183 lines
7.6 KiB
C++
183 lines
7.6 KiB
C++
#include "AbstractionLayer_SURFFeatures.h"
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// Parameters for algorithm:
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// maxCorners – The maximum number of corners to return. If there are more corners than that will be found, the strongest of them will be returned
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// qualityLevel – Characterizes the minimal accepted quality of image corners;
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// minDistance – The minimum possible Euclidean distance between the returned corners
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// mask – The optional region of interest. It will specify the region in which the corners are detected
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// blockSize – Size of the averaging block for computing derivative covariation
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// useHarrisDetector – Indicates, whether to use operator or cornerMinEigenVal()
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// k – Free parameter of Harris detector
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#include <iostream>
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#include "opencv2/highgui/highgui.hpp"
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#include "opencv2/imgproc/imgproc.hpp"
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using namespace cv;
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using namespace std;
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bool AbstractionLayer_SURFFeatures::PreProcessing(coor mySize, const vector<Part*>* partArray)
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{
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cout << "Abstraction 4 (Features) Preprocessing... " << flush;
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InitialiseConstraintMatrixSize(mySize.col, mySize.row);
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if(!PreProcessingFullImg(mySize)) return false;
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if(!PreProcessingPieces(mySize, partArray)) return false;
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return true;
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}
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bool AbstractionLayer_SURFFeatures::EvaluateQuality (coor constraintCoordinate, qualityVector& qVector)
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{
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// Calculate absolute difference between constraints and each piece and safe it
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for( int i = 0; i < qVector.size(); i++ )
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{
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float diff = abs(m_constraintMatrix[constraintCoordinate.row][constraintCoordinate.col].m_numberOfFeaturesDetected - qVector[i].second->m_a4.m_numberOfFeaturesDetected);
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qVector[i].first = 1 - diff;
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//cout << fixed << qVector[i].first << endl;
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}
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return true;
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}
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bool AbstractionLayer_SURFFeatures::SetConstraintOnPosition(const coor constraintCoordinate, const AbstractionLayer_SURFFeatures_Properties constraint)
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{
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//TODO: Benötigen wir nicht unbedint.
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//TODO: Hier erhalten wir vom Dispatcher welches Teil an welche Position gesetzt wird und wir könnten hier die Features des Bilds in die m_constraintMatrix speichern
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return true;
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}
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bool AbstractionLayer_SURFFeatures::RemoveConstraintOnPosition(const coor constraintCoordinate)
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{
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//TODO: Wie auch beim SetConstraint sollte uns das hier nicht wirklich interessieren.
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//TODO: Außer wir setzen etwas in die Contraintmatrix.
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//TODO: Dann ruft uns der Dispatcher beim Backtrack hier auf und wir müssten das jeweilige PuzzlePart hier wieder rauslöschen.
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return true;
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}
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bool AbstractionLayer_SURFFeatures::PreProcessingFullImg(coor mySize)
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{
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std::vector< cv::Point2f > corners; // Variable to store corner-positions at
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// Load and resize image, so that number of parts in row and col fit in
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Mat image = imread(PATH_FULL_PUZZLE, IMREAD_GRAYSCALE);
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if (!image.data) {
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cerr << "Problem loading image of complete puzzle!" << endl;
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return false;
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}
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//cout << "PRE: " << image.cols << " x " << image.rows << endl;
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resize(image, image, Size(int(ceil(double(image.cols)/mySize.col)*mySize.col), int(ceil(double(image.rows)/mySize.row)*mySize.row)));
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//cout << "POST: " << image.cols << " x " << image.rows << endl;
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// PARAMETERS (for description see top of file)
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int maxCorners = 10000;
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double qualityLevel = 0.01;
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double minDistance = .5;
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Mat mask;
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int blockSize = 3;
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bool useHarrisDetector = false;
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double k = 0.04;
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// Detect features - this is where the magic happens
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goodFeaturesToTrack( image, corners, maxCorners, qualityLevel, minDistance, mask, blockSize, useHarrisDetector, k );
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// Empty the matrix
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for( int j = 0; j < mySize.row ; j++ )
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{ for( int i = 0; i < mySize.col; i++ )
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{
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m_constraintMatrix[j][i].m_numberOfFeaturesDetected = 0;
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}
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}
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int pieceColSize = image.cols/mySize.col;
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int pieceRowSize = image.rows/mySize.row;
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// Calculate number of features for each piece-position
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for( int i = 0; i < corners.size(); i++ ) // For all found features
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{
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// Increment number of found pieces
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m_constraintMatrix[int(corners[i].y/pieceRowSize)][int(corners[i].x/pieceColSize)].m_numberOfFeaturesDetected++;
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}
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// Get minimal and maximal number of features -> TODO: Do in first loop to safe time?
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int minFeatures = int(m_constraintMatrix[0][0].m_numberOfFeaturesDetected);
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int maxFeatures = int(m_constraintMatrix[0][0].m_numberOfFeaturesDetected);
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for( int j = 0; j < mySize.row ; j++ )
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{
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for( int i = 0; i < mySize.col; i++ )
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{
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if(m_constraintMatrix[j][i].m_numberOfFeaturesDetected < minFeatures) minFeatures = int(m_constraintMatrix[j][i].m_numberOfFeaturesDetected);
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if(m_constraintMatrix[j][i].m_numberOfFeaturesDetected > maxFeatures) maxFeatures = int(m_constraintMatrix[j][i].m_numberOfFeaturesDetected);
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}
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}
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// Calculate percentage from 0 to 100% (normalized 0-1) with numberOfFeatures and safe it
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for( int j = 0; j < mySize.row ; j++ )
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{
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for( int i = 0; i < mySize.col; i++ )
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{
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m_constraintMatrix[j][i].m_numberOfFeaturesDetected = (m_constraintMatrix[j][i].m_numberOfFeaturesDetected - minFeatures) / (maxFeatures - minFeatures);
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//cout << fixed << m_constraintMatrix[i][j].m_numberOfFeaturesDetected << " ";
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}
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//cout << endl;
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}
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// DEBUG - Display image
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/*for( size_t i = 0; i < corners.size(); i++ )
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{
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cv::circle( image, corners[i], 2, cv::Scalar( 255. ), -1 );
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}
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cv::namedWindow( "Output", CV_WINDOW_AUTOSIZE );
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cv::imshow( "Output", image );
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cv::waitKey(0);*/
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return true;
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}
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bool AbstractionLayer_SURFFeatures::PreProcessingPieces(coor mySize, const vector<Part*>* partArray)
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{
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std::vector< cv::Point2f > corners; // Variable to store corner-positions at
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// PARAMETERS (for description see top of file)
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int maxCorners = 500;
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double qualityLevel = 0.05;
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double minDistance = .5;
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Mat mask;
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int blockSize = 3;
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bool useHarrisDetector = false;
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double k = 0.04;
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int minFeatures = maxCorners;
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int maxFeatures = 0;
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char name[100];
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for (unsigned imgID = 0; imgID < mySize.col*mySize.row; imgID++) {
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sprintf(name, PATH1, imgID);
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Mat src = imread(name, IMREAD_GRAYSCALE);
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if (!src.data) {
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cerr << "Problem loading image of puzzle piece!" << endl;
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return false;
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} else {
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goodFeaturesToTrack(src, corners, maxCorners, qualityLevel, minDistance, mask, blockSize,
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useHarrisDetector, k);
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if (corners.size() < minFeatures) minFeatures = corners.size();
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if (corners.size() > maxFeatures) maxFeatures = corners.size();
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partArray->at(imgID)->m_a4.m_numberOfFeaturesDetected = corners.size();
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/*for( size_t i = 0; i < corners.size(); i++ ) {
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cv::circle( src, corners[i], 2, cv::Scalar( 255. ), -1 );
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}
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cv::namedWindow( "Output", CV_WINDOW_AUTOSIZE );
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cv::imshow( "Output", src );
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cout << count << " " << corners.size() << endl;
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cv::waitKey(0);*/
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}
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}
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// Calculate percentage from 0 to 100% (normalized 0-1) with numberOfFeatures and safe it
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for( unsigned i = 0; i < mySize.col*mySize.row; i++ )
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{
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partArray->at(i)->m_a4.m_numberOfFeaturesDetected = (partArray->at(i)->m_a4.m_numberOfFeaturesDetected - minFeatures) / (maxFeatures - minFeatures);
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//cout << fixed << partArray->at(i)->m_a4.m_numberOfFeaturesDetected << endl;
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}
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//cout << endl;
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return true;
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} |