The idea behind this answer can help you develop very fast solution. Having ranges 0..2^N the complexity of a potential algorithm would be O(N) in the worst case (Assuming that complexity of a long arithmetic is O(1)) If programmed correctly it should easily handle N = 1000000 in a matter of milliseconds.

Imagine we have the following values:

```
LO = 0; (0000000000000000000000000000000)
HI = 2147483647; (1111111111111111111111111111111)
```

The lowest possible N1 in range LO..HI is 0
The highest possible N1 in range LO..HI is 31

So the computation of N2..NN part is done only for one of 32 values (i.e. 0..31).
Which can be done simply, even without a computer.
Now lets compute the amount of N1=X for a range of values LO..HI

When we have X = 0 we have count(N1=X) = 1 this is the following value:

```
1 0000000000000000000000000000000
```

When we have X = 1 we have count(N1=X) = 31 these are the following values:

```
01 1000000000000000000000000000000
02 0100000000000000000000000000000
03 0010000000000000000000000000000
...
30 0000000000000000000000000000010
31 0000000000000000000000000000001
```

When we have X = 2 we have the following pattern:

```
1100000000000000000000000000000
```

How many unique strings can be formed with 29 - '0' and 2 - '1'?

Imagine the rightmost '1'(#1) is cycling from left to right, we get the following picture:

```
01 1100000000000000000000000000000
02 1010000000000000000000000000000
03 1001000000000000000000000000000
...
30 1000000000000000000000000000001
```

Now we've got 30 unique strings while moving the '1'(#1) from left to right, it is now impossible to
create a unique string by moving the '1'(#1) in any direction. This means we should move '1'(#2) to the right,
let's also reset the position of '1'(#1) as left as possible remaining uniqueness, we get:

```
01 0110000000000000000000000000000
```

now we do the cycling of '1'(#1) once again

```
02 0101000000000000000000000000000
03 0100100000000000000000000000000
...
29 0100000000000000000000000000001
```

Now we've got 29 unique strings, continuing this whole operation 28 times we get the following expression

```
count(N1=2) = 30 + 29 + 28 + ... + 1 = 465
```

When we have X = 3 the picture remains similar but we are moving '1'(#1), '1'(#2), '1'(#3)

Moving the '1'(#1) creates 29 unique strings, when we start moving '1'(#2) we get

29 + 28 + ... + 1 = 435 unique strings, after that we are left to process '1'(#3) so we have

```
29 + 28 + ... + 1 = 435
28 + ... + 1 = 406
...
+ 1 = 1
435 + 406 + 378 + 351 + 325 + 300 + 276 +
253 + 231 + 210 + 190 + 171 + 153 + 136 +
120 + 105 + 091 + 078 + 066 + 055 + 045 +
036 + 028 + 021 + 015 + 010 + 006 + 003 + 001 = 4495
```

Let's try to solve the general case i.e. when we have N zeros and M ones.
Overall amount of permutations for the string of length (N + M) is equal to (N + M)!

The amount of '0' duplicates in this string is equal to N!
The amount of '1' duplicates in this string is equal to M!

thus receiving overall amount of unique strings formed of N zeros and M ones is

```
(N + M)! 32! 263130836933693530167218012160000000
F(N, M) = ============= => ========== = ====================================== = 4495
(N!) * (M!) 3! * 29! 6 * 304888344611713860501504000000
```

**Edit:**

```
F(N, M) = Binomial(N + M, M)
```

Now let's consider a real life example:

```
LO = 43797207; (0000010100111000100101011010111)
HI = 1562866180; (1011101001001110111001000000100)
```

So how do we apply our unique permutations formula to this example? Since we don't know how
many '1' is located below LO and how many '1' is located above HI.

So lets count these permutations below LO and above HI.

Lets remember how we cycled '1'(#1), '1'(#2), ...

```
1111100000000000000000000000000 => 2080374784
1111010000000000000000000000000 => 2046820352
1111001000000000000000000000000 => 2030043136
1111000000000000000000000000001 => 2013265921
1110110000000000000000000000000 => 1979711488
1110101000000000000000000000000 => 1962934272
1110100100000000000000000000000 => 1954545664
1110100010000000000000000000001 => 1950351361
```

As you see this cycling process decreases the decimal values smoothly. So we need to count amount of
cycles until we reach HI value. But we shouldn't be counting these values by one because
the worst case can generate up to 32!/(16!*16!) = 601080390 cycles, which we will be cycling very long :)
So we need cycle chunks of '1' at once.

Having our example we would want to count the amount of cycles of a transformation

```
1111100000000000000000000000000 => 1011101000000000000000000000000
1011101001001110111001000000100
```

So how many cycles causes the transformation

```
1111100000000000000000000000000 => 1011101000000000000000000000000
```

?

Lets see, the transformation:

```
1111100000000000000000000000000 => 1110110000000000000000000000000
```

is equal to following set of cycles:

```
01 1111100000000000000000000000000
02 1111010000000000000000000000000
...
27 1111000000000000000000000000001
28 1110110000000000000000000000000
```

So we need 28 cycles to transform

```
1111100000000000000000000000000 => 1110110000000000000000000000000
```

How many cycles do we need to transform

```
1111100000000000000000000000000 => 1101110000000000000000000000000
```

performing following moves we need:

```
1110110000000000000000000000000 28 cycles
1110011000000000000000000000000 27 cycles
1110001100000000000000000000000 26 cycles
...
1110000000000000000000000000011 1 cycle
```

and 1 cycle for receiving:

```
1101110000000000000000000000000 1 cycle
```

thus receiving 28 + 27 + ... + 1 + 1 = 406 + 1

but we have seen this value before and it was the result for the amount of unique permutations, which was
computed for 2 '1' and 27 '0'. This means that amount of cycles while moving

```
11100000000000000000000000000 => 01110000000000000000000000000
```

is equal to moving

```
_1100000000000000000000000000 => _0000000000000000000000000011
```

plus one additional cycle

so this means if we have M zeros and N ones and want to move the chunk of U '1' to the right we will need to
perform the following amount of cycles:

```
(U - 1 + M)!
1 + =============== = f(U, M)
M! * (U - 1)!
```

**Edit:**

```
f(U, M) = 1 + Binomial(U - 1 + M, M)
```

Now let's come back to our real life example:

```
LO = 43797207; (0000010100111000100101011010111)
HI = 1562866180; (1011101001001110111001000000100)
```

so what we want to do is count the amount cycles needed to perform the following
transformations (suppose N1 = 6)

```
1111110000000000000000000000000 => 1011101001000000000000000000000
1011101001001110111001000000100
```

this is equal to:

```
1011101001000000000000000000000 1011101001000000000000000000000
------------------------------- -------------------------------
_111110000000000000000000000000 => _011111000000000000000000000000 f(5, 25) = 118756
_____11000000000000000000000000 => _____01100000000000000000000000 f(2, 24) = 301
_______100000000000000000000000 => _______010000000000000000000000 f(1, 23) = 24
________10000000000000000000000 => ________01000000000000000000000 f(1, 22) = 23
```

thus resulting 119104 'lost' cycles which are located above HI

Regarding LO, there is actually no difference in what direction we are cycling
so for computing LO we can do reverse cycling:

```
0000010100111000100101011010111 0000010100111000100101011010111
------------------------------- -------------------------------
0000000000000000000000000111___ => 0000000000000000000000001110___ f(3, 25) = 2926
00000000000000000000000011_____ => 00000000000000000000000110_____ f(2, 24) = 301
```

Thus resulting 3227 'lost' cycles which are located below LO this means that

```
overall amount of lost cycles = 119104 + 3227 = 122331
overall amount of all possible cycles = F(6, 25) = 736281
N1 in range 43797207..1562866180 is equal to 736281 - 122331 = 613950
```

I wont provide the remaining part of the solution. It is not that hard to grasp the remaining part. Good luck!