This problem can be solved using dynamic programming. The main idea is to group the binary numbers according to the last x-1 bits and the length of each binary number. If appending a bit sequence to one number yields a number satisfying the constraint, then appending the same bit sequence to any number in the same group results in a number satisfying the constraint also.

For example, x = 4, y = 2. both of 01011 and 10011 have the same last 3 bits (011). Appending a 0 to each of them, resulting 010110 and 100110, both satisfy the constraint.

Here is pseudo code:

```
mask = (1<<(x-1)) - 1
count[0][0] = 1
for(i = 0; i < Len-1; ++i) {
for(j = 0; j < 1<<i && j < 1<<(x-1); ++j) {
if(i<x-1 || count1Bit(j*2+1)>=y)
count[i+1][(j*2+1)&mask] += count[i][j];
if(i<x-1 || count1Bit(j*2)>=y)
count[i+1][(j*2)&mask] += count[i][j];
}
}
answer = 0
for(j = 0; j < 1<<i && j < 1<<(x-1); ++j)
answer += count[Len][j];
```

This algorithm assumes that Len >= x. The time complexity is O(Len*2^x).

**EDIT**

The `count1Bit(j)`

function counts the number of 1 in the binary representation of `j`

.

The only input to this algorithm are `Len, x, and y`

. It starts from an empty binary string `[length 0, group 0]`

, and iteratively tries to append 0 and 1 until length equals to Len. It also does the grouping and counting the number of binary strings satisfying the 1-bits constraint in each group. The output of this algorithm is `answer`

, which is the number of binary strings (numbers) satisfying the constraints.

For a binary string in group `[length i, group j]`

, appending 0 to it results in a binary string in group `[length i+1, group (j*2)%(2^(x-1))]`

; appending 1 to it results in a binary string in group `[length i+1, group (j*2+1)%(2^(x-1))]`

.

Let `count[i,j]`

be the number of binary strings in group `[length i, group j]`

satisfying the 1-bits constraint. If there are at least `y`

1 in the binary representation of `j*2`

, then appending 0 to each of these `count[i,j]`

binary strings yields a binary string in group `[length i+1, group (j*2)%(2^(x-1))]`

which also satisfies the 1-bit constraint. Therefore, we can add `count[i,j]`

into `count[i+1,(j*2)%(2^(x-1))]`

. The case of appending 1 is similar.

The condition `i<x-1`

in the above algorithm is to keep the binary strings growing when length is less than x-1.

`011011`

has a length of 6 or 5? If you want to create an algorithm for your problem you need to clear out if, let's say,`000101`

is a valid number found by the algorithm, which is actually`101`

(less than`111111`

, the biggest number considering the`Len`

variable) and it also satisfies the`(x,y)`

condition. Basically, you have to know if you are looking in the`000000`

-`111111`

interval or just`100000`

-`111111`

. – Alex Filipovici May 22 '13 at 10:03`101`

is smaller than the biggest number generated by the`Len = 6`

variable (i.e.`111111`

). Should the algorithm count only between numbers that have a binary representation of exactly 6 digits or between all the numbers that are smaller or equal than`111111`

? If the latter,`Len`

will be only 3 for`101`

. – Alex Filipovici May 22 '13 at 10:16