(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* !elim_flag) ; optwrite = (fun b -> elim_flag := b) } let bifinite_elim_flag = ref false let _ = declare_bool_option { optsync = true; optdepr = false; optname = "automatic declaration of induction schemes for non-recursive types"; optkey = ["Nonrecursive";"Elimination";"Schemes"]; optread = (fun () -> !bifinite_elim_flag) ; optwrite = (fun b -> bifinite_elim_flag := b) } let _ = declare_bool_option { optsync = true; optdepr = true; (* compatibility 2014-09-03*) optname = "automatic declaration of induction schemes for non-recursive types"; optkey = ["Record";"Elimination";"Schemes"]; optread = (fun () -> !bifinite_elim_flag) ; optwrite = (fun b -> bifinite_elim_flag := b) } let case_flag = ref false let _ = declare_bool_option { optsync = true; optdepr = false; optname = "automatic declaration of case analysis schemes"; optkey = ["Case";"Analysis";"Schemes"]; optread = (fun () -> !case_flag) ; optwrite = (fun b -> case_flag := b) } let eq_flag = ref false let _ = declare_bool_option { optsync = true; optdepr = false; optname = "automatic declaration of boolean equality"; optkey = ["Boolean";"Equality";"Schemes"]; optread = (fun () -> !eq_flag) ; optwrite = (fun b -> eq_flag := b) } let _ = (* compatibility *) declare_bool_option { optsync = true; optdepr = true; optname = "automatic declaration of boolean equality"; optkey = ["Equality";"Scheme"]; optread = (fun () -> !eq_flag) ; optwrite = (fun b -> eq_flag := b) } let is_eq_flag () = !eq_flag && Flags.version_strictly_greater Flags.V8_2 let eq_dec_flag = ref false let _ = declare_bool_option { optsync = true; optdepr = false; optname = "automatic declaration of decidable equality"; optkey = ["Decidable";"Equality";"Schemes"]; optread = (fun () -> !eq_dec_flag) ; optwrite = (fun b -> eq_dec_flag := b) } let rewriting_flag = ref false let _ = declare_bool_option { optsync = true; optdepr = false; optname ="automatic declaration of rewriting schemes for equality types"; optkey = ["Rewriting";"Schemes"]; optread = (fun () -> !rewriting_flag) ; optwrite = (fun b -> rewriting_flag := b) } (* Util *) let define id internal ctx c t = let f = declare_constant ~internal in let kn = f id (DefinitionEntry { const_entry_body = c; const_entry_secctx = None; const_entry_type = t; const_entry_polymorphic = true; const_entry_universes = snd (Evd.universe_context ctx); const_entry_opaque = false; const_entry_inline_code = false; const_entry_feedback = None; }, Decl_kinds.IsDefinition Scheme) in definition_message id; kn (* Boolean equality *) let declare_beq_scheme_gen internal names kn = ignore (define_mutual_scheme beq_scheme_kind internal names kn) let alarm what internal msg = let debug = false in match internal with | UserAutomaticRequest | InternalTacticRequest -> (if debug then msg_warning (hov 0 msg ++ fnl () ++ what ++ str " not defined.")) | _ -> errorlabstrm "" msg let try_declare_scheme what f internal names kn = try f internal names kn with | ParameterWithoutEquality cst -> alarm what internal (str "Boolean equality not found for parameter " ++ pr_con cst ++ str".") | InductiveWithProduct -> alarm what internal (str "Unable to decide equality of functional arguments.") | InductiveWithSort -> alarm what internal (str "Unable to decide equality of type arguments.") | NonSingletonProp ind -> alarm what internal (str "Cannot extract computational content from proposition " ++ quote (Printer.pr_inductive (Global.env()) ind) ++ str ".") | EqNotFound (ind',ind) -> alarm what internal (str "Boolean equality on " ++ quote (Printer.pr_inductive (Global.env()) ind') ++ strbrk " is missing.") | UndefinedCst s -> alarm what internal (strbrk "Required constant " ++ str s ++ str " undefined.") | AlreadyDeclared msg -> alarm what internal (msg ++ str ".") | DecidabilityMutualNotSupported -> alarm what internal (str "Decidability lemma for mutual inductive types not supported.") | e when Errors.noncritical e -> alarm what internal (str "Unexpected error during scheme creation: " ++ Errors.print e) let beq_scheme_msg mind = let mib = Global.lookup_mind mind in (* TODO: mutual inductive case *) str "Boolean equality on " ++ pr_enum (fun ind -> quote (Printer.pr_inductive (Global.env()) ind)) (List.init (Array.length mib.mind_packets) (fun i -> (mind,i))) let declare_beq_scheme_with l kn = try_declare_scheme (beq_scheme_msg kn) declare_beq_scheme_gen UserIndividualRequest l kn let try_declare_beq_scheme kn = (* TODO: handle Fix, eventually handle proof-irrelevance; improve decidability by depending on decidability for the parameters rather than on the bl and lb properties *) try_declare_scheme (beq_scheme_msg kn) declare_beq_scheme_gen UserAutomaticRequest [] kn let declare_beq_scheme = declare_beq_scheme_with [] (* Case analysis schemes *) let declare_one_case_analysis_scheme ind = let (mib,mip) = Global.lookup_inductive ind in let kind = inductive_sort_family mip in let dep = if kind == InProp then case_scheme_kind_from_prop else case_dep_scheme_kind_from_type in let kelim = elim_sorts (mib,mip) in (* in case the inductive has a type elimination, generates only one induction scheme, the other ones share the same code with the apropriate type *) if Sorts.List.mem InType kelim then ignore (define_individual_scheme dep UserAutomaticRequest None ind) (* Induction/recursion schemes *) let kinds_from_prop = [InType,rect_scheme_kind_from_prop; InProp,ind_scheme_kind_from_prop; InSet,rec_scheme_kind_from_prop] let kinds_from_type = [InType,rect_dep_scheme_kind_from_type; InProp,ind_dep_scheme_kind_from_type; InSet,rec_dep_scheme_kind_from_type] let declare_one_induction_scheme ind = let (mib,mip) = Global.lookup_inductive ind in let kind = inductive_sort_family mip in let from_prop = kind == InProp in let kelim = elim_sorts (mib,mip) in let elims = List.map_filter (fun (sort,kind) -> if Sorts.List.mem sort kelim then Some kind else None) (if from_prop then kinds_from_prop else kinds_from_type) in List.iter (fun kind -> ignore (define_individual_scheme kind UserAutomaticRequest None ind)) elims let declare_induction_schemes kn = let mib = Global.lookup_mind kn in if mib.mind_finite <> Decl_kinds.CoFinite then begin for i = 0 to Array.length mib.mind_packets - 1 do declare_one_induction_scheme (kn,i); done; end (* Decidable equality *) let declare_eq_decidability_gen internal names kn = let mib = Global.lookup_mind kn in if mib.mind_finite <> Decl_kinds.CoFinite then ignore (define_mutual_scheme eq_dec_scheme_kind internal names kn) let eq_dec_scheme_msg ind = (* TODO: mutual inductive case *) str "Decidable equality on " ++ quote (Printer.pr_inductive (Global.env()) ind) let declare_eq_decidability_scheme_with l kn = try_declare_scheme (eq_dec_scheme_msg (kn,0)) declare_eq_decidability_gen UserIndividualRequest l kn let try_declare_eq_decidability kn = try_declare_scheme (eq_dec_scheme_msg (kn,0)) declare_eq_decidability_gen UserAutomaticRequest [] kn let declare_eq_decidability = declare_eq_decidability_scheme_with [] let ignore_error f x = try ignore (f x) with e when Errors.noncritical e -> () let declare_rewriting_schemes ind = if Hipattern.is_inductive_equality ind then begin ignore (define_individual_scheme rew_r2l_scheme_kind UserAutomaticRequest None ind); ignore (define_individual_scheme rew_r2l_dep_scheme_kind UserAutomaticRequest None ind); ignore (define_individual_scheme rew_r2l_forward_dep_scheme_kind UserAutomaticRequest None ind); (* These ones expect the equality to be symmetric; the first one also *) (* needs eq *) ignore_error (define_individual_scheme rew_l2r_scheme_kind UserAutomaticRequest None) ind; ignore_error (define_individual_scheme rew_l2r_dep_scheme_kind UserAutomaticRequest None) ind; ignore_error (define_individual_scheme rew_l2r_forward_dep_scheme_kind UserAutomaticRequest None) ind end let declare_congr_scheme ind = if Hipattern.is_equality_type (mkInd ind) then begin if try Coqlib.check_required_library Coqlib.logic_module_name; true with e when Errors.noncritical e -> false then ignore (define_individual_scheme congr_scheme_kind UserAutomaticRequest None ind) else msg_warning (strbrk "Cannot build congruence scheme because eq is not found") end let declare_sym_scheme ind = if Hipattern.is_inductive_equality ind then (* Expect the equality to be symmetric *) ignore_error (define_individual_scheme sym_scheme_kind UserAutomaticRequest None) ind (* Scheme command *) let smart_global_inductive y = smart_global_inductive y let rec split_scheme l = let env = Global.env() in match l with | [] -> [],[] | (Some id,t)::q -> let l1,l2 = split_scheme q in ( match t with | InductionScheme (x,y,z) -> ((id,x,smart_global_inductive y,z)::l1),l2 | CaseScheme (x,y,z) -> ((id,x,smart_global_inductive y,z)::l1),l2 | EqualityScheme x -> l1,((Some id,smart_global_inductive x)::l2) ) (* if no name has been provided, we build one from the types of the ind requested *) | (None,t)::q -> let l1,l2 = split_scheme q in let names inds recs isdep y z = let ind = smart_global_inductive y in let sort_of_ind = inductive_sort_family (snd (lookup_mind_specif env ind)) in let z' = interp_elimination_sort z in let suffix = ( match sort_of_ind with | InProp -> if isdep then (match z' with | InProp -> inds ^ "_dep" | InSet -> recs ^ "_dep" | InType -> recs ^ "t_dep") else ( match z' with | InProp -> inds | InSet -> recs | InType -> recs ^ "t" ) | _ -> if isdep then (match z' with | InProp -> inds | InSet -> recs | InType -> recs ^ "t" ) else (match z' with | InProp -> inds ^ "_nodep" | InSet -> recs ^ "_nodep" | InType -> recs ^ "t_nodep") ) in let newid = add_suffix (basename_of_global (IndRef ind)) suffix in let newref = (Loc.ghost,newid) in ((newref,isdep,ind,z)::l1),l2 in match t with | CaseScheme (x,y,z) -> names "_case" "_case" x y z | InductionScheme (x,y,z) -> names "_ind" "_rec" x y z | EqualityScheme x -> l1,((None,smart_global_inductive x)::l2) let do_mutual_induction_scheme lnamedepindsort = let lrecnames = List.map (fun ((_,f),_,_,_) -> f) lnamedepindsort and env0 = Global.env() in let sigma, lrecspec = List.fold_right (fun (_,dep,ind,sort) (evd, l) -> let evd, indu = Evd.fresh_inductive_instance env0 evd ind in (evd, (indu,dep,interp_elimination_sort sort) :: l)) lnamedepindsort (Evd.from_env env0,[]) in let sigma, listdecl = Indrec.build_mutual_induction_scheme env0 sigma lrecspec in let declare decl fi lrecref = let decltype = Retyping.get_type_of env0 sigma decl in (* let decltype = refresh_universes decltype in *) let proof_output = Future.from_val ((decl,Univ.ContextSet.empty),Safe_typing.empty_private_constants) in let cst = define fi UserIndividualRequest sigma proof_output (Some decltype) in ConstRef cst :: lrecref in let _ = List.fold_right2 declare listdecl lrecnames [] in fixpoint_message None lrecnames let get_common_underlying_mutual_inductive = function | [] -> assert false | (id,(mind,i as ind))::l as all -> match List.filter (fun (_,(mind',_)) -> not (eq_mind mind mind')) l with | (_,ind')::_ -> raise (RecursionSchemeError (NotMutualInScheme (ind,ind'))) | [] -> if not (List.distinct_f Int.compare (List.map snd (List.map snd all))) then error "A type occurs twice"; mind, List.map_filter (function (Some id,(_,i)) -> Some (i,snd id) | (None,_) -> None) all let do_scheme l = let ischeme,escheme = split_scheme l in (* we want 1 kind of scheme at a time so we check if the user tried to declare different schemes at once *) if not (List.is_empty ischeme) && not (List.is_empty escheme) then error "Do not declare equality and induction scheme at the same time." else ( if not (List.is_empty ischeme) then do_mutual_induction_scheme ischeme else let mind,l = get_common_underlying_mutual_inductive escheme in declare_beq_scheme_with l mind; declare_eq_decidability_scheme_with l mind ) (**********************************************************************) (* Combined scheme *) (* Matthieu Sozeau, Dec 2006 *) let list_split_rev_at index l = let rec aux i acc = function hd :: tl when Int.equal i index -> acc, tl | hd :: tl -> aux (succ i) (hd :: acc) tl | [] -> failwith "List.split_when: Invalid argument" in aux 0 [] l let fold_left' f = function [] -> invalid_arg "fold_left'" | hd :: tl -> List.fold_left f hd tl let build_combined_scheme env schemes = let defs = List.map (fun cst -> (* FIXME *) let evd, c = Evd.fresh_constant_instance env (Evd.from_env env) cst in (c, Typeops.type_of_constant_in env c)) schemes in (* let nschemes = List.length schemes in *) let find_inductive ty = let (ctx, arity) = decompose_prod ty in let (_, last) = List.hd ctx in match kind_of_term last with | App (ind, args) -> let ind = destInd ind in let (_,spec) = Inductive.lookup_mind_specif env (fst ind) in ctx, ind, spec.mind_nrealargs | _ -> ctx, destInd last, 0 in let (c, t) = List.hd defs in let ctx, ind, nargs = find_inductive t in (* Number of clauses, including the predicates quantification *) let prods = nb_prod t - (nargs + 1) in let coqand = Coqlib.build_coq_and () and coqconj = Coqlib.build_coq_conj () in let relargs = rel_vect 0 prods in let concls = List.rev_map (fun (cst, t) -> (* FIXME *) mkApp(mkConstU cst, relargs), snd (decompose_prod_n prods t)) defs in let concl_bod, concl_typ = fold_left' (fun (accb, acct) (cst, x) -> mkApp (coqconj, [| x; acct; cst; accb |]), mkApp (coqand, [| x; acct |])) concls in let ctx, _ = list_split_rev_at prods (List.rev_map (fun (x, y) -> x, None, y) ctx) in let typ = it_mkProd_wo_LetIn concl_typ ctx in let body = it_mkLambda_or_LetIn concl_bod ctx in (body, typ) let do_combined_scheme name schemes = let csts = List.map (fun x -> let refe = Ident x in let qualid = qualid_of_reference refe in try Nametab.locate_constant (snd qualid) with Not_found -> error ((string_of_qualid (snd qualid))^" is not declared.")) schemes in let body,typ = build_combined_scheme (Global.env ()) csts in let proof_output = Future.from_val ((body,Univ.ContextSet.empty),Safe_typing.empty_private_constants) in ignore (define (snd name) UserIndividualRequest Evd.empty proof_output (Some typ)); fixpoint_message None [snd name] (**********************************************************************) let map_inductive_block f kn n = for i=0 to n-1 do f (kn,i) done let declare_default_schemes kn = let mib = Global.lookup_mind kn in let n = Array.length mib.mind_packets in if !elim_flag && (mib.mind_finite <> BiFinite || !bifinite_elim_flag) then declare_induction_schemes kn; if !case_flag then map_inductive_block declare_one_case_analysis_scheme kn n; if is_eq_flag() then try_declare_beq_scheme kn; if !eq_dec_flag then try_declare_eq_decidability kn; if !rewriting_flag then map_inductive_block declare_congr_scheme kn n; if !rewriting_flag then map_inductive_block declare_sym_scheme kn n; if !rewriting_flag then map_inductive_block declare_rewriting_schemes kn n