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Probably the hardest part of learning lisp has been to think in the "lisp way" which is elegant and impressive, but not always easy. I know that recursion is used to solve a lot of problems, and I am working through a book that instead uses apply to solve a lot of problems, which I understand is not as lispy, and also not as portable.

An experienced lisper should be able to help with this logic without knowing specifically what describe-path location and edges refer to. Here is an example in a book I am working through:

(defun describe-paths (location edges)
  (apply (function append) (mapcar #'describe-path
               (cdr (assoc location edges)))))

I have successfully rewritten this to avoid apply and use recursion instead. It seems to be working:

(defun describe-paths-recursive (location edges)
  (labels ((processx-edge (edge)
         (if (null edge)
         (append (describe-path (first edge))
             (processx-edge (rest edge))))))
    (processx-edge (cdr (assoc location edges)))))

I would like some more seasoned pairs of eyes on this to advise if there is a more elegant way to translate the apply to recursion, or if I have done something unwise. This code seems decent, but would there been something even more "lispy" ?

share|improve this question
If you want code reviews, there is . Stackoverflow is for actual practical problems. – Rainer Joswig Nov 25 '13 at 8:53
More 'Lispy' would be to avoid stack overflows. – Rainer Joswig Nov 25 '13 at 8:54
@RainerJoswig thanks, though I would consider this practical. Granted, I'm new to lisp and the culture in this lisp area of stackoverflow seems very different than other languages i've worked in on here. This would be a welcome question that receives a lot of answers in an area like C++ – johnbakers Nov 25 '13 at 8:55
The original version is recursive. It calls itself in the call to MAPCAR. – Thomas Bartscher Nov 26 '13 at 9:33
@ThomasBartscher no it does not. look closely, the functions are different. – johnbakers Nov 26 '13 at 10:20
up vote -1 down vote accepted

There's nothing wrong with this question; plenty of questions similar to this are asked in the python category, for example.

But to your question: what you are doing is Good. In fact, it closely resembles, nearly identically, a more general technique Peter Norvig shows in one of his Lisp books, so either you've read that book, or you stumbled upon a good practice on your own. Either way, this is a perfectly acceptable implementation of recursion.

share|improve this answer
it is "Good", but as an executable pseudocode only. :) – Will Ness Nov 25 '13 at 13:55

(apply (function append) (mapcar #'g ...)) is just mapcan (update: with usual caveats about destructive update and quoted lists, see also this):

(defun describe-paths (location edges)
  (mapcan #'describe-path
               (cdr (assoc location edges))))

Recursion is good for thinking, for understanding. But actually using it in your code comes with a price.

Your recursive re-write is tail recursive modulo cons; no Lisp has this optimization AFAIK, even though it was first described in 1974, in Lisp.

So what you wrote is good as an executable specification.

But Common Lisp is a practical language. In particular, it has many ways to encode iteration. Remember, iterative processes are our goal; recursive processes are terrible, efficiency-wise. So when we write a code which is syntactically recursive, we still want it to describe an iterative process (such that runs in constant stack space).

Common Lisp, being a practical language, would have us just write the loop out directly. For one,

(defun describe-paths-loop (location edges &aux (res (list 1)) (p res))
  (dolist (x (cdr (assoc location edges)) 
             (cdr res))                   ; the return form
    (setf (cdr p) (describe-path x))
    (setf p (last p))))

is guaranteed to work in constant stack space.

update: this destructively concatenates lists returned by describe-path so it should take care not to return lists with the same last cons cell on separate invocations, or this could create circular structure. Alternatively, the call to describe-path could be wrapped in a copy-list call. Of course, if describe-path were to return a list which is already cyclic, last here would go into a loop too.

share|improve this answer
I'd be very surprised if it didn't, since it's an iteration construct, and the forms are executed in a tagbody, but I don't see where in the documentation that dolist is guaranteed to work in constant stack space. For instance, this could be an implementation of dolist (I think), but it's still recursive and might not use constant stack space. – Joshua Taylor Nov 25 '13 at 14:23
That possible caveat aside, +1 because this is the only answer that mentions the veritable mapcan! – Joshua Taylor Nov 25 '13 at 14:24
That said, I'd file a bug report if I found an implementation that didn't make it an proper iteration construct. (If it did TCO, it'd probably be OK.) – Joshua Taylor Nov 25 '13 at 14:37
@JoshuaTaylor "Veritable" mapcan? Or "venerable"? :) – Kaz Nov 26 '13 at 17:17
@Kaz hm… both really, I suppose :) – Joshua Taylor Nov 26 '13 at 17:26

I saw several opinions about using apply is a bad style. But actually that would be great if somebody will explain me why apply is considered to be bad.

What do you mean using a word "lispy". Common lisp allows to program in any style you want.

If "lispy" means functional programming style, then the first code is written in more functional programming style. A function is passed to a function mapcar and another function is passed to apply and all the job is done by passing the results of one function to another. In you code you don't pass functions as arguments to other functions. But recursion can be considered as functional programming style sign. And code in the book is shorter than yours.

If you don't like apply because of apply determines the argument count in runtime, you can use reduce in this situation (if I understood the data structures correctly): (Thanks to Joshua Taylor for pointing a huge resource overhead without :from-end t key argument)

(defun describe-paths (location edges)
  (reduce #'append (mapcar #'describe-path
            (rest (assoc location edges))) :from-end t))

Anyway I'm pretty sure that the purpose of the code in the book is the education reason. It's an example of mapcar and apply that shows how lists are treated as data and code in lisp.

p.s. Actually I figured why apply can be bad (stack is used for function calls).

> (apply #'+ (make-list 500000 :initial-element 1))
*** - Lisp stack overflow. RESET

So as Rainer Joswig told it's lispy to avoid stack overflows. Reduce fix the problem.

> (reduce #'+ (make-list 50000000 :initial-element 1))
share|improve this answer
This is also a good method, thanks for mentioning it. Basically the problem with apply is that you will eventually hit the limit for call arguments. Recursion and use of reduce solve that problem. – johnbakers Nov 25 '13 at 12:50
@OpenLearner, recursion solve this problem only if tail call recursion optimization is available(or another similar optimization). Otherwise you are going to overflow your stack. You example doesn't have tail recursion optimization, so you are will overflow the stack with your implementation on big data. – JustAnotherCurious Nov 25 '13 at 13:35
also, apply may have a limit on number of arguments. In some implementations, it can be in low hundreds I think. So for a list with 1000 elements or more, it would fail in such an implementation. – Will Ness Nov 25 '13 at 14:13
Yikes! (reduce 'append ...), if you're not using :from-end t, is very inefficient, as it allocates and discards lots of unnecessary memory. append copies all but its first argument. (append (append (append x '()) y) z) copies x three times, and copies y twice! If you need to (reduce 'append ...), be sure to (reduce 'append ... :from-end), but also consider looking for alternatives (but (reduce 'append ... :from-end t) may be the appropriate solution in some cases). – Joshua Taylor Nov 25 '13 at 14:14
@JoshuaTaylor You are 100% right. I'll edit my answer in case if someone won't read your comment. – JustAnotherCurious Nov 25 '13 at 14:28

The Lisp way is to use functional, imperative or object-oriented programming (with or without mutable state) to solve a problem, or to invent some other programming as you see fit and express it in macros. Looking for recursion while ignoring other approaches is not the Lisp way; it's the way of the wayward Lisp academic.

The most straightforward way to rewrite the function:

(defun describe-paths (location edges)
  (apply (function append) (mapcar #'describe-path
               (cdr (assoc location edges)))))

is to use loop. The proper motivation for eliminting apply is that we expect many paths, which could exceed the limit on the number of arguments to a function.

All you are doing with apply is making a big argument list to the append function. We can append any number of lists into a big list with loop like this:

(defun describe-paths (location edges)
  (loop for path in (cdr (assoc location edges))
        appending (describe-path path))

Presumably, describe-path returns a list, and you want to catenate these together.

The appending clause of loop, which may also be spelled append, gathers appends the value of is argument form into an anonymous list. That list becomes the return value when the loop terminates.

We can use nconcing to improve the performance if we have justification in believing that the lists returned by described-path are freshly allocated on each call.

share|improve this answer
i have heard that loop is not the "lisp way" as many lisp purists stay away from loop since its structure is at great odds to the style of the rest of the language. but it's nice to see it as an example here. – johnbakers Nov 26 '13 at 0:35
can we be sure that loop ... appending is not quadratic in time? (unlike nconcing). – Will Ness Nov 26 '13 at 8:45
@WillNess The loop spec only says, "The append keyword causes its list values to be concatenated into a single list, as if they were arguments to the function append." You can macroexpand the loop for to see what is going on in your implementation. The difference between nconc and append, by the way, isn't time complexity. Naive accumulation with nconc is still quadratic, but reduces memory allocation. Reducing complexity requires maintaining a tail pointer to avoid repeatedly searching the accumulated list for the tail. This is independent of whether the inputs are copied or modified. – Kaz Nov 26 '13 at 16:58
@Kaz right, just if we copy, we can't avoid the quadratic time, and if we don't, then we can, as you point out. Thanks. :) ... or maybe append's implementation isn't trivial, under the hood. – Will Ness Nov 26 '13 at 17:12
@WillNess Copying the inputs doesn't require quadratic time. It is linear time. Note that append itself, when given all the pieces at once as arguments, can work in linear time, and it can use destructive manipulation internally to build up the list. I.e. it's not going to just call reduce over a binary-only version of append. The difference between nconc or append is whether we copy the input lists to a new list structure with the same car fields, or whether we simply rewrite their tail cdr-s. – Kaz Nov 26 '13 at 17:15

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