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Why do we push ebp as the first action in the Callee of an Assembly function?

I understand that then we use mov edi, [ebp+8] to get the passed in variables, but our esp is already pointing to return address of the Caller function. We can easily access the passed in variables with mov edi, [esp+4] or if we pushed the Callee registers, then mov edi, [esp+16].

So, why have that extra register in the cpu (the ebp) which you later have to manage in functions? i.e.

push ebp
mov ebp, esp

...

mov esp, ebp
pop ebp
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    You don't have to. Compilers will often omit the frame pointer nowadays, if the function doesn't use variable length arrays or alloca().
    – EOF
    Mar 16, 2016 at 20:29
  • Why did you put "CALLEE" in all-caps in the title? Are you wondering why the caller doesn't make stack frames as part of the calling convention? It doesn't sound that way, based on the text other than the title. Mar 17, 2016 at 2:29

2 Answers 2

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It is establishing a new stack frame within the callee, while preserving the stack frame of the caller. A stack frame allows consistent access to passed parameters and local variables using fixed offsets relative to EBP anywhere in the function, while ESP is free to continue being modified as needed while the function is running. ESP is a moving target, so accessing parameters and variables using dynamic offsets relative to ESP can be tricky, if not impossible, depending on how the function uses the stack. Creating a stack frame is generally safer, at the cost of using a few bytes of stack space to preserve the pointer to the caller's stack frame.

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    The cost of keeping a frame pointer is not in the single push [r/e]bp, it's giving up free use of a caller-saved register on a register-starved (or very register starved, for 32-bit) architecture.
    – EOF
    Mar 16, 2016 at 20:40
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    @ArturGrigio the compiler can't always know at compile-time how much data has been pushed on the stack at run-time (for example, allocating stack space dynamically, which is non-standard but is supported by some compilers, such as for variable-length stack-based arrays and alloca()), so using offsets relative to ESP is not always feisible. Mar 16, 2016 at 20:46
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    @RemyLebeau: Have you ever looked at the assembly generated by a modern compiler (like gcc or clang) on high optimization settings (including -fomit-frame-pointer)?
    – EOF
    Mar 16, 2016 at 20:46
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    @RemyLebeau The point is, [r/e]bp is a perfectly normal general-purpose register.
    – EOF
    Mar 16, 2016 at 20:53
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    @EOF: the enter and leave instructions provide ISA support for that convention, but they're not worth using unless optimizing for code-size instead of speed. (Using stack frames can save code size, even though it costs insns to set up and tear down, because addressing modes using [e/rsp (+disp8/disp32)] have to use a SIB byte even though there's no index register. The encoding that would mean [rsp] instead means "there's a SIB byte".) So this convention has permeated its way into the ISA to some degree. Fortunately there's nothing really enforcing it, though. Mar 16, 2016 at 22:35
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The given answer from Remy is perfect, however here is one small addition, a thing you might also see right after

mov ebp, esp

it's very possible to see instruction such:

sub esp, 20h   ; creating space for local variables with size 20h
sub esp, CCh   ; creating space for local variables with size CCh

along side with an AND call sometimes (like and esp, 0FFFFFFF0h). This is also part of the dealing with the stack and it's done so the stack can be align and be divisible by 16. Of course all this depends on the used calling convention (cdecl, fastcall, stdcall etc.)

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