a -> Prop> = A { alen :: Nat , aval :: i:Upto alen -> a
} @-} {-@ new :: forall
a -> Prop>. n:Nat -> (i:Upto n -> a
) -> {v: Arr
a | alen v = n} @-} new n v = A { alen = n , aval = \i -> if (0 <= i && i < n) then v i else liquidError "Out of Bounds!" } {-@ (!) :: forall
a -> Prop>. a:Arr
a -> i:Upto (alen a) -> a
@-} (A _ f) ! i = f i {-@ set :: forall
a -> Prop>. a:Arr
a -> i:Upto (alen a) -> a
-> {v:Arr
a | alen v = alen a} @-} set a@(A _ f) i v = a { aval = \j -> if (i == j) then v else f j } {-@ ofList :: xs:[a] -> {v:Arr a | alen v = len xs} @-} ofList xs = new n f where n = length xs m = M.fromList $ zip [0..] xs f i = (M.!) m i {-@ map :: (a -> b) -> a:Arr a -> {v:Arr b | alen v = alen a} @-} map f a@(A n z) = A n (f . z) ------------------------------------------------------------- -- | An Imperative Array ------------------------------------ ------------------------------------------------------------- data IOArr a = IOA { size :: Int , pntr :: IORef (Arr a) } {-@ data IOArr a
a -> Prop> = IOA { size :: Nat , pntr :: IORef ({v:Arr
a | alen v = size}) } @-} {-@ newIO :: forall
a -> Prop>. n:Nat -> (i:Upto n -> a
) -> IO ({v: IOArr
a | size v = n}) @-} newIO n f = IOA n <$> newIORef (new n f) {-@ getIO :: forall
a -> Prop>. a:IOArr
a -> i:Upto (size a) -> IO (a
) @-} getIO a@(IOA sz p) i = do arr <- readIORef p return $ (arr ! i) {-@ setIO :: forall
a -> Prop>. a:IOArr
a -> i:Upto (size a) -> a
-> IO () @-} setIO a@(IOA sz p) i v = do arr <- readIORef p let arr' = set arr i v writeIORef p arr'