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I'm trying to implement the factorial lambda expression as described in the book Lambda-calculus, Combinators and Functional Programming

The way it's described there is :

fact = (Y)λf.λn.(((is-zero)n)one)((multiply)n)(f)(predecessor)n
Y = λy.(λx.(y)(x)x)λx.(y)(x)x


(x)y is equivalent to (x y) and
(x)(y)z is equivalent to (x (y x)) and
λx.x is equivalent to (fn [x] x)

and is-zero, one, multiply and predecessor are defined for the standard church numerals. Actual definitions here.

I translated that to the following

(defn Y-mine [y]        ;  (defn Y-rosetta [y]              
  ((fn [x] (y (x x)))   ;    ((fn [f] (f f))                
    (fn [x]             ;     (fn [f]                       
      (y                ;       (y (fn [& args]             
        (x x)))))       ;            (apply (f f) args))))))


(def fac-mine                                ; (def fac-rosetta
  (fn [f]                                    ;      (fn [f]
    (fn [n]                                  ;        (fn [n]
      (is-zero n                             ;          (if (zero? n)
        one                                  ;            1
        (multiply n (f (predecessor n))))))) ;            (* n (f (dec n)))))))

The commented out versions are the equivalent fac and Y functions from Rosetta code.

Question 1:

I understand from reading up elsewhere that the Y-rosetta β-reduces to Y-mine. In which case why is it preferable to use that one over the other?

Question 2:

Even if I use Y-rosetta. I get a StackOverflowError when I try

((Y-rosetta fac-mine) two)


((Y-rosetta fac-rosetta) 2)

works fine.

Where is the unguarded recursion happening?

I suspect it's something to do with how the if form works in clojure that's not completely equivalent to my is-zero implementation. But I haven't been able to find the error myself.



Taking into consideration @amalloy's answer, I changed fac-mine slightly to take lazy arguments. I'm not very familiar with clojure so, this is probably not the right way to do it. But, basically, I made is-zero take anonymous zero argument functions and evaluate whatever it returns.

(def lazy-one (fn [] one))
(defn lazy-next-term [n f]
  (fn []
    (multiply n (f (predecessor n)))))

(def fac-mine                       
  (fn [f]                           
    (fn [n]                         
      ((is-zero n                   
        (lazy-next-term n f))))))

I now get an error saying:

=> ((Y-rosetta fac-mine) two)
ArityException Wrong number of args (1) passed to: core$lazy-next-term$fn  clojure.lang.AFn.throwArity (AFn.java:437)

Which seems really strange considering that lazy-next-term is always called with n and f

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1 Answer 1

The body of fac-mine looks wrong: it's calling (is-zero n one) for side effects, and then unconditionally calling (multiply n (f (predecessor n))). Presumably you wanted a conditional choice here (though I don't see why this doesn't throw an arity exception, given your definition of is-zero.

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I'm sorry. I made a mistake copying the code over. I've corrected it now. But I think the point about unconditionally calling multiply still holds. Is there a way to make that lazy? –  rjsvaljean Dec 17 '12 at 2:15

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