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I just came across this strange behaviour of numpy.sum:

>>> import numpy
>>> ar = numpy.array([1,2,3], dtype=numpy.uint64)
>>> gen = (el for el in ar)
>>> lst = [el for el in ar]
>>> numpy.sum(gen)
6.0
>>> numpy.sum(lst)
6
>>> numpy.sum(iter(lst))
<listiterator object at 0x87d02cc>

According to the documentation the result should be of the same dtype of the iterable, but then why in the first case a numpy.float64 is returned instead of an numpy.uint64? And how come the last example does not return any kind of sum and does not raise any error either?

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2 Answers 2

up vote 5 down vote accepted

In general, numpy functions don't always do what you might expect when working with generators. To create a numpy array, you need to know its size and type before creating it, and this isn't possible for generators. So many numpy functions either don't work with generators, or do this sort of thing where they fall back on Python builtins.

However, for the same reason, using generators often isn't that useful in Numpy contexts. There's no real advantage to making a generator from a Numpy object, because you already have to have the entire Numpy object in memory anyway. If you need all the types to stay as you specify, you should just not wrap your Numpy objects in generators.

Some more info: Technically, the argument to np.sum is supposed to be an "array-like" object, not an iterable. Array-like is defined in the documentation as:

An array, any object exposing the array interface, an object whose __array__ method returns an array, or any (nested) sequence.

The array interface is documented here. Basically, arrays have to have a fixed shape and a uniform type.

Generators don't fit this protocol and so aren't really supported. Many numpy functions are nice and will accept other sorts of objects that don't technically qualify as array-like, but a strict reading of the docs implies you can't rely on this behavior. The operations may work, but you can't expect all the types to be preserved perfectly.

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Could you show where is this documented? –  Bakuriu Dec 15 '12 at 8:26
    
@Bakuriu: I updated my answer with some info and doc pointers. –  BrenBarn Dec 15 '12 at 8:56
    
+1. Very lucid and well-documented answer. Impressed. :) –  EOL Dec 15 '12 at 9:06
    
Last thing: I suppose numpy considers list/tuples as array-like even though they do not provide an __array__ method, correct? But, then why returning a list from __array__ raises an error? The quotation you posted says that it ought to be allowed since it is a sequence. –  Bakuriu Dec 15 '12 at 9:43
    
@Bakuriu: As I understand it, lists and tuples are sequences, and thus fit the definition of array-like, but they are not actually arrays (i.e., numpy arrays), and thus are not an appropriate return value for __array__. There is a slight potential ambiguity in the way the definition is phrased, but the last bit about "any (nested) sequence" is one possible array-like, not a possible __array__ return value. An array-like can be a sequence or can have an __array__ that returns an array, but it can't have an __array__ that returns a sequence. –  BrenBarn Dec 15 '12 at 20:03

If the argument is a generator, Python's builtin sum get used.

You can see this in the source code of numpy.sum (numpy/core/fromnumeric.py):

  0     if isinstance(a, _gentype):
  1         res = _sum_(a)
  2         if out is not None:
  3             out[...] = res
  4             return out
  5         return res

_gentype is just an alias of types.GeneratorType, and _sum_ is alias of the built-in sum.

If you try applying sum to gen and lst, you could see that the results are the same: 6.0.

The second parameter of sum is start, which defaults to 0, this is part of what makes your result a float64.

In [1]: import numpy as np

In [2]: type(np.uint64(1) + np.uint64(2))
Out[2]: numpy.uint64

In [3]: type(np.uint64(1) + 0)
Out[3]: numpy.float64

EDIT: BTW, I find a ticket on this issue, which is marked as a wontfix: http://projects.scipy.org/numpy/ticket/669

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Could you explain better why the sum is an integer when the dtype of the array is int64 but a float when the dtype is uint64? –  Bakuriu Dec 15 '12 at 8:54
    
@Bakuriu Researching ;) I will update my answer if I find anything new. –  satoru Dec 15 '12 at 8:56
    
@Bakuriu I've updated my answer a bit. –  satoru Dec 15 '12 at 13:24
    
Thank you a lot for the explanation. Your answer ought to deserve more than mine upvote. –  Bakuriu Dec 15 '12 at 17:38
    
+1 for going to the sorce code –  Jaime Dec 16 '12 at 16:03

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