From the Collections Framework Overview:

Collections that do not support modification operations (such as add, remove and clear) are referred to as unmodifiable. Collections that are not unmodifiable are modifiable.

Collections that additionally guarantee that no change in the Collection object will be visible are referred to as immutable. Collections that are not immutable are mutable.

I cannot understand the distinction.
What is the difference between unmodifiable and immutable here?


An unmodifiable collection is often a wrapper around a modifiable collection which other code may still have access to. So while you can't make any changes to it if you only have a reference to the unmodifiable collection, you can't rely on the contents not changing.

An immutable collection guarantees that nothing can change the collection any more. If it wraps a modifiable collection, it makes sure that no other code has access to that modifiable collection. Note that although no code can change which objects the collection contains references to, the objects themselves may still be mutable - creating an immutable collection of StringBuilder doesn't somehow "freeze" those objects.

Basically, the difference is about whether other code may be able to change the collection behind your back.

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    An immutable collection doesn't guarantee that nothing can change anymore. It just makes sure that the collection itself cannot be altered (and not by wrapping, but by copying). The objects which are present in the collection can still be altered, and no guarantee is given on those. – Hiery Nomus Jan 17 '12 at 9:44
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    @HieryNomus: Note that I didn't say that nothing could change - I said nothing could change the collection. – Jon Skeet Jan 17 '12 at 9:47
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    ok, might've misread that ;) But it is good to clarify it though. – Hiery Nomus Jan 17 '12 at 9:49
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    So, what you're saying. Is for true immutability you need an immutable collection that contains items of an immutable type. – Evan Plaice Feb 24 '14 at 9:58
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    @savanibharat: that depends on whether there's any code path that can still modify list. If something can later call list.add(10) then coll will reflect that change, so no, I wouldn't call it immutable. – Jon Skeet Apr 18 '16 at 5:46

Basically unModifiable Collection is a view, So indirectly it could still be 'modified' from some other reference that is modifiable. Also as its just a readonly view of annother collection , When the source collection changes unModifiable Collection will always present with latest values.

However immutable Collection can be treated as a readonly copy of another collection and can not be modified. In this case when the source collection changes , immutable Collection do not reflect the changes

Here is a testcase to visualise this difference.

public void testList() {

    List<String> modifiableList = new ArrayList<String>();



    assertEquals(1, modifiableList.size());

    List<String> unModifiableList=Collections.unmodifiableList(


    boolean exceptionThrown=false;
    try {
        fail("add supported for unModifiableList!!");
    } catch (UnsupportedOperationException e) {
        System.out.println("unModifiableList.add() not supported");


    assertEquals(2, modifiableList.size());
    assertEquals(2, unModifiableList.size());


    List<String> immutableList=Collections.unmodifiableList(
                            new ArrayList<String>(modifiableList));


    try {
        fail("add supported for immutableList!!");
    } catch (UnsupportedOperationException e) {
        System.out.println("immutableList.add() not supported");


    assertEquals(3, modifiableList.size());
    assertEquals(3, unModifiableList.size());
    assertEquals(2, immutableList.size());



unModifiableList.add() not supported
modifiableList:[a, b]
unModifiableList:[a, b]
immutableList.add() not supported
modifiableList:[a, b, c]
unModifiableList:[a, b, c]
immutableList:[a, b]
  • I am not able to see any difference, Can you please point out how Immutable is different? I can see both Immutable and unmodifiable are throwing error and add is not supported. Am I missing something here? – AKS Aug 20 '13 at 17:19
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    @AKS Please see output of last three list entries after addition of 'c' to the list while both size of modifiableList and unModifiableList has increased immutableList size has not changed – Prashant Bhate Aug 20 '13 at 17:28
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    Oh! got it! :).. So here you modified unmodifableList using the changes in modifiableList, but ImmutableList can not be modifed. But same way you can modify ImmutableList also, I think here client will get access to ImmutableList reference only, reference to modifiableList, using which ImmutableList is created, will not be exposed to client. right? – AKS Aug 20 '13 at 17:33
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    yes because there is no reference to new ArrayList<String>(modifiableList) immutableList can not be modified – Prashant Bhate Aug 20 '13 at 17:52
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    Woah! Nice example! – pramodc84 Aug 28 '13 at 4:33

I think the main difference is that the owner of a mutable collection might want to provide access to the collection to some other code, but provide that access through an interface that doens't allow the other code to modify the collection (while reserving that capability to the owning code). So the collection isn't immutable, but certain users aren't permitted to change the collection.

Oracle's Java Collection Wrapper tutorial has this to say (emphasis added):

Unmodifiable wrappers have two main uses, as follows:

  • To make a collection immutable once it has been built. In this case, it's good practice not to maintain a reference to the backing collection. This absolutely guarantees immutability.
  • To allow certain clients read-only access to your data structures. You keep a reference to the backing collection but hand out a reference to the wrapper. In this way, clients can look but not modify, while you maintain full access.

If we are talking about JDK Unmodifiable* vs guava Immutable*, actually the difference is also in performance. Immutable collections can be both faster and more memory-efficient if they are not wrappers around regular collections (JDK implementations are wrappers). Citing the guava team:

The JDK provides Collections.unmodifiableXXX methods, but in our opinion, these can be


  • inefficient: the data structures still have all the overhead of mutable collections, including concurrent modification checks, extra space in hash tables, etc.
  • thinking of performance, you should also take into account that an unmodifiable wrapper does not copy the collection, where as the immutable version used in guava and now also in jdk9+ with e.g. List.of(...) does indeed copy twice! – benez Sep 24 '18 at 18:03

To quote The Java™ Tutorials:

Unlike synchronization wrappers, which add functionality to the wrapped collection, the unmodifiable wrappers take functionality away. In particular, they take away the ability to modify the collection by intercepting all the operations that would modify the collection and throwing an UnsupportedOperationException. Unmodifiable wrappers have two main uses, as follows:

  • To make a collection immutable once it has been built. In this case, it's good practice not to maintain a reference to the backing collection. This absolutely guarantees immutability.

  • To allow certain clients read-only access to your data structures. You keep a reference to the backing collection but hand out a reference to the wrapper. In this way, clients can look but not modify, while you maintain full access.

(emphasis mine)

This really sums it up.


As noted above unmodifiable is not like immutable because an unmodifiable collection can be altered if for example an unmodifiable collection has an underlying delegate collection which is referenced by some other object and that object changes it.

Regarding immutable, it's not even well defined. However, generally it means that the object "will not change", but that would need to be defined recursively. For example, I can define immutable on classes whose instance variables are all primitives and whose methods all contain no arguments and return primitives. The methods then recursively allow the instance variables to be immutable and all methods to contain arguments that are immutable and that return immutable values. The methods should be guaranteed to return the same value over time.

Assuming that we can do that, there is also the concept thread safe. And you might be led to believe that immutable (or not changeble over time) also implies thread safe. However that is not the case and that is the main point I am making here that has not yet been noted in other answers. I can construct an immutable object that always returns the same results yet is not thread safe. To see this suppose that I construct an immutable collection by maintaining additions and deletions over time. Now the immutable collection returns its elements by looking at the internal collection (which may be changing over time) and then (internally) adding and deleting the elements that were added or deleted after creation of the collection. Clearly, although the collection would always return the same elements, it is not thread safe merely because it will never change value.

Now we can define immutable as objects that are thread safe and will never change. There are guidelines for creating immutable classes that generally lead to such classes, however, keep in mind that there may be ways to create immutable classes, that require attention to thread safety, for example, as described in the "snapshot" collection example above.

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