X-Git-Url: http://lambda.jimpryor.net/git/gitweb.cgi?p=lambda.git;a=blobdiff_plain;f=assignment1.mdwn;h=ea8f2511992e97ff0caed2f8f002426dd2bc053b;hp=4980cc2714311f140e0d465b374e7e494d0263c5;hb=HEAD;hpb=a1bb9458275d3da01448d6ad4a7b4a8d502b27cb diff --git a/assignment1.mdwn b/assignment1.mdwn deleted file mode 100644 index 4980cc27..00000000 --- a/assignment1.mdwn +++ /dev/null @@ -1,134 +0,0 @@ -*Reduction* - -Find "normal forms" for the following (that is, reduce them as far as it's possible to reduce -them): - -1. (\x \y. y x) z -2. (\x (x x)) z -3. (\x (\x x)) z -4. (\x (\z x)) z -5. (\x (x (\y y))) (\z (z z)) -6. (\x (x x)) (\x (x x)) -7. (\x (x x x)) (\x (x x x)) - - -*Booleans* - -Recall our definitions of true and false. - - "true" defined to be `\t \f. t` - "false" defined to be `\t \f. f` - -In Racket, these can be defined like this: - - (define true (lambda (t) (lambda (f) t))) - (define false (lambda (t) (lambda (f) f))) - - -8. Define a "neg" operator that negates "true" and "false". -Expeceted behavior: (((neg true) 10) 20) evaluates to 20, -(((neg false) 10) 20) evaluates to 10. - -9. Define an "and" operator. - -10. Define an "xor" operator. (If you haven't seen this term before, here's a truth table: - true xor true = false - true xor false = true - false xor true = true - false xor false = false -) - -11. Inspired by our definition of boolean values, propose a data structure -capable of representing one of the two values "black" or "white". If we have -one of those values, call it a black-or-white-value, we should be able to -write: - - the-black-or-white-value if-black if-white -(where if-black and if-white are anything), and get back one of if-black or -if-white, depending on which of the black-or-white values we started with. Give -a definition for each of "black" and "white". (Do it in both lambda calculus -and also in Racket.) - -12. Now propose a data structure capable of representing one of the three values -"red" "green" or "blue," based on the same model. (Do it in both lambda -calculus and also in Racket.) - - - -Pairs ------ - -Recall our definitions of ordered pairs. - - the pair (x,y) is defined as `\f. f x y` - -To extract the first element of a pair p, you write: - - p (\fst \snd. fst) - -Here are some defintions in Racket: - - (define make-pair (lambda (fst) (lambda (snd) (lambda (f) ((f fst) snd))))) - (define get-first (lamda (fst) (lambda (snd) fst))) - (define get-second (lamda (fst) (lambda (snd) snd))) - -Now we can write: - (define p ((make-pair 10) 20)) - (p get-first) ; will evaluate to 10 - (p get-second) ; will evaluate to 20 - -If you're bothered by having the pair to the left and the function that operates on it come seco\ -nd, think about why it's being done this way: the pair is a package that takes a function for op\ -erating on its elements as an argument, and returns the result of operating on its elemens with \ -that function. In other words, the pair is also a function. - -If you like, you can disguise what's going on like this: - (define lifted-get-first (lambda (p) (p get-first))) - (define lifted-get-second (lambda (p) (p get-second))) - -Now you can write: - (lifted-get-first p) -instead of: - (p get-first) -However, the latter is still what's going on under the hood. - - -13. Define a "swap" function that reverses the elements of a pair. -Expected behavior: - (define p ((make-pair 10) 20)) - ((p swap) get-first) ; evaluates to 20 - ((p swap) get-second) ; evaluates to 10 - -Write out the definition of swap in Racket. - - -14. Define a "dup" function that duplicates its argument to form a pair -whose elements are the same. -Expected behavior: - ((dup 10) get-first) ; evaluates to 10 - ((dup 10) get-second) ; evaluates to 10 -15. Define a "sixteen" function that makes -sixteen copies of its argument (and stores them in a data structure of -your choice). - -16. Inspired by our definition of ordered pairs, propose a data structure capable of representin\ -g ordered tripes. That is, - (((make-triple M) N) P) -should return an object that behaves in a reasonable way to serve as a triple. In addition to de\ -fining the make-triple function, you have to show how to extraxt elements of your triple. Write \ -a get-first-of-triple function, that does for triples what get-first does for pairs. Also write \ -get-second-of-triple and get-third-of-triple functions. - -> I expect some to come back with the lovely -> (\f. f first second third) -> and others, schooled in a certain mathematical perversion, to come back -> with: -> (\f. f first (\g. g second third)) - - -17. Write a function second-plus-third that when given to your triple, returns the result of add\ -ing the second and third members of the triple. - -You can help yourself to the following definition: - (define add (lambda (x) (lambda (y) (+ x y)))) -