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In the 5 by 5 matrix below, the minimal path sum from the top left to the bottom right, by only moving to the right and down, is indicated in bold red and is equal to 2427.

131 673 234 103 18

201 96 342 965 150

630 803 746 422 111

537 699 497 121 956

805 732 524 37 331

Find the minimal path sum, in matrix.txt (right click and 'Save Link/Target As...'), a 31K text file containing a 80 by 80 matrix, from the top left to the bottom right by only moving right and down.

Remark: I think they did mistake, when they mark the way http://projecteuler.net/problem=81

import numpy as np

matrix0 = [ map(int, row.split()) for row in open('matrix.txt')]


for i in range(80):
    for j in range(80):
        matrix[i, j]=0

for i in range(80):
    for j in range(80):
        matrix[i, j]=matrix0[i][j]


while (k+n)<158:
    for i in range(k, k+1):
        for j in range(n, n+1):
            if i!=79 and j!=79:
                if matrix[i+1, j]<=matrix[i, j+1]:
                    sum=sum+matrix[i+1, j]
                    sum+=matrix[i, j+1]
            elif i==79:
                sum+=matrix[i, j+1]
            elif j==79:
                sum+=matrix[i+1, j]

print sum

When I use this code for the matrix 5x5 like in problem it gives me correct answer. I can't understand why it doesn't work on bigger matrix?

share|improve this question

Because you're not performing the search properly. The problem is asking for the overall least cost path, so you want an A* search or Dijkstra's algorithm. A simple one pass check for lowest branch at each node won't cut it.

share|improve this answer
For an 80x80 matrix you could use the Floyd as well, just wait a little longer :) – unkulunkulu Jun 27 '12 at 8:28
so why it works on example matrix? – Alibek Galiyev Jun 27 '12 at 8:30
Because it just so happens that the naive algorithm that you are using happens to work on the example matrix. Consider instead the matrix: [[001, 002, 001, 001], [001, 002, 001, 001], [001, 002, 001, 001], [001, 999, 999, 001]]. The algorithm you have would take you down, (001 vs 002), down (001 vs 002), down (001 vs 002). Then right 3 times (999, 999, 001). Whereas a more intelligent algorithm would find the lower cost routes that have some locally suboptimal choices. – OmnipotentEntity Jun 27 '12 at 8:38
ok, i got it! I think i didn't understand the problem properly. In problem condition, they didn't have mistake!!! I'm going to learn this algorithms – Alibek Galiyev Jun 27 '12 at 8:47
i don't think the best way to solve the problem is any shortest path algorithm, there's quite a obvious DP model. – Marcus Jun 27 '12 at 8:56

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