In other cases, clang typically fixes up the stack before returning with a
push has an upside for efficiency in code-size (
push is only 1 byte vs. 4 bytes for
sub rsp, 8), and also in uops on Intel CPUs. (No need for a stack-sync uop, which you'd get if you access
rsp directly because the
call that brought us to the top of the current function makes the stack engine "dirty").
This long and rambling answer discusses the worst-case performance risks of using
push rax /
pop rcx for aligning the stack, and whether or not
rcx are good choices of register. (Sorry for making this so long.)
(TL:DR: looks good, the possible downside is usually small and the upside in the common case makes this worth it. Partial-register stalls could be a problem on Core2/Nehalem if
ax are "dirty", though. No other 64-bit capable CPU has big problems (because they don't rename partial regs, or merge efficiently), and 32-bit code needs more than 1 extra
push to align the stack by 16 for another
call unless it was already saving/restoring some call-preserved regs for its own use.)
push rax instead of
sub rsp, 8 introduces a dependency on the old value of
rax, so you'd think it might slow things down if the value of
rax is the result of a long-latency dependency chain (and/or a cache miss).
e.g. the caller might have done something slow with
rax that's unrelated to the function args, like
var = table[ x % y ]; var2 = foo(x);
# example caller that leaves RAX not-ready for a long time
mov rdi, rax ; prepare function arg
div rbx ; very high latency
mov rax, [table + rdx] ; rax = table[ value % something ], may miss in cache
mov [rsp + 24], rax ; spill the result.
call foo ; foo uses push rax to align the stack
Fortunately out-of-order execution will do a good job here.
push doesn't make the value of
rsp dependent on
rax. (It's either handled by the stack engine, or on very old CPUs
push decodes to multiple uops, one of which updates
rsp independently of the uops that store
rax. Micro-fusion of the store-address and store-data uops let
push be a single fused-domain uop, even though stores always take 2 unfused-domain uops.)
As long as nothing depends on the output
push rax /
pop rcx, it's not a problem for out-of-order execution. If
push rax has to wait because
rax isn't ready, it won't cause the ROB (ReOrder Buffer) to fill up and eventually block the execution of later independent instruction. The ROB would fill up even without the
push because the instruction that's slow to produce
rax, and whatever instruction in the caller consumes
rax before the call are even older, and can't retire either until
rax is ready. Retirement has to happen in-order in case of exceptions / interrupts.
(I don't think a cache-miss load can retire before the load completes, leaving just a load-buffer entry. But even if it could, it wouldn't make sense to produce a result in a call-clobbered register without reading it with another instruction before making a
call. The caller's instruction that consumes
rax definitely can't execute/retire until our
push can do the same.)
rax does become ready,
push can execute and retire in a couple cycles, allowing later instructions (which were already executed out of order) to also retire. The store-address uop will have already executed, and I assume the store-data uop can complete in a cycle or two after being dispatched to the store port. Stores can retire as soon as the data is written to the store buffer. Commit to L1D happens after retirement, when the store is known to be non-speculative.
So even in the worst case, where the instruction that produces
rax was so slow that it led to the ROB filling up with independent instructions that are mostly already executed and ready to retire, having to execute
push rax only causes a couple extra cycles of delay before independent instructions after it can retire. (And some of the caller's instructions will retire first, making a bit of room in the ROB even before our
push rax that has to wait will tie up some other microarchitectural resources, leaving one fewer entry for finding parallelism between other later instructions. (An
add rsp,8 that could execute would only be consuming a ROB entry, and not much else.)
It will use up one entry in the out-of-order scheduler (aka Reservation Station / RS). The store-address uop can execute as soon as there's a free cycle, so only the store-data uop will be left. The
pop rcx uop's load address is ready, so it should dispatch to a load port and execute. (When the
pop load executes, it finds that its address matches the incomplete
push store in the store buffer (aka memory order buffer), so it sets up the store-forwarding which will happen after the store-data uop executes. This probably consumes a load buffer entry.)
Even an old CPUs like Nehalem has a 36 entry RS, vs. 54 in Sandybridge, or 97 in Skylake. Keeping 1 entry occupied for longer than usual in rare cases is nothing to worry about. The alternative of executing two uops (stack-sync +
sub) is worse.
The ROB is larger than the RS, 128 (Nehalem), 168 (Sandybridge), 224 (Skylake). (It holds fused-domain uops from issue to retirement, vs. the RS holding unfused-domain uops from issue to execution). At 4 uops per clock max frontend throughput, that's over 50 cycles of delay-hiding on Skylake. (Older uarches are less likely to sustain 4 uops per clock for as long...)
ROB size determines the out-of-order window for hiding a slow independent operation. (Unless register-file size limits are a smaller limit). RS size determines the out-of-order window for finding parallelism between two separate dependency chains. (e.g. consider a 200 uop loop body where every iteration is independent, but within each iteration it's one long dependency chain without much instruction-level parallelism (e.g.
a[i] = complex_function(b[i])). Skylake's ROB can hold more than 1 iteration, but we can't get uops from the next iteration into the RS until we're within 97 uops of the end of the current one. If the dep chain wasn't so much larger than RS size, uops from 2 iterations could be in flight most of the time.)
There are cases where
push rax / pop rcx can be more dangerous:
The caller of this function knows that
rcx is call-clobbered, so won't read the value. But it might have a false dependency on
rcx after we return, like
bsf rcx, rax /
test eax,eax /
setz cl. Recent Intel CPUs don't rename low8 partial registers anymore, so
setcc cl has a false dep on
bsf actually leaves its destination unmodified if the source is 0, even though Intel documents it as an undefined value. AMD documents leave-unmodified behaviour.
The false dependency could create a loop-carried dep chain. On the other hand, a false dependency can do that anyway, if our function wrote
rcx with instructions dependent on its inputs.
It would be worse to use
pop rbx to save/restore a call-preserved register that we weren't going to use. The caller likely would read it after we return, and we'd have introduced a store-forwarding latency into the caller's dependency chain for that register. (Also, it's maybe more likely that
rbx would be written right before the
call, since anything the caller wanted to keep across the call would be moved to call-preserved registers like
On CPUs with partial-register stalls (Intel pre-Sandybridge), reading
push could cause a stall or 2-3 cycles on Core2 / Nehalem if the caller had done something like
setcc al before the
call. Sandybridge doesn't stall while inserting a merging uop, and Haswell and later don't rename low8 registers separately from
rax at all.
It would be nice to
push a register that was less likely to have had its low8 used. If compilers tried to avoid REX prefixes for code-size reasons, they'd avoid
rsi would be less likely to have partial-register issues. But unfortunately gcc and clang don't seem to favour using
cl as 8-bit scratch registers, using
sil even in tiny functions where nothing else is using
rcx. (Although lack of low8 renaming in some CPUs means that
setcc cl has a false dependency on the old
setcc dil is safer if the flag-setting was dependent on the function arg in
pop rcx at the end "cleans"
rcx of any partial-register stuff. Since
cl is used for shift counts, and functions do sometimes write just
cl even when they could have written
ecx instead. (IIRC I've seen clang do this. gcc more strongly favours 32-bit and 64-bit operand sizes to avoid partial-register issues.)
push rdi would probably be a good choice in a lot of cases, since the rest of the function also reads
rdi, so introducing another instruction dependent on it wouldn't hurt. It does stop out-of-order execution from getting the
push out of the way if
rax is ready before
Another potential downside is using cycles on the load/store ports. But they are unlikely to be saturated, and the alternative is uops for the ALU ports. With the extra stack-sync uop on Intel CPUs that you'd get from
sub rsp, 8, that would be 2 ALU uops at the top of the function.