I guess the best way depends on where your data is large:

- Do you have a huge matrix, with mostly small counts in it? or
- Do you have a moderately sized matrix with huge numbers of counts in it?

Here's a solution that will be suited to the second case, though it will also work
OK in the first case.

Basically, the fact that the counts happen to be in a 2D matrix is not so
important: this is basically the problem of sampling from a population that has
been binned. So what we can do is extract the bins directly, and forget about the
matrix for a bit:

```
import numpy as np
import random
# Input counts matrix
mat = np.array([
[5, 5, 2],
[1, 1, 3],
[6, 0, 4]
], dtype=np.int64)
# Build a list of (row,col) pairs, and a list of counts
keys, counts = zip(*[
((i,j), mat[i,j])
for i in range(mat.shape[0])
for j in range(mat.shape[1])
if mat[i,j] > 0
])
```

And then sample from those bins, using a cumulative array of counts:

```
# Make the cumulative counts array
counts = np.array(counts, dtype=np.int64)
sum_counts = np.cumsum(counts)
# Decide how many counts to include in the sample
frac_select = 0.30
count_select = int(sum_counts[-1] * frac_select)
# Choose unique counts
ind_select = sorted(random.sample(xrange(sum_counts[-1]), count_select))
# A vector to hold the new counts
out_counts = np.zeros(counts.shape, dtype=np.int64)
# Perform basically the merge step of merge-sort, finding where
# the counts land in the cumulative array
i = 0
j = 0
while i<len(sum_counts) and j<len(ind_select):
if ind_select[j] < sum_counts[i]:
j += 1
out_counts[i] += 1
else:
i += 1
# Rebuild the matrix using the `keys` list from before
out_mat = np.zeros(mat.shape, dtype=np.int64)
for i in range(len(out_counts)):
out_mat[keys[i]] = out_counts[i]
```

Now you will have the sampled matrix in `out_mat`

.