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(***********************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA-Rocquencourt & LRI-CNRS-Orsay *)
(* \VV/ *************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(***********************************************************************)
(* $Id$ *)
open Util
open Pp
open Names
open Nameops
open Declarations
(*s qualified names *)
type qualid = section_path
let make_qualid = make_path
let repr_qualid = repr_path
let string_of_qualid = string_of_path
let pr_qualid = pr_sp
let qualid_of_sp sp = sp
let make_short_qualid id = make_qualid empty_dirpath id
let qualid_of_dirpath dir =
let (l,a) = split_dirpath dir in
make_qualid l a
exception GlobalizationError of qualid
exception GlobalizationConstantError of qualid
let error_global_not_found_loc loc q =
Stdpp.raise_with_loc loc (GlobalizationError q)
let error_global_constant_not_found_loc loc q =
Stdpp.raise_with_loc loc (GlobalizationConstantError q)
let error_global_not_found q = raise (GlobalizationError q)
(* Constructions and syntactic definitions live in the same space *)
type global_reference =
| VarRef of variable
| ConstRef of constant
| IndRef of inductive
| ConstructRef of constructor
type extended_global_reference =
| TrueGlobal of global_reference
| SyntacticDef of section_path
let sp_of_global env = function
| VarRef id -> make_path empty_dirpath id
| ConstRef sp -> sp
| IndRef (sp,tyi) ->
(* Does not work with extracted inductive types when the first
inductive is logic : if tyi=0 then basename sp else *)
let mib = Environ.lookup_mind sp env in
assert (tyi < mib.mind_ntypes && tyi >= 0);
let mip = mib.mind_packets.(tyi) in
let (p,_) = repr_path sp in
make_path p mip.mind_typename
| ConstructRef ((sp,tyi),i) ->
let mib = Environ.lookup_mind sp env in
assert (tyi < mib.mind_ntypes && i >= 0);
let mip = mib.mind_packets.(tyi) in
assert (i <= Array.length mip.mind_consnames && i > 0);
let (p,_) = repr_path sp in
make_path p mip.mind_consnames.(i-1)
(* Dictionaries of short names *)
type 'a nametree = ('a option * 'a nametree ModIdmap.t)
type ccitab = extended_global_reference nametree Idmap.t
type objtab = section_path nametree Idmap.t
type dirtab = dir_path nametree ModIdmap.t
let the_ccitab = ref (Idmap.empty : ccitab)
let the_libtab = ref (ModIdmap.empty : dirtab)
let the_sectab = ref (ModIdmap.empty : dirtab)
let the_objtab = ref (Idmap.empty : objtab)
let dirpath_of_reference ref =
let sp = match ref with
| ConstRef sp -> sp
| VarRef id -> make_path empty_dirpath id
| ConstructRef ((sp,_),_) -> sp
| IndRef (sp,_) -> sp in
let (p,_) = repr_path sp in
p
let dirpath_of_extended_ref = function
| TrueGlobal ref -> dirpath_of_reference ref
| SyntacticDef sp ->
let (p,_) = repr_path sp in p
(* How [visibility] works: a value of [0] means all suffixes of [dir] are
allowed to access the object, a value of [1] means all suffixes, except the
base name, are available, [2] means all suffixes except the base name and
the name qualified by the module name *)
(* Concretely, library roots and directory are
always open but modules/files are open only during their interactive
construction or on demand if a precompiled one: for a name
"Root.Rep.Lib.name", then "Lib.name", "Rep.Lib.name" and
"Root.Rep.Lib.name", but not "name" are pushed; which means, visibility is
always 1 *)
(* We add a binding of [[modid1;...;modidn;id]] to [o] in the name tab *)
(* We proceed in the reverse way, looking first to [id] *)
let push_tree extract_dirpath tab visibility dir o =
let extract = option_app (fun c -> repr_dirpath (extract_dirpath c)) in
let rec push level (current,dirmap) = function
| modid :: path as dir ->
let mc =
try ModIdmap.find modid dirmap
with Not_found -> (None, ModIdmap.empty)
in
let this =
if level >= visibility then
if extract current = Some dir then
(* This is an absolute name, we must keep it otherwise it may
become unaccessible forever *)
current
else
Some o
else current in
(this, ModIdmap.add modid (push (level+1) mc path) dirmap)
| [] -> (Some o,dirmap) in
push 0 tab (repr_dirpath dir)
let push_idtree extract_dirpath tab n dir id o =
let modtab =
try Idmap.find id !tab
with Not_found -> (None, ModIdmap.empty) in
tab := Idmap.add id (push_tree extract_dirpath modtab n dir o) !tab
let push_long_names_ccipath = push_idtree dirpath_of_extended_ref the_ccitab
let push_short_name_ccipath = push_idtree dirpath_of_extended_ref the_ccitab
let push_short_name_objpath =
push_idtree (fun sp -> let (p,_) = repr_path sp in p) the_objtab
let push_modidtree tab dir id o =
let modtab =
try ModIdmap.find id !tab
with Not_found -> (None, ModIdmap.empty) in
tab := ModIdmap.add id (push_tree (fun x -> x) modtab 0 dir o) !tab
let push_long_names_secpath = push_modidtree the_sectab
let push_long_names_libpath = push_modidtree the_libtab
(* These are entry points for new declarations at toplevel *)
(* This is for permanent constructions (never discharged -- but with
possibly limited visibility, i.e. Theorem, Lemma, Definition, Axiom,
Parameter but also Remark and Fact) *)
let push_cci n sp ref =
let dir, s = repr_path sp in
(* We push partially qualified name (with at least one prefix) *)
push_long_names_ccipath n dir s (TrueGlobal ref)
let push = push_cci
(* This is for Syntactic Definitions *)
let push_syntactic_definition sp =
let dir, s = repr_path sp in
push_long_names_ccipath 0 dir s (SyntacticDef sp)
let push_short_name_syntactic_definition sp =
let _, s = repr_qualid (qualid_of_sp sp) in
push_short_name_ccipath Pervasives.max_int empty_dirpath s (SyntacticDef sp)
(* This is for dischargeable non-cci objects (removed at the end of the
section -- i.e. Hints, Grammar ...) *) (* --> Unused *)
let push_short_name_object sp =
let _, s = repr_qualid (qualid_of_sp sp) in
push_short_name_objpath 0 empty_dirpath s sp
(* This is to remember absolute Section/Module names and to avoid redundancy *)
let push_section fulldir =
let dir, s = split_dirpath fulldir in
(* We push all partially qualified name *)
push_long_names_secpath dir s fulldir;
push_long_names_secpath empty_dirpath s fulldir
(* These are entry points to locate names *)
let locate_in_tree tab dir =
let dir = repr_dirpath dir in
let rec search (current,modidtab) = function
| modid :: path -> search (ModIdmap.find modid modidtab) path
| [] -> match current with Some o -> o | _ -> raise Not_found
in
search tab dir
let locate_cci (qid:qualid) =
let (dir,id) = repr_qualid qid in
locate_in_tree (Idmap.find id !the_ccitab) dir
(* This should be used when syntactic definitions are allowed *)
let extended_locate = locate_cci
(* This should be used when no syntactic definitions is expected *)
let locate qid = match locate_cci qid with
| TrueGlobal ref -> ref
| SyntacticDef _ -> raise Not_found
let locate_obj qid =
let (dir,id) = repr_qualid qid in
locate_in_tree (Idmap.find id !the_objtab) dir
(* Actually, this table has only two levels, since only basename and *)
(* fullname are registered *)
let push_loaded_library fulldir =
let dir, s = split_dirpath fulldir in
push_long_names_libpath dir s fulldir;
push_long_names_libpath empty_dirpath s fulldir
let locate_loaded_library qid =
let (dir,id) = repr_qualid qid in
locate_in_tree (ModIdmap.find id !the_libtab) dir
let locate_section qid =
let (dir,id) = repr_qualid qid in
locate_in_tree (ModIdmap.find id !the_sectab) dir
(* Derived functions *)
let locate_constant qid =
(* TODO: restrict to defined constants *)
match locate_cci qid with
| TrueGlobal (ConstRef sp) -> sp
| _ -> raise Not_found
let sp_of_id id = match locate_cci (make_short_qualid id) with
| TrueGlobal ref -> ref
| SyntacticDef _ ->
anomaly ("sp_of_id: "^(string_of_id id)
^" is not a true global reference but a syntactic definition")
let constant_sp_of_id id =
match locate_cci (make_short_qualid id) with
| TrueGlobal (ConstRef sp) -> sp
| _ -> raise Not_found
let absolute_reference sp =
let a = locate_cci sp in
let (p,_) = repr_path sp in
if not (dirpath_of_extended_ref a = p) then
anomaly ("Not an absolute path: "^(string_of_path sp));
match a with
| TrueGlobal ref -> ref
| _ -> raise Not_found
let locate_in_absolute_module dir id =
absolute_reference (make_path dir id)
let global loc qid =
try match extended_locate qid with
| TrueGlobal ref -> ref
| SyntacticDef _ ->
error
("Unexpected reference to a syntactic definition: "
^(string_of_qualid qid))
with Not_found ->
error_global_not_found_loc loc qid
let exists_cci sp =
try let _ = locate_cci sp in true
with Not_found -> false
let exists_section dir =
try let _ = locate_section (qualid_of_dirpath dir) in true
with Not_found -> false
(* For a sp Coq.A.B.x, try to find the shortest among x, B.x, A.B.x
and Coq.A.B.x is a qualid that denotes the same object. *)
let shortest_qualid_of_global env ref =
let sp = sp_of_global env ref in
let (pth,id) = repr_path sp in
let rec find_visible dir qdir =
let qid = make_qualid qdir id in
if (try locate qid = ref with Not_found -> false) then qid
else match dir with
| [] -> qualid_of_sp sp
| a::l -> find_visible l (add_dirpath_prefix a qdir)
in
find_visible (repr_dirpath pth) (make_dirpath [])
let pr_global_env env ref =
(* Il est important de laisser le let-in, car les streams s'évaluent
paresseusement : il faut forcer l'évaluation pour capturer
l'éventuelle levée d'une exception (le cas échoit dans le debugger) *)
let s = string_of_qualid (shortest_qualid_of_global env ref) in
[< 'sTR s >]
(********************************************************************)
(********************************************************************)
(* Registration of tables as a global table and rollback *)
type frozen = ccitab * dirtab * dirtab * objtab * identifier list
let init () =
the_ccitab := Idmap.empty;
the_libtab := ModIdmap.empty;
the_sectab := ModIdmap.empty;
the_objtab := Idmap.empty
let freeze () =
!the_ccitab,
!the_libtab,
!the_sectab,
!the_objtab
let unfreeze (mc,ml,ms,mo) =
the_ccitab := mc;
the_libtab := ml;
the_sectab := ms;
the_objtab := mo
let _ =
Summary.declare_summary "names"
{ Summary.freeze_function = freeze;
Summary.unfreeze_function = unfreeze;
Summary.init_function = init;
Summary.survive_section = false }
|