Suppose there are some data types to express lambda and combinatorial terms:

```
data Lam α = Var α -- v
| Abs α (Lam α) -- λv . e1
| App (Lam α) (Lam α) -- e1 e2
deriving (Eq, Show)
infixl 0 :@
data SKI α = V α -- x
| SKI α :@ SKI α -- e1 e2
| I -- I
| K -- K
| S -- S
deriving (Eq, Show)
```

There is also a function to get a list of lambda term's free variables:

```
fv ∷ Eq α ⇒ Lam α → [α]
fv (Var v) = [v]
fv (Abs x e) = filter (/= x) $ fv e
fv (App e1 e2) = fv e1 ++ fv e2
```

To convert lambda term to combinatorial term abstract elimination rules could be usefull:

```
convert ∷ Eq α ⇒ Lam α → SKI α
```

1) T[x] => x

```
convert (Var x) = V x
```

2) T[(E₁ E₂)] => (T[E₁] T[E₂])

```
convert (App e1 e2) = (convert e1) :@ (convert e2)
```

3) T[λx.E] => (K T[E]) (if x does not occur free in E)

```
convert (Abs x e) | x `notElem` fv e = K :@ (convert e)
```

4) T[λx.x] => I

```
convert (Abs x (Var y)) = if x == y then I else K :@ V y
```

5) T[λx.λy.E] => T[λx.T[λy.E]] (if x occurs free in E)

```
convert (Abs x (Abs y e)) | x `elem` fv e = convert (Abs x (convert (Abs y e)))
```

6) T[λx.(E₁ E₂)] => (S T[λx.E₁] T[λx.E₂])

```
convert (Abs x (App y z)) = S :@ (convert (Abs x y)) :@ (convert (Abs x z))
convert _ = error ":["
```

This definition is not valid because of `5)`

:

```
Couldn't match expected type `Lam α' with actual type `SKI α'
In the return type of a call of `convert'
In the second argument of `Abs', namely `(convert (Abs y e))'
In the first argument of `convert', namely
`(Abs x (convert (Abs y e)))'
```

So, what I have now is:

```
> convert $ Abs "x" $ Abs "y" $ App (Var "y") (Var "x")
*** Exception: :[
```

What I want is (hope I calculate it right):

```
> convert $ Abs "x" $ Abs "y" $ App (Var "y") (Var "x")
S :@ (S (KS) (S (KK) I)) (S (KK) I)
```

**Question**:

If lambda term and combinatorial term have a different types of expression, how `5)`

could be formulated right?

`fv`

is wrong, btw: it should be`fv (Abs x e) = filter (/= x) $ fv e`

– Roman Cheplyaka Oct 22 '12 at 6:16`\x -> x x`

. – Roman Cheplyaka Oct 22 '12 at 6:25