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my solution

get the rightmost n bits of y
a = ~(~0 << n) & y

clean the n bits of x beginning from p
c = ( ~0 << p | ~(~0 << (p-n+1))) & x

set the cleaned n bits to the n rightmost bits of y
c | (a << (p-n+1))

it is rather long statements. do we have a better one?

x = 0 1 1 1 0 1 1 0 1 1 1 0
p = 4
y = 0 1 0 1 1 0 1 0 1 0 
n = 3

the 3 rightmost bits of y is 0 1 0 
it will replace x from bits 4 to bits 2 which is 1 1 1
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the "n bits that begin at position p" go from p to p+n-1... So why does p-n+1 show up in your expression (twice)? –  Nemo Jul 18 '11 at 0:54
the whole manipulation includes two parts, I am talking about beginning from rightmost parts: bits [p-n+1,p], and bits [0,p-n+1]. We want to change the value of the firs part and keep the second part unchanged. –  SecureFish Jul 18 '11 at 1:12
Right, but the bits from [p-n+1,p] are the n bits ending at position p, not the n bits starting at position p as your question says. (Assuming bits "start" from 0...) I think you need to fix your code or fix your question... –  Nemo Jul 18 '11 at 1:16
begins from p assuming iterate the bits string from left to right. Yes, you are right, I should have made it clearer. –  SecureFish Jul 18 '11 at 1:30
Yeah, I would phrase it just like you did in your comment: "From bit p-n+1 to bit p." If you say a bit string "begins at bit 7 and ends at bit 5" I bet 50% of programmers would take issue with that phrasing :-) –  Nemo Jul 18 '11 at 1:32
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2 Answers

I wrote similar one:

 unsigned setbits (unsigned x, int p, int n, unsigned y)
  return (x & ~(~(~0<<n)<<(p+1-n)))|((y & ~(~0<<n))<<(p+1-n));
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And today's award for C code Obfuscation goes to... –  Andrew Oct 26 '12 at 9:04
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There are two reasonable approaches.

One is yours: Grab the low n bits of y, nuke the middle n bits of x, and "or" them into place.

The other is to build the answer from three parts: Low bits "or" middle bits "or" high bits.

I think I actually like your version better, because I bet n and p are more likely to be compile-time constants than x and y. So your answer becomes two masking operations with constants and one "or"; I doubt you will do better.

I might modify it slightly to make it easier to read:

mask = (~0 << p | ~(~0 << (p-n+1)))
result = (mask & a) | (~mask & (y << (p-n+1)))

...but this is the same speed (indeed, code) as yours when mask is a constant, and quite possibly slower when mask is a variable.

Finally, make sure you have a good reason to worry about this in the first place. Clean code is good, but for something this short, put it in a well-documented function and it does not matter that much. Fast code is good, but do not attempt to micro-optimize something like this until your profiler tells you do. (Modern CPUs do this stuff very fast; it is unlikely your application's performance is bounded by this sort of function. At the very least it is "innocent until proven guilty".)

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