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transitive closure in alloy

Can any one here explains how the transitive closure operator works in Alloy in terms of the matrix. I mean what's translation rule for translating closure operator into actual matrix operation.

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To compute transitive closure, Kodkod uses iterative squaring.

In a nutshell, if you have a binary relation `r` (which directly translates to a 2-dimensional boolean matrix), transitive closure of `r` can be computed iteratively as

• r1 = r or (r . r)
• r2 = r1 or (r1 . r1)
• r3 = r1 or (r2 . r2)
• ...
• ^r = rn = rn-1 or (rn-1 . rn-1)

The question is when do we stop, i.e., what should `n` be. Since everything is bounded, Kodkod statically knows the maximum number of rows in `r`, and it should be intuitively clear that if `n` is set to be that number of rows, the algorithm will produce a semantically correct translation. However, even `n/2` is enough (since we are squaring the matrix every time), which is the actual number Kodkod uses.

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One more question, if I have c^.contents, what's the input matrix for computing transitive closure ? Suppose c is a type of signature C. Then what's input matrix? – user1197891 Jan 24 '13 at 16:57
what I mean is if I say c in c^.contents, how you can make sure c will be present in a transitive closure matrix then? – user1197891 Jan 24 '13 at 17:24
`c` is irrelevant when computing the transitive closure of `contents`. It is required that `contents` is a binary relation, then `^contents` is computed as I described previously, and finally a simple join between `c` and `^contents` is computed. – Aleksandar Milicevic Jan 25 '13 at 18:42