In general you should push the current value of
EBP on the stack before you move the value of
EBP is a "callee-save" register on 32-bit platforms, meaning if you are going to modify it in a function, you must save it first.
If you want your function to return the value of the where the stack is pointing (or where it will return after the function call), the best thing to-do would be the following:
void* stack_ptr = NULL;
//on 32-bit systems
//EBP is pointing at top of stack frame
//EBP + 4 is the return instruction address
//EBP + 8 is the value that was in ESP before function call for a function with no arguments
"movl %%ebp, %%eax\n\t"
"addl $8, %%eax\n\t"
: "=r" (stack_ptr)
EAX is now holding the address of the value that the stack was pointing to before the call to
get_stack_addr() was made. If you just returned the value of
ESP in the function, you actually have no idea where you're pointing to, since the compiler often pads the stack in a C/C++ function in order to maintain proper stack alignment. It also often reserves space on the stack for all local variables, which again will throw off the calculation of the stack. By using
EBP, which points at the top of the stack frame, you can accurately calculate on a 32-bit platform, the value of the stack before the function call. Finally we place the return value in
EAX since on most OS application binary interfaces for C/C++,
EAX holds the return value of a function, not
One more thing ... if you are wanting start of the parameters on the stack for the actual function that calls
get_stack_addr(), then change
movl %%ebp, %%eax\n\t to
movl (%%ebp), %%eax)\n\t. That way you're now getting the previous stack-frame base pointer (i.e., the stack frame base pointer of the caller), and by adding a value of +8 to that address, you're getting either the beginning of the parameters stored above the return address, or you're looking at an address pointing into the stack frame for the caller of the current function (i.e., the previous stack frame).