I have a single threaded Sudoku solver that I want to use multithreading in. I plan to delegate N number of threads to each array in the board. Each thread will return the number of possibilities that they found in each cell that they are working on and from there we test those values out and backtrack if necessary.

What I'm stuck on is how to keep everything synced once a thread inserts a possible value on the board because it changes the number of possibilities in other threads.

I am using a heuristic called *the most constrained variable*. At every step, we calculate the number of possibilities in each cell and try to find a value in that cell that has least possible candidates to minimize collision. For example:

```
1 2 0 0
0 0 0 0
0 0 0 0
0 0 3 4
```

Row 1 column 3 has the fewest possible candidates (1), and only 4 can be put there. This is the heart of the algorithm and what I want to parallelize using multi-threading.

Here is the class that I use to solve a Sudoku puzzle:

```
public class LogicalSolver
{
private int numberOfSteps;
public LogicalSolver()
{
numberOfSteps = 0;
}
public boolean runLogicSolver(SudokuBoard board)
{
return logicalSolver(board);
}
private boolean logicalSolver(SudokuBoard board)
{
boolean solved = false;
int row = -1;
int column = -1;
int candidates[] = new int[board.GRIDSIZE];
int numOfCandidates = 0;
for (int currentRow = 0; currentRow < board.GRIDSIZE; currentRow++)
{
for (int currentColumn = 0; currentColumn < board.GRIDSIZE; currentColumn++)
{
if (board.getValue(currentRow, currentColumn) == 0)
{
int newCandidates[] = getCandidates(board, currentRow, currentColumn);
int numOfNewCandidates = getNumOfNewCandidates(newCandidates);
if (row < 0 || numOfNewCandidates < numOfCandidates)
{
row = currentRow;
column = currentColumn;
candidates = newCandidates;
numOfCandidates = numOfNewCandidates;
}
}
}
}
if (row < 0)
{
solved = true;
}
else
{
for (int i = 0; i < candidates.length && candidates[i] != 0; i++)
{
board.setValue(row, column, candidates[i]);
numberOfSteps++;
if (logicalSolver(board))
{
solved = true;
break;
}
board.setValue(row, column, 0);
}
}
return solved;
}
private int[] getCandidates(SudokuBoard board, int row, int column)
{
int newCandidates[] = new int[board.GRIDSIZE];
int index = 0;
for (int value = 1; value <= board.GRIDSIZE; value++)
{
boolean collision = false;
for (int offset = 0; offset < board.GRIDSIZE; offset++)
{
int rowSubGrid = (row - row % board.ROWS) + (offset / board.ROWS);
int columnSubGrid = (column - column % board.COLUMNS) + (offset % board.COLUMNS);
if (board.getValue(row, offset) == value || board.getValue(offset, column) == value
|| board.getValue(rowSubGrid, columnSubGrid) == value)
{
collision = true;
break;
}
}
if (!collision)
{
newCandidates[index] = value;
index++;
}
}
return newCandidates;
}
private int getNumOfNewCandidates(int newCandidates[])
{
int numOfNewCandidates = 0;
for (int i = 0; i < newCandidates.length && newCandidates[i] != 0; i++)
{
numOfNewCandidates++;
}
return numOfNewCandidates;
}
public void displayNumberOfSteps()
{
System.out.println("It took " + numberOfSteps + " steps to solve this puzzle. \n");
}
}
```