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Could someone please explain to me what is happening here? I understand what is happening here: https://docs.scipy.org/doc/numpy-1.15.0/user/basics.indexing.html#index-arrays, but do not understand this piece of code.

import numpy as np
y = np.zeros((3,3))
y = y.astype(np.int16)
y[1,1] = 1
x = np.ones((3,3))
t = (1-y).astype(np.int16)
print(t)
print(x[t])
x[(1-y).astype(np.int16)] = 0
print(x)

output:

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

[[[1. 1. 1.]
  [1. 1. 1.]
  [1. 1. 1.]]

 [[1. 1. 1.]
  [1. 1. 1.]
  [1. 1. 1.]]

 [[1. 1. 1.]
  [1. 1. 1.]
  [1. 1. 1.]]]

[[0. 0. 0.]
 [0. 0. 0.]
 [1. 1. 1.]]
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  • x[t] indexes a (3,3) on the first dimension with a (3,3) array; the result is (3,3,3), picking x[0] for one term, x[1] for others. Since x is all 1s we don't see any pattern in the display, just the shape.
    – hpaulj
    Feb 13, 2019 at 2:01
  • 1
    x[t] = 0 assigns 0 to some elements of x. The result is the same shape as x, not the (3,3,3) of x[t]. t contains just 0 and 1, the result is that x[0,:] is set to 0. So is x[1,:], but x[2,:] is untouched.
    – hpaulj
    Feb 13, 2019 at 2:06
  • Adding to what @hpaulj said, you can test it by setting y = np.zeros((3,3)); x = np.ones((3,3)); x[1-y] = 0 and you will see [[1,1,1],[0,0,0],[1,1,1]]
    – ycx
    Feb 13, 2019 at 2:11

1 Answer 1

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import numpy as np              # Line 01
y = np.zeros((3,3))             # Line 02
y = y.astype(np.int16)          # Line 03
y[1,1] = 1                      # Line 04
x = np.ones((3,3))              # Line 05
t = (1-y).astype(np.int16)      # Line 06
print(t)                        # Line 07
print(x[t])                     # Line 08
x[(1-y).astype(np.int16)] = 0   # Line 09
print(x)                        # Line 10

Line 02:

Creates a two-dimensional 3 x 3 ndarray of zeros. y is a name that is made to point to this ndarray.

Line 03:

Sets the data-type of each element of y, to 16-bit integer.

Line 04:

Sets the element of y at the intersection of the middle row and middle column, to 1.

Line 05:

Creates a two-dimensional 3 x 3 ndarray of ones. x is a name that is made to point to this ndarray.

Line 06:

The subtraction (1-t) results in several scalar subtractions (1- elem), where elem is each element of t. The result will be another ndarray, having the same shape as t, and having the result of the subtraction (1- elem), as its values. That is, the values of the ndarray (1-t) will be:

[[1-t[0,0], 1-t[0,1], 1-t[0,2]],
 [1-t[1,0], 1-t[1,1], 1-t[1,2]],
 [1-t[2,0], 1-t[2,1], 1-t[2,2]]]

Since t is full of zeros, and a lone 1 at the intersection of the middle row and middle column, (1-t) will be a two-dimensional ndarray full of ones, with a lone 0 at the intersection of the middle row and middle column.

Line 07:

Prints t

Line 08:

Things get a little tricky from here. What is happening here is called "Combined Advanced and Basic Indexing" (https://docs.scipy.org/doc/numpy-1.13.0/reference/arrays.indexing.html#combining-advanced-and-basic-indexing). Let's go through the specifics, step-by-step. First, notice that x, is a two-dimensional ndarray, taking another integer ndarray t as an index. Since x needs two indices to be supplied, t will be taken to be the first of those two indices, and the second index will be implicitly assumed to be :. So, x[t] is first interpreted as x[t,:]. The presence of these two indices, where one index is an array of integers t, and the other index is a slice :, results in the situation that is called "Combined Advanced and Basic Indexing".

Now, what exactly happens in this "Combined" scenario? Here goes: First, the shape of the result will get contributions from the first index t, as well as from the second index :. Now t has the shape (3,3), and hence the contribution of t to the shape of the result of x[t,:], is to supply the outermost (leftmost) dimensions of the result shape. Hence the result shape will begin with (3,3,). Now, the contribution of : to the shape of x[t,:] is based on the answer to the question: On which dimension of x is the : being applied ? The answer is -- the second dimension (since : is the second index within x[t,:]). Hence the contribution of : to the result shape of x[t,:] is 3 (since 3 is the length of the second dimension of x). To recap, we have deduced that the result shape of x[t] will be that of x[t,:], which in turn will be (3,3,3). This means x[t] will be a three-dimensional array, even though x itself is only a two-dimensional array.

Note that in the shape (3,3,3) of the result, the first two 3s were contributed by the advanced index t, and the last 3 was contributed by the implicit basic index :. These two indexes t and : also use different ways to arrive at their respective contributions. The 3,3, contribution that came from the index t is just the shape of t itself. It doesn't care about the position of t among the indexes, in the expression x[t,:] (it doesn't care whether t occurs before : or : appears before t). The 3 contribution that came from the index : is the length of the second dimension of x, and we consider the second dimension of x because : is the second index in the expression x[t,:]. If x had the shape (3,5) instead of (3,3), then the shape of x[t,:] would have been (3,3,5) instead of (3,3,3).

Now that we've deduced the shape of the result of x[t] to be (3,3,3), let us move on to understand how the values themselves will get determined, in the result. The values in the result are obviously the values at positions [0,0,0], [0,0,1], [0,1,2], [0,1,0], [0,1,1], [0,1,2], [0,2,0], [0,2,1], [0,2,2], and so on. Let's walk through one example of these positions, and you will hopefully get the drift. For our example, let's look at the position [0,1,2] in the result. To get the value for this position, we will first index into the t array using the 0 and the 1. That is, we find out t[0,1], which will be 1 (refer to the output of print(t)). This 1, which was obtained at t[0,1], shall be taken to be our first index into x. The second index into x will be 2 (remember that we are discussing the position [0,1,2] within the result, and trying to determine the value at that position). Now, given these first and second indices into x, we get from x the value to be populated at position [0,1,2] of x[t].

Now, x is just full of ones. So, x[t] will only consist of ones, even though the shape of x[t] is (3,3,3). To really test your understanding of what I've said so far, you need to fill x with diverse values: So, temporarily, comment out Line 05, and have the following line in its place:

x = np.arange(9).reshape((3,3))    # New version of Line 05

Now, you will find that print(x[t]) at Line 08 gives you:

[[[3 4 5]
  [3 4 5]
  [3 4 5]]

 [[3 4 5]
  [0 1 2]
  [3 4 5]]

 [[3 4 5]
  [3 4 5]
  [3 4 5]]]

Against this output, test your understanding of what I've described above, about how the values in the result will get determined. (That is, if you've understood the above explanation of x[t], you should be able to manually re-construct this same output as above, for print (x[t]).

Line 09:

Given the definition of t on Line 06, Line 09 is equivalent to x[t], which, as we saw above, is equivalent to x[t, :] = 0.

And the effect of the assignment x[t, :] = 0 is the same as the effect of x[0:2, :] = 0.

Why is this so? Simply because, in x[t, :]:

  1. The index values generated by the index t are 0s and 1s (since t is an integer index array consisting of only 0s and 1s)
  2. The index values generated by the index : are 0, 1, and 2.
  3. We are referring only to positions within x that correspond to combinations of these index values. That is, x[t, :] relates only to the those positions x[i,j], where i takes values 0 or 1, and j takes values 0,1, or 2. That is, x[t, :] relates only to the positions x[0,0], x[0,1], x[0,2], x[1,0], x[1,1], x[1,2], within the array x.
  4. So, the assignment statement x[t, :] = 0 assigns the value 0 at these positions in x. Effectively, we are assigning the value 0 into all three columns in the first two rows of x, and we are leaving the third row of x unchanged.

Line 10:

Prints the value of x after the above assignment.

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  • While this is the combined advanced-basic, it is the simplest case, where is only one advanced index, the t.
    – hpaulj
    Feb 13, 2019 at 2:59

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