/* 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 WARRANNTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNNESS 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 INN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR INN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /* Testcase Scenarios of hipGraphDestroyNode API: Negative :: 1) Pass nullptr to graph node Functional :: 1) Create Node and destroy the node 2) Create graph with dependencies and destroy one of the dependency node before executing the graph. 3) Create a graph with N nodes and (N-1) dependencies between them as shown below. Start destroying the nodes in iteration from left. In each iteration verify the number of nodes and dependencies using hipGraphGetNodes and hipGraphGetEdges. Node1-->Node2-->Node3->...................->NodeN 4) Create a graph with N nodes and (N-1) dependencies between them as shown above. Clone the graph. Start destroying the nodes in iteration from left in the cloned graph. In each iteration verify the number of nodes and dependencies using hipGraphGetNodes and hipGraphGetEdges. Once all nodes in the cloned graph are deleted, verify the number of nodes in the original graph are intact. 5) Create a graph1 with N nodes and (N-1) dependencies between them as shown above. Create another empty graph0. Add graph1 as child node to graph0. Delete the child node in graph0. Verify that the nodes in graph1 are still intact after deleting the child node using hipGraphGetNodes and hipGraphGetEdges. */ #include #include #include #define NUM_OF_DUMMY_NODES 8 static __global__ void dummyKernel() { return; } /* This test covers the negative scenarios of hipGraphDestroyNode API */ TEST_CASE("Unit_hipGraphDestroyNode_Negative") { SECTION("Passing nullptr to graph Node") { REQUIRE(hipGraphDestroyNode(nullptr) == hipErrorInvalidValue); } } /* This test covers the basic functionality of hipGraphDestroyNode API where we create and destroy the node */ TEST_CASE("Unit_hipGraphDestroyNode_BasicFunctionality") { char *pOutBuff_d{}; constexpr size_t size = 1024; hipGraph_t graph{}; hipGraphNode_t memsetNode{}; HIP_CHECK(hipMalloc(&pOutBuff_d, size)); hipMemsetParams memsetParams{}; memsetParams.dst = reinterpret_cast(pOutBuff_d); memsetParams.value = 0; memsetParams.pitch = 0; memsetParams.elementSize = sizeof(char); memsetParams.width = size * sizeof(char); memsetParams.height = 1; HIP_CHECK(hipGraphCreate(&graph, 0)); HIP_CHECK(hipGraphAddMemsetNode(&memsetNode, graph, nullptr, 0, &memsetParams)); REQUIRE(hipGraphDestroyNode(memsetNode) == hipSuccess); HIP_CHECK(hipFree(pOutBuff_d)); } /* This testcase verifies the following scenario where graph is created with dependencies and one of the dependency is destroyed before execute the graph */ TEST_CASE("Unit_hipGraphDestroyNode_DestroyDependencyNode") { constexpr size_t N = 1024; constexpr size_t Nbytes = N * sizeof(int); constexpr auto blocksPerCU = 6; // to hide latency constexpr auto threadsPerBlock = 256; hipGraph_t graph; hipGraphNode_t memcpyH2D_A, memcpyH2D_B, memcpyH2D_B2Copies, memcpyD2H_C; hipGraphNode_t kernel_vecAdd; hipKernelNodeParams kernelNodeParams{}; int *A_d, *B_d, *C_d; int *A_h, *B_h, *C_h; hipGraphExec_t graphExec; size_t NElem{N}; hipStream_t streamForGraph; HIP_CHECK(hipStreamCreate(&streamForGraph)); HipTest::initArrays(&A_d, &B_d, &C_d, &A_h, &B_h, &C_h, N, false); unsigned blocks = HipTest::setNumBlocks(blocksPerCU, threadsPerBlock, N); HIP_CHECK(hipGraphCreate(&graph, 0)); HIP_CHECK(hipGraphAddMemcpyNode1D(&memcpyH2D_A, graph, nullptr, 0, A_d, A_h, Nbytes, hipMemcpyHostToDevice)); HIP_CHECK(hipGraphAddMemcpyNode1D(&memcpyH2D_B, graph, nullptr, 0, B_d, B_h, Nbytes, hipMemcpyHostToDevice)); HIP_CHECK(hipGraphAddMemcpyNode1D(&memcpyH2D_B2Copies, graph, nullptr, 0, B_d, C_h, Nbytes, hipMemcpyHostToDevice)); HIP_CHECK(hipGraphAddMemcpyNode1D(&memcpyD2H_C, graph, nullptr, 0, B_h, C_d, Nbytes, hipMemcpyDeviceToHost)); void* kernelArgs2[] = {&A_d, &B_d, &C_d, reinterpret_cast(&NElem)}; kernelNodeParams.func = reinterpret_cast(HipTest::vectorADD); kernelNodeParams.gridDim = dim3(blocks); kernelNodeParams.blockDim = dim3(threadsPerBlock); kernelNodeParams.sharedMemBytes = 0; kernelNodeParams.kernelParams = reinterpret_cast(kernelArgs2); kernelNodeParams.extra = nullptr; HIP_CHECK(hipGraphAddKernelNode(&kernel_vecAdd, graph, nullptr, 0, &kernelNodeParams)); // Create dependencies HIP_CHECK(hipGraphAddDependencies(graph, &memcpyH2D_A, &kernel_vecAdd, 1)); HIP_CHECK(hipGraphAddDependencies(graph, &memcpyH2D_B, &kernel_vecAdd, 1)); HIP_CHECK(hipGraphAddDependencies(graph, &memcpyH2D_B2Copies, &kernel_vecAdd, 1)); HIP_CHECK(hipGraphAddDependencies(graph, &kernel_vecAdd, &memcpyD2H_C, 1)); // Destroy one of the dependency node HIP_CHECK(hipGraphDestroyNode(memcpyH2D_B)); // Instantiate and launch the graph HIP_CHECK(hipGraphInstantiate(&graphExec, graph, nullptr, nullptr, 0)); HIP_CHECK(hipGraphLaunch(graphExec, streamForGraph)); HIP_CHECK(hipStreamSynchronize(streamForGraph)); // Verify graph execution result HipTest::checkVectorADD(A_h, C_h, B_h, N); HipTest::freeArrays(A_d, B_d, C_d, A_h, B_h, C_h, false); HIP_CHECK(hipGraphExecDestroy(graphExec)); HIP_CHECK(hipStreamDestroy(streamForGraph)); HIP_CHECK(hipGraphDestroy(graph)); } /** * Functional Test to test hipGraphDestroyNode using hipGraphGetNodes * and hipGraphGetEdges APIs. */ TEST_CASE("Unit_hipGraphDestroyNode_Complx_ChkNumOfNodesNDep") { hipGraph_t graph; hipGraphNode_t kernelnode[NUM_OF_DUMMY_NODES]; hipKernelNodeParams kernelNodeParams[NUM_OF_DUMMY_NODES]; HIP_CHECK(hipGraphCreate(&graph, 0)); // Create graph with no dependencies for (int i = 0; i < NUM_OF_DUMMY_NODES; i++) { void* kernelArgs[] = {nullptr}; kernelNodeParams[i].func = reinterpret_cast(dummyKernel); kernelNodeParams[i].gridDim = dim3(1); kernelNodeParams[i].blockDim = dim3(1); kernelNodeParams[i].sharedMemBytes = 0; kernelNodeParams[i].kernelParams = reinterpret_cast(kernelArgs); kernelNodeParams[i].extra = nullptr; HIP_CHECK(hipGraphAddKernelNode(&kernelnode[i], graph, nullptr, 0, &kernelNodeParams[i])); } // Create dependencies between nodes for (int i = 1; i < NUM_OF_DUMMY_NODES; i++) { HIP_CHECK(hipGraphAddDependencies(graph, &kernelnode[i-1], &kernelnode[i], 1)); } // Start destroying nodes from 0 size_t numOfNodes = 0, numOfDep = 0; for (size_t i = 0; i < (NUM_OF_DUMMY_NODES - 1); i++) { // destroy node i HIP_CHECK(hipGraphDestroyNode(kernelnode[i])); HIP_CHECK(hipGraphGetNodes(graph, nullptr, &numOfNodes)); REQUIRE(numOfNodes == (NUM_OF_DUMMY_NODES - i - 1)); HIP_CHECK(hipGraphGetEdges(graph, nullptr, nullptr, &numOfDep)); REQUIRE(numOfDep == (NUM_OF_DUMMY_NODES - i - 2)); } HIP_CHECK(hipGraphDestroyNode(kernelnode[NUM_OF_DUMMY_NODES-1])); HIP_CHECK(hipGraphGetNodes(graph, nullptr, &numOfNodes)); REQUIRE(numOfNodes == 0); HIP_CHECK(hipGraphDestroy(graph)); } /** * Functional Test to test hipGraphDestroyNode using hipGraphGetNodes * and hipGraphGetEdges APIs on a cloned graph */ TEST_CASE("Unit_hipGraphDestroyNode_Complx_ChkNumOfNodesNDep_ClonedGrph") { hipGraph_t graph, clonedgraph; hipGraphNode_t kernelnode[NUM_OF_DUMMY_NODES]; hipKernelNodeParams kernelNodeParams[NUM_OF_DUMMY_NODES]; HIP_CHECK(hipGraphCreate(&graph, 0)); HIP_CHECK(hipGraphCreate(&clonedgraph, 0)); // Create graph with no dependencies for (int i = 0; i < NUM_OF_DUMMY_NODES; i++) { void* kernelArgs[] = {nullptr}; kernelNodeParams[i].func = reinterpret_cast(dummyKernel); kernelNodeParams[i].gridDim = dim3(1); kernelNodeParams[i].blockDim = dim3(1); kernelNodeParams[i].sharedMemBytes = 0; kernelNodeParams[i].kernelParams = reinterpret_cast(kernelArgs); kernelNodeParams[i].extra = nullptr; HIP_CHECK(hipGraphAddKernelNode(&kernelnode[i], graph, nullptr, 0, &kernelNodeParams[i])); } // Create dependencies between nodes for (int i = 1; i < NUM_OF_DUMMY_NODES; i++) { HIP_CHECK(hipGraphAddDependencies(graph, &kernelnode[i-1], &kernelnode[i], 1)); } HIP_CHECK(hipGraphClone(&clonedgraph, graph)); // Start destroying nodes from 0 and validate number of nodes in // cloned graph size_t numOfNodes = 0, numOfDep = 0; for (size_t i = 0; i < (NUM_OF_DUMMY_NODES - 1); i++) { hipGraphNode_t node; // destroy node i HIP_CHECK(hipGraphNodeFindInClone(&node, kernelnode[i], clonedgraph)); HIP_CHECK(hipGraphDestroyNode(node)); HIP_CHECK(hipGraphGetNodes(clonedgraph, nullptr, &numOfNodes)); REQUIRE(numOfNodes == (NUM_OF_DUMMY_NODES - i - 1)); HIP_CHECK(hipGraphGetEdges(clonedgraph, nullptr, nullptr, &numOfDep)); REQUIRE(numOfDep == (NUM_OF_DUMMY_NODES - i - 2)); } // Verify the number of nodes in original graph numOfNodes = 0; HIP_CHECK(hipGraphGetNodes(graph, nullptr, &numOfNodes)); REQUIRE(numOfNodes == NUM_OF_DUMMY_NODES); HIP_CHECK(hipGraphDestroy(clonedgraph)); HIP_CHECK(hipGraphDestroy(graph)); } /** * Functional Test to test hipGraphDestroyNode on child node using * hipGraphGetNodes and hipGraphGetEdges APIs on a cloned graph. */ TEST_CASE("Unit_hipGraphDestroyNode_Complx_ChkNumOfNodesNDep_ChldNode") { hipGraph_t graph0, graph1; hipGraphNode_t kernelnode[NUM_OF_DUMMY_NODES], childGraphNode; hipKernelNodeParams kernelNodeParams[NUM_OF_DUMMY_NODES]; HIP_CHECK(hipGraphCreate(&graph0, 0)); HIP_CHECK(hipGraphCreate(&graph1, 0)); // Create graph with no dependencies for (int i = 0; i < NUM_OF_DUMMY_NODES; i++) { void* kernelArgs[] = {nullptr}; kernelNodeParams[i].func = reinterpret_cast(dummyKernel); kernelNodeParams[i].gridDim = dim3(1); kernelNodeParams[i].blockDim = dim3(1); kernelNodeParams[i].sharedMemBytes = 0; kernelNodeParams[i].kernelParams = reinterpret_cast(kernelArgs); kernelNodeParams[i].extra = nullptr; HIP_CHECK(hipGraphAddKernelNode(&kernelnode[i], graph0, nullptr, 0, &kernelNodeParams[i])); } // Create dependencies between nodes for (int i = 1; i < NUM_OF_DUMMY_NODES; i++) { HIP_CHECK(hipGraphAddDependencies(graph0, &kernelnode[i-1], &kernelnode[i], 1)); } // Create child node and add it to graph1 HIP_CHECK(hipGraphAddChildGraphNode(&childGraphNode, graph1, nullptr, 0, graph0)); // delete the child node from graph1 HIP_CHECK(hipGraphDestroyNode(childGraphNode)); // Start destroying nodes from 0 size_t numOfNodes = 0, numOfDep = 0; for (size_t i = 0; i < (NUM_OF_DUMMY_NODES - 1); i++) { // destroy node i HIP_CHECK(hipGraphDestroyNode(kernelnode[i])); HIP_CHECK(hipGraphGetNodes(graph0, nullptr, &numOfNodes)); REQUIRE(numOfNodes == (NUM_OF_DUMMY_NODES - i - 1)); HIP_CHECK(hipGraphGetEdges(graph0, nullptr, nullptr, &numOfDep)); REQUIRE(numOfDep == (NUM_OF_DUMMY_NODES - i - 2)); } HIP_CHECK(hipGraphGetNodes(graph1, nullptr, &numOfNodes)); REQUIRE(numOfNodes == 0); HIP_CHECK(hipGraphDestroy(graph0)); HIP_CHECK(hipGraphDestroy(graph1)); }