open Util open Names open Term open Pp open Indfun_common open Libnames open Rawterm open Declarations type annot = Struct of identifier | Wf of Topconstr.constr_expr * identifier option | Mes of Topconstr.constr_expr * identifier option type newfixpoint_expr = identifier * annot * Topconstr.local_binder list * Topconstr.constr_expr * Topconstr.constr_expr let rec abstract_rawconstr c = function | [] -> c | Topconstr.LocalRawDef (x,b)::bl -> Topconstr.mkLetInC(x,b,abstract_rawconstr c bl) | Topconstr.LocalRawAssum (idl,t)::bl -> List.fold_right (fun x b -> Topconstr.mkLambdaC([x],t,b)) idl (abstract_rawconstr c bl) let interp_casted_constr_with_implicits sigma env impls c = (* Constrintern.interp_rawconstr_with_implicits sigma env [] impls c *) Constrintern.intern_gen false sigma env ~impls:([],impls) ~allow_soapp:false ~ltacvars:([],[]) c let build_newrecursive (lnameargsardef) = let env0 = Global.env() and sigma = Evd.empty in let (rec_sign,rec_impls) = List.fold_left (fun (env,impls) (recname,_,bl,arityc,_) -> let arityc = Command.generalize_constr_expr arityc bl in let arity = Constrintern.interp_type sigma env0 arityc in let impl = if Impargs.is_implicit_args() then Impargs.compute_implicits env0 arity else [] in let impls' =(recname,([],impl,Notation.compute_arguments_scope arity))::impls in (Environ.push_named (recname,None,arity) env, impls')) (env0,[]) lnameargsardef in let recdef = (* Declare local notations *) let fs = States.freeze() in let def = try List.map (fun (_,_,bl,_,def) -> let def = abstract_rawconstr def bl in interp_casted_constr_with_implicits sigma rec_sign rec_impls def ) lnameargsardef with e -> States.unfreeze fs; raise e in States.unfreeze fs; def in recdef let compute_annot (name,annot,args,types,body) = let names = List.map snd (Topconstr.names_of_local_assums args) in match annot with | None -> if List.length names > 1 then user_err_loc (dummy_loc,"GenFixpoint", Pp.str "the recursive argument needs to be specified"); let new_annot = (id_of_name (List.hd names)) in (name,Struct new_annot,args,types,body) | Some r -> (name,r,args,types,body) let rec is_rec names = let names = List.fold_right Idset.add names Idset.empty in let check_id id = Idset.mem id names in let rec lookup = function | RVar(_,id) -> check_id id | RRef _ | REvar _ | RPatVar _ | RSort _ | RHole _ | RDynamic _ -> false | RCast(_,b,_,_) -> lookup b | RRec _ -> assert false | RIf _ -> failwith "Rif not implemented" | RLetIn(_,_,t,b) | RLambda(_,_,t,b) | RProd(_,_,t,b) | RLetTuple(_,_,_,t,b) -> lookup t || lookup b | RApp(_,f,args) -> List.exists lookup (f::args) | RCases(_,_,el,brl) -> List.exists (fun (e,_) -> lookup e) el || List.exists (fun (_,_,_,ret)-> lookup ret) brl in lookup let prepare_body (name,annot,args,types,body) rt = let n = (Topconstr.local_binders_length args) in (* Pp.msgnl (str "nb lambda to chop : " ++ str (string_of_int n) ++ fnl () ++Printer.pr_rawconstr rt); *) let fun_args,rt' = chop_rlambda_n n rt in (fun_args,rt') let generate_principle do_built fix_rec_l recdefs interactive_proof parametrize (continue_proof : int -> Names.constant array -> Term.constr array -> int -> Tacmach.tactic) = let names = List.map (function (name,_,_,_,_) -> name) fix_rec_l in let fun_bodies = List.map2 prepare_body fix_rec_l recdefs in let funs_args = List.map fst fun_bodies in let funs_types = List.map (function (_,_,_,types,_) -> types) fix_rec_l in try (* We then register the Inductive graphs of the functions *) Rawterm_to_relation.build_inductive parametrize names funs_args funs_types recdefs; if do_built then begin let f_R_mut = Ident (dummy_loc,mk_rel_id (List.nth names 0)) in let ind_kn = fst (locate_with_msg (pr_reference f_R_mut++str ": Not an inductive type!") locate_ind f_R_mut) in let fname_kn (fname,_,_,_,_) = let f_ref = Ident (dummy_loc,fname) in locate_with_msg (pr_reference f_ref++str ": Not an inductive type!") locate_constant f_ref in let funs_kn = Array.of_list (List.map fname_kn fix_rec_l) in let _ = Util.list_map_i (fun i x -> let princ = destConst (Indrec.lookup_eliminator (ind_kn,i) (InProp)) in let princ_type = (Global.lookup_constant princ).Declarations.const_type in New_arg_principle.generate_functional_principle interactive_proof princ_type None None funs_kn i (continue_proof 0 [|funs_kn.(i)|]) ) 0 fix_rec_l in () end with e -> Pp.msg_warning (Cerrors.explain_exn e) let register_struct is_rec fixpoint_exprl = match fixpoint_exprl with | [(fname,_,bl,ret_type,body),_] when not is_rec -> Command.declare_definition fname (Decl_kinds.Global,Options.boxed_definitions (),Decl_kinds.Definition) bl None body (Some ret_type) (fun _ _ -> ()) | _ -> Command.build_recursive fixpoint_exprl (Options.boxed_definitions()) let generate_correction_proof_wf tcc_lemma_ref is_mes f_ref eq_ref rec_arg_num rec_arg_type nb_args relation (_: int) (_:Names.constant array) (_:Term.constr array) (_:int) : Tacmach.tactic = Recdef.prove_principle tcc_lemma_ref is_mes f_ref eq_ref rec_arg_num rec_arg_type nb_args relation let register_wf ?(is_mes=false) fname wf_rel_expr wf_arg args ret_type body pre_hook = let type_of_f = Command.generalize_constr_expr ret_type args in let rec_arg_num = let names = List.map snd (Topconstr.names_of_local_assums args) in match wf_arg with | None -> if List.length names = 1 then 1 else error "Recursive argument must be specified" | Some wf_arg -> Util.list_index (Name wf_arg) names in let unbounded_eq = let f_app_args = Topconstr.CApp (dummy_loc, (None,Topconstr.mkIdentC fname) , (List.map (function | _,Anonymous -> assert false | _,Name e -> (Topconstr.mkIdentC e,None) ) (Topconstr.names_of_local_assums args) ) ) in Topconstr.CApp (dummy_loc,(None,Topconstr.mkIdentC (id_of_string "eq")), [(f_app_args,None);(body,None)]) in let eq = Command.generalize_constr_expr unbounded_eq args in let hook tcc_lemma_ref f_ref eq_ref rec_arg_num rec_arg_type nb_args relation = try pre_hook (generate_correction_proof_wf tcc_lemma_ref is_mes f_ref eq_ref rec_arg_num rec_arg_type nb_args relation ); Command.save_named true with e -> (* No proof done *) () in Recdef.recursive_definition is_mes fname type_of_f wf_rel_expr rec_arg_num eq hook let register_mes fname wf_mes_expr wf_arg args ret_type body = let wf_arg_type,wf_arg = match wf_arg with | None -> begin match args with | [Topconstr.LocalRawAssum ([(_,Name x)],t)] -> t,x | _ -> error "Recursive argument must be specified" end | Some wf_args -> try match List.find (function | Topconstr.LocalRawAssum(l,t) -> List.exists (function (_,Name id) -> id = wf_args | _ -> false) l | _ -> false ) args with | Topconstr.LocalRawAssum(_,t) -> t,wf_args | _ -> assert false with Not_found -> assert false in let ltof = let make_dir l = make_dirpath (List.map id_of_string (List.rev l)) in Libnames.Qualid (dummy_loc,Libnames.qualid_of_sp (Libnames.make_path (make_dir ["Arith";"Wf_nat"]) (id_of_string "ltof"))) in let fun_from_mes = let applied_mes = Topconstr.mkAppC(wf_mes_expr,[Topconstr.mkIdentC wf_arg]) in Topconstr.mkLambdaC ([(dummy_loc,Name wf_arg)],wf_arg_type,applied_mes) in let wf_rel_from_mes = Topconstr.mkAppC(Topconstr.mkRefC ltof,[wf_arg_type;fun_from_mes]) in register_wf ~is_mes:true fname wf_rel_from_mes (Some wf_arg) args ret_type body let do_generate_principle register_built interactive_proof fixpoint_exprl = let recdefs = build_newrecursive fixpoint_exprl in let _is_struct = match fixpoint_exprl with | [((name,Some (Wf (wf_rel,wf_x)),args,types,body))] -> let pre_hook = generate_principle register_built fixpoint_exprl recdefs true false in if register_built then register_wf name wf_rel wf_x args types body pre_hook; false | [((name,Some (Mes (wf_mes,wf_x)),args,types,body))] -> let pre_hook = generate_principle register_built fixpoint_exprl recdefs true false in if register_built then register_mes name wf_mes wf_x args types body pre_hook; false | _ -> let fix_names = List.map (function (name,_,_,_,_) -> name) fixpoint_exprl in let is_one_rec = is_rec fix_names in let old_fixpoint_exprl = List.map (function | (name,Some (Struct id),args,types,body),_ -> let names = List.map snd (Topconstr.names_of_local_assums args) in let annot = try Util.list_index (Name id) names - 1, Topconstr.CStructRec with Not_found -> raise (UserError("",str "Cannot find argument " ++ Ppconstr.pr_id id)) in (name,annot,args,types,body),(None:Vernacexpr.decl_notation) | (name,None,args,types,body),recdef -> let names = (Topconstr.names_of_local_assums args) in if is_one_rec recdef && List.length names > 1 then Util.user_err_loc (Util.dummy_loc,"GenFixpoint", Pp.str "the recursive argument needs to be specified") else (name,(0, Topconstr.CStructRec),args,types,body),(None:Vernacexpr.decl_notation) | (_,Some (Wf _),_,_,_),_ | (_,Some (Mes _),_,_,_),_-> error ("Cannot use mutual definition with well-founded recursion") ) (List.combine fixpoint_exprl recdefs) in (* ok all the expressions are structural *) let fix_names = List.map (function (name,_,_,_,_) -> name) fixpoint_exprl in let is_rec = List.exists (is_rec fix_names) recdefs in if register_built then register_struct is_rec old_fixpoint_exprl; generate_principle register_built fixpoint_exprl recdefs interactive_proof true (New_arg_principle.prove_princ_for_struct interactive_proof); true in () let make_graph (id:identifier) = let c_body = try let c = const_of_id id in Global.lookup_constant c with Not_found -> raise (UserError ("",str "Cannot find " ++ Ppconstr.pr_id id) ) in match c_body.const_body with | None -> error "Cannot build a graph over an axiom !" | Some b -> let env = Global.env () in let body = (force b) in let extern_body,extern_type = let old_implicit_args = Impargs.is_implicit_args () and old_strict_implicit_args = Impargs.is_strict_implicit_args () and old_contextual_implicit_args = Impargs.is_contextual_implicit_args () in let old_rawprint = !Options.raw_print in Options.raw_print := true; Impargs.make_implicit_args false; Impargs.make_strict_implicit_args false; Impargs.make_contextual_implicit_args false; try let res = Constrextern.extern_constr false env body in let res' = Constrextern.extern_type false env c_body.const_type in Impargs.make_implicit_args old_implicit_args; Impargs.make_strict_implicit_args old_strict_implicit_args; Impargs.make_contextual_implicit_args old_contextual_implicit_args; Options.raw_print := old_rawprint; res,res' with | UserError(s,msg) as e -> Impargs.make_implicit_args old_implicit_args; Impargs.make_strict_implicit_args old_strict_implicit_args; Impargs.make_contextual_implicit_args old_contextual_implicit_args; Options.raw_print := old_rawprint; raise e | e -> Impargs.make_implicit_args old_implicit_args; Impargs.make_strict_implicit_args old_strict_implicit_args; Impargs.make_contextual_implicit_args old_contextual_implicit_args; Options.raw_print := old_rawprint; raise e in let expr_list = match extern_body with | Topconstr.CFix(loc,l_id,fixexprl) -> let l = List.map (fun (id,(n,recexp),bl,t,b) -> let nal = List.flatten (List.map (function | Topconstr.LocalRawDef (na,_)-> [] | Topconstr.LocalRawAssum (nal,_) -> nal ) bl ) in let rec_id = match List.nth nal n with |(_,Name id) -> id | _ -> anomaly "" in (id, Some (Struct rec_id),bl,t,b) ) fixexprl in l | _ -> let rec get_args b t : Topconstr.local_binder list * Topconstr.constr_expr * Topconstr.constr_expr = (* Pp.msgnl (str "body: " ++Ppconstr.pr_lconstr_expr b); *) (* Pp.msgnl (str "type: " ++ Ppconstr.pr_lconstr_expr t); *) (* Pp.msgnl (fnl ()); *) match b with | Topconstr.CLambdaN (loc, (nal_ta), b') -> begin let n = (List.fold_left (fun n (nal,_) -> n+List.length nal) 0 nal_ta ) in let rec chop_n_arrow n t = if n > 0 then match t with | Topconstr.CArrow(_,_,t) -> chop_n_arrow (n-1) t | Topconstr.CProdN(_,nal_ta',t') -> let n' = List.fold_left (fun n (nal,t'') -> n+List.length nal) n nal_ta' in assert (n'<= n); chop_n_arrow (n - n') t' | _ -> anomaly "Not enough products" else t in let nal_tas,b'',t'' = get_args b' (chop_n_arrow n t) in (List.map (fun (nal,ta) -> (Topconstr.LocalRawAssum (nal,ta))) nal_ta)@nal_tas, b'',t'' end | _ -> [],b,t in let nal_tas,b,t = get_args extern_body extern_type in [(id,None,nal_tas,t,b)] in do_generate_principle false false expr_list (* let make_graph _ = assert false *) let do_generate_principle = do_generate_principle true