/* Copyright (c) 2015-2017 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. */ /* HIT_START * BUILD: %t %s ../test_common.cpp HIPCC_OPTIONS -O3 * TEST: %t * HIT_END */ #include "../test_common.h" #define test_passed(test_name) printf("%s %s PASSED!%s\n", KGRN, #test_name, KNRM); class HipFunctorTests { public: // Test that a class functor can be passed to hiplaunchparam // and can be used in kernel void TestForSimpleClassFunctor(void); // Test that a templated class functor can be passed to hiplaunchparam // and can be used in kernel void TestForClassTemplateFunctor(void); // Test that a class functor object ptr can be passed to hiplaunchparam // and can be used in kernel void TestForClassObjPtrFunctor(void); // Test that a class object containing functor can be passed to hiplaunchparam // and can be used in kernel void TestForFunctorContainInClassObj(void); // Test that a stuct functor can be passed to hiplaunchparam // and can be used in kernel void TestForSimpleStructFunctor(void); // Test that a stuct functor object ptr can be passed to hiplaunchparam // and can be used in kernel void TestForStructObjPtrFunctor(void); // Test that a templated struct functor can be passed to hiplaunchparam // and can be used in kernel void TestForStructTemplateFunctor(void); // Test that a struct object containing functor can be passed to hiplaunchparam // and can be used in kernel void TestForFunctorContainInStructObj(void); }; static const int BLOCK_DIM_SIZE = 1024; static const int THREADS_PER_BLOCK = 1; // class functor tests // Simple doubler Functor class DoublerFunctor{ public: __device__ int operator()(int x) { return x * 2;} }; // simple doubler functor passed to kernel __global__ void DoublerFunctorKernel( DoublerFunctor doubler_, bool* deviceResult) { int x = blockIdx.x * blockDim.x + threadIdx.x; int result = doubler_(5); deviceResult[x] = (result == 10); } void HipFunctorTests::TestForSimpleClassFunctor(void) { DoublerFunctor doubler; bool *deviceResults, *hostResults; HIPCHECK(hipMalloc(&deviceResults, BLOCK_DIM_SIZE*sizeof(bool))); HIPCHECK(hipHostMalloc(&hostResults, BLOCK_DIM_SIZE*sizeof(bool))); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) { // initialize to false, will be set to // true if the functor is called in device code hostResults[k] = false; } HIPCHECK(hipMemcpy(deviceResults, hostResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyHostToDevice)); hipLaunchKernelGGL(DoublerFunctorKernel, dim3(BLOCK_DIM_SIZE), dim3(THREADS_PER_BLOCK), 0, 0, doubler, deviceResults); // Validation part of TestForSimpleClassFunctor HIPCHECK(hipMemcpy(hostResults, deviceResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyDeviceToHost)); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) HIPASSERT(hostResults[k] == true); HIPCHECK(hipHostFree(hostResults)); HIPCHECK(hipFree(deviceResults)); } // pointer functor passed to kernel __global__ void PtrDoublerFunctorKernel( DoublerFunctor *doubler_, bool* deviceResult) { int x = blockIdx.x * blockDim.x + threadIdx.x; int result = (*doubler_)(5); deviceResult[x] = (result == 10); } void HipFunctorTests::TestForClassObjPtrFunctor(void) { DoublerFunctor *ptrdoubler; bool *deviceResults, *hostResults; HIPCHECK(hipMalloc(&deviceResults, BLOCK_DIM_SIZE*sizeof(bool))); HIPCHECK(hipHostMalloc(&hostResults, BLOCK_DIM_SIZE*sizeof(bool))); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) { // initialize to false, will be set to // true if the functor is called in device code hostResults[k] = false; } HIPCHECK(hipMemcpy(deviceResults, hostResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyHostToDevice)); hipLaunchKernelGGL(PtrDoublerFunctorKernel, dim3(BLOCK_DIM_SIZE), dim3(THREADS_PER_BLOCK), 0, 0, ptrdoubler, deviceResults); // Validation part of TestForClassObjPtrFunctor HIPCHECK(hipMemcpy(hostResults, deviceResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyDeviceToHost)); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) HIPASSERT(hostResults[k] == true); HIPCHECK(hipHostFree(hostResults)); HIPCHECK(hipFree(deviceResults)); delete ptrdoubler; } class compare { public: template __device__ bool operator()(const T1& v1, const T2& v2) { return v1 > v2; } }; // template functor passed to kernel __global__ void TemplateFunctorKernel( compare compare_, bool* deviceResult) { int x = blockIdx.x * blockDim.x + threadIdx.x; deviceResult[x] = compare_(2.2, 2.1); deviceResult[x] = compare_(2, 1); deviceResult[x] = compare_('b', 'a'); } void HipFunctorTests::TestForClassTemplateFunctor(void) { compare comparefunctor; bool *deviceResults, *hostResults; HIPCHECK(hipMalloc(&deviceResults, BLOCK_DIM_SIZE*sizeof(bool))); HIPCHECK(hipHostMalloc(&hostResults, BLOCK_DIM_SIZE*sizeof(bool))); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) { // initialize to false, will be set to // true if the functor is called in device code hostResults[k] = false; } HIPCHECK(hipMemcpy(deviceResults, hostResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyHostToDevice)); hipLaunchKernelGGL(TemplateFunctorKernel, dim3(BLOCK_DIM_SIZE), dim3(THREADS_PER_BLOCK), 0, 0, comparefunctor, deviceResults); // Validation part of TestForClassTemplateFunctor HIPCHECK(hipMemcpy(hostResults, deviceResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyDeviceToHost)); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) HIPASSERT(hostResults[k] == true); HIPCHECK(hipHostFree(hostResults)); HIPCHECK(hipFree(deviceResults)); } // Doubler calculator class DoublerCalculator { public: int a, result; // fucntor contained in class object DoublerFunctor doubler; }; // doubler functor conatined in class obj passed to kernel __global__ void DoublerCalculatorFunctorKernel( DoublerCalculator doubler_, bool* deviceResult) { int x = blockIdx.x * blockDim.x + threadIdx.x; int result = doubler_.doubler(doubler_.a); deviceResult[x] = (doubler_.result == result); } void HipFunctorTests::TestForFunctorContainInClassObj(void) { DoublerCalculator Doubler; bool *deviceResults, *hostResults; HIPCHECK(hipMalloc(&deviceResults, BLOCK_DIM_SIZE*sizeof(bool))); HIPCHECK(hipHostMalloc(&hostResults, BLOCK_DIM_SIZE*sizeof(bool))); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) { // initialize to false, will be set to // true if the functor is called in device code hostResults[k] = false; } Doubler.a = 5; Doubler.result = 10; // pass comparefunctor to hipLaunchParm HIPCHECK(hipMemcpy(deviceResults, hostResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyHostToDevice)); hipLaunchKernelGGL(DoublerCalculatorFunctorKernel, dim3(BLOCK_DIM_SIZE), dim3(THREADS_PER_BLOCK), 0, 0, Doubler, deviceResults); // Validation part of TestForStructTemplateFunctor HIPCHECK(hipMemcpy(hostResults, deviceResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyDeviceToHost)); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) HIPASSERT(hostResults[k] == true); HIPCHECK(hipHostFree(hostResults)); HIPCHECK(hipFree(deviceResults)); } // Struct functor tests // Simple doubler Functor struct sDoublerFunctor { public: __device__ int operator()(int x) { return x * 2;} }; // simple sturct doubler functor passed to kernel __global__ void structDoublerFunctorKernel( sDoublerFunctor doubler_, bool* deviceResult) { int x = blockIdx.x * blockDim.x + threadIdx.x; int result = doubler_(5); deviceResult[x] = (result == 10); } void HipFunctorTests::TestForSimpleStructFunctor(void) { sDoublerFunctor doubler; bool *deviceResults, *hostResults; HIPCHECK(hipMalloc(&deviceResults, BLOCK_DIM_SIZE*sizeof(bool))); HIPCHECK(hipHostMalloc(&hostResults, BLOCK_DIM_SIZE*sizeof(bool))); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) { // initialize to false, will be set to // true if the functor is called in device code hostResults[k] = false; } HIPCHECK(hipMemcpy(deviceResults, hostResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyHostToDevice)); hipLaunchKernelGGL(structDoublerFunctorKernel, dim3(BLOCK_DIM_SIZE), dim3(THREADS_PER_BLOCK), 0, 0, doubler, deviceResults); // Validation part of TestForSimpleStructFunctor HIPCHECK(hipMemcpy(hostResults, deviceResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyDeviceToHost)); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) HIPASSERT(hostResults[k] == true); HIPCHECK(hipHostFree(hostResults)); HIPCHECK(hipFree(deviceResults)); } // ptr functor passed to kernel __global__ void structPtrDoublerFunctorKernel( sDoublerFunctor *doubler_, bool* deviceResult) { int x = blockIdx.x * blockDim.x + threadIdx.x; int result = (*doubler_)(5); deviceResult[x] = (result == 10); } void HipFunctorTests::TestForStructObjPtrFunctor(void) { sDoublerFunctor *ptrdoubler; bool *deviceResults, *hostResults; HIPCHECK(hipMalloc(&deviceResults, BLOCK_DIM_SIZE*sizeof(bool))); HIPCHECK(hipHostMalloc(&hostResults, BLOCK_DIM_SIZE*sizeof(bool))); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) { // initialize to false, will be set to // true if the functor is called in device code hostResults[k] = false; } HIPCHECK(hipMemcpy(deviceResults, hostResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyHostToDevice)); hipLaunchKernelGGL(structPtrDoublerFunctorKernel, dim3(BLOCK_DIM_SIZE), dim3(THREADS_PER_BLOCK), 0, 0, ptrdoubler, deviceResults); // Validation part of TestForStructObjPtrFunctor HIPCHECK(hipMemcpy(hostResults, deviceResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyDeviceToHost)); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) HIPASSERT(hostResults[k] == true); HIPCHECK(hipHostFree(hostResults)); HIPCHECK(hipFree(deviceResults)); delete ptrdoubler; } struct sCompare { public: template< typename T1, typename T2 > __device__ bool operator()(const T1& v1, const T2& v2) { return v1 > v2; } }; // template functor passed to kernel __global__ void structTemplateFunctorKernel( sCompare compare_, bool* deviceResult) { int x = blockIdx.x * blockDim.x + threadIdx.x; deviceResult[x] = compare_(2.2, 2.1); deviceResult[x] = compare_(2, 1); deviceResult[x] = compare_('b', 'a'); } void HipFunctorTests::TestForStructTemplateFunctor(void) { sCompare comparefunctor; bool *deviceResults, *hostResults; HIPCHECK(hipMalloc(&deviceResults, BLOCK_DIM_SIZE*sizeof(bool))); HIPCHECK(hipHostMalloc(&hostResults, BLOCK_DIM_SIZE*sizeof(bool))); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) { // initialize to false, will be set to // true if the functor is called in device code hostResults[k] = false; } HIPCHECK(hipMemcpy(deviceResults, hostResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyHostToDevice)); // pass comparefunctor to hipLaunchKernelGGL hipLaunchKernelGGL(structTemplateFunctorKernel, dim3(BLOCK_DIM_SIZE), dim3(THREADS_PER_BLOCK), 0, 0, comparefunctor, deviceResults); // Validation part of TestForStructTemplateFunctor HIPCHECK(hipMemcpy(hostResults, deviceResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyDeviceToHost)); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) HIPASSERT(hostResults[k] == true); HIPCHECK(hipHostFree(hostResults)); HIPCHECK(hipFree(deviceResults)); } // Doubler calculator struct struct sDoublerCalculator { public: int a, result; // fucntor contained in class object DoublerFunctor doubler; }; // doubler functor contained in struct passed to kernel __global__ void DoublerCalculatorFunctorKernel( sDoublerCalculator doubler_, bool* deviceResult) { int x = blockIdx.x * blockDim.x + threadIdx.x; int result = doubler_.doubler(doubler_.a); deviceResult[x] = (doubler_.result == result); } void HipFunctorTests::TestForFunctorContainInStructObj(void) { sDoublerCalculator Doubler; bool *deviceResults, *hostResults; HIPCHECK(hipMalloc(&deviceResults, BLOCK_DIM_SIZE*sizeof(bool))); HIPCHECK(hipHostMalloc(&hostResults, BLOCK_DIM_SIZE*sizeof(bool))); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) { // initialize to false, will be set to // true if the functor is called in device code hostResults[k] = false; } Doubler.a = 5; Doubler.result = 10; HIPCHECK(hipMemcpy(deviceResults, hostResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyHostToDevice)); // pass comparefunctor to hipLaunchKernelGGL hipLaunchKernelGGL(DoublerCalculatorFunctorKernel, dim3(BLOCK_DIM_SIZE), dim3(THREADS_PER_BLOCK), 0, 0, Doubler, deviceResults); // Validation part of TestForStructTemplateFunctor HIPCHECK(hipMemcpy(hostResults, deviceResults, BLOCK_DIM_SIZE*sizeof(bool), hipMemcpyDeviceToHost)); for (int k = 0; k < BLOCK_DIM_SIZE; ++k) HIPASSERT(hostResults[k] == true); HIPCHECK(hipHostFree(hostResults)); HIPCHECK(hipFree(deviceResults)); } int main() { HipFunctorTests FunctorTests; FunctorTests.TestForSimpleClassFunctor(); test_passed(TestForSimpleClassFunctor); FunctorTests.TestForClassObjPtrFunctor(); test_passed(TestForClassObjPtrFunctor); FunctorTests.TestForClassTemplateFunctor(); test_passed(TestForClassTemplateFunctor); FunctorTests.TestForSimpleStructFunctor(); test_passed(TestForSimpleStructFunctor); FunctorTests.TestForStructObjPtrFunctor(); test_passed(TestForStructObjPtrFunctor); FunctorTests.TestForStructTemplateFunctor(); test_passed(TestForStructTemplateFunctor); FunctorTests.TestForFunctorContainInClassObj(); test_passed(TestForFunctorContainInClassObj); FunctorTests.TestForFunctorContainInStructObj(); test_passed(TestForFunctorContainInStructObj); }