Can someone suggest a way to create batches of a certain size in LINQ?
Ideally I want to be able to perform operations in chunks of some configurable amount.
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4This question was asked almost 9 years ago, and now there is a Enumerable.Chunk static method in Linq. Check out the documentation here: learn.microsoft.com/en-us/dotnet/api/…– BlakeHNov 18, 2021 at 13:41
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1there are still a lot of people sitting .NET Core 3 or 5, or even old good .NET Framework– Sergey BerezovskiyNov 23, 2021 at 1:09
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1@SergeyBerezovskiy that's a really good call. I think the question and answers should remain for that purpose - just wanted to provide context on why I originally asked it :D– BlakeHNov 29, 2021 at 19:26
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21 Answers
You don't need to write any code. Use MoreLINQ Batch method, which batches the source sequence into sized buckets (MoreLINQ is available as a NuGet package you can install):
int size = 10;
var batches = sequence.Batch(size);
Which is implemented as:
public static IEnumerable<IEnumerable<TSource>> Batch<TSource>(
this IEnumerable<TSource> source, int size)
{
TSource[] bucket = null;
var count = 0;
foreach (var item in source)
{
if (bucket == null)
bucket = new TSource[size];
bucket[count++] = item;
if (count != size)
continue;
yield return bucket;
bucket = null;
count = 0;
}
if (bucket != null && count > 0)
yield return bucket.Take(count).ToArray();
}
answered Dec 5, 2012 at 20:29
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44 bytes per item performs terribly? Do you have some tests which show what terribly means? If you are loading millions of items into memory, then I wouldn't do it. Use server-side paging Jul 11, 2013 at 19:26
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5I don't mean to offend you, but there are simpler solutions that do not accumulate at all. Furthermore this will allocate space even for non-existent elements:
Batch(new int[] { 1, 2 }, 1000000)Jul 12, 2013 at 18:56 -
10@NickWhaley well, agree with you that additional space will be allocated, but in real life you usually have just opposite situation - list of 1000 items which should go in batches of 50 :) Jul 12, 2013 at 19:02
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1Yes the situation should usually be the other way, but in real life, these may be user inputs. Jul 15, 2013 at 13:29
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11This is a perfectly fine solution. In real life you: validate user input, treat batches as entire collections of items (which accumulates the items anyways), and often process batches in parallel (which is not supported by the iterator approach, and will be a nasty surprise unless you know the implementation details). May 19, 2014 at 21:07
An Enumerable.Chunk() extension method was added to .NET 6.0.
Example:
var list = new List<int> { 1, 2, 3, 4, 5, 6, 7 };
var chunks = list.Chunk(3);
// returns { { 1, 2, 3 }, { 4, 5, 6 }, { 7 } }
For those who cannot upgrade, the source is available on GitHub.
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1I knew I saw something about a new Linq method - thanks for posting this!– BlakeHJun 21, 2021 at 12:15
public static class MyExtensions
{
public static IEnumerable<IEnumerable<T>> Batch<T>(this IEnumerable<T> items,
int maxItems)
{
return items.Select((item, inx) => new { item, inx })
.GroupBy(x => x.inx / maxItems)
.Select(g => g.Select(x => x.item));
}
}
and the usage would be:
List<int> list = new List<int>() { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9 };
foreach(var batch in list.Batch(3))
{
Console.WriteLine(String.Join(",",batch));
}
OUTPUT:
0,1,2
3,4,5
6,7,8
9
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26Once
GroupBystarts enumeration, doesn't it have to fully enumerate its source? This loses lazy evaluation of the source and thus, in some cases, all of the benefit of batching!– ErikEOct 27, 2015 at 18:37 -
1
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6As @ErikE mentions, this method fully enumerates its source so although it looks nice, it defeats the purpose of lazy evaluation / pipelining Apr 27, 2016 at 20:08
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4Do this - its totally appropriate when you need to break up an existing block of things into smaller batches of things for performant processing. The alternative is a gross looking for loop where you manually break up the batches.and still go through the entire source. Mar 19, 2020 at 20:32
If you start with sequence defined as an IEnumerable<T>, and you know that it can safely be enumerated multiple times (e.g. because it is an array or a list), you can just use this simple pattern to process the elements in batches:
while (sequence.Any())
{
var batch = sequence.Take(10);
sequence = sequence.Skip(10);
// do whatever you need to do with each batch here
}
answered Dec 21, 2016 at 21:23
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3Nice, simple way for batching w/o much code or need for external library– DevHawkJan 6, 2017 at 19:40
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10@DevHawk: it is. Note, however, that performance will suffer exponentially on large(r) collections.– RobIIIJan 29, 2018 at 10:07
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1@RobIII: i think the performance problem is the yield, which is not part of this sollution– IveApr 15, 2021 at 15:15
This is a fully lazy, low overhead, one-function implementation of Batch that doesn't do any accumulation and instead forwards iteration steps directly to the source IEnumerable, similar to python's itertools.GroupBy.
This design eliminates copying and buffering, which is nice, but has the following consequences:
- Elements must be enumerated in order.
- Elements must not be accessed more than once.
- Elements that aren't consumed in a batch are explicitly discarded when the next batch is requested.
If these conditions are violated, that is, trying to access elements out of order, a second time, or via a saved iterator, .NET will throw an exception such as InvalidOperationException: Enumeration already finished.. Note that the design and type, IEnumerable<IEnumerable<T>>, naturally implies these conditions; make up your own mind whether that counts as "exception unsafe" or "misuse".
You can test a complete sample at .NET Fiddle.
public static IEnumerable<IEnumerable<T>> Batch<T>(this IEnumerable<T> source, int size)
{
if (source == null)
throw new ArgumentNullException("source");
if (size <= 0)
throw new ArgumentOutOfRangeException("size", "Must be greater than zero.");
using (var enumerator = source.GetEnumerator())
while (enumerator.MoveNext())
{
int i = 0;
// Batch is a local iterator function closing over `i` and
// `enumerator` that executes the inner batch enumeration
IEnumerable<T> Batch()
{
do yield return enumerator.Current;
while (++i < size && enumerator.MoveNext());
}
yield return Batch();
// discard skipped items
while (++i < size && enumerator.MoveNext());
}
}
// Buffer() explicitly buffers the contents of intermediate IEnumerables, lifting the conditions of enumerating in order etc.
// but loses the memory and overhead benefits of not copying/buffering.
public static IEnumerable<IReadOnlyList<T>> Buffer<T>(this IEnumerable<IEnumerable<T>> batched) => batched.Select(e => e.ToList());
This solution is based on (and fixes issues in) Nick Whaley's solution with help from EricRoller.
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2This is the only fully lazy implementation here. Consistent with the python itertools.GroupBy implementation. Jan 3, 2018 at 18:25
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1You can eliminate the check for
doneby just always callinge.Count()afteryield return e. You would need to rearrange the loop in BatchInner to not invoke the undefined behaviorsource.Currentifi >= size. This will eliminate the need to allocate a newBatchInnerfor each batch. Jan 3, 2018 at 19:02 -
1You are right, you still need to capture information about the progress of each batch. I did find a bug in your code if you try getting the 2nd item from each batch: bug fiddle. Fixed implementation without a separate class (using C#7) is here: fixed fiddle. Note that I expect the CLR will still create the local function once per loop to capture variable
iso this isn't necessarily more efficient than defining a separate class, but it is a little cleaner I think. Apr 7, 2018 at 1:56 -
1I benchmarked this version using BenchmarkDotNet against System.Reactive.Linq.EnumerableEx.Buffer and your implementation was 3-4 faster, at the risk of safety. Internally, EnumerableEx.Buffer allocates a Queue of List<T> github.com/dotnet/reactive/blob/… Mar 7, 2019 at 22:25
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1If you want a buffered version of this, you can do: public static IEnumerable<IReadOnlyList<T>> BatchBuffered<T>(this IEnumerable<T> source, int size) => Batch(source, size).Select(chunk => (IReadOnlyList<T>)chunk.ToList()); Use of IReadOnlyList<T> is to hint the user the output is cached. You could also keep the IEnumerable<IEnumerable<T>> instead.– gfacheAug 20, 2019 at 15:23
All of the above perform terribly with large batches or low memory space. Had to write my own that will pipeline (notice no item accumulation anywhere):
public static class BatchLinq {
public static IEnumerable<IEnumerable<T>> Batch<T>(this IEnumerable<T> source, int size) {
if (size <= 0)
throw new ArgumentOutOfRangeException("size", "Must be greater than zero.");
using (IEnumerator<T> enumerator = source.GetEnumerator())
while (enumerator.MoveNext())
yield return TakeIEnumerator(enumerator, size);
}
private static IEnumerable<T> TakeIEnumerator<T>(IEnumerator<T> source, int size) {
int i = 0;
do
yield return source.Current;
while (++i < size && source.MoveNext());
}
}
Edit: Known issue with this approach is that each batch must be enumerated and enumerated fully before moving to the next batch. For example this doesn't work:
//Select first item of every 100 items
Batch(list, 100).Select(b => b.First())
answered Jul 11, 2013 at 16:36
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1The routine @L.B posted above doesn't perform item accumulation either. Jul 15, 2013 at 15:47
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3@neontapir Still does. A coin sorting machine that gives you nickels first, then dimes, MUST first inspect every single coin before giving you a dime to be sure there are no more nickels. Jul 23, 2013 at 14:11
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2Ahhh ahha, missed your edit note when I snagged this code. It took some time to understand why iterating over un-enumerated batches actually enumerated the entire original collection (!!!), providing X batches, each having enumerated 1 item (where X is the number of original collection items).– eliFeb 17, 2014 at 10:03
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2@NickWhaley if I do Count() on the IEnumerable<IEnumerable<T>> result by your code, it gives wrong answer, it gives total number of elements, when expected is total number of batches created. This is not the case with MoreLinq Batch code Mar 26, 2017 at 14:28
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1@JohnZabroski - Here's a quick gist: gist.github.com/mmurrell/9225ed7c4d107c2195057f77e07f0f68 Mar 8, 2019 at 19:09
I wonder why nobody has ever posted an old school for-loop solution. Here is one:
List<int> source = Enumerable.Range(1,23).ToList();
int batchsize = 10;
for (int i = 0; i < source.Count; i+= batchsize)
{
var batch = source.Skip(i).Take(batchsize);
}
This simplicity is possible because the Take method:
... enumerates
sourceand yields elements untilcountelements have been yielded orsourcecontains no more elements. Ifcountexceeds the number of elements insource, all elements ofsourceare returned
Disclaimer:
Using Skip and Take inside the loop means that the enumerable will be enumerated multiple times. This is dangerous if the enumerable is deferred. It may result in multiple executions of a database query, or a web request, or a file read. This example is explicitly for the usage of a List which is not deferred, so it is less of a problem. It is still a slow solution since skip will enumerate the collection each time it is called.
This can also be solved using the GetRange method, but it requires an extra calculation to extract a possible rest batch:
for (int i = 0; i < source.Count; i += batchsize)
{
int remaining = source.Count - i;
var batch = remaining > batchsize ? source.GetRange(i, batchsize) : source.GetRange(i, remaining);
}
Here is a third way to handle this, which works with 2 loops. This ensures that the collection is enumerated only 1 time!:
int batchsize = 10;
List<int> batch = new List<int>(batchsize);
for (int i = 0; i < source.Count; i += batchsize)
{
// calculated the remaining items to avoid an OutOfRangeException
batchsize = source.Count - i > batchsize ? batchsize : source.Count - i;
for (int j = i; j < i + batchsize; j++)
{
batch.Add(source[j]);
}
batch.Clear();
}
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2
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8Using
SkipandTakeinside the loop means that the enumerable will be enumerated multiple times. This is dangerous if the enumerable is deferred. It may result in multiple executions of a database query, or a web request, or a file read. In your example you have aListwhich is not deferred, so it is less of a problem. Dec 12, 2019 at 8:23 -
@TheodorZoulias yes I know, this is actually why I posted the second solution today. I posted your comment as a disclaimer, because you formulated it quite well, shall I cite you?– Mong ZhuDec 12, 2019 at 8:44
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I wrote a third solution with 2 loops so that the collection is enumerated only 1 time. the skip.take thing is a very inefficient solution– Mong ZhuDec 12, 2019 at 8:51
Here is an attempted improvement of Nick Whaley's (link) and infogulch's (link) lazy Batch implementations. This one is strict. You either enumerate the batches in the correct order, or you get an exception.
public static IEnumerable<IEnumerable<TSource>> Batch<TSource>(
this IEnumerable<TSource> source, int size)
{
if (size <= 0) throw new ArgumentOutOfRangeException(nameof(size));
using (var enumerator = source.GetEnumerator())
{
int i = 0;
while (enumerator.MoveNext())
{
if (i % size != 0) throw new InvalidOperationException(
"The enumeration is out of order.");
i++;
yield return GetBatch();
}
IEnumerable<TSource> GetBatch()
{
while (true)
{
yield return enumerator.Current;
if (i % size == 0 || !enumerator.MoveNext()) break;
i++;
}
}
}
}
And here is a lazy Batch implementation for sources of type IList<T>. This one imposes no restrictions on the enumeration. The batches can be enumerated partially, in any order, and more than once. The restriction of not modifying the collection during the enumeration is still in place though. This is achieved by making a dummy call to enumerator.MoveNext() before yielding any chunk or element. The downside is that the enumerator is left undisposed, since it is unknown when the enumeration is going to finish.
public static IEnumerable<IEnumerable<TSource>> Batch<TSource>(
this IList<TSource> source, int size)
{
if (size <= 0) throw new ArgumentOutOfRangeException(nameof(size));
var enumerator = source.GetEnumerator();
for (int i = 0; i < source.Count; i += size)
{
enumerator.MoveNext();
yield return GetChunk(i, Math.Min(i + size, source.Count));
}
IEnumerable<TSource> GetChunk(int from, int toExclusive)
{
for (int j = from; j < toExclusive; j++)
{
enumerator.MoveNext();
yield return source[j];
}
}
}
answered Jul 26, 2019 at 16:48
Same approach as MoreLINQ, but using List instead of Array. I haven't done benchmarking, but readability matters more to some people:
public static IEnumerable<IEnumerable<T>> Batch<T>(this IEnumerable<T> source, int size)
{
List<T> batch = new List<T>();
foreach (var item in source)
{
batch.Add(item);
if (batch.Count >= size)
{
yield return batch;
batch.Clear();
}
}
if (batch.Count > 0)
{
yield return batch;
}
}
answered May 4, 2016 at 19:04
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3You should NOT be reusing the batch variable. Your consumers could be completely screwed up by that. Also, pass in the
sizeparameter to yournew Listto optimize its size.– ErikESep 26, 2017 at 0:58 -
1
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also you can preallocate the list size with batch = new List<T>(size); Sep 30, 2022 at 10:53
Here's the cleanest version of Batch that I can come up with:
public static IEnumerable<IEnumerable<T>> Batch<T>(this IEnumerable<T> source, int count)
{
if (source == null) throw new System.ArgumentNullException("source");
if (count <= 0) throw new System.ArgumentOutOfRangeException("count");
using (var enumerator = source.GetEnumerator())
{
IEnumerable<T> BatchInner()
{
int counter = 0;
do
yield return enumerator.Current;
while (++counter < count && enumerator.MoveNext());
}
while (enumerator.MoveNext())
yield return BatchInner().ToArray();
}
}
Using this code:
Console.WriteLine(String.Join(Environment.NewLine,
Enumerable.Range(0, 20).Batch(8).Select(xs => String.Join(",", xs))));
I get:
0,1,2,3,4,5,6,7
8,9,10,11,12,13,14,15
16,17,18,19
It's important to note that on the answers from "" & "" that this code fails:
var e = Enumerable.Range(0, 20).Batch(8).ToArray();
Console.WriteLine(String.Join(Environment.NewLine, e.Select(xs => String.Join(",", xs))));
Console.WriteLine();
Console.WriteLine(String.Join(Environment.NewLine, e.Select(xs => String.Join(",", xs))));
On their answers it gives:
19
19
19
19
19
19
Due to the inner enumerable not being computed as an array.
answered Aug 24, 2021 at 6:42
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1There are more answers with lazy evaluation w/o accumulation. Why is this the cleanest? (Not disagreeing, I like the solution anyway, but an explanation would make it a lot more interesting). Aug 24, 2021 at 6:59
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@GertArnold - Well, I think it's a minimal amount of code. Each of the other solutions using a pure enumerator seem to have extra code that isn't necessary. Aug 24, 2021 at 21:53
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I totally agree! One more thing: you added
ToArray, but it also seems to work without. Are there case that require thisToArraycall? Aug 25, 2021 at 12:16 -
@GertArnold - Without the
.ToArray()the code only runs once forvar e = Enumerable.Range(0, 20).Batch(8).ToArray();. Try iterating over the inner enumerable with that. It effectively captures theenumeratorinBatchInnerso on subsequent executions the enumerator is done. Aug 25, 2021 at 12:26
So with a functional hat on, this appears trivial....but in C#, there are some significant downsides.
you'd probably view this as an unfold of IEnumerable (google it and you'll probably end up in some Haskell docs, but there may be some F# stuff using unfold, if you know F#, squint at the Haskell docs and it will make sense).
Unfold is related to fold ("aggregate") except rather than iterating through the input IEnumerable, it iterates through the output data structures (its a similar relationship between IEnumerable and IObservable, in fact I think IObservable does implement an "unfold" called generate...)
anyway first you need an unfold method, I think this works (unfortunately it will eventually blow the stack for large "lists"...you can write this safely in F# using yield! rather than concat);
static IEnumerable<T> Unfold<T, U>(Func<U, IEnumerable<Tuple<U, T>>> f, U seed)
{
var maybeNewSeedAndElement = f(seed);
return maybeNewSeedAndElement.SelectMany(x => new[] { x.Item2 }.Concat(Unfold(f, x.Item1)));
}
this is a bit obtuse because C# doesn't implement some of the things functional langauges take for granted...but it basically takes a seed and then generates a "Maybe" answer of the next element in the IEnumerable and the next seed (Maybe doesn't exist in C#, so we've used IEnumerable to fake it), and concatenates the rest of the answer (I can't vouch for the "O(n?)" complexity of this).
Once you've done that then;
static IEnumerable<IEnumerable<T>> Batch<T>(IEnumerable<T> xs, int n)
{
return Unfold(ys =>
{
var head = ys.Take(n);
var tail = ys.Skip(n);
return head.Take(1).Select(_ => Tuple.Create(tail, head));
},
xs);
}
it all looks quite clean...you take the "n" elements as the "next" element in the IEnumerable, and the "tail" is the rest of the unprocessed list.
if there is nothing in the head...you're over...you return "Nothing" (but faked as an empty IEnumerable>)...else you return the head element and the tail to process.
you probably can do this using IObservable, there's probably a "Batch" like method already there, and you can probably use that.
If the risk of stack overflows worries (it probably should), then you should implement in F# (and there's probably some F# library (FSharpX?) already with this).
(I have only done some rudimentary tests of this, so there may be the odd bugs in there).
answered Apr 16, 2018 at 10:12
I'm joining this very late but i found something more interesting.
So we can use here Skip and Take for better performance.
public static class MyExtensions
{
public static IEnumerable<IEnumerable<T>> Batch<T>(this IEnumerable<T> items, int maxItems)
{
return items.Select((item, index) => new { item, index })
.GroupBy(x => x.index / maxItems)
.Select(g => g.Select(x => x.item));
}
public static IEnumerable<T> Batch2<T>(this IEnumerable<T> items, int skip, int take)
{
return items.Skip(skip).Take(take);
}
}
Next I checked with 100000 records. The looping only is taking more time in case of Batch
Code Of console application.
static void Main(string[] args)
{
List<string> Ids = GetData("First");
List<string> Ids2 = GetData("tsriF");
Stopwatch FirstWatch = new Stopwatch();
FirstWatch.Start();
foreach (var batch in Ids2.Batch(5000))
{
// Console.WriteLine("Batch Ouput:= " + string.Join(",", batch));
}
FirstWatch.Stop();
Console.WriteLine("Done Processing time taken:= "+ FirstWatch.Elapsed.ToString());
Stopwatch Second = new Stopwatch();
Second.Start();
int Length = Ids2.Count;
int StartIndex = 0;
int BatchSize = 5000;
while (Length > 0)
{
var SecBatch = Ids2.Batch2(StartIndex, BatchSize);
// Console.WriteLine("Second Batch Ouput:= " + string.Join(",", SecBatch));
Length = Length - BatchSize;
StartIndex += BatchSize;
}
Second.Stop();
Console.WriteLine("Done Processing time taken Second:= " + Second.Elapsed.ToString());
Console.ReadKey();
}
static List<string> GetData(string name)
{
List<string> Data = new List<string>();
for (int i = 0; i < 100000; i++)
{
Data.Add(string.Format("{0} {1}", name, i.ToString()));
}
return Data;
}
Time taken Is like this.
First - 00:00:00.0708 , 00:00:00.0660
Second (Take and Skip One) - 00:00:00.0008, 00:00:00.0008
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2
GroupByfully enumerates before it produces a single row. This is not a good way to do batching.– ErikEApr 27, 2016 at 20:43 -
@ErikE That depends on what you are trying to achieve. If the batching is not the issue, and you just need to split the items into smaller chunks for processing it might be just the thing. I'm using this for MSCRM where there might be 100 records which is no problem for LAMBDA to batch.. its the saving that takes seconds..– JensBJan 27, 2017 at 12:02
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2Sure, there are use cases where the full enumeration doesn't matter. But why write a second-class utility method when you can write a superb one?– ErikEJan 27, 2017 at 16:15
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Good alternative but not identical as first returns a list of lists allowing you to loop through. Jan 26, 2018 at 19:08
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change
foreach (var batch in Ids2.Batch(5000))tovar gourpBatch = Ids2.Batch(5000)and check the timed results. or add tolist tovar SecBatch = Ids2.Batch2(StartIndex, BatchSize);i would be interested if your results for timing change. Dec 11, 2019 at 11:17
I wrote a custom IEnumerable implementation that works without linq and guarantees a single enumeration over the data. It also accomplishes all this without requiring backing lists or arrays that cause memory explosions over large data sets.
Here are some basic tests:
[Fact]
public void ShouldPartition()
{
var ints = new List<int> {0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
var data = ints.PartitionByMaxGroupSize(3);
data.Count().Should().Be(4);
data.Skip(0).First().Count().Should().Be(3);
data.Skip(0).First().ToList()[0].Should().Be(0);
data.Skip(0).First().ToList()[1].Should().Be(1);
data.Skip(0).First().ToList()[2].Should().Be(2);
data.Skip(1).First().Count().Should().Be(3);
data.Skip(1).First().ToList()[0].Should().Be(3);
data.Skip(1).First().ToList()[1].Should().Be(4);
data.Skip(1).First().ToList()[2].Should().Be(5);
data.Skip(2).First().Count().Should().Be(3);
data.Skip(2).First().ToList()[0].Should().Be(6);
data.Skip(2).First().ToList()[1].Should().Be(7);
data.Skip(2).First().ToList()[2].Should().Be(8);
data.Skip(3).First().Count().Should().Be(1);
data.Skip(3).First().ToList()[0].Should().Be(9);
}
The Extension Method to partition the data.
/// <summary>
/// A set of extension methods for <see cref="IEnumerable{T}"/>.
/// </summary>
public static class EnumerableExtender
{
/// <summary>
/// Splits an enumerable into chucks, by a maximum group size.
/// </summary>
/// <param name="source">The source to split</param>
/// <param name="maxSize">The maximum number of items per group.</param>
/// <typeparam name="T">The type of item to split</typeparam>
/// <returns>A list of lists of the original items.</returns>
public static IEnumerable<IEnumerable<T>> PartitionByMaxGroupSize<T>(this IEnumerable<T> source, int maxSize)
{
return new SplittingEnumerable<T>(source, maxSize);
}
}
This is the implementing class
using System.Collections;
using System.Collections.Generic;
internal class SplittingEnumerable<T> : IEnumerable<IEnumerable<T>>
{
private readonly IEnumerable<T> backing;
private readonly int maxSize;
private bool hasCurrent;
private T lastItem;
public SplittingEnumerable(IEnumerable<T> backing, int maxSize)
{
this.backing = backing;
this.maxSize = maxSize;
}
public IEnumerator<IEnumerable<T>> GetEnumerator()
{
return new Enumerator(this, this.backing.GetEnumerator());
}
IEnumerator IEnumerable.GetEnumerator()
{
return this.GetEnumerator();
}
private class Enumerator : IEnumerator<IEnumerable<T>>
{
private readonly SplittingEnumerable<T> parent;
private readonly IEnumerator<T> backingEnumerator;
private NextEnumerable current;
public Enumerator(SplittingEnumerable<T> parent, IEnumerator<T> backingEnumerator)
{
this.parent = parent;
this.backingEnumerator = backingEnumerator;
this.parent.hasCurrent = this.backingEnumerator.MoveNext();
if (this.parent.hasCurrent)
{
this.parent.lastItem = this.backingEnumerator.Current;
}
}
public bool MoveNext()
{
if (this.current == null)
{
this.current = new NextEnumerable(this.parent, this.backingEnumerator);
return true;
}
else
{
if (!this.current.IsComplete)
{
using (var enumerator = this.current.GetEnumerator())
{
while (enumerator.MoveNext())
{
}
}
}
}
if (!this.parent.hasCurrent)
{
return false;
}
this.current = new NextEnumerable(this.parent, this.backingEnumerator);
return true;
}
public void Reset()
{
throw new System.NotImplementedException();
}
public IEnumerable<T> Current
{
get { return this.current; }
}
object IEnumerator.Current
{
get { return this.Current; }
}
public void Dispose()
{
}
}
private class NextEnumerable : IEnumerable<T>
{
private readonly SplittingEnumerable<T> splitter;
private readonly IEnumerator<T> backingEnumerator;
private int currentSize;
public NextEnumerable(SplittingEnumerable<T> splitter, IEnumerator<T> backingEnumerator)
{
this.splitter = splitter;
this.backingEnumerator = backingEnumerator;
}
public bool IsComplete { get; private set; }
public IEnumerator<T> GetEnumerator()
{
return new NextEnumerator(this.splitter, this, this.backingEnumerator);
}
IEnumerator IEnumerable.GetEnumerator()
{
return this.GetEnumerator();
}
private class NextEnumerator : IEnumerator<T>
{
private readonly SplittingEnumerable<T> splitter;
private readonly NextEnumerable parent;
private readonly IEnumerator<T> enumerator;
private T currentItem;
public NextEnumerator(SplittingEnumerable<T> splitter, NextEnumerable parent, IEnumerator<T> enumerator)
{
this.splitter = splitter;
this.parent = parent;
this.enumerator = enumerator;
}
public bool MoveNext()
{
this.parent.currentSize += 1;
this.currentItem = this.splitter.lastItem;
var hasCcurent = this.splitter.hasCurrent;
this.parent.IsComplete = this.parent.currentSize > this.splitter.maxSize;
if (this.parent.IsComplete)
{
return false;
}
if (hasCcurent)
{
var result = this.enumerator.MoveNext();
this.splitter.lastItem = this.enumerator.Current;
this.splitter.hasCurrent = result;
}
return hasCcurent;
}
public void Reset()
{
throw new System.NotImplementedException();
}
public T Current
{
get { return this.currentItem; }
}
object IEnumerator.Current
{
get { return this.Current; }
}
public void Dispose()
{
}
}
}
}
Just another one line implementation. It works even with an empty list, in this case you get a zero size batches collection.
var aList = Enumerable.Range(1, 100).ToList(); //a given list
var size = 9; //the wanted batch size
//number of batches are: (aList.Count() + size - 1) / size;
var batches = Enumerable.Range(0, (aList.Count() + size - 1) / size).Select(i => aList.GetRange( i * size, Math.Min(size, aList.Count() - i * size)));
Assert.True(batches.Count() == 12);
Assert.AreEqual(batches.ToList().ElementAt(0), new List<int>() { 1, 2, 3, 4, 5, 6, 7, 8, 9 });
Assert.AreEqual(batches.ToList().ElementAt(1), new List<int>() { 10, 11, 12, 13, 14, 15, 16, 17, 18 });
Assert.AreEqual(batches.ToList().ElementAt(11), new List<int>() { 100 });
Another way is using Rx Buffer operator
//using System.Linq;
//using System.Reactive.Linq;
//using System.Reactive.Threading.Tasks;
var observableBatches = anAnumerable.ToObservable().Buffer(size);
var batches = aList.ToObservable().Buffer(size).ToList().ToTask().GetAwaiter().GetResult();
-
1You should never have to use
GetAwaiter().GetResult(). This is a code smell for synchronous code forcefully calling async code.– gfacheAug 20, 2019 at 15:18
An easy version to use and understand.
public static List<List<T>> chunkList<T>(List<T> listToChunk, int batchSize)
{
List<List<T>> batches = new List<List<T>>();
if (listToChunk.Count == 0) return batches;
bool moreRecords = true;
int fromRecord = 0;
int countRange = 0;
if (listToChunk.Count >= batchSize)
{
countRange = batchSize;
}
else
{
countRange = listToChunk.Count;
}
while (moreRecords)
{
List<T> batch = listToChunk.GetRange(fromRecord, countRange);
batches.Add(batch);
if ((fromRecord + batchSize) >= listToChunk.Count)
{
moreRecords = false;
}
fromRecord = fromRecord + batch.Count;
if ((fromRecord + batchSize) > listToChunk.Count)
{
countRange = listToChunk.Count - fromRecord;
}
else
{
countRange = batchSize;
}
}
return batches;
}
As a new helper method for LINQ in .NET 6 you can chunk any IEnumerable into batches:
int chunkNumber = 1;
foreach (int[] chunk in Enumerable.Range(0, 9).Chunk(3))
{
Console.WriteLine($"Chunk {chunkNumber++}");
foreach (var item in chunk)
{
Console.WriteLine(item);
}
}
answered Aug 24, 2021 at 4:48
-
1Correct and here's a reference: dotnetcoretutorials.com/2021/08/12/ienumerable-chunk-in-net-6 Feb 4, 2022 at 14:06
Here is an implementation that uses Async iteration in C# via IAsyncEnumerable - https://learn.microsoft.com/en-us/dotnet/csharp/whats-new/tutorials/generate-consume-asynchronous-stream
public static class EnumerableExtensions
{
/// <summary>
/// Chunks a sequence into a sub-sequences each containing maxItemsPerChunk, except for the last
/// which will contain any items left over.
///
/// NOTE: this implements a streaming implementation via <seealso cref="IAsyncEnumerable{T}"/>.
/// </summary>
public static async IAsyncEnumerable<IEnumerable<T>> ChunkAsync<T>(this IAsyncEnumerable<T> sequence, int maxItemsPerChunk)
{
if (sequence == null) throw new ArgumentNullException(nameof(sequence));
if (maxItemsPerChunk <= 0)
{
throw new ArgumentOutOfRangeException(nameof(maxItemsPerChunk), $"{nameof(maxItemsPerChunk)} must be greater than 0");
}
var chunk = new List<T>(maxItemsPerChunk);
await foreach (var item in sequence)
{
chunk.Add(item);
if (chunk.Count == maxItemsPerChunk)
{
yield return chunk.ToArray();
chunk.Clear();
}
}
// return the "crumbs" that
// didn't make it into a full chunk
if (chunk.Count > 0)
{
yield return chunk.ToArray();
}
}
/// <summary>
/// Chunks a sequence into a sub-sequences each containing maxItemsPerChunk, except for the last
/// which will contain any items left over.
/// </summary>
public static IEnumerable<IEnumerable<T>> Chunk<T>(this IEnumerable<T> sequence, int maxItemsPerChunk)
{
if (sequence == null) throw new ArgumentNullException(nameof(sequence));
if (maxItemsPerChunk <= 0)
{
throw new ArgumentOutOfRangeException(nameof(maxItemsPerChunk), $"{nameof(maxItemsPerChunk)} must be greater than 0");
}
var chunk = new List<T>(maxItemsPerChunk);
foreach (var item in sequence)
{
chunk.Add(item);
if (chunk.Count == maxItemsPerChunk)
{
yield return chunk.ToArray();
chunk.Clear();
}
}
// return the "crumbs" that
// didn't make it into a full chunk
if (chunk.Count > 0)
{
yield return chunk.ToArray();
}
}
}
answered Oct 20, 2021 at 18:26
I know everybody used complex systems to do this work, and I really don't get it why.
Take and skip will allow all those operations using the common select with Func<TSource,Int32,TResult> transform function.
Like:
public IEnumerable<IEnumerable<T>> Buffer<T>(IEnumerable<T> source, int size)=>
source.Select((item, index) => source.Skip(size * index).Take(size)).TakeWhile(bucket => bucket.Any());
-
4This might be very inefficient, because the given
sourcewill be iterated very often. May 13, 2019 at 13:27 -
2This is not only inefficient, but could also produce incorrect results. There is no guarantee that an enumerable will yield the same elements when enumerated twice. Take this enumerable as an example:
Enumerable.Range(0, 1).SelectMany(_ => Enumerable.Range(0, new Random().Next())). Jul 26, 2019 at 14:49
Another way to perform batching:
public static class Extensions
{
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
yield return func(v0, v1);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
yield return func(v0, v1, v2);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
yield return func(v0, v1, v2, v3);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v6 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5, v6);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v6 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v7 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5, v6, v7);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v6 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v7 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v8 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5, v6, v7, v8);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v6 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v7 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v8 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v9 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v6 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v7 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v8 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v9 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v10 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v6 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v7 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v8 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v9 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v10 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v11 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, T, T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v6 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v7 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v8 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v9 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v10 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v11 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v12 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, T, T, T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v6 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v7 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v8 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v9 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v10 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v11 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v12 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v13 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, v13);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, T, T, T, T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v6 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v7 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v8 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v9 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v10 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v11 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v12 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v13 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v14 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, v13, v14);
}
}
}
public static IEnumerable<TOut> Batch<T, TOut>(this IEnumerable<T> source, Func<T, T, T, T, T, T, T, T, T, T, T, T, T, T, T, T, TOut> func)
{
using (var enumerator = source.GetEnumerator())
{
while (true)
{
bool state;
state = enumerator.MoveNext(); if (!state) break; var v0 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v1 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v2 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v3 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v4 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v5 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v6 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v7 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v8 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v9 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v10 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v11 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v12 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v13 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v14 = enumerator.Current;
state = enumerator.MoveNext(); if (!state) break; var v15 = enumerator.Current;
yield return func(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, v13, v14, v15);
}
}
}
}
Here's an example usage:
using System;
using System.Linq;
namespace TestProgram
{
class Program
{
static void Main(string[] args)
{
foreach (var item in Enumerable.Range(0, 12).ToArray().Batch((R, X1, Y1, X2, Y2) => (R, X1, Y1, X2, Y2)))
{
Console.WriteLine($"{item.R}, {item.X1}, {item.Y1}, {item.X2}, {item.Y2}");
}
}
}
}
static IEnumerable<IEnumerable<T>> TakeBatch<T>(IEnumerable<T> ts,int batchSize)
{
return from @group in ts.Select((x, i) => new { x, i }).ToLookup(xi => xi.i / batchSize)
select @group.Select(xi => xi.x);
}
-
Add some description/ text in your answer. Putting only code may be meaning less most of time. Jul 2, 2015 at 16:52