// 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. // // Author: wan@google.com (Zhanyong Wan) // Google Mock - a framework for writing C++ mock classes. // // This file defines some utilities useful for implementing Google // Mock. They are subject to change without notice, so please DO NOT // USE THEM IN USER CODE. #ifndef GMOCK_INCLUDE_GMOCK_INTERNAL_GMOCK_INTERNAL_UTILS_H_ #define GMOCK_INCLUDE_GMOCK_INTERNAL_GMOCK_INTERNAL_UTILS_H_ #include #include // NOLINT #include #include #include #include // Concatenates two pre-processor symbols; works for concatenating // built-in macros like __FILE__ and __LINE__. #define GMOCK_CONCAT_TOKEN_IMPL_(foo, bar) foo##bar #define GMOCK_CONCAT_TOKEN_(foo, bar) GMOCK_CONCAT_TOKEN_IMPL_(foo, bar) #ifdef __GNUC__ #define GMOCK_ATTRIBUTE_UNUSED_ __attribute__ ((unused)) #else #define GMOCK_ATTRIBUTE_UNUSED_ #endif // __GNUC__ class ProtocolMessage; namespace proto2 { class Message; } namespace testing { namespace internal { // Converts an identifier name to a space-separated list of lower-case // words. Each maximum substring of the form [A-Za-z][a-z]*|\d+ is // treated as one word. For example, both "FooBar123" and // "foo_bar_123" are converted to "foo bar 123". string ConvertIdentifierNameToWords(const char* id_name); // Defining a variable of type CompileAssertTypesEqual will cause a // compiler error iff T1 and T2 are different types. template struct CompileAssertTypesEqual; template struct CompileAssertTypesEqual { }; // Removes the reference from a type if it is a reference type, // otherwise leaves it unchanged. This is the same as // tr1::remove_reference, which is not widely available yet. template struct RemoveReference { typedef T type; }; // NOLINT template struct RemoveReference { typedef T type; }; // NOLINT // A handy wrapper around RemoveReference that works when the argument // T depends on template parameters. #define GMOCK_REMOVE_REFERENCE_(T) \ typename ::testing::internal::RemoveReference::type // Removes const from a type if it is a const type, otherwise leaves // it unchanged. This is the same as tr1::remove_const, which is not // widely available yet. template struct RemoveConst { typedef T type; }; // NOLINT template struct RemoveConst { typedef T type; }; // NOLINT // MSVC 8.0 has a bug which causes the above definition to fail to // remove the const in 'const int[3]'. The following specialization // works around the bug. However, it causes trouble with gcc and thus // needs to be conditionally compiled. #ifdef _MSC_VER template struct RemoveConst { typedef typename RemoveConst::type type[N]; }; #endif // _MSC_VER // A handy wrapper around RemoveConst that works when the argument // T depends on template parameters. #define GMOCK_REMOVE_CONST_(T) \ typename ::testing::internal::RemoveConst::type // Adds reference to a type if it is not a reference type, // otherwise leaves it unchanged. This is the same as // tr1::add_reference, which is not widely available yet. template struct AddReference { typedef T& type; }; // NOLINT template struct AddReference { typedef T& type; }; // NOLINT // A handy wrapper around AddReference that works when the argument T // depends on template parameters. #define GMOCK_ADD_REFERENCE_(T) \ typename ::testing::internal::AddReference::type // Adds a reference to const on top of T as necessary. For example, // it transforms // // char ==> const char& // const char ==> const char& // char& ==> const char& // const char& ==> const char& // // The argument T must depend on some template parameters. #define GMOCK_REFERENCE_TO_CONST_(T) \ GMOCK_ADD_REFERENCE_(const GMOCK_REMOVE_REFERENCE_(T)) // PointeeOf::type is the type of a value pointed to by a // Pointer, which can be either a smart pointer or a raw pointer. The // following default implementation is for the case where Pointer is a // smart pointer. template struct PointeeOf { // Smart pointer classes define type element_type as the type of // their pointees. typedef typename Pointer::element_type type; }; // This specialization is for the raw pointer case. template struct PointeeOf { typedef T type; }; // NOLINT // GetRawPointer(p) returns the raw pointer underlying p when p is a // smart pointer, or returns p itself when p is already a raw pointer. // The following default implementation is for the smart pointer case. template inline typename Pointer::element_type* GetRawPointer(const Pointer& p) { return p.get(); } // This overloaded version is for the raw pointer case. template inline Element* GetRawPointer(Element* p) { return p; } // This comparator allows linked_ptr to be stored in sets. template struct LinkedPtrLessThan { bool operator()(const ::testing::internal::linked_ptr& lhs, const ::testing::internal::linked_ptr& rhs) const { return lhs.get() < rhs.get(); } }; // ImplicitlyConvertible::value is a compile-time bool // constant that's true iff type From can be implicitly converted to // type To. template class ImplicitlyConvertible { private: // We need the following helper functions only for their types. // They have no implementations. // MakeFrom() is an expression whose type is From. We cannot simply // use From(), as the type From may not have a public default // constructor. static From MakeFrom(); // These two functions are overloaded. Given an expression // Helper(x), the compiler will pick the first version if x can be // implicitly converted to type To; otherwise it will pick the // second version. // // The first version returns a value of size 1, and the second // version returns a value of size 2. Therefore, by checking the // size of Helper(x), which can be done at compile time, we can tell // which version of Helper() is used, and hence whether x can be // implicitly converted to type To. static char Helper(To); static char (&Helper(...))[2]; // NOLINT // We have to put the 'public' section after the 'private' section, // or MSVC refuses to compile the code. public: // MSVC warns about implicitly converting from double to int for // possible loss of data, so we need to temporarily disable the // warning. #ifdef _MSC_VER #pragma warning(push) // Saves the current warning state. #pragma warning(disable:4244) // Temporarily disables warning 4244. static const bool value = sizeof(Helper(ImplicitlyConvertible::MakeFrom())) == 1; #pragma warning(pop) // Restores the warning state. #else static const bool value = sizeof(Helper(ImplicitlyConvertible::MakeFrom())) == 1; #endif // _MSV_VER }; template const bool ImplicitlyConvertible::value; // In what follows, we use the term "kind" to indicate whether a type // is bool, an integer type (excluding bool), a floating-point type, // or none of them. This categorization is useful for determining // when a matcher argument type can be safely converted to another // type in the implementation of SafeMatcherCast. enum TypeKind { kBool, kInteger, kFloatingPoint, kOther }; // KindOf::value is the kind of type T. template struct KindOf { enum { value = kOther }; // The default kind. }; // This macro declares that the kind of 'type' is 'kind'. #define GMOCK_DECLARE_KIND_(type, kind) \ template <> struct KindOf { enum { value = kind }; } GMOCK_DECLARE_KIND_(bool, kBool); // All standard integer types. GMOCK_DECLARE_KIND_(char, kInteger); GMOCK_DECLARE_KIND_(signed char, kInteger); GMOCK_DECLARE_KIND_(unsigned char, kInteger); GMOCK_DECLARE_KIND_(short, kInteger); // NOLINT GMOCK_DECLARE_KIND_(unsigned short, kInteger); // NOLINT GMOCK_DECLARE_KIND_(int, kInteger); GMOCK_DECLARE_KIND_(unsigned int, kInteger); GMOCK_DECLARE_KIND_(long, kInteger); // NOLINT GMOCK_DECLARE_KIND_(unsigned long, kInteger); // NOLINT // MSVC can be configured to define wchar_t as a typedef of unsigned // short. It defines _NATIVE_WCHAR_T_DEFINED symbol when wchar_t is a // native type. #if !defined(_MSC_VER) || defined(_NATIVE_WCHAR_T_DEFINED) GMOCK_DECLARE_KIND_(wchar_t, kInteger); #endif // Non-standard integer types. GMOCK_DECLARE_KIND_(Int64, kInteger); GMOCK_DECLARE_KIND_(UInt64, kInteger); // All standard floating-point types. GMOCK_DECLARE_KIND_(float, kFloatingPoint); GMOCK_DECLARE_KIND_(double, kFloatingPoint); GMOCK_DECLARE_KIND_(long double, kFloatingPoint); #undef GMOCK_DECLARE_KIND_ // Evaluates to the kind of 'type'. #define GMOCK_KIND_OF_(type) \ static_cast< ::testing::internal::TypeKind>( \ ::testing::internal::KindOf::value) // Evaluates to true iff integer type T is signed. #define GMOCK_IS_SIGNED_(T) (static_cast(-1) < 0) // LosslessArithmeticConvertibleImpl::value // is true iff arithmetic type From can be losslessly converted to // arithmetic type To. // // It's the user's responsibility to ensure that both From and To are // raw (i.e. has no CV modifier, is not a pointer, and is not a // reference) built-in arithmetic types, kFromKind is the kind of // From, and kToKind is the kind of To; the value is // implementation-defined when the above pre-condition is violated. template struct LosslessArithmeticConvertibleImpl : public false_type {}; // Converting bool to bool is lossless. template <> struct LosslessArithmeticConvertibleImpl : public true_type {}; // NOLINT // Converting bool to any integer type is lossless. template struct LosslessArithmeticConvertibleImpl : public true_type {}; // NOLINT // Converting bool to any floating-point type is lossless. template struct LosslessArithmeticConvertibleImpl : public true_type {}; // NOLINT // Converting an integer to bool is lossy. template struct LosslessArithmeticConvertibleImpl : public false_type {}; // NOLINT // Converting an integer to another non-bool integer is lossless iff // the target type's range encloses the source type's range. template struct LosslessArithmeticConvertibleImpl : public bool_constant< // When converting from a smaller size to a larger size, we are // fine as long as we are not converting from signed to unsigned. ((sizeof(From) < sizeof(To)) && (!GMOCK_IS_SIGNED_(From) || GMOCK_IS_SIGNED_(To))) || // When converting between the same size, the signedness must match. ((sizeof(From) == sizeof(To)) && (GMOCK_IS_SIGNED_(From) == GMOCK_IS_SIGNED_(To)))> {}; // NOLINT #undef GMOCK_IS_SIGNED_ // Converting an integer to a floating-point type may be lossy, since // the format of a floating-point number is implementation-defined. template struct LosslessArithmeticConvertibleImpl : public false_type {}; // NOLINT // Converting a floating-point to bool is lossy. template struct LosslessArithmeticConvertibleImpl : public false_type {}; // NOLINT // Converting a floating-point to an integer is lossy. template struct LosslessArithmeticConvertibleImpl : public false_type {}; // NOLINT // Converting a floating-point to another floating-point is lossless // iff the target type is at least as big as the source type. template struct LosslessArithmeticConvertibleImpl< kFloatingPoint, From, kFloatingPoint, To> : public bool_constant {}; // NOLINT // LosslessArithmeticConvertible::value is true iff arithmetic // type From can be losslessly converted to arithmetic type To. // // It's the user's responsibility to ensure that both From and To are // raw (i.e. has no CV modifier, is not a pointer, and is not a // reference) built-in arithmetic types; the value is // implementation-defined when the above pre-condition is violated. template struct LosslessArithmeticConvertible : public LosslessArithmeticConvertibleImpl< GMOCK_KIND_OF_(From), From, GMOCK_KIND_OF_(To), To> {}; // NOLINT // IsAProtocolMessage::value is a compile-time bool constant that's // true iff T is type ProtocolMessage, proto2::Message, or a subclass // of those. template struct IsAProtocolMessage : public bool_constant< ImplicitlyConvertible::value || ImplicitlyConvertible::value> { }; // When the compiler sees expression IsContainerTest(0), the first // overload of IsContainerTest will be picked if C is an STL-style // container class (since C::const_iterator* is a valid type and 0 can // be converted to it), while the second overload will be picked // otherwise (since C::const_iterator will be an invalid type in this // case). Therefore, we can determine whether C is a container class // by checking the type of IsContainerTest(0). The value of the // expression is insignificant. typedef int IsContainer; template IsContainer IsContainerTest(typename C::const_iterator*) { return 0; } typedef char IsNotContainer; template IsNotContainer IsContainerTest(...) { return '\0'; } // This interface knows how to report a Google Mock failure (either // non-fatal or fatal). class FailureReporterInterface { public: // The type of a failure (either non-fatal or fatal). enum FailureType { NONFATAL, FATAL }; virtual ~FailureReporterInterface() {} // Reports a failure that occurred at the given source file location. virtual void ReportFailure(FailureType type, const char* file, int line, const string& message) = 0; }; // Returns the failure reporter used by Google Mock. FailureReporterInterface* GetFailureReporter(); // Asserts that condition is true; aborts the process with the given // message if condition is false. We cannot use LOG(FATAL) or CHECK() // as Google Mock might be used to mock the log sink itself. We // inline this function to prevent it from showing up in the stack // trace. inline void Assert(bool condition, const char* file, int line, const string& msg) { if (!condition) { GetFailureReporter()->ReportFailure(FailureReporterInterface::FATAL, file, line, msg); } } inline void Assert(bool condition, const char* file, int line) { Assert(condition, file, line, "Assertion failed."); } // Verifies that condition is true; generates a non-fatal failure if // condition is false. inline void Expect(bool condition, const char* file, int line, const string& msg) { if (!condition) { GetFailureReporter()->ReportFailure(FailureReporterInterface::NONFATAL, file, line, msg); } } inline void Expect(bool condition, const char* file, int line) { Expect(condition, file, line, "Expectation failed."); } // Severity level of a log. enum LogSeverity { INFO = 0, WARNING = 1, }; // Valid values for the --gmock_verbose flag. // All logs (informational and warnings) are printed. const char kInfoVerbosity[] = "info"; // Only warnings are printed. const char kWarningVerbosity[] = "warning"; // No logs are printed. const char kErrorVerbosity[] = "error"; // Returns true iff a log with the given severity is visible according // to the --gmock_verbose flag. bool LogIsVisible(LogSeverity severity); // Prints the given message to stdout iff 'severity' >= the level // specified by the --gmock_verbose flag. If stack_frames_to_skip >= // 0, also prints the stack trace excluding the top // stack_frames_to_skip frames. In opt mode, any positive // stack_frames_to_skip is treated as 0, since we don't know which // function calls will be inlined by the compiler and need to be // conservative. void Log(LogSeverity severity, const string& message, int stack_frames_to_skip); // TODO(wan@google.com): group all type utilities together. // Type traits. // is_reference::value is non-zero iff T is a reference type. template struct is_reference : public false_type {}; template struct is_reference : public true_type {}; // type_equals::value is non-zero iff T1 and T2 are the same type. template struct type_equals : public false_type {}; template struct type_equals : public true_type {}; // remove_reference::type removes the reference from type T, if any. template struct remove_reference { typedef T type; }; // NOLINT template struct remove_reference { typedef T type; }; // NOLINT // Invalid() returns an invalid value of type T. This is useful // when a value of type T is needed for compilation, but the statement // will not really be executed (or we don't care if the statement // crashes). template inline T Invalid() { return *static_cast::type*>(NULL); } template <> inline void Invalid() {} // Utilities for native arrays. // ArrayEq() compares two k-dimensional native arrays using the // elements' operator==, where k can be any integer >= 0. When k is // 0, ArrayEq() degenerates into comparing a single pair of values. template bool ArrayEq(const T* lhs, size_t size, const U* rhs); // This generic version is used when k is 0. template inline bool ArrayEq(const T& lhs, const U& rhs) { return lhs == rhs; } // This overload is used when k >= 1. template inline bool ArrayEq(const T(&lhs)[N], const U(&rhs)[N]) { return internal::ArrayEq(lhs, N, rhs); } // This helper reduces code bloat. If we instead put its logic inside // the previous ArrayEq() function, arrays with different sizes would // lead to different copies of the template code. template bool ArrayEq(const T* lhs, size_t size, const U* rhs) { for (size_t i = 0; i != size; i++) { if (!internal::ArrayEq(lhs[i], rhs[i])) return false; } return true; } // Finds the first element in the iterator range [begin, end) that // equals elem. Element may be a native array type itself. template Iter ArrayAwareFind(Iter begin, Iter end, const Element& elem) { for (Iter it = begin; it != end; ++it) { if (internal::ArrayEq(*it, elem)) return it; } return end; } // CopyArray() copies a k-dimensional native array using the elements' // operator=, where k can be any integer >= 0. When k is 0, // CopyArray() degenerates into copying a single value. template void CopyArray(const T* from, size_t size, U* to); // This generic version is used when k is 0. template inline void CopyArray(const T& from, U* to) { *to = from; } // This overload is used when k >= 1. template inline void CopyArray(const T(&from)[N], U(*to)[N]) { internal::CopyArray(from, N, *to); } // This helper reduces code bloat. If we instead put its logic inside // the previous CopyArray() function, arrays with different sizes // would lead to different copies of the template code. template void CopyArray(const T* from, size_t size, U* to) { for (size_t i = 0; i != size; i++) { internal::CopyArray(from[i], to + i); } } // The relation between an NativeArray object (see below) and the // native array it represents. enum RelationToSource { kReference, // The NativeArray references the native array. kCopy // The NativeArray makes a copy of the native array and // owns the copy. }; // Adapts a native array to a read-only STL-style container. Instead // of the complete STL container concept, this adaptor only implements // members useful for Google Mock's container matchers. New members // should be added as needed. To simplify the implementation, we only // support Element being a raw type (i.e. having no top-level const or // reference modifier). It's the client's responsibility to satisfy // this requirement. Element can be an array type itself (hence // multi-dimensional arrays are supported). template class NativeArray { public: // STL-style container typedefs. typedef Element value_type; typedef const Element* const_iterator; // Constructs from a native array passed by reference. template NativeArray(const Element (&array)[N], RelationToSource relation) { Init(array, N, relation); } // Constructs from a native array passed by a pointer and a size. // For generality we don't artificially restrict the types of the // pointer and the size. template NativeArray(const ::std::tr1::tuple& array, RelationToSource relation) { Init(internal::GetRawPointer(::std::tr1::get<0>(array)), ::std::tr1::get<1>(array), relation); } // Copy constructor. NativeArray(const NativeArray& rhs) { Init(rhs.array_, rhs.size_, rhs.relation_to_source_); } ~NativeArray() { // Ensures that the user doesn't instantiate NativeArray with a // const or reference type. testing::StaticAssertTypeEq(); if (relation_to_source_ == kCopy) delete[] array_; } // STL-style container methods. size_t size() const { return size_; } const_iterator begin() const { return array_; } const_iterator end() const { return array_ + size_; } bool operator==(const NativeArray& rhs) const { return size() == rhs.size() && ArrayEq(begin(), size(), rhs.begin()); } private: // Not implemented as we don't want to support assignment. void operator=(const NativeArray& rhs); // Initializes this object; makes a copy of the input array if // 'relation' is kCopy. void Init(const Element* array, size_t size, RelationToSource relation) { if (relation == kReference) { array_ = array; } else { Element* const copy = new Element[size]; CopyArray(array, size, copy); array_ = copy; } size_ = size; relation_to_source_ = relation; } const Element* array_; size_t size_; RelationToSource relation_to_source_; }; // Given a raw type (i.e. having no top-level reference or const // modifier) RawContainer that's either an STL-style container or a // native array, class StlContainerView has the // following members: // // - type is a type that provides an STL-style container view to // (i.e. implements the STL container concept for) RawContainer; // - const_reference is a type that provides a reference to a const // RawContainer; // - ConstReference(raw_container) returns a const reference to an STL-style // container view to raw_container, which is a RawContainer. // - Copy(raw_container) returns an STL-style container view of a // copy of raw_container, which is a RawContainer. // // This generic version is used when RawContainer itself is already an // STL-style container. template class StlContainerView { public: typedef RawContainer type; typedef const type& const_reference; static const_reference ConstReference(const RawContainer& container) { // Ensures that RawContainer is not a const type. testing::StaticAssertTypeEq(); return container; } static type Copy(const RawContainer& container) { return container; } }; // This specialization is used when RawContainer is a native array type. template class StlContainerView { public: typedef GMOCK_REMOVE_CONST_(Element) RawElement; typedef internal::NativeArray type; // NativeArray can represent a native array either by value or by // reference (selected by a constructor argument), so 'const type' // can be used to reference a const native array. We cannot // 'typedef const type& const_reference' here, as that would mean // ConstReference() has to return a reference to a local variable. typedef const type const_reference; static const_reference ConstReference(const Element (&array)[N]) { // Ensures that Element is not a const type. testing::StaticAssertTypeEq(); return type(array, kReference); } static type Copy(const Element (&array)[N]) { return type(array, kCopy); } }; // This specialization is used when RawContainer is a native array // represented as a (pointer, size) tuple. template class StlContainerView< ::std::tr1::tuple > { public: typedef GMOCK_REMOVE_CONST_( typename internal::PointeeOf::type) RawElement; typedef internal::NativeArray type; typedef const type const_reference; static const_reference ConstReference( const ::std::tr1::tuple& array) { return type(array, kReference); } static type Copy(const ::std::tr1::tuple& array) { return type(array, kCopy); } }; // The following specialization prevents the user from instantiating // StlContainer with a reference type. template class StlContainerView; } // namespace internal } // namespace testing #endif // GMOCK_INCLUDE_GMOCK_INTERNAL_GMOCK_INTERNAL_UTILS_H_