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#include <unittest/unittest.h>
#include <thrust/copy.h>
#include <array>
#include <algorithm>
#include <list>
#include <iterator>
#include <thrust/sequence.h>
#include <thrust/iterator/zip_iterator.h>
#include <thrust/iterator/counting_iterator.h>
#include <thrust/iterator/constant_iterator.h>
#include <thrust/iterator/discard_iterator.h>
#include <thrust/iterator/retag.h>
#include <thrust/device_malloc.h>
#include <thrust/device_free.h>
void TestCopyFromConstIterator(void)
{
typedef int T;
std::vector<T> v(5);
v[0] = 0; v[1] = 1; v[2] = 2; v[3] = 3; v[4] = 4;
std::vector<int>::const_iterator begin = v.begin();
std::vector<int>::const_iterator end = v.end();
// copy to host_vector
thrust::host_vector<T> h(5, (T) 10);
thrust::host_vector<T>::iterator h_result = thrust::copy(begin, end, h.begin());
ASSERT_EQUAL(h[0], 0);
ASSERT_EQUAL(h[1], 1);
ASSERT_EQUAL(h[2], 2);
ASSERT_EQUAL(h[3], 3);
ASSERT_EQUAL(h[4], 4);
ASSERT_EQUAL_QUIET(h_result, h.end());
// copy to device_vector
thrust::device_vector<T> d(5, (T) 10);
thrust::device_vector<T>::iterator d_result = thrust::copy(begin, end, d.begin());
ASSERT_EQUAL(d[0], 0);
ASSERT_EQUAL(d[1], 1);
ASSERT_EQUAL(d[2], 2);
ASSERT_EQUAL(d[3], 3);
ASSERT_EQUAL(d[4], 4);
ASSERT_EQUAL_QUIET(d_result, d.end());
}
DECLARE_UNITTEST(TestCopyFromConstIterator);
void TestCopyToDiscardIterator(void)
{
typedef int T;
thrust::host_vector<T> h_input(5,1);
thrust::device_vector<T> d_input = h_input;
thrust::discard_iterator<> reference(5);
// copy from host_vector
thrust::discard_iterator<> h_result =
thrust::copy(h_input.begin(), h_input.end(), thrust::make_discard_iterator());
// copy from device_vector
thrust::discard_iterator<> d_result =
thrust::copy(d_input.begin(), d_input.end(), thrust::make_discard_iterator());
ASSERT_EQUAL_QUIET(reference, h_result);
ASSERT_EQUAL_QUIET(reference, d_result);
}
DECLARE_UNITTEST(TestCopyToDiscardIterator);
void TestCopyToDiscardIteratorZipped(void)
{
typedef int T;
thrust::host_vector<T> h_input(5,1);
thrust::device_vector<T> d_input = h_input;
thrust::host_vector<T> h_output(5);
thrust::device_vector<T> d_output(5);
thrust::discard_iterator<> reference(5);
typedef thrust::tuple<thrust::discard_iterator<>,thrust::host_vector<T>::iterator> Tuple1;
typedef thrust::tuple<thrust::discard_iterator<>,thrust::device_vector<T>::iterator> Tuple2;
typedef thrust::zip_iterator<Tuple1> ZipIterator1;
typedef thrust::zip_iterator<Tuple2> ZipIterator2;
// copy from host_vector
ZipIterator1 h_result =
thrust::copy(thrust::make_zip_iterator(thrust::make_tuple(h_input.begin(), h_input.begin())),
thrust::make_zip_iterator(thrust::make_tuple(h_input.end(), h_input.end())),
thrust::make_zip_iterator(thrust::make_tuple(thrust::make_discard_iterator(), h_output.begin())));
// copy from device_vector
ZipIterator2 d_result =
thrust::copy(thrust::make_zip_iterator(thrust::make_tuple(d_input.begin(), d_input.begin())),
thrust::make_zip_iterator(thrust::make_tuple(d_input.end(), d_input.end())),
thrust::make_zip_iterator(thrust::make_tuple(thrust::make_discard_iterator(), d_output.begin())));
ASSERT_EQUAL(h_output, h_input);
ASSERT_EQUAL(d_output, d_input);
ASSERT_EQUAL_QUIET(reference, thrust::get<0>(h_result.get_iterator_tuple()));
ASSERT_EQUAL_QUIET(reference, thrust::get<0>(d_result.get_iterator_tuple()));
}
DECLARE_UNITTEST(TestCopyToDiscardIteratorZipped);
template <class Vector>
void TestCopyMatchingTypes(void)
{
typedef typename Vector::value_type T;
Vector v(5);
v[0] = 0; v[1] = 1; v[2] = 2; v[3] = 3; v[4] = 4;
// copy to host_vector
thrust::host_vector<T> h(5, (T) 10);
typename thrust::host_vector<T>::iterator h_result = thrust::copy(v.begin(), v.end(), h.begin());
ASSERT_EQUAL(h[0], 0);
ASSERT_EQUAL(h[1], 1);
ASSERT_EQUAL(h[2], 2);
ASSERT_EQUAL(h[3], 3);
ASSERT_EQUAL(h[4], 4);
ASSERT_EQUAL_QUIET(h_result, h.end());
// copy to device_vector
thrust::device_vector<T> d(5, (T) 10);
typename thrust::device_vector<T>::iterator d_result = thrust::copy(v.begin(), v.end(), d.begin());
ASSERT_EQUAL(d[0], 0);
ASSERT_EQUAL(d[1], 1);
ASSERT_EQUAL(d[2], 2);
ASSERT_EQUAL(d[3], 3);
ASSERT_EQUAL(d[4], 4);
ASSERT_EQUAL_QUIET(d_result, d.end());
}
DECLARE_VECTOR_UNITTEST(TestCopyMatchingTypes);
template <class Vector>
void TestCopyMixedTypes(void)
{
Vector v(5);
v[0] = 0; v[1] = 1; v[2] = 2; v[3] = 3; v[4] = 4;
// copy to host_vector with different type
thrust::host_vector<float> h(5, (float) 10);
typename thrust::host_vector<float>::iterator h_result = thrust::copy(v.begin(), v.end(), h.begin());
ASSERT_EQUAL(h[0], 0);
ASSERT_EQUAL(h[1], 1);
ASSERT_EQUAL(h[2], 2);
ASSERT_EQUAL(h[3], 3);
ASSERT_EQUAL(h[4], 4);
ASSERT_EQUAL_QUIET(h_result, h.end());
// copy to device_vector with different type
thrust::device_vector<float> d(5, (float) 10);
typename thrust::device_vector<float>::iterator d_result = thrust::copy(v.begin(), v.end(), d.begin());
ASSERT_EQUAL(d[0], 0);
ASSERT_EQUAL(d[1], 1);
ASSERT_EQUAL(d[2], 2);
ASSERT_EQUAL(d[3], 3);
ASSERT_EQUAL(d[4], 4);
ASSERT_EQUAL_QUIET(d_result, d.end());
}
DECLARE_INTEGRAL_VECTOR_UNITTEST(TestCopyMixedTypes);
void TestCopyVectorBool(void)
{
std::vector<bool> v(3);
v[0] = true; v[1] = false; v[2] = true;
thrust::host_vector<bool> h(3);
thrust::device_vector<bool> d(3);
thrust::copy(v.begin(), v.end(), h.begin());
thrust::copy(v.begin(), v.end(), d.begin());
ASSERT_EQUAL(h[0], true);
ASSERT_EQUAL(h[1], false);
ASSERT_EQUAL(h[2], true);
ASSERT_EQUAL(d[0], true);
ASSERT_EQUAL(d[1], false);
ASSERT_EQUAL(d[2], true);
}
DECLARE_UNITTEST(TestCopyVectorBool);
template <class Vector>
void TestCopyListTo(void)
{
typedef typename Vector::value_type T;
// copy from list to Vector
std::list<T> l;
l.push_back(0);
l.push_back(1);
l.push_back(2);
l.push_back(3);
l.push_back(4);
Vector v(l.size());
typename Vector::iterator v_result = thrust::copy(l.begin(), l.end(), v.begin());
ASSERT_EQUAL(v[0], T(0));
ASSERT_EQUAL(v[1], T(1));
ASSERT_EQUAL(v[2], T(2));
ASSERT_EQUAL(v[3], T(3));
ASSERT_EQUAL(v[4], T(4));
ASSERT_EQUAL_QUIET(v_result, v.end());
l.clear();
thrust::copy(v.begin(), v.end(), std::back_insert_iterator< std::list<T> >(l));
ASSERT_EQUAL(l.size(), 5lu);
typename std::list<T>::const_iterator iter = l.begin();
ASSERT_EQUAL(*iter, T(0)); iter++;
ASSERT_EQUAL(*iter, T(1)); iter++;
ASSERT_EQUAL(*iter, T(2)); iter++;
ASSERT_EQUAL(*iter, T(3)); iter++;
ASSERT_EQUAL(*iter, T(4)); iter++;
}
DECLARE_VECTOR_UNITTEST(TestCopyListTo);
template<typename T>
struct is_even
{
__host__ __device__
bool operator()(T x) { return (x & 1) == 0; }
};
template<typename T>
struct is_true
{
__host__ __device__
bool operator()(T x) { return x ? true : false; }
};
template<typename T>
struct mod_3
{
__host__ __device__
unsigned int operator()(T x) { return x % 3; }
};
template <class Vector>
void TestCopyIfSimple(void)
{
typedef typename Vector::value_type T;
Vector v(5);
v[0] = 0; v[1] = 1; v[2] = 2; v[3] = 3; v[4] = 4;
Vector dest(4);
typename Vector::iterator dest_end = thrust::copy_if(v.begin(), v.end(), dest.begin(), is_true<T>());
ASSERT_EQUAL(1, dest[0]);
ASSERT_EQUAL(2, dest[1]);
ASSERT_EQUAL(3, dest[2]);
ASSERT_EQUAL(4, dest[3]);
ASSERT_EQUAL_QUIET(dest.end(), dest_end);
}
DECLARE_VECTOR_UNITTEST(TestCopyIfSimple);
template <typename T>
void TestCopyIf(const size_t n)
{
thrust::host_vector<T> h_data = unittest::random_integers<T>(n);
thrust::device_vector<T> d_data = h_data;
typename thrust::host_vector<T>::iterator h_new_end;
typename thrust::device_vector<T>::iterator d_new_end;
{
thrust::host_vector<T> h_result(n);
thrust::device_vector<T> d_result(n);
h_new_end = thrust::copy_if(h_data.begin(), h_data.end(), h_result.begin(), is_true<T>());
d_new_end = thrust::copy_if(d_data.begin(), d_data.end(), d_result.begin(), is_true<T>());
h_result.resize(h_new_end - h_result.begin());
d_result.resize(d_new_end - d_result.begin());
ASSERT_EQUAL(h_result, d_result);
}
}
DECLARE_INTEGRAL_VARIABLE_UNITTEST(TestCopyIf);
template <typename T>
void TestCopyIfIntegral(const size_t n)
{
thrust::host_vector<T> h_data = unittest::random_integers<T>(n);
thrust::device_vector<T> d_data = h_data;
typename thrust::host_vector<T>::iterator h_new_end;
typename thrust::device_vector<T>::iterator d_new_end;
// test with Predicate that returns a bool
{
thrust::host_vector<T> h_result(n);
thrust::device_vector<T> d_result(n);
h_new_end = thrust::copy_if(h_data.begin(), h_data.end(), h_result.begin(), is_even<T>());
d_new_end = thrust::copy_if(d_data.begin(), d_data.end(), d_result.begin(), is_even<T>());
h_result.resize(h_new_end - h_result.begin());
d_result.resize(d_new_end - d_result.begin());
ASSERT_EQUAL(h_result, d_result);
}
// test with Predicate that returns a non-bool
{
thrust::host_vector<T> h_result(n);
thrust::device_vector<T> d_result(n);
h_new_end = thrust::copy_if(h_data.begin(), h_data.end(), h_result.begin(), mod_3<T>());
d_new_end = thrust::copy_if(d_data.begin(), d_data.end(), d_result.begin(), mod_3<T>());
h_result.resize(h_new_end - h_result.begin());
d_result.resize(d_new_end - d_result.begin());
ASSERT_EQUAL(h_result, d_result);
}
}
DECLARE_INTEGRAL_VARIABLE_UNITTEST(TestCopyIfIntegral);
template <typename T>
void TestCopyIfSequence(const size_t n)
{
thrust::host_vector<T> h_data(n); thrust::sequence(h_data.begin(), h_data.end());
thrust::device_vector<T> d_data(n); thrust::sequence(d_data.begin(), d_data.end());
thrust::host_vector<T> h_result(n);
thrust::device_vector<T> d_result(n);
typename thrust::host_vector<T>::iterator h_new_end;
typename thrust::device_vector<T>::iterator d_new_end;
// test with Predicate that returns a bool
{
thrust::host_vector<T> h_result(n);
thrust::device_vector<T> d_result(n);
h_new_end = thrust::copy_if(h_data.begin(), h_data.end(), h_result.begin(), is_even<T>());
d_new_end = thrust::copy_if(d_data.begin(), d_data.end(), d_result.begin(), is_even<T>());
h_result.resize(h_new_end - h_result.begin());
d_result.resize(d_new_end - d_result.begin());
ASSERT_EQUAL(h_result, d_result);
}
// test with Predicate that returns a non-bool
{
thrust::host_vector<T> h_result(n);
thrust::device_vector<T> d_result(n);
h_new_end = thrust::copy_if(h_data.begin(), h_data.end(), h_result.begin(), mod_3<T>());
d_new_end = thrust::copy_if(d_data.begin(), d_data.end(), d_result.begin(), mod_3<T>());
h_result.resize(h_new_end - h_result.begin());
d_result.resize(d_new_end - d_result.begin());
ASSERT_EQUAL(h_result, d_result);
}
}
DECLARE_INTEGRAL_VARIABLE_UNITTEST(TestCopyIfSequence);
template <class Vector>
void TestCopyIfStencilSimple(void)
{
typedef typename Vector::value_type T;
Vector v(5);
v[0] = 0; v[1] = 1; v[2] = 2; v[3] = 3; v[4] = 4;
Vector s(5);
s[0] = 1; s[1] = 1; s[2] = 0; s[3] = 1; s[4] = 0;
Vector dest(3);
typename Vector::iterator dest_end = thrust::copy_if(v.begin(), v.end(), s.begin(), dest.begin(), is_true<T>());
ASSERT_EQUAL(0, dest[0]);
ASSERT_EQUAL(1, dest[1]);
ASSERT_EQUAL(3, dest[2]);
ASSERT_EQUAL_QUIET(dest.end(), dest_end);
}
DECLARE_VECTOR_UNITTEST(TestCopyIfStencilSimple);
template <typename T>
void TestCopyIfStencil(const size_t n)
{
thrust::host_vector<T> h_data(n); thrust::sequence(h_data.begin(), h_data.end());
thrust::device_vector<T> d_data(n); thrust::sequence(d_data.begin(), d_data.end());
thrust::host_vector<T> h_stencil = unittest::random_integers<T>(n);
thrust::device_vector<T> d_stencil = unittest::random_integers<T>(n);
thrust::host_vector<T> h_result(n);
thrust::device_vector<T> d_result(n);
typename thrust::host_vector<T>::iterator h_new_end;
typename thrust::device_vector<T>::iterator d_new_end;
{
thrust::host_vector<T> h_result(n);
thrust::device_vector<T> d_result(n);
h_new_end = thrust::copy_if(h_data.begin(), h_data.end(), h_stencil.begin(), h_result.begin(), is_even<T>());
d_new_end = thrust::copy_if(d_data.begin(), d_data.end(), d_stencil.begin(), d_result.begin(), is_even<T>());
h_result.resize(h_new_end - h_result.begin());
d_result.resize(d_new_end - d_result.begin());
ASSERT_EQUAL(h_result, d_result);
}
}
DECLARE_INTEGRAL_VARIABLE_UNITTEST(TestCopyIfStencil);
namespace
{
struct object_with_non_trivial_ctor
{
// This struct will only properly assign if its `magic` member is
// set to this certain number.
static constexpr int MAGIC = 923390;
int field;
int magic;
__host__ __device__ object_with_non_trivial_ctor()
{
magic = MAGIC;
field = 0;
}
__host__ __device__ object_with_non_trivial_ctor(int f)
{
magic = MAGIC;
field = f;
}
object_with_non_trivial_ctor(const object_with_non_trivial_ctor& x) = default;
// This non-trivial assignment requires that `this` points to initialized
// memory
__host__ __device__ object_with_non_trivial_ctor&
operator=(const object_with_non_trivial_ctor& x)
{
// To really copy over x's field value, require we have magic value set.
// If copy_if copies to uninitialized bits, the field will rarely be 923390.
if (magic == MAGIC)
{
field = x.field;
}
return *this;
}
};
struct always_true
{
__host__ __device__
bool operator()(const object_with_non_trivial_ctor&)
{
return true;
};
};
} // end anon namespace
void TestCopyIfNonTrivial()
{
// Attempting to copy an object_with_non_trivial_ctor into uninitialized
// memory will fail:
{
static constexpr size_t BufferAlign = alignof(object_with_non_trivial_ctor);
static constexpr size_t BufferSize = sizeof(object_with_non_trivial_ctor);
alignas(BufferAlign) std::array<unsigned char, BufferSize> buffer;
// Fill buffer with 0s to prevent warnings about uninitialized reads while
// ensure that the 'magic number' mechanism works as intended:
std::fill(buffer.begin(), buffer.end(), 0);
object_with_non_trivial_ctor initialized;
object_with_non_trivial_ctor *uninitialized =
reinterpret_cast<object_with_non_trivial_ctor*>(buffer.data());
object_with_non_trivial_ctor source(42);
initialized = source;
*uninitialized = source;
ASSERT_EQUAL(42, initialized.field);
ASSERT_NOT_EQUAL(42, uninitialized->field);
}
// This test ensures that we use placement new instead of assigning
// to uninitialized memory. See Thrust Github issue #1153.
thrust::device_vector<object_with_non_trivial_ctor> a(10, object_with_non_trivial_ctor(99));
thrust::device_vector<object_with_non_trivial_ctor> b(10);
thrust::copy_if(a.begin(), a.end(), b.begin(), always_true());
for (int i = 0; i < 10; i++)
{
object_with_non_trivial_ctor ha(a[i]);
object_with_non_trivial_ctor hb(b[i]);
int ia = ha.field;
int ib = hb.field;
ASSERT_EQUAL(ia, ib);
}
}
DECLARE_UNITTEST(TestCopyIfNonTrivial);
template <typename Vector>
void TestCopyCountingIterator(void)
{
typedef typename Vector::value_type T;
thrust::counting_iterator<T> iter(1);
Vector vec(4);
thrust::copy(iter, iter + 4, vec.begin());
ASSERT_EQUAL(vec[0], 1);
ASSERT_EQUAL(vec[1], 2);
ASSERT_EQUAL(vec[2], 3);
ASSERT_EQUAL(vec[3], 4);
}
DECLARE_INTEGRAL_VECTOR_UNITTEST(TestCopyCountingIterator);
template <typename Vector>
void TestCopyZipIterator(void)
{
typedef typename Vector::value_type T;
Vector v1(3); v1[0] = 1; v1[1] = 2; v1[2] = 3;
Vector v2(3); v2[0] = 4; v2[1] = 5; v2[2] = 6;
Vector v3(3, T(0));
Vector v4(3, T(0));
thrust::copy(thrust::make_zip_iterator(thrust::make_tuple(v1.begin(),v2.begin())),
thrust::make_zip_iterator(thrust::make_tuple(v1.end(),v2.end())),
thrust::make_zip_iterator(thrust::make_tuple(v3.begin(),v4.begin())));
ASSERT_EQUAL(v1, v3);
ASSERT_EQUAL(v2, v4);
};
DECLARE_VECTOR_UNITTEST(TestCopyZipIterator);
template <typename Vector>
void TestCopyConstantIteratorToZipIterator(void)
{
typedef typename Vector::value_type T;
Vector v1(3,T(0));
Vector v2(3,T(0));
thrust::copy(thrust::make_constant_iterator(thrust::tuple<T,T>(4,7)),
thrust::make_constant_iterator(thrust::tuple<T,T>(4,7)) + v1.size(),
thrust::make_zip_iterator(thrust::make_tuple(v1.begin(),v2.begin())));
ASSERT_EQUAL(v1[0], 4);
ASSERT_EQUAL(v1[1], 4);
ASSERT_EQUAL(v1[2], 4);
ASSERT_EQUAL(v2[0], 7);
ASSERT_EQUAL(v2[1], 7);
ASSERT_EQUAL(v2[2], 7);
};
DECLARE_VECTOR_UNITTEST(TestCopyConstantIteratorToZipIterator);
template<typename InputIterator, typename OutputIterator>
OutputIterator copy(my_system &system, InputIterator, InputIterator, OutputIterator result)
{
system.validate_dispatch();
return result;
}
void TestCopyDispatchExplicit()
{
thrust::device_vector<int> vec(1);
my_system sys(0);
thrust::copy(sys,
vec.begin(),
vec.end(),
vec.begin());
ASSERT_EQUAL(true, sys.is_valid());
}
DECLARE_UNITTEST(TestCopyDispatchExplicit);
template<typename InputIterator, typename OutputIterator>
OutputIterator copy(my_tag, InputIterator, InputIterator, OutputIterator result)
{
*result = 13;
return result;
}
void TestCopyDispatchImplicit()
{
thrust::device_vector<int> vec(1);
thrust::copy(thrust::retag<my_tag>(vec.begin()),
thrust::retag<my_tag>(vec.end()),
thrust::retag<my_tag>(vec.begin()));
ASSERT_EQUAL(13, vec.front());
}
DECLARE_UNITTEST(TestCopyDispatchImplicit);
template<typename InputIterator, typename OutputIterator, typename Predicate>
OutputIterator copy_if(my_system &system, InputIterator, InputIterator, OutputIterator result, Predicate)
{
system.validate_dispatch();
return result;
}
void TestCopyIfDispatchExplicit()
{
thrust::device_vector<int> vec(1);
my_system sys(0);
thrust::copy_if(sys,
vec.begin(),
vec.end(),
vec.begin(),
0);
ASSERT_EQUAL(true, sys.is_valid());
}
DECLARE_UNITTEST(TestCopyIfDispatchExplicit);
template<typename InputIterator, typename OutputIterator, typename Predicate>
OutputIterator copy_if(my_tag, InputIterator, InputIterator, OutputIterator result, Predicate)
{
*result = 13;
return result;
}
void TestCopyIfDispatchImplicit()
{
thrust::device_vector<int> vec(1);
thrust::copy_if(thrust::retag<my_tag>(vec.begin()),
thrust::retag<my_tag>(vec.end()),
thrust::retag<my_tag>(vec.begin()),
0);
ASSERT_EQUAL(13, vec.front());
}
DECLARE_UNITTEST(TestCopyIfDispatchImplicit);
template<typename InputIterator1, typename InputIterator2, typename OutputIterator, typename Predicate>
OutputIterator copy_if(my_system &system, InputIterator1, InputIterator1, InputIterator2, OutputIterator result, Predicate)
{
system.validate_dispatch();
return result;
}
void TestCopyIfStencilDispatchExplicit()
{
thrust::device_vector<int> vec(1);
my_system sys(0);
thrust::copy_if(sys,
vec.begin(),
vec.end(),
vec.begin(),
vec.begin(),
0);
ASSERT_EQUAL(true, sys.is_valid());
}
DECLARE_UNITTEST(TestCopyIfStencilDispatchExplicit);
template<typename InputIterator1, typename InputIterator2, typename OutputIterator, typename Predicate>
OutputIterator copy_if(my_tag, InputIterator1, InputIterator1, InputIterator2, OutputIterator result, Predicate)
{
*result = 13;
return result;
}
void TestCopyIfStencilDispatchImplicit()
{
thrust::device_vector<int> vec(1);
thrust::copy_if(thrust::retag<my_tag>(vec.begin()),
thrust::retag<my_tag>(vec.end()),
thrust::retag<my_tag>(vec.begin()),
thrust::retag<my_tag>(vec.begin()),
0);
ASSERT_EQUAL(13, vec.front());
}
DECLARE_UNITTEST(TestCopyIfStencilDispatchImplicit);
struct only_set_when_expected_it
{
long long expected;
bool * flag;
__host__ __device__ only_set_when_expected_it operator++() const { return *this; }
__host__ __device__ only_set_when_expected_it operator*() const { return *this; }
template<typename Difference>
__host__ __device__ only_set_when_expected_it operator+(Difference) const { return *this; }
template<typename Difference>
__host__ __device__ only_set_when_expected_it operator+=(Difference) const { return *this; }
template<typename Index>
__host__ __device__ only_set_when_expected_it operator[](Index) const { return *this; }
__device__
void operator=(long long value) const
{
if (value == expected)
{
*flag = true;
}
}
};
namespace thrust
{
namespace detail
{
// We need this type to pass as a non-const ref for unary_transform_functor
// to compile:
template <>
struct is_non_const_reference<only_set_when_expected_it> : thrust::true_type {};
}
template<>
struct iterator_traits<only_set_when_expected_it>
{
typedef long long value_type;
typedef only_set_when_expected_it reference;
typedef thrust::random_access_device_iterator_tag iterator_category;
};
}
void TestCopyWithBigIndexesHelper(int magnitude)
{
thrust::counting_iterator<long long> begin(0);
thrust::counting_iterator<long long> end = begin + (1ll << magnitude);
ASSERT_EQUAL(thrust::distance(begin, end), 1ll << magnitude);
thrust::device_ptr<bool> has_executed = thrust::device_malloc<bool>(1);
*has_executed = false;
only_set_when_expected_it out = { (1ll << magnitude) - 1, thrust::raw_pointer_cast(has_executed) };
thrust::copy(thrust::device, begin, end, out);
bool has_executed_h = *has_executed;
thrust::device_free(has_executed);
ASSERT_EQUAL(has_executed_h, true);
}
void TestCopyWithBigIndexes()
{
TestCopyWithBigIndexesHelper(30);
TestCopyWithBigIndexesHelper(31);
TestCopyWithBigIndexesHelper(32);
TestCopyWithBigIndexesHelper(33);
}
DECLARE_UNITTEST(TestCopyWithBigIndexes);