Lambda calculus predecessor function reduction steps

I am getting stuck with the Wikipedia description of the predecessor function in lambda calculus.

What Wikipedia says is the following:

PRED := λnfx.n (λgh.h (g f)) (λu.x) (λu.u)

Can someone explain reduction processes step-by-step?

Thanks.

• I find lambda notation hard to follow, so I've done step-by-step reductions with S-expressions using Clojure for `(pred zero)`, `(pred one)` and `(pred two)` and published it on Github. – Agost Biro Apr 15 '17 at 11:05

Ok, so the idea of Church numerals is to encode "data" using functions, right? The way that works is by representing a value by some generic operation you'd perform with it. We can therefore go in the other direction as well, which can sometimes make things clearer.

Church numerals are a unary representation of the natural numbers. So, let's use `Z` to mean zero and `Sn` to represent the successor of `n`. Now we can count like this: `Z`, `SZ`, `SSZ`, `SSSZ`... The equivalent Church numeral takes two arguments--the first corresponding to `S`, and second to `Z`--then uses them to construct the above pattern. So given arguments `f` and `x`, we can count like this: `x`, `f x`, `f (f x)`, `f (f (f x))`...

Let's look at what PRED does.

First, it creates a lambda taking three arguments--`n` is the Church numeral whose predecessor we want, of course, which means that `f` and `x` are the arguments to the resulting numeral, which thus means that the body of that lambda will be `f` applied to `x` one time fewer than `n` would.

Next, it applies `n` to three arguments. This is the tricky part.

The second argument, that corresponds to `Z` from earlier, is `λu.x`--a constant function that ignores one argument and returns `x`.

The first argument, that corresponds to `S` from earlier, is `λgh.h (g f)`. We can rewrite this as `λg. (λh.h (g f))` to reflect the fact that only the outermost lambda is being applied `n` times. What this function does is take the accumulated result so far as `g` and return a new function taking one argument, which applies that argument to `g` applied to `f`. Which is absolutely baffling, of course.

So... what's going on here? Consider the direct substitution with `S` and `Z`. In a non-zero number `Sn`, the `n` corresponds to the argument bound to `g`. So, remembering that `f` and `x` are bound in an outside scope, we can count like this: `λu.x`, `λh. h ((λu.x) f)`, `λh'. h' ((λh. h ((λu.x) f)) f)` ... Performing the obvious reductions, we get this: `λu.x`, `λh. h x`, `λh'. h' (f x)` ... The pattern here is that a function is being passed "inward" one layer, at which point an `S` will apply it, while a `Z` will ignore it. So we get one application of `f` for each `S` except the outermost.

The third argument is simply the identity function, which is dutifully applied by the outermost `S`, returning the final result--`f` applied one fewer times than the number of `S` layers `n` corresponds to.

• +1 for the important insight that "the body of that lambda will be `f` applied to `x` one time fewer than `n` would." But how does it achieve this goal is still beyond me from your description. It would probably help with adding some more abstractions to this formula, abstracting the ideas in a bit higher level. For example, by replacing that `Lu.u` with `I`, the Identity function. And maybe some others too. I saw an interesting explanation of it here: mactech.com/articles/mactech/Vol.07/07.05/LambdaCalculus/… which deciphers these lambdas as list operations (cons,car,cdr). – SasQ Mar 14 '12 at 2:58
• I think the list version ends up being a different, more elaborate implementation, albeit an easier to understand one. The predecessor definition here really is just hard to comprehend, and the best way to see how it works might be to step through the evaluation manually to get a feel for what's going on. – C. A. McCann Mar 14 '12 at 3:20

McCann's answer explains it pretty well. Let's take a concrete example for Pred 3 = 2:

Consider expression: n (λgh.h (g f)) (λu.x). Let K = (λgh.h (g f))

For n = 0, we encode `0 = λfx.x`, so when we apply the beta reduction for `(λfx.x)(λgh.h(gf))` means `(λgh.h(gf))` is replaced 0 times. After further beta-reduction we get:

`λfx.(λu.x)(λu.u)`

reduces to

`λfx.x`

where `λfx.x = 0`, as expected.

For n = 1, we apply K for 1 times:

```(λgh.h (g f)) (λu.x) => λh. h((λu.x) f) => λh. h x```

For n = 2, we apply K for 2 times:

```(λgh.h (g f)) (λh. h x) => λh. h ((λh. h x) f) => λh. h (f x)```

For n = 3, we apply K for 3 times:

```(λgh.h (g f)) (λh. h (f x)) => λh.h ((λh. h (f x)) f) => λh.h (f (f x))```

Finally, we take this result and apply an id function to it, we got

```λh.h (f (f x)) (λu.u) => (λu.u)(f (f x)) => f (f x)```

This is the definition of number 2.

The list based implementation might be easier to understand, but it takes many intermediate steps. So it is not as nice as the Church's original implementation IMO.

• I don't understand how you get from "For n = so and so many times we apply K for so and so many times" to each of the first lines of the derivations. – Zelphir Sep 26 '16 at 23:38
• Yeah it's not explicitly stated; but it comes from the `f` term in a numeral. For instance 2 is defined as `λfx.f(fx)`. So that means when the beta reduction is done for `(λfx.f(fx))(λgh.h (g f))` the `(λgh.h (g f))` function is applied twice. – Greg Feb 12 '17 at 2:33

After Reading the previous answers (good ones), I’d like to give my own vision of the matter in hope it helps someone (corrections are welcomed). I’ll use an example.

First off, I’d like to add some parenthesis to the definition that made everything clearer to me. Let’s redifine the given formula to:

``````PRED := λn λf λx.(n (λgλh.h (g f)) (λu.x)) (λu.u)
``````

Let’s also define three Church numerals that will help with the example:

``````Zero := λfλx.x
One := λfλx. f (Zero f x)
Two := λfλx. f (One f x)
Three := λfλx. f (Two f x)
``````

In order to understand how this works, let's focus first on this part of the formula:

``````n (λgλh.h (g f)) (λu.x)
``````

From here, we can extract this conclusions: `n` is a Church numeral, the function to be applied is `λgλh.h (g f)` and the starting data is `λu.x`

With this in mind, let's try an example:

``````PRED Three := λf λx.(Three (λgλh.h (g f)) (λu.x)) (λu.u)
``````

Let's focus first on the reduction of the numeral (the part we explained before):

``````Three (λgλh.h (g f)) (λu.x)
``````

Which reduces to:

``````(λgλh.h (g f)) (Two (λgλh.h (g f)) (λu.x))
(λgλh.h (g f)) ((λgλh.h (g f)) (One (λgλh.h (g f)) (λu.x)))
(λgλh.h (g f)) ((λgλh.h (g f)) ((λgλh.h (g f)) (Zero (λgλh.h (g f)) (λu.x))))
(λgλh.h (g f)) ((λgλh.h (g f)) ((λgλh.h (g f)) ((λfλx.x) (λgλh.h (g f)) (λu.x)))) -- Here we lose one application of f
(λgλh.h (g f)) ((λgλh.h (g f)) ((λgλh.h (g f)) (λu.x)))
(λgλh.h (g f)) ((λgλh.h (g f)) (λh.h ((λu.x) f)))
(λgλh.h (g f)) ((λgλh.h (g f)) (λh.h x))
(λgλh.h (g f)) (λh.h ((λh.h x) f))
(λgλh.h (g f)) (λh.h (f x))
(λh.h ((λh.h (f x) f)))
``````

Ending up with:

``````λh.h f (f x)
``````

So, we have:

``````PRED Three := λf λx.(λh.h (f (f x))) (λu.u)
``````

Reducing again:

``````PRED Three := λf λx.((λu.u) (f (f x)))
PRED Three := λf λx.f (f x)
``````

As you can see in the reductions, we end up applying the function one time less thanks to a clever way of using functions.

Using add1 as `f` and 0 as `x`, we get:

``````PRED Three add1 0 := add1 (add1 0) = 2
``````

Hope this helps.

You can try to understand this definition of the predecessor function (not my favourite one) in terms of continuations.

To simplify the matter a bit, let us consider the following variant

``````    PRED := λn.n (λgh.h (g S)) (λu.0) (λu.u)
``````

then, you can replace S with f, and 0 with x.

The body of the function iterates n times a transformation M over an argument N. The argument N is a function of type (nat -> nat) -> nat that expects a continuation for nat and returns a nat. Initially, N = λu.0, that is it ignores the continuation and just returns 0. Let us call N the current computation.

The function M: (nat -> nat) -> nat) -> (nat -> nat) -> nat modifies the computation g: (nat -> nat)->nat as follows. It takes in input a continuation h, and applies it to the result of continuing the current computation g with S.

Since the initial computation ignored the continuation, after one application of M we get the computation (λh.h 0), then (λh.h (S 0)), and so on.

At the end, we apply the computation to the identity continuation to extract the result.