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When is it better to use a List(Of T) vs a LinkedList(Of T)?

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21  
A dude just asked me this in an interview question, I should have just looked it up here. –  rball May 4 '11 at 18:29
    
Java q, shouldnt be very different. –  nawfal Jul 3 at 0:39

10 Answers 10

up vote 66 down vote accepted

I know this answer is late but I found interesting results

// temp class to show example
class Temp
{
    public decimal A, B, C, D; 

    public Temp(decimal a, decimal b, decimal c, decimal d)
    {
        A = a;            B = b;            C = c;            D = d;
    }        
}

Linked list (3.9 seconds)

        LinkedList<Temp> list = new LinkedList<Temp>(); 

        for (var i = 0; i < 12345678; i++)
        {
            var a = new Temp(i, i, i, i);
            list.AddLast(a);
        }

        decimal sum = 0;
        foreach (var item in list)
            sum += item.A;

List (2.4 seconds)

        List<Temp> list = new List<Temp>(); // 2.4 seconds

        for (var i = 0; i < 12345678; i++)
        {
            var a = new Temp(i, i, i, i);
            list.Add(a);
        }

        decimal sum = 0;
        foreach (var item in list)
            sum += item.A;

Even if you only access data essentially it is much slower!! I say never use a linkedList.




Here is another comparison performing a lot of inserts (we plan on inserting an item at the middle of the list)

Linked List (51 seconds)

        LinkedList<Temp> list = new LinkedList<Temp>(); 

        for (var i = 0; i < 123456; i++)
        {
            var a = new Temp(i, i, i, i);

            list.AddLast(a);
            var curNode = list.First;

            for (var k = 0; k < i/2; k++) // in order to insert a node at the middle of the list we need to find it
                curNode = curNode.Next;

            list.AddAfter(curNode, a); // insert it after
        }

        decimal sum = 0;
        foreach (var item in list)
            sum += item.A;

List (7.26 seconds)

        List<Temp> list = new List<Temp>(); 

        for (var i = 0; i < 123456; i++)
        {
            var a = new Temp(i, i, i, i);

            list.Insert(i / 2, a);
        }

        decimal sum = 0;
        foreach (var item in list)
            sum += item.A;

Linked List having reference of location where to insert (.04 seconds)

        list.AddLast(new Temp(1,1,1,1));
        var referenceNode = list.First;

        for (var i = 0; i < 123456; i++)
        {
            var a = new Temp(i, i, i, i);

            list.AddLast(a);
            list.AddBefore(referenceNode, a);
        }

        decimal sum = 0;
        foreach (var item in list)
            sum += item.A;

So only if you plan on inserting several items and you also somewhere have the reference of where you plan to insert the item then use a linked list. Just because you have to insert a lot of items it does not make it faster because searching the location where you will like to insert it takes time.

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45  
There is one benefit to LinkedList over List (this is .net specific): since the List is backed by an internal array, it is allocated in one contiguous block. If that allocated block exceeds 85000 bytes in size, it will be allocated on the Large Object Heap, a non-compactable generation. Depending on the size, this can lead to heap fragmentation, a mild form of memory leak. –  JerKimball Sep 20 '12 at 6:32
13  
Note that if you're prepending a lot (as you're essentially doing in the last example) or deleting the first entry, a linked list will nearly always be significantly faster, as there is no searching or moving/copying to do. A List would require moving everything up a spot to accommodate the new item, making prepending an O(N) operation. –  cHao Sep 20 '12 at 19:32
3  
Note: This sounds completely typical of ANY linked list implementation, not just .Net's. –  Earlz Nov 11 '12 at 8:26
2  
I think it's notable that a List is implemented using an array. Which means that this array needs to be expanded once the list exceeds it's initial size. Which is again an O(n) operation. In contrast to a linkedlist, there is no storagemove needed so we never have that costly operation O(n). Alinked list is mostly handy when appending a lot of data in the beginning of the list. Correct me if I'm wrong. –  Christophe De Troyer Apr 24 '13 at 19:36
5  
Why the in-loop list.AddLast(a); in the last two LinkedList examples? I get doing it once before the loop, as with list.AddLast(new Temp(1,1,1,1)); in the next to last LinkedList, but it looks (to me) like you're adding twice as many Temp objects in the loops themselves. (And when I double-check myself with a test app, sure enough, twice as many in the LinkedList.) –  ruffin Apr 27 '13 at 16:54

In most cases, List<T> is more useful. LinkedList<T> will have less cost when adding/removing items in the middle of the list, whereas List<T> can only cheaply add/remove at the end of the list.

LinkedList<T> is only at it's most efficient if you are accessing sequential data (either forwards or backwards) - random access is relatively expensive since it must walk the chain each time (hence why it doesn't have an indexer). However, because a List<T> is essentially just an array (with a wrapper) random access is fine.

List<T> also offers a lot of support methods - Find, ToArray, etc; however, these are also available for LinkedList<T> with .NET 3.5/C# 3.0 via extension methods - so that is less of a factor.

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Linked lists provide very fast insertion or deletion of a list member. Each member in a linked list contains a pointer to the next member in the list so to insert a member at position i:

  • update the pointer in member i-1 to point to the new member
  • set the pointer in the new member to point to member i

The disadvantage to a linked list is that random access is not possible. Accessing a member requires traversing the list until the desired member is found.

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4  
I would add that linked lists have an overhead per item stored implied above via LinkedListNode which references the previous and next node. The payoff of that is a contiguous block of memory isn't required to store the list, unlike an array based list. –  paulecoyote Jul 22 '09 at 16:26
3  
Isn't a contiguous block of memory usually perferred? –  Jonathan Allen Feb 5 '10 at 19:52
5  
Yes, a contiguous block is preferred for random access performance and memory consumption but for collections that need to change size regularly a structure such as an Array generally need to be copied to a new location whereas a linked list only needs to manage the memory for the newly inserted/deleted nodes. –  jpierson Mar 17 '10 at 13:37
4  
If you have ever had to work with very large arrays or lists (a list just wraps an array) you will start to run into memory issues even though there appears to be plenty of memory available on your machine. The list uses a doubling strategy when it allocates new space in it's underlying array. So a 1000000 elemnt array that is full will be copied into a new array with 2000000 elements. This new array needs to be created in a contiguous memory space that is large enough to hold it. –  Andrew May 4 '11 at 8:57
1  
I had a specific case where all i did was adding and removing, and looping one by one... here the linked list was far superior to the normal list.. –  Peter Oct 27 '11 at 9:35

Thinking of a linked list as a list can be a bit misleading. It's more like a chain. In fact, in .NET, LinkedList<T> does not even implement IList<T>. There is no real concept of index in a linked list, even though it may seem there is. Certainly none of the methods provided on the class accept indexes.

Linked lists may be singly linked, or doubly linked. This refers to whether each element in the chain has a link only to the next one (singly linked) or to both the prior/next elements (doubly linked). LinkedList<T> is doubly linked.

Internally, List<T> is backed by an array. This provides a very compact representation in memory. Conversely, LinkedList<T> involves additional memory to store the bidirectional links between successive elements. So the memory footprint of a LinkedList<T> will generally be larger than for List<T> (with the caveat that List<T> can have unused internal array elements to improve performance during append operations.)

They have different performance characteristics too:

Append

  • LinkedList<T>.AddLast(item) constant time
  • List<T>.Add(item) amortized constant time, linear worst case

Prepend

  • LinkedList<T>.AddFirst(item) constant time
  • List<T>.Insert(0, item) linear time

Insertion

  • LinkedList<T>.AddBefore(node, item) constant time
  • LinkedList<T>.AddAfter(node, item) constant time
  • List<T>.Insert(index, item) linear time

Removal

  • LinkedList<T>.Remove(item) linear time
  • LinkedList<T>.Remove(node) constant time
  • List<T>.Remove(item) linear time
  • List<T>.RemoveAt(index) linear time

Count

  • LinkedList<T>.Count constant time
  • List<T>.Count constant time

Contains

  • LinkedList<T>.Contains(item) linear time
  • List<T>.Contains(item) linear time

Clear

  • LinkedList<T>.Clear() linear time
  • List<T>.Clear() linear time

As you can see, they're mostly equivalent. In practice, the API of LinkedList<T> is more cumbersome to use, and details of its internal needs spill out into your code.

However, if you need to do many insertions/removals from within a list, it offers constant time. List<T> offers linear time, as extra items in the list must be shuffled around after the insertion/removal.

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2  
Is count linkedlist constant? I thought that would be linear? –  Iain Ballard Nov 4 '11 at 10:05
4  
@Iain, the count is cached in both list classes. –  Drew Noakes Nov 4 '11 at 18:13
2  
You wrote that "List<T>.Add(item) logarithmic time", however it is in fact "Constant" if the list capacity can store the new item, and "Linear" if the list doesn't have enough space and new to be reallocated. –  aStranger Sep 16 '12 at 13:32
    
@aStranger, of course you're right. Not sure what I was thinking in the above -- perhaps that the amortized normal case time is logarithmic, which it isn't. In fact the amortized time is constant. I didn't get into best/worst case of the operations, aiming for a simple comparison. I think the add operation is significant enough to provide this detail however. Will edit the answer. Thanks. –  Drew Noakes Sep 16 '12 at 16:14
    
Good answer! You should mention that indexed access is constant time with List but linear with LinkedList. –  Robert Jeppesen Dec 3 '12 at 8:58

The difference between List and LinkedList lies in their underlying implementation. List is array based collection (ArrayList). LinkedList is node-pointer based collection (LinkedListNode). On the API level usage, both of them are pretty much the same since both implement same set of interfaces such as ICollection, IEnumerable, etc.

The key difference comes when performance matter. For example, if you are implementing the list that has heavy "INSERT" operation, LinkedList outperforms List. Since LinkedList can do it in O(1) time, but List may need to expand the size of underlying array. For more information/detail you might want to read up on the algorithmic difference between LinkedList and array data structures. http://en.wikipedia.org/wiki/Linked_list and Array

Hope this help,

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2  
List<T> is array (T[]) based, not ArrayList based. Re insert: the array resize isn't the issue (the doubling algorithm means that most of the time it doesn't have to do this): the issue is that it must block-copy all the existing data first, which takes a little time. –  Marc Gravell Oct 4 '08 at 8:38
2  
@Marc, the 'doubling algorithm" only makes it O(logN), but it is still worse than O(1) –  Ilya Ryzhenkov Oct 4 '08 at 10:02
1  
My point was that that it isn't the resize that causes the pain - it is the blit. So worst case, if we are adding the first (zeroth) element each time, then the blit has to move everything each time. –  Marc Gravell Oct 4 '08 at 10:23

The primary advantage of linked lists over arrays is that the links provide us with the capability to rearrange the items efficiently. Sedgewick, p. 91

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When you need built-in indexed access, sorting (and after this binary searching), and "ToArray()" method, you should use List.

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Use LinkedList<> when

1) You don't know how many objects are coming thru the flood gate. eg:Token Stream
2) When you ONLY wanted to delete\insert at the ends.

for everything else it is better to use List<>

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2  
I don't see why point 2 makes sense. Linked lists are great when you're doing many insertions/deletions throughout the entire list. –  Drew Noakes Dec 25 '12 at 20:23
    
Because of the fact that LinkedLists are not Index based, you really have to scan the entire list for insertion or deletion that incurs a O(n) penalty. List<> on the other hand suffers from Array resizing, but still,IMO, is a better option when compared to LinkedLists. –  Antony Thomas Dec 26 '12 at 22:45
    
You don't have to scan the list for insertions/deletions if you keep track of the LinkedListNode<T> objects in your code. If you can do that, then it's much better than using List<T>, especially for very long lists where inserts/removals are frequent. –  Drew Noakes Dec 26 '12 at 23:02
    
You mean thru a hashtable? If that is the case, that would be the typical space\time tradeoff that every computer programmer should make a choice based on the problem domain :) But yes, that would make it faster. –  Antony Thomas Dec 27 '12 at 4:23

A common circumstance to use LinkedList is like this:

Suppose you want to remove may certain strings from a list of string with large size, say 100,000. The strings to remove can be looked up in HashSet dic, and the list of strings is believed to contain between 30,000 to 60,000 such strings to remove.

Then what's the best type of List for storing the 100,000 Strings? The answer is LinkedList. If the they are stored in an ArrayList, then iterating over it and removing matched Strings whould take up to billions of operations, while it takes just around 100,000 operations by using an iterator and the remove() method.

LinkedList<String> strings = readStrings();
HashSet<String> dic = readDic();
Iterator<String> iterator = strings.iterator();
while (iterator.hasNext()){
    String string = iterator.next();
    if (dic.contains(string))
    iterator.remove();
}
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This is adapted from Tono Nam's accepted answer correcting a few wrong measurements in it.

The test:

static void Main()
{
    LinkedListPerformance.AddFirst_List(); // 12028 ms
    LinkedListPerformance.AddFirst_LinkedList(); // 33 ms

    LinkedListPerformance.AddLast_List(); // 33 ms
    LinkedListPerformance.AddLast_LinkedList(); // 32 ms

    LinkedListPerformance.Enumerate_List(); // 1.08 ms
    LinkedListPerformance.Enumerate_LinkedList(); // 3.4 ms

    //I tried below as fun exercise - not very meaningful, see code
    //sort of equivalent to insertion when having the reference to middle node

    LinkedListPerformance.AddMiddle_List(); // 5724 ms
    LinkedListPerformance.AddMiddle_LinkedList1(); // 36 ms
    LinkedListPerformance.AddMiddle_LinkedList2(); // 32 ms
    LinkedListPerformance.AddMiddle_LinkedList3(); // 454 ms

    Environment.Exit(-1);
}

And the code:

using System.Collections.Generic;
using System.Diagnostics;
using System.Linq;

namespace stackoverflow
{
    static class LinkedListPerformance
    {
        class Temp
        {
            public decimal A, B, C, D;

            public Temp(decimal a, decimal b, decimal c, decimal d)
            {
                A = a; B = b; C = c; D = d;
            }
        }



        static readonly int start = 0;
        static readonly int end = 123456;
        static readonly IEnumerable<Temp> query = Enumerable.Range(start, end - start).Select(temp);

        static Temp temp(int i)
        {
            return new Temp(i, i, i, i);
        }

        static void StopAndPrint(this Stopwatch watch)
        {
            watch.Stop();
            Console.WriteLine(watch.Elapsed.TotalMilliseconds);
        }

        public static void AddFirst_List()
        {
            var list = new List<Temp>();
            var watch = Stopwatch.StartNew();

            for (var i = start; i < end; i++)
                list.Insert(0, temp(i));

            watch.StopAndPrint();
        }

        public static void AddFirst_LinkedList()
        {
            var list = new LinkedList<Temp>();
            var watch = Stopwatch.StartNew();

            for (int i = start; i < end; i++)
                list.AddFirst(temp(i));

            watch.StopAndPrint();
        }

        public static void AddLast_List()
        {
            var list = new List<Temp>();
            var watch = Stopwatch.StartNew();

            for (var i = start; i < end; i++)
                list.Add(temp(i));

            watch.StopAndPrint();
        }

        public static void AddLast_LinkedList()
        {
            var list = new LinkedList<Temp>();
            var watch = Stopwatch.StartNew();

            for (int i = start; i < end; i++)
                list.AddLast(temp(i));

            watch.StopAndPrint();
        }

        public static void Enumerate_List()
        {
            var list = new List<Temp>(query);
            var watch = Stopwatch.StartNew();

            foreach (var item in list)
            {

            }

            watch.StopAndPrint();
        }

        public static void Enumerate_LinkedList()
        {
            var list = new LinkedList<Temp>(query);
            var watch = Stopwatch.StartNew();

            foreach (var item in list)
            {

            }

            watch.StopAndPrint();
        }

        //for the fun of it, I tried to time inserting to the middle of 
        //linked list - this is by no means a realistic scenario! or may be 
        //these make sense if you assume you have the reference to middle node

        //insertion to the middle of list
        public static void AddMiddle_List()
        {
            var list = new List<Temp>();
            var watch = Stopwatch.StartNew();

            for (var i = start; i < end; i++)
                list.Insert(list.Count / 2, temp(i));

            watch.StopAndPrint();
        }

        //insertion in linked list in such a fashion that 
        //it has the same effect as inserting into the middle of list
        public static void AddMiddle_LinkedList1()
        {
            var list = new LinkedList<Temp>();
            var watch = Stopwatch.StartNew();

            LinkedListNode<Temp> evenNode = null, oddNode = null;
            for (int i = start; i < end; i++)
            {
                if (list.Count == 0)
                    oddNode = evenNode = list.AddLast(temp(i));
                else
                    if (list.Count % 2 == 1)
                        oddNode = list.AddBefore(evenNode, temp(i));
                    else
                        evenNode = list.AddAfter(oddNode, temp(i));
            }

            watch.StopAndPrint();
        }

        //another hacky way
        public static void AddMiddle_LinkedList2()
        {
            var list = new LinkedList<Temp>();
            var watch = Stopwatch.StartNew();

            for (var i = start + 1; i < end; i += 2)
                list.AddLast(temp(i));
            for (int i = end - 2; i >= 0; i -= 2)
                list.AddLast(temp(i));

            watch.StopAndPrint();
        }

        //OP's original more sensible approach, but I tried to filter out
        //the intermediate iteration cost in finding the middle node.
        public static void AddMiddle_LinkedList3()
        {
            var list = new LinkedList<Temp>();
            var watch = Stopwatch.StartNew();

            for (var i = start; i < end; i++)
            {
                if (list.Count == 0)
                    list.AddLast(temp(i));
                else
                {
                    watch.Stop();
                    var curNode = list.First;
                    for (var j = 0; j < list.Count / 2; j++)
                        curNode = curNode.Next;
                    watch.Start();

                    list.AddBefore(curNode, temp(i));
                }
            }

            watch.StopAndPrint();
        }
    }
}

You can see the results are in accordance with theoretical performance others have documented here. Quite clear - LinkedList<T> gains big time in case of insertions. I haven't tested for removal from the middle of list, but the result should be the same. Of course List<T> has other areas where it performs way better like O(1) random access.

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