// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/bind.h" #include #include #include #include #include "base/callback.h" #include "base/macros.h" #include "base/memory/ref_counted.h" #include "base/memory/scoped_ptr.h" #include "base/memory/weak_ptr.h" #include "build/build_config.h" using ::testing::Mock; using ::testing::Return; using ::testing::StrictMock; namespace base { namespace { class IncompleteType; class NoRef { public: NoRef() {} MOCK_METHOD0(VoidMethod0, void()); MOCK_CONST_METHOD0(VoidConstMethod0, void()); MOCK_METHOD0(IntMethod0, int()); MOCK_CONST_METHOD0(IntConstMethod0, int()); private: // Particularly important in this test to ensure no copies are made. DISALLOW_COPY_AND_ASSIGN(NoRef); }; class HasRef : public NoRef { public: HasRef() {} MOCK_CONST_METHOD0(AddRef, void()); MOCK_CONST_METHOD0(Release, bool()); private: // Particularly important in this test to ensure no copies are made. DISALLOW_COPY_AND_ASSIGN(HasRef); }; class HasRefPrivateDtor : public HasRef { private: ~HasRefPrivateDtor() {} }; static const int kParentValue = 1; static const int kChildValue = 2; class Parent { public: virtual ~Parent() = default; void AddRef() const {} void Release() const {} virtual void VirtualSet() { value = kParentValue; } void NonVirtualSet() { value = kParentValue; } int value; }; class Child : public Parent { public: ~Child() override = default; void VirtualSet() override { value = kChildValue; } void NonVirtualSet() { value = kChildValue; } }; class NoRefParent { public: virtual ~NoRefParent() = default; virtual void VirtualSet() { value = kParentValue; } void NonVirtualSet() { value = kParentValue; } int value; }; class NoRefChild : public NoRefParent { public: ~NoRefChild() override = default; void VirtualSet() override { value = kChildValue; } void NonVirtualSet() { value = kChildValue; } }; // Used for probing the number of copies that occur if a type must be coerced // during argument forwarding in the Run() methods. struct DerivedCopyCounter { DerivedCopyCounter(int* copies, int* assigns) : copies_(copies), assigns_(assigns) { } int* copies_; int* assigns_; }; // Used for probing the number of copies in an argument. class CopyCounter { public: CopyCounter(int* copies, int* assigns) : copies_(copies), assigns_(assigns) { } CopyCounter(const CopyCounter& other) : copies_(other.copies_), assigns_(other.assigns_) { (*copies_)++; } // Probing for copies from coercion. explicit CopyCounter(const DerivedCopyCounter& other) : copies_(other.copies_), assigns_(other.assigns_) { (*copies_)++; } const CopyCounter& operator=(const CopyCounter& rhs) { copies_ = rhs.copies_; assigns_ = rhs.assigns_; if (assigns_) { (*assigns_)++; } return *this; } int copies() const { return *copies_; } private: int* copies_; int* assigns_; }; class DeleteCounter { public: explicit DeleteCounter(int* deletes) : deletes_(deletes) { } ~DeleteCounter() { (*deletes_)++; } void VoidMethod0() {} private: int* deletes_; }; template T PassThru(T scoper) { return scoper; } // Some test functions that we can Bind to. template T PolymorphicIdentity(T t) { return t; } template struct VoidPolymorphic { static void Run(Ts... t) {} }; int Identity(int n) { return n; } int ArrayGet(const int array[], int n) { return array[n]; } int Sum(int a, int b, int c, int d, int e, int f) { return a + b + c + d + e + f; } const char* CStringIdentity(const char* s) { return s; } int GetCopies(const CopyCounter& counter) { return counter.copies(); } int UnwrapNoRefParent(NoRefParent p) { return p.value; } int UnwrapNoRefParentPtr(NoRefParent* p) { return p->value; } int UnwrapNoRefParentConstRef(const NoRefParent& p) { return p.value; } void RefArgSet(int &n) { n = 2; } void PtrArgSet(int *n) { *n = 2; } int FunctionWithWeakFirstParam(WeakPtr o, int n) { return n; } int FunctionWithScopedRefptrFirstParam(const scoped_refptr& o, int n) { return n; } void TakesACallback(const Closure& callback) { callback.Run(); } class BindTest : public ::testing::Test { public: BindTest() { const_has_ref_ptr_ = &has_ref_; const_no_ref_ptr_ = &no_ref_; static_func_mock_ptr = &static_func_mock_; } virtual ~BindTest() { } static void VoidFunc0() { static_func_mock_ptr->VoidMethod0(); } static int IntFunc0() { return static_func_mock_ptr->IntMethod0(); } protected: StrictMock no_ref_; StrictMock has_ref_; const HasRef* const_has_ref_ptr_; const NoRef* const_no_ref_ptr_; StrictMock static_func_mock_; // Used by the static functions to perform expectations. static StrictMock* static_func_mock_ptr; private: DISALLOW_COPY_AND_ASSIGN(BindTest); }; StrictMock* BindTest::static_func_mock_ptr; // Sanity check that we can instantiate a callback for each arity. TEST_F(BindTest, ArityTest) { Callback c0 = Bind(&Sum, 32, 16, 8, 4, 2, 1); EXPECT_EQ(63, c0.Run()); Callback c1 = Bind(&Sum, 32, 16, 8, 4, 2); EXPECT_EQ(75, c1.Run(13)); Callback c2 = Bind(&Sum, 32, 16, 8, 4); EXPECT_EQ(85, c2.Run(13, 12)); Callback c3 = Bind(&Sum, 32, 16, 8); EXPECT_EQ(92, c3.Run(13, 12, 11)); Callback c4 = Bind(&Sum, 32, 16); EXPECT_EQ(94, c4.Run(13, 12, 11, 10)); Callback c5 = Bind(&Sum, 32); EXPECT_EQ(87, c5.Run(13, 12, 11, 10, 9)); Callback c6 = Bind(&Sum); EXPECT_EQ(69, c6.Run(13, 12, 11, 10, 9, 14)); } // Test the Currying ability of the Callback system. TEST_F(BindTest, CurryingTest) { Callback c6 = Bind(&Sum); EXPECT_EQ(69, c6.Run(13, 12, 11, 10, 9, 14)); Callback c5 = Bind(c6, 32); EXPECT_EQ(87, c5.Run(13, 12, 11, 10, 9)); Callback c4 = Bind(c5, 16); EXPECT_EQ(94, c4.Run(13, 12, 11, 10)); Callback c3 = Bind(c4, 8); EXPECT_EQ(92, c3.Run(13, 12, 11)); Callback c2 = Bind(c3, 4); EXPECT_EQ(85, c2.Run(13, 12)); Callback c1 = Bind(c2, 2); EXPECT_EQ(75, c1.Run(13)); Callback c0 = Bind(c1, 1); EXPECT_EQ(63, c0.Run()); } // Test that currying the rvalue result of another Bind() works correctly. // - rvalue should be usable as argument to Bind(). // - multiple runs of resulting Callback remain valid. TEST_F(BindTest, CurryingRvalueResultOfBind) { int n = 0; Closure cb = base::Bind(&TakesACallback, base::Bind(&PtrArgSet, &n)); // If we implement Bind() such that the return value has auto_ptr-like // semantics, the second call here will fail because ownership of // the internal BindState<> would have been transfered to a *temporary* // constructon of a Callback object on the first call. cb.Run(); EXPECT_EQ(2, n); n = 0; cb.Run(); EXPECT_EQ(2, n); } // Function type support. // - Normal function. // - Normal function bound with non-refcounted first argument. // - Method bound to non-const object. // - Method bound to scoped_refptr. // - Const method bound to non-const object. // - Const method bound to const object. // - Derived classes can be used with pointers to non-virtual base functions. // - Derived classes can be used with pointers to virtual base functions (and // preserve virtual dispatch). TEST_F(BindTest, FunctionTypeSupport) { EXPECT_CALL(static_func_mock_, VoidMethod0()); EXPECT_CALL(has_ref_, AddRef()).Times(5); EXPECT_CALL(has_ref_, Release()).Times(5); EXPECT_CALL(has_ref_, VoidMethod0()).Times(2); EXPECT_CALL(has_ref_, VoidConstMethod0()).Times(2); Closure normal_cb = Bind(&VoidFunc0); Callback normal_non_refcounted_cb = Bind(&PolymorphicIdentity, &no_ref_); normal_cb.Run(); EXPECT_EQ(&no_ref_, normal_non_refcounted_cb.Run()); Closure method_cb = Bind(&HasRef::VoidMethod0, &has_ref_); Closure method_refptr_cb = Bind(&HasRef::VoidMethod0, make_scoped_refptr(&has_ref_)); Closure const_method_nonconst_obj_cb = Bind(&HasRef::VoidConstMethod0, &has_ref_); Closure const_method_const_obj_cb = Bind(&HasRef::VoidConstMethod0, const_has_ref_ptr_); method_cb.Run(); method_refptr_cb.Run(); const_method_nonconst_obj_cb.Run(); const_method_const_obj_cb.Run(); Child child; child.value = 0; Closure virtual_set_cb = Bind(&Parent::VirtualSet, &child); virtual_set_cb.Run(); EXPECT_EQ(kChildValue, child.value); child.value = 0; Closure non_virtual_set_cb = Bind(&Parent::NonVirtualSet, &child); non_virtual_set_cb.Run(); EXPECT_EQ(kParentValue, child.value); } // Return value support. // - Function with return value. // - Method with return value. // - Const method with return value. TEST_F(BindTest, ReturnValues) { EXPECT_CALL(static_func_mock_, IntMethod0()).WillOnce(Return(1337)); EXPECT_CALL(has_ref_, AddRef()).Times(3); EXPECT_CALL(has_ref_, Release()).Times(3); EXPECT_CALL(has_ref_, IntMethod0()).WillOnce(Return(31337)); EXPECT_CALL(has_ref_, IntConstMethod0()) .WillOnce(Return(41337)) .WillOnce(Return(51337)); Callback normal_cb = Bind(&IntFunc0); Callback method_cb = Bind(&HasRef::IntMethod0, &has_ref_); Callback const_method_nonconst_obj_cb = Bind(&HasRef::IntConstMethod0, &has_ref_); Callback const_method_const_obj_cb = Bind(&HasRef::IntConstMethod0, const_has_ref_ptr_); EXPECT_EQ(1337, normal_cb.Run()); EXPECT_EQ(31337, method_cb.Run()); EXPECT_EQ(41337, const_method_nonconst_obj_cb.Run()); EXPECT_EQ(51337, const_method_const_obj_cb.Run()); } // IgnoreResult adapter test. // - Function with return value. // - Method with return value. // - Const Method with return. // - Method with return value bound to WeakPtr<>. // - Const Method with return bound to WeakPtr<>. TEST_F(BindTest, IgnoreResult) { EXPECT_CALL(static_func_mock_, IntMethod0()).WillOnce(Return(1337)); EXPECT_CALL(has_ref_, AddRef()).Times(2); EXPECT_CALL(has_ref_, Release()).Times(2); EXPECT_CALL(has_ref_, IntMethod0()).WillOnce(Return(10)); EXPECT_CALL(has_ref_, IntConstMethod0()).WillOnce(Return(11)); EXPECT_CALL(no_ref_, IntMethod0()).WillOnce(Return(12)); EXPECT_CALL(no_ref_, IntConstMethod0()).WillOnce(Return(13)); Closure normal_func_cb = Bind(IgnoreResult(&IntFunc0)); normal_func_cb.Run(); Closure non_void_method_cb = Bind(IgnoreResult(&HasRef::IntMethod0), &has_ref_); non_void_method_cb.Run(); Closure non_void_const_method_cb = Bind(IgnoreResult(&HasRef::IntConstMethod0), &has_ref_); non_void_const_method_cb.Run(); WeakPtrFactory weak_factory(&no_ref_); WeakPtrFactory const_weak_factory(const_no_ref_ptr_); Closure non_void_weak_method_cb = Bind(IgnoreResult(&NoRef::IntMethod0), weak_factory.GetWeakPtr()); non_void_weak_method_cb.Run(); Closure non_void_weak_const_method_cb = Bind(IgnoreResult(&NoRef::IntConstMethod0), weak_factory.GetWeakPtr()); non_void_weak_const_method_cb.Run(); weak_factory.InvalidateWeakPtrs(); non_void_weak_const_method_cb.Run(); non_void_weak_method_cb.Run(); } // Argument binding tests. // - Argument binding to primitive. // - Argument binding to primitive pointer. // - Argument binding to a literal integer. // - Argument binding to a literal string. // - Argument binding with template function. // - Argument binding to an object. // - Argument binding to pointer to incomplete type. // - Argument gets type converted. // - Pointer argument gets converted. // - Const Reference forces conversion. TEST_F(BindTest, ArgumentBinding) { int n = 2; Callback bind_primitive_cb = Bind(&Identity, n); EXPECT_EQ(n, bind_primitive_cb.Run()); Callback bind_primitive_pointer_cb = Bind(&PolymorphicIdentity, &n); EXPECT_EQ(&n, bind_primitive_pointer_cb.Run()); Callback bind_int_literal_cb = Bind(&Identity, 3); EXPECT_EQ(3, bind_int_literal_cb.Run()); Callback bind_string_literal_cb = Bind(&CStringIdentity, "hi"); EXPECT_STREQ("hi", bind_string_literal_cb.Run()); Callback bind_template_function_cb = Bind(&PolymorphicIdentity, 4); EXPECT_EQ(4, bind_template_function_cb.Run()); NoRefParent p; p.value = 5; Callback bind_object_cb = Bind(&UnwrapNoRefParent, p); EXPECT_EQ(5, bind_object_cb.Run()); IncompleteType* incomplete_ptr = reinterpret_cast(123); Callback bind_incomplete_ptr_cb = Bind(&PolymorphicIdentity, incomplete_ptr); EXPECT_EQ(incomplete_ptr, bind_incomplete_ptr_cb.Run()); NoRefChild c; c.value = 6; Callback bind_promotes_cb = Bind(&UnwrapNoRefParent, c); EXPECT_EQ(6, bind_promotes_cb.Run()); c.value = 7; Callback bind_pointer_promotes_cb = Bind(&UnwrapNoRefParentPtr, &c); EXPECT_EQ(7, bind_pointer_promotes_cb.Run()); c.value = 8; Callback bind_const_reference_promotes_cb = Bind(&UnwrapNoRefParentConstRef, c); EXPECT_EQ(8, bind_const_reference_promotes_cb.Run()); } // Unbound argument type support tests. // - Unbound value. // - Unbound pointer. // - Unbound reference. // - Unbound const reference. // - Unbound unsized array. // - Unbound sized array. // - Unbound array-of-arrays. TEST_F(BindTest, UnboundArgumentTypeSupport) { Callback unbound_value_cb = Bind(&VoidPolymorphic::Run); Callback unbound_pointer_cb = Bind(&VoidPolymorphic::Run); Callback unbound_ref_cb = Bind(&VoidPolymorphic::Run); Callback unbound_const_ref_cb = Bind(&VoidPolymorphic::Run); Callback unbound_unsized_array_cb = Bind(&VoidPolymorphic::Run); Callback unbound_sized_array_cb = Bind(&VoidPolymorphic::Run); Callback unbound_array_of_arrays_cb = Bind(&VoidPolymorphic::Run); Callback unbound_ref_with_bound_arg = Bind(&VoidPolymorphic::Run, 1); } // Function with unbound reference parameter. // - Original parameter is modified by callback. TEST_F(BindTest, UnboundReferenceSupport) { int n = 0; Callback unbound_ref_cb = Bind(&RefArgSet); unbound_ref_cb.Run(n); EXPECT_EQ(2, n); } // Functions that take reference parameters. // - Forced reference parameter type still stores a copy. // - Forced const reference parameter type still stores a copy. TEST_F(BindTest, ReferenceArgumentBinding) { int n = 1; int& ref_n = n; const int& const_ref_n = n; Callback ref_copies_cb = Bind(&Identity, ref_n); EXPECT_EQ(n, ref_copies_cb.Run()); n++; EXPECT_EQ(n - 1, ref_copies_cb.Run()); Callback const_ref_copies_cb = Bind(&Identity, const_ref_n); EXPECT_EQ(n, const_ref_copies_cb.Run()); n++; EXPECT_EQ(n - 1, const_ref_copies_cb.Run()); } // Check that we can pass in arrays and have them be stored as a pointer. // - Array of values stores a pointer. // - Array of const values stores a pointer. TEST_F(BindTest, ArrayArgumentBinding) { int array[4] = {1, 1, 1, 1}; const int (*const_array_ptr)[4] = &array; Callback array_cb = Bind(&ArrayGet, array, 1); EXPECT_EQ(1, array_cb.Run()); Callback const_array_cb = Bind(&ArrayGet, *const_array_ptr, 1); EXPECT_EQ(1, const_array_cb.Run()); array[1] = 3; EXPECT_EQ(3, array_cb.Run()); EXPECT_EQ(3, const_array_cb.Run()); } // Verify SupportsAddRefAndRelease correctly introspects the class type for // AddRef() and Release(). // - Class with AddRef() and Release() // - Class without AddRef() and Release() // - Derived Class with AddRef() and Release() // - Derived Class without AddRef() and Release() // - Derived Class with AddRef() and Release() and a private destructor. TEST_F(BindTest, SupportsAddRefAndRelease) { EXPECT_TRUE(internal::SupportsAddRefAndRelease::value); EXPECT_FALSE(internal::SupportsAddRefAndRelease::value); // StrictMock is a derived class of T. So, we use StrictMock and // StrictMock to test that SupportsAddRefAndRelease works over // inheritance. EXPECT_TRUE(internal::SupportsAddRefAndRelease >::value); EXPECT_FALSE(internal::SupportsAddRefAndRelease >::value); // This matters because the implementation creates a dummy class that // inherits from the template type. EXPECT_TRUE(internal::SupportsAddRefAndRelease::value); } // Unretained() wrapper support. // - Method bound to Unretained() non-const object. // - Const method bound to Unretained() non-const object. // - Const method bound to Unretained() const object. TEST_F(BindTest, Unretained) { EXPECT_CALL(no_ref_, VoidMethod0()); EXPECT_CALL(no_ref_, VoidConstMethod0()).Times(2); Callback method_cb = Bind(&NoRef::VoidMethod0, Unretained(&no_ref_)); method_cb.Run(); Callback const_method_cb = Bind(&NoRef::VoidConstMethod0, Unretained(&no_ref_)); const_method_cb.Run(); Callback const_method_const_ptr_cb = Bind(&NoRef::VoidConstMethod0, Unretained(const_no_ref_ptr_)); const_method_const_ptr_cb.Run(); } // WeakPtr() support. // - Method bound to WeakPtr<> to non-const object. // - Const method bound to WeakPtr<> to non-const object. // - Const method bound to WeakPtr<> to const object. // - Normal Function with WeakPtr<> as P1 can have return type and is // not canceled. TEST_F(BindTest, WeakPtr) { EXPECT_CALL(no_ref_, VoidMethod0()); EXPECT_CALL(no_ref_, VoidConstMethod0()).Times(2); WeakPtrFactory weak_factory(&no_ref_); WeakPtrFactory const_weak_factory(const_no_ref_ptr_); Closure method_cb = Bind(&NoRef::VoidMethod0, weak_factory.GetWeakPtr()); method_cb.Run(); Closure const_method_cb = Bind(&NoRef::VoidConstMethod0, const_weak_factory.GetWeakPtr()); const_method_cb.Run(); Closure const_method_const_ptr_cb = Bind(&NoRef::VoidConstMethod0, const_weak_factory.GetWeakPtr()); const_method_const_ptr_cb.Run(); Callback normal_func_cb = Bind(&FunctionWithWeakFirstParam, weak_factory.GetWeakPtr()); EXPECT_EQ(1, normal_func_cb.Run(1)); weak_factory.InvalidateWeakPtrs(); const_weak_factory.InvalidateWeakPtrs(); method_cb.Run(); const_method_cb.Run(); const_method_const_ptr_cb.Run(); // Still runs even after the pointers are invalidated. EXPECT_EQ(2, normal_func_cb.Run(2)); } // ConstRef() wrapper support. // - Binding w/o ConstRef takes a copy. // - Binding a ConstRef takes a reference. // - Binding ConstRef to a function ConstRef does not copy on invoke. TEST_F(BindTest, ConstRef) { int n = 1; Callback copy_cb = Bind(&Identity, n); Callback const_ref_cb = Bind(&Identity, ConstRef(n)); EXPECT_EQ(n, copy_cb.Run()); EXPECT_EQ(n, const_ref_cb.Run()); n++; EXPECT_EQ(n - 1, copy_cb.Run()); EXPECT_EQ(n, const_ref_cb.Run()); int copies = 0; int assigns = 0; CopyCounter counter(&copies, &assigns); Callback all_const_ref_cb = Bind(&GetCopies, ConstRef(counter)); EXPECT_EQ(0, all_const_ref_cb.Run()); EXPECT_EQ(0, copies); EXPECT_EQ(0, assigns); } TEST_F(BindTest, ScopedRefptr) { // BUG: The scoped_refptr should cause the only AddRef()/Release() pair. But // due to a bug in base::Bind(), there's an extra call when invoking the // callback. // https://code.google.com/p/chromium/issues/detail?id=251937 EXPECT_CALL(has_ref_, AddRef()).Times(2); EXPECT_CALL(has_ref_, Release()).Times(2); const scoped_refptr > refptr(&has_ref_); Callback scoped_refptr_const_ref_cb = Bind(&FunctionWithScopedRefptrFirstParam, base::ConstRef(refptr), 1); EXPECT_EQ(1, scoped_refptr_const_ref_cb.Run()); } // Test Owned() support. TEST_F(BindTest, Owned) { int deletes = 0; DeleteCounter* counter = new DeleteCounter(&deletes); // If we don't capture, delete happens on Callback destruction/reset. // return the same value. Callback no_capture_cb = Bind(&PolymorphicIdentity, Owned(counter)); ASSERT_EQ(counter, no_capture_cb.Run()); ASSERT_EQ(counter, no_capture_cb.Run()); EXPECT_EQ(0, deletes); no_capture_cb.Reset(); // This should trigger a delete. EXPECT_EQ(1, deletes); deletes = 0; counter = new DeleteCounter(&deletes); base::Closure own_object_cb = Bind(&DeleteCounter::VoidMethod0, Owned(counter)); own_object_cb.Run(); EXPECT_EQ(0, deletes); own_object_cb.Reset(); EXPECT_EQ(1, deletes); } // Passed() wrapper support. // - Passed() can be constructed from a pointer to scoper. // - Passed() can be constructed from a scoper rvalue. // - Using Passed() gives Callback Ownership. // - Ownership is transferred from Callback to callee on the first Run(). // - Callback supports unbound arguments. TEST_F(BindTest, ScopedPtr) { int deletes = 0; // Tests the Passed() function's support for pointers. scoped_ptr ptr(new DeleteCounter(&deletes)); Callback()> unused_callback = Bind(&PassThru >, Passed(&ptr)); EXPECT_FALSE(ptr.get()); EXPECT_EQ(0, deletes); // If we never invoke the Callback, it retains ownership and deletes. unused_callback.Reset(); EXPECT_EQ(1, deletes); // Tests the Passed() function's support for rvalues. deletes = 0; DeleteCounter* counter = new DeleteCounter(&deletes); Callback()> callback = Bind(&PassThru >, Passed(scoped_ptr(counter))); EXPECT_FALSE(ptr.get()); EXPECT_EQ(0, deletes); // Check that ownership can be transferred back out. scoped_ptr result = callback.Run(); ASSERT_EQ(counter, result.get()); EXPECT_EQ(0, deletes); // Resetting does not delete since ownership was transferred. callback.Reset(); EXPECT_EQ(0, deletes); // Ensure that we actually did get ownership. result.reset(); EXPECT_EQ(1, deletes); // Test unbound argument forwarding. Callback(scoped_ptr)> cb_unbound = Bind(&PassThru >); ptr.reset(new DeleteCounter(&deletes)); cb_unbound.Run(std::move(ptr)); } TEST_F(BindTest, UniquePtr) { int deletes = 0; // Tests the Passed() function's support for pointers. std::unique_ptr ptr(new DeleteCounter(&deletes)); Callback()> unused_callback = Bind(&PassThru>, Passed(&ptr)); EXPECT_FALSE(ptr.get()); EXPECT_EQ(0, deletes); // If we never invoke the Callback, it retains ownership and deletes. unused_callback.Reset(); EXPECT_EQ(1, deletes); // Tests the Passed() function's support for rvalues. deletes = 0; DeleteCounter* counter = new DeleteCounter(&deletes); Callback()> callback = Bind(&PassThru>, Passed(std::unique_ptr(counter))); EXPECT_FALSE(ptr.get()); EXPECT_EQ(0, deletes); // Check that ownership can be transferred back out. std::unique_ptr result = callback.Run(); ASSERT_EQ(counter, result.get()); EXPECT_EQ(0, deletes); // Resetting does not delete since ownership was transferred. callback.Reset(); EXPECT_EQ(0, deletes); // Ensure that we actually did get ownership. result.reset(); EXPECT_EQ(1, deletes); // Test unbound argument forwarding. Callback(std::unique_ptr)> cb_unbound = Bind(&PassThru>); ptr.reset(new DeleteCounter(&deletes)); cb_unbound.Run(std::move(ptr)); } // Argument Copy-constructor usage for non-reference parameters. // - Bound arguments are only copied once. // - Forwarded arguments are only copied once. // - Forwarded arguments with coercions are only copied twice (once for the // coercion, and one for the final dispatch). TEST_F(BindTest, ArgumentCopies) { int copies = 0; int assigns = 0; CopyCounter counter(&copies, &assigns); Callback copy_cb = Bind(&VoidPolymorphic::Run, counter); EXPECT_GE(1, copies); EXPECT_EQ(0, assigns); copies = 0; assigns = 0; Callback forward_cb = Bind(&VoidPolymorphic::Run); forward_cb.Run(counter); EXPECT_GE(1, copies); EXPECT_EQ(0, assigns); copies = 0; assigns = 0; DerivedCopyCounter derived(&copies, &assigns); Callback coerce_cb = Bind(&VoidPolymorphic::Run); coerce_cb.Run(CopyCounter(derived)); EXPECT_GE(2, copies); EXPECT_EQ(0, assigns); } // Callback construction and assignment tests. // - Construction from an InvokerStorageHolder should not cause ref/deref. // - Assignment from other callback should only cause one ref // // TODO(ajwong): Is there actually a way to test this? #if defined(OS_WIN) int __fastcall FastCallFunc(int n) { return n; } int __stdcall StdCallFunc(int n) { return n; } // Windows specific calling convention support. // - Can bind a __fastcall function. // - Can bind a __stdcall function. TEST_F(BindTest, WindowsCallingConventions) { Callback fastcall_cb = Bind(&FastCallFunc, 1); EXPECT_EQ(1, fastcall_cb.Run()); Callback stdcall_cb = Bind(&StdCallFunc, 2); EXPECT_EQ(2, stdcall_cb.Run()); } #endif #if (!defined(NDEBUG) || defined(DCHECK_ALWAYS_ON)) && GTEST_HAS_DEATH_TEST // Test null callbacks cause a DCHECK. TEST(BindDeathTest, NullCallback) { base::Callback null_cb; ASSERT_TRUE(null_cb.is_null()); EXPECT_DEATH(base::Bind(null_cb, 42), ""); } #endif // (!defined(NDEBUG) || defined(DCHECK_ALWAYS_ON)) && // GTEST_HAS_DEATH_TEST } // namespace } // namespace base