Bytecode features not available in the Java language
Are there currently (Java 6) things you can do in Java bytecode that you can't do from within the Java language?
I know both are Turing complete, so read "can do" as "can do significantly faster/better, or just in a different way".
I'm thinking of extra bytecodes like invokedynamic
, which can't be generated using Java, except that specific one is for a future version.
After working with Java byte code for quite a while and doing some additional research on this matter, here is a summary of my findings:
Execute code in a constructor before calling a super constructor or auxiliary constructor
In the Java programming language (JPL), a constructor's first statement must be an invocation of a super constructor or another constructor of the same class. This is not true for Java byte code (JBC). Within byte code, it is absolutely legitimate to execute any code before a constructor, as long as:
- Another compatible constructor is called at some time after this code block.
- This call is not within a conditional statement.
- Before this constructor call, no field of the constructed instance is read and none of its methods is invoked. This implies the next item.
Set instance fields before calling a super constructor or auxiliary constructor
As mentioned before, it is perfectly legal to set a field value of an instance before calling another constructor. There even exists a legacy hack which makes it able to exploit this "feature" in Java versions before 6:
class Foo {
public String s;
public Foo() {
System.out.println(s);
}
}
class Bar extends Foo {
public Bar() {
this(s = "Hello World!");
}
private Bar(String helper) {
super();
}
}
This way, a field could be set before the super constructor is invoked which is however not longer possible. In JBC, this behavior can still be implemented.
Branch a super constructor call
In Java, it is not possible to define a constructor call like
class Foo {
Foo() { }
Foo(Void v) { }
}
class Bar() {
if(System.currentTimeMillis() % 2 == 0) {
super();
} else {
super(null);
}
}
Until Java 7u23, the HotSpot VM's verifier did however miss this check which is why it was possible. This was used by several code generation tools as a sort of a hack but it is not longer legal to implement a class like this.
The latter was merely a bug in this compiler version. In newer compiler versions, this is again possible.
Define a class without any constructor
The Java compiler will always implement at least one constructor for any class. In Java byte code, this is not required. This allows the creation of classes that cannot be constructed even when using reflection. However, using sun.misc.Unsafe
still allows for the creation of such instances.
Define methods with identical signature but with different return type
In the JPL, a method is identified as unique by its name and its raw parameter types. In JBC, the raw return type is additionally considered.
Define fields that do not differ by name but only by type
A class file can contain several fields of the same name as long as they declare a different field type. The JVM always refers to a field as a tuple of name and type.
Throw undeclared checked exceptions without catching them
The Java runtime and the Java byte code are not aware of the concept of checked exceptions. It is only the Java compiler that verifies that checked exceptions are always either caught or declared if they are thrown.
Use dynamic method invocation outside of lambda expressions
The so-called dynamic method invocation can be used for anything, not only for Java's lambda expressions. Using this feature allows for example to switch out execution logic at runtime. Many dynamic programming languages that boil down to JBC improved their performance by using this instruction. In Java byte code, you could also emulate lambda expressions in Java 7 where the compiler did not yet allow for any use of dynamic method invocation while the JVM already understood the instruction.
Use identifiers that are not normally considered legal
Ever fancied using spaces and a line break in your method's name? Create your own JBC and good luck for code review. The only illegal characters for identifiers are .
, ;
, [
and /
. Additionally, methods that are not named <init>
or <clinit>
cannot contain <
and >
.
Reassign final
parameters or the this
reference
final
parameters do not exist in JBC and can consequently be reassigned. Any parameter, including the this
reference is only stored in a simple array within the JVM what allows to reassign the this
reference at index 0
within a single method frame.
Reassign final
fields
As long as a final field is assigned within a constructor, it is legal to reassign this value or even not assign a value at all. Therefore, the following two constructors are legal:
class Foo {
final int bar;
Foo() { } // bar == 0
Foo(Void v) { // bar == 2
bar = 1;
bar = 2;
}
}
For static final
fields, it is even allowed to reassign the fields outside of
the class initializer.
Treat constructors and the class initializer as if they were methods
This is more of a conceptional feature but constructors are not treated any differently within JBC than normal methods. It is only the JVM's verifier that assures that constructors call another legal constructor. Other than that, it is merely a Java naming convention that constructors must be called <init>
and that the class initializer is called <clinit>
. Besides this difference, the representation of methods and constructors is identical. As Holger pointed out in a comment, you can even define constructors with return types other than void
or a class initializer with arguments, even though it is not possible to call these methods.
Create asymmetric records*.
When creating a record
record Foo(Object bar) { }
javac will generate a class file with a single field named bar
, an accessor method named bar()
and a constructor taking a single Object
. Additionally, a record attribute for bar
is added. By manually generating a record, it is possible to create, a different constructor shape, to skip the field and to implement the accessor differently. At the same time, it is still possible to make the reflection API believe that the class represents an actual record.
Call any super method (until Java 1.1)
However, this is only possible for Java versions 1 and 1.1. In JBC, methods are always dispatched on an explicit target type. This means that for
class Foo {
void baz() { System.out.println("Foo"); }
}
class Bar extends Foo {
@Override
void baz() { System.out.println("Bar"); }
}
class Qux extends Bar {
@Override
void baz() { System.out.println("Qux"); }
}
it was possible to implement Qux#baz
to invoke Foo#baz
while jumping over Bar#baz
. While it is still possible to define an explicit invocation to call another super method implementation than that of the direct super class, this does no longer have any effect in Java versions after 1.1. In Java 1.1, this behavior was controlled by setting the ACC_SUPER
flag which would enable the same behavior that only calls the direct super class's implementation.
Define a non-virtual call of a method that is declared in the same class
In Java, it is not possible to define a class
class Foo {
void foo() {
bar();
}
void bar() { }
}
class Bar extends Foo {
@Override void bar() {
throw new RuntimeException();
}
}
The above code will always result in a RuntimeException
when foo
is invoked on an instance of Bar
. It is not possible to define the Foo::foo
method to invoke its own bar
method which is defined in Foo
. As bar
is a non-private instance method, the call is always virtual. With byte code, one can however define the invocation to use the INVOKESPECIAL
opcode which directly links the bar
method call in Foo::foo
to Foo
's version. This opcode is normally used to implement super method invocations but you can reuse the opcode to implement the described behavior.
Fine-grain type annotations
In Java, annotations are applied according to their @Target
that the annotations declares. Using byte code manipulation, it is possible to define annotations independently of this control. Also, it is for example possible to annotate a parameter type without annotating the parameter even if the @Target
annotation applies to both elements.
Define any attribute for a type or its members
Within the Java language, it is only possible to define annotations for fields, methods or classes. In JBC, you can basically embed any information into the Java classes. In order to make use of this information, you can however no longer rely on the Java class loading mechanism but you need to extract the meta information by yourself.
Overflow and implicitly assign byte
, short
, char
and boolean
values
The latter primitive types are not normally known in JBC but are only defined for array types or for field and method descriptors. Within byte code instructions, all of the named types take the space 32 bit which allows to represent them as int
. Officially, only the int
, float
, long
and double
types exist within byte code which all need explicit conversion by the rule of the JVM's verifier.
Not release a monitor
A synchronized
block is actually made up of two statements, one to acquire and one to release a monitor. In JBC, you can acquire one without releasing it.
Note: In recent implementations of HotSpot, this instead leads to an IllegalMonitorStateException
at the end of a method or to an implicit release if the method is terminated by an exception itself.
Add more than one return
statement to a type initializer
In Java, even a trivial type initializer such as
class Foo {
static {
return;
}
}
is illegal. In byte code, the type initializer is treated just as any other method, i.e. return statements can be defined anywhere.
Create irreducible loops
The Java compiler converts loops to goto statements in Java byte code. Such statements can be used to create irreducible loops, which the Java compiler never does.
Define a recursive catch block
In Java byte code, you can define a block:
try {
throw new Exception();
} catch (Exception e) {
<goto on exception>
throw Exception();
}
A similar statement is created implicitly when using a synchronized
block in Java where any exception while releasing a monitor returns to the instruction for releasing this monitor. Normally, no exception should occur on such an instruction but if it would (e.g. the deprecated ThreadDeath
), the monitor would still be released.
Call any default method
The Java compiler requires several conditions to be fulfilled in order to allow a default method's invocation:
- The method must be the most specific one (must not be overridden by a sub interface that is implemented by any type, including super types).
- The default method's interface type must be implemented directly by the class that is calling the default method. However, if interface
B
extends interfaceA
but does not override a method inA
, the method can still be invoked.
For Java byte code, only the second condition counts. The first one is however irrelevant.
Invoke a super method on an instance that is not this
The Java compiler only allows to invoke a super (or interface default) method on instances of this
. In byte code, it is however also possible to invoke the super method on an instance of the same type similar to the following:
class Foo {
void m(Foo f) {
f.super.toString(); // calls Object::toString
}
public String toString() {
return "foo";
}
}
Access synthetic members
In Java byte code, it is possible to access synthetic members directly. For example, consider how in the following example the outer instance of another Bar
instance is accessed:
class Foo {
class Bar {
void bar(Bar bar) {
Foo foo = bar.Foo.this;
}
}
}
This is generally true for any synthetic field, class or method.
Define out-of-sync generic type information
While the Java runtime does not process generic types (after the Java compiler applies type erasure), this information is still attcheched to a compiled class as meta information and made accessible via the reflection API.
The verifier does not check the consistency of these meta data String
-encoded values. It is therefore possible to define information on generic types that does not match the erasure. As a concequence, the following assertings can be true:
Method method = ...
assertTrue(method.getParameterTypes() != method.getGenericParameterTypes());
Field field = ...
assertTrue(field.getFieldType() == String.class);
assertTrue(field.getGenericFieldType() == Integer.class);
Also, the signature can be defined as invalid such that a runtime exception is thrown. This exception is thrown when the information is accessed for the first time as it is evaluated lazily. (Similar to annotation values with an error.)
Append parameter meta information only for certain methods
The Java compiler allows for embedding parameter name and modifier information when compiling a class with the parameter
flag enabled. In the Java class file format, this information is however stored per-method what makes it possible to only embed such method information for certain methods.
Mess things up and hard-crash your JVM
As an example, in Java byte code, you can define to invoke any method on any type. Usually, the verifier will complain if a type does not known of such a method. However, if you invoke an unknown method on an array, I found a bug in some JVM version where the verifier will miss this and your JVM will finish off once the instruction is invoked. This is hardly a feature though, but it is technically something that is not possible with javac compiled Java. Java has some sort of double validation. The first validation is applied by the Java compiler, the second one by the JVM when a class is loaded. By skipping the compiler, you might find a weak spot in the verifier's validation. This is rather a general statement than a feature, though.
Annotate a constructor's receiver type when there is no outer class
Since Java 8, non-static methods and constructors of inner classes can declare a receiver type and annotate these types. Constructors of top-level classes cannot annotate their receiver type as they most not declare one.
class Foo {
class Bar {
Bar(@TypeAnnotation Foo Foo.this) { }
}
Foo() { } // Must not declare a receiver type
}
Since Foo.class.getDeclaredConstructor().getAnnotatedReceiverType()
does however return an AnnotatedType
representing Foo
, it is possible to include type annotations for Foo
's constructor directly in the class file where these annotations are later read by the reflection API.
Use unused / legacy byte code instructions
Since others named it, I will include it as well. Java was formerly making use of subroutines by the JSR
and RET
statements. JBC even knew its own type of a return address for this purpose. However, the use of subroutines did overcomplicate static code analysis which is why these instructions are not longer used. Instead, the Java compiler will duplicate code it compiles. However, this basically creates identical logic which is why I do not really consider it to achieve something different. Similarly, you could for example add the NOOP
byte code instruction which is not used by the Java compiler either but this would not really allow you to achieve something new either. As pointed out in the context, these mentioned "feature instructions" are now removed from the set of legal opcodes which does render them even less of a feature.
As far as I know there are no major features in the bytecodes supported by Java 6 that are not also accessible from Java source code. The main reason for this is obviously that the Java bytecode was designed with the Java language in mind.
There are some features that are not produced by modern Java compilers, however:
-
The
ACC_SUPER
flag:This is a flag that can be set on a class and specifies how a specific corner case of the
invokespecial
bytecode is handled for this class. It is set by all modern Java compilers (where "modern" is >= Java 1.1, if I remember correctly) and only ancient Java compilers produced class files where this was un-set. This flag exists only for backwards-compatibility reasons. Note that starting with Java 7u51, ACC_SUPER is ignored completely due to security reasons. -
The
jsr
/ret
bytecodes.These bytecodes were used to implement sub-routines (mostly for implementing
finally
blocks). They are no longer produced since Java 6. The reason for their deprecation is that they complicate static verification a lot for no great gain (i.e. code that uses can almost always be re-implemented with normal jumps with very little overhead). -
Having two methods in a class that only differ in return type.
The Java language specification does not allow two methods in the same class when they differ only in their return type (i.e. same name, same argument list, ...). The JVM specification however, has no such restriction, so a class file can contain two such methods, there's just no way to produce such a class file using the normal Java compiler. There's a nice example/explanation in this answer.
Here are some features that can be done in Java bytecode but not in Java source code:
Throwing a checked exception from a method without declaring that the method throws it. The checked and unchecked exceptions are a thing which is checked only by the Java compiler, not the JVM. Because of this for example Scala can throw checked exceptions from methods without declaring them. Though with Java generics there is a workaround called sneaky throw.
Having two methods in a class that only differ in return type, as already mentioned in Joachim's answer: The Java language specification does not allow two methods in the same class when they differ only in their return type (i.e. same name, same argument list, ...). The JVM specification however, has no such restriction, so a class file can contain two such methods, there's just no way to produce such a class file using the normal Java compiler. There's a nice example/explanation in this answer.
-
GOTO
can be used with labels to create your own control structures (other thanfor
while
etc) - You can override the
this
local variable inside a method - Combining both of these you can create create tail call optimised bytecode (I do this in JCompilo)
As a related point you can get parameter name for methods if compiled with debug (Paranamer does this by reading the bytecode
Maybe section 7A in this document is of interest, although it's about bytecode pitfalls rather than bytecode features.