# How to push the for-loop down to numpy

I have the following piece of code doing exactly what i want (it is part of a kriging method). But the problem is that it goes too slow, and i wish to know if there is any option to push the for-loop down to numpy? If i push out the numpy.sum, and use the axis argument there, it speeds up a little bit, but apparently that is not the bottleneck. Any ideas on how i can push down the forloop to numpy to speed it up, or other ways to speed it up?)

``````# n = 2116
print GRZVV.shape  # (16309, 2116)
print GinvVV.shape  # (2117, 2117)
VVg = numpy.empty((GRZVV.shape))

for k in xrange(GRZVV.shape):
GRVV = numpy.empty((n+1, 1))
GRVV[n, 0] = 1
GRVV[:n, 0] = GRZVV[k, :]
EVV = numpy.array(GinvVV * GRVV)  # GinvVV is numpy.matrix
VVg[k] = numpy.sum(EVV[:n, 0] * VV)
``````

I posted the dimensions of the ndarrays n matrix to clear some stuff out

edit: shape of VV is 2116

• What shape is `VV`? – Joel Vroom Sep 23 '13 at 13:20
• If `VV.shape == (16309,)`, how can you mulitply it by `EVV[:n, 0]` which has shape `(n,)`? – askewchan Sep 23 '13 at 13:27
• Maybe the last line of your loop should have `EVV[:n, 0] * VV[k]`, which seems to be what @Jaime's answer assumes. – askewchan Sep 23 '13 at 13:35
• @askewchan shape was 2116, was a bit confused there, i edited it in, – usethedeathstar Sep 23 '13 at 13:38

## 2 Answers

You could do the following in place of your loop over k (runtime ~3s):

``````tmp = np.concatenate((GRZVV, np.ones((16309,1),dtype=np.double)), axis=1)
EVV1 = np.dot(GinvVV, tmp.T)
#Changed line below based on *askewchan's* recommendation
VVg1 = np.sum(np.multiply(EVV1[:n,:],VV[:,np.newaxis]), axis=0)
``````
• This gives the same result as @usethedeathstar's code, and runs 15x faster on my machine. – askewchan Sep 23 '13 at 13:55
• No need for the tile call, as the `np.multiply` broadcasts. Change it to: `VVg1 = np.sum(np.multiply(EVV1[:n,:],VV[:,np.newaxis]), axis=0)` for a small speedup. – askewchan Sep 23 '13 at 14:08
• +1 Good call....I edited the line above...thanks – Joel Vroom Sep 23 '13 at 14:17
• +1 Much, much faster than `np.einsum` for large arrays, not sure I understand why... – Jaime Sep 23 '13 at 16:11
• slight issue: VVg1 is still a numpy.matrix instead of ndarray? is this affecting the np.multiply or so? I assume/hope not, or should i after the np.dot do a cast to numpy.array on the EVV1? – usethedeathstar Sep 25 '13 at 8:18

You are basically taking each row of `GRZVV`, appending a 1 at the end, multiplying it with `GinvVV`, then adding up all the elements in the vector. If you weren't doing the "append 1" thing, you could do it all with no loops as:

``````VVg = np.sum(np.dot(GinvVV[:, :-1], GRZVV.T), axis=-1) * VV
``````

or even:

``````VVg = np.einsum('ij,kj->k', GinvVV[:, :-1], GRZVV) * VV
``````

How do we handle that extra 1? Well, the resulting vector coming from the matrix multiplication would be incremented by the corresponding value in `GinvVV[:, -1]`, and when you add them all, the value will be incremented by `np.sum(GinvVV[:, -1])`. So we can simply calculate this once and add it to all the items in the return vector:

``````VVg = (np.einsum('ij,kj->k', GinvVV[:-1, :-1], GRZVV) + np.sum(GinvVV[:-1, -1])) * VV
``````

The above code works if `VV` is a scalar. If it is an array of shape `(n,)`, then the following will work:

``````GinvVV = np.asarray(GinvVV)
VVgbis = (np.einsum('ij,kj->k', GinvVV[:-1, :-1]*VV[:, None], GRZVV) +
np.dot(GinvVV[:-1, -1], VV))
``````
• With @usethedeathstar's edit, `VV.shape` is now 2116, so doesn't broadcast in your solution (since `Wg.shape` is 16309) – askewchan Sep 23 '13 at 13:44
• Figured it was a scalar. With a full array, not collapsing the array till the end, as in Joel's answer, is much faster than the above for large arrays. – Jaime Sep 23 '13 at 16:12