# Lisp IF-THEN-ELSE Lambda Calc Implementation

I made this IF-THEN-ELSE Lambda Calculus code

``````(defvar IF-THEN-ELSE
#'(lambda(con)
#'(lambda(x)
#'(lambda(y)
#'(lambda(acc1)
#'(lambda (acc2)
(funcall (funcall (funcall (funcall con x) y) acc1) acc2))))))
)

(defun IF-THEN-ELSEOP(c x y a1 a2)
(funcall (funcall (funcall (funcall (funcall IF-THEN-ELSE c) x) y) a1) a2)
)
``````

And this Greater or Equal operator

``````(defvar GEQ
#'(lambda(p)
#'(lambda(q)
(funcall #'LEQOP q p)))
)
``````

LEQOP is a function for "Less or Equal" and it works OK. So when I call IF-THEN-ELSE like this ("six" and "two" are church numbers)

``````(if-then-elseop GEQ six two (print "THIS") (print "THAT"))
``````

as output I've got

``````"THIS"
"THAT"
"THIS"
``````

Both functions that I'm passing are being called. How can I avoid it in order to get only as output "THIS"?

This happens with every function I use, and this is a trouble because I want to use IF-THEN-ELSE in a recursive call, so just one function must be called dependign on the IF-THEN-ELSE eval.

Any help would be appreciated

Thanks.

-

Passing your `print` statements by wrapping them in `lambda`s should work, but maybe it's worth an explanation as to why this is necessary.

You're implementing a lambda calculus. By definition, all 'things' in the calculus are higher order functions. Your `six` and `two` and any other church numerals you may have defined are also higher order functions.

`IF-THEN-ELSE` is a lambda abstraction (also a higher-order function because it's 'arguments' are also functions). So this would have been valid:

``````(if-then-elseop GEQ six two one two)
``````

Where `one` and `two` are church numbers. By doing that, you're expressing in lambda calculus what you would in plain lisp as:

``````(if (>= 6 2)
1
2)
``````

But I'm guessing what you were aiming for was:

``````(if (>= 6 2)
(print "this")
(print "that"))
``````

(more later about why messing with `print` might be a distraction to your exercise)

So the 'real' `1` has a church encoding `one`, which I'me assuming you've defined. That way, it can be applied to the lambda abstraction `IF-THEN-ELSE` - In the same way that

``````(>= 6 2)
``````

evaluates to TRUE in the lisp world, your lambda calculus implementation of the same,

``````((GEQ six) two)
``````

will evaluate to the lambda encoding of TRUE, which is again, encoded as a higher-order function.

``````(defvar TRUE #'(lambda (x) #'(lambda (y) x)))
(defvar FALSE #'(lambda (x) #'(lambda (y) y)))
``````

So the rule to remember is that everything you are passing around and getting back in the lambda calculus are functions:

`````` 0 := λf.λx.x
1 := λf.λx.f x
2 := λf.λx.f (f x)
3 := λf.λx.f (f (f x))
... and so on
``````

Which is why, if you did:

``````(if-then-elseop GEQ six two
#'(lambda () (print "THIS"))
#'(lambda () (print "THAT")))
``````

(I'd stick to the faithful interpretation of `IF-THEN-ELSE` though:

``````(defvar IFTHENELSE
#'(lambda (p)
#'(lambda (a)
#'(lambda (b) (funcall (funcall p a) b)))))
``````

Where `p` is your condition... )

As a side note, it's worth pointing out that it might not be too helpful to bring in `print` and other code that 'does stuff' within lambda calculus - the calculus does not define IO, and is restricted to evaluation of lambda expressions. The church encodings are a way of encoding numbers as lambda terms; There's no simple and meaningful way to represent a statement with side-effects such a `(print "hello")` as a lambda term; `#'(lambda () (print "THIS"))` works but as an academic exercise it's best to stick to only evaluating things and getting back results.

What about lisp itself? `if` in lisp is not a function so `(if cond then-expr else-expr)` works the way you expect (that is, only one of `then-expr` or `else-expr` will actually be evaluated) because it is a special form. If you were to define your own, you would need a macro (as @wvxvw rightly suggests). But that's another topic.

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