# Efficiently multiply elements of each row together

Given a ndarray of size `(n, 3)` with `n` around 1000, how to multiply together all elements for each row, fast? The (inelegant) second solution below runs in about 0.3 millisecond, can it be improved?

``````# dummy data
n = 999
a = np.random.uniform(low=0, high=10, size=n).reshape(n/3,3)

# two solutions
def prod1(array):
return [np.prod(row) for row in array]

def prod2(array):
return [row[0]*row[1]*row[2] for row in array]

# benchmark
start = time.time()
prod1(a)
print time.time() - start
# 0.0015

start = time.time()
prod2(a)
print time.time() - start
# 0.0003
``````

`np.prod` accepts an axis argument:

``````np.prod(a, axis=1)
``````

With `axis=1`, the column-wise product is computed for each row.

Sanity check

``````assert np.array_equal(np.prod(a, axis=1), prod1(a))
``````

Performance

``````17.6 µs ± 146 ns per loop (mean ± std. dev. of 7 runs, 100000 loops each)
``````

(1000x speedup)

• (sorry for the unaccept, but the other answer provides an even better improvement) Apr 15, 2018 at 22:12
• @anderstood sure np, numpy was always going to lose to an njit solution. I'd retaliate with cython buuuut I think it might still fall just short.
– cs95
Apr 16, 2018 at 2:32

Improving performance further

At first a general rule of thumb. You are working with numerical arrays, so use arrays and not lists. Lists may look somewhat like a general array, but beeing completely different in the backend and absolutely not suteable for most numerical calculations.

If you write a simple code using Numpy-Arrays you can gain performance by simply jitting it as shown beyond. If you use lists you can more or less rewrite your code.

``````import numpy as np
import numba as nb

@nb.njit(fastmath=True)
def prod(array):
assert array.shape[1]==3 #Enable SIMD-Vectorization (adding some performance)
res=np.empty(array.shape[0],dtype=array.dtype)
for i in range(array.shape[0]):
res[i]=array[i,0]*array[i,1]*array[i,2]

return res
``````

Using `np.prod(a, axis=1)` isn't a bad idea, but the performance isn't really good. For an array with only 1000x3 the function call overhead is quite significant. This can be completely avoided, when using the jitted prod function in another jitted function.

Benchmarks

``````# The first call to the jitted function takes about 200ms compilation overhead.
#If you use @nb.njit(fastmath=True,cache=True) you can cache the compilation result for every successive call.
n=999
prod1   = 795  µs
prod2   = 187  µs
np.prod = 7.42 µs
prod      0.85 µs

n=9990
prod1   = 7863 µs
prod2   = 1810 µs
np.prod = 50.5 µs
prod      2.96 µs
``````