If I have a class like that:

public class MyObject {
    private int myField = 2;
    public void setMyField(int f) {
        this.myField = f;

Will objects of this class be mutable? Thanks!


Of course - if you want it to be immutable, then you need something like:

public class MyObject {
    private final int myField;

    public MyObject(int f) {
      myfield = f;

    public int getMyField() {
        return myField;
|improve this answer|||||


Mutable objects have fields that can be changed, immutable objects have no fields that can be changed after the object is created.

|improve this answer|||||
  • Mutable objects have STATE. The above object does not expose any state, since there is no getter and the field is private. – Christian Fries Jan 27 '14 at 10:51
  • @ChristianFries Of course it has state. It has myField. And it can be changed through the setter, meaning it's mutable. That there's no getter is irrelevant. – Svish Jan 27 '14 at 11:17
  • @Christian I think (if I remember correctly from my OCA certification Exam) "mutable object can be modified after it is created" nothing else. No note about "get" or "set" (bean style). – venergiac Jan 27 '14 at 11:19
  • Eventhough the state may not be visible it can still be viewed via reflection. – Blank Chisui Jan 27 '14 at 11:42
  • As I wrote in my answer: The object has state, but it does not expose it. I believe that an object of this class meets the definition of "effectively immutable". Reflection would work, but only if you modify the "private". In C++ I would suspect that a compiler would optimize the field and the setter away, if it realizes that the field is never read. - But, I do see your points. – Christian Fries Jan 27 '14 at 12:25

You already have several answers with a "Yes".

I would like to add a "but" (if I would be bold, I would say "No" ;-)

Yes, an object of this class appears to be mutable, since it provides a setter to change the field. However, since it does not have a getter for that field, neither any other getter depending on that field, and since the field is private, it is currently not possible to read that state.

Put differently: The object has state, but it does not expose any state to the outside.

I would call that object "effectively immutable".

There are some design patterns, where objects are "effectively immutable", for example "Lazy Initialization" of an "Immutable Object".

Note: The concept of being "effectively immutable" is discussed in Section 3.5.4 of Java Concurrency in Practice by Brian Goetz.

|improve this answer|||||
  • 1
    I know. I know (see also my comment above). But to do that you have to "modify" the private. And that way, you could make ANY object which is considered being (i.e. which "looks") immutable (also the ones in the other answers) mutable. I just wanted to mention "effectively immutable". The definition of "effectively immutable" relates to the way an object is used or intended to use. – Christian Fries Jan 27 '14 at 13:33

Yes, objects of this class are mutable. The designer of the class can't prohibit by any technical means (in real existing Java) consumers of the objects to observe and modify the contents of the field.

private is an explicitly declared contract regarding intended usage of the field - this contract can be broken, e.g. with reflection.

Not providing any methods that change the data of an object after creation can also be a (implicitly declared) contract about intended use and mutability - this contract, too, can be broken, like any contract that needs two conforming parties.

Edit: Unless there is another party that has the means to enforce - like in Java the SecurityManager stopping you from changing a final field at runtime.

|improve this answer|||||
  • I am wondering if that definition (like being able to change a field via reflection) would actually imply that there are no immutable objects in Java. – Christian Fries Jan 29 '14 at 12:44
  • If you don't want mutability don't use objects. – Oliver Schweitzer Jan 29 '14 at 12:49

Yes, your object is mutable as the value of myField can be changed after the instance is created using the setter.

Immutability can be achieved using final fields, as it will not allow you to change the value of a variable once it is initialized.

Answer by @JakubK points out how you can make your class Immutable.

But declaring reference final wont make the object being pointed by it final.

For example:

class MyObject{
    private final List<Integer> list = new ArrayList<Integer>();

    public List<Integer> getList(){
        return list;

I can change add a new element to the list from outside by doing something like this

instance.getList().add(1); //mutates the list

This example is not immutable, as the List can be changed by someone else.

|improve this answer|||||

To define whether something is mutable, one has to define what state is encapsulated thereby. If MyObject specifies that its state includes the value which Reflection will report for myField, then it is mutable. If that field is not specified as being part of the object's observable state, then it may be most purposes regarded as immutable.

To be more specific, I would regard a class as being immutable only if one could perform any combination of documented operations upon the class, in any sequence and with any timing (even on multiple threads), and not have any documented behavioral aspects of of any of them affected by any other. The fact that a method might change the contents of a private field is relevant if and only if that change would affect some documented behavioral aspect of another method call (to the same or different method). For example, I would say that the fact that String.hashCode() modifies the hash field does not make String mutable, because the value returned by hashCode() is not affected by whether or not the field had been written previously. If a class had a hashCode method which would, if a field was blank, generate a random number and store it in that field, and otherwise return the value directly, such a class would be mutable unless it ensured that the field was tested and set as an atomic operation. In the absence of such assurance, it would be possible for near-simultaneous calls to hashCode() to yield different values, and thus for future calls to differ values that would differ from at least one of them (implying that the object's state had changed between the call that returned the odd-ball value and the later call).

|improve this answer|||||

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.