I would try a few different things.
- Load your data from the hdf file instead of passing in what are effectively memory-mapped arrays.
- If that doesn't fix the problem, you can exploit a
scipy.sparse.coo_matrix to make the 2D histogram. With older versions of numpy,
digitize (which all of the various
histogram* functions use internally) could use excessive memory under some circumstances. It's no longer the case with recent (>
1.5??) versions of numpy, though.
As an example of the first suggestion, you'd do something like:
f = h5py.File(sys.argv, 'r')
A = np.empty(f['A'].shape, f['A'].dtype)
T = np.empty(f['T'].shape, f['T'].dtype)
The difference here is that the entirety of the arrays will be read into memory, instead of being
h5py's array-like objects, which are basically efficient memory-mapped arrays stored on disk.
As for the second suggestion, don't try it unless the first suggestion didn't help your problem.
It probably won't be significantly faster (and is likely slower for small arrays), and with recent versions of numpy, it's only slightly more memory-efficient. I do have a piece of code where I deliberately do this, but I wouldn't recommend it in general. It's a very hackish solution. In very select circumstances (many points and many bins), it can preform better than
All those caveats aside, though, here it is:
import numpy as np
x = np.random.random(num)
y = np.random.random(num)
return x, y
def crazy_histogram2d(x, y, bins=10):
nx, ny = bins
nx = ny = bins
xmin, xmax = x.min(), x.max()
ymin, ymax = y.min(), y.max()
dx = (xmax - xmin) / (nx - 1.0)
dy = (ymax - ymin) / (ny - 1.0)
weights = np.ones(x.size)
# Basically, this is just doing what np.digitize does with one less copy
xyi = np.vstack((x,y)).T
xyi -= [xmin, ymin]
xyi /= [dx, dy]
xyi = np.floor(xyi, xyi).T
# Now, we'll exploit a sparse coo_matrix to build the 2D histogram...
grid = scipy.sparse.coo_matrix((weights, xyi), shape=(nx, ny)).toarray()
return grid, np.linspace(xmin, xmax, nx), np.linspace(ymin, ymax, ny)
if __name__ == '__main__':
numruns = 1
x, y = generate_data(num)
t1 = timeit.timeit('crazy_histogram2d(x, y, bins=500)',
setup='from __main__ import crazy_histogram2d, x, y',
t2 = timeit.timeit('np.histogram2d(x, y, bins=500)',
setup='from __main__ import np, x, y',
print 'Average of %i runs, using %.1e points' % (numruns, num)
print 'Crazy histogram', t1 / numruns, 'sec'
print 'numpy.histogram2d', t2 / numruns, 'sec'
On my system, this yields:
Average of 10 runs, using 1.0e+06 points
Crazy histogram 0.104092288017 sec
numpy.histogram2d 0.686891794205 sec