I'm looking for an algorithm that will count the number of binary bit patterns in an `n-bit`

word which are equal to or less than an arbitrary limit that is less than `2^n`

. Further, I want to generate the count for all `1-bit`

combinations, `2-bit`

combinations, etc. Obviously, if the limit were `2^n`

, there would be `2^n`

combinations `(C(n,1) 1-bit combinations plus C(n,2) 2-bit plus C(n,3) 3-bit and so on)`

. If a limit were imposed, however, not every one of those possible combinations would be valid (less than the imposed limit).

For example, say `n=4`

. There are 16 possible bit patterns, 15 of which contain 1 or more `1-bits`

. If a limit of 10 were imposed, those patterns greater than 10 would not be included in the count. So, for single bit patterns, the valid ones would be `0001`

, `0010`

, `0100`

, and `1000`

. Two-bit patterns would be `0011`

, `0101`

, `0110`

, `1001`

. Patterns `1010`

and `1100`

would not be counted because they exceed 10. The only 3-bit bit would be `0111`

while the sole 4-bit pattern, `1111`

, is over the limit.

If `F`

is my counting function, `F(4,10,1)`

would return 4, the number of `4-bit`

patterns of 1 bit that are less than 10. `F(4,10,2)`

would return 4 where as `C(4,2)`

is 6. Because the actual value of `n`

can be large (40 or bits), enumerating the possible patterns, testing against the limit, and counting valid ones is impractical.

Any ideas as to how this might be done efficiently?