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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. */ #include #include /* * These testcases verify that synchronous memset functions are asynchronous with respect to the * host except when the target is pinned host memory or a Unified Memory region */ // value used for memset operations constexpr int testValue = 0x11; enum class allocType { deviceMalloc, hostMalloc, hostRegisted, devRegistered }; enum class memSetType { hipMemset, hipMemsetD8, hipMemsetD16, hipMemsetD32, hipMemset2D, hipMemset3D }; // helper struct containing vars needed for 2D and 3D memset Testing struct MultiDData { size_t width{}; // set to 0 for 1D size_t height{}; // set to 0 for 2D size_t depth{}; size_t pitch{}; }; // set of helper functions to tidy the nested switch statements template static std::pair deviceMallocHelper(memSetType memType, size_t dataW, size_t dataH, size_t dataD, size_t& dataPitch) { size_t elementSize = sizeof(T); size_t sizeInBytes = elementSize * dataW * dataH * dataD; T* aPtr{}; switch (memType) { case memSetType::hipMemset3D: { hipPitchedPtr pitchedAPtr{}; hipExtent extent; extent.width = dataW * elementSize; extent.height = dataH; extent.depth = dataD; pitchedAPtr = make_hipPitchedPtr(aPtr, extent.width, extent.width / elementSize, extent.height); HIP_CHECK(hipMalloc3D(&pitchedAPtr, extent)); aPtr = reinterpret_cast(pitchedAPtr.ptr); dataPitch = pitchedAPtr.pitch; break; } case memSetType::hipMemset2D: HIP_CHECK( hipMallocPitch(reinterpret_cast(&aPtr), &dataPitch, dataW * elementSize, dataH)); dataPitch = dataW * elementSize; break; default: HIP_CHECK(hipMalloc(&aPtr, sizeInBytes)); dataPitch = dataW * elementSize; break; } return std::make_pair(aPtr, nullptr); } template static std::pair hostMallocHelper(size_t dataW, size_t dataH, size_t dataD, size_t& dataPitch) { size_t elementSize = sizeof(T); size_t sizeInBytes = elementSize * dataW * dataH * dataD; T* aPtr; HIP_CHECK(hipHostMalloc(&aPtr, sizeInBytes)); dataPitch = dataW * elementSize; return std::make_pair(aPtr, nullptr); } template static std::pair hostRegisteredHelper(size_t dataW, size_t dataH, size_t dataD, size_t& dataPitch) { size_t elementSize = sizeof(T); size_t sizeInBytes = elementSize * dataW * dataH * dataD; T* aPtr = new T[dataW * dataH * dataD]; HIP_CHECK(hipHostRegister(aPtr, sizeInBytes, hipHostRegisterDefault)); dataPitch = dataW * elementSize; return std::make_pair(aPtr, nullptr); } template static std::pair devRegisteredHelper(size_t dataW, size_t dataH, size_t dataD, size_t& dataPitch) { size_t elementSize = sizeof(T); size_t sizeInBytes = elementSize * dataW * dataH * dataD; T* aPtr = new T[dataW * dataH * dataD]; T* retPtr; HIP_CHECK(hipHostRegister(aPtr, sizeInBytes, hipHostRegisterDefault)); HIP_CHECK(hipHostGetDevicePointer(reinterpret_cast(&retPtr), aPtr, 0)); dataPitch = dataW * elementSize; // keep the address of the host memory return std::make_pair(retPtr, aPtr); } // helper function to allocate memory and set it to a value. // retunr a pair of pointers due to the device registered allocation case, we need to keep track of // the pointer to host memory to be able to unregister and free it template static std::pair initMemory(allocType type, memSetType memType, MultiDData& data) { size_t dataH = data.height == 0 ? 1 : data.height; size_t dataD = data.depth == 0 ? 1 : data.depth; std::pair retPtr{}; // check different types of allocation switch (type) { case allocType::deviceMalloc: retPtr = deviceMallocHelper(memType, data.width, dataH, dataD, data.pitch); break; case allocType::hostMalloc: retPtr = hostMallocHelper(data.width, dataH, dataD, data.pitch); break; case allocType::hostRegisted: retPtr = hostRegisteredHelper(data.width, dataH, dataD, data.pitch); break; case allocType::devRegistered: retPtr = devRegisteredHelper(data.width, dataH, dataD, data.pitch); break; default: REQUIRE(false); break; } return retPtr; } // set of helper functions to tidy the nested switch statements template static void deviceMallocCopy(memSetType memType, T* aPtr, T* hostMem, size_t dataW, size_t dataH, size_t dataD, size_t& dataPitch) { size_t elementSize = sizeof(T); size_t sizeInBytes = elementSize * dataW * dataH * dataD; switch (memType) { case memSetType::hipMemset3D: { hipMemcpy3DParms params{}; params.kind = hipMemcpyDeviceToHost; params.srcPos = make_hipPos(0, 0, 0); params.srcPtr = make_hipPitchedPtr(aPtr, dataPitch, dataW, dataH); params.dstPos = make_hipPos(0, 0, 0); params.dstPtr = make_hipPitchedPtr(hostMem, dataPitch, dataW, dataH); hipExtent extent; extent.width = dataPitch; extent.height = dataH; extent.depth = dataD; params.extent = extent; HIP_CHECK(hipMemcpy3D(¶ms)); break; } case memSetType::hipMemset2D: HIP_CHECK(hipMemcpy2D(hostMem, dataW * elementSize, aPtr, dataPitch, dataW, dataH, hipMemcpyDeviceToHost)); break; default: HIP_CHECK(hipMemcpy(hostMem, aPtr, sizeInBytes, hipMemcpyDeviceToHost)); break; } } template static void hostCopy(memSetType memType, T* aPtr, T* hostMem, size_t dataW, size_t dataH, size_t dataD, size_t& dataPitch) { size_t elementSize = sizeof(T); size_t sizeInBytes = elementSize * dataW * dataH * dataD; hipMemcpy3DParms params{}; switch (memType) { case memSetType::hipMemset3D: { params.kind = hipMemcpyHostToHost; params.srcPos = make_hipPos(0, 0, 0); params.dstPos = make_hipPos(0, 0, 0); params.srcPtr = make_hipPitchedPtr(aPtr, dataPitch, dataW, dataH); params.dstPtr = make_hipPitchedPtr(hostMem, dataW, dataW, dataH); hipExtent extent; extent.width = dataW; extent.height = dataH; extent.depth = dataD; params.extent = extent; HIP_CHECK(hipMemcpy3D(¶ms)); break; } case memSetType::hipMemset2D: HIP_CHECK(hipMemcpy2D(hostMem, dataW * elementSize, aPtr, dataPitch, dataW, dataH, hipMemcpyHostToHost)); break; default: HIP_CHECK(hipMemcpy(hostMem, aPtr, sizeInBytes, hipMemcpyHostToHost)); break; } } template static void devRegisteredCopy(memSetType memType, T* aPtr, T* hostMem, size_t dataW, size_t dataH, size_t dataD, size_t& dataPitch) { size_t elementSize = sizeof(T); switch (memType) { case memSetType::hipMemset3D: { hipMemcpy3DParms params{}; params.kind = hipMemcpyHostToHost; params.srcPos = make_hipPos(0, 0, 0); params.dstPos = make_hipPos(0, 0, 0); params.srcPtr = make_hipPitchedPtr(aPtr, dataPitch, dataW, dataH); params.dstPtr = make_hipPitchedPtr(hostMem, dataW, dataW, dataH); hipExtent extent; extent.width = dataW; extent.height = dataH; extent.depth = dataD; params.extent = extent; HIP_CHECK(hipMemcpy3D(¶ms)); break; } case memSetType::hipMemset2D: HIP_CHECK(hipMemcpy2D(hostMem, dataW * elementSize, aPtr, dataPitch, dataW, dataH, hipMemcpyDeviceToHost)); break; default: { size_t sizeInBytes = elementSize * dataW * dataH * dataD; HIP_CHECK(hipMemcpy(hostMem, aPtr, sizeInBytes, hipMemcpyDeviceToHost)); break; } } } // Copies device data to host and checks that each element is equal to the // specified value template void verifyData(T* aPtr, size_t value, MultiDData& data, allocType type, memSetType memType) { auto dataH = data.height == 0 ? 1 : data.height; auto dataD = data.depth == 0 ? 1 : data.depth; std::unique_ptr hostPtr = std::make_unique(data.pitch * dataH * dataD / sizeof(T)); switch (type) { case allocType::deviceMalloc: deviceMallocCopy(memType, aPtr, hostPtr.get(), data.width, dataH, dataD, data.pitch); break; case allocType::devRegistered: devRegisteredCopy(memType, aPtr, hostPtr.get(), data.width, dataH, dataD, data.pitch); break; default: // host allocated or host registered memory hostCopy(memType, aPtr, hostPtr.get(), data.width, dataH, dataD, data.pitch); break; } size_t idx; bool allMatch = true; for (size_t k = 0; k < dataD; k++) { for (size_t j = 0; j < dataH; j++) { for (size_t i = 0; i < data.width; i++) { idx = data.pitch * dataH * k + data.pitch * j + i; allMatch = allMatch && static_cast(hostPtr.get()[idx]) == value; if (!allMatch) REQUIRE(false); } } } } // macro to allow reuse of functions for testing versions of hipMemset template void memsetCheck(T* aPtr, size_t value, memSetType memsetType, MultiDData& data, bool async = false, hipStream_t stream = nullptr) { size_t dataW = data.width; size_t dataH = data.height == 0 ? 1 : data.height; size_t dataD = data.depth == 0 ? 1 : data.depth; size_t count = dataW * dataH * dataD; switch (memsetType) { case memSetType::hipMemset: if (async) { HIP_CHECK(hipMemsetAsync(aPtr, value, count, stream)); } else { HIP_CHECK(hipMemset(aPtr, value, count)); } break; case memSetType::hipMemsetD8: if (async) { HIP_CHECK(hipMemsetD8Async(reinterpret_cast(aPtr), value, count, stream)); } else { HIP_CHECK(hipMemsetD8(reinterpret_cast(aPtr), value, count)); } break; case memSetType::hipMemsetD16: if (async) { HIP_CHECK(hipMemsetD16Async(reinterpret_cast(aPtr), value, count, stream)); } else { HIP_CHECK(hipMemsetD16(reinterpret_cast(aPtr), value, count)); } break; case memSetType::hipMemsetD32: if (async) { HIP_CHECK(hipMemsetD32Async(reinterpret_cast(aPtr), value, count, stream)); } else { HIP_CHECK(hipMemsetD32(reinterpret_cast(aPtr), value, count)); } break; case memSetType::hipMemset2D: if (async) { HIP_CHECK(hipMemset2DAsync(aPtr, data.pitch, value, data.width, data.height, stream)); } else { HIP_CHECK(hipMemset2D(aPtr, data.pitch, value, data.width, data.height)); } break; case memSetType::hipMemset3D: hipExtent extent; extent.width = data.width; extent.height = data.height; extent.depth = data.depth; if (async) { HIP_CHECK(hipMemset3DAsync(make_hipPitchedPtr(aPtr, data.pitch, data.width, data.height), value, extent, stream)); } else { HIP_CHECK(hipMemset3D(make_hipPitchedPtr(aPtr, data.pitch, data.width, data.height), value, extent)); } break; default: REQUIRE(false); break; } } template void freeStuff(T* aPtr, allocType type) { switch (type) { case allocType::deviceMalloc: HIP_CHECK(hipFree(aPtr)); break; case allocType::hostMalloc: HIP_CHECK(hipHostFree(aPtr)); break; case allocType::hostRegisted: HIP_CHECK(hipHostUnregister(aPtr)); delete[] aPtr; break; case allocType::devRegistered: HIP_CHECK(hipHostUnregister(aPtr)); delete[] aPtr; break; default: REQUIRE(false); break; } } // Helper function to run tests for hipMemset allocation types template void runTests(allocType type, memSetType memsetType, MultiDData data, hipStream_t stream) { bool async = GENERATE(true, false); CAPTURE(type, memsetType, data.width, data.height, data.depth, stream, async); std::pair aPtr = initMemory(type, memsetType, data); using namespace std::chrono_literals; const std::chrono::duration delay = 100ms; LaunchDelayKernel(delay, stream); memsetCheck(aPtr.first, testValue, memsetType, data, async, stream); if (async || type == allocType::deviceMalloc) { HIP_CHECK_ERROR(hipStreamQuery(stream), hipErrorNotReady); } else { HIP_CHECK(hipStreamQuery(stream)); } HIP_CHECK(hipStreamSynchronize(stream)); verifyData(aPtr.first, testValue, data, type, memsetType); if (type == allocType::devRegistered) { freeStuff(aPtr.second, type); } else { freeStuff(aPtr.first, type); } } template static void doMemsetTest(allocType mallocType, memSetType memset_type, MultiDData data) { enum StreamType { NULLSTR, CREATEDSTR }; auto streamType = GENERATE(NULLSTR, CREATEDSTR); hipStream_t stream{nullptr}; if (streamType == CREATEDSTR) HIP_CHECK(hipStreamCreate(&stream)); runTests(mallocType, memset_type, data, stream); if (streamType == CREATEDSTR) HIP_CHECK(hipStreamDestroy(stream)); } TEST_CASE("Unit_hipMemsetSync") { allocType type = GENERATE(allocType::deviceMalloc, allocType::hostMalloc, allocType::hostRegisted, allocType::devRegistered); memSetType memset_type = memSetType::hipMemset; MultiDData data; data.width = GENERATE(512, 1024); doMemsetTest(type, memset_type, data); } TEMPLATE_TEST_CASE("Unit_hipMemsetDSync", "", int8_t, int16_t, uint32_t) { allocType mallocType = GENERATE(allocType::hostRegisted, allocType::deviceMalloc, allocType::hostMalloc, allocType::devRegistered); memSetType memset_type; MultiDData data; data.width = GENERATE(512, 1024); if (std::is_same::value) { memset_type = memSetType::hipMemsetD8; } else if (std::is_same::value) { memset_type = memSetType::hipMemsetD16; } else if (std::is_same::value) { memset_type = memSetType::hipMemsetD32; } doMemsetTest(mallocType, memset_type, data); } TEST_CASE("Unit_hipMemset2DSync") { allocType mallocType = GENERATE(allocType::deviceMalloc, allocType::hostMalloc, allocType::hostRegisted, allocType::devRegistered); memSetType memset_type = memSetType::hipMemset2D; MultiDData data; data.width = GENERATE(512, 1024); data.height = GENERATE(512, 1024); doMemsetTest(mallocType, memset_type, data); } TEST_CASE("Unit_hipMemset3DSync") { allocType mallocType = GENERATE(allocType::deviceMalloc, allocType::hostMalloc, allocType::hostRegisted, allocType::devRegistered); memSetType memset_type = memSetType::hipMemset3D; MultiDData data; data.width = GENERATE(128, 256); data.height = GENERATE(128, 256); data.depth = GENERATE(128, 256); doMemsetTest(mallocType, memset_type, data); }