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Why do we have commands like push and pop?

From what I understand pop and push are basically the same as doing a (mov then add) and (sub then mov) on esp respectively.


For example wouldn't:

pushl %eax

be equivalent to:

subl $4, %esp
movl %eax, (%esp-4)

please correct me if stack access is not (%esp-4), I'm still learning assembly


The only true benefit I can see is if doing both operation simultaneously offers some advantage; however I don't see how it could.

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1  
It saves space, and x86 is actually a CISC design so why not. –  harold Apr 14 '12 at 17:45
    
@harold it provides no extra function that's why not. The CPU still spends time on both operations. –  Hawken Apr 14 '12 at 17:52
    
Yes.. but it's a CISC design, so it was designed to make it easy for assembly programmers to work with by providing instructions that "do a lot". See also: leave, enter, rep movsb etc. And it really does save a lot of space in bytes as well. –  harold Apr 14 '12 at 17:54

3 Answers 3

up vote 7 down vote accepted

But then, there's no reason for a CALL instruction, either. After all, you can simulate a call with:

sub esp,4
mov [esp-4], offset return_address
jmp myproc

And there's no need for a RET instruction, either, because you can simulate it with:

mov eax,[esp]
add esp,4
jmp [eax]

If you look hard enough, you'll find lots of instructions that can be simulated by combining other instructions. What's the point?

The answer to these types of questions is rooted in the long history of the x86 processor family, and in processors that came before it. The designers studied how programmers use processors and created an instruction set that was efficient in terms of execution speed and memory use.

In the late '70s, 64 kilobytes was a lot of RAM, and RAM was much slower. Every instruction byte was precious, and there was a huge amount of overhead just fetching an instruction from memory. It was not uncommon for instruction fetch to take longer than execution. So there was a huge performance gain to be had by encoding things in as few instruction bytes as possible.

RAM is still incredibly slow when compared to CPU clock speeds, so there's still a gain to be had by encoding in as few instruction bytes as possible. It's true that the large CPU caches we have help a great deal, as does branch prediction and prefetch logic, but every byte transferred from RAM to the CPU cache is still expensive. It pays to be frugal with instruction encodings.

About calling procedures:

The standard way of calling procedures in assembly language is to push the parameters and then call the procedure. For example, this passes two dword values:

push eax
push ebx
call proc    ; pushes the return address and jumps to proc
...

proc:
  ; at this point, [esp] contains the return address

The ret instruction pops the return address into the instruction pointer.

Somebody has to clean up the stack, of course. The caller can clean up the stack by incrementing the stack pointer. Or the called procedure can clean up the stack by using ret 8, which will pop the return address and increment the stack pointer.

See http://www.delorie.com/djgpp/doc/ug/asm/calling.html for more info on calling conventions.

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I thought subl $4, %esp is required before a call anyway or at least before an interrupt it is; also, why does %esp have the return address in your example? –  Hawken Apr 14 '12 at 21:50
    
@Hawken: You have to put the return address somewhere. –  Jim Mischel Apr 15 '12 at 0:35
    
but why is the return address at the stack pointer? Is this assuming you cleared the stack vars you used for the called function? –  Hawken Apr 15 '12 at 0:43
    
@Hawken: The standard calling conventions push the parameters and then the return address. (Actually, the call instruction pushes the return address.) So the return address is always at the "top" of the stack (i.e. pointed to by SP). –  Jim Mischel Apr 15 '12 at 1:07
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@Hawken: See my additional information, especially the link to information about calling conventions. –  Jim Mischel Apr 15 '12 at 3:28

Well. If you have two instructions, then they probably use more space. Which requires cpu to transfer more data. And that takes more time. Two separate instructions also typically require more cpu resources. Even if cpu parallelizes them, there is more work for fetcher, decoder... If you try to remove all but absolutely neccessary instructions you end up with turing machine. Ultimate risc, but not very effective in practice.

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1 opcode > 2 opcodes, at least when you are trying to reduce CPU usage.

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I understand, this saves memory on part of the executable, but both operations must still be carried out. Perhaps this is the kind of thing that inspired the RISC architecture? –  Hawken Apr 14 '12 at 17:32
2  
Hmm, it possibly inspired the demise of RISC architectures. –  Hans Passant Apr 14 '12 at 18:46
    
@hanspassant why? RISC is more predictable per instruction, CISC seems to do nothing except make a 'shortcut' which still takes the same amount of time to execute (not much of a shortcut). From what I have read of CISC it is slower in many scenarios due to these shortcuts. If I understand correctly something like addl %eax,%ebx will waste time checking if %eax and %ebx are memory addresses before running the addl because it needs to support using a memory address in place of registers. –  Hawken Apr 14 '12 at 20:01
    
@Hawken: You might want to read a bit more about RISC vs. CISC. One would expect, if RISC were significantly better (i.e. faster), that people would be using them more. Yes, RISC is more predictable per instruction. But a program written on a RISC processor will require more instruction bytes than the equivalent program on a CISC processor. And instruction fetch isn't free. –  Jim Mischel Apr 14 '12 at 20:14
    
@hanspassant the main problem of RISC, I hear, was poor adoption; Apple is rumored to have switched due to PowerPC chips producing too much heat for portables, and PowerPC being less developed due to poor adoption. –  Hawken Apr 14 '12 at 21:55

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