I realize the difference may be negligible, but which is more efficient in trying to zero an unsigned long?
unsigned long x; ... x=0; --OR-- x^=x;
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If you were to implement a compiler, what would you do? Indeed, you would pick the fastest implementation for both. Since both are equal, this fastest implementation is the same for both.
In other words, any compiler released after 5000 B.C. will generate the same assembly code for both
This doesn't go for only assignment/xorring, but also for multiplication, among other algorithms. Express your intent and let the compiler optimize it. The compiler is better at optimizations than you are, trust me.
In other words, write readable code and use
Oh and by the way, bitwise xorring an uninitialized integer by itself is undefined behavior and a good compiler should optimize out the entire thing.
First of all, if the variable has not been assigned a value, it is technically "undefined behaviour" to do anything other than assign a value to it.
Second, to XOR it with itself is unlikely to be faster on a processor produced in the last 15-20 years, since it requires an extra read. It may have been faster (due to being SHORTER CODE) a very long time back, but actually, I believe even that is false.
Edit: I should point out that it MAY still be faster/more compact to XOR a register to make it zero in modern processors. But if we assume that we can't know if
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Why speculate about what the compiler does? Let's try it out instead!
Here's some test code:
And now lets look at the resulting machine code:
Oh, Look! They were equally fast, both taking exactly 0 ns.