Each bit level has a pattern consisting of `2^power`

0s followed by `2^power`

1s.

So there are three cases:

When `M`

and `N`

are such that `M = 0 mod 2^(power+1)`

and `N = 2^(power+1)-1 mod 2^(power+1)`

. In this case the answer is simply `(N-M+1) / 2`

When `M`

and `N`

are such that both M and N = the same number when integer divided by `2^(power+1)`

. In this case there are a few subcases:

- Both
`M`

and `N`

are such that both `M`

and `N`

= the same number when integer divided by `2^(power)`

. In this case if `N < 2^(power) mod 2^(power+1)`

then the answer is `0`

, else the answer is `N-M+1`

- Else they are different, in this case the answer is
`N - (N/2^(power+1))*2^(power+1) + 2**(power)`

(integer division) if `N > 2^(power) mod 2^(power+1)`

, else the answer is `(M/2^(power+1))*2^(power+1) - 1 - M`

Last case is where M and N = different numbers when integer divided by `2^(power+1)`

. This this case you can combine the techniques of 1 and 2. Find the number of numbers between `M`

and `(M/(2^(power+1)) + 1)*(2^(power+1)) - 1`

. Then between `(M/(2^(power+1)) + 1)*(2^(power+1))`

and `(N/(2^(power+1)))*2^(power+1)-1`

. And finally between `(N/(2^(power+1)))*2^(power+1)`

and `N`

.

If this answer has logical bugs in it, let me know, it's complicated and I may have messed something up slightly.

UPDATE:

python implementation

```
def case1(M, N):
return (N - M + 1) // 2
def case2(M, N, power):
if (M > N):
return 0
if (M // 2**(power) == N // 2**(power)):
if (N % 2**(power+1) < 2**(power)):
return 0
else:
return N - M + 1
else:
if (N % 2**(power+1) >= 2**(power)):
return N - (getNextLower(N,power+1) + 2**(power)) + 1
else:
return getNextHigher(M, power+1) - M
def case3(M, N, power):
return case2(M, getNextHigher(M, power+1) - 1, power) + case1(getNextHigher(M, power+1), getNextLower(N, power+1)-1) + case2(getNextLower(N, power+1), N, power)
def getNextLower(M, power):
return (M // 2**(power))*2**(power)
def getNextHigher(M, power):
return (M // 2**(power) + 1)*2**(power)
def numSetBits(M, N, power):
if (M % 2**(power+1) == 0 and N % 2**(power+1) == 2**(power+1)-1):
return case1(M,N)
if (M // 2**(power+1) == N // 2**(power+1)):
return case2(M,N,power)
else:
return case3(M,N,power)
if (__name__ == "__main__"):
print numSetBits(0,10,0)
print numSetBits(0,10,1)
print numSetBits(0,10,2)
print numSetBits(0,10,3)
print numSetBits(0,10,4)
print numSetBits(5,18,0)
print numSetBits(5,18,1)
print numSetBits(5,18,2)
print numSetBits(5,18,3)
print numSetBits(5,18,4)
```