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I'm learning lambda calculus these days and found it very beautiful and interesting, but I haven't found out how to implement the EQ primitive of LISP, which judges if two symbols are the same.

I have found many materials for implementing integer arithmetic (using Church Numbers) and boolean logic, but failed to find a solution for EQ. I hope EQ works like this(the same of LISP):

(EQ x x) --> True
(EQ x y) --> False
(EQ (x y) (x y)) --> False // return true only for simple symbols, not structures

Any help.


I do not mind to wrap symbols into some contexts, for example:

(EQ (lambda u . u symbol x) (lambda u . u symbol x)) --> True
(EQ (lambda u . u symbol x) (lambda u . u symbol y)) --> False

I've found a possible solution:

If we restrict symbols in a finite set, e.g., Symbols = {A, B, C}, then we can define an EQ like this:

A = λ A B C. A
B = λ A B C. B
C = λ A B C. C
EQ = λ x y. ChurchEQ (x 1 2 3) (y 1 2 3)    // Here 1, 2, 3 should be replaced by Church Numbers

I have tested these code in an interpreter, and it works.

But one problem remains: The EQ itself can't be placed into Symbols.

share|improve this question
then what would ((lambda symbol. symbol) 1) evaluate to? –  Will Ness Jan 9 '14 at 6:30
and what should EQ (λu.ux) (λ inside (λy.(λx.EQ (λu.ux) (λ y) evaluate to? –  Will Ness Jan 9 '14 at 6:35

1 Answer 1

up vote 4 down vote accepted

There is no way to define a general notion of equality for arbitrary terms in the lambda calculus. Depending on the implementation EQ is either defined as syntactic equality (perhaps up to α-equivalence) or pointer equality which have to be defined in the implementation of your interpreter and not in the language itself.

That said, there are many cases of specific lambda expressions ( i.e. church numerals, church booleans ) where there is a well-defined decision procedure for determining equality which of course be encoded in the lambda calculus, just like it can be encoded in any language. For example for booleans:

T = λ x y. x
F = λ x y. y
not = λ p. p F T
xor = λ p q. p (q F T) q
equ = λ p q. not (xor p q)
share|improve this answer
Yeah, I know these booleans work, but how about EQ? I do not mind wrapping symbols in some context, e.g. EQ (symbol x) (symbol x). –  SaltyEgg Jan 9 '14 at 5:48
@SaltyEgg There's no symbols in LC itself, by definition, it only deals with values. You can not define the notions of "free" and "bound" variables in lambda calculus itself, either. It's all a part of how you implement it in the computer, or in your head when working with pencil and paper. –  Will Ness Jan 9 '14 at 6:29
@SaltyEgg it's the other way around; you implement LC in LISP. EQ as part of LISP is non-reducible to LC. There's no EQ in LC because EQ is pointer-equality and there's no pointers in LC. –  Will Ness Jan 9 '14 at 6:43
@SaltyEgg Ask yourself how you would define eq in terms of Turing machines, it's just as meaningless to ask. I don't know what you're thinking, but my guess is you've misunderstood some existence proof you've heard about the calculable equivalence of the abstract Turing machines and abstract LC and are trying to apply this assumed property to a concrete implementation on stock hardware and it's leading you to wrong assumptions about what you can and can't write in the LC. –  Stephen Diehl Jan 10 '14 at 3:01
@freyrs Thanks very much, and I'll go for more reading. –  SaltyEgg Jan 10 '14 at 15:25

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