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The problem: I've a Function Object interface defined in a class:

    public static interface FunctionObject<T>  {
        void process(T object);

I need it generic because I'd like to use T methods in the process implementations.
Then, in other generic class, I've a Map where I have classes as keys and function objects as values:

    Map<Class<T>, FunctionObject<T>> map;

But I also want the map to accept subtype classes and function objects of supertypes OF THE KEY TYPE, so I did this:

    Map<Class<? extends T>, FunctionObject<? super T>> map; //not what I need

The basic idea is to be able to use the map as follows:

    //if T were Number, this should be legal
    map.put(Class<Integer>, new FunctionObject<Integer>(){...});
    map.put(Class<Float>, new FunctionObject<Number>(){...});
    map.put(Class<Double>, new FunctionObject<Object>(){...});

As I want to enforce the FunctionObject has the type of the class key or a supertype, what I really would like to define is this:

    Map<Class<E extends T>, FunctionObject<? super E>>> map;

How can I achieve the desired effect? Is a typesafe heterogenous container the only option? What would the Map generic types look like to allow populating it from a reference?

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2 Answers 2

up vote 3 down vote accepted

Parametrized container, seems to work just fine:

public class MyMap<T>
    interface FunctionObject<X> {}

    private Map<Class<? extends T>, FunctionObject<Object>> map = new HashMap<>();

    public <E extends T> void put(Class<E> c, FunctionObject<? super E> f)
        map.put(c, (FunctionObject<Object>) f);

    public <E extends T> FunctionObject<Object> get(Class<E> c)
        return map.get(c);

    public static void Main(String[] args)
        MyMap<Number> map = new MyMap<>();

        map.put(Integer.class, new FunctionObject<Integer>() {});
        map.put(Float.class, new FunctionObject<Number>() {});
        map.put(Double.class, new FunctionObject<Object>() {});

Edited to comply to the question. Sadly there is no way to avoid the downcasting to object.

Edit added get().

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Could work depending on use case. –  Peter Lawrey Jan 13 '12 at 10:44
Yes, but implementing the get is when the fun starts XD. –  Mister Smith Jan 13 '12 at 10:57
The get() can only ever return FunctionObject<Object>(): since the parameter is a superclass of T and the key, there is no way to establish an upper bound. I added it to the answer. –  Viruzzo Jan 13 '12 at 11:00
I think it is a reasonable concession to make. –  Mister Smith Jan 13 '12 at 11:26
There is really no alternative: unless you specify an upper bound, there is no way for Java to know which superclass of the key type the value had, so it must default to Object. You can manually upcast it in the specific place if you can make a valid assumption on the type (but then, why use generics?). –  Viruzzo Jan 13 '12 at 11:30

You can do this with encapsulation, assuming you only use the map through the method which check this on a per entry basis.

The following add method avoids the need to double up on the type as well.

public class Main {
interface FunctionObject<T> { }

private final Map<Class, FunctionObject> map = new LinkedHashMap<Class, FunctionObject>();

public <T> void add(FunctionObject<T> functionObject) {
    Class<T> tClass = null;
    for (Type iType : functionObject.getClass().getGenericInterfaces()) {
        ParameterizedType pt = (ParameterizedType) iType;
        if (!pt.getRawType().equals(FunctionObject.class)) continue;
        Type t = pt.getActualTypeArguments()[0];
        tClass = (Class<T>) t;
    map.put(tClass, functionObject);

public <T> void put(Class<T> tClass, FunctionObject<T> functionObject) {
    map.put(tClass, functionObject);

public <T> FunctionObject<T> get(Class<T> tClass) {
    return map.get(tClass);

public static void main(String... args) throws IOException {
    Main m = new Main();
    m.add(new FunctionObject<Integer>() {
    FunctionObject<Integer> foi = m.get(Integer.class);



You can use @SuppressWarnings("unchecked") if you want to disable the warning.

The point is; there is no way to describe the constraint you have in the field declaration, you can achieve the same result if you use accessor methods which do the check on a per entry basis. You can add runtime checks as well if you need to ensure raw types are correct.

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But this only allows type T and nothing more, isn't it? And by the way, that Map declaration gives a warning for using raw types. –  Mister Smith Jan 13 '12 at 9:40
Yes, that's the point of Peter's answer: it's not the map that guarantees the type safety. It's the fact that the only way to put/get values in/from the map is to use these methods, which always associate a Funtion<T> with a Class<T>. Of course, if you use raw types when calling these methods, you don't have any guarantee. –  JB Nizet Jan 13 '12 at 9:43
Ok, so there's no choice but to code a typesafe container. I wonder if this is the same in C#. –  Mister Smith Jan 13 '12 at 9:58
Can't you make an encapsulating parametric class then? To avoid warnings and inconsistencies. –  Viruzzo Jan 13 '12 at 10:01
You can add SupressWarning at the start of the class. The warnings make sense because you are trying to do something which the compiler doesn't directly support so it can't check what you are doing is entirely safe. –  Peter Lawrey Jan 13 '12 at 13:56

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