// // Copyright 2015 Pixar // // Licensed under the Apache License, Version 2.0 (the "Apache License") // with the following modification; you may not use this file except in // compliance with the Apache License and the following modification to it: // Section 6. Trademarks. is deleted and replaced with: // // 6. Trademarks. This License does not grant permission to use the trade // names, trademarks, service marks, or product names of the Licensor // and its affiliates, except as required to comply with Section 4(c) of // the License and to reproduce the content of the NOTICE file. // // You may obtain a copy of the Apache License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the Apache License with the above modification is // distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY // KIND, either express or implied. See the Apache License for the specific // language governing permissions and limitations under the Apache License. // #include "../osd/clEvaluator.h" #include #include #include #include #include "../osd/opencl.h" #include "../far/error.h" #include "../far/stencilTable.h" namespace OpenSubdiv { namespace OPENSUBDIV_VERSION { namespace Osd { static const char *clSource = #include "clKernel.gen.h" ; static const char *patchBasisTypesSource = #include "patchBasisTypes.gen.h" ; static const char *patchBasisSource = #include "patchBasis.gen.h" ; // ---------------------------------------------------------------------------- template cl_mem createCLBuffer(std::vector const & src, cl_context clContext) { if (src.empty()) { return NULL; } cl_int errNum = 0; cl_mem devicePtr = clCreateBuffer(clContext, CL_MEM_READ_WRITE|CL_MEM_COPY_HOST_PTR, src.size()*sizeof(T), (void*)(&src.at(0)), &errNum); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "clCreateBuffer: %d", errNum); } return devicePtr; } // ---------------------------------------------------------------------------- CLStencilTable::CLStencilTable(Far::StencilTable const *stencilTable, cl_context clContext) { _numStencils = stencilTable->GetNumStencils(); if (_numStencils > 0) { _sizes = createCLBuffer(stencilTable->GetSizes(), clContext); _offsets = createCLBuffer(stencilTable->GetOffsets(), clContext); _indices = createCLBuffer(stencilTable->GetControlIndices(), clContext); _weights = createCLBuffer(stencilTable->GetWeights(), clContext); _duWeights = _dvWeights = NULL; _duuWeights = _duvWeights = _dvvWeights = NULL; } else { _sizes = _offsets = _indices = _weights = NULL; _duWeights = _dvWeights = NULL; _duuWeights = _duvWeights = _dvvWeights = NULL; } } CLStencilTable::CLStencilTable(Far::LimitStencilTable const *limitStencilTable, cl_context clContext) { _numStencils = limitStencilTable->GetNumStencils(); if (_numStencils > 0) { _sizes = createCLBuffer(limitStencilTable->GetSizes(), clContext); _offsets = createCLBuffer(limitStencilTable->GetOffsets(), clContext); _indices = createCLBuffer(limitStencilTable->GetControlIndices(), clContext); _weights = createCLBuffer(limitStencilTable->GetWeights(), clContext); _duWeights = createCLBuffer( limitStencilTable->GetDuWeights(), clContext); _dvWeights = createCLBuffer( limitStencilTable->GetDvWeights(), clContext); _duuWeights = createCLBuffer( limitStencilTable->GetDuuWeights(), clContext); _duvWeights = createCLBuffer( limitStencilTable->GetDuvWeights(), clContext); _dvvWeights = createCLBuffer( limitStencilTable->GetDvvWeights(), clContext); } else { _sizes = _offsets = _indices = _weights = NULL; _duWeights = _dvWeights = NULL; _duuWeights = _duvWeights = _dvvWeights = NULL; } } CLStencilTable::~CLStencilTable() { if (_sizes) clReleaseMemObject(_sizes); if (_offsets) clReleaseMemObject(_offsets); if (_indices) clReleaseMemObject(_indices); if (_weights) clReleaseMemObject(_weights); if (_duWeights) clReleaseMemObject(_duWeights); if (_dvWeights) clReleaseMemObject(_dvWeights); if (_duuWeights) clReleaseMemObject(_duuWeights); if (_duvWeights) clReleaseMemObject(_duvWeights); if (_dvvWeights) clReleaseMemObject(_dvvWeights); } // --------------------------------------------------------------------------- CLEvaluator::CLEvaluator(cl_context context, cl_command_queue queue) : _clContext(context), _clCommandQueue(queue), _program(NULL), _stencilKernel(NULL), _stencilDerivKernel(NULL), _patchKernel(NULL) { } CLEvaluator::~CLEvaluator() { if (_stencilKernel) clReleaseKernel(_stencilKernel); if (_stencilDerivKernel) clReleaseKernel(_stencilDerivKernel); if (_patchKernel) clReleaseKernel(_patchKernel); if (_program) clReleaseProgram(_program); } bool CLEvaluator::Compile(BufferDescriptor const &srcDesc, BufferDescriptor const &dstDesc, BufferDescriptor const & /*duDesc*/, BufferDescriptor const & /*dvDesc*/, BufferDescriptor const & /*duuDesc*/, BufferDescriptor const & /*duvDesc*/, BufferDescriptor const & /*dvvDesc*/) { if (srcDesc.length > dstDesc.length) { Far::Error(Far::FAR_RUNTIME_ERROR, "srcDesc length must be less than or equal to " "dstDesc length.\n"); return false; } cl_int errNum; std::ostringstream defines; defines << "#define LENGTH " << srcDesc.length << "\n" << "#define SRC_STRIDE " << srcDesc.stride << "\n" << "#define DST_STRIDE " << dstDesc.stride << "\n" << "#define OSD_PATCH_BASIS_OPENCL\n"; std::string defineStr = defines.str(); const char *sources[] = { defineStr.c_str(), patchBasisTypesSource, patchBasisSource, clSource }; _program = clCreateProgramWithSource(_clContext, 4, sources, 0, &errNum); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "clCreateProgramWithSource (%d)", errNum); } errNum = clBuildProgram(_program, 0, NULL, NULL, NULL, NULL); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "clBuildProgram (%d) \n", errNum); cl_int numDevices = 0; clGetContextInfo( _clContext, CL_CONTEXT_NUM_DEVICES, sizeof(cl_uint), &numDevices, NULL); cl_device_id *devices = new cl_device_id[numDevices]; clGetContextInfo(_clContext, CL_CONTEXT_DEVICES, sizeof(cl_device_id)*numDevices, devices, NULL); for (int i = 0; i < numDevices; ++i) { char cBuildLog[10240]; clGetProgramBuildInfo( _program, devices[i], CL_PROGRAM_BUILD_LOG, sizeof(cBuildLog), cBuildLog, NULL); Far::Error(Far::FAR_RUNTIME_ERROR, cBuildLog); } delete[] devices; return false; } _stencilKernel = clCreateKernel(_program, "computeStencils", &errNum); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "buildKernel (%d)\n", errNum); return false; } _stencilDerivKernel = clCreateKernel(_program, "computeStencilsDerivatives", &errNum); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "buildKernel (%d)\n", errNum); return false; } _patchKernel = clCreateKernel(_program, "computePatches", &errNum); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "buildKernel (%d)\n", errNum); return false; } return true; } bool CLEvaluator::EvalStencils(cl_mem src, BufferDescriptor const &srcDesc, cl_mem dst, BufferDescriptor const &dstDesc, cl_mem sizes, cl_mem offsets, cl_mem indices, cl_mem weights, int start, int end, unsigned int numStartEvents, const cl_event* startEvents, cl_event* endEvent) const { if (end <= start) return true; size_t globalWorkSize = (size_t)(end - start); clSetKernelArg(_stencilKernel, 0, sizeof(cl_mem), &src); clSetKernelArg(_stencilKernel, 1, sizeof(int), &srcDesc.offset); clSetKernelArg(_stencilKernel, 2, sizeof(cl_mem), &dst); clSetKernelArg(_stencilKernel, 3, sizeof(int), &dstDesc.offset); clSetKernelArg(_stencilKernel, 4, sizeof(cl_mem), &sizes); clSetKernelArg(_stencilKernel, 5, sizeof(cl_mem), &offsets); clSetKernelArg(_stencilKernel, 6, sizeof(cl_mem), &indices); clSetKernelArg(_stencilKernel, 7, sizeof(cl_mem), &weights); clSetKernelArg(_stencilKernel, 8, sizeof(int), &start); clSetKernelArg(_stencilKernel, 9, sizeof(int), &end); cl_int errNum = clEnqueueNDRangeKernel( _clCommandQueue, _stencilKernel, 1, NULL, &globalWorkSize, NULL, numStartEvents, startEvents, endEvent); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "ApplyStencilKernel (%d) ", errNum); return false; } if (endEvent == NULL) { clFinish(_clCommandQueue); } return true; } bool CLEvaluator::EvalStencils(cl_mem src, BufferDescriptor const &srcDesc, cl_mem dst, BufferDescriptor const &dstDesc, cl_mem du, BufferDescriptor const &duDesc, cl_mem dv, BufferDescriptor const &dvDesc, cl_mem sizes, cl_mem offsets, cl_mem indices, cl_mem weights, cl_mem duWeights, cl_mem dvWeights, int start, int end, unsigned int numStartEvents, const cl_event* startEvents, cl_event* endEvent) const { if (end <= start) return true; size_t globalWorkSize = (size_t)(end - start); BufferDescriptor empty; clSetKernelArg(_stencilDerivKernel, 0, sizeof(cl_mem), &src); clSetKernelArg(_stencilDerivKernel, 1, sizeof(int), &srcDesc.offset); clSetKernelArg(_stencilDerivKernel, 2, sizeof(cl_mem), &dst); clSetKernelArg(_stencilDerivKernel, 3, sizeof(int), &dstDesc.offset); clSetKernelArg(_stencilDerivKernel, 4, sizeof(cl_mem), &du); clSetKernelArg(_stencilDerivKernel, 5, sizeof(int), &duDesc.offset); clSetKernelArg(_stencilDerivKernel, 6, sizeof(int), &duDesc.stride); clSetKernelArg(_stencilDerivKernel, 7, sizeof(cl_mem), &dv); clSetKernelArg(_stencilDerivKernel, 8, sizeof(int), &dvDesc.offset); clSetKernelArg(_stencilDerivKernel, 9, sizeof(int), &dvDesc.stride); clSetKernelArg(_stencilDerivKernel, 10, sizeof(cl_mem), NULL); clSetKernelArg(_stencilDerivKernel, 11, sizeof(int), &empty.offset); clSetKernelArg(_stencilDerivKernel, 12, sizeof(int), &empty.stride); clSetKernelArg(_stencilDerivKernel, 13, sizeof(cl_mem), NULL); clSetKernelArg(_stencilDerivKernel, 14, sizeof(int), &empty.offset); clSetKernelArg(_stencilDerivKernel, 15, sizeof(int), &empty.stride); clSetKernelArg(_stencilDerivKernel, 16, sizeof(cl_mem), NULL); clSetKernelArg(_stencilDerivKernel, 17, sizeof(int), &empty.offset); clSetKernelArg(_stencilDerivKernel, 18, sizeof(int), &empty.stride); clSetKernelArg(_stencilDerivKernel, 19, sizeof(cl_mem), &sizes); clSetKernelArg(_stencilDerivKernel, 20, sizeof(cl_mem), &offsets); clSetKernelArg(_stencilDerivKernel, 21, sizeof(cl_mem), &indices); clSetKernelArg(_stencilDerivKernel, 22, sizeof(cl_mem), &weights); clSetKernelArg(_stencilDerivKernel, 23, sizeof(cl_mem), &duWeights); clSetKernelArg(_stencilDerivKernel, 24, sizeof(cl_mem), &dvWeights); clSetKernelArg(_stencilDerivKernel, 25, sizeof(cl_mem), NULL); clSetKernelArg(_stencilDerivKernel, 26, sizeof(cl_mem), NULL); clSetKernelArg(_stencilDerivKernel, 27, sizeof(cl_mem), NULL); clSetKernelArg(_stencilDerivKernel, 28, sizeof(int), &start); clSetKernelArg(_stencilDerivKernel, 29, sizeof(int), &end); cl_int errNum = clEnqueueNDRangeKernel( _clCommandQueue, _stencilDerivKernel, 1, NULL, &globalWorkSize, NULL, numStartEvents, startEvents, endEvent); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "ApplyStencilKernel (%d) ", errNum); return false; } if (endEvent == NULL) { clFinish(_clCommandQueue); } return true; } bool CLEvaluator::EvalStencils(cl_mem src, BufferDescriptor const &srcDesc, cl_mem dst, BufferDescriptor const &dstDesc, cl_mem du, BufferDescriptor const &duDesc, cl_mem dv, BufferDescriptor const &dvDesc, cl_mem duu, BufferDescriptor const &duuDesc, cl_mem duv, BufferDescriptor const &duvDesc, cl_mem dvv, BufferDescriptor const &dvvDesc, cl_mem sizes, cl_mem offsets, cl_mem indices, cl_mem weights, cl_mem duWeights, cl_mem dvWeights, cl_mem duuWeights, cl_mem duvWeights, cl_mem dvvWeights, int start, int end, unsigned int numStartEvents, const cl_event* startEvents, cl_event* endEvent) const { if (end <= start) return true; size_t globalWorkSize = (size_t)(end - start); clSetKernelArg(_stencilDerivKernel, 0, sizeof(cl_mem), &src); clSetKernelArg(_stencilDerivKernel, 1, sizeof(int), &srcDesc.offset); clSetKernelArg(_stencilDerivKernel, 2, sizeof(cl_mem), &dst); clSetKernelArg(_stencilDerivKernel, 3, sizeof(int), &dstDesc.offset); clSetKernelArg(_stencilDerivKernel, 4, sizeof(cl_mem), &du); clSetKernelArg(_stencilDerivKernel, 5, sizeof(int), &duDesc.offset); clSetKernelArg(_stencilDerivKernel, 6, sizeof(int), &duDesc.stride); clSetKernelArg(_stencilDerivKernel, 7, sizeof(cl_mem), &dv); clSetKernelArg(_stencilDerivKernel, 8, sizeof(int), &dvDesc.offset); clSetKernelArg(_stencilDerivKernel, 9, sizeof(int), &dvDesc.stride); clSetKernelArg(_stencilDerivKernel, 10, sizeof(cl_mem), &duu); clSetKernelArg(_stencilDerivKernel, 11, sizeof(int), &duuDesc.offset); clSetKernelArg(_stencilDerivKernel, 12, sizeof(int), &duuDesc.stride); clSetKernelArg(_stencilDerivKernel, 13, sizeof(cl_mem), &duv); clSetKernelArg(_stencilDerivKernel, 14, sizeof(int), &duvDesc.offset); clSetKernelArg(_stencilDerivKernel, 15, sizeof(int), &duvDesc.stride); clSetKernelArg(_stencilDerivKernel, 16, sizeof(cl_mem), &dvv); clSetKernelArg(_stencilDerivKernel, 17, sizeof(int), &dvvDesc.offset); clSetKernelArg(_stencilDerivKernel, 18, sizeof(int), &dvvDesc.stride); clSetKernelArg(_stencilDerivKernel, 19, sizeof(cl_mem), &sizes); clSetKernelArg(_stencilDerivKernel, 20, sizeof(cl_mem), &offsets); clSetKernelArg(_stencilDerivKernel, 21, sizeof(cl_mem), &indices); clSetKernelArg(_stencilDerivKernel, 22, sizeof(cl_mem), &weights); clSetKernelArg(_stencilDerivKernel, 23, sizeof(cl_mem), &duWeights); clSetKernelArg(_stencilDerivKernel, 24, sizeof(cl_mem), &dvWeights); clSetKernelArg(_stencilDerivKernel, 25, sizeof(cl_mem), &duuWeights); clSetKernelArg(_stencilDerivKernel, 26, sizeof(cl_mem), &duvWeights); clSetKernelArg(_stencilDerivKernel, 27, sizeof(cl_mem), &dvvWeights); clSetKernelArg(_stencilDerivKernel, 28, sizeof(int), &start); clSetKernelArg(_stencilDerivKernel, 29, sizeof(int), &end); cl_int errNum = clEnqueueNDRangeKernel( _clCommandQueue, _stencilDerivKernel, 1, NULL, &globalWorkSize, NULL, numStartEvents, startEvents, endEvent); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "ApplyStencilKernel (%d) ", errNum); return false; } if (endEvent == NULL) { clFinish(_clCommandQueue); } return true; } bool CLEvaluator::EvalPatches(cl_mem src, BufferDescriptor const &srcDesc, cl_mem dst, BufferDescriptor const &dstDesc, cl_mem du, BufferDescriptor const &duDesc, cl_mem dv, BufferDescriptor const &dvDesc, int numPatchCoords, cl_mem patchCoordsBuffer, cl_mem patchArrayBuffer, cl_mem patchIndexBuffer, cl_mem patchParamBuffer, unsigned int numStartEvents, const cl_event* startEvents, cl_event* endEvent) const { size_t globalWorkSize = (size_t)(numPatchCoords); BufferDescriptor empty; clSetKernelArg(_patchKernel, 0, sizeof(cl_mem), &src); clSetKernelArg(_patchKernel, 1, sizeof(int), &srcDesc.offset); clSetKernelArg(_patchKernel, 2, sizeof(cl_mem), &dst); clSetKernelArg(_patchKernel, 3, sizeof(int), &dstDesc.offset); clSetKernelArg(_patchKernel, 4, sizeof(cl_mem), &du); clSetKernelArg(_patchKernel, 5, sizeof(int), &duDesc.offset); clSetKernelArg(_patchKernel, 6, sizeof(int), &duDesc.stride); clSetKernelArg(_patchKernel, 7, sizeof(cl_mem), &dv); clSetKernelArg(_patchKernel, 8, sizeof(int), &dvDesc.offset); clSetKernelArg(_patchKernel, 9, sizeof(int), &dvDesc.stride); clSetKernelArg(_patchKernel, 10, sizeof(cl_mem), NULL); clSetKernelArg(_patchKernel, 11, sizeof(int), &empty.offset); clSetKernelArg(_patchKernel, 12, sizeof(int), &empty.stride); clSetKernelArg(_patchKernel, 13, sizeof(cl_mem), NULL); clSetKernelArg(_patchKernel, 14, sizeof(int), &empty.offset); clSetKernelArg(_patchKernel, 15, sizeof(int), &empty.stride); clSetKernelArg(_patchKernel, 16, sizeof(cl_mem), NULL); clSetKernelArg(_patchKernel, 17, sizeof(int), &empty.offset); clSetKernelArg(_patchKernel, 18, sizeof(int), &empty.stride); clSetKernelArg(_patchKernel, 19, sizeof(cl_mem), &patchCoordsBuffer); clSetKernelArg(_patchKernel, 20, sizeof(cl_mem), &patchArrayBuffer); clSetKernelArg(_patchKernel, 21, sizeof(cl_mem), &patchIndexBuffer); clSetKernelArg(_patchKernel, 22, sizeof(cl_mem), &patchParamBuffer); cl_int errNum = clEnqueueNDRangeKernel( _clCommandQueue, _patchKernel, 1, NULL, &globalWorkSize, NULL, numStartEvents, startEvents, endEvent); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "ApplyPatchKernel (%d) ", errNum); return false; } if (endEvent == NULL) { clFinish(_clCommandQueue); } return true; } bool CLEvaluator::EvalPatches(cl_mem src, BufferDescriptor const &srcDesc, cl_mem dst, BufferDescriptor const &dstDesc, cl_mem du, BufferDescriptor const &duDesc, cl_mem dv, BufferDescriptor const &dvDesc, cl_mem duu, BufferDescriptor const &duuDesc, cl_mem duv, BufferDescriptor const &duvDesc, cl_mem dvv, BufferDescriptor const &dvvDesc, int numPatchCoords, cl_mem patchCoordsBuffer, cl_mem patchArrayBuffer, cl_mem patchIndexBuffer, cl_mem patchParamBuffer, unsigned int numStartEvents, const cl_event* startEvents, cl_event* endEvent) const { size_t globalWorkSize = (size_t)(numPatchCoords); clSetKernelArg(_patchKernel, 0, sizeof(cl_mem), &src); clSetKernelArg(_patchKernel, 1, sizeof(int), &srcDesc.offset); clSetKernelArg(_patchKernel, 2, sizeof(cl_mem), &dst); clSetKernelArg(_patchKernel, 3, sizeof(int), &dstDesc.offset); clSetKernelArg(_patchKernel, 4, sizeof(cl_mem), &du); clSetKernelArg(_patchKernel, 5, sizeof(int), &duDesc.offset); clSetKernelArg(_patchKernel, 6, sizeof(int), &duDesc.stride); clSetKernelArg(_patchKernel, 7, sizeof(cl_mem), &dv); clSetKernelArg(_patchKernel, 8, sizeof(int), &dvDesc.offset); clSetKernelArg(_patchKernel, 9, sizeof(int), &dvDesc.stride); clSetKernelArg(_patchKernel, 10, sizeof(cl_mem), &duu); clSetKernelArg(_patchKernel, 11, sizeof(int), &duuDesc.offset); clSetKernelArg(_patchKernel, 12, sizeof(int), &duuDesc.stride); clSetKernelArg(_patchKernel, 13, sizeof(cl_mem), &duv); clSetKernelArg(_patchKernel, 14, sizeof(int), &duvDesc.offset); clSetKernelArg(_patchKernel, 15, sizeof(int), &duvDesc.stride); clSetKernelArg(_patchKernel, 16, sizeof(cl_mem), &dvv); clSetKernelArg(_patchKernel, 17, sizeof(int), &dvvDesc.offset); clSetKernelArg(_patchKernel, 18, sizeof(int), &dvvDesc.stride); clSetKernelArg(_patchKernel, 19, sizeof(cl_mem), &patchCoordsBuffer); clSetKernelArg(_patchKernel, 20, sizeof(cl_mem), &patchArrayBuffer); clSetKernelArg(_patchKernel, 21, sizeof(cl_mem), &patchIndexBuffer); clSetKernelArg(_patchKernel, 22, sizeof(cl_mem), &patchParamBuffer); cl_int errNum = clEnqueueNDRangeKernel( _clCommandQueue, _patchKernel, 1, NULL, &globalWorkSize, NULL, numStartEvents, startEvents, endEvent); if (errNum != CL_SUCCESS) { Far::Error(Far::FAR_RUNTIME_ERROR, "ApplyPatchKernel (%d) ", errNum); return false; } if (endEvent == NULL) { clFinish(_clCommandQueue); } return true; } /* static */ void CLEvaluator::Synchronize(cl_command_queue clCommandQueue) { clFinish(clCommandQueue); } } // end namespace Osd } // end namespace OPENSUBDIV_VERSION } // end namespace OpenSubdiv