open Parse_ast open Ast open Type_internal (* TODO: put this somewhere common *) let id_to_string (Id_aux(id,l)) = match id with | Id(s) -> s | DeIid(s) -> s (* TODO: check for temporary failwiths *) let optmap v f = match v with | None -> None | Some v -> Some (f v) let disable_const_propagation = ref false (* Based on current type checker's behaviour *) let pat_id_is_variable t_env id = match Envmap.apply t_env id with | Some (Base(_,Constructor _,_,_,_,_)) | Some (Base(_,Enum _,_,_,_,_)) -> false | _ -> true let nexp_subst substs exp = let s_t t = typ_subst substs true t in (* let s_typschm (TypSchm_aux (TypSchm_ts (q,t),l)) = TypSchm_aux (TypSchm_ts (q,s_t t),l) in hopefully don't need this anyway *) let s_typschm tsh = tsh in let s_tannot = function | Base ((params,t),tag,ranges,effl,effc,bounds) -> (* TODO: do other fields need mapped? *) Base ((params,s_t t),tag,ranges,effl,effc,bounds) | tannot -> tannot in let rec s_pat (P_aux (p,(l,annot))) = let re p = P_aux (p,(l,s_tannot annot)) in match p with | P_lit _ | P_wild | P_id _ -> re p | P_as (p',id) -> re (P_as (s_pat p', id)) | P_typ (ty,p') -> re (P_typ (ty,s_pat p')) | P_app (id,ps) -> re (P_app (id, List.map s_pat ps)) | P_record (fps,flag) -> re (P_record (List.map s_fpat fps, flag)) | P_vector ps -> re (P_vector (List.map s_pat ps)) | P_vector_indexed ips -> re (P_vector_indexed (List.map (fun (i,p) -> (i,s_pat p)) ips)) | P_vector_concat ps -> re (P_vector_concat (List.map s_pat ps)) | P_tup ps -> re (P_tup (List.map s_pat ps)) | P_list ps -> re (P_list (List.map s_pat ps)) and s_fpat (FP_aux (FP_Fpat (id, p), (l,annot))) = FP_aux (FP_Fpat (id, s_pat p), (l,s_tannot annot)) in let rec s_exp (E_aux (e,(l,annot))) = let re e = E_aux (e,(l,s_tannot annot)) in match e with | E_block es -> re (E_block (List.map s_exp es)) | E_nondet es -> re (E_nondet (List.map s_exp es)) | E_id _ | E_lit _ | E_comment _ -> re e | E_sizeof ne -> re (E_sizeof ne) (* TODO: do this need done? does it appear in type checked code? *) | E_internal_exp (l,annot) -> re (E_internal_exp (l, s_tannot annot)) | E_sizeof_internal (l,annot) -> re (E_sizeof_internal (l, s_tannot annot)) | E_internal_exp_user ((l1,annot1),(l2,annot2)) -> re (E_internal_exp_user ((l1, s_tannot annot1),(l2, s_tannot annot2))) | E_cast (t,e') -> re (E_cast (t, s_exp e')) | E_app (id,es) -> re (E_app (id,List.map s_exp es)) | E_app_infix (e1,id,e2) -> re (E_app_infix (s_exp e1,id,s_exp e2)) | E_tuple es -> re (E_tuple (List.map s_exp es)) | E_if (e1,e2,e3) -> re (E_if (s_exp e1, s_exp e2, s_exp e3)) | E_for (id,e1,e2,e3,ord,e4) -> re (E_for (id,s_exp e1,s_exp e2,s_exp e3,ord,s_exp e4)) | E_vector es -> re (E_vector (List.map s_exp es)) | E_vector_indexed (ies,ed) -> re (E_vector_indexed (List.map (fun (i,e) -> (i,s_exp e)) ies, s_opt_default ed)) | E_vector_access (e1,e2) -> re (E_vector_access (s_exp e1,s_exp e2)) | E_vector_subrange (e1,e2,e3) -> re (E_vector_subrange (s_exp e1,s_exp e2,s_exp e3)) | E_vector_update (e1,e2,e3) -> re (E_vector_update (s_exp e1,s_exp e2,s_exp e3)) | E_vector_update_subrange (e1,e2,e3,e4) -> re (E_vector_update_subrange (s_exp e1,s_exp e2,s_exp e3,s_exp e4)) | E_vector_append (e1,e2) -> re (E_vector_append (s_exp e1,s_exp e2)) | E_list es -> re (E_list (List.map s_exp es)) | E_cons (e1,e2) -> re (E_cons (s_exp e1,s_exp e2)) | E_record fes -> re (E_record (s_fexps fes)) | E_record_update (e,fes) -> re (E_record_update (s_exp e, s_fexps fes)) | E_field (e,id) -> re (E_field (s_exp e,id)) | E_case (e,cases) -> re (E_case (s_exp e, List.map s_pexp cases)) | E_let (lb,e) -> re (E_let (s_letbind lb, s_exp e)) | E_assign (le,e) -> re (E_assign (s_lexp le, s_exp e)) | E_exit e -> re (E_exit (s_exp e)) | E_return e -> re (E_return (s_exp e)) | E_assert (e1,e2) -> re (E_assert (s_exp e1,s_exp e2)) | E_internal_cast ((l,ann),e) -> re (E_internal_cast ((l,s_tannot ann),s_exp e)) | E_comment_struc e -> re (E_comment_struc e) | E_internal_let (le,e1,e2) -> re (E_internal_let (s_lexp le, s_exp e1, s_exp e2)) | E_internal_plet (p,e1,e2) -> re (E_internal_plet (s_pat p, s_exp e1, s_exp e2)) | E_internal_return e -> re (E_internal_return (s_exp e)) and s_opt_default (Def_val_aux (ed,(l,annot))) = match ed with | Def_val_empty -> Def_val_aux (Def_val_empty,(l,s_tannot annot)) | Def_val_dec e -> Def_val_aux (Def_val_dec (s_exp e),(l,s_tannot annot)) and s_fexps (FES_aux (FES_Fexps (fes,flag), (l,annot))) = FES_aux (FES_Fexps (List.map s_fexp fes, flag), (l,s_tannot annot)) and s_fexp (FE_aux (FE_Fexp (id,e), (l,annot))) = FE_aux (FE_Fexp (id,s_exp e),(l,s_tannot annot)) and s_pexp (Pat_aux (Pat_exp (p,e),(l,annot))) = Pat_aux (Pat_exp (s_pat p, s_exp e),(l,s_tannot annot)) and s_letbind (LB_aux (lb,(l,annot))) = match lb with | LB_val_explicit (tysch,p,e) -> LB_aux (LB_val_explicit (s_typschm tysch,s_pat p,s_exp e), (l,s_tannot annot)) | LB_val_implicit (p,e) -> LB_aux (LB_val_implicit (s_pat p,s_exp e), (l,s_tannot annot)) and s_lexp (LEXP_aux (e,(l,annot))) = let re e = LEXP_aux (e,(l,s_tannot annot)) in match e with | LEXP_id _ | LEXP_cast _ -> re e | LEXP_memory (id,es) -> re (LEXP_memory (id,List.map s_exp es)) | LEXP_tup les -> re (LEXP_tup (List.map s_lexp les)) | LEXP_vector (le,e) -> re (LEXP_vector (s_lexp le, s_exp e)) | LEXP_vector_range (le,e1,e2) -> re (LEXP_vector_range (s_lexp le, s_exp e1, s_exp e2)) | LEXP_field (le,id) -> re (LEXP_field (s_lexp le, id)) in s_exp exp let bindings_from_pat t_env p = let rec aux_pat (P_aux (p,annot)) = match p with | P_lit _ | P_wild -> [] | P_as (p,id) -> id_to_string id::(aux_pat p) | P_typ (_,p) -> aux_pat p | P_id id -> let i = id_to_string id in if pat_id_is_variable t_env i then [i] else [] | P_vector ps | P_vector_concat ps | P_app (_,ps) | P_tup ps | P_list ps -> List.concat (List.map aux_pat ps) | P_record (fps,_) -> List.concat (List.map aux_fpat fps) | P_vector_indexed ips -> List.concat (List.map (fun (_,p) -> aux_pat p) ips) and aux_fpat (FP_aux (FP_Fpat (_,p), _)) = aux_pat p in aux_pat p let remove_bound t_env env pat = let bound = bindings_from_pat t_env pat in List.fold_left (fun sub v -> Envmap.remove env v) env bound let split_defs splits (Type_check.Env (d_env,t_env,b_env,tp_env)) defs = let can_match (E_aux (e,(l,annot)) as exp) cases = match e with | E_id id -> let i = id_to_string id in (match Envmap.apply t_env i with | Some(Base(_,Enum _,_,_,_,_)) -> let rec findpat cases = match cases with | [] -> (Reporting_basic.print_err false true l "Monomorphisation" ("Failed to find a case for " ^ i); None) | [Pat_aux (Pat_exp (P_aux (P_wild,_),exp),_)] -> Some exp | (Pat_aux (Pat_exp (P_aux (P_id id',_),exp),_))::tl | (Pat_aux (Pat_exp (P_aux (P_app (id',[]),_),exp),_))::tl -> if i = id_to_string id' then Some exp else findpat tl | (Pat_aux (Pat_exp (P_aux (_,(l',_)),_),_))::_ -> (Reporting_basic.print_err false true l' "Monomorphisation" "Unexpected kind of pattern for enumeration"; None) in findpat cases | _ -> None) (* TODO: could generalise Lit matching *) | E_lit (L_aux ((L_zero | L_one | L_true | L_false) as bit, _)) -> let rec findpat cases = match cases with | [] -> (Reporting_basic.print_err false true l "Monomorphisation" ("Failed to find a case for bit"); None) | [Pat_aux (Pat_exp (P_aux (P_wild,_),exp),_)] -> Some exp | (Pat_aux (Pat_exp (P_aux (P_lit (L_aux (lit, _)),_),exp),_))::tl -> (match bit,lit with | (L_zero | L_false), (L_zero | L_false) -> Some exp | (L_one | L_true ), (L_one | L_true ) -> Some exp | _ -> findpat tl) | (Pat_aux (Pat_exp (P_aux (_,(l',_)),_),_))::_ -> (Reporting_basic.print_err false true l' "Monomorphisation" "Unexpected kind of pattern for bit"; None) in findpat cases | _ -> None in (* TODO: doublecheck *) let lit_eq (L_aux (l1,_)) (L_aux (l2,_)) = match l1,l2 with | (L_zero|L_false), (L_zero|L_false) | (L_one |L_true ), (L_one |L_true) -> Some true | L_undef, _ | _, L_undef -> None | _ -> Some (l1 = l2) in (* TODO: any useful type information revealed? (probably not) *) let try_app_infix (l,ann) (E_aux (e1,ann1)) id (E_aux (e2,ann2)) = let new_l = Generated l in match e1, id, e2 with | E_lit l1, ("=="|"!="), E_lit l2 -> let lit b = if b then L_true else L_false in let lit b = lit (if id = "==" then b else not b) in (match lit_eq l1 l2 with | Some b -> Some (E_aux (E_lit (L_aux (lit b,new_l)), (l,ann))) | None -> None) | _ -> None in let build_nexp_subst l t1 t2 = let rec from_types t1 t2 = let t1 = match t1.t with Tabbrev(_,t) -> t | _ -> t1 in let t2 = match t2.t with Tabbrev(_,t) -> t | _ -> t2 in if t1 = t2 then [] else match t1.t,t2.t with | Tapp (s1,args1), Tapp (s2,args2) -> if s1 = s2 then List.concat (List.map2 from_args args1 args2) else (Reporting_basic.print_err false true l "Monomorphisation" "Unexpected type mismatch"; []) | Ttup ts1, Ttup ts2 -> if List.length ts1 = List.length ts2 then List.concat (List.map2 from_types ts1 ts2) else (Reporting_basic.print_err false true l "Monomorphisation" "Unexpected type mismatch"; []) | _ -> [] and from_args arg1 arg2 = match arg1,arg2 with | TA_typ t1, TA_typ t2 -> from_types t1 t2 | TA_nexp n1, TA_nexp n2 -> from_nexps n1 n2 | _ -> [] and from_nexps n1 n2 = match n1.nexp, n2.nexp with | Nvar s, Nvar s' when s = s' -> [] | Nvar s, _ -> [(s,n2)] | Nadd (n3,n4), Nadd (n5,n6) | Nsub (n3,n4), Nsub (n5,n6) | Nmult (n3,n4), Nmult (n5,n6) -> from_nexps n3 n5 @ from_nexps n4 n6 | N2n (n3,p1), N2n (n4,p2) when p1 = p2 -> from_nexps n3 n4 | Npow (n3,p1), Npow (n4,p2) when p1 = p2 -> from_nexps n3 n4 | Nneg n3, Nneg n4 -> from_nexps n3 n4 | _ -> [] in match t1,t2 with | Base ((_,t1),_,_,_,_,_),Base ((_,t2),_,_,_,_,_) -> from_types t1 t2 | _ -> [] in let nexp_substs = ref [] in (* Constant propogation *) let rec const_prop_exp substs ((E_aux (e,(l,annot))) as exp) = let re e = E_aux (e,(l,annot)) in match e with (* TODO: are there circumstances in which we should get rid of these? *) | E_block es -> re (E_block (List.map (const_prop_exp substs) es)) | E_nondet es -> re (E_nondet (List.map (const_prop_exp substs) es)) | E_id id -> (match Envmap.apply substs (id_to_string id) with | None -> exp | Some exp' -> exp') | E_lit _ | E_sizeof _ | E_internal_exp _ | E_sizeof_internal _ | E_internal_exp_user _ | E_comment _ -> exp | E_cast (t,e') -> re (E_cast (t, const_prop_exp substs e')) | E_app (id,es) -> re (E_app (id,List.map (const_prop_exp substs) es)) | E_app_infix (e1,id,e2) -> let e1',e2' = const_prop_exp substs e1,const_prop_exp substs e2 in (match try_app_infix (l,annot) e1' (id_to_string id) e2' with | Some exp -> exp | None -> re (E_app_infix (e1',id,e2'))) | E_tuple es -> re (E_tuple (List.map (const_prop_exp substs) es)) | E_if (e1,e2,e3) -> let e1' = const_prop_exp substs e1 in let e2',e3' = const_prop_exp substs e2, const_prop_exp substs e3 in (match e1' with | E_aux (E_lit (L_aux ((L_true|L_false) as lit ,_)),_) -> let e' = match lit with L_true -> e2' | _ -> e3' in (match e' with E_aux (_,(_,annot')) -> nexp_substs := build_nexp_subst l annot annot' @ !nexp_substs; e') | _ -> re (E_if (e1',e2',e3'))) | E_for (id,e1,e2,e3,ord,e4) -> re (E_for (id,const_prop_exp substs e1,const_prop_exp substs e2,const_prop_exp substs e3,ord,const_prop_exp (Envmap.remove substs (id_to_string id)) e4)) | E_vector es -> re (E_vector (List.map (const_prop_exp substs) es)) | E_vector_indexed (ies,ed) -> re (E_vector_indexed (List.map (fun (i,e) -> (i,const_prop_exp substs e)) ies, const_prop_opt_default substs ed)) | E_vector_access (e1,e2) -> re (E_vector_access (const_prop_exp substs e1,const_prop_exp substs e2)) | E_vector_subrange (e1,e2,e3) -> re (E_vector_subrange (const_prop_exp substs e1,const_prop_exp substs e2,const_prop_exp substs e3)) | E_vector_update (e1,e2,e3) -> re (E_vector_update (const_prop_exp substs e1,const_prop_exp substs e2,const_prop_exp substs e3)) | E_vector_update_subrange (e1,e2,e3,e4) -> re (E_vector_update_subrange (const_prop_exp substs e1,const_prop_exp substs e2,const_prop_exp substs e3,const_prop_exp substs e4)) | E_vector_append (e1,e2) -> re (E_vector_append (const_prop_exp substs e1,const_prop_exp substs e2)) | E_list es -> re (E_list (List.map (const_prop_exp substs) es)) | E_cons (e1,e2) -> re (E_cons (const_prop_exp substs e1,const_prop_exp substs e2)) | E_record fes -> re (E_record (const_prop_fexps substs fes)) | E_record_update (e,fes) -> re (E_record_update (const_prop_exp substs e, const_prop_fexps substs fes)) | E_field (e,id) -> re (E_field (const_prop_exp substs e,id)) | E_case (e,cases) -> let e' = const_prop_exp substs e in (match can_match e' cases with | None -> re (E_case (e', List.map (const_prop_pexp substs) cases)) | Some (E_aux (_,(_,annot')) as exp) -> nexp_substs := build_nexp_subst l annot annot' @ !nexp_substs; const_prop_exp substs exp) | E_let (lb,e) -> let (lb',substs') = const_prop_letbind substs lb in re (E_let (lb', const_prop_exp substs' e)) | E_assign (le,e) -> re (E_assign (const_prop_lexp substs le, const_prop_exp substs e)) | E_exit e -> re (E_exit (const_prop_exp substs e)) | E_return e -> re (E_return (const_prop_exp substs e)) | E_assert (e1,e2) -> re (E_assert (const_prop_exp substs e1,const_prop_exp substs e2)) | E_internal_cast (ann,e) -> re (E_internal_cast (ann,const_prop_exp substs e)) | E_comment_struc e -> re (E_comment_struc e) | E_internal_let _ | E_internal_plet _ | E_internal_return _ -> raise (Reporting_basic.err_unreachable l "Unexpected internal expression encountered in monomorphisation") and const_prop_opt_default substs ((Def_val_aux (ed,annot)) as eda) = match ed with | Def_val_empty -> eda | Def_val_dec e -> Def_val_aux (Def_val_dec (const_prop_exp substs e),annot) and const_prop_fexps substs (FES_aux (FES_Fexps (fes,flag), annot)) = FES_aux (FES_Fexps (List.map (const_prop_fexp substs) fes, flag), annot) and const_prop_fexp substs (FE_aux (FE_Fexp (id,e), annot)) = FE_aux (FE_Fexp (id,const_prop_exp substs e),annot) and const_prop_pexp substs (Pat_aux (Pat_exp (p,e),l)) = Pat_aux (Pat_exp (p,const_prop_exp (remove_bound t_env substs p) e),l) and const_prop_letbind substs (LB_aux (lb,annot)) = match lb with | LB_val_explicit (tysch,p,e) -> (LB_aux (LB_val_explicit (tysch,p,const_prop_exp substs e), annot), remove_bound t_env substs p) | LB_val_implicit (p,e) -> (LB_aux (LB_val_implicit (p,const_prop_exp substs e), annot), remove_bound t_env substs p) and const_prop_lexp substs ((LEXP_aux (e,annot)) as le) = let re e = LEXP_aux (e,annot) in match e with | LEXP_id _ (* shouldn't end up substituting here *) | LEXP_cast _ -> le | LEXP_memory (id,es) -> re (LEXP_memory (id,List.map (const_prop_exp substs) es)) (* or here *) | LEXP_tup les -> re (LEXP_tup (List.map (const_prop_lexp substs) les)) | LEXP_vector (le,e) -> re (LEXP_vector (const_prop_lexp substs le, const_prop_exp substs e)) | LEXP_vector_range (le,e1,e2) -> re (LEXP_vector_range (const_prop_lexp substs le, const_prop_exp substs e1, const_prop_exp substs e2)) | LEXP_field (le,id) -> re (LEXP_field (const_prop_lexp substs le, id)) in let subst_exp subst exp = if !disable_const_propagation then (* TODO: This just sticks a let in - we really need propogation *) let (subi,(E_aux (_,subannot) as sube)) = subst in let E_aux (e,(l,annot)) = exp in let lg = Generated l in let p = P_aux (P_id (Id_aux (Id subi, lg)), subannot) in E_aux (E_let (LB_aux (LB_val_implicit (p,sube),(lg,annot)), exp),(lg,annot)) else let substs = Envmap.from_list [subst] in let () = nexp_substs := [] in let exp' = const_prop_exp substs exp in (* Substitute what we've learned about nvars into the term *) let nsubsts = Envmap.from_list (List.map (fun (id,ne) -> (id,TA_nexp ne)) !nexp_substs) in let () = nexp_substs := [] in nexp_subst nsubsts exp' in (* Split a variable pattern into every possible value *) let split id l tannot = let new_l = Generated l in let new_id i = Id_aux (Id i, new_l) in match tannot with | Type_internal.NoTyp -> raise (Reporting_basic.err_general l ("No type information for variable " ^ id ^ " to split on")) | Type_internal.Overload _ -> raise (Reporting_basic.err_general l ("Type for variable " ^ id ^ " to split on is overloaded")) | Type_internal.Base ((tparams,ty0),_,cs,_,_,_) -> let () = match tparams with | [] -> () | _ -> raise (Reporting_basic.err_general l ("Type for variable " ^ id ^ " to split on has parameters")) in let ty = match ty0.t with Tabbrev(_,ty) -> ty | _ -> ty0 in let cannot () = raise (Reporting_basic.err_general l ("Cannot split type " ^ Type_internal.t_to_string ty ^ " for variable " ^ id)) in (match ty.t with | Tid i -> (match Envmap.apply d_env.enum_env i with (* enumerations *) | Some ns -> List.map (fun n -> (P_aux (P_id (new_id n),(l,tannot)), (id,E_aux (E_id (new_id n),(new_l,tannot))))) ns | None -> if i = "bit" then List.map (fun b -> P_aux (P_lit (L_aux (b,new_l)),(l,tannot)), (id,E_aux (E_lit (L_aux (b,new_l)),(new_l, tannot)))) [L_zero; L_one] else cannot ()) (*| vectors TODO *) (*| numbers TODO *) | _ -> cannot ()) in (* Split variable patterns at the given locations *) let map_locs ls (Defs defs) = let rec match_l = function | Unknown | Int _ -> [] | Generated l -> [] (* Could do match_l l, but only want to split user-written patterns *) | Range (p,q) -> List.filter (fun ((filename,line),_) -> Filename.basename p.Lexing.pos_fname = filename && p.Lexing.pos_lnum <= line && line <= q.Lexing.pos_lnum) ls in let split_pat var p = let rec list f = function | [] -> None | h::t -> match f h with | None -> (match list f t with None -> None | Some (l,ps,r) -> Some (h::l,ps,r)) | Some ps -> Some ([],ps,t) in let rec spl (P_aux (p,(l,annot))) = let relist f ctx ps = optmap (list f ps) (fun (left,ps,right) -> List.map (fun (p,sub) -> P_aux (ctx (left@p::right),(l,annot)),sub) ps) in let re f p = optmap (spl p) (fun ps -> List.map (fun (p,sub) -> (P_aux (f p,(l,annot)), sub)) ps) in let fpat (FP_aux ((FP_Fpat (id,p),annot))) = optmap (spl p) (fun ps -> List.map (fun (p,sub) -> FP_aux (FP_Fpat (id,p), annot), sub) ps) in let ipat (i,p) = optmap (spl p) (List.map (fun (p,sub) -> (i,p),sub)) in match p with | P_lit _ | P_wild -> None | P_as (p',id) -> let i = id_to_string id in if i = var then raise (Reporting_basic.err_general l ("Cannot split " ^ var ^ " on 'as' pattern")) else re (fun p -> P_as (p,id)) p' | P_typ (t,p') -> re (fun p -> P_typ (t,p)) p' | P_id id -> let i = id_to_string id in if i = var then Some (split i l annot) else None | P_app (id,ps) -> relist spl (fun ps -> P_app (id,ps)) ps | P_record (fps,flag) -> relist fpat (fun fps -> P_record (fps,flag)) fps | P_vector ps -> relist spl (fun ps -> P_vector ps) ps | P_vector_indexed ips -> relist ipat (fun ips -> P_vector_indexed ips) ips | P_vector_concat ps -> relist spl (fun ps -> P_vector_concat ps) ps | P_tup ps -> relist spl (fun ps -> P_tup ps) ps | P_list ps -> relist spl (fun ps -> P_list ps) ps in spl p in let map_pat (P_aux (_,(l,_)) as p) = match match_l l with | [] -> None | [(_,var)] -> split_pat var p | lvs -> raise (Reporting_basic.err_general l ("Multiple variables to split on: " ^ String.concat ", " (List.map snd lvs))) in let check_single_pat (P_aux (_,(l,_)) as p) = match match_l l with | [] -> p | lvs -> let pvs = bindings_from_pat t_env p in let overlap = List.exists (fun (_,v) -> List.mem v pvs) lvs in let () = if overlap then Reporting_basic.print_err false true l "Monomorphisation" "Splitting a singleton pattern is not possible" in p in let rec map_exp ((E_aux (e,annot)) as ea) = let re e = E_aux (e,annot) in match e with | E_block es -> re (E_block (List.map map_exp es)) | E_nondet es -> re (E_nondet (List.map map_exp es)) | E_id _ | E_lit _ | E_sizeof _ | E_internal_exp _ | E_sizeof_internal _ | E_internal_exp_user _ | E_comment _ -> ea | E_cast (t,e') -> re (E_cast (t, map_exp e')) | E_app (id,es) -> re (E_app (id,List.map map_exp es)) | E_app_infix (e1,id,e2) -> re (E_app_infix (map_exp e1,id,map_exp e2)) | E_tuple es -> re (E_tuple (List.map map_exp es)) | E_if (e1,e2,e3) -> re (E_if (map_exp e1, map_exp e2, map_exp e3)) | E_for (id,e1,e2,e3,ord,e4) -> re (E_for (id,map_exp e1,map_exp e2,map_exp e3,ord,map_exp e4)) | E_vector es -> re (E_vector (List.map map_exp es)) | E_vector_indexed (ies,ed) -> re (E_vector_indexed (List.map (fun (i,e) -> (i,map_exp e)) ies, map_opt_default ed)) | E_vector_access (e1,e2) -> re (E_vector_access (map_exp e1,map_exp e2)) | E_vector_subrange (e1,e2,e3) -> re (E_vector_subrange (map_exp e1,map_exp e2,map_exp e3)) | E_vector_update (e1,e2,e3) -> re (E_vector_update (map_exp e1,map_exp e2,map_exp e3)) | E_vector_update_subrange (e1,e2,e3,e4) -> re (E_vector_update_subrange (map_exp e1,map_exp e2,map_exp e3,map_exp e4)) | E_vector_append (e1,e2) -> re (E_vector_append (map_exp e1,map_exp e2)) | E_list es -> re (E_list (List.map map_exp es)) | E_cons (e1,e2) -> re (E_cons (map_exp e1,map_exp e2)) | E_record fes -> re (E_record (map_fexps fes)) | E_record_update (e,fes) -> re (E_record_update (map_exp e, map_fexps fes)) | E_field (e,id) -> re (E_field (map_exp e,id)) | E_case (e,cases) -> re (E_case (map_exp e, List.concat (List.map map_pexp cases))) | E_let (lb,e) -> re (E_let (map_letbind lb, map_exp e)) | E_assign (le,e) -> re (E_assign (map_lexp le, map_exp e)) | E_exit e -> re (E_exit (map_exp e)) | E_return e -> re (E_return (map_exp e)) | E_assert (e1,e2) -> re (E_assert (map_exp e1,map_exp e2)) | E_internal_cast (ann,e) -> re (E_internal_cast (ann,map_exp e)) | E_comment_struc e -> re (E_comment_struc e) | E_internal_let (le,e1,e2) -> re (E_internal_let (map_lexp le, map_exp e1, map_exp e2)) | E_internal_plet (p,e1,e2) -> re (E_internal_plet (check_single_pat p, map_exp e1, map_exp e2)) | E_internal_return e -> re (E_internal_return (map_exp e)) and map_opt_default ((Def_val_aux (ed,annot)) as eda) = match ed with | Def_val_empty -> eda | Def_val_dec e -> Def_val_aux (Def_val_dec (map_exp e),annot) and map_fexps (FES_aux (FES_Fexps (fes,flag), annot)) = FES_aux (FES_Fexps (List.map map_fexp fes, flag), annot) and map_fexp (FE_aux (FE_Fexp (id,e), annot)) = FE_aux (FE_Fexp (id,map_exp e),annot) and map_pexp (Pat_aux (Pat_exp (p,e),l)) = match map_pat p with | None -> [Pat_aux (Pat_exp (p,map_exp e),l)] | Some patsubsts -> List.map (fun (pat',subst) -> let exp' = subst_exp subst e in Pat_aux (Pat_exp (pat', map_exp exp'),l)) patsubsts and map_letbind (LB_aux (lb,annot)) = match lb with | LB_val_explicit (tysch,p,e) -> LB_aux (LB_val_explicit (tysch,check_single_pat p,map_exp e), annot) | LB_val_implicit (p,e) -> LB_aux (LB_val_implicit (check_single_pat p,map_exp e), annot) and map_lexp ((LEXP_aux (e,annot)) as le) = let re e = LEXP_aux (e,annot) in match e with | LEXP_id _ | LEXP_cast _ -> le | LEXP_memory (id,es) -> re (LEXP_memory (id,List.map map_exp es)) | LEXP_tup les -> re (LEXP_tup (List.map map_lexp les)) | LEXP_vector (le,e) -> re (LEXP_vector (map_lexp le, map_exp e)) | LEXP_vector_range (le,e1,e2) -> re (LEXP_vector_range (map_lexp le, map_exp e1, map_exp e2)) | LEXP_field (le,id) -> re (LEXP_field (map_lexp le, id)) in let map_funcl (FCL_aux (FCL_Funcl (id,pat,exp),annot)) = match map_pat pat with | None -> [FCL_aux (FCL_Funcl (id, pat, map_exp exp), annot)] | Some patsubsts -> List.map (fun (pat',subst) -> let exp' = subst_exp subst exp in FCL_aux (FCL_Funcl (id, pat', map_exp exp'), annot)) patsubsts in let map_fundef (FD_aux (FD_function (r,t,e,fcls),annot)) = FD_aux (FD_function (r,t,e,List.concat (List.map map_funcl fcls)),annot) in let map_scattered_def sd = match sd with | SD_aux (SD_scattered_funcl fcl, annot) -> List.map (fun fcl' -> SD_aux (SD_scattered_funcl fcl', annot)) (map_funcl fcl) | _ -> [sd] in let map_def d = match d with | DEF_kind _ | DEF_type _ | DEF_spec _ | DEF_default _ | DEF_reg_dec _ | DEF_comm _ -> [d] | DEF_fundef fd -> [DEF_fundef (map_fundef fd)] | DEF_val lb -> [DEF_val (map_letbind lb)] | DEF_scattered sd -> List.map (fun x -> DEF_scattered x) (map_scattered_def sd) in Defs (List.concat (List.map map_def defs)) in map_locs splits defs