# Beta reduction in lambda calculus: Order of evaluation important?

Given the following lambda expression, where `\` resembles `lambda`:

``````(\kf.f(\c.co)km)(\x.dox)(\le.le)
``````

Is it wrong if I convert `(\c.co)k` into `ko`? I did that and apparently, it was wrong. The right way to go would have been to evaluate the outer function first, meaning `(\f.f(\c.co)(\x.dox)m)(\le.le)` would have been the desired solution.

Is that true, because I can't find any rule that could indicate that in our lecture notes? If yes, why can't I evaluate inner functions first? I've done it like this and my solution was correct, nonetheless.

Regards.

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Candidate for migration to cs.stackexchange.com? –  Mox Jan 28 '13 at 21:33

So, beta-reduction in the (untyped) lambda calculus is what we call a confluent rewrite rule. This means if you can rewrite `A` to `B` with beta reduction, and also rewrite `A` to `C` with beta-reduction, then you can find some `D` such that `B` rewrites to `D` and `C` rewrites to `D` - there will be, in effect, some common descendent. The theorem that shows this for the lambda calculus is normally called the Church-Rosser theorem. The overall property is sometimes called the diamond property, as the diagram resembles a diamond (two routes branch out, but eventually come back together again). It also means that the final outcome of a "termination" lambda expression will be identical no matter how you choose to apply beta-reduction.

However, not all lambda terms have one final outcome. This means the untyped calculus is not what we call normalising. There are plenty of lambda terms that will expand forever under beta-reduction (never reaching an irreducible, or normal form). In these situations, having some system for ordering your rewrites is useful, as it ensures that evaluation of programs proceeds identically for two identical programs.

Of course, you need to ensure you are respecting the binding rules of lambda, so you don't try and apply terms to the wrong lambda variables.

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I asked my TA, he said that application is left associative, meaning

``````(\kf.f(\c.co)km)(\x.dox)(\le.le)
``````

is equivalent to

``````( [\kf.( [ f(\c.co) ]k )m ][\x.dox] )[ \le.le ]
``````

That explains why `k` can't be applied to `(\c.co)`.:/

Brackets/parentheses are used only to make it more readable.

Regards.

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