// Copyright 2007, Google Inc. // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following disclaimer // in the documentation and/or other materials provided with the // distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // Google Mock - a framework for writing C++ mock classes. // // This file tests the built-in actions. // Silence C4100 (unreferenced formal parameter) and C4503 (decorated name // length exceeded) for MSVC. #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable : 4100) #pragma warning(disable : 4503) #if _MSC_VER == 1900 // and silence C4800 (C4800: 'int *const ': forcing value // to bool 'true' or 'false') for MSVC 15 #pragma warning(disable : 4800) #endif #endif #include "gmock/gmock-actions.h" #include #include #include #include #include #include #include #include "gmock/gmock.h" #include "gmock/internal/gmock-port.h" #include "gtest/gtest-spi.h" #include "gtest/gtest.h" namespace testing { namespace { using ::testing::internal::BuiltInDefaultValue; TEST(TypeTraits, Negation) { // Direct use with std types. static_assert(std::is_base_of>::value, ""); static_assert(std::is_base_of>::value, ""); // With other types that fit the requirement of a value member that is // convertible to bool. static_assert(std::is_base_of< std::true_type, internal::negation>>::value, ""); static_assert(std::is_base_of< std::false_type, internal::negation>>::value, ""); static_assert(std::is_base_of< std::false_type, internal::negation>>::value, ""); } // Weird false/true types that aren't actually bool constants (but should still // be legal according to [meta.logical] because `bool(T::value)` is valid), are // distinct from std::false_type and std::true_type, and are distinct from other // instantiations of the same template. // // These let us check finicky details mandated by the standard like // "std::conjunction should evaluate to a type that inherits from the first // false-y input". template struct MyFalse : std::integral_constant {}; template struct MyTrue : std::integral_constant {}; TEST(TypeTraits, Conjunction) { // Base case: always true. static_assert(std::is_base_of>::value, ""); // One predicate: inherits from that predicate, regardless of value. static_assert( std::is_base_of, internal::conjunction>>::value, ""); static_assert( std::is_base_of, internal::conjunction>>::value, ""); // Multiple predicates, with at least one false: inherits from that one. static_assert( std::is_base_of, internal::conjunction, MyFalse<1>, MyTrue<2>>>::value, ""); static_assert( std::is_base_of, internal::conjunction, MyFalse<1>, MyFalse<2>>>::value, ""); // Short circuiting: in the case above, additional predicates need not even // define a value member. struct Empty {}; static_assert( std::is_base_of, internal::conjunction, MyFalse<1>, Empty>>::value, ""); // All predicates true: inherits from the last. static_assert( std::is_base_of, internal::conjunction, MyTrue<1>, MyTrue<2>>>::value, ""); } TEST(TypeTraits, Disjunction) { // Base case: always false. static_assert( std::is_base_of>::value, ""); // One predicate: inherits from that predicate, regardless of value. static_assert( std::is_base_of, internal::disjunction>>::value, ""); static_assert( std::is_base_of, internal::disjunction>>::value, ""); // Multiple predicates, with at least one true: inherits from that one. static_assert( std::is_base_of, internal::disjunction, MyTrue<1>, MyFalse<2>>>::value, ""); static_assert( std::is_base_of, internal::disjunction, MyTrue<1>, MyTrue<2>>>::value, ""); // Short circuiting: in the case above, additional predicates need not even // define a value member. struct Empty {}; static_assert( std::is_base_of, internal::disjunction, MyTrue<1>, Empty>>::value, ""); // All predicates false: inherits from the last. static_assert( std::is_base_of, internal::disjunction, MyFalse<1>, MyFalse<2>>>::value, ""); } TEST(TypeTraits, IsInvocableRV) { struct C { int operator()() const { return 0; } void operator()(int) & {} std::string operator()(int) && { return ""; }; }; // The first overload is callable for const and non-const rvalues and lvalues. // It can be used to obtain an int, cv void, or anything int is convertible // to. static_assert(internal::is_callable_r::value, ""); static_assert(internal::is_callable_r::value, ""); static_assert(internal::is_callable_r::value, ""); static_assert(internal::is_callable_r::value, ""); static_assert(internal::is_callable_r::value, ""); static_assert(internal::is_callable_r::value, ""); static_assert(internal::is_callable_r::value, ""); // It's possible to provide an int. If it's given to an lvalue, the result is // void. Otherwise it is std::string (which is also treated as allowed for a // void result type). static_assert(internal::is_callable_r::value, ""); static_assert(!internal::is_callable_r::value, ""); static_assert(!internal::is_callable_r::value, ""); static_assert(!internal::is_callable_r::value, ""); static_assert(internal::is_callable_r::value, ""); static_assert(internal::is_callable_r::value, ""); static_assert(!internal::is_callable_r::value, ""); // It's not possible to provide other arguments. static_assert(!internal::is_callable_r::value, ""); static_assert(!internal::is_callable_r::value, ""); // In C++17 and above, where it's guaranteed that functions can return // non-moveable objects, everything should work fine for non-moveable rsult // types too. #if defined(__cplusplus) && __cplusplus >= 201703L { struct NonMoveable { NonMoveable() = default; NonMoveable(NonMoveable&&) = delete; }; static_assert(!std::is_move_constructible_v); struct Callable { NonMoveable operator()() { return NonMoveable(); } }; static_assert(internal::is_callable_r::value); static_assert(internal::is_callable_r::value); static_assert( internal::is_callable_r::value); static_assert(!internal::is_callable_r::value); static_assert(!internal::is_callable_r::value); } #endif // C++17 and above // Nothing should choke when we try to call other arguments besides directly // callable objects, but they should not show up as callable. static_assert(!internal::is_callable_r::value, ""); static_assert(!internal::is_callable_r::value, ""); static_assert(!internal::is_callable_r::value, ""); } // Tests that BuiltInDefaultValue::Get() returns NULL. TEST(BuiltInDefaultValueTest, IsNullForPointerTypes) { EXPECT_TRUE(BuiltInDefaultValue::Get() == nullptr); EXPECT_TRUE(BuiltInDefaultValue::Get() == nullptr); EXPECT_TRUE(BuiltInDefaultValue::Get() == nullptr); } // Tests that BuiltInDefaultValue::Exists() return true. TEST(BuiltInDefaultValueTest, ExistsForPointerTypes) { EXPECT_TRUE(BuiltInDefaultValue::Exists()); EXPECT_TRUE(BuiltInDefaultValue::Exists()); EXPECT_TRUE(BuiltInDefaultValue::Exists()); } // Tests that BuiltInDefaultValue::Get() returns 0 when T is a // built-in numeric type. TEST(BuiltInDefaultValueTest, IsZeroForNumericTypes) { EXPECT_EQ(0U, BuiltInDefaultValue::Get()); EXPECT_EQ(0, BuiltInDefaultValue::Get()); EXPECT_EQ(0, BuiltInDefaultValue::Get()); #if GMOCK_WCHAR_T_IS_NATIVE_ #if !defined(__WCHAR_UNSIGNED__) EXPECT_EQ(0, BuiltInDefaultValue::Get()); #else EXPECT_EQ(0U, BuiltInDefaultValue::Get()); #endif #endif EXPECT_EQ(0U, BuiltInDefaultValue::Get()); // NOLINT EXPECT_EQ(0, BuiltInDefaultValue::Get()); // NOLINT EXPECT_EQ(0, BuiltInDefaultValue::Get()); // NOLINT EXPECT_EQ(0U, BuiltInDefaultValue::Get()); EXPECT_EQ(0, BuiltInDefaultValue::Get()); EXPECT_EQ(0, BuiltInDefaultValue::Get()); EXPECT_EQ(0U, BuiltInDefaultValue::Get()); // NOLINT EXPECT_EQ(0, BuiltInDefaultValue::Get()); // NOLINT EXPECT_EQ(0, BuiltInDefaultValue::Get()); // NOLINT EXPECT_EQ(0U, BuiltInDefaultValue::Get()); // NOLINT EXPECT_EQ(0, BuiltInDefaultValue::Get()); // NOLINT EXPECT_EQ(0, BuiltInDefaultValue::Get()); // NOLINT EXPECT_EQ(0, BuiltInDefaultValue::Get()); EXPECT_EQ(0, BuiltInDefaultValue::Get()); } // Tests that BuiltInDefaultValue::Exists() returns true when T is a // built-in numeric type. TEST(BuiltInDefaultValueTest, ExistsForNumericTypes) { EXPECT_TRUE(BuiltInDefaultValue::Exists()); EXPECT_TRUE(BuiltInDefaultValue::Exists()); EXPECT_TRUE(BuiltInDefaultValue::Exists()); #if GMOCK_WCHAR_T_IS_NATIVE_ EXPECT_TRUE(BuiltInDefaultValue::Exists()); #endif EXPECT_TRUE(BuiltInDefaultValue::Exists()); // NOLINT EXPECT_TRUE(BuiltInDefaultValue::Exists()); // NOLINT EXPECT_TRUE(BuiltInDefaultValue::Exists()); // NOLINT EXPECT_TRUE(BuiltInDefaultValue::Exists()); EXPECT_TRUE(BuiltInDefaultValue::Exists()); EXPECT_TRUE(BuiltInDefaultValue::Exists()); EXPECT_TRUE(BuiltInDefaultValue::Exists()); // NOLINT EXPECT_TRUE(BuiltInDefaultValue::Exists()); // NOLINT EXPECT_TRUE(BuiltInDefaultValue::Exists()); // NOLINT EXPECT_TRUE(BuiltInDefaultValue::Exists()); // NOLINT EXPECT_TRUE(BuiltInDefaultValue::Exists()); // NOLINT EXPECT_TRUE(BuiltInDefaultValue::Exists()); // NOLINT EXPECT_TRUE(BuiltInDefaultValue::Exists()); EXPECT_TRUE(BuiltInDefaultValue::Exists()); } // Tests that BuiltInDefaultValue::Get() returns false. TEST(BuiltInDefaultValueTest, IsFalseForBool) { EXPECT_FALSE(BuiltInDefaultValue::Get()); } // Tests that BuiltInDefaultValue::Exists() returns true. TEST(BuiltInDefaultValueTest, BoolExists) { EXPECT_TRUE(BuiltInDefaultValue::Exists()); } // Tests that BuiltInDefaultValue::Get() returns "" when T is a // string type. TEST(BuiltInDefaultValueTest, IsEmptyStringForString) { EXPECT_EQ("", BuiltInDefaultValue<::std::string>::Get()); } // Tests that BuiltInDefaultValue::Exists() returns true when T is a // string type. TEST(BuiltInDefaultValueTest, ExistsForString) { EXPECT_TRUE(BuiltInDefaultValue<::std::string>::Exists()); } // Tests that BuiltInDefaultValue::Get() returns the same // value as BuiltInDefaultValue::Get() does. TEST(BuiltInDefaultValueTest, WorksForConstTypes) { EXPECT_EQ("", BuiltInDefaultValue::Get()); EXPECT_EQ(0, BuiltInDefaultValue::Get()); EXPECT_TRUE(BuiltInDefaultValue::Get() == nullptr); EXPECT_FALSE(BuiltInDefaultValue::Get()); } // A type that's default constructible. class MyDefaultConstructible { public: MyDefaultConstructible() : value_(42) {} int value() const { return value_; } private: int value_; }; // A type that's not default constructible. class MyNonDefaultConstructible { public: // Does not have a default ctor. explicit MyNonDefaultConstructible(int a_value) : value_(a_value) {} int value() const { return value_; } private: int value_; }; TEST(BuiltInDefaultValueTest, ExistsForDefaultConstructibleType) { EXPECT_TRUE(BuiltInDefaultValue::Exists()); } TEST(BuiltInDefaultValueTest, IsDefaultConstructedForDefaultConstructibleType) { EXPECT_EQ(42, BuiltInDefaultValue::Get().value()); } TEST(BuiltInDefaultValueTest, DoesNotExistForNonDefaultConstructibleType) { EXPECT_FALSE(BuiltInDefaultValue::Exists()); } // Tests that BuiltInDefaultValue::Get() aborts the program. TEST(BuiltInDefaultValueDeathTest, IsUndefinedForReferences) { EXPECT_DEATH_IF_SUPPORTED({ BuiltInDefaultValue::Get(); }, ""); EXPECT_DEATH_IF_SUPPORTED({ BuiltInDefaultValue::Get(); }, ""); } TEST(BuiltInDefaultValueDeathTest, IsUndefinedForNonDefaultConstructibleType) { EXPECT_DEATH_IF_SUPPORTED( { BuiltInDefaultValue::Get(); }, ""); } // Tests that DefaultValue::IsSet() is false initially. TEST(DefaultValueTest, IsInitiallyUnset) { EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_FALSE(DefaultValue::IsSet()); } // Tests that DefaultValue can be set and then unset. TEST(DefaultValueTest, CanBeSetAndUnset) { EXPECT_TRUE(DefaultValue::Exists()); EXPECT_FALSE(DefaultValue::Exists()); DefaultValue::Set(1); DefaultValue::Set( MyNonDefaultConstructible(42)); EXPECT_EQ(1, DefaultValue::Get()); EXPECT_EQ(42, DefaultValue::Get().value()); EXPECT_TRUE(DefaultValue::Exists()); EXPECT_TRUE(DefaultValue::Exists()); DefaultValue::Clear(); DefaultValue::Clear(); EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_TRUE(DefaultValue::Exists()); EXPECT_FALSE(DefaultValue::Exists()); } // Tests that DefaultValue::Get() returns the // BuiltInDefaultValue::Get() when DefaultValue::IsSet() is // false. TEST(DefaultValueDeathTest, GetReturnsBuiltInDefaultValueWhenUnset) { EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_TRUE(DefaultValue::Exists()); EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_FALSE(DefaultValue::Exists()); EXPECT_EQ(0, DefaultValue::Get()); EXPECT_DEATH_IF_SUPPORTED({ DefaultValue::Get(); }, ""); } TEST(DefaultValueTest, GetWorksForMoveOnlyIfSet) { EXPECT_TRUE(DefaultValue>::Exists()); EXPECT_TRUE(DefaultValue>::Get() == nullptr); DefaultValue>::SetFactory( [] { return std::unique_ptr(new int(42)); }); EXPECT_TRUE(DefaultValue>::Exists()); std::unique_ptr i = DefaultValue>::Get(); EXPECT_EQ(42, *i); } // Tests that DefaultValue::Get() returns void. TEST(DefaultValueTest, GetWorksForVoid) { return DefaultValue::Get(); } // Tests using DefaultValue with a reference type. // Tests that DefaultValue::IsSet() is false initially. TEST(DefaultValueOfReferenceTest, IsInitiallyUnset) { EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_FALSE(DefaultValue::IsSet()); } // Tests that DefaultValue::Exists is false initiallly. TEST(DefaultValueOfReferenceTest, IsInitiallyNotExisting) { EXPECT_FALSE(DefaultValue::Exists()); EXPECT_FALSE(DefaultValue::Exists()); EXPECT_FALSE(DefaultValue::Exists()); } // Tests that DefaultValue can be set and then unset. TEST(DefaultValueOfReferenceTest, CanBeSetAndUnset) { int n = 1; DefaultValue::Set(n); MyNonDefaultConstructible x(42); DefaultValue::Set(x); EXPECT_TRUE(DefaultValue::Exists()); EXPECT_TRUE(DefaultValue::Exists()); EXPECT_EQ(&n, &(DefaultValue::Get())); EXPECT_EQ(&x, &(DefaultValue::Get())); DefaultValue::Clear(); DefaultValue::Clear(); EXPECT_FALSE(DefaultValue::Exists()); EXPECT_FALSE(DefaultValue::Exists()); EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_FALSE(DefaultValue::IsSet()); } // Tests that DefaultValue::Get() returns the // BuiltInDefaultValue::Get() when DefaultValue::IsSet() is // false. TEST(DefaultValueOfReferenceDeathTest, GetReturnsBuiltInDefaultValueWhenUnset) { EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_FALSE(DefaultValue::IsSet()); EXPECT_DEATH_IF_SUPPORTED({ DefaultValue::Get(); }, ""); EXPECT_DEATH_IF_SUPPORTED({ DefaultValue::Get(); }, ""); } // Tests that ActionInterface can be implemented by defining the // Perform method. typedef int MyGlobalFunction(bool, int); class MyActionImpl : public ActionInterface { public: int Perform(const std::tuple& args) override { return std::get<0>(args) ? std::get<1>(args) : 0; } }; TEST(ActionInterfaceTest, CanBeImplementedByDefiningPerform) { MyActionImpl my_action_impl; (void)my_action_impl; } TEST(ActionInterfaceTest, MakeAction) { Action action = MakeAction(new MyActionImpl); // When exercising the Perform() method of Action, we must pass // it a tuple whose size and type are compatible with F's argument // types. For example, if F is int(), then Perform() takes a // 0-tuple; if F is void(bool, int), then Perform() takes a // std::tuple, and so on. EXPECT_EQ(5, action.Perform(std::make_tuple(true, 5))); } // Tests that Action can be constructed from a pointer to // ActionInterface. TEST(ActionTest, CanBeConstructedFromActionInterface) { Action action(new MyActionImpl); } // Tests that Action delegates actual work to ActionInterface. TEST(ActionTest, DelegatesWorkToActionInterface) { const Action action(new MyActionImpl); EXPECT_EQ(5, action.Perform(std::make_tuple(true, 5))); EXPECT_EQ(0, action.Perform(std::make_tuple(false, 1))); } // Tests that Action can be copied. TEST(ActionTest, IsCopyable) { Action a1(new MyActionImpl); Action a2(a1); // Tests the copy constructor. // a1 should continue to work after being copied from. EXPECT_EQ(5, a1.Perform(std::make_tuple(true, 5))); EXPECT_EQ(0, a1.Perform(std::make_tuple(false, 1))); // a2 should work like the action it was copied from. EXPECT_EQ(5, a2.Perform(std::make_tuple(true, 5))); EXPECT_EQ(0, a2.Perform(std::make_tuple(false, 1))); a2 = a1; // Tests the assignment operator. // a1 should continue to work after being copied from. EXPECT_EQ(5, a1.Perform(std::make_tuple(true, 5))); EXPECT_EQ(0, a1.Perform(std::make_tuple(false, 1))); // a2 should work like the action it was copied from. EXPECT_EQ(5, a2.Perform(std::make_tuple(true, 5))); EXPECT_EQ(0, a2.Perform(std::make_tuple(false, 1))); } // Tests that an Action object can be converted to a // compatible Action object. class IsNotZero : public ActionInterface { // NOLINT public: bool Perform(const std::tuple& arg) override { return std::get<0>(arg) != 0; } }; TEST(ActionTest, CanBeConvertedToOtherActionType) { const Action a1(new IsNotZero); // NOLINT const Action a2 = Action(a1); // NOLINT EXPECT_EQ(1, a2.Perform(std::make_tuple('a'))); EXPECT_EQ(0, a2.Perform(std::make_tuple('\0'))); } // The following two classes are for testing MakePolymorphicAction(). // Implements a polymorphic action that returns the second of the // arguments it receives. class ReturnSecondArgumentAction { public: // We want to verify that MakePolymorphicAction() can work with a // polymorphic action whose Perform() method template is either // const or not. This lets us verify the non-const case. template Result Perform(const ArgumentTuple& args) { return std::get<1>(args); } }; // Implements a polymorphic action that can be used in a nullary // function to return 0. class ReturnZeroFromNullaryFunctionAction { public: // For testing that MakePolymorphicAction() works when the // implementation class' Perform() method template takes only one // template parameter. // // We want to verify that MakePolymorphicAction() can work with a // polymorphic action whose Perform() method template is either // const or not. This lets us verify the const case. template Result Perform(const std::tuple<>&) const { return 0; } }; // These functions verify that MakePolymorphicAction() returns a // PolymorphicAction where T is the argument's type. PolymorphicAction ReturnSecondArgument() { return MakePolymorphicAction(ReturnSecondArgumentAction()); } PolymorphicAction ReturnZeroFromNullaryFunction() { return MakePolymorphicAction(ReturnZeroFromNullaryFunctionAction()); } // Tests that MakePolymorphicAction() turns a polymorphic action // implementation class into a polymorphic action. TEST(MakePolymorphicActionTest, ConstructsActionFromImpl) { Action a1 = ReturnSecondArgument(); // NOLINT EXPECT_EQ(5, a1.Perform(std::make_tuple(false, 5, 2.0))); } // Tests that MakePolymorphicAction() works when the implementation // class' Perform() method template has only one template parameter. TEST(MakePolymorphicActionTest, WorksWhenPerformHasOneTemplateParameter) { Action a1 = ReturnZeroFromNullaryFunction(); EXPECT_EQ(0, a1.Perform(std::make_tuple())); Action a2 = ReturnZeroFromNullaryFunction(); EXPECT_TRUE(a2.Perform(std::make_tuple()) == nullptr); } // Tests that Return() works as an action for void-returning // functions. TEST(ReturnTest, WorksForVoid) { const Action ret = Return(); // NOLINT return ret.Perform(std::make_tuple(1)); } // Tests that Return(v) returns v. TEST(ReturnTest, ReturnsGivenValue) { Action ret = Return(1); // NOLINT EXPECT_EQ(1, ret.Perform(std::make_tuple())); ret = Return(-5); EXPECT_EQ(-5, ret.Perform(std::make_tuple())); } // Tests that Return("string literal") works. TEST(ReturnTest, AcceptsStringLiteral) { Action a1 = Return("Hello"); EXPECT_STREQ("Hello", a1.Perform(std::make_tuple())); Action a2 = Return("world"); EXPECT_EQ("world", a2.Perform(std::make_tuple())); } // Return(x) should work fine when the mock function's return type is a // reference-like wrapper for decltype(x), as when x is a std::string and the // mock function returns std::string_view. TEST(ReturnTest, SupportsReferenceLikeReturnType) { // A reference wrapper for std::vector, implicitly convertible from it. struct Result { const std::vector* v; Result(const std::vector& v) : v(&v) {} // NOLINT }; // Set up an action for a mock function that returns the reference wrapper // type, initializing it with an actual vector. // // The returned wrapper should be initialized with a copy of that vector // that's embedded within the action itself (which should stay alive as long // as the mock object is alive), rather than e.g. a reference to the temporary // we feed to Return. This should work fine both for WillOnce and // WillRepeatedly. MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(Return(std::vector{17, 19, 23})) .WillRepeatedly(Return(std::vector{29, 31, 37})); EXPECT_THAT(mock.AsStdFunction()(), Field(&Result::v, Pointee(ElementsAre(17, 19, 23)))); EXPECT_THAT(mock.AsStdFunction()(), Field(&Result::v, Pointee(ElementsAre(29, 31, 37)))); } TEST(ReturnTest, PrefersConversionOperator) { // Define types In and Out such that: // // * In is implicitly convertible to Out. // * Out also has an explicit constructor from In. // struct In; struct Out { int x; explicit Out(const int x) : x(x) {} explicit Out(const In&) : x(0) {} }; struct In { operator Out() const { return Out{19}; } // NOLINT }; // Assumption check: the C++ language rules are such that a function that // returns Out which uses In a return statement will use the implicit // conversion path rather than the explicit constructor. EXPECT_THAT([]() -> Out { return In(); }(), Field(&Out::x, 19)); // Return should work the same way: if the mock function's return type is Out // and we feed Return an In value, then the Out should be created through the // implicit conversion path rather than the explicit constructor. MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(Return(In())); EXPECT_THAT(mock.AsStdFunction()(), Field(&Out::x, 19)); } // It should be possible to use Return(R) with a mock function result type U // that is convertible from const R& but *not* R (such as // std::reference_wrapper). This should work for both WillOnce and // WillRepeatedly. TEST(ReturnTest, ConversionRequiresConstLvalueReference) { using R = int; using U = std::reference_wrapper; static_assert(std::is_convertible::value, ""); static_assert(!std::is_convertible::value, ""); MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(Return(17)).WillRepeatedly(Return(19)); EXPECT_EQ(17, mock.AsStdFunction()()); EXPECT_EQ(19, mock.AsStdFunction()()); } // Return(x) should not be usable with a mock function result type that's // implicitly convertible from decltype(x) but requires a non-const lvalue // reference to the input. It doesn't make sense for the conversion operator to // modify the input. TEST(ReturnTest, ConversionRequiresMutableLvalueReference) { // Set up a type that is implicitly convertible from std::string&, but not // std::string&& or `const std::string&`. // // Avoid asserting about conversion from std::string on MSVC, which seems to // implement std::is_convertible incorrectly in this case. struct S { S(std::string&) {} // NOLINT }; static_assert(std::is_convertible::value, ""); #ifndef _MSC_VER static_assert(!std::is_convertible::value, ""); #endif static_assert(!std::is_convertible::value, ""); // It shouldn't be possible to use the result of Return(std::string) in a // context where an S is needed. // // Here too we disable the assertion for MSVC, since its incorrect // implementation of is_convertible causes our SFINAE to be wrong. using RA = decltype(Return(std::string())); static_assert(!std::is_convertible>::value, ""); #ifndef _MSC_VER static_assert(!std::is_convertible>::value, ""); #endif } TEST(ReturnTest, MoveOnlyResultType) { // Return should support move-only result types when used with WillOnce. { MockFunction()> mock; EXPECT_CALL(mock, Call) // NOLINTNEXTLINE .WillOnce(Return(std::unique_ptr(new int(17)))); EXPECT_THAT(mock.AsStdFunction()(), Pointee(17)); } // The result of Return should not be convertible to Action (so it can't be // used with WillRepeatedly). static_assert(!std::is_convertible())), Action()>>::value, ""); } // Tests that Return(v) is covaraint. struct Base { bool operator==(const Base&) { return true; } }; struct Derived : public Base { bool operator==(const Derived&) { return true; } }; TEST(ReturnTest, IsCovariant) { Base base; Derived derived; Action ret = Return(&base); EXPECT_EQ(&base, ret.Perform(std::make_tuple())); ret = Return(&derived); EXPECT_EQ(&derived, ret.Perform(std::make_tuple())); } // Tests that the type of the value passed into Return is converted into T // when the action is cast to Action rather than when the action is // performed. See comments on testing::internal::ReturnAction in // gmock-actions.h for more information. class FromType { public: explicit FromType(bool* is_converted) : converted_(is_converted) {} bool* converted() const { return converted_; } private: bool* const converted_; }; class ToType { public: // Must allow implicit conversion due to use in ImplicitCast_. ToType(const FromType& x) { *x.converted() = true; } // NOLINT }; TEST(ReturnTest, ConvertsArgumentWhenConverted) { bool converted = false; FromType x(&converted); Action action(Return(x)); EXPECT_TRUE(converted) << "Return must convert its argument in its own " << "conversion operator."; converted = false; action.Perform(std::tuple<>()); EXPECT_FALSE(converted) << "Action must NOT convert its argument " << "when performed."; } // Tests that ReturnNull() returns NULL in a pointer-returning function. TEST(ReturnNullTest, WorksInPointerReturningFunction) { const Action a1 = ReturnNull(); EXPECT_TRUE(a1.Perform(std::make_tuple()) == nullptr); const Action a2 = ReturnNull(); // NOLINT EXPECT_TRUE(a2.Perform(std::make_tuple(true)) == nullptr); } // Tests that ReturnNull() returns NULL for shared_ptr and unique_ptr returning // functions. TEST(ReturnNullTest, WorksInSmartPointerReturningFunction) { const Action()> a1 = ReturnNull(); EXPECT_TRUE(a1.Perform(std::make_tuple()) == nullptr); const Action(std::string)> a2 = ReturnNull(); EXPECT_TRUE(a2.Perform(std::make_tuple("foo")) == nullptr); } // Tests that ReturnRef(v) works for reference types. TEST(ReturnRefTest, WorksForReference) { const int n = 0; const Action ret = ReturnRef(n); // NOLINT EXPECT_EQ(&n, &ret.Perform(std::make_tuple(true))); } // Tests that ReturnRef(v) is covariant. TEST(ReturnRefTest, IsCovariant) { Base base; Derived derived; Action a = ReturnRef(base); EXPECT_EQ(&base, &a.Perform(std::make_tuple())); a = ReturnRef(derived); EXPECT_EQ(&derived, &a.Perform(std::make_tuple())); } template ()))> bool CanCallReturnRef(T&&) { return true; } bool CanCallReturnRef(Unused) { return false; } // Tests that ReturnRef(v) is working with non-temporaries (T&) TEST(ReturnRefTest, WorksForNonTemporary) { int scalar_value = 123; EXPECT_TRUE(CanCallReturnRef(scalar_value)); std::string non_scalar_value("ABC"); EXPECT_TRUE(CanCallReturnRef(non_scalar_value)); const int const_scalar_value{321}; EXPECT_TRUE(CanCallReturnRef(const_scalar_value)); const std::string const_non_scalar_value("CBA"); EXPECT_TRUE(CanCallReturnRef(const_non_scalar_value)); } // Tests that ReturnRef(v) is not working with temporaries (T&&) TEST(ReturnRefTest, DoesNotWorkForTemporary) { auto scalar_value = []() -> int { return 123; }; EXPECT_FALSE(CanCallReturnRef(scalar_value())); auto non_scalar_value = []() -> std::string { return "ABC"; }; EXPECT_FALSE(CanCallReturnRef(non_scalar_value())); // cannot use here callable returning "const scalar type", // because such const for scalar return type is ignored EXPECT_FALSE(CanCallReturnRef(static_cast(321))); auto const_non_scalar_value = []() -> const std::string { return "CBA"; }; EXPECT_FALSE(CanCallReturnRef(const_non_scalar_value())); } // Tests that ReturnRefOfCopy(v) works for reference types. TEST(ReturnRefOfCopyTest, WorksForReference) { int n = 42; const Action ret = ReturnRefOfCopy(n); EXPECT_NE(&n, &ret.Perform(std::make_tuple())); EXPECT_EQ(42, ret.Perform(std::make_tuple())); n = 43; EXPECT_NE(&n, &ret.Perform(std::make_tuple())); EXPECT_EQ(42, ret.Perform(std::make_tuple())); } // Tests that ReturnRefOfCopy(v) is covariant. TEST(ReturnRefOfCopyTest, IsCovariant) { Base base; Derived derived; Action a = ReturnRefOfCopy(base); EXPECT_NE(&base, &a.Perform(std::make_tuple())); a = ReturnRefOfCopy(derived); EXPECT_NE(&derived, &a.Perform(std::make_tuple())); } // Tests that ReturnRoundRobin(v) works with initializer lists TEST(ReturnRoundRobinTest, WorksForInitList) { Action ret = ReturnRoundRobin({1, 2, 3}); EXPECT_EQ(1, ret.Perform(std::make_tuple())); EXPECT_EQ(2, ret.Perform(std::make_tuple())); EXPECT_EQ(3, ret.Perform(std::make_tuple())); EXPECT_EQ(1, ret.Perform(std::make_tuple())); EXPECT_EQ(2, ret.Perform(std::make_tuple())); EXPECT_EQ(3, ret.Perform(std::make_tuple())); } // Tests that ReturnRoundRobin(v) works with vectors TEST(ReturnRoundRobinTest, WorksForVector) { std::vector v = {4.4, 5.5, 6.6}; Action ret = ReturnRoundRobin(v); EXPECT_EQ(4.4, ret.Perform(std::make_tuple())); EXPECT_EQ(5.5, ret.Perform(std::make_tuple())); EXPECT_EQ(6.6, ret.Perform(std::make_tuple())); EXPECT_EQ(4.4, ret.Perform(std::make_tuple())); EXPECT_EQ(5.5, ret.Perform(std::make_tuple())); EXPECT_EQ(6.6, ret.Perform(std::make_tuple())); } // Tests that DoDefault() does the default action for the mock method. class MockClass { public: MockClass() {} MOCK_METHOD1(IntFunc, int(bool flag)); // NOLINT MOCK_METHOD0(Foo, MyNonDefaultConstructible()); MOCK_METHOD0(MakeUnique, std::unique_ptr()); MOCK_METHOD0(MakeUniqueBase, std::unique_ptr()); MOCK_METHOD0(MakeVectorUnique, std::vector>()); MOCK_METHOD1(TakeUnique, int(std::unique_ptr)); MOCK_METHOD2(TakeUnique, int(const std::unique_ptr&, std::unique_ptr)); private: MockClass(const MockClass&) = delete; MockClass& operator=(const MockClass&) = delete; }; // Tests that DoDefault() returns the built-in default value for the // return type by default. TEST(DoDefaultTest, ReturnsBuiltInDefaultValueByDefault) { MockClass mock; EXPECT_CALL(mock, IntFunc(_)).WillOnce(DoDefault()); EXPECT_EQ(0, mock.IntFunc(true)); } // Tests that DoDefault() throws (when exceptions are enabled) or aborts // the process when there is no built-in default value for the return type. TEST(DoDefaultDeathTest, DiesForUnknowType) { MockClass mock; EXPECT_CALL(mock, Foo()).WillRepeatedly(DoDefault()); #if GTEST_HAS_EXCEPTIONS EXPECT_ANY_THROW(mock.Foo()); #else EXPECT_DEATH_IF_SUPPORTED({ mock.Foo(); }, ""); #endif } // Tests that using DoDefault() inside a composite action leads to a // run-time error. void VoidFunc(bool /* flag */) {} TEST(DoDefaultDeathTest, DiesIfUsedInCompositeAction) { MockClass mock; EXPECT_CALL(mock, IntFunc(_)) .WillRepeatedly(DoAll(Invoke(VoidFunc), DoDefault())); // Ideally we should verify the error message as well. Sadly, // EXPECT_DEATH() can only capture stderr, while Google Mock's // errors are printed on stdout. Therefore we have to settle for // not verifying the message. EXPECT_DEATH_IF_SUPPORTED({ mock.IntFunc(true); }, ""); } // Tests that DoDefault() returns the default value set by // DefaultValue::Set() when it's not overridden by an ON_CALL(). TEST(DoDefaultTest, ReturnsUserSpecifiedPerTypeDefaultValueWhenThereIsOne) { DefaultValue::Set(1); MockClass mock; EXPECT_CALL(mock, IntFunc(_)).WillOnce(DoDefault()); EXPECT_EQ(1, mock.IntFunc(false)); DefaultValue::Clear(); } // Tests that DoDefault() does the action specified by ON_CALL(). TEST(DoDefaultTest, DoesWhatOnCallSpecifies) { MockClass mock; ON_CALL(mock, IntFunc(_)).WillByDefault(Return(2)); EXPECT_CALL(mock, IntFunc(_)).WillOnce(DoDefault()); EXPECT_EQ(2, mock.IntFunc(false)); } // Tests that using DoDefault() in ON_CALL() leads to a run-time failure. TEST(DoDefaultTest, CannotBeUsedInOnCall) { MockClass mock; EXPECT_NONFATAL_FAILURE( { // NOLINT ON_CALL(mock, IntFunc(_)).WillByDefault(DoDefault()); }, "DoDefault() cannot be used in ON_CALL()"); } // Tests that SetArgPointee(v) sets the variable pointed to by // the N-th (0-based) argument to v. TEST(SetArgPointeeTest, SetsTheNthPointee) { typedef void MyFunction(bool, int*, char*); Action a = SetArgPointee<1>(2); int n = 0; char ch = '\0'; a.Perform(std::make_tuple(true, &n, &ch)); EXPECT_EQ(2, n); EXPECT_EQ('\0', ch); a = SetArgPointee<2>('a'); n = 0; ch = '\0'; a.Perform(std::make_tuple(true, &n, &ch)); EXPECT_EQ(0, n); EXPECT_EQ('a', ch); } // Tests that SetArgPointee() accepts a string literal. TEST(SetArgPointeeTest, AcceptsStringLiteral) { typedef void MyFunction(std::string*, const char**); Action a = SetArgPointee<0>("hi"); std::string str; const char* ptr = nullptr; a.Perform(std::make_tuple(&str, &ptr)); EXPECT_EQ("hi", str); EXPECT_TRUE(ptr == nullptr); a = SetArgPointee<1>("world"); str = ""; a.Perform(std::make_tuple(&str, &ptr)); EXPECT_EQ("", str); EXPECT_STREQ("world", ptr); } TEST(SetArgPointeeTest, AcceptsWideStringLiteral) { typedef void MyFunction(const wchar_t**); Action a = SetArgPointee<0>(L"world"); const wchar_t* ptr = nullptr; a.Perform(std::make_tuple(&ptr)); EXPECT_STREQ(L"world", ptr); #if GTEST_HAS_STD_WSTRING typedef void MyStringFunction(std::wstring*); Action a2 = SetArgPointee<0>(L"world"); std::wstring str = L""; a2.Perform(std::make_tuple(&str)); EXPECT_EQ(L"world", str); #endif } // Tests that SetArgPointee() accepts a char pointer. TEST(SetArgPointeeTest, AcceptsCharPointer) { typedef void MyFunction(bool, std::string*, const char**); const char* const hi = "hi"; Action a = SetArgPointee<1>(hi); std::string str; const char* ptr = nullptr; a.Perform(std::make_tuple(true, &str, &ptr)); EXPECT_EQ("hi", str); EXPECT_TRUE(ptr == nullptr); char world_array[] = "world"; char* const world = world_array; a = SetArgPointee<2>(world); str = ""; a.Perform(std::make_tuple(true, &str, &ptr)); EXPECT_EQ("", str); EXPECT_EQ(world, ptr); } TEST(SetArgPointeeTest, AcceptsWideCharPointer) { typedef void MyFunction(bool, const wchar_t**); const wchar_t* const hi = L"hi"; Action a = SetArgPointee<1>(hi); const wchar_t* ptr = nullptr; a.Perform(std::make_tuple(true, &ptr)); EXPECT_EQ(hi, ptr); #if GTEST_HAS_STD_WSTRING typedef void MyStringFunction(bool, std::wstring*); wchar_t world_array[] = L"world"; wchar_t* const world = world_array; Action a2 = SetArgPointee<1>(world); std::wstring str; a2.Perform(std::make_tuple(true, &str)); EXPECT_EQ(world_array, str); #endif } // Tests that SetArgumentPointee(v) sets the variable pointed to by // the N-th (0-based) argument to v. TEST(SetArgumentPointeeTest, SetsTheNthPointee) { typedef void MyFunction(bool, int*, char*); Action a = SetArgumentPointee<1>(2); int n = 0; char ch = '\0'; a.Perform(std::make_tuple(true, &n, &ch)); EXPECT_EQ(2, n); EXPECT_EQ('\0', ch); a = SetArgumentPointee<2>('a'); n = 0; ch = '\0'; a.Perform(std::make_tuple(true, &n, &ch)); EXPECT_EQ(0, n); EXPECT_EQ('a', ch); } // Sample functions and functors for testing Invoke() and etc. int Nullary() { return 1; } class NullaryFunctor { public: int operator()() { return 2; } }; bool g_done = false; void VoidNullary() { g_done = true; } class VoidNullaryFunctor { public: void operator()() { g_done = true; } }; short Short(short n) { return n; } // NOLINT char Char(char ch) { return ch; } const char* CharPtr(const char* s) { return s; } bool Unary(int x) { return x < 0; } const char* Binary(const char* input, short n) { return input + n; } // NOLINT void VoidBinary(int, char) { g_done = true; } int Ternary(int x, char y, short z) { return x + y + z; } // NOLINT int SumOf4(int a, int b, int c, int d) { return a + b + c + d; } class Foo { public: Foo() : value_(123) {} int Nullary() const { return value_; } private: int value_; }; // Tests InvokeWithoutArgs(function). TEST(InvokeWithoutArgsTest, Function) { // As an action that takes one argument. Action a = InvokeWithoutArgs(Nullary); // NOLINT EXPECT_EQ(1, a.Perform(std::make_tuple(2))); // As an action that takes two arguments. Action a2 = InvokeWithoutArgs(Nullary); // NOLINT EXPECT_EQ(1, a2.Perform(std::make_tuple(2, 3.5))); // As an action that returns void. Action a3 = InvokeWithoutArgs(VoidNullary); // NOLINT g_done = false; a3.Perform(std::make_tuple(1)); EXPECT_TRUE(g_done); } // Tests InvokeWithoutArgs(functor). TEST(InvokeWithoutArgsTest, Functor) { // As an action that takes no argument. Action a = InvokeWithoutArgs(NullaryFunctor()); // NOLINT EXPECT_EQ(2, a.Perform(std::make_tuple())); // As an action that takes three arguments. Action a2 = // NOLINT InvokeWithoutArgs(NullaryFunctor()); EXPECT_EQ(2, a2.Perform(std::make_tuple(3, 3.5, 'a'))); // As an action that returns void. Action a3 = InvokeWithoutArgs(VoidNullaryFunctor()); g_done = false; a3.Perform(std::make_tuple()); EXPECT_TRUE(g_done); } // Tests InvokeWithoutArgs(obj_ptr, method). TEST(InvokeWithoutArgsTest, Method) { Foo foo; Action a = // NOLINT InvokeWithoutArgs(&foo, &Foo::Nullary); EXPECT_EQ(123, a.Perform(std::make_tuple(true, 'a'))); } // Tests using IgnoreResult() on a polymorphic action. TEST(IgnoreResultTest, PolymorphicAction) { Action a = IgnoreResult(Return(5)); // NOLINT a.Perform(std::make_tuple(1)); } // Tests using IgnoreResult() on a monomorphic action. int ReturnOne() { g_done = true; return 1; } TEST(IgnoreResultTest, MonomorphicAction) { g_done = false; Action a = IgnoreResult(Invoke(ReturnOne)); a.Perform(std::make_tuple()); EXPECT_TRUE(g_done); } // Tests using IgnoreResult() on an action that returns a class type. MyNonDefaultConstructible ReturnMyNonDefaultConstructible(double /* x */) { g_done = true; return MyNonDefaultConstructible(42); } TEST(IgnoreResultTest, ActionReturningClass) { g_done = false; Action a = IgnoreResult(Invoke(ReturnMyNonDefaultConstructible)); // NOLINT a.Perform(std::make_tuple(2)); EXPECT_TRUE(g_done); } TEST(AssignTest, Int) { int x = 0; Action a = Assign(&x, 5); a.Perform(std::make_tuple(0)); EXPECT_EQ(5, x); } TEST(AssignTest, String) { ::std::string x; Action a = Assign(&x, "Hello, world"); a.Perform(std::make_tuple()); EXPECT_EQ("Hello, world", x); } TEST(AssignTest, CompatibleTypes) { double x = 0; Action a = Assign(&x, 5); a.Perform(std::make_tuple(0)); EXPECT_DOUBLE_EQ(5, x); } // DoAll should support &&-qualified actions when used with WillOnce. TEST(DoAll, SupportsRefQualifiedActions) { struct InitialAction { void operator()(const int arg) && { EXPECT_EQ(17, arg); } }; struct FinalAction { int operator()() && { return 19; } }; MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(DoAll(InitialAction{}, FinalAction{})); EXPECT_EQ(19, mock.AsStdFunction()(17)); } // DoAll should never provide rvalue references to the initial actions. If the // mock action itself accepts an rvalue reference or a non-scalar object by // value then the final action should receive an rvalue reference, but initial // actions should receive only lvalue references. TEST(DoAll, ProvidesLvalueReferencesToInitialActions) { struct Obj {}; // Mock action accepts by value: the initial action should be fed a const // lvalue reference, and the final action an rvalue reference. { struct InitialAction { void operator()(Obj&) const { FAIL() << "Unexpected call"; } void operator()(const Obj&) const {} void operator()(Obj&&) const { FAIL() << "Unexpected call"; } void operator()(const Obj&&) const { FAIL() << "Unexpected call"; } }; MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(DoAll(InitialAction{}, InitialAction{}, [](Obj&&) {})) .WillRepeatedly(DoAll(InitialAction{}, InitialAction{}, [](Obj&&) {})); mock.AsStdFunction()(Obj{}); mock.AsStdFunction()(Obj{}); } // Mock action accepts by const lvalue reference: both actions should receive // a const lvalue reference. { struct InitialAction { void operator()(Obj&) const { FAIL() << "Unexpected call"; } void operator()(const Obj&) const {} void operator()(Obj&&) const { FAIL() << "Unexpected call"; } void operator()(const Obj&&) const { FAIL() << "Unexpected call"; } }; MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(DoAll(InitialAction{}, InitialAction{}, [](const Obj&) {})) .WillRepeatedly( DoAll(InitialAction{}, InitialAction{}, [](const Obj&) {})); mock.AsStdFunction()(Obj{}); mock.AsStdFunction()(Obj{}); } // Mock action accepts by non-const lvalue reference: both actions should get // a non-const lvalue reference if they want them. { struct InitialAction { void operator()(Obj&) const {} void operator()(Obj&&) const { FAIL() << "Unexpected call"; } }; MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(DoAll(InitialAction{}, InitialAction{}, [](Obj&) {})) .WillRepeatedly(DoAll(InitialAction{}, InitialAction{}, [](Obj&) {})); Obj obj; mock.AsStdFunction()(obj); mock.AsStdFunction()(obj); } // Mock action accepts by rvalue reference: the initial actions should receive // a non-const lvalue reference if it wants it, and the final action an rvalue // reference. { struct InitialAction { void operator()(Obj&) const {} void operator()(Obj&&) const { FAIL() << "Unexpected call"; } }; MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(DoAll(InitialAction{}, InitialAction{}, [](Obj&&) {})) .WillRepeatedly(DoAll(InitialAction{}, InitialAction{}, [](Obj&&) {})); mock.AsStdFunction()(Obj{}); mock.AsStdFunction()(Obj{}); } // &&-qualified initial actions should also be allowed with WillOnce. { struct InitialAction { void operator()(Obj&) && {} }; MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(DoAll(InitialAction{}, InitialAction{}, [](Obj&) {})); Obj obj; mock.AsStdFunction()(obj); } { struct InitialAction { void operator()(Obj&) && {} }; MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(DoAll(InitialAction{}, InitialAction{}, [](Obj&&) {})); mock.AsStdFunction()(Obj{}); } } // DoAll should support being used with type-erased Action objects, both through // WillOnce and WillRepeatedly. TEST(DoAll, SupportsTypeErasedActions) { // With only type-erased actions. const Action initial_action = [] {}; const Action final_action = [] { return 17; }; MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(DoAll(initial_action, initial_action, final_action)) .WillRepeatedly(DoAll(initial_action, initial_action, final_action)); EXPECT_EQ(17, mock.AsStdFunction()()); // With &&-qualified and move-only final action. { struct FinalAction { FinalAction() = default; FinalAction(FinalAction&&) = default; int operator()() && { return 17; } }; EXPECT_CALL(mock, Call) .WillOnce(DoAll(initial_action, initial_action, FinalAction{})); EXPECT_EQ(17, mock.AsStdFunction()()); } } // Tests using WithArgs and with an action that takes 1 argument. TEST(WithArgsTest, OneArg) { Action a = WithArgs<1>(Invoke(Unary)); // NOLINT EXPECT_TRUE(a.Perform(std::make_tuple(1.5, -1))); EXPECT_FALSE(a.Perform(std::make_tuple(1.5, 1))); } // Tests using WithArgs with an action that takes 2 arguments. TEST(WithArgsTest, TwoArgs) { Action a = // NOLINT WithArgs<0, 2>(Invoke(Binary)); const char s[] = "Hello"; EXPECT_EQ(s + 2, a.Perform(std::make_tuple(CharPtr(s), 0.5, Short(2)))); } struct ConcatAll { std::string operator()() const { return {}; } template std::string operator()(const char* a, I... i) const { return a + ConcatAll()(i...); } }; // Tests using WithArgs with an action that takes 10 arguments. TEST(WithArgsTest, TenArgs) { Action a = WithArgs<0, 1, 2, 3, 2, 1, 0, 1, 2, 3>(Invoke(ConcatAll{})); EXPECT_EQ("0123210123", a.Perform(std::make_tuple(CharPtr("0"), CharPtr("1"), CharPtr("2"), CharPtr("3")))); } // Tests using WithArgs with an action that is not Invoke(). class SubtractAction : public ActionInterface { public: int Perform(const std::tuple& args) override { return std::get<0>(args) - std::get<1>(args); } }; TEST(WithArgsTest, NonInvokeAction) { Action a = WithArgs<2, 1>(MakeAction(new SubtractAction)); std::tuple dummy = std::make_tuple(std::string("hi"), 2, 10); EXPECT_EQ(8, a.Perform(dummy)); } // Tests using WithArgs to pass all original arguments in the original order. TEST(WithArgsTest, Identity) { Action a = // NOLINT WithArgs<0, 1, 2>(Invoke(Ternary)); EXPECT_EQ(123, a.Perform(std::make_tuple(100, Char(20), Short(3)))); } // Tests using WithArgs with repeated arguments. TEST(WithArgsTest, RepeatedArguments) { Action a = // NOLINT WithArgs<1, 1, 1, 1>(Invoke(SumOf4)); EXPECT_EQ(4, a.Perform(std::make_tuple(false, 1, 10))); } // Tests using WithArgs with reversed argument order. TEST(WithArgsTest, ReversedArgumentOrder) { Action a = // NOLINT WithArgs<1, 0>(Invoke(Binary)); const char s[] = "Hello"; EXPECT_EQ(s + 2, a.Perform(std::make_tuple(Short(2), CharPtr(s)))); } // Tests using WithArgs with compatible, but not identical, argument types. TEST(WithArgsTest, ArgsOfCompatibleTypes) { Action a = // NOLINT WithArgs<0, 1, 3>(Invoke(Ternary)); EXPECT_EQ(123, a.Perform(std::make_tuple(Short(100), Char(20), 5.6, Char(3)))); } // Tests using WithArgs with an action that returns void. TEST(WithArgsTest, VoidAction) { Action a = WithArgs<2, 1>(Invoke(VoidBinary)); g_done = false; a.Perform(std::make_tuple(1.5, 'a', 3)); EXPECT_TRUE(g_done); } TEST(WithArgsTest, ReturnReference) { Action aa = WithArgs<0>([](int& a) -> int& { return a; }); int i = 0; const int& res = aa.Perform(std::forward_as_tuple(i, nullptr)); EXPECT_EQ(&i, &res); } TEST(WithArgsTest, InnerActionWithConversion) { Action inner = [] { return nullptr; }; MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(WithoutArgs(inner)) .WillRepeatedly(WithoutArgs(inner)); EXPECT_EQ(nullptr, mock.AsStdFunction()(1.1)); EXPECT_EQ(nullptr, mock.AsStdFunction()(1.1)); } // It should be possible to use an &&-qualified inner action as long as the // whole shebang is used as an rvalue with WillOnce. TEST(WithArgsTest, RefQualifiedInnerAction) { struct SomeAction { int operator()(const int arg) && { EXPECT_EQ(17, arg); return 19; } }; MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(WithArg<1>(SomeAction{})); EXPECT_EQ(19, mock.AsStdFunction()(0, 17)); } #if !GTEST_OS_WINDOWS_MOBILE class SetErrnoAndReturnTest : public testing::Test { protected: void SetUp() override { errno = 0; } void TearDown() override { errno = 0; } }; TEST_F(SetErrnoAndReturnTest, Int) { Action a = SetErrnoAndReturn(ENOTTY, -5); EXPECT_EQ(-5, a.Perform(std::make_tuple())); EXPECT_EQ(ENOTTY, errno); } TEST_F(SetErrnoAndReturnTest, Ptr) { int x; Action a = SetErrnoAndReturn(ENOTTY, &x); EXPECT_EQ(&x, a.Perform(std::make_tuple())); EXPECT_EQ(ENOTTY, errno); } TEST_F(SetErrnoAndReturnTest, CompatibleTypes) { Action a = SetErrnoAndReturn(EINVAL, 5); EXPECT_DOUBLE_EQ(5.0, a.Perform(std::make_tuple())); EXPECT_EQ(EINVAL, errno); } #endif // !GTEST_OS_WINDOWS_MOBILE // Tests ByRef(). // Tests that the result of ByRef() is copyable. TEST(ByRefTest, IsCopyable) { const std::string s1 = "Hi"; const std::string s2 = "Hello"; auto ref_wrapper = ByRef(s1); const std::string& r1 = ref_wrapper; EXPECT_EQ(&s1, &r1); // Assigns a new value to ref_wrapper. ref_wrapper = ByRef(s2); const std::string& r2 = ref_wrapper; EXPECT_EQ(&s2, &r2); auto ref_wrapper1 = ByRef(s1); // Copies ref_wrapper1 to ref_wrapper. ref_wrapper = ref_wrapper1; const std::string& r3 = ref_wrapper; EXPECT_EQ(&s1, &r3); } // Tests using ByRef() on a const value. TEST(ByRefTest, ConstValue) { const int n = 0; // int& ref = ByRef(n); // This shouldn't compile - we have a // negative compilation test to catch it. const int& const_ref = ByRef(n); EXPECT_EQ(&n, &const_ref); } // Tests using ByRef() on a non-const value. TEST(ByRefTest, NonConstValue) { int n = 0; // ByRef(n) can be used as either an int&, int& ref = ByRef(n); EXPECT_EQ(&n, &ref); // or a const int&. const int& const_ref = ByRef(n); EXPECT_EQ(&n, &const_ref); } // Tests explicitly specifying the type when using ByRef(). TEST(ByRefTest, ExplicitType) { int n = 0; const int& r1 = ByRef(n); EXPECT_EQ(&n, &r1); // ByRef(n); // This shouldn't compile - we have a negative // compilation test to catch it. Derived d; Derived& r2 = ByRef(d); EXPECT_EQ(&d, &r2); const Derived& r3 = ByRef(d); EXPECT_EQ(&d, &r3); Base& r4 = ByRef(d); EXPECT_EQ(&d, &r4); const Base& r5 = ByRef(d); EXPECT_EQ(&d, &r5); // The following shouldn't compile - we have a negative compilation // test for it. // // Base b; // ByRef(b); } // Tests that Google Mock prints expression ByRef(x) as a reference to x. TEST(ByRefTest, PrintsCorrectly) { int n = 42; ::std::stringstream expected, actual; testing::internal::UniversalPrinter::Print(n, &expected); testing::internal::UniversalPrint(ByRef(n), &actual); EXPECT_EQ(expected.str(), actual.str()); } struct UnaryConstructorClass { explicit UnaryConstructorClass(int v) : value(v) {} int value; }; // Tests using ReturnNew() with a unary constructor. TEST(ReturnNewTest, Unary) { Action a = ReturnNew(4000); UnaryConstructorClass* c = a.Perform(std::make_tuple()); EXPECT_EQ(4000, c->value); delete c; } TEST(ReturnNewTest, UnaryWorksWhenMockMethodHasArgs) { Action a = ReturnNew(4000); UnaryConstructorClass* c = a.Perform(std::make_tuple(false, 5)); EXPECT_EQ(4000, c->value); delete c; } TEST(ReturnNewTest, UnaryWorksWhenMockMethodReturnsPointerToConst) { Action a = ReturnNew(4000); const UnaryConstructorClass* c = a.Perform(std::make_tuple()); EXPECT_EQ(4000, c->value); delete c; } class TenArgConstructorClass { public: TenArgConstructorClass(int a1, int a2, int a3, int a4, int a5, int a6, int a7, int a8, int a9, int a10) : value_(a1 + a2 + a3 + a4 + a5 + a6 + a7 + a8 + a9 + a10) {} int value_; }; // Tests using ReturnNew() with a 10-argument constructor. TEST(ReturnNewTest, ConstructorThatTakes10Arguments) { Action a = ReturnNew( 1000000000, 200000000, 30000000, 4000000, 500000, 60000, 7000, 800, 90, 0); TenArgConstructorClass* c = a.Perform(std::make_tuple()); EXPECT_EQ(1234567890, c->value_); delete c; } std::unique_ptr UniquePtrSource() { return std::unique_ptr(new int(19)); } std::vector> VectorUniquePtrSource() { std::vector> out; out.emplace_back(new int(7)); return out; } TEST(MockMethodTest, CanReturnMoveOnlyValue_Return) { MockClass mock; std::unique_ptr i(new int(19)); EXPECT_CALL(mock, MakeUnique()).WillOnce(Return(ByMove(std::move(i)))); EXPECT_CALL(mock, MakeVectorUnique()) .WillOnce(Return(ByMove(VectorUniquePtrSource()))); Derived* d = new Derived; EXPECT_CALL(mock, MakeUniqueBase()) .WillOnce(Return(ByMove(std::unique_ptr(d)))); std::unique_ptr result1 = mock.MakeUnique(); EXPECT_EQ(19, *result1); std::vector> vresult = mock.MakeVectorUnique(); EXPECT_EQ(1u, vresult.size()); EXPECT_NE(nullptr, vresult[0]); EXPECT_EQ(7, *vresult[0]); std::unique_ptr result2 = mock.MakeUniqueBase(); EXPECT_EQ(d, result2.get()); } TEST(MockMethodTest, CanReturnMoveOnlyValue_DoAllReturn) { testing::MockFunction mock_function; MockClass mock; std::unique_ptr i(new int(19)); EXPECT_CALL(mock_function, Call()); EXPECT_CALL(mock, MakeUnique()) .WillOnce(DoAll(InvokeWithoutArgs(&mock_function, &testing::MockFunction::Call), Return(ByMove(std::move(i))))); std::unique_ptr result1 = mock.MakeUnique(); EXPECT_EQ(19, *result1); } TEST(MockMethodTest, CanReturnMoveOnlyValue_Invoke) { MockClass mock; // Check default value DefaultValue>::SetFactory( [] { return std::unique_ptr(new int(42)); }); EXPECT_EQ(42, *mock.MakeUnique()); EXPECT_CALL(mock, MakeUnique()).WillRepeatedly(Invoke(UniquePtrSource)); EXPECT_CALL(mock, MakeVectorUnique()) .WillRepeatedly(Invoke(VectorUniquePtrSource)); std::unique_ptr result1 = mock.MakeUnique(); EXPECT_EQ(19, *result1); std::unique_ptr result2 = mock.MakeUnique(); EXPECT_EQ(19, *result2); EXPECT_NE(result1, result2); std::vector> vresult = mock.MakeVectorUnique(); EXPECT_EQ(1u, vresult.size()); EXPECT_NE(nullptr, vresult[0]); EXPECT_EQ(7, *vresult[0]); } TEST(MockMethodTest, CanTakeMoveOnlyValue) { MockClass mock; auto make = [](int i) { return std::unique_ptr(new int(i)); }; EXPECT_CALL(mock, TakeUnique(_)).WillRepeatedly([](std::unique_ptr i) { return *i; }); // DoAll() does not compile, since it would move from its arguments twice. // EXPECT_CALL(mock, TakeUnique(_, _)) // .WillRepeatedly(DoAll(Invoke([](std::unique_ptr j) {}), // Return(1))); EXPECT_CALL(mock, TakeUnique(testing::Pointee(7))) .WillOnce(Return(-7)) .RetiresOnSaturation(); EXPECT_CALL(mock, TakeUnique(testing::IsNull())) .WillOnce(Return(-1)) .RetiresOnSaturation(); EXPECT_EQ(5, mock.TakeUnique(make(5))); EXPECT_EQ(-7, mock.TakeUnique(make(7))); EXPECT_EQ(7, mock.TakeUnique(make(7))); EXPECT_EQ(7, mock.TakeUnique(make(7))); EXPECT_EQ(-1, mock.TakeUnique({})); // Some arguments are moved, some passed by reference. auto lvalue = make(6); EXPECT_CALL(mock, TakeUnique(_, _)) .WillOnce([](const std::unique_ptr& i, std::unique_ptr j) { return *i * *j; }); EXPECT_EQ(42, mock.TakeUnique(lvalue, make(7))); // The unique_ptr can be saved by the action. std::unique_ptr saved; EXPECT_CALL(mock, TakeUnique(_)).WillOnce([&saved](std::unique_ptr i) { saved = std::move(i); return 0; }); EXPECT_EQ(0, mock.TakeUnique(make(42))); EXPECT_EQ(42, *saved); } // It should be possible to use callables with an &&-qualified call operator // with WillOnce, since they will be called only once. This allows actions to // contain and manipulate move-only types. TEST(MockMethodTest, ActionHasRvalueRefQualifiedCallOperator) { struct Return17 { int operator()() && { return 17; } }; // Action is directly compatible with mocked function type. { MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(Return17()); EXPECT_EQ(17, mock.AsStdFunction()()); } // Action doesn't want mocked function arguments. { MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(Return17()); EXPECT_EQ(17, mock.AsStdFunction()(0)); } } // Edge case: if an action has both a const-qualified and an &&-qualified call // operator, there should be no "ambiguous call" errors. The &&-qualified // operator should be used by WillOnce (since it doesn't need to retain the // action beyond one call), and the const-qualified one by WillRepeatedly. TEST(MockMethodTest, ActionHasMultipleCallOperators) { struct ReturnInt { int operator()() && { return 17; } int operator()() const& { return 19; } }; // Directly compatible with mocked function type. { MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(ReturnInt()).WillRepeatedly(ReturnInt()); EXPECT_EQ(17, mock.AsStdFunction()()); EXPECT_EQ(19, mock.AsStdFunction()()); EXPECT_EQ(19, mock.AsStdFunction()()); } // Ignores function arguments. { MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(ReturnInt()).WillRepeatedly(ReturnInt()); EXPECT_EQ(17, mock.AsStdFunction()(0)); EXPECT_EQ(19, mock.AsStdFunction()(0)); EXPECT_EQ(19, mock.AsStdFunction()(0)); } } // WillOnce should have no problem coping with a move-only action, whether it is // &&-qualified or not. TEST(MockMethodTest, MoveOnlyAction) { // &&-qualified { struct Return17 { Return17() = default; Return17(Return17&&) = default; Return17(const Return17&) = delete; Return17 operator=(const Return17&) = delete; int operator()() && { return 17; } }; MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(Return17()); EXPECT_EQ(17, mock.AsStdFunction()()); } // Not &&-qualified { struct Return17 { Return17() = default; Return17(Return17&&) = default; Return17(const Return17&) = delete; Return17 operator=(const Return17&) = delete; int operator()() const { return 17; } }; MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(Return17()); EXPECT_EQ(17, mock.AsStdFunction()()); } } // It should be possible to use an action that returns a value with a mock // function that doesn't, both through WillOnce and WillRepeatedly. TEST(MockMethodTest, ActionReturnsIgnoredValue) { struct ReturnInt { int operator()() const { return 0; } }; MockFunction mock; EXPECT_CALL(mock, Call).WillOnce(ReturnInt()).WillRepeatedly(ReturnInt()); mock.AsStdFunction()(); mock.AsStdFunction()(); } // Despite the fanciness around move-only actions and so on, it should still be // possible to hand an lvalue reference to a copyable action to WillOnce. TEST(MockMethodTest, WillOnceCanAcceptLvalueReference) { MockFunction mock; const auto action = [] { return 17; }; EXPECT_CALL(mock, Call).WillOnce(action); EXPECT_EQ(17, mock.AsStdFunction()()); } // A callable that doesn't use SFINAE to restrict its call operator's overload // set, but is still picky about which arguments it will accept. struct StaticAssertSingleArgument { template static constexpr bool CheckArgs() { static_assert(sizeof...(Args) == 1, ""); return true; } template ()> int operator()(Args...) const { return 17; } }; // WillOnce and WillRepeatedly should both work fine with naïve implementations // of actions that don't use SFINAE to limit the overload set for their call // operator. If they are compatible with the actual mocked signature, we // shouldn't probe them with no arguments and trip a static_assert. TEST(MockMethodTest, ActionSwallowsAllArguments) { MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(StaticAssertSingleArgument{}) .WillRepeatedly(StaticAssertSingleArgument{}); EXPECT_EQ(17, mock.AsStdFunction()(0)); EXPECT_EQ(17, mock.AsStdFunction()(0)); } struct ActionWithTemplatedConversionOperators { template operator OnceAction() && { // NOLINT return [] { return 17; }; } template operator Action() const { // NOLINT return [] { return 19; }; } }; // It should be fine to hand both WillOnce and WillRepeatedly a function that // defines templated conversion operators to OnceAction and Action. WillOnce // should prefer the OnceAction version. TEST(MockMethodTest, ActionHasTemplatedConversionOperators) { MockFunction mock; EXPECT_CALL(mock, Call) .WillOnce(ActionWithTemplatedConversionOperators{}) .WillRepeatedly(ActionWithTemplatedConversionOperators{}); EXPECT_EQ(17, mock.AsStdFunction()()); EXPECT_EQ(19, mock.AsStdFunction()()); } // Tests for std::function based action. int Add(int val, int& ref, int* ptr) { // NOLINT int result = val + ref + *ptr; ref = 42; *ptr = 43; return result; } int Deref(std::unique_ptr ptr) { return *ptr; } struct Double { template T operator()(T t) { return 2 * t; } }; std::unique_ptr UniqueInt(int i) { return std::unique_ptr(new int(i)); } TEST(FunctorActionTest, ActionFromFunction) { Action a = &Add; int x = 1, y = 2, z = 3; EXPECT_EQ(6, a.Perform(std::forward_as_tuple(x, y, &z))); EXPECT_EQ(42, y); EXPECT_EQ(43, z); Action)> a1 = &Deref; EXPECT_EQ(7, a1.Perform(std::make_tuple(UniqueInt(7)))); } TEST(FunctorActionTest, ActionFromLambda) { Action a1 = [](bool b, int i) { return b ? i : 0; }; EXPECT_EQ(5, a1.Perform(std::make_tuple(true, 5))); EXPECT_EQ(0, a1.Perform(std::make_tuple(false, 5))); std::unique_ptr saved; Action)> a2 = [&saved](std::unique_ptr p) { saved = std::move(p); }; a2.Perform(std::make_tuple(UniqueInt(5))); EXPECT_EQ(5, *saved); } TEST(FunctorActionTest, PolymorphicFunctor) { Action ai = Double(); EXPECT_EQ(2, ai.Perform(std::make_tuple(1))); Action ad = Double(); // Double? Double double! EXPECT_EQ(3.0, ad.Perform(std::make_tuple(1.5))); } TEST(FunctorActionTest, TypeConversion) { // Numeric promotions are allowed. const Action a1 = [](int i) { return i > 1; }; const Action a2 = Action(a1); EXPECT_EQ(1, a1.Perform(std::make_tuple(42))); EXPECT_EQ(0, a2.Perform(std::make_tuple(42))); // Implicit constructors are allowed. const Action s1 = [](std::string s) { return !s.empty(); }; const Action s2 = Action(s1); EXPECT_EQ(0, s2.Perform(std::make_tuple(""))); EXPECT_EQ(1, s2.Perform(std::make_tuple("hello"))); // Also between the lambda and the action itself. const Action x1 = [](Unused) { return 42; }; const Action x2 = [] { return 42; }; EXPECT_TRUE(x1.Perform(std::make_tuple("hello"))); EXPECT_TRUE(x2.Perform(std::make_tuple("hello"))); // Ensure decay occurs where required. std::function f = [] { return 7; }; Action d = f; f = nullptr; EXPECT_EQ(7, d.Perform(std::make_tuple(1))); // Ensure creation of an empty action succeeds. Action(nullptr); } TEST(FunctorActionTest, UnusedArguments) { // Verify that users can ignore uninteresting arguments. Action a = [](int i, Unused, Unused) { return 2 * i; }; std::tuple dummy = std::make_tuple(3, 7.3, 9.44); EXPECT_EQ(6, a.Perform(dummy)); } // Test that basic built-in actions work with move-only arguments. TEST(MoveOnlyArgumentsTest, ReturningActions) { Action)> a = Return(1); EXPECT_EQ(1, a.Perform(std::make_tuple(nullptr))); a = testing::WithoutArgs([]() { return 7; }); EXPECT_EQ(7, a.Perform(std::make_tuple(nullptr))); Action, int*)> a2 = testing::SetArgPointee<1>(3); int x = 0; a2.Perform(std::make_tuple(nullptr, &x)); EXPECT_EQ(x, 3); } ACTION(ReturnArity) { return std::tuple_size::value; } TEST(ActionMacro, LargeArity) { EXPECT_EQ( 1, testing::Action(ReturnArity()).Perform(std::make_tuple(0))); EXPECT_EQ( 10, testing::Action( ReturnArity()) .Perform(std::make_tuple(0, 1, 2, 3, 4, 5, 6, 7, 8, 9))); EXPECT_EQ( 20, testing::Action( ReturnArity()) .Perform(std::make_tuple(0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19))); } } // namespace } // namespace testing