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I have a n*n matrix, where each element represents an integer. Starting in [0,0] I have to find the path of exactly m elements down to the last row, returning the maximum cost. The path can end in any column on the last row and n ≤ m ≤ n^2

I thought of finding all paths of length m from [0,0] to [n-1, 0], [n-1, 1] ... [n-1, n-1]. But it does not feel optimal...

Which algorithm would be the most efficient way of doing this? BFS or DFS?


Possible directions are down/right/left, but only visit each element at most once.


So for example, if this matrix is given (n=4):

[   1   4   1  20 ]
[   5   0   2   8 ]
[   6   8   3   8 ]
[   3   2   9   5 ]

And m=7, the path could be

[   →   →   →   ↓ ]
[   5   0   2   ↓ ]
[   6   8   3   ↓ ]
[   3   2   9   x ] = Path cost = 47


[   ↓   4   1  20 ]
[   ↓   0   2   8 ]
[   →   →   ↓   8 ]
[   3   2   →   x ] = Path cost = 32 

or if m = n^2

[   →   →   →   ↓ ]
[   ↓   ←   ←   ← ]
[   →   →   →   ↓ ]
[   x   ←   ←   ← ]


Thanks to Wanderley Guimarães,

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Can you "go back" (or only right/down?) Are there negative integers? –  amit Oct 5 '12 at 10:38
Only down/left/right, can only visit each element at most 1 time. Only positive integers aswell –  hamohl Oct 5 '12 at 10:39

4 Answers 4

up vote 2 down vote accepted

You can solve this problem with dynamic programming. Let value(i, j) the value from position (i, j) of your matrix (i-th line, j-th column).

if i <  0 then f(i, j) = 0
if i == 0 then f(i, j) = value(i, j)
if i >  0 then f(i, j) = max(f(i-1, j), f(i, j-1)) + value(i, j)

That recurrence assume that you use a position from your matrix when you step down. So, you answer is max(f(m, 0), f(m-1, 1), f(m - 2, 2), ..., f(1, m)).

For example:

Give the follow matrix for n = 4:

1 1 1 1
1 2 1 1
2 1 1 1
1 2 1 1

If m = 2 then you cant go after second line. And you answer is f(2, 2) = 4.

If m = 4 then you cant go after third line. And you answer is f(3, 2) = 5.

(Im learning english so If you didnt understand something let me know and I will try to improve my explanation).

Edit :: allow down/left/right moves

You can implement follow recurrence:

if i == n, j == n, p == m, j == 0 then f(i, j, p, d) = 0
if d == DOWN  then f(i, j, p, d) = max(f(i+1, j, p+1, DOWN), f(i, j-1, p+1, RIGHT),   f(i, j+1, p+1,LEFT)) + value(i, j)
if d == LEFT  then f(i, j, p, d) = max(f(i+1, j, p+1, DOWN), f(i, j+1, p+1, LEFT )) + value(i, j)
if d == RIGHT then f(i, j, p, d) = max(f(i+1, j, p+1, DOWN), f(i, j-1, p+1, RIGHT)) + value(i, j)

This solution is O(n^4). Im trying to improve it.

You can test it at

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Note that this solution as well fails for the specific problem at hand since you can move left as well as right. –  amit Oct 5 '12 at 10:56
Note that m ≥ n, and one must always finish on the last row. Thus, if m=4 (number of visisted elements), the only path possible is [0,0]->[1,0]->[2,0]->[3,0] giving path cost of 5 –  hamohl Oct 5 '12 at 11:00
@hakanito: Your claim is true only if you assume m <= 2n. However, this is not the case - you assume m <=n^2 - you can make a complete "swap" of the matrix with m=n^2. I added a counter example that shows this issue in my answer, have a look. –  amit Oct 5 '12 at 11:29
max(f(i-1, j), f(i-1, j)) ?? This doesn't make much sense. –  Haile Oct 5 '12 at 11:37
@hakanito I think that I fixed my solution. –  Wanderley Guimarães Oct 5 '12 at 17:54

This problem is very known. The most efficient way of doing this is dynamic programming.

Let dp[i][j] is the maximum sum when coming to i,j from 0,0.
Then, dp[i][j] = max(dp[i - 1][j], dp[i][j - 1]) + matrix[i][j];

After doing this, check every value of position where you are able to go and get the maximum value.

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Note that the problem also allows "left", not only "right". –  amit Oct 5 '12 at 10:44
Yes, sorry, you are right. Haven't noticed this at first. –  dreamzor Oct 5 '12 at 10:46
You are of course right that dynamic programming is the way to go. But how do I restrict the path to a specific length? –  hamohl Oct 5 '12 at 10:50
Well, you get maximum of elements where i + j == m or something. –  dreamzor Oct 5 '12 at 10:51

This is actually a DAG, and therefore the dynamic programming solution to the longest path problem works.

Why a DAG, you say? There is an obvious cycle going from two vertices that are horizontally adjacent. If you use the "obvious" graph, of course.

The less obvious approach is to rework this as a graph of (vertex, direction), in which direction is the last direction you took from down/left/right. A vertex that has direction down can go either down, left, or right, whereas a vertex with direction right can only go down/right, and a vertex with direction left can only go left/down. This graph is clearly acyclic, and it comprises all possible paths in the original matrix.

Therefore, ignoring the limit m, a possible recursion for the longest path to (a, b, direction) is

pdl[i][j] = max(pdl[i][j-1], pd[i-1][j])+arr[i][j];
pdr[i][j] = max(pdr[i][j+1], pd[i-1][j])+arr[i][j];
pd[i][j] = max(pdl[i][j], pdr[i][j]);

pd is the array for the "down" vertices, pdr for right and pdl is for left. As an implementation detail, note that I keep the max of the left and corresponding down vertex in pdl, but this doesn't really matter as any vertex with direction "down" can go left and down just as a "left" vertex would. Same for pdr.

The limit means you'll have to add another dimension to that DP solution, that is, you have to keep pd[i][j][moves], that keeps the highest sum possible until vertex (i, j) using exactly moves movements, obtaining the recursion

pdl[i][j][moves] = max(pdl[i][j-1][moves-1], pd[i-1][j][moves-1])+arr[i][j];
pdr[i][j][moves] = max(pdr[i][j+1][moves-1], pd[i-1][j][moves-1])+arr[i][j];
pd[i][j][moves] = max(pdl[i][j][moves-1], pdr[i][j][moves-1]);
share|improve this answer
how would you express this algorithm in pseudo-code? –  hamohl Oct 6 '12 at 12:52
The algorithm above is in C++, how could pseudo-code be any better? (I honestly don't know what else I could say in a pseudocode snippet.) –  ffao Oct 6 '12 at 13:28
No you are right, but your algorithm looked different than the one proposed by Wanderely. So I thought you perhaps could elaborate in psuedocode. Also, the C++ code does not work, I get the wrong answer in different test cases –  hamohl Oct 6 '12 at 13:34
algo is actually the same, that one works too. –  ffao Oct 7 '12 at 21:07

This Question can be solved using recursion and backtracking. Keep the count of steps covered till now and the cost of path till now.

Here is my implementation

void fun_me(int arr[4][4], int m, int n,int i,int j,int steps,int cost)

if(i>=n || j>=n)
if(i==n-1 && steps==m-1)

if(isvalid(i+1,j,n) && !visited[i+1][j])

if(isvalid(i,j+1,n) && !visited[i][j+1])

if(isvalid(i,j-1,n) && !visited[i][j-1])

return ;
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