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|
(************************************************************************)
(* * The Coq Proof Assistant / The Coq Development Team *)
(* v * INRIA, CNRS and contributors - Copyright 1999-2018 *)
(* <O___,, * (see CREDITS file for the list of authors) *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(* * (see LICENSE file for the text of the license) *)
(************************************************************************)
open Pp
open CErrors
open Util
open Names
(**********************************************)
let pr_dirpath sl = DirPath.print sl
(*s Operations on dirpaths *)
let split_dirpath d = match DirPath.repr d with
| id :: l -> DirPath.make l, id
| _ -> failwith "split_dirpath"
let pop_dirpath p = match DirPath.repr p with
| _::l -> DirPath.make l
| [] -> failwith "pop_dirpath"
(* Pop the last n module idents *)
let pop_dirpath_n n dir = DirPath.make (List.skipn n (DirPath.repr dir))
let is_dirpath_prefix_of d1 d2 =
List.prefix_of Id.equal
(List.rev (DirPath.repr d1)) (List.rev (DirPath.repr d2))
let is_dirpath_suffix_of dir1 dir2 =
let dir1 = DirPath.repr dir1 in
let dir2 = DirPath.repr dir2 in
List.prefix_of Id.equal dir1 dir2
let chop_dirpath n d =
let d1,d2 = List.chop n (List.rev (DirPath.repr d)) in
DirPath.make (List.rev d1), DirPath.make (List.rev d2)
let drop_dirpath_prefix d1 d2 =
let d =
List.drop_prefix Id.equal
(List.rev (DirPath.repr d1)) (List.rev (DirPath.repr d2))
in
DirPath.make (List.rev d)
let append_dirpath d1 d2 = DirPath.make (DirPath.repr d2 @ DirPath.repr d1)
let add_dirpath_prefix id d = DirPath.make (DirPath.repr d @ [id])
let add_dirpath_suffix p id = DirPath.make (id :: DirPath.repr p)
(* parsing *)
let parse_dir s =
let len = String.length s in
let rec decoupe_dirs dirs n =
if Int.equal n len && n > 0 then user_err Pp.(str @@ s ^ " is an invalid path.");
if n >= len then dirs else
let pos =
try
String.index_from s n '.'
with Not_found -> len
in
if Int.equal pos n then user_err Pp.(str @@ s ^ " is an invalid path.");
let dir = String.sub s n (pos-n) in
decoupe_dirs ((Id.of_string dir)::dirs) (pos+1)
in
decoupe_dirs [] 0
let dirpath_of_string s =
let path = match s with
| "" -> []
| _ -> parse_dir s
in
DirPath.make path
let string_of_dirpath = Names.DirPath.to_string
module Dirset = Set.Make(DirPath)
module Dirmap = Map.Make(DirPath)
(*s Section paths are absolute names *)
type full_path = {
dirpath : DirPath.t ;
basename : Id.t }
let dirpath sp = sp.dirpath
let basename sp = sp.basename
let make_path pa id = { dirpath = pa; basename = id }
let repr_path { dirpath = pa; basename = id } = (pa,id)
let eq_full_path p1 p2 =
Id.equal p1.basename p2.basename &&
DirPath.equal p1.dirpath p2.dirpath
(* parsing and printing of section paths *)
let string_of_path sp =
let (sl,id) = repr_path sp in
match DirPath.repr sl with
| [] -> Id.to_string id
| _ -> (DirPath.to_string sl) ^ "." ^ (Id.to_string id)
let sp_ord sp1 sp2 =
let (p1,id1) = repr_path sp1
and (p2,id2) = repr_path sp2 in
let p_bit = DirPath.compare p1 p2 in
if Int.equal p_bit 0 then Id.compare id1 id2 else p_bit
module SpOrdered =
struct
type t = full_path
let compare = sp_ord
end
module Spmap = Map.Make(SpOrdered)
let path_of_string s =
try
let dir, id = split_dirpath (dirpath_of_string s) in
make_path dir id
with
| Invalid_argument _ -> invalid_arg "path_of_string"
let pr_path sp = str (string_of_path sp)
let restrict_path n sp =
let dir, s = repr_path sp in
let dir' = List.firstn n (DirPath.repr dir) in
make_path (DirPath.make dir') s
(*s qualified names *)
type qualid = full_path
let make_qualid = make_path
let repr_qualid = repr_path
let qualid_eq = eq_full_path
let string_of_qualid = string_of_path
let pr_qualid = pr_path
let qualid_of_string = path_of_string
let qualid_of_path sp = sp
let qualid_of_ident id = make_qualid DirPath.empty id
let qualid_of_dirpath dir =
let (l,a) = split_dirpath dir in
make_qualid l a
type object_name = full_path * KerName.t
type object_prefix = {
obj_dir : DirPath.t;
obj_mp : ModPath.t;
obj_sec : DirPath.t;
}
(* let make_oname (dirpath,(mp,dir)) id = *)
let make_oname { obj_dir; obj_mp; obj_sec } id =
make_path obj_dir id, KerName.make obj_mp obj_sec (Label.of_id id)
(* to this type are mapped DirPath.t's in the nametab *)
type global_dir_reference =
| DirOpenModule of object_prefix
| DirOpenModtype of object_prefix
| DirOpenSection of object_prefix
| DirModule of object_prefix
| DirClosedSection of DirPath.t
(* this won't last long I hope! *)
let eq_op op1 op2 =
DirPath.equal op1.obj_dir op2.obj_dir &&
DirPath.equal op1.obj_sec op2.obj_sec &&
ModPath.equal op1.obj_mp op2.obj_mp
let eq_global_dir_reference r1 r2 = match r1, r2 with
| DirOpenModule op1, DirOpenModule op2 -> eq_op op1 op2
| DirOpenModtype op1, DirOpenModtype op2 -> eq_op op1 op2
| DirOpenSection op1, DirOpenSection op2 -> eq_op op1 op2
| DirModule op1, DirModule op2 -> eq_op op1 op2
| DirClosedSection dp1, DirClosedSection dp2 -> DirPath.equal dp1 dp2
| _ -> false
type reference_r =
| Qualid of qualid
| Ident of Id.t
type reference = reference_r CAst.t
let qualid_of_reference = CAst.map (function
| Qualid qid -> qid
| Ident id -> qualid_of_ident id)
let string_of_reference = CAst.with_val (function
| Qualid qid -> string_of_qualid qid
| Ident id -> Id.to_string id)
let pr_reference = CAst.with_val (function
| Qualid qid -> pr_qualid qid
| Ident id -> Id.print id)
let eq_reference {CAst.v=r1} {CAst.v=r2} = match r1, r2 with
| Qualid q1, Qualid q2 -> qualid_eq q1 q2
| Ident id1, Ident id2 -> Id.equal id1 id2
| _ -> false
let join_reference {CAst.loc=l1;v=ns} {CAst.loc=l2;v=r} =
CAst.make ?loc:(Loc.merge_opt l1 l2) (
match ns , r with
Qualid q1, Qualid q2 ->
let (dp1,id1) = repr_qualid q1 in
let (dp2,id2) = repr_qualid q2 in
Qualid (make_qualid
(append_dirpath (append_dirpath dp1 (dirpath_of_string (Names.Id.to_string id1))) dp2)
id2)
| Qualid q1, Ident id2 ->
let (dp1,id1) = repr_qualid q1 in
Qualid (make_qualid
(append_dirpath dp1 (dirpath_of_string (Names.Id.to_string id1)))
id2)
| Ident id1, Qualid q2 ->
let (dp2,id2) = repr_qualid q2 in
Qualid (make_qualid
(append_dirpath (dirpath_of_string (Names.Id.to_string id1)) dp2)
id2)
| Ident id1, Ident id2 ->
Qualid (make_qualid
(dirpath_of_string (Names.Id.to_string id1)) id2)
)
(* Default paths *)
let default_library = Names.DirPath.initial (* = ["Top"] *)
(*s Roots of the space of absolute names *)
let coq_string = "Coq"
let coq_root = Id.of_string coq_string
let default_root_prefix = DirPath.empty
(* Deprecated synonyms *)
let make_short_qualid = qualid_of_ident
let qualid_of_sp = qualid_of_path
|
