(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* loc | PatCstr(loc,_,_,_) -> loc type patvar = identifier type glob_sort = GProp of Term.contents | GType of Univ.universe option type binding_kind = Lib.binding_kind = Explicit | Implicit type quantified_hypothesis = AnonHyp of int | NamedHyp of identifier type 'a explicit_bindings = (loc * quantified_hypothesis * 'a) list type 'a bindings = | ImplicitBindings of 'a list | ExplicitBindings of 'a explicit_bindings | NoBindings type 'a with_bindings = 'a * 'a bindings type 'a cast_type = | CastConv of cast_kind * 'a | CastCoerce (* Cast to a base type (eg, an underlying inductive type) *) type glob_constr = | GRef of (loc * global_reference) | GVar of (loc * identifier) | GEvar of loc * existential_key * glob_constr list option | GPatVar of loc * (bool * patvar) (* Used for patterns only *) | GApp of loc * glob_constr * glob_constr list | GLambda of loc * name * binding_kind * glob_constr * glob_constr | GProd of loc * name * binding_kind * glob_constr * glob_constr | GLetIn of loc * name * glob_constr * glob_constr | GCases of loc * case_style * glob_constr option * tomatch_tuples * cases_clauses | GLetTuple of loc * name list * (name * glob_constr option) * glob_constr * glob_constr | GIf of loc * glob_constr * (name * glob_constr option) * glob_constr * glob_constr | GRec of loc * fix_kind * identifier array * glob_decl list array * glob_constr array * glob_constr array | GSort of loc * glob_sort | GHole of (loc * hole_kind) | GCast of loc * glob_constr * glob_constr cast_type and glob_decl = name * binding_kind * glob_constr option * glob_constr and fix_recursion_order = GStructRec | GWfRec of glob_constr | GMeasureRec of glob_constr * glob_constr option and fix_kind = | GFix of ((int option * fix_recursion_order) array * int) | GCoFix of int and predicate_pattern = name * (loc * inductive * int * name list) option and tomatch_tuple = (glob_constr * predicate_pattern) and tomatch_tuples = tomatch_tuple list and cases_clause = (loc * identifier list * cases_pattern list * glob_constr) and cases_clauses = cases_clause list let cases_predicate_names tml = List.flatten (List.map (function | (tm,(na,None)) -> [na] | (tm,(na,Some (_,_,_,nal))) -> na::nal) tml) let mkGApp loc p t = match p with | GApp (loc,f,l) -> GApp (loc,f,l@[t]) | _ -> GApp (loc,p,[t]) let map_glob_decl_left_to_right f (na,k,obd,ty) = let comp1 = Option.map f obd in let comp2 = f ty in (na,k,comp1,comp2) let map_glob_constr_left_to_right f = function | GApp (loc,g,args) -> let comp1 = f g in let comp2 = Util.list_map_left f args in GApp (loc,comp1,comp2) | GLambda (loc,na,bk,ty,c) -> let comp1 = f ty in let comp2 = f c in GLambda (loc,na,bk,comp1,comp2) | GProd (loc,na,bk,ty,c) -> let comp1 = f ty in let comp2 = f c in GProd (loc,na,bk,comp1,comp2) | GLetIn (loc,na,b,c) -> let comp1 = f b in let comp2 = f c in GLetIn (loc,na,comp1,comp2) | GCases (loc,sty,rtntypopt,tml,pl) -> let comp1 = Option.map f rtntypopt in let comp2 = Util.list_map_left (fun (tm,x) -> (f tm,x)) tml in let comp3 = Util.list_map_left (fun (loc,idl,p,c) -> (loc,idl,p,f c)) pl in GCases (loc,sty,comp1,comp2,comp3) | GLetTuple (loc,nal,(na,po),b,c) -> let comp1 = Option.map f po in let comp2 = f b in let comp3 = f c in GLetTuple (loc,nal,(na,comp1),comp2,comp3) | GIf (loc,c,(na,po),b1,b2) -> let comp1 = Option.map f po in let comp2 = f b1 in let comp3 = f b2 in GIf (loc,f c,(na,comp1),comp2,comp3) | GRec (loc,fk,idl,bl,tyl,bv) -> let comp1 = Array.map (Util.list_map_left (map_glob_decl_left_to_right f)) bl in let comp2 = Array.map f tyl in let comp3 = Array.map f bv in GRec (loc,fk,idl,comp1,comp2,comp3) | GCast (loc,c,k) -> let comp1 = f c in let comp2 = match k with CastConv (k,t) -> CastConv (k, f t) | x -> x in GCast (loc,comp1,comp2) | (GVar _ | GSort _ | GHole _ | GRef _ | GEvar _ | GPatVar _) as x -> x let map_glob_constr = map_glob_constr_left_to_right (* let name_app f e = function | Name id -> let (id, e) = f id e in (Name id, e) | Anonymous -> Anonymous, e let fold_ident g idl e = let (idl,e) = Array.fold_right (fun id (idl,e) -> let id,e = g id e in (id::idl,e)) idl ([],e) in (Array.of_list idl,e) let map_glob_constr_with_binders_loc loc g f e = function | GVar (_,id) -> GVar (loc,id) | GApp (_,a,args) -> GApp (loc,f e a, List.map (f e) args) | GLambda (_,na,ty,c) -> let na,e = name_app g e na in GLambda (loc,na,f e ty,f e c) | GProd (_,na,ty,c) -> let na,e = name_app g e na in GProd (loc,na,f e ty,f e c) | GLetIn (_,na,b,c) -> let na,e = name_app g e na in GLetIn (loc,na,f e b,f e c) | GCases (_,tyopt,tml,pl) -> (* We don't modify pattern variable since we don't traverse patterns *) let g' id e = snd (g id e) in let h (_,idl,p,c) = (loc,idl,p,f (List.fold_right g' idl e) c) in GCases (loc,Option.map (f e) tyopt,List.map (f e) tml, List.map h pl) | GRec (_,fk,idl,tyl,bv) -> let idl',e' = fold_ident g idl e in GRec (loc,fk,idl',Array.map (f e) tyl,Array.map (f e') bv) | GCast (_,c,t) -> GCast (loc,f e c,f e t) | GSort (_,x) -> GSort (loc,x) | GHole (_,x) -> GHole (loc,x) | GRef (_,x) -> GRef (loc,x) | GEvar (_,x,l) -> GEvar (loc,x,l) | GPatVar (_,x) -> GPatVar (loc,x) *) let fold_glob_constr f acc = let rec fold acc = function | GVar _ -> acc | GApp (_,c,args) -> List.fold_left fold (fold acc c) args | GLambda (_,_,_,b,c) | GProd (_,_,_,b,c) | GLetIn (_,_,b,c) -> fold (fold acc b) c | GCases (_,_,rtntypopt,tml,pl) -> List.fold_left fold_pattern (List.fold_left fold (Option.fold_left fold acc rtntypopt) (List.map fst tml)) pl | GLetTuple (_,_,rtntyp,b,c) -> fold (fold (fold_return_type acc rtntyp) b) c | GIf (_,c,rtntyp,b1,b2) -> fold (fold (fold (fold_return_type acc rtntyp) c) b1) b2 | GRec (_,_,_,bl,tyl,bv) -> let acc = Array.fold_left (List.fold_left (fun acc (na,k,bbd,bty) -> fold (Option.fold_left fold acc bbd) bty)) acc bl in Array.fold_left fold (Array.fold_left fold acc tyl) bv | GCast (_,c,k) -> fold (match k with CastConv (_, t) -> fold acc t | CastCoerce -> acc) c | (GSort _ | GHole _ | GRef _ | GEvar _ | GPatVar _) -> acc and fold_pattern acc (_,idl,p,c) = fold acc c and fold_return_type acc (na,tyopt) = Option.fold_left fold acc tyopt in fold acc let iter_glob_constr f = fold_glob_constr (fun () -> f) () let occur_glob_constr id = let rec occur = function | GVar (loc,id') -> id = id' | GApp (loc,f,args) -> (occur f) or (List.exists occur args) | GLambda (loc,na,bk,ty,c) -> (occur ty) or ((na <> Name id) & (occur c)) | GProd (loc,na,bk,ty,c) -> (occur ty) or ((na <> Name id) & (occur c)) | GLetIn (loc,na,b,c) -> (occur b) or ((na <> Name id) & (occur c)) | GCases (loc,sty,rtntypopt,tml,pl) -> (occur_option rtntypopt) or (List.exists (fun (tm,_) -> occur tm) tml) or (List.exists occur_pattern pl) | GLetTuple (loc,nal,rtntyp,b,c) -> occur_return_type rtntyp id or (occur b) or (not (List.mem (Name id) nal) & (occur c)) | GIf (loc,c,rtntyp,b1,b2) -> occur_return_type rtntyp id or (occur c) or (occur b1) or (occur b2) | GRec (loc,fk,idl,bl,tyl,bv) -> not (array_for_all4 (fun fid bl ty bd -> let rec occur_fix = function [] -> not (occur ty) && (fid=id or not(occur bd)) | (na,k,bbd,bty)::bl -> not (occur bty) && (match bbd with Some bd -> not (occur bd) | _ -> true) && (na=Name id or not(occur_fix bl)) in occur_fix bl) idl bl tyl bv) | GCast (loc,c,k) -> (occur c) or (match k with CastConv (_, t) -> occur t | CastCoerce -> false) | (GSort _ | GHole _ | GRef _ | GEvar _ | GPatVar _) -> false and occur_pattern (loc,idl,p,c) = not (List.mem id idl) & (occur c) and occur_option = function None -> false | Some p -> occur p and occur_return_type (na,tyopt) id = na <> Name id & occur_option tyopt in occur let add_name_to_ids set na = match na with | Anonymous -> set | Name id -> Idset.add id set let free_glob_vars = let rec vars bounded vs = function | GVar (loc,id') -> if Idset.mem id' bounded then vs else Idset.add id' vs | GApp (loc,f,args) -> List.fold_left (vars bounded) vs (f::args) | GLambda (loc,na,_,ty,c) | GProd (loc,na,_,ty,c) | GLetIn (loc,na,ty,c) -> let vs' = vars bounded vs ty in let bounded' = add_name_to_ids bounded na in vars bounded' vs' c | GCases (loc,sty,rtntypopt,tml,pl) -> let vs1 = vars_option bounded vs rtntypopt in let vs2 = List.fold_left (fun vs (tm,_) -> vars bounded vs tm) vs1 tml in List.fold_left (vars_pattern bounded) vs2 pl | GLetTuple (loc,nal,rtntyp,b,c) -> let vs1 = vars_return_type bounded vs rtntyp in let vs2 = vars bounded vs1 b in let bounded' = List.fold_left add_name_to_ids bounded nal in vars bounded' vs2 c | GIf (loc,c,rtntyp,b1,b2) -> let vs1 = vars_return_type bounded vs rtntyp in let vs2 = vars bounded vs1 c in let vs3 = vars bounded vs2 b1 in vars bounded vs3 b2 | GRec (loc,fk,idl,bl,tyl,bv) -> let bounded' = Array.fold_right Idset.add idl bounded in let vars_fix i vs fid = let vs1,bounded1 = List.fold_left (fun (vs,bounded) (na,k,bbd,bty) -> let vs' = vars_option bounded vs bbd in let vs'' = vars bounded vs' bty in let bounded' = add_name_to_ids bounded na in (vs'',bounded') ) (vs,bounded') bl.(i) in let vs2 = vars bounded1 vs1 tyl.(i) in vars bounded1 vs2 bv.(i) in array_fold_left_i vars_fix vs idl | GCast (loc,c,k) -> let v = vars bounded vs c in (match k with CastConv (_,t) -> vars bounded v t | _ -> v) | (GSort _ | GHole _ | GRef _ | GEvar _ | GPatVar _) -> vs and vars_pattern bounded vs (loc,idl,p,c) = let bounded' = List.fold_right Idset.add idl bounded in vars bounded' vs c and vars_option bounded vs = function None -> vs | Some p -> vars bounded vs p and vars_return_type bounded vs (na,tyopt) = let bounded' = add_name_to_ids bounded na in vars_option bounded' vs tyopt in fun rt -> let vs = vars Idset.empty Idset.empty rt in Idset.elements vs let loc_of_glob_constr = function | GRef (loc,_) -> loc | GVar (loc,_) -> loc | GEvar (loc,_,_) -> loc | GPatVar (loc,_) -> loc | GApp (loc,_,_) -> loc | GLambda (loc,_,_,_,_) -> loc | GProd (loc,_,_,_,_) -> loc | GLetIn (loc,_,_,_) -> loc | GCases (loc,_,_,_,_) -> loc | GLetTuple (loc,_,_,_,_) -> loc | GIf (loc,_,_,_,_) -> loc | GRec (loc,_,_,_,_,_) -> loc | GSort (loc,_) -> loc | GHole (loc,_) -> loc | GCast (loc,_,_) -> loc (**********************************************************************) (* Conversion from glob_constr to cases pattern, if possible *) let rec cases_pattern_of_glob_constr na = function | GVar (loc,id) when na<>Anonymous -> (* Unable to manage the presence of both an alias and a variable *) raise Not_found | GVar (loc,id) -> PatVar (loc,Name id) | GHole (loc,_) -> PatVar (loc,na) | GRef (loc,ConstructRef cstr) -> PatCstr (loc,cstr,[],na) | GApp (loc,GRef (_,ConstructRef (ind,_ as cstr)),args) -> let mib,_ = Global.lookup_inductive ind in let nparams = mib.Declarations.mind_nparams in if nparams > List.length args then user_err_loc (loc,"",Pp.str "Invalid notation for pattern."); let params,args = list_chop nparams args in List.iter (function GHole _ -> () | _ -> user_err_loc (loc,"",Pp.str"Invalid notation for pattern.")) params; let args = List.map (cases_pattern_of_glob_constr Anonymous) args in PatCstr (loc,cstr,args,na) | _ -> raise Not_found (* Turn a closed cases pattern into a glob_constr *) let rec glob_constr_of_closed_cases_pattern_aux = function | PatCstr (loc,cstr,[],Anonymous) -> GRef (loc,ConstructRef cstr) | PatCstr (loc,cstr,l,Anonymous) -> let ref = GRef (loc,ConstructRef cstr) in GApp (loc,ref, List.map glob_constr_of_closed_cases_pattern_aux l) | _ -> raise Not_found let glob_constr_of_closed_cases_pattern = function | PatCstr (loc,cstr,l,na) -> na,glob_constr_of_closed_cases_pattern_aux (PatCstr (loc,cstr,l,Anonymous)) | _ -> raise Not_found (**********************************************************************) (* Reduction expressions *) type 'a glob_red_flag = { rBeta : bool; rIota : bool; rZeta : bool; rDelta : bool; (* true = delta all but rConst; false = delta only on rConst*) rConst : 'a list } let all_flags = {rBeta = true; rIota = true; rZeta = true; rDelta = true; rConst = []} type 'a or_var = ArgArg of 'a | ArgVar of identifier located type occurrences_expr = bool * int or_var list let all_occurrences_expr_but l = (false,l) let no_occurrences_expr_but l = (true,l) let all_occurrences_expr = (false,[]) let no_occurrences_expr = (true,[]) type 'a with_occurrences = occurrences_expr * 'a type ('a,'b,'c) red_expr_gen = | Red of bool | Hnf | Simpl of 'c with_occurrences option | Cbv of 'b glob_red_flag | Lazy of 'b glob_red_flag | Unfold of 'b with_occurrences list | Fold of 'a list | Pattern of 'a with_occurrences list | ExtraRedExpr of string | CbvVm type ('a,'b,'c) may_eval = | ConstrTerm of 'a | ConstrEval of ('a,'b,'c) red_expr_gen * 'a | ConstrContext of (loc * identifier) * 'a | ConstrTypeOf of 'a