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Check realloc's return code to prevent segfault on out of memory condition (Part 2)
author | Sergey Mironov <grrwlf@gmail.com> |
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date | Sun, 24 Aug 2014 11:56:41 +0400 |
parents | 146ec8e90063 |
children | d9f918b79b5a |
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datatype t = datatype Basis.list val show = fn [a] (_ : show a) => let fun show' (ls : list a) = case ls of [] => "[]" | x :: ls => show x ^ " :: " ^ show' ls in mkShow show' end val eq = fn [a] (_ : eq a) => let fun eq' (ls1 : list a) ls2 = case (ls1, ls2) of ([], []) => True | (x1 :: ls1, x2 :: ls2) => x1 = x2 && eq' ls1 ls2 | _ => False in mkEq eq' end fun foldl [a] [b] (f : a -> b -> b) = let fun foldl' acc ls = case ls of [] => acc | x :: ls => foldl' (f x acc) ls in foldl' end val rev = fn [a] => let fun rev' acc (ls : list a) = case ls of [] => acc | x :: ls => rev' (x :: acc) ls in rev' [] end fun foldr [a] [b] f (acc : b) (ls : list a) = foldl f acc (rev ls) fun foldlAbort [a] [b] f = let fun foldlAbort' acc ls = case ls of [] => Some acc | x :: ls => case f x acc of None => None | Some acc' => foldlAbort' acc' ls in foldlAbort' end val length = fn [a] => let fun length' acc (ls : list a) = case ls of [] => acc | _ :: ls => length' (acc + 1) ls in length' 0 end fun foldlMapAbort [a] [b] [c] f = let fun foldlMapAbort' ls' acc ls = case ls of [] => Some (rev ls', acc) | x :: ls => case f x acc of None => None | Some (x', acc') => foldlMapAbort' (x' :: ls') acc' ls in foldlMapAbort' [] end val revAppend = fn [a] => let fun ra (ls : list a) acc = case ls of [] => acc | x :: ls => ra ls (x :: acc) in ra end fun append [a] (ls1 : t a) (ls2 : t a) = revAppend (rev ls1) ls2 fun mp [a] [b] f = let fun mp' acc ls = case ls of [] => rev acc | x :: ls => mp' (f x :: acc) ls in mp' [] end fun mapi [a] [b] f = let fun mp' n acc ls = case ls of [] => rev acc | x :: ls => mp' (n + 1) (f n x :: acc) ls in mp' 0 [] end fun mapPartial [a] [b] f = let fun mp' acc ls = case ls of [] => rev acc | x :: ls => mp' (case f x of None => acc | Some y => y :: acc) ls in mp' [] end fun mapX [a] [ctx ::: {Unit}] f = let fun mapX' ls = case ls of [] => <xml/> | x :: ls => <xml>{f x}{mapX' ls}</xml> in mapX' end fun mapXi [a] [ctx ::: {Unit}] f = let fun mapX' i ls = case ls of [] => <xml/> | x :: ls => <xml>{f i x}{mapX' (i + 1) ls}</xml> in mapX' 0 end fun mapM [m ::: (Type -> Type)] (_ : monad m) [a] [b] f = let fun mapM' acc ls = case ls of [] => return (rev acc) | x :: ls => x' <- f x; mapM' (x' :: acc) ls in mapM' [] end fun mapPartialM [m ::: (Type -> Type)] (_ : monad m) [a] [b] f = let fun mapPartialM' acc ls = case ls of [] => return (rev acc) | x :: ls => v <- f x; mapPartialM' (case v of None => acc | Some x' => x' :: acc) ls in mapPartialM' [] end fun mapXM [m ::: (Type -> Type)] (_ : monad m) [a] [ctx ::: {Unit}] f = let fun mapXM' ls = case ls of [] => return <xml/> | x :: ls => this <- f x; rest <- mapXM' ls; return <xml>{this}{rest}</xml> in mapXM' end fun filter [a] f = let fun fil acc ls = case ls of [] => rev acc | x :: ls => fil (if f x then x :: acc else acc) ls in fil [] end fun exists [a] f = let fun ex ls = case ls of [] => False | x :: ls => if f x then True else ex ls in ex end fun foldlMap [a] [b] [c] f = let fun fold ls' st ls = case ls of [] => (rev ls', st) | x :: ls => case f x st of (y, st) => fold (y :: ls') st ls in fold [] end fun find [a] f = let fun find' ls = case ls of [] => None | x :: ls => if f x then Some x else find' ls in find' end fun search [a] [b] f = let fun search' ls = case ls of [] => None | x :: ls => case f x of None => search' ls | v => v in search' end fun foldlM [m] (_ : monad m) [a] [b] f = let fun foldlM' acc ls = case ls of [] => return acc | x :: ls => acc <- f x acc; foldlM' acc ls in foldlM' end fun foldlMi [m] (_ : monad m) [a] [b] f = let fun foldlMi' i acc ls = case ls of [] => return acc | x :: ls => acc <- f i x acc; foldlMi' (i + 1) acc ls in foldlMi' 0 end fun filterM [m] (_ : monad m) [a] (p : a -> m bool) = let fun filterM' (acc : list a) (xs : list a) : m (list a) = case xs of [] => return (rev acc) | x :: xs => c <- p x; filterM' (if c then x :: acc else acc) xs in filterM' [] end fun all [m] f = let fun all' ls = case ls of [] => True | x :: ls => f x && all' ls in all' end fun app [m] (_ : monad m) [a] f = let fun app' ls = case ls of [] => return () | x :: ls => f x; app' ls in app' end fun mapQuery [tables ::: {{Type}}] [exps ::: {Type}] [t ::: Type] [tables ~ exps] (q : sql_query [] [] tables exps) (f : $(exps ++ map (fn fields :: {Type} => $fields) tables) -> t) = ls <- query q (fn fs acc => return (f fs :: acc)) []; return (rev ls) fun mapQueryM [tables ::: {{Type}}] [exps ::: {Type}] [t ::: Type] [tables ~ exps] (q : sql_query [] [] tables exps) (f : $(exps ++ map (fn fields :: {Type} => $fields) tables) -> transaction t) = ls <- query q (fn fs acc => v <- f fs; return (v :: acc)) []; return (rev ls) fun mapQueryPartialM [tables ::: {{Type}}] [exps ::: {Type}] [t ::: Type] [tables ~ exps] (q : sql_query [] [] tables exps) (f : $(exps ++ map (fn fields :: {Type} => $fields) tables) -> transaction (option t)) = ls <- query q (fn fs acc => v <- f fs; return (case v of None => acc | Some v => v :: acc)) []; return (rev ls) fun sort [a] (gt : a -> a -> bool) (ls : t a) : t a = let fun split ls acc1 acc2 = case ls of [] => (rev acc1, rev acc2) | x :: [] => (rev (x :: acc1), rev acc2) | x1 :: x2 :: ls' => split ls' (x1 :: acc1) (x2 :: acc2) fun merge ls1 ls2 acc = case (ls1, ls2) of ([], _) => revAppend acc ls2 | (_, []) => revAppend acc ls1 | (x1 :: ls1', x2 :: ls2') => if gt x1 x2 then merge ls1 ls2' (x2 :: acc) else merge ls1' ls2 (x1 :: acc) fun sort' ls = case ls of [] => ls | _ :: [] => ls | _ => let val (ls1, ls2) = split ls [] [] in merge (sort' ls1) (sort' ls2) [] end in sort' ls end val nth [a] = let fun nth (ls : list a) (n : int) : option a = case ls of [] => None | x :: ls' => if n <= 0 then Some x else nth ls' (n-1) in nth end fun replaceNth [a] (ls : list a) (n : int) (v : a) : list a = let fun repNth (ls : list a) (n : int) (acc : list a) = case ls of [] => rev acc | x :: ls' => if n <= 0 then revAppend acc (v :: ls') else repNth ls' (n-1) (x :: acc) in repNth ls n [] end fun assoc [a] [b] (_ : eq a) (x : a) = let fun assoc' (ls : list (a * b)) = case ls of [] => None | (y, z) :: ls => if x = y then Some z else assoc' ls in assoc' end fun assocAdd [a] [b] (_ : eq a) (x : a) (y : b) (ls : t (a * b)) = case assoc x ls of None => (x, y) :: ls | Some _ => ls fun recToList [a ::: Type] [r ::: {Unit}] (fl : folder r) = @foldUR [a] [fn _ => list a] (fn [nm ::_] [rest ::_] [[nm] ~ rest] x xs => x :: xs) [] fl fun take [a] (n : int) (xs : list a) : list a = if n <= 0 then [] else case xs of [] => [] | x :: xs => x :: take (n-1) xs fun drop [a] (n : int) (xs : list a) : list a = if n <= 0 then xs else case xs of [] => [] | x :: xs => drop (n-1) xs fun splitAt [a] (n : int) (xs : list a) : list a * list a = (take n xs, drop n xs) fun mapXiM [m ::: Type -> Type] (_ : monad m) [a] [ctx ::: {Unit}] (f : int -> a -> m (xml ctx [] [])) : t a -> m (xml ctx [] []) = let fun mapXiM' i ls = case ls of [] => return <xml/> | x :: ls => this <- f i x; rest <- mapXiM' (i+1) ls; return <xml>{this}{rest}</xml> in mapXiM' 0 end fun tabulateM [m] (_ : monad m) [a] (f : int -> m a) n = let fun tabulate' n acc = if n <= 0 then return acc else (v <- f (n-1); tabulate' (n-1) (v :: acc)) in tabulate' n [] end