vnpy/binding/generator/3rd_party/include/gtest/internal/gtest-param-util-generated.h

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// This file was GENERATED by command:
// pump.py gtest-param-util-generated.h.pump
// DO NOT EDIT BY HAND!!!
// Copyright 2008 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.
// Type and function utilities for implementing parameterized tests.
// This file is generated by a SCRIPT. DO NOT EDIT BY HAND!
//
// Currently Google Test supports at most 50 arguments in Values,
// and at most 10 arguments in Combine. Please contact
// googletestframework@googlegroups.com if you need more.
// Please note that the number of arguments to Combine is limited
// by the maximum arity of the implementation of tuple which is
// currently set at 10.
// GOOGLETEST_CM0001 DO NOT DELETE
#include <assert.h>
#include <memory>
#ifndef GTEST_INCLUDE_GTEST_INTERNAL_GTEST_PARAM_UTIL_GENERATED_H_
#define GTEST_INCLUDE_GTEST_INTERNAL_GTEST_PARAM_UTIL_GENERATED_H_
#include "gtest/internal/gtest-param-util.h"
#include "gtest/internal/gtest-port.h"
namespace testing {
namespace internal {
// INTERNAL IMPLEMENTATION - DO NOT USE IN USER CODE.
//
// Generates values from the Cartesian product of values produced
// by the argument generators.
//
template <typename T1, typename T2>
class CartesianProductGenerator2
: public ParamGeneratorInterface< ::std::tuple<T1, T2> > {
public:
typedef ::std::tuple<T1, T2> ParamType;
CartesianProductGenerator2(const ParamGenerator<T1>& g1,
const ParamGenerator<T2>& g2)
: g1_(g1), g2_(g2) {}
~CartesianProductGenerator2() override {}
ParamIteratorInterface<ParamType>* Begin() const override {
return new Iterator(this, g1_, g1_.begin(), g2_, g2_.begin());
}
ParamIteratorInterface<ParamType>* End() const override {
return new Iterator(this, g1_, g1_.end(), g2_, g2_.end());
}
private:
class Iterator : public ParamIteratorInterface<ParamType> {
public:
Iterator(const ParamGeneratorInterface<ParamType>* base,
const ParamGenerator<T1>& g1,
const typename ParamGenerator<T1>::iterator& current1,
const ParamGenerator<T2>& g2,
const typename ParamGenerator<T2>::iterator& current2)
: base_(base),
begin1_(g1.begin()), end1_(g1.end()), current1_(current1),
begin2_(g2.begin()), end2_(g2.end()), current2_(current2) {
ComputeCurrentValue();
}
~Iterator() override {}
const ParamGeneratorInterface<ParamType>* BaseGenerator() const override {
return base_;
}
// Advance should not be called on beyond-of-range iterators
// so no component iterators must be beyond end of range, either.
void Advance() override {
assert(!AtEnd());
++current2_;
if (current2_ == end2_) {
current2_ = begin2_;
++current1_;
}
ComputeCurrentValue();
}
ParamIteratorInterface<ParamType>* Clone() const override {
return new Iterator(*this);
}
const ParamType* Current() const override { return current_value_.get(); }
bool Equals(const ParamIteratorInterface<ParamType>& other) const override {
// Having the same base generator guarantees that the other
// iterator is of the same type and we can downcast.
GTEST_CHECK_(BaseGenerator() == other.BaseGenerator())
<< "The program attempted to compare iterators "
<< "from different generators." << std::endl;
const Iterator* typed_other =
CheckedDowncastToActualType<const Iterator>(&other);
// We must report iterators equal if they both point beyond their
// respective ranges. That can happen in a variety of fashions,
// so we have to consult AtEnd().
return (AtEnd() && typed_other->AtEnd()) ||
(
current1_ == typed_other->current1_ &&
current2_ == typed_other->current2_);
}
private:
Iterator(const Iterator& other)
: base_(other.base_),
begin1_(other.begin1_),
end1_(other.end1_),
current1_(other.current1_),
begin2_(other.begin2_),
end2_(other.end2_),
current2_(other.current2_) {
ComputeCurrentValue();
}
void ComputeCurrentValue() {
if (!AtEnd())
current_value_.reset(new ParamType(*current1_, *current2_));
}
bool AtEnd() const {
// We must report iterator past the end of the range when either of the
// component iterators has reached the end of its range.
return
current1_ == end1_ ||
current2_ == end2_;
}
// No implementation - assignment is unsupported.
void operator=(const Iterator& other);
const ParamGeneratorInterface<ParamType>* const base_;
// begin[i]_ and end[i]_ define the i-th range that Iterator traverses.
// current[i]_ is the actual traversing iterator.
const typename ParamGenerator<T1>::iterator begin1_;
const typename ParamGenerator<T1>::iterator end1_;
typename ParamGenerator<T1>::iterator current1_;
const typename ParamGenerator<T2>::iterator begin2_;
const typename ParamGenerator<T2>::iterator end2_;
typename ParamGenerator<T2>::iterator current2_;
std::shared_ptr<ParamType> current_value_;
}; // class CartesianProductGenerator2::Iterator
// No implementation - assignment is unsupported.
void operator=(const CartesianProductGenerator2& other);
const ParamGenerator<T1> g1_;
const ParamGenerator<T2> g2_;
}; // class CartesianProductGenerator2
template <typename T1, typename T2, typename T3>
class CartesianProductGenerator3
: public ParamGeneratorInterface< ::std::tuple<T1, T2, T3> > {
public:
typedef ::std::tuple<T1, T2, T3> ParamType;
CartesianProductGenerator3(const ParamGenerator<T1>& g1,
const ParamGenerator<T2>& g2, const ParamGenerator<T3>& g3)
: g1_(g1), g2_(g2), g3_(g3) {}
~CartesianProductGenerator3() override {}
ParamIteratorInterface<ParamType>* Begin() const override {
return new Iterator(this, g1_, g1_.begin(), g2_, g2_.begin(), g3_,
g3_.begin());
}
ParamIteratorInterface<ParamType>* End() const override {
return new Iterator(this, g1_, g1_.end(), g2_, g2_.end(), g3_, g3_.end());
}
private:
class Iterator : public ParamIteratorInterface<ParamType> {
public:
Iterator(const ParamGeneratorInterface<ParamType>* base,
const ParamGenerator<T1>& g1,
const typename ParamGenerator<T1>::iterator& current1,
const ParamGenerator<T2>& g2,
const typename ParamGenerator<T2>::iterator& current2,
const ParamGenerator<T3>& g3,
const typename ParamGenerator<T3>::iterator& current3)
: base_(base),
begin1_(g1.begin()), end1_(g1.end()), current1_(current1),
begin2_(g2.begin()), end2_(g2.end()), current2_(current2),
begin3_(g3.begin()), end3_(g3.end()), current3_(current3) {
ComputeCurrentValue();
}
~Iterator() override {}
const ParamGeneratorInterface<ParamType>* BaseGenerator() const override {
return base_;
}
// Advance should not be called on beyond-of-range iterators
// so no component iterators must be beyond end of range, either.
void Advance() override {
assert(!AtEnd());
++current3_;
if (current3_ == end3_) {
current3_ = begin3_;
++current2_;
}
if (current2_ == end2_) {
current2_ = begin2_;
++current1_;
}
ComputeCurrentValue();
}
ParamIteratorInterface<ParamType>* Clone() const override {
return new Iterator(*this);
}
const ParamType* Current() const override { return current_value_.get(); }
bool Equals(const ParamIteratorInterface<ParamType>& other) const override {
// Having the same base generator guarantees that the other
// iterator is of the same type and we can downcast.
GTEST_CHECK_(BaseGenerator() == other.BaseGenerator())
<< "The program attempted to compare iterators "
<< "from different generators." << std::endl;
const Iterator* typed_other =
CheckedDowncastToActualType<const Iterator>(&other);
// We must report iterators equal if they both point beyond their
// respective ranges. That can happen in a variety of fashions,
// so we have to consult AtEnd().
return (AtEnd() && typed_other->AtEnd()) ||
(
current1_ == typed_other->current1_ &&
current2_ == typed_other->current2_ &&
current3_ == typed_other->current3_);
}
private:
Iterator(const Iterator& other)
: base_(other.base_),
begin1_(other.begin1_),
end1_(other.end1_),
current1_(other.current1_),
begin2_(other.begin2_),
end2_(other.end2_),
current2_(other.current2_),
begin3_(other.begin3_),
end3_(other.end3_),
current3_(other.current3_) {
ComputeCurrentValue();
}
void ComputeCurrentValue() {
if (!AtEnd())
current_value_.reset(new ParamType(*current1_, *current2_, *current3_));
}
bool AtEnd() const {
// We must report iterator past the end of the range when either of the
// component iterators has reached the end of its range.
return
current1_ == end1_ ||
current2_ == end2_ ||
current3_ == end3_;
}
// No implementation - assignment is unsupported.
void operator=(const Iterator& other);
const ParamGeneratorInterface<ParamType>* const base_;
// begin[i]_ and end[i]_ define the i-th range that Iterator traverses.
// current[i]_ is the actual traversing iterator.
const typename ParamGenerator<T1>::iterator begin1_;
const typename ParamGenerator<T1>::iterator end1_;
typename ParamGenerator<T1>::iterator current1_;
const typename ParamGenerator<T2>::iterator begin2_;
const typename ParamGenerator<T2>::iterator end2_;
typename ParamGenerator<T2>::iterator current2_;
const typename ParamGenerator<T3>::iterator begin3_;
const typename ParamGenerator<T3>::iterator end3_;
typename ParamGenerator<T3>::iterator current3_;
std::shared_ptr<ParamType> current_value_;
}; // class CartesianProductGenerator3::Iterator
// No implementation - assignment is unsupported.
void operator=(const CartesianProductGenerator3& other);
const ParamGenerator<T1> g1_;
const ParamGenerator<T2> g2_;
const ParamGenerator<T3> g3_;
}; // class CartesianProductGenerator3
template <typename T1, typename T2, typename T3, typename T4>
class CartesianProductGenerator4
: public ParamGeneratorInterface< ::std::tuple<T1, T2, T3, T4> > {
public:
typedef ::std::tuple<T1, T2, T3, T4> ParamType;
CartesianProductGenerator4(const ParamGenerator<T1>& g1,
const ParamGenerator<T2>& g2, const ParamGenerator<T3>& g3,
const ParamGenerator<T4>& g4)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4) {}
~CartesianProductGenerator4() override {}
ParamIteratorInterface<ParamType>* Begin() const override {
return new Iterator(this, g1_, g1_.begin(), g2_, g2_.begin(), g3_,
g3_.begin(), g4_, g4_.begin());
}
ParamIteratorInterface<ParamType>* End() const override {
return new Iterator(this, g1_, g1_.end(), g2_, g2_.end(), g3_, g3_.end(),
g4_, g4_.end());
}
private:
class Iterator : public ParamIteratorInterface<ParamType> {
public:
Iterator(const ParamGeneratorInterface<ParamType>* base,
const ParamGenerator<T1>& g1,
const typename ParamGenerator<T1>::iterator& current1,
const ParamGenerator<T2>& g2,
const typename ParamGenerator<T2>::iterator& current2,
const ParamGenerator<T3>& g3,
const typename ParamGenerator<T3>::iterator& current3,
const ParamGenerator<T4>& g4,
const typename ParamGenerator<T4>::iterator& current4)
: base_(base),
begin1_(g1.begin()), end1_(g1.end()), current1_(current1),
begin2_(g2.begin()), end2_(g2.end()), current2_(current2),
begin3_(g3.begin()), end3_(g3.end()), current3_(current3),
begin4_(g4.begin()), end4_(g4.end()), current4_(current4) {
ComputeCurrentValue();
}
~Iterator() override {}
const ParamGeneratorInterface<ParamType>* BaseGenerator() const override {
return base_;
}
// Advance should not be called on beyond-of-range iterators
// so no component iterators must be beyond end of range, either.
void Advance() override {
assert(!AtEnd());
++current4_;
if (current4_ == end4_) {
current4_ = begin4_;
++current3_;
}
if (current3_ == end3_) {
current3_ = begin3_;
++current2_;
}
if (current2_ == end2_) {
current2_ = begin2_;
++current1_;
}
ComputeCurrentValue();
}
ParamIteratorInterface<ParamType>* Clone() const override {
return new Iterator(*this);
}
const ParamType* Current() const override { return current_value_.get(); }
bool Equals(const ParamIteratorInterface<ParamType>& other) const override {
// Having the same base generator guarantees that the other
// iterator is of the same type and we can downcast.
GTEST_CHECK_(BaseGenerator() == other.BaseGenerator())
<< "The program attempted to compare iterators "
<< "from different generators." << std::endl;
const Iterator* typed_other =
CheckedDowncastToActualType<const Iterator>(&other);
// We must report iterators equal if they both point beyond their
// respective ranges. That can happen in a variety of fashions,
// so we have to consult AtEnd().
return (AtEnd() && typed_other->AtEnd()) ||
(
current1_ == typed_other->current1_ &&
current2_ == typed_other->current2_ &&
current3_ == typed_other->current3_ &&
current4_ == typed_other->current4_);
}
private:
Iterator(const Iterator& other)
: base_(other.base_),
begin1_(other.begin1_),
end1_(other.end1_),
current1_(other.current1_),
begin2_(other.begin2_),
end2_(other.end2_),
current2_(other.current2_),
begin3_(other.begin3_),
end3_(other.end3_),
current3_(other.current3_),
begin4_(other.begin4_),
end4_(other.end4_),
current4_(other.current4_) {
ComputeCurrentValue();
}
void ComputeCurrentValue() {
if (!AtEnd())
current_value_.reset(new ParamType(*current1_, *current2_, *current3_,
*current4_));
}
bool AtEnd() const {
// We must report iterator past the end of the range when either of the
// component iterators has reached the end of its range.
return
current1_ == end1_ ||
current2_ == end2_ ||
current3_ == end3_ ||
current4_ == end4_;
}
// No implementation - assignment is unsupported.
void operator=(const Iterator& other);
const ParamGeneratorInterface<ParamType>* const base_;
// begin[i]_ and end[i]_ define the i-th range that Iterator traverses.
// current[i]_ is the actual traversing iterator.
const typename ParamGenerator<T1>::iterator begin1_;
const typename ParamGenerator<T1>::iterator end1_;
typename ParamGenerator<T1>::iterator current1_;
const typename ParamGenerator<T2>::iterator begin2_;
const typename ParamGenerator<T2>::iterator end2_;
typename ParamGenerator<T2>::iterator current2_;
const typename ParamGenerator<T3>::iterator begin3_;
const typename ParamGenerator<T3>::iterator end3_;
typename ParamGenerator<T3>::iterator current3_;
const typename ParamGenerator<T4>::iterator begin4_;
const typename ParamGenerator<T4>::iterator end4_;
typename ParamGenerator<T4>::iterator current4_;
std::shared_ptr<ParamType> current_value_;
}; // class CartesianProductGenerator4::Iterator
// No implementation - assignment is unsupported.
void operator=(const CartesianProductGenerator4& other);
const ParamGenerator<T1> g1_;
const ParamGenerator<T2> g2_;
const ParamGenerator<T3> g3_;
const ParamGenerator<T4> g4_;
}; // class CartesianProductGenerator4
template <typename T1, typename T2, typename T3, typename T4, typename T5>
class CartesianProductGenerator5
: public ParamGeneratorInterface< ::std::tuple<T1, T2, T3, T4, T5> > {
public:
typedef ::std::tuple<T1, T2, T3, T4, T5> ParamType;
CartesianProductGenerator5(const ParamGenerator<T1>& g1,
const ParamGenerator<T2>& g2, const ParamGenerator<T3>& g3,
const ParamGenerator<T4>& g4, const ParamGenerator<T5>& g5)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5) {}
~CartesianProductGenerator5() override {}
ParamIteratorInterface<ParamType>* Begin() const override {
return new Iterator(this, g1_, g1_.begin(), g2_, g2_.begin(), g3_,
g3_.begin(), g4_, g4_.begin(), g5_, g5_.begin());
}
ParamIteratorInterface<ParamType>* End() const override {
return new Iterator(this, g1_, g1_.end(), g2_, g2_.end(), g3_, g3_.end(),
g4_, g4_.end(), g5_, g5_.end());
}
private:
class Iterator : public ParamIteratorInterface<ParamType> {
public:
Iterator(const ParamGeneratorInterface<ParamType>* base,
const ParamGenerator<T1>& g1,
const typename ParamGenerator<T1>::iterator& current1,
const ParamGenerator<T2>& g2,
const typename ParamGenerator<T2>::iterator& current2,
const ParamGenerator<T3>& g3,
const typename ParamGenerator<T3>::iterator& current3,
const ParamGenerator<T4>& g4,
const typename ParamGenerator<T4>::iterator& current4,
const ParamGenerator<T5>& g5,
const typename ParamGenerator<T5>::iterator& current5)
: base_(base),
begin1_(g1.begin()), end1_(g1.end()), current1_(current1),
begin2_(g2.begin()), end2_(g2.end()), current2_(current2),
begin3_(g3.begin()), end3_(g3.end()), current3_(current3),
begin4_(g4.begin()), end4_(g4.end()), current4_(current4),
begin5_(g5.begin()), end5_(g5.end()), current5_(current5) {
ComputeCurrentValue();
}
~Iterator() override {}
const ParamGeneratorInterface<ParamType>* BaseGenerator() const override {
return base_;
}
// Advance should not be called on beyond-of-range iterators
// so no component iterators must be beyond end of range, either.
void Advance() override {
assert(!AtEnd());
++current5_;
if (current5_ == end5_) {
current5_ = begin5_;
++current4_;
}
if (current4_ == end4_) {
current4_ = begin4_;
++current3_;
}
if (current3_ == end3_) {
current3_ = begin3_;
++current2_;
}
if (current2_ == end2_) {
current2_ = begin2_;
++current1_;
}
ComputeCurrentValue();
}
ParamIteratorInterface<ParamType>* Clone() const override {
return new Iterator(*this);
}
const ParamType* Current() const override { return current_value_.get(); }
bool Equals(const ParamIteratorInterface<ParamType>& other) const override {
// Having the same base generator guarantees that the other
// iterator is of the same type and we can downcast.
GTEST_CHECK_(BaseGenerator() == other.BaseGenerator())
<< "The program attempted to compare iterators "
<< "from different generators." << std::endl;
const Iterator* typed_other =
CheckedDowncastToActualType<const Iterator>(&other);
// We must report iterators equal if they both point beyond their
// respective ranges. That can happen in a variety of fashions,
// so we have to consult AtEnd().
return (AtEnd() && typed_other->AtEnd()) ||
(
current1_ == typed_other->current1_ &&
current2_ == typed_other->current2_ &&
current3_ == typed_other->current3_ &&
current4_ == typed_other->current4_ &&
current5_ == typed_other->current5_);
}
private:
Iterator(const Iterator& other)
: base_(other.base_),
begin1_(other.begin1_),
end1_(other.end1_),
current1_(other.current1_),
begin2_(other.begin2_),
end2_(other.end2_),
current2_(other.current2_),
begin3_(other.begin3_),
end3_(other.end3_),
current3_(other.current3_),
begin4_(other.begin4_),
end4_(other.end4_),
current4_(other.current4_),
begin5_(other.begin5_),
end5_(other.end5_),
current5_(other.current5_) {
ComputeCurrentValue();
}
void ComputeCurrentValue() {
if (!AtEnd())
current_value_.reset(new ParamType(*current1_, *current2_, *current3_,
*current4_, *current5_));
}
bool AtEnd() const {
// We must report iterator past the end of the range when either of the
// component iterators has reached the end of its range.
return
current1_ == end1_ ||
current2_ == end2_ ||
current3_ == end3_ ||
current4_ == end4_ ||
current5_ == end5_;
}
// No implementation - assignment is unsupported.
void operator=(const Iterator& other);
const ParamGeneratorInterface<ParamType>* const base_;
// begin[i]_ and end[i]_ define the i-th range that Iterator traverses.
// current[i]_ is the actual traversing iterator.
const typename ParamGenerator<T1>::iterator begin1_;
const typename ParamGenerator<T1>::iterator end1_;
typename ParamGenerator<T1>::iterator current1_;
const typename ParamGenerator<T2>::iterator begin2_;
const typename ParamGenerator<T2>::iterator end2_;
typename ParamGenerator<T2>::iterator current2_;
const typename ParamGenerator<T3>::iterator begin3_;
const typename ParamGenerator<T3>::iterator end3_;
typename ParamGenerator<T3>::iterator current3_;
const typename ParamGenerator<T4>::iterator begin4_;
const typename ParamGenerator<T4>::iterator end4_;
typename ParamGenerator<T4>::iterator current4_;
const typename ParamGenerator<T5>::iterator begin5_;
const typename ParamGenerator<T5>::iterator end5_;
typename ParamGenerator<T5>::iterator current5_;
std::shared_ptr<ParamType> current_value_;
}; // class CartesianProductGenerator5::Iterator
// No implementation - assignment is unsupported.
void operator=(const CartesianProductGenerator5& other);
const ParamGenerator<T1> g1_;
const ParamGenerator<T2> g2_;
const ParamGenerator<T3> g3_;
const ParamGenerator<T4> g4_;
const ParamGenerator<T5> g5_;
}; // class CartesianProductGenerator5
template <typename T1, typename T2, typename T3, typename T4, typename T5,
typename T6>
class CartesianProductGenerator6
: public ParamGeneratorInterface< ::std::tuple<T1, T2, T3, T4, T5, T6> > {
public:
typedef ::std::tuple<T1, T2, T3, T4, T5, T6> ParamType;
CartesianProductGenerator6(const ParamGenerator<T1>& g1,
const ParamGenerator<T2>& g2, const ParamGenerator<T3>& g3,
const ParamGenerator<T4>& g4, const ParamGenerator<T5>& g5,
const ParamGenerator<T6>& g6)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5), g6_(g6) {}
~CartesianProductGenerator6() override {}
ParamIteratorInterface<ParamType>* Begin() const override {
return new Iterator(this, g1_, g1_.begin(), g2_, g2_.begin(), g3_,
g3_.begin(), g4_, g4_.begin(), g5_, g5_.begin(), g6_, g6_.begin());
}
ParamIteratorInterface<ParamType>* End() const override {
return new Iterator(this, g1_, g1_.end(), g2_, g2_.end(), g3_, g3_.end(),
g4_, g4_.end(), g5_, g5_.end(), g6_, g6_.end());
}
private:
class Iterator : public ParamIteratorInterface<ParamType> {
public:
Iterator(const ParamGeneratorInterface<ParamType>* base,
const ParamGenerator<T1>& g1,
const typename ParamGenerator<T1>::iterator& current1,
const ParamGenerator<T2>& g2,
const typename ParamGenerator<T2>::iterator& current2,
const ParamGenerator<T3>& g3,
const typename ParamGenerator<T3>::iterator& current3,
const ParamGenerator<T4>& g4,
const typename ParamGenerator<T4>::iterator& current4,
const ParamGenerator<T5>& g5,
const typename ParamGenerator<T5>::iterator& current5,
const ParamGenerator<T6>& g6,
const typename ParamGenerator<T6>::iterator& current6)
: base_(base),
begin1_(g1.begin()), end1_(g1.end()), current1_(current1),
begin2_(g2.begin()), end2_(g2.end()), current2_(current2),
begin3_(g3.begin()), end3_(g3.end()), current3_(current3),
begin4_(g4.begin()), end4_(g4.end()), current4_(current4),
begin5_(g5.begin()), end5_(g5.end()), current5_(current5),
begin6_(g6.begin()), end6_(g6.end()), current6_(current6) {
ComputeCurrentValue();
}
~Iterator() override {}
const ParamGeneratorInterface<ParamType>* BaseGenerator() const override {
return base_;
}
// Advance should not be called on beyond-of-range iterators
// so no component iterators must be beyond end of range, either.
void Advance() override {
assert(!AtEnd());
++current6_;
if (current6_ == end6_) {
current6_ = begin6_;
++current5_;
}
if (current5_ == end5_) {
current5_ = begin5_;
++current4_;
}
if (current4_ == end4_) {
current4_ = begin4_;
++current3_;
}
if (current3_ == end3_) {
current3_ = begin3_;
++current2_;
}
if (current2_ == end2_) {
current2_ = begin2_;
++current1_;
}
ComputeCurrentValue();
}
ParamIteratorInterface<ParamType>* Clone() const override {
return new Iterator(*this);
}
const ParamType* Current() const override { return current_value_.get(); }
bool Equals(const ParamIteratorInterface<ParamType>& other) const override {
// Having the same base generator guarantees that the other
// iterator is of the same type and we can downcast.
GTEST_CHECK_(BaseGenerator() == other.BaseGenerator())
<< "The program attempted to compare iterators "
<< "from different generators." << std::endl;
const Iterator* typed_other =
CheckedDowncastToActualType<const Iterator>(&other);
// We must report iterators equal if they both point beyond their
// respective ranges. That can happen in a variety of fashions,
// so we have to consult AtEnd().
return (AtEnd() && typed_other->AtEnd()) ||
(
current1_ == typed_other->current1_ &&
current2_ == typed_other->current2_ &&
current3_ == typed_other->current3_ &&
current4_ == typed_other->current4_ &&
current5_ == typed_other->current5_ &&
current6_ == typed_other->current6_);
}
private:
Iterator(const Iterator& other)
: base_(other.base_),
begin1_(other.begin1_),
end1_(other.end1_),
current1_(other.current1_),
begin2_(other.begin2_),
end2_(other.end2_),
current2_(other.current2_),
begin3_(other.begin3_),
end3_(other.end3_),
current3_(other.current3_),
begin4_(other.begin4_),
end4_(other.end4_),
current4_(other.current4_),
begin5_(other.begin5_),
end5_(other.end5_),
current5_(other.current5_),
begin6_(other.begin6_),
end6_(other.end6_),
current6_(other.current6_) {
ComputeCurrentValue();
}
void ComputeCurrentValue() {
if (!AtEnd())
current_value_.reset(new ParamType(*current1_, *current2_, *current3_,
*current4_, *current5_, *current6_));
}
bool AtEnd() const {
// We must report iterator past the end of the range when either of the
// component iterators has reached the end of its range.
return
current1_ == end1_ ||
current2_ == end2_ ||
current3_ == end3_ ||
current4_ == end4_ ||
current5_ == end5_ ||
current6_ == end6_;
}
// No implementation - assignment is unsupported.
void operator=(const Iterator& other);
const ParamGeneratorInterface<ParamType>* const base_;
// begin[i]_ and end[i]_ define the i-th range that Iterator traverses.
// current[i]_ is the actual traversing iterator.
const typename ParamGenerator<T1>::iterator begin1_;
const typename ParamGenerator<T1>::iterator end1_;
typename ParamGenerator<T1>::iterator current1_;
const typename ParamGenerator<T2>::iterator begin2_;
const typename ParamGenerator<T2>::iterator end2_;
typename ParamGenerator<T2>::iterator current2_;
const typename ParamGenerator<T3>::iterator begin3_;
const typename ParamGenerator<T3>::iterator end3_;
typename ParamGenerator<T3>::iterator current3_;
const typename ParamGenerator<T4>::iterator begin4_;
const typename ParamGenerator<T4>::iterator end4_;
typename ParamGenerator<T4>::iterator current4_;
const typename ParamGenerator<T5>::iterator begin5_;
const typename ParamGenerator<T5>::iterator end5_;
typename ParamGenerator<T5>::iterator current5_;
const typename ParamGenerator<T6>::iterator begin6_;
const typename ParamGenerator<T6>::iterator end6_;
typename ParamGenerator<T6>::iterator current6_;
std::shared_ptr<ParamType> current_value_;
}; // class CartesianProductGenerator6::Iterator
// No implementation - assignment is unsupported.
void operator=(const CartesianProductGenerator6& other);
const ParamGenerator<T1> g1_;
const ParamGenerator<T2> g2_;
const ParamGenerator<T3> g3_;
const ParamGenerator<T4> g4_;
const ParamGenerator<T5> g5_;
const ParamGenerator<T6> g6_;
}; // class CartesianProductGenerator6
template <typename T1, typename T2, typename T3, typename T4, typename T5,
typename T6, typename T7>
class CartesianProductGenerator7
: public ParamGeneratorInterface< ::std::tuple<T1, T2, T3, T4, T5, T6,
T7> > {
public:
typedef ::std::tuple<T1, T2, T3, T4, T5, T6, T7> ParamType;
CartesianProductGenerator7(const ParamGenerator<T1>& g1,
const ParamGenerator<T2>& g2, const ParamGenerator<T3>& g3,
const ParamGenerator<T4>& g4, const ParamGenerator<T5>& g5,
const ParamGenerator<T6>& g6, const ParamGenerator<T7>& g7)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5), g6_(g6), g7_(g7) {}
~CartesianProductGenerator7() override {}
ParamIteratorInterface<ParamType>* Begin() const override {
return new Iterator(this, g1_, g1_.begin(), g2_, g2_.begin(), g3_,
g3_.begin(), g4_, g4_.begin(), g5_, g5_.begin(), g6_, g6_.begin(), g7_,
g7_.begin());
}
ParamIteratorInterface<ParamType>* End() const override {
return new Iterator(this, g1_, g1_.end(), g2_, g2_.end(), g3_, g3_.end(),
g4_, g4_.end(), g5_, g5_.end(), g6_, g6_.end(), g7_, g7_.end());
}
private:
class Iterator : public ParamIteratorInterface<ParamType> {
public:
Iterator(const ParamGeneratorInterface<ParamType>* base,
const ParamGenerator<T1>& g1,
const typename ParamGenerator<T1>::iterator& current1,
const ParamGenerator<T2>& g2,
const typename ParamGenerator<T2>::iterator& current2,
const ParamGenerator<T3>& g3,
const typename ParamGenerator<T3>::iterator& current3,
const ParamGenerator<T4>& g4,
const typename ParamGenerator<T4>::iterator& current4,
const ParamGenerator<T5>& g5,
const typename ParamGenerator<T5>::iterator& current5,
const ParamGenerator<T6>& g6,
const typename ParamGenerator<T6>::iterator& current6,
const ParamGenerator<T7>& g7,
const typename ParamGenerator<T7>::iterator& current7)
: base_(base),
begin1_(g1.begin()), end1_(g1.end()), current1_(current1),
begin2_(g2.begin()), end2_(g2.end()), current2_(current2),
begin3_(g3.begin()), end3_(g3.end()), current3_(current3),
begin4_(g4.begin()), end4_(g4.end()), current4_(current4),
begin5_(g5.begin()), end5_(g5.end()), current5_(current5),
begin6_(g6.begin()), end6_(g6.end()), current6_(current6),
begin7_(g7.begin()), end7_(g7.end()), current7_(current7) {
ComputeCurrentValue();
}
~Iterator() override {}
const ParamGeneratorInterface<ParamType>* BaseGenerator() const override {
return base_;
}
// Advance should not be called on beyond-of-range iterators
// so no component iterators must be beyond end of range, either.
void Advance() override {
assert(!AtEnd());
++current7_;
if (current7_ == end7_) {
current7_ = begin7_;
++current6_;
}
if (current6_ == end6_) {
current6_ = begin6_;
++current5_;
}
if (current5_ == end5_) {
current5_ = begin5_;
++current4_;
}
if (current4_ == end4_) {
current4_ = begin4_;
++current3_;
}
if (current3_ == end3_) {
current3_ = begin3_;
++current2_;
}
if (current2_ == end2_) {
current2_ = begin2_;
++current1_;
}
ComputeCurrentValue();
}
ParamIteratorInterface<ParamType>* Clone() const override {
return new Iterator(*this);
}
const ParamType* Current() const override { return current_value_.get(); }
bool Equals(const ParamIteratorInterface<ParamType>& other) const override {
// Having the same base generator guarantees that the other
// iterator is of the same type and we can downcast.
GTEST_CHECK_(BaseGenerator() == other.BaseGenerator())
<< "The program attempted to compare iterators "
<< "from different generators." << std::endl;
const Iterator* typed_other =
CheckedDowncastToActualType<const Iterator>(&other);
// We must report iterators equal if they both point beyond their
// respective ranges. That can happen in a variety of fashions,
// so we have to consult AtEnd().
return (AtEnd() && typed_other->AtEnd()) ||
(
current1_ == typed_other->current1_ &&
current2_ == typed_other->current2_ &&
current3_ == typed_other->current3_ &&
current4_ == typed_other->current4_ &&
current5_ == typed_other->current5_ &&
current6_ == typed_other->current6_ &&
current7_ == typed_other->current7_);
}
private:
Iterator(const Iterator& other)
: base_(other.base_),
begin1_(other.begin1_),
end1_(other.end1_),
current1_(other.current1_),
begin2_(other.begin2_),
end2_(other.end2_),
current2_(other.current2_),
begin3_(other.begin3_),
end3_(other.end3_),
current3_(other.current3_),
begin4_(other.begin4_),
end4_(other.end4_),
current4_(other.current4_),
begin5_(other.begin5_),
end5_(other.end5_),
current5_(other.current5_),
begin6_(other.begin6_),
end6_(other.end6_),
current6_(other.current6_),
begin7_(other.begin7_),
end7_(other.end7_),
current7_(other.current7_) {
ComputeCurrentValue();
}
void ComputeCurrentValue() {
if (!AtEnd())
current_value_.reset(new ParamType(*current1_, *current2_, *current3_,
*current4_, *current5_, *current6_, *current7_));
}
bool AtEnd() const {
// We must report iterator past the end of the range when either of the
// component iterators has reached the end of its range.
return
current1_ == end1_ ||
current2_ == end2_ ||
current3_ == end3_ ||
current4_ == end4_ ||
current5_ == end5_ ||
current6_ == end6_ ||
current7_ == end7_;
}
// No implementation - assignment is unsupported.
void operator=(const Iterator& other);
const ParamGeneratorInterface<ParamType>* const base_;
// begin[i]_ and end[i]_ define the i-th range that Iterator traverses.
// current[i]_ is the actual traversing iterator.
const typename ParamGenerator<T1>::iterator begin1_;
const typename ParamGenerator<T1>::iterator end1_;
typename ParamGenerator<T1>::iterator current1_;
const typename ParamGenerator<T2>::iterator begin2_;
const typename ParamGenerator<T2>::iterator end2_;
typename ParamGenerator<T2>::iterator current2_;
const typename ParamGenerator<T3>::iterator begin3_;
const typename ParamGenerator<T3>::iterator end3_;
typename ParamGenerator<T3>::iterator current3_;
const typename ParamGenerator<T4>::iterator begin4_;
const typename ParamGenerator<T4>::iterator end4_;
typename ParamGenerator<T4>::iterator current4_;
const typename ParamGenerator<T5>::iterator begin5_;
const typename ParamGenerator<T5>::iterator end5_;
typename ParamGenerator<T5>::iterator current5_;
const typename ParamGenerator<T6>::iterator begin6_;
const typename ParamGenerator<T6>::iterator end6_;
typename ParamGenerator<T6>::iterator current6_;
const typename ParamGenerator<T7>::iterator begin7_;
const typename ParamGenerator<T7>::iterator end7_;
typename ParamGenerator<T7>::iterator current7_;
std::shared_ptr<ParamType> current_value_;
}; // class CartesianProductGenerator7::Iterator
// No implementation - assignment is unsupported.
void operator=(const CartesianProductGenerator7& other);
const ParamGenerator<T1> g1_;
const ParamGenerator<T2> g2_;
const ParamGenerator<T3> g3_;
const ParamGenerator<T4> g4_;
const ParamGenerator<T5> g5_;
const ParamGenerator<T6> g6_;
const ParamGenerator<T7> g7_;
}; // class CartesianProductGenerator7
template <typename T1, typename T2, typename T3, typename T4, typename T5,
typename T6, typename T7, typename T8>
class CartesianProductGenerator8
: public ParamGeneratorInterface< ::std::tuple<T1, T2, T3, T4, T5, T6, T7,
T8> > {
public:
typedef ::std::tuple<T1, T2, T3, T4, T5, T6, T7, T8> ParamType;
CartesianProductGenerator8(const ParamGenerator<T1>& g1,
const ParamGenerator<T2>& g2, const ParamGenerator<T3>& g3,
const ParamGenerator<T4>& g4, const ParamGenerator<T5>& g5,
const ParamGenerator<T6>& g6, const ParamGenerator<T7>& g7,
const ParamGenerator<T8>& g8)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5), g6_(g6), g7_(g7),
g8_(g8) {}
~CartesianProductGenerator8() override {}
ParamIteratorInterface<ParamType>* Begin() const override {
return new Iterator(this, g1_, g1_.begin(), g2_, g2_.begin(), g3_,
g3_.begin(), g4_, g4_.begin(), g5_, g5_.begin(), g6_, g6_.begin(), g7_,
g7_.begin(), g8_, g8_.begin());
}
ParamIteratorInterface<ParamType>* End() const override {
return new Iterator(this, g1_, g1_.end(), g2_, g2_.end(), g3_, g3_.end(),
g4_, g4_.end(), g5_, g5_.end(), g6_, g6_.end(), g7_, g7_.end(), g8_,
g8_.end());
}
private:
class Iterator : public ParamIteratorInterface<ParamType> {
public:
Iterator(const ParamGeneratorInterface<ParamType>* base,
const ParamGenerator<T1>& g1,
const typename ParamGenerator<T1>::iterator& current1,
const ParamGenerator<T2>& g2,
const typename ParamGenerator<T2>::iterator& current2,
const ParamGenerator<T3>& g3,
const typename ParamGenerator<T3>::iterator& current3,
const ParamGenerator<T4>& g4,
const typename ParamGenerator<T4>::iterator& current4,
const ParamGenerator<T5>& g5,
const typename ParamGenerator<T5>::iterator& current5,
const ParamGenerator<T6>& g6,
const typename ParamGenerator<T6>::iterator& current6,
const ParamGenerator<T7>& g7,
const typename ParamGenerator<T7>::iterator& current7,
const ParamGenerator<T8>& g8,
const typename ParamGenerator<T8>::iterator& current8)
: base_(base),
begin1_(g1.begin()), end1_(g1.end()), current1_(current1),
begin2_(g2.begin()), end2_(g2.end()), current2_(current2),
begin3_(g3.begin()), end3_(g3.end()), current3_(current3),
begin4_(g4.begin()), end4_(g4.end()), current4_(current4),
begin5_(g5.begin()), end5_(g5.end()), current5_(current5),
begin6_(g6.begin()), end6_(g6.end()), current6_(current6),
begin7_(g7.begin()), end7_(g7.end()), current7_(current7),
begin8_(g8.begin()), end8_(g8.end()), current8_(current8) {
ComputeCurrentValue();
}
~Iterator() override {}
const ParamGeneratorInterface<ParamType>* BaseGenerator() const override {
return base_;
}
// Advance should not be called on beyond-of-range iterators
// so no component iterators must be beyond end of range, either.
void Advance() override {
assert(!AtEnd());
++current8_;
if (current8_ == end8_) {
current8_ = begin8_;
++current7_;
}
if (current7_ == end7_) {
current7_ = begin7_;
++current6_;
}
if (current6_ == end6_) {
current6_ = begin6_;
++current5_;
}
if (current5_ == end5_) {
current5_ = begin5_;
++current4_;
}
if (current4_ == end4_) {
current4_ = begin4_;
++current3_;
}
if (current3_ == end3_) {
current3_ = begin3_;
++current2_;
}
if (current2_ == end2_) {
current2_ = begin2_;
++current1_;
}
ComputeCurrentValue();
}
ParamIteratorInterface<ParamType>* Clone() const override {
return new Iterator(*this);
}
const ParamType* Current() const override { return current_value_.get(); }
bool Equals(const ParamIteratorInterface<ParamType>& other) const override {
// Having the same base generator guarantees that the other
// iterator is of the same type and we can downcast.
GTEST_CHECK_(BaseGenerator() == other.BaseGenerator())
<< "The program attempted to compare iterators "
<< "from different generators." << std::endl;
const Iterator* typed_other =
CheckedDowncastToActualType<const Iterator>(&other);
// We must report iterators equal if they both point beyond their
// respective ranges. That can happen in a variety of fashions,
// so we have to consult AtEnd().
return (AtEnd() && typed_other->AtEnd()) ||
(
current1_ == typed_other->current1_ &&
current2_ == typed_other->current2_ &&
current3_ == typed_other->current3_ &&
current4_ == typed_other->current4_ &&
current5_ == typed_other->current5_ &&
current6_ == typed_other->current6_ &&
current7_ == typed_other->current7_ &&
current8_ == typed_other->current8_);
}
private:
Iterator(const Iterator& other)
: base_(other.base_),
begin1_(other.begin1_),
end1_(other.end1_),
current1_(other.current1_),
begin2_(other.begin2_),
end2_(other.end2_),
current2_(other.current2_),
begin3_(other.begin3_),
end3_(other.end3_),
current3_(other.current3_),
begin4_(other.begin4_),
end4_(other.end4_),
current4_(other.current4_),
begin5_(other.begin5_),
end5_(other.end5_),
current5_(other.current5_),
begin6_(other.begin6_),
end6_(other.end6_),
current6_(other.current6_),
begin7_(other.begin7_),
end7_(other.end7_),
current7_(other.current7_),
begin8_(other.begin8_),
end8_(other.end8_),
current8_(other.current8_) {
ComputeCurrentValue();
}
void ComputeCurrentValue() {
if (!AtEnd())
current_value_.reset(new ParamType(*current1_, *current2_, *current3_,
*current4_, *current5_, *current6_, *current7_, *current8_));
}
bool AtEnd() const {
// We must report iterator past the end of the range when either of the
// component iterators has reached the end of its range.
return
current1_ == end1_ ||
current2_ == end2_ ||
current3_ == end3_ ||
current4_ == end4_ ||
current5_ == end5_ ||
current6_ == end6_ ||
current7_ == end7_ ||
current8_ == end8_;
}
// No implementation - assignment is unsupported.
void operator=(const Iterator& other);
const ParamGeneratorInterface<ParamType>* const base_;
// begin[i]_ and end[i]_ define the i-th range that Iterator traverses.
// current[i]_ is the actual traversing iterator.
const typename ParamGenerator<T1>::iterator begin1_;
const typename ParamGenerator<T1>::iterator end1_;
typename ParamGenerator<T1>::iterator current1_;
const typename ParamGenerator<T2>::iterator begin2_;
const typename ParamGenerator<T2>::iterator end2_;
typename ParamGenerator<T2>::iterator current2_;
const typename ParamGenerator<T3>::iterator begin3_;
const typename ParamGenerator<T3>::iterator end3_;
typename ParamGenerator<T3>::iterator current3_;
const typename ParamGenerator<T4>::iterator begin4_;
const typename ParamGenerator<T4>::iterator end4_;
typename ParamGenerator<T4>::iterator current4_;
const typename ParamGenerator<T5>::iterator begin5_;
const typename ParamGenerator<T5>::iterator end5_;
typename ParamGenerator<T5>::iterator current5_;
const typename ParamGenerator<T6>::iterator begin6_;
const typename ParamGenerator<T6>::iterator end6_;
typename ParamGenerator<T6>::iterator current6_;
const typename ParamGenerator<T7>::iterator begin7_;
const typename ParamGenerator<T7>::iterator end7_;
typename ParamGenerator<T7>::iterator current7_;
const typename ParamGenerator<T8>::iterator begin8_;
const typename ParamGenerator<T8>::iterator end8_;
typename ParamGenerator<T8>::iterator current8_;
std::shared_ptr<ParamType> current_value_;
}; // class CartesianProductGenerator8::Iterator
// No implementation - assignment is unsupported.
void operator=(const CartesianProductGenerator8& other);
const ParamGenerator<T1> g1_;
const ParamGenerator<T2> g2_;
const ParamGenerator<T3> g3_;
const ParamGenerator<T4> g4_;
const ParamGenerator<T5> g5_;
const ParamGenerator<T6> g6_;
const ParamGenerator<T7> g7_;
const ParamGenerator<T8> g8_;
}; // class CartesianProductGenerator8
template <typename T1, typename T2, typename T3, typename T4, typename T5,
typename T6, typename T7, typename T8, typename T9>
class CartesianProductGenerator9
: public ParamGeneratorInterface< ::std::tuple<T1, T2, T3, T4, T5, T6, T7,
T8, T9> > {
public:
typedef ::std::tuple<T1, T2, T3, T4, T5, T6, T7, T8, T9> ParamType;
CartesianProductGenerator9(const ParamGenerator<T1>& g1,
const ParamGenerator<T2>& g2, const ParamGenerator<T3>& g3,
const ParamGenerator<T4>& g4, const ParamGenerator<T5>& g5,
const ParamGenerator<T6>& g6, const ParamGenerator<T7>& g7,
const ParamGenerator<T8>& g8, const ParamGenerator<T9>& g9)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5), g6_(g6), g7_(g7), g8_(g8),
g9_(g9) {}
~CartesianProductGenerator9() override {}
ParamIteratorInterface<ParamType>* Begin() const override {
return new Iterator(this, g1_, g1_.begin(), g2_, g2_.begin(), g3_,
g3_.begin(), g4_, g4_.begin(), g5_, g5_.begin(), g6_, g6_.begin(), g7_,
g7_.begin(), g8_, g8_.begin(), g9_, g9_.begin());
}
ParamIteratorInterface<ParamType>* End() const override {
return new Iterator(this, g1_, g1_.end(), g2_, g2_.end(), g3_, g3_.end(),
g4_, g4_.end(), g5_, g5_.end(), g6_, g6_.end(), g7_, g7_.end(), g8_,
g8_.end(), g9_, g9_.end());
}
private:
class Iterator : public ParamIteratorInterface<ParamType> {
public:
Iterator(const ParamGeneratorInterface<ParamType>* base,
const ParamGenerator<T1>& g1,
const typename ParamGenerator<T1>::iterator& current1,
const ParamGenerator<T2>& g2,
const typename ParamGenerator<T2>::iterator& current2,
const ParamGenerator<T3>& g3,
const typename ParamGenerator<T3>::iterator& current3,
const ParamGenerator<T4>& g4,
const typename ParamGenerator<T4>::iterator& current4,
const ParamGenerator<T5>& g5,
const typename ParamGenerator<T5>::iterator& current5,
const ParamGenerator<T6>& g6,
const typename ParamGenerator<T6>::iterator& current6,
const ParamGenerator<T7>& g7,
const typename ParamGenerator<T7>::iterator& current7,
const ParamGenerator<T8>& g8,
const typename ParamGenerator<T8>::iterator& current8,
const ParamGenerator<T9>& g9,
const typename ParamGenerator<T9>::iterator& current9)
: base_(base),
begin1_(g1.begin()), end1_(g1.end()), current1_(current1),
begin2_(g2.begin()), end2_(g2.end()), current2_(current2),
begin3_(g3.begin()), end3_(g3.end()), current3_(current3),
begin4_(g4.begin()), end4_(g4.end()), current4_(current4),
begin5_(g5.begin()), end5_(g5.end()), current5_(current5),
begin6_(g6.begin()), end6_(g6.end()), current6_(current6),
begin7_(g7.begin()), end7_(g7.end()), current7_(current7),
begin8_(g8.begin()), end8_(g8.end()), current8_(current8),
begin9_(g9.begin()), end9_(g9.end()), current9_(current9) {
ComputeCurrentValue();
}
~Iterator() override {}
const ParamGeneratorInterface<ParamType>* BaseGenerator() const override {
return base_;
}
// Advance should not be called on beyond-of-range iterators
// so no component iterators must be beyond end of range, either.
void Advance() override {
assert(!AtEnd());
++current9_;
if (current9_ == end9_) {
current9_ = begin9_;
++current8_;
}
if (current8_ == end8_) {
current8_ = begin8_;
++current7_;
}
if (current7_ == end7_) {
current7_ = begin7_;
++current6_;
}
if (current6_ == end6_) {
current6_ = begin6_;
++current5_;
}
if (current5_ == end5_) {
current5_ = begin5_;
++current4_;
}
if (current4_ == end4_) {
current4_ = begin4_;
++current3_;
}
if (current3_ == end3_) {
current3_ = begin3_;
++current2_;
}
if (current2_ == end2_) {
current2_ = begin2_;
++current1_;
}
ComputeCurrentValue();
}
ParamIteratorInterface<ParamType>* Clone() const override {
return new Iterator(*this);
}
const ParamType* Current() const override { return current_value_.get(); }
bool Equals(const ParamIteratorInterface<ParamType>& other) const override {
// Having the same base generator guarantees that the other
// iterator is of the same type and we can downcast.
GTEST_CHECK_(BaseGenerator() == other.BaseGenerator())
<< "The program attempted to compare iterators "
<< "from different generators." << std::endl;
const Iterator* typed_other =
CheckedDowncastToActualType<const Iterator>(&other);
// We must report iterators equal if they both point beyond their
// respective ranges. That can happen in a variety of fashions,
// so we have to consult AtEnd().
return (AtEnd() && typed_other->AtEnd()) ||
(
current1_ == typed_other->current1_ &&
current2_ == typed_other->current2_ &&
current3_ == typed_other->current3_ &&
current4_ == typed_other->current4_ &&
current5_ == typed_other->current5_ &&
current6_ == typed_other->current6_ &&
current7_ == typed_other->current7_ &&
current8_ == typed_other->current8_ &&
current9_ == typed_other->current9_);
}
private:
Iterator(const Iterator& other)
: base_(other.base_),
begin1_(other.begin1_),
end1_(other.end1_),
current1_(other.current1_),
begin2_(other.begin2_),
end2_(other.end2_),
current2_(other.current2_),
begin3_(other.begin3_),
end3_(other.end3_),
current3_(other.current3_),
begin4_(other.begin4_),
end4_(other.end4_),
current4_(other.current4_),
begin5_(other.begin5_),
end5_(other.end5_),
current5_(other.current5_),
begin6_(other.begin6_),
end6_(other.end6_),
current6_(other.current6_),
begin7_(other.begin7_),
end7_(other.end7_),
current7_(other.current7_),
begin8_(other.begin8_),
end8_(other.end8_),
current8_(other.current8_),
begin9_(other.begin9_),
end9_(other.end9_),
current9_(other.current9_) {
ComputeCurrentValue();
}
void ComputeCurrentValue() {
if (!AtEnd())
current_value_.reset(new ParamType(*current1_, *current2_, *current3_,
*current4_, *current5_, *current6_, *current7_, *current8_,
*current9_));
}
bool AtEnd() const {
// We must report iterator past the end of the range when either of the
// component iterators has reached the end of its range.
return
current1_ == end1_ ||
current2_ == end2_ ||
current3_ == end3_ ||
current4_ == end4_ ||
current5_ == end5_ ||
current6_ == end6_ ||
current7_ == end7_ ||
current8_ == end8_ ||
current9_ == end9_;
}
// No implementation - assignment is unsupported.
void operator=(const Iterator& other);
const ParamGeneratorInterface<ParamType>* const base_;
// begin[i]_ and end[i]_ define the i-th range that Iterator traverses.
// current[i]_ is the actual traversing iterator.
const typename ParamGenerator<T1>::iterator begin1_;
const typename ParamGenerator<T1>::iterator end1_;
typename ParamGenerator<T1>::iterator current1_;
const typename ParamGenerator<T2>::iterator begin2_;
const typename ParamGenerator<T2>::iterator end2_;
typename ParamGenerator<T2>::iterator current2_;
const typename ParamGenerator<T3>::iterator begin3_;
const typename ParamGenerator<T3>::iterator end3_;
typename ParamGenerator<T3>::iterator current3_;
const typename ParamGenerator<T4>::iterator begin4_;
const typename ParamGenerator<T4>::iterator end4_;
typename ParamGenerator<T4>::iterator current4_;
const typename ParamGenerator<T5>::iterator begin5_;
const typename ParamGenerator<T5>::iterator end5_;
typename ParamGenerator<T5>::iterator current5_;
const typename ParamGenerator<T6>::iterator begin6_;
const typename ParamGenerator<T6>::iterator end6_;
typename ParamGenerator<T6>::iterator current6_;
const typename ParamGenerator<T7>::iterator begin7_;
const typename ParamGenerator<T7>::iterator end7_;
typename ParamGenerator<T7>::iterator current7_;
const typename ParamGenerator<T8>::iterator begin8_;
const typename ParamGenerator<T8>::iterator end8_;
typename ParamGenerator<T8>::iterator current8_;
const typename ParamGenerator<T9>::iterator begin9_;
const typename ParamGenerator<T9>::iterator end9_;
typename ParamGenerator<T9>::iterator current9_;
std::shared_ptr<ParamType> current_value_;
}; // class CartesianProductGenerator9::Iterator
// No implementation - assignment is unsupported.
void operator=(const CartesianProductGenerator9& other);
const ParamGenerator<T1> g1_;
const ParamGenerator<T2> g2_;
const ParamGenerator<T3> g3_;
const ParamGenerator<T4> g4_;
const ParamGenerator<T5> g5_;
const ParamGenerator<T6> g6_;
const ParamGenerator<T7> g7_;
const ParamGenerator<T8> g8_;
const ParamGenerator<T9> g9_;
}; // class CartesianProductGenerator9
template <typename T1, typename T2, typename T3, typename T4, typename T5,
typename T6, typename T7, typename T8, typename T9, typename T10>
class CartesianProductGenerator10
: public ParamGeneratorInterface< ::std::tuple<T1, T2, T3, T4, T5, T6, T7,
T8, T9, T10> > {
public:
typedef ::std::tuple<T1, T2, T3, T4, T5, T6, T7, T8, T9, T10> ParamType;
CartesianProductGenerator10(const ParamGenerator<T1>& g1,
const ParamGenerator<T2>& g2, const ParamGenerator<T3>& g3,
const ParamGenerator<T4>& g4, const ParamGenerator<T5>& g5,
const ParamGenerator<T6>& g6, const ParamGenerator<T7>& g7,
const ParamGenerator<T8>& g8, const ParamGenerator<T9>& g9,
const ParamGenerator<T10>& g10)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5), g6_(g6), g7_(g7), g8_(g8),
g9_(g9), g10_(g10) {}
~CartesianProductGenerator10() override {}
ParamIteratorInterface<ParamType>* Begin() const override {
return new Iterator(this, g1_, g1_.begin(), g2_, g2_.begin(), g3_,
g3_.begin(), g4_, g4_.begin(), g5_, g5_.begin(), g6_, g6_.begin(), g7_,
g7_.begin(), g8_, g8_.begin(), g9_, g9_.begin(), g10_, g10_.begin());
}
ParamIteratorInterface<ParamType>* End() const override {
return new Iterator(this, g1_, g1_.end(), g2_, g2_.end(), g3_, g3_.end(),
g4_, g4_.end(), g5_, g5_.end(), g6_, g6_.end(), g7_, g7_.end(), g8_,
g8_.end(), g9_, g9_.end(), g10_, g10_.end());
}
private:
class Iterator : public ParamIteratorInterface<ParamType> {
public:
Iterator(const ParamGeneratorInterface<ParamType>* base,
const ParamGenerator<T1>& g1,
const typename ParamGenerator<T1>::iterator& current1,
const ParamGenerator<T2>& g2,
const typename ParamGenerator<T2>::iterator& current2,
const ParamGenerator<T3>& g3,
const typename ParamGenerator<T3>::iterator& current3,
const ParamGenerator<T4>& g4,
const typename ParamGenerator<T4>::iterator& current4,
const ParamGenerator<T5>& g5,
const typename ParamGenerator<T5>::iterator& current5,
const ParamGenerator<T6>& g6,
const typename ParamGenerator<T6>::iterator& current6,
const ParamGenerator<T7>& g7,
const typename ParamGenerator<T7>::iterator& current7,
const ParamGenerator<T8>& g8,
const typename ParamGenerator<T8>::iterator& current8,
const ParamGenerator<T9>& g9,
const typename ParamGenerator<T9>::iterator& current9,
const ParamGenerator<T10>& g10,
const typename ParamGenerator<T10>::iterator& current10)
: base_(base),
begin1_(g1.begin()), end1_(g1.end()), current1_(current1),
begin2_(g2.begin()), end2_(g2.end()), current2_(current2),
begin3_(g3.begin()), end3_(g3.end()), current3_(current3),
begin4_(g4.begin()), end4_(g4.end()), current4_(current4),
begin5_(g5.begin()), end5_(g5.end()), current5_(current5),
begin6_(g6.begin()), end6_(g6.end()), current6_(current6),
begin7_(g7.begin()), end7_(g7.end()), current7_(current7),
begin8_(g8.begin()), end8_(g8.end()), current8_(current8),
begin9_(g9.begin()), end9_(g9.end()), current9_(current9),
begin10_(g10.begin()), end10_(g10.end()), current10_(current10) {
ComputeCurrentValue();
}
~Iterator() override {}
const ParamGeneratorInterface<ParamType>* BaseGenerator() const override {
return base_;
}
// Advance should not be called on beyond-of-range iterators
// so no component iterators must be beyond end of range, either.
void Advance() override {
assert(!AtEnd());
++current10_;
if (current10_ == end10_) {
current10_ = begin10_;
++current9_;
}
if (current9_ == end9_) {
current9_ = begin9_;
++current8_;
}
if (current8_ == end8_) {
current8_ = begin8_;
++current7_;
}
if (current7_ == end7_) {
current7_ = begin7_;
++current6_;
}
if (current6_ == end6_) {
current6_ = begin6_;
++current5_;
}
if (current5_ == end5_) {
current5_ = begin5_;
++current4_;
}
if (current4_ == end4_) {
current4_ = begin4_;
++current3_;
}
if (current3_ == end3_) {
current3_ = begin3_;
++current2_;
}
if (current2_ == end2_) {
current2_ = begin2_;
++current1_;
}
ComputeCurrentValue();
}
ParamIteratorInterface<ParamType>* Clone() const override {
return new Iterator(*this);
}
const ParamType* Current() const override { return current_value_.get(); }
bool Equals(const ParamIteratorInterface<ParamType>& other) const override {
// Having the same base generator guarantees that the other
// iterator is of the same type and we can downcast.
GTEST_CHECK_(BaseGenerator() == other.BaseGenerator())
<< "The program attempted to compare iterators "
<< "from different generators." << std::endl;
const Iterator* typed_other =
CheckedDowncastToActualType<const Iterator>(&other);
// We must report iterators equal if they both point beyond their
// respective ranges. That can happen in a variety of fashions,
// so we have to consult AtEnd().
return (AtEnd() && typed_other->AtEnd()) ||
(
current1_ == typed_other->current1_ &&
current2_ == typed_other->current2_ &&
current3_ == typed_other->current3_ &&
current4_ == typed_other->current4_ &&
current5_ == typed_other->current5_ &&
current6_ == typed_other->current6_ &&
current7_ == typed_other->current7_ &&
current8_ == typed_other->current8_ &&
current9_ == typed_other->current9_ &&
current10_ == typed_other->current10_);
}
private:
Iterator(const Iterator& other)
: base_(other.base_),
begin1_(other.begin1_),
end1_(other.end1_),
current1_(other.current1_),
begin2_(other.begin2_),
end2_(other.end2_),
current2_(other.current2_),
begin3_(other.begin3_),
end3_(other.end3_),
current3_(other.current3_),
begin4_(other.begin4_),
end4_(other.end4_),
current4_(other.current4_),
begin5_(other.begin5_),
end5_(other.end5_),
current5_(other.current5_),
begin6_(other.begin6_),
end6_(other.end6_),
current6_(other.current6_),
begin7_(other.begin7_),
end7_(other.end7_),
current7_(other.current7_),
begin8_(other.begin8_),
end8_(other.end8_),
current8_(other.current8_),
begin9_(other.begin9_),
end9_(other.end9_),
current9_(other.current9_),
begin10_(other.begin10_),
end10_(other.end10_),
current10_(other.current10_) {
ComputeCurrentValue();
}
void ComputeCurrentValue() {
if (!AtEnd())
current_value_.reset(new ParamType(*current1_, *current2_, *current3_,
*current4_, *current5_, *current6_, *current7_, *current8_,
*current9_, *current10_));
}
bool AtEnd() const {
// We must report iterator past the end of the range when either of the
// component iterators has reached the end of its range.
return
current1_ == end1_ ||
current2_ == end2_ ||
current3_ == end3_ ||
current4_ == end4_ ||
current5_ == end5_ ||
current6_ == end6_ ||
current7_ == end7_ ||
current8_ == end8_ ||
current9_ == end9_ ||
current10_ == end10_;
}
// No implementation - assignment is unsupported.
void operator=(const Iterator& other);
const ParamGeneratorInterface<ParamType>* const base_;
// begin[i]_ and end[i]_ define the i-th range that Iterator traverses.
// current[i]_ is the actual traversing iterator.
const typename ParamGenerator<T1>::iterator begin1_;
const typename ParamGenerator<T1>::iterator end1_;
typename ParamGenerator<T1>::iterator current1_;
const typename ParamGenerator<T2>::iterator begin2_;
const typename ParamGenerator<T2>::iterator end2_;
typename ParamGenerator<T2>::iterator current2_;
const typename ParamGenerator<T3>::iterator begin3_;
const typename ParamGenerator<T3>::iterator end3_;
typename ParamGenerator<T3>::iterator current3_;
const typename ParamGenerator<T4>::iterator begin4_;
const typename ParamGenerator<T4>::iterator end4_;
typename ParamGenerator<T4>::iterator current4_;
const typename ParamGenerator<T5>::iterator begin5_;
const typename ParamGenerator<T5>::iterator end5_;
typename ParamGenerator<T5>::iterator current5_;
const typename ParamGenerator<T6>::iterator begin6_;
const typename ParamGenerator<T6>::iterator end6_;
typename ParamGenerator<T6>::iterator current6_;
const typename ParamGenerator<T7>::iterator begin7_;
const typename ParamGenerator<T7>::iterator end7_;
typename ParamGenerator<T7>::iterator current7_;
const typename ParamGenerator<T8>::iterator begin8_;
const typename ParamGenerator<T8>::iterator end8_;
typename ParamGenerator<T8>::iterator current8_;
const typename ParamGenerator<T9>::iterator begin9_;
const typename ParamGenerator<T9>::iterator end9_;
typename ParamGenerator<T9>::iterator current9_;
const typename ParamGenerator<T10>::iterator begin10_;
const typename ParamGenerator<T10>::iterator end10_;
typename ParamGenerator<T10>::iterator current10_;
std::shared_ptr<ParamType> current_value_;
}; // class CartesianProductGenerator10::Iterator
// No implementation - assignment is unsupported.
void operator=(const CartesianProductGenerator10& other);
const ParamGenerator<T1> g1_;
const ParamGenerator<T2> g2_;
const ParamGenerator<T3> g3_;
const ParamGenerator<T4> g4_;
const ParamGenerator<T5> g5_;
const ParamGenerator<T6> g6_;
const ParamGenerator<T7> g7_;
const ParamGenerator<T8> g8_;
const ParamGenerator<T9> g9_;
const ParamGenerator<T10> g10_;
}; // class CartesianProductGenerator10
// INTERNAL IMPLEMENTATION - DO NOT USE IN USER CODE.
//
// Helper classes providing Combine() with polymorphic features. They allow
// casting CartesianProductGeneratorN<T> to ParamGenerator<U> if T is
// convertible to U.
//
template <class Generator1, class Generator2>
class CartesianProductHolder2 {
public:
CartesianProductHolder2(const Generator1& g1, const Generator2& g2)
: g1_(g1), g2_(g2) {}
template <typename T1, typename T2>
operator ParamGenerator< ::std::tuple<T1, T2> >() const {
return ParamGenerator< ::std::tuple<T1, T2> >(
new CartesianProductGenerator2<T1, T2>(
static_cast<ParamGenerator<T1> >(g1_),
static_cast<ParamGenerator<T2> >(g2_)));
}
private:
// No implementation - assignment is unsupported.
void operator=(const CartesianProductHolder2& other);
const Generator1 g1_;
const Generator2 g2_;
}; // class CartesianProductHolder2
template <class Generator1, class Generator2, class Generator3>
class CartesianProductHolder3 {
public:
CartesianProductHolder3(const Generator1& g1, const Generator2& g2,
const Generator3& g3)
: g1_(g1), g2_(g2), g3_(g3) {}
template <typename T1, typename T2, typename T3>
operator ParamGenerator< ::std::tuple<T1, T2, T3> >() const {
return ParamGenerator< ::std::tuple<T1, T2, T3> >(
new CartesianProductGenerator3<T1, T2, T3>(
static_cast<ParamGenerator<T1> >(g1_),
static_cast<ParamGenerator<T2> >(g2_),
static_cast<ParamGenerator<T3> >(g3_)));
}
private:
// No implementation - assignment is unsupported.
void operator=(const CartesianProductHolder3& other);
const Generator1 g1_;
const Generator2 g2_;
const Generator3 g3_;
}; // class CartesianProductHolder3
template <class Generator1, class Generator2, class Generator3,
class Generator4>
class CartesianProductHolder4 {
public:
CartesianProductHolder4(const Generator1& g1, const Generator2& g2,
const Generator3& g3, const Generator4& g4)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4) {}
template <typename T1, typename T2, typename T3, typename T4>
operator ParamGenerator< ::std::tuple<T1, T2, T3, T4> >() const {
return ParamGenerator< ::std::tuple<T1, T2, T3, T4> >(
new CartesianProductGenerator4<T1, T2, T3, T4>(
static_cast<ParamGenerator<T1> >(g1_),
static_cast<ParamGenerator<T2> >(g2_),
static_cast<ParamGenerator<T3> >(g3_),
static_cast<ParamGenerator<T4> >(g4_)));
}
private:
// No implementation - assignment is unsupported.
void operator=(const CartesianProductHolder4& other);
const Generator1 g1_;
const Generator2 g2_;
const Generator3 g3_;
const Generator4 g4_;
}; // class CartesianProductHolder4
template <class Generator1, class Generator2, class Generator3,
class Generator4, class Generator5>
class CartesianProductHolder5 {
public:
CartesianProductHolder5(const Generator1& g1, const Generator2& g2,
const Generator3& g3, const Generator4& g4, const Generator5& g5)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5) {}
template <typename T1, typename T2, typename T3, typename T4, typename T5>
operator ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5> >() const {
return ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5> >(
new CartesianProductGenerator5<T1, T2, T3, T4, T5>(
static_cast<ParamGenerator<T1> >(g1_),
static_cast<ParamGenerator<T2> >(g2_),
static_cast<ParamGenerator<T3> >(g3_),
static_cast<ParamGenerator<T4> >(g4_),
static_cast<ParamGenerator<T5> >(g5_)));
}
private:
// No implementation - assignment is unsupported.
void operator=(const CartesianProductHolder5& other);
const Generator1 g1_;
const Generator2 g2_;
const Generator3 g3_;
const Generator4 g4_;
const Generator5 g5_;
}; // class CartesianProductHolder5
template <class Generator1, class Generator2, class Generator3,
class Generator4, class Generator5, class Generator6>
class CartesianProductHolder6 {
public:
CartesianProductHolder6(const Generator1& g1, const Generator2& g2,
const Generator3& g3, const Generator4& g4, const Generator5& g5,
const Generator6& g6)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5), g6_(g6) {}
template <typename T1, typename T2, typename T3, typename T4, typename T5,
typename T6>
operator ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5, T6> >() const {
return ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5, T6> >(
new CartesianProductGenerator6<T1, T2, T3, T4, T5, T6>(
static_cast<ParamGenerator<T1> >(g1_),
static_cast<ParamGenerator<T2> >(g2_),
static_cast<ParamGenerator<T3> >(g3_),
static_cast<ParamGenerator<T4> >(g4_),
static_cast<ParamGenerator<T5> >(g5_),
static_cast<ParamGenerator<T6> >(g6_)));
}
private:
// No implementation - assignment is unsupported.
void operator=(const CartesianProductHolder6& other);
const Generator1 g1_;
const Generator2 g2_;
const Generator3 g3_;
const Generator4 g4_;
const Generator5 g5_;
const Generator6 g6_;
}; // class CartesianProductHolder6
template <class Generator1, class Generator2, class Generator3,
class Generator4, class Generator5, class Generator6, class Generator7>
class CartesianProductHolder7 {
public:
CartesianProductHolder7(const Generator1& g1, const Generator2& g2,
const Generator3& g3, const Generator4& g4, const Generator5& g5,
const Generator6& g6, const Generator7& g7)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5), g6_(g6), g7_(g7) {}
template <typename T1, typename T2, typename T3, typename T4, typename T5,
typename T6, typename T7>
operator ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5, T6, T7> >() const {
return ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5, T6, T7> >(
new CartesianProductGenerator7<T1, T2, T3, T4, T5, T6, T7>(
static_cast<ParamGenerator<T1> >(g1_),
static_cast<ParamGenerator<T2> >(g2_),
static_cast<ParamGenerator<T3> >(g3_),
static_cast<ParamGenerator<T4> >(g4_),
static_cast<ParamGenerator<T5> >(g5_),
static_cast<ParamGenerator<T6> >(g6_),
static_cast<ParamGenerator<T7> >(g7_)));
}
private:
// No implementation - assignment is unsupported.
void operator=(const CartesianProductHolder7& other);
const Generator1 g1_;
const Generator2 g2_;
const Generator3 g3_;
const Generator4 g4_;
const Generator5 g5_;
const Generator6 g6_;
const Generator7 g7_;
}; // class CartesianProductHolder7
template <class Generator1, class Generator2, class Generator3,
class Generator4, class Generator5, class Generator6, class Generator7,
class Generator8>
class CartesianProductHolder8 {
public:
CartesianProductHolder8(const Generator1& g1, const Generator2& g2,
const Generator3& g3, const Generator4& g4, const Generator5& g5,
const Generator6& g6, const Generator7& g7, const Generator8& g8)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5), g6_(g6), g7_(g7),
g8_(g8) {}
template <typename T1, typename T2, typename T3, typename T4, typename T5,
typename T6, typename T7, typename T8>
operator ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5, T6, T7,
T8> >() const {
return ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5, T6, T7, T8> >(
new CartesianProductGenerator8<T1, T2, T3, T4, T5, T6, T7, T8>(
static_cast<ParamGenerator<T1> >(g1_),
static_cast<ParamGenerator<T2> >(g2_),
static_cast<ParamGenerator<T3> >(g3_),
static_cast<ParamGenerator<T4> >(g4_),
static_cast<ParamGenerator<T5> >(g5_),
static_cast<ParamGenerator<T6> >(g6_),
static_cast<ParamGenerator<T7> >(g7_),
static_cast<ParamGenerator<T8> >(g8_)));
}
private:
// No implementation - assignment is unsupported.
void operator=(const CartesianProductHolder8& other);
const Generator1 g1_;
const Generator2 g2_;
const Generator3 g3_;
const Generator4 g4_;
const Generator5 g5_;
const Generator6 g6_;
const Generator7 g7_;
const Generator8 g8_;
}; // class CartesianProductHolder8
template <class Generator1, class Generator2, class Generator3,
class Generator4, class Generator5, class Generator6, class Generator7,
class Generator8, class Generator9>
class CartesianProductHolder9 {
public:
CartesianProductHolder9(const Generator1& g1, const Generator2& g2,
const Generator3& g3, const Generator4& g4, const Generator5& g5,
const Generator6& g6, const Generator7& g7, const Generator8& g8,
const Generator9& g9)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5), g6_(g6), g7_(g7), g8_(g8),
g9_(g9) {}
template <typename T1, typename T2, typename T3, typename T4, typename T5,
typename T6, typename T7, typename T8, typename T9>
operator ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5, T6, T7, T8,
T9> >() const {
return ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5, T6, T7, T8, T9> >(
new CartesianProductGenerator9<T1, T2, T3, T4, T5, T6, T7, T8, T9>(
static_cast<ParamGenerator<T1> >(g1_),
static_cast<ParamGenerator<T2> >(g2_),
static_cast<ParamGenerator<T3> >(g3_),
static_cast<ParamGenerator<T4> >(g4_),
static_cast<ParamGenerator<T5> >(g5_),
static_cast<ParamGenerator<T6> >(g6_),
static_cast<ParamGenerator<T7> >(g7_),
static_cast<ParamGenerator<T8> >(g8_),
static_cast<ParamGenerator<T9> >(g9_)));
}
private:
// No implementation - assignment is unsupported.
void operator=(const CartesianProductHolder9& other);
const Generator1 g1_;
const Generator2 g2_;
const Generator3 g3_;
const Generator4 g4_;
const Generator5 g5_;
const Generator6 g6_;
const Generator7 g7_;
const Generator8 g8_;
const Generator9 g9_;
}; // class CartesianProductHolder9
template <class Generator1, class Generator2, class Generator3,
class Generator4, class Generator5, class Generator6, class Generator7,
class Generator8, class Generator9, class Generator10>
class CartesianProductHolder10 {
public:
CartesianProductHolder10(const Generator1& g1, const Generator2& g2,
const Generator3& g3, const Generator4& g4, const Generator5& g5,
const Generator6& g6, const Generator7& g7, const Generator8& g8,
const Generator9& g9, const Generator10& g10)
: g1_(g1), g2_(g2), g3_(g3), g4_(g4), g5_(g5), g6_(g6), g7_(g7), g8_(g8),
g9_(g9), g10_(g10) {}
template <typename T1, typename T2, typename T3, typename T4, typename T5,
typename T6, typename T7, typename T8, typename T9, typename T10>
operator ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5, T6, T7, T8, T9,
T10> >() const {
return ParamGenerator< ::std::tuple<T1, T2, T3, T4, T5, T6, T7, T8, T9,
T10> >(
new CartesianProductGenerator10<T1, T2, T3, T4, T5, T6, T7, T8, T9,
T10>(
static_cast<ParamGenerator<T1> >(g1_),
static_cast<ParamGenerator<T2> >(g2_),
static_cast<ParamGenerator<T3> >(g3_),
static_cast<ParamGenerator<T4> >(g4_),
static_cast<ParamGenerator<T5> >(g5_),
static_cast<ParamGenerator<T6> >(g6_),
static_cast<ParamGenerator<T7> >(g7_),
static_cast<ParamGenerator<T8> >(g8_),
static_cast<ParamGenerator<T9> >(g9_),
static_cast<ParamGenerator<T10> >(g10_)));
}
private:
// No implementation - assignment is unsupported.
void operator=(const CartesianProductHolder10& other);
const Generator1 g1_;
const Generator2 g2_;
const Generator3 g3_;
const Generator4 g4_;
const Generator5 g5_;
const Generator6 g6_;
const Generator7 g7_;
const Generator8 g8_;
const Generator9 g9_;
const Generator10 g10_;
}; // class CartesianProductHolder10
} // namespace internal
} // namespace testing
#endif // GTEST_INCLUDE_GTEST_INTERNAL_GTEST_PARAM_UTIL_GENERATED_H_