ocaml/asmcomp/reg.ml

198 lines
5.3 KiB
OCaml

(***********************************************************************)
(* *)
(* 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 Q Public License version 1.0. *)
(* *)
(***********************************************************************)
open Cmm
module Raw_name = struct
type t =
| Anon
| R
| Ident of Ident.t
let create_from_ident ident = Ident ident
let to_string t =
match t with
| Anon -> None
| R -> Some "R"
| Ident ident ->
let name = Ident.name ident in
if String.length name <= 0 then None else Some name
end
type t =
{ mutable raw_name: Raw_name.t;
stamp: int;
mutable typ: Cmm.machtype_component;
mutable loc: location;
mutable spill: bool;
mutable part: int option;
mutable interf: t list;
mutable prefer: (t * int) list;
mutable degree: int;
mutable spill_cost: int;
mutable visited: bool }
and location =
Unknown
| Reg of int
| Stack of stack_location
and stack_location =
Local of int
| Incoming of int
| Outgoing of int
type reg = t
let dummy =
{ raw_name = Raw_name.Anon; stamp = 0; typ = Int; loc = Unknown;
spill = false; interf = []; prefer = []; degree = 0; spill_cost = 0;
visited = false; part = None;
}
let currstamp = ref 0
let reg_list = ref([] : t list)
let create ty =
let r = { raw_name = Raw_name.Anon; stamp = !currstamp; typ = ty;
loc = Unknown; spill = false; interf = []; prefer = []; degree = 0;
spill_cost = 0; visited = false; part = None; } in
reg_list := r :: !reg_list;
incr currstamp;
r
let createv tyv =
let n = Array.length tyv in
let rv = Array.make n dummy in
for i = 0 to n-1 do rv.(i) <- create tyv.(i) done;
rv
let createv_like rv =
let n = Array.length rv in
let rv' = Array.make n dummy in
for i = 0 to n-1 do rv'.(i) <- create rv.(i).typ done;
rv'
let clone r =
let nr = create r.typ in
nr.raw_name <- r.raw_name;
nr
let at_location ty loc =
let r = { raw_name = Raw_name.R; stamp = !currstamp; typ = ty; loc;
spill = false; interf = []; prefer = []; degree = 0;
spill_cost = 0; visited = false; part = None; } in
incr currstamp;
r
let anonymous t =
match Raw_name.to_string t.raw_name with
| None -> true
| Some _raw_name -> false
let name t =
match Raw_name.to_string t.raw_name with
| None -> ""
| Some raw_name ->
let with_spilled =
if t.spill then
"spilled-" ^ raw_name
else
raw_name
in
match t.part with
| None -> with_spilled
| Some part -> with_spilled ^ "#" ^ string_of_int part
let first_virtual_reg_stamp = ref (-1)
let reset() =
(* When reset() is called for the first time, the current stamp reflects
all hard pseudo-registers that have been allocated by Proc, so
remember it and use it as the base stamp for allocating
soft pseudo-registers *)
if !first_virtual_reg_stamp = -1 then first_virtual_reg_stamp := !currstamp;
currstamp := !first_virtual_reg_stamp;
reg_list := []
let all_registers() = !reg_list
let num_registers() = !currstamp
let reinit_reg r =
r.loc <- Unknown;
r.interf <- [];
r.prefer <- [];
r.degree <- 0;
(* Preserve the very high spill costs introduced by the reloading pass *)
if r.spill_cost >= 100000
then r.spill_cost <- 100000
else r.spill_cost <- 0
let reinit() =
List.iter reinit_reg !reg_list
module RegOrder =
struct
type t = reg
let compare r1 r2 = r1.stamp - r2.stamp
end
module Set = Set.Make(RegOrder)
module Map = Map.Make(RegOrder)
let add_set_array s v =
match Array.length v with
0 -> s
| 1 -> Set.add v.(0) s
| n -> let rec add_all i =
if i >= n then s else Set.add v.(i) (add_all(i+1))
in add_all 0
let diff_set_array s v =
match Array.length v with
0 -> s
| 1 -> Set.remove v.(0) s
| n -> let rec remove_all i =
if i >= n then s else Set.remove v.(i) (remove_all(i+1))
in remove_all 0
let inter_set_array s v =
match Array.length v with
0 -> Set.empty
| 1 -> if Set.mem v.(0) s
then Set.add v.(0) Set.empty
else Set.empty
| n -> let rec inter_all i =
if i >= n then Set.empty
else if Set.mem v.(i) s then Set.add v.(i) (inter_all(i+1))
else inter_all(i+1)
in inter_all 0
let disjoint_set_array s v =
match Array.length v with
0 -> true
| 1 -> not (Set.mem v.(0) s)
| n -> let rec disjoint_all i =
if i >= n then true
else if Set.mem v.(i) s then false
else disjoint_all (i+1)
in disjoint_all 0
let set_of_array v =
match Array.length v with
0 -> Set.empty
| 1 -> Set.add v.(0) Set.empty
| n -> let rec add_all i =
if i >= n then Set.empty else Set.add v.(i) (add_all(i+1))
in add_all 0