I keep hearing about all the new cool features that are being added to the JVM and one of those cool features is invokedynamic. I would like to know what it is and how does it make reflective programming in Java easier or better?


It is a new JVM instruction which allows a compiler to generate code which calls methods with a looser specification than was previously possible -- if you know what "duck typing" is, invokedynamic basically allows for duck typing. There's not too much you as a Java programmer can do with it; if you're a tool creator, though, you can use it to build more flexible, more efficient JVM-based languages. Here is a really sweet blog post that gives a lot of detail.

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    In day to day Java programming it is not uncommon to see reflection being used to invoke methods dynamically with meth.invoke(args). So how does invokedynamic fit with meth.invoke? – David K. Jul 10 '11 at 2:26
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    The blog post I mention talks about MethodHandle, which is really the same kind of thing but with much more flexibility. But the real power in all this comes not in additions to the Java language, but in the capabilities of the JVM itself in supporting other languages that are intrinsically more dynamic. – Ernest Friedman-Hill Jul 10 '11 at 2:28
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    +1 for the "really sweet blog post that gives a lot of detail". – ntc2 Dec 12 '13 at 1:56
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    Seems that Java 8 translates some of the lambdas using invokedynamic which makes it performant (compared to wrap them in an anonymous inner-class which was almost the only choice before introducing invokedynamic). Most probably a lot of functional programming languages on top of JVM will opt to compile to this instead of anon-inner-classes. – Nader Ghanbari Feb 21 '15 at 11:34
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    Just a small warning, that blog post from 2008 is hopelessly outdated and doesn’t reflect the actual release state (2011). – Holger Jun 21 '17 at 9:06

Some time ago, C# added a cool feature, dynamic syntax within C#

Object obj = ...; // no static type available 
dynamic duck = obj;
duck.quack(); // or any method. no compiler checking.

Think of it as syntax sugar for reflective method calls. It can have very interesting applications. see http://www.infoq.com/presentations/Statically-Dynamic-Typing-Neal-Gafter

Neal Gafter, who's responsible for C#'s dynamic type, just defected from SUN to MS. So it's not unreasonable to think that the same things had been discussed inside SUN.

I remember soon after that, some Java dude announced something similar

InvokeDynamic duck = obj;

Unfortunately, the feature is no where to be found in Java 7. Very disappointed. For Java programmers, they have no easy way to take advantage of invokedynamic in their programs.

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    invokedynamic was never intended to be used for Java programmers. IMO it doesn't fit the Java philosophy at all. It was added as a JVM feature for non-Java languages. – Mark Peters Jul 10 '11 at 5:05
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    @Mark Never intended by who? It's not like there's a clear power structure in Java language celebrities, or there's a well defined collective "intention". As for language philosophy - it's quite feasible, see Neal Gafter (traitor!) explanation: infoq.com/presentations/Statically-Dynamic-Typing-Neal-Gafter – irreputable Jul 10 '11 at 5:58
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    @mark peters: invokedynamic is actually also intended for java programmers only not directly accessible. It's the basis for Java 8's closures. – M Platvoet Jul 10 '11 at 6:34
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    @irreputable: Never intended by the JSR contributors. It's telling that the name of the JSR is "Supporting Dynamically Typed Languages on the Java Platform". Java isn't a dynamically typed language. – Mark Peters Jul 10 '11 at 16:33
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    @M Platvoet: I haven't stayed up to date with closures, but it certainly wouldn't be an absolute requirement for closures. Another option they discussed was simply making closures syntactic sugar for anonymous inner classes which could be done without a VM spec change. But my point was that the JSR was never intended to bring dynamic typing to the Java language, that much is clear if you read the JSR. – Mark Peters Jul 10 '11 at 16:36

As part of my Java Records article, I articulated about the motivation behind Inoke Dynamic. Let's start with a rough definition of Indy.

Introducing Indy

Invoke Dynamic (Also known as Indy) was part of JSR 292 intending to enhance the JVM support for Dynamic Type Languages. After its first release in Java 7, The invokedynamic opcode along with its java.lang.invoke luggage is used quite extensively by dynamic JVM-based languages like JRuby.

Although indy specifically designed to enhance the dynamic language support, it offers much more than that. As a matter of fact, it’s suitable to use wherever a language designer needs any form of dynamicity, from dynamic type acrobatics to dynamic strategies!

For instance, the Java 8 Lambda Expressions are actually implemented using invokedynamic, even though Java is a statically typed language!

User-Definable Bytecode

For quite some time JVM did support four method invocation types: invokestatic to call static methods, invokeinterface to call interface methods, invokespecial to call constructors, super() or private methods and invokevirtual to call instance methods.

Despite their differences, these invocation types share one common trait: we can’t enrich them with our own logic. On the contrary, invokedynamic enables us to Bootstrap the invocation process in any way we want. Then the JVM takes care of calling the Bootstrapped Method directly.

How Does Indy Work?

The first time JVM sees an invokedynamic instruction, it calls a special static method called Bootstrap Method. The bootstrap method is a piece of Java code that we’ve written to prepare the actual to-be-invoked logic:

enter image description here

Then the bootstrap method returns an instance of java.lang.invoke.CallSite. This CallSite holds a reference to the actual method, i.e. MethodHandle.

From now on, every time JVM sees this invokedynamic instruction again, it skips the Slow Path and directly calls the underlying executable. The JVM continues to skip the slow path unless something changes.

Example: Java 14 Records

Java 14 Records are providing a nice compact syntax to declare classes that are supposed to be dumb data holders.

Considering this simple record:

public record Range(int min, int max) {}

The bytecode for this example would be something like:

Compiled from "Range.java"
public java.lang.String toString();
    descriptor: ()Ljava/lang/String;
    flags: (0x0001) ACC_PUBLIC
      stack=1, locals=1, args_size=1
         0: aload_0
         1: invokedynamic #18,  0 // InvokeDynamic #0:toString:(LRange;)Ljava/lang/String;
         6: areturn

In its Bootstrap Method Table:

  0: #41 REF_invokeStatic java/lang/runtime/ObjectMethods.bootstrap:
    Method arguments:
      #8 Range
      #48 min;max
      #50 REF_getField Range.min:I
      #51 REF_getField Range.max:I

So the bootstrap method for Records is called bootstrap which resides in the java.lang.runtime.ObjectMethods class. As you can see, this bootstrap method expects the following parameters:

  • An instance of MethodHandles.Lookup representing the lookup context (The Ljava/lang/invoke/MethodHandles$Lookup part).
  • The method name (i.e. toString, equals, hashCode, etc.) the bootstrap is going to link. For example, when the value is toString, bootstrap will return a ConstantCallSite (a CallSite that never changes) that points to the actual toString implementation for this particular Record.
  • The TypeDescriptor for the method (Ljava/lang/invoke/TypeDescriptor part).
  • A type token, i.e. Class<?>, representing the Record class type. It’s Class<Range> in this case.
  • A semi-colon separated list of all component names, i.e. min;max.
  • One MethodHandle per component. This way the bootstrap method can create a MethodHandle based on the components for this particular method implementation.

The invokedynamic instruction passes all those arguments to the bootstrap method. Bootstrap method, in turn, returns an instance of ConstantCallSite. This ConstantCallSite is holding a reference to requested method implementation, e.g. toString.

Why Indy?

As opposed to the Reflection APIs, the java.lang.invoke API is quite efficient since the JVM can completely see through all invocations. Therefore, JVM may apply all sorts of optimizations as long as we avoid the slow path as much as possible!

In addition to the efficiency argument, the invokedynamic approach is more reliable and less brittle because of its simplicity.

Moreover, the generated bytecode for Java Records is independent of the number of properties. So, less bytecode and faster startup time.

Finally, let’s suppose a new version of Java includes a new and more efficient bootstrap method implementation. With invokedynamic, our app can take advantage of this improvement without recompilation. This way we have some sort of Forward Binary Compatibility. Also, That’s the dynamic strategy we were talking about!

Other Examples

In addition to Java Records, the invoke dynamic has been used to implement features like:


There are two concepts to understand before continuing to invokedynamic.

1. Static vs. Dynamic Typing

Static - preforms type checking at compile time (e.g. Java)

Dynamic - preforms type checking at runtime (e.g. JavaScript)

Type checking is a process of verifying that a program is type safe, this is, checking typed information for class and instance variables, method parameters, return values, and other variables. E.g. Java knows about int, String,.. at compile time, while type of an object in JavaScript can only be determined at runtime

2. Strong vs. Weak typing

Strong - specifies restrictions on the types of values supplied to its operations (e.g. Java)

Weak - converts (casts) arguments of an operation if those arguments have incompatible types (e.g. Visual Basic)

Knowing that Java is a Statically and Weakly typed, how do you implement Dynamically and Strongly typed languages on the JVM?

The invokedynamic implements a runtime system that can choose the most appropriate implementation of a method or function — after the program has been compiled.

Example: Having (a + b) and not knowing anything about the variables a,b at compile time, invokedynamic maps this operation to the most appropriate method in Java at runtime. E.g., if it turns out a,b are Strings, then call method(String a, String b). If it turns out a,b are ints, then call method(int a, int b).

invokedynamic was introduced with Java 7.

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