Following code is taken from here

sa = sort(a[i:i+block])
n += np.r_[sa.searchsorted(bins[:-1], 'left'),
           sa.searchsorted(bins[-1], 'right')]

So I know that searchsorted finds the position in the array sa where the elements of bins would have to be inserted in order to keep sa sorted (left gives the index left of where we would insert the value and right the right index). What I don't understand is the whole construction around it meaning what is


What is np.r_?

  • 3
    Just so the community can better focus any answers, is there anything in the documentation for np.r_ that isn't clear? – Alex Riley Jun 2 '15 at 13:45
  • For some reason it didn't occur to me to google for numpy.r - stupid. This solves it, thanks. – Philipp Jun 2 '15 at 13:53

What it does is row-wise merging. This post has some nice example:

>>>V = array([1,2,3,4,5,6 ])
>>>Y = array([7,8,9,10,11,12])
array([ 1,  2,  7,  4,  8,  9,  5,  6, 11, 12])

Read more about it in this , and in the documentation of numpy.

  • 1
    Why not to use np.hstack? – mrgloom Nov 2 '18 at 14:24
  • @mrgloom you might want to read this answer... – omerbp Nov 5 '18 at 14:28
numpy.r_[array[], array[]]

This is used to concatenate any number of array slices along row (first) axis. This is a simple way to create numpy arrays quickly and efficiently.

For instance, to create an array from two different arrays by selecting the elements of your choice, we'll have to assign the sliced values to a new varaible and use concatenation method to join them along an axis.

>>> a = np.arange(9).reshape(3,3)
>>> b = np.arange(10,19).reshape(3,3)
>>> a
array([[0, 1, 2],
       [3, 4, 5],
       [6, 7, 8]])
>>> b
array([[10, 11, 12],
       [13, 14, 15],
       [16, 17, 18]])

I want to create a new 2-D array, with 2*2 elements ([4,5,14,15]) then, I'll have to do the following,

>>> slided_a = a[1,1:3]
>>> sliced_b = b[1,1:3]
>>> new_array = np.concatenate((sliced_a, sliced_b), axis = 0) 

As this is clearly an inefficient way because, as the number of elements that are to be included in the new array increases, the temporary variables that are assigned to store the sliced values increases.

This is where we use np.r_

>>> c = np.r_[a[1,1:3],b[1,1:3]]
array([ 4,  5, 14, 15])

Likewise, if we want to create a new array by stacking the sliced values in 2nd axis, we can use np.c_

>>> c = np.c_[a[1,1:3],b[1,1:3]]
array([[ 4, 14],
       [ 5, 15]])
  • You say that "as number of elements ...increases, the temp variables ... increases. This is where we use np.r_". But I don't see the difference between the line: np.concatenate((a[1,1:3], b[1,1:3]), axis = 0) and np.r_[a[1,1:3],b[1,1:3]]. Why should using np.r_ be more efficient here? As I know the advantage of np.r_ over np.concatenate is that np.concatenate only takes arrays as input. – Code Pope Aug 20 '18 at 13:31

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