In this files, we verify a self interpreter for the SK lambda calculus. The idea is based on "Functional Bits: Lambda Calculus based Algorithmic Information Theory" (John Tromp 2022) (Github Repository).
An SK-expression is encoded as a bit-sequence which can be interpreted using a lambda calculus expression.
- K is encoded as 00
- S is encoded as 01
- Application A B is encoded as 1 followed by the encoding of A followed by the encoding of B
Sequences are encoded using nested tuples:
nilasλ x y. y<a,b>asλ f. f a b
Bits are encoded as booleans (functioning as conditionals):
0asλ x y. x1asλ x y. y
[0,1,0] becomes ⟨0, ⟨1, ⟨0, nil⟩⟩⟩.
The idea behind the interpreter is to write a continuation passing style function that checks:
- If the first bit is a 0:
- If the second bit is a 0, then we have a K
- If the second bit is a 1, then we have an S
- If the first bit is a 1, then we have an application
- Recursively, interpret the next two expressions and apply them to each other
The full interpreter is:
F := Y (λ F C xs. xs (λ a. a F₀ F₁))F₀ := λ ys. ys (λ b. C (b K S))F₁ := F (λ A. F (λ B. C (A B)))
xs=a::xr is either xs=0::(b::tl as ys) or xs=1::(encode a ++ encode b ++ tl).
The specification of the interpreter is:
F₀ ⟨b, xs⟩ ≡ C (b K S) xsF₁ (encode A ++ encode B ++ encode xs) ≡ C (A B) (encode xs)F C (encode x ++ encode xs) ≡ C x (encode xs)
The proofs work as follows:
- F₀: proof by careful reduction
- F₁: proof using the specification of F
- F
- unfolding lemma
- F₀/F₁ selection on head
- F₀ reduction to K, S
- F reduction on K/S encoding
- F₁ reduction to application
- induction on the encoded SK term