I have a generics class, Foo<T>. In a method of Foo, I want to get the class instance of type T, but I just can't call T.class.

What is the preferred way to get around it using T.class?

17 Answers 17

up vote 467 down vote accepted

The short answer is, that there is no way to find out the runtime type of generic type parameters in Java. I suggest reading the chapter about type erasure in the Java Tutorial for more details.

A popular solution to this is to pass the Class of the type parameter into the constructor of the generic type, e.g.

class Foo<T> {
    final Class<T> typeParameterClass;

    public Foo(Class<T> typeParameterClass) {
        this.typeParameterClass = typeParameterClass;
    }

    public void bar() {
        // you can access the typeParameterClass here and do whatever you like
    }
}
  • 56
    This answer does provide a valid solution but it is inaccurate to say there is no way to find the generic type at runtime. It turns out type erasure is far more complex than a blanket erasure. My answer shows you how to get the classes generic type. – Ben Thurley Nov 22 '12 at 10:58
  • 3
    @BenThurley Neat trick, but as far as I can see it only works if there is a generic supertype for it to use. In my example, you can't retrieve the type of T in Foo<T>. – Zsolt Török Jun 10 '13 at 9:54
  • 3
    Fair point about a generic supertype. I can't think of an occasion where I've used generics without one though, except in exam questions. I've added the extra detail to my answer to make it clearer. Thanks. – Ben Thurley Jun 17 '13 at 11:09
  • 1
    @ses I've yet to see a language that is. They're all a compromise in one way or another. Anyone who tells you otherwise has yet to learn. ;) – Ben Thurley Sep 14 '13 at 22:47
  • 3
    This would fail if you @Autowire where spring will look for the empty constructor – madhairsilence Feb 20 '17 at 6:30

I was looking for a way to do this myself without adding an extra dependency to the classpath. After some investigation I found that it is possible as long as you have a generic supertype. This was OK for me as I was working with a DAO layer with a generic layer supertype. If this fits your scenario then it's the neatest approach IMHO.

Most generics use cases I've come across have some kind of generic supertype e.g. List<T> for ArrayList<T> or GenericDAO<T> for DAO<T>, etc.

Pure Java solution

The article Accessing generic types at runtime in Java explains how you can do it using pure Java.

Spring solution

My project was using Spring which is even better as Spring has a handy utility method for finding the type. This is the best approach for me as it looks neatest. I guess if you weren't using Spring you could write your own utility method.

import org.springframework.core.GenericTypeResolver;

public abstract class AbstractHibernateDao<T extends DomainObject> implements DataAccessObject<T>
{

    @Autowired
    private SessionFactory sessionFactory;

    private final Class<T> genericType;

    private final String RECORD_COUNT_HQL;
    private final String FIND_ALL_HQL;

    @SuppressWarnings("unchecked")
    public AbstractHibernateDao()
    {
        this.genericType = (Class<T>) GenericTypeResolver.resolveTypeArgument(getClass(), AbstractHibernateDao.class);
        this.RECORD_COUNT_HQL = "select count(*) from " + this.genericType.getName();
        this.FIND_ALL_HQL = "from " + this.genericType.getName() + " t ";
    }
  • 1
    please clarify meaning of resolveTypeArgument arguments – gstackoverflow Dec 14 '15 at 16:21
  • getClass() is a method of java.lang.Object which will return the class of the specific object at runtime, this is the object you want to resolve the type for. AbstractHibernateDao.class is just the name of the base class or superclass of the generic type class hierarchy. The import statement is included so you should be able to easily find the docs and check yourself. This is the page docs.spring.io/spring/docs/current/javadoc-api/org/… – Ben Thurley Dec 14 '15 at 16:30
  • What is the spring solution with version 4.3.6 and higher. It doesn't work with spring 4.3.6. – Erlan Mar 3 '17 at 7:20
  • @Erlan are you sure? I just checked the docs and this class is still present and the methods here haven't been deprecated. – Ben Thurley Jun 22 '17 at 11:20
  • 1
    @AlikElzin-kilaka it gets initialised in the constructor using the Spring class GenericTypeResolver. – Ben Thurley Sep 5 at 11:24

There is a small loophole however: if you define your Foo class as abstract. That would mean you have to instantiate you class as:

Foo<MyType> myFoo = new Foo<MyType>(){};

(Note the double braces at the end.)

Now you can retrieve the type of T at runtime:

Type mySuperclass = myFoo.getClass().getGenericSuperclass();
Type tType = ((ParameterizedType)mySuperclass).getActualTypeArguments()[0];

Note however that mySuperclass has to be the superclass of the class definition actually defining the final type for T.

It is also not very elegant, but you have to decide whether you prefer new Foo<MyType>(){} or new Foo<MyType>(MyType.class); in your code.


For example:

import java.lang.reflect.ParameterizedType;
import java.lang.reflect.Type;

import java.util.ArrayDeque;
import java.util.Deque;
import java.util.NoSuchElementException;

/**
 * Captures and silently ignores stack exceptions upon popping.
 */
public abstract class SilentStack<E> extends ArrayDeque<E> {
  public E pop() {
    try {
      return super.pop();
    }
    catch( NoSuchElementException nsee ) {
      return create();
    }
  }

  public E create() {
    try {
      Type sooper = getClass().getGenericSuperclass();
      Type t = ((ParameterizedType)sooper).getActualTypeArguments()[ 0 ];

      return (E)(Class.forName( t.toString() ).newInstance());
    }
    catch( Exception e ) {
      return null;
    }
  }
}

Then:

public class Main {
    // Note the braces...
    private Deque<String> stack = new SilentStack<String>(){};

    public static void main( String args[] ) {
      // Returns a new instance of String.
      String s = stack.pop();
      System.out.printf( "s = '%s'\n", s );
    }
}
  • 5
    This is easily the best answer on here! Also, for what it's worth, this is the strategy that Google Guice uses for binding classes with TypeLiteral – ATG Jun 5 '14 at 23:44
  • 13
    Note that every time this method of object construction is used, a new anonymous class is created. In other words, two objects a and b created this way will both extend the same class but not have identical instance classes. a.getClass() != b.getClass() – Martin Serrano Mar 20 '15 at 17:04
  • 3
    There is one scenario in which this doesn't work. If Foo should implement an interface, such as Serializable, than the anonymous class would not be Serializable unless the class instantiating is. I tried to workaround it by creating a serializable factory class that creates the anonymous class derived from Foo, but then, for some reason, getActualTypeArguments returns the generic type instead of the actual class. For example: (new FooFactory<MyType>()).createFoo() – Lior Chaga May 7 '15 at 9:25

A standard approach/workaround/solution is to add a class object to the constructor(s), like:

 public class Foo<T> {

    private Class<T> type;
    public Foo(Class<T> type) {
      this.type = type;
    }

    public Class<T> getType() {
      return type;
    }

    public T newInstance() {
      return type.newInstance();
    }
 }
  • But it seemed cannot @autowired in actual use, any way to work around? – Alfred Huang Feb 2 at 7:16

Imagine you have an abstract superclass that is generic:

public abstract class Foo<? extends T> {}

And then you have a second class that extends Foo with a generic Bar that extends T:

public class Second extends Foo<Bar> {}

You can get the class Bar.class in the Foo class by selecting the Type (from bert bruynooghe answer) and infering it using Class instance:

Type mySuperclass = myFoo.getClass().getGenericSuperclass();
Type tType = ((ParameterizedType)mySuperclass).getActualTypeArguments()[0];
//Parse it as String
String className = tType.toString().split(" ")[1];
Class clazz = Class.forName(className);

You have to note this operation is not ideal, so it is a good idea to cache the computed value to avoid multiple calculations on this. One of the typical uses is in generic DAO implementation.

The final implementation:

public abstract class Foo<T> {

    private Class<T> inferedClass;

    public Class<T> getGenericClass(){
        if(inferedClass == null){
            Type mySuperclass = getClass().getGenericSuperclass();
            Type tType = ((ParameterizedType)mySuperclass).getActualTypeArguments()[0];
            String className = tType.toString().split(" ")[1];
            inferedClass = Class.forName(className);
        }
        return inferedClass;
    }
}

The value returned is Bar.class when invoked from Foo class in other function or from Bar class.

  • 1
    toString().split(" ")[1] that was the problem, avoid the "class " – IgniteCoders May 10 '16 at 19:09

Here is a working solution:

@SuppressWarnings("unchecked")
private Class<T> getGenericTypeClass() {
    try {
        String className = ((ParameterizedType) getClass().getGenericSuperclass()).getActualTypeArguments()[0].getTypeName();
        Class<?> clazz = Class.forName(className);
        return (Class<T>) clazz;
    } catch (Exception e) {
        throw new IllegalStateException("Class is not parametrized with generic type!!! Please use extends <> ");
    }
} 

NOTES: Can be used only as superclass

  1. Has to be extended with typed class (Child extends Generic<Integer>)

OR

  1. Has to be created as anonymous implementation (new Generic<Integer>() {};)
  • Only works since 1.8 (getTypeName()) – Aure77 Jan 18 '16 at 14:10
  • 2
    getTypeName calls toString, so can be replaced by .getActualTypeArguments()[0].toString(); – Yaroslav Kovbas Jan 20 '16 at 14:50

You can't do it because of type erasure. See also Stack Overflow question Java generics - type erasure - when and what happens.

I had this problem in an abstract generic class. In this particular case, the solution is simpler:

abstract class Foo<T> {
    abstract Class<T> getTClass();
    //...
}

and later on the derived class:

class Bar extends Foo<Whatever> {
    @Override
    Class<T> getTClass() {
        return Whatever.class;
    }
}

A better route than the Class the others suggested is to pass in an object that can do what you would have done with the Class, e.g., create a new instance.

interface Factory<T> {
  T apply();
}

<T> void List<T> make10(Factory<T> factory) {
  List<T> result = new ArrayList<T>();
  for (int a = 0; a < 10; a++)
    result.add(factory.apply());
  return result;
}

class FooFactory<T> implements Factory<Foo<T>> {
  public Foo<T> apply() {
    return new Foo<T>();
  }
}

List<Foo<Integer>> foos = make10(new FooFactory<Integer>());
  • Elegant solution – Stephan Nov 17 '11 at 15:37
  • @ Ricky Clarkson: I don't see how this factory should return parametrized foos. Could you please explain how you get Foo<T> out of this? It seems to me this gives only unparametrized Foo. Isn't the T in make10 simply Foo here? – ib84 Mar 13 '13 at 9:03
  • @ib84 I've fixed the code; I seem to have missed that Foo was parameterised when I wrote the answer originally. – Ricky Clarkson Mar 14 '13 at 13:04

It's possible:

class Foo<T> {
  Class<T> clazz = (Class<T>) DAOUtil.getTypeArguments(Foo.class, this.getClass()).get(0);
}

You need two functions from svn/trunk/dao/src/main/java/com/googlecode/genericdao/dao/ DAOUtil.java.

For more explanations, see Reflecting generics.

I have an (ugly but effective) solution for this problem, which I used recently:

import java.lang.reflect.TypeVariable;


public static <T> Class<T> getGenericClass()
{
    __<T> ins = new __<T>();
    TypeVariable<?>[] cls = ins.getClass().getTypeParameters(); 

    return (Class<T>)cls[0].getClass();
}

private final class __<T> // generic helper class which does only provide type information
{
    private __()
    {
    }
}

I found a generic and simple way to do that. In my class I created a method that returns the generic type according to it's position in the class definition. Let's assume a class definition like this:

public class MyClass<A, B, C> {

}

Now let's create some attributes to persist the types:

public class MyClass<A, B, C> {

    private Class<A> aType;

    private Class<B> bType;

    private Class<C> cType;

// Getters and setters (not necessary if you are going to use them internally)

    } 

Then you can create a generic method that returns the type based on the index of the generic definition:

   /**
     * Returns a {@link Type} object to identify generic types
     * @return type
     */
    private Type getGenericClassType(int index) {
        // To make it use generics without supplying the class type
        Type type = getClass().getGenericSuperclass();

        while (!(type instanceof ParameterizedType)) {
            if (type instanceof ParameterizedType) {
                type = ((Class<?>) ((ParameterizedType) type).getRawType()).getGenericSuperclass();
            } else {
                type = ((Class<?>) type).getGenericSuperclass();
            }
        }

        return ((ParameterizedType) type).getActualTypeArguments()[index];
    }

Finally, in the constructor just call the method and send the index for each type. The complete code should look like:

public class MyClass<A, B, C> {

    private Class<A> aType;

    private Class<B> bType;

    private Class<C> cType;


    public MyClass() {
      this.aType = (Class<A>) getGenericClassType(0);
      this.bType = (Class<B>) getGenericClassType(1);
      this.cType = (Class<C>) getGenericClassType(2);
    }

   /**
     * Returns a {@link Type} object to identify generic types
     * @return type
     */
    private Type getGenericClassType(int index) {

        Type type = getClass().getGenericSuperclass();

        while (!(type instanceof ParameterizedType)) {
            if (type instanceof ParameterizedType) {
                type = ((Class<?>) ((ParameterizedType) type).getRawType()).getGenericSuperclass();
            } else {
                type = ((Class<?>) type).getGenericSuperclass();
            }
        }

        return ((ParameterizedType) type).getActualTypeArguments()[index];
    }
}

As explained in other answers, to use this ParameterizedType approach, you need to extend the class, but that seems like extra work to make a whole new class that extends it...

So, making the class abstract it forces you to extend it, thus satisfying the subclassing requirement. (using lombok's @Getter).

@Getter
public abstract class ConfigurationDefinition<T> {

    private Class<T> type;
    ...

    public ConfigurationDefinition(...) {
        this.type = (Class<T>) ((ParameterizedType) this.getClass().getGenericSuperclass()).getActualTypeArguments()[0];
        ...
    }
}

Now to extend it without defining a new class. (Note the {} on the end... extended, but don't overwrite anything - unless you want to).

private ConfigurationDefinition<String> myConfigA = new ConfigurationDefinition<String>(...){};
private ConfigurationDefinition<File> myConfigB = new ConfigurationDefinition<File>(...){};
...
Class stringType = myConfigA.getType();
Class fileType = myConfigB.getType();
   public <T> T yourMethodSignature(Class<T> type) {

        // get some object and check the type match the given type
        Object result = ...            

        if (type.isAssignableFrom(result.getClass())) {
            return (T)result;
        } else {
            // handle the error
        }
   }

If you are extending or implementing any class/interface that are using generics , you may get the Generic Type of parent class/interface, without modifying any existing class/interface at all.

There could be three possibilities,

Case 1 When your class is extending a class that is using Generics

public class TestGenerics {
    public static void main(String[] args) {
        Type type = TestMySuperGenericType.class.getGenericSuperclass();
        Type[] gTypes = ((ParameterizedType)type).getActualTypeArguments();
        for(Type gType : gTypes){
            System.out.println("Generic type:"+gType.toString());
        }
    }
}

class GenericClass<T> {
    public void print(T obj){};
}

class TestMySuperGenericType extends GenericClass<Integer> {
}

Case 2 When your class is implementing an interface that is using Generics

public class TestGenerics {
    public static void main(String[] args) {
        Type[] interfaces = TestMySuperGenericType.class.getGenericInterfaces();
        for(Type type : interfaces){
            Type[] gTypes = ((ParameterizedType)type).getActualTypeArguments();
            for(Type gType : gTypes){
                System.out.println("Generic type:"+gType.toString());
            }
        }
    }
}

interface GenericClass<T> {
    public void print(T obj);
}

class TestMySuperGenericType implements GenericClass<Integer> {
    public void print(Integer obj){}
}

Case 3 When your interface is extending an interface that is using Generics

public class TestGenerics {
    public static void main(String[] args) {
        Type[] interfaces = TestMySuperGenericType.class.getGenericInterfaces();
        for(Type type : interfaces){
            Type[] gTypes = ((ParameterizedType)type).getActualTypeArguments();
            for(Type gType : gTypes){
                System.out.println("Generic type:"+gType.toString());
            }
        }
    }
}

interface GenericClass<T> {
    public void print(T obj);
}

interface TestMySuperGenericType extends GenericClass<Integer> {
}

Actually, I suppose you have a field in your class of type T. If there's no field of type T, what's the point of having a generic Type? So, you can simply do an instanceof on that field.

In my case, I have a

List<T> items;
in my class, and I check if the class type is "Locality" by

if (items.get(0) instanceof Locality) ...

Of course, this only works if the total number of possible classes is limited.

I'm using workaround for this:

class MyClass extends Foo<T> {
....
}

MyClass myClassInstance = MyClass.class.newInstance();

Your Answer

 

By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

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