# python interpolation takes a long time

I do an interpolation with scipy.interpolate.griddata in a 1000 x 1000 grid. When I have a point-cloud with 1,000 (x,y,z)-values, calculation only takes a few seconds. But now I have 1,000,000 values. So I created a loop to extract 1,000 values out of these 1,000,000 values, like this:

``````p = [...]
z = [...]
#p and z are my lists with 1,000,000 values
p_new = []
z_new = []
for i in range(1000000):
if condition:
#condition is True for about 1000 times
p_new.append(p[i])
z_new.append(z[i])
print 'loop finished'

points = np.array(p_new)
values = np.array(z_new)
grid_z1 = griddata(points, values, (grid_x, grid_y), method='cubic')
plt.imshow(grid_z1.T, origin='lower')
plt.show()
``````

`print len(p_new)` returns me `1000`, so my loop works as expected. But after my loop finished, I canceled my program after 15minutes of waiting because nothing happened.

So finally my question is: Why takes this calculation so long although in both cases (1000 values by default and 1000 values extracting them out of 1000000) I have the same number of values? In my output `loop finished` I can see that loop only takes about 10sec, so it should have nothing to do with my loop =/

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do you require cubic interpolation? using `method='linear'` will save time if cubic is not required –  Big Al Oct 1 '13 at 18:13
more or less. you're right, `method='linear'` only takes a few seconds, but cubic interpolation would be much better for me... –  Munchkin Oct 1 '13 at 18:17
Is your condition random, or do you sort them somehow or what? That could be really relevant. –  Vernepator Cur Oct 1 '13 at 18:21
was your data structured/regular before? maybe now that you've sampled here and there, it takes more time to interpolate between the larger intervals. –  Big Al Oct 1 '13 at 18:22
@atomic: my condition searches for a certain z-value (+/- a little offset): `if z[i] < h+offset and z[i] > h-offset:` @Big Al: data is totally random. But in the first test, with 1000 values WITHOUT this loop, my data also was random. –  Munchkin Oct 1 '13 at 18:27

I can't see anything unusual going on here - as far as I can tell the time taken to interpolate is roughly proportional to the number of elements in the point cloud.

Here's some test data:

``````def fake_data(n):

# xy coordinates for an n-by-n grid
grid = np.indices((n,n),dtype=np.float32).reshape(2,-1).T

# interpolated coordinates
xy_i = grid.copy()
# not monotonically increasing
np.random.shuffle(xy_i)

# values
z = np.random.rand(n**2)

# input coordinates
xy = grid.copy()
# not regularly gridded
xy += np.random.rand(*xy_i.shape)*0.25

# pick n random points to use
inc = np.random.choice(np.arange(n**2),(n,),replace=False)
xy = grid[inc,:]
z = z[inc]

return xy, z, xy_i
``````

For all three methods a log-log plot of N vs time is roughly a straight line, with a slope of ~2, i.e. they all require O(N^2) time.

If, in your case, you see that the lines are not straight but deviate upwards for large values of N, that might indicate that you're having some other problem, such as running out of memory and hitting the swap.

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