/* Copyright (c) 2021, NVIDIA CORPORATION. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of NVIDIA CORPORATION nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include "cuda_consumer.h" #include #include "nvmedia_image_nvscibuf.h" #include "nvmedia_utils/cmdline.h" // Enable this to 1 if require cuda processed output to ppm file. #define WRITE_OUTPUT_IMAGE 0 #define checkNvSciErrors(call) \ do { \ NvSciError _status = call; \ if (NvSciError_Success != _status) { \ printf( \ "NVSCI call in file '%s' in line %i returned" \ " %d, expected %d\n", \ __FILE__, __LINE__, _status, NvSciError_Success); \ fflush(stdout); \ exit(EXIT_FAILURE); \ } \ } while (0) __global__ static void yuvToGrayscale(cudaSurfaceObject_t surfaceObject, unsigned int *dstImage, int32_t imageWidth, int32_t imageHeight) { size_t x = blockIdx.x * blockDim.x + threadIdx.x; size_t y = blockIdx.y * blockDim.y + threadIdx.y; uchar4 *dstImageUchar4 = (uchar4 *)dstImage; for (; x < imageWidth && y < imageHeight; x += gridDim.x * blockDim.x, y += gridDim.y * blockDim.y) { int colInBytes = x * sizeof(unsigned char); unsigned char luma = surf2Dread(surfaceObject, colInBytes, y); uchar4 grayscalePix = make_uchar4(luma, luma, luma, 0); dstImageUchar4[y * imageWidth + x] = grayscalePix; } } static void cudaImportNvSciSync(cudaExternalSemaphore_t &extSem, NvSciSyncObj &syncObj) { cudaExternalSemaphoreHandleDesc extSemDesc; memset(&extSemDesc, 0, sizeof(extSemDesc)); extSemDesc.type = cudaExternalSemaphoreHandleTypeNvSciSync; extSemDesc.handle.nvSciSyncObj = (void *)syncObj; checkCudaErrors(cudaImportExternalSemaphore(&extSem, &extSemDesc)); } static void waitExternalSemaphore(cudaExternalSemaphore_t &waitSem, NvSciSyncFence *fence, cudaStream_t stream) { cudaExternalSemaphoreWaitParams waitParams; memset(&waitParams, 0, sizeof(waitParams)); // For cross-process signaler-waiter applications need to use NvSciIpc // and NvSciSync[Export|Import] utilities to share the NvSciSyncFence // across process. This step is optional in single-process. waitParams.params.nvSciSync.fence = (void *)fence; waitParams.flags = 0; checkCudaErrors( cudaWaitExternalSemaphoresAsync(&waitSem, &waitParams, 1, stream)); } static void signalExternalSemaphore(cudaExternalSemaphore_t &signalSem, NvSciSyncFence *fence, cudaStream_t stream) { cudaExternalSemaphoreSignalParams signalParams; memset(&signalParams, 0, sizeof(signalParams)); // For cross-process signaler-waiter applications need to use NvSciIpc // and NvSciSync[Export|Import] utilities to share the NvSciSyncFence // across process. This step is optional in single-process. signalParams.params.nvSciSync.fence = (void *)fence; signalParams.flags = 0; checkCudaErrors( cudaSignalExternalSemaphoresAsync(&signalSem, &signalParams, 1, stream)); } static void yuvToGrayscaleCudaKernel(cudaExternalResInterop &cudaExtResObj, int32_t imageWidth, int32_t imageHeight) { #if WRITE_OUTPUT_IMAGE unsigned int *h_dstImage; checkCudaErrors(cudaMallocHost( &h_dstImage, sizeof(unsigned int) * imageHeight * imageWidth)); #endif dim3 block(16, 16, 1); dim3 grid((imageWidth / block.x) + 1, (imageHeight / block.y) + 1, 1); yuvToGrayscale<<>>( cudaExtResObj.cudaSurfaceNvmediaBuf[0], cudaExtResObj.d_outputImage, imageWidth, imageHeight); #if WRITE_OUTPUT_IMAGE checkCudaErrors( cudaMemcpyAsync(h_dstImage, cudaExtResObj.d_outputImage, sizeof(unsigned int) * imageHeight * imageWidth, cudaMemcpyDeviceToHost, cudaExtResObj.stream)); checkCudaErrors(cudaStreamSynchronize(cudaExtResObj.stream)); char outputFilename[1024]; std::string image_filename = "Grayscale"; strcpy(outputFilename, image_filename.c_str()); strcpy(outputFilename + image_filename.length(), "_nvsci_out.ppm"); sdkSavePPM4ub(outputFilename, (unsigned char *)h_dstImage, imageWidth, imageHeight); printf("Wrote '%s'\n", outputFilename); checkCudaErrors(cudaFreeHost(h_dstImage)); #endif } static void cudaImportNvSciImage(cudaExternalResInterop &cudaExtResObj, NvSciBufObj &inputBufObj) { NvSciBufModule module = NULL; NvSciBufAttrList attrlist = NULL; NvSciBufAttrKeyValuePair pairArrayOut[10]; checkNvSciErrors(NvSciBufModuleOpen(&module)); checkNvSciErrors(NvSciBufAttrListCreate(module, &attrlist)); checkNvSciErrors(NvSciBufObjGetAttrList(inputBufObj, &attrlist)); memset(pairArrayOut, 0, sizeof(NvSciBufAttrKeyValuePair) * 10); int numAttrs = 0; pairArrayOut[numAttrs++].key = NvSciBufImageAttrKey_Size; pairArrayOut[numAttrs++].key = NvSciBufImageAttrKey_PlaneChannelCount; pairArrayOut[numAttrs++].key = NvSciBufImageAttrKey_PlaneCount; pairArrayOut[numAttrs++].key = NvSciBufImageAttrKey_PlaneWidth; pairArrayOut[numAttrs++].key = NvSciBufImageAttrKey_PlaneHeight; pairArrayOut[numAttrs++].key = NvSciBufImageAttrKey_Layout; pairArrayOut[numAttrs++].key = NvSciBufImageAttrKey_PlaneBitsPerPixel; pairArrayOut[numAttrs++].key = NvSciBufImageAttrKey_PlaneOffset; checkNvSciErrors(NvSciBufAttrListGetAttrs(attrlist, pairArrayOut, numAttrs)); uint64_t size = *(uint64_t *)pairArrayOut[0].value; uint8_t channelCount = *(uint8_t *)pairArrayOut[1].value; cudaExtResObj.planeCount = *(int32_t *)pairArrayOut[2].value; cudaExtResObj.imageWidth = (int32_t *)malloc(sizeof(int32_t) * cudaExtResObj.planeCount); cudaExtResObj.imageHeight = (int32_t *)malloc(sizeof(int32_t) * cudaExtResObj.planeCount); cudaExtResObj.planeOffset = (uint64_t *)malloc(sizeof(uint64_t) * cudaExtResObj.planeCount); memcpy(cudaExtResObj.imageWidth, (int32_t *)pairArrayOut[3].value, cudaExtResObj.planeCount * sizeof(int32_t)); memcpy(cudaExtResObj.imageHeight, (int32_t *)pairArrayOut[4].value, cudaExtResObj.planeCount * sizeof(int32_t)); memcpy(cudaExtResObj.planeOffset, (uint64_t *)pairArrayOut[7].value, cudaExtResObj.planeCount * sizeof(uint64_t)); NvSciBufAttrValImageLayoutType layout = *(NvSciBufAttrValImageLayoutType *)pairArrayOut[5].value; uint32_t bitsPerPixel = *(uint32_t *)pairArrayOut[6].value; if (layout != NvSciBufImage_BlockLinearType) { printf("Image layout is not block linear.. waiving execution\n"); exit(EXIT_WAIVED); } cudaExternalMemoryHandleDesc memHandleDesc; memset(&memHandleDesc, 0, sizeof(memHandleDesc)); memHandleDesc.type = cudaExternalMemoryHandleTypeNvSciBuf; memHandleDesc.handle.nvSciBufObject = inputBufObj; memHandleDesc.size = size; checkCudaErrors( cudaImportExternalMemory(&cudaExtResObj.extMemImageBuf, &memHandleDesc)); cudaExtResObj.d_mipmapArray = (cudaMipmappedArray_t *)malloc( sizeof(cudaMipmappedArray_t) * cudaExtResObj.planeCount); for (int i = 0; i < cudaExtResObj.planeCount; i++) { cudaExtent extent = {}; memset(&extent, 0, sizeof(extent)); extent.width = cudaExtResObj.imageWidth[i]; extent.height = cudaExtResObj.imageHeight[i]; extent.depth = 0; cudaChannelFormatDesc desc; switch (channelCount) { case 1: default: desc = cudaCreateChannelDesc(bitsPerPixel, 0, 0, 0, cudaChannelFormatKindUnsigned); break; case 2: desc = cudaCreateChannelDesc(bitsPerPixel, bitsPerPixel, 0, 0, cudaChannelFormatKindUnsigned); break; case 3: desc = cudaCreateChannelDesc(bitsPerPixel, bitsPerPixel, bitsPerPixel, 0, cudaChannelFormatKindUnsigned); break; case 4: desc = cudaCreateChannelDesc(bitsPerPixel, bitsPerPixel, bitsPerPixel, bitsPerPixel, cudaChannelFormatKindUnsigned); break; } cudaExternalMemoryMipmappedArrayDesc mipmapDesc = {0}; mipmapDesc.offset = cudaExtResObj.planeOffset[i]; mipmapDesc.formatDesc = desc; mipmapDesc.extent = extent; mipmapDesc.flags = 0; mipmapDesc.numLevels = 1; checkCudaErrors(cudaExternalMemoryGetMappedMipmappedArray( &cudaExtResObj.d_mipmapArray[i], cudaExtResObj.extMemImageBuf, &mipmapDesc)); } } static cudaSurfaceObject_t createCudaSurface(cudaArray_t &d_mipLevelArray) { cudaResourceDesc resourceDesc; memset(&resourceDesc, 0, sizeof(resourceDesc)); resourceDesc.resType = cudaResourceTypeArray; resourceDesc.res.array.array = d_mipLevelArray; cudaSurfaceObject_t surfaceObject; checkCudaErrors(cudaCreateSurfaceObject(&surfaceObject, &resourceDesc)); return surfaceObject; } static cudaStream_t createCudaStream(int deviceId) { checkCudaErrors(cudaSetDevice(deviceId)); cudaStream_t stream; checkCudaErrors(cudaStreamCreateWithFlags(&stream, cudaStreamNonBlocking)); return stream; } // CUDA setup buffers/synchronization objects for interop via NvSci API. void setupCuda(cudaExternalResInterop &cudaExtResObj, NvSciBufObj &inputBufObj, NvSciSyncObj &syncObj, NvSciSyncObj &cudaSignalerSyncObj, int deviceId) { checkCudaErrors(cudaSetDevice(deviceId)); cudaImportNvSciSync(cudaExtResObj.waitSem, syncObj); cudaImportNvSciSync(cudaExtResObj.signalSem, cudaSignalerSyncObj); cudaImportNvSciImage(cudaExtResObj, inputBufObj); cudaExtResObj.d_mipLevelArray = (cudaArray_t *)malloc(sizeof(cudaArray_t) * cudaExtResObj.planeCount); cudaExtResObj.cudaSurfaceNvmediaBuf = (cudaSurfaceObject_t *)malloc( sizeof(cudaSurfaceObject_t) * cudaExtResObj.planeCount); for (int i = 0; i < cudaExtResObj.planeCount; ++i) { uint32_t mipLevelId = 0; checkCudaErrors( cudaGetMipmappedArrayLevel(&cudaExtResObj.d_mipLevelArray[i], cudaExtResObj.d_mipmapArray[i], mipLevelId)); cudaExtResObj.cudaSurfaceNvmediaBuf[i] = createCudaSurface(cudaExtResObj.d_mipLevelArray[i]); } cudaExtResObj.stream = createCudaStream(deviceId); checkCudaErrors(cudaMalloc(&cudaExtResObj.d_outputImage, sizeof(unsigned int) * cudaExtResObj.imageWidth[0] * cudaExtResObj.imageHeight[0])); } // CUDA clean up buffers used **with** NvSci API. void cleanupCuda(cudaExternalResInterop &cudaExtResObj) { for (int i = 0; i < cudaExtResObj.planeCount; i++) { checkCudaErrors( cudaDestroySurfaceObject(cudaExtResObj.cudaSurfaceNvmediaBuf[i])); checkCudaErrors(cudaFreeMipmappedArray(cudaExtResObj.d_mipmapArray[i])); } free(cudaExtResObj.d_mipmapArray); free(cudaExtResObj.d_mipLevelArray); free(cudaExtResObj.cudaSurfaceNvmediaBuf); free(cudaExtResObj.imageWidth); free(cudaExtResObj.imageHeight); checkCudaErrors(cudaDestroyExternalSemaphore(cudaExtResObj.waitSem)); checkCudaErrors(cudaDestroyExternalSemaphore(cudaExtResObj.signalSem)); checkCudaErrors(cudaDestroyExternalMemory(cudaExtResObj.extMemImageBuf)); checkCudaErrors(cudaStreamDestroy(cudaExtResObj.stream)); checkCudaErrors(cudaFree(cudaExtResObj.d_outputImage)); } void runCudaOperation(cudaExternalResInterop &cudaExtResObj, NvSciSyncFence *cudaWaitFence, NvSciSyncFence *cudaSignalFence, int deviceId, int iterations) { checkCudaErrors(cudaSetDevice(deviceId)); static int64_t launch = 0; waitExternalSemaphore(cudaExtResObj.waitSem, cudaWaitFence, cudaExtResObj.stream); // run cuda kernel over surface object of the LUMA surface part to extract // grayscale. yuvToGrayscaleCudaKernel(cudaExtResObj, cudaExtResObj.imageWidth[0], cudaExtResObj.imageHeight[0]); // signal fence till the second last iterations for NvMedia2DBlit to wait for // cuda signal and for final iteration as there is no corresponding NvMedia // operation pending therefore we end with cudaStreamSynchronize() if (launch < iterations - 1) { signalExternalSemaphore(cudaExtResObj.signalSem, cudaSignalFence, cudaExtResObj.stream); } else { checkCudaErrors(cudaStreamSynchronize(cudaExtResObj.stream)); } launch++; } // CUDA imports and operates on NvSci buffer/synchronization objects void setupCuda(Blit2DTest *ctx, cudaResources &cudaResObj, int deviceId) { checkCudaErrors(cudaSetDevice(deviceId)); cudaResObj.d_yuvArray = (cudaArray_t *)malloc(sizeof(cudaArray_t) * ctx->numSurfaces); cudaResObj.cudaSurfaceNvmediaBuf = (cudaSurfaceObject_t *)malloc( sizeof(cudaSurfaceObject_t) * ctx->numSurfaces); cudaChannelFormatDesc channelDesc; switch (ctx->bytesPerPixel) { case 1: default: channelDesc = cudaCreateChannelDesc(8, 0, 0, 0, cudaChannelFormatKindUnsigned); break; } for (int k = 0; k < ctx->numSurfaces; k++) { checkCudaErrors(cudaMallocArray( &cudaResObj.d_yuvArray[k], &channelDesc, ctx->widthSurface * ctx->xScalePtr[k] * ctx->bytesPerPixel, ctx->heightSurface * ctx->yScalePtr[k])); cudaResObj.cudaSurfaceNvmediaBuf[k] = createCudaSurface(cudaResObj.d_yuvArray[k]); } checkCudaErrors(cudaMalloc( &cudaResObj.d_outputImage, sizeof(unsigned int) * ctx->widthSurface * ctx->heightSurface)); cudaResObj.stream = createCudaStream(deviceId); } // CUDA clean up buffers used **without** NvSci API. void cleanupCuda(Blit2DTest *ctx, cudaResources &cudaResObj) { for (int k = 0; k < ctx->numSurfaces; k++) { checkCudaErrors( cudaDestroySurfaceObject(cudaResObj.cudaSurfaceNvmediaBuf[k])); checkCudaErrors(cudaFreeArray(cudaResObj.d_yuvArray[k])); } free(cudaResObj.cudaSurfaceNvmediaBuf); checkCudaErrors(cudaStreamDestroy(cudaResObj.stream)); checkCudaErrors(cudaFree(cudaResObj.d_outputImage)); } static void yuvToGrayscaleCudaKernelNonNvSci(cudaResources &cudaResObj, int deviceId, int32_t imageWidth, int32_t imageHeight) { #if WRITE_OUTPUT_IMAGE unsigned int *h_dstImage; checkCudaErrors(cudaMallocHost( &h_dstImage, sizeof(unsigned int) * imageHeight * imageWidth)); #endif dim3 block(16, 16, 1); dim3 grid((imageWidth / block.x) + 1, (imageHeight / block.y) + 1, 1); yuvToGrayscale<<>>( cudaResObj.cudaSurfaceNvmediaBuf[0], cudaResObj.d_outputImage, imageWidth, imageHeight); #if WRITE_OUTPUT_IMAGE checkCudaErrors( cudaMemcpyAsync(h_dstImage, cudaResObj.d_outputImage, sizeof(unsigned int) * imageHeight * imageWidth, cudaMemcpyDeviceToHost, cudaResObj.stream)); checkCudaErrors(cudaStreamSynchronize(cudaResObj.stream)); char outputFilename[1024]; std::string image_filename = "Grayscale"; strcpy(outputFilename, image_filename.c_str()); strcpy(outputFilename + image_filename.length(), "_non-nvsci_out.ppm"); sdkSavePPM4ub(outputFilename, (unsigned char *)h_dstImage, imageWidth, imageHeight); printf("Wrote '%s'\n", outputFilename); checkCudaErrors(cudaFreeHost(h_dstImage)); #else checkCudaErrors(cudaStreamSynchronize(cudaResObj.stream)); #endif } // CUDA operates **without** NvSci APIs buffer/synchronization objects. void runCudaOperation(Blit2DTest *ctx, cudaResources &cudaResObj, int deviceId) { for (int k = 0; k < ctx->numSurfaces; k++) { checkCudaErrors(cudaMemcpy2DToArray( cudaResObj.d_yuvArray[k], 0, 0, ctx->dstBuff[k], ctx->widthSurface * ctx->xScalePtr[k] * ctx->bytesPerPixel, ctx->widthSurface * ctx->xScalePtr[k] * ctx->bytesPerPixel, ctx->heightSurface * ctx->yScalePtr[k], cudaMemcpyHostToDevice)); } // run cuda kernel over surface object of the LUMA surface part to extract // grayscale. yuvToGrayscaleCudaKernelNonNvSci(cudaResObj, deviceId, ctx->widthSurface, ctx->heightSurface); }