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 often run into the case where I want to eval a query right where I declare it. This is usually because I need to iterate over it multiple times and it is expensive to compute. For example:

string raw = "...";
var lines = (from l in raw.Split('\n')
             let ll = l.Trim()
             where !string.IsNullOrEmpty(ll)
             select ll).ToList();

This works fine. But if I am not going to modify the result, then I might as well call ToArray() instead of ToList().

I wonder however whether ToArray() is implemented by first calling ToList() and is therefore less memory efficient than just calling ToList().

Am I crazy? Should I just call ToArray() - safe and secure in the knowledge that the memory won't be allocated twice?

share|improve this question
6  
If you ever want to find out what happens behind the curtains in .NET, i really recommend .NET Reflector –  David Hedlund Jul 9 '09 at 19:39
    
@DavidHedlund I recommend .net source code. –  LoveRight Jun 9 at 19:05
add comment

11 Answers

up vote 58 down vote accepted

Unless you simply need an array to meet other constraints you should use ToList. In the majority of scenarios ToArray will allocate more memory than ToList.

Both use arrays for storage, but ToList has a more flexible constraint. It needs the array to be at least as large as the number of elements in the collection. If the array is larger, that is not a problem. However ToArray needs the array to be sized exactly to the number of elements.

To meet this constraint ToArray often does one more allocation than ToList. Once it has an array that is big enough it allocates an array which is exactly the correct size and copies the elements back into that array. The only time it can avoid this is when the grow algorithm for the array just happens to coincide with the number of elements needing to be stored (definitely in the minority).

EDIT

A couple of people have asked me about the consequence of having the extra unused memory in the List<T> value.

This is a valid concern. If the created collection is long lived, is never modified after being created and has a high chance of landing in the Gen2 heap then you may be better off taking the extra allocation of ToArray up front.

In general though I find this to be the rarer case. It's much more common to see a lot of ToArray calls which are immediately passed to other short lived uses of memory in which case ToList is demonstrably better.

The key here is to profile, profile and then profile some more.

share|improve this answer
    
On the other hand, wouldn't the extra memory allocated for the legwork of creating the array be eligible for garbage collection, whereas the extra overhead for the List would remain? I say keep it simpler. If you need to add or remove elements, there's a tool for that. If you don't, there's a different tool for that. Use the one that makes sense. If later on, you discover an issue with memory and performance, and this is it, change it. –  Anthony Pegram May 1 '13 at 18:00
    
@AnthonyPegram yes that is a valid consideration to make. If the value is being used in long term storage, won't be modified, and potentially will make it into Gen 2 then you may be better off paying the extra allocation now vs polluting the Gen 2 heap. IME though I rarely see this. It's much more common to see ToArray being passed immediately to another short lived LINQ query. –  JaredPar May 1 '13 at 18:22
1  
@AnthonyPegram i updated my answer to include this side of the discussion –  JaredPar May 1 '13 at 18:27
    
@JaredPar If all you want to do is resolve the enumerable to a fixed collection for iteration, how does ImmutableList<T> stack against List<T> and T[]? –  Adam Houldsworth Sep 6 '13 at 10:40
2  
@JaredPar I don't understand how ToArray Can allocate more memory if it needs the exact locations size where ToList<> obviously has it's automatic spare locations. (autoincrease) –  Royi Namir May 25 at 11:56
show 2 more comments

A very late answer but I think it will be helpful for googlers.

They both suck when they created using linq. They both implement same code to resize buffer if necessary. ToArray internally uses a class to convert IEnumerable<> to array, by allocating an array of 4 elements. If that is not enough than it doubles the size by creating a new array double the size of current and copying current array to it. At the end it allocates a new array of count of your items. If your query returns 129 elements then ToArray will make 6 allocations and memory copy operations to create a 256 element array and than am another array of 129 to return. so much for memory efficiency.

ToList does the same thing, but it skips the last allocation since you can add items in the future. List does not care if it is created from a linq query or created manually.

for creation List is better with memory but worse with cpu since list is a generic solution every action requires range checks additional to the .net's internal range checks for arrays.

So if you will iterate through your result set too many times, then arrays are good since it means less range checks than lists, and compilers generally optimizes arrays for sequential access.

List's initialization allocation can be better if you specify capacity parameter when you create it. In this case it will allocate array only once, assuming you know the result size. ToList of linq does not specify an overload to provide it, so we have to create our extension method that creates a list with given capacity and then uses List<>.AddRange.

To finish this answer I have to write following sentences

  1. At the end, you can use either an ToArray, or ToList, performance will not be so different ( see answer of @EMP ).
  2. You are using C#. If you need performance then do not worry about writing about high performance code, but worry about not writing bad performance code.
  3. Always target x64 for high performance code. AFAIK, x64 JIT is based on C++ compiler, and does some funny things like tail recursion optimizations.
  4. With 4.5 you can also enjoy the profile guided optimization and multi core JIT.
  5. At last, you can use async/await pattern to process it quicker.
share|improve this answer
    
They both suck? Do you have an alternate idea that doesn't require redundant memory allocation? –  nawfal Oct 22 '13 at 9:35
    
In the context of question, yes, they both suck but because of redundant allocations, and nothing else. To reduce redundant allocation one can use linked lists at the expense of memory and iteration speed. At the end of the day, this is what we do, we make trade offs. Another idea if to create a list with a capacity of 200 (for example) and then load items. This will also reduce redundancy, but arrays are always faster, so this is another trade off. –  edokan Oct 24 '13 at 16:29
    
Create a list of 200? That might avoid resizing, but I was talking about redundant memory used. You cannot help it because there is no pre knowledge about what the size could be. You can already specify the capacity in the constructor of a List<T>, but when you don't or when you can't, you can't help it. –  nawfal Oct 24 '13 at 18:15
1  
the only redundant data in memory is the contents of the array which is a list of pointers (in this case). one million 64 bit pointers takes as much as 8 MB of memory, which is nothing compared to one million objects they point to. 200 is just a number, and it has a chance to reduce number of resize calls a maximum of 5 times. and yes, we can't help it. we don't have better options. I don't have a better solution, but this doesn't mean I am not allowed to say where the problem is. –  edokan Oct 25 '13 at 8:30
    
hmm in the end it is where you draw the line. I like the current implementation. The tone of your answer made me think it was criticism rather than where the problem is :) –  nawfal Oct 25 '13 at 8:59
show 1 more comment

You should base your decision to go for ToList or ToArray based on what ideally the design choice is. If you want a collection that can only be iterated and accessed by index, choose ToArray. If you want additional capabilities of adding and removing from the collection later on without much hassle, then do a ToList (not really that you cant add to an array, but that's not the right tool for it usually).

If performance matters, you should also consider what would be faster to operate on. Realistically, you wont call ToList or ToArray a million times, but might work on the obtained collection a million times. In that respect [] is better, since List<> is [] with some overhead. See this thread for some efficiency comparison: Which one is more effecient : List<int> or int[]

In my own tests a while ago, I had found ToArray faster. And I'm not sure how skewed the tests were. The performance difference is so insignificant though, which can noticeable only if you are running these queries in a loop millions of times.

share|improve this answer
1  
Yes - if the compiler knows that you are iterating over an array (rather than an IEnumerable<>), it can optimize the iteration significantly. –  RobSiklos Apr 12 '13 at 17:47
    
Oh may be the cast is not performed in foreach? –  nawfal Apr 13 '13 at 0:14
add comment

Edit: The last part of this answer is not valid. However, the rest is still useful information, so I'll leave it.

I know this is an old post, but after having the same question and doing some research, I have found something interesting that might be worth sharing.

First, I agree with @mquander and his answer. He is correct in saying that performance-wise, the two are identical.

However, I have been using Reflector to take a look at the methods in the System.Linq.Enumerable extensions namespace, and I have noticed a very common optimization.
Whenever possible, the IEnumerable<T> source is cast to IList<T> or ICollection<T> to optimize the method. For example, look at ElementAt(int).

Interestingly, Microsoft chose to only optimize for IList<T>, but not IList. It looks like Microsoft prefers to use the IList<T> interface.

System.Array only implements IList, so it will not benefit from any of these extension optimizations.
Therefore, I submit that the best practice is to use the .ToList() method.
If you use any of the extension methods, or pass the list to another method, there is a chance that it might be optimized for an IList<T>.

share|improve this answer
11  
I did a test and found out something surprising. An array DOES implement IList<T>! Using Reflector to analyze System.Array only reveals an inheritance chain of IList, ICollection, IEnumerable but using run-time reflection I found out that string[] has an inheritance chain of IList, ICollection, IEnumerable, IList<string>, ICollection<string>, IEnumerable<string>. Therefore, I don't have a better answer than @mquander! –  Scott Rippey Jul 12 '10 at 20:41
    
Still is good info to have around. Thanks! –  Frank Krueger May 18 '11 at 19:57
add comment

For anyone interested in using this result in another Linq-to-sql such as

from q in context.MyTable
where myListOrArray.Contains(q.someID)
select q;

then the SQL that is generated is the same whether you used a List or Array for the myListOrArray. Now I know some may ask why even enumerate before this statement, but there is a difference between the SQL generated from an IQueryable vs (List or Array).

share|improve this answer
add comment

One option is to add your own extension method that returns a readonly ICollection<T>. This can be better than using ToList or ToArray when you do not want to use either the indexing properties of an array/list, or add/remove from a list.

public static class EnumerableExtension
{
    /// <summary>
    /// Causes immediate evaluation of the linq but only if required.
    /// As it returns a readonly ICollection, is better than using ToList or ToArray
    /// when you do not want to use the indexing properties of an IList, or add to the collection.
    /// </summary>
    /// <typeparam name="T"></typeparam>
    /// <param name="enumerable"></param>
    /// <returns>Readonly collection</returns>
    public static ICollection<T> Evaluate<T>(this IEnumerable<T> enumerable)
    {
        //if it's already a readonly collection, use it
        var collection = enumerable as ICollection<T>;
        if ((collection != null) && collection.IsReadOnly)
        {
            return collection;
        }
        //or make a new collection
        return enumerable.ToList().AsReadOnly();
    }
}

Unit tests:

[TestClass]
public sealed class EvaluateLinqTests
{
    [TestMethod]
    public void EvalTest()
    {
        var list = new List<int> {1, 2, 3};
        var linqResult = list.Select(i => i);
        var linqResultEvaluated = list.Select(i => i).Evaluate();
        list.Clear();
        Assert.AreEqual(0, linqResult.Count());
        //even though we have cleared the underlying list, the evaluated list does not change
        Assert.AreEqual(3, linqResultEvaluated.Count());
    }

    [TestMethod]
    public void DoesNotSaveCreatingListWhenHasListTest()
    {
        var list = new List<int> {1, 2, 3};
        var linqResultEvaluated = list.Evaluate();
        //list is not readonly, so we expect a new list
        Assert.AreNotSame(list, linqResultEvaluated);
    }

    [TestMethod]
    public void SavesCreatingListWhenHasReadonlyListTest()
    {
        var list = new List<int> {1, 2, 3}.AsReadOnly();
        var linqResultEvaluated = list.Evaluate();
        //list is readonly, so we don't expect a new list
        Assert.AreSame(list, linqResultEvaluated);
    }

    [TestMethod]
    public void SavesCreatingListWhenHasArrayTest()
    {
        var list = new[] {1, 2, 3};
        var linqResultEvaluated = list.Evaluate();
        //arrays are readonly (wrt ICollection<T> interface), so we don't expect a new object
        Assert.AreSame(list, linqResultEvaluated);
    }

    [TestMethod]
    [ExpectedException(typeof (NotSupportedException))]
    public void CantAddToResultTest()
    {
        var list = new List<int> {1, 2, 3};
        var linqResultEvaluated = list.Evaluate();
        Assert.AreNotSame(list, linqResultEvaluated);
        linqResultEvaluated.Add(4);
    }

    [TestMethod]
    [ExpectedException(typeof (NotSupportedException))]
    public void CantRemoveFromResultTest()
    {
        var list = new List<int> {1, 2, 3};
        var linqResultEvaluated = list.Evaluate();
        Assert.AreNotSame(list, linqResultEvaluated);
        linqResultEvaluated.Remove(1);
    }
}
share|improve this answer
add comment

ToList() is usually preferred if you use it on IEnumerable<T> (from ORM, for instance). If the length of sequence is not known at the beginning, ToArray() creates dynamic-length collection like List and then converts it to array, which takes extra time.

share|improve this answer
15  
I've decided that readability trumps performance in this case. I now only use ToList when I expect to continue adding elements. In all other cases (most cases), I use ToArray. But thanks for the input! –  Frank Krueger Feb 1 '10 at 17:43
4  
Looking in ILSpy, Enumerable.ToArray() calls new Buffer<TSource>(source).ToArray(). In the Buffer constructor if the source implement ICollection then it calls source.CopyTo(items, 0), and then .ToArray() returns the internal items array directly. So there is no conversion that takes extra time in that case. If the source doesn't implement ICollection then the ToArray will result in an array copy in order to trim the extra unused locations from the end of the array as described by Scott Rippey's comment above. –  BrandonAGr Jan 8 '13 at 23:18
add comment

This is an old question - but for the benefit of users who stumble upon it, there is also and alternative of 'Memoizing' the Enumerable - which has the effect of caching and stopping multiple enumeration of a Linq statement, which is what ToArray() and ToList() are used for a lot, even though the collection attributes of the list or array are never used.

Memoize is available in the RX/System.Interactive lib, and is explained here: More LINQ with System.Interactive

(From Bart De'Smet's blog which is a highly recommended read if you are working with Linq to Objects a lot)

share|improve this answer
add comment

I agree with @mquander that the performance difference should be insignificant. However, I wanted to benchmark it to be sure, so I did - and it is, insignificant.

Testing with List<T> source:
ToArray time: 1934 ms (0.01934 ms/call), memory used: 4021 bytes/array
ToList  time: 1902 ms (0.01902 ms/call), memory used: 4045 bytes/List

Testing with array source:
ToArray time: 1957 ms (0.01957 ms/call), memory used: 4021 bytes/array
ToList  time: 2022 ms (0.02022 ms/call), memory used: 4045 bytes/List

Each source array/List had 1000 elements. So you can see that both time and memory differences are negligible.

My conclusion: you might as well use ToList(), since a List<T> provides more functionality than an array, unless a few bytes of memory really matter to you.

share|improve this answer
    
I wonder if this result would be different if you used a large struct instead of a primitive type or class. –  Scott Rippey May 20 '11 at 16:20
4  
List<T>.ToList ???? What sense ? U'd better try to give an IEnumerable into it, wich doesn't implement ICollection interface. –  Grigory Sep 30 '11 at 12:31
7  
I wanted to make sure I'm measuring only the time of the ToList or ToArray call and not the enumeration of any IEnumerable. List<T>.ToList() still creates a new List<T> - it doesn't simply "return this". –  EMP Sep 30 '11 at 14:06
1  
-1 The behaviours of ToArray() and ToList() differ too much when they are supplied with an ICollection<T> parameter - They just do a single allocation and a single copy operation. Both List<T> and Array implement ICollection<T>, so your benchmarks are not valid at all. –  MD.Unicorn Feb 25 at 7:32
add comment

The memory will always be allocated twice - or something close to that. As you can not resize an array, both methods will use some sort of mechanism to gather the data in a growing collection. (Well, the List is a growing collection in itself.)

The List uses an array as internal storage, and doubles the capacity when needed. This means that by average 2/3 of the items has been reallocated at least once, half of those reallocated at least twice, half of those at least thrice, and so on. That means that each item has by average been reallocated 1.3 times, which is not very much overhead.

Remember also that if you are colleting strings, the collection itself only contains the references to the strings, the strings themselves aren't reallocated.

share|improve this answer
    
This may be an ignorant thing to ask, but doesn't the 2/3, 1/3, 1/6 logic you outline assume that the List's array can be extended in place? That is, there's free space at the end of the array so that the existing allocation need not be moved? –  Jon of All Trades Aug 2 '13 at 14:38
    
@JonofAllTrades: No, the array is never extended in place, the memory management in .NET simply doesn't do that. If it would be extended in place, there would be no need for reallocation of the items. –  Guffa Aug 2 '13 at 15:09
    
Ah, I see: the items which are not reallocated did not have to do so because they were in the final allocation. All of the items allocated in previous allocations are moved, but due to the logarithmic increases in array length this is a calculable fraction. Thanks for clarifying! –  Jon of All Trades Aug 2 '13 at 15:43
add comment

The performance difference will be insignificant, since List<T> is implemented as a dynamically sized array. Calling either ToArray() (which uses an internal Buffer<T> class to grow the array) or ToList() (which calls the List<T>(IEnumerable<T>) constructor) will end up being a matter of putting them into an array and growing the array until it fits them all.

If you desire concrete confirmation of this fact, check out the implementation of the methods in question in Reflector -- you'll see they boil down to almost identical code.

share|improve this answer
    
In Entity-Framework there is an option for eager reloading using EntityCollection.CreateSourceQuery, where sometimes I am actually discarding the results, then I think it's more proper to use ToArray. –  Shimmy Dec 30 '09 at 16:14
2  
An interesting fact that I came across is that for correlated queries caused by using a group defined through a group join in your projection causes Linq to SQL to add another sub-query to retrieve the count for that group. I'm assuming that this means in these cases the size of the collection will be known before the items are retrieved and thus an exact sized array could be created directly which would save on processing and memory resources while materializing the results. –  jpierson Jun 28 '10 at 20:04
75  
If the Count is known in advance, the performance is identical. However, if the Count isn't known in advance, the only difference between ToArray() and ToList() is that the former has to trim the excess, which involves copying the entire array, whereas the latter doesn't trim the excess, but uses an average of 25% more memory. This will only have implications if the data type is a large struct. Just food for thought. –  Scott Rippey Oct 26 '10 at 21:35
    
@ScottRippey: I would think that the necessity to copy data to a precisely-sized array could be offset by having the "reading" process keep all of the temporary arrays, and then load the final array with 16 elements from the first, 32 from the second, 64 from the third, etc. so every item would end up being read once and copied exactly once (whereas with List<T>, (up to) half the items would be read but not copied, half would be copied once, half copied twice, etc. thus being copied an average of (at least) once each). –  supercat Aug 13 '13 at 18:47
1  
@EldritchConundrum 25% comes from this logic: If the number of items is unknown, then calling ToList or ToArray will start by creating a small buffer. When that buffer is filled, it doubles the capacity of the buffer and continues. Since the capacity is always doubled, the unused buffer will always be between 0% and 50%. –  Scott Rippey Dec 18 '13 at 17:45
show 1 more comment

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.