opencv/modules/superres/src/btv_l1_cuda.cpp

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/*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.
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// 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*/
// S. Farsiu , D. Robinson, M. Elad, P. Milanfar. Fast and robust multiframe super resolution.
// Dennis Mitzel, Thomas Pock, Thomas Schoenemann, Daniel Cremers. Video Super Resolution using Duality Based TV-L1 Optical Flow.
#include "precomp.hpp"
using namespace cv;
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using namespace cv::cuda;
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using namespace cv::superres;
using namespace cv::superres::detail;
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#if !defined(HAVE_CUDA) || !defined(HAVE_OPENCV_CUDAARITHM) || !defined(HAVE_OPENCV_CUDAWARPING) || !defined(HAVE_OPENCV_CUDAFILTERS)
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Ptr<SuperResolution> cv::superres::createSuperResolution_BTVL1_GPU()
{
CV_Error(Error::StsNotImplemented, "The called functionality is disabled for current build or platform");
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return Ptr<SuperResolution>();
}
#else // HAVE_CUDA
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namespace btv_l1_cudev
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{
void buildMotionMaps(PtrStepSzf forwardMotionX, PtrStepSzf forwardMotionY,
PtrStepSzf backwardMotionX, PtrStepSzf bacwardMotionY,
PtrStepSzf forwardMapX, PtrStepSzf forwardMapY,
PtrStepSzf backwardMapX, PtrStepSzf backwardMapY);
template <int cn>
void upscale(const PtrStepSzb src, PtrStepSzb dst, int scale, cudaStream_t stream);
void diffSign(PtrStepSzf src1, PtrStepSzf src2, PtrStepSzf dst, cudaStream_t stream);
void loadBtvWeights(const float* weights, size_t count);
template <int cn> void calcBtvRegularization(PtrStepSzb src, PtrStepSzb dst, int ksize);
}
namespace
{
void calcRelativeMotions(const std::vector<std::pair<GpuMat, GpuMat> >& forwardMotions, const std::vector<std::pair<GpuMat, GpuMat> >& backwardMotions,
std::vector<std::pair<GpuMat, GpuMat> >& relForwardMotions, std::vector<std::pair<GpuMat, GpuMat> >& relBackwardMotions,
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int baseIdx, Size size)
{
const int count = static_cast<int>(forwardMotions.size());
relForwardMotions.resize(count);
relForwardMotions[baseIdx].first.create(size, CV_32FC1);
relForwardMotions[baseIdx].first.setTo(Scalar::all(0));
relForwardMotions[baseIdx].second.create(size, CV_32FC1);
relForwardMotions[baseIdx].second.setTo(Scalar::all(0));
relBackwardMotions.resize(count);
relBackwardMotions[baseIdx].first.create(size, CV_32FC1);
relBackwardMotions[baseIdx].first.setTo(Scalar::all(0));
relBackwardMotions[baseIdx].second.create(size, CV_32FC1);
relBackwardMotions[baseIdx].second.setTo(Scalar::all(0));
for (int i = baseIdx - 1; i >= 0; --i)
{
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cuda::add(relForwardMotions[i + 1].first, forwardMotions[i].first, relForwardMotions[i].first);
cuda::add(relForwardMotions[i + 1].second, forwardMotions[i].second, relForwardMotions[i].second);
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cuda::add(relBackwardMotions[i + 1].first, backwardMotions[i + 1].first, relBackwardMotions[i].first);
cuda::add(relBackwardMotions[i + 1].second, backwardMotions[i + 1].second, relBackwardMotions[i].second);
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}
for (int i = baseIdx + 1; i < count; ++i)
{
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cuda::add(relForwardMotions[i - 1].first, backwardMotions[i].first, relForwardMotions[i].first);
cuda::add(relForwardMotions[i - 1].second, backwardMotions[i].second, relForwardMotions[i].second);
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cuda::add(relBackwardMotions[i - 1].first, forwardMotions[i - 1].first, relBackwardMotions[i].first);
cuda::add(relBackwardMotions[i - 1].second, forwardMotions[i - 1].second, relBackwardMotions[i].second);
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}
}
void upscaleMotions(const std::vector<std::pair<GpuMat, GpuMat> >& lowResMotions, std::vector<std::pair<GpuMat, GpuMat> >& highResMotions, int scale)
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{
highResMotions.resize(lowResMotions.size());
for (size_t i = 0; i < lowResMotions.size(); ++i)
{
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cuda::resize(lowResMotions[i].first, highResMotions[i].first, Size(), scale, scale, INTER_CUBIC);
cuda::resize(lowResMotions[i].second, highResMotions[i].second, Size(), scale, scale, INTER_CUBIC);
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cuda::multiply(highResMotions[i].first, Scalar::all(scale), highResMotions[i].first);
cuda::multiply(highResMotions[i].second, Scalar::all(scale), highResMotions[i].second);
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}
}
void buildMotionMaps(const std::pair<GpuMat, GpuMat>& forwardMotion, const std::pair<GpuMat, GpuMat>& backwardMotion,
std::pair<GpuMat, GpuMat>& forwardMap, std::pair<GpuMat, GpuMat>& backwardMap)
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{
forwardMap.first.create(forwardMotion.first.size(), CV_32FC1);
forwardMap.second.create(forwardMotion.first.size(), CV_32FC1);
backwardMap.first.create(forwardMotion.first.size(), CV_32FC1);
backwardMap.second.create(forwardMotion.first.size(), CV_32FC1);
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btv_l1_cudev::buildMotionMaps(forwardMotion.first, forwardMotion.second,
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backwardMotion.first, backwardMotion.second,
forwardMap.first, forwardMap.second,
backwardMap.first, backwardMap.second);
}
void upscale(const GpuMat& src, GpuMat& dst, int scale, Stream& stream)
{
typedef void (*func_t)(const PtrStepSzb src, PtrStepSzb dst, int scale, cudaStream_t stream);
static const func_t funcs[] =
{
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0, btv_l1_cudev::upscale<1>, 0, btv_l1_cudev::upscale<3>, btv_l1_cudev::upscale<4>
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};
CV_Assert( src.channels() == 1 || src.channels() == 3 || src.channels() == 4 );
dst.create(src.rows * scale, src.cols * scale, src.type());
dst.setTo(Scalar::all(0));
const func_t func = funcs[src.channels()];
func(src, dst, scale, StreamAccessor::getStream(stream));
}
void diffSign(const GpuMat& src1, const GpuMat& src2, GpuMat& dst, Stream& stream)
{
dst.create(src1.size(), src1.type());
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btv_l1_cudev::diffSign(src1.reshape(1), src2.reshape(1), dst.reshape(1), StreamAccessor::getStream(stream));
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}
void calcBtvWeights(int btvKernelSize, double alpha, std::vector<float>& btvWeights)
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{
const size_t size = btvKernelSize * btvKernelSize;
btvWeights.resize(size);
const int ksize = (btvKernelSize - 1) / 2;
const float alpha_f = static_cast<float>(alpha);
for (int m = 0, ind = 0; m <= ksize; ++m)
{
for (int l = ksize; l + m >= 0; --l, ++ind)
btvWeights[ind] = pow(alpha_f, std::abs(m) + std::abs(l));
}
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btv_l1_cudev::loadBtvWeights(&btvWeights[0], size);
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}
void calcBtvRegularization(const GpuMat& src, GpuMat& dst, int btvKernelSize)
{
typedef void (*func_t)(PtrStepSzb src, PtrStepSzb dst, int ksize);
static const func_t funcs[] =
{
0,
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btv_l1_cudev::calcBtvRegularization<1>,
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0,
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btv_l1_cudev::calcBtvRegularization<3>,
btv_l1_cudev::calcBtvRegularization<4>
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};
dst.create(src.size(), src.type());
dst.setTo(Scalar::all(0));
const int ksize = (btvKernelSize - 1) / 2;
funcs[src.channels()](src, dst, ksize);
}
class BTVL1_GPU_Base
{
public:
BTVL1_GPU_Base();
void process(const std::vector<GpuMat>& src, GpuMat& dst,
const std::vector<std::pair<GpuMat, GpuMat> >& forwardMotions, const std::vector<std::pair<GpuMat, GpuMat> >& backwardMotions,
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int baseIdx);
void collectGarbage();
protected:
int scale_;
int iterations_;
double lambda_;
double tau_;
double alpha_;
int btvKernelSize_;
int blurKernelSize_;
double blurSigma_;
Ptr<DenseOpticalFlowExt> opticalFlow_;
private:
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std::vector<Ptr<cuda::Filter> > filters_;
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int curBlurKernelSize_;
double curBlurSigma_;
int curSrcType_;
std::vector<float> btvWeights_;
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int curBtvKernelSize_;
double curAlpha_;
std::vector<std::pair<GpuMat, GpuMat> > lowResForwardMotions_;
std::vector<std::pair<GpuMat, GpuMat> > lowResBackwardMotions_;
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std::vector<std::pair<GpuMat, GpuMat> > highResForwardMotions_;
std::vector<std::pair<GpuMat, GpuMat> > highResBackwardMotions_;
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std::vector<std::pair<GpuMat, GpuMat> > forwardMaps_;
std::vector<std::pair<GpuMat, GpuMat> > backwardMaps_;
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GpuMat highRes_;
std::vector<Stream> streams_;
std::vector<GpuMat> diffTerms_;
std::vector<GpuMat> a_, b_, c_;
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GpuMat regTerm_;
};
BTVL1_GPU_Base::BTVL1_GPU_Base()
{
scale_ = 4;
iterations_ = 180;
lambda_ = 0.03;
tau_ = 1.3;
alpha_ = 0.7;
btvKernelSize_ = 7;
blurKernelSize_ = 5;
blurSigma_ = 0.0;
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#ifdef HAVE_OPENCV_CUDAOPTFLOW
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opticalFlow_ = createOptFlow_Farneback_GPU();
#else
opticalFlow_ = createOptFlow_Farneback();
#endif
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curBlurKernelSize_ = -1;
curBlurSigma_ = -1.0;
curSrcType_ = -1;
curBtvKernelSize_ = -1;
curAlpha_ = -1.0;
}
void BTVL1_GPU_Base::process(const std::vector<GpuMat>& src, GpuMat& dst,
const std::vector<std::pair<GpuMat, GpuMat> >& forwardMotions, const std::vector<std::pair<GpuMat, GpuMat> >& backwardMotions,
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int baseIdx)
{
CV_Assert( scale_ > 1 );
CV_Assert( iterations_ > 0 );
CV_Assert( tau_ > 0.0 );
CV_Assert( alpha_ > 0.0 );
CV_Assert( btvKernelSize_ > 0 && btvKernelSize_ <= 16 );
CV_Assert( blurKernelSize_ > 0 );
CV_Assert( blurSigma_ >= 0.0 );
// update blur filter and btv weights
if (filters_.size() != src.size() || blurKernelSize_ != curBlurKernelSize_ || blurSigma_ != curBlurSigma_ || src[0].type() != curSrcType_)
{
filters_.resize(src.size());
for (size_t i = 0; i < src.size(); ++i)
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filters_[i] = cuda::createGaussianFilter(src[0].type(), -1, Size(blurKernelSize_, blurKernelSize_), blurSigma_);
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curBlurKernelSize_ = blurKernelSize_;
curBlurSigma_ = blurSigma_;
curSrcType_ = src[0].type();
}
if (btvWeights_.empty() || btvKernelSize_ != curBtvKernelSize_ || alpha_ != curAlpha_)
{
calcBtvWeights(btvKernelSize_, alpha_, btvWeights_);
curBtvKernelSize_ = btvKernelSize_;
curAlpha_ = alpha_;
}
// calc motions between input frames
calcRelativeMotions(forwardMotions, backwardMotions, lowResForwardMotions_, lowResBackwardMotions_, baseIdx, src[0].size());
upscaleMotions(lowResForwardMotions_, highResForwardMotions_, scale_);
upscaleMotions(lowResBackwardMotions_, highResBackwardMotions_, scale_);
forwardMaps_.resize(highResForwardMotions_.size());
backwardMaps_.resize(highResForwardMotions_.size());
for (size_t i = 0; i < highResForwardMotions_.size(); ++i)
buildMotionMaps(highResForwardMotions_[i], highResBackwardMotions_[i], forwardMaps_[i], backwardMaps_[i]);
// initial estimation
const Size lowResSize = src[0].size();
const Size highResSize(lowResSize.width * scale_, lowResSize.height * scale_);
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cuda::resize(src[baseIdx], highRes_, highResSize, 0, 0, INTER_CUBIC);
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// iterations
streams_.resize(src.size());
diffTerms_.resize(src.size());
a_.resize(src.size());
b_.resize(src.size());
c_.resize(src.size());
for (int i = 0; i < iterations_; ++i)
{
for (size_t k = 0; k < src.size(); ++k)
{
// a = M * Ih
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cuda::remap(highRes_, a_[k], backwardMaps_[k].first, backwardMaps_[k].second, INTER_NEAREST, BORDER_REPLICATE, Scalar(), streams_[k]);
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// b = HM * Ih
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filters_[k]->apply(a_[k], b_[k], streams_[k]);
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// c = DHF * Ih
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cuda::resize(b_[k], c_[k], lowResSize, 0, 0, INTER_NEAREST, streams_[k]);
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diffSign(src[k], c_[k], c_[k], streams_[k]);
// a = Dt * diff
upscale(c_[k], a_[k], scale_, streams_[k]);
// b = HtDt * diff
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filters_[k]->apply(a_[k], b_[k], streams_[k]);
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// diffTerm = MtHtDt * diff
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cuda::remap(b_[k], diffTerms_[k], forwardMaps_[k].first, forwardMaps_[k].second, INTER_NEAREST, BORDER_REPLICATE, Scalar(), streams_[k]);
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}
if (lambda_ > 0)
{
calcBtvRegularization(highRes_, regTerm_, btvKernelSize_);
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cuda::addWeighted(highRes_, 1.0, regTerm_, -tau_ * lambda_, 0.0, highRes_);
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}
for (size_t k = 0; k < src.size(); ++k)
{
streams_[k].waitForCompletion();
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cuda::addWeighted(highRes_, 1.0, diffTerms_[k], tau_, 0.0, highRes_);
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}
}
Rect inner(btvKernelSize_, btvKernelSize_, highRes_.cols - 2 * btvKernelSize_, highRes_.rows - 2 * btvKernelSize_);
highRes_(inner).copyTo(dst);
}
void BTVL1_GPU_Base::collectGarbage()
{
filters_.clear();
lowResForwardMotions_.clear();
lowResBackwardMotions_.clear();
highResForwardMotions_.clear();
highResBackwardMotions_.clear();
forwardMaps_.clear();
backwardMaps_.clear();
highRes_.release();
diffTerms_.clear();
a_.clear();
b_.clear();
c_.clear();
regTerm_.release();
}
////////////////////////////////////////////////////////////
class BTVL1_GPU : public SuperResolution, private BTVL1_GPU_Base
{
public:
AlgorithmInfo* info() const;
BTVL1_GPU();
void collectGarbage();
protected:
void initImpl(Ptr<FrameSource>& frameSource);
void processImpl(Ptr<FrameSource>& frameSource, OutputArray output);
private:
int temporalAreaRadius_;
void readNextFrame(Ptr<FrameSource>& frameSource);
void processFrame(int idx);
GpuMat curFrame_;
GpuMat prevFrame_;
std::vector<GpuMat> frames_;
std::vector<std::pair<GpuMat, GpuMat> > forwardMotions_;
std::vector<std::pair<GpuMat, GpuMat> > backwardMotions_;
std::vector<GpuMat> outputs_;
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int storePos_;
int procPos_;
int outPos_;
std::vector<GpuMat> srcFrames_;
std::vector<std::pair<GpuMat, GpuMat> > srcForwardMotions_;
std::vector<std::pair<GpuMat, GpuMat> > srcBackwardMotions_;
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GpuMat finalOutput_;
};
CV_INIT_ALGORITHM(BTVL1_GPU, "SuperResolution.BTVL1_GPU",
obj.info()->addParam(obj, "scale", obj.scale_, false, 0, 0, "Scale factor.");
obj.info()->addParam(obj, "iterations", obj.iterations_, false, 0, 0, "Iteration count.");
obj.info()->addParam(obj, "tau", obj.tau_, false, 0, 0, "Asymptotic value of steepest descent method.");
obj.info()->addParam(obj, "lambda", obj.lambda_, false, 0, 0, "Weight parameter to balance data term and smoothness term.");
obj.info()->addParam(obj, "alpha", obj.alpha_, false, 0, 0, "Parameter of spacial distribution in Bilateral-TV.");
obj.info()->addParam(obj, "btvKernelSize", obj.btvKernelSize_, false, 0, 0, "Kernel size of Bilateral-TV filter.");
obj.info()->addParam(obj, "blurKernelSize", obj.blurKernelSize_, false, 0, 0, "Gaussian blur kernel size.");
obj.info()->addParam(obj, "blurSigma", obj.blurSigma_, false, 0, 0, "Gaussian blur sigma.");
obj.info()->addParam(obj, "temporalAreaRadius", obj.temporalAreaRadius_, false, 0, 0, "Radius of the temporal search area.");
obj.info()->addParam<DenseOpticalFlowExt>(obj, "opticalFlow", obj.opticalFlow_, false, 0, 0, "Dense optical flow algorithm."));
BTVL1_GPU::BTVL1_GPU()
{
temporalAreaRadius_ = 4;
}
void BTVL1_GPU::collectGarbage()
{
curFrame_.release();
prevFrame_.release();
frames_.clear();
forwardMotions_.clear();
backwardMotions_.clear();
outputs_.clear();
srcFrames_.clear();
srcForwardMotions_.clear();
srcBackwardMotions_.clear();
finalOutput_.release();
SuperResolution::collectGarbage();
BTVL1_GPU_Base::collectGarbage();
}
void BTVL1_GPU::initImpl(Ptr<FrameSource>& frameSource)
{
const int cacheSize = 2 * temporalAreaRadius_ + 1;
frames_.resize(cacheSize);
forwardMotions_.resize(cacheSize);
backwardMotions_.resize(cacheSize);
outputs_.resize(cacheSize);
storePos_ = -1;
for (int t = -temporalAreaRadius_; t <= temporalAreaRadius_; ++t)
readNextFrame(frameSource);
for (int i = 0; i <= temporalAreaRadius_; ++i)
processFrame(i);
procPos_ = temporalAreaRadius_;
outPos_ = -1;
}
void BTVL1_GPU::processImpl(Ptr<FrameSource>& frameSource, OutputArray _output)
{
if (outPos_ >= storePos_)
{
_output.release();
return;
}
readNextFrame(frameSource);
if (procPos_ < storePos_)
{
++procPos_;
processFrame(procPos_);
}
++outPos_;
const GpuMat& curOutput = at(outPos_, outputs_);
if (_output.kind() == _InputArray::GPU_MAT)
curOutput.convertTo(_output.getGpuMatRef(), CV_8U);
else
{
curOutput.convertTo(finalOutput_, CV_8U);
arrCopy(finalOutput_, _output);
}
}
void BTVL1_GPU::readNextFrame(Ptr<FrameSource>& frameSource)
{
frameSource->nextFrame(curFrame_);
if (curFrame_.empty())
return;
++storePos_;
curFrame_.convertTo(at(storePos_, frames_), CV_32F);
if (storePos_ > 0)
{
std::pair<GpuMat, GpuMat>& forwardMotion = at(storePos_ - 1, forwardMotions_);
std::pair<GpuMat, GpuMat>& backwardMotion = at(storePos_, backwardMotions_);
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opticalFlow_->calc(prevFrame_, curFrame_, forwardMotion.first, forwardMotion.second);
opticalFlow_->calc(curFrame_, prevFrame_, backwardMotion.first, backwardMotion.second);
}
curFrame_.copyTo(prevFrame_);
}
void BTVL1_GPU::processFrame(int idx)
{
const int startIdx = std::max(idx - temporalAreaRadius_, 0);
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const int procIdx = idx;
const int endIdx = std::min(startIdx + 2 * temporalAreaRadius_, storePos_);
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const int count = endIdx - startIdx + 1;
srcFrames_.resize(count);
srcForwardMotions_.resize(count);
srcBackwardMotions_.resize(count);
int baseIdx = -1;
for (int i = startIdx, k = 0; i <= endIdx; ++i, ++k)
{
if (i == procIdx)
baseIdx = k;
srcFrames_[k] = at(i, frames_);
if (i < endIdx)
srcForwardMotions_[k] = at(i, forwardMotions_);
if (i > startIdx)
srcBackwardMotions_[k] = at(i, backwardMotions_);
}
process(srcFrames_, at(idx, outputs_), srcForwardMotions_, srcBackwardMotions_, baseIdx);
}
}
Ptr<SuperResolution> cv::superres::createSuperResolution_BTVL1_GPU()
{
return new BTVL1_GPU;
}
#endif // HAVE_CUDA