^{(Make sure you understand higher-order functions).} In Alonzo Church's untyped lambda calculus a function is the only primitive data type. There are no numbers, booleans, lists or anything else, only functions. Functions can have only 1 argument, but functions can accept and/or return functions—not values of these functions, but functions themselves. Therefore to represent numbers, booleans, lists and other types of data, you must come up with a clever way for anonymous functions to stand for them. Church numerals is the way to represent natural numbers. Three most primitive constructs in untyped lambda calculus are:

`λx.x`

, an identity function, accepts some function and immediately returns it.
`λx.x x`

, self-application.
`λf.λx.f x`

, function application, takes a function and an argument, and applies a function to an argument.

How do you encode 0, 1, 2 as nothing else but functions? We somehow need to build the notion of *quantity* into the system. We have only functions, every function can be applied only to 1 argument. Where can we see anything resembling quantity? Hey, we can apply a function to a parameter multiple times! There's obviously a sense of quantity in 3 repeated invocations of a function: `f (f (f x))`

. So let's encode it in lambda calculus:

- 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. But how do you go from 0 to 1, or from 1 to 2? How would you write a function that, given a number, would return a number incremented by 1? We see the pattern in Church numerals that the term always starts with `λf.λx.`

and after you have a finite repeated application of **f**, so we need to somehow get into the body of `λf.λx.`

and wrap it into another `f`

. How do you change a body of an abstraction without reduction? Well, you can apply a function, wrap the body in a function, then wrap the new body into the old lambda abstraction. But you don't want arguments to change, therefore you apply abstractions to the values of the same name: `((λf.λx.f x) f) x → f x`

, but `((λf.λx.f x) a) b) → a b`

, which is not what we need.

That's why `add1`

is `λn.λf.λx.f ((n f) x)`

: you apply `n`

to `f`

and then `x`

to reduce the expression to the body, then apply `f`

to that body, then abstract it again with `λf.λx.`

. **Exercise:** too see that it's true, quickly learn β-reduction and reduce `(λn.λf.λx.f ((n f) x)) (λf.λx.f (f x))`

to increment 2 by 1.

Now understanding the intuition behind wrapping the body into another function invocation, how do we implement addition of 2 numbers? We need a function that, given `λf.λx.f (f x)`

(2) and `λf.λx.f (f (f x))`

(3), would return `λf.λx.f (f (f (f (f x))))`

(5). Look at 2. What if you could *replace* its `x`

with the body of 3, that is `f (f (f x))`

? To get body of 3, it's obvious, just apply it to `f`

and then `x`

. Now apply 2 to `f`

, but then apply it to body of 3, not to `x`

. Then wrap it in `λf.λx.`

again: `λa.λb.λf.λx.a f (b f x)`

.

**Conclusion:** To add 2 numbers `a`

and `b`

together, both of which are represented as Church numerals, you want to *replace* `x`

in `a`

with the body of `b`

, so that `f (f x)`

+ `f (f (f x))`

= `f (f (f (f (f x))))`

. To make this happen, apply `a`

to `f`

, then to `b f x`

.