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I´m quite new to lambda-calculus and I´m trying to do the following exercise, but I´m not able to resolve it.

uncurry(curry E) = E

Could anyone help me?

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closed as not a real question by Jan Dvorak, Eng.Fouad, Peter DeWeese, jv42, jadarnel27 Feb 14 '13 at 15:26

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1 Answer 1

up vote 2 down vote accepted

assuming the following definions (you need to check if those match you definitions)

// creates a pair of two values
pair    := λx.λy.λf. fxy
// selects the first element of the pair     
first   := λp. p(λx.λy. x)
// selects the second element of the pair                     
second  := λp. p(λx.λy. y)
// currys f
curry   := λf.λx.λy . f (pair x y)
// uncurrys f
uncurry := λf.λp . f (first p) (second p)

you show

uncurry(curry E) = E

by inserting the definitions above into curry and uncurry in

uncurry(curry E)

which leads to

(λf.λp . f (first p) (second p)) ( (λf.λx.λy . f (pair x y)) E)

Then you reduce the term above using the reduction rules of the lambda-caluclus, namely using:

  • α-conversion: changing bound variables
  • β-reduction: applying functions to their arguments

http://en.wikipedia.org/wiki/Lambda_calculus http://www.mathstat.dal.ca/~selinger/papers/lambdanotes.pdf

which should lead to


if you write down each reduction step, you have proven that

uncurry(curry E) = E

here a sketch how it should look like:

uncurry(curry E) = // by curry-, uncurry-definion
(λf.λp . f (first p) (second p)) ( (λf.λx.λy . f (pair x y)) E) = // by pair-definiton
(λf.λp . f (first p) (second p)) ( (λf.λx.λy . f (λx.λy.λf. fxy x y)) E) = // 2 alpha-conversions
(λf.λp . f (first p) (second p)) ( (λf.λx.λy . f (λa.λb.λf. fab x y)) E) = // 2 beta-reductions
(λf.λp . f (first p) (second p)) ( (λf.λx.λy . f (λf. fxy)) E) = // ...

... = // β-reduction
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the definitions match but I think that I´m failing on some reduction step. could you write down all the steps? thank you! –  ikerexxe Feb 14 '13 at 16:23
I think that's the point of the exercise. –  Marco Träger Feb 14 '13 at 17:11
Is it well that way? uncurry (curry E) = λf.λp . f (first p) (second p) ( λf.λx.λy . f (pair xy) E) = λf.λp . f (first p) (second p) ( λx.λy.E (pair xy) ) = λf.λp . f (first p) (second p) E = λp . E (first p) (second p) = E –  ikerexxe Feb 14 '13 at 20:22
first of all: I had some bracket misses around the 'functions', I added them. They were the reasons of your odd reductions. theirfore: uncurry (curry E) = (λf.λp . f (first p) (second p)) ( λf.λx.λy . f (pair xy) E) = (λf.λp . f (first p) (second p)) ( λx.λy.E (pair xy) ) = λp . ( λx.λy.E (pair xy) ) (first p) (second p) = λp . E (pair (first p) (second p) ) = **then insert the definition of pair, first and second and the rest should cancel –  Marco Träger Feb 15 '13 at 0:34
I think I´m doing it the wrong way λp . E (λxyf . fxy ((λo . oT) p) ((λo . oF) p) ) = λp . E (λxyf . fxy ((λo . o(λx.λy . x)) p) ((λo . o(λx.λy . y)) p) ) = λp . E (λxyf . fxy (p (λx.λy . x)) (p (λx.λy . y))) = λp . E (λf . f(p (λx.λy . x))(p (λx.λy . y))) = λp . E (λf . fpp) and now what? –  ikerexxe Feb 15 '13 at 10:56

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