# Numpy Lookup (Map, or Point)

I have a large numpy array:

``````array([[32, 32, 99,  9, 45],  # A
[99, 45,  9, 45, 32],
[45, 45, 99, 99, 32],
[ 9,  9, 32, 45, 99]])
``````

and a large-ish array of unique values in a particular order:

``````array([ 99, 32, 45, 9])       # B
``````

How can I quickly (no python dictionaries, no copies of `A`, no python loops) replace the values in `A` so that become the indicies of the values in `B`?:

``````array([[1, 1, 0, 3, 2],
[0, 2, 3, 2, 1],
[2, 2, 0, 0, 1],
[3, 3, 1, 2, 0]])
``````

I feel reaaly dumb for not being able to do this off the top of my head, nor find it in the documentation. Easy points!

-

Here you go

``````A = array([[32, 32, 99,  9, 45],  # A
[99, 45,  9, 45, 32],
[45, 45, 99, 99, 32],
[ 9,  9, 32, 45, 99]])

B = array([ 99, 32, 45, 9])

ii = np.argsort(B)
C = np.digitize(A.reshape(-1,),np.sort(B)) - 1
``````

Originally I suggested:

``````D = np.choose(C,ii).reshape(A.shape)
``````

But I realized that that had limitations when you went to larger arrays. Instead, borrowing from @unutbu's clever reply:

``````D = np.argsort(B)[C].reshape(A.shape)
``````

Or the one-liner

``````np.argsort(B)[np.digitize(A.reshape(-1,),np.sort(B)) - 1].reshape(A.shape)
``````

Which I found to be faster or slower than @unutbu's code depending on the size of the arrays under consideration and the number of unique values.

-
This solution performed moderately faster for my use-case (B.size<<A.size), but for the record, @unutbu's solution seems to have better general performance. Neither, however was an "in-place" solution which I may have only hinted at wanting when I said "replace the values in `A`." ..which I don't reckon is possible without Cython. Thank you to you both! –  Paul Feb 22 '11 at 1:52
I also found unutbu's solution to be generally faster except when B.size << A.size. It's always fun to see multiple solutions and tinker with optimization –  JoshAdel Feb 22 '11 at 2:00
``````import numpy as np
A=np.array([[32, 32, 99,  9, 45],
[99, 45,  9, 45, 32],
[45, 45, 99, 99, 32],
[ 9,  9, 32, 45, 99]])

B=np.array([ 99, 32, 45, 9])

cutoffs=np.sort(B)
print(cutoffs)
# [ 9 32 45 99]

index=cutoffs.searchsorted(A)
print(index)
# [[1 1 3 0 2]
#  [3 2 0 2 1]
#  [2 2 3 3 1]
#  [0 0 1 2 3]]
``````

`index` holds the indices into the array cutoff associated with each element of `A`. Note we had to sort `B` since `np.searchsorted` expects a sorted array.

`index` is almost the desired answer, except that we want to map

``````1-->1
3-->0
0-->3
2-->2
``````

`np.argsort` provides us with this mapping:

``````print(np.argsort(B))
# [3 1 2 0]
print(np.argsort(B)[1])
# 1
print(np.argsort(B)[3])
# 0
print(np.argsort(B)[0])
# 3
print(np.argsort(B)[2])
# 2

print(np.argsort(B)[index])
# [[1 1 0 3 2]
#  [0 2 3 2 1]
#  [2 2 0 0 1]
#  [3 3 1 2 0]]
``````

So, as a one-liner, the answer is:

``````np.argsort(B)[np.sort(B).searchsorted(A)]
``````

Calling both `np.sort(B)` and `np.argsort(B)` is inefficient since both operations amount to sorting `B`. For any 1D-array `B`,

``````np.sort(B) == B[np.argsort(B)]
``````

So we can compute the desired result a bit faster using

``````key=np.argsort(B)
result=key[B[key].searchsorted(A)]
``````
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