# 3D Array vs Sparse Matrix for Sparse Data

I am building a simple model of the Milky Way and one of the things I need to store is a 3D grid of mass densities.

The problem is that if I put a rectangular box around the galaxy, most of the grid cells are empty. Which leaves me saving a lot of useless zeros. So the naive array seems wasteful:

``````galaxy = [[[0 for k in xrange(1601)] for j in xrange(1601)] for i in xrange(253)]
# then fill in i,j,k values that are non-zero
``````

I tried to build a sparse array using a dictionary:

``````for x in range(1601):
for y in range(1601):
for z in range (253):
galaxy[str(x) + "," + str(y) + "," + str(z)] = # whatever
``````

But, (aside from being ugly) the strings that I was using for keys were taking up more memory than I was saving. I got `OutOfMemoryError`s because (I calculated) the keys alone were taking a couple of gigs of memory.

At some point, I will want to increase the resolution of my model, and that will mean a much larger grid. Is there a more efficient way to store my values than using a 3D-Array of floats?

I am also concerned about the time it takes to iterate through all the cells (or just the non-zero cells in my grid. This will be very important.

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Here's an n-dimensional sparse array implementation for Numpy: www2.maths.lth.se/matematiklth/personal/solem/downloads/… –  Blender Feb 28 '13 at 20:34
Curious: what percentage of cells will be zero? –  Robᵩ Feb 28 '13 at 20:59
@Rob perhaps 9/10 will end up being zero. –  theJollySin Feb 28 '13 at 21:17
@Blender What version of Numpy/Python was that made from? I can't seem to run that code without hand-modifying certain things. Like dense(), which requires numpy.ones (something my version of numpy doesn't recognize). –  theJollySin Mar 1 '13 at 1:36

Quick math: `1601 * 1601 * 253 => 648489853 items`. A test indicates that the dictionary takes about 24 bytes per entry on a 32-bit machine, 49 bytes on a 64-bit machine, so that's 15,563,756,472 bytes (or 30GB on 64-bit). 10% of that is 1.5GB (or 3.0GB on 64-bit). If you have a 64-bit system with a bunch of memory, I think you'll be okay with a sparse representation.

I recommend:

1. Use a tuple as the key, not a string, and
2. Use a sparse storage system where you don't store zero values.

Here is one possibility:

``````class SparseDict(dict):
def __init__(self, default_value):
dict.__init__(self)
self._value = default_value
def __getitem__(self, key):
try:
return dict.__getitem__(self, key)
except KeyError:
return self._value
def __setitem__(self, key, val):
# I'm sure this can go faster if I were smarter
if val == self._value:
if  key in self:
del self[key]
else:
dict.__setitem__(self, key, val)

def test(galaxy):
import sys
print len(galaxy), sys.getsizeof(galaxy)

# test is 1/10th size in each dimension,
# so 1/1000th of the volume
for x in range(160):
for y in range(160):
for z in range (25):
import random
# 90% of space is essentially a vacuum
if random.random() < .1:
galaxy[x,y,z] = 1502100
else:
galaxy[x,y,z] = 0

print len(galaxy), sys.getsizeof(galaxy)

test(SparseDict(0))
``````
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I really like the sparse array, for larger and large size grids, it saves me more memory. For some reason though, it is much slower to iterate over a large grid using `SparseDict` than using a normal 3d array. –  theJollySin Mar 1 '13 at 1:39
Try structuring your algorithms so you only need to iterate over the non-zero values, then use `for location, mass in galaxy.iteritems(): ...`. That should make it go much faster. –  Robᵩ Mar 1 '13 at 2:44
I like your `SparseDict` solution! But I have one more question, why is `iteritems` so fast? –  theJollySin Mar 1 '13 at 16:10