Java 9 introduced new factory methods for lists, List.of:

List<String> strings = List.of("first", "second");

What's the difference between the previous and the new option? That is, what's the difference between this:

Arrays.asList(1, 2, 3);

and this:

List.of(1, 2, 3);
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    See also this talk by Stuart "Beaker" Marks. Commented Oct 5, 2017 at 11:40
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    @user1803551 Though I understand your frustration, this reasoning might set a really unwanted precedent. A lot of questions here have an answer that's 'clearly stated' (depending on how one defines this). I'd urge you to bring this discussion to meta but I'm pretty sure such a discussion should already exist (and I'm hoping someone can find it and link it :-) Commented Oct 5, 2017 at 13:23
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    @user1803551 Javadocs do not mention the difference between implementation details of these two methods (like space consumption or performance). I think people would like to know these details too. Commented Oct 5, 2017 at 13:33
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    @ZhekaKozlov The accepted and super-upvoted answer doesn't either. What does that tell you about the accepted standards? It even has less information than in the docs (serialization, identity, ordering). If anything, file a request to OpenJDK to add that info. Commented Oct 6, 2017 at 3:20
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    This question is being discussed on meta. Commented Oct 6, 2017 at 7:15

5 Answers 5


Arrays.asList returns a mutable list while the list returned by List.of is structurally immutable:

List<Integer> list = Arrays.asList(1, 2, null);
list.set(1, 10); // OK

List<Integer> list = List.of(1, 2, 3);
list.set(1, 10); // Fails with UnsupportedOperationException

Arrays.asList allows null elements while List.of doesn't:

List<Integer> list = Arrays.asList(1, 2, null); // OK
List<Integer> list = List.of(1, 2, null); // Fails with NullPointerException

contains behaves differently with nulls:

List<Integer> list = Arrays.asList(1, 2, 3);
list.contains(null); // Returns false

List<Integer> list = List.of(1, 2, 3);
list.contains(null); // Fails with NullPointerException

Arrays.asList returns a view of the passed array, so the changes to the array will be reflected in the list too. For List.of this is not true:

Integer[] array = {1,2,3};
List<Integer> list = Arrays.asList(array);
array[1] = 10;
System.out.println(list); // Prints [1, 10, 3]

Integer[] array = {1,2,3};
List<Integer> list = List.of(array);
array[1] = 10;
System.out.println(list); // Prints [1, 2, 3]
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    For a list to behave differently based on how it's constructed doesn't seem very object oriented to me. Maybe if List.of returned an ImmutableList type, this would make sense. This is a very leaky abstraction here. Commented Oct 5, 2017 at 11:22
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    I'm not a Java developer, so take it as a casual observation. There's possibly a good reason for the behavior to differ, but if I had a method returning a List<Integer> like the example, the interface wouldn't be sufficient for me to know if I'll get a runtime exception if I check it for nulls. Likewise, a change in that methods implementation could affect code distant from the call site of my method if that check happens elsewhere. @Nicolai Commented Oct 5, 2017 at 11:52
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    @SandyChapman this might be unexpected behaviour to some (or most?), but it is documented behaviour. From the List.contains(Object o)'s javadoc : "Throws [...] NullPointerException - if the specified element is null and this list does not permit null elements (optional)". Or from the interface's lenghty introduction that few read : "Some collection implementations have restrictions on the elements that they may contain"
    – Aaron
    Commented Oct 5, 2017 at 14:04
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    @Aaron well at least it's a well documented leaky abstraction :) Commented Oct 5, 2017 at 18:26
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    @Sandy Chapman: List.of does return some ImmutableList type, its actual name is just a non-public implementation detail. If it was public and someone cast it to List again, where was the difference? Where is the difference to Arrays.asList, which returns a non-public List implementation, that throws an exception when attempting add or remove, or the list returned by Collections.unmodifiableList which allows no modification at all? It’s all about contracts specified in the List interface. The Collections interfaces with optional methods always were impure OOP since Java 1.2…
    – Holger
    Commented Oct 6, 2017 at 6:32

The differences between Arrays.asList and List.of

See the JavaDocs and this talk by Stuart Marks (or previous versions of it).

I'll be using the following for the code examples:

List<Integer> listOf = List.of(...);
List<Integer> asList = Arrays.asList(...);
List<Integer> unmodif = Collections.unmodifiableList(asList);

Structural immutability (Or: unmodifiability)

Any attempt to structurally change List.of will result in an UnsupportedOperationException. That includes operations such as add, set and remove. You can, however, change the contents of the objects in the list (if the objects are not immutable), so the list is not "completely immutable".

This is the same fate for unmodifiable lists created with Collections.unmodifiableList. Only this list is a view of the original list, so it can change if you change the original list.

Arrays.asList is not completely immutable, it does not have a restriction on set.

listOf.set(1, "a");  // UnsupportedOperationException
unmodif.set(1, "a"); // UnsupportedOperationException
asList.set(1, "a");  // modified unmodif! unmodif is not truly unmodifiable

Similarly, changing the backing array (if you hold it) will change the list.

Structural immutability comes with many side-effects related to defensive coding, concurrency and security which are beyond the scope of this answer.

Null hostility

List.of and any collection since Java 1.5 do not allow null as an element. Attempting to pass null as an element or even a lookup will result in a NullPointerException.

Since Arrays.asList is a collection from 1.2 (the Collections Framework), it allows nulls.

listOf.contains(null);  // NullPointerException
unmodif.contains(null); // allowed
asList.contains(null);  // allowed

Serialized form

Since List.of has been introduced in Java 9 and the lists created by this method have their own (binary) serialized form, they cannot be deserialized on earlier JDK versions (no binary compatibility). However, you can de/serialize with JSON, for example.


Arrays.asList internally calls new ArrayList, which guarantees reference inequality.

List.of depends on internal implementation. The instances returned can have reference equality, but since this is not guaranteed you can not rely on it.

asList1 == asList2; // false
listOf1 == listOf2; // true or false

Worth mentioning that lists are equal (via List.equals) if they contain the same elements in the same order, regardless of how they were created or what operations they support.

asList.equals(listOf); // true i.f.f. same elements in same order

Implementation (warning: details can change over versions)

If the number of elements in the list of List.of is 2 or less, the elements are stored in fields of a specialized (internal) class. An example is the list that stores 2 elements (partial source):

static final class List2<E> extends AbstractImmutableList<E> {
    private final E e0;
    private final E e1;

    List2(E e0, E e1) {
        this.e0 = Objects.requireNonNull(e0);
        this.e1 = Objects.requireNonNull(e1);

Otherwise they are stored in an array in a similar fashion to Arrays.asList.

Time and Space efficiency

The List.of implementations which are field-based (size<2) perform slightly faster on some operations. As examples, size() can return a constant without fetching the array length, and contains(E e) does not require iteration overhead.

Constructing an unmodifiable list via List.of is also faster. Compare the above constructor with 2 reference assignments (and even the one for arbitrary amount of elements) to


which creates 2 lists plus other overhead. In terms of space, you save the UnmodifiableList wrapper plus some pennies. Ultimately, the savings in the HashSet equivalent are more convincing.

Conclusion time: use List.of when you want a list that doesn't change and Arrays.asList when you want a list that can change (as shown above).

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    For people wondering why this answer exists, see this. Commented Oct 6, 2017 at 14:36
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    Arrays.asList is not fully mutable. asList.add(1); throws an UnsupportedOperationException.
    – mapeters
    Commented Oct 6, 2017 at 20:44
  • "Null hostile" is a great way to put it. I pretty much can't use List.of any time people might want to call contains and not be surprised by a NullPointerException.
    – Noumenon
    Commented Feb 26, 2020 at 6:08

Apart from the above answers there are certain operations on which both List::of and Arrays::asList differ:

|          add         |       ❌      |     ❌  |        ❌      |          ✔️          |
|        addAll        |       ❌      |     ❌  |        ❌      |          ✔️          |
|         clear        |       ❌      |     ❌  |        ❌      |          ✔️          |
|        remove        |       ❌      |     ❌  |        ❌      |          ✔️          |
|       removeAll      |       ❗️       |     ❌   |        ❗️       |          ✔️          |
|       retainAll      |       ❗️       |     ❌  |        ❗️        |          ✔️          |
|      replaceAll      |       ❌      |     ❌  |        ✔️       |          ✔️          |
|          set         |       ❌      |     ❌  |        ✔️       |          ✔️          |
|         sort         |       ✔️       |     ❌   |        ✔️      |          ✔️          |
|  remove on iterator  |       ❌      |     ❌  |        ❌      |          ✔️          |
| set on list-iterator |       ❌      |     ❌  |        ✔️       |          ✔️          |
  1. ✔️ means the method is supported
  2. ❌ means that calling this method will throw an UnsupportedOperationException
  3. ❗️ means the method is supported only if the method's arguments do not cause a mutation, e.g. Collections.singletonList("foo").retainAll("foo") is OK but Collections.singletonList("foo").retainAll("bar")throws an UnsupportedOperationException

More about Collections::singletonList Vs. List::of

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    answer for java exam Commented Jun 18, 2020 at 1:22
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    thanks for the summary table. this answer should be on top
    – R...
    Commented Dec 28, 2021 at 21:11

Let summarize the differences between List.of and Arrays.asList

  1. List.of can be best used when data set is less and unchanged, while Arrays.asList can be used best in case of large and dynamic data set.

  2. List.of take very less overhead space because it has field-based implementation and consume less heap space, both in terms of fixed overhead and on a per-element basis. while Arrays.asList take more overhead space because while initialization it creates more objects in heap.

  3. Collection returned by List.of is immutable and hence thread-safe while Collection returned by Arrays.asList is mutable and not thread safe. (Immutable collection instances generally consume much less memory than their mutable counterparts.)

  4. List.of doesn't allow null elements while Arrays.asList allows null elements.

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    "Immutable collection instances generally consume much less memory than their mutable counterparts." - Really? Would you care to elaborate a bit on that - do you mean because they can be shared safely, or do you mean that the instances themselfes can be implemented more efficiently somehow?
    – Hulk
    Commented Oct 5, 2017 at 9:15
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    @Hulk The answerer is right about the space efficiency. See Stuart Marks' talk: youtu.be/q6zF3vf114M?t=49m48s Commented Oct 5, 2017 at 9:34
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    @ZhekaKozlov That appears to be true in general, but I'm very skeptical that it's true when talking about Arrays.asList versus List.of, given that the former is literally just a wrapper around an array. At least OpenJDK's implementation appears to have extremely small overhead. In fact, List.of would need to make copies of any array passed in, so unless the array itself is going to be GC'd soon, it would seem like List.of has a significantly larger memory footprint. Commented Oct 5, 2017 at 9:40
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    @ChrisHayes At least List.of(x) and List.of(x, y) are more efficient because they do not allocate arrays at all Commented Oct 5, 2017 at 10:20
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    @Hulk: don’t forget that the List.of methods are not required to return new lists each time. These lists have an unspecified identity, so there could be caching or deduplication or scalarization handled on the JVM level. If not in this version, then perhaps in the next. It’s allowed by the contract. In contrast, Array.asList depends on the identity of the array you’re passing in, as the resulting list is mutable view on the array, reflecting all changing bidirectionally.
    – Holger
    Commented Oct 6, 2017 at 6:39

Arrays.asList(1, 2, 3);

A fixed-sized List will be create:

public static void main(String[] args) {
        List<Integer> asList = Arrays.asList(1, 2, 3, 4, 5);
        asList.add(6);    // java.lang.UnsupportedOperationException
        asList.remove(0); // java.lang.UnsupportedOperationException
        asList.set(0, 0); // allowed

List.of(1, 2, 3);

A Immutable(Java 9)/Unmodifiable(Java 11) List will be create:

public static void main(String[] args) {
    List<Integer> listOf = List.of(1, 2, 3, 4, 5);
    listOf.add(6);    // java.lang.UnsupportedOperationException
    listOf.remove(0); // java.lang.UnsupportedOperationException
    listOf.set(0, 0); // java.lang.UnsupportedOperationException

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