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(* * The Rocq Prover / The Rocq Development Team *) (* v * Copyright INRIA, CNRS and contributors *) (* <O___,, * (see version control and CREDITS file for authors & dates) *) (* \VV/ **************************************************************) (* // * This file is distributed under the terms of the *) (* * GNU Lesser General Public License Version 2.1 *) (* * (see LICENSE file for the text of the license) *) (************************************************************************) open Lexing open Coqpp_ast open Format open Coqpp_parser let fatal msg = let () = Format.eprintf "Error: %s@\n%!" msg in exit 1 let mk_code s = { code = s; loc = None } (** Annotating at the end of user code with the current line of the generated file. To get the current line while generating the output we would need to flush format and either intercept format's output (Format.formatter_of_out_functions) or read the generated file as we generate it. This is both inconvenient to write, and also the flushing breaks the formatting. Instead we generate the code with the following dummy annotation and afterwards replace it with the real annotation. *) let exit_code_str = "# COQPP EXIT CODE" let exit_code fmt () = fprintf fmt "@<0>%s" ("\n"^exit_code_str^"\n") let fix_exit_code ~filename str = let lines = String.split_on_char '\n' str in let lines = List.mapi (fun i l -> if String.equal l exit_code_str then asprintf "# %i \"%s\"" (i+2) filename else l) lines in String.concat "\n" lines let print_code fmt c = match c.loc with | None -> fprintf fmt "%s" c.code | Some loc -> (* Print the line location as a source annotation *) let loc = loc.loc_start in let padding = String.make (loc.pos_cnum - loc.pos_bol + 1) ' ' in let code_insert = asprintf "\n# %i \"%s\"\n%s%s" loc.pos_lnum loc.pos_fname padding c.co fprintf fmt "@[@<0>%s@]" code_insert; exit_code fmt () module StringSet = Set.Make(String) let string_split s = let len = String.length s in let rec split n = try let pos = String.index_from s n '.' in let dir = String.sub s n (pos-n) in dir :: split (succ pos) with | Not_found -> [String.sub s n (len-n)] in if len == 0 then [] else split 0 (* Used to generate unique ids *) let file_name = ref "" (* We used to output __plugin_name = "bla" then refer to __plugin_name in generated code but this is not robust to eg DECLARE PLUGIN "bla" open G_ltac use the plugin name since g_ltac has no mli its __plugin_name will shadow the local one and wreak havoc *) let plugin_name = ref None let force_is_plugin ~what () = match !plugin_name with | Some (Some n) -> n | Some None | None -> fatal ("DECLARE PLUGIN required before "^what) let check_is_plugin ~what () = match !plugin_name with | Some b -> b | None -> fatal ("DECLARE PLUGIN required before "^what) let pp_opt_plugin_arg ~what () = match check_is_plugin ~what () with | Some name -> "(Some \""^name^"\")" | None -> "None" let print_list fmt pr l = let rec prl fmt = function | [] -> () | [x] -> fprintf fmt "%a" pr x | x :: l -> fprintf fmt "%a;@ %a" pr x prl l in fprintf fmt "@[ let rec print_binders fmt = function | [] -> () | ExtTerminal _ :: rem -> print_binders fmt rem | ExtNonTerminal (_, TokNone) :: rem -> fprintf fmt "_@ %a" print_binders rem | ExtNonTerminal (_, TokName id) :: rem -> fprintf fmt "%s@ %a" id print_binders rem let rec print_symbol fmt = function | Ulist1 s -> fprintf fmt "@[Extend.TUlist1 (%a)@]" print_symbol s | Ulist1sep (s, sep) -> fprintf fmt "@[Extend.TUlist1sep (%a, \"%s\")@]" print_symbol s sep | Ulist0 s -> fprintf fmt "@[Extend.TUlist0 (%a)@]" print_symbol s | Ulist0sep (s, sep) -> fprintf fmt "@[Extend.TUlist0sep (%a, \"%s\")@]" print_symbol s sep | Uopt s -> fprintf fmt "@[Extend.TUopt (%a)@]" print_symbol s | Uentry e -> fprintf fmt "@[Extend.TUentry (Genarg.get_arg_tag wit_%s)@]" e | Uentryl (e, l) -> assert (e = "tactic"); fprintf fmt "@[Extend.TUentryl (Genarg.get_arg_tag wit_%s, %i)@]" e l let print_string fmt s = fprintf fmt "\"%s\"" s let print_opt fmt pr = function | None -> fprintf fmt "None" | Some x -> fprintf fmt "Some@ @[(%a)@]" pr x module GramExt : sig val print_extrule : Format.formatter -> (symb list * string option list * code) -> unit val print_ast : Format.formatter -> grammar_ext -> unit end = struct let is_uident s = match s.[0] with | 'A'..'Z' -> true | _ -> false let is_qualified = is_uident let get_local_entries ext = let global = StringSet.of_list ext.gramext_globals in let map e = e.gentry_name in let entries = List.map map ext.gramext_entries in let local = List.filter (fun e -> not (is_qualified e || StringSet.mem e global)) entries in let rec uniquize seen = function | [] -> [] | id :: rem -> let rem = uniquize (StringSet.add id seen) rem in if StringSet.mem id seen then rem else id :: rem in uniquize StringSet.empty local let print_local fmt ext = let locals = get_local_entries ext in match locals with | [] -> () | e :: locals -> let mk_e fmt e = fprintf fmt "Procq.Entry.make \"%s\"" e in let () = fprintf fmt "@[ let iter e = fprintf fmt "@[ let () = List.iter iter locals in fprintf fmt "in@ " let print_position fmt pos = match pos with | First -> fprintf fmt "Gramlib.Gramext.First" | Last -> fprintf fmt "Gramlib.Gramext.Last" | Before s -> fprintf fmt "Gramlib.Gramext.Before@ \"%s\"" s | After s -> fprintf fmt "Gramlib.Gramext.After@ \"%s\"" s let print_assoc fmt = function | LeftA -> fprintf fmt "Gramlib.Gramext.LeftA" | RightA -> fprintf fmt "Gramlib.Gramext.RightA" | NonA -> fprintf fmt "Gramlib.Gramext.NonA" let is_token s = match string_split s with | [s] -> is_uident s | _ -> false let rec parse_tokens ?(in_anon=false) = let err_anon () = if in_anon then fatal (Printf.sprintf "'SELF' or 'NEXT' illegal in anonymous entry level") in function | [GSymbString s] -> SymbToken ("", Some s) | [GSymbQualid ("QUOTATION", None); GSymbString s] -> SymbToken ("QUOTATION", Some s) | [GSymbQualid ("SELF", None)] -> err_anon (); SymbSelf | [GSymbQualid ("NEXT", None)] -> err_anon (); SymbNext | [GSymbQualid ("LIST0", None); tkn] -> SymbList0 (parse_token ~in_anon tkn, None) | [GSymbQualid ("LIST1", None); tkn] -> SymbList1 (parse_token ~in_anon tkn, None) | [GSymbQualid ("LIST0", None); tkn; GSymbQualid ("SEP", None); tkn'] -> SymbList0 (parse_token ~in_anon tkn, Some (parse_token ~in_anon tkn')) | [GSymbQualid ("LIST1", None); tkn; GSymbQualid ("SEP", None); tkn'] -> SymbList1 (parse_token ~in_anon tkn, Some (parse_token ~in_anon tkn')) | [GSymbQualid ("OPT", None); tkn] -> SymbOpt (parse_token ~in_anon tkn) | [GSymbQualid (e, None)] when is_token e -> SymbToken (e, None) | [GSymbQualid (e, None); GSymbString s] when is_token e -> SymbToken (e, Some s) | [GSymbQualid (e, lvl)] when not (is_token e) -> SymbEntry (e, lvl) | [GSymbParen tkns] -> parse_tokens ~in_anon tkns | [GSymbProd prds] -> let map p = let map (pat, tkns) = (pat, parse_tokens ~in_anon:true tkns) in (List.map map p.gprod_symbs, p.gprod_body) in SymbRules (List.map map prds) | t -> let rec db_token = function | GSymbString s -> Printf.sprintf "\"%s\"" s | GSymbQualid (s, _) -> Printf.sprintf "%s" s | GSymbParen s -> Printf.sprintf "(%s)" (db_tokens s) | GSymbProd _ -> Printf.sprintf "[...]" and db_tokens tkns = let s = List.map db_token tkns in String.concat " " s in fatal (Printf.sprintf "Invalid token: %s" (db_tokens t)) and parse_token ~in_anon tkn = parse_tokens ~in_anon [tkn] let print_fun fmt (vars, body) = let vars = List.rev vars in let iter = function | None -> fprintf fmt "_@ " | Some id -> fprintf fmt "%s@ " id in let () = fprintf fmt "fun@ " in let () = List.iter iter vars in let () = fprintf fmt "loc ->@ @[%a@]" print_code body in () (** Meta-program instead of calling Tok.of_pattern here because otherwise violates value restriction *) let print_tok fmt = let print_pat fmt = print_opt fmt print_string in function | "", Some s -> fprintf fmt "Tok.PKEYWORD (%a)" print_string s | "IDENT", s -> fprintf fmt "Tok.PIDENT (%a)" print_pat s | "FIELD", s -> fprintf fmt "Tok.PFIELD (%a)" print_pat s | "NUMBER", None -> fprintf fmt "Tok.PNUMBER None" | "NUMBER", Some s -> fprintf fmt "Tok.PNUMBER (Some (Option.get (NumTok.Unsigned.parse_ | "STRING", s -> fprintf fmt "Tok.PSTRING (%a)" print_pat s | "LEFTQMARK", None -> fprintf fmt "Tok.PLEFTQMARK" | "BULLET", s -> fprintf fmt "Tok.PBULLET (%a)" print_pat s | "QUOTATION", Some s -> fprintf fmt "Tok.PQUOTATION %a" print_string s | "EOI", None -> fprintf fmt "Tok.PEOI" | _ -> failwith "Tok.of_pattern: not a constructor" let rec print_prod fmt p = let (vars, tkns) = List.split p.gprod_symbs in let tkn = List.map parse_tokens tkns in print_extrule fmt (tkn, vars, p.gprod_body) and print_extrule fmt (tkn, vars, body) = let tkn = List.rev tkn in fprintf fmt "@[Procq.Production.make@ @[(%a)@]@ @[(%a)@]@]" (print_symbols ~norec:fa and print_symbols ~norec fmt = function | [] -> fprintf fmt "Procq.Rule.stop" | tkn :: tkns -> let c = if norec then "Procq.Rule.next_norec" else "Procq.Rule.next" in fprintf fmt "@[%s@ (%a)@ (%a)@]" c (print_symbols ~norec) tkns print_symbol tkn and print_symbol fmt tkn = match tkn with | SymbToken (t, s) -> fprintf fmt "(Procq.Symbol.token (%a))" print_tok (t, s) | SymbEntry (e, None) -> fprintf fmt "(Procq.Symbol.nterm %s)" e | SymbEntry (e, Some l) -> fprintf fmt "(Procq.Symbol.nterml %s (%a))" e print_string l | SymbSelf -> fprintf fmt "Procq.Symbol.self" | SymbNext -> fprintf fmt "Procq.Symbol.next" | SymbList0 (s, None) -> fprintf fmt "(Procq.Symbol.list0 %a)" print_symbol s | SymbList0 (s, Some sep) -> fprintf fmt "(Procq.Symbol.list0sep (%a) (%a) false)" print_symbol s print_anonymized | SymbList1 (s, None) -> fprintf fmt "(Procq.Symbol.list1 (%a))" print_symbol s | SymbList1 (s, Some sep) -> fprintf fmt "(Procq.Symbol.list1sep (%a) (%a) false)" print_symbol s print_anonymized | SymbOpt s -> fprintf fmt "(Procq.Symbol.opt %a)" print_symbol s | SymbRules rules -> let pr fmt (r, body) = let (vars, tkn) = List.split r in let tkn = List.rev tkn in fprintf fmt "Procq.Rules.make @[(%a)@ (%a)@]" (print_symbols ~norec:true) tkn print_fu in let pr fmt rules = print_list fmt pr rules in fprintf fmt "(Procq.Symbol.rules %a)" pr (List.rev rules) | SymbQuote c -> fprintf fmt "(%s)" c and print_anonymized_symbol fmt tkn = match tkn with | SymbToken (t, s) -> fprintf fmt "(Procq.Symbol.tokens [Procq.TPattern (%a)])" print_tok (t, s) | _ -> print_symbol fmt (SymbRules [[None, tkn], mk_code "()"]) let print_rule fmt r = let pr_lvl fmt lvl = print_opt fmt print_string lvl in let pr_asc fmt asc = print_opt fmt print_assoc asc in let pr_prd fmt prd = print_list fmt print_prod prd in fprintf fmt "@[(%a,@ %a,@ %a)@]" pr_lvl r.grule_label pr_asc r.grule_assoc pr_prd (List. let gramext_count = ref 0 let gramext_plugin_uid name = let cnt = !gramext_count in incr gramext_count; " ~plugin_uid:(\""^name^"\", \""^(!file_name)^":"^string_of_int cnt^"\")" let grammar_extend () = match check_is_plugin ~what:"GRAMMAR EXTEND" () with | Some name -> "Egramml.grammar_extend"^gramext_plugin_uid name | None -> "Procq.grammar_extend" let print_entry fmt e = match e.gentry_rules with | GDataReuse (pos, r) -> let rules = List.rev r in let pr_pos fmt pos = print_opt fmt print_string pos in let pr_prd fmt prd = print_list fmt print_prod prd in fprintf fmt "let () =@ @[%s@ %s@ @[(Procq.Reuse (%a, %a))@]@]@ in@ " (grammar_extend ()) e.gentry_name pr_pos pos pr_prd rules | GDataFresh (pos, rules) -> let print_rules fmt rules = print_list fmt print_rule rules in let pr_check fmt () = match pos with | None -> fprintf fmt "let () =@ @[assert@ (Procq.Entry.is_empty@ %s)@]@ in@\n" e.gentr | Some _ -> fprintf fmt "" in let pos = match pos with None -> First | Some pos -> pos in fprintf fmt "%alet () =@ @[%s@ %s@ @[(Procq.Fresh@ (%a, %a))@]@]@ in@ " pr_check () (grammar_extend ()) e.gentry_name print_position pos print_rules rules let print_ast fmt ext = let () = fprintf fmt "@[<2>let _ =@ " in let () = fprintf fmt "@[ let () = List.iter (fun e -> print_entry fmt e) ext.gramext_entries in let () = fprintf fmt "()@]@\n" in () end module VernacExt : sig val print_ast : Format.formatter -> vernac_ext -> unit end = struct let print_rule_classifier fmt r = match r.vernac_class with | None -> fprintf fmt "None" | Some f -> let no_binder = function ExtTerminal _ -> true | ExtNonTerminal _ -> false in if List.for_all no_binder r.vernac_toks then fprintf fmt "Some @[(fun ~atts -> %a)@]" print_code f else fprintf fmt "Some @[(fun %a ~atts -> %a)@]" print_binders r.vernac_toks print_code f (* let print_atts fmt = function *) (* | None -> fprintf fmt "@[let () = Attributes.unsupported_attributes atts in@] " *) (* | Some atts -> *) (* let rec print_left fmt = function *) (* | [] -> assert false *) (* | [x,_] -> fprintf fmt "%s" x *) (* | (x,_) :: rem -> fprintf fmt "(%s, %a)" x print_left rem *) (* in *) (* let rec print_right fmt = function *) (* | [] -> assert false *) (* | [_,y] -> fprintf fmt "%s" y *) (* | (_,y) :: rem -> fprintf fmt "(%s ++ %a)" y print_right rem *) (* in *) (* let nota = match atts with [_] -> "" | _ -> "Attributes.Notations." in *) (* fprintf fmt "@[let %a = Attributes.parse %s(%a) atts in@] " *) (* print_left atts nota print_right atts *) let print_atts_left fmt = function | None -> fprintf fmt "()" | Some atts -> let rec aux fmt = function | [] -> assert false | [x,_] -> fprintf fmt "%s" x | (x,_) :: rem -> fprintf fmt "(%s, %a)" x aux rem in aux fmt atts let print_atts_right fmt = function | None -> fprintf fmt "(Attributes.unsupported_attributes atts)" | Some atts -> let rec aux fmt = function | [] -> assert false | [_,y] -> print_code fmt y | (_,y) :: rem -> fprintf fmt "(%a ++ %a)" print_code y aux rem in let nota = match atts with [_] -> "" | _ -> "Attributes.Notations." in fprintf fmt "(Attributes.parse %s%a atts)" nota aux atts let understand_state = function | "close_proof" -> "vtcloseproof", ["lemma"; "pm"] | "open_proof" -> "vtopenproof", [] | "proof" -> "vtmodifyproof", ["pstate"] | "proof_opt_query" -> "vtreadproofopt", ["pstate"] | "proof_query" -> "vtreadproof", ["pstate"] | "read_program" -> "vtreadprogram", ["pm"] | "program" -> "vtmodifyprogram", ["pm"] | "declare_program" -> "vtdeclareprogram", ["pm"] | "program_interactive" -> "vtopenproofprogram", ["pm"] | "opaque_access" -> "vtopaqueaccess", ["opaque_access"] | s -> fatal ("unsupported state specifier: " ^ s) let rec pr_named_arguments fmt = function | [] -> assert false | [s] -> fprintf fmt "~%s" s | s :: l -> fprintf fmt "~%s@ %a" s pr_named_arguments l let pr_begin_wrapper fmt = function | [] -> fprintf fmt "fun () ->" | args -> fprintf fmt "fun %a ->" pr_named_arguments args let pr_end_wrapper fmt = function | [] -> fprintf fmt "" | args -> fprintf fmt "@ %a" pr_named_arguments args let print_body_state state fmt r = let state = match r.vernac_state with Some _ as s -> s | None -> state in match state with | None -> fprintf fmt "Vernactypes.vtdefault (fun () -> %a)" print_code r.vernac_body | Some "CUSTOM" -> print_code fmt r.vernac_body | Some state -> let state, wrap = understand_state state in fprintf fmt "Vernactypes.%s (%a (%a)%a)" state pr_begin_wrapper wrap print_code r.vernac_body pr_end_wrapper wrap let print_body_fun state fmt r = match r.vernac_synterp with | None -> fprintf fmt "let coqpp_body %a%a =@ @[%a@] in@ " print_binders r.vernac_toks print_atts_left r.vernac_atts (print_body_state state) r | Some (id,pe) -> fprintf fmt "let coqpp_body %a%a =@ @[(let %s = %a in %a)@] in@ " print_binders r.vernac_toks print_atts_left r.vernac_atts id print_code pe (print_body_ let print_body state fmt r = fprintf fmt "@[<2>(%a@[<2>fun %a?loc ~atts () ->@]@ @[<2>coqpp_body@ %a%a@])@]" (print_body_fun state) r print_binders r.vernac_toks print_binders r.vernac_toks print_atts_right r.vernac_atts let rec print_sig fmt = function | [] -> fprintf fmt "@[Vernacextend.TyNil@]" | ExtTerminal s :: rem -> fprintf fmt "@[Vernacextend.TyTerminal@ @[<1>(\"%s\",@ %a)@]@]" s print_sig rem | ExtNonTerminal (symb, _) :: rem -> fprintf fmt "@[Vernacextend.TyNonTerminal (%a,@ %a)@]" print_symbol symb print_sig rem let print_rule state fmt r = fprintf fmt "Vernacextend.TyML@ @[ r.vernac_depr print_sig r.vernac_toks (print_body state) r print_rule_classifier r let print_rules state fmt rules = print_list fmt (fun fmt r -> fprintf fmt "(%a)" (print_rule state) r) rules let print_classifier fmt = function (* error could be interesting but would need to check that not all of the rules have a classifier, if we do that we could also check that at least 1 rule has no classifier when the block level classifier is specified *) | ClassifDefault -> fprintf fmt "" | ClassifName "QUERY" -> fprintf fmt "~classifier:(fun ~atts:_ _ -> Vernacextend.classify_as_query)" | ClassifName "SIDEFF" -> fprintf fmt "~classifier:(fun ~atts:_ _ -> Vernacextend.classify_as_sideeff)" | ClassifName s -> fatal (Printf.sprintf "Unknown classifier %s" s) | ClassifCode c -> fprintf fmt "~classifier:(fun ~atts -> %s)" c.code let print_entry fmt = function | None -> fprintf fmt "None" | Some e -> fprintf fmt "(Some (%s))" e.code let print_ast fmt ext = let pr fmt () = fprintf fmt "Vernacextend.static_vernac_extend ~plugin:%s ~command:\"%s\" %a ?entr (pp_opt_plugin_arg ~what:"VERNAC EXTEND" ()) ext.vernacext_name print_classifier ext.vernacext_class print_entry ext.vernacext_entry (print_rules ext.vernacext_state) ext.vernacext_rule in let () = fprintf fmt "let () = @[%a@]@\n" pr () in () end module TacticExt : sig val print_ast : Format.formatter -> tactic_ext -> unit end = struct let rec print_clause fmt = function | [] -> fprintf fmt "@[Tacentries.TyNil@]" | ExtTerminal s :: cl -> fprintf fmt "@[Tacentries.TyIdent (\"%s\", %a)@]" s print_clause cl | ExtNonTerminal (g, _) :: cl -> fprintf fmt "@[Tacentries.TyArg (%a, %a)@]" print_symbol g print_clause cl let print_rule fmt r = fprintf fmt "@[Tacentries.TyML (%a, @[(fun %aist@ -> %a)@])@]" print_clause r.tac_toks print_binders r.tac_toks print_code r.tac_body let print_rules fmt rules = print_list fmt (fun fmt r -> fprintf fmt "(%a)" print_rule r) rules let print_ast fmt ext = let deprecation fmt = function | None -> () | Some { code } -> fprintf fmt "~deprecation:(%s) " code in let pr fmt () = let level = match ext.tacext_level with None -> 0 | Some i -> i in let name = force_is_plugin ~what:"TACTIC EXTEND" () in fprintf fmt "Tacentries.tactic_extend \"%s\" \"%s\" ~level:%i %a%a" name ext.tacext_name level deprecation ext.tacext_deprecated print_rules ext.tacext_rules in let () = fprintf fmt "let () = @[%a@]\n" pr () in () end module VernacArgumentExt : sig val print_ast : Format.formatter -> vernac_argument_ext -> unit val print_rules : Format.formatter -> string * tactic_rule list -> unit end = struct let terminal s = let p = if s <> "" && s.[0] >= '0' && s.[0] <= '9' then "CLexer.terminal_number" else "Procq.terminal" in let c = Printf.sprintf "Procq.Symbol.token (%s \"%s\")" p s in SymbQuote c let rec parse_symb self = function | Ulist1 s -> SymbList1 (parse_symb self s, None) | Ulist1sep (s, sep) -> SymbList1 (parse_symb self s, Some (terminal sep)) | Ulist0 s -> SymbList0 (parse_symb self s, None) | Ulist0sep (s, sep) -> SymbList0 (parse_symb self s, Some (terminal sep)) | Uopt s -> SymbOpt (parse_symb self s) | Uentry e -> if e = self then SymbSelf else SymbEntry (e, None) | Uentryl (e, l) -> assert (e = "tactic"); if l = 5 then SymbEntry ("Pltac.binder_tactic", None) else SymbEntry ("Pltac.ltac_expr", Some (string_of_int l)) let parse_token self = function | ExtTerminal s -> (terminal s, None) | ExtNonTerminal (e, TokNone) -> (parse_symb self e, None) | ExtNonTerminal (e, TokName s) -> (parse_symb self e, Some s) let parse_rule self r = let symbs = List.map (fun t -> parse_token self t) r.tac_toks in let symbs, vars = List.split symbs in (symbs, vars, r.tac_body) let print_rules fmt (name, rules) = (* Rules are reversed. *) let rules = List.rev rules in let rules = List.map (fun r -> parse_rule name r) rules in let pr fmt l = print_list fmt (fun fmt r -> fprintf fmt "(%a)" GramExt.print_extrule r) l in match rules with | [([SymbEntry (e, None)], [Some s], { code = c } )] when String.trim c = s -> (* This is a horrible hack to work around limitations of camlp5 regarding factorization of parsing rules. It allows to recognize rules of the form [ entry(x) ] -> [ x ] so as not to generate a proxy entry and reuse the same entry directly. *) fprintf fmt "@[Vernacextend.Arg_alias@ @[<2>(%s)@]@]" e | _ -> fprintf fmt "@[Vernacextend.Arg_rules@ @[<2>(%a)@]@]" pr rules let print_printer fmt = function | None -> fprintf fmt "@[fun _ -> Pp.str \"missing printer\"@]" | Some f -> print_code fmt f let print_ast fmt arg = let name = arg.vernacargext_name in let pr fmt () = fprintf fmt "Vernacextend.vernac_argument_extend ~plugin:%s ~name:%a @[<2>{@\n\ Vernacextend.arg_parsing =@ %a;@\n\ Vernacextend.arg_printer = fun env sigma ->@ %a;@\n}@]" (pp_opt_plugin_arg ~what:"VERNAC ARGUMENT EXTEND" ()) print_string name print_rules (name, arg.vernacargext_rules) print_printer arg.vernacargext_printer in fprintf fmt "@[<2>let (wit_%s, %s) =@ @[%a@]@]@\nlet _ = (wit_%s, %s)@\n" name name pr () name name end module ArgumentExt : sig val print_ast : Format.formatter -> argument_ext -> unit end = struct let rec print_argtype fmt = function | ExtraArgType s -> fprintf fmt "Geninterp.val_tag (Genarg.topwit wit_%s)" s | PairArgType (arg1, arg2) -> fprintf fmt "Geninterp.Val.Pair (@[(%a)@], @[(%a)@])" print_argtype arg1 print_argtyp | ListArgType arg -> fprintf fmt "Geninterp.Val.List @[(%a)@]" print_argtype arg | OptArgType arg -> fprintf fmt "Geninterp.Val.Opt @[(%a)@]" print_argtype arg let rec print_wit fmt = function | ExtraArgType s -> fprintf fmt "wit_%s" s | PairArgType (arg1, arg2) -> fprintf fmt "Genarg.PairArg (@[(%a)@], @[(%a)@])" print_wit arg1 print_wit arg2 | ListArgType arg -> fprintf fmt "Genarg.ListArg @[(%a)@]" print_wit arg | OptArgType arg -> fprintf fmt "Genarg.OptArg @[(%a)@]" print_wit arg let print_ast fmt arg = let name = arg.argext_name in let pr_tag fmt t = print_opt fmt print_argtype t in let intern fmt () = match arg.argext_glob, arg.argext_type with | Some f, (None | Some _) -> fprintf fmt "@[Tacentries.ArgInternFun ((fun f ist v -> (ist, f ist v)) (%a))@]" pr | None, Some t -> fprintf fmt "@[Tacentries.ArgInternWit (%a)@]" print_wit t | None, None -> fprintf fmt "@[Tacentries.ArgInternFun (fun ist v -> (ist, v))@]" in let subst fmt () = match arg.argext_subst, arg.argext_type with | Some f, (None | Some _) -> fprintf fmt "@[Tacentries.ArgSubstFun (%a)@]" print_code f | None, Some t -> fprintf fmt "@[Tacentries.ArgSubstWit (%a)@]" print_wit t | None, None -> fprintf fmt "@[Tacentries.ArgSubstFun (fun s v -> v)@]" in let interp fmt () = match arg.argext_interp, arg.argext_type with | Some (None, f), (None | Some _) -> fprintf fmt "@[Tacentries.ArgInterpSimple (%a)@]" print_code f | Some (Some kind, f), (None | Some _) -> fatal (Printf.sprintf "Unknown kind %s of interpretation function" kind) | None, Some t -> fprintf fmt "@[Tacentries.ArgInterpWit (%a)@]" print_wit t | None, None -> fprintf fmt "@[Tacentries.ArgInterpRet@]" in let default_printer = mk_code "fun _ _ _ _ -> Pp.str \"missing printer\"" in let rpr = match arg.argext_rprinter, arg.argext_tprinter with | Some f, (None | Some _) -> f | None, Some f -> f | None, None -> default_printer in let gpr = match arg.argext_gprinter, arg.argext_tprinter with | Some f, (None | Some _) -> f | None, Some f -> f | None, None -> default_printer in let tpr = match arg.argext_tprinter with | Some f -> f | None -> default_printer in let pr fmt () = fprintf fmt "Tacentries.argument_extend ~plugin:\"%s\" ~name:%a @[{@\n\ Tacentries.arg_parsing = %a;@\n\ Tacentries.arg_tag = @[%a@];@\n\ Tacentries.arg_intern = @[%a@];@\n\ Tacentries.arg_subst = @[%a@];@\n\ Tacentries.arg_interp = @[%a@];@\n\ Tacentries.arg_printer = @[((fun env sigma -> %a), (fun env sigma -> %a), (fun env sigma -> %a))@]; (force_is_plugin ~what:"ARGUMENT EXTEND" ()) print_string name VernacArgumentExt.print_rules (name, arg.argext_rules) pr_tag arg.argext_type intern () subst () interp () print_code rpr print_code gpr print_code tpr in fprintf fmt "let (wit_%s, %s) = @[%a@]@\nlet _ = (wit_%s, %s)@\n" name name pr () name name end let declare_plugin fmt name = Option.iter (fprintf fmt "let _ = Mltop.add_known_module \"%s\"@\n") name; let () = match !plugin_name with | None -> plugin_name := Some name | Some _ -> fatal "Multiple DECLARE PLUGIN not allowed"; in () let pr_ast fmt = function | Code s -> fprintf fmt "%a@\n" print_code s | Comment s -> fprintf fmt "%s@\n" s | DeclarePlugin name -> declare_plugin fmt name | GramExt gram -> fprintf fmt "%a@\n" GramExt.print_ast gram | VernacExt vernac -> fprintf fmt "%a@\n" VernacExt.print_ast vernac | VernacArgumentExt arg -> fprintf fmt "%a@\n" VernacArgumentExt.print_ast arg | TacticExt tac -> fprintf fmt "%a@\n" TacticExt.print_ast tac | ArgumentExt arg -> fprintf fmt "%a@\n" ArgumentExt.print_ast arg let help () = Format.eprintf "Usage: rocq preprocess-mlg file.mlg@\n%!"; exit 1 let parse = function | ["-help"|"--help"] -> help() | [file] -> file | _ -> help () let output_name file = try Filename.chop_extension file ^ ".ml" with | Invalid_argument _ -> fatal "Input file must have an extension for coqpp [input.ext -> input.ml]" let main args = let file = parse args in let output = output_name file in let ast = parse_file file in let () = file_name := Filename.basename file in let iter fmt ast = Format.fprintf fmt "@[%a@]%!" pr_ast ast in let str = asprintf "%a" (fun fmt ast -> List.iter (iter fmt) ast) ast in let str = fix_exit_code ~filename:output str in let chan = open_out output in let () = output_string chan str in let () = close_out chan in exit 0 ¤ Dauer der Verarbeitung: 0.6 Sekunden (vorverarbeitet) ¤*© Formatika GbR, Deutschland |
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2026-03-28