On a fully stack-based calling convention, there's nothing wrong with implementing the assembly side of calls like:
void myfunction(void)
{
call_some_func(1, 2, 3);
call_another_func(1, 2, 3);
call_more_stuff(1, 2, 3);
call_even_more_stuff(0, 1, 2, 3);
call_yet_more(2, 3);
...
}
as a sequence like (AT&T syntax, 32bit x86, I'm a UN*X guy):
myfunction:
pushl $3
pushl $2
pushl $1
call call_some_func
call call_another_func
call call_more_stuff
pushl $0
call call_even_more_stuff
addl $8, %esp
call call_yet_more_stuff
...
addl $8, %esp
ret
The calling conventions (for, as Microsoft calls it, cdecl
style, as is also used on the UN*X i386 ABI) for stack-based parameter passing all have the property that the stackpointer is unchanged after call
returns. That means if you pushed a series of arguments onto the stack and performed a call
, they will still be on the stack after whatever function you called returns. So there's nothing stopping you from re-using these in-place; as shown, in some cases you might even be able to re-use what's already on the stack if you're calling funcs with more/less arguments than you've used in previous calls.
After a function returns, the stack is again yours; you don't have to clean up (do an addl $..., %esp
directly after a call
), if what's already on there is useful to you just keep it.
This obviously doesn't work the same way for register-based function calling. Although, if your CPU architecture allows a multi-register load/store of sorts, you might still be able to use the thing. On ARM, for example, the above can be made into:
myfunction:
stmfd sp!, {lr}
mov r0, #1
mov r1, #2
mov r2, #3
stmfd sp!, {r0-r2}
bl call_some_func
ldmfd sp, {r0-r2}
bl call_another_func
ldmfd sp, {r0-r2}
bl call_more_stuff
ldmfd sp!, {r1-r3}
mov r0, #0
stmfd sp!, {r2, r3}
bl call_even_more_stuff
ldmfd sp!, {r0, r1, lr}
b call_yet_more_stuff
I.e. you keep the stuff on the stack and load it from there without changing the stackpointer for the loads (the sp!
on ARM makes the difference between changing and just using the stack register).
In the end, it'll be a good idea to create a C version of the code, run it through a highly optimizing compiler for your platform / CPU / calling convention and check out the code generated. These days, compilers have become quite good at figuring out such opportunities for re-using things.
Edit:
If you're thinking of the following:
void myfunc(void *a1, void *a2, void *a3)
{
func1(a1, a2, a3);
func2(a1, a2, a3);
func3(a1, a2, a3);
}
then what you can do is to "play towers-of-hanoi" with the stack and re-order it; the return address into the caller of myfunc
is topmost on the stack, and the arguments follow; so use the clobber registers (%eax
, %ecx
and %edx
on UN*X) to temporarily store values while you move the return address to the very bottom of the stack. With three args that's easy enough as a single rounds of "hanoi" will do:
myfunc:
popl %eax ; return address now in EAX
popl %ecx ; arg[1]
popl %edx ; arg[2]
xchgl %eax, (%esp) ; swap return address and arg[3]
pushl %eax ; re-push arg[3]
pushl %edx ; and arg[2]
pushl %ecx ; and arg[1]
call func1
call func2
call func3
popl %ecx ; pop of dummy, gets %esp to pre-call
jmpl 0xc(%esp) ; use jmpl to return - address at "bottom"
Edit2: I've initially made a mistake here using a nonvolatile register (%ebx
) to hold the return address; as correctly remarked by commentators that'd clobber the value in the register and cause problems to our caller. To prevent this, the above method of re-ordering things on the stack can be used.