// 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 implements some commonly used argument matchers. More // matchers can be defined by the user implementing the // MatcherInterface interface if necessary. #ifndef GMOCK_INCLUDE_GMOCK_GMOCK_MATCHERS_H_ #define GMOCK_INCLUDE_GMOCK_GMOCK_MATCHERS_H_ #include #include #include // NOLINT #include #include #include #include #include "gmock/internal/gmock-internal-utils.h" #include "gmock/internal/gmock-port.h" #include "gtest/gtest.h" namespace testing { // To implement a matcher Foo for type T, define: // 1. a class FooMatcherImpl that implements the // MatcherInterface interface, and // 2. a factory function that creates a Matcher object from a // FooMatcherImpl*. // // The two-level delegation design makes it possible to allow a user // to write "v" instead of "Eq(v)" where a Matcher is expected, which // is impossible if we pass matchers by pointers. It also eases // ownership management as Matcher objects can now be copied like // plain values. // MatchResultListener is an abstract class. Its << operator can be // used by a matcher to explain why a value matches or doesn't match. // // TODO(wan@google.com): add method // bool InterestedInWhy(bool result) const; // to indicate whether the listener is interested in why the match // result is 'result'. class MatchResultListener { public: // Creates a listener object with the given underlying ostream. The // listener does not own the ostream. explicit MatchResultListener(::std::ostream* os) : stream_(os) {} virtual ~MatchResultListener() = 0; // Makes this class abstract. // Streams x to the underlying ostream; does nothing if the ostream // is NULL. template MatchResultListener& operator<<(const T& x) { if (stream_ != NULL) *stream_ << x; return *this; } // Returns the underlying ostream. ::std::ostream* stream() { return stream_; } // Returns true iff the listener is interested in an explanation of // the match result. A matcher's MatchAndExplain() method can use // this information to avoid generating the explanation when no one // intends to hear it. bool IsInterested() const { return stream_ != NULL; } private: ::std::ostream* const stream_; GTEST_DISALLOW_COPY_AND_ASSIGN_(MatchResultListener); }; inline MatchResultListener::~MatchResultListener() { } // The implementation of a matcher. template class MatcherInterface { public: virtual ~MatcherInterface() {} // Returns true iff the matcher matches x; also explains the match // result to 'listener', in the form of a non-restrictive relative // clause ("which ...", "whose ...", etc) that describes x. For // example, the MatchAndExplain() method of the Pointee(...) matcher // should generate an explanation like "which points to ...". // // You should override this method when defining a new matcher. // // It's the responsibility of the caller (Google Mock) to guarantee // that 'listener' is not NULL. This helps to simplify a matcher's // implementation when it doesn't care about the performance, as it // can talk to 'listener' without checking its validity first. // However, in order to implement dummy listeners efficiently, // listener->stream() may be NULL. virtual bool MatchAndExplain(T x, MatchResultListener* listener) const = 0; // Describes this matcher to an ostream. The function should print // a verb phrase that describes the property a value matching this // matcher should have. The subject of the verb phrase is the value // being matched. For example, the DescribeTo() method of the Gt(7) // matcher prints "is greater than 7". virtual void DescribeTo(::std::ostream* os) const = 0; // Describes the negation of this matcher to an ostream. For // example, if the description of this matcher is "is greater than // 7", the negated description could be "is not greater than 7". // You are not required to override this when implementing // MatcherInterface, but it is highly advised so that your matcher // can produce good error messages. virtual void DescribeNegationTo(::std::ostream* os) const { *os << "not ("; DescribeTo(os); *os << ")"; } }; namespace internal { // A match result listener that ignores the explanation. class DummyMatchResultListener : public MatchResultListener { public: DummyMatchResultListener() : MatchResultListener(NULL) {} private: GTEST_DISALLOW_COPY_AND_ASSIGN_(DummyMatchResultListener); }; // A match result listener that forwards the explanation to a given // ostream. The difference between this and MatchResultListener is // that the former is concrete. class StreamMatchResultListener : public MatchResultListener { public: explicit StreamMatchResultListener(::std::ostream* os) : MatchResultListener(os) {} private: GTEST_DISALLOW_COPY_AND_ASSIGN_(StreamMatchResultListener); }; // A match result listener that stores the explanation in a string. class StringMatchResultListener : public MatchResultListener { public: StringMatchResultListener() : MatchResultListener(&ss_) {} // Returns the explanation heard so far. internal::string str() const { return ss_.str(); } private: ::std::stringstream ss_; GTEST_DISALLOW_COPY_AND_ASSIGN_(StringMatchResultListener); }; // An internal class for implementing Matcher, which will derive // from it. We put functionalities common to all Matcher // specializations here to avoid code duplication. template class MatcherBase { public: // Returns true iff the matcher matches x; also explains the match // result to 'listener'. bool MatchAndExplain(T x, MatchResultListener* listener) const { return impl_->MatchAndExplain(x, listener); } // Returns true iff this matcher matches x. bool Matches(T x) const { DummyMatchResultListener dummy; return MatchAndExplain(x, &dummy); } // Describes this matcher to an ostream. void DescribeTo(::std::ostream* os) const { impl_->DescribeTo(os); } // Describes the negation of this matcher to an ostream. void DescribeNegationTo(::std::ostream* os) const { impl_->DescribeNegationTo(os); } // Explains why x matches, or doesn't match, the matcher. void ExplainMatchResultTo(T x, ::std::ostream* os) const { StreamMatchResultListener listener(os); MatchAndExplain(x, &listener); } protected: MatcherBase() {} // Constructs a matcher from its implementation. explicit MatcherBase(const MatcherInterface* impl) : impl_(impl) {} virtual ~MatcherBase() {} private: // shared_ptr (util/gtl/shared_ptr.h) and linked_ptr have similar // interfaces. The former dynamically allocates a chunk of memory // to hold the reference count, while the latter tracks all // references using a circular linked list without allocating // memory. It has been observed that linked_ptr performs better in // typical scenarios. However, shared_ptr can out-perform // linked_ptr when there are many more uses of the copy constructor // than the default constructor. // // If performance becomes a problem, we should see if using // shared_ptr helps. ::testing::internal::linked_ptr > impl_; }; } // namespace internal // A Matcher is a copyable and IMMUTABLE (except by assignment) // object that can check whether a value of type T matches. The // implementation of Matcher is just a linked_ptr to const // MatcherInterface, so copying is fairly cheap. Don't inherit // from Matcher! template class Matcher : public internal::MatcherBase { public: // Constructs a null matcher. Needed for storing Matcher objects in STL // containers. A default-constructed matcher is not yet initialized. You // cannot use it until a valid value has been assigned to it. Matcher() {} // Constructs a matcher from its implementation. explicit Matcher(const MatcherInterface* impl) : internal::MatcherBase(impl) {} // Implicit constructor here allows people to write // EXPECT_CALL(foo, Bar(5)) instead of EXPECT_CALL(foo, Bar(Eq(5))) sometimes Matcher(T value); // NOLINT }; // The following two specializations allow the user to write str // instead of Eq(str) and "foo" instead of Eq("foo") when a string // matcher is expected. template <> class Matcher : public internal::MatcherBase { public: Matcher() {} explicit Matcher(const MatcherInterface* impl) : internal::MatcherBase(impl) {} // Allows the user to write str instead of Eq(str) sometimes, where // str is a string object. Matcher(const internal::string& s); // NOLINT // Allows the user to write "foo" instead of Eq("foo") sometimes. Matcher(const char* s); // NOLINT }; template <> class Matcher : public internal::MatcherBase { public: Matcher() {} explicit Matcher(const MatcherInterface* impl) : internal::MatcherBase(impl) {} // Allows the user to write str instead of Eq(str) sometimes, where // str is a string object. Matcher(const internal::string& s); // NOLINT // Allows the user to write "foo" instead of Eq("foo") sometimes. Matcher(const char* s); // NOLINT }; // The PolymorphicMatcher class template makes it easy to implement a // polymorphic matcher (i.e. a matcher that can match values of more // than one type, e.g. Eq(n) and NotNull()). // // To define a polymorphic matcher, a user should provide an Impl // class that has a DescribeTo() method and a DescribeNegationTo() // method, and define a member function (or member function template) // // bool MatchAndExplain(const Value& value, // MatchResultListener* listener) const; // // See the definition of NotNull() for a complete example. template class PolymorphicMatcher { public: explicit PolymorphicMatcher(const Impl& an_impl) : impl_(an_impl) {} // Returns a mutable reference to the underlying matcher // implementation object. Impl& mutable_impl() { return impl_; } // Returns an immutable reference to the underlying matcher // implementation object. const Impl& impl() const { return impl_; } template operator Matcher() const { return Matcher(new MonomorphicImpl(impl_)); } private: template class MonomorphicImpl : public MatcherInterface { public: explicit MonomorphicImpl(const Impl& impl) : impl_(impl) {} virtual void DescribeTo(::std::ostream* os) const { impl_.DescribeTo(os); } virtual void DescribeNegationTo(::std::ostream* os) const { impl_.DescribeNegationTo(os); } virtual bool MatchAndExplain(T x, MatchResultListener* listener) const { return impl_.MatchAndExplain(x, listener); } private: const Impl impl_; GTEST_DISALLOW_ASSIGN_(MonomorphicImpl); }; Impl impl_; GTEST_DISALLOW_ASSIGN_(PolymorphicMatcher); }; // Creates a matcher from its implementation. This is easier to use // than the Matcher constructor as it doesn't require you to // explicitly write the template argument, e.g. // // MakeMatcher(foo); // vs // Matcher(foo); template inline Matcher MakeMatcher(const MatcherInterface* impl) { return Matcher(impl); }; // Creates a polymorphic matcher from its implementation. This is // easier to use than the PolymorphicMatcher constructor as it // doesn't require you to explicitly write the template argument, e.g. // // MakePolymorphicMatcher(foo); // vs // PolymorphicMatcher(foo); template inline PolymorphicMatcher MakePolymorphicMatcher(const Impl& impl) { return PolymorphicMatcher(impl); } // In order to be safe and clear, casting between different matcher // types is done explicitly via MatcherCast(m), which takes a // matcher m and returns a Matcher. It compiles only when T can be // statically converted to the argument type of m. template Matcher MatcherCast(M m); // Implements SafeMatcherCast(). // // We use an intermediate class to do the actual safe casting as Nokia's // Symbian compiler cannot decide between // template ... (M) and // template ... (const Matcher&) // for function templates but can for member function templates. template class SafeMatcherCastImpl { public: // This overload handles polymorphic matchers only since monomorphic // matchers are handled by the next one. template static inline Matcher Cast(M polymorphic_matcher) { return Matcher(polymorphic_matcher); } // This overload handles monomorphic matchers. // // In general, if type T can be implicitly converted to type U, we can // safely convert a Matcher to a Matcher (i.e. Matcher is // contravariant): just keep a copy of the original Matcher, convert the // argument from type T to U, and then pass it to the underlying Matcher. // The only exception is when U is a reference and T is not, as the // underlying Matcher may be interested in the argument's address, which // is not preserved in the conversion from T to U. template static inline Matcher Cast(const Matcher& matcher) { // Enforce that T can be implicitly converted to U. GTEST_COMPILE_ASSERT_((internal::ImplicitlyConvertible::value), T_must_be_implicitly_convertible_to_U); // Enforce that we are not converting a non-reference type T to a reference // type U. GTEST_COMPILE_ASSERT_( internal::is_reference::value || !internal::is_reference::value, cannot_convert_non_referentce_arg_to_reference); // In case both T and U are arithmetic types, enforce that the // conversion is not lossy. typedef GTEST_REMOVE_REFERENCE_AND_CONST_(T) RawT; typedef GTEST_REMOVE_REFERENCE_AND_CONST_(U) RawU; const bool kTIsOther = GMOCK_KIND_OF_(RawT) == internal::kOther; const bool kUIsOther = GMOCK_KIND_OF_(RawU) == internal::kOther; GTEST_COMPILE_ASSERT_( kTIsOther || kUIsOther || (internal::LosslessArithmeticConvertible::value), conversion_of_arithmetic_types_must_be_lossless); return MatcherCast(matcher); } }; template inline Matcher SafeMatcherCast(const M& polymorphic_matcher) { return SafeMatcherCastImpl::Cast(polymorphic_matcher); } // A() returns a matcher that matches any value of type T. template Matcher A(); // Anything inside the 'internal' namespace IS INTERNAL IMPLEMENTATION // and MUST NOT BE USED IN USER CODE!!! namespace internal { // If the explanation is not empty, prints it to the ostream. inline void PrintIfNotEmpty(const internal::string& explanation, std::ostream* os) { if (explanation != "" && os != NULL) { *os << ", " << explanation; } } // Returns true if the given type name is easy to read by a human. // This is used to decide whether printing the type of a value might // be helpful. inline bool IsReadableTypeName(const string& type_name) { // We consider a type name readable if it's short or doesn't contain // a template or function type. return (type_name.length() <= 20 || type_name.find_first_of("<(") == string::npos); } // Matches the value against the given matcher, prints the value and explains // the match result to the listener. Returns the match result. // 'listener' must not be NULL. // Value cannot be passed by const reference, because some matchers take a // non-const argument. template bool MatchPrintAndExplain(Value& value, const Matcher& matcher, MatchResultListener* listener) { if (!listener->IsInterested()) { // If the listener is not interested, we do not need to construct the // inner explanation. return matcher.Matches(value); } StringMatchResultListener inner_listener; const bool match = matcher.MatchAndExplain(value, &inner_listener); UniversalPrint(value, listener->stream()); #if GTEST_HAS_RTTI const string& type_name = GetTypeName(); if (IsReadableTypeName(type_name)) *listener->stream() << " (of type " << type_name << ")"; #endif PrintIfNotEmpty(inner_listener.str(), listener->stream()); return match; } // An internal helper class for doing compile-time loop on a tuple's // fields. template class TuplePrefix { public: // TuplePrefix::Matches(matcher_tuple, value_tuple) returns true // iff the first N fields of matcher_tuple matches the first N // fields of value_tuple, respectively. template static bool Matches(const MatcherTuple& matcher_tuple, const ValueTuple& value_tuple) { using ::std::tr1::get; return TuplePrefix::Matches(matcher_tuple, value_tuple) && get(matcher_tuple).Matches(get(value_tuple)); } // TuplePrefix::ExplainMatchFailuresTo(matchers, values, os) // describes failures in matching the first N fields of matchers // against the first N fields of values. If there is no failure, // nothing will be streamed to os. template static void ExplainMatchFailuresTo(const MatcherTuple& matchers, const ValueTuple& values, ::std::ostream* os) { using ::std::tr1::tuple_element; using ::std::tr1::get; // First, describes failures in the first N - 1 fields. TuplePrefix::ExplainMatchFailuresTo(matchers, values, os); // Then describes the failure (if any) in the (N - 1)-th (0-based) // field. typename tuple_element::type matcher = get(matchers); typedef typename tuple_element::type Value; Value value = get(values); StringMatchResultListener listener; if (!matcher.MatchAndExplain(value, &listener)) { // TODO(wan): include in the message the name of the parameter // as used in MOCK_METHOD*() when possible. *os << " Expected arg #" << N - 1 << ": "; get(matchers).DescribeTo(os); *os << "\n Actual: "; // We remove the reference in type Value to prevent the // universal printer from printing the address of value, which // isn't interesting to the user most of the time. The // matcher's MatchAndExplain() method handles the case when // the address is interesting. internal::UniversalPrint(value, os); PrintIfNotEmpty(listener.str(), os); *os << "\n"; } } }; // The base case. template <> class TuplePrefix<0> { public: template static bool Matches(const MatcherTuple& /* matcher_tuple */, const ValueTuple& /* value_tuple */) { return true; } template static void ExplainMatchFailuresTo(const MatcherTuple& /* matchers */, const ValueTuple& /* values */, ::std::ostream* /* os */) {} }; // TupleMatches(matcher_tuple, value_tuple) returns true iff all // matchers in matcher_tuple match the corresponding fields in // value_tuple. It is a compiler error if matcher_tuple and // value_tuple have different number of fields or incompatible field // types. template bool TupleMatches(const MatcherTuple& matcher_tuple, const ValueTuple& value_tuple) { using ::std::tr1::tuple_size; // Makes sure that matcher_tuple and value_tuple have the same // number of fields. GTEST_COMPILE_ASSERT_(tuple_size::value == tuple_size::value, matcher_and_value_have_different_numbers_of_fields); return TuplePrefix::value>:: Matches(matcher_tuple, value_tuple); } // Describes failures in matching matchers against values. If there // is no failure, nothing will be streamed to os. template void ExplainMatchFailureTupleTo(const MatcherTuple& matchers, const ValueTuple& values, ::std::ostream* os) { using ::std::tr1::tuple_size; TuplePrefix::value>::ExplainMatchFailuresTo( matchers, values, os); } // The MatcherCastImpl class template is a helper for implementing // MatcherCast(). We need this helper in order to partially // specialize the implementation of MatcherCast() (C++ allows // class/struct templates to be partially specialized, but not // function templates.). // This general version is used when MatcherCast()'s argument is a // polymorphic matcher (i.e. something that can be converted to a // Matcher but is not one yet; for example, Eq(value)). template class MatcherCastImpl { public: static Matcher Cast(M polymorphic_matcher) { return Matcher(polymorphic_matcher); } }; // This more specialized version is used when MatcherCast()'s argument // is already a Matcher. This only compiles when type T can be // statically converted to type U. template class MatcherCastImpl > { public: static Matcher Cast(const Matcher& source_matcher) { return Matcher(new Impl(source_matcher)); } private: class Impl : public MatcherInterface { public: explicit Impl(const Matcher& source_matcher) : source_matcher_(source_matcher) {} // We delegate the matching logic to the source matcher. virtual bool MatchAndExplain(T x, MatchResultListener* listener) const { return source_matcher_.MatchAndExplain(static_cast(x), listener); } virtual void DescribeTo(::std::ostream* os) const { source_matcher_.DescribeTo(os); } virtual void DescribeNegationTo(::std::ostream* os) const { source_matcher_.DescribeNegationTo(os); } private: const Matcher source_matcher_; GTEST_DISALLOW_ASSIGN_(Impl); }; }; // This even more specialized version is used for efficiently casting // a matcher to its own type. template class MatcherCastImpl > { public: static Matcher Cast(const Matcher& matcher) { return matcher; } }; // Implements A(). template class AnyMatcherImpl : public MatcherInterface { public: virtual bool MatchAndExplain( T /* x */, MatchResultListener* /* listener */) const { return true; } virtual void DescribeTo(::std::ostream* os) const { *os << "is anything"; } virtual void DescribeNegationTo(::std::ostream* os) const { // This is mostly for completeness' safe, as it's not very useful // to write Not(A()). However we cannot completely rule out // such a possibility, and it doesn't hurt to be prepared. *os << "never matches"; } }; // Implements _, a matcher that matches any value of any // type. This is a polymorphic matcher, so we need a template type // conversion operator to make it appearing as a Matcher for any // type T. class AnythingMatcher { public: template operator Matcher() const { return A(); } }; // Implements a matcher that compares a given value with a // pre-supplied value using one of the ==, <=, <, etc, operators. The // two values being compared don't have to have the same type. // // The matcher defined here is polymorphic (for example, Eq(5) can be // used to match an int, a short, a double, etc). Therefore we use // a template type conversion operator in the implementation. // // We define this as a macro in order to eliminate duplicated source // code. // // The following template definition assumes that the Rhs parameter is // a "bare" type (i.e. neither 'const T' nor 'T&'). #define GMOCK_IMPLEMENT_COMPARISON_MATCHER_( \ name, op, relation, negated_relation) \ template class name##Matcher { \ public: \ explicit name##Matcher(const Rhs& rhs) : rhs_(rhs) {} \ template \ operator Matcher() const { \ return MakeMatcher(new Impl(rhs_)); \ } \ private: \ template \ class Impl : public MatcherInterface { \ public: \ explicit Impl(const Rhs& rhs) : rhs_(rhs) {} \ virtual bool MatchAndExplain(\ Lhs lhs, MatchResultListener* /* listener */) const { \ return lhs op rhs_; \ } \ virtual void DescribeTo(::std::ostream* os) const { \ *os << relation " "; \ UniversalPrint(rhs_, os); \ } \ virtual void DescribeNegationTo(::std::ostream* os) const { \ *os << negated_relation " "; \ UniversalPrint(rhs_, os); \ } \ private: \ Rhs rhs_; \ GTEST_DISALLOW_ASSIGN_(Impl); \ }; \ Rhs rhs_; \ GTEST_DISALLOW_ASSIGN_(name##Matcher); \ } // Implements Eq(v), Ge(v), Gt(v), Le(v), Lt(v), and Ne(v) // respectively. GMOCK_IMPLEMENT_COMPARISON_MATCHER_(Eq, ==, "is equal to", "isn't equal to"); GMOCK_IMPLEMENT_COMPARISON_MATCHER_(Ge, >=, "is >=", "isn't >="); GMOCK_IMPLEMENT_COMPARISON_MATCHER_(Gt, >, "is >", "isn't >"); GMOCK_IMPLEMENT_COMPARISON_MATCHER_(Le, <=, "is <=", "isn't <="); GMOCK_IMPLEMENT_COMPARISON_MATCHER_(Lt, <, "is <", "isn't <"); GMOCK_IMPLEMENT_COMPARISON_MATCHER_(Ne, !=, "isn't equal to", "is equal to"); #undef GMOCK_IMPLEMENT_COMPARISON_MATCHER_ // Implements the polymorphic IsNull() matcher, which matches any raw or smart // pointer that is NULL. class IsNullMatcher { public: template bool MatchAndExplain(const Pointer& p, MatchResultListener* /* listener */) const { return GetRawPointer(p) == NULL; } void DescribeTo(::std::ostream* os) const { *os << "is NULL"; } void DescribeNegationTo(::std::ostream* os) const { *os << "isn't NULL"; } }; // Implements the polymorphic NotNull() matcher, which matches any raw or smart // pointer that is not NULL. class NotNullMatcher { public: template bool MatchAndExplain(const Pointer& p, MatchResultListener* /* listener */) const { return GetRawPointer(p) != NULL; } void DescribeTo(::std::ostream* os) const { *os << "isn't NULL"; } void DescribeNegationTo(::std::ostream* os) const { *os << "is NULL"; } }; // Ref(variable) matches any argument that is a reference to // 'variable'. This matcher is polymorphic as it can match any // super type of the type of 'variable'. // // The RefMatcher template class implements Ref(variable). It can // only be instantiated with a reference type. This prevents a user // from mistakenly using Ref(x) to match a non-reference function // argument. For example, the following will righteously cause a // compiler error: // // int n; // Matcher m1 = Ref(n); // This won't compile. // Matcher m2 = Ref(n); // This will compile. template class RefMatcher; template class RefMatcher { // Google Mock is a generic framework and thus needs to support // mocking any function types, including those that take non-const // reference arguments. Therefore the template parameter T (and // Super below) can be instantiated to either a const type or a // non-const type. public: // RefMatcher() takes a T& instead of const T&, as we want the // compiler to catch using Ref(const_value) as a matcher for a // non-const reference. explicit RefMatcher(T& x) : object_(x) {} // NOLINT template operator Matcher() const { // By passing object_ (type T&) to Impl(), which expects a Super&, // we make sure that Super is a super type of T. In particular, // this catches using Ref(const_value) as a matcher for a // non-const reference, as you cannot implicitly convert a const // reference to a non-const reference. return MakeMatcher(new Impl(object_)); } private: template class Impl : public MatcherInterface { public: explicit Impl(Super& x) : object_(x) {} // NOLINT // MatchAndExplain() takes a Super& (as opposed to const Super&) // in order to match the interface MatcherInterface. virtual bool MatchAndExplain( Super& x, MatchResultListener* listener) const { *listener << "which is located @" << static_cast(&x); return &x == &object_; } virtual void DescribeTo(::std::ostream* os) const { *os << "references the variable "; UniversalPrinter::Print(object_, os); } virtual void DescribeNegationTo(::std::ostream* os) const { *os << "does not reference the variable "; UniversalPrinter::Print(object_, os); } private: const Super& object_; GTEST_DISALLOW_ASSIGN_(Impl); }; T& object_; GTEST_DISALLOW_ASSIGN_(RefMatcher); }; // Polymorphic helper functions for narrow and wide string matchers. inline bool CaseInsensitiveCStringEquals(const char* lhs, const char* rhs) { return String::CaseInsensitiveCStringEquals(lhs, rhs); } inline bool CaseInsensitiveCStringEquals(const wchar_t* lhs, const wchar_t* rhs) { return String::CaseInsensitiveWideCStringEquals(lhs, rhs); } // String comparison for narrow or wide strings that can have embedded NUL // characters. template bool CaseInsensitiveStringEquals(const StringType& s1, const StringType& s2) { // Are the heads equal? if (!CaseInsensitiveCStringEquals(s1.c_str(), s2.c_str())) { return false; } // Skip the equal heads. const typename StringType::value_type nul = 0; const size_t i1 = s1.find(nul), i2 = s2.find(nul); // Are we at the end of either s1 or s2? if (i1 == StringType::npos || i2 == StringType::npos) { return i1 == i2; } // Are the tails equal? return CaseInsensitiveStringEquals(s1.substr(i1 + 1), s2.substr(i2 + 1)); } // String matchers. // Implements equality-based string matchers like StrEq, StrCaseNe, and etc. template class StrEqualityMatcher { public: typedef typename StringType::const_pointer ConstCharPointer; StrEqualityMatcher(const StringType& str, bool expect_eq, bool case_sensitive) : string_(str), expect_eq_(expect_eq), case_sensitive_(case_sensitive) {} // When expect_eq_ is true, returns true iff s is equal to string_; // otherwise returns true iff s is not equal to string_. bool MatchAndExplain(ConstCharPointer s, MatchResultListener* listener) const { if (s == NULL) { return !expect_eq_; } return MatchAndExplain(StringType(s), listener); } bool MatchAndExplain(const StringType& s, MatchResultListener* /* listener */) const { const bool eq = case_sensitive_ ? s == string_ : CaseInsensitiveStringEquals(s, string_); return expect_eq_ == eq; } void DescribeTo(::std::ostream* os) const { DescribeToHelper(expect_eq_, os); } void DescribeNegationTo(::std::ostream* os) const { DescribeToHelper(!expect_eq_, os); } private: void DescribeToHelper(bool expect_eq, ::std::ostream* os) const { *os << (expect_eq ? "is " : "isn't "); *os << "equal to "; if (!case_sensitive_) { *os << "(ignoring case) "; } UniversalPrint(string_, os); } const StringType string_; const bool expect_eq_; const bool case_sensitive_; GTEST_DISALLOW_ASSIGN_(StrEqualityMatcher); }; // Implements the polymorphic HasSubstr(substring) matcher, which // can be used as a Matcher as long as T can be converted to a // string. template class HasSubstrMatcher { public: typedef typename StringType::const_pointer ConstCharPointer; explicit HasSubstrMatcher(const StringType& substring) : substring_(substring) {} // These overloaded methods allow HasSubstr(substring) to be used as a // Matcher as long as T can be converted to string. Returns true // iff s contains substring_ as a substring. bool MatchAndExplain(ConstCharPointer s, MatchResultListener* listener) const { return s != NULL && MatchAndExplain(StringType(s), listener); } bool MatchAndExplain(const StringType& s, MatchResultListener* /* listener */) const { return s.find(substring_) != StringType::npos; } // Describes what this matcher matches. void DescribeTo(::std::ostream* os) const { *os << "has substring "; UniversalPrint(substring_, os); } void DescribeNegationTo(::std::ostream* os) const { *os << "has no substring "; UniversalPrint(substring_, os); } private: const StringType substring_; GTEST_DISALLOW_ASSIGN_(HasSubstrMatcher); }; // Implements the polymorphic StartsWith(substring) matcher, which // can be used as a Matcher as long as T can be converted to a // string. template class StartsWithMatcher { public: typedef typename StringType::const_pointer ConstCharPointer; explicit StartsWithMatcher(const StringType& prefix) : prefix_(prefix) { } // These overloaded methods allow StartsWith(prefix) to be used as a // Matcher as long as T can be converted to string. Returns true // iff s starts with prefix_. bool MatchAndExplain(ConstCharPointer s, MatchResultListener* listener) const { return s != NULL && MatchAndExplain(StringType(s), listener); } bool MatchAndExplain(const StringType& s, MatchResultListener* /* listener */) const { return s.length() >= prefix_.length() && s.substr(0, prefix_.length()) == prefix_; } void DescribeTo(::std::ostream* os) const { *os << "starts with "; UniversalPrint(prefix_, os); } void DescribeNegationTo(::std::ostream* os) const { *os << "doesn't start with "; UniversalPrint(prefix_, os); } private: const StringType prefix_; GTEST_DISALLOW_ASSIGN_(StartsWithMatcher); }; // Implements the polymorphic EndsWith(substring) matcher, which // can be used as a Matcher as long as T can be converted to a // string. template class EndsWithMatcher { public: typedef typename StringType::const_pointer ConstCharPointer; explicit EndsWithMatcher(const StringType& suffix) : suffix_(suffix) {} // These overloaded methods allow EndsWith(suffix) to be used as a // Matcher as long as T can be converted to string. Returns true // iff s ends with suffix_. bool MatchAndExplain(ConstCharPointer s, MatchResultListener* listener) const { return s != NULL && MatchAndExplain(StringType(s), listener); } bool MatchAndExplain(const StringType& s, MatchResultListener* /* listener */) const { return s.length() >= suffix_.length() && s.substr(s.length() - suffix_.length()) == suffix_; } void DescribeTo(::std::ostream* os) const { *os << "ends with "; UniversalPrint(suffix_, os); } void DescribeNegationTo(::std::ostream* os) const { *os << "doesn't end with "; UniversalPrint(suffix_, os); } private: const StringType suffix_; GTEST_DISALLOW_ASSIGN_(EndsWithMatcher); }; // Implements polymorphic matchers MatchesRegex(regex) and // ContainsRegex(regex), which can be used as a Matcher as long as // T can be converted to a string. class MatchesRegexMatcher { public: MatchesRegexMatcher(const RE* regex, bool full_match) : regex_(regex), full_match_(full_match) {} // These overloaded methods allow MatchesRegex(regex) to be used as // a Matcher as long as T can be converted to string. Returns // true iff s matches regular expression regex. When full_match_ is // true, a full match is done; otherwise a partial match is done. bool MatchAndExplain(const char* s, MatchResultListener* listener) const { return s != NULL && MatchAndExplain(internal::string(s), listener); } bool MatchAndExplain(const internal::string& s, MatchResultListener* /* listener */) const { return full_match_ ? RE::FullMatch(s, *regex_) : RE::PartialMatch(s, *regex_); } void DescribeTo(::std::ostream* os) const { *os << (full_match_ ? "matches" : "contains") << " regular expression "; UniversalPrinter::Print(regex_->pattern(), os); } void DescribeNegationTo(::std::ostream* os) const { *os << "doesn't " << (full_match_ ? "match" : "contain") << " regular expression "; UniversalPrinter::Print(regex_->pattern(), os); } private: const internal::linked_ptr regex_; const bool full_match_; GTEST_DISALLOW_ASSIGN_(MatchesRegexMatcher); }; // Implements a matcher that compares the two fields of a 2-tuple // using one of the ==, <=, <, etc, operators. The two fields being // compared don't have to have the same type. // // The matcher defined here is polymorphic (for example, Eq() can be // used to match a tuple, a tuple, // etc). Therefore we use a template type conversion operator in the // implementation. // // We define this as a macro in order to eliminate duplicated source // code. #define GMOCK_IMPLEMENT_COMPARISON2_MATCHER_(name, op, relation) \ class name##2Matcher { \ public: \ template \ operator Matcher< ::std::tr1::tuple >() const { \ return MakeMatcher(new Impl< ::std::tr1::tuple >); \ } \ template \ operator Matcher&>() const { \ return MakeMatcher(new Impl&>); \ } \ private: \ template \ class Impl : public MatcherInterface { \ public: \ virtual bool MatchAndExplain( \ Tuple args, \ MatchResultListener* /* listener */) const { \ return ::std::tr1::get<0>(args) op ::std::tr1::get<1>(args); \ } \ virtual void DescribeTo(::std::ostream* os) const { \ *os << "are " relation; \ } \ virtual void DescribeNegationTo(::std::ostream* os) const { \ *os << "aren't " relation; \ } \ }; \ } // Implements Eq(), Ge(), Gt(), Le(), Lt(), and Ne() respectively. GMOCK_IMPLEMENT_COMPARISON2_MATCHER_(Eq, ==, "an equal pair"); GMOCK_IMPLEMENT_COMPARISON2_MATCHER_( Ge, >=, "a pair where the first >= the second"); GMOCK_IMPLEMENT_COMPARISON2_MATCHER_( Gt, >, "a pair where the first > the second"); GMOCK_IMPLEMENT_COMPARISON2_MATCHER_( Le, <=, "a pair where the first <= the second"); GMOCK_IMPLEMENT_COMPARISON2_MATCHER_( Lt, <, "a pair where the first < the second"); GMOCK_IMPLEMENT_COMPARISON2_MATCHER_(Ne, !=, "an unequal pair"); #undef GMOCK_IMPLEMENT_COMPARISON2_MATCHER_ // Implements the Not(...) matcher for a particular argument type T. // We do not nest it inside the NotMatcher class template, as that // will prevent different instantiations of NotMatcher from sharing // the same NotMatcherImpl class. template class NotMatcherImpl : public MatcherInterface { public: explicit NotMatcherImpl(const Matcher& matcher) : matcher_(matcher) {} virtual bool MatchAndExplain(T x, MatchResultListener* listener) const { return !matcher_.MatchAndExplain(x, listener); } virtual void DescribeTo(::std::ostream* os) const { matcher_.DescribeNegationTo(os); } virtual void DescribeNegationTo(::std::ostream* os) const { matcher_.DescribeTo(os); } private: const Matcher matcher_; GTEST_DISALLOW_ASSIGN_(NotMatcherImpl); }; // Implements the Not(m) matcher, which matches a value that doesn't // match matcher m. template class NotMatcher { public: explicit NotMatcher(InnerMatcher matcher) : matcher_(matcher) {} // This template type conversion operator allows Not(m) to be used // to match any type m can match. template operator Matcher() const { return Matcher(new NotMatcherImpl(SafeMatcherCast(matcher_))); } private: InnerMatcher matcher_; GTEST_DISALLOW_ASSIGN_(NotMatcher); }; // Implements the AllOf(m1, m2) matcher for a particular argument type // T. We do not nest it inside the BothOfMatcher class template, as // that will prevent different instantiations of BothOfMatcher from // sharing the same BothOfMatcherImpl class. template class BothOfMatcherImpl : public MatcherInterface { public: BothOfMatcherImpl(const Matcher& matcher1, const Matcher& matcher2) : matcher1_(matcher1), matcher2_(matcher2) {} virtual void DescribeTo(::std::ostream* os) const { *os << "("; matcher1_.DescribeTo(os); *os << ") and ("; matcher2_.DescribeTo(os); *os << ")"; } virtual void DescribeNegationTo(::std::ostream* os) const { *os << "("; matcher1_.DescribeNegationTo(os); *os << ") or ("; matcher2_.DescribeNegationTo(os); *os << ")"; } virtual bool MatchAndExplain(T x, MatchResultListener* listener) const { // If either matcher1_ or matcher2_ doesn't match x, we only need // to explain why one of them fails. StringMatchResultListener listener1; if (!matcher1_.MatchAndExplain(x, &listener1)) { *listener << listener1.str(); return false; } StringMatchResultListener listener2; if (!matcher2_.MatchAndExplain(x, &listener2)) { *listener << listener2.str(); return false; } // Otherwise we need to explain why *both* of them match. const internal::string s1 = listener1.str(); const internal::string s2 = listener2.str(); if (s1 == "") { *listener << s2; } else { *listener << s1; if (s2 != "") { *listener << ", and " << s2; } } return true; } private: const Matcher matcher1_; const Matcher matcher2_; GTEST_DISALLOW_ASSIGN_(BothOfMatcherImpl); }; // Used for implementing the AllOf(m_1, ..., m_n) matcher, which // matches a value that matches all of the matchers m_1, ..., and m_n. template class BothOfMatcher { public: BothOfMatcher(Matcher1 matcher1, Matcher2 matcher2) : matcher1_(matcher1), matcher2_(matcher2) {} // This template type conversion operator allows a // BothOfMatcher object to match any type that // both Matcher1 and Matcher2 can match. template operator Matcher() const { return Matcher(new BothOfMatcherImpl(SafeMatcherCast(matcher1_), SafeMatcherCast(matcher2_))); } private: Matcher1 matcher1_; Matcher2 matcher2_; GTEST_DISALLOW_ASSIGN_(BothOfMatcher); }; // Implements the AnyOf(m1, m2) matcher for a particular argument type // T. We do not nest it inside the AnyOfMatcher class template, as // that will prevent different instantiations of AnyOfMatcher from // sharing the same EitherOfMatcherImpl class. template class EitherOfMatcherImpl : public MatcherInterface { public: EitherOfMatcherImpl(const Matcher& matcher1, const Matcher& matcher2) : matcher1_(matcher1), matcher2_(matcher2) {} virtual void DescribeTo(::std::ostream* os) const { *os << "("; matcher1_.DescribeTo(os); *os << ") or ("; matcher2_.DescribeTo(os); *os << ")"; } virtual void DescribeNegationTo(::std::ostream* os) const { *os << "("; matcher1_.DescribeNegationTo(os); *os << ") and ("; matcher2_.DescribeNegationTo(os); *os << ")"; } virtual bool MatchAndExplain(T x, MatchResultListener* listener) const { // If either matcher1_ or matcher2_ matches x, we just need to // explain why *one* of them matches. StringMatchResultListener listener1; if (matcher1_.MatchAndExplain(x, &listener1)) { *listener << listener1.str(); return true; } StringMatchResultListener listener2; if (matcher2_.MatchAndExplain(x, &listener2)) { *listener << listener2.str(); return true; } // Otherwise we need to explain why *both* of them fail. const internal::string s1 = listener1.str(); const internal::string s2 = listener2.str(); if (s1 == "") { *listener << s2; } else { *listener << s1; if (s2 != "") { *listener << ", and " << s2; } } return false; } private: const Matcher matcher1_; const Matcher matcher2_; GTEST_DISALLOW_ASSIGN_(EitherOfMatcherImpl); }; // Used for implementing the AnyOf(m_1, ..., m_n) matcher, which // matches a value that matches at least one of the matchers m_1, ..., // and m_n. template class EitherOfMatcher { public: EitherOfMatcher(Matcher1 matcher1, Matcher2 matcher2) : matcher1_(matcher1), matcher2_(matcher2) {} // This template type conversion operator allows a // EitherOfMatcher object to match any type that // both Matcher1 and Matcher2 can match. template operator Matcher() const { return Matcher(new EitherOfMatcherImpl( SafeMatcherCast(matcher1_), SafeMatcherCast(matcher2_))); } private: Matcher1 matcher1_; Matcher2 matcher2_; GTEST_DISALLOW_ASSIGN_(EitherOfMatcher); }; // Used for implementing Truly(pred), which turns a predicate into a // matcher. template class TrulyMatcher { public: explicit TrulyMatcher(Predicate pred) : predicate_(pred) {} // This method template allows Truly(pred) to be used as a matcher // for type T where T is the argument type of predicate 'pred'. The // argument is passed by reference as the predicate may be // interested in the address of the argument. template bool MatchAndExplain(T& x, // NOLINT MatchResultListener* /* listener */) const { // Without the if-statement, MSVC sometimes warns about converting // a value to bool (warning 4800). // // We cannot write 'return !!predicate_(x);' as that doesn't work // when predicate_(x) returns a class convertible to bool but // having no operator!(). if (predicate_(x)) return true; return false; } void DescribeTo(::std::ostream* os) const { *os << "satisfies the given predicate"; } void DescribeNegationTo(::std::ostream* os) const { *os << "doesn't satisfy the given predicate"; } private: Predicate predicate_; GTEST_DISALLOW_ASSIGN_(TrulyMatcher); }; // Used for implementing Matches(matcher), which turns a matcher into // a predicate. template class MatcherAsPredicate { public: explicit MatcherAsPredicate(M matcher) : matcher_(matcher) {} // This template operator() allows Matches(m) to be used as a // predicate on type T where m is a matcher on type T. // // The argument x is passed by reference instead of by value, as // some matcher may be interested in its address (e.g. as in // Matches(Ref(n))(x)). template bool operator()(const T& x) const { // We let matcher_ commit to a particular type here instead of // when the MatcherAsPredicate object was constructed. This // allows us to write Matches(m) where m is a polymorphic matcher // (e.g. Eq(5)). // // If we write Matcher(matcher_).Matches(x) here, it won't // compile when matcher_ has type Matcher; if we write // Matcher(matcher_).Matches(x) here, it won't compile // when matcher_ has type Matcher; if we just write // matcher_.Matches(x), it won't compile when matcher_ is // polymorphic, e.g. Eq(5). // // MatcherCast() is necessary for making the code work // in all of the above situations. return MatcherCast(matcher_).Matches(x); } private: M matcher_; GTEST_DISALLOW_ASSIGN_(MatcherAsPredicate); }; // For implementing ASSERT_THAT() and EXPECT_THAT(). The template // argument M must be a type that can be converted to a matcher. template class PredicateFormatterFromMatcher { public: explicit PredicateFormatterFromMatcher(const M& m) : matcher_(m) {} // This template () operator allows a PredicateFormatterFromMatcher // object to act as a predicate-formatter suitable for using with // Google Test's EXPECT_PRED_FORMAT1() macro. template AssertionResult operator()(const char* value_text, const T& x) const { // We convert matcher_ to a Matcher *now* instead of // when the PredicateFormatterFromMatcher object was constructed, // as matcher_ may be polymorphic (e.g. NotNull()) and we won't // know which type to instantiate it to until we actually see the // type of x here. // // We write MatcherCast(matcher_) instead of // Matcher(matcher_), as the latter won't compile when // matcher_ has type Matcher (e.g. An()). const Matcher matcher = MatcherCast(matcher_); StringMatchResultListener listener; if (MatchPrintAndExplain(x, matcher, &listener)) return AssertionSuccess(); ::std::stringstream ss; ss << "Value of: " << value_text << "\n" << "Expected: "; matcher.DescribeTo(&ss); ss << "\n Actual: " << listener.str(); return AssertionFailure() << ss.str(); } private: const M matcher_; GTEST_DISALLOW_ASSIGN_(PredicateFormatterFromMatcher); }; // A helper function for converting a matcher to a predicate-formatter // without the user needing to explicitly write the type. This is // used for implementing ASSERT_THAT() and EXPECT_THAT(). template inline PredicateFormatterFromMatcher MakePredicateFormatterFromMatcher(const M& matcher) { return PredicateFormatterFromMatcher(matcher); } // Implements the polymorphic floating point equality matcher, which // matches two float values using ULP-based approximation. The // template is meant to be instantiated with FloatType being either // float or double. template class FloatingEqMatcher { public: // Constructor for FloatingEqMatcher. // The matcher's input will be compared with rhs. The matcher treats two // NANs as equal if nan_eq_nan is true. Otherwise, under IEEE standards, // equality comparisons between NANs will always return false. FloatingEqMatcher(FloatType rhs, bool nan_eq_nan) : rhs_(rhs), nan_eq_nan_(nan_eq_nan) {} // Implements floating point equality matcher as a Matcher. template class Impl : public MatcherInterface { public: Impl(FloatType rhs, bool nan_eq_nan) : rhs_(rhs), nan_eq_nan_(nan_eq_nan) {} virtual bool MatchAndExplain(T value, MatchResultListener* /* listener */) const { const FloatingPoint lhs(value), rhs(rhs_); // Compares NaNs first, if nan_eq_nan_ is true. if (nan_eq_nan_ && lhs.is_nan()) { return rhs.is_nan(); } return lhs.AlmostEquals(rhs); } virtual void DescribeTo(::std::ostream* os) const { // os->precision() returns the previously set precision, which we // store to restore the ostream to its original configuration // after outputting. const ::std::streamsize old_precision = os->precision( ::std::numeric_limits::digits10 + 2); if (FloatingPoint(rhs_).is_nan()) { if (nan_eq_nan_) { *os << "is NaN"; } else { *os << "never matches"; } } else { *os << "is approximately " << rhs_; } os->precision(old_precision); } virtual void DescribeNegationTo(::std::ostream* os) const { // As before, get original precision. const ::std::streamsize old_precision = os->precision( ::std::numeric_limits::digits10 + 2); if (FloatingPoint(rhs_).is_nan()) { if (nan_eq_nan_) { *os << "isn't NaN"; } else { *os << "is anything"; } } else { *os << "isn't approximately " << rhs_; } // Restore original precision. os->precision(old_precision); } private: const FloatType rhs_; const bool nan_eq_nan_; GTEST_DISALLOW_ASSIGN_(Impl); }; // The following 3 type conversion operators allow FloatEq(rhs) and // NanSensitiveFloatEq(rhs) to be used as a Matcher, a // Matcher, or a Matcher, but nothing else. // (While Google's C++ coding style doesn't allow arguments passed // by non-const reference, we may see them in code not conforming to // the style. Therefore Google Mock needs to support them.) operator Matcher() const { return MakeMatcher(new Impl(rhs_, nan_eq_nan_)); } operator Matcher() const { return MakeMatcher(new Impl(rhs_, nan_eq_nan_)); } operator Matcher() const { return MakeMatcher(new Impl(rhs_, nan_eq_nan_)); } private: const FloatType rhs_; const bool nan_eq_nan_; GTEST_DISALLOW_ASSIGN_(FloatingEqMatcher); }; // Implements the Pointee(m) matcher for matching a pointer whose // pointee matches matcher m. The pointer can be either raw or smart. template class PointeeMatcher { public: explicit PointeeMatcher(const InnerMatcher& matcher) : matcher_(matcher) {} // This type conversion operator template allows Pointee(m) to be // used as a matcher for any pointer type whose pointee type is // compatible with the inner matcher, where type Pointer can be // either a raw pointer or a smart pointer. // // The reason we do this instead of relying on // MakePolymorphicMatcher() is that the latter is not flexible // enough for implementing the DescribeTo() method of Pointee(). template operator Matcher() const { return MakeMatcher(new Impl(matcher_)); } private: // The monomorphic implementation that works for a particular pointer type. template class Impl : public MatcherInterface { public: typedef typename PointeeOf::type Pointee; explicit Impl(const InnerMatcher& matcher) : matcher_(MatcherCast(matcher)) {} virtual void DescribeTo(::std::ostream* os) const { *os << "points to a value that "; matcher_.DescribeTo(os); } virtual void DescribeNegationTo(::std::ostream* os) const { *os << "does not point to a value that "; matcher_.DescribeTo(os); } virtual bool MatchAndExplain(Pointer pointer, MatchResultListener* listener) const { if (GetRawPointer(pointer) == NULL) return false; *listener << "which points to "; return MatchPrintAndExplain(*pointer, matcher_, listener); } private: const Matcher matcher_; GTEST_DISALLOW_ASSIGN_(Impl); }; const InnerMatcher matcher_; GTEST_DISALLOW_ASSIGN_(PointeeMatcher); }; // Implements the Field() matcher for matching a field (i.e. member // variable) of an object. template class FieldMatcher { public: FieldMatcher(FieldType Class::*field, const Matcher& matcher) : field_(field), matcher_(matcher) {} void DescribeTo(::std::ostream* os) const { *os << "is an object whose given field "; matcher_.DescribeTo(os); } void DescribeNegationTo(::std::ostream* os) const { *os << "is an object whose given field "; matcher_.DescribeNegationTo(os); } template bool MatchAndExplain(const T& value, MatchResultListener* listener) const { return MatchAndExplainImpl( typename ::testing::internal:: is_pointer::type(), value, listener); } private: // The first argument of MatchAndExplainImpl() is needed to help // Symbian's C++ compiler choose which overload to use. Its type is // true_type iff the Field() matcher is used to match a pointer. bool MatchAndExplainImpl(false_type /* is_not_pointer */, const Class& obj, MatchResultListener* listener) const { *listener << "whose given field is "; return MatchPrintAndExplain(obj.*field_, matcher_, listener); } bool MatchAndExplainImpl(true_type /* is_pointer */, const Class* p, MatchResultListener* listener) const { if (p == NULL) return false; *listener << "which points to an object "; // Since *p has a field, it must be a class/struct/union type and // thus cannot be a pointer. Therefore we pass false_type() as // the first argument. return MatchAndExplainImpl(false_type(), *p, listener); } const FieldType Class::*field_; const Matcher matcher_; GTEST_DISALLOW_ASSIGN_(FieldMatcher); }; // Implements the Property() matcher for matching a property // (i.e. return value of a getter method) of an object. template class PropertyMatcher { public: // The property may have a reference type, so 'const PropertyType&' // may cause double references and fail to compile. That's why we // need GTEST_REFERENCE_TO_CONST, which works regardless of // PropertyType being a reference or not. typedef GTEST_REFERENCE_TO_CONST_(PropertyType) RefToConstProperty; PropertyMatcher(PropertyType (Class::*property)() const, const Matcher& matcher) : property_(property), matcher_(matcher) {} void DescribeTo(::std::ostream* os) const { *os << "is an object whose given property "; matcher_.DescribeTo(os); } void DescribeNegationTo(::std::ostream* os) const { *os << "is an object whose given property "; matcher_.DescribeNegationTo(os); } template bool MatchAndExplain(const T&value, MatchResultListener* listener) const { return MatchAndExplainImpl( typename ::testing::internal:: is_pointer::type(), value, listener); } private: // The first argument of MatchAndExplainImpl() is needed to help // Symbian's C++ compiler choose which overload to use. Its type is // true_type iff the Property() matcher is used to match a pointer. bool MatchAndExplainImpl(false_type /* is_not_pointer */, const Class& obj, MatchResultListener* listener) const { *listener << "whose given property is "; // Cannot pass the return value (for example, int) to MatchPrintAndExplain, // which takes a non-const reference as argument. RefToConstProperty result = (obj.*property_)(); return MatchPrintAndExplain(result, matcher_, listener); } bool MatchAndExplainImpl(true_type /* is_pointer */, const Class* p, MatchResultListener* listener) const { if (p == NULL) return false; *listener << "which points to an object "; // Since *p has a property method, it must be a class/struct/union // type and thus cannot be a pointer. Therefore we pass // false_type() as the first argument. return MatchAndExplainImpl(false_type(), *p, listener); } PropertyType (Class::*property_)() const; const Matcher matcher_; GTEST_DISALLOW_ASSIGN_(PropertyMatcher); }; // Type traits specifying various features of different functors for ResultOf. // The default template specifies features for functor objects. // Functor classes have to typedef argument_type and result_type // to be compatible with ResultOf. template struct CallableTraits { typedef typename Functor::result_type ResultType; typedef Functor StorageType; static void CheckIsValid(Functor /* functor */) {} template static ResultType Invoke(Functor f, T arg) { return f(arg); } }; // Specialization for function pointers. template struct CallableTraits { typedef ResType ResultType; typedef ResType(*StorageType)(ArgType); static void CheckIsValid(ResType(*f)(ArgType)) { GTEST_CHECK_(f != NULL) << "NULL function pointer is passed into ResultOf()."; } template static ResType Invoke(ResType(*f)(ArgType), T arg) { return (*f)(arg); } }; // Implements the ResultOf() matcher for matching a return value of a // unary function of an object. template class ResultOfMatcher { public: typedef typename CallableTraits::ResultType ResultType; ResultOfMatcher(Callable callable, const Matcher& matcher) : callable_(callable), matcher_(matcher) { CallableTraits::CheckIsValid(callable_); } template operator Matcher() const { return Matcher(new Impl(callable_, matcher_)); } private: typedef typename CallableTraits::StorageType CallableStorageType; template class Impl : public MatcherInterface { public: Impl(CallableStorageType callable, const Matcher& matcher) : callable_(callable), matcher_(matcher) {} virtual void DescribeTo(::std::ostream* os) const { *os << "is mapped by the given callable to a value that "; matcher_.DescribeTo(os); } virtual void DescribeNegationTo(::std::ostream* os) const { *os << "is mapped by the given callable to a value that "; matcher_.DescribeNegationTo(os); } virtual bool MatchAndExplain(T obj, MatchResultListener* listener) const { *listener << "which is mapped by the given callable to "; // Cannot pass the return value (for example, int) to // MatchPrintAndExplain, which takes a non-const reference as argument. ResultType result = CallableTraits::template Invoke(callable_, obj); return MatchPrintAndExplain(result, matcher_, listener); } private: // Functors often define operator() as non-const method even though // they are actualy stateless. But we need to use them even when // 'this' is a const pointer. It's the user's responsibility not to // use stateful callables with ResultOf(), which does't guarantee // how many times the callable will be invoked. mutable CallableStorageType callable_; const Matcher matcher_; GTEST_DISALLOW_ASSIGN_(Impl); }; // class Impl const CallableStorageType callable_; const Matcher matcher_; GTEST_DISALLOW_ASSIGN_(ResultOfMatcher); }; // Implements an equality matcher for any STL-style container whose elements // support ==. This matcher is like Eq(), but its failure explanations provide // more detailed information that is useful when the container is used as a set. // The failure message reports elements that are in one of the operands but not // the other. The failure messages do not report duplicate or out-of-order // elements in the containers (which don't properly matter to sets, but can // occur if the containers are vectors or lists, for example). // // Uses the container's const_iterator, value_type, operator ==, // begin(), and end(). template class ContainerEqMatcher { public: typedef internal::StlContainerView View; typedef typename View::type StlContainer; typedef typename View::const_reference StlContainerReference; // We make a copy of rhs in case the elements in it are modified // after this matcher is created. explicit ContainerEqMatcher(const Container& rhs) : rhs_(View::Copy(rhs)) { // Makes sure the user doesn't instantiate this class template // with a const or reference type. (void)testing::StaticAssertTypeEq(); } void DescribeTo(::std::ostream* os) const { *os << "equals "; UniversalPrint(rhs_, os); } void DescribeNegationTo(::std::ostream* os) const { *os << "does not equal "; UniversalPrint(rhs_, os); } template bool MatchAndExplain(const LhsContainer& lhs, MatchResultListener* listener) const { // GTEST_REMOVE_CONST_() is needed to work around an MSVC 8.0 bug // that causes LhsContainer to be a const type sometimes. typedef internal::StlContainerView LhsView; typedef typename LhsView::type LhsStlContainer; StlContainerReference lhs_stl_container = LhsView::ConstReference(lhs); if (lhs_stl_container == rhs_) return true; ::std::ostream* const os = listener->stream(); if (os != NULL) { // Something is different. Check for extra values first. bool printed_header = false; for (typename LhsStlContainer::const_iterator it = lhs_stl_container.begin(); it != lhs_stl_container.end(); ++it) { if (internal::ArrayAwareFind(rhs_.begin(), rhs_.end(), *it) == rhs_.end()) { if (printed_header) { *os << ", "; } else { *os << "which has these unexpected elements: "; printed_header = true; } UniversalPrint(*it, os); } } // Now check for missing values. bool printed_header2 = false; for (typename StlContainer::const_iterator it = rhs_.begin(); it != rhs_.end(); ++it) { if (internal::ArrayAwareFind( lhs_stl_container.begin(), lhs_stl_container.end(), *it) == lhs_stl_container.end()) { if (printed_header2) { *os << ", "; } else { *os << (printed_header ? ",\nand" : "which") << " doesn't have these expected elements: "; printed_header2 = true; } UniversalPrint(*it, os); } } } return false; } private: const StlContainer rhs_; GTEST_DISALLOW_ASSIGN_(ContainerEqMatcher); }; // Implements Pointwise(tuple_matcher, rhs_container). tuple_matcher // must be able to be safely cast to Matcher >, where T1 and T2 are the types of elements in the LHS // container and the RHS container respectively. template class PointwiseMatcher { public: typedef internal::StlContainerView RhsView; typedef typename RhsView::type RhsStlContainer; typedef typename RhsStlContainer::value_type RhsValue; // Like ContainerEq, we make a copy of rhs in case the elements in // it are modified after this matcher is created. PointwiseMatcher(const TupleMatcher& tuple_matcher, const RhsContainer& rhs) : tuple_matcher_(tuple_matcher), rhs_(RhsView::Copy(rhs)) { // Makes sure the user doesn't instantiate this class template // with a const or reference type. (void)testing::StaticAssertTypeEq(); } template operator Matcher() const { return MakeMatcher(new Impl(tuple_matcher_, rhs_)); } template class Impl : public MatcherInterface { public: typedef internal::StlContainerView< GTEST_REMOVE_REFERENCE_AND_CONST_(LhsContainer)> LhsView; typedef typename LhsView::type LhsStlContainer; typedef typename LhsView::const_reference LhsStlContainerReference; typedef typename LhsStlContainer::value_type LhsValue; // We pass the LHS value and the RHS value to the inner matcher by // reference, as they may be expensive to copy. We must use tuple // instead of pair here, as a pair cannot hold references (C++ 98, // 20.2.2 [lib.pairs]). typedef std::tr1::tuple InnerMatcherArg; Impl(const TupleMatcher& tuple_matcher, const RhsStlContainer& rhs) // mono_tuple_matcher_ holds a monomorphic version of the tuple matcher. : mono_tuple_matcher_(SafeMatcherCast(tuple_matcher)), rhs_(rhs) {} virtual void DescribeTo(::std::ostream* os) const { *os << "contains " << rhs_.size() << " values, where each value and its corresponding value in "; UniversalPrinter::Print(rhs_, os); *os << " "; mono_tuple_matcher_.DescribeTo(os); } virtual void DescribeNegationTo(::std::ostream* os) const { *os << "doesn't contain exactly " << rhs_.size() << " values, or contains a value x at some index i" << " where x and the i-th value of "; UniversalPrint(rhs_, os); *os << " "; mono_tuple_matcher_.DescribeNegationTo(os); } virtual bool MatchAndExplain(LhsContainer lhs, MatchResultListener* listener) const { LhsStlContainerReference lhs_stl_container = LhsView::ConstReference(lhs); const size_t actual_size = lhs_stl_container.size(); if (actual_size != rhs_.size()) { *listener << "which contains " << actual_size << " values"; return false; } typename LhsStlContainer::const_iterator left = lhs_stl_container.begin(); typename RhsStlContainer::const_iterator right = rhs_.begin(); for (size_t i = 0; i != actual_size; ++i, ++left, ++right) { const InnerMatcherArg value_pair(*left, *right); if (listener->IsInterested()) { StringMatchResultListener inner_listener; if (!mono_tuple_matcher_.MatchAndExplain( value_pair, &inner_listener)) { *listener << "where the value pair ("; UniversalPrint(*left, listener->stream()); *listener << ", "; UniversalPrint(*right, listener->stream()); *listener << ") at index #" << i << " don't match"; PrintIfNotEmpty(inner_listener.str(), listener->stream()); return false; } } else { if (!mono_tuple_matcher_.Matches(value_pair)) return false; } } return true; } private: const Matcher mono_tuple_matcher_; const RhsStlContainer rhs_; GTEST_DISALLOW_ASSIGN_(Impl); }; private: const TupleMatcher tuple_matcher_; const RhsStlContainer rhs_; GTEST_DISALLOW_ASSIGN_(PointwiseMatcher); }; // Holds the logic common to ContainsMatcherImpl and EachMatcherImpl. template class QuantifierMatcherImpl : public MatcherInterface { public: typedef GTEST_REMOVE_REFERENCE_AND_CONST_(Container) RawContainer; typedef StlContainerView View; typedef typename View::type StlContainer; typedef typename View::const_reference StlContainerReference; typedef typename StlContainer::value_type Element; template explicit QuantifierMatcherImpl(InnerMatcher inner_matcher) : inner_matcher_( testing::SafeMatcherCast(inner_matcher)) {} // Checks whether: // * All elements in the container match, if all_elements_should_match. // * Any element in the container matches, if !all_elements_should_match. bool MatchAndExplainImpl(bool all_elements_should_match, Container container, MatchResultListener* listener) const { StlContainerReference stl_container = View::ConstReference(container); size_t i = 0; for (typename StlContainer::const_iterator it = stl_container.begin(); it != stl_container.end(); ++it, ++i) { StringMatchResultListener inner_listener; const bool matches = inner_matcher_.MatchAndExplain(*it, &inner_listener); if (matches != all_elements_should_match) { *listener << "whose element #" << i << (matches ? " matches" : " doesn't match"); PrintIfNotEmpty(inner_listener.str(), listener->stream()); return !all_elements_should_match; } } return all_elements_should_match; } protected: const Matcher inner_matcher_; GTEST_DISALLOW_ASSIGN_(QuantifierMatcherImpl); }; // Implements Contains(element_matcher) for the given argument type Container. // Symmetric to EachMatcherImpl. template class ContainsMatcherImpl : public QuantifierMatcherImpl { public: template explicit ContainsMatcherImpl(InnerMatcher inner_matcher) : QuantifierMatcherImpl(inner_matcher) {} // Describes what this matcher does. virtual void DescribeTo(::std::ostream* os) const { *os << "contains at least one element that "; this->inner_matcher_.DescribeTo(os); } virtual void DescribeNegationTo(::std::ostream* os) const { *os << "doesn't contain any element that "; this->inner_matcher_.DescribeTo(os); } virtual bool MatchAndExplain(Container container, MatchResultListener* listener) const { return this->MatchAndExplainImpl(false, container, listener); } private: GTEST_DISALLOW_ASSIGN_(ContainsMatcherImpl); }; // Implements Each(element_matcher) for the given argument type Container. // Symmetric to ContainsMatcherImpl. template class EachMatcherImpl : public QuantifierMatcherImpl { public: template explicit EachMatcherImpl(InnerMatcher inner_matcher) : QuantifierMatcherImpl(inner_matcher) {} // Describes what this matcher does. virtual void DescribeTo(::std::ostream* os) const { *os << "only contains elements that "; this->inner_matcher_.DescribeTo(os); } virtual void DescribeNegationTo(::std::ostream* os) const { *os << "contains some element that "; this->inner_matcher_.DescribeNegationTo(os); } virtual bool MatchAndExplain(Container container, MatchResultListener* listener) const { return this->MatchAndExplainImpl(true, container, listener); } private: GTEST_DISALLOW_ASSIGN_(EachMatcherImpl); }; // Implements polymorphic Contains(element_matcher). template class ContainsMatcher { public: explicit ContainsMatcher(M m) : inner_matcher_(m) {} template operator Matcher() const { return MakeMatcher(new ContainsMatcherImpl(inner_matcher_)); } private: const M inner_matcher_; GTEST_DISALLOW_ASSIGN_(ContainsMatcher); }; // Implements polymorphic Each(element_matcher). template class EachMatcher { public: explicit EachMatcher(M m) : inner_matcher_(m) {} template operator Matcher() const { return MakeMatcher(new EachMatcherImpl(inner_matcher_)); } private: const M inner_matcher_; GTEST_DISALLOW_ASSIGN_(EachMatcher); }; // Implements Key(inner_matcher) for the given argument pair type. // Key(inner_matcher) matches an std::pair whose 'first' field matches // inner_matcher. For example, Contains(Key(Ge(5))) can be used to match an // std::map that contains at least one element whose key is >= 5. template class KeyMatcherImpl : public MatcherInterface { public: typedef GTEST_REMOVE_REFERENCE_AND_CONST_(PairType) RawPairType; typedef typename RawPairType::first_type KeyType; template explicit KeyMatcherImpl(InnerMatcher inner_matcher) : inner_matcher_( testing::SafeMatcherCast(inner_matcher)) { } // Returns true iff 'key_value.first' (the key) matches the inner matcher. virtual bool MatchAndExplain(PairType key_value, MatchResultListener* listener) const { StringMatchResultListener inner_listener; const bool match = inner_matcher_.MatchAndExplain(key_value.first, &inner_listener); const internal::string explanation = inner_listener.str(); if (explanation != "") { *listener << "whose first field is a value " << explanation; } return match; } // Describes what this matcher does. virtual void DescribeTo(::std::ostream* os) const { *os << "has a key that "; inner_matcher_.DescribeTo(os); } // Describes what the negation of this matcher does. virtual void DescribeNegationTo(::std::ostream* os) const { *os << "doesn't have a key that "; inner_matcher_.DescribeTo(os); } private: const Matcher inner_matcher_; GTEST_DISALLOW_ASSIGN_(KeyMatcherImpl); }; // Implements polymorphic Key(matcher_for_key). template class KeyMatcher { public: explicit KeyMatcher(M m) : matcher_for_key_(m) {} template operator Matcher() const { return MakeMatcher(new KeyMatcherImpl(matcher_for_key_)); } private: const M matcher_for_key_; GTEST_DISALLOW_ASSIGN_(KeyMatcher); }; // Implements Pair(first_matcher, second_matcher) for the given argument pair // type with its two matchers. See Pair() function below. template class PairMatcherImpl : public MatcherInterface { public: typedef GTEST_REMOVE_REFERENCE_AND_CONST_(PairType) RawPairType; typedef typename RawPairType::first_type FirstType; typedef typename RawPairType::second_type SecondType; template PairMatcherImpl(FirstMatcher first_matcher, SecondMatcher second_matcher) : first_matcher_( testing::SafeMatcherCast(first_matcher)), second_matcher_( testing::SafeMatcherCast(second_matcher)) { } // Describes what this matcher does. virtual void DescribeTo(::std::ostream* os) const { *os << "has a first field that "; first_matcher_.DescribeTo(os); *os << ", and has a second field that "; second_matcher_.DescribeTo(os); } // Describes what the negation of this matcher does. virtual void DescribeNegationTo(::std::ostream* os) const { *os << "has a first field that "; first_matcher_.DescribeNegationTo(os); *os << ", or has a second field that "; second_matcher_.DescribeNegationTo(os); } // Returns true iff 'a_pair.first' matches first_matcher and 'a_pair.second' // matches second_matcher. virtual bool MatchAndExplain(PairType a_pair, MatchResultListener* listener) const { if (!listener->IsInterested()) { // If the listener is not interested, we don't need to construct the // explanation. return first_matcher_.Matches(a_pair.first) && second_matcher_.Matches(a_pair.second); } StringMatchResultListener first_inner_listener; if (!first_matcher_.MatchAndExplain(a_pair.first, &first_inner_listener)) { *listener << "whose first field does not match"; PrintIfNotEmpty(first_inner_listener.str(), listener->stream()); return false; } StringMatchResultListener second_inner_listener; if (!second_matcher_.MatchAndExplain(a_pair.second, &second_inner_listener)) { *listener << "whose second field does not match"; PrintIfNotEmpty(second_inner_listener.str(), listener->stream()); return false; } ExplainSuccess(first_inner_listener.str(), second_inner_listener.str(), listener); return true; } private: void ExplainSuccess(const internal::string& first_explanation, const internal::string& second_explanation, MatchResultListener* listener) const { *listener << "whose both fields match"; if (first_explanation != "") { *listener << ", where the first field is a value " << first_explanation; } if (second_explanation != "") { *listener << ", "; if (first_explanation != "") { *listener << "and "; } else { *listener << "where "; } *listener << "the second field is a value " << second_explanation; } } const Matcher first_matcher_; const Matcher second_matcher_; GTEST_DISALLOW_ASSIGN_(PairMatcherImpl); }; // Implements polymorphic Pair(first_matcher, second_matcher). template class PairMatcher { public: PairMatcher(FirstMatcher first_matcher, SecondMatcher second_matcher) : first_matcher_(first_matcher), second_matcher_(second_matcher) {} template operator Matcher () const { return MakeMatcher( new PairMatcherImpl( first_matcher_, second_matcher_)); } private: const FirstMatcher first_matcher_; const SecondMatcher second_matcher_; GTEST_DISALLOW_ASSIGN_(PairMatcher); }; // Implements ElementsAre() and ElementsAreArray(). template class ElementsAreMatcherImpl : public MatcherInterface { public: typedef GTEST_REMOVE_REFERENCE_AND_CONST_(Container) RawContainer; typedef internal::StlContainerView View; typedef typename View::type StlContainer; typedef typename View::const_reference StlContainerReference; typedef typename StlContainer::value_type Element; // Constructs the matcher from a sequence of element values or // element matchers. template ElementsAreMatcherImpl(InputIter first, size_t a_count) { matchers_.reserve(a_count); InputIter it = first; for (size_t i = 0; i != a_count; ++i, ++it) { matchers_.push_back(MatcherCast(*it)); } } // Describes what this matcher does. virtual void DescribeTo(::std::ostream* os) const { if (count() == 0) { *os << "is empty"; } else if (count() == 1) { *os << "has 1 element that "; matchers_[0].DescribeTo(os); } else { *os << "has " << Elements(count()) << " where\n"; for (size_t i = 0; i != count(); ++i) { *os << "element #" << i << " "; matchers_[i].DescribeTo(os); if (i + 1 < count()) { *os << ",\n"; } } } } // Describes what the negation of this matcher does. virtual void DescribeNegationTo(::std::ostream* os) const { if (count() == 0) { *os << "isn't empty"; return; } *os << "doesn't have " << Elements(count()) << ", or\n"; for (size_t i = 0; i != count(); ++i) { *os << "element #" << i << " "; matchers_[i].DescribeNegationTo(os); if (i + 1 < count()) { *os << ", or\n"; } } } virtual bool MatchAndExplain(Container container, MatchResultListener* listener) const { StlContainerReference stl_container = View::ConstReference(container); const size_t actual_count = stl_container.size(); if (actual_count != count()) { // The element count doesn't match. If the container is empty, // there's no need to explain anything as Google Mock already // prints the empty container. Otherwise we just need to show // how many elements there actually are. if (actual_count != 0) { *listener << "which has " << Elements(actual_count); } return false; } typename StlContainer::const_iterator it = stl_container.begin(); // explanations[i] is the explanation of the element at index i. std::vector explanations(count()); for (size_t i = 0; i != count(); ++it, ++i) { StringMatchResultListener s; if (matchers_[i].MatchAndExplain(*it, &s)) { explanations[i] = s.str(); } else { // The container has the right size but the i-th element // doesn't match its expectation. *listener << "whose element #" << i << " doesn't match"; PrintIfNotEmpty(s.str(), listener->stream()); return false; } } // Every element matches its expectation. We need to explain why // (the obvious ones can be skipped). bool reason_printed = false; for (size_t i = 0; i != count(); ++i) { const internal::string& s = explanations[i]; if (!s.empty()) { if (reason_printed) { *listener << ",\nand "; } *listener << "whose element #" << i << " matches, " << s; reason_printed = true; } } return true; } private: static Message Elements(size_t count) { return Message() << count << (count == 1 ? " element" : " elements"); } size_t count() const { return matchers_.size(); } std::vector > matchers_; GTEST_DISALLOW_ASSIGN_(ElementsAreMatcherImpl); }; // Implements ElementsAre() of 0 arguments. class ElementsAreMatcher0 { public: ElementsAreMatcher0() {} template operator Matcher() const { typedef GTEST_REMOVE_REFERENCE_AND_CONST_(Container) RawContainer; typedef typename internal::StlContainerView::type::value_type Element; const Matcher* const matchers = NULL; return MakeMatcher(new ElementsAreMatcherImpl(matchers, 0)); } }; // Implements ElementsAreArray(). template class ElementsAreArrayMatcher { public: ElementsAreArrayMatcher(const T* first, size_t count) : first_(first), count_(count) {} template operator Matcher() const { typedef GTEST_REMOVE_REFERENCE_AND_CONST_(Container) RawContainer; typedef typename internal::StlContainerView::type::value_type Element; return MakeMatcher(new ElementsAreMatcherImpl(first_, count_)); } private: const T* const first_; const size_t count_; GTEST_DISALLOW_ASSIGN_(ElementsAreArrayMatcher); }; // Returns the description for a matcher defined using the MATCHER*() // macro where the user-supplied description string is "", if // 'negation' is false; otherwise returns the description of the // negation of the matcher. 'param_values' contains a list of strings // that are the print-out of the matcher's parameters. string FormatMatcherDescription(bool negation, const char* matcher_name, const Strings& param_values); } // namespace internal // Implements MatcherCast(). template inline Matcher MatcherCast(M matcher) { return internal::MatcherCastImpl::Cast(matcher); } // _ is a matcher that matches anything of any type. // // This definition is fine as: // // 1. The C++ standard permits using the name _ in a namespace that // is not the global namespace or ::std. // 2. The AnythingMatcher class has no data member or constructor, // so it's OK to create global variables of this type. // 3. c-style has approved of using _ in this case. const internal::AnythingMatcher _ = {}; // Creates a matcher that matches any value of the given type T. template inline Matcher A() { return MakeMatcher(new internal::AnyMatcherImpl()); } // Creates a matcher that matches any value of the given type T. template inline Matcher An() { return A(); } // Creates a polymorphic matcher that matches anything equal to x. // Note: if the parameter of Eq() were declared as const T&, Eq("foo") // wouldn't compile. template inline internal::EqMatcher Eq(T x) { return internal::EqMatcher(x); } // Constructs a Matcher from a 'value' of type T. The constructed // matcher matches any value that's equal to 'value'. template Matcher::Matcher(T value) { *this = Eq(value); } // Creates a monomorphic matcher that matches anything with type Lhs // and equal to rhs. A user may need to use this instead of Eq(...) // in order to resolve an overloading ambiguity. // // TypedEq(x) is just a convenient short-hand for Matcher(Eq(x)) // or Matcher(x), but more readable than the latter. // // We could define similar monomorphic matchers for other comparison // operations (e.g. TypedLt, TypedGe, and etc), but decided not to do // it yet as those are used much less than Eq() in practice. A user // can always write Matcher(Lt(5)) to be explicit about the type, // for example. template inline Matcher TypedEq(const Rhs& rhs) { return Eq(rhs); } // Creates a polymorphic matcher that matches anything >= x. template inline internal::GeMatcher Ge(Rhs x) { return internal::GeMatcher(x); } // Creates a polymorphic matcher that matches anything > x. template inline internal::GtMatcher Gt(Rhs x) { return internal::GtMatcher(x); } // Creates a polymorphic matcher that matches anything <= x. template inline internal::LeMatcher Le(Rhs x) { return internal::LeMatcher(x); } // Creates a polymorphic matcher that matches anything < x. template inline internal::LtMatcher Lt(Rhs x) { return internal::LtMatcher(x); } // Creates a polymorphic matcher that matches anything != x. template inline internal::NeMatcher Ne(Rhs x) { return internal::NeMatcher(x); } // Creates a polymorphic matcher that matches any NULL pointer. inline PolymorphicMatcher IsNull() { return MakePolymorphicMatcher(internal::IsNullMatcher()); } // Creates a polymorphic matcher that matches any non-NULL pointer. // This is convenient as Not(NULL) doesn't compile (the compiler // thinks that that expression is comparing a pointer with an integer). inline PolymorphicMatcher NotNull() { return MakePolymorphicMatcher(internal::NotNullMatcher()); } // Creates a polymorphic matcher that matches any argument that // references variable x. template inline internal::RefMatcher Ref(T& x) { // NOLINT return internal::RefMatcher(x); } // Creates a matcher that matches any double argument approximately // equal to rhs, where two NANs are considered unequal. inline internal::FloatingEqMatcher DoubleEq(double rhs) { return internal::FloatingEqMatcher(rhs, false); } // Creates a matcher that matches any double argument approximately // equal to rhs, including NaN values when rhs is NaN. inline internal::FloatingEqMatcher NanSensitiveDoubleEq(double rhs) { return internal::FloatingEqMatcher(rhs, true); } // Creates a matcher that matches any float argument approximately // equal to rhs, where two NANs are considered unequal. inline internal::FloatingEqMatcher FloatEq(float rhs) { return internal::FloatingEqMatcher(rhs, false); } // Creates a matcher that matches any double argument approximately // equal to rhs, including NaN values when rhs is NaN. inline internal::FloatingEqMatcher NanSensitiveFloatEq(float rhs) { return internal::FloatingEqMatcher(rhs, true); } // Creates a matcher that matches a pointer (raw or smart) that points // to a value that matches inner_matcher. template inline internal::PointeeMatcher Pointee( const InnerMatcher& inner_matcher) { return internal::PointeeMatcher(inner_matcher); } // Creates a matcher that matches an object whose given field matches // 'matcher'. For example, // Field(&Foo::number, Ge(5)) // matches a Foo object x iff x.number >= 5. template inline PolymorphicMatcher< internal::FieldMatcher > Field( FieldType Class::*field, const FieldMatcher& matcher) { return MakePolymorphicMatcher( internal::FieldMatcher( field, MatcherCast(matcher))); // The call to MatcherCast() is required for supporting inner // matchers of compatible types. For example, it allows // Field(&Foo::bar, m) // to compile where bar is an int32 and m is a matcher for int64. } // Creates a matcher that matches an object whose given property // matches 'matcher'. For example, // Property(&Foo::str, StartsWith("hi")) // matches a Foo object x iff x.str() starts with "hi". template inline PolymorphicMatcher< internal::PropertyMatcher > Property( PropertyType (Class::*property)() const, const PropertyMatcher& matcher) { return MakePolymorphicMatcher( internal::PropertyMatcher( property, MatcherCast(matcher))); // The call to MatcherCast() is required for supporting inner // matchers of compatible types. For example, it allows // Property(&Foo::bar, m) // to compile where bar() returns an int32 and m is a matcher for int64. } // Creates a matcher that matches an object iff the result of applying // a callable to x matches 'matcher'. // For example, // ResultOf(f, StartsWith("hi")) // matches a Foo object x iff f(x) starts with "hi". // callable parameter can be a function, function pointer, or a functor. // Callable has to satisfy the following conditions: // * It is required to keep no state affecting the results of // the calls on it and make no assumptions about how many calls // will be made. Any state it keeps must be protected from the // concurrent access. // * If it is a function object, it has to define type result_type. // We recommend deriving your functor classes from std::unary_function. template internal::ResultOfMatcher ResultOf( Callable callable, const ResultOfMatcher& matcher) { return internal::ResultOfMatcher( callable, MatcherCast::ResultType>( matcher)); // The call to MatcherCast() is required for supporting inner // matchers of compatible types. For example, it allows // ResultOf(Function, m) // to compile where Function() returns an int32 and m is a matcher for int64. } // String matchers. // Matches a string equal to str. inline PolymorphicMatcher > StrEq(const internal::string& str) { return MakePolymorphicMatcher(internal::StrEqualityMatcher( str, true, true)); } // Matches a string not equal to str. inline PolymorphicMatcher > StrNe(const internal::string& str) { return MakePolymorphicMatcher(internal::StrEqualityMatcher( str, false, true)); } // Matches a string equal to str, ignoring case. inline PolymorphicMatcher > StrCaseEq(const internal::string& str) { return MakePolymorphicMatcher(internal::StrEqualityMatcher( str, true, false)); } // Matches a string not equal to str, ignoring case. inline PolymorphicMatcher > StrCaseNe(const internal::string& str) { return MakePolymorphicMatcher(internal::StrEqualityMatcher( str, false, false)); } // Creates a matcher that matches any string, std::string, or C string // that contains the given substring. inline PolymorphicMatcher > HasSubstr(const internal::string& substring) { return MakePolymorphicMatcher(internal::HasSubstrMatcher( substring)); } // Matches a string that starts with 'prefix' (case-sensitive). inline PolymorphicMatcher > StartsWith(const internal::string& prefix) { return MakePolymorphicMatcher(internal::StartsWithMatcher( prefix)); } // Matches a string that ends with 'suffix' (case-sensitive). inline PolymorphicMatcher > EndsWith(const internal::string& suffix) { return MakePolymorphicMatcher(internal::EndsWithMatcher( suffix)); } // Matches a string that fully matches regular expression 'regex'. // The matcher takes ownership of 'regex'. inline PolymorphicMatcher MatchesRegex( const internal::RE* regex) { return MakePolymorphicMatcher(internal::MatchesRegexMatcher(regex, true)); } inline PolymorphicMatcher MatchesRegex( const internal::string& regex) { return MatchesRegex(new internal::RE(regex)); } // Matches a string that contains regular expression 'regex'. // The matcher takes ownership of 'regex'. inline PolymorphicMatcher ContainsRegex( const internal::RE* regex) { return MakePolymorphicMatcher(internal::MatchesRegexMatcher(regex, false)); } inline PolymorphicMatcher ContainsRegex( const internal::string& regex) { return ContainsRegex(new internal::RE(regex)); } #if GTEST_HAS_GLOBAL_WSTRING || GTEST_HAS_STD_WSTRING // Wide string matchers. // Matches a string equal to str. inline PolymorphicMatcher > StrEq(const internal::wstring& str) { return MakePolymorphicMatcher(internal::StrEqualityMatcher( str, true, true)); } // Matches a string not equal to str. inline PolymorphicMatcher > StrNe(const internal::wstring& str) { return MakePolymorphicMatcher(internal::StrEqualityMatcher( str, false, true)); } // Matches a string equal to str, ignoring case. inline PolymorphicMatcher > StrCaseEq(const internal::wstring& str) { return MakePolymorphicMatcher(internal::StrEqualityMatcher( str, true, false)); } // Matches a string not equal to str, ignoring case. inline PolymorphicMatcher > StrCaseNe(const internal::wstring& str) { return MakePolymorphicMatcher(internal::StrEqualityMatcher( str, false, false)); } // Creates a matcher that matches any wstring, std::wstring, or C wide string // that contains the given substring. inline PolymorphicMatcher > HasSubstr(const internal::wstring& substring) { return MakePolymorphicMatcher(internal::HasSubstrMatcher( substring)); } // Matches a string that starts with 'prefix' (case-sensitive). inline PolymorphicMatcher > StartsWith(const internal::wstring& prefix) { return MakePolymorphicMatcher(internal::StartsWithMatcher( prefix)); } // Matches a string that ends with 'suffix' (case-sensitive). inline PolymorphicMatcher > EndsWith(const internal::wstring& suffix) { return MakePolymorphicMatcher(internal::EndsWithMatcher( suffix)); } #endif // GTEST_HAS_GLOBAL_WSTRING || GTEST_HAS_STD_WSTRING // Creates a polymorphic matcher that matches a 2-tuple where the // first field == the second field. inline internal::Eq2Matcher Eq() { return internal::Eq2Matcher(); } // Creates a polymorphic matcher that matches a 2-tuple where the // first field >= the second field. inline internal::Ge2Matcher Ge() { return internal::Ge2Matcher(); } // Creates a polymorphic matcher that matches a 2-tuple where the // first field > the second field. inline internal::Gt2Matcher Gt() { return internal::Gt2Matcher(); } // Creates a polymorphic matcher that matches a 2-tuple where the // first field <= the second field. inline internal::Le2Matcher Le() { return internal::Le2Matcher(); } // Creates a polymorphic matcher that matches a 2-tuple where the // first field < the second field. inline internal::Lt2Matcher Lt() { return internal::Lt2Matcher(); } // Creates a polymorphic matcher that matches a 2-tuple where the // first field != the second field. inline internal::Ne2Matcher Ne() { return internal::Ne2Matcher(); } // Creates a matcher that matches any value of type T that m doesn't // match. template inline internal::NotMatcher Not(InnerMatcher m) { return internal::NotMatcher(m); } // Returns a matcher that matches anything that satisfies the given // predicate. The predicate can be any unary function or functor // whose return type can be implicitly converted to bool. template inline PolymorphicMatcher > Truly(Predicate pred) { return MakePolymorphicMatcher(internal::TrulyMatcher(pred)); } // Returns a matcher that matches an equal container. // This matcher behaves like Eq(), but in the event of mismatch lists the // values that are included in one container but not the other. (Duplicate // values and order differences are not explained.) template inline PolymorphicMatcher > ContainerEq(const Container& rhs) { // This following line is for working around a bug in MSVC 8.0, // which causes Container to be a const type sometimes. typedef GTEST_REMOVE_CONST_(Container) RawContainer; return MakePolymorphicMatcher( internal::ContainerEqMatcher(rhs)); } // Matches an STL-style container or a native array that contains the // same number of elements as in rhs, where its i-th element and rhs's // i-th element (as a pair) satisfy the given pair matcher, for all i. // TupleMatcher must be able to be safely cast to Matcher >, where T1 and T2 are the types of elements in the // LHS container and the RHS container respectively. template inline internal::PointwiseMatcher Pointwise(const TupleMatcher& tuple_matcher, const Container& rhs) { // This following line is for working around a bug in MSVC 8.0, // which causes Container to be a const type sometimes. typedef GTEST_REMOVE_CONST_(Container) RawContainer; return internal::PointwiseMatcher( tuple_matcher, rhs); } // Matches an STL-style container or a native array that contains at // least one element matching the given value or matcher. // // Examples: // ::std::set page_ids; // page_ids.insert(3); // page_ids.insert(1); // EXPECT_THAT(page_ids, Contains(1)); // EXPECT_THAT(page_ids, Contains(Gt(2))); // EXPECT_THAT(page_ids, Not(Contains(4))); // // ::std::map page_lengths; // page_lengths[1] = 100; // EXPECT_THAT(page_lengths, // Contains(::std::pair(1, 100))); // // const char* user_ids[] = { "joe", "mike", "tom" }; // EXPECT_THAT(user_ids, Contains(Eq(::std::string("tom")))); template inline internal::ContainsMatcher Contains(M matcher) { return internal::ContainsMatcher(matcher); } // Matches an STL-style container or a native array that contains only // elements matching the given value or matcher. // // Each(m) is semantically equivalent to Not(Contains(Not(m))). Only // the messages are different. // // Examples: // ::std::set page_ids; // // Each(m) matches an empty container, regardless of what m is. // EXPECT_THAT(page_ids, Each(Eq(1))); // EXPECT_THAT(page_ids, Each(Eq(77))); // // page_ids.insert(3); // EXPECT_THAT(page_ids, Each(Gt(0))); // EXPECT_THAT(page_ids, Not(Each(Gt(4)))); // page_ids.insert(1); // EXPECT_THAT(page_ids, Not(Each(Lt(2)))); // // ::std::map page_lengths; // page_lengths[1] = 100; // page_lengths[2] = 200; // page_lengths[3] = 300; // EXPECT_THAT(page_lengths, Not(Each(Pair(1, 100)))); // EXPECT_THAT(page_lengths, Each(Key(Le(3)))); // // const char* user_ids[] = { "joe", "mike", "tom" }; // EXPECT_THAT(user_ids, Not(Each(Eq(::std::string("tom"))))); template inline internal::EachMatcher Each(M matcher) { return internal::EachMatcher(matcher); } // Key(inner_matcher) matches an std::pair whose 'first' field matches // inner_matcher. For example, Contains(Key(Ge(5))) can be used to match an // std::map that contains at least one element whose key is >= 5. template inline internal::KeyMatcher Key(M inner_matcher) { return internal::KeyMatcher(inner_matcher); } // Pair(first_matcher, second_matcher) matches a std::pair whose 'first' field // matches first_matcher and whose 'second' field matches second_matcher. For // example, EXPECT_THAT(map_type, ElementsAre(Pair(Ge(5), "foo"))) can be used // to match a std::map that contains exactly one element whose key // is >= 5 and whose value equals "foo". template inline internal::PairMatcher Pair(FirstMatcher first_matcher, SecondMatcher second_matcher) { return internal::PairMatcher( first_matcher, second_matcher); } // Returns a predicate that is satisfied by anything that matches the // given matcher. template inline internal::MatcherAsPredicate Matches(M matcher) { return internal::MatcherAsPredicate(matcher); } // Returns true iff the value matches the matcher. template inline bool Value(const T& value, M matcher) { return testing::Matches(matcher)(value); } // Matches the value against the given matcher and explains the match // result to listener. template inline bool ExplainMatchResult( M matcher, const T& value, MatchResultListener* listener) { return SafeMatcherCast(matcher).MatchAndExplain(value, listener); } // AllArgs(m) is a synonym of m. This is useful in // // EXPECT_CALL(foo, Bar(_, _)).With(AllArgs(Eq())); // // which is easier to read than // // EXPECT_CALL(foo, Bar(_, _)).With(Eq()); template inline InnerMatcher AllArgs(const InnerMatcher& matcher) { return matcher; } // These macros allow using matchers to check values in Google Test // tests. ASSERT_THAT(value, matcher) and EXPECT_THAT(value, matcher) // succeed iff the value matches the matcher. If the assertion fails, // the value and the description of the matcher will be printed. #define ASSERT_THAT(value, matcher) ASSERT_PRED_FORMAT1(\ ::testing::internal::MakePredicateFormatterFromMatcher(matcher), value) #define EXPECT_THAT(value, matcher) EXPECT_PRED_FORMAT1(\ ::testing::internal::MakePredicateFormatterFromMatcher(matcher), value) } // namespace testing #endif // GMOCK_INCLUDE_GMOCK_GMOCK_MATCHERS_H_