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Due to the implementation of Java generics, you can't have code like this:

public class GenSet<E> {
    private E a[];
    public GenSet()
    {
        a = new E[INITIAL_ARRAY_LENGTH]; // error: generic array creation
    }
}

How can I implement this while maintaining type safety?

I saw a solution on the Java forums that goes like this:

import java.lang.reflect.Array;

class Stack<T> {
  public Stack(Class<T> clazz,int capacity) {
     array=(T[])Array.newInstance(clazz,capacity);
  }

  private final T[] array;
}

But I really don't get what's going on. Can anyone help?

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3  
Do you really need to use an array here? What about using a Collection? –  matt b Feb 9 '09 at 18:34
3  
Yes I also think that collections are more elegant to for this problem. But this is for a class assignment and they are required :( –  tatsuhirosatou Feb 9 '09 at 19:47

19 Answers 19

up vote 216 down vote accepted

I have to ask a question in return: is your GenSet "checked" or "unchecked"? What does that mean?

  • checked: strong typing. GenSet knows explicitly what type of objects it contains (i.e. its constructor was explicitly called with a Class<E> argument, and methods will throw an exception when they are passed arguments that are not of type E. See Collections.checkedCollection.

    -> in that case, you should write:

    public class GenSet<E> {
    
        private E[] a;
    
        public GenSet(Class<E> c, int s) {
            // Use Array native method to create array of a type only known at run time
            @SuppressWarnings("unchecked")
            final E[] a = (E[]) Array.newInstance(c, s);
            this.a = a;
        }
    
        E get(int i) {
            return a[i];
        }
    }
    
  • unchecked: weak typing. No type checking is actually done on any of the objects passed as argument.

    -> in that case, you should write

    public class GenSet<E> {
    
        private Object[] a;
    
        public GenSet(int s) {
            a = new Object[s];
        }
    
        E get(int i) {
            @SuppressWarnings("unchecked")
            final E e = (E) a[i];
            return e;
        }
    }
    

    Note that the component type of the array should be the erasure of the type parameter:

    public class GenSet<E extends Foo> { // E has an upper bound of Foo
    
        private Foo[] a; // E erases to Foo, so use Foo[]
    
        public GenSet(int s) {
            a = new Foo[s];
        }
    
        ...
    }
    

All of this results from a known, and deliberate, weakness of generics in Java: it was implemented using erasure, so "generic" classes don't know what type argument they were created with at run time, and therefore can not provide type-safety unless some explicit mechanism (type-checking) is implemented.

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What would performance-wise be the best option? I need to get elements from this array quite often (within a loop). So a collection is probably slower, but which of these two is fastest? –  user1111929 Sep 8 '12 at 3:52
1  
And if the generic type is bounded, the backing array should be of the bounding type. –  MouseEvent Apr 8 '13 at 5:59
3  
@AaronDigulla Just to clarify that's not assignment, but initialization of a local variable. You can't annotate an expression/statement. –  KennyTM Sep 26 '13 at 12:17
    
@Varkhan Is there a way to resize these arrays from within the class implementation. For example if I want to resize after overflow like ArrayList. I looked up the Implementation of ArrayList they have Object[] EMPTY_ELEMENTDATA = {} for storage. Can I use this mechanism to resize without knowing the type using generics? –  JourneyMan Aug 28 at 17:53

A quick test confirms you can do this also:

E[] arr = (E[])new Object[INITIAL_ARRAY_LENGTH];

My test:

public class ArrTest<E> {
  public static void main(String[] args){
    ArrTest<String> t = new ArrTest<String>();
    t.test("Hello World");
  }

  public void test(E a){
    E[] b = (E[])new Object[1];
    b[0] = a;
    System.out.println(b[0]);
  }
}

No warnings, no type errors, no need to cast the array repeatedly. HOWEVER this is potentially dangerous, and should be used with caution. As detailed in the comments, this Object[] is now masquerading as our E[] type, and can cause unexpected errors or ClassCastExceptions if used unsafely.

As a rule of thumb, this behavior is safe as long as the cast array is used internally, and not returned or exposed to client code. Should you need to return an array of a generic type to other code, the reflection Array class you mention is the right way to go.


Worth mentioning that wherever possible, you'll have a much happier time working with Lists rather than arrays if you're using generics. Certainly sometimes you don't have a choice, but using the collections framework is far more robust.

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18  
This will not work if the array is treated as a typed array of any kind, such as String[] s=b; in the above test() method. That's because the array of E isn't really, it's Object[]. This matters if you want, e.g. a List<String>[] - you can't use an Object[] for that, you must have a List[] specifically. Which is why you need to use the reflected Class<?> array creation. –  Lawrence Dol Oct 11 '10 at 16:09
2  
The corner-case/problem is if you want to do, for example, public E[] toArray() { return (E[])internalArray.clone(); } when internalArray is typed as E[], and is therefore actually an Object[]. This fails at runtime with a type-cast exception because an Object[] cannot be assigned to an array of whatever type E happens to be. –  Lawrence Dol Aug 10 '11 at 20:04
9  
Basically, this approach will work as long as you do not return the array or pass it or store it in some place outside of the class that requires an array of a certain type. As long as you're inside the class you're fine because E is erased. It's "dangerous" because if you try to return it or something, you get no warning that it's unsafe. But if you're careful then it works. –  newacct Sep 23 '11 at 22:07
2  
It is quite safe. In E[] b = (E[])new Object[1]; you can clearly see that the only reference to the created array is b and that the type of b is E[]. Therefore there is no danger of you accidentally accessing the same array through a different variable of a different type. If instead, you had Object[] a = new Object[1]; E[]b = (E[])a; then you would need to be paranoid about how you use a. –  Aaron McDaid Jan 21 '12 at 19:53
3  
At least in Java 1.6, this generates a warning: "Unchecked cast from Object[] to T[]" –  Quantum7 Mar 24 '12 at 0:42

Here's how to use generics to get an array of precisely the type you’re looking for while preserving type safety (as opposed to the other answers, which will either give you back an Object array or result in warnings at compile time):

import java.lang.reflect.Array;  

public class GenSet<E>   {  
   private E[] a;  

   public GenSet(Class<E[]> clazz, int length)  {  
      a = clazz.cast(Array.newInstance(clazz.getComponentType(), length));  
   }  

   public static void main(String[] args)  {  
      GenSet<String> foo = new GenSet<String>(String[].class, 1);  
      String[] bar = foo.a;  
      foo.a[0] = "xyzzy";  
      String baz = foo.a[0];  
   }  
}

That compiles without warnings, and as you can see in main, for whatever type you declare an instance of GenSet as, you can assign a to an array of that type, and you can assign an element from a to a variable of that type, meaning that the array and the values in the array are of the correct type.

It works by using class literals as runtime type tokens, as discussed in the Java Tutorials. Class literals are treated by the compiler as instances of java.lang.Class. To use one, simply follow the name of a class with .class. So, String.class acts as a Class object representing the class String. This also works for interfaces, enums, any-dimensional arrays (e.g. String[].class), primitives (e.g. int.class), and the keyword void (i.e. void.class).

Class itself is generic (declared as Class<T>, where T stands for the type that the Class object is representing), meaning that the type of String.class is Class<String>.

So, whenever you call the constructor for GenSet, you pass in a class literal for the first argument representing an array of the GenSet instance's declared type (e.g. String[].class for GenSet<String>). Note that you won't be able to get an array of primitives, since primitives can't be used for type variables.

Inside the constructor, calling the method cast returns the passed Object argument cast to the class represented by the Class object on which the method was called. Calling the static method newInstance in java.lang.reflect.Array returns as an Object an array of the type represented by the Class object passed as the first argument and of the length specified by the int passed as the second argument. Calling the method getComponentType returns a Class object representing the component type of the array represented by the Class object on which the method was called (e.g. String.class for String[].class, null if the Class object doesn't represent an array).

That last sentence isn't entirely accurate. Calling String[].class.getComponentType() returns a Class object representing the class String, but its type is Class<?>, not Class<String>, which is why you can't do something like the following.

String foo = String[].class.getComponentType().cast("bar"); // won't compile

Same goes for every method in Class that returns a Class object.

Regarding Joachim Sauer's comment on this answer (I don't have enough reputation to comment on it myself), the example using the cast to T[] will result in a warning because the compiler can't guarantee type safety in that case.


Edit regarding Ingo's comments:

public static <T> T[] newArray(Class<T[]> type, int size) {
   return type.cast(Array.newInstance(type.getComponentType(), size));
}
share|improve this answer
2  
This is useless, it is only a complicated way to write new String[...]. But what is really needed is something like public static <T> T[] newArray(int size) { ... }, and this simply does not exist in java noir can it be simulated with reflection - the reason is that information about how a generic type is instantiated is not available at runtime. –  Ingo Mar 21 '11 at 10:11
2  
@Ingo What are you talking about? My code can be used to create an array of any type. –  gdejohn Mar 23 '11 at 12:34
    
@Charlatan: Sure, but so can new []. The question is: who knows the type and when. Therefore, if all you have is a generic type, you can't. –  Ingo Mar 23 '11 at 12:48
    
@Ingo That's static. This is dynamic. I'm not sure what you don't understand. –  gdejohn Mar 23 '11 at 12:54
    
I don't doubt that. The point is, you don't get a Class object at runtime for generic type X. –  Ingo Mar 23 '11 at 12:58

This is the only answer that is type safe

E[] a;


a = newArray(size);


@SafeVarargs
static <E> E[] newArray(int length, E... array)
{
    return Arrays.copyOf(array, length);
}
share|improve this answer
    
I had to look it up, but yes, the second "length" argument to Arrays#copyOf() is independent of the length of the array supplied as the first argument. That's clever, though it does pay the cost of calls to Math#min() and System#arrayCopy(), neither of which are strictly necessary to get this job done. docs.oracle.com/javase/7/docs/api/java/util/… –  seh Oct 4 '12 at 19:53

To extend to more dimensions, just add []'s and dimension parameters to newInstance() (T is a type parameter, cls is a Class<T>, d1 through d5 are integers):

T[] array = (T[])Array.newInstance(cls, d1);
T[][] array = (T[][])Array.newInstance(cls, d1, d2);
T[][][] array = (T[][][])Array.newInstance(cls, d1, d2, d3);
T[][][][] array = (T[][][][])Array.newInstance(cls, d1, d2, d3, d4);
T[][][][][] array = (T[][][][][])Array.newInstance(cls, d1, d2, d3, d4, d5);

See Array.newInstance() for details.

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1  
+1 There have been questions about multi-dimensional array creation that get closed as dupes of this post - but no answers had specifically addressed that. –  Paul Bellora Aug 15 '13 at 13:52
    
Could this be an answer here?: stackoverflow.com/q/5670972 –  JordanC Nov 11 at 19:48
    
@JordanC Maybe; although it is the same in spirit as stackoverflow.com/a/5671304/616460; I will think about best way to handle tomorrow. I am sleepy. –  Jason C Nov 12 at 5:19

This is covered in Chapter 5 (Generics) of Effective Java, 2nd Edition, item 25...Prefer lists to arrays

Your code will work, although it will generate an unchecked warning (which you could suppress with the following annotation:

@SuppressWarnings({"unchecked"})

However, it would probably be better to use a List instead of an Array.

There's an interesting discussion of this bug/feature on Sun's site.

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The example is using Java reflection to create an array. Doing this is generally not recommended, since it isn't typesafe. Instead, what you should do is just use an internal List, and avoid the array at all.

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9  
The second example (using Array.newInstance()) is in fact typesafe. This is possible because the type T of the Class object needs to match the T of the array. It basically forces you to provide the information that the Java runtime discards for generics. –  Joachim Sauer Feb 9 '09 at 22:41

Java generics work by checking types at compile time and inserting appropriate casts, but erasing the types in the compiled files. This makes generic libraries usable by code which doesn't understand generics (which was a deliberate design decision) but which means you can't normally find out what the type is at run time.

The public Stack(Class<T> clazz,int capacity) constructor requires you to pass a Class object at run time, which means class information is available at runtime to code that needs it. And the Class<T> form means that the compiler will check that the Class object you pass is precisely the Class object for type T. Not a subclass of T, not a superclass of T, but precisely T.

This then means that you can create an array object of the appropriate type in your constructor, which means that the type of the objects you store in your collection will have their types checked at the point they are added to the collection.

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Hi although the thread is dead, I would like to draw your attention to this:

Generics is used for type checking during compile time:

  • Therefore the purpose is to check that what comes in is what you need.
  • What you return is what the consumer needs.
  • Check this:

enter image description here

Do don't worry about typecasting warnings when you are writing generic class. Worry when you are using it.

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You could create an Object array and cast it to E everywhere. Yeah, it's not very clean way to do it but it should at least work.

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"We're looking for long answers that provide some explanation and context. Don't just give a one-line answer; explain why your answer is correct, ideally with citations. Answers without explanations may be removed." –  deleteme Sep 16 at 15:46
    
@damry, thank you for your pedantic comment on a 5 and half year old post. –  Esko Sep 16 at 19:36
    
Yeah, so? So what? To me, it doesn't matter if a post is old or not. –  deleteme Sep 16 at 20:54

try this.

private int m = 0;
private int n = 0;
private Element<T>[][] elements = null;

public MatrixData(int m, int n)
{
    this.m = m;
    this.n = n;

    this.elements = new Element[m][n];
    for (int i = 0; i < m; i++)
    {
        for (int j = 0; j < n; j++)
        {
            this.elements[i][j] = new Element<T>();
        }
    }
}
share|improve this answer

An easy, albeit messy workaround to this would be to nest a second "holder" class inside of your main class, and use it to hold your data.

public class Whatever<Thing>{
    private class Holder<OtherThing>{
        OtherThing thing;
    }
    public Holder<Thing>[] arrayOfHolders = new Holder<Thing>[10]
}
share|improve this answer
2  
This doesn't actually work. new Holder<Thing>[10] is a generic array creation. –  Radiodef Mar 10 at 19:43

I made this code snippet to reflectively instantiate a class which is passed for a simple automated test utility.

Object attributeValue = null;
try {
    if(clazz.isArray()){
        Class<?> arrayType = clazz.getComponentType();
        attributeValue = Array.newInstance(arrayType, 0);
    }
    else if(!clazz.isInterface()){
        attributeValue = BeanUtils.instantiateClass(clazz);
    }
} catch (Exception e) {
    logger.debug("Cannot instanciate \"{}\"", new Object[]{clazz});
}

Note this segment:

    if(clazz.isArray()){
        Class<?> arrayType = clazz.getComponentType();
        attributeValue = Array.newInstance(arrayType, 0);
    }

for array initiating where Array.newInstance(class of array, size of array). Class can be both primitive (int.class) and object (Integer.class).

BeanUtils is part of Spring.

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The forced cast suggested by other people did not work for me, throwing an exception of illegal casting.

However, this implicit cast worked fine:

Item<K>[] array = new Item[SIZE];

where Item is a class I defined containing the member:

private K value;

This way you get an array of type K (if the item only has the value) or any generic type you want defined in the class Item.

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You could use a cast:

public class GenSet<Item> {
    private Item[] a;

    public GenSet(int s) {
        a = (Item[]) new Object[s];
    }
}
share|improve this answer

Look also to this code:

public static <T> T[] toArray(final List<T> obj) {
    if (obj == null || obj.isEmpty()) {
        return null;
    }
    final T t = obj.get(0);
    final T[] res = (T[]) Array.newInstance(t.getClass(), obj.size());
    for (int i = 0; i < obj.size(); i++) {
        res[i] = obj.get(i);
    }
    return res;
}

It converts a list of any kind of object to an array of the same type.

share|improve this answer
    
This of course fails if the array is empty. –  Kevin Cox Feb 7 at 14:05
    
by array you mean obj? if so, I didn't get your point –  MatheusJardimB Feb 7 at 14:40
    
Yes, you return null, which isn't the expected empty array. It is the best you can do, but not ideal. –  Kevin Cox Feb 7 at 14:49
    
Thanks, got it :) –  MatheusJardimB Feb 7 at 14:50

Maybe unrelated to this question but while I was getting the "generic array creation" error for using

Tuple<Long,String>[] tupleArray = new Tuple<Long,String>[10];

I find out the following works (and worked for me) with @SuppressWarnings({"unchecked"}):

 Tuple<Long, String>[] tupleArray = new Tuple[10];
share|improve this answer
    
Yeah, this is not quite related, but rooted in the same issues (erasure, array covariance). Here's an example of a post about creating arrays of parameterized types: stackoverflow.com/questions/9542076/… –  Paul Bellora Aug 21 '13 at 16:23

I wanted to add this to the list here because I think it's rather nifty and I don't see anything like it. In Java 8, we can do a kind of generic array creation using a lambda.

@FunctionalInterface
public interface ArraySupplier<E> {
    public E[] get(int length);
}

public class GenericArrayHolder<E> {
    private final ArraySupplier<E> supplier;
    private E[] arr;

    public GenericArrayHolder(ArraySupplier<E> supplier) {
        this.supplier = supplier;
        arr = supplier.get(10);
    }
}

GenericArrayHolder<String> gh = (
    new GenericArrayHolder<>(String[]::new)
);

We can do stuff like that in pre-Java 8 using anonymous classes but it's not as nice as the above.

share|improve this answer

I'm wondering if this code would create an effective generic array?

public T [] createArray(int desiredSize){
    ArrayList<T> builder = new ArrayList<T>();
    for(int x=0;x<desiredSize;x++){
        builder.add(null);
    }
    return builder.toArray(zeroArray());
}

//zeroArray should, in theory, create a zero-sized array of T
//when it is not given any parameters.

private T [] zeroArray(T... i){
    return i;
}

Edit: Perhaps an alternate way of creating such an array, if the size you required was known and small, would be to simply feed the required number of "null"s into the zeroArray command?

Though obviously this isn't as versatile as using the createArray code.

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