# Numpy meshgrid points

I want to create the list of points that would correspond to a grid. So if I want to create a grid of the region from (0,0) to (1,1), it would contain the points (0,0), (0,1), (1,0), (1,0).

I know that that this can be done with the following code:

g = np.meshgrid([0,1],[0,1])
np.append(g[0].reshape(-1,1),g[1].reshape(-1,1),axis=1)

Yielding the result:

array([[0, 0],
[1, 0],
[0, 1],
[1, 1]])

My question is twofold:

1. Is there a better way of doing this?
2. Is there a way of generalizing this to higher dimensions?
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I just noticed that the documentation in numpy provides an even faster way to do this:

X, Y = np.mgrid[xmin:xmax:100j, ymin:ymax:100j]
positions = np.vstack([X.ravel(), Y.ravel()])

This can easily be generalized to more dimensions using the linked meshgrid2 function and mapping 'ravel' to the resulting grid.

g = meshgrid2(x, y, z)
positions = np.vstack(map(np.ravel, g))

The result is about 35 times faster than the zip method for a 3D array with 1000 ticks on each axis.

To compare the two methods consider the following sections of code:

Create the proverbial tick marks that will help to create the grid.

In [23]: import numpy as np

In [34]: from numpy import asarray

In [35]: x = np.random.rand(100,1)

In [36]: y = np.random.rand(100,1)

In [37]: z = np.random.rand(100,1)

Define the function that mgilson linked to for the meshgrid:

In [38]: def meshgrid2(*arrs):
....:     arrs = tuple(reversed(arrs))
....:     lens = map(len, arrs)
....:     dim = len(arrs)
....:     sz = 1
....:     for s in lens:
....:        sz *= s
....:     ans = []
....:     for i, arr in enumerate(arrs):
....:         slc = [1]*dim
....:         slc[i] = lens[i]
....:         arr2 = asarray(arr).reshape(slc)
....:         for j, sz in enumerate(lens):
....:             if j != i:
....:                 arr2 = arr2.repeat(sz, axis=j)
....:         ans.append(arr2)
....:     return tuple(ans)

Create the grid and time the two functions.

In [39]: g = meshgrid2(x, y, z)

In [40]: %timeit pos = np.vstack(map(np.ravel, g)).T
100 loops, best of 3: 7.26 ms per loop

In [41]: %timeit zip(*(x.flat for x in g))
1 loops, best of 3: 264 ms per loop
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Are your gridpoints always integral? If so, you could use numpy.ndindex

print list(np.ndindex(2,2))

Higher dimensions:

print list(np.ndindex(2,2,2))

Unfortunately, this does not meet the requirements of the OP since the integral assumption (starting with 0) is not met. I'll leave this answer only in case someone else is looking for the same thing where those assumptions are true.

Another way to do this relies on zip:

g = np.meshgrid([0,1],[0,1])
zip(*(x.flat for x in g))

This portion scales nicely to arbitrary dimensions. Unfortunately, np.meshgrid doesn't scale well to multiple dimensions, so that part will need to be worked out, or (assuming it works), you could use this SO answer to create your own ndmeshgrid function.

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Good suggestion, but unfortunately they are not. Edit... also the ranges won't necessarily begin with the point (0,0,...). –  juniper- Oct 12 '12 at 17:51
@juniper -- Too bad. I've added another solution which might be of interest ... –  mgilson Oct 12 '12 at 18:06
That'll do. Thanks! –  juniper- Oct 12 '12 at 18:21

Yet another way to do it is:

np.indices((2,2)).T.reshape(-1,2)

Which can be generalized to higher dimensions, e.g.:

In [60]: np.indices((2,2,2)).T.reshape(-1,3)
Out[60]:
array([[0, 0, 0],
[1, 0, 0],
[0, 1, 0],
[1, 1, 0],
[0, 0, 1],
[1, 0, 1],
[0, 1, 1],
[1, 1, 1]])
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