// This file is part of OpenCV project. // It is subject to the license terms in the LICENSE file found in the top-level directory // of this distribution and at http://opencv.org/license.html. // Copyright (C) 2015, Itseez, Inc., all rights reserved. // Third party copyrights are property of their respective owners. #include "precomp.hpp" #ifdef HAVE_VA # include #else // HAVE_VA # define NO_VA_SUPPORT_ERROR CV_Error(cv::Error::StsBadFunc, "OpenCV was build without VA support (libva)") #endif // HAVE_VA using namespace cv; //////////////////////////////////////////////////////////////////////// // CL-VA Interoperability #ifdef HAVE_OPENCL # include "opencv2/core/opencl/runtime/opencl_core.hpp" # include "opencv2/core.hpp" # include "opencv2/core/ocl.hpp" # include "opencl_kernels_core.hpp" #endif // HAVE_OPENCL #ifdef HAVE_VA_INTEL #ifdef HAVE_VA_INTEL_OLD_HEADER # include #else # include #endif #endif namespace cv { namespace va_intel { #ifdef HAVE_VA_INTEL static clGetDeviceIDsFromVA_APIMediaAdapterINTEL_fn clGetDeviceIDsFromVA_APIMediaAdapterINTEL = NULL; static clCreateFromVA_APIMediaSurfaceINTEL_fn clCreateFromVA_APIMediaSurfaceINTEL = NULL; static clEnqueueAcquireVA_APIMediaSurfacesINTEL_fn clEnqueueAcquireVA_APIMediaSurfacesINTEL = NULL; static clEnqueueReleaseVA_APIMediaSurfacesINTEL_fn clEnqueueReleaseVA_APIMediaSurfacesINTEL = NULL; static bool contextInitialized = false; #endif // HAVE_VA_INTEL namespace ocl { Context& initializeContextFromVA(VADisplay display, bool tryInterop) { CV_UNUSED(display); CV_UNUSED(tryInterop); #if !defined(HAVE_VA) NO_VA_SUPPORT_ERROR; #else // !HAVE_VA # ifdef HAVE_VA_INTEL contextInitialized = false; if (tryInterop) { cl_uint numPlatforms; cl_int status = clGetPlatformIDs(0, NULL, &numPlatforms); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLInitError, "OpenCL: Can't get number of platforms"); if (numPlatforms == 0) CV_Error(cv::Error::OpenCLInitError, "OpenCL: No available platforms"); std::vector platforms(numPlatforms); status = clGetPlatformIDs(numPlatforms, &platforms[0], NULL); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLInitError, "OpenCL: Can't get platform Id list"); // For CL-VA interop, we must find platform/device with "cl_intel_va_api_media_sharing" extension. // With standard initialization procedure, we should examine platform extension string for that. // But in practice, the platform ext string doesn't contain it, while device ext string does. // Follow Intel procedure (see tutorial), we should obtain device IDs by extension call. // Note that we must obtain function pointers using specific platform ID, and can't provide pointers in advance. // So, we iterate and select the first platform, for which we got non-NULL pointers, device, and CL context. int found = -1; cl_context context = 0; cl_device_id device = 0; for (int i = 0; i < (int)numPlatforms; ++i) { // Get extension function pointers clGetDeviceIDsFromVA_APIMediaAdapterINTEL = (clGetDeviceIDsFromVA_APIMediaAdapterINTEL_fn) clGetExtensionFunctionAddressForPlatform(platforms[i], "clGetDeviceIDsFromVA_APIMediaAdapterINTEL"); clCreateFromVA_APIMediaSurfaceINTEL = (clCreateFromVA_APIMediaSurfaceINTEL_fn) clGetExtensionFunctionAddressForPlatform(platforms[i], "clCreateFromVA_APIMediaSurfaceINTEL"); clEnqueueAcquireVA_APIMediaSurfacesINTEL = (clEnqueueAcquireVA_APIMediaSurfacesINTEL_fn) clGetExtensionFunctionAddressForPlatform(platforms[i], "clEnqueueAcquireVA_APIMediaSurfacesINTEL"); clEnqueueReleaseVA_APIMediaSurfacesINTEL = (clEnqueueReleaseVA_APIMediaSurfacesINTEL_fn) clGetExtensionFunctionAddressForPlatform(platforms[i], "clEnqueueReleaseVA_APIMediaSurfacesINTEL"); if (((void*)clGetDeviceIDsFromVA_APIMediaAdapterINTEL == NULL) || ((void*)clCreateFromVA_APIMediaSurfaceINTEL == NULL) || ((void*)clEnqueueAcquireVA_APIMediaSurfacesINTEL == NULL) || ((void*)clEnqueueReleaseVA_APIMediaSurfacesINTEL == NULL)) { continue; } // Query device list cl_uint numDevices = 0; status = clGetDeviceIDsFromVA_APIMediaAdapterINTEL(platforms[i], CL_VA_API_DISPLAY_INTEL, display, CL_PREFERRED_DEVICES_FOR_VA_API_INTEL, 0, NULL, &numDevices); if ((status != CL_SUCCESS) || !(numDevices > 0)) continue; numDevices = 1; // OpenCV expects only 1 device status = clGetDeviceIDsFromVA_APIMediaAdapterINTEL(platforms[i], CL_VA_API_DISPLAY_INTEL, display, CL_PREFERRED_DEVICES_FOR_VA_API_INTEL, numDevices, &device, NULL); if (status != CL_SUCCESS) continue; // Creating CL-VA media sharing OpenCL context cl_context_properties props[] = { CL_CONTEXT_VA_API_DISPLAY_INTEL, (cl_context_properties) display, CL_CONTEXT_INTEROP_USER_SYNC, CL_FALSE, // no explicit sync required 0 }; context = clCreateContext(props, numDevices, &device, NULL, NULL, &status); if (status != CL_SUCCESS) { clReleaseDevice(device); } else { found = i; break; } } if (found >= 0) { contextInitialized = true; cl_platform_id platform = platforms[found]; char platformName[1024] = {0}; size_t sz = 0; if (clGetPlatformInfo(platform, CL_PLATFORM_NAME, sizeof(platformName) - 16, platformName, &sz) != CL_SUCCESS || sz >= sizeof(platformName)) { CV_Error(cv::Error::OpenCLInitError, "OpenCL: Failed to get platform name"); } OpenCLExecutionContext clExecCtx; try { clExecCtx = OpenCLExecutionContext::create(platformName, platform, context, device); } catch (...) { clReleaseDevice(device); clReleaseContext(context); throw; } clExecCtx.bind(); return const_cast(clExecCtx.getContext()); } } # endif // HAVE_VA_INTEL { Context& ctx = Context::getDefault(true); return ctx; } #endif // !HAVE_VA } #ifdef HAVE_VA_INTEL static bool ocl_convert_nv12_to_bgr(cl_mem clImageY, cl_mem clImageUV, cl_mem clBuffer, int step, int cols, int rows) { ocl::Kernel k; k.create("YUV2BGR_NV12_8u", cv::ocl::core::cvtclr_dx_oclsrc, ""); if (k.empty()) return false; k.args(clImageY, clImageUV, clBuffer, step, cols, rows); size_t globalsize[] = { (size_t)cols, (size_t)rows }; return k.run(2, globalsize, 0, false); } static bool ocl_convert_bgr_to_nv12(cl_mem clBuffer, int step, int cols, int rows, cl_mem clImageY, cl_mem clImageUV) { ocl::Kernel k; k.create("BGR2YUV_NV12_8u", cv::ocl::core::cvtclr_dx_oclsrc, ""); if (k.empty()) return false; k.args(clBuffer, step, cols, rows, clImageY, clImageUV); size_t globalsize[] = { (size_t)cols, (size_t)rows }; return k.run(2, globalsize, 0, false); } #endif // HAVE_VA_INTEL } // namespace cv::va_intel::ocl #if defined(HAVE_VA) const int NCHANNELS = 3; static void copy_convert_nv12_to_bgr(const VAImage& image, const unsigned char* buffer, Mat& bgr) { const float d1 = 16.0f; const float d2 = 128.0f; static const float coeffs[5] = { 1.163999557f, 2.017999649f, -0.390999794f, -0.812999725f, 1.5959997177f }; const size_t srcOffsetY = image.offsets[0]; const size_t srcOffsetUV = image.offsets[1]; const size_t srcStepY = image.pitches[0]; const size_t srcStepUV = image.pitches[1]; const size_t dstStep = bgr.step; const unsigned char* srcY0 = buffer + srcOffsetY; const unsigned char* srcUV = buffer + srcOffsetUV; unsigned char* dst0 = bgr.data; for (int y = 0; y < bgr.rows; y += 2) { const unsigned char* srcY1 = srcY0 + srcStepY; unsigned char *dst1 = dst0 + dstStep; for (int x = 0; x < bgr.cols; x += 2) { float Y0 = float(srcY0[x+0]); float Y1 = float(srcY0[x+1]); float Y2 = float(srcY1[x+0]); float Y3 = float(srcY1[x+1]); float U = float(srcUV[2*(x/2)+0]) - d2; float V = float(srcUV[2*(x/2)+1]) - d2; Y0 = std::max(0.0f, Y0 - d1) * coeffs[0]; Y1 = std::max(0.0f, Y1 - d1) * coeffs[0]; Y2 = std::max(0.0f, Y2 - d1) * coeffs[0]; Y3 = std::max(0.0f, Y3 - d1) * coeffs[0]; float ruv = coeffs[4]*V; float guv = coeffs[3]*V + coeffs[2]*U; float buv = coeffs[1]*U; dst0[(x+0)*NCHANNELS+0] = saturate_cast(Y0 + buv); dst0[(x+0)*NCHANNELS+1] = saturate_cast(Y0 + guv); dst0[(x+0)*NCHANNELS+2] = saturate_cast(Y0 + ruv); dst0[(x+1)*NCHANNELS+0] = saturate_cast(Y1 + buv); dst0[(x+1)*NCHANNELS+1] = saturate_cast(Y1 + guv); dst0[(x+1)*NCHANNELS+2] = saturate_cast(Y1 + ruv); dst1[(x+0)*NCHANNELS+0] = saturate_cast(Y2 + buv); dst1[(x+0)*NCHANNELS+1] = saturate_cast(Y2 + guv); dst1[(x+0)*NCHANNELS+2] = saturate_cast(Y2 + ruv); dst1[(x+1)*NCHANNELS+0] = saturate_cast(Y3 + buv); dst1[(x+1)*NCHANNELS+1] = saturate_cast(Y3 + guv); dst1[(x+1)*NCHANNELS+2] = saturate_cast(Y3 + ruv); } srcY0 = srcY1 + srcStepY; srcUV += srcStepUV; dst0 = dst1 + dstStep; } } static void copy_convert_bgr_to_nv12(const VAImage& image, const Mat& bgr, unsigned char* buffer) { const float d1 = 16.0f; const float d2 = 128.0f; static const float coeffs[8] = { 0.256999969f, 0.50399971f, 0.09799957f, -0.1479988098f, -0.2909994125f, 0.438999176f, -0.3679990768f, -0.0709991455f }; const size_t dstOffsetY = image.offsets[0]; const size_t dstOffsetUV = image.offsets[1]; const size_t dstStepY = image.pitches[0]; const size_t dstStepUV = image.pitches[1]; const size_t srcStep = bgr.step; const unsigned char* src0 = bgr.data; unsigned char* dstY0 = buffer + dstOffsetY; unsigned char* dstUV = buffer + dstOffsetUV; for (int y = 0; y < bgr.rows; y += 2) { const unsigned char *src1 = src0 + srcStep; unsigned char* dstY1 = dstY0 + dstStepY; for (int x = 0; x < bgr.cols; x += 2) { float B0 = float(src0[(x+0)*NCHANNELS+0]); float G0 = float(src0[(x+0)*NCHANNELS+1]); float R0 = float(src0[(x+0)*NCHANNELS+2]); float B1 = float(src0[(x+1)*NCHANNELS+0]); float G1 = float(src0[(x+1)*NCHANNELS+1]); float R1 = float(src0[(x+1)*NCHANNELS+2]); float B2 = float(src1[(x+0)*NCHANNELS+0]); float G2 = float(src1[(x+0)*NCHANNELS+1]); float R2 = float(src1[(x+0)*NCHANNELS+2]); float B3 = float(src1[(x+1)*NCHANNELS+0]); float G3 = float(src1[(x+1)*NCHANNELS+1]); float R3 = float(src1[(x+1)*NCHANNELS+2]); float Y0 = coeffs[0]*R0 + coeffs[1]*G0 + coeffs[2]*B0 + d1; float Y1 = coeffs[0]*R1 + coeffs[1]*G1 + coeffs[2]*B1 + d1; float Y2 = coeffs[0]*R2 + coeffs[1]*G2 + coeffs[2]*B2 + d1; float Y3 = coeffs[0]*R3 + coeffs[1]*G3 + coeffs[2]*B3 + d1; float U = coeffs[3]*R0 + coeffs[4]*G0 + coeffs[5]*B0 + d2; float V = coeffs[5]*R0 + coeffs[6]*G0 + coeffs[7]*B0 + d2; dstY0[x+0] = saturate_cast(Y0); dstY0[x+1] = saturate_cast(Y1); dstY1[x+0] = saturate_cast(Y2); dstY1[x+1] = saturate_cast(Y3); dstUV[2*(x/2)+0] = saturate_cast(U); dstUV[2*(x/2)+1] = saturate_cast(V); } src0 = src1 + srcStep; dstY0 = dstY1 + dstStepY; dstUV += dstStepUV; } } static void copy_convert_yv12_to_bgr(const VAImage& image, const unsigned char* buffer, Mat& bgr) { const float d1 = 16.0f; const float d2 = 128.0f; static const float coeffs[5] = { 1.163999557f, 2.017999649f, -0.390999794f, -0.812999725f, 1.5959997177f }; CV_CheckEQ((size_t)image.format.fourcc, (size_t)VA_FOURCC_YV12, "Unexpected image format"); CV_CheckEQ((size_t)image.num_planes, (size_t)3, ""); const size_t srcOffsetY = image.offsets[0]; const size_t srcOffsetV = image.offsets[1]; const size_t srcOffsetU = image.offsets[2]; const size_t srcStepY = image.pitches[0]; const size_t srcStepU = image.pitches[1]; const size_t srcStepV = image.pitches[2]; const size_t dstStep = bgr.step; const unsigned char* srcY_ = buffer + srcOffsetY; const unsigned char* srcV_ = buffer + srcOffsetV; const unsigned char* srcU_ = buffer + srcOffsetU; for (int y = 0; y < bgr.rows; y += 2) { const unsigned char* srcY0 = srcY_ + (srcStepY) * y; const unsigned char* srcY1 = srcY0 + srcStepY; const unsigned char* srcV = srcV_ + (srcStepV) * y / 2; const unsigned char* srcU = srcU_ + (srcStepU) * y / 2; unsigned char* dst0 = bgr.data + (dstStep) * y; unsigned char* dst1 = dst0 + dstStep; for (int x = 0; x < bgr.cols; x += 2) { float Y0 = float(srcY0[x+0]); float Y1 = float(srcY0[x+1]); float Y2 = float(srcY1[x+0]); float Y3 = float(srcY1[x+1]); float U = float(srcU[x/2]) - d2; float V = float(srcV[x/2]) - d2; Y0 = std::max(0.0f, Y0 - d1) * coeffs[0]; Y1 = std::max(0.0f, Y1 - d1) * coeffs[0]; Y2 = std::max(0.0f, Y2 - d1) * coeffs[0]; Y3 = std::max(0.0f, Y3 - d1) * coeffs[0]; float ruv = coeffs[4]*V; float guv = coeffs[3]*V + coeffs[2]*U; float buv = coeffs[1]*U; dst0[(x+0)*NCHANNELS+0] = saturate_cast(Y0 + buv); dst0[(x+0)*NCHANNELS+1] = saturate_cast(Y0 + guv); dst0[(x+0)*NCHANNELS+2] = saturate_cast(Y0 + ruv); dst0[(x+1)*NCHANNELS+0] = saturate_cast(Y1 + buv); dst0[(x+1)*NCHANNELS+1] = saturate_cast(Y1 + guv); dst0[(x+1)*NCHANNELS+2] = saturate_cast(Y1 + ruv); dst1[(x+0)*NCHANNELS+0] = saturate_cast(Y2 + buv); dst1[(x+0)*NCHANNELS+1] = saturate_cast(Y2 + guv); dst1[(x+0)*NCHANNELS+2] = saturate_cast(Y2 + ruv); dst1[(x+1)*NCHANNELS+0] = saturate_cast(Y3 + buv); dst1[(x+1)*NCHANNELS+1] = saturate_cast(Y3 + guv); dst1[(x+1)*NCHANNELS+2] = saturate_cast(Y3 + ruv); } } } static void copy_convert_bgr_to_yv12(const VAImage& image, const Mat& bgr, unsigned char* buffer) { const float d1 = 16.0f; const float d2 = 128.0f; static const float coeffs[8] = { 0.256999969f, 0.50399971f, 0.09799957f, -0.1479988098f, -0.2909994125f, 0.438999176f, -0.3679990768f, -0.0709991455f }; CV_CheckEQ((size_t)image.format.fourcc, (size_t)VA_FOURCC_YV12, "Unexpected image format"); CV_CheckEQ((size_t)image.num_planes, (size_t)3, ""); const size_t dstOffsetY = image.offsets[0]; const size_t dstOffsetV = image.offsets[1]; const size_t dstOffsetU = image.offsets[2]; const size_t dstStepY = image.pitches[0]; const size_t dstStepU = image.pitches[1]; const size_t dstStepV = image.pitches[2]; unsigned char* dstY_ = buffer + dstOffsetY; unsigned char* dstV_ = buffer + dstOffsetV; unsigned char* dstU_ = buffer + dstOffsetU; const size_t srcStep = bgr.step; for (int y = 0; y < bgr.rows; y += 2) { unsigned char* dstY0 = dstY_ + (dstStepY) * y; unsigned char* dstY1 = dstY0 + dstStepY; unsigned char* dstV = dstV_ + (dstStepV) * y / 2; unsigned char* dstU = dstU_ + (dstStepU) * y / 2; const unsigned char* src0 = bgr.data + (srcStep) * y; const unsigned char* src1 = src0 + srcStep; for (int x = 0; x < bgr.cols; x += 2) { float B0 = float(src0[(x+0)*NCHANNELS+0]); float G0 = float(src0[(x+0)*NCHANNELS+1]); float R0 = float(src0[(x+0)*NCHANNELS+2]); float B1 = float(src0[(x+1)*NCHANNELS+0]); float G1 = float(src0[(x+1)*NCHANNELS+1]); float R1 = float(src0[(x+1)*NCHANNELS+2]); float B2 = float(src1[(x+0)*NCHANNELS+0]); float G2 = float(src1[(x+0)*NCHANNELS+1]); float R2 = float(src1[(x+0)*NCHANNELS+2]); float B3 = float(src1[(x+1)*NCHANNELS+0]); float G3 = float(src1[(x+1)*NCHANNELS+1]); float R3 = float(src1[(x+1)*NCHANNELS+2]); float Y0 = coeffs[0]*R0 + coeffs[1]*G0 + coeffs[2]*B0 + d1; float Y1 = coeffs[0]*R1 + coeffs[1]*G1 + coeffs[2]*B1 + d1; float Y2 = coeffs[0]*R2 + coeffs[1]*G2 + coeffs[2]*B2 + d1; float Y3 = coeffs[0]*R3 + coeffs[1]*G3 + coeffs[2]*B3 + d1; float U = coeffs[3]*R0 + coeffs[4]*G0 + coeffs[5]*B0 + d2; float V = coeffs[5]*R0 + coeffs[6]*G0 + coeffs[7]*B0 + d2; dstY0[x+0] = saturate_cast(Y0); dstY0[x+1] = saturate_cast(Y1); dstY1[x+0] = saturate_cast(Y2); dstY1[x+1] = saturate_cast(Y3); dstU[x/2] = saturate_cast(U); dstV[x/2] = saturate_cast(V); } } } #endif // HAVE_VA void convertToVASurface(VADisplay display, InputArray src, VASurfaceID surface, Size size) { CV_UNUSED(display); CV_UNUSED(src); CV_UNUSED(surface); CV_UNUSED(size); #if !defined(HAVE_VA) NO_VA_SUPPORT_ERROR; #else // !HAVE_VA const int stype = CV_8UC3; int srcType = src.type(); CV_Assert(srcType == stype); Size srcSize = src.size(); CV_Assert(srcSize.width == size.width && srcSize.height == size.height); #ifdef HAVE_VA_INTEL if (contextInitialized) { UMat u = src.getUMat(); // TODO Add support for roi CV_Assert(u.offset == 0); CV_Assert(u.isContinuous()); cl_mem clBuffer = (cl_mem)u.handle(ACCESS_READ); using namespace cv::ocl; Context& ctx = Context::getDefault(); cl_context context = (cl_context)ctx.ptr(); cl_int status = 0; cl_mem clImageY = clCreateFromVA_APIMediaSurfaceINTEL(context, CL_MEM_WRITE_ONLY, &surface, 0, &status); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clCreateFromVA_APIMediaSurfaceINTEL failed (Y plane)"); cl_mem clImageUV = clCreateFromVA_APIMediaSurfaceINTEL(context, CL_MEM_WRITE_ONLY, &surface, 1, &status); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clCreateFromVA_APIMediaSurfaceINTEL failed (UV plane)"); cl_command_queue q = (cl_command_queue)Queue::getDefault().ptr(); cl_mem images[2] = { clImageY, clImageUV }; status = clEnqueueAcquireVA_APIMediaSurfacesINTEL(q, 2, images, 0, NULL, NULL); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clEnqueueAcquireVA_APIMediaSurfacesINTEL failed"); if (!ocl::ocl_convert_bgr_to_nv12(clBuffer, (int)u.step[0], u.cols, u.rows, clImageY, clImageUV)) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: ocl_convert_bgr_to_nv12 failed"); clEnqueueReleaseVA_APIMediaSurfacesINTEL(q, 2, images, 0, NULL, NULL); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clEnqueueReleaseVA_APIMediaSurfacesINTEL failed"); status = clFinish(q); // TODO Use events if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clFinish failed"); status = clReleaseMemObject(clImageY); // TODO RAII if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clReleaseMem failed (Y plane)"); status = clReleaseMemObject(clImageUV); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clReleaseMem failed (UV plane)"); } else # endif // HAVE_VA_INTEL { Mat m = src.getMat(); // TODO Add support for roi CV_Assert(m.data == m.datastart); CV_Assert(m.isContinuous()); VAStatus status = 0; status = vaSyncSurface(display, surface); if (status != VA_STATUS_SUCCESS) CV_Error(cv::Error::StsError, "VA-API: vaSyncSurface failed"); VAImage image; status = vaDeriveImage(display, surface, &image); if (status != VA_STATUS_SUCCESS) CV_Error(cv::Error::StsError, "VA-API: vaDeriveImage failed"); unsigned char* buffer = 0; status = vaMapBuffer(display, image.buf, (void **)&buffer); if (status != VA_STATUS_SUCCESS) CV_Error(cv::Error::StsError, "VA-API: vaMapBuffer failed"); if (image.format.fourcc == VA_FOURCC_NV12) copy_convert_bgr_to_nv12(image, m, buffer); if (image.format.fourcc == VA_FOURCC_YV12) copy_convert_bgr_to_yv12(image, m, buffer); else CV_Check((int)image.format.fourcc, image.format.fourcc == VA_FOURCC_NV12 || image.format.fourcc == VA_FOURCC_YV12, "Unexpected image format"); status = vaUnmapBuffer(display, image.buf); if (status != VA_STATUS_SUCCESS) CV_Error(cv::Error::StsError, "VA-API: vaUnmapBuffer failed"); status = vaDestroyImage(display, image.image_id); if (status != VA_STATUS_SUCCESS) CV_Error(cv::Error::StsError, "VA-API: vaDestroyImage failed"); } #endif // !HAVE_VA } void convertFromVASurface(VADisplay display, VASurfaceID surface, Size size, OutputArray dst) { CV_UNUSED(display); CV_UNUSED(surface); CV_UNUSED(dst); CV_UNUSED(size); #if !defined(HAVE_VA) NO_VA_SUPPORT_ERROR; #else // !HAVE_VA const int dtype = CV_8UC3; // TODO Need to specify ACCESS_WRITE here somehow to prevent useless data copying! dst.create(size, dtype); #ifdef HAVE_VA_INTEL if (contextInitialized) { UMat u = dst.getUMat(); // TODO Add support for roi CV_Assert(u.offset == 0); CV_Assert(u.isContinuous()); cl_mem clBuffer = (cl_mem)u.handle(ACCESS_WRITE); using namespace cv::ocl; Context& ctx = Context::getDefault(); cl_context context = (cl_context)ctx.ptr(); cl_int status = 0; cl_mem clImageY = clCreateFromVA_APIMediaSurfaceINTEL(context, CL_MEM_READ_ONLY, &surface, 0, &status); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clCreateFromVA_APIMediaSurfaceINTEL failed (Y plane)"); cl_mem clImageUV = clCreateFromVA_APIMediaSurfaceINTEL(context, CL_MEM_READ_ONLY, &surface, 1, &status); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clCreateFromVA_APIMediaSurfaceINTEL failed (UV plane)"); cl_command_queue q = (cl_command_queue)Queue::getDefault().ptr(); cl_mem images[2] = { clImageY, clImageUV }; status = clEnqueueAcquireVA_APIMediaSurfacesINTEL(q, 2, images, 0, NULL, NULL); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clEnqueueAcquireVA_APIMediaSurfacesINTEL failed"); if (!ocl::ocl_convert_nv12_to_bgr(clImageY, clImageUV, clBuffer, (int)u.step[0], u.cols, u.rows)) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: ocl_convert_nv12_to_bgr failed"); status = clEnqueueReleaseVA_APIMediaSurfacesINTEL(q, 2, images, 0, NULL, NULL); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clEnqueueReleaseVA_APIMediaSurfacesINTEL failed"); status = clFinish(q); // TODO Use events if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clFinish failed"); status = clReleaseMemObject(clImageY); // TODO RAII if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clReleaseMem failed (Y plane)"); status = clReleaseMemObject(clImageUV); if (status != CL_SUCCESS) CV_Error(cv::Error::OpenCLApiCallError, "OpenCL: clReleaseMem failed (UV plane)"); } else # endif // HAVE_VA_INTEL { Mat m = dst.getMat(); // TODO Add support for roi CV_Assert(m.data == m.datastart); CV_Assert(m.isContinuous()); VAStatus status = 0; status = vaSyncSurface(display, surface); if (status != VA_STATUS_SUCCESS) CV_Error(cv::Error::StsError, "VA-API: vaSyncSurface failed"); VAImage image; status = vaDeriveImage(display, surface, &image); if (status != VA_STATUS_SUCCESS) CV_Error(cv::Error::StsError, "VA-API: vaDeriveImage failed"); unsigned char* buffer = 0; status = vaMapBuffer(display, image.buf, (void **)&buffer); if (status != VA_STATUS_SUCCESS) CV_Error(cv::Error::StsError, "VA-API: vaMapBuffer failed"); if (image.format.fourcc == VA_FOURCC_NV12) copy_convert_nv12_to_bgr(image, buffer, m); if (image.format.fourcc == VA_FOURCC_YV12) copy_convert_yv12_to_bgr(image, buffer, m); else CV_Check((int)image.format.fourcc, image.format.fourcc == VA_FOURCC_NV12 || image.format.fourcc == VA_FOURCC_YV12, "Unexpected image format"); status = vaUnmapBuffer(display, image.buf); if (status != VA_STATUS_SUCCESS) CV_Error(cv::Error::StsError, "VA-API: vaUnmapBuffer failed"); status = vaDestroyImage(display, image.image_id); if (status != VA_STATUS_SUCCESS) CV_Error(cv::Error::StsError, "VA-API: vaDestroyImage failed"); } #endif // !HAVE_VA } }} // namespace cv::va_intel