XGitUrl: http://lambda.jimpryor.net/git/gitweb.cgi?p=lambda.git;a=blobdiff_plain;f=assignment2.mdwn;h=5d75a855a5a09ef187dcdd9b6e4e22bb11b6ee7a;hp=65fe479ccb1357c6711e689115b38cefb8df757b;hb=ff95f5a38d61a6fa0b9c5e4da4253a6a3266a7dc;hpb=8aa265f15b21b2f78be32a940f8df98720387c1b
diff git a/assignment2.mdwn b/assignment2.mdwn
index 65fe479c..5d75a855 100644
 a/assignment2.mdwn
+++ b/assignment2.mdwn
@@ 1,3 +1,6 @@
+For these assignments, you'll probably want to use our [[lambda evaluator]] to check your work. This accepts any grammatical lambda expression and reduces it to normal form, when possible.
+
+
More Lambda Practice

@@ 30,6 +33,36 @@ Reduce to betanormal forms:
`(\x y z. x z (y z)) (\u v. u)`
+Combinatory Logic
+
+
+Reduce the following forms, if possible:
+
+
+ `Kxy`
+
 `KKxy`
+
 `KKKxy`
+
 `SKKxy`
+
 `SIII`
+
 `SII(SII)`
+
+
 Give Combinatory Logic combinators that behave like our boolean functions.
+ You'll need combinators for `true`, `false`, `neg`, `and`, `or`, and `xor`.
+
+
+Using the mapping specified in the lecture notes,
+translate the following lambda terms into combinatory logic:
+
+
+ `\x.x`
+
 `\xy.x`
+
 `\xy.y`
+
 `\xy.yx`
+
 `\x.xx`
+
 `\xyz.x(yz)`
+
 For each translation, how many I's are there? Give a rule for
+ describing what each I corresponds to in the original lambda term.
+
Lists and Numbers

@@ 56,6 +89,7 @@ The `junk` in `extracthead` is what you get back if you evaluate:
As we said, the predecessor and the extracttail functions are harder to define. We'll just give you one implementation of these, so that you'll be able to test and evaluate lambdaexpressions using them in Scheme or OCaml.
predecesor ≡ (\shift n. n shift (makepair zero junk) getsecond) (\pair. pair (\fst snd. makepair (successor fst) fst))
+
extracttail ≡ (\shift lst. lst shift (makepair empty junk) getsecond) (\hd pair. pair (\fst snd. makepair (makelist hd fst) fst))
The `junk` is what you get back if you evaluate:
@@ 73,7 +107,7 @@ For these exercises, assume that `LIST` is the result of evaluating:
 What would be the result of evaluating (see [[Assignment 2 hint 1]] for a hint):
+
 What would be the result of evaluating (see [[hints/Assignment 2 hint]] for a hint):
LIST makelist empty
@@ 87,7 +121,7 @@ For these exercises, assume that `LIST` is the result of evaluating:
should evaluate to a list containing just those of `a`, `b`, `c`, `d`, and `e` such that `f` applied to them evaluates to `true`.

 How would you implement map using the either the version 1 or the version 2 implementation of lists?
+
 What goes wrong when we try to apply these techniques using the version 1 or version 2 implementation of lists?
 Our version 3 implementation of the numbers are usually called "Church numerals". If `m` is a Church numeral, then `m s z` applies the function `s` to the result of applying `s` to ... to `z`, for a total of *m* applications of `s`, where *m* is the number that `m` represents or encodes.