I am currently studying the beautiful topic of recursive backtracking.
I've already tried classical examples like finding the shortest path out of a maze, or the n-queens problem. But the problem I'm working on right now really keeps me confused:
Actually I thought it might be an easy exercise to solve a simple jigsaw-puzzle:
I have a board with the size of n = a * b and exactly that much (n) pieces.

In the end I want to have all the pieces to be put on the board in a certain order where they obey certain restrictions (like matching their neighbours). Fairly easy, I thought and I came up with the following algorithm:

```
public board recursiveSolve(Board board, Piece[] pieces, int position){
// base case
if(position == board.getLength())
return board;
else{
// For each possible piece
for(int i = 0; i < pieces.length; i++){
// if the piece is placeable at that position
// place it and search on recursively
if(board.isValid(piece[i], position)){
board.putPiece(pieces[i], position);
// THIS IS THE FISHY PART!!
// Now I need to pass a set of pieces to the function recursively
// that does not contain the current one (pieces[i])
// But I fear my (following) approach is too heap-intensive
Piece[] subPieces = new Piece[pieces.length - 1];
// fill subPieces with all elements from pieces except from the one
// at position i
for (int j = 0; j < subPieces.length; j++) {
if(j >= i)
subPieces[j] = pieces[j+1];
else
subPieces[j] = pieces[j];
}
if(recursiveSolve(board, subPieces, position + 1) != null)
return board;
else
board.removePiece(position);
}
}
// If this is reached, none of the pieces have worked -> go back
return null;
}
```

Well basically, this algorithm does what it should do - but unfortunately it only works for "small" board sizes (n < 100). Because if I have a board like 10 x 10 squares and 100 pieces, the function searches and searches and just doesn't come to an end until JVM crashes due to insufficient heap space. I even tried setting eclipse's memory size limit up to 1.2g which made the function work longer but still was not enough.

So my question is: Is it possible to optimize the algorithm above to make it work for board sizes n > 100? What am I doing wrong? Or am I taking the entirely wrong approach?

Thank your very much for you help in advance.