# Is it possible to write a function adding two integers without control flow and strictly bitwise operations?

I misunderstood a question that said to add two integers using bitwise operations. I did not use any control flow and could not do it. After giving up, all the solutions I found use control flow to accomplish this whether it be an `if`, `while`, `for`, recursion, etc,. Is there a proof that is can\cannot be accomplished?

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It's done all the time. Check out adders. –  SáT Dec 10 '13 at 12:20
What sort of integers? For fixed length integers it is trivial (just unroll the loop by the maximum amount that may be needed, unnecessary iterations will have no effect). –  harold Dec 10 '13 at 12:56

For a fixed length integer, you can just unroll a ripple carry adder. In the worst case, a carry signal has to propagate all the way from the least significant bit to the most significant bit.

Like this (only slightly tested) (to avoid the C-purists' wrath, I will call this C# code)

``````int add_3bits(int x, int y)
{
int c = x & y;
x = x ^ y;
y = c << 1;
//
c = x & y;  //  \
x = x ^ y;  //  | for more bits, insert more of these blocks
y = c << 1; //  /
//
// optimized last iteration
return (x ^ y) & 7; // for more bits, change that mask
}
``````

If you do it for as many bits as your integer will hold, you won't need the mask in the end.

That's not very efficient, clearly. For 3 bits it's fine, but for 32 bits it becomes quite long. A Kogge-Stone adder (one of the O(log n) delay adder circuits) is also surprisingly easy to implement in software (in hardware you have to deal with a lot of wires, software doesn't have that problem).

For example: (verified using my website)

``````static uint add_32bits(uint x, uint y)
{
uint p = x ^ y;
uint g = x & y;

g |= p & (g << 1);
p &= p << 1;

g |= p & (g << 2);
p &= p << 2;

g |= p & (g << 4);
p &= p << 4;

g |= p & (g << 8);
p &= p << 8;

g |= p & (g << 16);

return x ^ y ^ (g << 1);
}
``````
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That link works for me, but apparently not for everyone. Pity. Not that important, though. –  harold Dec 11 '13 at 9:22