(***********************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* (name,liftn n (k-i) c)) 0 l let transform_rec loc env sigma (pj,c,lf) indt = let p = pj.uj_val in let (indf,realargs) = dest_ind_type indt in let (ind,params) = dest_ind_family indf in let (mib,mip) = lookup_mind_specif env ind in let recargs = mip.mind_recargs in let mI = mkInd ind in let ci = make_default_case_info env (if Options.do_translate() then RegularStyle else MatchStyle) ind in let nconstr = Array.length mip.mind_consnames in if Array.length lf <> nconstr then (let cj = {uj_val=c; uj_type=mkAppliedInd indt} in error_number_branches_loc loc env sigma cj nconstr); let tyi = snd ind in if mis_is_recursive_subset [tyi] recargs then let dep = is_dependent_elimination env (nf_evar sigma pj.uj_type) indf in let init_depFvec i = if i = tyi then Some(dep,mkRel 1) else None in let depFvec = Array.init mib.mind_ntypes init_depFvec in (* build now the fixpoint *) let lnames,_ = get_arity env indf in let nar = List.length lnames in let nparams = mip.mind_nparams in let constrs = get_constructors env (lift_inductive_family (nar+2) indf) in let branches = array_map3 (fun f t reca -> whd_beta (Indrec.make_rec_branch_arg env sigma (nparams,depFvec,nar+1) f t reca)) (Array.map (lift (nar+2)) lf) constrs (dest_subterms recargs) in let deffix = it_mkLambda_or_LetIn_name env (lambda_create env (applist (mI,List.append (List.map (lift (nar+1)) params) (extended_rel_list 0 lnames)), mkCase (ci, lift (nar+2) p, mkRel 1, branches))) (lift_rel_context 1 lnames) in if noccurn 1 deffix then whd_beta (applist (pop deffix,realargs@[c])) else let ind = applist (mI,(List.append (List.map (lift nar) params) (extended_rel_list 0 lnames))) in let typPfix = it_mkProd_or_LetIn_name env (prod_create env (ind, (if dep then let ext_lnames = (Anonymous,None,ind)::lnames in let args = extended_rel_list 0 ext_lnames in whd_beta (applist (lift (nar+1) p, args)) else let args = extended_rel_list 1 lnames in whd_beta (applist (lift (nar+1) p, args))))) lnames in let fix = mkFix (([|nar|],0), ([|Name(id_of_string "F")|],[|typPfix|],[|deffix|])) in applist (fix,realargs@[c]) else mkCase (ci, p, c, lf) (***********************************************************************) (* To embed constr in rawconstr *) let ((constr_in : constr -> Dyn.t), (constr_out : Dyn.t -> constr)) = create "constr" let mt_evd = Evd.empty let vect_lift_type = Array.mapi (fun i t -> type_app (lift i) t) (* Utilisé pour inférer le prédicat des Cases *) (* Semble exagérement fort *) (* Faudra préférer une unification entre les types de toutes les clauses *) (* et autoriser des ? à rester dans le résultat de l'unification *) let evar_type_fixpoint loc env isevars lna lar vdefj = let lt = Array.length vdefj in if Array.length lar = lt then for i = 0 to lt-1 do if not (the_conv_x_leq env isevars (vdefj.(i)).uj_type (lift lt lar.(i))) then error_ill_typed_rec_body_loc loc env (evars_of isevars) i lna vdefj lar done let check_branches_message loc env isevars c (explft,lft) = for i = 0 to Array.length explft - 1 do if not (the_conv_x_leq env isevars lft.(i) explft.(i)) then let sigma = evars_of isevars in error_ill_formed_branch_loc loc env sigma c i lft.(i) explft.(i) done (* coerce to tycon if any *) let inh_conv_coerce_to_tycon loc env isevars j = function | None -> j | Some typ -> inh_conv_coerce_to loc env isevars j typ let push_rels vars env = List.fold_right push_rel vars env (* let evar_type_case isevars env ct pt lft p c = let (mind,bty,rslty) = type_case_branches env (evars_of isevars) ct pt p c in check_branches_message isevars env (c,ct) (bty,lft); (mind,rslty) *) let strip_meta id = (* For Grammar v7 compatibility *) let s = string_of_id id in if s.[0]='$' then id_of_string (String.sub s 1 (String.length s - 1)) else id let pretype_id loc env (lvar,unbndltacvars) id = let id = strip_meta id in (* May happen in tactics defined by Grammar *) try List.assoc id lvar with Not_found -> try let (n,typ) = lookup_rel_id id (rel_context env) in { uj_val = mkRel n; uj_type = type_app (lift n) typ } with Not_found -> try let (_,_,typ) = lookup_named id env in { uj_val = mkVar id; uj_type = typ } with Not_found -> try (* To build a nicer ltac error message *) match List.assoc id unbndltacvars with | None -> user_err_loc (loc,"", str (string_of_id id ^ " ist not bound to a term")) | Some id0 -> Pretype_errors.error_var_not_found_loc loc id0 with Not_found -> error_var_not_found_loc loc id (* make a dependent predicate from an undependent one *) let make_dep_of_undep env (IndType (indf,realargs)) pj = let n = List.length realargs in let rec decomp n p = if n=0 then p else match kind_of_term p with | Lambda (_,_,c) -> decomp (n-1) c | _ -> decomp (n-1) (applist (lift 1 p, [mkRel 1])) in let sign,s = decompose_prod_n n pj.uj_type in let ind = build_dependent_inductive env indf in let s' = mkProd (Anonymous, ind, s) in let ccl = lift 1 (decomp n pj.uj_val) in let ccl' = mkLambda (Anonymous, ind, ccl) in {uj_val=lam_it ccl' sign; uj_type=prod_it s' sign} (*************************************************************************) (* Main pretyping function *) let pretype_ref isevars env ref = let c = constr_of_reference ref in make_judge c (Retyping.get_type_of env Evd.empty c) let pretype_sort = function | RProp c -> judge_of_prop_contents c | RType _ -> judge_of_new_Type () (* [pretype tycon env isevars lvar lmeta cstr] attempts to type [cstr] *) (* in environment [env], with existential variables [(evars_of isevars)] and *) (* the type constraint tycon *) let rec pretype tycon env isevars lvar = function | RRef (loc,ref) -> inh_conv_coerce_to_tycon loc env isevars (pretype_ref isevars env ref) tycon | RVar (loc, id) -> inh_conv_coerce_to_tycon loc env isevars (pretype_id loc env lvar id) tycon | REvar (loc, ev, instopt) -> (* Ne faudrait-il pas s'assurer que hyps est bien un sous-contexte du contexte courant, et qu'il n'y a pas de Rel "caché" *) let hyps = (Evd.map (evars_of isevars) ev).evar_hyps in let args = match instopt with | None -> instance_from_named_context hyps | Some inst -> failwith "Evar subtitutions not implemented" in let c = mkEvar (ev, args) in let j = (Retyping.get_judgment_of env (evars_of isevars) c) in inh_conv_coerce_to_tycon loc env isevars j tycon | RPatVar (loc,(someta,n)) -> anomaly "Found a pattern variable in a rawterm to type" | RHole (loc,k) -> if !compter then nbimpl:=!nbimpl+1; (match tycon with | Some ty -> { uj_val = new_isevar isevars env (loc,k) ty; uj_type = ty } | None -> error_unsolvable_implicit loc env (evars_of isevars) k) | RRec (loc,fixkind,names,lar,vdef) -> let larj = Array.map (pretype_type empty_valcon env isevars lvar) lar in let lara = Array.map (fun a -> a.utj_val) larj in let nbfix = Array.length lar in let names = Array.map (fun id -> Name id) names in let newenv = push_rec_types (names,lara,[||]) env in let vdefj = Array.mapi (fun i def -> (* we lift nbfix times the type in tycon, because of * the nbfix variables pushed to newenv *) pretype (mk_tycon (lift nbfix (larj.(i).utj_val))) newenv isevars lvar def) vdef in evar_type_fixpoint loc env isevars names lara vdefj; let fixj = match fixkind with | RFix (vn,i as vni) -> let fix = (vni,(names,lara,Array.map j_val vdefj)) in check_fix env fix; make_judge (mkFix fix) lara.(i) | RCoFix i -> let cofix = (i,(names,lara,Array.map j_val vdefj)) in check_cofix env cofix; make_judge (mkCoFix cofix) lara.(i) in inh_conv_coerce_to_tycon loc env isevars fixj tycon | RSort (loc,s) -> inh_conv_coerce_to_tycon loc env isevars (pretype_sort s) tycon | RApp (loc,f,args) -> let fj = pretype empty_tycon env isevars lvar f in let floc = loc_of_rawconstr f in let rec apply_rec env n resj = function | [] -> resj | c::rest -> let argloc = loc_of_rawconstr c in let resj = inh_app_fun env isevars resj in let resty = whd_betadeltaiota env (evars_of isevars) resj.uj_type in match kind_of_term resty with | Prod (na,c1,c2) -> let hj = pretype (mk_tycon c1) env isevars lvar c in let newresj = { uj_val = applist (j_val resj, [j_val hj]); uj_type = subst1 hj.uj_val c2 } in apply_rec env (n+1) newresj rest | _ -> let hj = pretype empty_tycon env isevars lvar c in error_cant_apply_not_functional_loc (join_loc floc argloc) env (evars_of isevars) resj [hj] in let resj = apply_rec env 1 fj args in (* let apply_one_arg (floc,tycon,jl) c = let (dom,rng) = split_tycon floc env isevars tycon in let cj = pretype dom env isevars lvar c in let rng_tycon = option_app (subst1 cj.uj_val) rng in let argloc = loc_of_rawconstr c in (join_loc floc argloc,rng_tycon,(argloc,cj)::jl) in let _,_,jl = List.fold_left apply_one_arg (floc,mk_tycon j.uj_type,[]) args in let jl = List.rev jl in let resj = inh_apply_rel_list loc env isevars jl (floc,j) tycon in *) inh_conv_coerce_to_tycon loc env isevars resj tycon | RLambda(loc,name,c1,c2) -> let (dom,rng) = split_tycon loc env isevars tycon in let dom_valcon = valcon_of_tycon dom in let j = pretype_type dom_valcon env isevars lvar c1 in let var = (name,None,j.utj_val) in let j' = pretype rng (push_rel var env) isevars lvar c2 in judge_of_abstraction env name j j' | RProd(loc,name,c1,c2) -> let j = pretype_type empty_valcon env isevars lvar c1 in let var = (name,j.utj_val) in let env' = push_rel_assum var env in let j' = pretype_type empty_valcon env' isevars lvar c2 in let resj = try judge_of_product env name j j' with TypeError _ as e -> Stdpp.raise_with_loc loc e in inh_conv_coerce_to_tycon loc env isevars resj tycon | RLetIn(loc,name,c1,c2) -> let j = pretype empty_tycon env isevars lvar c1 in let t = Evarutil.refresh_universes j.uj_type in let var = (name,Some j.uj_val,t) in let tycon = option_app (lift 1) tycon in let j' = pretype tycon (push_rel var env) isevars lvar c2 in { uj_val = mkLetIn (name, j.uj_val, t, j'.uj_val) ; uj_type = type_app (subst1 j.uj_val) j'.uj_type } | RLetTuple (loc,nal,(na,po),c,d) -> let cj = pretype empty_tycon env isevars lvar c in let (IndType (indf,realargs) as indt) = try find_rectype env (evars_of isevars) cj.uj_type with Not_found -> let cloc = loc_of_rawconstr c in error_case_not_inductive_loc cloc env (evars_of isevars) cj in let cstrs = get_constructors env indf in if Array.length cstrs <> 1 then user_err_loc (loc,"",str "Destructing let is only for inductive types with one constructor"); let cs = cstrs.(0) in if List.length nal <> cs.cs_nargs then user_err_loc (loc,"", str "Destructing let on this type expects " ++ int cs.cs_nargs ++ str " variables"); let fsign = List.map2 (fun na (_,c,t) -> (na,c,t)) (List.rev nal) cs.cs_args in let env_f = push_rels fsign env in (* Make dependencies from arity signature impossible *) let arsgn,_ = get_arity env indf in let arsgn = List.map (fun (_,b,t) -> (Anonymous,b,t)) arsgn in let psign = (na,None,build_dependent_inductive env indf)::arsgn in let nar = List.length arsgn in (match po with | Some p -> let env_p = push_rels psign env in let pj = pretype_type empty_valcon env_p isevars lvar p in let ccl = nf_evar (evars_of isevars) pj.utj_val in let psign = make_arity_signature env true indf in (* with names *) let p = it_mkLambda_or_LetIn ccl psign in let inst = (Array.to_list cs.cs_concl_realargs) @[build_dependent_constructor cs] in let lp = lift cs.cs_nargs p in let fty = hnf_lam_applist env (evars_of isevars) lp inst in let fj = pretype (mk_tycon fty) env_f isevars lvar d in let f = it_mkLambda_or_LetIn fj.uj_val fsign in let v = let mis,_ = dest_ind_family indf in let ci = make_default_case_info env LetStyle mis in mkCase (ci, p, cj.uj_val,[|f|]) in let cs = build_dependent_constructor cs in { uj_val = v; uj_type = substl (realargs@[cj.uj_val]) ccl } | None -> let tycon = option_app (lift cs.cs_nargs) tycon in let fj = pretype tycon env_f isevars lvar d in let f = it_mkLambda_or_LetIn fj.uj_val fsign in let ccl = nf_evar (evars_of isevars) fj.uj_type in let ccl = if noccur_between 1 cs.cs_nargs ccl then lift (- cs.cs_nargs) ccl else error_cant_find_case_type_loc loc env (evars_of isevars) cj.uj_val in let p = it_mkLambda_or_LetIn (lift (nar+1) ccl) psign in let v = let mis,_ = dest_ind_family indf in let ci = make_default_case_info env LetStyle mis in mkCase (ci, p, cj.uj_val,[|f|] ) in { uj_val = v; uj_type = ccl }) (* Special Case for let constructions to avoid exponential behavior *) | ROrderedCase (loc,st,po,c,[|f|],xx) when st <> MatchStyle -> let cj = pretype empty_tycon env isevars lvar c in let (IndType (indf,realargs) as indt) = try find_rectype env (evars_of isevars) cj.uj_type with Not_found -> let cloc = loc_of_rawconstr c in error_case_not_inductive_loc cloc env (evars_of isevars) cj in let j = match po with | Some p -> let pj = pretype empty_tycon env isevars lvar p in let dep = is_dependent_elimination env pj.uj_type indf in let ar = arity_of_case_predicate env indf dep (Type (new_univ())) in let _ = the_conv_x_leq env isevars pj.uj_type ar in let pj = j_nf_evar (evars_of isevars) pj in let pj = if dep then pj else make_dep_of_undep env indt pj in let (bty,rsty) = Indrec.type_rec_branches false env (evars_of isevars) indt pj.uj_val cj.uj_val in if Array.length bty <> 1 then error_number_branches_loc loc env (evars_of isevars) cj (Array.length bty); let fj = let tyc = bty.(0) in pretype (mk_tycon tyc) env isevars lvar f in let fv = j_val fj in let ft = fj.uj_type in check_branches_message loc env isevars cj.uj_val (bty,[|ft|]); let v = let mis,_ = dest_ind_family indf in let ci = make_default_case_info env st mis in mkCase (ci, (nf_betaiota pj.uj_val), cj.uj_val,[|fv|]) in { uj_val = v; uj_type = rsty } | None -> (* get type information from type of branches *) let expbr = Cases.branch_scheme env isevars false indf in if Array.length expbr <> 1 then error_number_branches_loc loc env (evars_of isevars) cj (Array.length expbr); let expti = expbr.(0) in let fj = pretype (mk_tycon expti) env isevars lvar f in let use_constraint () = (* get type information from constraint *) (* warning: if the constraint comes from an evar type, it *) (* may be Type while Prop or Set would be expected *) match tycon with | Some pred -> let arsgn = make_arity_signature env true indf in let pred = lift (List.length arsgn) pred in let pred = it_mkLambda_or_LetIn (nf_evar (evars_of isevars) pred) arsgn in false, pred | None -> let sigma = evars_of isevars in error_cant_find_case_type_loc loc env sigma cj.uj_val in let ok, p = try let pred = Cases.pred_case_ml env (evars_of isevars) false indt (0,fj.uj_type) in if has_undefined_isevars isevars pred then use_constraint () else true, pred with Cases.NotInferable _ -> use_constraint () in let p = nf_evar (evars_of isevars) p in let (bty,rsty) = Indrec.type_rec_branches false env (evars_of isevars) indt p cj.uj_val in let _ = option_app (the_conv_x_leq env isevars rsty) tycon in let fj = if ok then fj else pretype (mk_tycon bty.(0)) env isevars lvar f in let fv = fj.uj_val in let ft = fj.uj_type in let v = let mis,_ = dest_ind_family indf in let ci = make_default_case_info env st mis in mkCase (ci, (nf_betaiota p), cj.uj_val,[|fv|] ) in { uj_val = v; uj_type = rsty } in (* Build the LetTuple form for v8 *) let c = let (ind,params) = dest_ind_family indf in let rtntypopt, indnalopt = match po with | None -> None, (Anonymous,None) | Some p -> let pj = pretype empty_tycon env isevars lvar p in let dep = is_dependent_elimination env pj.uj_type indf in let rec decomp_lam_force n avoid l p = (* avoid is not exhaustive ! *) if n = 0 then (List.rev l,p,avoid) else match p with | RLambda (_,(Name id as na),_,c) -> decomp_lam_force (n-1) (id::avoid) (na::l) c | RLambda (_,(Anonymous as na),_,c) -> decomp_lam_force (n-1) avoid (na::l) c | _ -> let x = Nameops.next_ident_away (id_of_string "x") avoid in decomp_lam_force (n-1) (x::avoid) (Name x :: l) (* eta-expansion *) (RApp (dummy_loc,p, [RVar (dummy_loc,x)])) in let (nal,p,avoid) = decomp_lam_force (List.length realargs) [] [] p in let na,rtntyp,_ = if dep then decomp_lam_force 1 avoid [] p else [Anonymous],p,[] in let intyp = if List.for_all (function | Anonymous -> true | Name id -> not (occur_rawconstr id rtntyp)) nal then (* No dependency in realargs *) None else let args = List.map (fun _ -> Anonymous) params @ nal in Some (dummy_loc,ind,args) in (Some rtntyp,(List.hd na,intyp)) in let cs = (get_constructors env indf).(0) in match indnalopt with | (na,None) -> (* Represented as a let *) let rec decomp_lam_force n avoid l p = if n = 0 then (List.rev l,p) else match p with | RLambda (_,(Name id as na),_,c) -> decomp_lam_force (n-1) (id::avoid) (na::l) c | RLambda (_,(Anonymous as na),_,c) -> decomp_lam_force (n-1) avoid (na::l) c | _ -> let x = Nameops.next_ident_away (id_of_string "x") avoid in decomp_lam_force (n-1) (x::avoid) (Name x :: l) (* eta-expansion *) (let a = RVar (dummy_loc,x) in match p with | RApp (loc,p,l) -> RApp (loc,p,l@[a]) | _ -> (RApp (dummy_loc,p,[a]))) in let (nal,d) = decomp_lam_force cs.cs_nargs [] [] f in RLetTuple (loc,nal,(na,rtntypopt),c,d) | _ -> (* Represented as a match *) let detype_eqn constr construct_nargs branch = let name_cons = function | Anonymous -> fun l -> l | Name id -> fun l -> id::l in let make_pat na avoid b ids = PatVar (dummy_loc,na), name_cons na avoid,name_cons na ids in let rec buildrec ids patlist avoid n b = if n=0 then (dummy_loc, ids, [PatCstr(dummy_loc, constr, List.rev patlist,Anonymous)], b) else match b with | RLambda (_,x,_,b) -> let pat,new_avoid,new_ids = make_pat x avoid b ids in buildrec new_ids (pat::patlist) new_avoid (n-1) b | RLetIn (_,x,_,b) -> let pat,new_avoid,new_ids = make_pat x avoid b ids in buildrec new_ids (pat::patlist) new_avoid (n-1) b | RCast (_,c,_) -> (* Oui, il y a parfois des cast *) buildrec ids patlist avoid n c | _ -> (* eta-expansion *) (* nommage de la nouvelle variable *) let id = Nameops.next_ident_away (id_of_string "x") avoid in let new_b = RApp (dummy_loc, b, [RVar(dummy_loc,id)])in let pat,new_avoid,new_ids = make_pat (Name id) avoid new_b ids in buildrec new_ids (pat::patlist) new_avoid (n-1) new_b in buildrec [] [] [] construct_nargs branch in let eqn = detype_eqn (ind,1) cs.cs_nargs f in RCases (loc,(po,ref rtntypopt),[c,ref indnalopt],[eqn]) in xx := Some c; (* End building the v8 syntax *) j | RIf (loc,c,(na,po),b1,b2) -> let cj = pretype empty_tycon env isevars lvar c in let (IndType (indf,realargs) as indt) = try find_rectype env (evars_of isevars) cj.uj_type with Not_found -> let cloc = loc_of_rawconstr c in error_case_not_inductive_loc cloc env (evars_of isevars) cj in (* Make dependencies from arity signature impossible *) let arsgn,_ = get_arity env indf in let arsgn = List.map (fun (_,b,t) -> (Anonymous,b,t)) arsgn in let psign = (na,None,build_dependent_inductive env indf)::arsgn in let nar = List.length arsgn in let p = match po with | Some p -> let env_p = push_rels psign env in let pj = pretype_type empty_valcon env_p isevars lvar p in let ccl = nf_evar (evars_of isevars) pj.utj_val in it_mkLambda_or_LetIn ccl psign | None -> (* get type information from type of branches *) let expbr = Cases.branch_scheme env isevars false indf in try let fj = pretype (mk_tycon expbr.(0)) env isevars lvar b1 in let pred = Cases.pred_case_ml env (evars_of isevars) false indt (0,fj.uj_type) in if has_undefined_isevars isevars pred then raise Not_found else (* let _ = option_app (the_conv_x_leq env isevars pred) tycon in *) pred with Cases.NotInferable _ | Not_found -> try let fj = pretype (mk_tycon expbr.(1)) env isevars lvar b2 in let pred = Cases.pred_case_ml env (evars_of isevars) false indt (1,fj.uj_type) in if has_undefined_isevars isevars pred then raise Not_found else (* let _ = option_app (the_conv_x_leq env isevars pred) tycon in *) pred with Cases.NotInferable _ | Not_found -> (* get type information from constraint *) (* warning: if the constraint comes from an evar type, it *) (* may be Type while Prop or Set would be expected *) match tycon with | Some pred -> let arsgn = make_arity_signature env true indf in let pred = lift (List.length arsgn) pred in it_mkLambda_or_LetIn (nf_evar (evars_of isevars) pred) arsgn | None -> let sigma = evars_of isevars in error_cant_find_case_type_loc loc env sigma cj.uj_val in let (bty,rsty) = Indrec.type_rec_branches false env (evars_of isevars) indt p cj.uj_val in let _ = option_app (the_conv_x_leq env isevars rsty) tycon in if Array.length bty <> 2 then user_err_loc (loc,"", str "If is only for inductive types with two constructors"); let bj1 = pretype (mk_tycon bty.(0)) env isevars lvar b1 in let bj2 = pretype (mk_tycon bty.(1)) env isevars lvar b2 in let v = let mis,_ = dest_ind_family indf in let ci = make_default_case_info env IfStyle mis in mkCase (ci, p, cj.uj_val, [|bj1.uj_val;bj2.uj_val|]) in { uj_val = v; uj_type = rsty } | ROrderedCase (loc,st,po,c,lf,x) -> let isrec = (st = MatchStyle) in let cj = pretype empty_tycon env isevars lvar c in let (IndType (indf,realargs) as indt) = try find_rectype env (evars_of isevars) cj.uj_type with Not_found -> let cloc = loc_of_rawconstr c in error_case_not_inductive_loc cloc env (evars_of isevars) cj in let (dep,pj) = match po with | Some p -> let pj = pretype empty_tycon env isevars lvar p in let dep = is_dependent_elimination env pj.uj_type indf in let ar = arity_of_case_predicate env indf dep (Type (new_univ())) in let _ = the_conv_x_leq env isevars pj.uj_type ar in (dep, pj) | None -> (* get type information from type of branches *) let expbr = Cases.branch_scheme env isevars isrec indf in let rec findtype i = if i >= Array.length lf then (* get type information from constraint *) (* warning: if the constraint comes from an evar type, it *) (* may be Type while Prop or Set would be expected *) match tycon with | Some pred -> let arsgn = make_arity_signature env true indf in let pred = lift (List.length arsgn) pred in let pred = it_mkLambda_or_LetIn (nf_evar (evars_of isevars) pred) arsgn in (true, Retyping.get_judgment_of env (evars_of isevars) pred) | None -> let sigma = evars_of isevars in error_cant_find_case_type_loc loc env sigma cj.uj_val else try let expti = expbr.(i) in let fj = pretype (mk_tycon expti) env isevars lvar lf.(i) in let pred = Cases.pred_case_ml (* eta-expanse *) env (evars_of isevars) isrec indt (i,fj.uj_type) in if has_undefined_isevars isevars pred then findtype (i+1) else let pty = Retyping.get_type_of env (evars_of isevars) pred in let pj = { uj_val = pred; uj_type = pty } in (* let _ = option_app (the_conv_x_leq env isevars pred) tycon in *) (true,pj) with Cases.NotInferable _ -> findtype (i+1) in findtype 0 in let pj = j_nf_evar (evars_of isevars) pj in let pj = if dep then pj else make_dep_of_undep env indt pj in let (bty,rsty) = Indrec.type_rec_branches isrec env (evars_of isevars) indt pj.uj_val cj.uj_val in let _ = option_app (the_conv_x_leq env isevars rsty) tycon in if Array.length bty <> Array.length lf then error_number_branches_loc loc env (evars_of isevars) cj (Array.length bty) else let lfj = array_map2 (fun tyc f -> pretype (mk_tycon tyc) env isevars lvar f) bty lf in let lfv = Array.map j_val lfj in let lft = Array.map (fun j -> j.uj_type) lfj in check_branches_message loc env isevars cj.uj_val (bty,lft); let v = if isrec then transform_rec loc env (evars_of isevars)(pj,cj.uj_val,lfv) indt else let mis,_ = dest_ind_family indf in let ci = make_default_case_info env st mis in mkCase (ci, (nf_betaiota pj.uj_val), cj.uj_val, Array.map (fun j-> j.uj_val) lfj) in (* Build the Cases form for v8 *) let c = let (ind,params) = dest_ind_family indf in let (mib,mip) = lookup_mind_specif env ind in let recargs = mip.mind_recargs in let mI = mkInd ind in let nconstr = Array.length mip.mind_consnames in let tyi = snd ind in if isrec && mis_is_recursive_subset [tyi] recargs then Some (Detyping.detype (false,env) (ids_of_context env) (names_of_rel_context env) (nf_evar (evars_of isevars) v)) else (* Translate into a "match ... with" *) let rtntypopt, indnalopt = match po with | None -> None, (Anonymous,None) | Some p -> let rec decomp_lam_force n avoid l p = (* avoid is not exhaustive ! *) if n = 0 then (List.rev l,p,avoid) else match p with | RLambda (_,(Name id as na),_,c) -> decomp_lam_force (n-1) (id::avoid) (na::l) c | RLambda (_,(Anonymous as na),_,c) -> decomp_lam_force (n-1) avoid (na::l) c | _ -> let x = Nameops.next_ident_away (id_of_string "x") avoid in decomp_lam_force (n-1) (x::avoid) (Name x :: l) (* eta-expansion *) (RApp (dummy_loc,p, [RVar (dummy_loc,x)])) in let (nal,p,avoid) = decomp_lam_force (List.length realargs) [] [] p in let na,rtntyopt,_ = if dep then decomp_lam_force 1 avoid [] p else [Anonymous],p,[] in let intyp = if nal=[] then None else let args = List.map (fun _ -> Anonymous) params @ nal in Some (dummy_loc,ind,args) in (Some rtntyopt,(List.hd na,intyp)) in if st = IfStyle & snd indnalopt = None then (* Translate into a "if ... then ... else" *) (* TODO: translate into a "if" even if po is dependent *) Some (RIf (loc,c,(fst indnalopt,rtntypopt),lf.(0),lf.(1))) else let detype_eqn constr construct_nargs branch = let name_cons = function | Anonymous -> fun l -> l | Name id -> fun l -> id::l in let make_pat na avoid b ids = PatVar (dummy_loc,na), name_cons na avoid,name_cons na ids in let rec buildrec ids patlist avoid n b = if n=0 then (dummy_loc, ids, [PatCstr(dummy_loc, constr, List.rev patlist,Anonymous)], b) else match b with | RLambda (_,x,_,b) -> let pat,new_avoid,new_ids = make_pat x avoid b ids in buildrec new_ids (pat::patlist) new_avoid (n-1) b | RLetIn (_,x,_,b) -> let pat,new_avoid,new_ids = make_pat x avoid b ids in buildrec new_ids (pat::patlist) new_avoid (n-1) b | RCast (_,c,_) -> (* Oui, il y a parfois des cast *) buildrec ids patlist avoid n c | _ -> (* eta-expansion *) (* nommage de la nouvelle variable *) let id = Nameops.next_ident_away (id_of_string "x") avoid in let new_b = RApp (dummy_loc, b, [RVar(dummy_loc,id)])in let pat,new_avoid,new_ids = make_pat (Name id) avoid new_b ids in buildrec new_ids (pat::patlist) new_avoid (n-1) new_b in buildrec [] [] [] construct_nargs branch in let (mib,mip) = Inductive.lookup_mind_specif (Global.env()) ind in let get_consnarg j = let typi = mis_nf_constructor_type (ind,mib,mip) (j+1) in let _,t = decompose_prod_n_assum mip.mind_nparams typi in List.rev (fst (decompose_prod_assum t)) in let consnargs = Array.init (Array.length mip.mind_consnames) get_consnarg in let consnargsl = Array.map List.length consnargs in let constructs = Array.init (Array.length lf) (fun i -> (ind,i+1)) in let eqns = array_map3 detype_eqn constructs consnargsl lf in Some (RCases (loc,(po,ref rtntypopt),[c,ref indnalopt],Array.to_list eqns)) in x := c; (* End build the Cases form for v8 *) { uj_val = v; uj_type = rsty } | RCases (loc,po,tml,eqns) -> Cases.compile_cases loc ((fun vtyc env -> pretype vtyc env isevars lvar),isevars) tycon env (* loc *) (po,tml,eqns) | RCast(loc,c,t) -> let tj = pretype_type empty_tycon env isevars lvar t in let cj = pretype (mk_tycon tj.utj_val) env isevars lvar c in (* User Casts are for helping pretyping, experimentally not to be kept*) (* ... except for Correctness *) let v = mkCast (cj.uj_val, tj.utj_val) in let cj = { uj_val = v; uj_type = tj.utj_val } in inh_conv_coerce_to_tycon loc env isevars cj tycon | RDynamic (loc,d) -> if (tag d) = "constr" then let c = constr_out d in let j = (Retyping.get_judgment_of env (evars_of isevars) c) in j (*inh_conv_coerce_to_tycon loc env isevars j tycon*) else user_err_loc (loc,"pretype",(str "Not a constr tagged Dynamic")) (* [pretype_type valcon env isevars lvar c] coerces [c] into a type *) and pretype_type valcon env isevars lvar = function | RHole loc -> if !compter then nbimpl:=!nbimpl+1; (match valcon with | Some v -> { utj_val = v; utj_type = Retyping.get_sort_of env (evars_of isevars) v } | None -> let s = new_Type_sort () in { utj_val = new_isevar isevars env loc (mkSort s); utj_type = s}) | c -> let j = pretype empty_tycon env isevars lvar c in let tj = inh_coerce_to_sort env isevars j in match valcon with | None -> tj | Some v -> if the_conv_x_leq env isevars v tj.utj_val then tj else error_unexpected_type_loc (loc_of_rawconstr c) env (evars_of isevars) tj.utj_val v let unsafe_infer tycon isevars env lvar constr = let j = pretype tycon env isevars lvar constr in j_nf_evar (evars_of isevars) j let unsafe_infer_type valcon isevars env lvar constr = let tj = pretype_type valcon env isevars lvar constr in tj_nf_evar (evars_of isevars) tj (* If fail_evar is false, [process_evars] builds a meta_map with the unresolved Evar that were not in initial sigma; otherwise it fail on the first unresolved Evar not already in the initial sigma. *) (* [fail_evar] says how to process unresolved evars: * true -> raise an error message * false -> convert them into new Metas (casted with their type) *) (* assumes the defined existentials have been replaced in c (should be done in unsafe_infer and unsafe_infer_type) *) let check_evars fail_evar env initial_sigma isevars c = let sigma = evars_of isevars in let rec proc_rec c = match kind_of_term c with | Evar (ev,args as k) -> assert (Evd.in_dom sigma ev); if not (Evd.in_dom initial_sigma ev) then (if fail_evar then let (loc,k) = evar_source ev isevars in error_unsolvable_implicit loc env sigma k) | _ -> iter_constr proc_rec c in proc_rec c (* TODO: comment faire remonter l'information si le typage a resolu des variables du sigma original. il faudrait que la fonction de typage retourne aussi le nouveau sigma... *) (* constr with holes *) type open_constr = evar_map * constr let ise_resolve_casted_gen fail_evar sigma env lvar typ c = let isevars = create_evar_defs sigma in let j = unsafe_infer (mk_tycon typ) isevars env lvar c in check_evars fail_evar env sigma isevars (mkCast(j.uj_val,j.uj_type)); (evars_of isevars, j) let ise_resolve_casted sigma env typ c = ise_resolve_casted_gen true sigma env ([],[]) typ c (* Raw calls to the unsafe inference machine: boolean says if we must fail on unresolved evars, or replace them by Metas; the unsafe_judgment list allows us to extend env with some bindings *) let ise_infer_gen fail_evar sigma env lvar exptyp c = let tycon = match exptyp with None -> empty_tycon | Some t -> mk_tycon t in let isevars = create_evar_defs sigma in let j = unsafe_infer tycon isevars env lvar c in check_evars fail_evar env sigma isevars (mkCast(j.uj_val,j.uj_type)); (evars_of isevars, j) let ise_infer_type_gen fail_evar sigma env lvar c = let isevars = create_evar_defs sigma in let tj = unsafe_infer_type empty_valcon isevars env lvar c in check_evars fail_evar env sigma isevars tj.utj_val; (evars_of isevars, tj) type var_map = (identifier * unsafe_judgment) list let understand_judgment sigma env c = snd (ise_infer_gen true sigma env ([],[]) None c) let understand_type_judgment sigma env c = snd (ise_infer_type_gen true sigma env ([],[]) c) let understand sigma env c = let _, c = ise_infer_gen true sigma env ([],[]) None c in c.uj_val let understand_type sigma env c = let _,c = ise_infer_type_gen true sigma env ([],[]) c in c.utj_val let understand_gen_ltac sigma env lvar ~expected_type:exptyp c = let _, c = ise_infer_gen true sigma env lvar exptyp c in c.uj_val let understand_gen sigma env lvar ~expected_type:exptyp c = let _, c = ise_infer_gen true sigma env (lvar,[]) exptyp c in c.uj_val let understand_gen_tcc sigma env lvar exptyp c = let metamap, c = ise_infer_gen false sigma env (lvar,[]) exptyp c in metamap, c.uj_val let interp_sort = function | RProp c -> Prop c | RType _ -> new_Type_sort () let interp_elimination_sort = function | RProp Null -> InProp | RProp Pos -> InSet | RType _ -> InType