## BACKGROUND:

I'm trying to learn algorithms and java. Running a grid of 320x320, 100 trials runs about 5 times faster than a non-recursive Quick-Union implementation. However, beyond above a grid of about 400x400 (160,000 sites), I have stack overflow errors.

I understand that java is not optimized for tail-recursion (let alone non-tail recursion). However, I suppose there to be times when a recursive algorithm could be chosen over a non-recursive version because it can run faster and just as safe.

Please keep in mind I'm just learning this stuff, and my code may not be optimal. However, I'm including it to better understand my question.

## THE QUESTION

What is the process to evaluate when a recursive algorithm can safely be used in a java application (given that it runs faster than a non-recursive alternative)?

## STATS ON RECURSIVE VERSUS UNION-FIND IMPLEMENTATION

(note: The 2x Ratio is simply the previous current run-time divided by the previous run-time)

```
|-----------|-----------|------------|-------------|-------------|
| N | Recursive | Recursive | Quick-Union | Quick-Union |
| (sites) | time | 2x Ratio | time | 2x Ratio |
|===========|===========|============|=============|=============|
| 196 | 35 | | 42 | |
| 400 | 25 | 0.71 | 44 | 1.05 |
| 784 | 45 | 1.80 | 46 | 1.05 |
| 1600 | 107 | 2.38 | 86 | 1.87 |
| 3136 | 48 | 0.45 | 113 | 1.31 |
| 6400 | 75 | 1.56 | 303 | 2.68 |
| 12769 | 183 | 2.44 | 858 | 2.83 |
| 25600 | 479 | 2.62 | 2682 | 3.13 |
| 51076 | 1253 | 2.62 | 8521 | 3.18 |
| 102400 | 4730 | 3.77 | 27256 | 3.20 |
|-----------|-----------|------------|-------------|-------------|
```

## THE RECURSIVE CLASS

```
public class PercolateRecur implements Percolation {
// the site has been opened for percolation but is not connected
private final int OPEN = 0;
// the site is not open for percolation (default state)
private final int BLOCKED = -1;
// the matrix that will be percolated. Values default to `BLOCKED = -1`
// two sites that are connected together share the same value.
private int[][] matrix;
// the size of the sides of the matrix (1 to n)
private int size;
// whether water can flow from top to bottom of the matrix
private boolean percolated;
public PercolateRecur(int N) {
percolated = false;
size = N;
initMatrix();
}
/**
* initializes the matrix to default values
*/
private void initMatrix() {
matrix = new int[size+1][size+1];
// open up the top of the matrix
for (int x = 1; x < size+1; x++)
matrix[x][0] = x;
// set all values in matrix to closed
for (int x = 1; x < size+1; x++)
for (int y = 1; y < size+1; y++)
matrix[x][y] = BLOCKED;
}
/**
* indicates site (x,y) is a valid coordinate
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
* @return boolean
*/
private boolean isValid(int x, int y) {
return x > 0 && x < size+1 && y > 0 && y < size+1;
}
/**
* returns value of site above (x,y)
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
* @return int value
*/
private int above(int x, int y) {
if (y <= 0)
return BLOCKED;
else
return matrix[x][y-1];
}
/**
* returns value of site below (x,y)
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
* @return int value
*/
private int below(int x, int y) {
if (y >= size)
return BLOCKED;
else
return matrix[x][y+1];
}
/**
* returns value of site left of (x,y)
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
* @return int value
*/
private int left(int x, int y) {
if (x <= 0)
return BLOCKED;
return matrix[x-1][y];
}
/**
* returns value of site right of (x,y)
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
* @return int value
*/
private int right(int x, int y) {
if (x >= size)
return BLOCKED;
else
return matrix[x+1][y];
}
/**
* connects (x,y) to open adjacent sites
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
*/
private void connect(int x, int y) {
if (isFull(x,y))
return;
if (above(x,y) > OPEN)
matrix[x][y] = above(x, y);
else if (below(x, y) > OPEN)
matrix[x][y] = below(x, y);
else if (left(x, y) > OPEN)
matrix[x][y] = left(x, y);
else if (right(x, y) > OPEN)
matrix[x][y] = right(x, y);
else if (matrix[x][y] == BLOCKED)
matrix[x][y] = OPEN;
}
/**
* recursively connects open sites in same group as (x,y)
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
*/
private void expand(int x, int y) {
if (!isFull(x, y))
return;
if (above(x,y) == OPEN)
openWith(x,y-1, matrix[x][y]);
if (below(x,y) == OPEN)
openWith(x,y+1, matrix[x][y]);
if (left(x,y) == OPEN)
openWith(x-1,y, matrix[x][y]);
if (right(x,y) == OPEN)
openWith(x+1,y, matrix[x][y]);
}
/**
* opens a site (x,y) on the matrix
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
*/
public void open(int x, int y) {
if (percolated || !isValid(x, y))
return;
connect(x, y);
expand(x, y);
}
/**
* opens a site with given value
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
* @param val value of point
*/
private void openWith(int x, int y, int val) {
matrix[x][y] = val;
open(x, y);
}
/**
* Returns whether site (x,y) is open
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
* @return true if not blocked
*/
public boolean isOpen(int x, int y) {
return matrix[x][y] > BLOCKED;
}
/**
* Returns whether site (x,y) is full (connected to the top)
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
* @return true if is full
*/
public boolean isFull(int x, int y) {
return matrix[x][y] > OPEN;
}
/**
* indicates whether site is blocked (not open)
* @param x x-portion of x/y coordinate
* @param y y-portion of x/y coordinate
* @return true if blocked
*/
public boolean isBlocked(int x, int y) {
return matrix[x][y] == BLOCKED;
}
/**
* indicates whether water can flow from top to bottom of matrix
* @return true if matrix is percolated
*/
public boolean percolates() {
for (int x = 1; x <= size; x++)
if (matrix[x][size] > OPEN)
percolated = true;
return percolated;
}
/**
* prints the matrix to the command line
*/
public void print() {
for (int y = 1; y < size+1; y++) {
System.out.println();
for (int x = 1; x < size+1; x++) {
if (matrix[x][y] == BLOCKED)
System.out.print("XX ");
else if (matrix[x][y] < 10)
System.out.print(matrix[x][y] + " ");
else
System.out.print(matrix[x][y] + " ");
}
}
System.out.println();
}
}
```