(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* unit; solve : int -> unit; abort : string -> unit; search : searchable -> dir_path list * bool -> unit; print_name : reference -> unit; print_check : Environ.env -> Environ.unsafe_judgment -> unit; print_eval : Reductionops.reduction_function -> Environ.env -> Evd.evar_map -> constr_expr -> Environ.unsafe_judgment -> unit; show_goal : int option -> unit } let pcoq = ref None let set_pcoq_hook f = pcoq := Some f (* Misc *) let cl_of_qualid = function | FunClass -> Classops.CL_FUN | SortClass -> Classops.CL_SORT | RefClass r -> Class.class_of_global (global_with_alias r) (*******************) (* "Show" commands *) let show_proof () = let pts = get_pftreestate () in let cursor = cursor_of_pftreestate pts in let evc = evc_of_pftreestate pts in let (pfterm,meta_types) = extract_open_pftreestate pts in msgnl (str"LOC: " ++ prlist_with_sep pr_spc pr_int (List.rev cursor) ++ fnl () ++ str"Subgoals" ++ fnl () ++ prlist (fun (mv,ty) -> Nameops.pr_meta mv ++ str" -> " ++ pr_ltype ty ++ fnl ()) meta_types ++ str"Proof: " ++ pr_lconstr (Evarutil.nf_evar evc pfterm)) let show_node () = let pts = get_pftreestate () in let pf = proof_of_pftreestate pts and cursor = cursor_of_pftreestate pts in msgnl (prlist_with_sep pr_spc pr_int (List.rev cursor) ++ fnl () ++ pr_goal (goal_of_proof pf) ++ fnl () ++ (match pf.Proof_type.ref with | None -> (str"BY ") | Some(r,spfl) -> (str"BY " ++ pr_rule r ++ fnl () ++ str" " ++ hov 0 (prlist_with_sep pr_fnl pr_goal (List.map goal_of_proof spfl))))) let show_script () = let pts = get_pftreestate () in let pf = proof_of_pftreestate pts and evc = evc_of_pftreestate pts in msgnl_with !Pp_control.deep_ft (print_treescript evc pf) let show_thesis () = msgnl (anomaly "TODO" ) let show_top_evars () = let pfts = get_pftreestate () in let gls = top_goal_of_pftreestate pfts in let sigma = project gls in msg (pr_evars_int 1 (Evarutil.non_instantiated sigma)) let show_prooftree () = let pts = get_pftreestate () in let pf = proof_of_pftreestate pts and evc = evc_of_pftreestate pts in msg (print_proof evc (Global.named_context()) pf) let print_subgoals () = if_verbose (fun () -> msg (pr_open_subgoals ())) () (* Simulate the Intro(s) tactic *) let show_intro all = let pf = get_pftreestate() in let gl = nth_goal_of_pftreestate 1 pf in let l,_= Sign.decompose_prod_assum (strip_outer_cast (pf_concl gl)) in if all then let lid = Tactics.find_intro_names l gl in msgnl (hov 0 (prlist_with_sep spc pr_id lid)) else try let n = list_last l in msgnl (pr_id (List.hd (Tactics.find_intro_names [n] gl))) with Failure "list_last" -> message "" let id_of_name = function | Names.Anonymous -> id_of_string "x" | Names.Name x -> x (* Building of match expression *) (* From ide/coq.ml *) 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 | Libnames.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 n t l -> let (al,_) = Term.decompose_prod t in let al,_ = Util.list_chop (List.length al - np) al in let rec rename avoid = function | [] -> [] | (n,_)::l -> let n' = Termops.next_global_ident_away true (id_of_name n) avoid in string_of_id n' :: rename (n'::avoid) l in let al' = rename [] (List.rev al) in (string_of_id n :: al') :: l) carr tarr [] | _ -> raise Not_found let show_match id = try let s = string_of_id (snd id) in let patterns = make_cases s in let cases = List.fold_left (fun acc x -> match x with | [] -> assert false | [x] -> "| "^ x ^ " => \n" ^ acc | x::l -> "| (" ^ List.fold_left (fun acc s -> acc ^ " " ^ s) x l ^ ")" ^ " => \n" ^ acc) "end" patterns in msg (str ("match # with\n" ^ cases)) with Not_found -> error "Unknown inductive type." (* "Print" commands *) let print_path_entry (s,l) = (str (string_of_dirpath l) ++ str " " ++ tbrk (0,0) ++ str s) let print_loadpath () = let l = Library.get_full_load_paths () in msgnl (Pp.t (str "Logical Path: " ++ tab () ++ str "Physical path:" ++ fnl () ++ prlist_with_sep pr_fnl print_path_entry l)) let print_modules () = let opened = Library.opened_libraries () and loaded = Library.loaded_libraries () in let loaded_opened = list_intersect loaded opened and only_loaded = list_subtract 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,_)) -> msgnl (Printmod.print_module (Printmod.printable_body dirpath) mp) | _ -> raise Not_found with Not_found -> msgnl (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 msgnl (Printmod.print_modtype kn) with Not_found -> msgnl (str"Unknown Module Type " ++ pr_qualid qid) let dump_universes s = let output = open_out s in try Univ.dump_universes output (Global.universes ()); close_out output; msgnl (str ("Universes written to file \""^s^"\".")) with e -> close_out output; raise e (*********************) (* "Locate" commands *) let locate_file f = try let _,file = System.where_in_path false (Library.get_load_paths ()) f in msgnl (str file) with Not_found -> msgnl (hov 0 (str"Can't find file" ++ spc () ++ str f ++ spc () ++ str"on loadpath")) let msg_found_library = function | Library.LibLoaded, fulldir, file -> msgnl (hov 0 (pr_dirpath fulldir ++ strbrk " has been loaded from file " ++ str file)) | Library.LibInPath, fulldir, file -> msgnl (hov 0 (pr_dirpath fulldir ++ strbrk " is bound to file " ++ str file)) let msg_notfound_library loc qid = function | Library.LibUnmappedDir -> let dir = fst (repr_qualid qid) in user_err_loc (loc,"locate_library", strbrk "Cannot find a physical path bound to logical path " ++ pr_dirpath dir ++ str".") | Library.LibNotFound -> msgnl (hov 0 (strbrk "Unable to locate library " ++ pr_qualid qid ++ str".")) | e -> assert false let print_located_library r = let (loc,qid) = qualid_of_reference r in try msg_found_library (Library.locate_qualified_library false qid) with e -> msg_notfound_library loc qid e let print_located_module r = let (loc,qid) = qualid_of_reference r in let msg = try let dir = Nametab.full_name_module qid in str "Module " ++ pr_dirpath dir with Not_found -> (if fst (repr_qualid qid) = empty_dirpath then str "No module is referred to by basename " else str "No module is referred to by name ") ++ pr_qualid qid in msgnl msg let global_with_alias r = let gr = global_with_alias r in Dumpglob.add_glob (loc_of_reference r) gr; gr (**********) (* Syntax *) let vernac_syntax_extension = Metasyntax.add_syntax_extension let vernac_delimiters = Metasyntax.add_delimiters let vernac_bind_scope sc cll = List.iter (fun cl -> Metasyntax.add_class_scope sc (cl_of_qualid cl)) cll let vernac_open_close_scope = Notation.open_close_scope let vernac_arguments_scope local r scl = Notation.declare_arguments_scope local (global_with_alias r) scl let vernac_infix = Metasyntax.add_infix let vernac_notation = Metasyntax.add_notation (***********) (* Gallina *) let start_proof_and_print k l hook = start_proof_com k l hook; print_subgoals (); if !pcoq <> None then (Option.get !pcoq).start_proof () let vernac_definition (local,_,_ as k) (loc,id as lid) def hook = Dumpglob.dump_definition lid false "def"; (match def with | ProveBody (bl,t) -> (* local binders, typ *) if Lib.is_modtype () then errorlabstrm "Vernacentries.VernacDefinition" (str "Proof editing mode not supported in module types.") else let hook _ _ = () in start_proof_and_print (local,DefinitionBody Definition) [Some lid, (bl,t)] hook | DefineBody (bl,red_option,c,typ_opt) -> let red_option = match red_option with | None -> None | Some r -> let (evc,env)= Command.get_current_context () in Some (interp_redexp env evc r) in declare_definition id k bl red_option c typ_opt hook) let vernac_start_proof kind l lettop hook = 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."); if Lib.is_modtype () then errorlabstrm "Vernacentries.StartProof" (str "Proof editing mode not supported in module types."); start_proof_and_print (Global, Proof kind) l hook let vernac_end_proof = function | Admitted -> admit () | Proved (is_opaque,idopt) -> if not !Flags.print_emacs then if_verbose show_script (); match idopt with | None -> save_named is_opaque | Some ((_,id),None) -> save_anonymous is_opaque id | Some ((_,id),Some kind) -> save_anonymous_with_strength kind is_opaque id (* A stupid macro that should be replaced by ``Exact c. Save.'' all along the theories [??] *) let vernac_exact_proof c = let pfs = top_of_tree (get_pftreestate()) in let pf = proof_of_pftreestate pfs in if (is_leaf_proof pf) then begin by (Tactics.exact_proof c); save_named true end else errorlabstrm "Vernacentries.ExactProof" (strbrk "Command 'Proof ...' can only be used at the beginning of the proof.") let vernac_assumption kind l nl= let global = fst kind = Global 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; declare_assumption idl is_coe kind [] c false false nl) l let vernac_record k finite struc binders sort nameopt cfs = let const = match nameopt with | None -> add_prefix "Build_" (snd (snd struc)) | Some (_,id as lid) -> Dumpglob.dump_definition lid false "constr"; id in if Dumpglob.dump () then ( Dumpglob.dump_definition (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,finite,struc,binders,cfs,const,sort)) let vernac_inductive finite indl = if Dumpglob.dump () then List.iter (fun ((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 | [ ( id , bl , c ,RecordDecl (b,oc,fs) ), None ] -> vernac_record b finite (false,id) bl c oc fs | [ ( _ , _ , _ , RecordDecl _ ) , _ ] -> Util.error "where clause not supported for (co)inductive records" | _ -> let unpack = function | ( id , bl , c , Constructors l ) , ntn -> ( id , bl , c , l ) , ntn | _ -> Util.error "Cannot handle mutually (co)inductive records." in let indl = List.map unpack indl in Command.build_mutual indl finite let vernac_fixpoint l b = if Dumpglob.dump () then List.iter (fun ((lid, _, _, _, _), _) -> Dumpglob.dump_definition lid false "def") l; build_recursive l b let vernac_cofixpoint l b = if Dumpglob.dump () then List.iter (fun ((lid, _, _, _), _) -> Dumpglob.dump_definition lid false "def") l; build_corecursive l b let vernac_scheme = build_scheme let vernac_combined_scheme = build_combined_scheme (**********************) (* Modules *) let vernac_import export refl = let import ref = Library.import_module export (qualid_of_reference ref) in List.iter import refl; Lib.add_frozen_state () let vernac_declare_module export (loc, id) binders_ast mty_ast_o = (* 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 export <> None 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_modtype Modintern.interp_modexpr id binders_ast (Some mty_ast_o) None in Dumpglob.dump_moddef loc mp "mod"; if_verbose message ("Module "^ string_of_id id ^" is declared"); Option.iter (fun export -> vernac_import export [Ident (dummy_loc,id)]) export let vernac_define_module export (loc, id) binders_ast mty_ast_o mexpr_ast_o = (* 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_o with | None -> 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_modtype export id binders_ast mty_ast_o in Dumpglob.dump_moddef loc mp "mod"; if_verbose message ("Interactive Module "^ string_of_id id ^" started") ; List.iter (fun (export,id) -> Option.iter (fun export -> vernac_import export [Ident (dummy_loc,id)]) export ) argsexport | Some _ -> let binders_ast = List.map (fun (export,idl,ty) -> if export <> None 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_modtype Modintern.interp_modexpr id binders_ast mty_ast_o mexpr_ast_o in Dumpglob.dump_moddef loc mp "mod"; if_verbose message ("Module "^ string_of_id id ^" is defined"); Option.iter (fun export -> vernac_import export [Ident (dummy_loc,id)]) export let vernac_end_module export (loc,id) = let mp = Declaremods.end_module id in Dumpglob.dump_modref loc mp "mod"; if_verbose message ("Module "^ string_of_id id ^" is defined") ; Option.iter (fun export -> vernac_import export [Ident (dummy_loc,id)]) export let vernac_declare_module_type (loc,id) binders_ast mty_ast_o = if Lib.sections_are_opened () then error "Modules and Module Types are not allowed inside sections."; match mty_ast_o with | None -> 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) binders_ast ([],[]) in let mp = Declaremods.start_modtype Modintern.interp_modtype id binders_ast in Dumpglob.dump_moddef loc mp "modtype"; if_verbose message ("Interactive Module Type "^ string_of_id id ^" started"); List.iter (fun (export,id) -> Option.iter (fun export -> vernac_import export [Ident (dummy_loc,id)]) export ) argsexport | Some base_mty -> let binders_ast = List.map (fun (export,idl,ty) -> if export <> None 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_modtype id binders_ast base_mty in Dumpglob.dump_moddef loc mp "modtype"; if_verbose message ("Module Type "^ string_of_id id ^" is defined") let vernac_end_modtype (loc,id) = let mp = Declaremods.end_modtype id in Dumpglob.dump_modref loc mp "modtype"; if_verbose message ("Module Type "^ string_of_id id ^" is defined") let vernac_include = function | CIMTE mty_ast -> Declaremods.declare_include Modintern.interp_modtype mty_ast false | CIME mexpr_ast -> Declaremods.declare_include Modintern.interp_modexpr mexpr_ast true (**********************) (* 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, id) = Dumpglob.dump_reference loc (string_of_dirpath (Lib.current_dirpath true)) "<>" "sec"; Lib.close_section id let vernac_end_segment lid = check_no_pending_proofs (); let o = try Lib.what_is_opened () with Not_found -> error "There is nothing to end." in match o with | _,Lib.OpenedModule (export,_,_) -> vernac_end_module export lid | _,Lib.OpenedModtype _ -> vernac_end_modtype lid | _,Lib.OpenedSection _ -> vernac_end_section lid | _ -> anomaly "No more opened things" let vernac_require import _ qidl = let qidl = List.map qualid_of_reference qidl in let modrefl = List.map Library.try_locate_qualified_library qidl in (* let modrefl = List.map (fun qid -> let (dp, _) = (Library.try_locate_qualified_library qid) in dp) 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 let vernac_canonical r = Recordops.declare_canonical_structure (global_with_alias r) let vernac_coercion stre ref qids qidt = let target = cl_of_qualid qidt in let source = cl_of_qualid qids in let ref' = global_with_alias ref in Class.try_add_new_coercion_with_target ref' stre source target; if_verbose message ((string_of_reference ref) ^ " is now a coercion") let vernac_identity_coercion stre id qids qidt = let target = cl_of_qualid qidt in let source = cl_of_qualid qids in Class.try_add_new_identity_coercion id stre source target (* Type classes *) let vernac_instance glob sup inst props pri = Dumpglob.dump_constraint inst false "inst"; ignore(Classes.new_instance ~global:glob sup inst props pri) let vernac_context l = List.iter (fun x -> Dumpglob.dump_local_binder x true "var") l; Classes.context l let vernac_declare_instance id = Dumpglob.dump_definition id false "inst"; Classes.declare_instance false id (***********) (* Solving *) let vernac_solve n tcom b = if not (refining ()) then error "Unknown command of the non proof-editing mode."; Decl_mode.check_not_proof_mode "Unknown proof instruction"; begin if b then solve_nth n (Tacinterp.hide_interp tcom (get_end_tac ())) else solve_nth n (Tacinterp.hide_interp tcom None) end; (* in case a strict subtree was completed, go back to the top of the prooftree *) if subtree_solved () then begin Flags.if_verbose msgnl (str "Subgoal proved"); make_focus 0; reset_top_of_script () end; print_subgoals(); if !pcoq <> None then (Option.get !pcoq).solve n (* 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."; if tac <> (Tacexpr.TacId []) then set_end_tac (Tacinterp.interp tac) else () (* TO DO verifier s'il faut pas mettre exist s | TacId s ici*) (***********************) (* Proof Language Mode *) let vernac_decl_proof () = check_not_proof_mode "Already in Proof Mode"; if tree_solved () then error "Nothing left to prove here." else begin Decl_proof_instr.go_to_proof_mode (); print_subgoals () end let vernac_return () = match get_current_mode () with Mode_tactic -> Decl_proof_instr.return_from_tactic_mode (); print_subgoals () | Mode_proof -> error "\"return\" is only used after \"escape\"." | Mode_none -> error "There is no proof to end." let vernac_proof_instr instr = Decl_proof_instr.proof_instr instr; print_subgoals () (*****************************) (* Auxiliary file management *) let vernac_require_from export spec filename = Library.require_library_from_file None (System.expand_path_macros filename) export let vernac_add_loadpath isrec pdir ldiropt = let pdir = System.expand_path_macros pdir in let alias = match ldiropt with | None -> Nameops.default_root_prefix | Some ldir -> ldir in (if isrec then Mltop.add_rec_path else Mltop.add_path) pdir alias let vernac_remove_loadpath path = Library.remove_load_path (System.expand_path_macros 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) (System.expand_path_macros path) let vernac_declare_ml_module l = Mltop.declare_ml_modules (List.map System.expand_path_macros l) let vernac_chdir = function | None -> message (Sys.getcwd()) | Some path -> begin try Sys.chdir (System.expand_path_macros path) with Sys_error str -> warning ("Cd failed: " ^ str) end; if_verbose message (Sys.getcwd()) (********************) (* State management *) let abort_refine f x = if Pfedit.refining() then delete_all_proofs (); f x (* used to be: error "Must save or abort current goal first" *) let vernac_write_state file = abort_refine States.extern_state file let vernac_restore_state file = abort_refine States.intern_state file (*************) (* Resetting *) let vernac_reset_name id = abort_refine Lib.reset_name id let vernac_reset_initial () = abort_refine Lib.reset_initial () let vernac_back n = Lib.back n let vernac_backto n = Lib.reset_label n (* see also [vernac_backtrack] which combines undoing and resetting *) (************) (* Commands *) let vernac_declare_tactic_definition = Tacinterp.add_tacdef let vernac_create_hintdb local id b = Auto.create_hint_db local id full_transparent_state b let vernac_hints = Auto.add_hints let vernac_syntactic_definition lid = Dumpglob.dump_definition lid false "syndef"; Command.syntax_definition (snd lid) let vernac_declare_implicits local r = function | Some imps -> Impargs.declare_manual_implicits local (global_with_alias r) ~enriching:false (List.map (fun (ex,b,f) -> ex, (b,f)) imps) | None -> Impargs.declare_implicits local (global_with_alias r) let vernac_reserve idl c = let t = Constrintern.interp_type Evd.empty (Global.env()) c in let t = Detyping.detype false [] [] t in List.iter (fun id -> Reserve.declare_reserved_type id t) idl let make_silent_if_not_pcoq b = if !pcoq <> None then error "Turning on/off silent flag is not supported in Pcoq mode." else make_silent b let _ = declare_bool_option { optsync = false; optname = "silent"; optkey = (PrimaryTable "Silent"); optread = is_silent; optwrite = make_silent_if_not_pcoq } let _ = declare_bool_option { optsync = true; optname = "implicit arguments"; optkey = (SecondaryTable ("Implicit","Arguments")); optread = Impargs.is_implicit_args; optwrite = Impargs.make_implicit_args } let _ = declare_bool_option { optsync = true; optname = "manual implicit arguments"; optkey = (TertiaryTable ("Manual","Implicit","Arguments")); optread = Impargs.is_manual_implicit_args; optwrite = Impargs.make_manual_implicit_args } let _ = declare_bool_option { optsync = true; optname = "strict implicit arguments"; optkey = (SecondaryTable ("Strict","Implicit")); optread = Impargs.is_strict_implicit_args; optwrite = Impargs.make_strict_implicit_args } let _ = declare_bool_option { optsync = true; optname = "strong strict implicit arguments"; optkey = (TertiaryTable ("Strongly","Strict","Implicit")); optread = Impargs.is_strongly_strict_implicit_args; optwrite = Impargs.make_strongly_strict_implicit_args } let _ = declare_bool_option { optsync = true; optname = "contextual implicit arguments"; optkey = (SecondaryTable ("Contextual","Implicit")); optread = Impargs.is_contextual_implicit_args; optwrite = Impargs.make_contextual_implicit_args } (* let _ = *) (* declare_bool_option *) (* { optsync = true; *) (* optname = "forceable implicit arguments"; *) (* optkey = (SecondaryTable ("Forceable","Implicit")); *) (* optread = Impargs.is_forceable_implicit_args; *) (* optwrite = Impargs.make_forceable_implicit_args } *) let _ = declare_bool_option { optsync = true; optname = "implicit status of reversible patterns"; optkey = (TertiaryTable ("Reversible","Pattern","Implicit")); optread = Impargs.is_reversible_pattern_implicit_args; optwrite = Impargs.make_reversible_pattern_implicit_args } let _ = declare_bool_option { optsync = true; optname = "maximal insertion of implicit"; optkey = (TertiaryTable ("Maximal","Implicit","Insertion")); optread = Impargs.is_maximal_implicit_args; optwrite = Impargs.make_maximal_implicit_args } let _ = declare_bool_option { optsync = true; optname = "coercion printing"; optkey = (SecondaryTable ("Printing","Coercions")); optread = (fun () -> !Constrextern.print_coercions); optwrite = (fun b -> Constrextern.print_coercions := b) } let _ = declare_bool_option { optsync = true; optname = "printing of existential variable instances"; optkey = (TertiaryTable ("Printing","Existential","Instances")); optread = (fun () -> !Constrextern.print_evar_arguments); optwrite = (:=) Constrextern.print_evar_arguments } let _ = declare_bool_option { optsync = true; optname = "implicit arguments printing"; optkey = (SecondaryTable ("Printing","Implicit")); optread = (fun () -> !Constrextern.print_implicits); optwrite = (fun b -> Constrextern.print_implicits := b) } let _ = declare_bool_option { optsync = true; optname = "implicit arguments defensive printing"; optkey = (TertiaryTable ("Printing","Implicit","Defensive")); optread = (fun () -> !Constrextern.print_implicits_defensive); optwrite = (fun b -> Constrextern.print_implicits_defensive := b) } let _ = declare_bool_option { optsync = true; optname = "projection printing using dot notation"; optkey = (SecondaryTable ("Printing","Projections")); optread = (fun () -> !Constrextern.print_projections); optwrite = (fun b -> Constrextern.print_projections := b) } let _ = declare_bool_option { optsync = true; optname = "notations printing"; optkey = (SecondaryTable ("Printing","Notations")); optread = (fun () -> not !Constrextern.print_no_symbol); optwrite = (fun b -> Constrextern.print_no_symbol := not b) } let _ = declare_bool_option { optsync = true; optname = "raw printing"; optkey = (SecondaryTable ("Printing","All")); optread = (fun () -> !Flags.raw_print); optwrite = (fun b -> Flags.raw_print := b) } let _ = declare_bool_option { optsync = true; optname = "use of virtual machine inside the kernel"; optkey = (SecondaryTable ("Virtual","Machine")); optread = (fun () -> Vconv.use_vm ()); optwrite = (fun b -> Vconv.set_use_vm b) } let _ = declare_bool_option { optsync = true; optname = "use of boxed definitions"; optkey = (SecondaryTable ("Boxed","Definitions")); optread = Flags.boxed_definitions; optwrite = (fun b -> Flags.set_boxed_definitions b) } let _ = declare_bool_option { optsync = true; optname = "use of boxed values"; optkey = (SecondaryTable ("Boxed","Values")); optread = (fun _ -> not (Vm.transp_values ())); optwrite = (fun b -> Vm.set_transp_values (not b)) } let _ = declare_int_option { optsync=false; optkey=PrimaryTable("Undo"); optname="the undo limit"; optread=Pfedit.get_undo; optwrite=Pfedit.set_undo } let _ = declare_int_option { optsync=false; optkey=SecondaryTable("Hyps","Limit"); optname="the hypotheses limit"; optread=Flags.print_hyps_limit; optwrite=Flags.set_print_hyps_limit } let _ = declare_int_option { optsync=true; optkey=SecondaryTable("Printing","Depth"); optname="the printing depth"; optread=Pp_control.get_depth_boxes; optwrite=Pp_control.set_depth_boxes } let _ = declare_int_option { optsync=true; optkey=SecondaryTable("Printing","Width"); optname="the printing width"; optread=Pp_control.get_margin; optwrite=Pp_control.set_margin } let _ = declare_bool_option { optsync=true; optkey=SecondaryTable("Printing","Universes"); optname="printing of universes"; optread=(fun () -> !Constrextern.print_universes); optwrite=(fun b -> Constrextern.print_universes:=b) } let vernac_debug b = set_debug (if b then Tactic_debug.DebugOn 0 else Tactic_debug.DebugOff) let _ = declare_bool_option { optsync=false; optkey=SecondaryTable("Ltac","Debug"); optname="Ltac debug"; optread=(fun () -> get_debug () <> Tactic_debug.DebugOff); optwrite=vernac_debug } let vernac_set_opacity local str = let glob_ref r = match global_with_alias r with | ConstRef sp -> EvalConstRef sp | VarRef id -> EvalVarRef id | _ -> error "cannot set an inductive type or a constructor as transparent" in let str = List.map (fun (lev,ql) -> (lev,List.map glob_ref ql)) str in Redexpr.set_strategy local str let vernac_set_option key = function | StringValue s -> set_string_option_value key s | IntValue n -> set_int_option_value key (Some n) | BoolValue b -> set_bool_option_value key b let vernac_unset_option key = try set_bool_option_value key false with _ -> set_int_option_value key None 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 (evmap,env) = get_current_context_of_args glopt in let c = interp_constr evmap env rc in let j = Typeops.typing env c in match redexp with | None -> if !pcoq <> None then (Option.get !pcoq).print_check env j else msg (print_judgment env j) | Some r -> let redfun = fst (reduction_of_red_expr (interp_redexp env evmap r)) in if !pcoq <> None then (Option.get !pcoq).print_eval redfun env evmap rc j else msg (print_eval redfun env evmap rc j) (* The same but avoiding the current goal context if any *) let vernac_global_check c = let evmap = Evd.empty in let env = Global.env() in let c = interp_constr evmap env c in let senv = Global.safe_env() in let j = Safe_typing.typing senv c in msg (print_safe_judgment env j) let vernac_print = function | PrintTables -> print_tables () | PrintFullContext -> msg (print_full_context_typ ()) | PrintSectionContext qid -> msg (print_sec_context_typ qid) | PrintInspect n -> msg (inspect n) | PrintGrammar ent -> Metasyntax.print_grammar ent | PrintLoadPath -> (* For compatibility ? *) print_loadpath () | PrintModules -> msg (print_modules ()) | PrintModule qid -> print_module qid | PrintModuleType qid -> print_modtype qid | PrintMLLoadPath -> Mltop.print_ml_path () | PrintMLModules -> Mltop.print_ml_modules () | PrintName qid -> if !pcoq <> None then (Option.get !pcoq).print_name qid else msg (print_name qid) | PrintOpaqueName qid -> msg (print_opaque_name qid) | PrintGraph -> ppnl (Prettyp.print_graph()) | PrintClasses -> ppnl (Prettyp.print_classes()) | PrintTypeClasses -> ppnl (Prettyp.print_typeclasses()) | PrintInstances c -> ppnl (Prettyp.print_instances (global c)) | PrintLtac qid -> ppnl (Tacinterp.print_ltac (snd (qualid_of_reference qid))) | PrintCoercions -> ppnl (Prettyp.print_coercions()) | PrintCoercionPaths (cls,clt) -> ppnl (Prettyp.print_path_between (cl_of_qualid cls) (cl_of_qualid clt)) | PrintCanonicalConversions -> ppnl (Prettyp.print_canonical_projections ()) | PrintUniverses None -> pp (Univ.pr_universes (Global.universes ())) | PrintUniverses (Some s) -> dump_universes s | PrintHint r -> Auto.print_hint_ref (global_with_alias r) | PrintHintGoal -> Auto.print_applicable_hint () | PrintHintDbName s -> Auto.print_hint_db_by_name s | PrintRewriteHintDbName s -> Autorewrite.print_rewrite_hintdb s | PrintHintDb -> Auto.print_searchtable () | PrintSetoids -> Setoid_replace.print_setoids() | PrintScopes -> pp (Notation.pr_scopes (Constrextern.without_symbols pr_lrawconstr)) | PrintScope s -> pp (Notation.pr_scope (Constrextern.without_symbols pr_lrawconstr) s) | PrintVisibility s -> pp (Notation.pr_visibility (Constrextern.without_symbols pr_lrawconstr) s) | PrintAbout qid -> msgnl (print_about qid) | PrintImplicit qid -> msg (print_impargs qid) (*spiwack: prints all the axioms and section variables used by a term *) | PrintAssumptions r -> let cstr = constr_of_global (global_with_alias r) in let nassumptions = Environ.assumptions cstr (Global.env ()) in msg (Printer.pr_assumptionset (Global.env ()) nassumptions) 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 is_ident s = try ignore (check_ident s); true with UserError _ -> false let interp_search_about_item = function | SearchRef r -> GlobSearchRef (global_with_alias r) | SearchString (s,None) when is_ident s -> GlobSearchString s | SearchString (s,sc) -> try let ref = Notation.interp_notation_as_global_reference dummy_loc (fun _ -> true) s sc in GlobSearchRef ref with UserError _ -> error ("Unable to interp \""^s^"\" either as a reference or as an identifier component") let vernac_search s r = let r = interp_search_restriction r in if !pcoq <> None then (Option.get !pcoq).search s r else match s with | SearchPattern c -> let _,pat = interp_constrpattern Evd.empty (Global.env()) c in Search.search_pattern pat r | SearchRewrite c -> let _,pat = interp_constrpattern Evd.empty (Global.env()) c in Search.search_rewrite pat r | SearchHead ref -> Search.search_by_head (global_with_alias ref) r | SearchAbout sl -> Search.search_about (List.map (on_snd interp_search_about_item) sl) r let vernac_locate = function | LocateTerm qid -> msgnl (print_located_qualid qid) | LocateLibrary qid -> print_located_library qid | LocateModule qid -> print_located_module qid | LocateFile f -> locate_file f | LocateNotation ntn -> ppnl (Notation.locate_notation (Constrextern.without_symbols pr_lrawconstr) (Metasyntax.standardize_locatable_notation ntn)) (********************) (* Proof management *) let vernac_goal = function | None -> () | Some c -> if not (refining()) then begin let unnamed_kind = Lemma (* Arbitrary *) in start_proof_com (Global, Proof unnamed_kind) [None,c] (fun _ _ ->()); print_subgoals () end else error "repeated Goal not permitted in refining mode." let vernac_abort = function | None -> delete_current_proof (); if_verbose message "Current goal aborted"; if !pcoq <> None then (Option.get !pcoq).abort "" | Some id -> delete_proof id; let s = string_of_id (snd id) in if_verbose message ("Goal "^s^" aborted"); if !pcoq <> None then (Option.get !pcoq).abort s let vernac_abort_all () = if refining() then begin delete_all_proofs (); message "Current goals aborted" end else error "No proof-editing in progress." let vernac_restart () = restart_proof(); print_subgoals () (* Proof switching *) let vernac_suspend = suspend_proof let vernac_resume = function | None -> resume_last_proof () | Some id -> resume_proof id let vernac_undo n = undo n; print_subgoals () (* backtrack with [naborts] abort, then undo_todepth to [pnum], then back-to state number [snum]. This allows to backtrack proofs and state with one command (easier for proofgeneral). *) let vernac_backtrack snum pnum naborts = for i = 1 to naborts do vernac_abort None done; undo_todepth pnum; vernac_backto snum; Pp.flush_all(); (* there may be no proof in progress, even if no abort *) (try print_subgoals () with UserError _ -> ()) let vernac_focus gln = check_not_proof_mode "No focussing or Unfocussing in Proof Mode."; match gln with | None -> traverse_nth_goal 1; print_subgoals () | Some n -> traverse_nth_goal n; print_subgoals () (* Reset the focus to the top of the tree *) let vernac_unfocus () = check_not_proof_mode "No focussing or Unfocussing in Proof Mode."; make_focus 0; reset_top_of_script (); print_subgoals () let vernac_go = function | GoTo n -> Pfedit.traverse n;show_node() | GoTop -> Pfedit.reset_top_of_tree ();show_node() | GoNext -> Pfedit.traverse_next_unproven ();show_node() | GoPrev -> Pfedit.traverse_prev_unproven ();show_node() let apply_subproof f occ = let pts = get_pftreestate() in let evc = evc_of_pftreestate pts in let rec aux pts = function | [] -> pts | (n::l) -> aux (Tacmach.traverse n pts) occ in let pts = aux pts (occ@[-1]) in let pf = proof_of_pftreestate pts in f evc (Global.named_context()) pf let explain_proof occ = msg (apply_subproof (fun evd _ -> print_treescript evd) occ) let explain_tree occ = msg (apply_subproof print_proof occ) let vernac_show = function | ShowGoal nopt -> if !pcoq <> None then (Option.get !pcoq).show_goal nopt else msg (match nopt with | None -> pr_open_subgoals () | Some n -> pr_nth_open_subgoal n) | ShowGoalImplicitly None -> Constrextern.with_implicits msg (pr_open_subgoals ()) | ShowGoalImplicitly (Some n) -> Constrextern.with_implicits msg (pr_nth_open_subgoal n) | ShowProof -> show_proof () | ShowNode -> show_node () | ShowScript -> show_script () | ShowExistentials -> show_top_evars () | ShowTree -> show_prooftree () | ShowProofNames -> msgnl (prlist_with_sep pr_spc pr_id (Pfedit.get_all_proof_names())) | ShowIntros all -> show_intro all | ShowMatch id -> show_match id | ShowThesis -> show_thesis () | ExplainProof occ -> explain_proof occ | ExplainTree occ -> explain_tree occ let vernac_check_guard () = let pts = get_pftreestate () in let pf = proof_of_pftreestate pts in let (pfterm,_) = extract_open_pftreestate pts in let message = try Inductiveops.control_only_guard (Evd.evar_env (goal_of_proof pf)) pfterm; (str "The condition holds up to here") with UserError(_,s) -> (str ("Condition violated: ") ++s) in msgnl message let interp c = match c with (* Control (done in vernac) *) | (VernacTime _ | VernacList _ | VernacLoad _) -> assert false (* Syntax *) | VernacTacticNotation (n,r,e) -> Metasyntax.add_tactic_notation (n,r,e) | VernacSyntaxExtension (lcl,sl) -> vernac_syntax_extension lcl sl | VernacDelimiters (sc,lr) -> vernac_delimiters sc lr | VernacBindScope (sc,rl) -> vernac_bind_scope sc rl | VernacOpenCloseScope sc -> vernac_open_close_scope sc | VernacArgumentsScope (lcl,qid,scl) -> vernac_arguments_scope lcl qid scl | VernacInfix (local,mv,qid,sc) -> vernac_infix local mv qid sc | VernacNotation (local,c,infpl,sc) -> vernac_notation local c infpl sc (* Gallina *) | VernacDefinition (k,lid,d,f) -> vernac_definition k lid d f | VernacStartTheoremProof (k,l,top,f) -> vernac_start_proof k l top f | VernacEndProof e -> vernac_end_proof e | VernacExactProof c -> vernac_exact_proof c | VernacAssumption (stre,nl,l) -> vernac_assumption stre l nl | VernacInductive (finite,l) -> vernac_inductive finite l | VernacFixpoint (l,b) -> vernac_fixpoint l b | VernacCoFixpoint (l,b) -> vernac_cofixpoint l b | VernacScheme l -> vernac_scheme l | VernacCombinedScheme (id, l) -> vernac_combined_scheme id l (* Modules *) | VernacDeclareModule (export,lid,bl,mtyo) -> vernac_declare_module export lid bl mtyo | VernacDefineModule (export,lid,bl,mtyo,mexpro) -> vernac_define_module export lid bl mtyo mexpro | VernacDeclareModuleType (lid,bl,mtyo) -> vernac_declare_module_type lid bl mtyo | VernacInclude (in_ast) -> vernac_include in_ast (* Gallina extensions *) | VernacBeginSection lid -> vernac_begin_section lid | VernacEndSegment lid -> vernac_end_segment lid | VernacRecord ((k,finite),id,bl,s,idopt,fs) -> vernac_record k finite id bl s idopt fs | VernacRequire (export,spec,qidl) -> vernac_require export spec qidl | VernacImport (export,qidl) -> vernac_import export qidl | VernacCanonical qid -> vernac_canonical qid | VernacCoercion (str,r,s,t) -> vernac_coercion str r s t | VernacIdentityCoercion (str,(_,id),s,t) -> vernac_identity_coercion str id s t (* Type classes *) (* | VernacClass (id, par, ar, sup, props) -> vernac_class id par ar sup props *) | VernacInstance (glob, sup, inst, props, pri) -> vernac_instance glob sup inst props pri | VernacContext sup -> vernac_context sup | VernacDeclareInstance id -> vernac_declare_instance id (* Solving *) | VernacSolve (n,tac,b) -> vernac_solve n tac b | VernacSolveExistential (n,c) -> vernac_solve_existential n c (* MMode *) | VernacDeclProof -> vernac_decl_proof () | VernacReturn -> vernac_return () | VernacProofInstr stp -> vernac_proof_instr stp (* /MMode *) (* Auxiliary file and library management *) | VernacRequireFrom (exp,spec,f) -> vernac_require_from exp spec f | 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 l | VernacChdir s -> vernac_chdir s (* State management *) | VernacWriteState s -> vernac_write_state s | VernacRestoreState s -> vernac_restore_state s (* Resetting *) | VernacRemoveName id -> Lib.remove_name id | VernacResetName id -> vernac_reset_name id | VernacResetInitial -> vernac_reset_initial () | VernacBack n -> vernac_back n | VernacBackTo n -> vernac_backto n (* Commands *) | VernacDeclareTacticDefinition (x,l) -> vernac_declare_tactic_definition x l | VernacCreateHintDb (local,dbname,b) -> vernac_create_hintdb local dbname b | VernacHints (local,dbnames,hints) -> vernac_hints local dbnames hints | VernacSyntacticDefinition (id,c,l,b) ->vernac_syntactic_definition id c l b | VernacDeclareImplicits (local,qid,l) ->vernac_declare_implicits local qid l | VernacReserve (idl,c) -> vernac_reserve idl c | VernacSetOpacity (local,qidl) -> vernac_set_opacity local qidl | VernacSetOption (key,v) -> vernac_set_option key v | VernacUnsetOption key -> vernac_unset_option 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 | VernacGlobalCheck c -> vernac_global_check c | VernacPrint p -> vernac_print p | VernacSearch (s,r) -> vernac_search s r | VernacLocate l -> vernac_locate l | VernacComments l -> if_verbose message ("Comments ok\n") | VernacNop -> () (* Proof management *) | VernacGoal t -> vernac_start_proof Theorem [None,([],t)] false (fun _ _->()) | VernacAbort id -> vernac_abort id | VernacAbortAll -> vernac_abort_all () | VernacRestart -> vernac_restart () | VernacSuspend -> vernac_suspend () | VernacResume id -> vernac_resume id | VernacUndo n -> vernac_undo n | VernacUndoTo n -> undo_todepth n | VernacBacktrack (snum,pnum,naborts) -> vernac_backtrack snum pnum naborts | VernacFocus n -> vernac_focus n | VernacUnfocus -> vernac_unfocus () | VernacGo g -> vernac_go g | VernacShow s -> vernac_show s | VernacCheckGuard -> vernac_check_guard () | VernacProof tac -> vernac_set_end_tac tac (* Toplevel control *) | VernacToplevelControl e -> raise e (* Extensions *) | VernacExtend (opn,args) -> Vernacinterp.call (opn,args)