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678 lines
21 KiB
C++
678 lines
21 KiB
C++
/*M///////////////////////////////////////////////////////////////////////////////////////
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//
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// IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING.
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//
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// By downloading, copying, installing or using the software you agree to this license.
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// If you do not agree to this license, do not download, install,
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// copy or use the software.
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//
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//
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// Intel License Agreement
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// For Open Source Computer Vision Library
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//
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// Copyright( C) 2000, Intel Corporation, all rights reserved.
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// Third party copyrights are property of their respective owners.
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//
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// Redistribution and use in source and binary forms, with or without modification,
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// are permitted provided that the following conditions are met:
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//
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// * Redistribution's of source code must retain the above copyright notice,
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// this list of conditions and the following disclaimer.
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//
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// * Redistribution's in binary form must reproduce the above copyright notice,
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// this list of conditions and the following disclaimer in the documentation
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// and/or other materials provided with the distribution.
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//
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// * The name of Intel Corporation may not be used to endorse or promote products
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// derived from this software without specific prior written permission.
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//
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// This software is provided by the copyright holders and contributors "as is" and
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// any express or implied warranties, including, but not limited to, the implied
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// warranties of merchantability and fitness for a particular purpose are disclaimed.
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// In no event shall the Intel Corporation or contributors be liable for any direct,
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// indirect, incidental, special, exemplary, or consequential damages
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//(including, but not limited to, procurement of substitute goods or services;
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// loss of use, data, or profits; or business interruption) however caused
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// and on any theory of liability, whether in contract, strict liability,
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// or tort(including negligence or otherwise) arising in any way out of
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// the use of this software, even ifadvised of the possibility of such damage.
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//
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//M*/
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#include "precomp.hpp"
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namespace cv
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{
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const double minEigenValue = DBL_EPSILON;
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///////////////////////////////////////////////////////////////////////////////////////////////////////
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EM::EM(int _nclusters, int _covMatType, const TermCriteria& _termCrit)
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{
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nclusters = _nclusters;
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covMatType = _covMatType;
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maxIters = (_termCrit.type & TermCriteria::MAX_ITER) ? _termCrit.maxCount : DEFAULT_MAX_ITERS;
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epsilon = (_termCrit.type & TermCriteria::EPS) ? _termCrit.epsilon : 0;
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}
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EM::~EM()
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{
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//clear();
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}
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void EM::clear()
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{
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trainSamples.release();
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trainProbs.release();
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trainLogLikelihoods.release();
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trainLabels.release();
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weights.release();
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means.release();
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covs.clear();
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covsEigenValues.clear();
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invCovsEigenValues.clear();
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covsRotateMats.clear();
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logWeightDivDet.release();
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}
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bool EM::train(InputArray samples,
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OutputArray logLikelihoods,
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OutputArray labels,
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OutputArray probs)
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{
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Mat samplesMat = samples.getMat();
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setTrainData(START_AUTO_STEP, samplesMat, 0, 0, 0, 0);
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return doTrain(START_AUTO_STEP, logLikelihoods, labels, probs);
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}
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bool EM::trainE(InputArray samples,
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InputArray _means0,
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InputArray _covs0,
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InputArray _weights0,
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OutputArray logLikelihoods,
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OutputArray labels,
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OutputArray probs)
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{
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Mat samplesMat = samples.getMat();
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vector<Mat> covs0;
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_covs0.getMatVector(covs0);
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Mat means0 = _means0.getMat(), weights0 = _weights0.getMat();
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setTrainData(START_E_STEP, samplesMat, 0, !_means0.empty() ? &means0 : 0,
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!_covs0.empty() ? &covs0 : 0, !_weights0.empty() ? &weights0 : 0);
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return doTrain(START_E_STEP, logLikelihoods, labels, probs);
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}
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bool EM::trainM(InputArray samples,
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InputArray _probs0,
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OutputArray logLikelihoods,
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OutputArray labels,
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OutputArray probs)
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{
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Mat samplesMat = samples.getMat();
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Mat probs0 = _probs0.getMat();
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setTrainData(START_M_STEP, samplesMat, !_probs0.empty() ? &probs0 : 0, 0, 0, 0);
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return doTrain(START_M_STEP, logLikelihoods, labels, probs);
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}
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Vec2d EM::predict(InputArray _sample, OutputArray _probs) const
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{
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Mat sample = _sample.getMat();
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CV_Assert(isTrained());
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CV_Assert(!sample.empty());
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if(sample.type() != CV_64FC1)
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{
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Mat tmp;
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sample.convertTo(tmp, CV_64FC1);
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sample = tmp;
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}
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sample.reshape(1, 1);
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Mat probs;
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if( _probs.needed() )
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{
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_probs.create(1, nclusters, CV_64FC1);
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probs = _probs.getMat();
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}
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return computeProbabilities(sample, !probs.empty() ? &probs : 0);
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}
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bool EM::isTrained() const
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{
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return !means.empty();
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}
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static
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void checkTrainData(int startStep, const Mat& samples,
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int nclusters, int covMatType, const Mat* probs, const Mat* means,
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const vector<Mat>* covs, const Mat* weights)
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{
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// Check samples.
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CV_Assert(!samples.empty());
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CV_Assert(samples.channels() == 1);
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int nsamples = samples.rows;
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int dim = samples.cols;
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// Check training params.
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CV_Assert(nclusters > 0);
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CV_Assert(nclusters <= nsamples);
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CV_Assert(startStep == EM::START_AUTO_STEP ||
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startStep == EM::START_E_STEP ||
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startStep == EM::START_M_STEP);
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CV_Assert(covMatType == EM::COV_MAT_GENERIC ||
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covMatType == EM::COV_MAT_DIAGONAL ||
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covMatType == EM::COV_MAT_SPHERICAL);
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CV_Assert(!probs ||
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(!probs->empty() &&
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probs->rows == nsamples && probs->cols == nclusters &&
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(probs->type() == CV_32FC1 || probs->type() == CV_64FC1)));
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CV_Assert(!weights ||
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(!weights->empty() &&
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(weights->cols == 1 || weights->rows == 1) && static_cast<int>(weights->total()) == nclusters &&
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(weights->type() == CV_32FC1 || weights->type() == CV_64FC1)));
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CV_Assert(!means ||
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(!means->empty() &&
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means->rows == nclusters && means->cols == dim &&
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means->channels() == 1));
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CV_Assert(!covs ||
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(!covs->empty() &&
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static_cast<int>(covs->size()) == nclusters));
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if(covs)
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{
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const Size covSize(dim, dim);
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for(size_t i = 0; i < covs->size(); i++)
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{
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const Mat& m = (*covs)[i];
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CV_Assert(!m.empty() && m.size() == covSize && (m.channels() == 1));
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}
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}
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if(startStep == EM::START_E_STEP)
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{
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CV_Assert(means);
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}
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else if(startStep == EM::START_M_STEP)
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{
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CV_Assert(probs);
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}
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}
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static
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void preprocessSampleData(const Mat& src, Mat& dst, int dstType, bool isAlwaysClone)
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{
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if(src.type() == dstType && !isAlwaysClone)
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dst = src;
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else
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src.convertTo(dst, dstType);
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}
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static
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void preprocessProbability(Mat& probs)
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{
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max(probs, 0., probs);
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const double uniformProbability = (double)(1./probs.cols);
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for(int y = 0; y < probs.rows; y++)
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{
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Mat sampleProbs = probs.row(y);
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double maxVal = 0;
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minMaxLoc(sampleProbs, 0, &maxVal);
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if(maxVal < FLT_EPSILON)
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sampleProbs.setTo(uniformProbability);
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else
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normalize(sampleProbs, sampleProbs, 1, 0, NORM_L1);
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}
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}
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void EM::setTrainData(int startStep, const Mat& samples,
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const Mat* probs0,
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const Mat* means0,
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const vector<Mat>* covs0,
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const Mat* weights0)
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{
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clear();
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checkTrainData(startStep, samples, nclusters, covMatType, probs0, means0, covs0, weights0);
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bool isKMeansInit = (startStep == EM::START_AUTO_STEP) || (startStep == EM::START_E_STEP && (covs0 == 0 || weights0 == 0));
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// Set checked data
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preprocessSampleData(samples, trainSamples, isKMeansInit ? CV_32FC1 : CV_64FC1, false);
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// set probs
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if(probs0 && startStep == EM::START_M_STEP)
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{
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preprocessSampleData(*probs0, trainProbs, CV_64FC1, true);
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preprocessProbability(trainProbs);
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}
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// set weights
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if(weights0 && (startStep == EM::START_E_STEP && covs0))
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{
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weights0->convertTo(weights, CV_64FC1);
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weights.reshape(1,1);
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preprocessProbability(weights);
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}
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// set means
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if(means0 && (startStep == EM::START_E_STEP/* || startStep == EM::START_AUTO_STEP*/))
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means0->convertTo(means, isKMeansInit ? CV_32FC1 : CV_64FC1);
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// set covs
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if(covs0 && (startStep == EM::START_E_STEP && weights0))
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{
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covs.resize(nclusters);
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for(size_t i = 0; i < covs0->size(); i++)
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(*covs0)[i].convertTo(covs[i], CV_64FC1);
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}
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}
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void EM::decomposeCovs()
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{
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CV_Assert(!covs.empty());
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covsEigenValues.resize(nclusters);
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if(covMatType == EM::COV_MAT_GENERIC)
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covsRotateMats.resize(nclusters);
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invCovsEigenValues.resize(nclusters);
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for(int clusterIndex = 0; clusterIndex < nclusters; clusterIndex++)
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{
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CV_Assert(!covs[clusterIndex].empty());
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SVD svd(covs[clusterIndex], SVD::MODIFY_A + SVD::FULL_UV);
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if(covMatType == EM::COV_MAT_SPHERICAL)
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{
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double maxSingularVal = svd.w.at<double>(0);
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covsEigenValues[clusterIndex] = Mat(1, 1, CV_64FC1, Scalar(maxSingularVal));
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}
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else if(covMatType == EM::COV_MAT_DIAGONAL)
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{
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covsEigenValues[clusterIndex] = svd.w;
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}
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else //EM::COV_MAT_GENERIC
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{
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covsEigenValues[clusterIndex] = svd.w;
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covsRotateMats[clusterIndex] = svd.u;
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}
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max(covsEigenValues[clusterIndex], minEigenValue, covsEigenValues[clusterIndex]);
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invCovsEigenValues[clusterIndex] = 1./covsEigenValues[clusterIndex];
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}
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}
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void EM::clusterTrainSamples()
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{
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int nsamples = trainSamples.rows;
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// Cluster samples, compute/update means
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// Convert samples and means to 32F, because kmeans requires this type.
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Mat trainSamplesFlt, meansFlt;
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if(trainSamples.type() != CV_32FC1)
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trainSamples.convertTo(trainSamplesFlt, CV_32FC1);
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else
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trainSamplesFlt = trainSamples;
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if(!means.empty())
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{
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if(means.type() != CV_32FC1)
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means.convertTo(meansFlt, CV_32FC1);
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else
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meansFlt = means;
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}
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Mat labels;
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kmeans(trainSamplesFlt, nclusters, labels, TermCriteria(TermCriteria::COUNT, means.empty() ? 10 : 1, 0.5), 10, KMEANS_PP_CENTERS, meansFlt);
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// Convert samples and means back to 64F.
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CV_Assert(meansFlt.type() == CV_32FC1);
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if(trainSamples.type() != CV_64FC1)
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{
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Mat trainSamplesBuffer;
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trainSamplesFlt.convertTo(trainSamplesBuffer, CV_64FC1);
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trainSamples = trainSamplesBuffer;
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}
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meansFlt.convertTo(means, CV_64FC1);
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// Compute weights and covs
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weights = Mat(1, nclusters, CV_64FC1, Scalar(0));
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covs.resize(nclusters);
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for(int clusterIndex = 0; clusterIndex < nclusters; clusterIndex++)
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{
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Mat clusterSamples;
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for(int sampleIndex = 0; sampleIndex < nsamples; sampleIndex++)
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{
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if(labels.at<int>(sampleIndex) == clusterIndex)
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{
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const Mat sample = trainSamples.row(sampleIndex);
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clusterSamples.push_back(sample);
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}
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}
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CV_Assert(!clusterSamples.empty());
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calcCovarMatrix(clusterSamples, covs[clusterIndex], means.row(clusterIndex),
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CV_COVAR_NORMAL + CV_COVAR_ROWS + CV_COVAR_USE_AVG + CV_COVAR_SCALE, CV_64FC1);
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weights.at<double>(clusterIndex) = static_cast<double>(clusterSamples.rows)/static_cast<double>(nsamples);
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}
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decomposeCovs();
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}
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void EM::computeLogWeightDivDet()
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{
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CV_Assert(!covsEigenValues.empty());
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Mat logWeights;
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cv::max(weights, DBL_MIN, weights);
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log(weights, logWeights);
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logWeightDivDet.create(1, nclusters, CV_64FC1);
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// note: logWeightDivDet = log(weight_k) - 0.5 * log(|det(cov_k)|)
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for(int clusterIndex = 0; clusterIndex < nclusters; clusterIndex++)
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{
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double logDetCov = 0.;
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const int evalCount = static_cast<int>(covsEigenValues[clusterIndex].total());
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for(int di = 0; di < evalCount; di++)
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logDetCov += std::log(covsEigenValues[clusterIndex].at<double>(covMatType != EM::COV_MAT_SPHERICAL ? di : 0));
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logWeightDivDet.at<double>(clusterIndex) = logWeights.at<double>(clusterIndex) - 0.5 * logDetCov;
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}
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}
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bool EM::doTrain(int startStep, OutputArray logLikelihoods, OutputArray labels, OutputArray probs)
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{
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int dim = trainSamples.cols;
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// Precompute the empty initial train data in the cases of EM::START_E_STEP and START_AUTO_STEP
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if(startStep != EM::START_M_STEP)
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{
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if(covs.empty())
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{
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CV_Assert(weights.empty());
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clusterTrainSamples();
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}
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}
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if(!covs.empty() && covsEigenValues.empty() )
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{
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CV_Assert(invCovsEigenValues.empty());
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decomposeCovs();
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}
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if(startStep == EM::START_M_STEP)
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mStep();
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double trainLogLikelihood, prevTrainLogLikelihood = 0.;
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for(int iter = 0; ; iter++)
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{
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eStep();
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trainLogLikelihood = sum(trainLogLikelihoods)[0];
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if(iter >= maxIters - 1)
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break;
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double trainLogLikelihoodDelta = trainLogLikelihood - prevTrainLogLikelihood;
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if( iter != 0 &&
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(trainLogLikelihoodDelta < -DBL_EPSILON ||
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trainLogLikelihoodDelta < epsilon * std::fabs(trainLogLikelihood)))
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break;
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mStep();
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prevTrainLogLikelihood = trainLogLikelihood;
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}
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if( trainLogLikelihood <= -DBL_MAX/10000. )
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{
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clear();
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return false;
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}
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// postprocess covs
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covs.resize(nclusters);
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for(int clusterIndex = 0; clusterIndex < nclusters; clusterIndex++)
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{
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if(covMatType == EM::COV_MAT_SPHERICAL)
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{
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covs[clusterIndex].create(dim, dim, CV_64FC1);
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setIdentity(covs[clusterIndex], Scalar(covsEigenValues[clusterIndex].at<double>(0)));
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}
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else if(covMatType == EM::COV_MAT_DIAGONAL)
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{
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covs[clusterIndex] = Mat::diag(covsEigenValues[clusterIndex]);
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}
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}
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if(labels.needed())
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trainLabels.copyTo(labels);
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if(probs.needed())
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trainProbs.copyTo(probs);
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if(logLikelihoods.needed())
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trainLogLikelihoods.copyTo(logLikelihoods);
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trainSamples.release();
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trainProbs.release();
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trainLabels.release();
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trainLogLikelihoods.release();
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return true;
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}
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Vec2d EM::computeProbabilities(const Mat& sample, Mat* probs) const
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{
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// L_ik = log(weight_k) - 0.5 * log(|det(cov_k)|) - 0.5 *(x_i - mean_k)' cov_k^(-1) (x_i - mean_k)]
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// q = arg(max_k(L_ik))
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// probs_ik = exp(L_ik - L_iq) / (1 + sum_j!=q (exp(L_ij - L_iq))
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// see Alex Smola's blog http://blog.smola.org/page/2 for
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// details on the log-sum-exp trick
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CV_Assert(!means.empty());
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CV_Assert(sample.type() == CV_64FC1);
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CV_Assert(sample.rows == 1);
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CV_Assert(sample.cols == means.cols);
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int dim = sample.cols;
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Mat L(1, nclusters, CV_64FC1);
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int label = 0;
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for(int clusterIndex = 0; clusterIndex < nclusters; clusterIndex++)
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{
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const Mat centeredSample = sample - means.row(clusterIndex);
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Mat rotatedCenteredSample = covMatType != EM::COV_MAT_GENERIC ?
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centeredSample : centeredSample * covsRotateMats[clusterIndex];
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double Lval = 0;
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for(int di = 0; di < dim; di++)
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{
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double w = invCovsEigenValues[clusterIndex].at<double>(covMatType != EM::COV_MAT_SPHERICAL ? di : 0);
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double val = rotatedCenteredSample.at<double>(di);
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Lval += w * val * val;
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}
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CV_DbgAssert(!logWeightDivDet.empty());
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L.at<double>(clusterIndex) = logWeightDivDet.at<double>(clusterIndex) - 0.5 * Lval;
|
|
|
|
if(L.at<double>(clusterIndex) > L.at<double>(label))
|
|
label = clusterIndex;
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|
}
|
|
|
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double maxLVal = L.at<double>(label);
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Mat expL_Lmax = L; // exp(L_ij - L_iq)
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|
for(int i = 0; i < L.cols; i++)
|
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expL_Lmax.at<double>(i) = std::exp(L.at<double>(i) - maxLVal);
|
|
double expDiffSum = sum(expL_Lmax)[0]; // sum_j(exp(L_ij - L_iq))
|
|
|
|
if(probs)
|
|
{
|
|
probs->create(1, nclusters, CV_64FC1);
|
|
double factor = 1./expDiffSum;
|
|
expL_Lmax *= factor;
|
|
expL_Lmax.copyTo(*probs);
|
|
}
|
|
|
|
Vec2d res;
|
|
res[0] = std::log(expDiffSum) + maxLVal - 0.5 * dim * CV_LOG2PI;
|
|
res[1] = label;
|
|
|
|
return res;
|
|
}
|
|
|
|
void EM::eStep()
|
|
{
|
|
// Compute probs_ik from means_k, covs_k and weights_k.
|
|
trainProbs.create(trainSamples.rows, nclusters, CV_64FC1);
|
|
trainLabels.create(trainSamples.rows, 1, CV_32SC1);
|
|
trainLogLikelihoods.create(trainSamples.rows, 1, CV_64FC1);
|
|
|
|
computeLogWeightDivDet();
|
|
|
|
CV_DbgAssert(trainSamples.type() == CV_64FC1);
|
|
CV_DbgAssert(means.type() == CV_64FC1);
|
|
|
|
for(int sampleIndex = 0; sampleIndex < trainSamples.rows; sampleIndex++)
|
|
{
|
|
Mat sampleProbs = trainProbs.row(sampleIndex);
|
|
Vec2d res = computeProbabilities(trainSamples.row(sampleIndex), &sampleProbs);
|
|
trainLogLikelihoods.at<double>(sampleIndex) = res[0];
|
|
trainLabels.at<int>(sampleIndex) = static_cast<int>(res[1]);
|
|
}
|
|
}
|
|
|
|
void EM::mStep()
|
|
{
|
|
// Update means_k, covs_k and weights_k from probs_ik
|
|
int dim = trainSamples.cols;
|
|
|
|
// Update weights
|
|
// not normalized first
|
|
reduce(trainProbs, weights, 0, CV_REDUCE_SUM);
|
|
|
|
// Update means
|
|
means.create(nclusters, dim, CV_64FC1);
|
|
means = Scalar(0);
|
|
|
|
const double minPosWeight = trainSamples.rows * DBL_EPSILON;
|
|
double minWeight = DBL_MAX;
|
|
int minWeightClusterIndex = -1;
|
|
for(int clusterIndex = 0; clusterIndex < nclusters; clusterIndex++)
|
|
{
|
|
if(weights.at<double>(clusterIndex) <= minPosWeight)
|
|
continue;
|
|
|
|
if(weights.at<double>(clusterIndex) < minWeight)
|
|
{
|
|
minWeight = weights.at<double>(clusterIndex);
|
|
minWeightClusterIndex = clusterIndex;
|
|
}
|
|
|
|
Mat clusterMean = means.row(clusterIndex);
|
|
for(int sampleIndex = 0; sampleIndex < trainSamples.rows; sampleIndex++)
|
|
clusterMean += trainProbs.at<double>(sampleIndex, clusterIndex) * trainSamples.row(sampleIndex);
|
|
clusterMean /= weights.at<double>(clusterIndex);
|
|
}
|
|
|
|
// Update covsEigenValues and invCovsEigenValues
|
|
covs.resize(nclusters);
|
|
covsEigenValues.resize(nclusters);
|
|
if(covMatType == EM::COV_MAT_GENERIC)
|
|
covsRotateMats.resize(nclusters);
|
|
invCovsEigenValues.resize(nclusters);
|
|
for(int clusterIndex = 0; clusterIndex < nclusters; clusterIndex++)
|
|
{
|
|
if(weights.at<double>(clusterIndex) <= minPosWeight)
|
|
continue;
|
|
|
|
if(covMatType != EM::COV_MAT_SPHERICAL)
|
|
covsEigenValues[clusterIndex].create(1, dim, CV_64FC1);
|
|
else
|
|
covsEigenValues[clusterIndex].create(1, 1, CV_64FC1);
|
|
|
|
if(covMatType == EM::COV_MAT_GENERIC)
|
|
covs[clusterIndex].create(dim, dim, CV_64FC1);
|
|
|
|
Mat clusterCov = covMatType != EM::COV_MAT_GENERIC ?
|
|
covsEigenValues[clusterIndex] : covs[clusterIndex];
|
|
|
|
clusterCov = Scalar(0);
|
|
|
|
Mat centeredSample;
|
|
for(int sampleIndex = 0; sampleIndex < trainSamples.rows; sampleIndex++)
|
|
{
|
|
centeredSample = trainSamples.row(sampleIndex) - means.row(clusterIndex);
|
|
|
|
if(covMatType == EM::COV_MAT_GENERIC)
|
|
clusterCov += trainProbs.at<double>(sampleIndex, clusterIndex) * centeredSample.t() * centeredSample;
|
|
else
|
|
{
|
|
double p = trainProbs.at<double>(sampleIndex, clusterIndex);
|
|
for(int di = 0; di < dim; di++ )
|
|
{
|
|
double val = centeredSample.at<double>(di);
|
|
clusterCov.at<double>(covMatType != EM::COV_MAT_SPHERICAL ? di : 0) += p*val*val;
|
|
}
|
|
}
|
|
}
|
|
|
|
if(covMatType == EM::COV_MAT_SPHERICAL)
|
|
clusterCov /= dim;
|
|
|
|
clusterCov /= weights.at<double>(clusterIndex);
|
|
|
|
// Update covsRotateMats for EM::COV_MAT_GENERIC only
|
|
if(covMatType == EM::COV_MAT_GENERIC)
|
|
{
|
|
SVD svd(covs[clusterIndex], SVD::MODIFY_A + SVD::FULL_UV);
|
|
covsEigenValues[clusterIndex] = svd.w;
|
|
covsRotateMats[clusterIndex] = svd.u;
|
|
}
|
|
|
|
max(covsEigenValues[clusterIndex], minEigenValue, covsEigenValues[clusterIndex]);
|
|
|
|
// update invCovsEigenValues
|
|
invCovsEigenValues[clusterIndex] = 1./covsEigenValues[clusterIndex];
|
|
}
|
|
|
|
for(int clusterIndex = 0; clusterIndex < nclusters; clusterIndex++)
|
|
{
|
|
if(weights.at<double>(clusterIndex) <= minPosWeight)
|
|
{
|
|
Mat clusterMean = means.row(clusterIndex);
|
|
means.row(minWeightClusterIndex).copyTo(clusterMean);
|
|
covs[minWeightClusterIndex].copyTo(covs[clusterIndex]);
|
|
covsEigenValues[minWeightClusterIndex].copyTo(covsEigenValues[clusterIndex]);
|
|
if(covMatType == EM::COV_MAT_GENERIC)
|
|
covsRotateMats[minWeightClusterIndex].copyTo(covsRotateMats[clusterIndex]);
|
|
invCovsEigenValues[minWeightClusterIndex].copyTo(invCovsEigenValues[clusterIndex]);
|
|
}
|
|
}
|
|
|
|
// Normalize weights
|
|
weights /= trainSamples.rows;
|
|
}
|
|
|
|
void EM::read(const FileNode& fn)
|
|
{
|
|
Algorithm::read(fn);
|
|
|
|
decomposeCovs();
|
|
computeLogWeightDivDet();
|
|
}
|
|
|
|
} // namespace cv
|
|
|
|
/* End of file. */
|