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I'm trying to understand the unification algorithm described in SICP here

In particular, in the procedure "extend-if-possible", there's a check (the first place marked with asterix "*") which is checking to see if the right hand "expression" is a variable that is already bound to something in the current frame:

(define (extend-if-possible var val frame)
  (let ((binding (binding-in-frame var frame)))
    (cond (binding
       (unify-match
        (binding-value binding) val frame))
      ((var? val)                      ; *** why do we need this?
       (let ((binding (binding-in-frame val frame)))
         (if binding
             (unify-match
              var (binding-value binding) frame)
             (extend var val frame))))
      ((depends-on? val var frame)
       'failed)
      (else (extend var val frame)))))

The associated commentary states:

"In the first case, if the variable we are trying to match is not bound, but the value we are trying to match it with is itself a (different) variable, it is necessary to check to see if the value is bound, and if so, to match its value. If both parties to the match are unbound, we may bind either to the other."

However, I cannot think of a case where this is actually necessary.

What's it's talking about, I think, is where you might have the following frame bindings currently present:

{?y = 4}

And are then asked to "extendIfPossible" a binding from ?z to ?y.

With that "*" check present, when asked to extend "?z" with "?y", we see that "?y" is already bound to 4, and then recursively try to unify "?z" with "4", which results with us extending the frame with "?z = 4".

Without the check, we would end up extending the frame with just "?z = ?y". But in both cases, so long as ?z is not already bound to something else, I don't see the problem.

Note, if ?z had already been bound to something else then the code doesn't reach the part marked "*" (we would have already recursed to unifying with what ?z had already been matched to).

After thinking it over, I have realised that there might be some sort of argument for generating a "simplest" MGU (Most General Unifier). e.g. you might want an MGU with a minimal number of variables referring to other variables... that is, we'd rather generate the substitution {?x = 4, ?y = 4} than the substitution {?x = ?y, ?y = 4}... but I don't think this algorithm would guarantee this behaviour in any case, because if you asked it to unify "(?x 4)" with "(?y ?y)" then you would still end up with {?x = ?y, ?y = 4}. And if the behaviour can't be guaranteed, why the additional complexity?

Is my reasoning here all correct? If not, what's a counter example where the "*" check is necessary to generate a correct MGU?

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2 Answers

up vote 5 down vote accepted

That's a good question!

I think the reason is that you don't want to end up with circular bindings such as { ?x = ?y, ?y = ?x }. In particular, unifying (?x ?y) with (?y ?x) would give you the circular frame above if you omitted the check. With the check, you get the frame { ?x = ?y } as expected.

Circular bindings in a frame are bad, because they may cause functions performing substitutions using the frame, such as instantiate, to run in an infinite loop.

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The 1st point is reasonable. Upvoted. But I can't mark it correct because I don't agree with the 2nd, because of the "binding-in-frame" check (that's why I said "Note, if ?z had already been bound to something else..."). In your example: unifying ?x with (1 2) subject to { ?y = (1 3), ?x = ?y }, first checks (binding-in-frame ?x frame) which returns ?y, so it recursively unifies ?y with (1 2)... Again (binding-in-frame ?y frame) returns (1 3), so it tries to unify (1 3) with (1 2), which will fail as it should, without ever needing the check for the right hand side being a variable. –  Paul Hollingsworth Sep 15 '09 at 21:51
    
btw sorry for the delay in replying - I was on vacation and then it took me a while to think about your answer properly! Thanks for answering... –  Paul Hollingsworth Sep 15 '09 at 21:54
    
Ah, you're right about the second point. I removed it. –  namin Sep 17 '09 at 12:34
    
That's a good enough reason for me –  Paul Hollingsworth Sep 17 '09 at 22:30
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Without it, you wouldn't get the most general unifier. There'd still be work to be done: unifying x and y.

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Define "most general"? How is { ?x = ?y, ?y = 4} any less general than { ?x = 4, ?y = 4 }? There's no binding for x and y that satisfies the first one that does not also satisfy the second one... –  Paul Hollingsworth Aug 10 '09 at 14:09
    
Yeah, you're right, it has nothing to do with the 'most general' unifier. I confused the variables with the values at the definition here: cs.ualberta.ca/~you/courses/325/Mynotes/Log/unif.html Actually, I haven't seen an implementation that doesn't try to unify as much as possible... –  Thomas Danecker Aug 10 '09 at 14:46
    
Is it even called unification if you're stopping in the middle of it? I remember by Prof. in Logic Programming deducted some points if you didn't unify everything that's possible. –  Thomas Danecker Aug 10 '09 at 14:51
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