(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* flush_all (); Pp_control.std_ft := out_ft; Pp_control.err_ft := out_ft; Pp_control.deep_ft := deep_out_ft; ), (fun () -> Format.pp_print_flush out_ft (); let r = Buffer.contents out_buff in Buffer.clear out_buff; r) let pr_with_pid s = Printf.eprintf "[pid %d] %s\n%!" (Unix.getpid ()) s let pr_debug s = if !Flags.debug then pr_with_pid s let pr_debug_call q = if !Flags.debug then pr_with_pid ("<-- " ^ Xmlprotocol.pr_call q) let pr_debug_answer q r = if !Flags.debug then pr_with_pid ("--> " ^ Xmlprotocol.pr_full_value q r) (** Categories of commands *) let coqide_known_option table = List.mem table [ ["Printing";"Implicit"]; ["Printing";"Coercions"]; ["Printing";"Matching"]; ["Printing";"Synth"]; ["Printing";"Notations"]; ["Printing";"All"]; ["Printing";"Records"]; ["Printing";"Existential";"Instances"]; ["Printing";"Universes"]] let is_known_option cmd = match cmd with | VernacSetOption (o,BoolValue true) | VernacUnsetOption o -> coqide_known_option o | _ -> false let is_debug cmd = match cmd with | VernacSetOption (["Ltac";"Debug"], _) -> true | _ -> false let is_query cmd = match cmd with | VernacChdir None | VernacMemOption _ | VernacPrintOption _ | VernacCheckMayEval _ | VernacGlobalCheck _ | VernacPrint _ | VernacSearch _ | VernacLocate _ -> true | _ -> false let is_undo cmd = match cmd with | VernacUndo _ | VernacUndoTo _ -> true | _ -> false (** Check whether a command is forbidden by CoqIDE *) let coqide_cmd_checks (loc,ast) = let user_error s = Errors.user_err_loc (loc, "CoqIde", str s) in if is_debug ast then user_error "Debug mode not available within CoqIDE"; if is_known_option ast then msg_warning (strbrk"This will not work. Use CoqIDE display menu instead"); if Vernac.is_navigation_vernac ast || is_undo ast then msg_warning (strbrk "Rather use CoqIDE navigation instead"); if is_query ast then msg_warning (strbrk "Query commands should not be inserted in scripts") (** Interpretation (cf. [Ide_intf.interp]) *) let add ((s,eid),(sid,verbose)) = let newid, rc = Stm.add ~ontop:sid verbose ~check:coqide_cmd_checks eid s in let rc = match rc with `NewTip -> CSig.Inl () | `Unfocus id -> CSig.Inr id in newid, (rc, read_stdout ()) let edit_at id = match Stm.edit_at id with | `NewTip -> CSig.Inl () | `Focus { Stm.start; stop; tip} -> CSig.Inr (start, (stop, tip)) let query (s,id) = Stm.query ~at:id s; read_stdout () let annotate phrase = let (loc, ast) = let pa = Pcoq.Gram.parsable (Stream.of_string phrase) in Vernac.parse_sentence (pa,None) in let (_, xml) = Richprinter.richpp_vernac ast in xml (** Goal display *) let hyp_next_tac sigma env (id,_,ast) = let id_s = Names.Id.to_string id in let type_s = string_of_ppcmds (pr_ltype_env env sigma ast) in [ ("clear "^id_s),("clear "^id_s^"."); ("apply "^id_s),("apply "^id_s^"."); ("exact "^id_s),("exact "^id_s^"."); ("generalize "^id_s),("generalize "^id_s^"."); ("absurd <"^id_s^">"),("absurd "^type_s^".") ] @ [ ("discriminate "^id_s),("discriminate "^id_s^"."); ("injection "^id_s),("injection "^id_s^".") ] @ [ ("rewrite "^id_s),("rewrite "^id_s^"."); ("rewrite <- "^id_s),("rewrite <- "^id_s^".") ] @ [ ("elim "^id_s), ("elim "^id_s^"."); ("inversion "^id_s), ("inversion "^id_s^"."); ("inversion clear "^id_s), ("inversion_clear "^id_s^".") ] let concl_next_tac sigma concl = let expand s = (s,s^".") in List.map expand ([ "intro"; "intros"; "intuition" ] @ [ "reflexivity"; "discriminate"; "symmetry" ] @ [ "assumption"; "omega"; "ring"; "auto"; "eauto"; "tauto"; "trivial"; "decide equality"; "simpl"; "subst"; "red"; "split"; "left"; "right" ]) let process_goal sigma g = let env = Goal.V82.env sigma g in let min_env = Environ.reset_context env in let id = Goal.uid g in let ccl = let norm_constr = Reductionops.nf_evar sigma (Goal.V82.concl sigma g) in string_of_ppcmds (pr_goal_concl_style_env env sigma norm_constr) in let process_hyp d (env,l) = let d = Context.map_named_list_declaration (Reductionops.nf_evar sigma) d in let d' = List.map (fun x -> (x, pi2 d, pi3 d)) (pi1 d) in (List.fold_right Environ.push_named d' env, (string_of_ppcmds (pr_var_list_decl env sigma d)) :: l) in let (_env, hyps) = Context.fold_named_list_context process_hyp (Termops.compact_named_context (Environ.named_context env)) ~init:(min_env,[]) in { Interface.goal_hyp = List.rev hyps; Interface.goal_ccl = ccl; Interface.goal_id = id; } let export_pre_goals pgs = { Interface.fg_goals = pgs.Proof.fg_goals; Interface.bg_goals = pgs.Proof.bg_goals; Interface.shelved_goals = pgs.Proof.shelved_goals; Interface.given_up_goals = pgs.Proof.given_up_goals } let goals () = Stm.finish (); let s = read_stdout () in if not (String.is_empty s) then msg_info (str s); try let pfts = Proof_global.give_me_the_proof () in Some (export_pre_goals (Proof.map_structured_proof pfts process_goal)) with Proof_global.NoCurrentProof -> None let evars () = try Stm.finish (); let s = read_stdout () in if not (String.is_empty s) then msg_info (str s); let pfts = Proof_global.give_me_the_proof () in let { Evd.it = all_goals ; sigma = sigma } = Proof.V82.subgoals pfts in let exl = Evar.Map.bindings (Evarutil.non_instantiated sigma) in let map_evar ev = { Interface.evar_info = string_of_ppcmds (pr_evar sigma ev); } in let el = List.map map_evar exl in Some el with Proof_global.NoCurrentProof -> None let hints () = try let pfts = Proof_global.give_me_the_proof () in let { Evd.it = all_goals ; sigma = sigma } = Proof.V82.subgoals pfts in match all_goals with | [] -> None | g :: _ -> let env = Goal.V82.env sigma g in let hint_goal = concl_next_tac sigma g in let get_hint_hyp env d accu = hyp_next_tac sigma env d :: accu in let hint_hyps = List.rev (Environ.fold_named_context get_hint_hyp env ~init: []) in Some (hint_hyps, hint_goal) with Proof_global.NoCurrentProof -> None (** Other API calls *) let status force = (** We remove the initial part of the current [DirPath.t] (usually Top in an interactive session, cf "coqtop -top"), and display the other parts (opened sections and modules) *) Stm.finish (); if force then Stm.join (); let s = read_stdout () in if not (String.is_empty s) then msg_info (str s); let path = let l = Names.DirPath.repr (Lib.cwd ()) in List.rev_map Names.Id.to_string l in let proof = try Some (Names.Id.to_string (Proof_global.get_current_proof_name ())) with Proof_global.NoCurrentProof -> None in let allproofs = let l = Proof_global.get_all_proof_names () in List.map Names.Id.to_string l in { Interface.status_path = path; Interface.status_proofname = proof; Interface.status_allproofs = allproofs; Interface.status_proofnum = Stm.current_proof_depth (); } let export_coq_object t = { Interface.coq_object_prefix = t.Search.coq_object_prefix; Interface.coq_object_qualid = t.Search.coq_object_qualid; Interface.coq_object_object = t.Search.coq_object_object } let import_search_constraint = function | Interface.Name_Pattern s -> Search.Name_Pattern s | Interface.Type_Pattern s -> Search.Type_Pattern s | Interface.SubType_Pattern s -> Search.SubType_Pattern s | Interface.In_Module ms -> Search.In_Module ms | Interface.Include_Blacklist -> Search.Include_Blacklist let search flags = List.map export_coq_object (Search.interface_search ( List.map (fun (c, b) -> (import_search_constraint c, b)) flags) ) let export_option_value = function | Goptions.BoolValue b -> Interface.BoolValue b | Goptions.IntValue x -> Interface.IntValue x | Goptions.StringValue s -> Interface.StringValue s | Goptions.StringOptValue s -> Interface.StringOptValue s let import_option_value = function | Interface.BoolValue b -> Goptions.BoolValue b | Interface.IntValue x -> Goptions.IntValue x | Interface.StringValue s -> Goptions.StringValue s | Interface.StringOptValue s -> Goptions.StringOptValue s let export_option_state s = { Interface.opt_sync = s.Goptions.opt_sync; Interface.opt_depr = s.Goptions.opt_depr; Interface.opt_name = s.Goptions.opt_name; Interface.opt_value = export_option_value s.Goptions.opt_value; } let get_options () = let table = Goptions.get_tables () in let fold key state accu = (key, export_option_state state) :: accu in Goptions.OptionMap.fold fold table [] let set_options options = let iter (name, value) = match import_option_value value with | BoolValue b -> Goptions.set_bool_option_value name b | IntValue i -> Goptions.set_int_option_value name i | StringValue s -> Goptions.set_string_option_value name s | StringOptValue (Some s) -> Goptions.set_string_option_value name s | StringOptValue None -> Goptions.unset_option_value_gen None name in List.iter iter options let about () = { Interface.coqtop_version = Coq_config.version; Interface.protocol_version = Xmlprotocol.protocol_version; Interface.release_date = Coq_config.date; Interface.compile_date = Coq_config.compile_date; } let handle_exn (e, info) = let dummy = Stateid.dummy in let loc_of e = match Loc.get_loc e with | Some loc when not (Loc.is_ghost loc) -> Some (Loc.unloc loc) | _ -> None in let mk_msg () = read_stdout ()^"\n"^string_of_ppcmds (Errors.print ~info e) in match e with | Errors.Drop -> dummy, None, "Drop is not allowed by coqide!" | Errors.Quit -> dummy, None, "Quit is not allowed by coqide!" | e -> match Stateid.get info with | Some (valid, _) -> valid, loc_of info, mk_msg () | None -> dummy, loc_of info, mk_msg () let init = let initialized = ref false in fun file -> if !initialized then anomaly (str "Already initialized") else begin initialized := true; match file with | None -> Stm.get_current_state () | Some file -> if not (Filename.check_suffix file ".v") then error "A file with suffix .v is expected."; let dir = Filename.dirname file in let open Loadpath in let open CUnix in let initial_id, _ = if not (is_in_load_paths (physical_path_of_string dir)) then Stm.add false ~ontop:(Stm.get_current_state ()) 0 (Printf.sprintf "Add LoadPath \"%s\". " dir) else Stm.get_current_state (), `NewTip in Stm.set_compilation_hints file; initial_id end (* Retrocompatibility stuff *) let interp ((_raw, verbose), s) = let vernac_parse s = let pa = Pcoq.Gram.parsable (Stream.of_string s) in Flags.with_option Flags.we_are_parsing (fun () -> match Pcoq.Gram.entry_parse Pcoq.main_entry pa with | None -> raise (Invalid_argument "vernac_parse") | Some ast -> ast) () in Stm.interp verbose (vernac_parse s); Stm.get_current_state (), CSig.Inl (read_stdout ()) (** When receiving the Quit call, we don't directly do an [exit 0], but rather set this reference, in order to send a final answer before exiting. *) let quit = ref false (** Grouping all call handlers together + error handling *) let eval_call xml_oc log c = let interruptible f x = catch_break := true; Control.check_for_interrupt (); let r = f x in catch_break := false; let out = read_stdout () in if not (String.is_empty out) then log (str out); r in let handler = { Interface.add = interruptible add; Interface.edit_at = interruptible edit_at; Interface.query = interruptible query; Interface.goals = interruptible goals; Interface.evars = interruptible evars; Interface.hints = interruptible hints; Interface.status = interruptible status; Interface.search = interruptible search; Interface.get_options = interruptible get_options; Interface.set_options = interruptible set_options; Interface.mkcases = interruptible Vernacentries.make_cases; Interface.quit = (fun () -> quit := true); Interface.init = interruptible init; Interface.about = interruptible about; Interface.interp = interruptible interp; Interface.handle_exn = handle_exn; Interface.stop_worker = Stm.stop_worker; Interface.print_ast = Stm.print_ast; Interface.annotate = interruptible annotate; } in Xmlprotocol.abstract_eval_call handler c (** Message dispatching. Since coqtop -ideslave starts 1 thread per slave, and each thread forwards feedback messages from the slave to the GUI on the same xml channel, we need mutual exclusion. The mutex should be per-channel, but here we only use 1 channel. *) let print_xml = let m = Mutex.create () in fun oc xml -> Mutex.lock m; try Xml_printer.print oc xml; Mutex.unlock m with e -> let e = Errors.push e in Mutex.unlock m; iraise e let slave_logger xml_oc level message = (* convert the message into XML *) let msg = string_of_ppcmds (hov 0 message) in let message = { Pp.message_level = level; Pp.message_content = msg; } in let () = pr_debug (Printf.sprintf "-> %S" msg) in let xml = Pp.of_message message in print_xml xml_oc xml let slave_feeder xml_oc msg = let xml = Feedback.of_feedback msg in print_xml xml_oc xml (** The main loop *) (** Exceptions during eval_call should be converted into [Interface.Fail] messages by [handle_exn] above. Otherwise, we die badly, without trying to answer malformed requests. *) let loop () = init_signal_handler (); catch_break := false; let in_ch, out_ch = Spawned.get_channels () in let xml_oc = Xml_printer.make (Xml_printer.TChannel out_ch) in let in_lb = Lexing.from_function (fun s len -> CThread.thread_friendly_read in_ch s ~off:0 ~len) in let xml_ic = Xml_parser.make (Xml_parser.SLexbuf in_lb) in let () = Xml_parser.check_eof xml_ic false in set_logger (slave_logger xml_oc); set_feeder (slave_feeder xml_oc); (* We'll handle goal fetching and display in our own way *) Vernacentries.enable_goal_printing := false; Vernacentries.qed_display_script := false; while not !quit do try let xml_query = Xml_parser.parse xml_ic in (* pr_with_pid (Xml_printer.to_string_fmt xml_query); *) let q = Xmlprotocol.to_call xml_query in let () = pr_debug_call q in let r = eval_call xml_oc (slave_logger xml_oc Pp.Notice) q in let () = pr_debug_answer q r in (* pr_with_pid (Xml_printer.to_string_fmt (Xmlprotocol.of_answer q r)); *) print_xml xml_oc (Xmlprotocol.of_answer q r); flush out_ch with | Xml_parser.Error (Xml_parser.Empty, _) -> pr_debug "End of input, exiting gracefully."; exit 0 | Xml_parser.Error (err, loc) -> pr_debug ("Syntax error in query: " ^ Xml_parser.error_msg err); exit 1 | Serialize.Marshal_error -> pr_debug "Incorrect query."; exit 1 | any -> pr_debug ("Fatal exception in coqtop:\n" ^ Printexc.to_string any); exit 1 done; pr_debug "Exiting gracefully."; exit 0 let rec parse = function | "--help-XML-protocol" :: rest -> Xmlprotocol.document Xml_printer.to_string_fmt; exit 0 | x :: rest -> x :: parse rest | [] -> [] let () = Coqtop.toploop_init := (fun args -> let args = parse args in Flags.make_silent true; init_stdout (); CoqworkmgrApi.(init Flags.High); args) let () = Coqtop.toploop_run := loop let () = Usage.add_to_usage "coqidetop" " --help-XML-protocol print the documentation of the XML protocol used by CoqIDE\n"