# Given a NxN matrix, how could I find all possible paths to a location (i,i)?

Given a `NxN` matrix, how could I find all possible paths to a location `(i,i)`. Navigation would be only `downwards` and towards the `right`. The starting point would be `(0,0)`.

P.S. Not a homework.

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Where's the starting point? (0,0)? –  Mateusz Dymczyk Jul 31 '12 at 13:53
@Zenzen Yes, assuming the starting point as (0,0) –  Rahul Jul 31 '12 at 13:55

The easiest (for me) would be to do it recursively:

1) the stop condition would be arriving at (i,i)

2) you would try two next moves at each recursion level:

• can you go down
• can you go right

Assuming that your current position is (x,y): You cannot go right if your current "y" plus 1 would be bigger than "i" in the (i,i). You cannot go down if your current "x" plus 1 would be bigger than "i" in the (i,i).

You'd just have to remember the path in some variable or pass it downwards and print it when the stop condition occurs.

So assuming you start at (0,0) you remember this and then check if you can go right or down, if yes for both then you recursively call this same method for (0,1) and (1,0).

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I had the same in mind but was thinking about how to store the path and didn't think about the idea of passing the current path down the recursion. Thanx a lot. –  Rahul Jul 31 '12 at 14:09

?

To a location (i, i), i.e. one on the diagonal, there are exactly comb(i, 2 * i) paths (number of ways to select i elements from a set of 2 * i elements), each consisting of i movements rightward and i movements downward. Enumerating them is trivial.

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Although you can use DP to solve this, this is just simle math:

You have to make `2i` steps, from which `i` must be steps to the right. The total combinations are `C(2i,i)`. See: computing the binomial coefficients.

Another similar problem is where you cannot cross the diagonal, called monotonic path, for which the interesting Catalan number sequence is the solution.

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Solution 1 - Using dynamic programming : Add up the solutions bottom up till (i,j) indices you want:

ans(i,i) = ans(i-1,j) + ans(i,j-1) and use the same for position (i,i).

Solution 2 - Using simple permutation and combination

ans = (2i)!/ i!i! (Since you have to choose any of the i steps towards the right and ji steps downwards starting from (0,0) and total are 2i steps).

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Look at the problem from a 45 degree angle. You'll see that you're trying to calculate the number of paths to a vertex on a triangular array. The solution is given by Pascal's triangle.

`2i choose i`

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