# Filling in a symmetric 2D array

I have this code, but I don't know how can I make it looks like a python code and not a c-like code:

``````n=10

a = [[0 for row in xrange(n)]for col in range(n) ]
for i in xrange(n):
a[i][0] = 1
a[0][i] = 1

for i in xrange(1,n):
for j in xrange(1,n):
a[i][j] = a[i-1][j] + a[i][j-1]
``````
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..Looks like python to me >_> –  Patrick T Nelson Mar 19 '12 at 5:31
he probably means `more pythonic` –  Doboy Mar 19 '12 at 5:34
you could use `[0]*n` with immutable types such as `int`, otherwise the code is fine. Without knowing where this code is used it is unclear whether you need to use `numpy` arrays, `comb(i+j, j, 1)` or something else –  J.F. Sebastian Mar 19 '12 at 6:51
Add some comments ;-) –  Tony Blundell Mar 19 '12 at 9:32

``````from itertools import product
n = 10

a = [[1 if i==0 or j==0 else 0 for i in range(n)] for j in range(n)]

for i,j in product(range(1, n), repeat=2):
a[i][j] = a[i-1][j] + a[i][j-1]
``````

You could also generate `a` like this:

``````a = [[1 - (i > 0 < j) for i in range(n)] for j in range(n)]
``````
-

You seem to be generating a grid of binomial coefficients.

Look how this is done with Scipy:

``````>>> from scipy import *
>>> n = 10
>>> fromfunction(lambda i,j: comb(i+j, j), shape=(n,n))
array([[  1.00e+00,   1.00e+00,   1.00e+00,   1.00e+00,   1.00e+00,   1.00e+00,   1.00e+00,   1.00e+00,   1.00e+00,   1.00e+00],
[  1.00e+00,   2.00e+00,   3.00e+00,   4.00e+00,   5.00e+00,   6.00e+00,   7.00e+00,   8.00e+00,   9.00e+00,   1.00e+01],
[  1.00e+00,   3.00e+00,   6.00e+00,   1.00e+01,   1.50e+01,   2.10e+01,   2.80e+01,   3.60e+01,   4.50e+01,   5.50e+01],
[  1.00e+00,   4.00e+00,   1.00e+01,   2.00e+01,   3.50e+01,   5.60e+01,   8.40e+01,   1.20e+02,   1.65e+02,   2.20e+02],
[  1.00e+00,   5.00e+00,   1.50e+01,   3.50e+01,   7.00e+01,   1.26e+02,   2.10e+02,   3.30e+02,   4.95e+02,   7.15e+02],
[  1.00e+00,   6.00e+00,   2.10e+01,   5.60e+01,   1.26e+02,   2.52e+02,   4.62e+02,   7.92e+02,   1.29e+03,   2.00e+03],
[  1.00e+00,   7.00e+00,   2.80e+01,   8.40e+01,   2.10e+02,   4.62e+02,   9.24e+02,   1.72e+03,   3.00e+03,   5.01e+03],
[  1.00e+00,   8.00e+00,   3.60e+01,   1.20e+02,   3.30e+02,   7.92e+02,   1.72e+03,   3.43e+03,   6.43e+03,   1.14e+04],
[  1.00e+00,   9.00e+00,   4.50e+01,   1.65e+02,   4.95e+02,   1.29e+03,   3.00e+03,   6.43e+03,   1.29e+04,   2.43e+04],
[  1.00e+00,   1.00e+01,   5.50e+01,   2.20e+02,   7.15e+02,   2.00e+03,   5.00e+03,   1.14e+04,   2.43e+04,   4.86e+04]])
``````

This is also much faster than iterating over each element indexes with `for` loops.

Simple is better than complex. PEP20

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is there a way to keep numbers as `ints` and `longs`? –  Doboy Mar 19 '12 at 6:33
Argh, I was writing a very similar answer and then you answer came up. Anyways +1 :). –  Avaris Mar 19 '12 at 6:34
@Doboy, yes, just wrap the result in `array(..., dtype=int)`. –  ulidtko Mar 19 '12 at 6:35
don't use wildcard imports –  J.F. Sebastian Mar 19 '12 at 6:53

maybe using dictionaries would be cleaner? not sure though..

``````a = {}
for i in xrange(n):
a[i, 0] = a[0, i] = 1

for i in xrange(1, n):
for j in xrange(1, n):
a[i, j] = a[i-1, j] + a[i, j-1]
``````

or you can just write a function for this and letting the recursion figure things out.

``````@memoize
def a(i, j):
if i == 0 or j == 0:
return 1
else:
return a(i-1, j) + a(i, j-1)
``````
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spaces immediately inside `()`? ow my eyes hurt –  gnibbler Mar 19 '12 at 5:47
it was a convention at a place that i used to work at, sorry. –  Doboy Mar 19 '12 at 5:48
is that better guys? :D –  Doboy Mar 19 '12 at 5:57
Close :) can you take out the spaces around the `-` too? –  gnibbler Mar 19 '12 at 6:06
@gnibbler Spaces around operators is PEP8. –  agf Mar 19 '12 at 6:24

It looks fine to me, except that since you appear to be working with a 2D array, maybe numpy would be useful.

Then you could write e.g.

``````a = numpy.zeros((n,n))
a[0,:] = 1
a[:,0] = 1
``````
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I'm out of votes today; so have my virtual +1. By the way, numerical `for` loops in Python are very slow, I'd suggest that the best answer would use vectorization techniques and Numpy broadcasting. –  ulidtko Mar 19 '12 at 6:03