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Implements a subset of TR1 tuple needed by gtest and gmock (by Zhanyong Wan); cleaned up the Python tests (by Vlad Losev); made run_tests.py invokable from any directory (by Vlad Losev).

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This commit is contained in:
zhanyong.wan
2009-06-17 21:06:27 +00:00
parent 210ea10e7a
commit 532dc2de35
23 changed files with 1941 additions and 161 deletions
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43
include/gtest/internal/gtest-port.h
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@@ -58,11 +58,15 @@
// GTEST_HAS_STD_WSTRING - Define it to 1/0 to indicate that
// std::wstring does/doesn't work (Google Test can
// be used where std::wstring is unavailable).
// GTEST_HAS_TR1_TUPLE 1 - Define it to 1/0 to indicate tr1::tuple
// GTEST_HAS_TR1_TUPLE - Define it to 1/0 to indicate tr1::tuple
// is/isn't available.
// GTEST_HAS_SEH - Define it to 1/0 to indicate whether the
// compiler supports Microsoft's "Structured
// Exception Handling".
// GTEST_USE_OWN_TR1_TUPLE - Define it to 1/0 to indicate whether Google
// Test's own tr1 tuple implementation should be
// used. Unused when the user sets
// GTEST_HAS_TR1_TUPLE to 0.
// This header defines the following utilities:
//
@@ -339,28 +343,41 @@
#define GTEST_HAS_PTHREAD (GTEST_OS_LINUX || GTEST_OS_MAC)
#endif // GTEST_HAS_PTHREAD
// Determines whether tr1/tuple is available. If you have tr1/tuple
// on your platform, define GTEST_HAS_TR1_TUPLE=1 for both the Google
// Test project and your tests. If you would like Google Test to detect
// tr1/tuple on your platform automatically, please open an issue
// ticket at http://code.google.com/p/googletest.
// Determines whether Google Test can use tr1/tuple. You can define
// this macro to 0 to prevent Google Test from using tuple (any
// feature depending on tuple with be disabled in this mode).
#ifndef GTEST_HAS_TR1_TUPLE
// The user didn't tell us not to do it, so we assume it's OK.
#define GTEST_HAS_TR1_TUPLE 1
#endif // GTEST_HAS_TR1_TUPLE
// Determines whether Google Test's own tr1 tuple implementation
// should be used.
#ifndef GTEST_USE_OWN_TR1_TUPLE
// The user didn't tell us, so we need to figure it out.
// GCC provides <tr1/tuple> since 4.0.0.
// We use our own tr1 tuple if we aren't sure the user has an
// implementation of it already. At this time, GCC 4.0.0+ is the only
// mainstream compiler that comes with a TR1 tuple implementation.
// MSVC 2008 (9.0) provides TR1 tuple in a 323 MB Feature Pack
// download, which we cannot assume the user has. MSVC 2010 isn't
// released yet.
#if defined(__GNUC__) && (GTEST_GCC_VER_ >= 40000)
#define GTEST_HAS_TR1_TUPLE 1
#define GTEST_USE_OWN_TR1_TUPLE 0
#else
#define GTEST_HAS_TR1_TUPLE 0
#endif // __GNUC__
#endif // GTEST_HAS_TR1_TUPLE
#define GTEST_USE_OWN_TR1_TUPLE 1
#endif // defined(__GNUC__) && (GTEST_GCC_VER_ >= 40000)
#endif // GTEST_USE_OWN_TR1_TUPLE
// To avoid conditional compilation everywhere, we make it
// gtest-port.h's responsibility to #include the header implementing
// tr1/tuple.
#if GTEST_HAS_TR1_TUPLE
#if GTEST_OS_SYMBIAN
#if GTEST_USE_OWN_TR1_TUPLE
#include <gtest/internal/gtest-tuple.h>
#elif GTEST_OS_SYMBIAN
// On Symbian, BOOST_HAS_TR1_TUPLE causes Boost's TR1 tuple library to
// use STLport's tuple implementation, which unfortunately doesn't
@@ -398,7 +415,7 @@
// If the compiler is not GCC 4.0+, we assume the user is using a
// spec-conforming TR1 implementation.
#include <tuple>
#endif // GTEST_OS_SYMBIAN
#endif // GTEST_USE_OWN_TR1_TUPLE
#endif // GTEST_HAS_TR1_TUPLE

945
include/gtest/internal/gtest-tuple.h Normal file
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@@ -0,0 +1,945 @@
// This file was GENERATED by a script. DO NOT EDIT BY HAND!!!
// Copyright 2009 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)
// Implements a subset of TR1 tuple needed by Google Test and Google Mock.
#ifndef GTEST_INCLUDE_GTEST_INTERAL_GTEST_TUPLE_H_
#define GTEST_INCLUDE_GTEST_INTERAL_GTEST_TUPLE_H_
#include <utility> // For ::std::pair.
// GTEST_n_TUPLE_(T) is the type of an n-tuple.
#define GTEST_0_TUPLE_(T) tuple<>
#define GTEST_1_TUPLE_(T) tuple<T##0>
#define GTEST_2_TUPLE_(T) tuple<T##0, T##1>
#define GTEST_3_TUPLE_(T) tuple<T##0, T##1, T##2>
#define GTEST_4_TUPLE_(T) tuple<T##0, T##1, T##2, T##3>
#define GTEST_5_TUPLE_(T) tuple<T##0, T##1, T##2, T##3, T##4>
#define GTEST_6_TUPLE_(T) tuple<T##0, T##1, T##2, T##3, T##4, T##5>
#define GTEST_7_TUPLE_(T) tuple<T##0, T##1, T##2, T##3, T##4, T##5, T##6>
#define GTEST_8_TUPLE_(T) tuple<T##0, T##1, T##2, T##3, T##4, T##5, T##6, T##7>
#define GTEST_9_TUPLE_(T) tuple<T##0, T##1, T##2, T##3, T##4, T##5, T##6, \
T##7, T##8>
#define GTEST_10_TUPLE_(T) tuple<T##0, T##1, T##2, T##3, T##4, T##5, T##6, \
T##7, T##8, T##9>
// GTEST_n_TYPENAMES_(T) declares a list of n typenames.
#define GTEST_0_TYPENAMES_(T)
#define GTEST_1_TYPENAMES_(T) typename T##0
#define GTEST_2_TYPENAMES_(T) typename T##0, typename T##1
#define GTEST_3_TYPENAMES_(T) typename T##0, typename T##1, typename T##2
#define GTEST_4_TYPENAMES_(T) typename T##0, typename T##1, typename T##2, \
typename T##3
#define GTEST_5_TYPENAMES_(T) typename T##0, typename T##1, typename T##2, \
typename T##3, typename T##4
#define GTEST_6_TYPENAMES_(T) typename T##0, typename T##1, typename T##2, \
typename T##3, typename T##4, typename T##5
#define GTEST_7_TYPENAMES_(T) typename T##0, typename T##1, typename T##2, \
typename T##3, typename T##4, typename T##5, typename T##6
#define GTEST_8_TYPENAMES_(T) typename T##0, typename T##1, typename T##2, \
typename T##3, typename T##4, typename T##5, typename T##6, typename T##7
#define GTEST_9_TYPENAMES_(T) typename T##0, typename T##1, typename T##2, \
typename T##3, typename T##4, typename T##5, typename T##6, \
typename T##7, typename T##8
#define GTEST_10_TYPENAMES_(T) typename T##0, typename T##1, typename T##2, \
typename T##3, typename T##4, typename T##5, typename T##6, \
typename T##7, typename T##8, typename T##9
// In theory, defining stuff in the ::std namespace is undefined
// behavior. We can do this as we are playing the role of a standard
// library vendor.
namespace std {
namespace tr1 {
template <typename T0 = void, typename T1 = void, typename T2 = void,
typename T3 = void, typename T4 = void, typename T5 = void,
typename T6 = void, typename T7 = void, typename T8 = void,
typename T9 = void>
class tuple;
// Anything in namespace gtest_internal is Google Test's INTERNAL
// IMPLEMENTATION DETAIL and MUST NOT BE USED DIRECTLY in user code.
namespace gtest_internal {
// ByRef<T>::type is T if T is a reference; otherwise it's const T&.
template <typename T>
struct ByRef { typedef const T& type; }; // NOLINT
template <typename T>
struct ByRef<T&> { typedef T& type; }; // NOLINT
// A handy wrapper for ByRef.
#define GTEST_BY_REF_(T) typename ::std::tr1::gtest_internal::ByRef<T>::type
// AddRef<T>::type is T if T is a reference; otherwise it's T&. This
// is the same as tr1::add_reference<T>::type.
template <typename T>
struct AddRef { typedef T& type; }; // NOLINT
template <typename T>
struct AddRef<T&> { typedef T& type; }; // NOLINT
// A handy wrapper for AddRef.
#define GTEST_ADD_REF_(T) typename ::std::tr1::gtest_internal::AddRef<T>::type
// A helper for implementing get<k>().
template <int k> class Get;
// A helper for implementing tuple_element<k, T>. kIndexValid is true
// iff k < the number of fields in tuple type T.
template <bool kIndexValid, int kIndex, class Tuple>
struct TupleElement;
template <GTEST_10_TYPENAMES_(T)>
struct TupleElement<true, 0, GTEST_10_TUPLE_(T)> { typedef T0 type; };
template <GTEST_10_TYPENAMES_(T)>
struct TupleElement<true, 1, GTEST_10_TUPLE_(T)> { typedef T1 type; };
template <GTEST_10_TYPENAMES_(T)>
struct TupleElement<true, 2, GTEST_10_TUPLE_(T)> { typedef T2 type; };
template <GTEST_10_TYPENAMES_(T)>
struct TupleElement<true, 3, GTEST_10_TUPLE_(T)> { typedef T3 type; };
template <GTEST_10_TYPENAMES_(T)>
struct TupleElement<true, 4, GTEST_10_TUPLE_(T)> { typedef T4 type; };
template <GTEST_10_TYPENAMES_(T)>
struct TupleElement<true, 5, GTEST_10_TUPLE_(T)> { typedef T5 type; };
template <GTEST_10_TYPENAMES_(T)>
struct TupleElement<true, 6, GTEST_10_TUPLE_(T)> { typedef T6 type; };
template <GTEST_10_TYPENAMES_(T)>
struct TupleElement<true, 7, GTEST_10_TUPLE_(T)> { typedef T7 type; };
template <GTEST_10_TYPENAMES_(T)>
struct TupleElement<true, 8, GTEST_10_TUPLE_(T)> { typedef T8 type; };
template <GTEST_10_TYPENAMES_(T)>
struct TupleElement<true, 9, GTEST_10_TUPLE_(T)> { typedef T9 type; };
} // namespace gtest_internal
template <>
class tuple<> {
public:
tuple() {}
tuple(const tuple& /* t */) {}
tuple& operator=(const tuple& /* t */) { return *this; }
};
template <GTEST_1_TYPENAMES_(T)>
class GTEST_1_TUPLE_(T) {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_10_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple(GTEST_BY_REF_(T0) f0) : f0_(f0) {}
tuple(const tuple& t) : f0_(t.f0_) {}
template <GTEST_1_TYPENAMES_(U)>
tuple(const GTEST_1_TUPLE_(U)& t) : f0_(t.f0_) {}
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_1_TYPENAMES_(U)>
tuple& operator=(const GTEST_1_TUPLE_(U)& t) {
return CopyFrom(t);
}
private:
template <GTEST_1_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_1_TUPLE_(U)& t) {
f0_ = t.f0_;
return *this;
}
T0 f0_;
};
template <GTEST_2_TYPENAMES_(T)>
class GTEST_2_TUPLE_(T) {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_10_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple(GTEST_BY_REF_(T0) f0, GTEST_BY_REF_(T1) f1) : f0_(f0),
f1_(f1) {}
tuple(const tuple& t) : f0_(t.f0_), f1_(t.f1_) {}
template <GTEST_2_TYPENAMES_(U)>
tuple(const GTEST_2_TUPLE_(U)& t) : f0_(t.f0_), f1_(t.f1_) {}
template <typename U0, typename U1>
tuple(const ::std::pair<U0, U1>& p) : f0_(p.first), f1_(p.second) {}
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_2_TYPENAMES_(U)>
tuple& operator=(const GTEST_2_TUPLE_(U)& t) {
return CopyFrom(t);
}
template <typename U0, typename U1>
tuple& operator=(const ::std::pair<U0, U1>& p) {
f0_ = p.first;
f1_ = p.second;
return *this;
}
private:
template <GTEST_2_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_2_TUPLE_(U)& t) {
f0_ = t.f0_;
f1_ = t.f1_;
return *this;
}
T0 f0_;
T1 f1_;
};
template <GTEST_3_TYPENAMES_(T)>
class GTEST_3_TUPLE_(T) {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_10_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple(GTEST_BY_REF_(T0) f0, GTEST_BY_REF_(T1) f1,
GTEST_BY_REF_(T2) f2) : f0_(f0), f1_(f1), f2_(f2) {}
tuple(const tuple& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_) {}
template <GTEST_3_TYPENAMES_(U)>
tuple(const GTEST_3_TUPLE_(U)& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_) {}
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_3_TYPENAMES_(U)>
tuple& operator=(const GTEST_3_TUPLE_(U)& t) {
return CopyFrom(t);
}
private:
template <GTEST_3_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_3_TUPLE_(U)& t) {
f0_ = t.f0_;
f1_ = t.f1_;
f2_ = t.f2_;
return *this;
}
T0 f0_;
T1 f1_;
T2 f2_;
};
template <GTEST_4_TYPENAMES_(T)>
class GTEST_4_TUPLE_(T) {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_10_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple(GTEST_BY_REF_(T0) f0, GTEST_BY_REF_(T1) f1,
GTEST_BY_REF_(T2) f2, GTEST_BY_REF_(T3) f3) : f0_(f0), f1_(f1), f2_(f2),
f3_(f3) {}
tuple(const tuple& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_), f3_(t.f3_) {}
template <GTEST_4_TYPENAMES_(U)>
tuple(const GTEST_4_TUPLE_(U)& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_),
f3_(t.f3_) {}
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_4_TYPENAMES_(U)>
tuple& operator=(const GTEST_4_TUPLE_(U)& t) {
return CopyFrom(t);
}
private:
template <GTEST_4_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_4_TUPLE_(U)& t) {
f0_ = t.f0_;
f1_ = t.f1_;
f2_ = t.f2_;
f3_ = t.f3_;
return *this;
}
T0 f0_;
T1 f1_;
T2 f2_;
T3 f3_;
};
template <GTEST_5_TYPENAMES_(T)>
class GTEST_5_TUPLE_(T) {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_10_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple(GTEST_BY_REF_(T0) f0, GTEST_BY_REF_(T1) f1,
GTEST_BY_REF_(T2) f2, GTEST_BY_REF_(T3) f3,
GTEST_BY_REF_(T4) f4) : f0_(f0), f1_(f1), f2_(f2), f3_(f3), f4_(f4) {}
tuple(const tuple& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_), f3_(t.f3_),
f4_(t.f4_) {}
template <GTEST_5_TYPENAMES_(U)>
tuple(const GTEST_5_TUPLE_(U)& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_),
f3_(t.f3_), f4_(t.f4_) {}
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_5_TYPENAMES_(U)>
tuple& operator=(const GTEST_5_TUPLE_(U)& t) {
return CopyFrom(t);
}
private:
template <GTEST_5_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_5_TUPLE_(U)& t) {
f0_ = t.f0_;
f1_ = t.f1_;
f2_ = t.f2_;
f3_ = t.f3_;
f4_ = t.f4_;
return *this;
}
T0 f0_;
T1 f1_;
T2 f2_;
T3 f3_;
T4 f4_;
};
template <GTEST_6_TYPENAMES_(T)>
class GTEST_6_TUPLE_(T) {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_10_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple(GTEST_BY_REF_(T0) f0, GTEST_BY_REF_(T1) f1,
GTEST_BY_REF_(T2) f2, GTEST_BY_REF_(T3) f3, GTEST_BY_REF_(T4) f4,
GTEST_BY_REF_(T5) f5) : f0_(f0), f1_(f1), f2_(f2), f3_(f3), f4_(f4),
f5_(f5) {}
tuple(const tuple& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_), f3_(t.f3_),
f4_(t.f4_), f5_(t.f5_) {}
template <GTEST_6_TYPENAMES_(U)>
tuple(const GTEST_6_TUPLE_(U)& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_),
f3_(t.f3_), f4_(t.f4_), f5_(t.f5_) {}
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_6_TYPENAMES_(U)>
tuple& operator=(const GTEST_6_TUPLE_(U)& t) {
return CopyFrom(t);
}
private:
template <GTEST_6_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_6_TUPLE_(U)& t) {
f0_ = t.f0_;
f1_ = t.f1_;
f2_ = t.f2_;
f3_ = t.f3_;
f4_ = t.f4_;
f5_ = t.f5_;
return *this;
}
T0 f0_;
T1 f1_;
T2 f2_;
T3 f3_;
T4 f4_;
T5 f5_;
};
template <GTEST_7_TYPENAMES_(T)>
class GTEST_7_TUPLE_(T) {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_10_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple(GTEST_BY_REF_(T0) f0, GTEST_BY_REF_(T1) f1,
GTEST_BY_REF_(T2) f2, GTEST_BY_REF_(T3) f3, GTEST_BY_REF_(T4) f4,
GTEST_BY_REF_(T5) f5, GTEST_BY_REF_(T6) f6) : f0_(f0), f1_(f1), f2_(f2),
f3_(f3), f4_(f4), f5_(f5), f6_(f6) {}
tuple(const tuple& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_), f3_(t.f3_),
f4_(t.f4_), f5_(t.f5_), f6_(t.f6_) {}
template <GTEST_7_TYPENAMES_(U)>
tuple(const GTEST_7_TUPLE_(U)& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_),
f3_(t.f3_), f4_(t.f4_), f5_(t.f5_), f6_(t.f6_) {}
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_7_TYPENAMES_(U)>
tuple& operator=(const GTEST_7_TUPLE_(U)& t) {
return CopyFrom(t);
}
private:
template <GTEST_7_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_7_TUPLE_(U)& t) {
f0_ = t.f0_;
f1_ = t.f1_;
f2_ = t.f2_;
f3_ = t.f3_;
f4_ = t.f4_;
f5_ = t.f5_;
f6_ = t.f6_;
return *this;
}
T0 f0_;
T1 f1_;
T2 f2_;
T3 f3_;
T4 f4_;
T5 f5_;
T6 f6_;
};
template <GTEST_8_TYPENAMES_(T)>
class GTEST_8_TUPLE_(T) {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_10_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple(GTEST_BY_REF_(T0) f0, GTEST_BY_REF_(T1) f1,
GTEST_BY_REF_(T2) f2, GTEST_BY_REF_(T3) f3, GTEST_BY_REF_(T4) f4,
GTEST_BY_REF_(T5) f5, GTEST_BY_REF_(T6) f6,
GTEST_BY_REF_(T7) f7) : f0_(f0), f1_(f1), f2_(f2), f3_(f3), f4_(f4),
f5_(f5), f6_(f6), f7_(f7) {}
tuple(const tuple& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_), f3_(t.f3_),
f4_(t.f4_), f5_(t.f5_), f6_(t.f6_), f7_(t.f7_) {}
template <GTEST_8_TYPENAMES_(U)>
tuple(const GTEST_8_TUPLE_(U)& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_),
f3_(t.f3_), f4_(t.f4_), f5_(t.f5_), f6_(t.f6_), f7_(t.f7_) {}
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_8_TYPENAMES_(U)>
tuple& operator=(const GTEST_8_TUPLE_(U)& t) {
return CopyFrom(t);
}
private:
template <GTEST_8_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_8_TUPLE_(U)& t) {
f0_ = t.f0_;
f1_ = t.f1_;
f2_ = t.f2_;
f3_ = t.f3_;
f4_ = t.f4_;
f5_ = t.f5_;
f6_ = t.f6_;
f7_ = t.f7_;
return *this;
}
T0 f0_;
T1 f1_;
T2 f2_;
T3 f3_;
T4 f4_;
T5 f5_;
T6 f6_;
T7 f7_;
};
template <GTEST_9_TYPENAMES_(T)>
class GTEST_9_TUPLE_(T) {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_10_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple(GTEST_BY_REF_(T0) f0, GTEST_BY_REF_(T1) f1,
GTEST_BY_REF_(T2) f2, GTEST_BY_REF_(T3) f3, GTEST_BY_REF_(T4) f4,
GTEST_BY_REF_(T5) f5, GTEST_BY_REF_(T6) f6, GTEST_BY_REF_(T7) f7,
GTEST_BY_REF_(T8) f8) : f0_(f0), f1_(f1), f2_(f2), f3_(f3), f4_(f4),
f5_(f5), f6_(f6), f7_(f7), f8_(f8) {}
tuple(const tuple& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_), f3_(t.f3_),
f4_(t.f4_), f5_(t.f5_), f6_(t.f6_), f7_(t.f7_), f8_(t.f8_) {}
template <GTEST_9_TYPENAMES_(U)>
tuple(const GTEST_9_TUPLE_(U)& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_),
f3_(t.f3_), f4_(t.f4_), f5_(t.f5_), f6_(t.f6_), f7_(t.f7_), f8_(t.f8_) {}
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_9_TYPENAMES_(U)>
tuple& operator=(const GTEST_9_TUPLE_(U)& t) {
return CopyFrom(t);
}
private:
template <GTEST_9_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_9_TUPLE_(U)& t) {
f0_ = t.f0_;
f1_ = t.f1_;
f2_ = t.f2_;
f3_ = t.f3_;
f4_ = t.f4_;
f5_ = t.f5_;
f6_ = t.f6_;
f7_ = t.f7_;
f8_ = t.f8_;
return *this;
}
T0 f0_;
T1 f1_;
T2 f2_;
T3 f3_;
T4 f4_;
T5 f5_;
T6 f6_;
T7 f7_;
T8 f8_;
};
template <GTEST_10_TYPENAMES_(T)>
class tuple {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_10_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple(GTEST_BY_REF_(T0) f0, GTEST_BY_REF_(T1) f1,
GTEST_BY_REF_(T2) f2, GTEST_BY_REF_(T3) f3, GTEST_BY_REF_(T4) f4,
GTEST_BY_REF_(T5) f5, GTEST_BY_REF_(T6) f6, GTEST_BY_REF_(T7) f7,
GTEST_BY_REF_(T8) f8, GTEST_BY_REF_(T9) f9) : f0_(f0), f1_(f1), f2_(f2),
f3_(f3), f4_(f4), f5_(f5), f6_(f6), f7_(f7), f8_(f8), f9_(f9) {}
tuple(const tuple& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_), f3_(t.f3_),
f4_(t.f4_), f5_(t.f5_), f6_(t.f6_), f7_(t.f7_), f8_(t.f8_), f9_(t.f9_) {}
template <GTEST_10_TYPENAMES_(U)>
tuple(const GTEST_10_TUPLE_(U)& t) : f0_(t.f0_), f1_(t.f1_), f2_(t.f2_),
f3_(t.f3_), f4_(t.f4_), f5_(t.f5_), f6_(t.f6_), f7_(t.f7_), f8_(t.f8_),
f9_(t.f9_) {}
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_10_TYPENAMES_(U)>
tuple& operator=(const GTEST_10_TUPLE_(U)& t) {
return CopyFrom(t);
}
private:
template <GTEST_10_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_10_TUPLE_(U)& t) {
f0_ = t.f0_;
f1_ = t.f1_;
f2_ = t.f2_;
f3_ = t.f3_;
f4_ = t.f4_;
f5_ = t.f5_;
f6_ = t.f6_;
f7_ = t.f7_;
f8_ = t.f8_;
f9_ = t.f9_;
return *this;
}
T0 f0_;
T1 f1_;
T2 f2_;
T3 f3_;
T4 f4_;
T5 f5_;
T6 f6_;
T7 f7_;
T8 f8_;
T9 f9_;
};
// 6.1.3.2 Tuple creation functions.
// Known limitations: we don't support passing an
// std::tr1::reference_wrapper<T> to make_tuple(). And we don't
// implement tie().
inline tuple<> make_tuple() { return tuple<>(); }
template <GTEST_1_TYPENAMES_(T)>
inline GTEST_1_TUPLE_(T) make_tuple(const T0& f0) {
return GTEST_1_TUPLE_(T)(f0);
}
template <GTEST_2_TYPENAMES_(T)>
inline GTEST_2_TUPLE_(T) make_tuple(const T0& f0, const T1& f1) {
return GTEST_2_TUPLE_(T)(f0, f1);
}
template <GTEST_3_TYPENAMES_(T)>
inline GTEST_3_TUPLE_(T) make_tuple(const T0& f0, const T1& f1, const T2& f2) {
return GTEST_3_TUPLE_(T)(f0, f1, f2);
}
template <GTEST_4_TYPENAMES_(T)>
inline GTEST_4_TUPLE_(T) make_tuple(const T0& f0, const T1& f1, const T2& f2,
const T3& f3) {
return GTEST_4_TUPLE_(T)(f0, f1, f2, f3);
}
template <GTEST_5_TYPENAMES_(T)>
inline GTEST_5_TUPLE_(T) make_tuple(const T0& f0, const T1& f1, const T2& f2,
const T3& f3, const T4& f4) {
return GTEST_5_TUPLE_(T)(f0, f1, f2, f3, f4);
}
template <GTEST_6_TYPENAMES_(T)>
inline GTEST_6_TUPLE_(T) make_tuple(const T0& f0, const T1& f1, const T2& f2,
const T3& f3, const T4& f4, const T5& f5) {
return GTEST_6_TUPLE_(T)(f0, f1, f2, f3, f4, f5);
}
template <GTEST_7_TYPENAMES_(T)>
inline GTEST_7_TUPLE_(T) make_tuple(const T0& f0, const T1& f1, const T2& f2,
const T3& f3, const T4& f4, const T5& f5, const T6& f6) {
return GTEST_7_TUPLE_(T)(f0, f1, f2, f3, f4, f5, f6);
}
template <GTEST_8_TYPENAMES_(T)>
inline GTEST_8_TUPLE_(T) make_tuple(const T0& f0, const T1& f1, const T2& f2,
const T3& f3, const T4& f4, const T5& f5, const T6& f6, const T7& f7) {
return GTEST_8_TUPLE_(T)(f0, f1, f2, f3, f4, f5, f6, f7);
}
template <GTEST_9_TYPENAMES_(T)>
inline GTEST_9_TUPLE_(T) make_tuple(const T0& f0, const T1& f1, const T2& f2,
const T3& f3, const T4& f4, const T5& f5, const T6& f6, const T7& f7,
const T8& f8) {
return GTEST_9_TUPLE_(T)(f0, f1, f2, f3, f4, f5, f6, f7, f8);
}
template <GTEST_10_TYPENAMES_(T)>
inline GTEST_10_TUPLE_(T) make_tuple(const T0& f0, const T1& f1, const T2& f2,
const T3& f3, const T4& f4, const T5& f5, const T6& f6, const T7& f7,
const T8& f8, const T9& f9) {
return GTEST_10_TUPLE_(T)(f0, f1, f2, f3, f4, f5, f6, f7, f8, f9);
}
// 6.1.3.3 Tuple helper classes.
template <typename Tuple> struct tuple_size;
template <GTEST_0_TYPENAMES_(T)>
struct tuple_size<GTEST_0_TUPLE_(T)> { static const int value = 0; };
template <GTEST_1_TYPENAMES_(T)>
struct tuple_size<GTEST_1_TUPLE_(T)> { static const int value = 1; };
template <GTEST_2_TYPENAMES_(T)>
struct tuple_size<GTEST_2_TUPLE_(T)> { static const int value = 2; };
template <GTEST_3_TYPENAMES_(T)>
struct tuple_size<GTEST_3_TUPLE_(T)> { static const int value = 3; };
template <GTEST_4_TYPENAMES_(T)>
struct tuple_size<GTEST_4_TUPLE_(T)> { static const int value = 4; };
template <GTEST_5_TYPENAMES_(T)>
struct tuple_size<GTEST_5_TUPLE_(T)> { static const int value = 5; };
template <GTEST_6_TYPENAMES_(T)>
struct tuple_size<GTEST_6_TUPLE_(T)> { static const int value = 6; };
template <GTEST_7_TYPENAMES_(T)>
struct tuple_size<GTEST_7_TUPLE_(T)> { static const int value = 7; };
template <GTEST_8_TYPENAMES_(T)>
struct tuple_size<GTEST_8_TUPLE_(T)> { static const int value = 8; };
template <GTEST_9_TYPENAMES_(T)>
struct tuple_size<GTEST_9_TUPLE_(T)> { static const int value = 9; };
template <GTEST_10_TYPENAMES_(T)>
struct tuple_size<GTEST_10_TUPLE_(T)> { static const int value = 10; };
template <int k, class Tuple>
struct tuple_element {
typedef typename gtest_internal::TupleElement<
k < (tuple_size<Tuple>::value), k, Tuple>::type type;
};
#define GTEST_TUPLE_ELEMENT_(k, Tuple) typename tuple_element<k, Tuple >::type
// 6.1.3.4 Element access.
namespace gtest_internal {
template <>
class Get<0> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(0, Tuple))
Field(Tuple& t) { return t.f0_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(0, Tuple))
ConstField(const Tuple& t) { return t.f0_; }
};
template <>
class Get<1> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(1, Tuple))
Field(Tuple& t) { return t.f1_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(1, Tuple))
ConstField(const Tuple& t) { return t.f1_; }
};
template <>
class Get<2> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(2, Tuple))
Field(Tuple& t) { return t.f2_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(2, Tuple))
ConstField(const Tuple& t) { return t.f2_; }
};
template <>
class Get<3> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(3, Tuple))
Field(Tuple& t) { return t.f3_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(3, Tuple))
ConstField(const Tuple& t) { return t.f3_; }
};
template <>
class Get<4> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(4, Tuple))
Field(Tuple& t) { return t.f4_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(4, Tuple))
ConstField(const Tuple& t) { return t.f4_; }
};
template <>
class Get<5> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(5, Tuple))
Field(Tuple& t) { return t.f5_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(5, Tuple))
ConstField(const Tuple& t) { return t.f5_; }
};
template <>
class Get<6> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(6, Tuple))
Field(Tuple& t) { return t.f6_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(6, Tuple))
ConstField(const Tuple& t) { return t.f6_; }
};
template <>
class Get<7> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(7, Tuple))
Field(Tuple& t) { return t.f7_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(7, Tuple))
ConstField(const Tuple& t) { return t.f7_; }
};
template <>
class Get<8> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(8, Tuple))
Field(Tuple& t) { return t.f8_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(8, Tuple))
ConstField(const Tuple& t) { return t.f8_; }
};
template <>
class Get<9> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(9, Tuple))
Field(Tuple& t) { return t.f9_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(9, Tuple))
ConstField(const Tuple& t) { return t.f9_; }
};
} // namespace gtest_internal
template <int k, GTEST_10_TYPENAMES_(T)>
GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(k, GTEST_10_TUPLE_(T)))
get(GTEST_10_TUPLE_(T)& t) {
return gtest_internal::Get<k>::Field(t);
}
template <int k, GTEST_10_TYPENAMES_(T)>
GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(k, GTEST_10_TUPLE_(T)))
get(const GTEST_10_TUPLE_(T)& t) {
return gtest_internal::Get<k>::ConstField(t);
}
// 6.1.3.5 Relational operators
// We only implement == and !=, as we don't have a need for the rest yet.
namespace gtest_internal {
// SameSizeTuplePrefixComparator<k, k>::Eq(t1, t2) returns true if the
// first k fields of t1 equals the first k fields of t2.
// SameSizeTuplePrefixComparator(k1, k2) would be a compiler error if
// k1 != k2.
template <int kSize1, int kSize2>
struct SameSizeTuplePrefixComparator;
template <>
struct SameSizeTuplePrefixComparator<0, 0> {
template <class Tuple1, class Tuple2>
static bool Eq(const Tuple1& /* t1 */, const Tuple2& /* t2 */) {
return true;
}
};
template <int k>
struct SameSizeTuplePrefixComparator<k, k> {
template <class Tuple1, class Tuple2>
static bool Eq(const Tuple1& t1, const Tuple2& t2) {
return SameSizeTuplePrefixComparator<k - 1, k - 1>::Eq(t1, t2) &&
::std::tr1::get<k - 1>(t1) == ::std::tr1::get<k - 1>(t2);
}
};
} // namespace gtest_internal
template <GTEST_10_TYPENAMES_(T), GTEST_10_TYPENAMES_(U)>
inline bool operator==(const GTEST_10_TUPLE_(T)& t,
const GTEST_10_TUPLE_(U)& u) {
return gtest_internal::SameSizeTuplePrefixComparator<
tuple_size<GTEST_10_TUPLE_(T)>::value,
tuple_size<GTEST_10_TUPLE_(U)>::value>::Eq(t, u);
}
template <GTEST_10_TYPENAMES_(T), GTEST_10_TYPENAMES_(U)>
inline bool operator!=(const GTEST_10_TUPLE_(T)& t,
const GTEST_10_TUPLE_(U)& u) { return !(t == u); }
// 6.1.4 Pairs.
// Unimplemented.
} // namespace tr1
} // namespace std
#undef GTEST_0_TUPLE_
#undef GTEST_1_TUPLE_
#undef GTEST_2_TUPLE_
#undef GTEST_3_TUPLE_
#undef GTEST_4_TUPLE_
#undef GTEST_5_TUPLE_
#undef GTEST_6_TUPLE_
#undef GTEST_7_TUPLE_
#undef GTEST_8_TUPLE_
#undef GTEST_9_TUPLE_
#undef GTEST_10_TUPLE_
#undef GTEST_0_TYPENAMES_
#undef GTEST_1_TYPENAMES_
#undef GTEST_2_TYPENAMES_
#undef GTEST_3_TYPENAMES_
#undef GTEST_4_TYPENAMES_
#undef GTEST_5_TYPENAMES_
#undef GTEST_6_TYPENAMES_
#undef GTEST_7_TYPENAMES_
#undef GTEST_8_TYPENAMES_
#undef GTEST_9_TYPENAMES_
#undef GTEST_10_TYPENAMES_
#undef GTEST_BY_REF_
#undef GTEST_ADD_REF_
#undef GTEST_TUPLE_ELEMENT_
#endif // GTEST_INCLUDE_GTEST_INTERAL_GTEST_TUPLE_H_

320
include/gtest/internal/gtest-tuple.h.pump Normal file
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@@ -0,0 +1,320 @@
$$ -*- mode: c++; -*-
$var n = 10 $$ Maximum number of tuple fields we want to support.
$$ This meta comment fixes auto-indentation in Emacs. }}
// Copyright 2009 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)
// Implements a subset of TR1 tuple needed by Google Test and Google Mock.
#ifndef GTEST_INCLUDE_GTEST_INTERAL_GTEST_TUPLE_H_
#define GTEST_INCLUDE_GTEST_INTERAL_GTEST_TUPLE_H_
#include <utility> // For ::std::pair.
$range i 0..n-1
$range j 0..n
$range k 1..n
// GTEST_n_TUPLE_(T) is the type of an n-tuple.
$for j [[
$range m 0..j-1
#define GTEST_$(j)_TUPLE_(T) tuple<$for m, [[T##$m]]>
]]
// GTEST_n_TYPENAMES_(T) declares a list of n typenames.
$for j [[
$range m 0..j-1
#define GTEST_$(j)_TYPENAMES_(T) $for m, [[typename T##$m]]
]]
// In theory, defining stuff in the ::std namespace is undefined
// behavior. We can do this as we are playing the role of a standard
// library vendor.
namespace std {
namespace tr1 {
template <$for i, [[typename T$i = void]]>
class tuple;
// Anything in namespace gtest_internal is Google Test's INTERNAL
// IMPLEMENTATION DETAIL and MUST NOT BE USED DIRECTLY in user code.
namespace gtest_internal {
// ByRef<T>::type is T if T is a reference; otherwise it's const T&.
template <typename T>
struct ByRef { typedef const T& type; }; // NOLINT
template <typename T>
struct ByRef<T&> { typedef T& type; }; // NOLINT
// A handy wrapper for ByRef.
#define GTEST_BY_REF_(T) typename ::std::tr1::gtest_internal::ByRef<T>::type
// AddRef<T>::type is T if T is a reference; otherwise it's T&. This
// is the same as tr1::add_reference<T>::type.
template <typename T>
struct AddRef { typedef T& type; }; // NOLINT
template <typename T>
struct AddRef<T&> { typedef T& type; }; // NOLINT
// A handy wrapper for AddRef.
#define GTEST_ADD_REF_(T) typename ::std::tr1::gtest_internal::AddRef<T>::type
// A helper for implementing get<k>().
template <int k> class Get;
// A helper for implementing tuple_element<k, T>. kIndexValid is true
// iff k < the number of fields in tuple type T.
template <bool kIndexValid, int kIndex, class Tuple>
struct TupleElement;
$for i [[
template <GTEST_$(n)_TYPENAMES_(T)>
struct TupleElement<true, $i, GTEST_$(n)_TUPLE_(T)> [[]]
{ typedef T$i type; };
]]
} // namespace gtest_internal
template <>
class tuple<> {
public:
tuple() {}
tuple(const tuple& /* t */) {}
tuple& operator=(const tuple& /* t */) { return *this; }
};
$for k [[
$range m 0..k-1
template <GTEST_$(k)_TYPENAMES_(T)>
class $if k < n [[GTEST_$(k)_TUPLE_(T)]] $else [[tuple]] {
public:
template <int k> friend class gtest_internal::Get;
template <GTEST_$(n)_TYPENAMES_(U)> friend class tuple;
tuple() {}
explicit tuple($for m, [[GTEST_BY_REF_(T$m) f$m]]) : [[]]
$for m, [[f$(m)_(f$m)]] {}
tuple(const tuple& t) : $for m, [[f$(m)_(t.f$(m)_)]] {}
template <GTEST_$(k)_TYPENAMES_(U)>
tuple(const GTEST_$(k)_TUPLE_(U)& t) : $for m, [[f$(m)_(t.f$(m)_)]] {}
$if k == 2 [[
template <typename U0, typename U1>
tuple(const ::std::pair<U0, U1>& p) : f0_(p.first), f1_(p.second) {}
]]
tuple& operator=(const tuple& t) { return CopyFrom(t); }
template <GTEST_$(k)_TYPENAMES_(U)>
tuple& operator=(const GTEST_$(k)_TUPLE_(U)& t) {
return CopyFrom(t);
}
$if k == 2 [[
template <typename U0, typename U1>
tuple& operator=(const ::std::pair<U0, U1>& p) {
f0_ = p.first;
f1_ = p.second;
return *this;
}
]]
private:
template <GTEST_$(k)_TYPENAMES_(U)>
tuple& CopyFrom(const GTEST_$(k)_TUPLE_(U)& t) {
$for m [[
f$(m)_ = t.f$(m)_;
]]
return *this;
}
$for m [[
T$m f$(m)_;
]]
};
]]
// 6.1.3.2 Tuple creation functions.
// Known limitations: we don't support passing an
// std::tr1::reference_wrapper<T> to make_tuple(). And we don't
// implement tie().
inline tuple<> make_tuple() { return tuple<>(); }
$for k [[
$range m 0..k-1
template <GTEST_$(k)_TYPENAMES_(T)>
inline GTEST_$(k)_TUPLE_(T) make_tuple($for m, [[const T$m& f$m]]) {
return GTEST_$(k)_TUPLE_(T)($for m, [[f$m]]);
}
]]
// 6.1.3.3 Tuple helper classes.
template <typename Tuple> struct tuple_size;
$for j [[
template <GTEST_$(j)_TYPENAMES_(T)>
struct tuple_size<GTEST_$(j)_TUPLE_(T)> { static const int value = $j; };
]]
template <int k, class Tuple>
struct tuple_element {
typedef typename gtest_internal::TupleElement<
k < (tuple_size<Tuple>::value), k, Tuple>::type type;
};
#define GTEST_TUPLE_ELEMENT_(k, Tuple) typename tuple_element<k, Tuple >::type
// 6.1.3.4 Element access.
namespace gtest_internal {
$for i [[
template <>
class Get<$i> {
public:
template <class Tuple>
static GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_($i, Tuple))
Field(Tuple& t) { return t.f$(i)_; } // NOLINT
template <class Tuple>
static GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_($i, Tuple))
ConstField(const Tuple& t) { return t.f$(i)_; }
};
]]
} // namespace gtest_internal
template <int k, GTEST_$(n)_TYPENAMES_(T)>
GTEST_ADD_REF_(GTEST_TUPLE_ELEMENT_(k, GTEST_$(n)_TUPLE_(T)))
get(GTEST_$(n)_TUPLE_(T)& t) {
return gtest_internal::Get<k>::Field(t);
}
template <int k, GTEST_$(n)_TYPENAMES_(T)>
GTEST_BY_REF_(GTEST_TUPLE_ELEMENT_(k, GTEST_$(n)_TUPLE_(T)))
get(const GTEST_$(n)_TUPLE_(T)& t) {
return gtest_internal::Get<k>::ConstField(t);
}
// 6.1.3.5 Relational operators
// We only implement == and !=, as we don't have a need for the rest yet.
namespace gtest_internal {
// SameSizeTuplePrefixComparator<k, k>::Eq(t1, t2) returns true if the
// first k fields of t1 equals the first k fields of t2.
// SameSizeTuplePrefixComparator(k1, k2) would be a compiler error if
// k1 != k2.
template <int kSize1, int kSize2>
struct SameSizeTuplePrefixComparator;
template <>
struct SameSizeTuplePrefixComparator<0, 0> {
template <class Tuple1, class Tuple2>
static bool Eq(const Tuple1& /* t1 */, const Tuple2& /* t2 */) {
return true;
}
};
template <int k>
struct SameSizeTuplePrefixComparator<k, k> {
template <class Tuple1, class Tuple2>
static bool Eq(const Tuple1& t1, const Tuple2& t2) {
return SameSizeTuplePrefixComparator<k - 1, k - 1>::Eq(t1, t2) &&
::std::tr1::get<k - 1>(t1) == ::std::tr1::get<k - 1>(t2);
}
};
} // namespace gtest_internal
template <GTEST_$(n)_TYPENAMES_(T), GTEST_$(n)_TYPENAMES_(U)>
inline bool operator==(const GTEST_$(n)_TUPLE_(T)& t,
const GTEST_$(n)_TUPLE_(U)& u) {
return gtest_internal::SameSizeTuplePrefixComparator<
tuple_size<GTEST_$(n)_TUPLE_(T)>::value,
tuple_size<GTEST_$(n)_TUPLE_(U)>::value>::Eq(t, u);
}
template <GTEST_$(n)_TYPENAMES_(T), GTEST_$(n)_TYPENAMES_(U)>
inline bool operator!=(const GTEST_$(n)_TUPLE_(T)& t,
const GTEST_$(n)_TUPLE_(U)& u) { return !(t == u); }
// 6.1.4 Pairs.
// Unimplemented.
} // namespace tr1
} // namespace std
$for j [[
#undef GTEST_$(j)_TUPLE_
]]
$for j [[
#undef GTEST_$(j)_TYPENAMES_
]]
#undef GTEST_BY_REF_
#undef GTEST_ADD_REF_
#undef GTEST_TUPLE_ELEMENT_
#endif // GTEST_INCLUDE_GTEST_INTERAL_GTEST_TUPLE_H_