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// Copyright 2007, Google Inc.
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// Google Mock - a framework for writing C++ mock classes.
//
// This file tests some commonly used argument matchers.
#include <cmath>
#include <limits>
#include <memory>
#include <string>
#include "test/gmock-matchers_test.h"
// Silence warning C4244: 'initializing': conversion from 'int' to 'short',
// possible loss of data and C4100, unreferenced local parameter
GTEST_DISABLE_MSC_WARNINGS_PUSH_(4244 4100)
namespace testing {
namespace gmock_matchers_test {
namespace {
typedef ::std::tuple<long, int> Tuple2; // NOLINT
// Tests that Eq() matches a 2-tuple where the first field == the
// second field.
TEST(Eq2Test, MatchesEqualArguments) {
Matcher<const Tuple2&> m = Eq();
EXPECT_TRUE(m.Matches(Tuple2(5L, 5)));
EXPECT_FALSE(m.Matches(Tuple2(5L, 6)));
}
// Tests that Eq() describes itself properly.
TEST(Eq2Test, CanDescribeSelf) {
Matcher<const Tuple2&> m = Eq();
EXPECT_EQ("are an equal pair", Describe(m));
}
// Tests that Ge() matches a 2-tuple where the first field >= the
// second field.
TEST(Ge2Test, MatchesGreaterThanOrEqualArguments) {
Matcher<const Tuple2&> m = Ge();
EXPECT_TRUE(m.Matches(Tuple2(5L, 4)));
EXPECT_TRUE(m.Matches(Tuple2(5L, 5)));
EXPECT_FALSE(m.Matches(Tuple2(5L, 6)));
}
// Tests that Ge() describes itself properly.
TEST(Ge2Test, CanDescribeSelf) {
Matcher<const Tuple2&> m = Ge();
EXPECT_EQ("are a pair where the first >= the second", Describe(m));
}
// Tests that Gt() matches a 2-tuple where the first field > the
// second field.
TEST(Gt2Test, MatchesGreaterThanArguments) {
Matcher<const Tuple2&> m = Gt();
EXPECT_TRUE(m.Matches(Tuple2(5L, 4)));
EXPECT_FALSE(m.Matches(Tuple2(5L, 5)));
EXPECT_FALSE(m.Matches(Tuple2(5L, 6)));
}
// Tests that Gt() describes itself properly.
TEST(Gt2Test, CanDescribeSelf) {
Matcher<const Tuple2&> m = Gt();
EXPECT_EQ("are a pair where the first > the second", Describe(m));
}
// Tests that Le() matches a 2-tuple where the first field <= the
// second field.
TEST(Le2Test, MatchesLessThanOrEqualArguments) {
Matcher<const Tuple2&> m = Le();
EXPECT_TRUE(m.Matches(Tuple2(5L, 6)));
EXPECT_TRUE(m.Matches(Tuple2(5L, 5)));
EXPECT_FALSE(m.Matches(Tuple2(5L, 4)));
}
// Tests that Le() describes itself properly.
TEST(Le2Test, CanDescribeSelf) {
Matcher<const Tuple2&> m = Le();
EXPECT_EQ("are a pair where the first <= the second", Describe(m));
}
// Tests that Lt() matches a 2-tuple where the first field < the
// second field.
TEST(Lt2Test, MatchesLessThanArguments) {
Matcher<const Tuple2&> m = Lt();
EXPECT_TRUE(m.Matches(Tuple2(5L, 6)));
EXPECT_FALSE(m.Matches(Tuple2(5L, 5)));
EXPECT_FALSE(m.Matches(Tuple2(5L, 4)));
}
// Tests that Lt() describes itself properly.
TEST(Lt2Test, CanDescribeSelf) {
Matcher<const Tuple2&> m = Lt();
EXPECT_EQ("are a pair where the first < the second", Describe(m));
}
// Tests that Ne() matches a 2-tuple where the first field != the
// second field.
TEST(Ne2Test, MatchesUnequalArguments) {
Matcher<const Tuple2&> m = Ne();
EXPECT_TRUE(m.Matches(Tuple2(5L, 6)));
EXPECT_TRUE(m.Matches(Tuple2(5L, 4)));
EXPECT_FALSE(m.Matches(Tuple2(5L, 5)));
}
// Tests that Ne() describes itself properly.
TEST(Ne2Test, CanDescribeSelf) {
Matcher<const Tuple2&> m = Ne();
EXPECT_EQ("are an unequal pair", Describe(m));
}
TEST(PairMatchBaseTest, WorksWithMoveOnly) {
using Pointers = std::tuple<std::unique_ptr<int>, std::unique_ptr<int>>;
Matcher<Pointers> matcher = Eq();
Pointers pointers;
// Tested values don't matter; the point is that matcher does not copy the
// matched values.
EXPECT_TRUE(matcher.Matches(pointers));
}
// Tests that IsNan() matches a NaN, with float.
TEST(IsNan, FloatMatchesNan) {
float quiet_nan = std::numeric_limits<float>::quiet_NaN();
float other_nan = std::nanf("1");
float real_value = 1.0f;
Matcher<float> m = IsNan();
EXPECT_TRUE(m.Matches(quiet_nan));
EXPECT_TRUE(m.Matches(other_nan));
EXPECT_FALSE(m.Matches(real_value));
Matcher<float&> m_ref = IsNan();
EXPECT_TRUE(m_ref.Matches(quiet_nan));
EXPECT_TRUE(m_ref.Matches(other_nan));
EXPECT_FALSE(m_ref.Matches(real_value));
Matcher<const float&> m_cref = IsNan();
EXPECT_TRUE(m_cref.Matches(quiet_nan));
EXPECT_TRUE(m_cref.Matches(other_nan));
EXPECT_FALSE(m_cref.Matches(real_value));
}
// Tests that IsNan() matches a NaN, with double.
TEST(IsNan, DoubleMatchesNan) {
double quiet_nan = std::numeric_limits<double>::quiet_NaN();
double other_nan = std::nan("1");
double real_value = 1.0;
Matcher<double> m = IsNan();
EXPECT_TRUE(m.Matches(quiet_nan));
EXPECT_TRUE(m.Matches(other_nan));
EXPECT_FALSE(m.Matches(real_value));
Matcher<double&> m_ref = IsNan();
EXPECT_TRUE(m_ref.Matches(quiet_nan));
EXPECT_TRUE(m_ref.Matches(other_nan));
EXPECT_FALSE(m_ref.Matches(real_value));
Matcher<const double&> m_cref = IsNan();
EXPECT_TRUE(m_cref.Matches(quiet_nan));
EXPECT_TRUE(m_cref.Matches(other_nan));
EXPECT_FALSE(m_cref.Matches(real_value));
}
// Tests that IsNan() matches a NaN, with long double.
TEST(IsNan, LongDoubleMatchesNan) {
long double quiet_nan = std::numeric_limits<long double>::quiet_NaN();
long double other_nan = std::nan("1");
long double real_value = 1.0;
Matcher<long double> m = IsNan();
EXPECT_TRUE(m.Matches(quiet_nan));
EXPECT_TRUE(m.Matches(other_nan));
EXPECT_FALSE(m.Matches(real_value));
Matcher<long double&> m_ref = IsNan();
EXPECT_TRUE(m_ref.Matches(quiet_nan));
EXPECT_TRUE(m_ref.Matches(other_nan));
EXPECT_FALSE(m_ref.Matches(real_value));
Matcher<const long double&> m_cref = IsNan();
EXPECT_TRUE(m_cref.Matches(quiet_nan));
EXPECT_TRUE(m_cref.Matches(other_nan));
EXPECT_FALSE(m_cref.Matches(real_value));
}
// Tests that IsNan() works with Not.
TEST(IsNan, NotMatchesNan) {
Matcher<float> mf = Not(IsNan());
EXPECT_FALSE(mf.Matches(std::numeric_limits<float>::quiet_NaN()));
EXPECT_FALSE(mf.Matches(std::nanf("1")));
EXPECT_TRUE(mf.Matches(1.0));
Matcher<double> md = Not(IsNan());
EXPECT_FALSE(md.Matches(std::numeric_limits<double>::quiet_NaN()));
EXPECT_FALSE(md.Matches(std::nan("1")));
EXPECT_TRUE(md.Matches(1.0));
Matcher<long double> mld = Not(IsNan());
EXPECT_FALSE(mld.Matches(std::numeric_limits<long double>::quiet_NaN()));
EXPECT_FALSE(mld.Matches(std::nanl("1")));
EXPECT_TRUE(mld.Matches(1.0));
}
// Tests that IsNan() can describe itself.
TEST(IsNan, CanDescribeSelf) {
Matcher<float> mf = IsNan();
EXPECT_EQ("is NaN", Describe(mf));
Matcher<double> md = IsNan();
EXPECT_EQ("is NaN", Describe(md));
Matcher<long double> mld = IsNan();
EXPECT_EQ("is NaN", Describe(mld));
}
// Tests that IsNan() can describe itself with Not.
TEST(IsNan, CanDescribeSelfWithNot) {
Matcher<float> mf = Not(IsNan());
EXPECT_EQ("isn't NaN", Describe(mf));
Matcher<double> md = Not(IsNan());
EXPECT_EQ("isn't NaN", Describe(md));
Matcher<long double> mld = Not(IsNan());
EXPECT_EQ("isn't NaN", Describe(mld));
}
// Tests that FloatEq() matches a 2-tuple where
// FloatEq(first field) matches the second field.
TEST(FloatEq2Test, MatchesEqualArguments) {
typedef ::std::tuple<float, float> Tpl;
Matcher<const Tpl&> m = FloatEq();
EXPECT_TRUE(m.Matches(Tpl(1.0f, 1.0f)));
EXPECT_TRUE(m.Matches(Tpl(0.3f, 0.1f + 0.1f + 0.1f)));
EXPECT_FALSE(m.Matches(Tpl(1.1f, 1.0f)));
}
// Tests that FloatEq() describes itself properly.
TEST(FloatEq2Test, CanDescribeSelf) {
Matcher<const ::std::tuple<float, float>&> m = FloatEq();
EXPECT_EQ("are an almost-equal pair", Describe(m));
}
// Tests that NanSensitiveFloatEq() matches a 2-tuple where
// NanSensitiveFloatEq(first field) matches the second field.
TEST(NanSensitiveFloatEqTest, MatchesEqualArgumentsWithNaN) {
typedef ::std::tuple<float, float> Tpl;
Matcher<const Tpl&> m = NanSensitiveFloatEq();
EXPECT_TRUE(m.Matches(Tpl(1.0f, 1.0f)));
EXPECT_TRUE(m.Matches(Tpl(std::numeric_limits<float>::quiet_NaN(),
std::numeric_limits<float>::quiet_NaN())));
EXPECT_FALSE(m.Matches(Tpl(1.1f, 1.0f)));
EXPECT_FALSE(m.Matches(Tpl(1.0f, std::numeric_limits<float>::quiet_NaN())));
EXPECT_FALSE(m.Matches(Tpl(std::numeric_limits<float>::quiet_NaN(), 1.0f)));
}
// Tests that NanSensitiveFloatEq() describes itself properly.
TEST(NanSensitiveFloatEqTest, CanDescribeSelfWithNaNs) {
Matcher<const ::std::tuple<float, float>&> m = NanSensitiveFloatEq();
EXPECT_EQ("are an almost-equal pair", Describe(m));
}
// Tests that DoubleEq() matches a 2-tuple where
// DoubleEq(first field) matches the second field.
TEST(DoubleEq2Test, MatchesEqualArguments) {
typedef ::std::tuple<double, double> Tpl;
Matcher<const Tpl&> m = DoubleEq();
EXPECT_TRUE(m.Matches(Tpl(1.0, 1.0)));
EXPECT_TRUE(m.Matches(Tpl(0.3, 0.1 + 0.1 + 0.1)));
EXPECT_FALSE(m.Matches(Tpl(1.1, 1.0)));
}
// Tests that DoubleEq() describes itself properly.
TEST(DoubleEq2Test, CanDescribeSelf) {
Matcher<const ::std::tuple<double, double>&> m = DoubleEq();
EXPECT_EQ("are an almost-equal pair", Describe(m));
}
// Tests that NanSensitiveDoubleEq() matches a 2-tuple where
// NanSensitiveDoubleEq(first field) matches the second field.
TEST(NanSensitiveDoubleEqTest, MatchesEqualArgumentsWithNaN) {
typedef ::std::tuple<double, double> Tpl;
Matcher<const Tpl&> m = NanSensitiveDoubleEq();
EXPECT_TRUE(m.Matches(Tpl(1.0f, 1.0f)));
EXPECT_TRUE(m.Matches(Tpl(std::numeric_limits<double>::quiet_NaN(),
std::numeric_limits<double>::quiet_NaN())));
EXPECT_FALSE(m.Matches(Tpl(1.1f, 1.0f)));
EXPECT_FALSE(m.Matches(Tpl(1.0f, std::numeric_limits<double>::quiet_NaN())));
EXPECT_FALSE(m.Matches(Tpl(std::numeric_limits<double>::quiet_NaN(), 1.0f)));
}
// Tests that DoubleEq() describes itself properly.
TEST(NanSensitiveDoubleEqTest, CanDescribeSelfWithNaNs) {
Matcher<const ::std::tuple<double, double>&> m = NanSensitiveDoubleEq();
EXPECT_EQ("are an almost-equal pair", Describe(m));
}
// Tests that FloatEq() matches a 2-tuple where
// FloatNear(first field, max_abs_error) matches the second field.
TEST(FloatNear2Test, MatchesEqualArguments) {
typedef ::std::tuple<float, float> Tpl;
Matcher<const Tpl&> m = FloatNear(0.5f);
EXPECT_TRUE(m.Matches(Tpl(1.0f, 1.0f)));
EXPECT_TRUE(m.Matches(Tpl(1.3f, 1.0f)));
EXPECT_FALSE(m.Matches(Tpl(1.8f, 1.0f)));
}
// Tests that FloatNear() describes itself properly.
TEST(FloatNear2Test, CanDescribeSelf) {
Matcher<const ::std::tuple<float, float>&> m = FloatNear(0.5f);
EXPECT_EQ("are an almost-equal pair", Describe(m));
}
// Tests that NanSensitiveFloatNear() matches a 2-tuple where
// NanSensitiveFloatNear(first field) matches the second field.
TEST(NanSensitiveFloatNearTest, MatchesNearbyArgumentsWithNaN) {
typedef ::std::tuple<float, float> Tpl;
Matcher<const Tpl&> m = NanSensitiveFloatNear(0.5f);
EXPECT_TRUE(m.Matches(Tpl(1.0f, 1.0f)));
EXPECT_TRUE(m.Matches(Tpl(1.1f, 1.0f)));
EXPECT_TRUE(m.Matches(Tpl(std::numeric_limits<float>::quiet_NaN(),
std::numeric_limits<float>::quiet_NaN())));
EXPECT_FALSE(m.Matches(Tpl(1.6f, 1.0f)));
EXPECT_FALSE(m.Matches(Tpl(1.0f, std::numeric_limits<float>::quiet_NaN())));
EXPECT_FALSE(m.Matches(Tpl(std::numeric_limits<float>::quiet_NaN(), 1.0f)));
}
// Tests that NanSensitiveFloatNear() describes itself properly.
TEST(NanSensitiveFloatNearTest, CanDescribeSelfWithNaNs) {
Matcher<const ::std::tuple<float, float>&> m = NanSensitiveFloatNear(0.5f);
EXPECT_EQ("are an almost-equal pair", Describe(m));
}
// Tests that FloatEq() matches a 2-tuple where
// DoubleNear(first field, max_abs_error) matches the second field.
TEST(DoubleNear2Test, MatchesEqualArguments) {
typedef ::std::tuple<double, double> Tpl;
Matcher<const Tpl&> m = DoubleNear(0.5);
EXPECT_TRUE(m.Matches(Tpl(1.0, 1.0)));
EXPECT_TRUE(m.Matches(Tpl(1.3, 1.0)));
EXPECT_FALSE(m.Matches(Tpl(1.8, 1.0)));
}
// Tests that DoubleNear() describes itself properly.
TEST(DoubleNear2Test, CanDescribeSelf) {
Matcher<const ::std::tuple<double, double>&> m = DoubleNear(0.5);
EXPECT_EQ("are an almost-equal pair", Describe(m));
}
// Tests that NanSensitiveDoubleNear() matches a 2-tuple where
// NanSensitiveDoubleNear(first field) matches the second field.
TEST(NanSensitiveDoubleNearTest, MatchesNearbyArgumentsWithNaN) {
typedef ::std::tuple<double, double> Tpl;
Matcher<const Tpl&> m = NanSensitiveDoubleNear(0.5f);
EXPECT_TRUE(m.Matches(Tpl(1.0f, 1.0f)));
EXPECT_TRUE(m.Matches(Tpl(1.1f, 1.0f)));
EXPECT_TRUE(m.Matches(Tpl(std::numeric_limits<double>::quiet_NaN(),
std::numeric_limits<double>::quiet_NaN())));
EXPECT_FALSE(m.Matches(Tpl(1.6f, 1.0f)));
EXPECT_FALSE(m.Matches(Tpl(1.0f, std::numeric_limits<double>::quiet_NaN())));
EXPECT_FALSE(m.Matches(Tpl(std::numeric_limits<double>::quiet_NaN(), 1.0f)));
}
// Tests that NanSensitiveDoubleNear() describes itself properly.
TEST(NanSensitiveDoubleNearTest, CanDescribeSelfWithNaNs) {
Matcher<const ::std::tuple<double, double>&> m = NanSensitiveDoubleNear(0.5f);
EXPECT_EQ("are an almost-equal pair", Describe(m));
}
// Tests that Not(m) matches any value that doesn't match m.
TEST(NotTest, NegatesMatcher) {
Matcher<int> m;
m = Not(Eq(2));
EXPECT_TRUE(m.Matches(3));
EXPECT_FALSE(m.Matches(2));
}
// Tests that Not(m) describes itself properly.
TEST(NotTest, CanDescribeSelf) {
Matcher<int> m = Not(Eq(5));
EXPECT_EQ("isn't equal to 5", Describe(m));
}
// Tests that monomorphic matchers are safely cast by the Not matcher.
TEST(NotTest, NotMatcherSafelyCastsMonomorphicMatchers) {
// greater_than_5 is a monomorphic matcher.
Matcher<int> greater_than_5 = Gt(5);
Matcher<const int&> m = Not(greater_than_5);
Matcher<int&> m2 = Not(greater_than_5);
Matcher<int&> m3 = Not(m);
}
// Helper to allow easy testing of AllOf matchers with num parameters.
void AllOfMatches(int num, const Matcher<int>& m) {
SCOPED_TRACE(Describe(m));
EXPECT_TRUE(m.Matches(0));
for (int i = 1; i <= num; ++i) {
EXPECT_FALSE(m.Matches(i));
}
EXPECT_TRUE(m.Matches(num + 1));
}
INSTANTIATE_GTEST_MATCHER_TEST_P(AllOfTest);
// Tests that AllOf(m1, ..., mn) matches any value that matches all of
// the given matchers.
TEST(AllOfTest, MatchesWhenAllMatch) {
Matcher<int> m;
m = AllOf(Le(2), Ge(1));
EXPECT_TRUE(m.Matches(1));
EXPECT_TRUE(m.Matches(2));
EXPECT_FALSE(m.Matches(0));
EXPECT_FALSE(m.Matches(3));
m = AllOf(Gt(0), Ne(1), Ne(2));
EXPECT_TRUE(m.Matches(3));
EXPECT_FALSE(m.Matches(2));
EXPECT_FALSE(m.Matches(1));
EXPECT_FALSE(m.Matches(0));
m = AllOf(Gt(0), Ne(1), Ne(2), Ne(3));
EXPECT_TRUE(m.Matches(4));
EXPECT_FALSE(m.Matches(3));
EXPECT_FALSE(m.Matches(2));
EXPECT_FALSE(m.Matches(1));
EXPECT_FALSE(m.Matches(0));
m = AllOf(Ge(0), Lt(10), Ne(3), Ne(5), Ne(7));
EXPECT_TRUE(m.Matches(0));
EXPECT_TRUE(m.Matches(1));
EXPECT_FALSE(m.Matches(3));
// The following tests for varying number of sub-matchers. Due to the way
// the sub-matchers are handled it is enough to test every sub-matcher once
// with sub-matchers using the same matcher type. Varying matcher types are
// checked for above.
AllOfMatches(2, AllOf(Ne(1), Ne(2)));
AllOfMatches(3, AllOf(Ne(1), Ne(2), Ne(3)));
AllOfMatches(4, AllOf(Ne(1), Ne(2), Ne(3), Ne(4)));
AllOfMatches(5, AllOf(Ne(1), Ne(2), Ne(3), Ne(4), Ne(5)));
AllOfMatches(6, AllOf(Ne(1), Ne(2), Ne(3), Ne(4), Ne(5), Ne(6)));
AllOfMatches(7, AllOf(Ne(1), Ne(2), Ne(3), Ne(4), Ne(5), Ne(6), Ne(7)));
AllOfMatches(8,
AllOf(Ne(1), Ne(2), Ne(3), Ne(4), Ne(5), Ne(6), Ne(7), Ne(8)));
AllOfMatches(
9, AllOf(Ne(1), Ne(2), Ne(3), Ne(4), Ne(5), Ne(6), Ne(7), Ne(8), Ne(9)));
AllOfMatches(10, AllOf(Ne(1), Ne(2), Ne(3), Ne(4), Ne(5), Ne(6), Ne(7), Ne(8),
Ne(9), Ne(10)));
AllOfMatches(
50, AllOf(Ne(1), Ne(2), Ne(3), Ne(4), Ne(5), Ne(6), Ne(7), Ne(8), Ne(9),
Ne(10), Ne(11), Ne(12), Ne(13), Ne(14), Ne(15), Ne(16), Ne(17),
Ne(18), Ne(19), Ne(20), Ne(21), Ne(22), Ne(23), Ne(24), Ne(25),
Ne(26), Ne(27), Ne(28), Ne(29), Ne(30), Ne(31), Ne(32), Ne(33),
Ne(34), Ne(35), Ne(36), Ne(37), Ne(38), Ne(39), Ne(40), Ne(41),
Ne(42), Ne(43), Ne(44), Ne(45), Ne(46), Ne(47), Ne(48), Ne(49),
Ne(50)));
}
// Tests that AllOf(m1, ..., mn) describes itself properly.
TEST(AllOfTest, CanDescribeSelf) {
Matcher<int> m;
m = AllOf(Le(2), Ge(1));
EXPECT_EQ("(is <= 2) and (is >= 1)", Describe(m));
m = AllOf(Gt(0), Ne(1), Ne(2));
std::string expected_descr1 =
"(is > 0) and (isn't equal to 1) and (isn't equal to 2)";
EXPECT_EQ(expected_descr1, Describe(m));
m = AllOf(Gt(0), Ne(1), Ne(2), Ne(3));
std::string expected_descr2 =
"(is > 0) and (isn't equal to 1) and (isn't equal to 2) and (isn't equal "
"to 3)";
EXPECT_EQ(expected_descr2, Describe(m));
m = AllOf(Ge(0), Lt(10), Ne(3), Ne(5), Ne(7));
std::string expected_descr3 =
"(is >= 0) and (is < 10) and (isn't equal to 3) and (isn't equal to 5) "
"and (isn't equal to 7)";
EXPECT_EQ(expected_descr3, Describe(m));
}
// Tests that AllOf(m1, ..., mn) describes its negation properly.
TEST(AllOfTest, CanDescribeNegation) {
Matcher<int> m;
m = AllOf(Le(2), Ge(1));
std::string expected_descr4 = "(isn't <= 2) or (isn't >= 1)";
EXPECT_EQ(expected_descr4, DescribeNegation(m));
m = AllOf(Gt(0), Ne(1), Ne(2));
std::string expected_descr5 =
"(isn't > 0) or (is equal to 1) or (is equal to 2)";
EXPECT_EQ(expected_descr5, DescribeNegation(m));
m = AllOf(Gt(0), Ne(1), Ne(2), Ne(3));
std::string expected_descr6 =
"(isn't > 0) or (is equal to 1) or (is equal to 2) or (is equal to 3)";
EXPECT_EQ(expected_descr6, DescribeNegation(m));
m = AllOf(Ge(0), Lt(10), Ne(3), Ne(5), Ne(7));
std::string expected_desr7 =
"(isn't >= 0) or (isn't < 10) or (is equal to 3) or (is equal to 5) or "
"(is equal to 7)";
EXPECT_EQ(expected_desr7, DescribeNegation(m));
m = AllOf(Ne(1), Ne(2), Ne(3), Ne(4), Ne(5), Ne(6), Ne(7), Ne(8), Ne(9),
Ne(10), Ne(11));
AllOf(1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11);
EXPECT_THAT(Describe(m), EndsWith("and (isn't equal to 11)"));
AllOfMatches(11, m);
}
// Tests that monomorphic matchers are safely cast by the AllOf matcher.
TEST(AllOfTest, AllOfMatcherSafelyCastsMonomorphicMatchers) {
// greater_than_5 and less_than_10 are monomorphic matchers.
Matcher<int> greater_than_5 = Gt(5);
Matcher<int> less_than_10 = Lt(10);
Matcher<const int&> m = AllOf(greater_than_5, less_than_10);
Matcher<int&> m2 = AllOf(greater_than_5, less_than_10);
Matcher<int&> m3 = AllOf(greater_than_5, m2);
// Tests that BothOf works when composing itself.
Matcher<const int&> m4 = AllOf(greater_than_5, less_than_10, less_than_10);
Matcher<int&> m5 = AllOf(greater_than_5, less_than_10, less_than_10);
}
TEST_P(AllOfTestP, ExplainsResult) {
Matcher<int> m;
// Successful match. Both matchers need to explain. The second
// matcher doesn't give an explanation, so only the first matcher's
// explanation is printed.
m = AllOf(GreaterThan(10), Lt(30));
EXPECT_EQ("which is 15 more than 10", Explain(m, 25));
// Successful match. Both matchers need to explain.
m = AllOf(GreaterThan(10), GreaterThan(20));
EXPECT_EQ("which is 20 more than 10, and which is 10 more than 20",
Explain(m, 30));
// Successful match. All matchers need to explain. The second
// matcher doesn't given an explanation.
m = AllOf(GreaterThan(10), Lt(30), GreaterThan(20));
EXPECT_EQ("which is 15 more than 10, and which is 5 more than 20",
Explain(m, 25));
// Successful match. All matchers need to explain.
m = AllOf(GreaterThan(10), GreaterThan(20), GreaterThan(30));
EXPECT_EQ(
"which is 30 more than 10, and which is 20 more than 20, "
"and which is 10 more than 30",
Explain(m, 40));
// Failed match. The first matcher, which failed, needs to
// explain.
m = AllOf(GreaterThan(10), GreaterThan(20));
EXPECT_EQ("which is 5 less than 10", Explain(m, 5));
// Failed match. The second matcher, which failed, needs to
// explain. Since it doesn't given an explanation, nothing is
// printed.
m = AllOf(GreaterThan(10), Lt(30));
EXPECT_EQ("", Explain(m, 40));
// Failed match. The second matcher, which failed, needs to
// explain.
m = AllOf(GreaterThan(10), GreaterThan(20));
EXPECT_EQ("which is 5 less than 20", Explain(m, 15));
}
// Helper to allow easy testing of AnyOf matchers with num parameters.
static void AnyOfMatches(int num, const Matcher<int>& m) {
SCOPED_TRACE(Describe(m));
EXPECT_FALSE(m.Matches(0));
for (int i = 1; i <= num; ++i) {
EXPECT_TRUE(m.Matches(i));
}
EXPECT_FALSE(m.Matches(num + 1));
}
static void AnyOfStringMatches(int num, const Matcher<std::string>& m) {
SCOPED_TRACE(Describe(m));
EXPECT_FALSE(m.Matches(std::to_string(0)));
for (int i = 1; i <= num; ++i) {
EXPECT_TRUE(m.Matches(std::to_string(i)));
}
EXPECT_FALSE(m.Matches(std::to_string(num + 1)));
}
INSTANTIATE_GTEST_MATCHER_TEST_P(AnyOfTest);
// Tests that AnyOf(m1, ..., mn) matches any value that matches at
// least one of the given matchers.
TEST(AnyOfTest, MatchesWhenAnyMatches) {
Matcher<int> m;
m = AnyOf(Le(1), Ge(3));
EXPECT_TRUE(m.Matches(1));
EXPECT_TRUE(m.Matches(4));
EXPECT_FALSE(m.Matches(2));
m = AnyOf(Lt(0), Eq(1), Eq(2));
EXPECT_TRUE(m.Matches(-1));
EXPECT_TRUE(m.Matches(1));
EXPECT_TRUE(m.Matches(2));
EXPECT_FALSE(m.Matches(0));
m = AnyOf(Lt(0), Eq(1), Eq(2), Eq(3));
EXPECT_TRUE(m.Matches(-1));
EXPECT_TRUE(m.Matches(1));
EXPECT_TRUE(m.Matches(2));
EXPECT_TRUE(m.Matches(3));
EXPECT_FALSE(m.Matches(0));
m = AnyOf(Le(0), Gt(10), 3, 5, 7);
EXPECT_TRUE(m.Matches(0));
EXPECT_TRUE(m.Matches(11));
EXPECT_TRUE(m.Matches(3));
EXPECT_FALSE(m.Matches(2));
// The following tests for varying number of sub-matchers. Due to the way
// the sub-matchers are handled it is enough to test every sub-matcher once
// with sub-matchers using the same matcher type. Varying matcher types are
// checked for above.
AnyOfMatches(2, AnyOf(1, 2));
AnyOfMatches(3, AnyOf(1, 2, 3));
AnyOfMatches(4, AnyOf(1, 2, 3, 4));
AnyOfMatches(5, AnyOf(1, 2, 3, 4, 5));
AnyOfMatches(6, AnyOf(1, 2, 3, 4, 5, 6));
AnyOfMatches(7, AnyOf(1, 2, 3, 4, 5, 6, 7));
AnyOfMatches(8, AnyOf(1, 2, 3, 4, 5, 6, 7, 8));
AnyOfMatches(9, AnyOf(1, 2, 3, 4, 5, 6, 7, 8, 9));
AnyOfMatches(10, AnyOf(1, 2, 3, 4, 5, 6, 7, 8, 9, 10));
}
// Tests the variadic version of the AnyOfMatcher.
TEST(AnyOfTest, VariadicMatchesWhenAnyMatches) {
// Also make sure AnyOf is defined in the right namespace and does not depend
// on ADL.
Matcher<int> m = ::testing::AnyOf(1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11);
EXPECT_THAT(Describe(m), EndsWith("or (is equal to 11)"));
AnyOfMatches(11, m);
AnyOfMatches(50, AnyOf(1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16,
17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30,
31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44,
45, 46, 47, 48, 49, 50));
AnyOfStringMatches(
50, AnyOf("1", "2", "3", "4", "5", "6", "7", "8", "9", "10", "11", "12",
"13", "14", "15", "16", "17", "18", "19", "20", "21", "22",
"23", "24", "25", "26", "27", "28", "29", "30", "31", "32",
"33", "34", "35", "36", "37", "38", "39", "40", "41", "42",
"43", "44", "45", "46", "47", "48", "49", "50"));
}
TEST(ConditionalTest, MatchesFirstIfCondition) {
Matcher<std::string> eq_red = Eq("red");
Matcher<std::string> ne_red = Ne("red");
Matcher<std::string> m = Conditional(true, eq_red, ne_red);
EXPECT_TRUE(m.Matches("red"));
EXPECT_FALSE(m.Matches("green"));
StringMatchResultListener listener;
StringMatchResultListener expected;
EXPECT_FALSE(m.MatchAndExplain("green", &listener));
EXPECT_FALSE(eq_red.MatchAndExplain("green", &expected));
EXPECT_THAT(listener.str(), Eq(expected.str()));
}
TEST(ConditionalTest, MatchesSecondIfCondition) {
Matcher<std::string> eq_red = Eq("red");
Matcher<std::string> ne_red = Ne("red");
Matcher<std::string> m = Conditional(false, eq_red, ne_red);
EXPECT_FALSE(m.Matches("red"));
EXPECT_TRUE(m.Matches("green"));
StringMatchResultListener listener;
StringMatchResultListener expected;
EXPECT_FALSE(m.MatchAndExplain("red", &listener));
EXPECT_FALSE(ne_red.MatchAndExplain("red", &expected));
EXPECT_THAT(listener.str(), Eq(expected.str()));
}
// Tests that AnyOf(m1, ..., mn) describes itself properly.
TEST(AnyOfTest, CanDescribeSelf) {
Matcher<int> m;
m = AnyOf(Le(1), Ge(3));
EXPECT_EQ("(is <= 1) or (is >= 3)", Describe(m));
m = AnyOf(Lt(0), Eq(1), Eq(2));
EXPECT_EQ("(is < 0) or (is equal to 1) or (is equal to 2)", Describe(m));
m = AnyOf(Lt(0), Eq(1), Eq(2), Eq(3));
EXPECT_EQ("(is < 0) or (is equal to 1) or (is equal to 2) or (is equal to 3)",
Describe(m));
m = AnyOf(Le(0), Gt(10), 3, 5, 7);
EXPECT_EQ(
"(is <= 0) or (is > 10) or (is equal to 3) or (is equal to 5) or (is "
"equal to 7)",
Describe(m));
}
// Tests that AnyOf(m1, ..., mn) describes its negation properly.
TEST(AnyOfTest, CanDescribeNegation) {
Matcher<int> m;
m = AnyOf(Le(1), Ge(3));
EXPECT_EQ("(isn't <= 1) and (isn't >= 3)", DescribeNegation(m));
m = AnyOf(Lt(0), Eq(1), Eq(2));
EXPECT_EQ("(isn't < 0) and (isn't equal to 1) and (isn't equal to 2)",
DescribeNegation(m));
m = AnyOf(Lt(0), Eq(1), Eq(2), Eq(3));
EXPECT_EQ(
"(isn't < 0) and (isn't equal to 1) and (isn't equal to 2) and (isn't "
"equal to 3)",
DescribeNegation(m));
m = AnyOf(Le(0), Gt(10), 3, 5, 7);
EXPECT_EQ(
"(isn't <= 0) and (isn't > 10) and (isn't equal to 3) and (isn't equal "
"to 5) and (isn't equal to 7)",
DescribeNegation(m));
}
// Tests that monomorphic matchers are safely cast by the AnyOf matcher.
TEST(AnyOfTest, AnyOfMatcherSafelyCastsMonomorphicMatchers) {
// greater_than_5 and less_than_10 are monomorphic matchers.
Matcher<int> greater_than_5 = Gt(5);
Matcher<int> less_than_10 = Lt(10);
Matcher<const int&> m = AnyOf(greater_than_5, less_than_10);
Matcher<int&> m2 = AnyOf(greater_than_5, less_than_10);
Matcher<int&> m3 = AnyOf(greater_than_5, m2);
// Tests that EitherOf works when composing itself.
Matcher<const int&> m4 = AnyOf(greater_than_5, less_than_10, less_than_10);
Matcher<int&> m5 = AnyOf(greater_than_5, less_than_10, less_than_10);
}
TEST_P(AnyOfTestP, ExplainsResult) {
Matcher<int> m;
// Failed match. Both matchers need to explain. The second
// matcher doesn't give an explanation, so only the first matcher's
// explanation is printed.
m = AnyOf(GreaterThan(10), Lt(0));
EXPECT_EQ("which is 5 less than 10", Explain(m, 5));
// Failed match. Both matchers need to explain.
m = AnyOf(GreaterThan(10), GreaterThan(20));
EXPECT_EQ("which is 5 less than 10, and which is 15 less than 20",
Explain(m, 5));
// Failed match. All matchers need to explain. The second
// matcher doesn't given an explanation.
m = AnyOf(GreaterThan(10), Gt(20), GreaterThan(30));
EXPECT_EQ("which is 5 less than 10, and which is 25 less than 30",
Explain(m, 5));
// Failed match. All matchers need to explain.
m = AnyOf(GreaterThan(10), GreaterThan(20), GreaterThan(30));
EXPECT_EQ(
"which is 5 less than 10, and which is 15 less than 20, "
"and which is 25 less than 30",
Explain(m, 5));
// Successful match. The first matcher, which succeeded, needs to
// explain.
m = AnyOf(GreaterThan(10), GreaterThan(20));
EXPECT_EQ("which is 5 more than 10", Explain(m, 15));
// Successful match. The second matcher, which succeeded, needs to
// explain. Since it doesn't given an explanation, nothing is
// printed.
m = AnyOf(GreaterThan(10), Lt(30));
EXPECT_EQ("", Explain(m, 0));
// Successful match. The second matcher, which succeeded, needs to
// explain.
m = AnyOf(GreaterThan(30), GreaterThan(20));
EXPECT_EQ("which is 5 more than 20", Explain(m, 25));
}
// The following predicate function and predicate functor are for
// testing the Truly(predicate) matcher.
// Returns non-zero if the input is positive. Note that the return
// type of this function is not bool. It's OK as Truly() accepts any
// unary function or functor whose return type can be implicitly
// converted to bool.
int IsPositive(double x) { return x > 0 ? 1 : 0; }
// This functor returns true if the input is greater than the given
// number.
class IsGreaterThan {
public:
explicit IsGreaterThan(int threshold) : threshold_(threshold) {}
bool operator()(int n) const { return n > threshold_; }
private:
int threshold_;
};
// For testing Truly().
const int foo = 0;
// This predicate returns true if and only if the argument references foo and
// has a zero value.
bool ReferencesFooAndIsZero(const int& n) { return (&n == &foo) && (n == 0); }
// Tests that Truly(predicate) matches what satisfies the given
// predicate.
TEST(TrulyTest, MatchesWhatSatisfiesThePredicate) {
Matcher<double> m = Truly(IsPositive);
EXPECT_TRUE(m.Matches(2.0));
EXPECT_FALSE(m.Matches(-1.5));
}
// Tests that Truly(predicate_functor) works too.
TEST(TrulyTest, CanBeUsedWithFunctor) {
Matcher<int> m = Truly(IsGreaterThan(5));
EXPECT_TRUE(m.Matches(6));
EXPECT_FALSE(m.Matches(4));
}
// A class that can be implicitly converted to bool.
class ConvertibleToBool {
public:
explicit ConvertibleToBool(int number) : number_(number) {}
operator bool() const { return number_ != 0; }
private:
int number_;
};
ConvertibleToBool IsNotZero(int number) { return ConvertibleToBool(number); }
// Tests that the predicate used in Truly() may return a class that's
// implicitly convertible to bool, even when the class has no
// operator!().
TEST(TrulyTest, PredicateCanReturnAClassConvertibleToBool) {
Matcher<int> m = Truly(IsNotZero);
EXPECT_TRUE(m.Matches(1));
EXPECT_FALSE(m.Matches(0));
}
// Tests that Truly(predicate) can describe itself properly.
TEST(TrulyTest, CanDescribeSelf) {
Matcher<double> m = Truly(IsPositive);
EXPECT_EQ("satisfies the given predicate", Describe(m));
}
// Tests that Truly(predicate) works when the matcher takes its
// argument by reference.
TEST(TrulyTest, WorksForByRefArguments) {
Matcher<const int&> m = Truly(ReferencesFooAndIsZero);
EXPECT_TRUE(m.Matches(foo));
int n = 0;
EXPECT_FALSE(m.Matches(n));
}
// Tests that Truly(predicate) provides a helpful reason when it fails.
TEST(TrulyTest, ExplainsFailures) {
StringMatchResultListener listener;
EXPECT_FALSE(ExplainMatchResult(Truly(IsPositive), -1, &listener));
EXPECT_EQ(listener.str(), "didn't satisfy the given predicate");
}
// Tests that Matches(m) is a predicate satisfied by whatever that
// matches matcher m.
TEST(MatchesTest, IsSatisfiedByWhatMatchesTheMatcher) {
EXPECT_TRUE(Matches(Ge(0))(1));
EXPECT_FALSE(Matches(Eq('a'))('b'));
}
// Tests that Matches(m) works when the matcher takes its argument by
// reference.
TEST(MatchesTest, WorksOnByRefArguments) {
int m = 0, n = 0;
EXPECT_TRUE(Matches(AllOf(Ref(n), Eq(0)))(n));
EXPECT_FALSE(Matches(Ref(m))(n));
}
// Tests that a Matcher on non-reference type can be used in
// Matches().
TEST(MatchesTest, WorksWithMatcherOnNonRefType) {
Matcher<int> eq5 = Eq(5);
EXPECT_TRUE(Matches(eq5)(5));
EXPECT_FALSE(Matches(eq5)(2));
}
// Tests Value(value, matcher). Since Value() is a simple wrapper for
// Matches(), which has been tested already, we don't spend a lot of
// effort on testing Value().
TEST(ValueTest, WorksWithPolymorphicMatcher) {
EXPECT_TRUE(Value("hi", StartsWith("h")));
EXPECT_FALSE(Value(5, Gt(10)));
}
TEST(ValueTest, WorksWithMonomorphicMatcher) {
const Matcher<int> is_zero = Eq(0);
EXPECT_TRUE(Value(0, is_zero));
EXPECT_FALSE(Value('a', is_zero));
int n = 0;
const Matcher<const int&> ref_n = Ref(n);
EXPECT_TRUE(Value(n, ref_n));
EXPECT_FALSE(Value(1, ref_n));
}
TEST(AllArgsTest, WorksForTuple) {
EXPECT_THAT(std::make_tuple(1, 2L), AllArgs(Lt()));
EXPECT_THAT(std::make_tuple(2L, 1), Not(AllArgs(Lt())));
}
TEST(AllArgsTest, WorksForNonTuple) {
EXPECT_THAT(42, AllArgs(Gt(0)));
EXPECT_THAT('a', Not(AllArgs(Eq('b'))));
}
class AllArgsHelper {
public:
AllArgsHelper() {}
MOCK_METHOD2(Helper, int(char x, int y));
private:
AllArgsHelper(const AllArgsHelper&) = delete;
AllArgsHelper& operator=(const AllArgsHelper&) = delete;
};
TEST(AllArgsTest, WorksInWithClause) {
AllArgsHelper helper;
ON_CALL(helper, Helper(_, _)).With(AllArgs(Lt())).WillByDefault(Return(1));
EXPECT_CALL(helper, Helper(_, _));
EXPECT_CALL(helper, Helper(_, _)).With(AllArgs(Gt())).WillOnce(Return(2));
EXPECT_EQ(1, helper.Helper('\1', 2));
EXPECT_EQ(2, helper.Helper('a', 1));
}
class OptionalMatchersHelper {
public:
OptionalMatchersHelper() {}
MOCK_METHOD0(NoArgs, int());
MOCK_METHOD1(OneArg, int(int y));
MOCK_METHOD2(TwoArgs, int(char x, int y));
MOCK_METHOD1(Overloaded, int(char x));
MOCK_METHOD2(Overloaded, int(char x, int y));
private:
OptionalMatchersHelper(const OptionalMatchersHelper&) = delete;
OptionalMatchersHelper& operator=(const OptionalMatchersHelper&) = delete;
};
TEST(AllArgsTest, WorksWithoutMatchers) {
OptionalMatchersHelper helper;
ON_CALL(helper, NoArgs).WillByDefault(Return(10));
ON_CALL(helper, OneArg).WillByDefault(Return(20));
ON_CALL(helper, TwoArgs).WillByDefault(Return(30));
EXPECT_EQ(10, helper.NoArgs());
EXPECT_EQ(20, helper.OneArg(1));
EXPECT_EQ(30, helper.TwoArgs('\1', 2));
EXPECT_CALL(helper, NoArgs).Times(1);
EXPECT_CALL(helper, OneArg).WillOnce(Return(100));
EXPECT_CALL(helper, OneArg(17)).WillOnce(Return(200));
EXPECT_CALL(helper, TwoArgs).Times(0);
EXPECT_EQ(10, helper.NoArgs());
EXPECT_EQ(100, helper.OneArg(1));
EXPECT_EQ(200, helper.OneArg(17));
}
// Tests floating-point matchers.
template <typename RawType>
class FloatingPointTest : public testing::Test {
protected:
typedef testing::internal::FloatingPoint<RawType> Floating;
typedef typename Floating::Bits Bits;
FloatingPointTest()
: max_ulps_(Floating::kMaxUlps),
zero_bits_(Floating(0).bits()),
one_bits_(Floating(1).bits()),
infinity_bits_(Floating(Floating::Infinity()).bits()),
close_to_positive_zero_(
Floating::ReinterpretBits(zero_bits_ + max_ulps_ / 2)),
close_to_negative_zero_(
-Floating::ReinterpretBits(zero_bits_ + max_ulps_ - max_ulps_ / 2)),
further_from_negative_zero_(-Floating::ReinterpretBits(
zero_bits_ + max_ulps_ + 1 - max_ulps_ / 2)),
close_to_one_(Floating::ReinterpretBits(one_bits_ + max_ulps_)),
further_from_one_(Floating::ReinterpretBits(one_bits_ + max_ulps_ + 1)),
infinity_(Floating::Infinity()),
close_to_infinity_(
Floating::ReinterpretBits(infinity_bits_ - max_ulps_)),
further_from_infinity_(
Floating::ReinterpretBits(infinity_bits_ - max_ulps_ - 1)),
max_(std::numeric_limits<RawType>::max()),
nan1_(Floating::ReinterpretBits(Floating::kExponentBitMask | 1)),
nan2_(Floating::ReinterpretBits(Floating::kExponentBitMask | 200)) {}
void TestSize() { EXPECT_EQ(sizeof(RawType), sizeof(Bits)); }
// A battery of tests for FloatingEqMatcher::Matches.
// matcher_maker is a pointer to a function which creates a FloatingEqMatcher.
void TestMatches(
testing::internal::FloatingEqMatcher<RawType> (*matcher_maker)(RawType)) {
Matcher<RawType> m1 = matcher_maker(0.0);
EXPECT_TRUE(m1.Matches(-0.0));
EXPECT_TRUE(m1.Matches(close_to_positive_zero_));
EXPECT_TRUE(m1.Matches(close_to_negative_zero_));
EXPECT_FALSE(m1.Matches(1.0));
Matcher<RawType> m2 = matcher_maker(close_to_positive_zero_);
EXPECT_FALSE(m2.Matches(further_from_negative_zero_));
Matcher<RawType> m3 = matcher_maker(1.0);
EXPECT_TRUE(m3.Matches(close_to_one_));
EXPECT_FALSE(m3.Matches(further_from_one_));
// Test commutativity: matcher_maker(0.0).Matches(1.0) was tested above.
EXPECT_FALSE(m3.Matches(0.0));
Matcher<RawType> m4 = matcher_maker(-infinity_);
EXPECT_TRUE(m4.Matches(-close_to_infinity_));
Matcher<RawType> m5 = matcher_maker(infinity_);
EXPECT_TRUE(m5.Matches(close_to_infinity_));
// This is interesting as the representations of infinity_ and nan1_
// are only 1 DLP apart.
EXPECT_FALSE(m5.Matches(nan1_));
// matcher_maker can produce a Matcher<const RawType&>, which is needed in
// some cases.
Matcher<const RawType&> m6 = matcher_maker(0.0);
EXPECT_TRUE(m6.Matches(-0.0));
EXPECT_TRUE(m6.Matches(close_to_positive_zero_));
EXPECT_FALSE(m6.Matches(1.0));
// matcher_maker can produce a Matcher<RawType&>, which is needed in some
// cases.
Matcher<RawType&> m7 = matcher_maker(0.0);
RawType x = 0.0;
EXPECT_TRUE(m7.Matches(x));
x = 0.01f;
EXPECT_FALSE(m7.Matches(x));
}
// Pre-calculated numbers to be used by the tests.
const Bits max_ulps_;
const Bits zero_bits_; // The bits that represent 0.0.
const Bits one_bits_; // The bits that represent 1.0.
const Bits infinity_bits_; // The bits that represent +infinity.
// Some numbers close to 0.0.
const RawType close_to_positive_zero_;
const RawType close_to_negative_zero_;
const RawType further_from_negative_zero_;
// Some numbers close to 1.0.
const RawType close_to_one_;
const RawType further_from_one_;
// Some numbers close to +infinity.
const RawType infinity_;
const RawType close_to_infinity_;
const RawType further_from_infinity_;
// Maximum representable value that's not infinity.
const RawType max_;
// Some NaNs.
const RawType nan1_;
const RawType nan2_;
};
// Tests floating-point matchers with fixed epsilons.
template <typename RawType>
class FloatingPointNearTest : public FloatingPointTest<RawType> {
protected:
typedef FloatingPointTest<RawType> ParentType;
// A battery of tests for FloatingEqMatcher::Matches with a fixed epsilon.
// matcher_maker is a pointer to a function which creates a FloatingEqMatcher.
void TestNearMatches(testing::internal::FloatingEqMatcher<RawType> (
*matcher_maker)(RawType, RawType)) {
Matcher<RawType> m1 = matcher_maker(0.0, 0.0);
EXPECT_TRUE(m1.Matches(0.0));
EXPECT_TRUE(m1.Matches(-0.0));
EXPECT_FALSE(m1.Matches(ParentType::close_to_positive_zero_));
EXPECT_FALSE(m1.Matches(ParentType::close_to_negative_zero_));
EXPECT_FALSE(m1.Matches(1.0));
Matcher<RawType> m2 = matcher_maker(0.0, 1.0);
EXPECT_TRUE(m2.Matches(0.0));
EXPECT_TRUE(m2.Matches(-0.0));
EXPECT_TRUE(m2.Matches(1.0));
EXPECT_TRUE(m2.Matches(-1.0));
EXPECT_FALSE(m2.Matches(ParentType::close_to_one_));
EXPECT_FALSE(m2.Matches(-ParentType::close_to_one_));
// Check that inf matches inf, regardless of the of the specified max
// absolute error.
Matcher<RawType> m3 = matcher_maker(ParentType::infinity_, 0.0);
EXPECT_TRUE(m3.Matches(ParentType::infinity_));
EXPECT_FALSE(m3.Matches(ParentType::close_to_infinity_));
EXPECT_FALSE(m3.Matches(-ParentType::infinity_));
Matcher<RawType> m4 = matcher_maker(-ParentType::infinity_, 0.0);
EXPECT_TRUE(m4.Matches(-ParentType::infinity_));
EXPECT_FALSE(m4.Matches(-ParentType::close_to_infinity_));
EXPECT_FALSE(m4.Matches(ParentType::infinity_));
// Test various overflow scenarios.
Matcher<RawType> m5 = matcher_maker(ParentType::max_, ParentType::max_);
EXPECT_TRUE(m5.Matches(ParentType::max_));
EXPECT_FALSE(m5.Matches(-ParentType::max_));
Matcher<RawType> m6 = matcher_maker(-ParentType::max_, ParentType::max_);
EXPECT_FALSE(m6.Matches(ParentType::max_));
EXPECT_TRUE(m6.Matches(-ParentType::max_));
Matcher<RawType> m7 = matcher_maker(ParentType::max_, 0);
EXPECT_TRUE(m7.Matches(ParentType::max_));
EXPECT_FALSE(m7.Matches(-ParentType::max_));
Matcher<RawType> m8 = matcher_maker(-ParentType::max_, 0);
EXPECT_FALSE(m8.Matches(ParentType::max_));
EXPECT_TRUE(m8.Matches(-ParentType::max_));
// The difference between max() and -max() normally overflows to infinity,
// but it should still match if the max_abs_error is also infinity.
Matcher<RawType> m9 =
matcher_maker(ParentType::max_, ParentType::infinity_);
EXPECT_TRUE(m8.Matches(-ParentType::max_));
// matcher_maker can produce a Matcher<const RawType&>, which is needed in
// some cases.
Matcher<const RawType&> m10 = matcher_maker(0.0, 1.0);
EXPECT_TRUE(m10.Matches(-0.0));
EXPECT_TRUE(m10.Matches(ParentType::close_to_positive_zero_));
EXPECT_FALSE(m10.Matches(ParentType::close_to_one_));
// matcher_maker can produce a Matcher<RawType&>, which is needed in some
// cases.
Matcher<RawType&> m11 = matcher_maker(0.0, 1.0);
RawType x = 0.0;
EXPECT_TRUE(m11.Matches(x));
x = 1.0f;
EXPECT_TRUE(m11.Matches(x));
x = -1.0f;
EXPECT_TRUE(m11.Matches(x));
x = 1.1f;
EXPECT_FALSE(m11.Matches(x));
x = -1.1f;
EXPECT_FALSE(m11.Matches(x));
}
};
// Instantiate FloatingPointTest for testing floats.
typedef FloatingPointTest<float> FloatTest;
TEST_F(FloatTest, FloatEqApproximatelyMatchesFloats) { TestMatches(&FloatEq); }
TEST_F(FloatTest, NanSensitiveFloatEqApproximatelyMatchesFloats) {
TestMatches(&NanSensitiveFloatEq);
}
TEST_F(FloatTest, FloatEqCannotMatchNaN) {
// FloatEq never matches NaN.
Matcher<float> m = FloatEq(nan1_);
EXPECT_FALSE(m.Matches(nan1_));
EXPECT_FALSE(m.Matches(nan2_));
EXPECT_FALSE(m.Matches(1.0));
}
TEST_F(FloatTest, NanSensitiveFloatEqCanMatchNaN) {
// NanSensitiveFloatEq will match NaN.
Matcher<float> m = NanSensitiveFloatEq(nan1_);
EXPECT_TRUE(m.Matches(nan1_));
EXPECT_TRUE(m.Matches(nan2_));
EXPECT_FALSE(m.Matches(1.0));
}
TEST_F(FloatTest, FloatEqCanDescribeSelf) {
Matcher<float> m1 = FloatEq(2.0f);
EXPECT_EQ("is approximately 2", Describe(m1));
EXPECT_EQ("isn't approximately 2", DescribeNegation(m1));
Matcher<float> m2 = FloatEq(0.5f);
EXPECT_EQ("is approximately 0.5", Describe(m2));
EXPECT_EQ("isn't approximately 0.5", DescribeNegation(m2));
Matcher<float> m3 = FloatEq(nan1_);
EXPECT_EQ("never matches", Describe(m3));
EXPECT_EQ("is anything", DescribeNegation(m3));
}
TEST_F(FloatTest, NanSensitiveFloatEqCanDescribeSelf) {
Matcher<float> m1 = NanSensitiveFloatEq(2.0f);
EXPECT_EQ("is approximately 2", Describe(m1));
EXPECT_EQ("isn't approximately 2", DescribeNegation(m1));
Matcher<float> m2 = NanSensitiveFloatEq(0.5f);
EXPECT_EQ("is approximately 0.5", Describe(m2));
EXPECT_EQ("isn't approximately 0.5", DescribeNegation(m2));
Matcher<float> m3 = NanSensitiveFloatEq(nan1_);
EXPECT_EQ("is NaN", Describe(m3));
EXPECT_EQ("isn't NaN", DescribeNegation(m3));
}
// Instantiate FloatingPointTest for testing floats with a user-specified
// max absolute error.
typedef FloatingPointNearTest<float> FloatNearTest;
TEST_F(FloatNearTest, FloatNearMatches) { TestNearMatches(&FloatNear); }
TEST_F(FloatNearTest, NanSensitiveFloatNearApproximatelyMatchesFloats) {
TestNearMatches(&NanSensitiveFloatNear);
}
TEST_F(FloatNearTest, FloatNearCanDescribeSelf) {
Matcher<float> m1 = FloatNear(2.0f, 0.5f);
EXPECT_EQ("is approximately 2 (absolute error <= 0.5)", Describe(m1));
EXPECT_EQ("isn't approximately 2 (absolute error > 0.5)",
DescribeNegation(m1));
Matcher<float> m2 = FloatNear(0.5f, 0.5f);
EXPECT_EQ("is approximately 0.5 (absolute error <= 0.5)", Describe(m2));
EXPECT_EQ("isn't approximately 0.5 (absolute error > 0.5)",
DescribeNegation(m2));
Matcher<float> m3 = FloatNear(nan1_, 0.0);
EXPECT_EQ("never matches", Describe(m3));
EXPECT_EQ("is anything", DescribeNegation(m3));
}
TEST_F(FloatNearTest, NanSensitiveFloatNearCanDescribeSelf) {
Matcher<float> m1 = NanSensitiveFloatNear(2.0f, 0.5f);
EXPECT_EQ("is approximately 2 (absolute error <= 0.5)", Describe(m1));
EXPECT_EQ("isn't approximately 2 (absolute error > 0.5)",
DescribeNegation(m1));
Matcher<float> m2 = NanSensitiveFloatNear(0.5f, 0.5f);
EXPECT_EQ("is approximately 0.5 (absolute error <= 0.5)", Describe(m2));
EXPECT_EQ("isn't approximately 0.5 (absolute error > 0.5)",
DescribeNegation(m2));
Matcher<float> m3 = NanSensitiveFloatNear(nan1_, 0.1f);
EXPECT_EQ("is NaN", Describe(m3));
EXPECT_EQ("isn't NaN", DescribeNegation(m3));
}
TEST_F(FloatNearTest, FloatNearCannotMatchNaN) {
// FloatNear never matches NaN.
Matcher<float> m = FloatNear(ParentType::nan1_, 0.1f);
EXPECT_FALSE(m.Matches(nan1_));
EXPECT_FALSE(m.Matches(nan2_));
EXPECT_FALSE(m.Matches(1.0));
}
TEST_F(FloatNearTest, NanSensitiveFloatNearCanMatchNaN) {
// NanSensitiveFloatNear will match NaN.
Matcher<float> m = NanSensitiveFloatNear(nan1_, 0.1f);
EXPECT_TRUE(m.Matches(nan1_));
EXPECT_TRUE(m.Matches(nan2_));
EXPECT_FALSE(m.Matches(1.0));
}
// Instantiate FloatingPointTest for testing doubles.
typedef FloatingPointTest<double> DoubleTest;
TEST_F(DoubleTest, DoubleEqApproximatelyMatchesDoubles) {
TestMatches(&DoubleEq);
}
TEST_F(DoubleTest, NanSensitiveDoubleEqApproximatelyMatchesDoubles) {
TestMatches(&NanSensitiveDoubleEq);
}
TEST_F(DoubleTest, DoubleEqCannotMatchNaN) {
// DoubleEq never matches NaN.
Matcher<double> m = DoubleEq(nan1_);
EXPECT_FALSE(m.Matches(nan1_));
EXPECT_FALSE(m.Matches(nan2_));
EXPECT_FALSE(m.Matches(1.0));
}
TEST_F(DoubleTest, NanSensitiveDoubleEqCanMatchNaN) {
// NanSensitiveDoubleEq will match NaN.
Matcher<double> m = NanSensitiveDoubleEq(nan1_);
EXPECT_TRUE(m.Matches(nan1_));
EXPECT_TRUE(m.Matches(nan2_));
EXPECT_FALSE(m.Matches(1.0));
}
TEST_F(DoubleTest, DoubleEqCanDescribeSelf) {
Matcher<double> m1 = DoubleEq(2.0);
EXPECT_EQ("is approximately 2", Describe(m1));
EXPECT_EQ("isn't approximately 2", DescribeNegation(m1));
Matcher<double> m2 = DoubleEq(0.5);
EXPECT_EQ("is approximately 0.5", Describe(m2));
EXPECT_EQ("isn't approximately 0.5", DescribeNegation(m2));
Matcher<double> m3 = DoubleEq(nan1_);
EXPECT_EQ("never matches", Describe(m3));
EXPECT_EQ("is anything", DescribeNegation(m3));
}
TEST_F(DoubleTest, NanSensitiveDoubleEqCanDescribeSelf) {
Matcher<double> m1 = NanSensitiveDoubleEq(2.0);
EXPECT_EQ("is approximately 2", Describe(m1));
EXPECT_EQ("isn't approximately 2", DescribeNegation(m1));
Matcher<double> m2 = NanSensitiveDoubleEq(0.5);
EXPECT_EQ("is approximately 0.5", Describe(m2));
EXPECT_EQ("isn't approximately 0.5", DescribeNegation(m2));
Matcher<double> m3 = NanSensitiveDoubleEq(nan1_);
EXPECT_EQ("is NaN", Describe(m3));
EXPECT_EQ("isn't NaN", DescribeNegation(m3));
}
// Instantiate FloatingPointTest for testing floats with a user-specified
// max absolute error.
typedef FloatingPointNearTest<double> DoubleNearTest;
TEST_F(DoubleNearTest, DoubleNearMatches) { TestNearMatches(&DoubleNear); }
TEST_F(DoubleNearTest, NanSensitiveDoubleNearApproximatelyMatchesDoubles) {
TestNearMatches(&NanSensitiveDoubleNear);
}
TEST_F(DoubleNearTest, DoubleNearCanDescribeSelf) {
Matcher<double> m1 = DoubleNear(2.0, 0.5);
EXPECT_EQ("is approximately 2 (absolute error <= 0.5)", Describe(m1));
EXPECT_EQ("isn't approximately 2 (absolute error > 0.5)",
DescribeNegation(m1));
Matcher<double> m2 = DoubleNear(0.5, 0.5);
EXPECT_EQ("is approximately 0.5 (absolute error <= 0.5)", Describe(m2));
EXPECT_EQ("isn't approximately 0.5 (absolute error > 0.5)",
DescribeNegation(m2));
Matcher<double> m3 = DoubleNear(nan1_, 0.0);
EXPECT_EQ("never matches", Describe(m3));
EXPECT_EQ("is anything", DescribeNegation(m3));
}
TEST_F(DoubleNearTest, ExplainsResultWhenMatchFails) {
EXPECT_EQ("", Explain(DoubleNear(2.0, 0.1), 2.05));
EXPECT_EQ("which is 0.2 from 2", Explain(DoubleNear(2.0, 0.1), 2.2));
EXPECT_EQ("which is -0.3 from 2", Explain(DoubleNear(2.0, 0.1), 1.7));
const std::string explanation =
Explain(DoubleNear(2.1, 1e-10), 2.1 + 1.2e-10);
// Different C++ implementations may print floating-point numbers
// slightly differently.
EXPECT_TRUE(explanation == "which is 1.2e-10 from 2.1" || // GCC
explanation == "which is 1.2e-010 from 2.1") // MSVC
<< " where explanation is \"" << explanation << "\".";
}
TEST_F(DoubleNearTest, NanSensitiveDoubleNearCanDescribeSelf) {
Matcher<double> m1 = NanSensitiveDoubleNear(2.0, 0.5);
EXPECT_EQ("is approximately 2 (absolute error <= 0.5)", Describe(m1));
EXPECT_EQ("isn't approximately 2 (absolute error > 0.5)",
DescribeNegation(m1));
Matcher<double> m2 = NanSensitiveDoubleNear(0.5, 0.5);
EXPECT_EQ("is approximately 0.5 (absolute error <= 0.5)", Describe(m2));
EXPECT_EQ("isn't approximately 0.5 (absolute error > 0.5)",
DescribeNegation(m2));
Matcher<double> m3 = NanSensitiveDoubleNear(nan1_, 0.1);
EXPECT_EQ("is NaN", Describe(m3));
EXPECT_EQ("isn't NaN", DescribeNegation(m3));
}
TEST_F(DoubleNearTest, DoubleNearCannotMatchNaN) {
// DoubleNear never matches NaN.
Matcher<double> m = DoubleNear(ParentType::nan1_, 0.1);
EXPECT_FALSE(m.Matches(nan1_));
EXPECT_FALSE(m.Matches(nan2_));
EXPECT_FALSE(m.Matches(1.0));
}
TEST_F(DoubleNearTest, NanSensitiveDoubleNearCanMatchNaN) {
// NanSensitiveDoubleNear will match NaN.
Matcher<double> m = NanSensitiveDoubleNear(nan1_, 0.1);
EXPECT_TRUE(m.Matches(nan1_));
EXPECT_TRUE(m.Matches(nan2_));
EXPECT_FALSE(m.Matches(1.0));
}
TEST(NotTest, WorksOnMoveOnlyType) {
std::unique_ptr<int> p(new int(3));
EXPECT_THAT(p, Pointee(Eq(3)));
EXPECT_THAT(p, Not(Pointee(Eq(2))));
}
TEST(AllOfTest, HugeMatcher) {
// Verify that using AllOf with many arguments doesn't cause
// the compiler to exceed template instantiation depth limit.
EXPECT_THAT(0, testing::AllOf(_, _, _, _, _, _, _, _, _,
testing::AllOf(_, _, _, _, _, _, _, _, _, _)));
}
TEST(AnyOfTest, HugeMatcher) {
// Verify that using AnyOf with many arguments doesn't cause
// the compiler to exceed template instantiation depth limit.
EXPECT_THAT(0, testing::AnyOf(_, _, _, _, _, _, _, _, _,
testing::AnyOf(_, _, _, _, _, _, _, _, _, _)));
}
namespace adl_test {
// Verifies that the implementation of ::testing::AllOf and ::testing::AnyOf
// don't issue unqualified recursive calls. If they do, the argument dependent
// name lookup will cause AllOf/AnyOf in the 'adl_test' namespace to be found
// as a candidate and the compilation will break due to an ambiguous overload.
// The matcher must be in the same namespace as AllOf/AnyOf to make argument
// dependent lookup find those.
MATCHER(M, "") {
(void)arg;
return true;
}
template <typename T1, typename T2>
bool AllOf(const T1& /*t1*/, const T2& /*t2*/) {
return true;
}
TEST(AllOfTest, DoesNotCallAllOfUnqualified) {
EXPECT_THAT(42,
testing::AllOf(M(), M(), M(), M(), M(), M(), M(), M(), M(), M()));
}
template <typename T1, typename T2>
bool AnyOf(const T1&, const T2&) {
return true;
}
TEST(AnyOfTest, DoesNotCallAnyOfUnqualified) {
EXPECT_THAT(42,
testing::AnyOf(M(), M(), M(), M(), M(), M(), M(), M(), M(), M()));
}
} // namespace adl_test
TEST(AllOfTest, WorksOnMoveOnlyType) {
std::unique_ptr<int> p(new int(3));
EXPECT_THAT(p, AllOf(Pointee(Eq(3)), Pointee(Gt(0)), Pointee(Lt(5))));
EXPECT_THAT(p, Not(AllOf(Pointee(Eq(3)), Pointee(Gt(0)), Pointee(Lt(3)))));
}
TEST(AnyOfTest, WorksOnMoveOnlyType) {
std::unique_ptr<int> p(new int(3));
EXPECT_THAT(p, AnyOf(Pointee(Eq(5)), Pointee(Lt(0)), Pointee(Lt(5))));
EXPECT_THAT(p, Not(AnyOf(Pointee(Eq(5)), Pointee(Lt(0)), Pointee(Gt(5)))));
}
} // namespace
} // namespace gmock_matchers_test
} // namespace testing
GTEST_DISABLE_MSC_WARNINGS_POP_() // 4244 4100