{-@ LIQUID "--pruneunsorted" @-}

-- | A somewhat fancier example demonstrating the use of Abstract Predicates and exist-types

module Ex () where

-------------------------------------------------------------------------
-- | Data types ---------------------------------------------------------
-------------------------------------------------------------------------

data Vec a = Nil | Cons a (Vec a)

-- | We can encode the notion of length as an inductive measure @llen@

{-@ measure llen     :: forall a. Vec a -> Int
    llen (Nil)       = 0
    llen (Cons x xs) = 1 + llen(xs)
  @-}


-- | As a warmup, lets check that a /real/ length function indeed computes
-- the length of the list.

{-@ sizeOf :: xs:Vec a -> {v: Int | v = llen(xs)} @-}
sizeOf             :: Vec a -> Int
sizeOf Nil         = 0
sizeOf (Cons _ xs) = 1 + sizeOf xs

-------------------------------------------------------------------------
-- | Higher-order fold --------------------------------------------------
-------------------------------------------------------------------------

-- | Time to roll up the sleeves. Here's a a higher-order @foldr@ function
-- for our `Vec` type. Note that the `op` argument takes an extra /ghost/
-- parameter that will let us properly describe the type of `efoldr`

{-@ efoldr :: forall a b <p :: x0:Vec a -> x1:b -> Bool>. 
                (xs:Vec a -> x:a -> b <p xs> -> b <p (Ex.Cons x xs)>)
              -> b <p Ex.Nil>
              -> ys: Vec a
              -> b <p ys>
  @-}
efoldr :: (Vec a -> a -> b -> b) -> b -> Vec a -> b
efoldr op b Nil         = b
efoldr op b (Cons x xs) = op xs x (efoldr op b xs)

-------------------------------------------------------------------------
-- | Clients of `efold` -------------------------------------------------
-------------------------------------------------------------------------

-- | Finally, lets write a few /client/ functions that use `efoldr` to
-- operate on the `Vec`s.

-- | First: Computing the length using `efoldr`
{-@ size :: xs:Vec a -> {v: Int | v = llen(xs)} @-}
size :: Vec a -> Int
size = efoldr (\_ _ n -> n + 1) 0

{-@ suc :: x:Int -> {v: Int | v = x + 1} @-}
suc :: Int -> Int
suc x = x + 1

-- | Second: Appending two lists using `efoldr`
{-@ app  :: xs: Vec a -> ys: Vec a -> {v: Vec a | llen(v) = 1 + llen(xs) + llen(ys) } @-}
app xs ys = efoldr (\_ z zs -> Cons z zs) ys xs