/**
* Start all regression tests.
*
* @param threadsNumber Threads number.
* @return Number of tests with error result.
*/
public static int Start(int threadsNumber)
{
SudokuStore.consolePrintln("^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^");
SudokuStore.consolePrintln("All regression tests - starting.");
SudokuStore.consolePrintln(" - RegTestsSolver.start()");
SudokuStore.consolePrintln(" - RegTestsGenerator.start()");
SudokuStore.consolePrintln(" - RegTestsStore.start()");
SudokuStore.consolePrintln(" - RegTestsApi.start()");
SudokuStore.consolePrintln("^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^");
long startTime = DateTimeX.currentTimeMillis();
int solverErrors = RegTestsSolver.Start(threadsNumber);
int generatorErrors = RegTestsGenerator.Start(threadsNumber);
int storeErrors = RegTestsStore.Start(threadsNumber);
int apiErrors = RegTestsApi.Start(threadsNumber);
long endTime = DateTimeX.currentTimeMillis();
double computingTime = (endTime - startTime) / 1000.0;
int totalErrors = solverErrors + generatorErrors + storeErrors + apiErrors;
SudokuStore.consolePrintln("^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^");
SudokuStore.consolePrintln("All regression tests - finished.");
SudokuStore.consolePrintln("Errors: " + totalErrors);
SudokuStore.consolePrintln(" - RegTestsSolver errors: " + solverErrors);
SudokuStore.consolePrintln(" - RegTestsGenerator errors: " + generatorErrors);
SudokuStore.consolePrintln(" - RegTestsStore errors: " + storeErrors);
SudokuStore.consolePrintln(" - RegTestsApi errors: " + apiErrors);
SudokuStore.consolePrintln("");
SudokuStore.consolePrintln("Computing time: " + computingTime + " s.");
SudokuStore.consolePrintln("^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^");
return(totalErrors);
}
/**
* Runs SudokuSolver regression tests.
* @param threadsNumber Number of threads.
* @return Number of tests with errors.
*/
public static int Start(int threadsNumber)
{
int numberOfTests = SolverTests.NUMBER_OF_TESTS;
int resultsError = 0;
int resultsOk = 0;
long startTime = DateTimeX.currentTimeMillis();
SolverTests st = new SolverTests(threadsNumber);
st.start();
bool[] testResults = st.testsResults;
for (int t = 0; t < numberOfTests; t++)
{
if (testResults[t] == true)
{
resultsOk++;
}
else
{
resultsError++;
}
}
long endtTime = DateTimeX.currentTimeMillis();
double computingTime = (endtTime - startTime) / 1000.0;
SudokuStore.consolePrintln("=============================================================");
SudokuStore.consolePrintln("Number of SudokuSolver test: " + numberOfTests + ", OK: " + resultsOk + ", ERRORS: " + resultsError + ", computing time: " + computingTime);
for (int t = 0; t < numberOfTests; t++)
{
if (testResults[t] == false)
{
SudokuStore.consolePrintln("ERROR: " + t);
}
}
SudokuStore.consolePrintln("=============================================================");
return(resultsError);
}
/**
* Test scenario implementation.
* @param testId Test id.
* @param threadId Thread id.
* @return True is test successful, otherwise false.
*/
static bool runTest(int testId, int threadId)
{
SudokuSolver s;
int sol;
int solNum;
int solUnq;
int solvingState;
int boardState;
int[,] solution;
int[,] puzzle;
bool solCorr;
bool testResult = true;
switch (testId)
{
case 0:
for (int example = 0; example < SudokuPuzzles.NUMBER_OF_PUZZLE_EXAMPLES; example++)
{
s = new SudokuSolver(example);
solNum = s.findAllSolutions();
ErrorCodes.consolePrintlnIfError(solNum);
if (solNum != 1)
{
testResult = false;
}
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", findAllSolutions, example: " + example + ", solutions: " + solNum + ", time: " + s.getComputingTime() + " s.");
}
break;
case 1:
for (int example = 0; example < SudokuPuzzles.NUMBER_OF_PUZZLE_EXAMPLES; example++)
{
s = new SudokuSolver(example);
solUnq = s.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
if (solUnq != SudokuSolver.SOLUTION_UNIQUE)
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", checkIfUniqueSolution, example: " + example + ", is solution unique: NO, time: " + s.getComputingTime() + " s.");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", checkIfUniqueSolution, example: " + example + ", is solution unique: YES, time: " + s.getComputingTime() + " s.");
}
}
break;
case 2:
for (int example = 0; example < SudokuPuzzles.NUMBER_OF_PUZZLE_EXAMPLES; example++)
{
s = new SudokuSolver(example);
sol = s.solve();
ErrorCodes.consolePrintlnIfError(sol);
solution = s.getSolvedBoard();
solCorr = SudokuStore.checkSolvedBoard(solution);
if (solCorr != true)
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: " + example + ", is solution correct: NO, time: " + s.getComputingTime() + " s.");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: " + example + ", is solution correct: YES, time: " + s.getComputingTime() + " s.");
}
}
break;
case 3:
for (int example = 0; example < SudokuPuzzles.NUMBER_OF_PUZZLE_EXAMPLES; example++)
{
puzzle = SudokuStore.seqOfRandomBoardTransf(SudokuStore.getPuzzleExample(example));
s = new SudokuSolver(puzzle);
solNum = s.findAllSolutions();
ErrorCodes.consolePrintlnIfError(solNum);
if (solNum != 1)
{
testResult = false;
}
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", seqOfRandomBoardTransf + findAllSolutions, example: " + example + ", solutions: " + solNum + ", time: " + s.getComputingTime() + " s.");
}
break;
case 4:
for (int example = 0; example < SudokuPuzzles.NUMBER_OF_PUZZLE_EXAMPLES; example++)
{
puzzle = SudokuStore.seqOfRandomBoardTransf(SudokuStore.getPuzzleExample(example));
s = new SudokuSolver(puzzle);
solUnq = s.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
if (solUnq != SudokuSolver.SOLUTION_UNIQUE)
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", seqOfRandomBoardTransf + checkIfUniqueSolution, example: " + example + ", is solution unique: NO, time: " + s.getComputingTime() + " s.");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", seqOfRandomBoardTransf + checkIfUniqueSolution, example: " + example + ", is solution unique: YES, time: " + s.getComputingTime() + " s.");
}
}
break;
case 5:
for (int example = 0; example < SudokuPuzzles.NUMBER_OF_PUZZLE_EXAMPLES; example++)
{
puzzle = SudokuStore.seqOfRandomBoardTransf(SudokuStore.getPuzzleExample(example));
s = new SudokuSolver(puzzle);
sol = s.solve();
ErrorCodes.consolePrintlnIfError(sol);
solution = s.getSolvedBoard();
solCorr = SudokuStore.checkSolvedBoard(solution);
if (solCorr != true)
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", seqOfRandomBoardTransf + solve, example: " + example + ", is solution correct: NO, time: " + s.getComputingTime() + " s.");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", seqOfRandomBoardTransf + solve, example: " + example + ", is solution correct: YES, time: " + s.getComputingTime() + " s.");
}
}
break;
case 6:
s = new SudokuSolver(SudokuPuzzles.PUZZLE_NON_UNIQUE_SOLUTION);
solNum = s.findAllSolutions();
ErrorCodes.consolePrintlnIfError(solNum);
if (solNum <= 1)
{
testResult = false;
}
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", findAllSolutions, example: non unique, solutions: " + solNum + ", time: " + s.getComputingTime() + " s.");
break;
case 7:
s = new SudokuSolver(SudokuPuzzles.PUZZLE_NON_UNIQUE_SOLUTION);
solUnq = s.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
if (solUnq != SudokuSolver.SOLUTION_NON_UNIQUE)
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", checkIfUniqueSolution, example: non unique, is solution unique: YES, time: " + s.getComputingTime() + " s.");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", checkIfUniqueSolution, example: non unique, is solution unique: NO, time: " + s.getComputingTime() + " s.");
}
break;
case 8:
s = new SudokuSolver(SudokuPuzzles.PUZZLE_NON_UNIQUE_SOLUTION);
sol = s.solve();
ErrorCodes.consolePrintlnIfError(sol);
solution = s.getSolvedBoard();
solCorr = SudokuStore.checkSolvedBoard(solution);
if (solCorr != true)
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: non unique, is solution correct: NO, time: " + s.getComputingTime() + " s.");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: non unique, is solution correct: YES, time: " + s.getComputingTime() + " s.");
}
break;
case 9:
puzzle = SudokuStore.seqOfRandomBoardTransf(SudokuPuzzles.PUZZLE_NON_UNIQUE_SOLUTION);
s = new SudokuSolver(puzzle);
solNum = s.findAllSolutions();
ErrorCodes.consolePrintlnIfError(solNum);
if (solNum <= 1)
{
testResult = false;
}
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", seqOfRandomBoardTransf + findAllSolutions, example: non unique, solutions: " + solNum + ", time: " + s.getComputingTime() + " s.");
break;
case 10:
puzzle = SudokuStore.seqOfRandomBoardTransf(SudokuPuzzles.PUZZLE_NON_UNIQUE_SOLUTION);
s = new SudokuSolver(puzzle);
solUnq = s.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
if (solUnq != SudokuSolver.SOLUTION_NON_UNIQUE)
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", seqOfRandomBoardTransf + checkIfUniqueSolution, example: non unique, is solution unique: YES, time: " + s.getComputingTime() + " s.");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", seqOfRandomBoardTransf + checkIfUniqueSolution, example: non unique, is solution unique: NO, time: " + s.getComputingTime() + " s.");
}
break;
case 11:
puzzle = SudokuStore.seqOfRandomBoardTransf(SudokuPuzzles.PUZZLE_NON_UNIQUE_SOLUTION);
s = new SudokuSolver(puzzle);
sol = s.solve();
ErrorCodes.consolePrintlnIfError(sol);
solution = s.getSolvedBoard();
solCorr = SudokuStore.checkSolvedBoard(solution);
if (solCorr != true)
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", seqOfRandomBoardTransf + solve, example: non unique, is solution correct: NO, time: " + s.getComputingTime() + " s.");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", seqOfRandomBoardTransf + solve, example: non unique, is solution correct: YES, time: " + s.getComputingTime() + " s.");
}
break;
case 12:
s = new SudokuSolver(SudokuPuzzles.PUZZLE_NO_SOLUTION);
solNum = s.findAllSolutions();
ErrorCodes.consolePrintlnIfError(solNum);
if (solNum != 0)
{
testResult = false;
}
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", findAllSolutions, example: no solution, solutions: " + solNum + ", time: " + s.getComputingTime() + " s.");
break;
case 13:
s = new SudokuSolver(SudokuPuzzles.PUZZLE_NO_SOLUTION);
solUnq = s.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
if (solUnq == SudokuSolver.SOLUTION_NOT_EXISTS)
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", checkIfUniqueSolution, example: no solution, no solutions found: YES, time: " + s.getComputingTime() + " s.");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", checkIfUniqueSolution, example: no solution, no solutions found: NO, time: " + s.getComputingTime() + " s.");
}
break;
case 14:
s = new SudokuSolver(SudokuPuzzles.PUZZLE_NO_SOLUTION);
sol = s.solve();
solution = s.getSolvedBoard();
if (s.getSolvingState() == ErrorCodes.SUDOKUSOLVER_SOLVE_SOLVING_FAILED)
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: no solution, solving failed: YES, time: " + s.getComputingTime() + " s.");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: no solution, solving failed: NO, time: " + s.getComputingTime() + " s.");
}
break;
case 15:
s = new SudokuSolver(SudokuPuzzles.PUZZLE_ERROR);
solvingState = s.solve();
boardState = s.getBoardState();
if ((boardState == SudokuBoard.BOARD_STATE_ERROR) && (solvingState == ErrorCodes.SUDOKUSOLVER_SOLVE_SOLVING_NOT_STARTED))
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: board with error, board state error and solving not started: YES, time: " + s.getComputingTime() + " s.");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: board with error, board state error and solving not started: NO, time: " + s.getComputingTime() + " s.");
}
break;
case 16:
s = new SudokuSolver(SudokuPuzzles.PUZZLE_REGTESTS);
sol = s.solve();
ErrorCodes.consolePrintlnIfError(sol);
if (SudokuStore.boardsAreEqual(s.getSolvedBoard(), SudokuPuzzles.PUZZLE_REGTESTS_SOLUTION))
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: with solution, solutions are equal: YES, time: " + s.getComputingTime() + " s.");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: with solution, solutions are equal: NO, time: " + s.getComputingTime() + " s.");
}
break;
case 17:
s = new SudokuSolver(SudokuPuzzles.PUZZLE_EMPTY);
sol = s.solve();
solUnq = s.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(sol);
ErrorCodes.consolePrintlnIfError(solUnq);
if ((SudokuStore.checkSolvedBoard(s.getSolvedBoard()) == true) & (solUnq == SudokuSolver.SOLUTION_NON_UNIQUE))
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: empty puzzle, found solution and solution non unique: YES, time: " + s.getComputingTime() + " s.");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", solve, example: empty puzzle, found solution and solution non unique: NO, time: " + s.getComputingTime() + " s.");
}
break;
}
if (testResult == true)
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + " >>>>>>>>>>>>>>>>>>>>>> SudokuSolver, result: OK");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + " >>>>>>>>>>>>>>>>>>>>>> SudokuSolver, result: ERROR");
}
return(testResult);
}
/**
* Start the Janet-Sudoku Tutorial code.
* @param args No arguments are considered.
*/
public static void Start()
{
String tmpDir = FileX.getTmpDir();
{
/*
* Simple sudoku generation.
*/
SudokuStore.consolePrintln("");
SudokuStore.consolePrintln("Simple sudoku generation.");
SudokuGenerator sg = new SudokuGenerator();
int[,] puzzle = sg.generate();
SudokuStore.consolePrintBoard(puzzle);
}
{
/*
* Simple sudoku generation + parameters.
*/
SudokuStore.consolePrintln("");
SudokuStore.consolePrintln("Simple sudoku generation + parameters.");
SudokuGenerator sg = new SudokuGenerator(SudokuGenerator.PARAM_GEN_RND_BOARD);
int[,] puzzle = sg.generate();
SudokuStore.consolePrintBoard(puzzle);
}
{
/*
* Simple sudoku generation + puzzle rating.
*/
SudokuStore.consolePrintln("");
SudokuStore.consolePrintln("Simple sudoku generation + puzzle rating.");
SudokuGenerator sg = new SudokuGenerator();
int[,] puzzle = sg.generate();
int rating = SudokuStore.calculatePuzzleRating(puzzle);
SudokuStore.consolePrintBoard(puzzle);
SudokuStore.consolePrintln("Puzzle rating: " + rating);
}
{
/*
* Solving sudoku example.
*/
SudokuStore.consolePrintln("");
SudokuStore.consolePrintln("Solving sudoku example.");
SudokuSolver ss = new SudokuSolver(SudokuPuzzles.PUZZLE_EXAMPLE_001);
SudokuStore.consolePrintBoard(ss.getBoard());
ss.solve();
SudokuStore.consolePrintBoard(ss.getSolvedBoard());
}
{
/*
* Saving board examples
*/
SudokuStore.consolePrintln("");
SudokuStore.consolePrintln("Saving board examples " + tmpDir);
SudokuStore.saveBoard(SudokuPuzzles.PUZZLE_EXAMPLE_001, tmpDir + "sudoku-board-ex-1.txt");
SudokuStore.saveBoard(SudokuPuzzles.PUZZLE_EXAMPLE_001, tmpDir + "sudoku-board-ex-2.txt", "This is a head comment");
SudokuStore.saveBoard(SudokuPuzzles.PUZZLE_EXAMPLE_001, tmpDir + "sudoku-board-ex-3.txt", "This is a head comment", "And a tail comment");
SudokuSolver ss = new SudokuSolver(1);
ss.solve();
ss.saveSolvedBoard(tmpDir + "sudoku-board-ex-sol.txt", "Solution for the PUZZLE_EXAMPLE_001");
}
/*
* And many other staff provided by the library :-)
*/
}
/**
* Test scenario implementation.
* @param testId Test id.
* @param threadId Thread id.
* @return True is test successful, otherwise false.
*/
static bool runTest(int testId, int threadId)
{
SudokuSolver solverGen, solverInit;
SudokuGenerator g;
int solUnq;
int[,] genPuzzle;
int[,] solvedGen, solvedInit, initBoard;
bool testResult = true;
switch (testId)
{
case 0:
for (int example = 0; example < SudokuPuzzles.NUMBER_OF_PUZZLE_EXAMPLES; example++)
{
g = new SudokuGenerator(example, SudokuGenerator.PARAM_DO_NOT_TRANSFORM);
genPuzzle = g.generate();
solverGen = new SudokuSolver(genPuzzle);
ErrorCodes.consolePrintlnIfError(solverGen.solve());
solverInit = new SudokuSolver(example);
ErrorCodes.consolePrintlnIfError(solverInit.solve());
solUnq = solverGen.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
solvedGen = solverGen.getSolvedBoard();
solvedInit = solverInit.getSolvedBoard();
if ((solUnq == SudokuSolver.SOLUTION_UNIQUE) && (SudokuStore.boardsAreEqual(solvedGen, solvedInit) == true))
{
//SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by example number, example: " + example + ", solution unique and correct: YES, time (g, s1, s2): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., " + solverInit.getComputingTime() + " s.");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by example number, example: " + example + ", solution unique and correct: NO, time (g, s1, s2): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., " + solverInit.getComputingTime() + " s.");
Console.WriteLine("Initial board");
SudokuStore.consolePrintBoard(SudokuStore.getPuzzleExample(example));
Console.WriteLine("Generated puzzle");
SudokuStore.consolePrintBoard(genPuzzle);
Console.WriteLine("Solved initial board");
SudokuStore.consolePrintBoard(solvedInit);
Console.WriteLine("Solved generated puzzle");
SudokuStore.consolePrintBoard(solvedGen);
}
}
break;
case 1:
for (int example = 0; example < SudokuPuzzles.NUMBER_OF_PUZZLE_EXAMPLES; example++)
{
initBoard = SudokuStore.getPuzzleExample(example);
g = new SudokuGenerator(initBoard, SudokuGenerator.PARAM_DO_NOT_TRANSFORM, SudokuGenerator.PARAM_DO_NOT_SOLVE);
genPuzzle = g.generate();
solverGen = new SudokuSolver(genPuzzle);
ErrorCodes.consolePrintlnIfError(solverGen.solve());
solverInit = new SudokuSolver(initBoard);
ErrorCodes.consolePrintlnIfError(solverInit.solve());
solUnq = solverGen.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
solvedGen = solverGen.getSolvedBoard();
solvedInit = solverInit.getSolvedBoard();
if ((solUnq == SudokuSolver.SOLUTION_UNIQUE) && (SudokuStore.boardsAreEqual(solvedGen, solvedInit) == true))
{
//SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by example board, example: " + example + ", solution unique and correct: YES, time (g, s1, s2): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., " + solverInit.getComputingTime() + " s.");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by example board, example: " + example + ", solution unique and correct: NO, time (g, s1, s2): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., " + solverInit.getComputingTime() + " s.");
Console.WriteLine("Initial board");
SudokuStore.consolePrintBoard(initBoard);
Console.WriteLine("Generated puzzle");
SudokuStore.consolePrintBoard(genPuzzle);
Console.WriteLine("Solved initial board");
SudokuStore.consolePrintBoard(solvedInit);
Console.WriteLine("Solved generated puzzle");
SudokuStore.consolePrintBoard(solvedGen);
}
}
break;
case 2:
for (int example = 0; example < SudokuPuzzles.NUMBER_OF_PUZZLE_EXAMPLES; example++)
{
g = new SudokuGenerator(example);
genPuzzle = g.generate();
solverGen = new SudokuSolver(genPuzzle);
ErrorCodes.consolePrintlnIfError(solverGen.solve());
solUnq = solverGen.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
solvedGen = solverGen.getSolvedBoard();
if ((solUnq == SudokuSolver.SOLUTION_UNIQUE) && (SudokuStore.checkPuzzle(genPuzzle) == true))
{
//SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by example number, example: " + example + ", solution unique and correct: YES, time (g, s): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., ");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by example number, example: " + example + ", solution unique and correct: NO, time (g, s): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., ");
Console.WriteLine("Generated puzzle");
SudokuStore.consolePrintBoard(genPuzzle);
Console.WriteLine("Solved generated puzzle");
SudokuStore.consolePrintBoard(solvedGen);
}
}
break;
case 3:
for (int example = 0; example < SudokuPuzzles.NUMBER_OF_PUZZLE_EXAMPLES; example++)
{
initBoard = SudokuStore.getPuzzleExample(example);
g = new SudokuGenerator(initBoard, SudokuGenerator.PARAM_DO_NOT_SOLVE);
genPuzzle = g.generate();
solverGen = new SudokuSolver(genPuzzle);
ErrorCodes.consolePrintlnIfError(solverGen.solve());
solUnq = solverGen.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
solvedGen = solverGen.getSolvedBoard();
if ((solUnq == SudokuSolver.SOLUTION_UNIQUE) && (SudokuStore.checkPuzzle(genPuzzle) == true))
{
//SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by example board, example: " + example + ", solution unique and correct: YES, time (g, s): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., ");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by example board, example: " + example + ", solution unique and correct: NO, time (g, s): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., ");
Console.WriteLine("Generated puzzle");
SudokuStore.consolePrintBoard(genPuzzle);
Console.WriteLine("Solved initial board");
SudokuStore.consolePrintBoard(solvedGen);
}
}
break;
case 5:
initBoard = SudokuPuzzles.PUZZLE_EMPTY;
g = new SudokuGenerator(initBoard);
genPuzzle = g.generate();
solverGen = new SudokuSolver(genPuzzle);
ErrorCodes.consolePrintlnIfError(solverGen.solve());
solUnq = solverGen.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
solvedGen = solverGen.getSolvedBoard();
if ((solUnq == SudokuSolver.SOLUTION_UNIQUE) && (SudokuStore.checkPuzzle(genPuzzle) == true))
{
//SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by empty board, solution unique and correct: YES, time (g, s): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., ");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by empty board, solution unique and correct: NO, time (g, s): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., ");
Console.WriteLine("Generated puzzle");
SudokuStore.consolePrintBoard(genPuzzle);
Console.WriteLine("Solved initial board");
SudokuStore.consolePrintBoard(solvedGen);
}
break;
case 6:
initBoard = SudokuPuzzles.PUZZLE_EMPTY;
g = new SudokuGenerator(initBoard, SudokuGenerator.PARAM_DO_NOT_SOLVE);
if (g.getGeneratorState() == SudokuGenerator.GENERATOR_INIT_FAILED)
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by empty board, solution unique and correct: YES, time (g, s): ");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by empty board, solution unique and correct: NO, time (g, s): ");
SudokuStore.consolePrintln("Generator state: " + g.getGeneratorState());
Console.WriteLine(g.getMessages());
}
break;
case 7:
initBoard = SudokuPuzzles.PUZZLE_ERROR;
g = new SudokuGenerator(initBoard, SudokuGenerator.PARAM_DO_NOT_SOLVE);
if (g.getGeneratorState() == SudokuGenerator.GENERATOR_INIT_FAILED)
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by PUZZLE_ERROR + PARAM_DO_NOT_SOLVE, init failed: YES.");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by PUZZLE_ERROR + PARAM_DO_NOT_SOLVE, init failed: NO.");
SudokuStore.consolePrintln("Generator state: " + g.getGeneratorState());
Console.WriteLine(g.getMessages());
}
break;
case 8:
initBoard = SudokuPuzzles.PUZZLE_NON_UNIQUE_SOLUTION;
g = new SudokuGenerator(initBoard);
genPuzzle = g.generate();
solverGen = new SudokuSolver(genPuzzle);
ErrorCodes.consolePrintlnIfError(solverGen.solve());
solUnq = solverGen.checkIfUniqueSolution();
ErrorCodes.consolePrintlnIfError(solUnq);
solvedGen = solverGen.getSolvedBoard();
if ((solUnq == SudokuSolver.SOLUTION_UNIQUE) && (SudokuStore.checkPuzzle(genPuzzle) == true))
{
//SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by empty board, solution unique and correct: YES, time (g, s): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., ");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by empty board, solution unique and correct: NO, time (g, s): " + g.getComputingTime() + " s., " + solverGen.getComputingTime() + " s., ");
Console.WriteLine("Generated puzzle");
SudokuStore.consolePrintBoard(genPuzzle);
Console.WriteLine("Solved initial board");
SudokuStore.consolePrintBoard(solvedGen);
}
break;
case 9:
initBoard = SudokuPuzzles.PUZZLE_NON_UNIQUE_SOLUTION;
g = new SudokuGenerator(initBoard, SudokuGenerator.PARAM_DO_NOT_SOLVE);
if (g.getGeneratorState() == SudokuGenerator.GENERATOR_INIT_FAILED)
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by PUZZLE_NON_UNIQUE_SOLUTION + PARAM_DO_NOT_SOLVE, init failed: YES.");
}
else
{
testResult = false;
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + ", generate by PUZZLE_NON_UNIQUE_SOLUTION + PARAM_DO_NOT_SOLVE, init failed: NO.");
SudokuStore.consolePrintln("Generator state: " + g.getGeneratorState());
Console.WriteLine(g.getMessages());
}
break;
}
if (testResult == true)
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + " >>>>>>>>>>>>>>>>>>>>>> SudokuGenerator, result: OK");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + " >>>>>>>>>>>>>>>>>>>>>> SudokuGenerator, result: ERROR");
}
return(testResult);
}
/**
* Test scenario implementation.
* @param testId Test id.
* @param threadId Thread id.
* @return True is test successful, otherwise false.
*/
static bool runTest(int testId, int threadId)
{
bool testResult = true;
String testDesc = "", resultDesc = "";
int[,] a =
{
{ 0, 0, 0, 8, 0, 0, 0, 0, 0 },
{ 4, 0, 0, 0, 1, 5, 0, 3, 0 },
{ 0, 2, 9, 0, 4, 0, 5, 1, 8 },
{ 0, 4, 0, 0, 0, 0, 1, 2, 0 },
{ 0, 0, 0, 6, 0, 2, 0, 0, 0 },
{ 0, 3, 2, 0, 0, 0, 0, 9, 0 },
{ 6, 9, 3, 0, 5, 0, 8, 7, 0 },
{ 0, 5, 0, 4, 8, 0, 0, 0, 1 },
{ 0, 0, 0, 0, 0, 3, 0, 0, 0 }
};
switch (testId)
{
case 0:
testDesc = "SudokuSolver.setCell(int, int, int)";
{
SudokuSolver s = new SudokuSolver();
s.setCell(0, 0, 0);
s.setCell(1, 0, 4);
s.setCell(2, 0, 0);
s.setCell(3, 0, 0);
s.setCell(4, 0, 0);
s.setCell(5, 0, 0);
s.setCell(6, 0, 6);
s.setCell(7, 0, 0);
s.setCell(8, 0, 0);
s.setCell(0, 1, 0);
s.setCell(1, 1, 0);
s.setCell(2, 1, 2);
s.setCell(3, 1, 4);
s.setCell(4, 1, 0);
s.setCell(5, 1, 3);
s.setCell(6, 1, 9);
s.setCell(7, 1, 5);
s.setCell(8, 1, 0);
s.setCell(0, 2, 0);
s.setCell(1, 2, 0);
s.setCell(2, 2, 9);
s.setCell(3, 2, 0);
s.setCell(4, 2, 0);
s.setCell(5, 2, 2);
s.setCell(6, 2, 3);
s.setCell(7, 2, 0);
s.setCell(8, 2, 0);
s.setCell(0, 3, 8);
s.setCell(1, 3, 0);
s.setCell(2, 3, 0);
s.setCell(3, 3, 0);
s.setCell(4, 3, 6);
s.setCell(5, 3, 0);
s.setCell(6, 3, 0);
s.setCell(7, 3, 4);
s.setCell(8, 3, 0);
s.setCell(0, 4, 0);
s.setCell(1, 4, 1);
s.setCell(2, 4, 4);
s.setCell(3, 4, 0);
s.setCell(4, 4, 0);
s.setCell(5, 4, 0);
s.setCell(6, 4, 5);
s.setCell(7, 4, 8);
s.setCell(8, 4, 0);
s.setCell(0, 5, 0);
s.setCell(1, 5, 5);
s.setCell(2, 5, 0);
s.setCell(3, 5, 0);
s.setCell(4, 5, 2);
s.setCell(5, 5, 0);
s.setCell(6, 5, 0);
s.setCell(7, 5, 0);
s.setCell(8, 5, 3);
s.setCell(0, 6, 0);
s.setCell(1, 6, 0);
s.setCell(2, 6, 5);
s.setCell(3, 6, 1);
s.setCell(4, 6, 0);
s.setCell(5, 6, 0);
s.setCell(6, 6, 8);
s.setCell(7, 6, 0);
s.setCell(8, 6, 0);
s.setCell(0, 7, 0);
s.setCell(1, 7, 3);
s.setCell(2, 7, 1);
s.setCell(3, 7, 2);
s.setCell(4, 7, 0);
s.setCell(5, 7, 9);
s.setCell(6, 7, 7);
s.setCell(7, 7, 0);
s.setCell(8, 7, 0);
s.setCell(0, 8, 0);
s.setCell(1, 8, 0);
s.setCell(2, 8, 8);
s.setCell(3, 8, 0);
s.setCell(4, 8, 0);
s.setCell(5, 8, 0);
s.setCell(6, 8, 0);
s.setCell(7, 8, 1);
s.setCell(8, 8, 0);
int[,] b = s.getBoard();
if ((SudokuStore.boardsAreEqual(a, b) == true))
{
resultDesc = "Expecting equal - are equal.";
}
else
{
resultDesc = "Expecting equal - are not equal.";
testResult = false;
SudokuStore.consolePrintln(s.getMessages());
}
}
break;
case 1:
testDesc = "SudokuSolver.getCellDigit(int, int)";
{
SudokuSolver s1 = new SudokuSolver(a);
SudokuSolver s2 = new SudokuSolver();
for (int i = 0; i < SudokuBoard.BOARD_SIZE; i++)
{
for (int j = 0; j < SudokuBoard.BOARD_SIZE; j++)
{
int d = s1.getCellDigit(i, j);
s2.setCell(i, j, d);
}
}
int[,] b = s2.getBoard();
if ((SudokuStore.boardsAreEqual(a, b) == true))
{
resultDesc = "Expecting equal - are equal.";
}
else
{
resultDesc = "Expecting equal - are not equal.";
testResult = false;
}
}
break;
case 2:
testDesc = "SudokuSolver.getBoardCopy()";
{
SudokuSolver s = new SudokuSolver(a);
int[,] b = s.getBoard();
int[,] c = s.getBoardCopy();
if ((SudokuStore.boardsAreEqual(b, c) == true))
{
resultDesc = "Expecting equal - are equal.";
}
else
{
resultDesc = "Expecting equal - are not equal.";
testResult = false;
}
}
break;
case 3:
testDesc = "SudokuSolver.getSolutionBoardCells()";
{
SudokuSolver s = new SudokuSolver(a);
s.solve();
int[,] b = s.getSolvedBoard();
int[,] c = SudokuStore.boardCopy(a);
BoardCell[] sol = s.getSolutionBoardCells();
foreach (BoardCell bc in sol)
{
c[bc.rowIndex, bc.colIndex] = bc.digit;
}
if ((SudokuStore.boardsAreEqual(b, c) == true))
{
resultDesc = "Expecting equal - are equal.";
}
else
{
resultDesc = "Expecting equal - are not equal.";
testResult = false;
}
}
break;
case 4:
testDesc = "SudokuSolver.getAllBoardCells()";
{
SudokuSolver s = new SudokuSolver(a);
int[,] b = s.getBoardCopy();
int[,] c = new int[SudokuBoard.BOARD_SIZE, SudokuBoard.BOARD_SIZE];
BoardCell[] bc = s.getAllBoardCells();
foreach (BoardCell cell in bc)
{
c[cell.rowIndex, cell.colIndex] = cell.digit;
}
if ((SudokuStore.boardsAreEqual(b, c) == true))
{
resultDesc = "Expecting equal - are equal.";
}
else
{
resultDesc = "Expecting equal - are not equal.";
testResult = false;
}
}
break;
case 5:
testDesc = "SudokuSolver.getAllSolutionsList()";
{
SudokuSolver s = new SudokuSolver(SudokuPuzzles.PUZZLE_NON_UNIQUE_SOLUTION);
s.findAllSolutions();
List <SudokuBoard> solList;
solList = s.getAllSolutionsList();
foreach (SudokuBoard sb in solList)
{
if (SudokuStore.checkSolvedBoard(sb.board) == false)
{
testResult = false;
break;
}
}
if (testResult == true)
{
resultDesc = "Expecting each solution valid - each is valid.";
}
else
{
resultDesc = "Expecting each solution valid - found not valid.";
}
}
break;
case 6:
testDesc = "SudokuGenerator -> generate -> save -> load -> compare";
{
String filePath = FileX.getTmpDir() + FileX.genRndFileName(20, "txt");
SudokuGenerator g = new SudokuGenerator(SudokuGenerator.PARAM_GEN_RND_BOARD);
int[,] generated = g.generate();
g.saveBoard(filePath, "generated", "saved");
int[,] loaded = SudokuStore.loadBoard(filePath);
FileX.removeFile(filePath);
if (SudokuStore.boardsAreEqual(generated, loaded) == false)
{
testResult = false;
}
if (testResult == true)
{
resultDesc = "Expecting equal - are equal.";
}
else
{
resultDesc = "Expecting equal - are not equal.";
}
}
break;
case 7:
testDesc = "SudokuSolver -> solve -> save -> load -> compare";
{
String filePath = FileX.getTmpDir() + FileX.genRndFileName(20, "txt");
SudokuSolver s = new SudokuSolver(SudokuStore.getPuzzleExample());
s.solve();
int[,] solved = s.getSolvedBoard();
s.saveSolvedBoard(filePath, "solved", "saved");
int[,] loaded = SudokuStore.loadBoard(filePath);
FileX.removeFile(filePath);
if (SudokuStore.boardsAreEqual(solved, loaded) == false)
{
testResult = false;
}
if (testResult == true)
{
resultDesc = "Expecting equal - are equal.";
}
else
{
resultDesc = "Expecting equal - are not equal.";
}
}
break;
}
if (testResult == true)
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + " " + testDesc + " " + resultDesc + " >>> ApiTests, result: OK");
}
else
{
SudokuStore.consolePrintln("(Thread: " + threadId + ") " + "Test: " + testId + " " + testDesc + " " + resultDesc + " >>> ApiTests, result: ERROR");
}
return(testResult);
}
