Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them; it only takes a minute:

I will use C# syntax since I am familiar with it, but it is not really language-specific.

Let's say we want to provide an API to go over a Tree and do something with each Node.

Solution 1: void Visit(Tree tree, Action<Node> action)
It takes a tree, and calls action on each node in the tree.

Solution 2: IEnumerable<Node> ToEnumerable(Tree tree)
It converts tree to a flat lazy sequence so we can go over and call action on each node.

Now, let's see how we can convert one API to another.

It is pretty trivial to provide Visit on top of ToEnumerable:

void Visit(Tree tree, Action<Node> action) {

However, is there a concept/feature in any language that will allow to provide ToEnumerable on top of Visit (as lazy sequence, so list is not created in advance)?

share|improve this question
Not sure what you’re asking for … do you want a class / pattern which would automatically create a lazy IEnumerable for an object hierarchy, given an appropriate visitor method? (If so, I suspect the answer is “no” unless the object also supports a flat enumeration which traverses just the “children” of a given object). – Konrad Rudolph Jul 13 '12 at 13:31
@KonradRudolph yes. I do not necessary want a class/pattern though, more like a language feature or concept. I have a feeling continuations might be related, but I am not familiar enough with them. – Andrey Shchekin Jul 13 '12 at 13:35
I think this is a property of the structure, not of any language feature. The purest (as in most abstract) representation of this I know is Haskell's Foldable (…), see in particular foldMap. – Mauricio Scheffer Jul 13 '12 at 14:17
One thing I found that seems relevant: – Andrey Shchekin Jul 13 '12 at 14:33
Are you looking for implementation techniques? Or just for the concept itself? Implementation techniques will vary wildly in different languages (and even within a language there's many ways to do it). – Mauricio Scheffer Jul 13 '12 at 14:55

3 Answers 3

Not sure if I understand you correctly, but in Python, you can create iterable interface on any object. So you would just add special method __iter__ (which will yield nodes while traversing the tree). The visit procedure is then just about iterating through Tree object and calling action on each node.

share|improve this answer
That is on implementing visit on top of __iter__. But I have an object that implements visit, how do can I define __iter__ on it, using visit? – Andrey Shchekin Jul 13 '12 at 13:36
You can specify that visit method accepts any iterable. Passing Tree as this iterable will work, if you specify __iter__ method in the Tree. Sorry if I misunderstood you. – JoshuaBoshi Jul 13 '12 at 13:47
Let's say Tree does not have __iter__. It only have visit. You can't change Tree. You want to make iter that will iterate the Tree, using its visit. How would you do that? – Andrey Shchekin Jul 13 '12 at 13:56

If you are writing the code that will visit each node (as with a tree), it's possible to have an iterator call iterators for each branch, and perform a yield return on leaf nodes. This approach will work, and is very simple, but has the serious disadvantage that it's very easy to end up with code that will be very readable but execute very slowly. Some other questions and answers on this site will offer insight as to how to traverse trees efficiently within an iterator.

If the "tree" was just an example, and what you really have is a class which exposes a routine to call some delegate upon each node (similar to List.ForEach()), but does not expose an IEnumerable, you may be able to use the former to produce a List, which you could then iterate. Use something like var myList = new List<someThing>(); myCollection.ForEach( (x) => myList.Add(x) ); and then you may be able to enumerate myList.

If even that isn't sufficient, because the objects that were added to the list may not be valid by the time enumeration is complete, it may in rare cases be possible to use multiple threading to accomplish what's needed. For example, if you have two sorted collections whose ForEach method prepares each items for use, does the specified action, and then cleans up each item before proceeding to the next, and if you need to interleave the actions on items from two independent collections, one might be able to iterate the collections on separate threads, and use synchronization primitives so each thread will wait as necessary for the other.

Note that collections which only expose themselves via ForEach method are apt to restrict access during the execution of such a ForEach (if such restriction weren't necessary, they would probably implement IEnumerable). It may be possible for the "item action" called by one ForEach to perform another ForEach on the same collection on the same thread, since the latter ForEach would have to complete before the former one could resume. While one ForEach is running, however, an attempt to call a ForEach on a second thread would likely either malfunction or wait for the first operation to complete. If the first ForEach was waiting for some action by the second, deadlock would result. Because of this, scenarios where multi-threading will work better than simply building a List are rare. Nonetheless, there are a few cases where it may be helpful (e.g. the above-mentioned "zipper" operation on independent collections).

share|improve this answer
Thanks for taking time to answer. I think the threading example is the nearest to what I am asking about, but it is a specific implementation/approach to a more generic pattern, which in itself does not require threads, and only requires ability to save state/restore state. Now I think that is what called continuation, but I'll have to research it a bit more before finalizing my understanding. Thanks again. – Andrey Shchekin Jul 14 '12 at 2:20
@AndreyShchekin: Some objects allow a state to be saved and then restored after any arbitrary combination of save/restore operations; other objects enforce a LIFO sequence, such that if the state is saved to X and then later saved to Y, restoring state X will invalidate Y (if it hasn't already been invalidated via other means). Continuations are a means by which state can be held and acted upon in arbitrary sequence. Such mechanisms can be more versatile than ones which enforce strict stacking protocol, but can also be more complicated from standpoints of both implementation and semantics. – supercat Jul 16 '12 at 14:48
@AndreyShchekin: Note that being able to save/restore state is somewhat different from being able to hold and act upon state. The former can be used in cooperative multitasking between two tasks, but any time operation switches between tasks, the task being suspended must save its state and the task being awakened must restore its state. By contrast, if each stack can act upon its own private state, the two tasks can run simultaneously without interference. – supercat Jul 16 '12 at 14:54

I think now I understand the idea. The concept that I need here is called first-class continuations or, specifically, call/cc. The confusing thing about it for me is that C# already provides a limited implementation of this concept in yield return, but it is not applicable to my scenario.

So if C# provided full implementation, the solution would look like:

IEnumerable<Node> ToEnumerable(Tree tree) {
    tree.Visit(node => magic yield return node);

where magic yield return instead of returning sequence from node => ... lambda returns next element from ToEnumerable.

However, this answer is still not complete as I do not see the exact correlation between yield return and call/cc. I will update the answer when I understand this.

share|improve this answer
If you're interested in doing catamorphisms (i.e. folds) with continuations I recommend this series of blog posts: – Mauricio Scheffer Jul 14 '12 at 15:17

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.