open Mini_c open Trace let rec fold_type_value : ('a -> type_value -> 'a result) -> 'a -> type_value -> 'a result = fun f init t -> let self = fold_type_value f in let%bind init' = f init t in match t with | T_pair ((_, a), (_, b)) | T_or ((_, a), (_, b)) | T_function (a, b) | T_map (a, b) | T_big_map (a, b) -> bind_fold_pair self init' (a, b) | T_list a | T_set a | T_contract a | T_option a -> self init' a | T_base _ -> ok init' type 'a folder = 'a -> expression -> 'a result let rec fold_expression : 'a folder -> 'a -> expression -> 'a result = fun f init e -> let self = fold_expression f in let%bind init' = f init e in match e.content with | E_variable _ | E_skip | E_make_none _ | E_make_empty_map (_,_) | E_make_empty_list _ | E_make_empty_set _ -> ( ok init' ) | E_literal _ -> ok init' | E_constant (_, lst) -> ( let%bind res = bind_fold_list self init' lst in ok res ) | E_closure af -> ( let%bind res = self init' af.body in ok res ) | E_application farg -> ( let%bind res = bind_fold_pair self init' farg in ok res ) | E_iterator (_, ((_ , _) , body) , exp) -> ( let%bind res = bind_fold_pair self init' (exp,body) in ok res ) | E_fold (((_ , _) , body) , col , init) -> ( let%bind res = bind_fold_triple self init' (body,col,init) in ok res ) | E_while eb -> ( let%bind res = bind_fold_pair self init' eb in ok res ) | E_if_bool cab -> ( let%bind res = bind_fold_triple self init' cab in ok res ) | E_if_none (c, n, ((_, _) , s)) -> ( let%bind res = bind_fold_triple self init' (c,n,s) in ok res ) | E_if_cons (c, n, (((_, _) , (_, _)) , cons)) -> ( let%bind res = bind_fold_triple self init' (c,n,cons) in ok res ) | E_if_left (c, ((_, _) , l), ((_, _) , r)) -> ( let%bind res = bind_fold_triple self init' (c,l,r) in ok res ) | E_let_in ((_, _) , expr , body) -> ( let%bind res = bind_fold_pair self init' (expr,body) in ok res ) | E_sequence ab -> ( let%bind res = bind_fold_pair self init' ab in ok res ) | E_assignment (_, _, exp) -> ( let%bind res = self init' exp in ok res ) type mapper = expression -> expression result let rec map_expression : mapper -> expression -> expression result = fun f e -> let self = map_expression f in let%bind e' = f e in let return content = ok { e' with content } in match e'.content with | E_variable _ | E_literal _ | E_skip | E_make_none _ | E_make_empty_map (_,_) | E_make_empty_list _ | E_make_empty_set _ as em -> return em | E_constant (name, lst) -> ( let%bind lst' = bind_map_list self lst in return @@ E_constant (name,lst') ) | E_closure af -> ( let%bind body = self af.body in return @@ E_closure { af with body } ) | E_application farg -> ( let%bind farg' = bind_map_pair self farg in return @@ E_application farg' ) | E_iterator (s, ((name , tv) , body) , exp) -> ( let%bind (exp',body') = bind_map_pair self (exp,body) in return @@ E_iterator (s, ((name , tv) , body') , exp') ) | E_fold (((name , tv) , body) , col , init) -> ( let%bind (body',col',init') = bind_map_triple self (body,col,init) in return @@ E_fold (((name , tv) , body') , col', init') ) | E_while eb -> ( let%bind eb' = bind_map_pair self eb in return @@ E_while eb' ) | E_if_bool cab -> ( let%bind cab' = bind_map_triple self cab in return @@ E_if_bool cab' ) | E_if_none (c, n, ((name, tv) , s)) -> ( let%bind (c',n',s') = bind_map_triple self (c,n,s) in return @@ E_if_none (c', n', ((name, tv) , s')) ) | E_if_cons (c, n, (((hd, hdtv) , (tl, tltv)) , cons)) -> ( let%bind (c',n',cons') = bind_map_triple self (c,n,cons) in return @@ E_if_cons (c', n', (((hd, hdtv) , (tl, tltv)) , cons')) ) | E_if_left (c, ((name_l, tvl) , l), ((name_r, tvr) , r)) -> ( let%bind (c',l',r') = bind_map_triple self (c,l,r) in return @@ E_if_left (c', ((name_l, tvl) , l'), ((name_r, tvr) , r')) ) | E_let_in ((v , tv) , expr , body) -> ( let%bind (expr',body') = bind_map_pair self (expr,body) in return @@ E_let_in ((v , tv) , expr' , body') ) | E_sequence ab -> ( let%bind ab' = bind_map_pair self ab in return @@ E_sequence ab' ) | E_assignment (s, lrl, exp) -> ( let%bind exp' = self exp in return @@ E_assignment (s, lrl, exp') )