I saw a video about speed of loops in python, where it was explained that doing `sum(range(N))`

is much faster than manually looping through `range`

and adding the variables together, since the former runs in C due to built-in functions being used, while in the latter the summation is done in (slow) python. I was curious what happens when adding `numpy`

to the mix. As I expected `np.sum(np.arange(N))`

is the fastest, but `sum(np.arange(N))`

and `np.sum(range(N))`

are even slower than doing the naive for loop.

Why is this?

Here's the script I used to test, some comments about the supposed cause of slowing done where I know (taken mostly from the video) and the results I got on my machine (python 3.10.0, numpy 1.21.2):

**updated script:**

```
import numpy as np
from timeit import timeit
N = 10_000_000
repetition = 10
def sum0(N = N):
s = 0
i = 0
while i < N: # condition is checked in python
s += i
i += 1 # both additions are done in python
return s
def sum1(N = N):
s = 0
for i in range(N): # increment in C
s += i # addition in python
return s
def sum2(N = N):
return sum(range(N)) # everything in C
def sum3(N = N):
return sum(list(range(N)))
def sum4(N = N):
return np.sum(range(N)) # very slow np.array conversion
def sum5(N = N):
# much faster np.array conversion
return np.sum(np.fromiter(range(N),dtype = int))
def sum5v2_(N = N):
# much faster np.array conversion
return np.sum(np.fromiter(range(N),dtype = np.int_))
def sum6(N = N):
# possibly slow conversion to Py_long from np.int
return sum(np.arange(N))
def sum7(N = N):
# list returns a list of np.int-s
return sum(list(np.arange(N)))
def sum7v2(N = N):
# tolist conversion to python int seems faster than the implicit conversion
# in sum(list()) (tolist returns a list of python int-s)
return sum(np.arange(N).tolist())
def sum8(N = N):
return np.sum(np.arange(N)) # everything in numpy (fortran libblas?)
def sum9(N = N):
return np.arange(N).sum() # remove dispatch overhead
def array_basic(N = N):
return np.array(range(N))
def array_dtype(N = N):
return np.array(range(N),dtype = np.int_)
def array_iter(N = N):
# np.sum's source code mentions to use fromiter to convert from generators
return np.fromiter(range(N),dtype = np.int_)
print(f"while loop: {timeit(sum0, number = repetition)}")
print(f"for loop: {timeit(sum1, number = repetition)}")
print(f"sum_range: {timeit(sum2, number = repetition)}")
print(f"sum_rangelist: {timeit(sum3, number = repetition)}")
print(f"npsum_range: {timeit(sum4, number = repetition)}")
print(f"npsum_iterrange: {timeit(sum5, number = repetition)}")
print(f"npsum_iterrangev2: {timeit(sum5, number = repetition)}")
print(f"sum_arange: {timeit(sum6, number = repetition)}")
print(f"sum_list_arange: {timeit(sum7, number = repetition)}")
print(f"sum_arange_tolist: {timeit(sum7v2, number = repetition)}")
print(f"npsum_arange: {timeit(sum8, number = repetition)}")
print(f"nparangenpsum: {timeit(sum9, number = repetition)}")
print(f"array_basic: {timeit(array_basic, number = repetition)}")
print(f"array_dtype: {timeit(array_dtype, number = repetition)}")
print(f"array_iter: {timeit(array_iter, number = repetition)}")
print(f"npsumarangeREP: {timeit(lambda : sum8(N/1000), number = 100000*repetition)}")
print(f"npsumarangeREP: {timeit(lambda : sum9(N/1000), number = 100000*repetition)}")
# Example output:
#
# while loop: 11.493371912998555
# for loop: 7.385945574002108
# sum_range: 2.4605720699983067
# sum_rangelist: 4.509678105998319
# npsum_range: 11.85120212900074
# npsum_iterrange: 4.464334709002287
# npsum_iterrangev2: 4.498494338993623
# sum_arange: 9.537815956995473
# sum_list_arange: 13.290120724996086
# sum_arange_tolist: 5.231948580003518
# npsum_arange: 0.241889145996538
# nparangenpsum: 0.21876695199898677
# array_basic: 11.736577274998126
# array_dtype: 8.71628468400013
# array_iter: 4.303306431000237
# npsumarangeREP: 21.240833958996518
# npsumarangeREP: 16.690092379001726
```

`numpy`

is optimized for`numpy`

and not meant to be used with built-in python functions, just how it is designed, for example in the case of`sum(np.arange(N))`

the`numpy`

range has to first be converted to a python data structure and then do the summing and similarly with`np.sum`

perhaps the`range`

has to be converted to something that`numpy`

understands, but IDK`sum`

implementation here and the numpy function here (though that is a wrapper function). You can see the`dis`

output for all your functions on godbolt. I can't see a specific reason why other than maybe the cpython (`sum`

and`range`

) operates entirely in C.`np.sum`

's source I added a few other tests. I guess calling`np.sum`

on`range`

implicitly involves converting to`np.array`

which seems to be very inefficient conversion unless one explicitly tells numpy about using a generator. Looking at conversion time (bottom three rows) and how using`fromiter`

changes the runtime this explains why`np.sum(range(N))`

is slow. Now the only thing I don't get is why`sum(np.arange(N))`

is so slow.`sum(np.arange(N))`

would be slow as you are creating an array of numpy ints that`sum`

will be converting to a`Py_Long`

from the numpy representation.`sum(np.arange(N).tolist())`

. I'm guessing about 4.2more comments