# Performing operations on all values of a numpy array, referencing i and j

I am trying to improve numpy performance by applying operations on a 2d array, the problem is that the value at each element in the array depends on the i,j location of that element.

Obviously the easy way to do this is to use a nested for-loop, but I was wondering if there might be a better way by referencing np.indices or something along those lines? Here is my 'stupid' code:

``````for J in range(1025):
for I in range(1025):
PSI[I][J] = A*math.sin((float(I+1)-.5)*DI)*math.sin((float(J+1)-.5)*DJ)
P[I][J] = PCF*(math.cos(2.*float(I)*DI)+math.cos(2.*float(J)*DJ))+50000.
``````
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Noone explicitly addressed this but using python for loops where you index numpy arrays is losing the speed benefits of numpy being written in C. – n611x007 Jan 29 '13 at 10:21

Since you're doing multiplication among your two arrays, you can use the outer function, after using `arange` to get arrays of your sin/cos.

Something like this (use numpy's trig functions, since they're vectorized)

``````PSI_i = numpy.sin((arange(1,1026)-0.5)*DI)
PSI_j = numpy.sin((arange(1,1026)-0.5)*DJ)
PSI = A*outer(PSI_i, PSI_j)

P_i = numpy.cos(2.*arange(1,1026)*DI)
P_j = numpy.cos(2.*arange(1,1026)*DJ)
P = PCF*outer(P_i, P_j) + 50000
``````

If your environment is set up using `from numpy import *` or `from pylab import *`, then you don't need those `numpy.` prefixes before your trig functions. I kept them in to distinguish them from the `math` ones, which won't work for this approach.

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For this particular problem, I think that this is the best solution (+1) – mgilson May 30 '12 at 17:59
This is the right approach, but if you're using `numpy.sin` you probably should use `numpy.outer`. – DSM May 30 '12 at 18:00
@tillsten - For whatever it's worth, you can use `outer` for subtraction, division, power, etc as well. E.g. `numpy.subtract.outer(a, b)`, `numpy.power.outer(a, b)`, etc. – Joe Kington May 30 '12 at 18:08
@tillsten - It only works for `ufuncs`, so it's still limited (broadcasting is more general). It's a handy trick, though. Glad you found it useful! – Joe Kington May 30 '12 at 18:11

You can get a grid of the index values with indices:

``````I,J=np.indices(PSI.shape)
#All constants set to one
PSI2=np.sin(I+1-.5)*np.sin(J+1-.5)
print PSI-PSI2 # should be zero.
``````

I did some timings with ipython:

``````import numpy as np
import math
A = 1
P = 1
DI = 1
DJ = 1

def a():
PSI=np.zeros((1025,1025))
for J in range(1025):
for I in range(1025):
PSI[I][J] = A*math.sin((float(I+1)-.5)*DI)*math.sin((float(J+1)-.5)*DJ)
%timeit a()

def b():
PSI=np.zeros((1025,1025))
for I,J in np.ndindex(*PSI.shape):
PSI[I,J] = A*math.sin((float(I+1)-.5)*DI)*math.sin((float(J+1)-.5)*DJ)
%timeit b()

def c():
I,J=np.indices((1025, 1025))
P2=A*np.sin((I+1-.5)*DI)*np.sin((J+1-.5)*DJ)
%timeit c()

def d():
PSI_i = np.sin((np.arange(1,1026)-0.5)*DI)
PSI_j = np.sin((np.arange(1,1026)-0.5)*DJ)
PSI = A*np.outer(PSI_i, PSI_j)
%timeit d()
``````

The result is not at all surprising on my machine:

``````1 loops, best of 3: 1.75 s per loop
1 loops, best of 3: 3.51 s per loop
10 loops, best of 3: 77.1 ms per loop
100 loops, best of 3: 7.16 ms per loop
``````
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You're not actually calling the functions. You need `%timeit a()`, etc., not `%timeit a`. – DSM May 30 '12 at 18:52
Doing the timings correctly, I got that the solution with `np.outer` takes approximately 0.009s, the solution with indices takes ~0.12s the nested loops take 1.4s and `np.ndindex` takes a whopping 3.28s. I would like to know why `np.ndindex` is so slow -- I would have expected it to come between the other solutions, but I've deleted my answer anyway ;). (I guess this shows why we profile). – mgilson May 30 '12 at 19:14
@mgilson, the reason `ndindex` is so slow is that it returns a python iterator. `a = np.ndindex((10, 10)); print a.next(); print a.next()`. – senderle Jun 2 '12 at 13:58
@senderle -- Interesting. I thought that it would have returned a generator, but I guess that's what I get for not reading the docs carefully. – mgilson Jun 2 '12 at 15:36

Try the ndenumerate function of numpy, which returns the value as well as the indices:

``````>>> a
array([[5, 5, 5],
[1, 2, 3]])

>>> for index, value in numpy.ndenumerate(a):
...     print index, value

(0, 0) 5
(0, 1) 5
(0, 2) 5
(1, 0) 1
(1, 1) 2
(1, 2) 3
``````
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That's the way to do for decent-sized Python lists. But when using NumPy, that's to be avoided, both to not ruin the performance advantage of unboxed+packed data and C functions and because you're usually using those for huge amounts of data (OP's example already has a million elements). – delnan May 30 '12 at 17:54