A numerical integration is taking exponentially longer than I expect it to. I would like to know if the way that I implement the iteration over the mesh could be a contributing factor. My code looks like this:

```
import numpy as np
import itertools as it
U = np.linspace(0, 2*np.pi)
V = np.linspace(0, np.pi)
for (u, v) in it.product(U,V):
# values = computation on each grid point, does not call any outside functions
# solution = sum(values)
return solution
```

I left out the computations because they are long and my question is specifically about the way that I have implemented the computation over the parameter space (u, v). I know of alternatives such as `numpy.meshgrid`

; however, these all seem to create instances of (very large) matrices, and I would guess that storing them in memory would slow things down.

Is there an alternative to `it.product`

that would speed up my program, or should I be looking elsewhere for the bottleneck?

Edit: Here is the for loop in question (to see if it can be vectorized).

```
import random
import numpy as np
import itertools as it
##########################################################################
# Initialize the inputs with random (to save space)
##########################################################################
mat1 = np.array([[random.random() for i in range(3)] for i in range(3)])
mat2 = np.array([[random.random() for i in range(3)] for i in range(3)])
a1, a2, a3 = np.array([random.random() for i in range(3)])
plane_normal = np.array([random.random() for i in range(3)])
plane_point = np.array([random.random() for i in range(3)])
d = np.dot(plane_normal, plane_point)
truthval = True
##########################################################################
# Initialize the loop
##########################################################################
N = 100
U = np.linspace(0, 2*np.pi, N + 1, endpoint = False)
V = np.linspace(0, np.pi, N + 1, endpoint = False)
U = U[1:N+1] V = V[1:N+1]
Vsum = 0
Usum = 0
##########################################################################
# The for loops starts here
##########################################################################
for (u, v) in it.product(U,V):
cart_point = np.array([a1*np.cos(u)*np.sin(v),
a2*np.sin(u)*np.sin(v),
a3*np.cos(v)])
surf_normal = np.array(
[2*x / a**2 for (x, a) in zip(cart_point, [a1,a2,a3])])
differential_area = \
np.sqrt((a1*a2*np.cos(v)*np.sin(v))**2 + \
a3**2*np.sin(v)**4 * \
((a2*np.cos(u))**2 + (a1*np.sin(u))**2)) * \
(np.pi**2 / (2*N**2))
if (np.dot(plane_normal, cart_point) - d > 0) == truthval:
perp_normal = plane_normal
f = np.dot(np.dot(mat2, surf_normal), perp_normal)
Vsum += f*differential_area
else:
perp_normal = - plane_normal
f = np.dot(np.dot(mat2, surf_normal), perp_normal)
Usum += f*differential_area
integral = abs(Vsum) + abs(Usum)
```

`np.random.random([3,3])`

to generate`mat1`

etc, should shave off a bit of time. – hpaulj Aug 11 '13 at 19:32`np.random.random ...`

does not make a difference in times. – hpaulj Aug 13 '13 at 0:36