/* Copyright (c) 2022 Advanced Micro Devices, Inc. All rights reserved. Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #pragma once #pragma clang diagnostic ignored "-Wmissing-field-initializers" #pragma clang diagnostic ignored "-Wunused-lambda-capture" #pragma clang diagnostic ignored "-Wunused-parameter" #include #include #include #include #include using PtrVariant = std::variant; static inline hipMemcpyKind ReverseMemcpyDirection(const hipMemcpyKind direction) { switch (direction) { case hipMemcpyHostToDevice: return hipMemcpyDeviceToHost; case hipMemcpyDeviceToHost: return hipMemcpyHostToDevice; default: return direction; } }; static inline hipMemcpy3DParms GetMemcpy3DParms(PtrVariant dst_ptr, hipPos dst_pos, PtrVariant src_ptr, hipPos src_pos, hipExtent extent, hipMemcpyKind kind) { hipMemcpy3DParms parms = {0}; if (std::holds_alternative(dst_ptr)) { parms.dstArray = std::get(dst_ptr); } else { parms.dstPtr = std::get(dst_ptr); } parms.dstPos = dst_pos; if (std::holds_alternative(src_ptr)) { parms.srcArray = std::get(src_ptr); } else { parms.srcPtr = std::get(src_ptr); } parms.srcPos = src_pos; parms.extent = extent; parms.kind = kind; return parms; } static bool operator==(const hipPitchedPtr& lhs, const hipPitchedPtr& rhs) { // not checking for xsize currently as hipGraphMemcpyNodeGetParams returns incorrect value return lhs.ptr == rhs.ptr && lhs.pitch == rhs.pitch && lhs.ysize == rhs.ysize; } static bool operator==(const hipPos& lhs, const hipPos& rhs) { return lhs.x == rhs.x && lhs.y == rhs.y && lhs.z == rhs.z; } static bool operator==(const hipExtent& lhs, const hipExtent& rhs) { return lhs.width == rhs.width && lhs.height == rhs.height && lhs.depth == rhs.depth; } static inline bool operator==(const hipMemcpy3DParms& lhs, const hipMemcpy3DParms& rhs) { return lhs.dstArray == rhs.dstArray && lhs.dstPtr == rhs.dstPtr && lhs.dstPos == rhs.dstPos && lhs.srcArray == rhs.srcArray && lhs.srcPtr == rhs.srcPtr && lhs.srcPos == rhs.srcPos && lhs.extent == rhs.extent && lhs.kind == rhs.kind; } template hipError_t Memcpy3DWrapper(PtrVariant dst_ptr, hipPos dst_pos, PtrVariant src_ptr, hipPos src_pos, hipExtent extent, hipMemcpyKind kind, hipStream_t stream = nullptr) { auto parms = GetMemcpy3DParms(dst_ptr, dst_pos, src_ptr, src_pos, extent, kind); if constexpr (graph) { hipGraph_t g = nullptr; HIP_CHECK(hipGraphCreate(&g, 0)); hipGraphNode_t node = nullptr; if constexpr (set_params) { auto reversed_parms = GetMemcpy3DParms(src_ptr, src_pos, dst_ptr, dst_pos, extent, ReverseMemcpyDirection(kind)); HIP_CHECK(hipGraphAddMemcpyNode(&node, g, nullptr, 0, &reversed_parms)); HIP_CHECK(hipGraphMemcpyNodeSetParams(node, &parms)); } else { HIP_CHECK(hipGraphAddMemcpyNode(&node, g, nullptr, 0, &parms)); } hipMemcpy3DParms retrieved_params = {0}; HIP_CHECK(hipGraphMemcpyNodeGetParams(node, &retrieved_params)); REQUIRE(parms == retrieved_params); hipGraphExec_t graph_exec = nullptr; HIP_CHECK(hipGraphInstantiate(&graph_exec, g, nullptr, nullptr, 0)); HIP_CHECK(hipGraphLaunch(graph_exec, hipStreamPerThread)); HIP_CHECK(hipStreamSynchronize(hipStreamPerThread)); HIP_CHECK(hipGraphExecDestroy(graph_exec)); HIP_CHECK(hipGraphDestroy(g)); return hipSuccess; } if constexpr (async) { return hipMemcpy3DAsync(&parms, stream); } else { return hipMemcpy3D(&parms); } } template void Memcpy3DDeviceToHostShell(F memcpy_func, const hipStream_t kernel_stream = nullptr) { const auto kind = GENERATE(hipMemcpyDeviceToHost, hipMemcpyDefault); constexpr hipExtent extent{127 * sizeof(int), 128, 8}; LinearAllocGuard3D device_alloc(extent); const size_t host_pitch = GENERATE_REF(device_alloc.width(), device_alloc.width() + 64); LinearAllocGuard host_alloc(LinearAllocs::hipHostMalloc, host_pitch * device_alloc.height() * device_alloc.depth()); const dim3 threads_per_block(32, 32); const dim3 blocks(device_alloc.width_logical() / threads_per_block.x + 1, device_alloc.height() / threads_per_block.y + 1, device_alloc.depth()); Iota<<>>(device_alloc.ptr(), device_alloc.pitch(), device_alloc.width_logical(), device_alloc.height(), device_alloc.depth()); HIP_CHECK(hipGetLastError()); HIP_CHECK(hipDeviceSynchronize()); HIP_CHECK(memcpy_func( make_hipPitchedPtr(host_alloc.ptr(), host_pitch, device_alloc.width(), device_alloc.height()), make_hipPos(0, 0, 0), device_alloc.pitched_ptr(), make_hipPos(0, 0, 0), device_alloc.extent(), kind, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } const auto f = [extent](size_t x, size_t y, size_t z) { constexpr auto width_logical = extent.width / sizeof(int); return z * width_logical * extent.height + y * width_logical + x; }; PitchedMemoryVerify(host_alloc.ptr(), host_pitch, device_alloc.width_logical(), device_alloc.height(), device_alloc.depth(), f); } template void Memcpy3DDeviceToDeviceShell(F memcpy_func, hipStream_t kernel_stream = nullptr) { const auto kind = GENERATE(hipMemcpyDeviceToDevice, hipMemcpyDefault); constexpr hipExtent extent{127 * sizeof(int), 128, 8}; const auto device_count = HipTest::getDeviceCount(); const auto src_device = GENERATE_COPY(range(0, device_count)); const auto dst_device = GENERATE_COPY(range(0, device_count)); INFO("Src device: " << src_device << ", Dst device: " << dst_device); HIP_CHECK(hipSetDevice(src_device)); if (device_count > 0 && kernel_stream != nullptr && kernel_stream != hipStreamPerThread) { HIP_CHECK(hipStreamCreate(&kernel_stream)); } if constexpr (enable_peer_access) { if (src_device == dst_device) { if (device_count > 0 && kernel_stream != nullptr && kernel_stream != hipStreamPerThread) { HIP_CHECK(hipStreamDestroy(kernel_stream)); } return; } int can_access_peer = 0; HIP_CHECK(hipDeviceCanAccessPeer(&can_access_peer, src_device, dst_device)); if (!can_access_peer) { std::string msg = "Skipped as peer access cannot be enabled between devices " + std::to_string(src_device) + " " + std::to_string(dst_device); HipTest::HIP_SKIP_TEST(msg.c_str()); if (device_count > 0 && kernel_stream != nullptr && kernel_stream != hipStreamPerThread) { HIP_CHECK(hipStreamDestroy(kernel_stream)); } return; } HIP_CHECK(hipDeviceEnablePeerAccess(dst_device, 0)); } LinearAllocGuard3D src_alloc(extent); HIP_CHECK(hipSetDevice(dst_device)); LinearAllocGuard3D dst_alloc(extent); HIP_CHECK(hipSetDevice(src_device)); LinearAllocGuard host_alloc(LinearAllocs::hipHostMalloc, dst_alloc.width() * dst_alloc.height() * dst_alloc.depth()); const dim3 threads_per_block(32, 32); const dim3 blocks(dst_alloc.width_logical() / threads_per_block.x + 1, dst_alloc.height() / threads_per_block.y + 1, dst_alloc.depth()); // Using dst_alloc width and height to set only the elements that will be copied over to // dst_alloc Iota<<>>(src_alloc.ptr(), src_alloc.pitch(), dst_alloc.width_logical(), dst_alloc.height(), dst_alloc.depth()); HIP_CHECK(hipGetLastError()); HIP_CHECK(hipDeviceSynchronize()); HIP_CHECK(memcpy_func(dst_alloc.pitched_ptr(), make_hipPos(0, 0, 0), src_alloc.pitched_ptr(), make_hipPos(0, 0, 0), dst_alloc.extent(), kind, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } if (device_count > 0 && kernel_stream != nullptr && kernel_stream != hipStreamPerThread) { HIP_CHECK(hipStreamDestroy(kernel_stream)); } HIP_CHECK(Memcpy3DWrapper(make_hipPitchedPtr(host_alloc.ptr(), dst_alloc.width(), dst_alloc.width(), dst_alloc.height()), make_hipPos(0, 0, 0), dst_alloc.pitched_ptr(), make_hipPos(0, 0, 0), dst_alloc.extent(), hipMemcpyDeviceToHost)); const auto f = [extent](size_t x, size_t y, size_t z) { constexpr auto width_logical = extent.width / sizeof(int); return z * width_logical * extent.height + y * width_logical + x; }; PitchedMemoryVerify(host_alloc.ptr(), dst_alloc.width(), dst_alloc.width_logical(), dst_alloc.height(), dst_alloc.depth(), f); } template void Memcpy3DHostToDeviceShell(F memcpy_func, const hipStream_t kernel_stream = nullptr) { const auto kind = GENERATE(hipMemcpyHostToDevice, hipMemcpyDefault); constexpr hipExtent extent{127 * sizeof(int), 128, 8}; LinearAllocGuard3D device_alloc(extent); const size_t host_pitch = GENERATE_REF(device_alloc.pitch(), 2 * device_alloc.pitch()); LinearAllocGuard src_host_alloc(LinearAllocs::hipHostMalloc, host_pitch * device_alloc.height() * device_alloc.depth()); LinearAllocGuard dst_host_alloc( LinearAllocs::hipHostMalloc, device_alloc.width() * device_alloc.height() * device_alloc.depth()); const auto f = [extent](size_t x, size_t y, size_t z) { constexpr auto width_logical = extent.width / sizeof(int); return z * width_logical * extent.height + y * width_logical + x; }; PitchedMemorySet(src_host_alloc.ptr(), host_pitch, device_alloc.width_logical(), device_alloc.height(), device_alloc.depth(), f); std::fill_n(dst_host_alloc.ptr(), device_alloc.width_logical() * device_alloc.height() * device_alloc.depth(), 0); HIP_CHECK(memcpy_func(device_alloc.pitched_ptr(), make_hipPos(0, 0, 0), make_hipPitchedPtr(src_host_alloc.ptr(), host_pitch, device_alloc.width(), device_alloc.height()), make_hipPos(0, 0, 0), device_alloc.extent(), kind, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } HIP_CHECK(Memcpy3DWrapper(make_hipPitchedPtr(dst_host_alloc.ptr(), device_alloc.width(), device_alloc.width(), device_alloc.height()), make_hipPos(0, 0, 0), device_alloc.pitched_ptr(), make_hipPos(0, 0, 0), device_alloc.extent(), hipMemcpyDeviceToHost)); PitchedMemoryVerify(dst_host_alloc.ptr(), device_alloc.width(), device_alloc.width_logical(), device_alloc.height(), device_alloc.depth(), f); } template void Memcpy3DHostToHostShell(F memcpy_func, const hipStream_t kernel_stream = nullptr) { const auto kind = GENERATE(hipMemcpyHostToHost, hipMemcpyDefault); constexpr hipExtent extent{127 * sizeof(int), 128, 8}; const size_t padding = GENERATE_COPY(0, 64); const size_t src_pitch = extent.width + padding; LinearAllocGuard src_host(LinearAllocs::hipHostMalloc, src_pitch * extent.height * extent.depth); LinearAllocGuard dst_host(LinearAllocs::hipHostMalloc, extent.width * extent.height * extent.depth); const auto f = [extent](size_t x, size_t y, size_t z) { constexpr auto width_logical = extent.width / sizeof(int); return z * width_logical * extent.height + y * width_logical + x; }; PitchedMemorySet(src_host.ptr(), src_pitch, extent.width / sizeof(int), extent.height, extent.depth, f); HIP_CHECK( memcpy_func(make_hipPitchedPtr(dst_host.ptr(), extent.width, extent.width, extent.height), make_hipPos(0, 0, 0), make_hipPitchedPtr(src_host.ptr(), src_pitch, extent.width, extent.height), make_hipPos(0, 0, 0), extent, kind, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } PitchedMemoryVerify(dst_host.ptr(), extent.width, extent.width / sizeof(int), extent.height, extent.depth, f); } template void Memcpy3DArrayHostShell(F memcpy_func, const hipStream_t kernel_stream = nullptr) { constexpr hipExtent extent{127, 128, 8}; LinearAllocGuard src_host(LinearAllocs::hipHostMalloc, extent.width * sizeof(int) * extent.height * extent.depth); LinearAllocGuard dst_host(LinearAllocs::hipHostMalloc, extent.width * sizeof(int) * extent.height * extent.depth); ArrayAllocGuard src_array(extent); ArrayAllocGuard dst_array(extent); const auto f = [extent](size_t x, size_t y, size_t z) { return z * extent.width * extent.height + y * extent.width + x; }; PitchedMemorySet(src_host.ptr(), extent.width * sizeof(int), extent.width, extent.height, extent.depth, f); // Host -> Array HIP_CHECK(memcpy_func(src_array.ptr(), make_hipPos(0, 0, 0), make_hipPitchedPtr(src_host.ptr(), extent.width * sizeof(int), extent.width * sizeof(int), extent.height), make_hipPos(0, 0, 0), extent, hipMemcpyHostToDevice, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } // Array -> Array HIP_CHECK(memcpy_func(dst_array.ptr(), make_hipPos(0, 0, 0), src_array.ptr(), make_hipPos(0, 0, 0), extent, hipMemcpyDeviceToDevice, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } // Array -> Host HIP_CHECK(memcpy_func(make_hipPitchedPtr(dst_host.ptr(), extent.width * sizeof(int), extent.width * sizeof(int), extent.height), make_hipPos(0, 0, 0), dst_array.ptr(), make_hipPos(0, 0, 0), extent, hipMemcpyDeviceToHost, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } PitchedMemoryVerify(dst_host.ptr(), extent.width * sizeof(int), extent.width, extent.height, extent.depth, f); } template void Memcpy3DArrayDeviceShell(F memcpy_func, const hipStream_t kernel_stream = nullptr) { constexpr hipExtent extent{127, 128, 8}; LinearAllocGuard host_alloc(LinearAllocs::hipHostMalloc, extent.width * sizeof(int) * extent.height * extent.depth); ArrayAllocGuard src_array(extent); ArrayAllocGuard dst_array(extent); LinearAllocGuard3D src_device(extent.width, extent.height, extent.depth); LinearAllocGuard3D dst_device(extent.width, extent.height, extent.depth); const dim3 threads_per_block(32, 32); const dim3 blocks(src_device.width_logical() / threads_per_block.x + 1, src_device.height() / threads_per_block.y + 1, src_device.depth()); Iota<<>>(src_device.ptr(), src_device.pitch(), src_device.width_logical(), src_device.height(), src_device.depth()); HIP_CHECK(hipGetLastError()); HIP_CHECK(hipDeviceSynchronize()); // Device -> Array HIP_CHECK(memcpy_func(src_array.ptr(), make_hipPos(0, 0, 0), src_device.pitched_ptr(), make_hipPos(0, 0, 0), extent, hipMemcpyDeviceToDevice, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } // Array -> Array HIP_CHECK(memcpy_func(dst_array.ptr(), make_hipPos(0, 0, 0), src_array.ptr(), make_hipPos(0, 0, 0), extent, hipMemcpyDeviceToDevice, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } // Array -> Device HIP_CHECK(memcpy_func(dst_device.pitched_ptr(), make_hipPos(0, 0, 0), dst_array.ptr(), make_hipPos(0, 0, 0), extent, hipMemcpyDeviceToDevice, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } // Device -> Host HIP_CHECK(memcpy_func(make_hipPitchedPtr(host_alloc.ptr(), extent.width * sizeof(int), extent.width * sizeof(int), extent.height), make_hipPos(0, 0, 0), dst_device.pitched_ptr(), make_hipPos(0, 0, 0), dst_device.extent(), hipMemcpyDeviceToHost, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } const auto f = [extent](size_t x, size_t y, size_t z) { return z * extent.width * extent.height + y * extent.width + x; }; PitchedMemoryVerify(host_alloc.ptr(), extent.width * sizeof(int), extent.width, extent.height, extent.depth, f); } template void Memcpy3DHtoDSyncBehavior(F memcpy_func, const bool should_sync, const hipStream_t kernel_stream = nullptr) { using LA = LinearAllocs; LinearAllocGuard3D device_alloc(make_hipExtent(32 * sizeof(int), 32, 8)); LinearAllocGuard host_alloc( LA::hipHostMalloc, device_alloc.width() * device_alloc.height() * device_alloc.depth()); MemcpySyncBehaviorCheck( std::bind(memcpy_func, device_alloc.pitched_ptr(), make_hipPos(0, 0, 0), make_hipPitchedPtr(host_alloc.ptr(), device_alloc.width(), device_alloc.width(), device_alloc.height()), make_hipPos(0, 0, 0), device_alloc.extent(), hipMemcpyHostToDevice, kernel_stream), should_sync, kernel_stream); } template void Memcpy3DDtoHPageableSyncBehavior(F memcpy_func, const bool should_sync, const hipStream_t kernel_stream = nullptr) { LinearAllocGuard3D device_alloc(make_hipExtent(32 * sizeof(int), 32, 8)); LinearAllocGuard host_alloc( LinearAllocs::malloc, device_alloc.width() * device_alloc.height() * device_alloc.depth()); MemcpySyncBehaviorCheck( std::bind(memcpy_func, make_hipPitchedPtr(host_alloc.ptr(), device_alloc.width(), device_alloc.width(), device_alloc.height()), make_hipPos(0, 0, 0), device_alloc.pitched_ptr(), make_hipPos(0, 0, 0), device_alloc.extent(), hipMemcpyDeviceToHost, kernel_stream), should_sync, kernel_stream); } template void Memcpy3DDtoHPinnedSyncBehavior(F memcpy_func, const bool should_sync, const hipStream_t kernel_stream = nullptr) { LinearAllocGuard3D device_alloc(make_hipExtent(32 * sizeof(int), 32, 8)); LinearAllocGuard host_alloc( LinearAllocs::hipHostMalloc, device_alloc.width() * device_alloc.height() * device_alloc.depth()); MemcpySyncBehaviorCheck( std::bind(memcpy_func, make_hipPitchedPtr(host_alloc.ptr(), device_alloc.width(), device_alloc.width(), device_alloc.height()), make_hipPos(0, 0, 0), device_alloc.pitched_ptr(), make_hipPos(0, 0, 0), device_alloc.extent(), hipMemcpyDeviceToHost, kernel_stream), should_sync, kernel_stream); } template void Memcpy3DDtoDSyncBehavior(F memcpy_func, const bool should_sync, const hipStream_t kernel_stream = nullptr) { LinearAllocGuard3D src_alloc(make_hipExtent(32 * sizeof(int), 32, 8)); LinearAllocGuard3D dst_alloc(make_hipExtent(32 * sizeof(int), 32, 8)); MemcpySyncBehaviorCheck( std::bind(memcpy_func, dst_alloc.pitched_ptr(), make_hipPos(0, 0, 0), src_alloc.pitched_ptr(), make_hipPos(0, 0, 0), dst_alloc.extent(), hipMemcpyDeviceToDevice, kernel_stream), should_sync, kernel_stream); } template void Memcpy3DHtoHSyncBehavior(F memcpy_func, const bool should_sync, const hipStream_t kernel_stream = nullptr) { using LA = LinearAllocs; const auto src_alloc_type = GENERATE(LA::malloc, LA::hipHostMalloc); const auto dst_alloc_type = GENERATE(LA::malloc, LA::hipHostMalloc); LinearAllocGuard src_alloc(src_alloc_type, 32 * sizeof(int) * 32 * 8); LinearAllocGuard dst_alloc(dst_alloc_type, 32 * sizeof(int) * 32 * 8); MemcpySyncBehaviorCheck( std::bind(memcpy_func, make_hipPitchedPtr(dst_alloc.ptr(), 32 * sizeof(int), 32 * sizeof(int), 32), make_hipPos(0, 0, 0), make_hipPitchedPtr(src_alloc.ptr(), 32 * sizeof(int), 32 * sizeof(int), 32), make_hipPos(0, 0, 0), make_hipExtent(32 * sizeof(int), 32, 8), hipMemcpyHostToHost, kernel_stream), should_sync, kernel_stream); } template void Memcpy3DZeroWidthHeightDepth(F memcpy_func, const hipStream_t stream = nullptr) { constexpr hipExtent extent{127 * sizeof(int), 128, 8}; const auto [width_mult, height_mult, depth_mult] = GENERATE(std::make_tuple(0, 1, 1), std::make_tuple(1, 0, 1), std::make_tuple(1, 1, 0)); SECTION("Device to Host") { LinearAllocGuard3D device_alloc(extent); LinearAllocGuard host_alloc( LinearAllocs::hipHostMalloc, device_alloc.width() * device_alloc.height() * device_alloc.depth()); std::fill_n(host_alloc.ptr(), device_alloc.width_logical() * device_alloc.height() * device_alloc.depth(), 42); HIP_CHECK(hipMemset3D(device_alloc.pitched_ptr(), 1, device_alloc.extent())); HIP_CHECK(memcpy_func( make_hipPitchedPtr(host_alloc.ptr(), device_alloc.width(), device_alloc.width(), device_alloc.height()), make_hipPos(0, 0, 0), device_alloc.pitched_ptr(), make_hipPos(0, 0, 0), make_hipExtent(device_alloc.width() * width_mult, device_alloc.height() * height_mult, device_alloc.depth() * depth_mult), hipMemcpyDeviceToHost, stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(stream)); } ArrayFindIfNot(host_alloc.ptr(), static_cast(42), device_alloc.width_logical() * device_alloc.height() * device_alloc.depth()); } SECTION("Device to Device") { LinearAllocGuard3D src_alloc(extent); LinearAllocGuard3D dst_alloc(extent); LinearAllocGuard host_alloc( LinearAllocs::hipHostMalloc, dst_alloc.width() * dst_alloc.height() * dst_alloc.depth()); HIP_CHECK(hipMemset3D(src_alloc.pitched_ptr(), 1, src_alloc.extent())); HIP_CHECK(hipMemset3D(dst_alloc.pitched_ptr(), 42, dst_alloc.extent())); HIP_CHECK( memcpy_func(dst_alloc.pitched_ptr(), make_hipPos(0, 0, 0), src_alloc.pitched_ptr(), make_hipPos(0, 0, 0), make_hipExtent(dst_alloc.width() * width_mult, dst_alloc.height() * height_mult, dst_alloc.depth() * depth_mult), hipMemcpyDeviceToDevice, stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(stream)); } HIP_CHECK(Memcpy3DWrapper(make_hipPitchedPtr(host_alloc.ptr(), dst_alloc.width(), dst_alloc.width(), dst_alloc.height()), make_hipPos(0, 0, 0), dst_alloc.pitched_ptr(), make_hipPos(0, 0, 0), dst_alloc.extent(), hipMemcpyDeviceToHost)); ArrayFindIfNot(host_alloc.ptr(), static_cast(42), dst_alloc.width_logical() * dst_alloc.height()); } SECTION("Host to Device") { LinearAllocGuard3D device_alloc(extent); LinearAllocGuard src_host_alloc( LinearAllocs::hipHostMalloc, device_alloc.width() * device_alloc.height() * device_alloc.depth()); LinearAllocGuard dst_host_alloc( LinearAllocs::hipHostMalloc, device_alloc.width() * device_alloc.height() * device_alloc.depth()); std::fill_n(src_host_alloc.ptr(), device_alloc.width_logical() * device_alloc.height() * device_alloc.depth(), 1); HIP_CHECK(hipMemset3D(device_alloc.pitched_ptr(), 42, device_alloc.extent())); HIP_CHECK(memcpy_func( device_alloc.pitched_ptr(), make_hipPos(0, 0, 0), make_hipPitchedPtr(src_host_alloc.ptr(), device_alloc.width(), device_alloc.width(), device_alloc.height()), make_hipPos(0, 0, 0), make_hipExtent(device_alloc.width() * width_mult, device_alloc.height() * height_mult, device_alloc.depth() * depth_mult), hipMemcpyHostToDevice, stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(stream)); } HIP_CHECK(Memcpy3DWrapper(make_hipPitchedPtr(dst_host_alloc.ptr(), device_alloc.width(), device_alloc.width(), device_alloc.height()), make_hipPos(0, 0, 0), device_alloc.pitched_ptr(), make_hipPos(0, 0, 0), device_alloc.extent(), hipMemcpyDeviceToHost)); ArrayFindIfNot(dst_host_alloc.ptr(), static_cast(42), device_alloc.width_logical() * device_alloc.height()); } SECTION("Host to Host") { const auto alloc_size = extent.width * extent.height * extent.depth; LinearAllocGuard src_alloc(LinearAllocs::hipHostMalloc, alloc_size); LinearAllocGuard dst_alloc(LinearAllocs::hipHostMalloc, alloc_size); std::fill_n(src_alloc.ptr(), alloc_size, 1); std::fill_n(dst_alloc.ptr(), alloc_size, 42); HIP_CHECK( memcpy_func(make_hipPitchedPtr(dst_alloc.ptr(), extent.width, extent.width, extent.height), make_hipPos(0, 0, 0), make_hipPitchedPtr(src_alloc.ptr(), extent.width, extent.width, extent.height), make_hipPos(0, 0, 0), make_hipExtent(extent.width * width_mult, extent.height * height_mult, extent.depth * depth_mult), hipMemcpyHostToHost, stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(stream)); } ArrayFindIfNot(dst_alloc.ptr(), static_cast(42), alloc_size); } } constexpr auto MemTypeHost() { #if HT_AMD return hipMemoryTypeHost; #else return CU_MEMORYTYPE_HOST; #endif } constexpr auto MemTypeDevice() { #if HT_AMD return hipMemoryTypeDevice; #else return CU_MEMORYTYPE_DEVICE; #endif } constexpr auto MemTypeArray() { #if HT_AMD return hipMemoryTypeArray; #else return CU_MEMORYTYPE_ARRAY; #endif } constexpr auto MemTypeUnified() { #if HT_AMD return hipMemoryTypeUnified; #else return CU_MEMORYTYPE_UNIFIED; #endif } using DrvPtrVariant = std::variant; static inline HIP_MEMCPY3D GetDrvMemcpy3DParms(DrvPtrVariant dst_ptr, hipPos dst_pos, DrvPtrVariant src_ptr, hipPos src_pos, hipExtent extent, hipMemcpyKind kind) { HIP_MEMCPY3D parms = {0}; if (std::holds_alternative(dst_ptr)) { parms.dstMemoryType = hipMemoryTypeArray; parms.dstArray = std::get(dst_ptr); } else { auto ptr = std::get(dst_ptr); parms.dstPitch = ptr.pitch; switch (kind) { case hipMemcpyDeviceToHost: case hipMemcpyHostToHost: parms.dstMemoryType = hipMemoryTypeHost; parms.dstHost = ptr.ptr; break; case hipMemcpyDeviceToDevice: case hipMemcpyHostToDevice: parms.dstMemoryType = hipMemoryTypeDevice; parms.dstDevice = reinterpret_cast(ptr.ptr); break; case hipMemcpyDefault: parms.dstMemoryType = hipMemoryTypeUnified; parms.dstDevice = reinterpret_cast(ptr.ptr); break; default: assert(false); } } if (std::holds_alternative(src_ptr)) { parms.srcMemoryType = hipMemoryTypeArray; parms.srcArray = std::get(src_ptr); } else { auto ptr = std::get(src_ptr); parms.srcPitch = ptr.pitch; switch (kind) { case hipMemcpyDeviceToHost: case hipMemcpyDeviceToDevice: parms.srcMemoryType = hipMemoryTypeDevice; parms.srcDevice = reinterpret_cast(ptr.ptr); break; case hipMemcpyHostToDevice: case hipMemcpyHostToHost: parms.srcMemoryType = hipMemoryTypeHost; parms.srcHost = ptr.ptr; break; case hipMemcpyDefault: parms.srcMemoryType = hipMemoryTypeUnified; parms.srcDevice = reinterpret_cast(ptr.ptr); break; default: assert(false); } } parms.WidthInBytes = extent.width; parms.Height = extent.height; parms.Depth = extent.depth; parms.srcXInBytes = src_pos.x; parms.srcY = src_pos.y; parms.srcZ = src_pos.z; parms.dstXInBytes = dst_pos.x; parms.dstY = dst_pos.y; parms.dstZ = dst_pos.z; return parms; } static inline bool operator==(const HIP_MEMCPY3D& lhs, const HIP_MEMCPY3D& rhs) { bool pos_eq = lhs.dstXInBytes == rhs.dstXInBytes && lhs.dstY == rhs.dstY && lhs.dstZ == rhs.dstZ && lhs.srcXInBytes == rhs.srcXInBytes && lhs.srcY == rhs.srcY && lhs.srcZ == rhs.srcZ; bool extent_eq = lhs.WidthInBytes == rhs.WidthInBytes && lhs.Height == rhs.Height && lhs.Depth == rhs.Depth; bool mem_eq = true; if (lhs.dstArray) { mem_eq = lhs.dstArray == rhs.dstArray && lhs.dstMemoryType == rhs.dstMemoryType; } else { mem_eq = lhs.dstPitch == rhs.dstPitch && lhs.dstMemoryType == rhs.dstMemoryType; } if (lhs.srcArray) { mem_eq = lhs.srcArray == rhs.srcArray && lhs.srcMemoryType == rhs.srcMemoryType; } else { mem_eq = lhs.srcPitch == rhs.srcPitch && lhs.srcMemoryType == rhs.srcMemoryType; } if (lhs.dstDevice) { mem_eq = mem_eq && (lhs.dstDevice == rhs.dstDevice); } if (lhs.dstHost) { mem_eq = mem_eq && (lhs.dstDevice == rhs.dstDevice); } if (lhs.srcDevice) { mem_eq = mem_eq && (lhs.srcDevice == rhs.srcDevice); } if (lhs.srcHost) { mem_eq = mem_eq && (lhs.srcHost == rhs.srcHost); } return pos_eq && extent_eq && mem_eq; } template hipError_t DrvMemcpy3DGraphWrapper(DrvPtrVariant dst_ptr, hipPos dst_pos, DrvPtrVariant src_ptr, hipPos src_pos, hipExtent extent, hipMemcpyKind kind, hipCtx_t context, hipStream_t stream = nullptr) { auto parms = GetDrvMemcpy3DParms(dst_ptr, dst_pos, src_ptr, src_pos, extent, kind); hipGraph_t g = nullptr; HIP_CHECK(hipGraphCreate(&g, 0)); hipGraphNode_t node = nullptr; if constexpr (set_params) { auto reversed_parms = GetDrvMemcpy3DParms(src_ptr, src_pos, dst_ptr, dst_pos, extent, ReverseMemcpyDirection(kind)); HIP_CHECK(hipDrvGraphAddMemcpyNode(&node, g, nullptr, 0, &reversed_parms, context)); HIP_CHECK(hipDrvGraphMemcpyNodeSetParams(node, &parms)); } else { HIP_CHECK(hipDrvGraphAddMemcpyNode(&node, g, nullptr, 0, &parms, context)); } HIP_MEMCPY3D retrieved_params = {0}; HIP_CHECK(hipDrvGraphMemcpyNodeGetParams(node, &retrieved_params)); REQUIRE(parms == retrieved_params); hipGraphExec_t graph_exec = nullptr; HIP_CHECK(hipGraphInstantiate(&graph_exec, g, nullptr, nullptr, 0)); HIP_CHECK(hipGraphLaunch(graph_exec, hipStreamPerThread)); HIP_CHECK(hipStreamSynchronize(hipStreamPerThread)); HIP_CHECK(hipGraphExecDestroy(graph_exec)); HIP_CHECK(hipGraphDestroy(g)); return hipSuccess; } template hipError_t DrvMemcpy3DWrapper(DrvPtrVariant dst_ptr, hipPos dst_pos, DrvPtrVariant src_ptr, hipPos src_pos, hipExtent extent, hipMemcpyKind kind, hipStream_t stream = nullptr) { auto parms = GetDrvMemcpy3DParms(dst_ptr, dst_pos, src_ptr, src_pos, extent, kind); if constexpr (async) { return hipDrvMemcpy3DAsync(&parms, stream); } else { return hipDrvMemcpy3D(&parms); } } template void DrvMemcpy3DArrayHostShell(F memcpy_func, const hipStream_t kernel_stream = nullptr) { constexpr hipExtent extent{127 * sizeof(int), 128, 8}; LinearAllocGuard src_host(LinearAllocs::hipHostMalloc, extent.width * extent.height * extent.depth); LinearAllocGuard dst_host(LinearAllocs::hipHostMalloc, extent.width * extent.height * extent.depth); DrvArrayAllocGuard src_array(extent); DrvArrayAllocGuard dst_array(extent); const auto f = [extent](size_t x, size_t y, size_t z) { constexpr auto width_logical = extent.width / sizeof(int); return z * width_logical * extent.height + y * width_logical + x; }; PitchedMemorySet(src_host.ptr(), extent.width, extent.width / sizeof(int), extent.height, extent.depth, f); // Host -> Array HIP_CHECK( memcpy_func(src_array.ptr(), make_hipPos(0, 0, 0), make_hipPitchedPtr(src_host.ptr(), extent.width, extent.width, extent.height), make_hipPos(0, 0, 0), extent, hipMemcpyHostToDevice, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } // Array -> Array HIP_CHECK(memcpy_func(dst_array.ptr(), make_hipPos(0, 0, 0), src_array.ptr(), make_hipPos(0, 0, 0), extent, hipMemcpyDeviceToDevice, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } // Array -> Host HIP_CHECK( memcpy_func(make_hipPitchedPtr(dst_host.ptr(), extent.width, extent.width, extent.height), make_hipPos(0, 0, 0), dst_array.ptr(), make_hipPos(0, 0, 0), extent, hipMemcpyDeviceToHost, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } PitchedMemoryVerify(dst_host.ptr(), extent.width, extent.width / sizeof(int), extent.height, extent.depth, f); } template void DrvMemcpy3DArrayDeviceShell(F memcpy_func, const hipStream_t kernel_stream = nullptr) { constexpr hipExtent extent{127 * sizeof(int), 128, 8}; LinearAllocGuard host_alloc(LinearAllocs::hipHostMalloc, extent.width * extent.height * extent.depth); DrvArrayAllocGuard src_array(extent); DrvArrayAllocGuard dst_array(extent); LinearAllocGuard3D src_device(extent); LinearAllocGuard3D dst_device(extent); const dim3 threads_per_block(32, 32); const dim3 blocks(src_device.width_logical() / threads_per_block.x + 1, src_device.height() / threads_per_block.y + 1, src_device.depth()); Iota<<>>(src_device.ptr(), src_device.pitch(), src_device.width_logical(), src_device.height(), src_device.depth()); HIP_CHECK(hipGetLastError()); HIP_CHECK(hipDeviceSynchronize()); // Device -> Array HIP_CHECK(memcpy_func(src_array.ptr(), make_hipPos(0, 0, 0), src_device.pitched_ptr(), make_hipPos(0, 0, 0), extent, hipMemcpyDeviceToDevice, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } // Array -> Array HIP_CHECK(memcpy_func(dst_array.ptr(), make_hipPos(0, 0, 0), src_array.ptr(), make_hipPos(0, 0, 0), extent, hipMemcpyDeviceToDevice, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } // Array -> Device HIP_CHECK(memcpy_func(dst_device.pitched_ptr(), make_hipPos(0, 0, 0), dst_array.ptr(), make_hipPos(0, 0, 0), extent, hipMemcpyDeviceToDevice, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } HIP_CHECK( memcpy_func(make_hipPitchedPtr(host_alloc.ptr(), extent.width, extent.width, extent.height), make_hipPos(0, 0, 0), dst_device.pitched_ptr(), make_hipPos(0, 0, 0), dst_device.extent(), hipMemcpyDeviceToHost, kernel_stream)); if constexpr (should_synchronize) { HIP_CHECK(hipStreamSynchronize(kernel_stream)); } const auto f = [extent](size_t x, size_t y, size_t z) { constexpr auto width_logical = extent.width / sizeof(int); return z * width_logical * extent.height + y * width_logical + x; }; PitchedMemoryVerify(host_alloc.ptr(), extent.width, extent.width / sizeof(int), extent.height, extent.depth, f); }