Dosyalar
rocm-systems/catch/unit/graph/hipGraphMemcpyNodeSetParamsToSymbol.cc
T
ROCm CI Service Account 609edf1c9e SWDEV-306122 - [catch2][dtest] Added test for hipGraphMemcpyNodeSetParamsToSymbol API (#2813)
Change-Id: I486030661324f3fa4d6f6241882f4cd839211511
2022-09-27 13:34:31 +05:30

265 satır
12 KiB
C++

/*
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 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 hipGraphMemcpyNodeSetParamsToSymbol API:
Functional :
1) Allocate global symbol memory, add the node to the graph.
Set/Update the new values to the node. Make sure they are taking effect.
2) Allocate const symbol memory, add the node to the graph.
Set/Update the new values to the node. Make sure they are taking effect.
Negative :
1) Pass GraphNode as nullptr and check if api returns error.
2) Pass symbol ptr as nullptr, api expected to return error code.
3) Pass src ptr as nullptr, api expected to return error code.
4) Pass count as zero, api expected to return error code.
5) Pass count more than allocated size for source and destination ptr, api should return error code.
6) Pass offset+count greater than allocated size, api expected to return error code.
7) Pass same pointer as source ptr and symbol ptr, api expected to return error code.
8) Pass both destination ptr and source ptr as 2 different symbol ptr, api expected to return error code.
9) Copy from host ptr to device ptr but pass kind as different, api expected to return error code.
*/
#include <hip_test_common.hh>
#include <hip_test_checkers.hh>
#include <limits>
#define SIZE 256
__device__ int globalIn[SIZE], globalOut[SIZE];
__device__ __constant__ int globalConst[SIZE];
__global__ void CpyToSymbolKernel(int* B_d) {
for (int i = 0 ; i < SIZE; i++) {
B_d[i] = globalIn[i];
}
}
__global__ void CpyToConstSymbolKernel(int* B_d) {
for (int i = 0 ; i < SIZE; i++) {
B_d[i] = globalConst[i];
}
}
/* This testcase verifies negative scenarios of
hipGraphMemcpyNodeSetParamsToSymbol API */
TEST_CASE("Unit_hipGraphMemcpyNodeSetParamsToSymbol_Negative") {
constexpr size_t Nbytes = SIZE * sizeof(int);
int *A_d{nullptr}, *B_d{nullptr};
int *A_h{nullptr}, *B_h{nullptr};
HipTest::initArrays<int>(&A_d, &B_d, nullptr,
&A_h, &B_h, nullptr, SIZE, false);
hipGraph_t graph;
hipError_t ret;
hipGraphNode_t memcpyToSymbolNode, memcpyH2D_A;
std::vector<hipGraphNode_t> dependencies;
HIP_CHECK(hipGraphCreate(&graph, 0));
// Adding MemcpyNode
HIP_CHECK(hipGraphAddMemcpyNode1D(&memcpyH2D_A, graph, nullptr, 0, A_d, A_h,
Nbytes, hipMemcpyHostToDevice));
dependencies.push_back(memcpyH2D_A);
HIP_CHECK(hipGraphAddMemcpyNodeToSymbol(&memcpyToSymbolNode, graph,
dependencies.data(),
dependencies.size(),
HIP_SYMBOL(globalIn),
A_d, Nbytes, 0,
hipMemcpyDeviceToDevice));
SECTION("Pass GraphNode as nullptr") {
ret = hipGraphMemcpyNodeSetParamsToSymbol(nullptr,
HIP_SYMBOL(globalIn),
B_d, Nbytes, 0,
hipMemcpyDeviceToDevice);
REQUIRE(hipErrorInvalidValue == ret);
}
SECTION("Pass symbol ptr as nullptr") {
ret = hipGraphMemcpyNodeSetParamsToSymbol(memcpyToSymbolNode,
nullptr,
B_d, Nbytes, 0,
hipMemcpyDeviceToDevice);
REQUIRE(hipErrorInvalidSymbol == ret);
}
SECTION("Pass src ptr as nullptr") {
ret = hipGraphMemcpyNodeSetParamsToSymbol(memcpyToSymbolNode,
HIP_SYMBOL(globalIn),
nullptr, Nbytes, 0,
hipMemcpyDeviceToDevice);
REQUIRE(hipErrorInvalidValue == ret);
}
SECTION("Pass count as zero") {
ret = hipGraphMemcpyNodeSetParamsToSymbol(memcpyToSymbolNode,
HIP_SYMBOL(globalIn),
B_d, 0, 0,
hipMemcpyDeviceToDevice);
REQUIRE(hipErrorInvalidValue == ret);
}
SECTION("Pass count more than allocated size for source and dstn ptr") {
ret = hipGraphMemcpyNodeSetParamsToSymbol(memcpyToSymbolNode,
HIP_SYMBOL(globalIn),
B_d, Nbytes+8, 0,
hipMemcpyDeviceToDevice);
REQUIRE(hipErrorInvalidValue == ret);
}
SECTION("Pass offset+count greater than allocated size") {
ret = hipGraphMemcpyNodeSetParamsToSymbol(memcpyToSymbolNode,
HIP_SYMBOL(globalIn),
B_d, Nbytes, 10,
hipMemcpyDeviceToDevice);
REQUIRE(hipErrorInvalidValue == ret);
}
SECTION("Pass same symbol pointer as source ptr and destination ptr") {
ret = hipGraphMemcpyNodeSetParamsToSymbol(memcpyToSymbolNode,
HIP_SYMBOL(globalIn),
HIP_SYMBOL(globalIn),
Nbytes, 0,
hipMemcpyDeviceToDevice);
REQUIRE(hipErrorInvalidValue == ret);
}
SECTION("Pass 2 different symbol pointer as source ptr and dstn ptr") {
ret = hipGraphMemcpyNodeSetParamsToSymbol(memcpyToSymbolNode,
HIP_SYMBOL(globalIn),
HIP_SYMBOL(globalOut),
Nbytes, 0,
hipMemcpyDeviceToDevice);
REQUIRE(hipErrorInvalidValue == ret);
}
SECTION("Copy from host ptr to device ptr but pass kind as different") {
ret = hipGraphMemcpyNodeSetParamsToSymbol(memcpyToSymbolNode,
HIP_SYMBOL(globalIn),
A_h,
Nbytes, 0,
hipMemcpyDeviceToDevice);
REQUIRE(hipErrorInvalidValue == ret);
}
HipTest::freeArrays<int>(A_d, B_d, nullptr, A_h, B_h, nullptr, false);
HIP_CHECK(hipGraphDestroy(graph));
}
static
void hipGraphMemcpyNodeSetParamsToSymbol_GlobalMem(bool useConstDeviceVar) {
constexpr size_t Nbytes = SIZE * sizeof(int);
constexpr auto blocksPerCU = 6; // to hide latency
constexpr auto threadsPerBlock = 256;
unsigned blocks = HipTest::setNumBlocks(blocksPerCU, threadsPerBlock, SIZE);
hipGraphNode_t memcpytosymbolkernel, memcpyD2H_B;
hipKernelNodeParams kernelNodeParams{};
int *A_d{nullptr}, *B_d{nullptr}, *C_d{nullptr};
int *A_h{nullptr}, *B_h{nullptr};
HipTest::initArrays<int>(&A_d, &B_d, &C_d,
&A_h, &B_h, nullptr, SIZE, false);
hipGraph_t graph;
hipGraphExec_t graphExec;
hipGraphNode_t memcpyToSymbolNode, memcpyH2D_A;
std::vector<hipGraphNode_t> dependencies;
HIP_CHECK(hipGraphCreate(&graph, 0));
// Adding MemcpyNode
HIP_CHECK(hipGraphAddMemcpyNode1D(&memcpyH2D_A, graph, nullptr, 0, A_d, A_h,
Nbytes, hipMemcpyHostToDevice));
dependencies.push_back(memcpyH2D_A);
if (useConstDeviceVar) {
HIP_CHECK(hipGraphAddMemcpyNodeToSymbol(&memcpyToSymbolNode, graph,
dependencies.data(),
dependencies.size(),
HIP_SYMBOL(globalConst),
C_d, Nbytes, 0,
hipMemcpyDeviceToDevice));
} else {
HIP_CHECK(hipGraphAddMemcpyNodeToSymbol(&memcpyToSymbolNode, graph,
dependencies.data(),
dependencies.size(),
HIP_SYMBOL(globalIn),
C_d, Nbytes, 0,
hipMemcpyDeviceToDevice));
}
dependencies.clear();
dependencies.push_back(memcpyToSymbolNode);
// Update the node with source pointer from C_d to A_d
if (useConstDeviceVar) {
HIP_CHECK(hipGraphMemcpyNodeSetParamsToSymbol(memcpyToSymbolNode,
HIP_SYMBOL(globalConst), A_d,
Nbytes, 0,
hipMemcpyDeviceToDevice));
} else {
HIP_CHECK(hipGraphMemcpyNodeSetParamsToSymbol(memcpyToSymbolNode,
HIP_SYMBOL(globalIn), A_d,
Nbytes, 0,
hipMemcpyDeviceToDevice));
}
// Adding Kernel node
void* kernelArgs1[] = {&B_d};
if (useConstDeviceVar)
kernelNodeParams.func = reinterpret_cast<void *>(CpyToConstSymbolKernel);
else
kernelNodeParams.func = reinterpret_cast<void *>(CpyToSymbolKernel);
kernelNodeParams.gridDim = dim3(blocks);
kernelNodeParams.blockDim = dim3(threadsPerBlock);
kernelNodeParams.sharedMemBytes = 0;
kernelNodeParams.kernelParams = reinterpret_cast<void**>(kernelArgs1);
kernelNodeParams.extra = nullptr;
HIP_CHECK(hipGraphAddKernelNode(&memcpytosymbolkernel, graph,
dependencies.data(), dependencies.size(),
&kernelNodeParams));
dependencies.clear();
dependencies.push_back(memcpytosymbolkernel);
// Adding MemcpyNode
HIP_CHECK(hipGraphAddMemcpyNode1D(&memcpyD2H_B, graph, dependencies.data(),
dependencies.size(), B_h, B_d,
Nbytes, hipMemcpyDeviceToHost));
// Instantiate and launch the graph
HIP_CHECK(hipGraphInstantiate(&graphExec, graph, nullptr, nullptr, 0));
HIP_CHECK(hipGraphLaunch(graphExec, 0));
// Validating the result
for (int i = 0; i < SIZE; i++) {
if (B_h[i] != A_h[i]) {
WARN("Validation failed B_h[i] " << B_h[i] << "A_h[i] " << A_h[i]);
REQUIRE(false);
}
}
HipTest::freeArrays<int>(A_d, B_d, C_d,
A_h, B_h, nullptr, false);
HIP_CHECK(hipGraphExecDestroy(graphExec));
HIP_CHECK(hipGraphDestroy(graph));
}
/* Test verifies hipGraphMemcpyNodeSetParamsToSymbol API Functional scenario.
1) Allocate global symbol memory, add node to the graph.
Set/Update the new values to the node. Make sure they are taking effect.
2) Allocate const symbol memory, add node to the graph.
Set/Update the new values to the node. Make sure they are taking effect.
*/
TEST_CASE("Unit_hipGraphMemcpyNodeSetParamsToSymbol_Functional") {
SECTION("Check and update with Global Device Symbol Memory") {
hipGraphMemcpyNodeSetParamsToSymbol_GlobalMem(false);
}
SECTION("Check and update with Constant Global Device Symbol Memory") {
hipGraphMemcpyNodeSetParamsToSymbol_GlobalMem(true);
}
}