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I am implementing an impure untyped lambda-calculus interpreter in Haskell.

I'm presently stuck on implementing "alpha-congruence" (also called "alpha-equivalence" or "alpha-equality" in some textbooks). I want to be able to check whether two lambda-expressions are equal or not equal to each other. For example, if I enter the following expression into the interpreter it should yield True (\ is used to indicate the lambda symbol):

>\x.x == \y.y

The problem is understanding whether the following lambda-expressions are considered alpha-equivalent or not:

>\x.xy == \y.yx

>\x.yxy == \z.wzw

In the case of \x.xy == \y.yx I would guess that the answer is True. This is because \x.xy => \z.zy and \y.yx => \z.zy and the right-hand sides of both are equal (where the symbol => is used to denote alpha-reduction).

In the cae of \x.yxy == \z.wzw I would likewise guess that the answer is True. This is because \x.yxy => \a.yay and \z.wzw => \a.waw which (I think) are equal.

The trouble is that all of my textbooks' definitions state that only the names of the bound variables need to be changed for two lambda-expressions to be considered equal. It says nothing about the free variables in an expression needing to be renamed uniformly also. So even though y and w are both in their correct places in the lambda-expressions, how would the program "know" that the first y represents the first w and the second y represents the second w. I would need to be consistent about this in an implementation.

In short, how would I go about implementing an error-free version of a function isAlphaCongruent? What are the exact rules that I need to follow in order for this to work?

I would prefer to do this without using de Bruijn indices.

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They're not equivalent. Let's take \x.xy. You may rename x as you wish here and always obtain the same thing, but you can't rename y at will since it's not bounded by a lambda-abstraction. The same goes for \y.yx, but this time it's x that is not bound and thus cannot be renamed. This means you cannot rename them to make the congruence \x.xy == \y.yx true. See <a href="en.wikipedia.org/wiki/…; for more details. –  Riccardo May 28 '12 at 14:55
More specifically, \x.xy can be rewritten to \a.ay, and \y.yx can be rewritten to \a.ax, then it should be obvious that \a.ay /= \a.ax. –  Gabriel Gonzalez May 29 '12 at 3:42

1 Answer 1

up vote 9 down vote accepted

You are misunderstanding: different free variables are not alpha equivalent. So y /= x, and \w.wy /= \w.wx, and \x.xy /= \y.yx. Similarly, \x.yxy /= \z.wzw because y /= w.

Your book says nothing about free variables being allowed to be uniformly renamed because they are not allowed to be uniformly renamed.

(Think of it this way: if I haven't yet told you the definition of not and id, would you expect \x. not x and \x. id x to be equivalent? I sure hope not!)

share|improve this answer
It's exactly as Daniel says. When you see x as a free variable, it's not "any" x. –  Riccardo May 28 '12 at 15:00
Thank you! Both comments have cleared up the confusion. No wonder my program wasn't working! –  Mark May 28 '12 at 15:15

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