1 1. How would you define an operation to reverse a list? (Don't peek at the
2 [[lambda_library]]! Try to figure it out on your own.) Choose whichever
3 implementation of list you like. Even then, there are various strategies you
7 2. An advantage of the v3 lists and v3 (aka "Church") numerals is that they
8 have a recursive capacity built into their skeleton. So for many natural
9 operations on them, you won't need to use a fixed point combinator. Why is
10 that an advantage? Well, if you use a fixed point combinator, then the terms
12 won't be strongly normalizing: whether their reduction stops at a normal form
13 will depend on what evaluation order you use. Our online [[lambda evaluator]]
14 uses normal-order reduction, so it finds a normal form if there's one to be
15 had. But if you want to build lambda terms in, say, Scheme, and you wanted to
16 roll your own recursion as we've been doing, rather than relying on Scheme's
17 native `let rec` or `define`, then you can't use the fixed-point combinators
18 `Y` or <code>Θ</code>. Expressions using them will have non-terminating
19 reductions, with Scheme's eager/call-by-value strategy. There are other
20 fixed-point combinators you can use with Scheme (in the [week 3 notes](/week3/#index7h2) they
21 were <code>Y′</code> and <code>Θ′</code>. But even with
22 them, evaluation order still matters: for some (admittedly unusual)
23 evaluation strategies, expressions using them will also be non-terminating.
25 The fixed-point combinators may be the conceptual stars. They are cool and
26 mathematically elegant. But for efficiency and implementation elegance, it's
27 best to know how to do as much as you can without them. (Also, that knowledge
28 could carry over to settings where the fixed point combinators are in
29 principle unavailable.)
31 This is why the v3 lists and numbers are so lovely. However, one disadvantage
32 to them is that it's relatively inefficient to extract a list's tail, or get a
33 number's predecessor. To get the tail of the list `[a;b;c;d;e]`, one will
34 basically be performing some operation that builds up the tail afresh: at
35 different stages, one will have built up `[e]`, then `[d;e]`, then `[c;d;e]`, and
36 finally `[b;c;d;e]`. With short lists, this is no problem, but with longer lists
37 it takes longer and longer. And it may waste more of your computer's memory
38 than you'd like. Similarly for obtaining a number's predecessor.
40 The v1 lists and numbers on the other hand, had the tail and the predecessor
41 right there as an element, easy for the taking. The problem was just that the
42 v1 lists and numbers didn't have recursive capacity built into them, in the
43 way the v3 implementations do.
45 A clever approach would marry these two strategies.
47 Version 3 makes the list `[a;b;c;d;e]` look like this:
49 \f z. f a (f b (f c (f d (f e z))))
53 \f z. f a <the result of folding f and z over the tail>
55 Instead we could make it look like this:
57 \f z. f a <the tail itself> <the result of folding f and z over the tail>
59 That is, now `f` is a function expecting *three* arguments: the head of the
60 current list, the tail of the current list, and the result of continuing to
61 fold `f` over the tail, with a given base value `z`.
63 Call this a **version 4** list. The empty list can be the same as in v3:
65 <pre><code>empty ≡ \f z. z</code></pre>
67 The list constructor would be:
69 <pre><code>make_list ≡ \h t. \f z. f h t (t f z)</code></pre>
71 It differs from the version 3 `make_list` only in adding the extra argument
72 `t` to the new, outer application of `f`.
74 Similarly, 5 as a v3 or Church numeral looks like this:
76 \s z. s (s (s (s (s z))))
80 \s z. s <the result of applying s to z (pred 5)-many times>
82 Instead we could make it look like this:
84 \s z. s <pred 5> <the result of applying s to z (pred 5)-many times>
86 That is, now `s` is a function expecting *two* arguments: the predecessor of the
87 current number, and the result of continuing to apply `s` to the base value `z`
88 predecessor-many times.
90 Jim had the pleasure of "inventing" these implementations himself. However,
91 unsurprisingly, he wasn't the first to do so. See for example [Oleg's report
92 on P-numerals](http://okmij.org/ftp/Computation/lambda-calc.html#p-numerals).
98 You're now already in a position to implement sets: that is, collections with
99 no intrinsic order where elements can occur at most once. Like lists, we'll
100 understand the basic set structures to be *type-homogenous*. So you might have
101 a set of integers, or you might have a set of pairs of integers, but you
102 wouldn't have a set that mixed both types of elements. Something *like* the
103 last option is also achievable, but it's more difficult, and we won't pursue it
104 now. In fact, we won't talk about sets of pairs, either. We'll just talk about
105 sets of integers. The same techniques we discuss here could also be applied to
106 sets of pairs of integers, or sets of triples of booleans, or sets of pairs
107 whose first elements are booleans, and whose second elements are triples of
110 (You're also now in a position to implement *multi*sets: that is, collections
111 with no intrinsic order where elements can occur multiple times: the multiset
112 {a,a} is distinct from the multiset {a}. But we'll leave these as an exercise.)
114 The easiest way to implement sets of integers would just be to use lists. When
115 you "add" a member to a set, you'd get back a list that was either identical to
116 the original list, if the added member already was present in it, or consisted
117 of a new list with the added member prepended to the old list. That is:
119 let empty_set = empty in
120 ; see the library for definition of any
121 let make_set = \new_member old_set. any (eq new_member) old_set
122 ; if any element in old_set was eq new_member
125 make_list new_member old_set
127 Think about how you'd implement operations like `set_union`,
128 `set_intersection`, and `set_difference` with this implementation of sets.
130 The implementation just described works, and it's the simplest to code.
131 However, it's pretty inefficient. If you had a 100-member set, and you wanted
132 to create a set which had all those 100-members and some possibly new element
133 `e`, you might need to check all 100 members to see if they're equal to `e`
134 before concluding they're not, and returning the new list. And comparing for
135 numeric equality is a moderately expensive operation, in the first place.
137 (You might say, well, what's the harm in just prepending `e` to the list even
138 if it already occurs later in the list. The answer is, if you don't keep track
139 of things like this, it will likely mess up your implementations of
140 `set_difference` and so on. You'll have to do the book-keeping for duplicates
141 at some point in your code. It goes much more smoothly if you plan this from
144 How might we make the implementation more efficient? Well, the *semantics* of
145 sets says that they have no intrinsic order. That means, there's no difference
146 between the set {a,b} and the set {b,a}; whereas there is a difference between
147 the *list* `[a;b]` and the list `[b;a]`. But this semantic point can be respected
148 even if we *implement* sets with something ordered, like list---as we're
149 already doing. And we might *exploit* the intrinsic order of lists to make our
150 implementation of sets more efficient.
152 What we could do is arrange it so that a list that implements a set always
153 keeps in elements in some specified order. To do this, there'd have *to be*
154 some way to order its elements. Since we're talking now about sets of numbers,
155 that's easy. (If we were talking about sets of pairs of numbers, we'd use
156 "lexicographic" ordering, where `(a,b) < (c,d)` iff `a < c or (a == c and b <
159 So, if we were searching the list that implements some set to see if the number
160 5 belonged to it, once we get to elements in the list that are larger than 5,
161 we can stop. If we haven't found 5 already, we know it's not in the rest of the
164 This is an improvement, but it's still a "linear" search through the list.
165 There are even more efficient methods, which employ "binary" searching. They'd
166 represent the set in such a way that you could quickly determine whether some
167 element fell in one half, call it the left half, of the structure that
168 implements the set, if it belonged to the set at all. Or that it fell in the
169 right half, it it belonged to the set at all. And then the same sort of
170 determination could be made for whichever half you were directed to. And then
171 for whichever quarter you were directed to next. And so on. Until you either
172 found the element or exhausted the structure and could then conclude that the
173 element in question was not part of the set. These sorts of structures are done
174 using **binary trees** (see below).
177 4. **Aborting a search through a list**
179 We said that the sorted-list implementation of a set was more efficient than
180 the unsorted-list implementation, because as you were searching through the
181 list, you could come to a point where you knew the element wasn't going to be
182 found. So you wouldn't have to continue the search.
184 If your implementation of lists was, say v1 lists plus the Y-combinator, then
185 this is exactly right. When you get to a point where you know the answer, you
186 can just deliver that answer, and not branch into any further recursion. If
187 you've got the right evaluation strategy in place, everything will work out
190 But what if you're using v3 lists? What options would you have then for
193 Well, suppose we're searching through the list `[5;4;3;2;1]` to see if it
194 contains the number `3`. The expression which represents this search would have
195 something like the following form:
197 ..................<eq? 1 3> ~~>
198 .................. false ~~>
199 .............<eq? 2 3> ~~>
200 ............. false ~~>
201 .........<eq? 3 3> ~~>
205 Of course, whether those reductions actually followed in that order would
206 depend on what reduction strategy was in place. But the result of folding the
207 search function over the part of the list whose head is `3` and whose tail is `[2;
208 1]` will *semantically* depend on the result of applying that function to the
209 more rightmost pieces of the list, too, regardless of what order the reduction
210 is computed by. Conceptually, it will be easiest if we think of the reduction
211 happening in the order displayed above.
213 Well, once we've found a match between our sought number `3` and some member of
214 the list, we'd like to avoid any further unnecessary computations and just
215 deliver the answer `true` as "quickly" or directly as possible to the larger
216 computation in which the search was embedded.
218 With a Y-combinator based search, as we said, we could do this by just not
219 following a recursion branch.
221 But with the v3 lists, the fold is "pre-programmed" to continue over the whole
222 list. There is no way for us to bail out of applying the search function to the
223 parts of the list that have head `4` and head `5`, too.
225 We *can* avoid *some* unneccessary computation. The search function can detect
226 that the result we've accumulated so far during the fold is now true, so we
227 don't need to bother comparing `4` or `5` to `3` for equality. That will simplify the
228 computation to some degree, since as we said, numerical comparison in the
229 system we're working in is moderately expensive.
231 However, we're still going to have to traverse the remainder of the list. That
232 `true` result will have to be passed along all the way to the leftmost head of
233 the list. Only then can we deliver it to the larger computation in which the
236 It would be better if there were some way to "abort" the list traversal. If,
237 having found the element we're looking for (or having determined that the
238 element isn't going to be found), we could just immediately stop traversing the
239 list with our answer. Continuations will turn out to let us do that.
241 We won't try yet to fully exploit the terrible power of continuations. But
242 there's a way that we can gain their benefits here locally, without yet having
243 a fully general machinery or understanding of what's going on.
245 The key is to recall how our implementations of booleans and pairs worked.
246 Remember that with pairs, we supply the pair "handler" to the pair as *an
247 argument*, rather than the other way around:
255 to get the first element of the pair. Of course you can lift that if you want:
257 extract_1st === \pair. pair (\x y. x)
259 but at a lower level, the pair is still accepting its handler as an argument,
260 rather than the handler taking the pair as an argument. (The handler gets *the
261 pair's elements*, not the pair itself, as arguments.)
263 The v2 implementation of lists followed a similar strategy:
265 v2list (\h t. do_something_with_h_and_t) result_if_empty
267 If the v2list here is not empty, then this will reduce to the result of
268 supplying the list's head and tail to the handler `(\h t.
269 do_something_with_h_and_t)`.
271 Now, what we've been imagining ourselves doing with the search through the v3
272 list is something like this:
275 larger_computation (search_through_the_list_for_3) other_arguments
277 That is, the result of our search is supplied as an argument (perhaps together
278 with other arguments) to the "larger computation". Without knowing the
279 evaluation order/reduction strategy, we can't say whether the search is
280 evaluated before or after it's substituted into the larger computation. But
281 semantically, the search is the argument and the larger computation is the
282 function to which it's supplied.
284 What if, instead, we did the same kind of thing we did with pairs and v2
285 lists? That is, what if we made the larger computation a "handler" that we
286 passed as an argument to the search?
288 the_search (\search_result. larger_computation search_result other_arguments)
290 What's the advantage of that, you say. Other than to show off how cleverly
293 Well, think about it. Think about the difficulty we were having aborting the
294 search. Does this switch-around offer us anything useful?
298 What if the way we implemented the search procedure looked something like this?
300 At a given stage in the search, we wouldn't just apply some function f to the
301 head at this stage and the result accumulated so far, from folding the same
302 function (and a base value) to the tail at this stage. And then pass the result
303 of doing so leftward along the rest of the list.
305 We'd also give that function a "handler" that expected the result of the
306 current stage as an argument, and evaluated to passing that result leftwards
307 along the rest of the list.
309 Why would we do that, you say? Just more flamboyant lifting?
311 Well, no, there's a real point here. If we give the function a "handler" that
312 encodes the normal continuation of the fold leftwards through the list. We can
313 give it another "handler" as well. We can also give it the underlined handler:
316 the_search (\search_result. larger_computation search_result other_arguments)
317 ------------------------------------------------------------------
319 This "handler" encodes the search's having finished, and delivering a final
320 answer to whatever else you wanted your program to do with the result of the
321 search. If you like, at any stage in the search you might just give an argument
322 to this handler, instead of giving an argument to the handler that continues
323 the list traversal leftwards. Semantically, this would amount to *aborting* the
324 list traversal! (As we've said before, whether the rest of the list traversal
325 really gets evaluated will depend on what evaluation order is in place. But
326 semantically we'll have avoided it. Our larger computation won't depend on the
327 rest of the list traversal having been computed.)
329 Do you have the basic idea? Think about how you'd implement it. A good
330 understanding of the v2 lists will give you a helpful model.
332 In broad outline, a single stage of the search would look like before, except
333 now f would receive two extra, "handler" arguments.
335 f 3 <result of folding f and z over [2; 1]> <handler to continue folding leftwards> <handler to abort the traversal>
337 `f`'s job would be to check whether 3 matches the element we're searching for
338 (here also 3), and if it does, just evaluate to the result of passing `true` to
339 the abort handler. If it doesn't, then evaluate to the result of passing
340 `false` to the continue-leftwards handler.
342 In this case, `f` wouldn't need to consult the result of folding `f` and `z` over `[2;
343 1]`, since if we had found the element `3` in more rightward positions of the
344 list, we'd have called the abort handler and this application of `f` to `3` etc
345 would never be needed. However, in other applications the result of folding `f`
346 and `z` over the more rightward parts of the list would be needed. Consider if
347 you were trying to multiply all the elements of the list, and were going to
348 abort (with the result `0`) if you came across any element in the list that was
349 zero. If you didn't abort, you'd need to know what the more rightward elements
350 of the list multiplied to, because that would affect the answer you passed
351 along to the continue-leftwards handler.
353 A **version 5** list would encode this kind of fold operation over the list, in
354 the same way that v3 (and v4) lists encoded the simpler fold operation.
355 Roughly, the list `[5;4;3;2;1]` would look like this:
358 \f z continue_leftwards_handler abort_handler.
359 <fold f and z over [4; 3; 2; 1]>
360 (\result_of_fold_over_4321. f 5 result_of_fold_over_4321 continue_leftwards_handler abort_handler)
364 \f z continue_leftwards_handler abort_handler.
365 (\continue_leftwards_handler abort_handler.
366 <fold f and z over [3; 2; 1]>
367 (\result_of_fold_over_321. f 4 result_of_fold_over_321 continue_leftwards_handler abort_handler)
370 (\result_of_fold_over_4321. f 5 result_of_fold_over_4321 continue_leftwards_handler abort_handler)
375 Remarks: the `larger_computation_handler` should be supplied as both the
376 `continue_leftwards_handler` and the `abort_handler` for the leftmost
377 application, where the head `5` is supplied to `f`. Because the result of this
378 application should be passed to the larger computation, whether it's a "fall
379 off the left end of the list" result or it's a "I'm finished, possibly early"
380 result. The `larger_computation_handler` also then gets passed to the next
381 rightmost stage, where the head `4` is supplied to `f`, as the `abort_handler` to
382 use if that stage decides it has an early answer.
384 Finally, notice that we don't have the result of applying `f` to `4` etc given as
385 an argument to the application of `f` to `5` etc. Instead, we pass
387 (\result_of_fold_over_4321. f 5 result_of_fold_over_4321 one_handler another_handler)
389 *to* the application of `f` to `4` as its "continue" handler. The application of `f`
390 to `4` can decide whether this handler, or the other, "abort" handler, should be
391 given an argument and constitute its result.
394 I'll say once again: we're using temporally-loaded vocabulary throughout this,
395 but really all we're in a position to mean by that are claims about the result
396 of the complex expression semantically depending only on this, not on that. A
397 demon evaluator who custom-picked the evaluation order to make things maximally
398 bad for you could ensure that all the semantically unnecessary computations got
399 evaluated anyway. At this stage, we don't have any way to prevent that. Later,
400 we'll see ways to semantically guarantee one evaluation order rather than
401 another. Though even then the demonic evaluation-order-chooser could make it
402 take unnecessarily long to compute the semantically guaranteed result. Of
403 course, in any real computing environment you'll know you're dealing with a
404 fixed evaluation order and you'll be able to program efficiently around that.
406 In detail, then, here's what our v5 lists will look like:
408 let empty = \f z continue_handler abort_handler. continue_handler z in
409 let make_list = \h t. \f z continue_handler abort_handler.
410 t f z (\sofar. f h sofar continue_handler abort_handler) abort_handler in
411 let isempty = \lst larger_computation. lst
413 (\hd sofar continue_handler abort_handler. abort_handler false)
416 ; here's the continue_handler for the leftmost application of f
418 ; here's the abort_handler
419 larger_computation in
420 let extract_head = \lst larger_computation. lst
422 (\hd sofar continue_handler abort_handler. continue_handler hd)
425 ; here's the continue_handler for the leftmost application of f
427 ; here's the abort_handler
428 larger_computation in
429 let extract_tail = ; left as exercise
430 ;; for real efficiency, it'd be nice to fuse the apparatus developed
431 ;; in these v5 lists with the ideas from the v4 lists, above
432 ;; but that also is left as an exercise
434 These functions are used like this:
436 let my_list = make_list a (make_list b (make_list c empty) in
437 extract_head my_list larger_computation
439 If you just want to see `my_list`'s head, the use `I` as the
440 `larger_computation`.
442 What we've done here does take some work to follow. But it should be within
443 your reach. And once you have followed it, you'll be well on your way to
444 appreciating the full terrible power of continuations.
446 <!-- (Silly [cultural reference](http://www.newgrounds.com/portal/view/33440).) -->
448 Of course, like everything elegant and exciting in this seminar, [Oleg
449 discusses it in much more
450 detail](http://okmij.org/ftp/Streams.html#enumerator-stream).
454 5. Implementing (self-balancing) trees