204 lines
6.6 KiB
OCaml
204 lines
6.6 KiB
OCaml
(***********************************************************************)
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(* *)
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(* Objective Caml *)
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(* *)
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(* Xavier Leroy, projet Cristal, INRIA Rocquencourt *)
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(* *)
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(* Copyright 1996 Institut National de Recherche en Informatique et *)
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(* Automatique. Distributed only by permission. *)
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(* *)
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(***********************************************************************)
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(* $Id$ *)
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(* Renaming of registers at reload points to split live ranges. *)
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open Reg
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open Mach
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(* Substitutions are represented by register maps *)
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type subst = Reg.t Reg.Map.t
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let subst_reg r sub =
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try
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Reg.Map.find r sub
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with Not_found ->
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r
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let subst_regs rv sub =
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match sub with
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None -> rv
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| Some s ->
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let n = Array.length rv in
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let nv = Array.create n Reg.dummy in
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for i = 0 to n-1 do nv.(i) <- subst_reg rv.(i) s done;
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nv
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(* We maintain equivalence classes of registers using a standard
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union-find algorithm *)
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let equiv_classes = ref (Reg.Map.empty : Reg.t Reg.Map.t)
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let rec repres_reg r =
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try
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repres_reg(Reg.Map.find r !equiv_classes)
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with Not_found ->
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r
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let repres_regs rv =
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let n = Array.length rv in
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for i = 0 to n-1 do rv.(i) <- repres_reg rv.(i) done
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(* Identify two registers.
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The second register is chosen as canonical representative. *)
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let identify r1 r2 =
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let repres1 = repres_reg r1 in
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let repres2 = repres_reg r2 in
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if repres1.stamp = repres2.stamp then () else begin
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equiv_classes := Reg.Map.add repres1 repres2 !equiv_classes
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end
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(* Identify the image of a register by two substitutions.
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Be careful to use the original register as canonical representative
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in case it does not belong to the domain of one of the substitutions. *)
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let identify_sub sub1 sub2 reg =
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try
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let r1 = Reg.Map.find reg sub1 in
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try
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let r2 = Reg.Map.find reg sub2 in
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identify r1 r2
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with Not_found ->
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identify r1 reg
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with Not_found ->
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try
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let r2 = Reg.Map.find reg sub2 in
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identify r2 reg
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with Not_found ->
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()
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(* Identify registers so that the two substitutions agree on the
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registers live before the given instruction. *)
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let merge_substs sub1 sub2 i =
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match (sub1, sub2) with
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(None, None) -> None
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| (Some s1, None) -> sub1
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| (None, Some s2) -> sub2
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| (Some s1, Some s2) ->
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Reg.Set.iter (identify_sub s1 s2) (Reg.add_set_array i.live i.arg);
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sub1
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(* Same, for N substitutions *)
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let merge_subst_array subv instr =
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let rec find_one_subst i =
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if i >= Array.length subv then None else begin
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match subv.(i) with
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None -> find_one_subst (i+1)
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| Some si as sub ->
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for j = i+1 to Array.length subv - 1 do
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match subv.(j) with
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None -> ()
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| Some sj ->
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Reg.Set.iter (identify_sub si sj)
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(Reg.add_set_array instr.live instr.arg)
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done;
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sub
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end in
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find_one_subst 0
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(* First pass: rename registers at reload points *)
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let exit_subst = ref (None: subst option)
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let rec rename i sub =
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match i.desc with
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Iend ->
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(i, sub)
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| Ireturn | Iop(Itailcall_ind) | Iop(Itailcall_imm _) ->
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(instr_cons i.desc (subst_regs i.arg sub) [||] i.next,
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None)
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| Iop Ireload when i.res.(0).loc = Unknown ->
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begin match sub with
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None -> rename i.next sub
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| Some s ->
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let oldr = i.res.(0) in
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let newr = Reg.clone i.res.(0) in
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let (new_next, sub_next) =
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rename i.next (Some(Reg.Map.add oldr newr s)) in
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(instr_cons i.desc i.arg [|newr|] new_next,
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sub_next)
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end
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| Iop _ ->
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let (new_next, sub_next) = rename i.next sub in
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(instr_cons i.desc (subst_regs i.arg sub) (subst_regs i.res sub)
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new_next,
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sub_next)
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| Iifthenelse(tst, ifso, ifnot) ->
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let (new_ifso, sub_ifso) = rename ifso sub in
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let (new_ifnot, sub_ifnot) = rename ifnot sub in
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let (new_next, sub_next) =
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rename i.next (merge_substs sub_ifso sub_ifnot i.next) in
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(instr_cons (Iifthenelse(tst, new_ifso, new_ifnot))
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(subst_regs i.arg sub) [||] new_next,
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sub_next)
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| Iswitch(index, cases) ->
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let new_sub_cases = Array.map (fun c -> rename c sub) cases in
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let sub_merge =
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merge_subst_array (Array.map (fun (n, s) -> s) new_sub_cases) i.next in
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let (new_next, sub_next) = rename i.next sub_merge in
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(instr_cons (Iswitch(index, Array.map (fun (n, s) -> n) new_sub_cases))
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(subst_regs i.arg sub) [||] new_next,
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sub_next)
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| Iloop(body) ->
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let (new_body, sub_body) = rename body sub in
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let (new_next, sub_next) = rename i.next (merge_substs sub sub_body i) in
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(instr_cons (Iloop(new_body)) [||] [||] new_next,
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sub_next)
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| Icatch(body, handler) ->
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let saved_exit_subst = !exit_subst in
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exit_subst := None;
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let (new_body, sub_body) = rename body sub in
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let sub_entry_handler = !exit_subst in
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exit_subst := saved_exit_subst;
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let (new_handler, sub_handler) = rename handler sub_entry_handler in
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let (new_next, sub_next) =
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rename i.next (merge_substs sub_body sub_handler i.next) in
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(instr_cons (Icatch(new_body, new_handler)) [||] [||] new_next,
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sub_next)
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| Iexit ->
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exit_subst := merge_substs !exit_subst sub i;
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(i, None)
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| Itrywith(body, handler) ->
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let (new_body, sub_body) = rename body sub in
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let (new_handler, sub_handler) = rename handler sub in
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let (new_next, sub_next) =
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rename i.next (merge_substs sub_body sub_handler i.next) in
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(instr_cons (Itrywith(new_body, new_handler)) [||] [||] new_next,
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sub_next)
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| Iraise ->
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(instr_cons Iraise (subst_regs i.arg sub) [||] i.next,
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None)
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(* Second pass: replace registers by their final representatives *)
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let set_repres i =
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instr_iter (fun i -> repres_regs i.arg; repres_regs i.res) i
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(* Entry point *)
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let fundecl f =
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equiv_classes := Reg.Map.empty;
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let new_args = Array.copy f.fun_args in
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let (new_body, sub_body) = rename f.fun_body (Some Reg.Map.empty) in
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repres_regs new_args;
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set_repres new_body;
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equiv_classes := Reg.Map.empty;
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{ fun_name = f.fun_name;
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fun_args = new_args;
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fun_body = new_body;
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fun_fast = f.fun_fast }
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