Since this question was answered a lot happened - there are numexpr, numba and cython around. The goal of this answer is to take these possibilities into consideration.

But first let's state the obvious: no matter how you map a Python-function onto a numpy-array, it stays a Python function, that means for every evaluation:

- numpy-array element must be converted to a Python-object (e.g. a
`Float`

).
- all calculations are done with Python-objects, which means to have the overhead of interpreter, dynamic dispatch and immutable objects.

So which machinery is used to actually loop through the array doesn't play a big role because of the overhead mentioned above - it stays much slower than using numpy's vectorization.

Let's take a look at the following example:

```
# numpy-functionality
def f(x):
return x+2*x*x+4*x*x*x
# python-function as ufunc
import numpy as np
vf=np.vectorize(f)
vf.__name__="vf"
```

`np.vectorize`

is picked as a representative of the pure-python function class of approaches. Using `perfplot`

(see code in the appendix of this answer) we get the following running times:

We can see, that the numpy-approach is 10x-100x faster than the pure python version. The decrease of performance for bigger array-sizes is probably because data no longer fits the cache.

One often hears, that the numpy-performance is as good as it gets, because it is pure C under the hood. Yet there is a lot room for improvement!

The vectorized numpy-version uses a lot of additional memory and memory-accesses. Numexp-library tries to tile the numpy-arrays and thus get a better cache utilization:

```
# less cache misses than numpy-functionality
import numexpr as ne
def ne_f(x):
return ne.evaluate("x+2*x*x+4*x*x*x")
```

Leads to the following comparison:

I cannot explain everything in the plot above: we can see bigger overhead for numexpr-library at the beginning, but because it utilize the cache better it is about 10 time faster for bigger arrays!

Another approach is to jit-compile the function and thus getting a real pure-C UFunc. This is numba's approach:

```
# runtime generated C-function as ufunc
import numba as nb
@nb.vectorize(target="cpu")
def nb_vf(x):
return x+2*x*x+4*x*x*x
```

It is 10 times faster than the original numpy-approach:

However, the task is embarrassingly parallelizable, thus we also could use `prange`

in order to calculate the loop in parallel:

```
@nb.njit(parallel=True)
def nb_par_jitf(x):
y=np.empty(x.shape)
for i in nb.prange(len(x)):
y[i]=x[i]+2*x[i]*x[i]+4*x[i]*x[i]*x[i]
return y
```

As expected, the parallel function is slower for smaller inputs, but faster (almost factor 2) for larger sizes:

While numba specializes on optimizing operations with numpy-arrays, Cython is a more general tool. It is more complicated to extract the same performance as with numba - often it is down to llvm (numba) vs local compiler (gcc/MSVC):

```
%%cython -c=/openmp -a
import numpy as np
import cython
#single core:
@cython.boundscheck(False)
@cython.wraparound(False)
def cy_f(double[::1] x):
y_out=np.empty(len(x))
cdef Py_ssize_t i
cdef double[::1] y=y_out
for i in range(len(x)):
y[i] = x[i]+2*x[i]*x[i]+4*x[i]*x[i]*x[i]
return y_out
#parallel:
from cython.parallel import prange
@cython.boundscheck(False)
@cython.wraparound(False)
def cy_par_f(double[::1] x):
y_out=np.empty(len(x))
cdef double[::1] y=y_out
cdef Py_ssize_t i
cdef Py_ssize_t n = len(x)
for i in prange(n, nogil=True):
y[i] = x[i]+2*x[i]*x[i]+4*x[i]*x[i]*x[i]
return y_out
```

Cython results in somewhat slower functions:

# Conclusion

Obviously, testing only for one function doesn't prove anything. Also one should keep in mind, that for the choosen function-example, the bandwidth of the memory was the bottle neck for sizes larger than 10^5 elements - thus we had the same performance for numba, numexpr and cython in this region.

Yet from this investigation and from my experience so far, I would state, that numba seems to be the easiest tool with best performance.

Plotting running times with perfplot-package:

```
import perfplot
perfplot.show(
setup=lambda n: np.random.rand(n),
n_range=[2**k for k in range(0,24)],
kernels=[
f,
vf,
ne_f,
nb_vf, nb_par_jitf,
cy_f, cy_par_f,
],
logx=True,
logy=True,
xlabel='len(x)'
)
```

`squarer(x)`

? – Life Jan 10 '18 at 16:12`x = np.array([1, 2, 3, 4, 5]); x**2`

works – Shark Deng Aug 25 at 3:35