# Python's sum vs. NumPy's numpy.sum

What are the differences in performance and behavior between using Python's native `sum` function and NumPy's `numpy.sum`? `sum` works on NumPy's arrays and `numpy.sum` works on Python lists and they both return the same effective result (haven't tested edge cases such as overflow) but different types.

``````>>> import numpy as np
>>> np_a = np.array(range(5))
>>> np_a
array([0, 1, 2, 3, 4])
>>> type(np_a)
<class 'numpy.ndarray')

>>> py_a = list(range(5))
>>> py_a
[0, 1, 2, 3, 4]
>>> type(py_a)
<class 'list'>

# The numerical answer (10) is the same for the following sums:
>>> type(np.sum(np_a))
<class 'numpy.int32'>
>>> type(sum(np_a))
<class 'numpy.int32'>
>>> type(np.sum(py_a))
<class 'numpy.int32'>
>>> type(sum(py_a))
<class 'int'>
``````

Edit: I think my practical question here is would using `numpy.sum` on a list of Python integers be any faster than using Python's own `sum`?

Additionally, what are the implications (including performance) of using a Python integer versus a scalar `numpy.int32`? For example, for `a += 1`, is there a behavior or performance difference if the type of `a` is a Python integer or a `numpy.int32`? I am curious if it is faster to use a NumPy scalar datatype such as `numpy.int32` for a value that is added or subtracted a lot in Python code.

For clarification, I am working on a bioinformatics simulation which partly consists of collapsing multidimensional `numpy.ndarray`s into single scalar sums which are then additionally processed. I am using Python 3.2 and NumPy 1.6.

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I got curious and timed it. `numpy.sum` seems much faster for numpy arrays, but much slower on lists.

``````import numpy as np
import timeit

x = range(1000)
# or
#x = np.random.standard_normal(1000)

def pure_sum():
return sum(x)

def numpy_sum():
return np.sum(x)

n = 10000

t1 = timeit.timeit(pure_sum, number = n)
print 'Pure Python Sum:', t1
t2 = timeit.timeit(numpy_sum, number = n)
print 'Numpy Sum:', t2
``````

Result when `x = range(1000)`:

``````Pure Python Sum: 0.445913167735
Numpy Sum: 8.54926219673
``````

Result when `x = np.random.standard_normal(1000)`:

``````Pure Python Sum: 12.1442425643
Numpy Sum: 0.303303771848
``````

I am using Python 2.7.2 and Numpy 1.6.1

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+1, But don't you have these results backwards? – dawg Jun 6 '12 at 22:08
@drewk, Yes, I did have them backwards. Thank You for pointing this out! Fixed. – Akavall Jun 6 '12 at 22:14

Numpy should be much faster, especially when your data is already a numpy array.

Numpy arrays are a thin layer over a standard C array. When numpy sum iterates over this, it isn't doing type checking and it is very fast. The speed should be comparable to doing the operation using standard C.

In comparison, using python's sum it has to first convert the numpy array to a python array, and then iterate over that array. It has to do some type checking and is generally going to be slower.

The exact amount that python sum is slower than numpy sum is not well defined as the python sum is going to be a somewhat optimized function as compared to writing your own sum function in python.

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It doesn't 'convert' the numpy array - a numpy array is already iterable in Python. On the other hand, `numpy.sum` may have to convert a list to a numpy array, which would explain the results of @Akavall's timing. – Thomas K Jun 7 '12 at 12:03
Regardless of if the conversion occurs as an array to array or by typecasting individual items, you will at some level be converting the item (from/to native types), and that was the point I was trying to make. – Claris Jun 7 '12 at 21:57

Note that Python sum on multidimensional numpy arrays will only perform a sum along the first axis:

``````sum(np.array([[[2,3,4],[4,5,6]],[[7,8,9],[10,11,12]]]))
Out[47]:
array([[ 9, 11, 13],
[14, 16, 18]])

np.sum(np.array([[[2,3,4],[4,5,6]],[[7,8,9],[10,11,12]]]), axis=0)
Out[48]:
array([[ 9, 11, 13],
[14, 16, 18]])

np.sum(np.array([[[2,3,4],[4,5,6]],[[7,8,9],[10,11,12]]]))
Out[49]: 81
``````
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