/* Copyright (c) 2023 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. */ /* This testfile verifies the following scenarios of hipHostMalloc API 1. Basic scenario of hipHostMalloc API 2. Negative Scenarios of hipHostMalloc API 3. Allocating memory using hipHostMalloc with Coherent flag 4. Allocating memory using hipHostMalloc with NonCoherent flag 5. Allocating memory using hipHostMalloc with default flag */ #include #include #include #include #include #define SYNC_EVENT 0 #define SYNC_STREAM 1 #define SYNC_DEVICE 2 #define MEMORY_PERCENT 5 #define BLOCK_SIZE 512 #define VALUE 32 std::vector syncMsg = {"event", "stream", "device"}; static constexpr int numElements{1024 * 16}; static constexpr size_t sizeBytes{numElements * sizeof(int)}; #if HT_AMD static __global__ void kerTestMemAccess(char* buf) { size_t myId = threadIdx.x + blockDim.x * blockIdx.x; buf[myId] = VALUE; } #endif void CheckHostPointer(int numElements, int* ptr, unsigned eventFlags, int syncMethod, std::string msg) { std::cerr << "test: CheckHostPointer " << msg << " eventFlags = " << std::hex << eventFlags << ((eventFlags & hipEventReleaseToDevice) ? " hipEventReleaseToDevice" : "") << ((eventFlags & hipEventReleaseToSystem) ? " hipEventReleaseToSystem" : "") << " ptr=" << ptr << " syncMethod=" << syncMsg[syncMethod] << "\n"; hipStream_t s; hipEvent_t e; // Init: HIP_CHECK(hipStreamCreate(&s)); HIP_CHECK(hipEventCreateWithFlags(&e, eventFlags)) dim3 dimBlock(64, 1, 1); dim3 dimGrid(numElements / dimBlock.x, 1, 1); const int expected = 13; // Init array to know state: HipTest::launchKernel(Set, dimGrid, dimBlock, 0, 0x0, ptr, -42); HIP_CHECK(hipDeviceSynchronize()); HipTest::launchKernel(Set, dimGrid, dimBlock, 0, s, ptr, expected); HIP_CHECK(hipEventRecord(e, s)); // Host waits for event : switch (syncMethod) { case SYNC_EVENT: HIP_CHECK(hipEventSynchronize(e)); break; case SYNC_STREAM: HIP_CHECK(hipStreamSynchronize(s)); break; case SYNC_DEVICE: HIP_CHECK(hipDeviceSynchronize()); break; default: assert(0); } for (int i = 0; i < numElements; i++) { if (ptr[i] != expected) { printf("mismatch at %d: %d != %d\n", i, ptr[i], expected); REQUIRE(ptr[i] == expected); } } HIP_CHECK(hipStreamDestroy(s)); HIP_CHECK(hipEventDestroy(e)); } /* This testcase performs the basic scenario of hipHostMalloc API Allocates the memory using hipHostMalloc API Launches the kernel and performs vector addition. validates thes result. */ TEST_CASE("Unit_hipHostMalloc_Basic") { static constexpr auto LEN{1024 * 1024}; static constexpr auto SIZE{LEN * sizeof(float)}; hipDeviceProp_t prop; int device; HIP_CHECK(hipGetDevice(&device)); HIP_CHECK(hipGetDeviceProperties(&prop, device)); if (prop.canMapHostMemory != 1) { SUCCEED("Does support HostPinned Memory"); } else { float *A_h, *B_h, *C_h; float *A_d, *B_d, *C_d; unsigned int flag = 0; HIP_CHECK(hipHostMalloc(reinterpret_cast(&A_h), SIZE, hipHostMallocWriteCombined | hipHostMallocMapped)); SECTION("hipHostMallocDefault") { flag = hipHostMallocDefault; } #if (HT_AMD == 1) && (HT_LINUX == 1) if (!IsNavi4X()) { SECTION("hipHostMallocUncached") { flag = hipHostMallocUncached; } } SECTION("hipHostMallocCoherent") { flag = hipHostMallocCoherent; } SECTION("hipHostMallocNonCoherent") { flag = hipHostMallocNonCoherent; } #endif HIP_CHECK(hipHostMalloc(reinterpret_cast(&B_h), SIZE, flag)); HIP_CHECK(hipHostMalloc(reinterpret_cast(&C_h), SIZE, hipHostMallocMapped)); HIP_CHECK(hipHostGetDevicePointer(reinterpret_cast(&A_d), A_h, 0)); HIP_CHECK(hipHostGetDevicePointer(reinterpret_cast(&C_d), C_h, 0)); HipTest::setDefaultData(LEN, A_h, B_h, C_h); HIP_CHECK(hipMalloc(reinterpret_cast(&B_d), SIZE)); HIP_CHECK(hipMemcpy(B_d, B_h, SIZE, hipMemcpyHostToDevice)); dim3 dimGrid(LEN / 512, 1, 1); dim3 dimBlock(512, 1, 1); HipTest::launchKernel(HipTest::vectorADD, dimGrid, dimBlock, 0, 0, static_cast(A_d), static_cast(B_d), C_d, static_cast(LEN)); HIP_CHECK(hipMemcpy(C_h, C_d, LEN * sizeof(float), hipMemcpyDeviceToHost)); HIP_CHECK(hipDeviceSynchronize()); HipTest::checkVectorADD(A_h, B_h, C_h, numElements); HIP_CHECK(hipHostFree(A_h)); HIP_CHECK(hipHostFree(B_h)); HIP_CHECK(hipHostFree(C_h)); HIP_CHECK(hipFree(B_d)); } } /* This testcase verifies the hipHostMalloc API by passing nullptr to the pointer variable */ TEST_CASE("Unit_hipHostMalloc_Negative") { #if HT_AMD { // Stimulate error condition: int* A = nullptr; REQUIRE(hipHostMalloc(reinterpret_cast(&A), sizeBytes, hipHostMallocCoherent | hipHostMallocNonCoherent) != hipSuccess); REQUIRE(A == nullptr); } #endif } /* This testcase verifies the hipHostMalloc API by 1.Allocating memory using noncoherent flag 2. Launches the kernel and modifies the variable using different synchronization techniquies 3. validates the result. */ TEST_CASE("Unit_hipHostMalloc_NonCoherent") { int* A = nullptr; HIP_CHECK(hipHostMalloc(reinterpret_cast(&A), sizeBytes, hipHostMallocNonCoherent)); const char* ptrType = "non-coherent"; CheckHostPointer(numElements, A, hipEventReleaseToSystem, SYNC_DEVICE, ptrType); CheckHostPointer(numElements, A, hipEventReleaseToSystem, SYNC_STREAM, ptrType); CheckHostPointer(numElements, A, hipEventReleaseToSystem, SYNC_EVENT, ptrType); HIP_CHECK(hipFreeHost(A)); } /* This testcase verifies the hipHostMalloc API by 1.Allocating memory using coherent flag 2. Launches the kernel and modifies the variable using different synchronization techniquies 3. validates the result. */ TEST_CASE("Unit_hipHostMalloc_Coherent") { int* A = nullptr; if (hipHostMalloc(reinterpret_cast(&A), sizeBytes, hipHostMallocCoherent) == hipSuccess) { const char* ptrType = "coherent"; CheckHostPointer(numElements, A, hipEventReleaseToDevice, SYNC_DEVICE, ptrType); CheckHostPointer(numElements, A, hipEventReleaseToDevice, SYNC_STREAM, ptrType); CheckHostPointer(numElements, A, hipEventReleaseToDevice, SYNC_EVENT, ptrType); CheckHostPointer(numElements, A, hipEventReleaseToSystem, SYNC_DEVICE, ptrType); CheckHostPointer(numElements, A, hipEventReleaseToSystem, SYNC_STREAM, ptrType); CheckHostPointer(numElements, A, hipEventReleaseToSystem, SYNC_EVENT, ptrType); HIP_CHECK(hipFreeHost(A)); } else { SUCCEED("Coherence memory allocation failed. Is SVM atomic supported?"); } } /* This testcase verifies the hipHostMalloc API by 1.Allocating memory using default flag 2. Launches the kernel and modifies the variable using different synchronization techniquies 3. validates the result. */ TEST_CASE("Unit_hipHostMalloc_Default") { int* A = nullptr; HIP_CHECK(hipHostMalloc(reinterpret_cast(&A), sizeBytes)); const char* ptrType = "default"; CheckHostPointer(numElements, A, 0, SYNC_DEVICE, ptrType); CheckHostPointer(numElements, A, 0, SYNC_STREAM, ptrType); CheckHostPointer(numElements, A, 0, SYNC_EVENT, ptrType); HIP_CHECK(hipFreeHost(A)); } TEST_CASE("Unit_hipHostGetDevicePointer_NullCheck") { int* d_a; HIP_CHECK(hipHostMalloc(reinterpret_cast(&d_a), sizeof(int))); auto res = hipHostGetDevicePointer(nullptr, d_a, 0); REQUIRE(res == hipErrorInvalidValue); HIP_CHECK(hipHostFree(d_a)); } /* This testcase verifies the hipHostMalloc API by 1. Allocating more memory than total GPU memory. Should return hipSuccess. 2. Allocating more memory than the total GPU memory and accessing the memory in a device function. */ TEST_CASE("Unit_hipHostMalloc_AllocateMoreThanAvailGPUMemory") { char* A = nullptr; size_t maxGpuMem = 0, availableMem = 0; // Get available GPU memory and total GPU memory HIP_CHECK(hipMemGetInfo(&availableMem, &maxGpuMem)); #if defined(_WIN32) size_t allocsize = availableMem - (256 * 1024 * 1024); allocsize -= allocsize * (MEMORY_PERCENT / 100.0); #else size_t allocsize = maxGpuMem + ((maxGpuMem * MEMORY_PERCENT) / 100); #endif // Get free host In bytes size_t hostMemFree = HipTest::getMemoryAmount() * 1024 * 1024; // Ensure that allocsize < hostMemFree if (allocsize < hostMemFree) { HIP_CHECK(hipHostMalloc(reinterpret_cast(&A), allocsize)); HIP_CHECK(hipHostFree(A)); } else { WARN("Skipping test as CPU memory is less than GPU memory"); } } #if HT_AMD TEST_CASE("Unit_hipHostMalloc_AllocateUseMoreThanAvailGPUMemory") { char* A = nullptr; size_t maxGpuMem = 0, availableMem = 0; // Get available GPU memory and total GPU memory HIP_CHECK(hipMemGetInfo(&availableMem, &maxGpuMem)); #if defined(_WIN32) size_t allocsize = availableMem - (256 * 1024 * 1024); allocsize -= allocsize * (MEMORY_PERCENT / 100.0); #else size_t allocsize = maxGpuMem + ((maxGpuMem * MEMORY_PERCENT) / 100); #endif // Get free host In bytes size_t hostMemFree = HipTest::getMemoryAmount() * 1024 * 1024; // Ensure that allocsize < hostMemFree if (allocsize < hostMemFree) { HIP_CHECK(hipHostMalloc(reinterpret_cast(&A), allocsize)); constexpr int sample_size = 1024; // memset a sample size to 0 HIP_CHECK(hipMemset(A, 0, sample_size)); unsigned int grid_size = allocsize / BLOCK_SIZE; // Check if the allocated memory can be accessed in kernels kerTestMemAccess<<>>(A); HIP_CHECK(hipDeviceSynchronize()); HIP_CHECK(hipHostFree(A)); } else { WARN("Skipping test as CPU memory is less than GPU memory"); } } #endif TEST_CASE("Unit_hipHostMalloc_Capture") { int* host_ptr = nullptr; hipError_t capture_error = hipSuccess; constexpr bool kRelaxedModeAllowed = true; BEGIN_CAPTURE_SYNC(capture_error, kRelaxedModeAllowed); HIP_CHECK_ERROR(hipHostMalloc(reinterpret_cast(&host_ptr), sizeBytes), capture_error); END_CAPTURE_SYNC(capture_error); if (host_ptr != nullptr) { HIP_CHECK(hipHostFree(host_ptr)); } }