If you only have to deal with this specific case, i.e., converting from

```
(((Int, String), Maybe Int), (Char, Int))
```

to

```
(Int, (Char, (Maybe Int, (String, (Int, ()))))
```

then, depending on whether you want to preserve the order of the `Int`

-components or swap them, you can simply use one of these two functions:

```
from1 (((m, s), mb), (c, n)) = (m, (c, mb, (s, (n, ()))))
from2 (((m, s), mb), (c, n)) = (n, (c, mb, (s, (m, ()))))
```

But we can of course be just a bit more ambitious and aim for a more generic solution; see, for example, Jeuring and Atanassow (MPC 2004). To this end, let us enable some language extensions

```
{-# LANGUAGE GADTs #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE TypeOperators #-}
{-# LANGUAGE UndecidableInstances #-}
```

and introduce a GADT for codes that we can use to represent tuple types

```
infixr 5 :*:
data U a where
Unit :: U ()
Int :: U Int
Char :: U Char
List :: U a -> U [a]
Maybe :: U a -> U (Maybe a)
(:*:) :: U a -> U b -> U (a, b)
```

For example, the target type from your example can now be encoded by the expression

```
Int :*: Char :*: Maybe Int :*: string :*: Int :*: Unit
```

of type

```
U (Int, (Char, (Maybe Int, (String, (Int, ()))))
```

As a convenience, we introduce

```
string :: U String
string = List Char
```

We furthermore introduce a type of explicitly typed tuple values

```
data Typed where
Typed :: U a -> a -> Typed
```

and a notion of type-level equality:

```
infix 4 :==:
data a :==: b where
Refl :: a :==: a
```

With that, we can define a heterogeneous equality check on tuple-type encodings:

```
eq :: U a -> U b -> Maybe (a :==: b)
eq Unit Unit = Just Refl
eq Int Int = Just Refl
eq Char Char = Just Refl
eq (List u1) (List u2) = case eq u1 u2 of
Just Refl -> Just Refl
_ -> Nothing
eq (Maybe u1) (Maybe u2) = case eq u1 u2 of
Just Refl -> Just Refl
_ -> Nothing
eq (u11 :*: u12) (u21 :*: u22) = case (eq u11 u21, eq u12 u22) of
(Just Refl, Just Refl) -> Just Refl
_ -> Nothing
eq _ _ = Nothing
```

That is `eq u1 u2`

returns `Just Refl`

if `u1`

and `u2`

encode the same tuple type, and `Nothing`

otherwise. In the `Just`

-case the constructor `Refl`

acts as proof for the type checker that the tuple types are indeed the same.

Now we want to be able to convert tuple types to a "flattened", i.e., right-nested, representation. For this, we introduce a type family `Flatten`

:

```
type family Flatten a
type instance Flatten () = ()
type instance Flatten Int = Flatten (Int, ())
type instance Flatten Char = Flatten (Char, ())
type instance Flatten [a] = Flatten ([a], ())
type instance Flatten (Maybe a) = Flatten (Maybe a, ())
type instance Flatten ((), a) = Flatten a
type instance Flatten (Int, a) = (Int, Flatten a)
type instance Flatten (Char, a) = (Char, Flatten a)
type instance Flatten ([a], b) = ([a], Flatten b)
type instance Flatten (Maybe a, b) = (Maybe a, Flatten b)
type instance Flatten ((a, b), c) = Flatten (a, (b, c))
```

and two functions `flattenV`

and `flattenU`

for, respectively, flattening tuple values and the encodings of their types:

```
flattenV :: U a -> a -> Flatten a
flattenV Unit _ = ()
flattenV Int n = flattenV (Int :*: Unit) (n, ())
flattenV Char c = flattenV (Char :*: Unit) (c, ())
flattenV (List u) xs = flattenV (List u :*: Unit) (xs, ())
flattenV (Maybe u) mb = flattenV (Maybe u :*: Unit) (mb, ())
flattenV (Unit :*: u) (_, x) = flattenV u x
flattenV (Int :*: u) (n, x) = (n, flattenV u x)
flattenV (Char :*: u) (c, x) = (c, flattenV u x)
flattenV (List _ :*: u) (xs, x) = (xs, flattenV u x)
flattenV (Maybe _ :*: u) (mb, x) = (mb, flattenV u x)
flattenV ((u1 :*: u2) :*: u3) ((x1, x2), x3)
= flattenV (u1 :*: u2 :*: u3) (x1, (x2, x3))
flattenU :: U a -> U (Flatten a)
flattenU Unit = Unit
flattenU Int = Int :*: Unit
flattenU Char = Char :*: Unit
flattenU (List u) = List u :*: Unit
flattenU (Maybe u) = Maybe u :*: Unit
flattenU (Unit :*: u) = flattenU u
flattenU (Int :*: u) = Int :*: flattenU u
flattenU (Char :*: u) = Char :*: flattenU u
flattenU (List u1 :*: u2) = List u1 :*: flattenU u2
flattenU (Maybe u1 :*: u2) = Maybe u1 :*: flattenU u2
flattenU ((u1 :*: u2) :*: u3) = flattenU (u1 :*: u2 :*: u3)
```

The two are then combined into a single function `flatten`

:

```
flatten :: U a -> a -> Typed
flatten u x = Typed (flattenU u) (flattenV u x)
```

We also need a way to recover the original nesting of tuple-components from a flattened representation:

```
reify :: U a -> Flatten a -> a
reify Unit _ = ()
reify Int (n, _) = n
reify Char (c, _) = c
reify (List u) (xs, _) = xs
reify (Maybe u) (mb, _) = mb
reify (Unit :*: u) y = ((), reify u y)
reify (Int :*: u) (n, y) = (n, reify u y)
reify (Char :*: u) (c, y) = (c, reify u y)
reify (List _ :*: u) (xs, y) = (xs, reify u y)
reify (Maybe _ :*: u) (mb, y) = (mb, reify u y)
reify ((u1 :*: u2) :*: u3) y = let (x1, (x2, x3)) = reify (u1 :*: u2 :*: u3) y
in ((x1, x2), x3)
```

Now, given a type code `u`

for a tuple component and a flattened tuple together with an encoding of its type, we define function `select`

that returns all possible ways to select from the tuple a component with a type that matches `u`

and a flattened representation of the remaining components:

```
select :: U b -> Typed -> [(b, Typed)]
select _ (Typed Unit _) = []
select u2 (Typed (u11 :*: u12) (x1, x2)) =
case u11 `eq` u2 of
Just Refl -> (x1, Typed u12 x2) : zs
_ -> zs
where
zs = [(y, Typed (u11 :*: u') (x1, x')) |
(y, Typed u' x') <- select u2 (Typed u12 x2)]
```

Finally, we can then define a function `conv`

that takes two tuple-type codes and a tuple of a type that matches the first code, and returns all possible conversions into a tuple of a type that matches the second code:

```
conv :: U a -> U b -> a -> [b]
conv u1 u2 x = [reify u2 y | y <- go (flattenU u2) (flatten u1 x)]
where
go :: U b -> Typed -> [b]
go Unit (Typed Unit _ ) = [()]
go (u1 :*: u2) t =
[(y1, y2) | (y1, t') <- select u1 t, y2 <- go u2 t']
```

As an example, we have that

```
conv (Int :*: Char) (Char :*: Int) (2, 'x')
```

yields

```
[('x', 2)]
```

Returning to your original example, if we define

```
from = conv u1 u2
where
u1 = ((Int :*: string) :*: Maybe Int) :*: Char :*: Int
u2 = Int :*: Char :*: Maybe Int :*: string :*: Int :*: Unit
```

then

```
from (((1, ""), Nothing), (' ', 6))
```

yields

```
[ (1, (' ', (Nothing, ("", (6, ())))))
, (6, (' ', (Nothing, ("", (1, ())))))
]
```

We can make things even a bit nicer, by introducing a type class for representable tuple types:

```
class Rep a where
rep :: U a
instance Rep () where rep = Unit
instance Rep Int where rep = Int
instance Rep Char where rep = Char
instance Rep a => Rep [a] where rep = List rep
instance Rep a => Rep (Maybe a) where rep = Maybe rep
instance (Rep a, Rep b) => Rep (a, b) where rep = rep :*: rep
```

That way, we can define a conversion function that does not need the type codes for the tuples:

```
conv' :: (Rep a, Rep b) => a -> [b]
conv' = conv rep rep
```

Then, for example

```
conv' ("foo", 'x') :: [((Char, ()), String)]
```

yields

```
[(('x', ()), "foo")]
```

`f (((n,s),m),(c,i))=(i,(c,(m,(s,(n,())))))`

But I'm not sure that's what you're seeking. – ja. Apr 17 '13 at 5:39