Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have a sequence of elements. The sequence can only be iterated once and can be "infinite".

What is the best way get the head and the tail of such a sequence?

share|improve this question
4  
What would be the tail of an infinite sequence? –  Jon Mar 9 '11 at 12:24
1  
How do you define the "tail" of an infinite sequence? Does the sequence begin to repeat at some point? –  Ani Mar 9 '11 at 12:24
    
Can you specify why you can iterate only once? –  Davide Piras Mar 9 '11 at 12:24
2  
The tail is an infinite sequence with the remainder of the original sequence. I can not see why that should not be possible? I can only iterate once because the computation generating the sequence is resource heavy. –  asgerhallas Mar 9 '11 at 12:32
1  
Of course you can get the tail of an infinite sequence! The tail of [1,2,3,4,...] is [2,3,4,...]. –  Squirrelsama Mar 2 '12 at 1:07

5 Answers 5

up vote 13 down vote accepted

Decomposing IEnumerable<T> into head & tail isn't particularly good for recursive processing (unlike functional lists) because when you use the tail operation recursively, you'll create a number of indirections. However, you can write something like this:

I'm ignoring things like argument checking and exception handling, but it shows the idea...

Tuple<T, IEnumerable<T>> HeadAndTail<T>(IEnumerable<T> source) {
  // Get first element of the 'source' (assuming it is there)
  var en = source.GetEnumerator();
  en.MoveNext();
  // Return first element and Enumerable that iterates over the rest
  return Tuple.Create(en.Current, EnumerateTail(en));
}

// Turn remaining (unconsumed) elements of enumerator into enumerable
IEnumerable<T> EnumerateTail<T>(IEnumerator en) {
  while(en.MoveNext()) yield return en.Current; 
}

The HeadAndTail method gets the first element and returns it as the first element of a tuple. The second element of a tuple is IEnumerable<T> that's generated from the remaining elements (by iterating over the rest of the enumerator that we already created).

share|improve this answer
    
This is exactly it! Thanks a lot! :) –  asgerhallas Mar 9 '11 at 12:54
1  
The IEnumerator parameter in EnumerateTail, shouldn't that be IEnumerator<T>? –  asgerhallas Mar 9 '11 at 12:55
2  
I would make the tuple a Tuple<T, IEnumerator<T>> - otherwise it looks like you can iterate over the tail several times, but you really can't. –  Jon Skeet Mar 9 '11 at 12:56
1  
@Jon Skeet: I'm a little confused by that suggestion. Wouldn't that result in an awkward syntax where it's being used, where you for example can't use Linq directly on the tail? –  asgerhallas Mar 9 '11 at 13:06
3  
@asgerhallas: Yes, for the 100,000th item you'll ask the 99,999th iterator to move to the next item, which will ask the 99,998th iterator etc. Nasty stack :) –  Jon Skeet Mar 9 '11 at 14:30

probably not the best way to do it but if you use the .ToList() method you can then get the elements in position [0] and [Count-1], if Count > 0.

But you should specify what do you mean by "can be iterated only once"

share|improve this answer
8  
Thanks, but ToList() on an infinite sequence will take a too long :) –  asgerhallas Mar 9 '11 at 12:44

What exactly is wrong with .First() and .Last()? Though yeah, I have to agree with the people who asked "what does the tail of an infinite list mean"... the notion doesn't make sense, IMO.

share|improve this answer
2  
The sequence can only be iterated once, so if you've called First you won't then be able to call Last. –  LukeH Mar 9 '11 at 12:44
2  
The tail of {1, 2, 3, 4, .... } is {2, 3, 4, 5, ...} -- now does it make sense? –  Eric Lippert Mar 9 '11 at 15:20
    
Yep. That was stupid - in retrospect it does make a lot of sense. –  Marcel Popescu Mar 11 '11 at 19:24

While other approaches here suggest using yield return for the tail enumerable, such an approach adds unnecessary nesting overhead. A better approach would be to convert the Enumerator<T> back into something that can be used with foreach:

public struct WrappedEnumerator<T>
{
    T myEnumerator;
    public T GetEnumerator() { return myEnumerator; }
    public WrappedEnumerator(T theEnumerator) { myEnumerator = theEnumerator; }
}
public static class AsForEachHelper
{
    static public WrappedEnumerator<IEnumerator<T>> AsForEach<T>(this IEnumerator<T> theEnumerator) {return new WrappedEnumerator<IEnumerator<T>>(theEnumerator);}

    static public WrappedEnumerator<System.Collections.IEnumerator> AsForEach(this System.Collections.IEnumerator theEnumerator) 
        { return new WrappedEnumerator<System.Collections.IEnumerator>(theEnumerator); }
}

If one used separate WrappedEnumerator structs for the generic IEnumerable<T> and non-generic IEnumerable, one could have them implement IEnumerable<T> and IEnumerable respectively; they wouldn't really obey the IEnumerable<T> contract, though, which specifies that it should be possible to possible to call GetEnumerator() multiple times, with each call returning an independent enumerator.

Another important caveat is that if one uses AsForEach on an IEnumerator<T>, the resulting WrappedEnumerator should be enumerated exactly once. If it is never enumerated, the underlying IEnumerator<T> will never have its Dispose method called.

Applying the above-supplied methods to the problem at hand, it would be easy to call GetEnumerator() on an IEnumerable<T>, read out the first few items, and then use AsForEach() to convert the remainder so it can be used with a ForEach loop (or perhaps, as noted above, to convert it into an implementation of IEnumerable<T>). It's important to note, however, that calling GetEnumerator() creates an obligation to Dispose the resulting IEnumerator<T>, and the class that performs the head/tail split would have no way to do that if nothing ever calls GetEnumerator() on the tail.

share|improve this answer

Obviously, each call to HeadAndTail should enumerate the sequence again (unless there is some sort of caching used). For example, consider the following:

var a = HeadAndTail(sequence);
Console.WriteLine(HeadAndTail(a.Tail).Tail);
//Element #2; enumerator is at least at #2 now.

var b = HeadAndTail(sequence);
Console.WriteLine(b.Tail);
//Element #1; there is no way to get #1 unless we enumerate the sequence again.

For the same reason, HeadAndTail could not be implemented as separate Head and Tail methods (unless you want even the first call to Tail to enumerate the sequence again even if it was already enumerated by a call to Head).

Additionally, HeadAndTail should not return an instance of IEnumerable (as it could be enumerated multiple times).

This leaves us with the only option: HeadAndTail should return IEnumerator, and, to make things more obvious, it should accept IEnumerator as well (we're just moving an invocation of GetEnumerator from inside the HeadAndTail to the outside, to emphasize it is of one-time use only).

Now that we have worked out the requirements, the implementation is pretty straightforward:

class HeadAndTail<T> {
    public readonly T Head;
    public readonly IEnumerator<T> Tail;

    public HeadAndTail(T head, IEnumerator<T> tail) {
        Head = head;
        Tail = tail;
    }
}

static class IEnumeratorExtensions {
    public static HeadAndTail<T> HeadAndTail<T>(this IEnumerator<T> enumerator) {
        if (!enumerator.MoveNext()) return null;
        return new HeadAndTail<T>(enumerator.Current, enumerator);
    }
}

And now it can be used like this:

Console.WriteLine(sequence.GetEnumerator().HeadAndTail().Tail.HeadAndTail().Head);
//Element #2

Or in recursive functions like this:

TResult FoldR<TSource, TResult>(
    IEnumerator<TSource> sequence,
    TResult seed,
    Func<TSource, TResult, TResult> f
) {
    var headAndTail = sequence.HeadAndTail();
    if (headAndTail == null) return seed;
    return f(headAndTail.Head, FoldR(headAndTail.Tail, seed, f));
}

int Sum(IEnumerator<int> sequence) {
    return FoldR(sequence, 0, (x, y) => x+y);
}

var array = Enumerable.Range(1, 5);
Console.WriteLine(Sum(array.GetEnumerator())); //1+(2+(3+(4+(5+0)))))
share|improve this answer
    
Your code wouldn't compile, due to syntax errors. The part which should get //Element #2 also fails. –  Chris Nash May 18 '13 at 22:54
    
@ChrisNash There were three minor errors; fixed now. –  penartur May 20 '13 at 14:13

Your Answer

 
discard

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.