## Anonymous recursion

A fixed-point combinator is a higher-order function `fix`

that by definition satisfies the equivalence

```
forall f. fix f = f (fix f)
```

`fix f`

represents a solution `x`

to the fixed-point equation

```
x = f x
```

The factorial of a natural number can be proved by

```
fact 0 = 1
fact n = n * fact (n - 1)
```

Using `fix`

, arbitrary constructive proofs over general/μ-recursive functions can be derived without nonymous self-referentiality.

```
fact n = (fix fact') n
```

where

```
fact' rec n = if n == 0
then 1
else n * rec (n - 1)
```

such that

```
fact 3
= (fix fact') 3
= fact' (fix fact') 3
= if 3 == 0 then 1 else 3 * (fix fact') (3 - 1)
= 3 * (fix fact') 2
= 3 * fact' (fix fact') 2
= 3 * if 2 == 0 then 1 else 2 * (fix fact') (2 - 1)
= 3 * 2 * (fix fact') 1
= 3 * 2 * fact' (fix fact') 1
= 3 * 2 * if 1 == 0 then 1 else 1 * (fix fact') (1 - 1)
= 3 * 2 * 1 * (fix fact') 0
= 3 * 2 * 1 * fact' (fix fact') 0
= 3 * 2 * 1 * if 0 == 0 then 1 else 0 * (fix fact') (0 - 1)
= 3 * 2 * 1 * 1
= 6
```

This formal proof that

```
fact 3 = 6
```

methodically uses the fixed-point combinator equivalence for *rewrites*

```
fix fact' -> fact' (fix fact')
```

## Lambda calculus

The *untyped lambda calculus* formalism consists in a context-free grammar

```
E ::= v Variable
| λ v. E Abstraction
| E E Application
```

where `v`

ranges over variables, together with the *beta* and *eta reduction* rules

```
(λ x. B) E -> B[x := E] Beta
λ x. E x -> E if x doesn’t occur free in E Eta
```

Beta reduction substitutes all free occurrences of the variable `x`

in the abstraction (“function”) body `B`

by the expression (“argument”) `E`

. Eta reduction eliminates redundant abstraction. It is sometimes omitted from the formalism. An *irreducible* expression, to which no reduction rule applies, is in *normal* or *canonical form*.

```
λ x y. E
```

is shorthand for

```
λ x. λ y. E
```

(abstraction multiarity),

```
E F G
```

is shorthand for

```
(E F) G
```

(application left-associativity),

```
λ x. x
```

and

```
λ y. y
```

are *alpha-equivalent*.

Abstraction and application are the two only “language primitives” of the lambda calculus, but they allow *encoding* of arbitrarily complex data and operations.

The Church numerals are an encoding of the natural numbers similar to the Peano-axiomatic naturals.

```
0 = λ f x. x No application
1 = λ f x. f x One application
2 = λ f x. f (f x) Twofold
3 = λ f x. f (f (f x)) Threefold
. . .
SUCC = λ n f x. f (n f x) Successor
ADD = λ n m f x. n f (m f x) Addition
MULT = λ n m f x. n (m f) x Multiplication
. . .
```

A formal proof that

```
1 + 2 = 3
```

using the rewrite rule of beta reduction:

```
ADD 1 2
= (λ n m f x. n f (m f x)) (λ g y. g y) (λ h z. h (h z))
= (λ m f x. (λ g y. g y) f (m f x)) (λ h z. h (h z))
= (λ m f x. (λ y. f y) (m f x)) (λ h z. h (h z))
= (λ m f x. f (m f x)) (λ h z. h (h z))
= λ f x. f ((λ h z. h (h z)) f x)
= λ f x. f ((λ z. f (f z)) x)
= λ f x. f (f (f x)) Normal form
= 3
```

## Combinators

In lambda calculus, *combinators* are abstractions that contain no free variables. Most simply: `I`

, the identity combinator

```
λ x. x
```

isomorphic to the identity function

```
id x = x
```

Such combinators are the primitive operators of *combinator calculi* like the SKI system.

```
S = λ x y z. x z (y z)
K = λ x y. x
I = λ x. x
```

Beta reduction is not *strongly normalizing*; not all reducible expressions, “redexes”, converge to normal form under beta reduction. A simple example is divergent application of the omega `ω`

combinator

```
λ x. x x
```

to itself:

```
(λ x. x x) (λ y. y y)
= (λ y. y y) (λ y. y y)
. . .
= _|_ Bottom
```

Reduction of leftmost subexpressions (“heads”) is prioritized. *Applicative order* normalizes arguments before substitution, *normal order* does not. The two strategies are analogous to eager evaluation, e.g. C, and lazy evaluation, e.g. Haskell.

```
K (I a) (ω ω)
= (λ k l. k) ((λ i. i) a) ((λ x. x x) (λ y. y y))
```

diverges under eager applicative-order beta reduction

```
= (λ k l. k) a ((λ x. x x) (λ y. y y))
= (λ l. a) ((λ x. x x) (λ y. y y))
= (λ l. a) ((λ y. y y) (λ y. y y))
. . .
= _|_
```

since in *strict* semantics

```
forall f. f _|_ = _|_
```

but converges under lazy normal-order beta reduction

```
= (λ l. ((λ i. i) a)) ((λ x. x x) (λ y. y y))
= (λ l. a) ((λ x. x x) (λ y. y y))
= a
```

If an expression has a normal form, normal-order beta reduction will find it.

## Y

The essential property of the `Y`

*fixed-point combinator*

```
λ f. (λ x. f (x x)) (λ x. f (x x))
```

is given by

```
Y g
= (λ f. (λ x. f (x x)) (λ x. f (x x))) g
= (λ x. g (x x)) (λ x. g (x x)) = Y g
= g ((λ x. g (x x)) (λ x. g (x x))) = g (Y g)
= g (g ((λ x. g (x x)) (λ x. g (x x)))) = g (g (Y g))
. . . . . .
```

The equivalence

```
Y g = g (Y g)
```

is isomorphic to

```
fix f = f (fix f)
```

The untyped lambda calculus can encode arbitrary constructive proofs over general/μ-recursive functions.

```
FACT = λ n. Y FACT' n
FACT' = λ rec n. if n == 0 then 1 else n * rec (n - 1)
FACT 3
= (λ n. Y FACT' n) 3
= Y FACT' 3
= FACT' (Y FACT') 3
= if 3 == 0 then 1 else 3 * (Y FACT') (3 - 1)
= 3 * (Y FACT') (3 - 1)
= 3 * FACT' (Y FACT') 2
= 3 * if 2 == 0 then 1 else 2 * (Y FACT') (2 - 1)
= 3 * 2 * (Y FACT') 1
= 3 * 2 * FACT' (Y FACT') 1
= 3 * 2 * if 1 == 0 then 1 else 1 * (Y FACT') (1 - 1)
= 3 * 2 * 1 * (Y FACT') 0
= 3 * 2 * 1 * FACT' (Y FACT') 0
= 3 * 2 * 1 * if 0 == 0 then 1 else 0 * (Y FACT') (0 - 1)
= 3 * 2 * 1 * 1
= 6
```

(Multiplication delayed, confluence)

For Churchian untyped lambda calculus, there has been shown to exist a recursively enumerable infinity of fixed-point combinators besides `Y`

.

```
X = λ f. (λ x. x x) (λ x. f (x x))
Y' = (λ x y. x y x) (λ y x. y (x y x))
Z = λ f. (λ x. f (λ v. x x v)) (λ x. f (λ v. x x v))
Θ = (λ x y. y (x x y)) (λ x y. y (x x y))
. . .
```

Normal-order beta reduction makes the unextended untyped lambda calculus a Turing-complete rewrite system.

In Haskell, the fixed-point combinator can be elegantly implemented

```
fix :: forall t. (t -> t) -> t
fix f = f (fix f)
```

Haskell’s laziness normalizes to a finity before all subexpressions have been evaluated.

```
primes :: Integral t => [t]
primes = sieve [2 ..]
where
sieve = fix (\ rec (p : ns) ->
p : rec [n | n <- ns
, n `rem` p /= 0])
```