It won't be efficient, but you can solve this ~~in polynomial time~~ with a straightforward dynamic programming algorithm. ~~The degree of the polynomial will depend on the number of different sizes that you have.~~

I have included an implementation that for 3 different sizes will be `O(n1 * n2 * n3 * (C/s2) * (C/s3) * ((n1*s1 + n2*s2 + n3*s3)/C))`

with a pretty crappy constant. (That figure comes courtesy of the fact that we the number of distinct patterns of availability is `O(n1 * n2 * n3)`

and for each one we generate `O((C/s2) * (C/s3))`

possible next bins to try, for each of which we have to work with a set of bins whose size is `O((n1*s1 + n2*s2 + n3*s3)/C))`

. A number of routine optimizations could massively speed up this program.)

```
#! /usr/bin/python
import heapq
def min_bins(bin_size, sizes, counts):
available = zip(sizes, counts)
available.sort(reverse=True)
seen = set([])
upcoming = [(0, available, [])]
while 0 < len(upcoming):
(n, available, bins) = heapq.heappop(upcoming)
for (bin, left) in bin_packing_and_left(bin_size, available):
new_bins = bins + [bin]
if 0 == len(left):
return new_bins
elif left not in seen:
heapq.heappush(upcoming, (n+1, left, new_bins))
seen.add(left)
def bin_packing_and_left(bin_size, available, top=True):
if 0 == len(available):
yield ((), ())
else:
(size, count) = available[0]
available = available[1:]
for (bin, left, used) in bin_packing_and_left_size(bin_size, available):
can_use = (bin_size - used) / size
if count <= can_use:
yield(((size, count),) + bin, left)
elif 0 < can_use:
yield(((size, can_use),) + bin,
((size, count - can_use),) + left)
else:
yield(bin, ((size, count),) + left)
def bin_packing_and_left_size(bin_size, available):
if 0 == len(available):
yield ((), (), 0)
else:
(size, count) = available[0]
available = available[1:]
for (bin, left, used) in bin_packing_and_left_size(bin_size, available):
for i in range(1 + min(count, (bin_size - used) / size)):
if count == i:
yield(((size, count),) + bin, left, used + size * count)
elif 0 < i:
yield(((size, i),) + bin,
((size, count - i),) + left,
used + size * i)
else:
yield(bin, ((size, count),) + left, used)
answer = min_bins(23, (2, 3, 5), (20, 30, 40))
print len(answer)
print answer
```