# Rewrite Recursive algorithm more simply - Euler 15

I would like to rewrite the functionality of this algorithm (which I used to solve ProjectEuler problem 15) in a non recursive way.

Yes, I realise there are many better ways to solve the actual problem, but as a challenge I would like to simplify this logic as much as possible.

``````public class SolveRecursion
{
public long Combination = 0;
public int GridSize;

public void CalculateCombination(int x = 0, int y = 0)
{
if (x < GridSize)
{
CalculateCombination(x + 1, y);
}
if (y < GridSize)
{
CalculateCombination(x, y + 1);
}
if (x == GridSize && y == GridSize)
Combination++;
}
}
``````

And tests:

``````[Test]
{
solveRecursion.GridSize = 3;
solveRecursion.CalculateCombination();
var result = solveRecursion.Combination;
Assert.AreEqual(20, result);
}

[Test]
{
solveRecursion.GridSize = 4;
solveRecursion.CalculateCombination();
var result = solveRecursion.Combination;
Assert.AreEqual(70, result);
}
``````

EDIT: Here is another simple function written in both ways:

``````//recursion
private int Factorial(int number)
{
if (number == 0)
return 1;
int returnedValue = Factorial(number - 1);

int result = number*returnedValue;
return result;
}

//loop
private int FactorialAsLoop(int number)
{
//4*3*2*1
for (int i = number-1; i >= 1; i--)
{
number = number*i;
}
return number;
}
``````

Any hints would be greatly appreciated. I've tried dynamic programming solution (which uses a more maths based approach), and an equation to successfully solve the puzzle.

I wonder - can this first algorithm be made non recursive, simply?

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possible duplicate of Way to go from recursion to iteration – Kirk Woll Jun 5 '12 at 1:46
If you mean you want to preserve the algorithm without using recursive call, so stack and loop might be used to mimic the recursion, yet I don't see any point to do so. – tia Jun 5 '12 at 1:51
Thanks...agreed that doing a stack and loop wouldn't make things simpler.. – Dave Mateer Jun 5 '12 at 3:12

The non-recursive solution is:

``````const int n = 4;
int a[n + 2][n + 2] = {0};

a[0][0] = 1;
for (int i = 0; i < n + 1; ++i)
for (int j = 0; j < n + 1; ++j) {
a[i][j + 1] += a[i][j];
a[i + 1][j] += a[i][j];
}

std::cout << a[n][n] << std::endl;
``````

Just for information, this problem should have been solved on the paper, the answer for NxM grid is C(N+M,N), where C is the combination function - http://en.wikipedia.org/wiki/Combination

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