There is this post, which has recently received some remarkable bunch of upvotes, asking about the + operator in C.
It shows the following implementation:

// replaces the + operator
int add(int x, int y) {
    while(x) {
        int t = (x & y) <<1;
        y ^= x;
        x = t;
    return y;

Coincidentally, I wrote an implementation myself too (an algorithm book exercise) and came up with that:

uint32_t bit_add(uint16_t a, uint16_t b) {
    uint32_t carry = ((uint32_t) a & b) << 1;
    uint16_t add = a ^ b;

    return carry ^ add;

I tested it a couple of times and it seems to work. Thing is, it is significantly faster than the implementation from the referenced post, lacking any jumps on an x86.

Is my implementation correct or is there something wrong I am not aware of?
I cannot imagine my code to be faster than the code of a post so often seen and reviewed.

  • I didn't check, but it might be correct. Don't assume people write the most efficient code possible all the time; After all these answers were mostly created for toy problems or for demonstration purposes, not for actual use (+ is still faster). – Cubic Feb 29 '16 at 13:12
  • The two examples are differents, the first operates one bit per instruction in loop, in yours all bits are affected. The compiler may also have optimized your code. – Mathieu Feb 29 '16 at 13:13
  • Try adding 3 and 7, it outputs 2. – Kenney Feb 29 '16 at 13:15
  • 4
    This algorithm is the software implementation of the hardware adder logic, where the xor is used to add single bits and the and to extract carry to add over next bit. As such absolutely useless and much more slower that the hardware add instruction. Your code fails because, respect the original solution, the carry shift is not correctly performed. See en.wikipedia.org/wiki/Adder_(electronics) – Frankie_C Feb 29 '16 at 13:18
  • 1
    The original code invokes undefined behaviour for certain values of x and y. – too honest for this site Feb 29 '16 at 13:34

Your function doesn't work.

A simple counterexample is 127 + 1.

This is easy to see. Number 127 has all lest significant 7 bits sets to 1. Anding it with the number 1, and shifting it one to the left, will give the value 2. From then on, using the operator xor, no combination of values we have available, can produce a value that is larger than 127.

  • Crap, you're right. Could you explain why? I'm already about to start debugging but an explanation would make for an even finer answer, IMO... – cadaniluk Feb 29 '16 at 13:15
  • @cad you compute your add and carry correctly but in the return statement you made a mistake! that is where you need the Loop – Lrrr Feb 29 '16 at 13:17

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