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(************************************************************************)
(*  v      *   The Coq Proof Assistant  /  The Coq Development Team     *)
(* <O___,, *   INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2015     *)
(*   \VV/  **************************************************************)
(*    //   *      This file is distributed under the terms of the       *)
(*         *       GNU Lesser General Public License Version 2.1        *)
(************************************************************************)

(* Concrete syntax of the mathematical vernacular MV V2.6 *)

open Pp
open Errors
open Util
open Flags
open Names
open Nameops
open Term
open Pfedit
open Tacmach
open Constrintern
open Prettyp
open Printer
open Tacinterp
open Command
open Goptions
open Libnames
open Globnames
open Vernacexpr
open Decl_kinds
open Constrexpr
open Redexpr
open Lemmas
open Misctypes
open Locality

let debug = false
let prerr_endline =
  if debug then prerr_endline else fun _ -> ()

(* Misc *)

let cl_of_qualid = function
  | FunClass -> Classops.CL_FUN
  | SortClass -> Classops.CL_SORT
  | RefClass r -> Class.class_of_global (Smartlocate.smart_global ~head:true r)

let scope_class_of_qualid qid =
  Notation.scope_class_of_reference (Smartlocate.smart_global qid)

(*******************)
(* "Show" commands *)

let show_proof () =
  (* spiwack: this would probably be cooler with a bit of polishing. *)
  let p = Proof_global.give_me_the_proof () in
  let pprf = Proof.partial_proof p in
  msg_notice (Pp.prlist_with_sep Pp.fnl Printer.pr_constr pprf)

let show_node () =
  (* spiwack: I'm have little clue what this function used to do. I deactivated it, 
      could, possibly, be cleaned away. (Feb. 2010) *)
  ()

let show_thesis () =
     msg_error (anomaly (Pp.str "TODO") )

let show_top_evars () =
  (* spiwack: new as of Feb. 2010: shows goal evars in addition to non-goal evars. *)
  let pfts = get_pftreestate () in
  let gls = Proof.V82.subgoals pfts in
  let sigma = gls.Evd.sigma in
  msg_notice (pr_evars_int sigma 1 (Evarutil.non_instantiated sigma))

let show_universes () =
  let pfts = get_pftreestate () in
  let gls = Proof.V82.subgoals pfts in
  let sigma = gls.Evd.sigma in
  let ctx = Evd.universe_context_set (Evd.nf_constraints sigma) in
    msg_notice (Evd.pr_evar_universe_context (Evd.evar_universe_context sigma));
    msg_notice (str"Normalized constraints: " ++ Univ.pr_universe_context_set (Evd.pr_evd_level sigma) ctx)

let show_prooftree () =
  (* Spiwack: proof tree is currently not working *)
  ()

let enable_goal_printing = ref true

let print_subgoals () =
  if !enable_goal_printing && is_verbose ()
  then begin
    msg_notice (pr_open_subgoals ())
  end

let try_print_subgoals () =
  Pp.flush_all();
  try print_subgoals () with Proof_global.NoCurrentProof | UserError _ -> ()


  (* Simulate the Intro(s) tactic *)

let show_intro all =
  let pf = get_pftreestate() in
  let {Evd.it=gls ; sigma=sigma; } = Proof.V82.subgoals pf in
  if not (List.is_empty gls) then begin
    let gl = {Evd.it=List.hd gls ; sigma = sigma; } in
    let l,_= decompose_prod_assum (strip_outer_cast (pf_concl gl)) in
    if all then
      let lid = Tactics.find_intro_names l gl in
      msg_notice (hov 0 (prlist_with_sep  spc pr_id lid))
    else if not (List.is_empty l) then
      let n = List.last l in
      msg_notice (pr_id (List.hd (Tactics.find_intro_names [n] gl)))
  end

(** Prepare a "match" template for a given inductive type.
    For each branch of the match, we list the constructor name
    followed by enough pattern variables.
    [Not_found] is raised if the given string isn't the qualid of
    a known inductive type. *)

let make_cases s =
  let qualified_name = Libnames.qualid_of_string s in
  let glob_ref = Nametab.locate qualified_name in
  match glob_ref with
    | Globnames.IndRef i ->
	let {Declarations.mind_nparams = np}
	    , {Declarations.mind_consnames = carr ; Declarations.mind_nf_lc = tarr }
	      = Global.lookup_inductive i in
	Util.Array.fold_right2
	  (fun consname typ l ->
	     let al = List.rev (fst (decompose_prod typ)) in
	     let al = Util.List.skipn np al in
	     let rec rename avoid = function
	       | [] -> []
	       | (n,_)::l ->
		   let n' = Namegen.next_name_away_in_cases_pattern ([],mkMeta 0) n avoid in
		   Id.to_string n' :: rename (n'::avoid) l in
	     let al' = rename [] al in
	     (Id.to_string consname :: al') :: l)
	  carr tarr []
    | _ -> raise Not_found

(** Textual display of a generic "match" template *)

let show_match id =
  let patterns =
    try make_cases (Id.to_string (snd id))
    with Not_found -> error "Unknown inductive type."
  in
  let pr_branch l =
    str "| " ++ hov 1 (prlist_with_sep spc str l) ++ str " =>"
  in
  msg_notice (v 1 (str "match # with" ++ fnl () ++
	    prlist_with_sep fnl pr_branch patterns ++ fnl () ++ str "end" ++ fnl ()))

(* "Print" commands *)

let print_path_entry p =
  let dir = str (DirPath.to_string (Loadpath.logical p)) in
  let path = str (Loadpath.physical p) in
  (dir ++ str " " ++ tbrk (0, 0) ++ path)

let print_loadpath dir =
  let l = Loadpath.get_load_paths () in
  let l = match dir with
  | None -> l
  | Some dir ->
    let filter p = is_dirpath_prefix_of dir (Loadpath.logical p) in
    List.filter filter l
  in
  Pp.t (str "Logical Path:                 " ++
                tab () ++ str "Physical path:" ++ fnl () ++
                prlist_with_sep fnl print_path_entry l)

let print_modules () =
  let opened = Library.opened_libraries ()
  and loaded = Library.loaded_libraries () in
  (* we intersect over opened to preserve the order of opened since *)
  (* non-commutative operations (e.g. visibility) are done at import time *)
  let loaded_opened = List.intersect DirPath.equal opened loaded
  and only_loaded = List.subtract DirPath.equal loaded opened in
  str"Loaded and imported library files: " ++
  pr_vertical_list pr_dirpath loaded_opened ++ fnl () ++
  str"Loaded and not imported library files: " ++
  pr_vertical_list pr_dirpath only_loaded


let print_module r =
  let (loc,qid) = qualid_of_reference r in
  try
    let globdir = Nametab.locate_dir qid in
      match globdir with
	  DirModule (dirpath,(mp,_)) ->
	    msg_notice (Printmod.print_module (Printmod.printable_body dirpath) mp)
	| _ -> raise Not_found
  with
      Not_found -> msg_error (str"Unknown Module " ++ pr_qualid qid)

let print_modtype r =
  let (loc,qid) = qualid_of_reference r in
  try
    let kn = Nametab.locate_modtype qid in
    msg_notice (Printmod.print_modtype kn)
  with Not_found ->
    (* Is there a module of this name ? If yes we display its type *)
    try
      let mp = Nametab.locate_module qid in
      msg_notice (Printmod.print_module false mp)
    with Not_found ->
      msg_error (str"Unknown Module Type or Module " ++ pr_qualid qid)

let print_namespace ns =
  let ns = List.rev (Names.DirPath.repr ns) in
  (* [match_dirpath], [match_modulpath] are helpers for [matches]
     which checks whether a constant is in the namespace [ns]. *)
  let rec match_dirpath ns = function
    | [] -> Some ns
    | id::dir ->
        begin match match_dirpath ns dir with
        | Some [] as y -> y
        | Some (a::ns') ->
            if Names.Id.equal a id then Some ns'
            else None
        | None -> None
        end
  in
  let rec match_modulepath ns = function
    | MPbound _ -> None (* Not a proper namespace. *)
    | MPfile dir -> match_dirpath ns (Names.DirPath.repr dir)
    | MPdot (mp,lbl) ->
        let id = Names.Label.to_id lbl in
        begin match match_modulepath ns mp with
        | Some [] as y -> y
        | Some (a::ns') ->
            if Names.Id.equal a id then Some ns'
            else None
        | None -> None
        end
  in
  (* [qualified_minus n mp] returns a list of qualifiers representing
     [mp] except the [n] first (in the concrete syntax order).  The
     idea is that if [mp] matches [ns], then [qualified_minus mp
     (length ns)] will be the correct representation of [mp] assuming
     [ns] is imported. *)
  (* precondition: [mp] matches some namespace of length [n] *)
  let qualified_minus n mp =
    let rec list_of_modulepath = function
      | MPbound _ -> assert false (* MPbound never matches *)
      | MPfile dir -> Names.DirPath.repr dir
      | MPdot (mp,lbl) -> (Names.Label.to_id lbl)::(list_of_modulepath mp)
    in
    snd (Util.List.chop n (List.rev (list_of_modulepath mp)))
  in
  let print_list pr l = prlist_with_sep (fun () -> str".") pr l in
  let print_kn kn =
    (* spiwack: I'm ignoring the dirpath, is that bad? *)
    let (mp,_,lbl) = Names.repr_kn kn in
    let qn = (qualified_minus (List.length ns) mp)@[Names.Label.to_id lbl] in
    print_list pr_id qn
  in
  let print_constant k body =
    (* FIXME: universes *)
    let t = Typeops.type_of_constant_type (Global.env ()) body.Declarations.const_type in
    print_kn k ++ str":" ++ spc() ++ Printer.pr_type t
  in
  let matches mp = match match_modulepath ns mp with
  | Some [] -> true
  | _ -> false in
  let constants = (Environ.pre_env (Global.env ())).Pre_env.env_globals.Pre_env.env_constants in
  let constants_in_namespace =
    Cmap_env.fold (fun c (body,_) acc ->
      let kn = user_con c in
      if matches (modpath kn) then
        acc++fnl()++hov 2 (print_constant kn body)
      else
        acc
    ) constants (str"")
  in
  msg_notice ((print_list pr_id ns)++str":"++fnl()++constants_in_namespace)

let print_strategy r =
  let open Conv_oracle in
  let pr_level = function
  | Expand -> str "expand"
  | Level 0 -> str "transparent"
  | Level n -> str "level" ++ spc() ++ int n
  | Opaque -> str "opaque"
  in
  let pr_strategy (ref, lvl) = pr_global ref ++ str " : " ++ pr_level lvl in
  let oracle = Environ.oracle (Global.env ()) in
  match r with
  | None ->
    let fold key lvl (vacc, cacc) = match key with
    | VarKey id -> ((VarRef id, lvl) :: vacc, cacc)
    | ConstKey cst -> (vacc, (ConstRef cst, lvl) :: cacc)
    | RelKey _ -> (vacc, cacc)
    in
    let var_lvl, cst_lvl = fold_strategy fold oracle ([], []) in
    let var_msg =
      if List.is_empty var_lvl then mt ()
      else str "Variable strategies" ++ fnl () ++
        hov 0 (prlist_with_sep fnl pr_strategy var_lvl) ++ fnl ()
    in
    let cst_msg =
      if List.is_empty cst_lvl then mt ()
      else str "Constant strategies" ++ fnl () ++
        hov 0 (prlist_with_sep fnl pr_strategy cst_lvl)
    in
    msg_notice (var_msg ++ cst_msg)
  | Some r ->
    let r = Smartlocate.smart_global r in
    let key = match r with
    | VarRef id -> VarKey id
    | ConstRef cst -> ConstKey cst
    | IndRef _ | ConstructRef _ -> error "The reference is not unfoldable"
    in
    let lvl = get_strategy oracle key in
    msg_notice (pr_strategy (r, lvl))

let dump_universes_gen g s =
  let output = open_out s in
  let output_constraint, close =
    if Filename.check_suffix s ".dot" || Filename.check_suffix s ".gv" then begin
      (* the lazy unit is to handle errors while printing the first line *)
      let init = lazy (Printf.fprintf output "digraph universes {\n") in
      begin fun kind left right ->
        let () = Lazy.force init in
        match kind with
          | Univ.Lt ->
            Printf.fprintf output "  \"%s\" -> \"%s\" [style=bold];\n" right left
          | Univ.Le ->
            Printf.fprintf output "  \"%s\" -> \"%s\" [style=solid];\n" right left
          | Univ.Eq ->
            Printf.fprintf output "  \"%s\" -> \"%s\" [style=dashed];\n" left right
      end, begin fun () ->
        if Lazy.lazy_is_val init then Printf.fprintf output "}\n";
        close_out output
      end
    end else begin
      begin fun kind left right ->
        let kind = match kind with
          | Univ.Lt -> "<"
          | Univ.Le -> "<="
          | Univ.Eq -> "="
        in Printf.fprintf output "%s %s %s ;\n" left kind right
      end, (fun () -> close_out output)
    end
  in
  try
    Univ.dump_universes output_constraint g;
    close ();
    msg_info (str "Universes written to file \"" ++ str s ++ str "\".")
  with reraise ->
    let reraise = Errors.push reraise in
    close ();
    iraise reraise

let dump_universes sorted s =
  let g = Global.universes () in
  let g = if sorted then Univ.sort_universes g else g in
  dump_universes_gen g s

(*********************)
(* "Locate" commands *)

let locate_file f =
  let file = Flags.silently Loadpath.locate_file f in
  str file

let msg_found_library = function
  | Library.LibLoaded, fulldir, file ->
      msg_info (hov 0
	(pr_dirpath fulldir ++ strbrk " has been loaded from file " ++
	 str file))
  | Library.LibInPath, fulldir, file ->
      msg_info (hov 0
	(pr_dirpath fulldir ++ strbrk " is bound to file " ++ str file))

let err_unmapped_library loc ?from qid =
  let dir = fst (repr_qualid qid) in
  let prefix = match from with
  | None -> str "."
  | Some from ->
    str " and prefix " ++ pr_dirpath from ++ str "."
  in
  user_err_loc
    (loc,"locate_library",
     strbrk "Cannot find a physical path bound to logical path matching suffix " ++
       pr_dirpath dir ++ prefix)

let err_notfound_library loc ?from qid =
  let prefix = match from with
  | None -> str "."
  | Some from ->
    str " with prefix " ++ pr_dirpath from ++ str "."
  in
  user_err_loc
    (loc,"locate_library",
     strbrk "Unable to locate library " ++ pr_qualid qid ++ prefix)

let print_located_library r =
  let (loc,qid) = qualid_of_reference r in
  try msg_found_library (Library.locate_qualified_library ~warn:false qid)
  with
    | Library.LibUnmappedDir -> err_unmapped_library loc qid
    | Library.LibNotFound -> err_notfound_library loc qid

let smart_global r =
  let gr = Smartlocate.smart_global r in
    Dumpglob.add_glob (Constrarg.loc_of_or_by_notation loc_of_reference r) gr;
    gr

let dump_global r =
  try
    let gr = Smartlocate.smart_global r in
    Dumpglob.add_glob (Constrarg.loc_of_or_by_notation loc_of_reference r) gr
  with e when Errors.noncritical e -> ()
(**********)
(* Syntax *)

let vernac_syntax_extension locality local =
  let local = enforce_module_locality locality local in
  Metasyntax.add_syntax_extension local

let vernac_delimiters sc = function
  | Some lr -> Metasyntax.add_delimiters sc lr
  | None -> Metasyntax.remove_delimiters sc

let vernac_bind_scope sc cll =
  Metasyntax.add_class_scope sc (List.map scope_class_of_qualid cll)

let vernac_open_close_scope locality local (b,s) =
  let local = enforce_section_locality locality local in
  Notation.open_close_scope (local,b,s)

let vernac_arguments_scope locality r scl =
  let local = make_section_locality locality in
  Notation.declare_arguments_scope local (smart_global r) scl

let vernac_infix locality local =
  let local = enforce_module_locality locality local in
  Metasyntax.add_infix local

let vernac_notation locality local =
  let local = enforce_module_locality locality local in
  Metasyntax.add_notation local

(***********)
(* Gallina *)

let start_proof_and_print k l hook = start_proof_com k l hook

let no_hook = Lemmas.mk_hook (fun _ _ -> ())

let vernac_definition_hook p = function
| Coercion -> Class.add_coercion_hook p
| CanonicalStructure ->
    Lemmas.mk_hook (fun _ -> Recordops.declare_canonical_structure)
| SubClass -> Class.add_subclass_hook p
| _ -> no_hook

let vernac_definition locality p (local,k) ((loc,id as lid),pl) def =
  let local = enforce_locality_exp locality local in
  let hook = vernac_definition_hook p k in
  let () = match local with
  | Discharge -> Dumpglob.dump_definition lid true "var"
  | Local | Global -> Dumpglob.dump_definition lid false "def"
  in
  (match def with
    | ProveBody (bl,t) ->   (* local binders, typ *)
 	  start_proof_and_print (local,p,DefinitionBody Definition)
	    [Some (lid,pl), (bl,t,None)] no_hook
    | DefineBody (bl,red_option,c,typ_opt) ->
 	let red_option = match red_option with
          | None -> None
          | Some r ->
	      let (evc,env)= get_current_context () in
 		Some (snd (interp_redexp env evc r)) in
	do_definition id (local,p,k) pl bl red_option c typ_opt hook)

let vernac_start_proof locality p kind l lettop =
  let local = enforce_locality_exp locality None in
  if Dumpglob.dump () then
    List.iter (fun (id, _) ->
      match id with
	| Some (lid,_) -> Dumpglob.dump_definition lid false "prf"
	| None -> ()) l;
  if not(refining ()) then
    if lettop then
      errorlabstrm "Vernacentries.StartProof"
	(str "Let declarations can only be used in proof editing mode.");
  start_proof_and_print (local, p, Proof kind) l no_hook

let qed_display_script = ref true

let vernac_end_proof ?proof = function
  | Admitted -> save_proof ?proof Admitted
  | Proved (_,_) as e ->
    if is_verbose () && !qed_display_script && !Flags.coqtop_ui then
      Stm.show_script ?proof ();
    save_proof ?proof e

  (* A stupid macro that should be replaced by ``Exact c. Save.'' all along
     the theories [??] *)

let vernac_exact_proof c =
  (* spiwack: for simplicity I do not enforce that "Proof proof_term" is
     called only at the begining of a proof. *)
  let status = by (Tactics.New.exact_proof c) in
  save_proof (Vernacexpr.(Proved(Opaque None,None)));
  if not status then Pp.feedback Feedback.AddedAxiom

let vernac_assumption locality poly (local, kind) l nl =
  let local = enforce_locality_exp locality local in
  let global = local == Global in
  let kind = local, poly, kind in
  List.iter (fun (is_coe,(idl,c)) ->
    if Dumpglob.dump () then
      List.iter (fun (lid, _) ->
	if global then Dumpglob.dump_definition lid false "ax"
	else Dumpglob.dump_definition lid true "var") idl) l;
  let status = do_assumptions kind nl l in
  if not status then Pp.feedback Feedback.AddedAxiom

let vernac_record k poly finite struc binders sort nameopt cfs =
  let const = match nameopt with
    | None -> add_prefix "Build_" (snd (fst (snd struc)))
    | Some (_,id as lid) ->
	Dumpglob.dump_definition lid false "constr"; id in
    if Dumpglob.dump () then (
      Dumpglob.dump_definition (fst (snd struc)) false "rec";
      List.iter (fun (((_, x), _), _) ->
	match x with
	| Vernacexpr.AssumExpr ((loc, Name id), _) -> Dumpglob.dump_definition (loc,id) false "proj"
	| _ -> ()) cfs);
    ignore(Record.definition_structure (k,poly,finite,struc,binders,cfs,const,sort))

let vernac_inductive poly lo finite indl =
  if Dumpglob.dump () then
    List.iter (fun (((coe,(lid,_)), _, _, _, cstrs), _) ->
      match cstrs with
	| Constructors cstrs ->
	    Dumpglob.dump_definition lid false "ind";
	    List.iter (fun (_, (lid, _)) ->
			 Dumpglob.dump_definition lid false "constr") cstrs
	| _ -> () (* dumping is done by vernac_record (called below) *) )
      indl;
  match indl with
  | [ ( _ , _ , _ ,Record, Constructors _ ),_ ] ->
      Errors.error "The Record keyword cannot be used to define a variant type. Use Variant instead."
  | [ (_ , _ , _ ,Variant, RecordDecl _),_ ] ->
      Errors.error "The Variant keyword cannot be used to define a record type. Use Record instead."
  | [ ( id , bl , c , b, RecordDecl (oc,fs) ), [] ] ->
      vernac_record (match b with Class true -> Class false | _ -> b)
       poly finite id bl c oc fs
  | [ ( id , bl , c , Class true, Constructors [l]), _ ] ->
      let f =
	let (coe, ((loc, id), ce)) = l in
	let coe' = if coe then Some true else None in
  	  (((coe', AssumExpr ((loc, Name id), ce)), None), [])
      in vernac_record (Class true) poly finite id bl c None [f]
  | [ ( id , bl , c , Class true, _), _ ] ->
      Errors.error "Definitional classes must have a single method"
  | [ ( id , bl , c , Class false, Constructors _), _ ] ->
      Errors.error "Inductive classes not supported"
  | [ ( _ , _ , _ , _, RecordDecl _ ) , _ ] ->
      Errors.error "where clause not supported for (co)inductive records"
  | _ -> let unpack = function
      | ( (false, id) , bl , c , _ , Constructors l ) , ntn  -> ( id , bl , c , l ) , ntn
      | ( (true,_),_,_,_,Constructors _),_ ->
          Errors.error "Variant types do not handle the \"> Name\" syntax, which is reserved for records. Use the \":>\" syntax on constructors instead."
      | _ -> Errors.error "Cannot handle mutually (co)inductive records."
    in
    let indl = List.map unpack indl in
    do_mutual_inductive indl poly lo finite

let vernac_fixpoint locality poly local l =
  let local = enforce_locality_exp locality local in
  if Dumpglob.dump () then
    List.iter (fun (((lid,_), _, _, _, _), _) -> Dumpglob.dump_definition lid false "def") l;
  do_fixpoint local poly l

let vernac_cofixpoint locality poly local l =
  let local = enforce_locality_exp locality local in
  if Dumpglob.dump () then
    List.iter (fun (((lid,_), _, _, _), _) -> Dumpglob.dump_definition lid false "def") l;
  do_cofixpoint local poly l

let vernac_scheme l =
  if Dumpglob.dump () then
    List.iter (fun (lid, s) ->
	       Option.iter (fun lid -> Dumpglob.dump_definition lid false "def") lid;
	       match s with
	       | InductionScheme (_, r, _)
	       | CaseScheme (_, r, _) 
	       | EqualityScheme r -> dump_global r) l;
  Indschemes.do_scheme l

let vernac_combined_scheme lid l =
  if Dumpglob.dump () then
    (Dumpglob.dump_definition lid false "def";
     List.iter (fun lid -> dump_global (Misctypes.AN (Ident lid))) l);
 Indschemes.do_combined_scheme lid l

let vernac_universe loc poly l =
  if poly && not (Lib.sections_are_opened ()) then
    user_err_loc (loc, "vernac_universe",
		  str"Polymorphic universes can only be declared inside sections, " ++
		  str "use Monomorphic Universe instead");
  do_universe poly l

let vernac_constraint loc poly l =
  if poly && not (Lib.sections_are_opened ()) then
    user_err_loc (loc, "vernac_constraint",
		  str"Polymorphic universe constraints can only be declared"
		  ++ str " inside sections, use Monomorphic Constraint instead");
  do_constraint poly l

(**********************)
(* Modules            *)

let vernac_import export refl =
  Library.import_module export (List.map qualid_of_reference refl);
  Lib.add_frozen_state ()

let vernac_declare_module export (loc, id) binders_ast mty_ast =
  (* We check the state of the system (in section, in module type)
     and what module information is supplied *)
  if Lib.sections_are_opened () then
    error "Modules and Module Types are not allowed inside sections.";
  let binders_ast = List.map
   (fun (export,idl,ty) ->
     if not (Option.is_empty export) then
      error "Arguments of a functor declaration cannot be exported. Remove the \"Export\" and \"Import\" keywords from every functor argument."
     else (idl,ty)) binders_ast in
  let mp =
    Declaremods.declare_module Modintern.interp_module_ast
      id binders_ast (Enforce mty_ast) []
  in
  Dumpglob.dump_moddef loc mp "mod";
  if_verbose msg_info (str "Module " ++ pr_id id ++ str " is declared");
  Option.iter (fun export -> vernac_import export [Ident (Loc.ghost,id)]) export

let vernac_define_module export (loc, id) binders_ast mty_ast_o mexpr_ast_l =
  (* We check the state of the system (in section, in module type)
     and what module information is supplied *)
  if Lib.sections_are_opened () then
    error "Modules and Module Types are not allowed inside sections.";
  match mexpr_ast_l with
    | [] ->
       check_no_pending_proofs ();
       let binders_ast,argsexport =
        List.fold_right
         (fun (export,idl,ty) (args,argsexport) ->
           (idl,ty)::args, (List.map (fun (_,i) -> export,i)idl)@argsexport) binders_ast
             ([],[]) in
       let mp =
         Declaremods.start_module Modintern.interp_module_ast
           export id binders_ast mty_ast_o
       in
       Dumpglob.dump_moddef loc mp "mod";
       if_verbose msg_info
         (str "Interactive Module " ++ pr_id id ++ str " started");
       List.iter
         (fun (export,id) ->
           Option.iter
             (fun export -> vernac_import export [Ident (Loc.ghost,id)]) export
         ) argsexport
    | _::_ ->
       let binders_ast = List.map
        (fun (export,idl,ty) ->
          if not (Option.is_empty export) then
           error "Arguments of a functor definition can be imported only if the definition is interactive. Remove the \"Export\" and \"Import\" keywords from every functor argument."
          else (idl,ty)) binders_ast in
       let mp =
         Declaremods.declare_module Modintern.interp_module_ast
	   id binders_ast mty_ast_o mexpr_ast_l
       in
       Dumpglob.dump_moddef loc mp "mod";
       if_verbose msg_info
	 (str "Module " ++ pr_id id ++ str " is defined");
       Option.iter (fun export -> vernac_import export [Ident (Loc.ghost,id)])
         export

let vernac_end_module export (loc,id as lid) =
  let mp = Declaremods.end_module () in
  Dumpglob.dump_modref loc mp "mod";
  if_verbose msg_info (str "Module " ++ pr_id id ++ str " is defined");
  Option.iter (fun export -> vernac_import export [Ident lid]) export

let vernac_declare_module_type (loc,id) binders_ast mty_sign mty_ast_l =
  if Lib.sections_are_opened () then
    error "Modules and Module Types are not allowed inside sections.";

  match mty_ast_l with
    | [] ->
       check_no_pending_proofs ();
       let binders_ast,argsexport =
	 List.fold_right
         (fun (export,idl,ty) (args,argsexport) ->
           (idl,ty)::args, (List.map (fun (_,i) -> export,i)idl)@argsexport) binders_ast
             ([],[]) in

       let mp =
         Declaremods.start_modtype Modintern.interp_module_ast
           id binders_ast mty_sign
       in
       Dumpglob.dump_moddef loc mp "modtype";
       if_verbose msg_info
	 (str "Interactive Module Type " ++ pr_id id ++ str " started");
       List.iter
         (fun (export,id) ->
           Option.iter
             (fun export -> vernac_import export [Ident (Loc.ghost,id)]) export
         ) argsexport

    | _ :: _ ->
	let binders_ast = List.map
          (fun (export,idl,ty) ->
            if not (Option.is_empty export) then
              error "Arguments of a functor definition can be imported only if the definition is interactive. Remove the \"Export\" and \"Import\" keywords from every functor argument."
            else (idl,ty)) binders_ast in
	let mp =
          Declaremods.declare_modtype Modintern.interp_module_ast
	    id binders_ast mty_sign mty_ast_l
        in
        Dumpglob.dump_moddef loc mp "modtype";
	if_verbose msg_info
	  (str "Module Type " ++ pr_id id ++ str " is defined")

let vernac_end_modtype (loc,id) =
  let mp = Declaremods.end_modtype () in
  Dumpglob.dump_modref loc mp "modtype";
  if_verbose msg_info (str "Module Type " ++ pr_id id ++ str " is defined")

let vernac_include l =
  Declaremods.declare_include Modintern.interp_module_ast l

(**********************)
(* Gallina extensions *)

(* Sections *)

let vernac_begin_section (_, id as lid) =
  check_no_pending_proofs ();
  Dumpglob.dump_definition lid true "sec";
  Lib.open_section id

let vernac_end_section (loc,_) =
  Dumpglob.dump_reference loc
    (DirPath.to_string (Lib.current_dirpath true)) "<>" "sec";
  Lib.close_section ()

let vernac_name_sec_hyp (_,id) set = Proof_using.name_set id set

(* Dispatcher of the "End" command *)

let vernac_end_segment (_,id as lid) =
  check_no_pending_proofs ();
  match Lib.find_opening_node id with
  | Lib.OpenedModule (false,export,_,_) -> vernac_end_module export lid
  | Lib.OpenedModule (true,_,_,_) -> vernac_end_modtype lid
  | Lib.OpenedSection _ -> vernac_end_section lid
  | _ -> assert false

(* Libraries *)

let vernac_require from import qidl =
  let qidl = List.map qualid_of_reference qidl in
  let root = match from with
  | None -> None
  | Some from ->
    let (_, qid) = Libnames.qualid_of_reference from in
    let (hd, tl) = Libnames.repr_qualid qid in
    Some (Libnames.add_dirpath_suffix hd tl)
  in
  let locate (loc, qid) =
    try
      let warn = Flags.is_verbose () in
      let (_, dir, f) = Library.locate_qualified_library ?root ~warn qid in
      (dir, f)
    with
      | Library.LibUnmappedDir -> err_unmapped_library loc ?from:root qid
      | Library.LibNotFound -> err_notfound_library loc ?from:root qid
  in
  let modrefl = List.map locate qidl in
  if Dumpglob.dump () then
    List.iter2 (fun (loc, _) dp -> Dumpglob.dump_libref loc dp "lib") qidl (List.map fst modrefl);
  Library.require_library_from_dirpath modrefl import

(* Coercions and canonical structures *)

let vernac_canonical r =
  Recordops.declare_canonical_structure (smart_global r)

let vernac_coercion locality poly local ref qids qidt =
  let local = enforce_locality locality local in
  let target = cl_of_qualid qidt in
  let source = cl_of_qualid qids in
  let ref' = smart_global ref in
  Class.try_add_new_coercion_with_target ref' ~local poly ~source ~target;
  if_verbose msg_info (pr_global ref' ++ str " is now a coercion")

let vernac_identity_coercion locality poly local id qids qidt =
  let local = enforce_locality locality local in
  let target = cl_of_qualid qidt in
  let source = cl_of_qualid qids in
  Class.try_add_new_identity_coercion id ~local poly ~source ~target

(* Type classes *)

let vernac_instance abst locality poly sup inst props pri =
  let global = not (make_section_locality locality) in
  Dumpglob.dump_constraint inst false "inst";
  ignore(Classes.new_instance ~abstract:abst ~global poly sup inst props pri)

let vernac_context poly l =
  if not (Classes.context poly l) then Pp.feedback Feedback.AddedAxiom

let vernac_declare_instances locality ids pri =
  let glob = not (make_section_locality locality) in
  List.iter (fun id -> Classes.existing_instance glob id pri) ids

let vernac_declare_class id =
  Record.declare_existing_class (Nametab.global id)

(***********)
(* Solving *)

let command_focus = Proof.new_focus_kind ()
let focus_command_cond = Proof.no_cond command_focus


let print_info_trace = ref None

let _ = let open Goptions in declare_int_option {
  optsync = true;
  optdepr = false;
  optname = "print info trace";
  optkey = ["Info" ; "Level"];
  optread = (fun () -> !print_info_trace);
  optwrite = fun n -> print_info_trace := n;
}

let vernac_solve n info tcom b =
  if not (refining ()) then
    error "Unknown command of the non proof-editing mode.";
  let status = Proof_global.with_current_proof (fun etac p ->
    let with_end_tac = if b then Some etac else None in
    let global = match n with SelectAll -> true | _ -> false in
    let info = Option.append info !print_info_trace in
    let (p,status) =
      solve n info (Tacinterp.hide_interp global tcom None) ?with_end_tac p
    in
    (* in case a strict subtree was completed,
       go back to the top of the prooftree *)
    let p = Proof.maximal_unfocus command_focus p in
    p,status) in
    if not status then Pp.feedback Feedback.AddedAxiom
 

  (* A command which should be a tactic. It has been
     added by Christine to patch an error in the design of the proof
     machine, and enables to instantiate existential variables when
     there are no more goals to solve. It cannot be a tactic since
     all tactics fail if there are no further goals to prove. *)

let vernac_solve_existential = instantiate_nth_evar_com

let vernac_set_end_tac tac =
  if not (refining ()) then
    error "Unknown command of the non proof-editing mode.";
  match tac with
  | Tacexpr.TacId [] -> ()
  | _ -> set_end_tac tac
    (* TO DO verifier s'il faut pas mettre exist s | TacId s ici*)

let vernac_set_used_variables e =
  let env = Global.env () in
  let tys =
    List.map snd (Proof.initial_goals (Proof_global.give_me_the_proof ())) in
  let l = Proof_using.process_expr env e tys in
  let vars = Environ.named_context env in
  List.iter (fun id -> 
    if not (List.exists (fun (id',_,_) -> Id.equal id id') vars) then
      errorlabstrm "vernac_set_used_variables"
        (str "Unknown variable: " ++ pr_id id))
    l;
  let _, to_clear = set_used_variables l in
  vernac_solve
    SelectAll None Tacexpr.(TacAtom (Loc.ghost,TacClear(false,to_clear))) false


(*****************************)
(* Auxiliary file management *)

let expand filename =
  Envars.expand_path_macros ~warn:(fun x -> msg_warning (str x)) filename

let vernac_add_loadpath implicit pdir ldiropt =
  let pdir = expand pdir in
  let alias = Option.default Nameops.default_root_prefix ldiropt in
  Mltop.add_rec_path ~unix_path:pdir ~coq_root:alias ~implicit

let vernac_remove_loadpath path =
  Loadpath.remove_load_path (expand path)

  (* Coq syntax for ML or system commands *)

let vernac_add_ml_path isrec path =
  (if isrec then Mltop.add_rec_ml_dir else Mltop.add_ml_dir) (expand path)

let vernac_declare_ml_module locality l =
  let local = make_locality locality in
  Mltop.declare_ml_modules local (List.map expand l)

let vernac_chdir = function
  | None -> msg_notice (str (Sys.getcwd()))
  | Some path ->
      begin
	try Sys.chdir (expand path)
	with Sys_error err -> msg_warning (str "Cd failed: " ++ str err)
      end;
      if_verbose msg_info (str (Sys.getcwd()))


(********************)
(* State management *)

let vernac_write_state file =
  Pfedit.delete_all_proofs ();
  let file = CUnix.make_suffix file ".coq" in
  States.extern_state file

let vernac_restore_state file =
  Pfedit.delete_all_proofs ();
  let file = Loadpath.locate_file (CUnix.make_suffix file ".coq") in
  States.intern_state file

(************)
(* Commands *)

type tacdef_kind =
  | NewTac of Id.t
  | UpdateTac of Nametab.ltac_constant

let is_defined_tac kn =
  try ignore (Tacenv.interp_ltac kn); true with Not_found -> false

let make_absolute_name ident repl =
  let loc = loc_of_reference ident in
  if repl then
    let kn =
      try Nametab.locate_tactic (snd (qualid_of_reference ident))
      with Not_found ->
        Errors.user_err_loc (loc, "",
                    str "There is no Ltac named " ++ pr_reference ident ++ str ".")
    in
    UpdateTac kn
  else
    let id = Constrexpr_ops.coerce_reference_to_id ident in
    let kn = Lib.make_kn id in
    let () = if is_defined_tac kn then
      Errors.user_err_loc (loc, "",
        str "There is already an Ltac named " ++ pr_reference ident ++ str".")
    in
    let is_primitive =
      try
        match Pcoq.parse_string Pcoq.Tactic.tactic (Id.to_string id) with
        | Tacexpr.TacArg _ -> false
        | _ -> true (* most probably TacAtom, i.e. a primitive tactic ident *)
      with e when Errors.noncritical e -> true (* prim tactics with args, e.g. "apply" *)
    in
    let () = if is_primitive then
      msg_warning (str "The Ltac name " ++ pr_reference ident ++
        str " may be unusable because of a conflict with a notation.")
    in
    NewTac id

let register_ltac local isrec tacl =
  let map (ident, repl, body) =
    let name = make_absolute_name ident repl in
    (name, body)
  in
  let rfun = List.map map tacl in
  let recvars =
    let fold accu (op, _) = match op with
    | UpdateTac _ -> accu
    | NewTac id -> (Lib.make_path id, Lib.make_kn id) :: accu
    in
    if isrec then List.fold_left fold [] rfun
    else []
  in
  let ist = Tacintern.make_empty_glob_sign () in
  let map (name, body) =
    let body = Flags.with_option Tacintern.strict_check (Tacintern.intern_tactic_or_tacarg ist) body in
    (name, body)
  in
  let defs () =
    (** Register locally the tactic to handle recursivity. This function affects
        the whole environment, so that we transactify it afterwards. *)
    let iter_rec (sp, kn) = Nametab.push_tactic (Nametab.Until 1) sp kn in
    let () = List.iter iter_rec recvars in
    List.map map rfun
  in
  let defs = Future.transactify defs () in
  let iter (def, tac) = match def with
  | NewTac id ->
    Tacenv.register_ltac false local id tac;
    Flags.if_verbose msg_info (Nameops.pr_id id ++ str " is defined")
  | UpdateTac kn ->
    Tacenv.redefine_ltac local kn tac;
    let name = Nametab.shortest_qualid_of_tactic kn in
    Flags.if_verbose msg_info (Libnames.pr_qualid name ++ str " is redefined")
  in
  List.iter iter defs

let vernac_declare_tactic_definition locality (x,def) =
  let local = make_module_locality locality in
  register_ltac local x def

let vernac_create_hintdb locality id b =
  let local = make_module_locality locality in
  Hints.create_hint_db local id full_transparent_state b

let vernac_remove_hints locality dbs ids =
  let local = make_module_locality locality in
  Hints.remove_hints local dbs (List.map Smartlocate.global_with_alias ids)

let vernac_hints locality poly local lb h =
  let local = enforce_module_locality locality local in
  Hints.add_hints local lb (Hints.interp_hints poly h)

let vernac_syntactic_definition locality lid x local y =
  Dumpglob.dump_definition lid false "syndef";
  let local = enforce_module_locality locality local in
  Metasyntax.add_syntactic_definition (snd lid) x local y

let vernac_declare_implicits locality r l =
  let local = make_section_locality locality in
  match l with
  | [] ->
      Impargs.declare_implicits local (smart_global r)
  | _::_ as imps ->
      Impargs.declare_manual_implicits local (smart_global r) ~enriching:false
	(List.map (List.map (fun (ex,b,f) -> ex, (b,true,f))) imps)

let vernac_declare_arguments locality r l nargs flags =
  let extra_scope_flag = List.mem `ExtraScopes flags in
  let names = List.map (List.map (fun (id, _,_,_,_) -> id)) l in
  let names, rest = List.hd names, List.tl names in
  let scopes = List.map (List.map (fun (_,_, s, _,_) -> s)) l in
  if List.exists (fun na -> not (List.equal Name.equal na names)) rest then
    error "All arguments lists must declare the same names.";
  if not (List.distinct_f Name.compare (List.filter ((!=) Anonymous) names))
  then error "Arguments names must be distinct.";
  let sr = smart_global r in
  let inf_names =
    let ty = Global.type_of_global_unsafe sr in
      Impargs.compute_implicits_names (Global.env ()) ty in
  let rec check li ld ls = match li, ld, ls with
    | [], [], [] -> ()
    | [], Anonymous::ld, (Some _)::ls when extra_scope_flag -> check li ld ls
    | [], _::_, (Some _)::ls when extra_scope_flag ->
       error "Extra notation scopes can be set on anonymous arguments only"
    | [], x::_, _ -> errorlabstrm "vernac_declare_arguments"
                       (str "Extra argument " ++ pr_name x ++ str ".")
    | l, [], _ -> errorlabstrm "vernac_declare_arguments"
                    (str "The following arguments are not declared: " ++
                       prlist_with_sep pr_comma pr_name l ++ str ".")
    | _::li, _::ld, _::ls -> check li ld ls 
    | _ -> assert false in
  let () = match l with
  | [[]] -> ()
  | _ ->
    List.iter2 (fun l -> check inf_names l) (names :: rest) scopes
  in
  (* we take extra scopes apart, and we check they are consistent *)
  let l, scopes = 
    let scopes, rest = List.hd scopes, List.tl scopes in
    if List.exists (List.exists ((!=) None)) rest then
      error "Notation scopes can be given only once";
    if not extra_scope_flag then l, scopes else
    let l, _ = List.split (List.map (List.chop (List.length inf_names)) l) in
    l, scopes in
  (* we interpret _ as the inferred names *)
  let l = match l with
  | [[]] -> l
  | _ ->
    let name_anons = function
      | (Anonymous, a,b,c,d), Name id -> Name id, a,b,c,d
      | x, _ -> x in
    List.map (fun ns -> List.map name_anons (List.combine ns inf_names)) l in
  let names_decl = List.map (List.map (fun (id, _,_,_,_) -> id)) l in
  let renamed_arg = ref None in
  let set_renamed a b =
    if Option.is_empty !renamed_arg && not (Id.equal a b) then renamed_arg := Some(b,a) in
  let some_renaming_specified =
    try
      let names = Arguments_renaming.arguments_names sr in
      not (List.equal (List.equal Name.equal) names names_decl)
    with Not_found -> false in
  let some_renaming_specified, implicits =
    match l with
    | [[]] -> false, [[]]
    | _ ->
    List.fold_map (fun sr il ->
      let sr', impl = List.fold_map (fun b -> function
        | (Anonymous, _,_, true, max), Name id -> assert false
        | (Name x, _,_, true, _), Anonymous ->
            errorlabstrm "vernac_declare_arguments"
              (str "Argument " ++ pr_id x ++ str " cannot be declared implicit.")
        | (Name iid, _,_, true, max), Name id ->
           set_renamed iid id;
           b || not (Id.equal iid id), Some (ExplByName id, max, false)
        | (Name iid, _,_, _, _), Name id ->
           set_renamed iid id;
           b || not (Id.equal iid id), None
        | _ -> b, None)
        sr (List.combine il inf_names) in
      sr || sr', List.map_filter (fun x -> x) impl)
      some_renaming_specified l in
  if some_renaming_specified then
    if not (List.mem `Rename flags) then
      errorlabstrm "vernac_declare_arguments"
        (str "To rename arguments the \"rename\" flag must be specified." ++
           match !renamed_arg with
           | None -> mt ()
           | Some (o,n) ->
              str "\nArgument " ++ pr_id o ++ str " renamed to " ++ pr_id n ++ str ".")
    else
      Arguments_renaming.rename_arguments
        (make_section_locality locality) sr names_decl;
  (* All other infos are in the first item of l *)
  let l = List.hd l in
  let some_implicits_specified = match implicits with
  | [[]] -> false | _ -> true in
  let scopes = List.map (function
    | None -> None
    | Some (o, k) ->
        try ignore (Notation.find_scope k); Some k
        with UserError _ ->
          Some (Notation.find_delimiters_scope o k)) scopes
  in
  let some_scopes_specified = List.exists ((!=) None) scopes in
  let rargs =
    Util.List.map_filter (function (n, true) -> Some n | _ -> None)
      (Util.List.map_i (fun i (_, b, _,_,_) -> i, b) 0 l) in
  if some_scopes_specified || List.mem `ClearScopes flags then
    vernac_arguments_scope locality r scopes;
  if not some_implicits_specified && List.mem `DefaultImplicits flags then
    vernac_declare_implicits locality r []
  else if some_implicits_specified || List.mem `ClearImplicits flags then
    vernac_declare_implicits locality r implicits;
  if nargs >= 0 && nargs < List.fold_left max 0 rargs then
    error "The \"/\" option must be placed after the last \"!\".";
  let no_flags = List.is_empty flags in
  let rec narrow = function
    | #Reductionops.ReductionBehaviour.flag as x :: tl -> x :: narrow tl
    | [] -> [] | _ :: tl -> narrow tl in
  let flags = narrow flags in
  let some_simpl_flags_specified =
    not (List.is_empty rargs) || nargs >= 0 || not (List.is_empty flags) in
  if some_simpl_flags_specified then begin
    match sr with
    | ConstRef _ as c ->
       Reductionops.ReductionBehaviour.set
         (make_section_locality locality) c (rargs, nargs, flags)
    | _ -> errorlabstrm "" (strbrk "Modifiers of the behavior of the simpl tactic are relevant for constants only.")
  end;
  if not (some_renaming_specified ||
          some_implicits_specified ||
          some_scopes_specified ||
          some_simpl_flags_specified) &&
     no_flags then
    msg_warning (strbrk "This command is just asserting the number and names of arguments of " ++ pr_global sr ++ strbrk". If this is what you want add ': assert' to silence the warning. If you want to clear implicit arguments add ': clear implicits'. If you want to clear notation scopes add ': clear scopes'")


let default_env () = {
  Notation_term.ninterp_var_type = Id.Map.empty;
  ninterp_rec_vars = Id.Map.empty;
  ninterp_only_parse = false;
}

let vernac_reserve bl =
  let sb_decl = (fun (idl,c) ->
    let env = Global.env() in
    let sigma = Evd.from_env env in
    let t,ctx = Constrintern.interp_type env sigma c in
    let t = Detyping.detype false [] env (Evd.from_ctx ctx) t in
    let t = Notation_ops.notation_constr_of_glob_constr (default_env ()) t in
    Reserve.declare_reserved_type idl t)
  in List.iter sb_decl bl

let vernac_generalizable locality =
  let local = make_non_locality locality in
  Implicit_quantifiers.declare_generalizable local

let _ =
  declare_bool_option
    { optsync  = false;
      optdepr  = false;
      optname  = "silent";
      optkey   = ["Silent"];
      optread  = is_silent;
      optwrite = make_silent }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "implicit arguments";
      optkey   = ["Implicit";"Arguments"];
      optread  = Impargs.is_implicit_args;
      optwrite = Impargs.make_implicit_args }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "strict implicit arguments";
      optkey   = ["Strict";"Implicit"];
      optread  = Impargs.is_strict_implicit_args;
      optwrite = Impargs.make_strict_implicit_args }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "strong strict implicit arguments";
      optkey   = ["Strongly";"Strict";"Implicit"];
      optread  = Impargs.is_strongly_strict_implicit_args;
      optwrite = Impargs.make_strongly_strict_implicit_args }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "contextual implicit arguments";
      optkey   = ["Contextual";"Implicit"];
      optread  = Impargs.is_contextual_implicit_args;
      optwrite = Impargs.make_contextual_implicit_args }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "implicit status of reversible patterns";
      optkey   = ["Reversible";"Pattern";"Implicit"];
      optread  = Impargs.is_reversible_pattern_implicit_args;
      optwrite = Impargs.make_reversible_pattern_implicit_args }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "maximal insertion of implicit";
      optkey   = ["Maximal";"Implicit";"Insertion"];
      optread  = Impargs.is_maximal_implicit_args;
      optwrite = Impargs.make_maximal_implicit_args }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "automatic introduction of variables";
      optkey   = ["Automatic";"Introduction"];
      optread  = Flags.is_auto_intros;
      optwrite = make_auto_intros }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "coercion printing";
      optkey   = ["Printing";"Coercions"];
      optread  = (fun () -> !Constrextern.print_coercions);
      optwrite = (fun b ->  Constrextern.print_coercions := b) }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "printing of existential variable instances";
      optkey   = ["Printing";"Existential";"Instances"];
      optread  = (fun () -> !Detyping.print_evar_arguments);
      optwrite = (:=) Detyping.print_evar_arguments }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "implicit arguments printing";
      optkey   = ["Printing";"Implicit"];
      optread  = (fun () -> !Constrextern.print_implicits);
      optwrite = (fun b ->  Constrextern.print_implicits := b) }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "implicit arguments defensive printing";
      optkey   = ["Printing";"Implicit";"Defensive"];
      optread  = (fun () -> !Constrextern.print_implicits_defensive);
      optwrite = (fun b ->  Constrextern.print_implicits_defensive := b) }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "projection printing using dot notation";
      optkey   = ["Printing";"Projections"];
      optread  = (fun () -> !Constrextern.print_projections);
      optwrite = (fun b ->  Constrextern.print_projections := b) }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "notations printing";
      optkey   = ["Printing";"Notations"];
      optread  = (fun () -> not !Constrextern.print_no_symbol);
      optwrite = (fun b ->  Constrextern.print_no_symbol := not b) }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "raw printing";
      optkey   = ["Printing";"All"];
      optread  = (fun () -> !Flags.raw_print);
      optwrite = (fun b -> Flags.raw_print := b) }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "record printing";
      optkey   = ["Printing";"Records"];
      optread  = (fun () -> !Flags.record_print);
      optwrite = (fun b -> Flags.record_print := b) }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "use of the program extension";
      optkey   = ["Program";"Mode"];
      optread  = (fun () -> !Flags.program_mode);
      optwrite = (fun b -> Flags.program_mode:=b) }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "universe polymorphism";
      optkey   = ["Universe"; "Polymorphism"];
      optread  = Flags.is_universe_polymorphism;
      optwrite = Flags.make_universe_polymorphism }

let _ =
  declare_int_option
    { optsync  = true;
      optdepr  = false;
      optname  = "the level of inlining during functor application";
      optkey   = ["Inline";"Level"];
      optread  = (fun () -> Some (Flags.get_inline_level ()));
      optwrite = (fun o ->
	           let lev = Option.default Flags.default_inline_level o in
	           Flags.set_inline_level lev) }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "kernel term sharing";
      optkey   = ["Kernel"; "Term"; "Sharing"];
      optread  = (fun () -> !Closure.share);
      optwrite = (fun b -> Closure.share := b) }

(* No more undo limit in the new proof engine.
   The command still exists for compatibility (e.g. with ProofGeneral) *)

let _ =
  declare_int_option
    { optsync  = false;
      optdepr  = true;
      optname  = "the undo limit (OBSOLETE)";
      optkey   = ["Undo"];
      optread  = (fun _ -> None);
      optwrite = (fun _ -> ()) }

let _ =
  declare_int_option
    { optsync  = false;
      optdepr  = false;
      optname  = "the hypotheses limit";
      optkey   = ["Hyps";"Limit"];
      optread  = Flags.print_hyps_limit;
      optwrite = Flags.set_print_hyps_limit }

let _ =
  declare_int_option
    { optsync  = true;
      optdepr  = false;
      optname  = "the printing depth";
      optkey   = ["Printing";"Depth"];
      optread  = Pp_control.get_depth_boxes;
      optwrite = Pp_control.set_depth_boxes }

let _ =
  declare_int_option
    { optsync  = true;
      optdepr  = false;
      optname  = "the printing width";
      optkey   = ["Printing";"Width"];
      optread  = Pp_control.get_margin;
      optwrite = Pp_control.set_margin }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "printing of universes";
      optkey   = ["Printing";"Universes"];
      optread  = (fun () -> !Constrextern.print_universes);
      optwrite = (fun b -> Constrextern.print_universes:=b) }
     
let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "dumping bytecode after compilation";
      optkey   = ["Dump";"Bytecode"];
      optread  = Flags.get_dump_bytecode;
      optwrite = Flags.set_dump_bytecode }

let vernac_debug b =
  set_debug (if b then Tactic_debug.DebugOn 0 else Tactic_debug.DebugOff)

let _ =
  declare_bool_option
    { optsync  = false;
      optdepr  = false;
      optname  = "Ltac debug";
      optkey   = ["Ltac";"Debug"];
      optread  = (fun () -> get_debug () != Tactic_debug.DebugOff);
      optwrite = vernac_debug }

let _ =
  declare_bool_option
    { optsync  = true;
      optdepr  = false;
      optname  = "explicitly parsing implicit arguments";
      optkey   = ["Parsing";"Explicit"];
      optread  = (fun () -> !Constrintern.parsing_explicit);
      optwrite = (fun b ->  Constrintern.parsing_explicit := b) }

let vernac_set_strategy locality l =
  let local = make_locality locality in
  let glob_ref r =
    match smart_global r with
      | ConstRef sp -> EvalConstRef sp
      | VarRef id -> EvalVarRef id
      | _ -> error
          "cannot set an inductive type or a constructor as transparent" in
  let l = List.map (fun (lev,ql) -> (lev,List.map glob_ref ql)) l in
  Redexpr.set_strategy local l

let vernac_set_opacity locality (v,l) =
  let local = make_non_locality locality in
  let glob_ref r =
    match smart_global r with
      | ConstRef sp -> EvalConstRef sp
      | VarRef id -> EvalVarRef id
      | _ -> error
          "cannot set an inductive type or a constructor as transparent" in
  let l = List.map glob_ref l in
  Redexpr.set_strategy local [v,l]

let vernac_set_option locality key = function
  | StringValue s -> set_string_option_value_gen locality key s
  | StringOptValue (Some s) -> set_string_option_value_gen locality key s
  | StringOptValue None -> unset_option_value_gen locality key
  | IntValue n -> set_int_option_value_gen locality key n
  | BoolValue b -> set_bool_option_value_gen locality key b

let vernac_unset_option locality key =
  unset_option_value_gen locality key

let vernac_add_option key lv =
  let f = function
    | StringRefValue s -> (get_string_table key)#add s
    | QualidRefValue locqid -> (get_ref_table key)#add locqid
  in
  try List.iter f lv with Not_found -> error_undeclared_key key

let vernac_remove_option key lv =
  let f = function
  | StringRefValue s -> (get_string_table key)#remove s
  | QualidRefValue locqid -> (get_ref_table key)#remove locqid
  in
  try List.iter f lv with Not_found -> error_undeclared_key key

let vernac_mem_option key lv =
  let f = function
  | StringRefValue s -> (get_string_table key)#mem s
  | QualidRefValue locqid -> (get_ref_table key)#mem locqid
  in
  try List.iter f lv with Not_found -> error_undeclared_key key

let vernac_print_option key =
  try (get_ref_table key)#print
  with Not_found ->
  try (get_string_table key)#print
  with Not_found ->
  try print_option_value key
  with Not_found -> error_undeclared_key key

let get_current_context_of_args = function
  | Some n -> get_goal_context n
  | None -> get_current_context ()

let vernac_check_may_eval redexp glopt rc =
  let (sigma, env) = get_current_context_of_args glopt in
  let sigma', c = interp_open_constr env sigma rc in
  let sigma' = Evarconv.consider_remaining_unif_problems env sigma' in
  Evarconv.check_problems_are_solved env sigma';
  let sigma',nf = Evarutil.nf_evars_and_universes sigma' in
  let pl, uctx = Evd.universe_context sigma' in
  let env = Environ.push_context uctx (Evarutil.nf_env_evar sigma' env) in
  let c = nf c in
  let j =
    if Evarutil.has_undefined_evars sigma' c then
      Evarutil.j_nf_evar sigma' (Retyping.get_judgment_of env sigma' c)
    else
      (* OK to call kernel which does not support evars *)
      Arguments_renaming.rename_typing env c in
  match redexp with
    | None ->
        let l = Evar.Set.union (Evd.evars_of_term j.Environ.uj_val) (Evd.evars_of_term j.Environ.uj_type) in
        let j = { j with Environ.uj_type = Reductionops.nf_betaiota sigma' j.Environ.uj_type } in
	msg_notice (print_judgment env sigma' j ++
                    pr_ne_evar_set (fnl () ++ str "where" ++ fnl ()) (mt ()) sigma' l ++
                    Printer.pr_universe_ctx sigma uctx)
    | Some r ->
        Tacintern.dump_glob_red_expr r;
        let (sigma',r_interp) = interp_redexp env sigma' r in
	let redfun env evm c = snd (fst (reduction_of_red_expr env r_interp) env evm c) in
	msg_notice (print_eval redfun env sigma' rc j)

let vernac_declare_reduction locality s r =
  let local = make_locality locality in
  declare_red_expr local s (snd (interp_redexp (Global.env()) Evd.empty r))

  (* The same but avoiding the current goal context if any *)
let vernac_global_check c =
  let env = Global.env() in
  let sigma = Evd.from_env env in
  let c,ctx = interp_constr env sigma c in
  let senv = Global.safe_env() in
  let cstrs = snd (Evd.evar_universe_context_set Univ.UContext.empty ctx) in
  let senv = Safe_typing.add_constraints cstrs senv in
  let j = Safe_typing.typing senv c in
  let env = Safe_typing.env_of_safe_env senv in
    msg_notice (print_safe_judgment env sigma j)


let get_nth_goal n =
  let pf = get_pftreestate() in
  let {Evd.it=gls ; sigma=sigma; } = Proof.V82.subgoals pf in
  let gl = {Evd.it=List.nth gls (n-1) ; sigma = sigma; } in
  gl
  
exception NoHyp
(* Printing "About" information of a hypothesis of the current goal.
   We only print the type and a small statement to this comes from the
   goal. Precondition: there must be at least one current goal. *)
let print_about_hyp_globs ref_or_by_not glnumopt =
  try
    let gl,id =
      match glnumopt,ref_or_by_not with
      | None,AN (Ident (_loc,id)) -> (* goal number not given, catch any failure *)
	 (try get_nth_goal 1,id with _ -> raise NoHyp)
      | Some n,AN (Ident (_loc,id)) ->  (* goal number given, catch if wong *)
	 (try get_nth_goal n,id
	  with
	    Failure _ -> errorlabstrm "print_about_hyp_globs"
                           (str "No such goal: " ++ int n ++ str "."))
      | _ , _ -> raise NoHyp in
    let hyps = pf_hyps gl in
    let (id,bdyopt,typ) = Context.lookup_named id hyps in
    let natureofid = match bdyopt with
      | None -> "Hypothesis"
      | Some bdy ->"Constant (let in)" in
    v 0 (str (Id.to_string id) ++ str":" ++ pr_constr typ ++ fnl() ++ fnl()
	 ++ str natureofid ++ str " of the goal context.")
  with (* fallback to globals *)
    | NoHyp | Not_found -> print_about ref_or_by_not

	       
let vernac_print = function
  | PrintTables -> msg_notice (print_tables ())
  | PrintFullContext-> msg_notice (print_full_context_typ ())
  | PrintSectionContext qid -> msg_notice (print_sec_context_typ qid)
  | PrintInspect n -> msg_notice (inspect n)
  | PrintGrammar ent -> msg_notice (Metasyntax.pr_grammar ent)
  | PrintLoadPath dir -> (* For compatibility ? *) msg_notice (print_loadpath dir)
  | PrintModules -> msg_notice (print_modules ())
  | PrintModule qid -> print_module qid
  | PrintModuleType qid -> print_modtype qid
  | PrintNamespace ns -> print_namespace ns
  | PrintMLLoadPath -> msg_notice (Mltop.print_ml_path ())
  | PrintMLModules -> msg_notice (Mltop.print_ml_modules ())
  | PrintDebugGC -> msg_notice (Mltop.print_gc ())
  | PrintName qid -> dump_global qid; msg_notice (print_name qid)
  | PrintGraph -> msg_notice (Prettyp.print_graph())
  | PrintClasses -> msg_notice (Prettyp.print_classes())
  | PrintTypeClasses -> msg_notice (Prettyp.print_typeclasses())
  | PrintInstances c -> msg_notice (Prettyp.print_instances (smart_global c))
  | PrintLtac qid -> msg_notice (Tacintern.print_ltac (snd (qualid_of_reference qid)))
  | PrintCoercions -> msg_notice (Prettyp.print_coercions())
  | PrintCoercionPaths (cls,clt) ->
      msg_notice (Prettyp.print_path_between (cl_of_qualid cls) (cl_of_qualid clt))
  | PrintCanonicalConversions -> msg_notice (Prettyp.print_canonical_projections ())
  | PrintUniverses (b, None) ->
     let univ = Global.universes () in
     let univ = if b then Univ.sort_universes univ else univ in
     let pr_remaining =
       if Global.is_joined_environment () then mt ()
       else str"There may remain asynchronous universe constraints"
     in
     msg_notice (Univ.pr_universes Universes.pr_with_global_universes univ ++ pr_remaining)
  | PrintUniverses (b, Some s) -> dump_universes b s
  | PrintHint r -> msg_notice (Hints.pr_hint_ref (smart_global r))
  | PrintHintGoal -> msg_notice (Hints.pr_applicable_hint ())
  | PrintHintDbName s -> msg_notice (Hints.pr_hint_db_by_name s)
  | PrintRewriteHintDbName s -> msg_notice (Autorewrite.print_rewrite_hintdb s)
  | PrintHintDb -> msg_notice (Hints.pr_searchtable ())
  | PrintScopes ->
      msg_notice (Notation.pr_scopes (Constrextern.without_symbols pr_lglob_constr))
  | PrintScope s ->
      msg_notice (Notation.pr_scope (Constrextern.without_symbols pr_lglob_constr) s)
  | PrintVisibility s ->
      msg_notice (Notation.pr_visibility (Constrextern.without_symbols pr_lglob_constr) s)
  | PrintAbout (ref_or_by_not,glnumopt) ->
     msg_notice (print_about_hyp_globs ref_or_by_not glnumopt)
  | PrintImplicit qid ->
    dump_global qid; msg_notice (print_impargs qid)
  | PrintAssumptions (o,t,r) ->
      (* Prints all the axioms and section variables used by a term *)
      let gr = smart_global r in
      let cstr = printable_constr_of_global gr in
      let st = Conv_oracle.get_transp_state (Environ.oracle (Global.env())) in
      let nassums =
	Assumptions.assumptions st ~add_opaque:o ~add_transparent:t gr cstr in
      msg_notice (Printer.pr_assumptionset (Global.env ()) nassums)
  | PrintStrategy r -> print_strategy r

let global_module r =
  let (loc,qid) = qualid_of_reference r in
  try Nametab.full_name_module qid
  with Not_found ->
    user_err_loc (loc, "global_module",
      str "Module/section " ++ pr_qualid qid ++ str " not found.")

let interp_search_restriction = function
  | SearchOutside l -> (List.map global_module l, true)
  | SearchInside l -> (List.map global_module l, false)

open Search

let interp_search_about_item env =
  function
  | SearchSubPattern pat ->
      let _,pat = intern_constr_pattern env pat in
      GlobSearchSubPattern pat
  | SearchString (s,None) when Id.is_valid s ->
      GlobSearchString s
  | SearchString (s,sc) ->
      try
	let ref =
	  Notation.interp_notation_as_global_reference Loc.ghost
	    (fun _ -> true) s sc in
	GlobSearchSubPattern (Pattern.PRef ref)
      with UserError _ ->
	errorlabstrm "interp_search_about_item"
          (str "Unable to interp \"" ++ str s ++ str "\" either as a reference or as an identifier component")

let vernac_search s gopt r =
  let r = interp_search_restriction r in
  let env,gopt =
    match gopt with | None ->
      (* 1st goal by default if it exists, otherwise no goal at all *)
      (try snd (Pfedit.get_goal_context 1) , Some 1
       with _ -> Global.env (),None)
    (* if goal selector is given and wrong, then let exceptions be raised. *)
    | Some g -> snd (Pfedit.get_goal_context g) , Some g
  in
  let get_pattern c = snd (intern_constr_pattern env c) in
  match s with
  | SearchPattern c ->
      msg_notice (Search.search_pattern gopt (get_pattern c) r)
  | SearchRewrite c ->
      msg_notice (Search.search_rewrite gopt (get_pattern c) r)
  | SearchHead c ->
      msg_notice (Search.search_by_head gopt (get_pattern c) r)
  | SearchAbout sl ->
     msg_notice (Search.search_about gopt (List.map (on_snd (interp_search_about_item env)) sl) r)

let vernac_locate = function
  | LocateAny (AN qid) -> msg_notice (print_located_qualid qid)
  | LocateTerm (AN qid) -> msg_notice (print_located_term qid)
  | LocateAny (ByNotation (_, ntn, sc)) (** TODO : handle Ltac notations *)
  | LocateTerm (ByNotation (_, ntn, sc)) ->
      msg_notice
        (Notation.locate_notation
          (Constrextern.without_symbols pr_lglob_constr) ntn sc)
  | LocateLibrary qid -> print_located_library qid
  | LocateModule qid -> msg_notice (print_located_module qid)
  | LocateTactic qid -> msg_notice (print_located_tactic qid)
  | LocateFile f -> msg_notice (locate_file f)

let vernac_register id r =
 if Pfedit.refining () then
    error "Cannot register a primitive while in proof editing mode.";
  let t = (Constrintern.global_reference (snd id)) in
  if not (isConst t) then
    error "Register inline: a constant is expected";
  let kn = destConst t in
  match r with
  | RegisterInline -> Global.register_inline (Univ.out_punivs kn)

(********************)
(* Proof management *)

let vernac_focus gln =
  Proof_global.simple_with_current_proof (fun _ p ->
    match gln with
      | None -> Proof.focus focus_command_cond () 1 p
      | Some 0 ->
         Errors.error "Invalid goal number: 0. Goal numbering starts with 1."
      | Some n ->
         Proof.focus focus_command_cond () n p)

  (* Unfocuses one step in the focus stack. *)
let vernac_unfocus () =
  Proof_global.simple_with_current_proof
    (fun _ p -> Proof.unfocus command_focus p ())

(* Checks that a proof is fully unfocused. Raises an error if not. *)
let vernac_unfocused () =
  let p = Proof_global.give_me_the_proof () in
  if Proof.unfocused p then
    msg_notice (str"The proof is indeed fully unfocused.")
  else
    error "The proof is not fully unfocused."


(* BeginSubproof / EndSubproof. 
    BeginSubproof (vernac_subproof) focuses on the first goal, or the goal
    given as argument.
    EndSubproof (vernac_end_subproof) unfocuses from a BeginSubproof, provided
    that the proof of the goal has been completed.
*)
let subproof_kind = Proof.new_focus_kind ()
let subproof_cond = Proof.done_cond subproof_kind

let vernac_subproof gln =
  Proof_global.simple_with_current_proof (fun _ p ->
    match gln with
    | None -> Proof.focus subproof_cond () 1 p
    | Some n -> Proof.focus subproof_cond () n p)

let vernac_end_subproof () =
  Proof_global.simple_with_current_proof (fun _ p ->
    Proof.unfocus subproof_kind p ())

let vernac_bullet (bullet:Proof_global.Bullet.t) =
  Proof_global.simple_with_current_proof (fun _ p ->
    Proof_global.Bullet.put p bullet)

let vernac_show = function
  | ShowGoal goalref ->
    let info = match goalref with
      | OpenSubgoals -> pr_open_subgoals ()
      | NthGoal n -> pr_nth_open_subgoal n
      | GoalId id -> pr_goal_by_id id
      | GoalUid id -> pr_goal_by_uid id
    in
    msg_notice info
  | ShowGoalImplicitly None ->
      Constrextern.with_implicits msg_notice (pr_open_subgoals ())
  | ShowGoalImplicitly (Some n) ->
      Constrextern.with_implicits msg_notice (pr_nth_open_subgoal n)
  | ShowProof -> show_proof ()
  | ShowNode -> show_node ()
  | ShowScript -> Stm.show_script ()
  | ShowExistentials -> show_top_evars ()
  | ShowUniverses -> show_universes ()
  | ShowTree -> show_prooftree ()
  | ShowProofNames ->
      msg_notice (pr_sequence pr_id (Pfedit.get_all_proof_names()))
  | ShowIntros all -> show_intro all
  | ShowMatch id -> show_match id
  | ShowThesis -> show_thesis ()


let vernac_check_guard () =
  let pts = get_pftreestate () in
  let pfterm = List.hd (Proof.partial_proof pts) in
  let message =
    try
      let { Evd.it=gl ; sigma=sigma } = Proof.V82.top_goal pts in
      Inductiveops.control_only_guard (Goal.V82.env sigma gl)
	pfterm;
      (str "The condition holds up to here")
    with UserError(_,s) ->
      (str ("Condition violated: ") ++s)
  in
  msg_notice message

exception End_of_input

let vernac_load interp fname =
  let parse_sentence = Flags.with_option Flags.we_are_parsing
    (fun po ->
    match Pcoq.Gram.entry_parse Pcoq.main_entry po with
      | Some x -> x
      | None -> raise End_of_input) in
  let fname =
    Envars.expand_path_macros ~warn:(fun x -> msg_warning (str x)) fname in
  let fname = CUnix.make_suffix fname ".v" in
  let input =
    let longfname = Loadpath.locate_file fname in
    let in_chan = open_utf8_file_in longfname in
    Pcoq.Gram.parsable (Stream.of_channel in_chan) in
  try while true do interp (snd (parse_sentence input)) done
  with End_of_input -> ()


(* "locality" is the prefix "Local" attribute, while the "local" component
 * is the outdated/deprecated "Local" attribute of some vernacular commands
 * still parsed as the obsolete_locality grammar entry for retrocompatibility.
 * loc is the Loc.t of the vernacular command being interpreted. *)
let interp ?proof ~loc locality poly c =
  prerr_endline ("interpreting: " ^ Pp.string_of_ppcmds (Ppvernac.pr_vernac c));
  match c with
  (* Done later in this file *)
  | VernacLoad _ -> assert false
  | VernacFail _ -> assert false
  | VernacTime _ -> assert false
  | VernacRedirect _ -> assert false
  | VernacTimeout _ -> assert false
  | VernacStm _ -> assert false

  | VernacError e -> raise e

  (* Syntax *)
  | VernacTacticNotation (n,r,e) ->
      Metasyntax.add_tactic_notation (make_module_locality locality,n,r,e)
  | VernacSyntaxExtension (local,sl) ->
      vernac_syntax_extension locality local sl
  | VernacDelimiters (sc,lr) -> vernac_delimiters sc lr
  | VernacBindScope (sc,rl) -> vernac_bind_scope sc rl
  | VernacOpenCloseScope (local, s) -> vernac_open_close_scope locality local s
  | VernacArgumentsScope (qid,scl) -> vernac_arguments_scope locality qid scl
  | VernacInfix (local,mv,qid,sc) -> vernac_infix locality local mv qid sc
  | VernacNotation (local,c,infpl,sc) ->
      vernac_notation locality local c infpl sc
  | VernacNotationAddFormat(n,k,v) ->
      Metasyntax.add_notation_extra_printing_rule n k v

  (* Gallina *)
  | VernacDefinition (k,lid,d) -> vernac_definition locality poly k lid d
  | VernacStartTheoremProof (k,l,top) -> vernac_start_proof locality poly k l top
  | VernacEndProof e -> vernac_end_proof ?proof e
  | VernacExactProof c -> vernac_exact_proof c
  | VernacAssumption (stre,nl,l) -> vernac_assumption locality poly stre l nl
  | VernacInductive (priv,finite,l) -> vernac_inductive poly priv finite l
  | VernacFixpoint (local, l) -> vernac_fixpoint locality poly local l
  | VernacCoFixpoint (local, l) -> vernac_cofixpoint locality poly local l
  | VernacScheme l -> vernac_scheme l
  | VernacCombinedScheme (id, l) -> vernac_combined_scheme id l
  | VernacUniverse l -> vernac_universe loc poly l
  | VernacConstraint l -> vernac_constraint loc poly l

  (* Modules *)
  | VernacDeclareModule (export,lid,bl,mtyo) ->
      vernac_declare_module export lid bl mtyo
  | VernacDefineModule (export,lid,bl,mtys,mexprl) ->
      vernac_define_module export lid bl mtys mexprl
  | VernacDeclareModuleType (lid,bl,mtys,mtyo) ->
      vernac_declare_module_type lid bl mtys mtyo
  | VernacInclude in_asts ->
      vernac_include in_asts
  (* Gallina extensions *)
  | VernacBeginSection lid -> vernac_begin_section lid

  | VernacEndSegment lid -> vernac_end_segment lid

  | VernacNameSectionHypSet (lid, set) -> vernac_name_sec_hyp lid set

  | VernacRequire (from, export, qidl) -> vernac_require from export qidl
  | VernacImport (export,qidl) -> vernac_import export qidl
  | VernacCanonical qid -> vernac_canonical qid
  | VernacCoercion (local,r,s,t) -> vernac_coercion locality poly local r s t
  | VernacIdentityCoercion (local,(_,id),s,t) ->
      vernac_identity_coercion locality poly local id s t

  (* Type classes *)
  | VernacInstance (abst, sup, inst, props, pri) ->
      vernac_instance abst locality poly sup inst props pri
  | VernacContext sup -> vernac_context poly sup
  | VernacDeclareInstances (ids, pri) -> vernac_declare_instances locality ids pri
  | VernacDeclareClass id -> vernac_declare_class id

  (* Solving *)
  | VernacSolve (n,info,tac,b) -> vernac_solve n info tac b
  | VernacSolveExistential (n,c) -> vernac_solve_existential n c

  (* Auxiliary file and library management *)
  | VernacAddLoadPath (isrec,s,alias) -> vernac_add_loadpath isrec s alias
  | VernacRemoveLoadPath s -> vernac_remove_loadpath s
  | VernacAddMLPath (isrec,s) -> vernac_add_ml_path isrec s
  | VernacDeclareMLModule l -> vernac_declare_ml_module locality l
  | VernacChdir s -> vernac_chdir s

  (* State management *)
  | VernacWriteState s -> vernac_write_state s
  | VernacRestoreState s -> vernac_restore_state s

  (* Resetting *)
  | VernacResetName _ -> anomaly (str "VernacResetName not handled by Stm")
  | VernacResetInitial -> anomaly (str "VernacResetInitial not handled by Stm")
  | VernacBack _ -> anomaly (str "VernacBack not handled by Stm")
  | VernacBackTo _ -> anomaly (str "VernacBackTo not handled by Stm")

  (* Commands *)
  | VernacDeclareTacticDefinition def ->
      vernac_declare_tactic_definition locality def
  | VernacCreateHintDb (dbname,b) -> vernac_create_hintdb locality dbname b
  | VernacRemoveHints (dbnames,ids) -> vernac_remove_hints locality dbnames ids
  | VernacHints (local,dbnames,hints) ->
      vernac_hints locality poly local dbnames hints
  | VernacSyntacticDefinition (id,c,local,b) ->
      vernac_syntactic_definition locality  id c local b
  | VernacDeclareImplicits (qid,l) ->
      vernac_declare_implicits locality qid l
  | VernacArguments (qid, l, narg, flags) ->
      vernac_declare_arguments locality qid l narg flags 
  | VernacReserve bl -> vernac_reserve bl
  | VernacGeneralizable gen -> vernac_generalizable locality gen
  | VernacSetOpacity qidl -> vernac_set_opacity locality qidl
  | VernacSetStrategy l -> vernac_set_strategy locality l
  | VernacSetOption (key,v) -> vernac_set_option locality key v
  | VernacUnsetOption key -> vernac_unset_option locality key
  | VernacRemoveOption (key,v) -> vernac_remove_option key v
  | VernacAddOption (key,v) -> vernac_add_option key v
  | VernacMemOption (key,v) -> vernac_mem_option key v
  | VernacPrintOption key -> vernac_print_option key
  | VernacCheckMayEval (r,g,c) -> vernac_check_may_eval r g c
  | VernacDeclareReduction (s,r) -> vernac_declare_reduction locality s r
  | VernacGlobalCheck c -> vernac_global_check c
  | VernacPrint p -> vernac_print p
  | VernacSearch (s,g,r) -> vernac_search s g r
  | VernacLocate l -> vernac_locate l
  | VernacRegister (id, r) -> vernac_register id r
  | VernacComments l -> if_verbose msg_info (str "Comments ok\n")
  | VernacNop -> ()

  (* The STM should handle that, but LOAD bypasses the STM... *)
  | VernacAbort id -> msg_warning (str "VernacAbort not handled by Stm")
  | VernacAbortAll -> msg_warning (str "VernacAbortAll not handled by Stm")
  | VernacRestart -> msg_warning (str "VernacRestart not handled by Stm")
  | VernacUndo _ -> msg_warning (str "VernacUndo not handled by Stm")
  | VernacUndoTo _ -> msg_warning (str "VernacUndoTo not handled by Stm")
  | VernacBacktrack _ -> msg_warning (str "VernacBacktrack not handled by Stm")
  
  (* Proof management *)
  | VernacGoal t -> vernac_start_proof locality poly Theorem [None,([],t,None)] false
  | VernacFocus n -> vernac_focus n
  | VernacUnfocus -> vernac_unfocus ()
  | VernacUnfocused -> vernac_unfocused ()
  | VernacBullet b -> vernac_bullet b
  | VernacSubproof n -> vernac_subproof n
  | VernacEndSubproof -> vernac_end_subproof ()
  | VernacShow s -> vernac_show s
  | VernacCheckGuard -> vernac_check_guard ()
  | VernacProof (None, None) ->
      Aux_file.record_in_aux_at loc "VernacProof" "tac:no using:no"
  | VernacProof (Some tac, None) ->
      Aux_file.record_in_aux_at loc "VernacProof" "tac:yes using:no";
      vernac_set_end_tac tac
  | VernacProof (None, Some l) ->
      Aux_file.record_in_aux_at loc "VernacProof" "tac:no using:yes";
      vernac_set_used_variables l
  | VernacProof (Some tac, Some l) -> 
      Aux_file.record_in_aux_at loc "VernacProof" "tac:yes using:yes";
      vernac_set_end_tac tac; vernac_set_used_variables l
  | VernacProofMode mn -> Proof_global.set_proof_mode mn
  (* Toplevel control *)
  | VernacToplevelControl e -> raise e

  (* Extensions *)
  | VernacExtend (opn,args) -> Vernacinterp.call ?locality (opn,args)

  (* Handled elsewhere *)
  | VernacProgram _
  | VernacPolymorphic _
  | VernacLocal _ -> assert false

(* Vernaculars that take a locality flag *)
let check_vernac_supports_locality c l =
  match l, c with
  | None, _ -> ()
  | Some _, (
      VernacTacticNotation _
    | VernacOpenCloseScope _
    | VernacSyntaxExtension _ | VernacInfix _ | VernacNotation _
    | VernacDefinition _ | VernacFixpoint _ | VernacCoFixpoint _
    | VernacAssumption _ | VernacStartTheoremProof _
    | VernacCoercion _ | VernacIdentityCoercion _
    | VernacInstance _ | VernacDeclareInstances _
    | VernacDeclareMLModule _
    | VernacDeclareTacticDefinition _
    | VernacCreateHintDb _ | VernacRemoveHints _ | VernacHints _
    | VernacSyntacticDefinition _
    | VernacArgumentsScope _ | VernacDeclareImplicits _ | VernacArguments _
    | VernacGeneralizable _
    | VernacSetOpacity _ | VernacSetStrategy _
    | VernacSetOption _ | VernacUnsetOption _
    | VernacDeclareReduction _
    | VernacExtend _ 
    | VernacInductive _) -> ()
  | Some _, _ -> Errors.error "This command does not support Locality"

(* Vernaculars that take a polymorphism flag *)
let check_vernac_supports_polymorphism c p =
  match p, c with
  | None, _ -> ()
  | Some _, (
      VernacDefinition _ | VernacFixpoint _ | VernacCoFixpoint _
    | VernacAssumption _ | VernacInductive _ 
    | VernacStartTheoremProof _
    | VernacCoercion _ | VernacIdentityCoercion _
    | VernacInstance _ | VernacDeclareInstances _
    | VernacHints _ | VernacContext _
    | VernacExtend _ | VernacUniverse _ | VernacConstraint _) -> ()
  | Some _, _ -> Errors.error "This command does not support Polymorphism"

let enforce_polymorphism = function
  | None -> Flags.is_universe_polymorphism ()
  | Some b -> b

(** A global default timeout, controled by option "Set Default Timeout n".
    Use "Unset Default Timeout" to deactivate it (or set it to 0). *)

let default_timeout = ref None

let _ =
  Goptions.declare_int_option
    { Goptions.optsync  = true;
      Goptions.optdepr  = false;
      Goptions.optname  = "the default timeout";
      Goptions.optkey   = ["Default";"Timeout"];
      Goptions.optread  = (fun () -> !default_timeout);
      Goptions.optwrite = ((:=) default_timeout) }

(** When interpreting a command, the current timeout is initially
    the default one, but may be modified locally by a Timeout command. *)

let current_timeout = ref None

let vernac_timeout f =
  match !current_timeout, !default_timeout with
    | Some n, _ | None, Some n ->
      let f () = f (); current_timeout := None in
      Control.timeout n f Timeout
    | None, None -> f ()

let restore_timeout () = current_timeout := None

let locate_if_not_already loc (e, info) =
  match Loc.get_loc info with
  | None -> (e, Loc.add_loc info loc)
  | Some l -> if Loc.is_ghost l then (e, Loc.add_loc info loc) else (e, info)

exception HasNotFailed
exception HasFailed of std_ppcmds

let with_fail b f =
  if not b then f ()
  else begin try
      (* If the command actually works, ignore its effects on the state.
       * Note that error has to be printed in the right state, hence
       * within the purified function *)
      Future.purify
        (fun v ->
           try f v; raise HasNotFailed
           with
           | HasNotFailed as e -> raise e
           | e ->
              let e = Errors.push e in
              raise (HasFailed (Errors.iprint
                (Cerrors.process_vernac_interp_error ~allow_uncaught:false ~with_header:false e))))
        ()
    with e when Errors.noncritical e -> 
      let (e, _) = Errors.push e in
      match e with
      | HasNotFailed ->
          errorlabstrm "Fail" (str "The command has not failed!")
      | HasFailed msg ->
          if is_verbose () || !test_mode || !ide_slave then msg_info
            (str "The command has indeed failed with message:" ++ fnl () ++ msg)
      | _ -> assert false
  end

let interp ?(verbosely=true) ?proof (loc,c) =
  let orig_program_mode = Flags.is_program_mode () in
  let rec aux ?locality ?polymorphism isprogcmd = function
    | VernacProgram c when not isprogcmd -> aux ?locality ?polymorphism true c
    | VernacProgram _ -> Errors.error "Program mode specified twice"
    | VernacLocal (b, c) when Option.is_empty locality -> 
      aux ~locality:b ?polymorphism isprogcmd c
    | VernacPolymorphic (b, c) when polymorphism = None -> 
      aux ?locality ~polymorphism:b isprogcmd c
    | VernacPolymorphic (b, c) -> Errors.error "Polymorphism specified twice"
    | VernacLocal _ -> Errors.error "Locality specified twice"
    | VernacStm (Command c) -> aux ?locality ?polymorphism isprogcmd c
    | VernacStm (PGLast c) -> aux ?locality ?polymorphism isprogcmd c
    | VernacStm _ -> assert false (* Done by Stm *)
    | VernacFail v ->
        with_fail true (fun () -> aux ?locality ?polymorphism isprogcmd v)
    | VernacTimeout (n,v) ->
        current_timeout := Some n;
        aux ?locality ?polymorphism isprogcmd v
    | VernacRedirect (s, v) ->
         Pp.with_output_to_file s (aux_list ?locality ?polymorphism isprogcmd) v;
    | VernacTime v ->
        System.with_time !Flags.time
          (aux_list ?locality ?polymorphism isprogcmd) v;
    | VernacLoad (_,fname) -> vernac_load (aux false) fname
    | c -> 
        check_vernac_supports_locality c locality;
        check_vernac_supports_polymorphism c polymorphism;
	let poly = enforce_polymorphism polymorphism in
        Obligations.set_program_mode isprogcmd;
        try
          vernac_timeout begin fun () ->
          if verbosely
            then Flags.verbosely (interp ?proof ~loc locality poly) c
            else Flags.silently  (interp ?proof ~loc locality poly) c;
          if orig_program_mode || not !Flags.program_mode || isprogcmd then
            Flags.program_mode := orig_program_mode
          end
        with
        | reraise when
              (match reraise with
              | Timeout -> true
              | e -> Errors.noncritical e)
          ->
            let e = Errors.push reraise in
            let e = locate_if_not_already loc e in
            let () = restore_timeout () in
            Flags.program_mode := orig_program_mode;
            iraise e
  and aux_list ?locality ?polymorphism isprogcmd l =
    List.iter (aux false) (List.map snd l)
  in
    if verbosely then Flags.verbosely (aux false) c
    else aux false c

let () = Hook.set Stm.interp_hook interp
let () = Hook.set Stm.with_fail_hook with_fail