# efficiently updating a subset of a numpy array with unknown dimensionality

I have a N-dimensional numpy array, called S. Every iteration, exactly one value in this array will change.

I have a second array, G that stores the gradient of S, as calculated by numpy's gradient() function. Currently, my code unnecessarily recalculates all of G every time I update S, but this is unnecessary, as only one value in S has changed, and so I only should have to update (i.e. recalculate) 1+d*2 values in G, where d is the number of dimensions in S.

This would be an easier problem to solve if I knew the dimensionality of the arrays, but the solutions I have come up with in the absence of this knowledge have been quite inefficient (not substantially better than just recalculating all of G).

I bet there is some uber-clever way of doing this efficiently! Can anyone help me?

Edit: adding my attempt, as requested

The following code is what I have so far. The function returns a vector indicating the gradient of S at `coords` in each dimension. It calculates this without calculating the gradient of S at every point, but the problem is that it does not seem to be very efficient. It looks similar in some ways to the answers already posted, but maybe there is something quite inefficient about it?

The idea is the following: I iterate through each dimension, creating a slice that is a vector only in that dimension. For each of these slices, I calculate the gradient and place the appropriate value from that gradient into the correct place in the returned vector `grad`.

The use of `min()` and `max()` is to deal with the boundary conditions.

``````    def getSGradAt(self,coords) :
"""Returns the gradient of S at position specified by
the vector argument 'coords'.

self.nDim : the number of dimensions of S
self.nBins : the width of S (same in every dim)
self.s : S  """
for d in xrange(self.nDim) :
# create a slice through S that has size > 1 only in the current
# dimension, d.
slices = list(coords)
slices[d] = slice(max(0,coords[d]-1),min(self.nBins,coords[d]+2))
# take the middle value from the gradient vector
``````

The problem is that this doesn't run very quickly. In fact, just taking the gradient of the whole array S seems to run faster (for nBins = 25 and nDim = 4).

Edited again, to add my final solution

Here is what i ended up using. This function updates S, changing the value at `X` by the amount `change`. It then updates G using a variation on the technique proposed by Jaime.

``````    def changeSField(self,X,change) :
# change s
self.s[X] += change

slices = tuple(slice(None if j-2 <= 0 else j-2, j+3, 1) for j in X)
for i in arange(self.nDim) :
``````
-
`gradient` returns an array if the input is 1-dimensional and a list of arrays if the input has a number of dimensions other than 1. It looks like it wasn't meant to be used with arrays of runtime-determined dimension, and the list is going to exclude most of the clever slice-assignments you could do with an array. –  user2357112 Jul 21 '13 at 18:29

Your question is much to open for you to get a good answer: it is always a good idea to post your inefficient code, so that potential answerers can better help you. Anyway, lets say you know the coordinates of the point that has changed, and that you store those in a tuple named `coords`. First, lets construct a tuple of slices encompassing your point:

``````slices = tuple(slice(None if j-1 <= 0 else j-1, j+2, 1) for j in coords)
``````

You may want to extend the limits to `j-2` and `j+3` so that the gradient is calculated using central differences whenever possible, but it will be slower.

You can now update you array doing something like:

``````G[slices] = np.gradient(N[slices])
``````
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Thank you for your response. This seems like the right direction to go. To make it compatible with gradient (see the comment made by user2357112 above) the assignment required a little bit more than what you suggested. `for i in arange(len(g)) : g[i][slices] = s[i]` –  weemattisnot Jul 21 '13 at 21:10