/*M/////////////////////////////////////////////////////////////////////////////////////// // // IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. // // By downloading, copying, installing or using the software you agree to this license. // If you do not agree to this license, do not download, install, // copy or use the software. // // // License Agreement // For Open Source Computer Vision Library // // Copyright (C) 2000-2008, Intel Corporation, all rights reserved. // Copyright (C) 2009, Willow Garage Inc., all rights reserved. // Third party copyrights are property of their respective owners. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // // * Redistribution's of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // // * Redistribution's 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. // // * The name of the copyright holders may not be used to endorse or promote products // derived from this software without specific prior written permission. // // This software is provided by the copyright holders and contributors "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 Intel Corporation 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. // //M*/ #include "precomp.hpp" using namespace cv; using namespace cv::gpu; #if !defined (HAVE_CUDA) void cv::gpu::remap(const GpuMat&, GpuMat&, const GpuMat&, const GpuMat&){ throw_nogpu(); } void cv::gpu::meanShiftFiltering(const GpuMat&, GpuMat&, int, int, TermCriteria) { throw_nogpu(); } void cv::gpu::drawColorDisp(const GpuMat&, GpuMat&, int) { throw_nogpu(); } void cv::gpu::drawColorDisp(const GpuMat&, GpuMat&, int, const Stream&) { throw_nogpu(); } void cv::gpu::reprojectImageTo3D(const GpuMat&, GpuMat&, const Mat&) { throw_nogpu(); } void cv::gpu::reprojectImageTo3D(const GpuMat&, GpuMat&, const Mat&, const Stream&) { throw_nogpu(); } void cv::gpu::cvtColor(const GpuMat&, GpuMat&, int, int) { throw_nogpu(); } void cv::gpu::cvtColor(const GpuMat&, GpuMat&, int, int, const Stream&) { throw_nogpu(); } #else /* !defined (HAVE_CUDA) */ namespace cv { namespace gpu { namespace improc { void remap_gpu_1c(const DevMem2D& src, const DevMem2Df& xmap, const DevMem2Df& ymap, DevMem2D dst); void remap_gpu_3c(const DevMem2D& src, const DevMem2Df& xmap, const DevMem2Df& ymap, DevMem2D dst); extern "C" void meanShiftFiltering_gpu(const DevMem2D& src, DevMem2D dst, int sp, int sr, int maxIter, float eps); void drawColorDisp_gpu(const DevMem2D& src, const DevMem2D& dst, int ndisp, const cudaStream_t& stream); void drawColorDisp_gpu(const DevMem2D_& src, const DevMem2D& dst, int ndisp, const cudaStream_t& stream); void reprojectImageTo3D_gpu(const DevMem2D& disp, const DevMem2Df& xyzw, const float* q, const cudaStream_t& stream); void reprojectImageTo3D_gpu(const DevMem2D_& disp, const DevMem2Df& xyzw, const float* q, const cudaStream_t& stream); void RGB2RGB_gpu(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, cudaStream_t stream); void RGB2RGB_gpu(const DevMem2D_& src, int srccn, const DevMem2D_& dst, int dstcn, int bidx, cudaStream_t stream); void RGB2RGB_gpu(const DevMem2Df& src, int srccn, const DevMem2Df& dst, int dstcn, int bidx, cudaStream_t stream); void Gray2RGB_gpu(const DevMem2D& src, const DevMem2D& dst, int dstcn, cudaStream_t stream); void Gray2RGB_gpu(const DevMem2D_& src, const DevMem2D_& dst, int dstcn, cudaStream_t stream); void Gray2RGB_gpu(const DevMem2Df& src, const DevMem2Df& dst, int dstcn, cudaStream_t stream); void RGB2Gray_gpu(const DevMem2D& src, int srccn, const DevMem2D& dst, int bidx, cudaStream_t stream); void RGB2Gray_gpu(const DevMem2D_& src, int srccn, const DevMem2D_& dst, int bidx, cudaStream_t stream); void RGB2Gray_gpu(const DevMem2Df& src, int srccn, const DevMem2Df& dst, int bidx, cudaStream_t stream); } }} //////////////////////////////////////////////////////////////////////// // remap void cv::gpu::remap(const GpuMat& src, GpuMat& dst, const GpuMat& xmap, const GpuMat& ymap) { typedef void (*remap_gpu_t)(const DevMem2D& src, const DevMem2Df& xmap, const DevMem2Df& ymap, DevMem2D dst); static const remap_gpu_t callers[] = {improc::remap_gpu_1c, 0, improc::remap_gpu_3c}; CV_Assert((src.type() == CV_8U || src.type() == CV_8UC3) && xmap.type() == CV_32F && ymap.type() == CV_32F); GpuMat out; if (dst.data != src.data) out = dst; out.create(xmap.size(), src.type()); callers[src.channels() - 1](src, xmap, ymap, out); dst = out; } //////////////////////////////////////////////////////////////////////// // meanShiftFiltering_GPU void cv::gpu::meanShiftFiltering(const GpuMat& src, GpuMat& dst, int sp, int sr, TermCriteria criteria) { if( src.empty() ) CV_Error( CV_StsBadArg, "The input image is empty" ); if( src.depth() != CV_8U || src.channels() != 4 ) CV_Error( CV_StsUnsupportedFormat, "Only 8-bit, 4-channel images are supported" ); dst.create( src.size(), CV_8UC4 ); if( !(criteria.type & TermCriteria::MAX_ITER) ) criteria.maxCount = 5; int maxIter = std::min(std::max(criteria.maxCount, 1), 100); float eps; if( !(criteria.type & TermCriteria::EPS) ) eps = 1.f; eps = (float)std::max(criteria.epsilon, 0.0); improc::meanShiftFiltering_gpu(src, dst, sp, sr, maxIter, eps); } //////////////////////////////////////////////////////////////////////// // drawColorDisp namespace { template void drawColorDisp_caller(const GpuMat& src, GpuMat& dst, int ndisp, const cudaStream_t& stream) { GpuMat out; if (dst.data != src.data) out = dst; out.create(src.size(), CV_8UC4); improc::drawColorDisp_gpu((DevMem2D_)src, out, ndisp, stream); dst = out; } typedef void (*drawColorDisp_caller_t)(const GpuMat& src, GpuMat& dst, int ndisp, const cudaStream_t& stream); const drawColorDisp_caller_t drawColorDisp_callers[] = {drawColorDisp_caller, 0, 0, drawColorDisp_caller, 0, 0, 0, 0}; } void cv::gpu::drawColorDisp(const GpuMat& src, GpuMat& dst, int ndisp) { CV_Assert(src.type() == CV_8U || src.type() == CV_16S); drawColorDisp_callers[src.type()](src, dst, ndisp, 0); } void cv::gpu::drawColorDisp(const GpuMat& src, GpuMat& dst, int ndisp, const Stream& stream) { CV_Assert(src.type() == CV_8U || src.type() == CV_16S); drawColorDisp_callers[src.type()](src, dst, ndisp, StreamAccessor::getStream(stream)); } //////////////////////////////////////////////////////////////////////// // reprojectImageTo3D namespace { template void reprojectImageTo3D_caller(const GpuMat& disp, GpuMat& xyzw, const Mat& Q, const cudaStream_t& stream) { xyzw.create(disp.rows, disp.cols, CV_32FC4); improc::reprojectImageTo3D_gpu((DevMem2D_)disp, xyzw, Q.ptr(), stream); } typedef void (*reprojectImageTo3D_caller_t)(const GpuMat& disp, GpuMat& xyzw, const Mat& Q, const cudaStream_t& stream); const reprojectImageTo3D_caller_t reprojectImageTo3D_callers[] = {reprojectImageTo3D_caller, 0, 0, reprojectImageTo3D_caller, 0, 0, 0, 0}; } void cv::gpu::reprojectImageTo3D(const GpuMat& disp, GpuMat& xyzw, const Mat& Q) { CV_Assert((disp.type() == CV_8U || disp.type() == CV_16S) && Q.type() == CV_32F && Q.rows == 4 && Q.cols == 4); reprojectImageTo3D_callers[disp.type()](disp, xyzw, Q, 0); } void cv::gpu::reprojectImageTo3D(const GpuMat& disp, GpuMat& xyzw, const Mat& Q, const Stream& stream) { CV_Assert((disp.type() == CV_8U || disp.type() == CV_16S) && Q.type() == CV_32F && Q.rows == 4 && Q.cols == 4); reprojectImageTo3D_callers[disp.type()](disp, xyzw, Q, StreamAccessor::getStream(stream)); } //////////////////////////////////////////////////////////////////////// // cvtColor namespace { void cvtColor_caller(const GpuMat& src, GpuMat& dst, int code, int dcn, const cudaStream_t& stream) { Size sz = src.size(); int scn = src.channels(), depth = src.depth(), bidx; CV_Assert(depth == CV_8U || depth == CV_16U || depth == CV_32F); GpuMat out; if (dst.data != src.data) out = dst; switch (code) { case CV_BGR2BGRA: case CV_RGB2BGRA: case CV_BGRA2BGR: case CV_RGBA2BGR: case CV_RGB2BGR: case CV_BGRA2RGBA: CV_Assert(scn == 3 || scn == 4); dcn = code == CV_BGR2BGRA || code == CV_RGB2BGRA || code == CV_BGRA2RGBA ? 4 : 3; bidx = code == CV_BGR2BGRA || code == CV_BGRA2BGR ? 0 : 2; out.create(sz, CV_MAKETYPE(depth, dcn)); if( depth == CV_8U ) improc::RGB2RGB_gpu((DevMem2D)src, scn, (DevMem2D)out, dcn, bidx, stream); else if( depth == CV_16U ) improc::RGB2RGB_gpu((DevMem2D_)src, scn, (DevMem2D_)out, dcn, bidx, stream); else improc::RGB2RGB_gpu((DevMem2Df)src, scn, (DevMem2Df)out, dcn, bidx, stream); break; //case CV_BGR2BGR565: case CV_BGR2BGR555: case CV_RGB2BGR565: case CV_RGB2BGR555: //case CV_BGRA2BGR565: case CV_BGRA2BGR555: case CV_RGBA2BGR565: case CV_RGBA2BGR555: // CV_Assert( (scn == 3 || scn == 4) && depth == CV_8U ); // dst.create(sz, CV_8UC2); // // CvtColorLoop(src, dst, RGB2RGB5x5(scn, // code == CV_BGR2BGR565 || code == CV_BGR2BGR555 || // code == CV_BGRA2BGR565 || code == CV_BGRA2BGR555 ? 0 : 2, // code == CV_BGR2BGR565 || code == CV_RGB2BGR565 || // code == CV_BGRA2BGR565 || code == CV_RGBA2BGR565 ? 6 : 5 // green bits // )); // break; //case CV_BGR5652BGR: case CV_BGR5552BGR: case CV_BGR5652RGB: case CV_BGR5552RGB: //case CV_BGR5652BGRA: case CV_BGR5552BGRA: case CV_BGR5652RGBA: case CV_BGR5552RGBA: // if(dcn <= 0) dcn = 3; // CV_Assert( (dcn == 3 || dcn == 4) && scn == 2 && depth == CV_8U ); // dst.create(sz, CV_MAKETYPE(depth, dcn)); // // CvtColorLoop(src, dst, RGB5x52RGB(dcn, // code == CV_BGR5652BGR || code == CV_BGR5552BGR || // code == CV_BGR5652BGRA || code == CV_BGR5552BGRA ? 0 : 2, // blue idx // code == CV_BGR5652BGR || code == CV_BGR5652RGB || // code == CV_BGR5652BGRA || code == CV_BGR5652RGBA ? 6 : 5 // green bits // )); // break; case CV_BGR2GRAY: case CV_BGRA2GRAY: case CV_RGB2GRAY: case CV_RGBA2GRAY: CV_Assert(scn == 3 || scn == 4); out.create(sz, CV_MAKETYPE(depth, 1)); bidx = code == CV_BGR2GRAY || code == CV_BGRA2GRAY ? 0 : 2; if( depth == CV_8U ) improc::RGB2Gray_gpu((DevMem2D)src, scn, (DevMem2D)out, bidx, stream); else if( depth == CV_16U ) improc::RGB2Gray_gpu((DevMem2D_)src, scn, (DevMem2D_)out, bidx, stream); else improc::RGB2Gray_gpu((DevMem2Df)src, scn, (DevMem2Df)out, bidx, stream); break; //case CV_BGR5652GRAY: case CV_BGR5552GRAY: // CV_Assert( scn == 2 && depth == CV_8U ); // dst.create(sz, CV_8UC1); // CvtColorLoop(src, dst, RGB5x52Gray(code == CV_BGR5652GRAY ? 6 : 5)); // break; case CV_GRAY2BGR: case CV_GRAY2BGRA: if (dcn <= 0) dcn = 3; CV_Assert(scn == 1 && (dcn == 3 || dcn == 4)); out.create(sz, CV_MAKETYPE(depth, dcn)); if( depth == CV_8U ) improc::Gray2RGB_gpu((DevMem2D)src, (DevMem2D)out, dcn, stream); else if( depth == CV_16U ) improc::Gray2RGB_gpu((DevMem2D_)src, (DevMem2D_)out, dcn, stream); else improc::Gray2RGB_gpu((DevMem2Df)src, (DevMem2Df)out, dcn, stream); break; //case CV_GRAY2BGR565: case CV_GRAY2BGR555: // CV_Assert( scn == 1 && depth == CV_8U ); // dst.create(sz, CV_8UC2); // // CvtColorLoop(src, dst, Gray2RGB5x5(code == CV_GRAY2BGR565 ? 6 : 5)); // break; //case CV_BGR2YCrCb: case CV_RGB2YCrCb: //case CV_BGR2YUV: case CV_RGB2YUV: // { // CV_Assert( scn == 3 || scn == 4 ); // bidx = code == CV_BGR2YCrCb || code == CV_RGB2YUV ? 0 : 2; // static const float yuv_f[] = { 0.114f, 0.587f, 0.299f, 0.492f, 0.877f }; // static const int yuv_i[] = { B2Y, G2Y, R2Y, 8061, 14369 }; // const float* coeffs_f = code == CV_BGR2YCrCb || code == CV_RGB2YCrCb ? 0 : yuv_f; // const int* coeffs_i = code == CV_BGR2YCrCb || code == CV_RGB2YCrCb ? 0 : yuv_i; // // dst.create(sz, CV_MAKETYPE(depth, 3)); // // if( depth == CV_8U ) // CvtColorLoop(src, dst, RGB2YCrCb_i(scn, bidx, coeffs_i)); // else if( depth == CV_16U ) // CvtColorLoop(src, dst, RGB2YCrCb_i(scn, bidx, coeffs_i)); // else // CvtColorLoop(src, dst, RGB2YCrCb_f(scn, bidx, coeffs_f)); // } // break; //case CV_YCrCb2BGR: case CV_YCrCb2RGB: //case CV_YUV2BGR: case CV_YUV2RGB: // { // if( dcn <= 0 ) dcn = 3; // CV_Assert( scn == 3 && (dcn == 3 || dcn == 4) ); // bidx = code == CV_YCrCb2BGR || code == CV_YUV2RGB ? 0 : 2; // static const float yuv_f[] = { 2.032f, -0.395f, -0.581f, 1.140f }; // static const int yuv_i[] = { 33292, -6472, -9519, 18678 }; // const float* coeffs_f = code == CV_YCrCb2BGR || code == CV_YCrCb2RGB ? 0 : yuv_f; // const int* coeffs_i = code == CV_YCrCb2BGR || code == CV_YCrCb2RGB ? 0 : yuv_i; // // dst.create(sz, CV_MAKETYPE(depth, dcn)); // // if( depth == CV_8U ) // CvtColorLoop(src, dst, YCrCb2RGB_i(dcn, bidx, coeffs_i)); // else if( depth == CV_16U ) // CvtColorLoop(src, dst, YCrCb2RGB_i(dcn, bidx, coeffs_i)); // else // CvtColorLoop(src, dst, YCrCb2RGB_f(dcn, bidx, coeffs_f)); // } // break; //case CV_BGR2XYZ: case CV_RGB2XYZ: // CV_Assert( scn == 3 || scn == 4 ); // bidx = code == CV_BGR2XYZ ? 0 : 2; // // dst.create(sz, CV_MAKETYPE(depth, 3)); // // if( depth == CV_8U ) // CvtColorLoop(src, dst, RGB2XYZ_i(scn, bidx, 0)); // else if( depth == CV_16U ) // CvtColorLoop(src, dst, RGB2XYZ_i(scn, bidx, 0)); // else // CvtColorLoop(src, dst, RGB2XYZ_f(scn, bidx, 0)); // break; //case CV_XYZ2BGR: case CV_XYZ2RGB: // if( dcn <= 0 ) dcn = 3; // CV_Assert( scn == 3 && (dcn == 3 || dcn == 4) ); // bidx = code == CV_XYZ2BGR ? 0 : 2; // // dst.create(sz, CV_MAKETYPE(depth, dcn)); // // if( depth == CV_8U ) // CvtColorLoop(src, dst, XYZ2RGB_i(dcn, bidx, 0)); // else if( depth == CV_16U ) // CvtColorLoop(src, dst, XYZ2RGB_i(dcn, bidx, 0)); // else // CvtColorLoop(src, dst, XYZ2RGB_f(dcn, bidx, 0)); // break; //case CV_BGR2HSV: case CV_RGB2HSV: case CV_BGR2HSV_FULL: case CV_RGB2HSV_FULL: //case CV_BGR2HLS: case CV_RGB2HLS: case CV_BGR2HLS_FULL: case CV_RGB2HLS_FULL: // { // CV_Assert( (scn == 3 || scn == 4) && (depth == CV_8U || depth == CV_32F) ); // bidx = code == CV_BGR2HSV || code == CV_BGR2HLS || // code == CV_BGR2HSV_FULL || code == CV_BGR2HLS_FULL ? 0 : 2; // int hrange = depth == CV_32F ? 360 : code == CV_BGR2HSV || code == CV_RGB2HSV || // code == CV_BGR2HLS || code == CV_RGB2HLS ? 180 : 255; // // dst.create(sz, CV_MAKETYPE(depth, 3)); // // if( code == CV_BGR2HSV || code == CV_RGB2HSV || // code == CV_BGR2HSV_FULL || code == CV_RGB2HSV_FULL ) // { // if( depth == CV_8U ) // CvtColorLoop(src, dst, RGB2HSV_b(scn, bidx, hrange)); // else // CvtColorLoop(src, dst, RGB2HSV_f(scn, bidx, (float)hrange)); // } // else // { // if( depth == CV_8U ) // CvtColorLoop(src, dst, RGB2HLS_b(scn, bidx, hrange)); // else // CvtColorLoop(src, dst, RGB2HLS_f(scn, bidx, (float)hrange)); // } // } // break; //case CV_HSV2BGR: case CV_HSV2RGB: case CV_HSV2BGR_FULL: case CV_HSV2RGB_FULL: //case CV_HLS2BGR: case CV_HLS2RGB: case CV_HLS2BGR_FULL: case CV_HLS2RGB_FULL: // { // if( dcn <= 0 ) dcn = 3; // CV_Assert( scn == 3 && (dcn == 3 || dcn == 4) && (depth == CV_8U || depth == CV_32F) ); // bidx = code == CV_HSV2BGR || code == CV_HLS2BGR || // code == CV_HSV2BGR_FULL || code == CV_HLS2BGR_FULL ? 0 : 2; // int hrange = depth == CV_32F ? 360 : code == CV_HSV2BGR || code == CV_HSV2RGB || // code == CV_HLS2BGR || code == CV_HLS2RGB ? 180 : 255; // // dst.create(sz, CV_MAKETYPE(depth, dcn)); // // if( code == CV_HSV2BGR || code == CV_HSV2RGB || // code == CV_HSV2BGR_FULL || code == CV_HSV2RGB_FULL ) // { // if( depth == CV_8U ) // CvtColorLoop(src, dst, HSV2RGB_b(dcn, bidx, hrange)); // else // CvtColorLoop(src, dst, HSV2RGB_f(dcn, bidx, (float)hrange)); // } // else // { // if( depth == CV_8U ) // CvtColorLoop(src, dst, HLS2RGB_b(dcn, bidx, hrange)); // else // CvtColorLoop(src, dst, HLS2RGB_f(dcn, bidx, (float)hrange)); // } // } // break; //case CV_BGR2Lab: case CV_RGB2Lab: case CV_LBGR2Lab: case CV_LRGB2Lab: //case CV_BGR2Luv: case CV_RGB2Luv: case CV_LBGR2Luv: case CV_LRGB2Luv: // { // CV_Assert( (scn == 3 || scn == 4) && (depth == CV_8U || depth == CV_32F) ); // bidx = code == CV_BGR2Lab || code == CV_BGR2Luv || // code == CV_LBGR2Lab || code == CV_LBGR2Luv ? 0 : 2; // bool srgb = code == CV_BGR2Lab || code == CV_RGB2Lab || // code == CV_BGR2Luv || code == CV_RGB2Luv; // // dst.create(sz, CV_MAKETYPE(depth, 3)); // // if( code == CV_BGR2Lab || code == CV_RGB2Lab || // code == CV_LBGR2Lab || code == CV_LRGB2Lab ) // { // if( depth == CV_8U ) // CvtColorLoop(src, dst, RGB2Lab_b(scn, bidx, 0, 0, srgb)); // else // CvtColorLoop(src, dst, RGB2Lab_f(scn, bidx, 0, 0, srgb)); // } // else // { // if( depth == CV_8U ) // CvtColorLoop(src, dst, RGB2Luv_b(scn, bidx, 0, 0, srgb)); // else // CvtColorLoop(src, dst, RGB2Luv_f(scn, bidx, 0, 0, srgb)); // } // } // break; //case CV_Lab2BGR: case CV_Lab2RGB: case CV_Lab2LBGR: case CV_Lab2LRGB: //case CV_Luv2BGR: case CV_Luv2RGB: case CV_Luv2LBGR: case CV_Luv2LRGB: // { // if( dcn <= 0 ) dcn = 3; // CV_Assert( scn == 3 && (dcn == 3 || dcn == 4) && (depth == CV_8U || depth == CV_32F) ); // bidx = code == CV_Lab2BGR || code == CV_Luv2BGR || // code == CV_Lab2LBGR || code == CV_Luv2LBGR ? 0 : 2; // bool srgb = code == CV_Lab2BGR || code == CV_Lab2RGB || // code == CV_Luv2BGR || code == CV_Luv2RGB; // // dst.create(sz, CV_MAKETYPE(depth, dcn)); // // if( code == CV_Lab2BGR || code == CV_Lab2RGB || // code == CV_Lab2LBGR || code == CV_Lab2LRGB ) // { // if( depth == CV_8U ) // CvtColorLoop(src, dst, Lab2RGB_b(dcn, bidx, 0, 0, srgb)); // else // CvtColorLoop(src, dst, Lab2RGB_f(dcn, bidx, 0, 0, srgb)); // } // else // { // if( depth == CV_8U ) // CvtColorLoop(src, dst, Luv2RGB_b(dcn, bidx, 0, 0, srgb)); // else // CvtColorLoop(src, dst, Luv2RGB_f(dcn, bidx, 0, 0, srgb)); // } // } // break; //case CV_BayerBG2BGR: case CV_BayerGB2BGR: case CV_BayerRG2BGR: case CV_BayerGR2BGR: //case CV_BayerBG2BGR_VNG: case CV_BayerGB2BGR_VNG: case CV_BayerRG2BGR_VNG: case CV_BayerGR2BGR_VNG: // if(dcn <= 0) dcn = 3; // CV_Assert( scn == 1 && dcn == 3 && depth == CV_8U ); // dst.create(sz, CV_8UC3); // // if( code == CV_BayerBG2BGR || code == CV_BayerGB2BGR || // code == CV_BayerRG2BGR || code == CV_BayerGR2BGR ) // Bayer2RGB_8u(src, dst, code); // else // Bayer2RGB_VNG_8u(src, dst, code); // break; default: CV_Error( CV_StsBadFlag, "Unknown/unsupported color conversion code" ); } dst = out; } } void cv::gpu::cvtColor(const GpuMat& src, GpuMat& dst, int code, int dcn) { cvtColor_caller(src, dst, code, dcn, 0); } void cv::gpu::cvtColor(const GpuMat& src, GpuMat& dst, int code, int dcn, const Stream& stream) { cvtColor_caller(src, dst, code, dcn, StreamAccessor::getStream(stream)); } #endif /* !defined (HAVE_CUDA) */