X-Git-Url: http://lambda.jimpryor.net/git/gitweb.cgi?p=lambda.git;a=blobdiff_plain;f=assignment3.mdwn;h=e240b732b1405e176d696bbab3c5974a1d125f35;hp=71960dc8429ebf75a81638f7c6664fe2dfc17c99;hb=434fc9bef584f51ac5338a39dc4ff5da44b5b435;hpb=f3400cc9679e5f4f78cee730349d74e465648eac diff --git a/assignment3.mdwn b/assignment3.mdwn index 71960dc8..e240b732 100644 --- a/assignment3.mdwn +++ b/assignment3.mdwn @@ -1,32 +1,151 @@ Assignment 3 ------------ +Erratum corrected 11PM Sun 3 Oct: the following line + + let tb = (make_list t12 (make_list t3 empty)) in + +originally read + + let tb = (make_list t12 t3) in + +This has been corrected below, and in the preloaded evaluator for +working on assignment 3, available here: [[assignment 3 evaluator]]. + +
+ Once again, the lambda evaluator will make working through this assignment much faster and more secure. -*Writing recursive functions on version 1 style lists* +#Writing recursive functions on version 1 style lists# + +Recall that version 1 style lists are constructed like this (see +[[lists and numbers]]): + + ; booleans + let true = \x y. x in + let false = \x y. y in + let and = \l r. l (r true false) false in + + let make_pair = \f s g. g f s in + let get_fst = true in + let get_snd = false in + let empty = make_pair true junk in + let isempty = \x. x get_fst in + let make_list = \h t. make_pair false (make_pair h t) in + let head = \l. isempty l err (l get_snd get_fst) in + let tail = \l. isempty l err (l get_snd get_snd) in + + ; a list of numbers to experiment on + let mylist = make_list 1 (make_list 2 (make_list 3 empty)) in + + ; church numerals + let iszero = \n. n (\x. false) true in + let succ = \n s z. s (n s z) in + let add = \l r. l succ r in + let mul = \m n s. m (n s) in + let pred = (\shift n. n shift (make\_pair 0 0) get\_snd) (\p. p (\x y. make\_pair (succ x) x)) in + let leq = \m n. iszero(n pred m) in + let eq = \m n. and (leq m n)(leq n m) in + + ; a fixed-point combinator for defining recursive functions + let Y = \f. (\h. f (h h)) (\h. f (h h)) in + let length = Y (\length l. isempty l 0 (succ (length (tail l)))) in + let fold = Y (\f l g z. isempty l z (g (head l)(f (tail l) g z))) in + + eq 2 2 yes no + + +Then `length mylist` evaluates to 3. + +1. What does `head (tail (tail mylist))` evaluate to? + +2. Using the `length` function as a model, and using the predecessor +function, write a function that computes factorials. (Recall that n!, +the factorial of n, is n times the factorial of n-1.) + + Warning: it takes a long time for my browser to compute factorials larger than 4! + +3. (Easy) Write a function `equal_length` that returns true just in case +two lists have the same length. That is, + + equal_length mylist (make_list junk (make_list junk (make_list junk empty))) ~~> true -Recall that version 1 style lists are constructed like this: + equal_length mylist (make_list junk (make_list junk empty))) ~~> false + + +4. (Still easy) Now write the same function, but don't use the length +function. + +5. In assignment 2, we discovered that version 3-type lists (the ones +that +work like Church numerals) made it much easier to define operations +like `map` and `filter`. But now that we have recursion in our +toolbox, +reasonable map and filter functions for version 1 lists are within our +reach. Give definitions for `map` and a `filter` for verson 1 type +lists. + +#Computing with trees# + +Linguists analyze natural language expressions into trees. + +We'll need trees in future weeks, and tree structures provide good +opportunities for learning how to write recursive functions. +Making use of the resources we have at the moment, we can approximate +trees as follows: instead of words, we'll use Church numerals. +Then a tree will be a (version 1 type) list in which each element is +itself a tree. For simplicity, we'll adopt the convention that +a tree of length 1 must contain a number as its only element. + +Then we have the following representations: 
-let true = \x y. x in
-let false = \x y. y in
-let makePair = \f s g. g f s in
-let nil = makePair true meh in
-let makeList = \h t. makePair false (makePair h t) in
-let mylist = makeList 1 (makeList 2 (makeList 3 nil)) in
-let fst = true in
-let snd = false in
-let isNil = \x. x fst in
-let head = \l. isNil l err (l snd fst) in
-let tail = \l. isNil l err (l snd snd) in
-let succ = \n s z. s (n s z) in
-let Y = \f. (\h. f (h h)) (\h. f (h h)) in
-let length = Y (\length l. isNil l 0 (succ (length (tail l)))) in
-
-length mylist
+   (a)           (b)             (c)
+    .
+   /|\            /\              /\
+  / | \          /\ 3            1 /\
+  1 2  3        1  2               2 3
+
+[[1];[2];[3]]  [[[1];[2]];[3]]   [[1];[[2];[3]]]
-Then `length mylist` evaluates to 3. +Limitations of this scheme include the following: there is no easy way +to label a constituent with a syntactic category (S or NP or VP, +etc.), and there is no way to represent a tree in which a mother has a +single daughter. + +When processing a tree, you can test for whether the tree contains +only a numeral (in which case the tree is leaf node) by testing for +whether the length of the list is less than or equal to 1. This will +be your base case for your recursive functions that operate on these +trees. + +
    +
  1. Write a function that sums the values at the leaves in a tree. + +Expected behavior: + + let t1 = (make_list 1 empty) in + let t2 = (make_list 2 empty) in + let t3 = (make_list 3 empty) in + let t12 = (make_list t1 (make_list t2 empty)) in + let t23 = (make_list t2 (make_list t3 empty)) in + let ta = (make_list t1 t23) in + let tb = (make_list t12 (make_list t3 empty)) in + let tc = (make_list t1 (make_list t23 empty)) in + + sum-leaves t1 ~~> 1 + sum-leaves t2 ~~> 2 + sum-leaves t3 ~~> 3 + sum-leaves t12 ~~> 3 + sum-leaves t23 ~~> 5 + sum-leaves ta ~~> 6 + sum-leaves tb ~~> 6 + sum-leaves tc ~~> 6 + + +
  2. Write a function that counts the number of leaves. + +
-What does `head (tail (tail mylist))` evaluate to?