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You are situated in an grid at position x,y. The dimensions of the row is dx,dy. In one step, you can walk one step ahead or behind in the row or the column. In how many ways can you take M steps such that you do not leave the grid at any point ?
You can visit the same position more than once.
You leave the grid if you for any x,y either x,y <= 0 or x,y > dx,dy.
1 <= M <= 300
1 <= x,y <= dx,dy <= 100

x y
dx dy

no of ways

6 6
12 12


6 6
12 12

If you are at position 6,6 then you can walk to (6,5),(6,7),(5,6),(7,6).

I am stuck at how to use Pascal's Triangle to solve it.Is that the correct approach? I have already tried brute force but its too slow.

C[i][j], Pascal Triangle
C[i][j] = C[i - 1][j - 1] + C[i - 1][j]

T[pos][stp] = T[pos + 1][stp - 1] + T[pos - 1][stp - 1]
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SO doesn't work like that. You post your code and ask about a problem with it, or you ask specific questions about different approaches to your problem. You don't post a puzzle and wait for the answers to roll in. –  Steve Jessop May 30 '12 at 8:37
@SteveJessop I have edited the question –  user1301541 May 30 '12 at 8:52
This is a variation of counting random walks on a 2D lattice. The Wikipedia article - en.wikipedia.org/wiki/Random_walk - would be a good place to start your research. It specifically refers to Pascal's Triangle as part of a solution to your counting problem. I tend to the view that a clever use of combinatorial formulae is a better approach than enumerating all the possibilities. –  High Performance Mark May 30 '12 at 9:19
You do not specify whether one may visit the same position more than once. Are you looking for a solution which allows or prohibits this? –  idz May 30 '12 at 10:12

2 Answers 2

up vote 0 down vote accepted

One way would be an O(n^3) dynamic programming solution:

Prepare a 3D array:

int Z[dx][dy][M]

Where Z[i][j][n] holds the number of paths that start from position (i,j) and last n moves.

The base case is Z[i][j][0] = 1 for all i, j

The recursive case is Z[i][j][n+1] = Z[i-1][j][n] + Z[i+1][j][n] + Z[i][j-1][n] + Z[i][j+1][n] (only include terms in the sumation that are on the map)

Once the array is filled out return Z[x][y][M]

To save space you can discard each 2D array for n after it is used.

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I need a faster solution than O(n^3) –  user1301541 May 30 '12 at 9:03
With the constraints given 300 x 100 x 100, this will only take a few milliseconds. I think this is what they are looking for. –  Andrew Tomazos May 30 '12 at 9:04

You can solve 1d problem with the formula you provided.

Let H[pos][step] be number of ways to move horizontal using given number of steps.
And V[pos][step] be number of ways to move vertical sing given number of steps.

You can iterate number of steps that will be made horizontal i = 0..M
Number of ways to move so is H[x][i]*V[y][M-i]*C[M][i], where C is binomial coefficient.

You can build H and V in O(max(dx,dy)*M) and do second step in O(M).

EDIT: Clarification on H and V. Supppose that you have line, that have d cells: 1,2,...,d. You're standing at cell number pos then T[pos][step] = T[pos-1][step-1] + T[pos+1][step-1], as you can move either forward or backward.

Base cases are T[0][step] = 0, T[d+1][step] = 0, T[pos][0] = 1.

We build H assuming d = dx and V assuming d = dy.

EDIT 2: Basically, the idea of algorithm is since we move in one of 2 dimensions and check is also based on each dimension independently, we can split 2d problem in 2 1d problems.

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does this count all possible interleavings of horizontal and vertical moves? –  Andrew Tomazos May 30 '12 at 9:11
@kilotaras Can you explain H & V in more detail –  user1301541 May 30 '12 at 9:15
@kilotaras M=2 dx=1 dy=12 x = 1 y = 6. V[6][2]*C[2][0]+V[6][1]*C[2][1]+V[6][0]*C[2][2] = (4*1)+(2*2)+(1*1)?? –  user1301541 May 30 '12 at 9:59
@user1301541 V[6][2]*H[1][0]*C[2][0]+V[6][1]*H[1][1]*C[2][1]+V[6][0]*H[1][2]*C[2][2] = (4*1*1)+(2*0*2)+(1*0*1) = 4 –  kilotaras May 31 '12 at 10:51

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