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I was experimenting with the new Lambdas in Java 8, and I am looking for a way to use reflection on the lambda classes to get the return type of a lambda function. I am especially interested in cases where the lambda implements a generic superinterface. In the code example below, MapFunction<F, T> is the generic superinterface, and I am looking for a way to find out what type binds to the generic parameter T.

While Java throws away a lot of generic type information after the compiler, subclasses (and anonymous subclasses) of generic superclasses and generic superinterfaces did preserve that type information. Via reflection, these types were accessible. In the example below (case 1), reflection tells my that the MyMapper implementation of MapFunction binds java.lang.Integer to the generic type parameter T.

Even for subclasses that are themselves generic, there are certain means to find out what binds to a generic parameter, if some others are known. Consider case 2 in the example below, the IdentityMapper where both F and T bind to the same type. When we know that, we know the type F if we know the parameter type T (which in my case we do).

The question is now, how can I realize something similar for the Java 8 lambdas? Since they are actually not regular subclasses of the generic superinterface, the above described method does not work. Specifically, can I figure out that the parseLambda binds java.lang.Integer to T, and the identityLambda binds the same to F and T?

PS: In theory it should possible to decompile the lambda code and then use an embedded compiler (like the JDT) and tap into its type inference. I hope that there is a simpler way to do this ;-)

/**
 * The superinterface.
 */
public interface MapFunction<F, T> {

    T map(F value);
}

/**
 * Case 1: A non-generic subclass.
 */
public class MyMapper implements MapFunction<String, Integer> {

    public Integer map(String value) {
        return Integer.valueOf(value);
    }
}

/**
 * A generic subclass
 */
public class IdentityMapper<E> implements MapFunction<E, E> {

    public E map(E value) {
        return value;
    }

}

/**
 * Instantiation through lambda
 */

public MapFunction<String, Integer> parseLambda = (String str) -> { return Integer.valueOf(str); }

public MapFunction<E, E> identityLambda = (value) -> { return value; }


public static void main(String[] args)
{
    // case 1
    getReturnType(MyMapper.class);    // -> returns java.lang.Integer

    // case 2
    getReturnTypeRelativeToParameter(IdentityMapper.class, String.class);    // -> returns java.lang.String
}

private static Class<?> getReturnType(Class<?> implementingClass)
{
    Type superType = implementingClass.getGenericInterfaces()[0];

    if (superType instanceof ParameterizedType) {
        ParameterizedType parameterizedType = (ParameterizedType) superType;
        return (Class<?>) parameterizedType.getActualTypeArguments()[1];
    }
    else return null;
}

private static Class<?> getReturnTypeRelativeToParameter(Class<?> implementingClass, Class<?> parameterType)
{
    Type superType = implementingClass.getGenericInterfaces()[0];

    if (superType instanceof ParameterizedType) {
        ParameterizedType parameterizedType = (ParameterizedType) superType;
        TypeVariable<?> inputType = (TypeVariable<?>) parameterizedType.getActualTypeArguments()[0];
        TypeVariable<?> returnType = (TypeVariable<?>) parameterizedType.getActualTypeArguments()[1];

        if (inputType.getName().equals(returnType.getName())) {
            return parameterType;
        }
        else {
            // some logic that figures out composed return types
        }
    }

    return null;
}
share|improve this question
1  
Just a minor comment: public MapFunction<String, Integer> parseLambda = (String str) -> { return Integer.valueOf(str); } can be written as public MapFunction<String, Integer> parseLambda = str -> Integer.valueOf(str);. –  skiwi Feb 20 '14 at 9:58
    
I don't think it is possible. It seems Project Lambda authors tried to prevent reflection for some reason as stack trace gives no info about method names, and even method references don't give method name by reflection. –  user270349 Feb 21 '14 at 18:19
    
@skiwi: I've not yet written any Java 8 code but my understanding is that public MapFunction<String, Integer> parseLambda = Integer::valueOf; would be effectively equivalent. –  Joachim Sauer Dec 9 '14 at 15:41
    
@JoachimSauer That's correct –  skiwi Dec 9 '14 at 15:42

5 Answers 5

The exact decision how to map lambda code to interface implementations is left to the actual runtime environment. In principle, all lambdas implementing the same raw interface could share a single runtime class just like MethodHandleProxies does. Using different classes for specific lambdas is an optimization performed by the actual LambdaMetafactory implementation but not a feature intended to aid debugging or Reflection.

So even if you find more detailed information in the actual runtime class of a lambda interface implementation it will be an artifact of the currently used runtime environment which might not be available in different implementation or even other versions of your current environment.

If the lambda is Serializable you can use the fact that the serialized form contains the method signature of the instantiated interface type to puzzle the actual type variable values together.

share|improve this answer
    
Thanks a lot, the approach of serializable lambdas looks very promising. I think might be able to work with that. Thanks for the good pointer! –  user3311158 Mar 24 '14 at 12:41
2  
Really bad idea. Serialized lambdas have significantly higher performance costs compared to nonserializable lambdas, and are less secure (serialization is inherently a public hidden constructor to behavior and/or captured data that the programmer might have intended to stay private.) –  Brian Goetz May 27 '14 at 14:16

Parameterized type information is only available at runtime for elements of code that are bound - that is, specifically compiled into a type. Lambdas do the same thing, but as your Lambda is de-sugared to a method rather than to a type, there is no type to capture that information.

Consider the following:

import java.util.Arrays;
import java.util.function.Function;

public class Erasure {

    static class RetainedFunction implements Function<Integer,String> {
        public String apply(Integer t) {
            return String.valueOf(t);
        }
    }

    public static void main(String[] args) throws Exception {
        Function<Integer,String> f0 = new RetainedFunction();
        Function<Integer,String> f1 = new Function<Integer,String>() {
            public String apply(Integer t) {
                return String.valueOf(t);
            }
        };
        Function<Integer,String> f2 = String::valueOf;
        Function<Integer,String> f3 = i -> String.valueOf(i);

        for (Function<Integer,String> f : Arrays.asList(f0, f1, f2, f3)) {
            try {
                System.out.println(f.getClass().getMethod("apply", Integer.class).toString());
            } catch (NoSuchMethodException e) {
                System.out.println(f.getClass().getMethod("apply", Object.class).toString());
            }
            System.out.println(Arrays.toString(f.getClass().getGenericInterfaces()));
        }
    }
}

f0 and f1 both retain their generic type information, as you'd expect. But as they're unbound methods that have been erased to Function<Object,Object>, f2 and f3 do not.

share|improve this answer
up vote 2 down vote accepted

I have found a way of doing it for serializable lambdas. All my lambdas are serializable, to that works.

Thanks, Holger, for pointing me to the SerializedLambda.

The generic parameters are captured in the lambda's synthetic static method and can be retrieved from there. Finding the static method that implements the lambda is possible with the information from the SerializedLambda

The steps are as follows:

  1. Get the SerializedLambda via the write replacement method that is auto-generated for all serializable lambdas
  2. Find the class that contains the lambda implementation (as a synthetic static method)
  3. Get the java.lang.reflect.Method for the synthetic static method
  4. Get generic types from that Method

UPDATE: Apparently, this does not work with all compilers. I have tried it with the compiler of Eclipse Luna (works) and the Oracle javac (does not work).


// sample how to use
public static interface SomeFunction<I, O> extends java.io.Serializable {

    List<O> applyTheFunction(Set<I> value);
}

public static void main(String[] args) throws Exception {

    SomeFunction<Double, Long> lambda = (set) -> Collections.singletonList(set.iterator().next().longValue());

    SerializedLambda sl = getSerializedLambda(lambda);      
    Method m = getLambdaMethod(sl);

    System.out.println(m);
    System.out.println(m.getGenericReturnType());
    for (Type t : m.getGenericParameterTypes()) {
        System.out.println(t);
    }

    // prints the following
    // (the method) private static java.util.List test.ClassWithLambdas.lambda$0(java.util.Set)
    // (the return type, including *Long* as the generic list type) java.util.List<java.lang.Long>
    // (the parameter, including *Double* as the generic set type) java.util.Set<java.lang.Double>

// getting the SerializedLambda
public static SerializedLambda getSerializedLambda(Object function) {
    if (function == null || !(function instanceof java.io.Serializable)) {
        throw new IllegalArgumentException();
    }

    for (Class<?> clazz = function.getClass(); clazz != null; clazz = clazz.getSuperclass()) {
        try {
            Method replaceMethod = clazz.getDeclaredMethod("writeReplace");
            replaceMethod.setAccessible(true);
            Object serializedForm = replaceMethod.invoke(function);

            if (serializedForm instanceof SerializedLambda) {
                return (SerializedLambda) serializedForm;
            }
        }
        catch (NoSuchMethodError e) {
            // fall through the loop and try the next class
        }
        catch (Throwable t) {
            throw new RuntimeException("Error while extracting serialized lambda", t);
        }
    }

    throw new Exception("writeReplace method not found");
}

// getting the synthetic static lambda method
public static Method getLambdaMethod(SerializedLambda lambda) throws Exception {
    String implClassName = lambda.getImplClass().replace('/', '.');
    Class<?> implClass = Class.forName(implClassName);

    String lambdaName = lambda.getImplMethodName();

    for (Method m : implClass.getDeclaredMethods()) {
        if (m.getName().equals(lambdaName)) {
            return m;
        }
    }

    throw new Exception("Lambda Method not found");
}
share|improve this answer
    
Note that SerializedLambda.getImplMethodSignature() already provides the type signature of the lambda’s synthetic method. It’s better to use that as the method name is not guaranteed to be unique. –  Holger Sep 8 '14 at 8:38
    
So what is it that happens on Oracle Javac? –  Antti Haapala Oct 31 '14 at 8:20
    
FYI: The Eclipse compiler supported this unintentional. Version 4.5 M4 will allow it with help of a compiler option "-genericsignature" (bugs.eclipse.org/bugs/show_bug.cgi?id=449063) –  twalthr Dec 12 '14 at 11:47

This is currently possible to solve but only in a pretty hackie way, but let me first explain a few things:

When you write a lambda, the compiler inserts a dynamic invoke instruction pointing to the LambdaMetafactory and a private static synthetic method with the body of the lambda. The synthetic method and the method handle in the constant pool both contain the generic type (if the lambda uses the type or is explicit as in your examples).

Now at runtime the LambdaMetaFactory is called and a class is generated using ASM that implements the functional interface and the body of the method then calls the private static method with any arguments passed. It is then injected into the original class using Unsafe.defineAnonymousClass (see John Rose post) so it can access the private members etc.

Unfortunately the generated Class does not store the generic signatures (it could) so you can't use the usual reflection methods that allow you to get around erasure

For a normal Class you could inspect the bytecode using Class.getResource(ClassName + ".class") but for anonymous classes defined using Unsafe you are out of luck. However you can make the LambdaMetaFactory dump them out with the JVM argument:

java -Djdk.internal.lambda.dumpProxyClasses=/some/folder

By looking at the dumped class file (using javap -p -s -v), one can see that it does indeed call the static method. But the problem remains how to get the bytecode from within Java itself.

This unfortunately is where it gets hackie:

Using reflection we can call Class.getConstantPool and then access the MethodRefInfo to get the type descriptors. We can then use ASM to parse this and return the argument types. Putting it all together:

Method getConstantPool = Class.class.getDeclaredMethod("getConstantPool");
getConstantPool.setAccessible(true);
ConstantPool constantPool = (ConstantPool) getConstantPool.invoke(lambda.getClass());
String[] methodRefInfo = constantPool.getMemberRefInfoAt(constantPool.size() - 2);

int argumentIndex = 0;
String argumentType = jdk.internal.org.objectweb.asm.Type.getArgumentTypes(methodRef[2])[argumentIndex].getClassName();
Class<?> type = (Class<?>) Class.forName(argumentType);

Updated with jonathan's suggestion

Now ideally the classes generated by LambdaMetaFactory should store the generic type signatures (I might see if I can submit a patch to the OpenJDK) but currently this is the best we can do. The code above has the following problems:

  • It uses undocumented methods and classes
  • It is extremely vulnerable to code changes in the JDK
  • It doesn't preserve the generic types, so if you pass List<String> into a lambda it will come out as List
share|improve this answer
    
Wow, this looks like serious business ;-) The solution outlined by me above is quite a bit simpler, but unfortunately does not work with the OpenJDK compiler (or the Oracle compiler), but only with the Eclipse compiler - the latter stores the generic method signature in the class file. The Method object can use that signature to get the generic parameter types and the generic return type. Submitting a patch to the OpenJDK team to include that signature in a similar way would be the perfect solution. Is it possible to make such suggestions? –  user3311158 Sep 8 '14 at 17:56
1  
This example will work for java.util.function.Function but not for some other functional interfaces since the member ref is located at different indexes. For Oracle JDK and Open JDK the member ref can be reliably obtained via constantPool.getMemberRefInfoAt(constantPool.size() - 2) –  Jonathan Dec 8 '14 at 18:14
    
Thanks Jonathan –  danielbodart Dec 9 '14 at 15:35
    
@danielbodart "Unfortunately the generated Class does not store the generic signatures (it could) so you can't use the usual reflection methods that allow you to get around erasure" - Why? You can reflect the generic type of an anonomous innerclass, but not lambda :( This is a bug in my opinion. –  momo Dec 18 '14 at 14:47
    
@danielbodart Is it possible to get the generic type, as one can with a class or anonymous inner class using getActualTypeArguments? Tehre is no information when switched to a lambda. –  momo Dec 18 '14 at 14:49

I recently added support for resolving lambda type arguments to TypeTools. Ex:

MapFunction<String, Integer> fn = str -> Integer.valueOf(str);
Class<?>[] typeArgs = TypeResolver.resolveRawArguments(MapFunction.class, fn.getClass());

The resolved type args are as expected:

assert typeArgs[0] == String.class;
assert typeArgs[1] == Integer.class;

To handle a passed lambda:

public void call(Callable<?> c) {
  // Assumes c is a lambda
  Class<?> callableType = TypeResolver.resolveRawArguments(Callable.class, c.getClass());
}

Note: The underlying implementation uses the ConstantPool approach outlined by @danielbodart which is known to work on Oracle JDK and OpenJDK (and possibly others).

share|improve this answer
    
Wait, I haven't checked your link it, but if you can do this, then I love you! –  momo Dec 18 '14 at 14:50
    
I looked at, but Jonathan, what I am looking for is to get the generic type of a passed lambda. I am not sure I understand the API, or that it can do this. interface Lamb<GenericType> { ... } (String str) -> {} ... do you understand what I am after? –  momo Dec 18 '14 at 15:05
    
Actually, I am not after the method String parameter, but the exception type that is thrown and defined by the generic type. MyInterface<E extends Throwable> { void call() throws E; } ... () { doSomthingThatThrowsE() } –  momo Dec 18 '14 at 15:25
    
I updated my post to include how to resolve type args from a passed lambda. Re: the exception type, you may be able to get that somehow via reflection, but it's not something TypeTools does right now. –  Jonathan Dec 18 '14 at 17:52

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