I've been trying to find the OCaml calling convention so that I can manually interpret the stack traces that gdb can't parse. Unfortunately, it seems like nothing has ever been written down in English except for general observations. E.g., people will comment on blogs that OCaml passes many arguments in registers. (If there is English documentation somewhere, a link would be much appreciated.)
So I've been trying to puzzle it out from the ocamlopt source. Could anyone confirm the accuracy of these guesses?
And, if I'm right about the first ten arguments being passed in registers, is it just not generally possible to recover the arguments to a function call? In C, the arguments would still be pushed onto the stack somewhere, if only I walk back up to the correct frame. In OCaml, it would seem that callees are free to destroy their callers' arguments.
Register allocation (from
For calling into OCaml functions,
- The first 10 integer and pointer arguments are passed in the registers rax, rbx, rdi, rsi, rdx, rcx, r8, r9, r10 and r11
- The first 10 floating-point arguments are passed in the registers xmm0 - xmm9
- Additional arguments are pushed onto the stack (leftmost-first-in?), floats and ints and pointers intermixed
- The trap pointer (see Exceptions below) is passed in r14
- The allocation pointer (presumably for the minor heap as described in this blog post) is passed in r15
- The return value is passed back in rax if it is an integer or pointer, and in xmm0 if it is a float
- All registers are caller-save?
For calling into C functions, the standard amd64 C convention is used:
- The first six integer and pointer arguments are passed in rdi, rsi, rdx, rcs, r8, and r9
- The first eight float arguments are passed in xmm0 - xmm7
- Additional arguments are pushed onto the stack
- The return value is passed back in rax or xmm0
- The registers rbx, rbp, and r12 - r15 are callee-save
Return address (from
The return address is the first pointer pushed into the call frame, in accordance with amd64 C convention. (I'm guessing the
ret instruction assumes this layout.)
try (...body...) with (...handler...); (...rest...) gets linearized like this:
Lsetuptrap .body (...handler...) Lbranch .join Llabel .body Lpushtrap (...body...) Lpoptrap Llabel .join (...rest...)
and then emitted as assembly like this (destinations on the right):
call .body (...handler...) jmp .join .body: pushq %r14 movq %rsp, %r14 (...body...) popq %r14 addq %rsp, 8 .join: (...rest...)
Somewhere in the body, there's a linearized opcode
Lraise which gets emitted as this exact assembly:
movq %r14, %rsp popq %r14 ret
Which is really neat! Instead of this setjmp/longjmp business, we create a dummy frame whose return address is the exception handler and whose only local is the previous such dummy frame. The
/asmcomp/amd64/proc.ml has a comment calling $r14 the "trap pointer" so I'll call this dummy frame the trap frame. When we want to raise an exception, we set the stack pointer to the most recent trap frame, set the trap pointer to the trap frame before that, and then "return" into the exception handler. And I bet if the exception handler can't handle this exception, it just reraises it.
The exception is in %eax.