# What are “reduction semantics”? Please explain the use of PLT Redex in layman's term

Somebody please explain the usage of reduction semantics and the PLT Redex in simpler language.

Thanks.

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Reduction semantics is a computation technique that involves replacing an expression by an equivalent (and hopefully smaller) expression until no more replacement is possible. If a language is Turing-complete, there are expressions that never stop replacing.

Reduction is usually notated by a right arrow, and it's best explained by example:

``````(3 + 7) + 5   -->  10 + 5  -->  15
``````

This shows the standard reduction semantics for arithmetic expressions. The expression `15` cannot be reduced any further.

Hope this helps.

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See also the redex website (redex.plt-scheme.org) and the book that was published recently ("Semantics Engineering with PLT Redex"). –  Eli Barzilay Jul 29 '09 at 18:01

Reduction semantics are similar (if not the same?) to contextual semantics. Any expression can be broken down into a context and redex.

Robert Harper's Practical Foundations for Programming Languages (draft PDF available here) section 9.3 Contextual Semantics does a decent job of explaining them.

An example:

``````print 5+4
**context: print [],  redex: 5+4
**evaluate redex: 9
**plug back into context

print 9
**context: [], redex: print 9
**evaluate redex: nil  ==> 9
**plug back into context

nil
``````

You can 'stick' the redex back into the 'hole' of the context to get: print 5+4. The evaluation happens at the redex. You break an expression into a context + redex, evaluate the redex to get a new expression, plug that back into the context, rinse and repeat.

Here's a slightly more complicated example that requires knowledge of an abstract machine that evaluates the lambda calculus:

``````(lambda x.x+1) 5
**context: [] 5, redex: (lambda x.x+1)
**evaluate redex: <(lambda x.x+1), {environment}> <- create a closure
**plug back into context

<(lambda x.x+1), {}> 5
**context: [], redex: <(lambda x.x+1), {}> 5
**evaluate redex: x+1 where x:=5
**plug back into context

x+1 where x:=5
**context: []+1, redex: x
**evaluate redex: 5 (since x:=5 in our environment)
*plug back into context

5+1...
6
``````

EDIT: The tricky part is recognizing where to break an expression into a context & redex. It requires knowledge of the operational semantics of the language (which 'piece' of an expression you need to evaluate next).

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