Super combinator: Difference between revisions
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* <code>\f g -> f (\x -> g x 2)</code> | * <code>\f g -> f (\x -> g x 2)</code> | ||
Any lambda calculus expression (or, indeed, Haskell program) with no free variables can be converted into supercombinators using [[Lambda lifting]]. For example, the last example can be expressed as: | |||
* <code>\f g -> f ((\h x -> h x 2) g)</code> | |||
A supercombinator which is not a lambda abstraction (i.e. for which n=0) is called a [[Constant applicative form]]. | |||
[[Category:Glossary]] | [[Category:Glossary]] | ||
[[Category:Combinators]] | [[Category:Combinators]] | ||
Revision as of 05:08, 1 February 2010
A super combinator is either a constant, or a Combinator which contains only super combinators as subexpressions.
To get a fuller idea of what a supercombinator is, it may help to use the following equivalent definition:
Any lambda expression is of the form \x1 x2 .. xn -> E, where E is not a lambda abstraction and n≥0. (Note that if the expression is not a lambda abstraction, n=0.) This is a supercombinator if and only if:
- the only free variables in E are x1..xn, and
- every lambda abstraction in E is a supercombinator.
So these are supercombinators:
0\x y -> x + y\f -> f (\x -> x + x)
These are not combinators, let alone supercombinators, because in each case, the variable y occurs free:
\x -> y\x -> y + x
This is a combinator, but not a supercombinator, because the inner lambda abstraction is not a combinator:
\f g -> f (\x -> g x 2)
Any lambda calculus expression (or, indeed, Haskell program) with no free variables can be converted into supercombinators using Lambda lifting. For example, the last example can be expressed as:
\f g -> f ((\h x -> h x 2) g)
A supercombinator which is not a lambda abstraction (i.e. for which n=0) is called a Constant applicative form.