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In short: I have two matrices (or arrays):

import numpy

block_1 = numpy.matrix([[ 0, 0, 0, 0, 0],
                        [ 0, 0, 0, 0, 0],
                        [ 0, 0, 0, 0, 0],
                        [ 0, 0, 0, 0, 0]])

block_2 = numpy.matrix([[ 1, 1, 1],
                        [ 1, 1, 1],
                        [ 1, 1, 1],
                        [ 1, 1, 1]])

I have the displacement of block_2 in the block_1 element coordinate system.

pos = (1,1)

I want to be able to add them (quickly), to get:

[[0 0 0 0 0]
 [0 1 1 1 0]
 [0 1 1 1 0]
 [0 1 1 1 0]]

In long: I would like a fast way to add two different shape matrices together, where one of the matrices can be displaced. The resulting matrix must have the shape of the first matrix, and the overlapping elements between the two matrices are summed. If there is no overlap, just the first matrix is returned unmutated.

I have a function that works fine, but it's kind of ugly, and elementwise:

def add_blocks(block_1, block_2, pos):
    for i in xrange(0, block_2.shape[0]):
        for j in xrange(0, block_2.shape[1]):
            if (i + pos[1] >= 0) and (i + pos[1] < block_1.shape[0])
               and (j + pos[0] >= 0) and (j + pos[0] < block_1.shape[1]):
                block_1[pos[1] + i, pos[0] + j] += block_2[i,j]
    return block_1

Can broadcasting or slicing perhaps do this?

I feel like maybe I'm missing something obvious.

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4 Answers 4

up vote 2 down vote accepted

You just have to find the overlapping range, and then add the arrays using slicing.

b1 = np.zeros((4,5))
b2 = np.ones((4,3))
pos_v, pos_h = 2, 3  # offset
v_range1 = slice(max(0, pos_v), max(min(pos_v + b2.shape[0], b1.shape[0]), 0))
h_range1 = slice(max(0, pos_h), max(min(pos_h + b2.shape[1], b1.shape[1]), 0))

v_range2 = slice(max(0, -pos_v), min(-pos_v + b1.shape[0], b2.shape[0]))
h_range2 = slice(max(0, -pos_h), min(-pos_h + b1.shape[1], b2.shape[1]))

b1[v_range1, h_range1] += b2[v_range2, h_range2]

They're added in-place, but you could also create a new array. I might have missed some corner cases, though, but it seems to work fine.

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I ended up doing something very similar to this. The ability to create slice objects is really great, thanks for that! –  fraxel Mar 27 '12 at 12:06
    
I think the v_range1 and h_range1 code is missing a final closing ')'. –  David Poole Mar 28 '12 at 15:03
    
Thanks! I just fixed that. –  jorgeca Mar 28 '12 at 17:58

An easy solution that looks like MATLAB solution is:

import numpy as np

block_1 = np.zeros((5,4)) #sample data 1
block_2 = np.ones((4,3))  #sample data 2

block_1[1:5,1:4] = block_1[1:5,1:4] + block_2
print(block_1)

So package it as a reusable function:

import numpy as np

#Usage:
#  addAtPos(xycoor)
#    - mat1  : matrix to be added
#    - mat2  : add this matrix to mat1
#    - xycoor: tuple (x,y) containing coordinates
def addAtPos(mat1, mat2, xycoor):
    size_x, size_y = np.shape(mat2)
    coor_x, coor_y = xycoor
    end_x, end_y   = (coor_x + size_x), (coor_y + size_y)
    mat1[coor_x:end_x, coor_y:end_y] = mat1[coor_x:end_x, coor_y:end_y] + mat2
    return mat1

block_1 = np.zeros((5,4))
block_2 = np.ones((3,3))
pos     = (1,1)

#print result
print(addAtPos(block_1, block_2, pos))
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This is looking good,and much more readable. But if some of block_2 falls outside block_1 it fails. Easy to fix of course. –  fraxel Mar 27 '12 at 9:45
    
@fraxel Yeah, you can always add size checking if needed ;) –  EwyynTomato Mar 27 '12 at 9:52

I'm sure there is a fast NumPy way to do this, but there is a more efficient way to do it even in normal Python:

block_1 = [ [ 0, 0, 0, 0, 0],
            [ 0, 0, 0, 0, 0],
            [ 0, 0, 0, 0, 0],
            [ 0, 0, 0, 0, 0]]

block_2 = [ [ 1, 1, 1],
            [ 1, 1, 1],
            [ 1, 1, 1],
            [ 1, 1, 1]]

pos = (1, 1)

x, y = pos

# width of the rows in block_2
length = len(block_2[0])

# skip the first y rows
for row_1, row_2 in zip(block_1[y:], block_2):
    # set length elements offset by x to the sum.
    row_1[x:length + x] = map(sum, zip(row_2, row_1[x:length + x]))

print '\n'.join(' '.join(map(str, row)) for row in block_1)

"""
0 0 0 0 0
0 1 1 1 0
0 1 1 1 0
0 1 1 1 0
"""
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This is great, and here's how to extend the addition to a 3D matrix by adding a few lines to jorgeca's code:

import numpy as np

#two 3d arrays, of different size.
b1 = np.zeros((5,5,5), dtype=np.int) # a 5x5x5 matrix of zeroes
b2 = np.ones((3,3,3), dtype=np.int)  # a 3x3x3 matrix of ones

pos_v, pos_h, pos_z = 2, 2, 2  # a 3d offset -> to plonk b2 in the corner of b1

v_range1 = slice(max(0, pos_v), max(min(pos_v + b2.shape[0], b1.shape[0]), 0))
h_range1 = slice(max(0, pos_h), max(min(pos_h + b2.shape[1], b1.shape[1]), 0))
z_range1 = slice(max(0, pos_z), max(min(pos_z + b2.shape[2], b1.shape[2]), 0))

v_range2 = slice(max(0, -pos_v), min(-pos_v + b1.shape[0], b2.shape[0]))
h_range2 = slice(max(0, -pos_h), min(-pos_h + b1.shape[1], b2.shape[1]))
z_range2 = slice(max(0, -pos_z), min(-pos_z + b1.shape[2], b2.shape[2]))

b1[v_range1, h_range1, z_range1] += b2[v_range2, h_range2, z_range2]

This might help someone who wants to do the same in 3d (like me).

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