zFactory = injector.get>(); zFactory(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) def test_register_factory_requiring_nonconst_then_requiring_const_declaring_const_requirement_error(self): source = ''' struct X {}; struct Y {}; struct Z {}; fruit::Component, std::function, std::function> getRootComponent() { return fruit::createComponent() .registerFactory([](X&) { return Y();}) .registerFactory([](const X&) { return Z();}); } ''' expect_compile_error( 'ConstBindingDeclaredAsRequiredButNonConstBindingRequiredError', 'The type T was declared as a const Required type in the returned Component, however', COMMON_DEFINITIONS, source, locals()) def test_register_factory_requiring_const_then_requiring_nonconst_ok(self): source = ''' struct X {}; struct Y {}; struct Z {}; fruit::Component, std::function> getRootComponent() { return fruit::createComponent() .registerFactory([](const X&) { return Y();}) .registerFactory([](X&) { return Z();}) .registerConstructor(); } int main() { fruit::Injector, std::function> injector(getRootComponent); std::function yFactory = injector.get>(); yFactory(); std::function zFactory = injector.get>(); zFactory(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) def test_register_factory_requiring_const_then_requiring_nonconst_declaring_const_requirement_error(self): source = ''' struct X {}; struct Y {}; struct Z {}; fruit::Component, std::function, std::function> getRootComponent() { return fruit::createComponent() .registerFactory([](const X&) { return Y();}) .registerFactory([](X&) { return Z();}); } ''' expect_compile_error( 'ConstBindingDeclaredAsRequiredButNonConstBindingRequiredError', 'The type T was declared as a const Required type in the returned Component, however', COMMON_DEFINITIONS, source, locals()) def test_provider_get_error_type_unique_pointer_pointer_not_provided(self): source = ''' struct X {}; void f(fruit::Provider provider) { provider.get*>(); } ''' expect_compile_error( r'TypeNotProvidedError)?>\*>', r'Trying to get an instance of T, but it is not provided by this Provider/Injector.', COMMON_DEFINITIONS, source) @multiple_parameters([ ('X()', 'X'), ('std::unique_ptr(new X())', 'std::unique_ptr'), ], [ 'X', 'std::unique_ptr', ], [ ('Y**', r'Y\*\*'), ('std::shared_ptr*', r'std::shared_ptr\*'), ('std::nullptr_t', r'(std::)?nullptr(_t)?'), ('Y*&', r'Y\*&'), ('Y(*)()', r'Y(\((__cdecl)?\*\))?\((void)?\)'), ('fruit::Annotated', r'Y\*\*'), ]) def test_register_factory_with_param_error_type_not_injectable(self, ConstructX, XPtr, XFactoryResult, YVariant, YVariantRegex): source = ''' struct Y {}; struct X {}; fruit::Component<> getComponent() { return fruit::createComponent() .registerFactory([](YVariant){ return ConstructX; }); } ''' expect_compile_error( 'NonInjectableTypeError', 'The type T is not injectable.', COMMON_DEFINITIONS, source, locals()) def test_register_factory_bind_nonconst_unique_ptr_factory_to_const_value_factory(self): source = ''' struct X { INJECT(X()) = default; }; fruit::Component> getChildComponent() { return fruit::createComponent(); } fruit::Component()>> getRootComponent() { return fruit::createComponent() .install(getChildComponent); } int main() { fruit::Injector()>> injector(getRootComponent); std::function()> xFactory(injector); xFactory(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) def test_register_factory_bind_const_interface_factory_to_nonconst_implementation_factory(self): source = ''' struct X { virtual void foo() = 0; virtual ~X() = default; }; struct Y : public X { INJECT(Y()) = default; void foo() override { } }; fruit::Component()>> getChildComponent() { return fruit::createComponent(); } fruit::Component()>> getRootComponent() { return fruit::createComponent() .install(getChildComponent) .bind(); } int main() { fruit::Injector()>> injector(getRootComponent); std::function()> xFactory(injector); xFactory(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) def test_register_factory_bind_nonconst_interface_factory_to_const_implementation_factory(self): source = ''' struct X { virtual void foo() = 0; virtual ~X() = default; }; struct Y : public X { INJECT(Y()) = default; void foo() override { } }; fruit::Component()>> getChildComponent() { return fruit::createComponent(); } fruit::Component()>> getRootComponent() { return fruit::createComponent() .install(getChildComponent) .bind(); } int main() { fruit::Injector()>> injector(getRootComponent); std::function()> xFactory(injector); xFactory(); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ 'WithNoAnnotation', 'WithAnnotation1', ]) def test_register_factory_abstract_class_ok(self, WithAnnot): source = ''' struct I { virtual int foo() = 0; virtual ~I() = default; }; struct X : public I { int foo() override { return 5; } }; fruit::Component()>>> getComponent() { return fruit::createComponent() .registerFactory>()>([](){return std::unique_ptr(static_cast(new X()));}); } int main() { fruit::Injector()>>> injector(getComponent); Assert(injector.get()>>>()()->foo() == 5); } ''' expect_success( COMMON_DEFINITIONS, source, locals()) @parameterized.parameters([ 'WithNoAnnotation', 'WithAnnotation1', ]) def test_register_factory_abstract_class_with_no_virtual_destructor_error(self, WithAnnot): if re.search('MSVC', CXX_COMPILER_NAME): # This is disabled in MSVC because it compiles cleanly with the latest MSVC. # TODO: investigate why this doesn't fail to compile with MSVC and then re-enable it for MSVC too. return source = ''' struct I { virtual int foo() = 0; }; struct X : public I { int foo() override { return 5; } }; fruit::Component()>>> getComponent() { return fruit::createComponent() .registerFactory>()>([](){return std::unique_ptr(static_cast(new X()));}); } ''' expect_compile_error( r'RegisterFactoryForUniquePtrOfAbstractClassWithNoVirtualDestructorError', r'registerFactory\(\) was called with a lambda that returns a std::unique_ptr, but T is an abstract class', COMMON_DEFINITIONS, source, locals(), ignore_warnings=True, disable_error_line_number_check=True) if __name__ == '__main__': absltest.main()