# Pure Lambda Calculus - and function

I am currently learning Haskell and also participating in a rather theoretical lecture about functional programming at university.

I know that this is purely theoretical/academic question, but nevertheless I am interested how to express different simple functions simply with pure lambda calculus (i.e. without any constants defined).

Some lecture materials of mine define the boolean values such as:

True = \xy.x
False = \xy.y

(\ denoting the lambda symbol)

If they are defined like these selector functions, the if-condition can be easily defined as:

If = \x.x

Now, I'm trying to come up with some short form for the logical "and"-function. My first guess is:

and = \xy.{(If x)[(If y) True False] False}

So basically this lambda function would receive 2 arguments u v where both have to be typed like True/False. If I do various beta-reductions with all 4 combinations of the logic table I receive the right result.

Nevertheless this function looks a little ugly and I'm thinking about making it more elegant. Any proposals here?

We can just do reductions on your answer to get a pithier one.

First some warm-ups. Obviously `IF x ==> x`, and as `TRUE TRUE FALSE ==> TRUE` and `FALSE TRUE FALSE ==> FALSE` if `x` is a boolean then `x TRUE FALSE ==> x`.

Now we reduce

``````\x y . (IF x) ( (IF y) TRUE FALSE ) FALSE
\x y .     x  (     y  TRUE FALSE ) FALSE  -- using IF x         ==> x
\x y .     x  (     y             ) FALSE  -- using y TRUE FALSE ==> y
\x y . x y FALSE                           -- clean up
``````

and this expression still works with truth tables

``````AND TRUE  TRUE  = TRUE  TRUE  FALSE = TRUE
AND FALSE TRUE  = FALSE TRUE  FALSE = FALSE
AND TRUE  FALSE = TRUE  FALSE FALSE = FALSE
AND FALSE FALSE = FALSE FALSE FALSE = FALSE
``````
• Enlightening. This is what I wanted to come up with. Thank you! – Rodney Jun 30 '14 at 23:47

Well, `and True` is the identity function, and `and False` is the constant function returning `False`, so we can use that.

``````and = \x. if x id (const False)
``````

which has a nice symmetry with

``````or = \x. if x (const True) id
``````

(where

``````id = \x. x
const = \x y. x
``````

)

The common pattern for eliminators takes the data at the end of the argument list which often works elegantly with pointfree style, so if you defined:

``````cond = \t f b. b t f
``````

then you could express

``````and = cond id (const False)
or  = cond (const True) id
``````

which is the best I've got. There are probably yet more elegant formulations by viewing bools in cool ways.

Church's booleans, right? :) I developed for fun a small module by using the `RankNTypes` feature in order to represent them as close to the original Lambda calculus version as possible.

So, if you enable `RankNTypes`:

``````{-# LANGUAGE RankNTypes #-}
``````

You might represent the type of Church booleans as the functions `a -> a -> a` for any type `a`, thus having a compact representation for True and False very similar to yours. The typing here will allow us to compose the functions more freely, though.

``````type CBool = forall a. a -> a -> a

ctrue :: CBool
ctrue t f = t

cfalse :: CBool
cfalse t f = f
``````

Now, how is a conjunction written in these terms? Let's say you have a left operand `l` and a right operand `r` which are both `CBool`, that is, functions `a -> a -> a` which either return you the first or the second parameter depending on whether it's `ctrue` or `cfalse`. You can evaluate this function by giving in input `r` as the first parameter and `l` itself as the third. If `l` is `ctrue`, then it will evaluate to its first parameter, which is `r`: should it be `ctrue` again, then our conjunction is satisfied. In any other case, `cfalse` will be returned.

``````cand :: CBool -> CBool -> CBool
cand l r = l r l
``````

The disjunction can be represented in a similar way, with the same trick of directly evaluating the functions representing booleans given in input. Except that here you'll swap the two arguments for evaluating `l`: if `l` is `ctrue`, it will return `l` itself otherwise it is all up to `r`'s value

``````cor :: CBool -> CBool -> CBool
cor l r = l l r
``````

By enabling RankNTypes, I think this is the closest as you can get to the original definitions of conjunction and disjunction for Church's boolean numbers in Lambda Calculus. I also wrote functions to translate back and forth from regular Bool and CBool, the negation, and also Church's natural numbers with the same style. You can find the whole source code at https://github.com/rtraverso86/haskkit/blob/master/Haskkit/Data/Church.hs.