In x86 assembly, is it possible to remove a value from the stack without storing it? Something along the lines of
pop word null? I could obviously use
add esp,4, but maybe there's a nice and clean cisc mnemonic i'm missing?
add esp,4 /
add rsp,8 is the normal / idiomatic / clean way. No special way is needed because stacks aren't magical or special (at least not in this respect); it's just a pointer in a register with some instructions that use it implicitly. (And for kernel stacks, interrupts use it asynchronously so software couldn't implement a kernel red-zone even if it wanted to...)
Other than that, the magical CISC way to clean up a whole stack frame at the end of a function is
mov esp, ebp /
pop ebp (or the 16 or 64-bit equivalent). Unlike
enter, it's fast enough on modern CPUs to be usable in practice, but still a 3 uop instruction on Intel CPUs. (http://agner.org/optimize/). But
leave only works in the first place if you spent extra instructions making a stack frame with
rbp in the first place. (Usually you wouldn't do that, unless you need to reserve a variable amount of stack space, e.g. with
push in a loop to make an array, or the equivalent of a C99 VLA or
alloca. Or for beginner code to make access to locals easier, or in 16-bit mode where
SP can't be used in addressing modes.)
The magical CISC way to clean up stack-args is for the callee to use
ret imm16 (costing 1 extra uop) to pop the args, creating a calling convention where the callee cleans the stack. In a caller-pops calling convention, there's no way to use this form of
ret, but you can simply leave the stack offset and use
mov to store args for the next function call instead of
push (if the function needs any stack-args at all; register-arg calling conventions are generally more efficient.)
So the magic CISC ways have no performance advantage on modern CPUs, only minor code-size.
There are 2 reasons you might use
pop reg instead of
pop r32/r64is a one-byte instruction, vs. 3 bytes for
add esp,4or 4 bytes for
performance: Intel's stack engine has to insert extra stack-sync uops when you use
rspexplicitly after a stack instruction (push/pop/call/ret). So after a
call(which returns with a
ret), it saves a uop to use
add esp,4before you
retat the end of the function.
AMD's stack engine doesn't need extra stack-sync uops, but still makes push/pop single-uop instructions. Unlike on older Intel/AMD CPUs, where push/pop cost more than plain
movloads/stores, needing a separate uop for the stack-pointer modification. And creating a data dependency on the stack pointer.
See Why does this function push RAX to the stack as the first operation? for more details about performance.
If you were looking for aesthetics, well you can indent, format, and comment your code nicely, but beyond you chose the wrong language when you picked x86 asm if aesthetics outweigh optimization.
Of course, if you need to adjust the stack by more than 1 register-width, definitely use
add if you don't need the data that
pop would load. Or, if you need to adjust it by +128 bytes, use
sub esp, -128, because
-128 is encodable as a sign-extended imm8, but +128 isn't.
Or maybe use
lea esp, [esp+4], like gcc does with
-mtune=atom. (For in-order atom, not silvermont). Like I said, if you wanted clean, you shouldn't have picked x86 asm.
You can almost always find a dead register to
pop into. If you need to adjust E/RSP by one stack slot before popping some registers you actually wanted to pop, you can always pop the same register twice.
In the extremely rare case where none of the 7 (x86-32) or 15 (x86-64) non-stack register are available as
pop destinations, this optimization is not available and you should simply use the traditional
add. It's not worth spending extra instructions to make it possible to
pop; that would outweigh the minor benefit of using
pop Sreg (segment register) still consumes the regular "stack width" (32 or 64 bits, depending on mode), rather than only 16 for a 16-bit register. But only
pop ds/es/ss are single-byte.
pop fs/gs are 2 bytes each. So if you're optimizing for code-size,
pop gs is 1 byte smaller than
add esp,4, but much much slower. (Or 2 bytes smaller than