(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* > let rec make_rawwit loc = function | BoolArgType -> <:expr< Genarg.rawwit_bool >> | IntArgType -> <:expr< Genarg.rawwit_int >> | IntOrVarArgType -> <:expr< Genarg.rawwit_int_or_var >> | StringArgType -> <:expr< Genarg.rawwit_string >> | PreIdentArgType -> <:expr< Genarg.rawwit_pre_ident >> | IntroPatternArgType -> <:expr< Genarg.rawwit_intro_pattern >> | IdentArgType b -> <:expr< Genarg.rawwit_ident_gen $mlexpr_of_bool b$ >> | VarArgType -> <:expr< Genarg.rawwit_var >> | RefArgType -> <:expr< Genarg.rawwit_ref >> | SortArgType -> <:expr< Genarg.rawwit_sort >> | ConstrArgType -> <:expr< Genarg.rawwit_constr >> | ConstrMayEvalArgType -> <:expr< Genarg.rawwit_constr_may_eval >> | QuantHypArgType -> <:expr< Genarg.rawwit_quant_hyp >> | RedExprArgType -> <:expr< Genarg.rawwit_red_expr >> | OpenConstrArgType b -> <:expr< Genarg.rawwit_open_constr_gen $mlexpr_of_bool b$ >> | ConstrWithBindingsArgType -> <:expr< Genarg.rawwit_constr_with_bindings >> | BindingsArgType -> <:expr< Genarg.rawwit_bindings >> | List0ArgType t -> <:expr< Genarg.wit_list0 $make_rawwit loc t$ >> | List1ArgType t -> <:expr< Genarg.wit_list1 $make_rawwit loc t$ >> | OptArgType t -> <:expr< Genarg.wit_opt $make_rawwit loc t$ >> | PairArgType (t1,t2) -> <:expr< Genarg.wit_pair $make_rawwit loc t1$ $make_rawwit loc t2$ >> | ExtraArgType s -> <:expr< let module WIT = struct open Extrawit; value wit = $lid:"rawwit_"^s$; end in WIT.wit >> let rec make_globwit loc = function | BoolArgType -> <:expr< Genarg.globwit_bool >> | IntArgType -> <:expr< Genarg.globwit_int >> | IntOrVarArgType -> <:expr< Genarg.globwit_int_or_var >> | StringArgType -> <:expr< Genarg.globwit_string >> | PreIdentArgType -> <:expr< Genarg.globwit_pre_ident >> | IntroPatternArgType -> <:expr< Genarg.globwit_intro_pattern >> | IdentArgType b -> <:expr< Genarg.globwit_ident_gen $mlexpr_of_bool b$ >> | VarArgType -> <:expr< Genarg.globwit_var >> | RefArgType -> <:expr< Genarg.globwit_ref >> | QuantHypArgType -> <:expr< Genarg.globwit_quant_hyp >> | SortArgType -> <:expr< Genarg.globwit_sort >> | ConstrArgType -> <:expr< Genarg.globwit_constr >> | ConstrMayEvalArgType -> <:expr< Genarg.globwit_constr_may_eval >> | RedExprArgType -> <:expr< Genarg.globwit_red_expr >> | OpenConstrArgType b -> <:expr< Genarg.globwit_open_constr_gen $mlexpr_of_bool b$ >> | ConstrWithBindingsArgType -> <:expr< Genarg.globwit_constr_with_bindings >> | BindingsArgType -> <:expr< Genarg.globwit_bindings >> | List0ArgType t -> <:expr< Genarg.wit_list0 $make_globwit loc t$ >> | List1ArgType t -> <:expr< Genarg.wit_list1 $make_globwit loc t$ >> | OptArgType t -> <:expr< Genarg.wit_opt $make_globwit loc t$ >> | PairArgType (t1,t2) -> <:expr< Genarg.wit_pair $make_globwit loc t1$ $make_globwit loc t2$ >> | ExtraArgType s -> <:expr< let module WIT = struct open Extrawit; value wit = $lid:"globwit_"^s$; end in WIT.wit >> let rec make_wit loc = function | BoolArgType -> <:expr< Genarg.wit_bool >> | IntArgType -> <:expr< Genarg.wit_int >> | IntOrVarArgType -> <:expr< Genarg.wit_int_or_var >> | StringArgType -> <:expr< Genarg.wit_string >> | PreIdentArgType -> <:expr< Genarg.wit_pre_ident >> | IntroPatternArgType -> <:expr< Genarg.wit_intro_pattern >> | IdentArgType b -> <:expr< Genarg.wit_ident_gen $mlexpr_of_bool b$ >> | VarArgType -> <:expr< Genarg.wit_var >> | RefArgType -> <:expr< Genarg.wit_ref >> | QuantHypArgType -> <:expr< Genarg.wit_quant_hyp >> | SortArgType -> <:expr< Genarg.wit_sort >> | ConstrArgType -> <:expr< Genarg.wit_constr >> | ConstrMayEvalArgType -> <:expr< Genarg.wit_constr_may_eval >> | RedExprArgType -> <:expr< Genarg.wit_red_expr >> | OpenConstrArgType b -> <:expr< Genarg.wit_open_constr_gen $mlexpr_of_bool b$ >> | ConstrWithBindingsArgType -> <:expr< Genarg.wit_constr_with_bindings >> | BindingsArgType -> <:expr< Genarg.wit_bindings >> | List0ArgType t -> <:expr< Genarg.wit_list0 $make_wit loc t$ >> | List1ArgType t -> <:expr< Genarg.wit_list1 $make_wit loc t$ >> | OptArgType t -> <:expr< Genarg.wit_opt $make_wit loc t$ >> | PairArgType (t1,t2) -> <:expr< Genarg.wit_pair $make_wit loc t1$ $make_wit loc t2$ >> | ExtraArgType s -> <:expr< let module WIT = struct open Extrawit; value wit = $lid:"wit_"^s$; end in WIT.wit >> let has_extraarg = List.exists (function GramNonTerminal(_,ExtraArgType _,_,_) -> true | _ -> false) let statically_known_possibly_empty s (prods,_) = List.for_all (function | GramNonTerminal(_,ExtraArgType s',_,_) -> (* For ExtraArg we don't know (we'll have to test dynamically) *) (* unless it is a recursive call *) s <> s' | GramNonTerminal(_,(OptArgType _|List0ArgType _),_,_) -> (* Opt and List0 parses the empty string *) true | _ -> (* This consumes a token for sure *) false) prods let possibly_empty_subentries loc (prods,act) = let bind_name p v e = match p with | None -> e | Some id -> let s = Names.string_of_id id in <:expr< let $lid:s$ = $v$ in $e$ >> in let rec aux = function | [] -> <:expr< let loc = $default_loc$ in let _ = loc = loc in $act$ >> | GramNonTerminal(_,OptArgType _,_,p) :: tl -> bind_name p <:expr< None >> (aux tl) | GramNonTerminal(_,List0ArgType _,_,p) :: tl -> bind_name p <:expr< [] >> (aux tl) | GramNonTerminal(_,(ExtraArgType _ as t),_,p) :: tl -> (* We check at runtime if extraarg s parses "epsilon" *) let s = match p with None -> "_" | Some id -> Names.string_of_id id in <:expr< let $lid:s$ = match Genarg.default_empty_value $make_rawwit loc t$ with [ None -> raise Exit | Some v -> v ] in $aux tl$ >> | _ -> assert false (* already filtered out *) in if has_extraarg prods then (* Needs a dynamic check; catch all exceptions if ever some rhs raises *) (* an exception rather than returning a value; *) (* declares loc because some code can refer to it; *) (* ensures loc is used to avoid "unused variable" warning *) (true, <:expr< try Some $aux prods$ with [ e when Errors.noncritical e -> None ] >>) else (* Static optimisation *) (false, aux prods) let make_possibly_empty_subentries loc s cl = let cl = List.filter (statically_known_possibly_empty s) cl in if cl = [] then <:expr< None >> else let rec aux = function | (true, e) :: l -> <:expr< match $e$ with [ Some v -> Some v | None -> $aux l$ ] >> | (false, e) :: _ -> <:expr< Some $e$ >> | [] -> <:expr< None >> in aux (List.map (possibly_empty_subentries loc) cl) let make_act loc act pil = let rec make = function | [] -> <:expr< Pcoq.Gram.action (fun loc -> ($act$ : 'a)) >> | GramNonTerminal (_,t,_,Some p) :: tl -> let p = Names.string_of_id p in <:expr< Pcoq.Gram.action (fun $lid:p$ -> let _ = Genarg.in_gen $make_rawwit loc t$ $lid:p$ in $make tl$) >> | (GramTerminal _ | GramNonTerminal (_,_,_,None)) :: tl -> <:expr< Pcoq.Gram.action (fun _ -> $make tl$) >> in make (List.rev pil) let make_prod_item = function | GramTerminal s -> <:expr< Pcoq.gram_token_of_string $str:s$ >> | GramNonTerminal (_,_,g,_) -> <:expr< Pcoq.symbol_of_prod_entry_key $mlexpr_of_prod_entry_key g$ >> let make_rule loc (prods,act) = <:expr< ($mlexpr_of_list make_prod_item prods$,$make_act loc act prods$) >> let declare_tactic_argument loc s (typ, pr, f, g, h) cl = let rawtyp, rawpr, globtyp, globpr = match typ with | `Uniform typ -> typ, pr, typ, pr | `Specialized (a, b, c, d) -> a, b, c, d in let glob = match g with | None -> <:expr< fun e x -> out_gen $make_globwit loc rawtyp$ (Tacinterp.intern_genarg e (Genarg.in_gen $make_rawwit loc rawtyp$ x)) >> | Some f -> <:expr< $lid:f$>> in let interp = match f with | None -> <:expr< fun ist gl x -> let (sigma,a_interp) = Tacinterp.interp_genarg ist gl (Genarg.in_gen $make_globwit loc globtyp$ x) in (sigma , out_gen $make_wit loc globtyp$ a_interp)>> | Some f -> <:expr< $lid:f$>> in let substitute = match h with | None -> <:expr< fun s x -> out_gen $make_globwit loc globtyp$ (Tacinterp.subst_genarg s (Genarg.in_gen $make_globwit loc globtyp$ x)) >> | Some f -> <:expr< $lid:f$>> in let se = mlexpr_of_string s in let wit = <:expr< $lid:"wit_"^s$ >> in let rawwit = <:expr< $lid:"rawwit_"^s$ >> in let globwit = <:expr< $lid:"globwit_"^s$ >> in let rules = mlexpr_of_list (make_rule loc) (List.rev cl) in let default_value = <:expr< $make_possibly_empty_subentries loc s cl$ >> in declare_str_items loc [ <:str_item< value ($lid:"wit_"^s$, $lid:"globwit_"^s$, $lid:"rawwit_"^s$) = Genarg.create_arg $default_value$ $se$>>; <:str_item< value $lid:s$ = Pcoq.create_generic_entry $se$ $rawwit$ >>; <:str_item< do { Tacinterp.add_interp_genarg $se$ ((fun e x -> (Genarg.in_gen $globwit$ ($glob$ e (out_gen $rawwit$ x)))), (fun ist gl x -> let (sigma,a_interp) = $interp$ ist gl (out_gen $globwit$ x) in (sigma , Genarg.in_gen $wit$ a_interp)), (fun subst x -> (Genarg.in_gen $globwit$ ($substitute$ subst (out_gen $globwit$ x))))); Compat.maybe_uncurry (Pcoq.Gram.extend ($lid:s$ : Pcoq.Gram.entry 'a)) (None, [(None, None, $rules$)]); Pptactic.declare_extra_genarg_pprule ($rawwit$, $lid:rawpr$) ($globwit$, $lid:globpr$) ($wit$, $lid:pr$) } >> ] let declare_vernac_argument loc s pr cl = let se = mlexpr_of_string s in let wit = <:expr< $lid:"wit_"^s$ >> in let rawwit = <:expr< $lid:"rawwit_"^s$ >> in let globwit = <:expr< $lid:"globwit_"^s$ >> in let rules = mlexpr_of_list (make_rule loc) (List.rev cl) in let pr_rules = match pr with | None -> <:expr< fun _ _ _ _ -> str $str:"[No printer for "^s^"]"$ >> | Some pr -> <:expr< fun _ _ _ -> $lid:pr$ >> in declare_str_items loc [ <:str_item< value (($lid:"wit_"^s$:Genarg.abstract_argument_type unit Genarg.tlevel), ($lid:"globwit_"^s$:Genarg.abstract_argument_type unit Genarg.glevel), $lid:"rawwit_"^s$) = Genarg.create_arg None $se$ >>; <:str_item< value $lid:s$ = Pcoq.create_generic_entry $se$ $rawwit$ >>; <:str_item< do { Compat.maybe_uncurry (Pcoq.Gram.extend ($lid:s$ : Pcoq.Gram.entry 'a)) (None, [(None, None, $rules$)]); Pptactic.declare_extra_genarg_pprule ($rawwit$, $pr_rules$) ($globwit$, fun _ _ _ _ -> Util.anomaly "vernac argument needs not globwit printer") ($wit$, fun _ _ _ _ -> Util.anomaly "vernac argument needs not wit printer") } >> ] open Vernacexpr open Pcoq open Pcaml open PcamlSig EXTEND GLOBAL: str_item; str_item: [ [ "ARGUMENT"; "EXTEND"; s = entry_name; header = argextend_header; OPT "|"; l = LIST1 argrule SEP "|"; "END" -> declare_tactic_argument loc s header l | "VERNAC"; "ARGUMENT"; "EXTEND"; s = entry_name; pr = OPT ["PRINTED"; "BY"; pr = LIDENT -> pr]; OPT "|"; l = LIST1 argrule SEP "|"; "END" -> declare_vernac_argument loc s pr l ] ] ; argextend_header: [ [ "TYPED"; "AS"; typ = argtype; "PRINTED"; "BY"; pr = LIDENT; f = OPT [ "INTERPRETED"; "BY"; f = LIDENT -> f ]; g = OPT [ "GLOBALIZED"; "BY"; f = LIDENT -> f ]; h = OPT [ "SUBSTITUTED"; "BY"; f = LIDENT -> f ] -> (`Uniform typ, pr, f, g, h) | "PRINTED"; "BY"; pr = LIDENT; f = OPT [ "INTERPRETED"; "BY"; f = LIDENT -> f ]; g = OPT [ "GLOBALIZED"; "BY"; f = LIDENT -> f ]; h = OPT [ "SUBSTITUTED"; "BY"; f = LIDENT -> f ]; "RAW_TYPED"; "AS"; rawtyp = argtype; "RAW_PRINTED"; "BY"; rawpr = LIDENT; "GLOB_TYPED"; "AS"; globtyp = argtype; "GLOB_PRINTED"; "BY"; globpr = LIDENT -> (`Specialized (rawtyp, rawpr, globtyp, globpr), pr, f, g, h) ] ] ; argtype: [ "2" [ e1 = argtype; "*"; e2 = argtype -> PairArgType (e1, e2) ] | "1" [ e = argtype; LIDENT "list" -> List0ArgType e | e = argtype; LIDENT "option" -> OptArgType e ] | "0" [ e = LIDENT -> fst (interp_entry_name false None e "") | "("; e = argtype; ")" -> e ] ] ; argrule: [ [ "["; l = LIST0 genarg; "]"; "->"; "["; e = Pcaml.expr; "]" -> (l,e) ] ] ; genarg: [ [ e = LIDENT; "("; s = LIDENT; ")" -> let t, g = interp_entry_name false None e "" in GramNonTerminal (loc, t, g, Some (Names.id_of_string s)) | e = LIDENT; "("; s = LIDENT; ","; sep = STRING; ")" -> let t, g = interp_entry_name false None e sep in GramNonTerminal (loc, t, g, Some (Names.id_of_string s)) | s = STRING -> if String.length s > 0 && Util.is_letter s.[0] then Lexer.add_keyword s; GramTerminal s ] ] ; entry_name: [ [ s = LIDENT -> s | UIDENT -> failwith "Argument entry names must be lowercase" ] ] ; END