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(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* $Id: dumpglob.ml 11582 2008-11-12 19:49:57Z notin $ *)
(* Dump of globalization (to be used by coqdoc) *)
let glob_file = ref Pervasives.stdout
let open_glob_file f =
glob_file := Pervasives.open_out f
let close_glob_file () =
Pervasives.close_out !glob_file
type glob_output_t =
| NoGlob
| StdOut
| MultFiles
| File of string
let glob_output = ref NoGlob
let dump () = !glob_output != NoGlob
let noglob () = glob_output := NoGlob
let dump_to_stdout () = glob_output := StdOut; glob_file := Pervasives.stdout
let multi_dump () = !glob_output = MultFiles
let dump_to_dotglob f = glob_output := MultFiles
let dump_into_file f = glob_output := File f; open_glob_file f
let dump_string s =
if dump () then Pervasives.output_string !glob_file s
let previous_state = ref MultFiles
let pause () = previous_state := !glob_output; glob_output := NoGlob
let continue () = glob_output := !previous_state
let token_number = ref 0
let last_pos = ref 0
type coqdoc_state = Lexer.location_table * int * int
let coqdoc_freeze () =
let lt = Lexer.location_table() in
let state = (lt,!token_number,!last_pos) in
token_number := 0;
last_pos := 0;
state
let coqdoc_unfreeze (lt,tn,lp) =
Lexer.restore_location_table lt;
token_number := tn;
last_pos := lp
open Decl_kinds
let type_of_logical_kind = function
| IsDefinition def ->
(match def with
| Definition -> "def"
| Coercion -> "coe"
| SubClass -> "subclass"
| CanonicalStructure -> "canonstruc"
| Example -> "ex"
| Fixpoint -> "def"
| CoFixpoint -> "def"
| Scheme -> "scheme"
| StructureComponent -> "proj"
| IdentityCoercion -> "coe"
| Instance -> "inst"
| Method -> "meth")
| IsAssumption a ->
(match a with
| Definitional -> "defax"
| Logical -> "prfax"
| Conjectural -> "prfax")
| IsProof th ->
(match th with
| Theorem
| Lemma
| Fact
| Remark
| Property
| Proposition
| Corollary -> "thm")
let type_of_global_ref gr =
if Typeclasses.is_class gr then
"class"
else
match gr with
| Libnames.ConstRef cst ->
type_of_logical_kind (Decls.constant_kind cst)
| Libnames.VarRef v ->
"var" ^ type_of_logical_kind (Decls.variable_kind v)
| Libnames.IndRef ind ->
let (mib,oib) = Inductive.lookup_mind_specif (Global.env ()) ind in
if mib.Declarations.mind_record then
if mib.Declarations.mind_finite then "rec"
else "corec"
else if mib.Declarations.mind_finite then "ind"
else "coind"
| Libnames.ConstructRef _ -> "constr"
let remove_sections dir =
if Libnames.is_dirpath_prefix_of dir (Lib.cwd ()) then
(* Not yet (fully) discharged *)
Libnames.extract_dirpath_prefix (Lib.sections_depth ()) (Lib.cwd ())
else
(* Theorem/Lemma outside its outer section of definition *)
dir
let dump_ref loc filepath modpath ident ty =
dump_string (Printf.sprintf "R%d %s %s %s %s\n"
(fst (Util.unloc loc)) filepath modpath ident ty)
let add_glob_gen loc sp lib_dp ty =
if dump () then
let mod_dp,id = Libnames.repr_path sp in
let mod_dp = remove_sections mod_dp in
let mod_dp_trunc = Libnames.drop_dirpath_prefix lib_dp mod_dp in
let filepath = Names.string_of_dirpath lib_dp in
let modpath = Names.string_of_dirpath mod_dp_trunc in
let ident = Names.string_of_id id in
dump_ref loc filepath modpath ident ty
let add_glob loc ref =
if dump () && loc <> Util.dummy_loc then
let sp = Nametab.sp_of_global ref in
let lib_dp = Lib.library_part ref in
let ty = type_of_global_ref ref in
add_glob_gen loc sp lib_dp ty
let mp_of_kn kn =
let mp,sec,l = Names.repr_kn kn in
Names.MPdot (mp,l)
let add_glob_kn loc kn =
if dump () && loc <> Util.dummy_loc then
let sp = Nametab.sp_of_syntactic_definition kn in
let lib_dp = Lib.dp_of_mp (mp_of_kn kn) in
add_glob_gen loc sp lib_dp "syndef"
let add_local loc id = ()
(* let mod_dp,id = repr_path sp in *)
(* let mod_dp = remove_sections mod_dp in *)
(* let mod_dp_trunc = drop_dirpath_prefix lib_dp mod_dp in *)
(* let filepath = string_of_dirpath lib_dp in *)
(* let modpath = string_of_dirpath mod_dp_trunc in *)
(* let ident = string_of_id id in *)
(* dump_string (Printf.sprintf "R%d %s %s %s %s\n" *)
(* (fst (unloc loc)) filepath modpath ident ty) *)
let dump_binding loc id = ()
let dump_definition (loc, id) sec s =
dump_string (Printf.sprintf "%s %d %s %s\n" s (fst (Util.unloc loc))
(Names.string_of_dirpath (Lib.current_dirpath sec)) (Names.string_of_id id))
let dump_reference loc modpath ident ty =
dump_string (Printf.sprintf "R%d %s %s %s %s\n"
(fst (Util.unloc loc)) (Names.string_of_dirpath (Lib.library_dp ())) modpath ident ty)
let dump_constraint ((loc, n), _, _) sec ty =
match n with
| Names.Name id -> dump_definition (loc, id) sec ty
| Names.Anonymous -> ()
let dump_name (loc, n) sec ty =
match n with
| Names.Name id -> dump_definition (loc, id) sec ty
| Names.Anonymous -> ()
let dump_local_binder b sec ty =
if dump () then
match b with
| Topconstr.LocalRawAssum (nl, _, _) ->
List.iter (fun x -> dump_name x sec ty) nl
| Topconstr.LocalRawDef _ -> ()
let dump_modref loc mp ty =
if dump () then
let (dp, l) = Lib.split_modpath mp in
let l = if l = [] then l else Util.list_drop_last l in
let fp = Names.string_of_dirpath dp in
let mp = Names.string_of_dirpath (Names.make_dirpath l) in
dump_string (Printf.sprintf "R%d %s %s %s %s\n"
(fst (Util.unloc loc)) fp mp "<>" ty)
let dump_moddef loc mp ty =
if dump () then
let (dp, l) = Lib.split_modpath mp in
let mp = Names.string_of_dirpath (Names.make_dirpath l) in
dump_string (Printf.sprintf "%s %d %s %s\n" ty (fst (Util.unloc loc)) "<>" mp)
let dump_libref loc dp ty =
dump_string (Printf.sprintf "R%d %s <> <> %s\n"
(fst (Util.unloc loc)) (Names.string_of_dirpath dp) ty)
let dump_notation_location pos ((path,df),sc) =
if dump () then
let rec next growing =
let loc = Lexer.location_function !token_number in
let (bp,_) = Util.unloc loc in
if growing then if bp >= pos then loc else (incr token_number; next true)
else if bp = pos then loc
else if bp > pos then (decr token_number;next false)
else (incr token_number;next true) in
let loc = next (pos >= !last_pos) in
last_pos := pos;
let path = Names.string_of_dirpath path in
let _sc = match sc with Some sc -> " "^sc | _ -> "" in
dump_string (Printf.sprintf "R%d %s \"%s\" not\n" (fst (Util.unloc loc)) path df)
|