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")))
```

should work. *(sort of, read ahead)*

(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.