All three of the earlier answers are wrong in different ways.
The accepted answer by Margaret Bloom implies that partial register stalls are to blame. Partial register stalls are a real thing, but are unlikely to be relevant to GCC's decision here.
If GCC replaced
mov edx,3 by
mov dl,3, then the code would just be wrong, because writes to byte registers (unlike writes to dword registers) don't zero the rest of the register. The parameter in
rdx is of type
size_t, which is 64 bits, so the callee will read the full register, which will contain garbage in bits 8 to 63. Partial register stalls are purely a performance issue; it doesn't matter how fast the code runs if it's wrong.
That bug could be fixed by inserting
xor edx,edx before
mov dl,3. With that fix, there is no partial register stall, because zeroing a full register with
sub and then writing to the low byte is special-cased in all CPUs that have the stalling problem. So partial register stalls are still irrelevant with the fix.
The only situation where partial register stalls would become relevant is if GCC happened to know that the register was zero, but it wasn't zeroed by one of the special-cased instructions. For example, if this syscall was preceded by
then GCC could deduce that
rdx was zero at the point where it wants to put 3 in it, and
mov dl,3 would be correct – but it would be a bad idea in general because it could cause a partial-register stall. (Here, it wouldn't matter because syscalls are so slow anyway, but I don't think GCC has a "slow function that there's no need to speed-optimize calls to" attribute in its internal type system.)
Why doesn't GCC emit
xor followed by a byte move, if not because of partial register stalls? I don't know but I can speculate.
It only saves space when initializing
r3, and even then it only saves one byte. It increases the number of instructions, which has its own costs (the instruction decoders are frequently a bottleneck). It also clobbers the flags unlike the standard
mov, which means it isn't a drop-in replacement. GCC would have to track a separate flag-clobbering register initialization sequence, which in most cases (11/15 of possible destination registers) would be unambiguously less efficient.
If you're aggressively optimizing for size, you can do
push 3 followed by
pop rdx, which saves 2 bytes regardless of the destination register, and doesn't clobber the flags. But it is probably much slower because it writes to memory and has a false read-write dependence on
rsp, and the space savings seem unlikely to be worth it. (It also modifies the red zone, so it isn't a drop-in replacement either.)
supercat's answer says
Processor cores often include logic to execute multiple 32-bit or 64-bit instructions simultaneously, but may not include logic to execute an 8-bit operation simultaneously with anything else. Consequently, while using 8-bit operations on the 8088 when possible was a useful optimization on the 8088, it can actually be a significant performance drain on newer processors.
Modern optimizing compilers actually use 8-bit GPRs quite a lot. (They use 16-bit GPRs relatively rarely, but I think that's because 16-bit quantities are uncommon in modern code.) 8-bit and 16-bit operations are at least as fast as 32-bit and 64-bit operations at most execution stages, and some are faster.
I previously wrote here "As far as I know, 8-bit operations are as fast as, or faster than, 32/64-bit operations on absolutely every 32/64 bit x86/x64 processor ever made." But I was wrong. Quite a few superscalar x86/x64 processors merge 8- and 16-bit destinations into the full register on every write, which means that write-only instructions like
mov have a false read dependency when the destination is 8/16 bits which doesn't exist when it's 32/64 bits. False dependency chains can slow execution if you don't clear the register before every move (or during, using something like
movzx). Newer processors have this problem even though the earliest superscalar processors (Pentium Pro/II/III) didn't have it. In spite of that, modern optimizing compilers do use the smaller registers in my experience.
BeeOnRope's answer says
The short answer for your particular case, is because gcc always sign or zero-extends arguments to 32-bits when calling a C ABI function.
But this function has no parameters shorter than 32 bits in the first place. File descriptors are exactly 32 bits long, and
size_t is exactly 64 bits long. It doesn't matter that many of those bits are often zero. They aren't variable-length integers that are encoded in 1 byte if they're small. It would only be correct to use
mov dl,3, with the rest of
rdx possibly being nonzero, for a parameter if there was no integer promotion requirement in the ABI and the actual parameter type was
char or some other 8-bit type.