Comparing the above 3 methods:
import numpy as np
import timeit
n = 1000
c = 20
a = np.random.rand(n,n)
a1 = a.copy()
a2 = a.copy()
a3 = a.copy()
t1 = np.zeros(1000)
t2 = np.zeros(1000)
t3 = np.zeros(1000)
for i in range(1000):
start = timeit.default_timer()
a1[np.diag_indices_from(a1)] /= c
stop = timeit.default_timer()
t1[i] = start-stop
start = timeit.default_timer()
a2.flat[::n+1] /= c
stop = timeit.default_timer()
t2[i] = start-stop
start = timeit.default_timer()
np.fill_diagonal(a3,a3.diagonal() / c)
stop = timeit.default_timer()
t3[i] = start-stop
print([t1.mean(), t1.std()])
print([t2.mean(), t2.std()])
print([t3.mean(), t3.std()])
[-4.5693619907979154e-05, 9.3142851395411316e-06]
[-2.338075107036275e-05, 6.7119609571872443e-06]
[-2.3731951987429056e-05, 8.0455946813059586e-06]
So you can see that the np.flat
method is the fastest but marginally. When I ran this for a few more times there were times when the fill_diagonal
method was slightly faster. But readability wise its probably worth using the fill_diagonal method.