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Is there a nice way to split a collection into 'n' parts with LINQ ? Not necessarily even of course

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1  
Retagged: The question has nothing to do with asp.net. Please tag your questions appropriately. –  Andreas Huber Jan 13 '09 at 7:37
    
How exactly do you want them split, if not even (allowing for the end, of course)? –  Marc Gravell Jan 13 '09 at 7:53
1  
who linked to this question? john was it you? :-) suddenly all these answers :-) –  Simon_Weaver Mar 17 '09 at 21:19
    

14 Answers 14

up vote 73 down vote accepted

A pure linq and the simplest solution is as under.

static class LinqExtensions
{
    public static IEnumerable<IEnumerable<T>> Split<T>(this IEnumerable<T> list, int parts)
    {
        int i = 0;
        var splits = from item in list
                     group item by i++ % parts into part
                     select part.AsEnumerable();
        return splits;
    }
}
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2  
You can do: select part.AsEnumerable() instead of select (IEnumerable<T>)part. It feels more elegant. –  tuinstoel Feb 11 '09 at 10:30
    
Thanks for the suggestion tuinstoel. It sure looks better now. –  Hasan Khan Feb 12 '09 at 4:36
    
Doing all those modulus operations can get a bit expensive on long lists. –  Jonathan Allen Mar 17 '09 at 18:11
7  
It would be better to use the Select overload that includes the index. –  Marc Gravell Aug 17 '09 at 21:21
1  
I've added a response that uses the select overload and method chaining syntax –  manu08 Mar 14 '11 at 20:21

EDIT: Okay, it looks like I misread the question. I read it as "pieces of length n" rather than "n pieces". Doh! Considering deleting answer...

(Original answer)

I don't believe there's a built-in way of partitioning, although I intend to write one in my set of additions to LINQ to Objects. Marc Gravell has an implementation here although I would probably modify it to return a read-only view:

public static IEnumerable<IEnumerable<T>> Partition<T>
    (this IEnumerable<T> source, int size)
{
    T[] array = null;
    int count = 0;
    foreach (T item in source)
    {
        if (array == null)
        {
            array = new T[size];
        }
        array[count] = item;
        count++;
        if (count == size)
        {
            yield return new ReadOnlyCollection<T>(array);
            array = null;
            count = 0;
        }
    }
    if (array != null)
    {             
        Array.Resize(ref array, count);
        yield return new ReadOnlyCollection<T>(array);
    }
}
share|improve this answer
    
Darn - beat me to it ;-p –  Marc Gravell Jan 13 '09 at 7:52
2  
You really don't like those "array[count++]", eh ;-p –  Marc Gravell Jan 13 '09 at 7:54
    
Ironically I might well have used it before yesterday. But having written that answer it would have been hypocritical - and looking at both versions I think this is slightly easier to read at a glance. At first I used a list instead - Add is even more readable :) –  Jon Skeet Jan 13 '09 at 8:03
    
Well, I just added a slightly different answer (to address "n pieces" rather than "pieces of length n"), and mixed in parts of your version ;-p –  Marc Gravell Jan 13 '09 at 8:09
8  
Thank you for not deleting even though it is not an answer for the OP, I wanted the exact same thing - pieces of length n :). –  Gishu Dec 6 '12 at 4:57

Ok, I'll throw my hat in the ring. The advantages of my algorithm:

  1. No expensive multiplication, division, or modulus operators
  2. All operations are O(1) (see note below)
  3. Works for IEnumerable<> source (no Count property needed)
  4. Simple

The code:

public static IEnumerable<IEnumerable<T>>
  Section<T>(this IEnumerable<T> source, int length)
{
  if (length <= 0)
    throw new ArgumentOutOfRangeException("length");

  var section = new List<T>(length);

  foreach (var item in source)
  {
    section.Add(item);

    if (section.Count == length)
    {
      yield return section.AsReadOnly();
      section = new List<T>(length);
    }
  }

  if (section.Count > 0)
    yield return section.AsReadOnly();
}

As pointed out in the comments below, this approach doesn't actually address the original question which asked for a fixed number of sections of approximately equal length. That said, you can still use my approach to solve the original question by calling it this way:

myEnum.Section(myEnum.Count() / number_of_sections + 1)

When used in this manner, the approach is no longer O(1) as the Count() operation is O(N).

share|improve this answer
    
Brilliant - best solution here! A few optimizations: * Clear the linked list instead of creating a new one for each section. A reference to the linked list is never returned to the caller, so it's completely safe. * Don't create the linked list until you reach the first item - that way there's no allocation if the source is empty –  ShadowChaser May 6 '11 at 17:24
3  
@ShadowChaser According to MSDN clearing the LinkedList is O(N) complexity so it would ruin my goal of O(1). Of course, you could argue that the foreach is O(N) to begin with... :) –  Mike May 9 '11 at 15:31
3  
your answer is right, but the question is wrong for it. Your answer gives unknown number of chunks with fixed size for each chunk. But OP wants a Split functionality where it gives fixed number of chunks with any size per chunk(hopefully of equal or close to equal sizes). Perhaps more suited here stackoverflow.com/questions/3773403/… –  nawfal Dec 6 '12 at 14:35
    
@nawfal - I agree. I approached it this way because it doesn't require knowing the enumerable's length ahead of time, which is more efficient for some applications. If you want a fixed number of chunks then you can call myEnum.Section(myEnum.Count() / number_of_chunks + 1). I will update my answer to reflect this. –  Mike Dec 6 '12 at 20:01
1  
@nawfal - Thank you for your detailed analysis, it helps keep me on my toes. Linked lists in general are known for efficient end-inserts, which is why I selected it here. However I just benchmarked it and indeed the List<> is much faster. I suspect this is some sort of .NET implementation detail, perhaps deserving of a separate StackOverflow question. I have modified my answer to use List<> as per your suggestion. Preallocating the list capacity guarantees that end-insertion is still O(1) and meets my original design goal. I also switched to the built-in .AsReadOnly() in .NET 4.5. –  Mike Dec 10 '12 at 15:58
static class LinqExtensions
{
    public static IEnumerable<IEnumerable<T>> Split<T>(this IEnumerable<T> list, int parts)
    {
            return list.Select((item, index) => new {index, item})
                       .GroupBy(x => x.index % parts)
                       .Select(x => x.Select(y => y.item));
    }
}
share|improve this answer
4  
I have an irrational dislike of SQL-style Linq, so this is my favorite answer. –  piedar Jan 2 at 19:53

I have been using the Partition function I posted earlier quite often. The only bad thing about it was that is wasn't completely streaming. This is not a problem if you work with few elements in your sequence. I needed a new solution when i started working with 100.000+ elements in my sequence.

The following solution is a lot more complex (and more code!), but it is very efficient.

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.Collections;

namespace LuvDaSun.Linq
{
    public static class EnumerableExtensions
    {
        public static IEnumerable<IEnumerable<T>> Partition<T>(this IEnumerable<T> enumerable, int partitionSize)
        {
            /*
            return enumerable
                .Select((item, index) => new { Item = item, Index = index, })
                .GroupBy(item => item.Index / partitionSize)
                .Select(group => group.Select(item => item.Item)                )
                ;
            */

            return new PartitioningEnumerable<T>(enumerable, partitionSize);
        }

    }


    class PartitioningEnumerable<T> : IEnumerable<IEnumerable<T>>
    {
        IEnumerable<T> _enumerable;
        int _partitionSize;
        public PartitioningEnumerable(IEnumerable<T> enumerable, int partitionSize)
        {
            _enumerable = enumerable;
            _partitionSize = partitionSize;
        }

        public IEnumerator<IEnumerable<T>> GetEnumerator()
        {
            return new PartitioningEnumerator<T>(_enumerable.GetEnumerator(), _partitionSize);
        }

        IEnumerator IEnumerable.GetEnumerator()
        {
            return GetEnumerator();
        }
    }


    class PartitioningEnumerator<T> : IEnumerator<IEnumerable<T>>
    {
        IEnumerator<T> _enumerator;
        int _partitionSize;
        public PartitioningEnumerator(IEnumerator<T> enumerator, int partitionSize)
        {
            _enumerator = enumerator;
            _partitionSize = partitionSize;
        }

        public void Dispose()
        {
            _enumerator.Dispose();
        }

        IEnumerable<T> _current;
        public IEnumerable<T> Current
        {
            get { return _current; }
        }
        object IEnumerator.Current
        {
            get { return _current; }
        }

        public void Reset()
        {
            _current = null;
            _enumerator.Reset();
        }

        public bool MoveNext()
        {
            bool result;

            if (_enumerator.MoveNext())
            {
                _current = new PartitionEnumerable<T>(_enumerator, _partitionSize);
                result = true;
            }
            else
            {
                _current = null;
                result = false;
            }

            return result;
        }

    }



    class PartitionEnumerable<T> : IEnumerable<T>
    {
        IEnumerator<T> _enumerator;
        int _partitionSize;
        public PartitionEnumerable(IEnumerator<T> enumerator, int partitionSize)
        {
            _enumerator = enumerator;
            _partitionSize = partitionSize;
        }

        public IEnumerator<T> GetEnumerator()
        {
            return new PartitionEnumerator<T>(_enumerator, _partitionSize);
        }

        IEnumerator IEnumerable.GetEnumerator()
        {
            return GetEnumerator();
        }
    }


    class PartitionEnumerator<T> : IEnumerator<T>
    {
        IEnumerator<T> _enumerator;
        int _partitionSize;
        int _count;
        public PartitionEnumerator(IEnumerator<T> enumerator, int partitionSize)
        {
            _enumerator = enumerator;
            _partitionSize = partitionSize;
        }

        public void Dispose()
        {
        }

        public T Current
        {
            get { return _enumerator.Current; }
        }
        object IEnumerator.Current
        {
            get { return _enumerator.Current; }
        }
        public void Reset()
        {
            if (_count > 0) throw new InvalidOperationException();
        }

        public bool MoveNext()
        {
            bool result;

            if (_count < _partitionSize)
            {
                if (_count > 0)
                {
                    result = _enumerator.MoveNext();
                }
                else
                {
                    result = true;
                }
                _count++;
            }
            else
            {
                result = false;
            }

            return result;
        }

    }
}

Enjoy!

share|improve this answer
    
very cool. thanks. –  Simon_Weaver Feb 18 '10 at 0:22
    
This version breaks the contract of IEnumerator. It's not valid to throw InvalidOperationException when Reset is called - I believe many of the LINQ extension methods rely on this behavior. –  ShadowChaser May 6 '11 at 17:05
    
@ShadowChaser I think Reset() should throw a NotSupportedException and everything would be fine. From the MSDN documentation: "The Reset method is provided for COM interoperability. It does not necessarily need to be implemented; instead, the implementer can simply throw a NotSupportedException." –  toong May 17 '13 at 12:25
    
@toong Wow, you're right. Not sure how I missed that after all this time. –  ShadowChaser May 27 '13 at 15:38
    
It is buggy! I don't remember exactly, but (as far as I remember) it performs unwanted step and it can lead to ugly side effects (with datareader for ex.). The best solution is here (Jeppe Stig Nielsen): stackoverflow.com/questions/13709626/… –  SalientBrain Aug 26 at 22:24

This is memory efficient and defers execution as much as possible (per batch) and operates in linear time O(n)

    public static IEnumerable<IEnumerable<T>> InBatchesOf<T>(this IEnumerable<T> items, int batchSize)
    {
        List<T> batch = new List<T>(batchSize);
        foreach (var item in items)
        {
            batch.Add(item);

            if (batch.Count >= batchSize)
            {
                yield return batch;
                batch = new List<T>();
            }
        }

        if (batch.Count != 0)
        {
            //can't be batch size or would've yielded above
            batch.TrimExcess();
            yield return batch;
        }
    }
share|improve this answer

I use this:

public static IEnumerable<IEnumerable<T>> Partition<T>(this IEnumerable<T> instance, int partitionSize)
{
    return instance
        .Select((value, index) => new { Index = index, Value = value })
        .GroupBy(i => i.Index / partitionSize)
        .Select(i => i.Select(i2 => i2.Value));
}
share|improve this answer
    
-1 your answer is wrong. Divide operator doesn't ensure the correct partition size –  Hasan Khan Nov 25 '11 at 7:33
    
Please explain why. I have been using this function without any trouble! –  Elmer Dec 2 '11 at 2:58
    
read the question again and see if you get n (almost) equal length parts with your function –  Hasan Khan Dec 2 '11 at 8:13
    
@Elmer your answer is right, but the question is wrong for it. Your answer gives unknown number of chunks with fixed size for each chunk (exactly as Partition, the name you have given for it). But OP wants a Split functionality where it gives fixed number of chunks with any size per chunk(hopefully of equal or close to equal sizes). Perhaps more suited here stackoverflow.com/questions/3773403/… –  nawfal Dec 6 '12 at 14:36
    
o i get it now! sorry 'bout that... –  Elmer Dec 10 '12 at 8:11

Interesting thread. To get a streaming version of Split/Partition, one can use enumerators and yield sequences from the enumerator using extension methods. Converting imperative code to functional code using yield is a very powerful technique indeed.

First an enumerator extension that turns a count of elements into a lazy sequence:

public static IEnumerable<T> TakeFromCurrent<T>(this IEnumerator<T> enumerator, int count)
{
    while (count > 0)
    {
        yield return enumerator.Current;
        if (--count > 0 && !enumerator.MoveNext()) yield break;
    }
}

And then an enumerable extension that partitions a sequence:

public static IEnumerable<IEnumerable<T>> Partition<T>(this IEnumerable<T> seq, int partitionSize)
{
    var enumerator = seq.GetEnumerator();

    while (enumerator.MoveNext())
    {
        yield return enumerator.TakeFromCurrent(partitionSize);
    }
}

The end result is a highly efficient, streaming and lazy implementation that relies on very simple code.

Enjoy!

share|improve this answer
    
I initially programmed the same thing, but the pattern breaks when Reset is called on one of the nested IEnumerable<T> instances. –  ShadowChaser May 6 '11 at 17:13
    
Does this still work if you only enumerate the partition and not the inner enumerable? since the inner enumerator is deferred then none of the code for the inner (take from current) will execute until it is enumerated therefore movenext() will only be called by the outer partition function, right? If my assumptions are true then this can potentially yield n partitions with n elements in the original enumerable and the inner enumerables will yield unexpected results –  Brad Nov 16 '11 at 19:11

This is same as the accepted answer, but a much simpler representation:

public static IEnumerable<IEnumerable<T>> Split<T>(this IEnumerable<T> items, 
                                                   int numOfParts)
{
    int i = 0;
    return items.GroupBy(x => i++ % numOfParts);
}

The above method splits an IEnumerable<T> into N number of chunks of equal sizes or close to equal sizes.

public static IEnumerable<IEnumerable<T>> Partition<T>(this IEnumerable<T> items, 
                                                       int partitionSize)
{
    int i = 0;
    return items.GroupBy(x => i++ / partitionSize).ToArray();
}

The above method splits an IEnumerable<T> into chunks of desired fixed size with total number of chunks being unimportant - which is not what the question is about.

The problem with the Split method, besides being slower, is that it scrambles the output in the sense that the grouping will be done on the basis of i'th multiple of N for each position, or in other words you don't get the chunks in the original order.

Almost every answer here either doesn't preserve order, or is about partitioning and not splitting, or is plainly wrong. Try this which is faster, preserves order but a lil' more verbose:

public static IEnumerable<IEnumerable<T>> Split<T>(this ICollection<T> items, 
                                                   int numberOfChunks)
{
    if (numberOfChunks <= 0 || numberOfChunks > items.Count)
        throw new ArgumentOutOfRangeException("numberOfChunks");

    int sizePerPacket = items.Count / numberOfChunks;
    int extra = items.Count % numberOfChunks;

    for (int i = 0; i < numberOfChunks - extra; i++)
        yield return items.Skip(i * sizePerPacket).Take(sizePerPacket);

    int alreadyReturnedCount = (numberOfChunks - extra) * sizePerPacket;
    int toReturnCount = extra == 0 ? 0 : (items.Count - numberOfChunks) / extra + 1;
    for (int i = 0; i < extra; i++)
        yield return items.Skip(alreadyReturnedCount + i * toReturnCount).Take(toReturnCount);
}

The equivalent method for a Partition operation here

share|improve this answer

If order in these parts is not very important you can try this:

int[] array = new int[] { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 };
int n = 3;

var result =
   array.Select((value, index) => new { Value = value, Index = index }).GroupBy(i => i.Index % n, i => i.Value);

// or
var result2 =
   from i in array.Select((value, index) => new { Value = value, Index = index })
   group i.Value by i.Index % n into g
   select g;

However these can't be cast to IEnumerable<IEnumerable<int>> by some reason...

share|improve this answer
    
It can be done. Instead of direct casting just make the function generic and then call it for your int array –  nawfal Dec 7 '12 at 1:19

This is my code, nice and short.

 <Extension()> Public Function Chunk(Of T)(ByVal this As IList(Of T), ByVal size As Integer) As List(Of List(Of T))
     Dim result As New List(Of List(Of T))
     For i = 0 To CInt(Math.Ceiling(this.Count / size)) - 1
         result.Add(New List(Of T)(this.GetRange(i * size, Math.Min(size, this.Count - (i * size)))))
     Next
     Return result
 End Function
share|improve this answer

This is my way, listing items and breaking row by columns

  int repat_count=4;

  arrItems.ForEach((x, i) => {
    if (i % repat_count == 0) 
        row = tbo.NewElement(el_tr, cls_min_height);
    var td = row.NewElement(el_td);
    td.innerHTML = x.Name;
  });
share|improve this answer
int[] items = new int[] { 0,1,2,3,4,5,6,7,8,9, 10 };

int itemIndex = 0;
int groupSize = 2;
int nextGroup = groupSize;

var seqItems = from aItem in items
               group aItem by 
                            (itemIndex++ < nextGroup) 
                            ? 
                            nextGroup / groupSize
                            :
                            (nextGroup += groupSize) / groupSize
                            into itemGroup
               select itemGroup.AsEnumerable();
share|improve this answer

Just came across this thread, and most of the solutions here involve adding items to collections, effectively materialising each page before returning it. This is bad for two reasons - firstly if your pages are large there's a memory overhead to filling the page, secondly there are iterators which invalidate previous records when you advance to the next one (for example if you wrap a DataReader within an enumerator method).

This solution uses two nested enumerator methods to avoid any need to cache items into temporary collections. Since the outer and inner iterators are traversing the same enumerable, they necessarily share the same enumerator, so it's important not to advance the outer one until you're done with processing the current page. That said, if you decide not to iterate all the way through the current page, when you move to the next page this solution will iterate forward to the page boundary automatically.

using System.Collections.Generic;

public static class EnumerableExtensions
{
    /// <summary>
    /// Partitions an enumerable into individual pages of a specified size, still scanning the source enumerable just once
    /// </summary>
    /// <typeparam name="T">The element type</typeparam>
    /// <param name="enumerable">The source enumerable</param>
    /// <param name="pageSize">The number of elements to return in each page</param>
    /// <returns></returns>
    public static IEnumerable<IEnumerable<T>> Partition<T>(this IEnumerable<T> enumerable, int pageSize)
    {
        var enumerator = enumerable.GetEnumerator();

        while (enumerator.MoveNext())
        {
            var indexWithinPage = new IntByRef { Value = 0 };

            yield return SubPartition(enumerator, pageSize, indexWithinPage);

            // Continue iterating through any remaining items in the page, to align with the start of the next page
            for (; indexWithinPage.Value < pageSize; indexWithinPage.Value++)
            {
                if (!enumerator.MoveNext())
                {
                    yield break;
                }
            }
        }
    }

    private static IEnumerable<T> SubPartition<T>(IEnumerator<T> enumerator, int pageSize, IntByRef index)
    {
        for (; index.Value < pageSize; index.Value++)
        {
            yield return enumerator.Current;

            if (!enumerator.MoveNext())
            {
                yield break;
            }
        }
    }

    private class IntByRef
    {
        public int Value { get; set; }
    }
}
share|improve this answer
    
This is not working at all! The best possible is here stackoverflow.com/questions/13709626/…! See comments. –  SalientBrain Aug 26 at 22:09

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