Given four integers a ≤ b ≤ c and k, how do you count integers in [a, c] whose binary representations differ in exactly k positions from that of b? a, b and c are about 30 bits long.

If you need to compute the count for a given a, b and c, and for all values of k, then I think your best bet is to iterate and count the number of bits in the xor'ed difference.
You can even parallellize this easily. You would need to keep a separate set of counts for each thread, and add them all up at the end to get the grand totals. For a range of 1 billion numbers, the parallel version of this algorithm took 3.7 seconds on my machine. EDIT: Actually, there is a way to get the counts without enumerating. Here's the basic idea for (a,b,c)=(17,25,29), or in binary (10001,11001,11101). First, notice that the range 1100011011 contains b, and is also entirely contained in (a,c). So these 2^2 values, contribute choose(2,k) to each count. The next interval down is 1010010111. The numbers in this range all have at least 2 bits different from b, so they contribute choose(2,k2) to the kth count. The next interval down that is fully contained in (a,c) is 1001010011, which contributes choose(1,k1), and so on. You also have to count upwards. 2nd edit: Couldn't resist implementing this. Total time for 1 billion numbers: 0.004ms... 


The total count of numbers which differ in exactly k positions from b and are written with at most 30 bits is 


Why not just explicitly enumerate all values between 


Write the binary repr for b, flip k of the bits and check if it violates the bounds. For a,b being 30 bits it shouldn't be prohibitive to write a shell script or a C program so long as k is reasonable. 

