LIVE / thrust /testing /async_transform.cu
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#include <thrust/detail/config.h>
#if THRUST_CPP_DIALECT >= 2014
#include <unittest/unittest.h>
#include <unittest/util_async.h>
#include <thrust/async/transform.h>
#include <thrust/async/copy.h>
#include <thrust/host_vector.h>
#include <thrust/device_vector.h>
template <typename T>
struct divide_by_2
{
__host__ __device__
T operator()(T x) const
{
return x / 2;
}
};
#define DEFINE_STATEFUL_ASYNC_TRANSFORM_UNARY_INVOKER( \
NAME, MEMBERS, CTOR, DTOR, VALIDATE, ... \
) \
template <typename T> \
struct NAME \
{ \
MEMBERS \
\
NAME() { CTOR } \
\
~NAME() { DTOR } \
\
template <typename Event> \
void validate_event(Event& e) \
{ \
THRUST_UNUSED_VAR(e); \
VALIDATE \
} \
\
template < \
typename ForwardIt, typename Sentinel, typename OutputIt \
, typename UnaryOperation \
> \
__host__ \
auto operator()( \
ForwardIt&& first, Sentinel&& last, OutputIt&& output \
, UnaryOperation&& op \
) \
THRUST_DECLTYPE_RETURNS( \
::thrust::async::transform( \
__VA_ARGS__ \
) \
) \
}; \
/**/
#define DEFINE_ASYNC_TRANSFORM_UNARY_INVOKER(NAME, ...) \
DEFINE_STATEFUL_ASYNC_TRANSFORM_UNARY_INVOKER( \
NAME \
, THRUST_PP_EMPTY(), THRUST_PP_EMPTY(), THRUST_PP_EMPTY(), THRUST_PP_EMPTY()\
, __VA_ARGS__ \
) \
/**/
#define DEFINE_SYNC_TRANSFORM_UNARY_INVOKER(NAME, ...) \
template <typename T> \
struct NAME \
{ \
\
template < \
typename ForwardIt, typename Sentinel, typename OutputIt \
, typename UnaryOperation \
> \
__host__ \
auto operator()( \
ForwardIt&& first, Sentinel&& last, OutputIt&& output \
, UnaryOperation&& op \
) \
THRUST_RETURNS( \
::thrust::transform( \
__VA_ARGS__ \
) \
) \
}; \
/**/
DEFINE_ASYNC_TRANSFORM_UNARY_INVOKER(
transform_unary_async_invoker
, THRUST_FWD(first), THRUST_FWD(last)
, THRUST_FWD(output)
, THRUST_FWD(op)
);
DEFINE_ASYNC_TRANSFORM_UNARY_INVOKER(
transform_unary_async_invoker_device
, thrust::device
, THRUST_FWD(first), THRUST_FWD(last)
, THRUST_FWD(output)
, THRUST_FWD(op)
);
DEFINE_ASYNC_TRANSFORM_UNARY_INVOKER(
transform_unary_async_invoker_device_allocator
, thrust::device(thrust::device_allocator<void>{})
, THRUST_FWD(first), THRUST_FWD(last)
, THRUST_FWD(output)
, THRUST_FWD(op)
);
DEFINE_STATEFUL_ASYNC_TRANSFORM_UNARY_INVOKER(
transform_unary_async_invoker_device_on
// Members.
, cudaStream_t stream_;
// Constructor.
, thrust::cuda_cub::throw_on_error(
cudaStreamCreateWithFlags(&stream_, cudaStreamNonBlocking)
);
// Destructor.
, thrust::cuda_cub::throw_on_error(
cudaStreamDestroy(stream_)
);
// `validate_event` member.
, ASSERT_EQUAL_QUIET(stream_, e.stream().native_handle());
// Arguments to `thrust::async::transform`.
, thrust::device.on(stream_)
, THRUST_FWD(first), THRUST_FWD(last)
, THRUST_FWD(output)
, THRUST_FWD(op)
);
DEFINE_STATEFUL_ASYNC_TRANSFORM_UNARY_INVOKER(
transform_unary_async_invoker_device_allocator_on
// Members.
, cudaStream_t stream_;
// Constructor.
, thrust::cuda_cub::throw_on_error(
cudaStreamCreateWithFlags(&stream_, cudaStreamNonBlocking)
);
// Destructor.
, thrust::cuda_cub::throw_on_error(
cudaStreamDestroy(stream_)
);
// `validate_event` member.
, ASSERT_EQUAL_QUIET(stream_, e.stream().native_handle());
// Arguments to `thrust::async::transform`.
, thrust::device(thrust::device_allocator<void>{}).on(stream_)
, THRUST_FWD(first), THRUST_FWD(last)
, THRUST_FWD(output)
, THRUST_FWD(op)
);
DEFINE_SYNC_TRANSFORM_UNARY_INVOKER(
transform_unary_sync_invoker
, THRUST_FWD(first), THRUST_FWD(last)
, THRUST_FWD(output)
, THRUST_FWD(op)
);
///////////////////////////////////////////////////////////////////////////////
template <
template <typename> class AsyncTransformUnaryInvoker
, template <typename> class SyncTransformUnaryInvoker
, template <typename> class UnaryOperation
>
struct test_async_transform_unary
{
template <typename T>
struct tester
{
__host__
void operator()(std::size_t n)
{
thrust::host_vector<T> h0(unittest::random_integers<T>(n));
thrust::device_vector<T> d0a(h0);
thrust::device_vector<T> d0b(h0);
thrust::device_vector<T> d0c(h0);
thrust::device_vector<T> d0d(h0);
thrust::host_vector<T> h1(n);
thrust::device_vector<T> d1a(n);
thrust::device_vector<T> d1b(n);
thrust::device_vector<T> d1c(n);
thrust::device_vector<T> d1d(n);
AsyncTransformUnaryInvoker<T> invoke_async;
SyncTransformUnaryInvoker<T> invoke_sync;
UnaryOperation<T> op;
ASSERT_EQUAL(h0, d0a);
ASSERT_EQUAL(h0, d0b);
ASSERT_EQUAL(h0, d0c);
ASSERT_EQUAL(h0, d0d);
auto f0a = invoke_async(d0a.begin(), d0a.end(), d1a.begin(), op);
auto f0b = invoke_async(d0b.begin(), d0b.end(), d1b.begin(), op);
auto f0c = invoke_async(d0c.begin(), d0c.end(), d1c.begin(), op);
auto f0d = invoke_async(d0d.begin(), d0d.end(), d1d.begin(), op);
invoke_async.validate_event(f0a);
invoke_async.validate_event(f0b);
invoke_async.validate_event(f0c);
invoke_async.validate_event(f0d);
// This potentially runs concurrently with the copies.
invoke_sync(h0.begin(), h0.end(), h1.begin(), op);
TEST_EVENT_WAIT(thrust::when_all(f0a, f0b, f0c, f0d));
ASSERT_EQUAL(h0, d0a);
ASSERT_EQUAL(h0, d0b);
ASSERT_EQUAL(h0, d0c);
ASSERT_EQUAL(h0, d0d);
ASSERT_EQUAL(h1, d1a);
ASSERT_EQUAL(h1, d1b);
ASSERT_EQUAL(h1, d1c);
ASSERT_EQUAL(h1, d1d);
}
};
};
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary<
transform_unary_async_invoker
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, NumericTypes
, test_async_transform_unary_divide_by_2
);
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary<
transform_unary_async_invoker_device
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, NumericTypes
, test_async_transform_unary_policy_divide_by_2
);
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary<
transform_unary_async_invoker_device_allocator
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, NumericTypes
, test_async_transform_unary_policy_allocator_divide_by_2
);
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary<
transform_unary_async_invoker_device_on
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, NumericTypes
, test_async_transform_unary_policy_on_divide_by_2
);
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary<
transform_unary_async_invoker_device_allocator_on
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, NumericTypes
, test_async_transform_unary_policy_allocator_on_divide_by_2
);
///////////////////////////////////////////////////////////////////////////////
template <
template <typename> class AsyncTransformUnaryInvoker
, template <typename> class SyncTransformUnaryInvoker
, template <typename> class UnaryOperation
>
struct test_async_transform_unary_inplace
{
template <typename T>
struct tester
{
__host__
void operator()(std::size_t n)
{
thrust::host_vector<T> h0(unittest::random_integers<T>(n));
thrust::device_vector<T> d0a(h0);
thrust::device_vector<T> d0b(h0);
thrust::device_vector<T> d0c(h0);
thrust::device_vector<T> d0d(h0);
AsyncTransformUnaryInvoker<T> invoke_async;
SyncTransformUnaryInvoker<T> invoke_sync;
UnaryOperation<T> op;
ASSERT_EQUAL(h0, d0a);
ASSERT_EQUAL(h0, d0b);
ASSERT_EQUAL(h0, d0c);
ASSERT_EQUAL(h0, d0d);
auto f0a = invoke_async(d0a.begin(), d0a.end(), d0a.begin(), op);
auto f0b = invoke_async(d0b.begin(), d0b.end(), d0b.begin(), op);
auto f0c = invoke_async(d0c.begin(), d0c.end(), d0c.begin(), op);
auto f0d = invoke_async(d0d.begin(), d0d.end(), d0d.begin(), op);
invoke_async.validate_event(f0a);
invoke_async.validate_event(f0b);
invoke_async.validate_event(f0c);
invoke_async.validate_event(f0d);
// This potentially runs concurrently with the copies.
invoke_sync(h0.begin(), h0.end(), h0.begin(), op);
TEST_EVENT_WAIT(thrust::when_all(f0a, f0b, f0c, f0d));
ASSERT_EQUAL(h0, d0a);
ASSERT_EQUAL(h0, d0b);
ASSERT_EQUAL(h0, d0c);
ASSERT_EQUAL(h0, d0d);
}
};
};
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary_inplace<
transform_unary_async_invoker
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, NumericTypes
, test_async_transform_unary_inplace_divide_by_2
);
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary_inplace<
transform_unary_async_invoker_device
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, NumericTypes
, test_async_transform_unary_inplace_policy_divide_by_2
);
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary_inplace<
transform_unary_async_invoker_device_allocator
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, NumericTypes
, test_async_transform_unary_inplace_policy_allocator_divide_by_2
);
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary_inplace<
transform_unary_async_invoker_device_on
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, NumericTypes
, test_async_transform_unary_inplace_policy_on_divide_by_2
);
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary_inplace<
transform_unary_async_invoker_device_allocator_on
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, NumericTypes
, test_async_transform_unary_inplace_policy_allocator_on_divide_by_2
);
///////////////////////////////////////////////////////////////////////////////
template <
template <typename> class AsyncTransformUnaryInvoker
, template <typename> class SyncTransformUnaryInvoker
, template <typename> class UnaryOperation
>
struct test_async_transform_unary_counting_iterator
{
template <typename T>
struct tester
{
__host__
void operator()()
{
constexpr std::size_t n = 15 * sizeof(T);
ASSERT_LEQUAL(T(n), unittest::truncate_to_max_representable<T>(n));
thrust::counting_iterator<T> first(0);
thrust::counting_iterator<T> last(n);
thrust::host_vector<T> h0(n);
thrust::device_vector<T> d0a(n);
thrust::device_vector<T> d0b(n);
thrust::device_vector<T> d0c(n);
thrust::device_vector<T> d0d(n);
AsyncTransformUnaryInvoker<T> invoke_async;
SyncTransformUnaryInvoker<T> invoke_sync;
UnaryOperation<T> op;
auto f0a = invoke_async(first, last, d0a.begin(), op);
auto f0b = invoke_async(first, last, d0b.begin(), op);
auto f0c = invoke_async(first, last, d0c.begin(), op);
auto f0d = invoke_async(first, last, d0d.begin(), op);
invoke_async.validate_event(f0a);
invoke_async.validate_event(f0b);
invoke_async.validate_event(f0c);
invoke_async.validate_event(f0d);
// This potentially runs concurrently with the copies.
invoke_sync(first, last, h0.begin(), op);
TEST_EVENT_WAIT(thrust::when_all(f0a, f0b, f0c, f0d));
ASSERT_EQUAL(h0, d0a);
ASSERT_EQUAL(h0, d0b);
ASSERT_EQUAL(h0, d0c);
ASSERT_EQUAL(h0, d0d);
}
};
};
DECLARE_GENERIC_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary_counting_iterator<
transform_unary_async_invoker
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, BuiltinNumericTypes
, test_async_transform_unary_counting_iterator_divide_by_2
);
DECLARE_GENERIC_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND_ARGS(
test_async_transform_unary_counting_iterator<
transform_unary_async_invoker_device
, transform_unary_sync_invoker
, divide_by_2
>::tester
)
, BuiltinNumericTypes
, test_async_transform_unary_counting_iterator_policy_divide_by_2
);
///////////////////////////////////////////////////////////////////////////////
template <
template <typename> class UnaryOperation
>
struct test_async_transform_using
{
template <typename T>
struct tester
{
__host__
void operator()(std::size_t n)
{
thrust::host_vector<T> h0(unittest::random_integers<T>(n));
thrust::device_vector<T> d0a(h0);
thrust::device_vector<T> d0b(h0);
thrust::host_vector<T> h1(n);
thrust::device_vector<T> d1a(n);
thrust::device_vector<T> d1b(n);
UnaryOperation<T> op;
ASSERT_EQUAL(h0, d0a);
ASSERT_EQUAL(h0, d0b);
thrust::device_event f0a;
thrust::device_event f0b;
// When you import the customization points into the global namespace,
// they should be selected instead of the synchronous algorithms.
{
using namespace thrust::async;
f0a = transform(d0a.begin(), d0a.end(), d1a.begin(), op);
}
{
using thrust::async::transform;
f0b = transform(d0b.begin(), d0b.end(), d1b.begin(), op);
}
// ADL should find the synchronous algorithms.
// This potentially runs concurrently with the copies.
transform(h0.begin(), h0.end(), h1.begin(), op);
TEST_EVENT_WAIT(thrust::when_all(f0a, f0b));
ASSERT_EQUAL(h0, d0a);
ASSERT_EQUAL(h0, d0b);
ASSERT_EQUAL(h1, d1a);
ASSERT_EQUAL(h1, d1b);
}
};
};
DECLARE_GENERIC_SIZED_UNITTEST_WITH_TYPES_AND_NAME(
THRUST_PP_EXPAND(test_async_transform_using<divide_by_2>::tester)
, NumericTypes
, test_async_transform_using_divide_by_2
);
///////////////////////////////////////////////////////////////////////////////
#endif