This is a possible assembly code of
int x = plus_10(40);
push 40 ; push argument
call plus_10 ; call function
retadd: add esp, 4 ; clean up stack (dummy pop)
; result of the function call is in EAX, per the calling convention
; if compiled without optimization, the caller might just store it:
mov DWORD PTR [ebp-x], eax ; store return value
; (in eax) in x
Now when you call
plus_10, the address
retadd is pushed on the stack by the
call instruction. It's effectively a
ret is effectively
So your stack looks like this in the
| ... |
| 40 | <- ESP+4 points here (the function argument)
| retadd | <- ESP points here
ESP points to a memory location that contains the return address.
Now if you use
pop edx the return address goes into
edx and the stack looks like this:
| ... |
| 40 | <- ESP points here
Now if you execute
ret at this point, the program will actually jump to address 40 and most likely segfault or behave in some other unpredictable way.
The actual assembly code generated by the compiler may be different, but this illustrates the problem.
BTW, a more efficient way to write your function is this: it's what most compilers would do with optimization enabled, for a non-inline version of this tiny function.
mov eax, [esp+4] ; retval = first arg
add eax, 10 ; retval += 10
This is smaller and slightly more efficient than
mov eax, 10
add eax, [esp+4] ; decode to a load + add.