I'm trying to understand how numpy's broadcasting affects the output of np.allclose.

>>> np.allclose([], [1.])

I don't see why that works, but this does not:

>>> np.allclose([], [1., 2.])
ValueError: operands could not be broadcast together with shapes (0,) (2,)

What are the rules here? I can't finding anything in the numpy docs regarding empty arrays.

  • Two dimensions are compatible when they are equal, or one of them is 1 - well this certainly is true, so by definition the two should be broadcasting compatible. However I do not see how this intuitively makes sense for a dimension 0 vs 1. – cel Jul 12 '16 at 14:56
  • @cel: see answer below – Julien Jul 12 '16 at 15:44
  • @cel consider np.allclose([], 1). Their dimension are (0,) and (), so neither equal nor 1. Is that the only compatibility rule? – Wilfred Hughes Jul 14 '16 at 10:05
  • @WilfredHughes, (0,) and () are the shapes, not the dimensions. The dimensions are 1 and 0 I would say (not 100% sure, though) – cel Jul 14 '16 at 10:43

Broadcasting rules apply to addition as well,

In [7]: np.array([])+np.array([1.])
Out[7]: array([], dtype=float64)

In [8]: np.array([])+np.array([1.,2.])

ValueError: operands could not be broadcast together with shapes (0,) (2,)

Let's look at the shapes.

In [9]: np.array([]).shape,np.array([1.]).shape,np.array([1,2]).shape
Out[9]: ((0,), (1,), (2,))

(0,) and (1,) - the (1,) can be adjusted to match the shape of the other array. A 1 dimension can be adjusted to match the other array, from example increased from 1 to 3. But here it was (apparently) adjusted from 1 to 0. I don't usually work with arrays with a 0 dimension, but this looks like a proper generalization of higher dimensions.

Try (0,) and (1,1). The result is (1,0):

In [10]: np.array([])+np.array([[1.]])
Out[10]: array([], shape=(1, 0), dtype=float64)

(0,), (1,1) => (1,0),(1,1) => (1,0)

As for the 2nd case with shapes (0,) and (2,); there isn't any size 1 dimension to adjust, hence the error.

Shapes (0,) and (2,1) do broadcast (to (2,0)):

In [12]: np.array([])+np.array([[1.,2]]).T
Out[12]: array([], shape=(2, 0), dtype=float64)

Broadcasting doesn't affect np.allclose in any other way than it affects any other function.

As in the comment by @cel, [1.] is of dimension 1 and so can be broadcasted to any other dimension, including 0. On the other hand [1., 2.] is of dimension 2 and thus cannot be broadcasted.

Now why allclose([],[1.]) == True? This actually makes sense: it means that all elements in [] are close to 1.. The opposite would mean that there is at least one element in [] which is not close to 1. which is obviously False since there are no elements at all in [].

Another way to think about it is to ask yourself how you would actually code allclose():

def allclose(array, target=1.):
    for x in array:
        if not isclose(x, target):
            return False
    return True

This would return True when called with [].

  • 1
    I agree in principle, but how would you interpret np.allclose([1.],[]) which is also True? All elements in [1.] are equal to .. hum...nothing? The other way feels very unintuitive. – cel Jul 12 '16 at 15:56
  • @cel: because you should not read it this way: [1.] is broadcasted to [] not the other way around. (The same way it is [1.] that would be broadcasted to [1., 2., 3.] and not the other way around which would also be nonsense.) – Julien Jul 12 '16 at 16:05

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