(**************************************************************************) (* *) (* 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. *) (* *) (**************************************************************************) open Local_store let lowest_scope = 0 let highest_scope = 100_000_000 (* assumed to fit in 27 bits, see Types.scope_field *) type t = | Local of { name: string; stamp: int } | Scoped of { name: string; stamp: int; scope: int } | Global of string | Predef of { name: string; stamp: int } (* the stamp is here only for fast comparison, but the name of predefined identifiers is always unique. *) (* A stamp of 0 denotes a persistent identifier *) let currentstamp = s_ref 0 let predefstamp = s_ref 0 let create_scoped ~scope s = incr currentstamp; Scoped { name = s; stamp = !currentstamp; scope } let create_local s = incr currentstamp; Local { name = s; stamp = !currentstamp } let create_predef s = incr predefstamp; Predef { name = s; stamp = !predefstamp } let create_persistent s = Global s let name = function | Local { name; _ } | Scoped { name; _ } | Global name | Predef { name; _ } -> name let rename = function | Local { name; stamp = _ } | Scoped { name; stamp = _; scope = _ } -> incr currentstamp; Local { name; stamp = !currentstamp } | id -> Misc.fatal_errorf "Ident.rename %s" (name id) let unique_name = function | Local { name; stamp } | Scoped { name; stamp } -> name ^ "_" ^ Int.to_string stamp | Global name -> (* we're adding a fake stamp, because someone could have named his unit [Foo_123] and since we're using unique_name to produce symbol names, we might clash with an ident [Local { "Foo"; 123 }]. *) name ^ "_0" | Predef { name; _ } -> (* we know that none of the predef names (currently) finishes in "_", and that their name is unique. *) name let unique_toplevel_name = function | Local { name; stamp } | Scoped { name; stamp } -> name ^ "/" ^ Int.to_string stamp | Global name | Predef { name; _ } -> name let persistent = function | Global _ -> true | _ -> false let equal i1 i2 = match i1, i2 with | Local { name = name1; _ }, Local { name = name2; _ } | Scoped { name = name1; _ }, Scoped { name = name2; _ } | Global name1, Global name2 -> name1 = name2 | Predef { stamp = s1; _ }, Predef { stamp = s2 } -> (* if they don't have the same stamp, they don't have the same name *) s1 = s2 | _ -> false let same i1 i2 = match i1, i2 with | Local { stamp = s1; _ }, Local { stamp = s2; _ } | Scoped { stamp = s1; _ }, Scoped { stamp = s2; _ } | Predef { stamp = s1; _ }, Predef { stamp = s2 } -> s1 = s2 | Global name1, Global name2 -> name1 = name2 | _ -> false let stamp = function | Local { stamp; _ } | Scoped { stamp; _ } -> stamp | _ -> 0 let compare_stamp id1 id2 = compare (stamp id1) (stamp id2) let scope = function | Scoped { scope; _ } -> scope | Local _ -> highest_scope | Global _ | Predef _ -> lowest_scope let reinit_level = ref (-1) let reinit () = if !reinit_level < 0 then reinit_level := !currentstamp else currentstamp := !reinit_level let global = function | Local _ | Scoped _ -> false | Global _ | Predef _ -> true let is_predef = function | Predef _ -> true | _ -> false let canonical_stamps = s_table Hashtbl.create 0 let next_canonical_stamp = s_table Hashtbl.create 0 let canonicalize name stamp = try Hashtbl.find !canonical_stamps (name, stamp) with Not_found -> let canonical_stamp = try Hashtbl.find !next_canonical_stamp name with Not_found -> 0 in Hashtbl.replace !next_canonical_stamp name (canonical_stamp + 1); Hashtbl.add !canonical_stamps (name, stamp) canonical_stamp; canonical_stamp let pp_stamped ppf (name, stamp) = let open Format_doc in if not !Clflags.unique_ids then fprintf ppf "%s" name else begin let stamp = if not !Clflags.canonical_ids then stamp else canonicalize name stamp in fprintf ppf "%s/%i" name stamp end let print ~with_scope ppf = let open Format_doc in function | Global name -> fprintf ppf "%s!" name | Predef { name; stamp } -> fprintf ppf "%a!" pp_stamped (name, stamp) | Local { name; stamp } -> fprintf ppf "%a" pp_stamped (name, stamp) | Scoped { name; stamp; scope } -> fprintf ppf "%a%s" pp_stamped (name, stamp) (if with_scope then asprintf "[%i]" scope else "") let print_with_scope ppf id = print ~with_scope:true ppf id let doc_print ppf id = print ~with_scope:false ppf id let print ppf id = Format_doc.compat doc_print ppf id (* For the documentation of ['a Ident.tbl], see ident.mli. The implementation is a copy-paste specialization of a balanced-tree implementation similar to Map. ['a tbl] is a slightly more compact version of [(Ident.t * 'a) list Map.Make(String)] This implementation comes from Caml Light where duplication was unavoidable in absence of functors. It works well enough, and so far we have not had strong incentives to do the deduplication work (implementation, tests, benchmarks, etc.). *) type 'a tbl = Empty | Node of 'a tbl * 'a data * 'a tbl * int and 'a data = { ident: t; data: 'a; previous: 'a data option } let empty = Empty (* Inline expansion of height for better speed * let height = function * Empty -> 0 * | Node(_,_,_,h) -> h *) let mknode l d r = let hl = match l with Empty -> 0 | Node(_,_,_,h) -> h and hr = match r with Empty -> 0 | Node(_,_,_,h) -> h in Node(l, d, r, (if hl >= hr then hl + 1 else hr + 1)) let balance l d r = let hl = match l with Empty -> 0 | Node(_,_,_,h) -> h and hr = match r with Empty -> 0 | Node(_,_,_,h) -> h in if hl > hr + 1 then match l with | Node (ll, ld, lr, _) when (match ll with Empty -> 0 | Node(_,_,_,h) -> h) >= (match lr with Empty -> 0 | Node(_,_,_,h) -> h) -> mknode ll ld (mknode lr d r) | Node (ll, ld, Node(lrl, lrd, lrr, _), _) -> mknode (mknode ll ld lrl) lrd (mknode lrr d r) | _ -> assert false else if hr > hl + 1 then match r with | Node (rl, rd, rr, _) when (match rr with Empty -> 0 | Node(_,_,_,h) -> h) >= (match rl with Empty -> 0 | Node(_,_,_,h) -> h) -> mknode (mknode l d rl) rd rr | Node (Node (rll, rld, rlr, _), rd, rr, _) -> mknode (mknode l d rll) rld (mknode rlr rd rr) | _ -> assert false else mknode l d r let rec add id data = function Empty -> Node(Empty, {ident = id; data = data; previous = None}, Empty, 1) | Node(l, k, r, h) -> let c = String.compare (name id) (name k.ident) in if c = 0 then Node(l, {ident = id; data = data; previous = Some k}, r, h) else if c < 0 then balance (add id data l) k r else balance l k (add id data r) let rec min_binding = function Empty -> raise Not_found | Node (Empty, d, _, _) -> d | Node (l, _, _, _) -> min_binding l let rec remove_min_binding = function Empty -> invalid_arg "Map.remove_min_elt" | Node (Empty, _, r, _) -> r | Node (l, d, r, _) -> balance (remove_min_binding l) d r let merge t1 t2 = match (t1, t2) with (Empty, t) -> t | (t, Empty) -> t | (_, _) -> let d = min_binding t2 in balance t1 d (remove_min_binding t2) let rec remove id = function Empty -> Empty | (Node (l, k, r, h) as m) -> let c = String.compare (name id) (name k.ident) in if c = 0 then match k.previous with | None -> merge l r | Some k -> Node (l, k, r, h) else if c < 0 then let ll = remove id l in if l == ll then m else balance ll k r else let rr = remove id r in if r == rr then m else balance l k rr let rec find_previous id = function None -> raise Not_found | Some k -> if same id k.ident then k.data else find_previous id k.previous let rec find_same id = function Empty -> raise Not_found | Node(l, k, r, _) -> let c = String.compare (name id) (name k.ident) in if c = 0 then if same id k.ident then k.data else find_previous id k.previous else find_same id (if c < 0 then l else r) let rec find_name n = function Empty -> raise Not_found | Node(l, k, r, _) -> let c = String.compare n (name k.ident) in if c = 0 then k.ident, k.data else find_name n (if c < 0 then l else r) let rec get_all = function | None -> [] | Some k -> (k.ident, k.data) :: get_all k.previous let rec find_all n = function Empty -> [] | Node(l, k, r, _) -> let c = String.compare n (name k.ident) in if c = 0 then (k.ident, k.data) :: get_all k.previous else find_all n (if c < 0 then l else r) let get_all_seq k () = Seq.unfold (Option.map (fun k -> (k.ident, k.data), k.previous)) k () let rec find_all_seq n tbl () = match tbl with | Empty -> Seq.Nil | Node(l, k, r, _) -> let c = String.compare n (name k.ident) in if c = 0 then Seq.Cons((k.ident, k.data), get_all_seq k.previous) else find_all_seq n (if c < 0 then l else r) () let rec fold_aux f stack accu = function Empty -> begin match stack with [] -> accu | a :: l -> fold_aux f l accu a end | Node(l, k, r, _) -> fold_aux f (l :: stack) (f k accu) r let fold_name f tbl accu = fold_aux (fun k -> f k.ident k.data) [] accu tbl let rec fold_data f d accu = match d with None -> accu | Some k -> f k.ident k.data (fold_data f k.previous accu) let fold_all f tbl accu = fold_aux (fun k -> fold_data f (Some k)) [] accu tbl (* let keys tbl = fold_name (fun k _ accu -> k::accu) tbl [] *) let rec iter f = function Empty -> () | Node(l, k, r, _) -> iter f l; f k.ident k.data; iter f r (* Idents for sharing keys *) (* They should be 'totally fresh' -> neg numbers *) let key_name = "" let make_key_generator () = let c = ref 1 in function | Local _ | Scoped _ -> let stamp = !c in decr c ; Local { name = key_name; stamp = stamp } | global_id -> Misc.fatal_errorf "Ident.make_key_generator () %s" (name global_id) let compare x y = match x, y with | Local x, Local y -> let c = x.stamp - y.stamp in if c <> 0 then c else compare x.name y.name | Local _, _ -> 1 | _, Local _ -> (-1) | Scoped x, Scoped y -> let c = x.stamp - y.stamp in if c <> 0 then c else compare x.name y.name | Scoped _, _ -> 1 | _, Scoped _ -> (-1) | Global x, Global y -> compare x y | Global _, _ -> 1 | _, Global _ -> (-1) | Predef { stamp = s1; _ }, Predef { stamp = s2; _ } -> compare s1 s2 let output oc id = output_string oc (unique_name id) let hash i = (Char.code (name i).[0]) lxor (stamp i) let original_equal = equal include Identifiable.Make (struct type nonrec t = t let compare = compare let output = output let print = print let hash = hash let equal = same end) let equal = original_equal