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:
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
x, we can count like this:
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
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
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
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
Z. In a non-zero number
n corresponds to the argument bound to
g. So, remembering that
x are bound in an outside scope, we can count like this:
λh. h ((λu.x) f),
λh'. h' ((λh. h ((λu.x) f)) f) ... Performing the obvious reductions, we get this:
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
n corresponds to.