(**************************************************************************) (* *) (* OCaml *) (* *) (* Xavier Leroy, projet Cristal, INRIA Rocquencourt *) (* *) (* Copyright 1996 Institut National de Recherche en Informatique et *) (* en Automatique. *) (* *) (* All rights reserved. This file is distributed under the terms of *) (* the GNU Lesser General Public License version 2.1, with the *) (* special exception on linking described in the file LICENSE. *) (* *) (**************************************************************************) (* Description of the Power PC *) open Misc open Cmm open Reg open Arch open Mach (* Instruction selection *) let word_addressed = false (* Registers available for register allocation *) (* Integer register map: 0 temporary, null register for some operations 1 stack pointer 2 pointer to table of contents 3 - 10 function arguments and results 11 - 12 temporaries 13 pointer to small data area 14 - 28 general purpose, preserved by C 29 trap pointer 30 allocation limit 31 allocation pointer Floating-point register map: 0 temporary 1 - 13 function arguments and results 14 - 31 general purpose, preserved by C *) let int_reg_name = [| "3"; "4"; "5"; "6"; "7"; "8"; "9"; "10"; "14"; "15"; "16"; "17"; "18"; "19"; "20"; "21"; "22"; "23"; "24"; "25"; "26"; "27"; "28" |] let float_reg_name = [| "1"; "2"; "3"; "4"; "5"; "6"; "7"; "8"; "9"; "10"; "11"; "12"; "13"; "14"; "15"; "16"; "17"; "18"; "19"; "20"; "21"; "22"; "23"; "24"; "25"; "26"; "27"; "28"; "29"; "30"; "31" |] let num_register_classes = 2 let register_class r = match r.typ with | Val | Int | Addr -> 0 | Float -> 1 let num_available_registers = [| 23; 31 |] let first_available_register = [| 0; 100 |] let register_name r = if r < 100 then int_reg_name.(r) else float_reg_name.(r - 100) let rotate_registers = true (* Representation of hard registers by pseudo-registers *) let hard_int_reg = let v = Array.make 23 Reg.dummy in for i = 0 to 22 do v.(i) <- Reg.at_location Int (Reg i) done; v let hard_float_reg = let v = Array.make 31 Reg.dummy in for i = 0 to 30 do v.(i) <- Reg.at_location Float (Reg(100 + i)) done; v let all_phys_regs = Array.append hard_int_reg hard_float_reg let phys_reg n = if n < 100 then hard_int_reg.(n) else hard_float_reg.(n - 100) let stack_slot slot ty = Reg.at_location ty (Stack slot) (* Calling conventions *) let calling_conventions first_int last_int first_float last_float make_stack stack_ofs reg_use_stack arg = let loc = Array.make (Array.length arg) [| Reg.dummy |] in let int = ref first_int in let float = ref first_float in let ofs = ref stack_ofs in for i = 0 to Array.length arg - 1 do match arg.(i) with | [| arg |] -> begin match arg.typ with | Val | Int | Addr as ty -> if !int <= last_int then begin loc.(i) <- [| phys_reg !int |]; incr int; if reg_use_stack then ofs := !ofs + size_int end else begin loc.(i) <- [| stack_slot (make_stack !ofs) ty |]; ofs := !ofs + size_int end | Float -> if !float <= last_float then begin loc.(i) <- [| phys_reg !float |]; incr float; (* On 64-bit platforms, passing a float in a float register reserves a normal register as well *) if size_int = 8 then incr int; if reg_use_stack then ofs := !ofs + size_float end else begin ofs := Misc.align !ofs size_float; loc.(i) <- [| stack_slot (make_stack !ofs) Float |]; ofs := !ofs + size_float end end | [| arg1; arg2 |] -> (* Passing of 64-bit quantities to external functions on 32-bit platform. *) assert (size_int = 4); begin match arg1.typ, arg2.typ with | Int, Int -> (* 64-bit quantities split across two registers must either be in a consecutive pair of registers where the lowest numbered is an even-numbered register; or in a stack slot that is 8-byte aligned. *) int := Misc.align !int 2; let pos_least, pos_most = if big_endian then (1, 0) else (0, 1) in if !int <= last_int - 1 then begin let reg_least = phys_reg (!int + pos_least) in let reg_most = phys_reg (!int + pos_most ) in loc.(i) <- [| reg_least; reg_most |]; int := !int + 2 end else begin let size_int64 = 8 in ofs := Misc.align !ofs size_int64; let ofs_least = !ofs + size_int * pos_least in let ofs_most = !ofs + size_int * pos_most in let stack_least = stack_slot (make_stack ofs_least) Int in let stack_most = stack_slot (make_stack ofs_most ) Int in loc.(i) <- [| stack_least; stack_most |]; ofs := !ofs + size_int64 end | _, _ -> let f = function Int -> "I" | Addr -> "A" | Val -> "V" | Float -> "F" in fatal_error (Printf.sprintf "Proc.calling_conventions: bad register \ type(s) for multi-register argument: %s, %s" (f arg1.typ) (f arg2.typ)) end | _ -> fatal_error "Proc.calling_conventions: bad number of registers for \ multi-register argument" done; (loc, Misc.align !ofs 16) (* Keep stack 16-aligned. *) let incoming ofs = Incoming ofs let outgoing ofs = Outgoing ofs let not_supported ofs = fatal_error "Proc.loc_results: cannot call" let single_regs arg = Array.map (fun arg -> [| arg |]) arg let ensure_single_regs res = Array.map (function | [| res |] -> res | _ -> failwith "Proc.ensure_single_regs") res let max_arguments_for_tailcalls = 8 let loc_arguments arg = let (loc, ofs) = calling_conventions 0 7 100 112 outgoing 0 false (single_regs arg) in (ensure_single_regs loc, ofs) let loc_parameters arg = let (loc, ofs) = calling_conventions 0 7 100 112 incoming 0 false (single_regs arg) in ensure_single_regs loc let loc_results res = let (loc, ofs) = calling_conventions 0 7 100 112 not_supported 0 false (single_regs res) in ensure_single_regs loc (* C calling conventions for ELF32: use GPR 3-10 and FPR 1-8 just like ML calling conventions. Using a float register does not affect the int registers. Always reserve 8 bytes at bottom of stack, plus whatever is needed to hold the overflow arguments. C calling conventions for ELF64v1: Use GPR 3-10 for the first integer arguments. Use FPR 1-13 for the first float arguments. Always reserve stack space for all arguments, even when passed in registers. Always reserve at least 8 words (64 bytes) for the arguments. Always reserve 48 bytes at bottom of stack, plus whatever is needed to hold the arguments. The reserved 48 bytes are automatically added in emit.mlp and need not appear here. C calling conventions for ELF64v2: Use GPR 3-10 for the first integer arguments. Use FPR 1-13 for the first float arguments. If all arguments fit in registers, don't reserve stack space. Otherwise, reserve stack space for all arguments. Always reserve 32 bytes at bottom of stack, plus whatever is needed to hold the arguments. The reserved 32 bytes are automatically added in emit.mlp and need not appear here. *) let loc_external_arguments = match abi with | ELF32 -> calling_conventions 0 7 100 107 outgoing 8 false | ELF64v1 -> fun args -> let (loc, ofs) = calling_conventions 0 7 100 112 outgoing 0 true args in (loc, max ofs 64) | ELF64v2 -> fun args -> let (loc, ofs) = calling_conventions 0 7 100 112 outgoing 0 true args in if Array.fold_left (fun stk r -> assert (Array.length r = 1); match r.(0).loc with | Stack _ -> true | _ -> stk) false loc then (loc, ofs) else (loc, 0) let extcall_use_push = false (* Results are in GPR 3 and FPR 1 *) let loc_external_results res = let (loc, ofs) = calling_conventions 0 1 100 100 not_supported 0 false (single_regs res) in ensure_single_regs loc (* Exceptions are in GPR 3 *) let loc_exn_bucket = phys_reg 0 (* Volatile registers: none *) let regs_are_volatile rs = false (* Registers destroyed by operations *) let destroyed_at_c_call = Array.of_list(List.map phys_reg [0; 1; 2; 3; 4; 5; 6; 7; 100; 101; 102; 103; 104; 105; 106; 107; 108; 109; 110; 111; 112]) let destroyed_at_oper = function Iop(Icall_ind | Icall_imm _ | Iextcall(_, true)) -> all_phys_regs | Iop(Iextcall(_, false)) -> destroyed_at_c_call | _ -> [||] let destroyed_at_raise = all_phys_regs (* Maximal register pressure *) let safe_register_pressure = function Iextcall(_, _) -> 15 | _ -> 23 let max_register_pressure = function Iextcall(_, _) -> [| 15; 18 |] | _ -> [| 23; 30 |] (* Pure operations (without any side effect besides updating their result registers). *) let op_is_pure = function | Icall_ind | Icall_imm _ | Itailcall_ind | Itailcall_imm _ | Iextcall _ | Istackoffset _ | Istore _ | Ialloc _ | Iintop(Icheckbound) | Iintop_imm(Icheckbound, _) -> false | Ispecific(Imultaddf | Imultsubf) -> true | Ispecific _ -> false | _ -> true (* Layout of the stack *) let num_stack_slots = [| 0; 0 |] let contains_calls = ref false (* Calling the assembler *) let assemble_file infile outfile = Ccomp.command (Config.asm ^ " -o " ^ Filename.quote outfile ^ " " ^ Filename.quote infile) let init () = ()