Added rotation functionality, minor cleanups on the way
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3567b77cec
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2c71dd7a47
@ -59,6 +59,7 @@ bool Puzzle::testRotationPiece(unsigned int m, unsigned int n, PuzzlePiece& myPa
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{
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if(PlaceOfPartGood(m,n,myPart))
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return 1;
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//cout << "was rotated in testRotationPiece" << endl;
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myPart.shift(1);
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}
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@ -3,12 +3,10 @@ void status(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puzzleMa
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bool next(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puzzleMat)
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{
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//status(log,p_Box,puzzleMat);
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//log not yet started
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if(!(log.size()))
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{
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//cout << "creating new log" << endl;
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log.push_back(LogEntry());
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log.push_back(LogEntry());
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log.back().myCoor = calculateFirstCoor(log, p_Box, puzzleMat);
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solve(log, p_Box,puzzleMat);
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}
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@ -28,10 +26,7 @@ bool next(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puzzleMat)
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//last log element is empty, backtrack
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else if(!(log.back().PieceCollector.size()))
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{
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//cout << "backtracking" << endl;
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backtrack(log,p_Box,puzzleMat);
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}
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//case last log element has multiple entries
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else if(log.back().PieceCollector.size() > 1)
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@ -39,14 +34,12 @@ bool next(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puzzleMat)
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//is not yet max abstracted
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if(log.back().abstractionLevel < MAX_ABSTRAX)
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{
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//cout << "advancing abstraction layer" << endl;
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log.back().advance();
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log.back().advance();
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solve(log,p_Box,puzzleMat);
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}
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//no more layers, pick first
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else
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{
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//cout << "setting first as solution" << endl;
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log.back().advanceRandomed();
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setsolution(log,p_Box,puzzleMat);
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}
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@ -55,32 +48,18 @@ bool next(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puzzleMat)
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//case last log exactly one solution
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else if(log.back().PieceCollector.size() == 1)
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{
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//cout << "exactly one solution" << endl;
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if(log.back().hasRandomed())
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{
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if(log.back().abstractionLevel < MAX_ABSTRAX)
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{
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//cout << "advancing abstraction layer" << endl;
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log.back().advance();
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log.back().advance();
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solve(log,p_Box,puzzleMat);
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}
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else
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{
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//cout << "setting as solution bec fit" << endl;
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setsolution(log,p_Box,puzzleMat);
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}
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setsolution(log,p_Box,puzzleMat);
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}
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else
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{
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//cout << "setting as solution bec trivial" << endl;
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setsolution(log,p_Box,puzzleMat);
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}
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}
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//cout << "next" << endl;
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if(log.back().myCoor.n>8)
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{
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cout << "m: " << log.back().myCoor.m << " n: " << log.back().myCoor.n << endl;
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// status(log,p_Box,puzzleMat);
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setsolution(log,p_Box,puzzleMat);
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}
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return 1;
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}
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@ -128,7 +107,6 @@ void solve(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puzzleMat
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default:
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break;
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}
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//status(log,p_Box,puzzleMat);
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}
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void abstractionlayer0solver(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puzzleMat)
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@ -146,17 +124,15 @@ void abstractionlayer1solver(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box,
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(*(log.back().PieceCollector[i])).resetShift();
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//TODO: change checker from checking every box piece to only checking the simplifyed version ob the box with abstraction layer one
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if(!(puzzleMat.testRotationPiece(log.back().myCoor.m, log.back().myCoor.n, *(log.back().PieceCollector[i]))))
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{
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log.back().PieceCollector.erase(log.back().PieceCollector.begin()+i);
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}
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else
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{
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i++; //otherwise loop stops before end!
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//set shift to 0 so that we have a defined starting position for all pieces
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while(log.back().PieceCollector[i]->getShift())
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log.back().PieceCollector[i]->shift(1);
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}
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}
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//for(int i=0;i<log.back().PieceCollector.size();i++)
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//{
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// (*(log.back().PieceCollector[i])).printPiece();
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// cout << endl;
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//}
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}
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void setsolution(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puzzleMat)
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@ -184,69 +160,71 @@ void setsolution(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puz
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bool backtrack(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puzzleMat)
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{
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//following possibilities:
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//last log entry empty
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//delete last log + backtrack
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//last log entry empty - delete last log + backtrack
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if(!(log.back().PieceCollector.size()))
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{
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//cout << "none" << endl;
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puzzleMat.removePiece(log.back().myCoor.m, log.back().myCoor.n);
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log.pop_back();
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//status(log,p_Box,puzzleMat);
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backtrack(log,p_Box,puzzleMat);
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return 1;
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}
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//last log entry only one solution
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//delete last logd put back into box + backtrack
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//last log entry only one solution - delete last logd put back into box + backtrack
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else if((log.back().PieceCollector.size())==1)
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{
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(*(log.back().PieceCollector[0])).shift(1);
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if(puzzleMat.testRotationPiece(log.back().myCoor.m, log.back().myCoor.n, *(log.back().PieceCollector[0]), 4-(*(log.back().PieceCollector[0])).getShift()))
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setsolution(log,p_Box,puzzleMat);
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else
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(log.back().PieceCollector[0])->shift(1);
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while((log.back().PieceCollector[0])->getShift() !=0 && (log.back().PieceCollector[0])->getShift() !=3)
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{
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//cout << "one" << endl;
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p_Box.push_back(log.back().PieceCollector[0]);
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//shuffleup
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random_shuffle(p_Box.begin(),p_Box.end());
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puzzleMat.removePiece(log.back().myCoor.m, log.back().myCoor.n);
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log.pop_back();
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//cout << "removed" << endl;
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//status(log,p_Box,puzzleMat);
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backtrack(log,p_Box,puzzleMat);
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log.back().PieceCollector[0]->shift(1);
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if(puzzleMat.testRotationPiece(log.back().myCoor.m, log.back().myCoor.n, *(log.back().PieceCollector[0]), 1))
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{
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setsolution(log,p_Box,puzzleMat);
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return 1;
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}
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}
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p_Box.push_back(log.back().PieceCollector[0]);
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//shuffleup
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random_shuffle(p_Box.begin(),p_Box.end());
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puzzleMat.removePiece(log.back().myCoor.m, log.back().myCoor.n);
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log.pop_back();
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//cout << "removed" << endl;
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//status(log,p_Box,puzzleMat);
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backtrack(log,p_Box,puzzleMat);
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return 1;
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}
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//last log entry multiple solutions (and current one was randomed)
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//delete randomed piece from PieceCollector and go to next (which might random again depending on function)
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//last log entry multiple solutions (and current one was randomed) - delete randomed piece and go to next
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else if((log.back().PieceCollector.size())>1)
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{
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//check if piece has second rotation solution
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(*(log.back().PieceCollector[0])).shift(1);
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if(puzzleMat.testRotationPiece(log.back().myCoor.m, log.back().myCoor.n, *(log.back().PieceCollector[0]), 4-(*(log.back().PieceCollector[0])).getShift()))
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setsolution(log,p_Box,puzzleMat);
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else
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(*(log.back().PieceCollector[0])).shift(1);
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while((log.back().PieceCollector[0])->getShift() !=0 && (log.back().PieceCollector[0])->getShift() !=3)
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{
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//cout << "multiple" << endl;
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p_Box.push_back(log.back().PieceCollector[0]);
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//shuffleup
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random_shuffle(p_Box.begin(),p_Box.end());
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log.back().PieceCollector.erase(log.back().PieceCollector.begin());
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if(log.back().PieceCollector.size()==1)
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log.back().decreaseRandomed();
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//for abstraction layer 1 so that first rotation solution is set.
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(*(log.back().PieceCollector[0])).resetShift();
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//cout << "erased first element" << endl;
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//status(log,p_Box,puzzleMat);
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setsolution(log,p_Box,puzzleMat);
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log.back().PieceCollector[0]->shift(1);
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if(puzzleMat.testRotationPiece(log.back().myCoor.m, log.back().myCoor.n, *(log.back().PieceCollector[0]), 1))
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{
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setsolution(log,p_Box,puzzleMat);
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return 1;
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}
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}
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p_Box.push_back(log.back().PieceCollector[0]);
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//shuffleup
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random_shuffle(p_Box.begin(),p_Box.end());
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log.back().PieceCollector.erase(log.back().PieceCollector.begin());
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if(log.back().PieceCollector.size()==1)
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log.back().decreaseRandomed();
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//for abstraction layer 1 so that first rotation solution is set.
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(*(log.back().PieceCollector[0])).resetShift();
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setsolution(log,p_Box,puzzleMat);
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return 1;
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//no need to remove from puzzle mat, as sersolution overwrites it anyway
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}
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@ -270,7 +248,7 @@ void status(vector<LogEntry>& log, vector<PuzzlePiece*>& p_Box, Puzzle& puzzleMa
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cout << "isset: 0" << endl;
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//cout << "Abstraction: " << log[i].abstractionLevel << endl;
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//cout << "m: " << log[i].myCoor.m << " n: " << log[i].myCoor.n << endl;
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cout << "m: " << log[i].myCoor.m << " n: " << log[i].myCoor.n << endl;
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/*for(int j=0;j<log[i].PieceCollector.size();j++)
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{
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(*(log[i].PieceCollector[j])).printPiece();
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@ -9,7 +9,7 @@
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int main()
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{
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int cols=10, rows=10;
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int cols=4, rows=4;
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//some basic part stuff
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vector<Part> myFirstPuzzle;
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Part myFirstPart;
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@ -40,7 +40,8 @@ int main()
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Puzzle puzzleMat(cols, rows);
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//vector<vector<PuzzlePiece*>> ab1class = abstractionLayer1classify(log, p_myFirstBox,puzzleMat);
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for(int i=0;i<myFirstBox.size();i++)
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cout << (*p_myFirstBox[i]).getShift() << endl;
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while(next(log, p_myFirstBox,puzzleMat));
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puzzleMat.printPuzzle();
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