Dense random matrix to (un)directed graph as sparse matrix?

I want to work on some "maximum flow" problems to understand the algorithms, but my notion of what would be a simple set-up to test them is proving difficult to implement.

Take a look at this Project Euler problem: http://projecteuler.net/problem=83

What I want to do is assume each of those cells is connected to all of its adjacent cells ("+" pattern), and then create a path between every pair with cost == to the largest value between the two of them ie: `max(cell1, cell2`)

So a simple `[[s 4],[3 t]]` matrix would become `[(s, (0,1), 4), (s, (1,0), 3), ((0,1), t, 3), ((1,0), 4, t)]` (node1, node2, cost) + all of the paths going in the other direction.

Maybe there is a simpler way of describing what it is that I am trying to do, but I would appreciate any help.

Other details: I'm using Python and NumPy.

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Maybe it is me, but I am unable to understand what your simple example is all about, can you try to reformulate it a bit? – Jaime Feb 25 '13 at 22:16

Here is the ipython notebook code to calculate the edges of Project Euler problem 83. Instead of 2D coordinates, I use index for every elements in the matrix.

``````In [1]:

import numpy as np
from StringIO import StringIO
data = StringIO("""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""")
m

Out[1]:

array([[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]])

In [2]:

# give every element an index
idx = np.arange(m.size).reshape(m.shape)
idx

Out[2]:

array([[ 0,  1,  2,  3,  4],
[ 5,  6,  7,  8,  9],
[10, 11, 12, 13, 14],
[15, 16, 17, 18, 19],
[20, 21, 22, 23, 24]])

In [3]:

# create edges
left_edges = np.concatenate([idx[:, :-1, None], idx[:, 1:, None], m[:, 1:, None]], axis=2).reshape(-1, 3)
right_edges = np.concatenate([idx[:, 1:, None], idx[:, :-1, None], m[:, :-1, None]], axis=2).reshape(-1, 3)
down_edges = np.concatenate([idx[:-1, :, None], idx[1:, :, None], m[1:, :, None]], axis=2).reshape(-1, 3)
up_edges = np.concatenate([idx[1:, :, None], idx[:-1, :, None], m[:-1, :, None]], axis=2).reshape(-1, 3)
edges = np.vstack((left_edges, right_edges, down_edges, up_edges))
edges

Out[3]:

array([[  0,   1, 673],
[  1,   2, 234],
[  2,   3, 103],
[  3,   4,  18],
[  5,   6,  96],
[  6,   7, 342],
[  7,   8, 965],
[  8,   9, 150],
[ 10,  11, 803],
[ 11,  12, 746],
[ 12,  13, 422],
[ 13,  14, 111],
[ 15,  16, 699],
[ 16,  17, 497],
[ 17,  18, 121],
[ 18,  19, 956],
[ 20,  21, 732],
[ 21,  22, 524],
[ 22,  23,  37],
[ 23,  24, 331],
[  1,   0, 131],
[  2,   1, 673],
[  3,   2, 234],
[  4,   3, 103],
[  6,   5, 201],
[  7,   6,  96],
[  8,   7, 342],
[  9,   8, 965],
[ 11,  10, 630],
[ 12,  11, 803],
[ 13,  12, 746],
[ 14,  13, 422],
[ 16,  15, 537],
[ 17,  16, 699],
[ 18,  17, 497],
[ 19,  18, 121],
[ 21,  20, 805],
[ 22,  21, 732],
[ 23,  22, 524],
[ 24,  23,  37],
[  0,   5, 201],
[  1,   6,  96],
[  2,   7, 342],
[  3,   8, 965],
[  4,   9, 150],
[  5,  10, 630],
[  6,  11, 803],
[  7,  12, 746],
[  8,  13, 422],
[  9,  14, 111],
[ 10,  15, 537],
[ 11,  16, 699],
[ 12,  17, 497],
[ 13,  18, 121],
[ 14,  19, 956],
[ 15,  20, 805],
[ 16,  21, 732],
[ 17,  22, 524],
[ 18,  23,  37],
[ 19,  24, 331],
[  5,   0, 131],
[  6,   1, 673],
[  7,   2, 234],
[  8,   3, 103],
[  9,   4,  18],
[ 10,   5, 201],
[ 11,   6,  96],
[ 12,   7, 342],
[ 13,   8, 965],
[ 14,   9, 150],
[ 15,  10, 630],
[ 16,  11, 803],
[ 17,  12, 746],
[ 18,  13, 422],
[ 19,  14, 111],
[ 20,  15, 537],
[ 21,  16, 699],
[ 22,  17, 497],
[ 23,  18, 121],
[ 24,  19, 956]])
``````

Then you can convert `edges` to a sparse matrix by `scipy.sparse.coo_matrix`

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-1 Every time you publish a solution to a Project Euler problem on-line, God kills a kitten. – Jaime Feb 26 '13 at 7:32
I have solved problems 81, 82 and 83 ages ago. They're just a good reference point for my current problem. – RodericDay Mar 8 '13 at 19:22