java.lang.invoke
package contains dynamic language support provided directly by
the Java core class libraries and virtual machine.See: Description
Interface | Description |
---|---|
MethodHandleInfo |
A symbolic reference obtained by cracking a direct method handle
into its consitutent symbolic parts.
|
Class | Description |
---|---|
CallSite | |
ConstantCallSite |
A
ConstantCallSite is a CallSite whose target is permanent, and can never be changed. |
LambdaMetafactory |
Methods to facilitate the creation of simple "function objects" that
implement one or more interfaces by delegation to a provided
MethodHandle ,
possibly after type adaptation and partial evaluation of arguments. |
MethodHandle |
A method handle is a typed, directly executable reference to an underlying method,
constructor, field, or similar low-level operation, with optional
transformations of arguments or return values.
|
MethodHandleProxies |
This class consists exclusively of static methods that help adapt
method handles to other JVM types, such as interfaces.
|
MethodHandles |
This class consists exclusively of static methods that operate on or return
method handles.
|
MethodHandles.Lookup |
A lookup object is a factory for creating method handles,
when the creation requires access checking.
|
MethodType |
A method type represents the arguments and return type accepted and
returned by a method handle, or the arguments and return type passed
and expected by a method handle caller.
|
MutableCallSite |
A
MutableCallSite is a CallSite whose target variable
behaves like an ordinary field. |
SerializedLambda |
Serialized form of a lambda expression.
|
SwitchPoint |
A
SwitchPoint is an object which can publish state transitions to other threads. |
VolatileCallSite |
A
VolatileCallSite is a CallSite whose target acts like a volatile variable. |
Exception | Description |
---|---|
LambdaConversionException |
LambdaConversionException
|
WrongMethodTypeException |
Thrown to indicate that code has attempted to call a method handle
via the wrong method type.
|
java.lang.invoke
package contains dynamic language support provided directly by
the Java core class libraries and virtual machine.
As described in the Java Virtual Machine Specification, certain types in this package have special relations to dynamic language support in the virtual machine:
MethodHandle
contains
signature polymorphic methods
which can be linked regardless of their type descriptor.
Normally, method linkage requires exact matching of type descriptors.
MethodHandle
and MethodType
.
invokedynamic
instruction is called a dynamic call site.
invokedynamic
instructions
Before the JVM can execute a dynamic call site (an invokedynamic
instruction),
the call site must first be linked.
Linking is accomplished by calling a bootstrap method
which is given the static information content of the call site,
and which must produce a method handle
that gives the behavior of the call site.
Each invokedynamic
instruction statically specifies its own
bootstrap method as a constant pool reference.
The constant pool reference also specifies the call site's name and type descriptor,
just like invokevirtual
and the other invoke instructions.
Linking starts with resolving the constant pool entry for the
bootstrap method, and resolving a MethodType
object for
the type descriptor of the dynamic call site.
This resolution process may trigger class loading.
It may therefore throw an error if a class fails to load.
This error becomes the abnormal termination of the dynamic
call site execution.
Linkage does not trigger class initialization.
The bootstrap method is invoked on at least three values:
MethodHandles.Lookup
, a lookup object on the caller class in which dynamic call site occurs String
, the method name mentioned in the call site MethodType
, the resolved type descriptor of the call MethodHandle.invoke
.
The returned result must be a CallSite
(or a subclass).
The type of the call site's target must be exactly equal to the type
derived from the dynamic call site's type descriptor and passed to
the bootstrap method.
The call site then becomes permanently linked to the dynamic call site.
As documented in the JVM specification, all failures arising from
the linkage of a dynamic call site are reported
by a BootstrapMethodError
,
which is thrown as the abnormal termination of the dynamic call
site execution.
If this happens, the same error will the thrown for all subsequent
attempts to execute the dynamic call site.
If there are several such threads, the bootstrap method may be
invoked in several threads concurrently.
Therefore, bootstrap methods which access global application
data must take the usual precautions against race conditions.
In any case, every invokedynamic
instruction is either
unlinked or linked to a unique CallSite
object.
In an application which requires dynamic call sites with individually
mutable behaviors, their bootstrap methods should produce distinct
CallSite
objects, one for each linkage request.
Alternatively, an application can link a single CallSite
object
to several invokedynamic
instructions, in which case
a change to the target method will become visible at each of
the instructions.
If several threads simultaneously execute a bootstrap method for a single dynamic
call site, the JVM must choose one CallSite
object and install it visibly to
all threads. Any other bootstrap method calls are allowed to complete, but their
results are ignored, and their dynamic call site invocations proceed with the originally
chosen target object.
Discussion: These rules do not enable the JVM to duplicate dynamic call sites, or to issue “causeless” bootstrap method calls. Every dynamic call site transitions at most once from unlinked to linked, just before its first invocation. There is no way to undo the effect of a completed bootstrap method call.
MethodHandle.invoke
, its detailed type is arbitrary.
For example, the first argument could be Object
instead of MethodHandles.Lookup
, and the return type
could also be Object
instead of CallSite
.
(Note that the types and number of the stacked arguments limit
the legal kinds of bootstrap methods to appropriately typed
static methods and constructors of CallSite
subclasses.)
If a given invokedynamic
instruction specifies no static arguments,
the instruction's bootstrap method will be invoked on three arguments,
conveying the instruction's caller class, name, and method type.
If the invokedynamic
instruction specifies one or more static arguments,
those values will be passed as additional arguments to the method handle.
(Note that because there is a limit of 255 arguments to any method,
at most 251 extra arguments can be supplied, since the bootstrap method
handle itself and its first three arguments must also be stacked.)
The bootstrap method will be invoked as if by either MethodHandle.invoke
or invokeWithArguments
. (There is no way to tell the difference.)
The normal argument conversion rules for MethodHandle.invoke
apply to all stacked arguments.
For example, if a pushed value is a primitive type, it may be converted to a reference by boxing conversion.
If the bootstrap method is a variable arity method (its modifier bit 0x0080
is set),
then some or all of the arguments specified here may be collected into a trailing array parameter.
(This is not a special rule, but rather a useful consequence of the interaction
between CONSTANT_MethodHandle
constants, the modifier bit for variable arity methods,
and the asVarargsCollector
transformation.)
Given these rules, here are examples of legal bootstrap method declarations,
given various numbers N
of extra arguments.
The first rows (marked *
) will work for any number of extra arguments.
N | sample bootstrap method |
---|---|
* | CallSite bootstrap(Lookup caller, String name, MethodType type, Object... args) |
* | CallSite bootstrap(Object... args) |
* | CallSite bootstrap(Object caller, Object... nameAndTypeWithArgs) |
0 | CallSite bootstrap(Lookup caller, String name, MethodType type) |
0 | CallSite bootstrap(Lookup caller, Object... nameAndType) |
1 | CallSite bootstrap(Lookup caller, String name, MethodType type, Object arg) |
2 | CallSite bootstrap(Lookup caller, String name, MethodType type, Object... args) |
2 | CallSite bootstrap(Lookup caller, String name, MethodType type, String... args) |
2 | CallSite bootstrap(Lookup caller, String name, MethodType type, String x, int y) |
CONSTANT_String
and CONSTANT_Integer
, respectively.
The second-to-last example assumes that all extra arguments are of type
CONSTANT_String
.
The other examples work with all types of extra arguments.
As noted above, the actual method type of the bootstrap method can vary.
For example, the fourth argument could be MethodHandle
,
if that is the type of the corresponding constant in
the CONSTANT_InvokeDynamic
entry.
In that case, the MethodHandle.invoke
call will pass the extra method handle
constant as an Object
, but the type matching machinery of MethodHandle.invoke
will cast the reference back to MethodHandle
before invoking the bootstrap method.
(If a string constant were passed instead, by badly generated code, that cast would then fail,
resulting in a BootstrapMethodError
.)
Note that, as a consequence of the above rules, the bootstrap method may accept a primitive
argument, if it can be represented by a constant pool entry.
However, arguments of type boolean
, byte
, short
, or char
cannot be created for bootstrap methods, since such constants cannot be directly
represented in the constant pool, and the invocation of the bootstrap method will
not perform the necessary narrowing primitive conversions.
Extra bootstrap method arguments are intended to allow language implementors to safely and compactly encode metadata. In principle, the name and extra arguments are redundant, since each call site could be given its own unique bootstrap method. Such a practice is likely to produce large class files and constant pools.
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For further API reference and developer documentation, see Java SE Documentation. That documentation contains more detailed, developer-targeted descriptions, with conceptual overviews, definitions of terms, workarounds, and working code examples.
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