public abstract class MethodHandle extends Object
Every method handle reports its type descriptor via the type
accessor.
This type descriptor is a MethodType
object,
whose structure is a series of classes, one of which is
the return type of the method (or void.class
if none).
A method handle's type controls the types of invocations it accepts, and the kinds of transformations that apply to it.
A method handle contains a pair of special invoker methods
called invokeExact
and invoke
.
Both invoker methods provide direct access to the method handle's
underlying method, constructor, field, or other operation,
as modified by transformations of arguments and return values.
Both invokers accept calls which exactly match the method handle's own type.
The plain, inexact invoker also accepts a range of other call types.
Method handles are immutable and have no visible state. Of course, they can be bound to underlying methods or data which exhibit state. With respect to the Java Memory Model, any method handle will behave as if all of its (internal) fields are final variables. This means that any method handle made visible to the application will always be fully formed. This is true even if the method handle is published through a shared variable in a data race.
Method handles cannot be subclassed by the user.
Implementations may (or may not) create internal subclasses of MethodHandle
which may be visible via the Object.getClass
operation. The programmer should not draw conclusions about a method handle
from its specific class, as the method handle class hierarchy (if any)
may change from time to time or across implementations from different vendors.
invokeExact
or invoke
can invoke a method handle from Java source code.
From the viewpoint of source code, these methods can take any arguments
and their result can be cast to any return type.
Formally this is accomplished by giving the invoker methods
Object
return types and variable arity Object
arguments,
but they have an additional quality called signature polymorphism
which connects this freedom of invocation directly to the JVM execution stack.
As is usual with virtual methods, source-level calls to invokeExact
and invoke
compile to an invokevirtual
instruction.
More unusually, the compiler must record the actual argument types,
and may not perform method invocation conversions on the arguments.
Instead, it must push them on the stack according to their own unconverted types.
The method handle object itself is pushed on the stack before the arguments.
The compiler then calls the method handle with a symbolic type descriptor which
describes the argument and return types.
To issue a complete symbolic type descriptor, the compiler must also determine
the return type. This is based on a cast on the method invocation expression,
if there is one, or else Object
if the invocation is an expression
or else void
if the invocation is a statement.
The cast may be to a primitive type (but not void
).
As a corner case, an uncasted null
argument is given
a symbolic type descriptor of java.lang.Void
.
The ambiguity with the type Void
is harmless, since there are no references of type
Void
except the null reference.
invokevirtual
instruction is executed
it is linked, by symbolically resolving the names in the instruction
and verifying that the method call is statically legal.
This is true of calls to invokeExact
and invoke
.
In this case, the symbolic type descriptor emitted by the compiler is checked for
correct syntax and names it contains are resolved.
Thus, an invokevirtual
instruction which invokes
a method handle will always link, as long
as the symbolic type descriptor is syntactically well-formed
and the types exist.
When the invokevirtual
is executed after linking,
the receiving method handle's type is first checked by the JVM
to ensure that it matches the symbolic type descriptor.
If the type match fails, it means that the method which the
caller is invoking is not present on the individual
method handle being invoked.
In the case of invokeExact
, the type descriptor of the invocation
(after resolving symbolic type names) must exactly match the method type
of the receiving method handle.
In the case of plain, inexact invoke
, the resolved type descriptor
must be a valid argument to the receiver's asType
method.
Thus, plain invoke
is more permissive than invokeExact
.
After type matching, a call to invokeExact
directly
and immediately invoke the method handle's underlying method
(or other behavior, as the case may be).
A call to plain invoke
works the same as a call to
invokeExact
, if the symbolic type descriptor specified by the caller
exactly matches the method handle's own type.
If there is a type mismatch, invoke
attempts
to adjust the type of the receiving method handle,
as if by a call to asType
,
to obtain an exactly invokable method handle M2
.
This allows a more powerful negotiation of method type
between caller and callee.
(Note: The adjusted method handle M2
is not directly observable,
and implementations are therefore not required to materialize it.)
WrongMethodTypeException
,
either directly (in the case of invokeExact
) or indirectly as if
by a failed call to asType
(in the case of invoke
).
Thus, a method type mismatch which might show up as a linkage error
in a statically typed program can show up as
a dynamic WrongMethodTypeException
in a program which uses method handles.
Because method types contain "live" Class
objects,
method type matching takes into account both types names and class loaders.
Thus, even if a method handle M
is created in one
class loader L1
and used in another L2
,
method handle calls are type-safe, because the caller's symbolic type
descriptor, as resolved in L2
,
is matched against the original callee method's symbolic type descriptor,
as resolved in L1
.
The resolution in L1
happens when M
is created
and its type is assigned, while the resolution in L2
happens
when the invokevirtual
instruction is linked.
Apart from the checking of type descriptors, a method handle's capability to call its underlying method is unrestricted. If a method handle is formed on a non-public method by a class that has access to that method, the resulting handle can be used in any place by any caller who receives a reference to it.
Unlike with the Core Reflection API, where access is checked every time
a reflective method is invoked,
method handle access checking is performed
when the method handle is created.
In the case of ldc
(see below), access checking is performed as part of linking
the constant pool entry underlying the constant method handle.
Thus, handles to non-public methods, or to methods in non-public classes, should generally be kept secret. They should not be passed to untrusted code unless their use from the untrusted code would be harmless.
MethodHandles.Lookup
For example, a static method handle can be obtained
from Lookup.findStatic
.
There are also conversion methods from Core Reflection API objects,
such as Lookup.unreflect
.
Like classes and strings, method handles that correspond to accessible
fields, methods, and constructors can also be represented directly
in a class file's constant pool as constants to be loaded by ldc
bytecodes.
A new type of constant pool entry, CONSTANT_MethodHandle
,
refers directly to an associated CONSTANT_Methodref
,
CONSTANT_InterfaceMethodref
, or CONSTANT_Fieldref
constant pool entry.
(For more details on method handle constants,
see the package summary.)
Method handles produced by lookups or constant loads from methods or
constructors with the variable arity modifier bit (0x0080
)
have a corresponding variable arity, as if they were defined with
the help of asVarargsCollector
.
A method reference may refer either to a static or non-static method.
In the non-static case, the method handle type includes an explicit
receiver argument, prepended before any other arguments.
In the method handle's type, the initial receiver argument is typed
according to the class under which the method was initially requested.
(E.g., if a non-static method handle is obtained via ldc
,
the type of the receiver is the class named in the constant pool entry.)
When a method handle to a virtual method is invoked, the method is always looked up in the receiver (that is, the first argument).
A non-virtual method handle to a specific virtual method implementation
can also be created. These do not perform virtual lookup based on
receiver type. Such a method handle simulates the effect of
an invokespecial
instruction to the same method.
Each of the above calls toObject x, y; String s; int i; MethodType mt; MethodHandle mh; MethodHandles.Lookup lookup = MethodHandles.lookup(); // mt is (char,char)String mt = MethodType.methodType(String.class, char.class, char.class); mh = lookup.findVirtual(String.class, "replace", mt); s = (String) mh.invokeExact("daddy",'d','n'); // invokeExact(Ljava/lang/String;CC)Ljava/lang/String; assertEquals(s, "nanny"); // weakly typed invocation (using MHs.invoke) s = (String) mh.invokeWithArguments("sappy", 'p', 'v'); assertEquals(s, "savvy"); // mt is (Object[])List mt = MethodType.methodType(java.util.List.class, Object[].class); mh = lookup.findStatic(java.util.Arrays.class, "asList", mt); assert(mh.isVarargsCollector()); x = mh.invoke("one", "two"); // invoke(Ljava/lang/String;Ljava/lang/String;)Ljava/lang/Object; assertEquals(x, java.util.Arrays.asList("one","two")); // mt is (Object,Object,Object)Object mt = MethodType.genericMethodType(3); mh = mh.asType(mt); x = mh.invokeExact((Object)1, (Object)2, (Object)3); // invokeExact(Ljava/lang/Object;Ljava/lang/Object;Ljava/lang/Object;)Ljava/lang/Object; assertEquals(x, java.util.Arrays.asList(1,2,3)); // mt is ()int mt = MethodType.methodType(int.class); mh = lookup.findVirtual(java.util.List.class, "size", mt); i = (int) mh.invokeExact(java.util.Arrays.asList(1,2,3)); // invokeExact(Ljava/util/List;)I assert(i == 3); mt = MethodType.methodType(void.class, String.class); mh = lookup.findVirtual(java.io.PrintStream.class, "println", mt); mh.invokeExact(System.out, "Hello, world."); // invokeExact(Ljava/io/PrintStream;Ljava/lang/String;)V
invokeExact
or plain invoke
generates a single invokevirtual instruction with
the symbolic type descriptor indicated in the following comment.
In these examples, the helper method assertEquals
is assumed to
be a method which calls java.util.Objects#equals
on its arguments, and asserts that the result is true.
invokeExact
and invoke
are declared
to throw Throwable
,
which is to say that there is no static restriction on what a method handle
can throw. Since the JVM does not distinguish between checked
and unchecked exceptions (other than by their class, of course),
there is no particular effect on bytecode shape from ascribing
checked exceptions to method handle invocations. But in Java source
code, methods which perform method handle calls must either explicitly
throw Throwable
, or else must catch all
throwables locally, rethrowing only those which are legal in the context,
and wrapping ones which are illegal.
invokeExact
and plain invoke
is referenced by the term signature polymorphism.
As defined in the Java Language Specification,
a signature polymorphic method is one which can operate with
any of a wide range of call signatures and return types.
In source code, a call to a signature polymorphic method will
compile, regardless of the requested symbolic type descriptor.
As usual, the Java compiler emits an invokevirtual
instruction with the given symbolic type descriptor against the named method.
The unusual part is that the symbolic type descriptor is derived from
the actual argument and return types, not from the method declaration.
When the JVM processes bytecode containing signature polymorphic calls, it will successfully link any such call, regardless of its symbolic type descriptor. (In order to retain type safety, the JVM will guard such calls with suitable dynamic type checks, as described elsewhere.)
Bytecode generators, including the compiler back end, are required to emit untransformed symbolic type descriptors for these methods. Tools which determine symbolic linkage are required to accept such untransformed descriptors, without reporting linkage errors.
Lookup
API,
any class member represented by a Core Reflection API object
can be converted to a behaviorally equivalent method handle.
For example, a reflective Method
can
be converted to a method handle using
Lookup.unreflect
.
The resulting method handles generally provide more direct and efficient
access to the underlying class members.
As a special case,
when the Core Reflection API is used to view the signature polymorphic
methods invokeExact
or plain invoke
in this class,
they appear as ordinary non-polymorphic methods.
Their reflective appearance, as viewed by
Class.getDeclaredMethod
,
is unaffected by their special status in this API.
For example, Method.getModifiers
will report exactly those modifier bits required for any similarly
declared method, including in this case native
and varargs
bits.
As with any reflected method, these methods (when reflected) may be
invoked via java.lang.reflect.Method.invoke
.
However, such reflective calls do not result in method handle invocations.
Such a call, if passed the required argument
(a single one, of type Object[]
), will ignore the argument and
will throw an UnsupportedOperationException
.
Since invokevirtual
instructions can natively
invoke method handles under any symbolic type descriptor, this reflective view conflicts
with the normal presentation of these methods via bytecodes.
Thus, these two native methods, when reflectively viewed by
Class.getDeclaredMethod
, may be regarded as placeholders only.
In order to obtain an invoker method for a particular type descriptor,
use MethodHandles.exactInvoker
,
or MethodHandles.invoker
.
The Lookup.findVirtual
API is also able to return a method handle
to call invokeExact
or plain invoke
,
for any specified type descriptor .
invokevirtual
instruction.
Method handles do not represent their function-like types in terms of Java parameterized (generic) types, because there are three mismatches between function-like types and parameterized Java types.
MethodType
,
MethodHandles
Modifier and Type | Method and Description |
---|---|
MethodHandle |
asCollector(Class<?> arrayType,
int arrayLength)
Makes an array-collecting method handle, which accepts a given number of trailing
positional arguments and collects them into an array argument.
|
MethodHandle |
asFixedArity()
Makes a fixed arity method handle which is otherwise
equivalent to the the current method handle.
|
MethodHandle |
asSpreader(Class<?> arrayType,
int arrayLength)
Makes an array-spreading method handle, which accepts a trailing array argument
and spreads its elements as positional arguments.
|
MethodHandle |
asType(MethodType newType)
Produces an adapter method handle which adapts the type of the
current method handle to a new type.
|
MethodHandle |
asVarargsCollector(Class<?> arrayType)
Makes a variable arity adapter which is able to accept
any number of trailing positional arguments and collect them
into an array argument.
|
MethodHandle |
bindTo(Object x)
Binds a value
x to the first argument of a method handle, without invoking it. |
Object |
invoke(Object... args)
Invokes the method handle, allowing any caller type descriptor,
and optionally performing conversions on arguments and return values.
|
Object |
invokeExact(Object... args)
Invokes the method handle, allowing any caller type descriptor, but requiring an exact type match.
|
Object |
invokeWithArguments(List<?> arguments)
Performs a variable arity invocation, passing the arguments in the given array
to the method handle, as if via an inexact
invoke from a call site
which mentions only the type Object , and whose arity is the length
of the argument array. |
Object |
invokeWithArguments(Object... arguments)
Performs a variable arity invocation, passing the arguments in the given array
to the method handle, as if via an inexact
invoke from a call site
which mentions only the type Object , and whose arity is the length
of the argument array. |
boolean |
isVarargsCollector()
Determines if this method handle
supports variable arity calls.
|
String |
toString()
Returns a string representation of the method handle,
starting with the string
"MethodHandle" and
ending with the string representation of the method handle's type. |
MethodType |
type()
Reports the type of this method handle.
|
public MethodType type()
invokeExact
must exactly match this type.public final Object invokeExact(Object... args) throws Throwable
invokeExact
must
exactly match this method handle's type
.
No conversions are allowed on arguments or return values.
When this method is observed via the Core Reflection API,
it will appear as a single native method, taking an object array and returning an object.
If this native method is invoked directly via
java.lang.reflect.Method.invoke
, via JNI,
or indirectly via Lookup.unreflect
,
it will throw an UnsupportedOperationException
.
WrongMethodTypeException
- if the target's type is not identical with the caller's symbolic type descriptorThrowable
- anything thrown by the underlying method propagates unchanged through the method handle callpublic final Object invoke(Object... args) throws Throwable
If the call site's symbolic type descriptor exactly matches this method handle's type
,
the call proceeds as if by invokeExact
.
Otherwise, the call proceeds as if this method handle were first
adjusted by calling asType
to adjust this method handle
to the required type, and then the call proceeds as if by
invokeExact
on the adjusted method handle.
There is no guarantee that the asType
call is actually made.
If the JVM can predict the results of making the call, it may perform
adaptations directly on the caller's arguments,
and call the target method handle according to its own exact type.
The resolved type descriptor at the call site of invoke
must
be a valid argument to the receivers asType
method.
In particular, the caller must specify the same argument arity
as the callee's type,
if the callee is not a variable arity collector.
When this method is observed via the Core Reflection API,
it will appear as a single native method, taking an object array and returning an object.
If this native method is invoked directly via
java.lang.reflect.Method.invoke
, via JNI,
or indirectly via Lookup.unreflect
,
it will throw an UnsupportedOperationException
.
WrongMethodTypeException
- if the target's type cannot be adjusted to the caller's symbolic type descriptorClassCastException
- if the target's type can be adjusted to the caller, but a reference cast failsThrowable
- anything thrown by the underlying method propagates unchanged through the method handle callpublic Object invokeWithArguments(Object... arguments) throws Throwable
invoke
from a call site
which mentions only the type Object
, and whose arity is the length
of the argument array.
Specifically, execution proceeds as if by the following steps, although the methods are not guaranteed to be called if the JVM can predict their effects.
N
.
For a null reference, N=0
. TN
of N
arguments as
as TN=MethodType.genericMethodType(N)
.MH0
to the
required type, as MH1 = MH0.asType(TN)
. N
separate arguments A0, ...
. Object
reference.
Because of the action of the asType
step, the following argument
conversions are applied as necessary:
The result returned by the call is boxed if it is a primitive, or forced to null if the return type is void.
This call is equivalent to the following code:
MethodHandle invoker = MethodHandles.spreadInvoker(this.type(), 0); Object result = invoker.invokeExact(this, arguments);
Unlike the signature polymorphic methods invokeExact
and invoke
,
invokeWithArguments
can be accessed normally via the Core Reflection API and JNI.
It can therefore be used as a bridge between native or reflective code and method handles.
arguments
- the arguments to pass to the targetClassCastException
- if an argument cannot be converted by reference castingWrongMethodTypeException
- if the target's type cannot be adjusted to take the given number of Object
argumentsThrowable
- anything thrown by the target method invocationMethodHandles.spreadInvoker(java.lang.invoke.MethodType, int)
public Object invokeWithArguments(List<?> arguments) throws Throwable
invoke
from a call site
which mentions only the type Object
, and whose arity is the length
of the argument array.
This method is also equivalent to the following code:
invokeWithArguments
(arguments.toArray())
arguments
- the arguments to pass to the targetNullPointerException
- if arguments
is a null referenceClassCastException
- if an argument cannot be converted by reference castingWrongMethodTypeException
- if the target's type cannot be adjusted to take the given number of Object
argumentsThrowable
- anything thrown by the target method invocationpublic MethodHandle asType(MethodType newType)
If the original type and new type are equal, returns this
.
The new method handle, when invoked, will perform the following steps:
This method provides the crucial behavioral difference between
invokeExact
and plain, inexact invoke
.
The two methods
perform the same steps when the caller's type descriptor exactly m atches
the callee's, but when the types differ, plain invoke
also calls asType
(or some internal equivalent) in order
to match up the caller's and callee's types.
If the current method is a variable arity method handle argument list conversion may involve the conversion and collection of several arguments into an array, as described elsewhere. In every other case, all conversions are applied pairwise, which means that each argument or return value is converted to exactly one argument or return value (or no return value). The applied conversions are defined by consulting the the corresponding component types of the old and new method handle types.
Let T0 and T1 be corresponding new and old parameter types,
or old and new return types. Specifically, for some valid index i
, let
T0=newType.parameterType(i)
and T1=this.type().parameterType(i)
.
Or else, going the other way for return values, let
T0=this.type().returnType()
and T1=newType.returnType()
.
If the types are the same, the new method handle makes no change
to the corresponding argument or return value (if any).
Otherwise, one of the following conversions is applied
if possible:
java.lang.reflect.Method.invoke
.)
The unboxing conversion must have a possibility of success, which means that
if T0 is not itself a wrapper class, there must exist at least one
wrapper class TW which is a subtype of T0 and whose unboxed
primitive value can be widened to T1.
The method handle conversion cannot be made if any one of the required pairwise conversions cannot be made.
At runtime, the conversions applied to reference arguments
or return values may require additional runtime checks which can fail.
An unboxing operation may fail because the original reference is null,
causing a NullPointerException
.
An unboxing operation or a reference cast may also fail on a reference
to an object of the wrong type,
causing a ClassCastException
.
Although an unboxing operation may accept several kinds of wrappers,
if none are available, a ClassCastException
will be thrown.
newType
- the expected type of the new method handlethis
after performing
any necessary argument conversions, and arranges for any
necessary return value conversionsNullPointerException
- if newType
is a null referenceWrongMethodTypeException
- if the conversion cannot be madeMethodHandles.explicitCastArguments(java.lang.invoke.MethodHandle, java.lang.invoke.MethodType)
public MethodHandle asSpreader(Class<?> arrayType, int arrayLength)
arrayLength
parameters of the target's type are replaced
by a single array parameter of type arrayType
.
If the array element type differs from any of the corresponding
argument types on the original target,
the original target is adapted to take the array elements directly,
as if by a call to asType
.
When called, the adapter replaces a trailing array argument by the array's elements, each as its own argument to the target. (The order of the arguments is preserved.) They are converted pairwise by casting and/or unboxing to the types of the trailing parameters of the target. Finally the target is called. What the target eventually returns is returned unchanged by the adapter.
Before calling the target, the adapter verifies that the array contains exactly enough elements to provide a correct argument count to the target method handle. (The array may also be null when zero elements are required.)
Here are some simple examples of array-spreading method handles:
MethodHandle equals = publicLookup() .findVirtual(String.class, "equals", methodType(boolean.class, Object.class)); assert( (boolean) equals.invokeExact("me", (Object)"me")); assert(!(boolean) equals.invokeExact("me", (Object)"thee")); // spread both arguments from a 2-array: MethodHandle eq2 = equals.asSpreader(Object[].class, 2); assert( (boolean) eq2.invokeExact(new Object[]{ "me", "me" })); assert(!(boolean) eq2.invokeExact(new Object[]{ "me", "thee" })); // spread both arguments from a String array: MethodHandle eq2s = equals.asSpreader(String[].class, 2); assert( (boolean) eq2s.invokeExact(new String[]{ "me", "me" })); assert(!(boolean) eq2s.invokeExact(new String[]{ "me", "thee" })); // spread second arguments from a 1-array: MethodHandle eq1 = equals.asSpreader(Object[].class, 1); assert( (boolean) eq1.invokeExact("me", new Object[]{ "me" })); assert(!(boolean) eq1.invokeExact("me", new Object[]{ "thee" })); // spread no arguments from a 0-array or null: MethodHandle eq0 = equals.asSpreader(Object[].class, 0); assert( (boolean) eq0.invokeExact("me", (Object)"me", new Object[0])); assert(!(boolean) eq0.invokeExact("me", (Object)"thee", (Object[])null)); // asSpreader and asCollector are approximate inverses: for (int n = 0; n <= 2; n++) { for (Class> a : new Class>[]{Object[].class, String[].class, CharSequence[].class}) { MethodHandle equals2 = equals.asSpreader(a, n).asCollector(a, n); assert( (boolean) equals2.invokeWithArguments("me", "me")); assert(!(boolean) equals2.invokeWithArguments("me", "thee")); } } MethodHandle caToString = publicLookup() .findStatic(Arrays.class, "toString", methodType(String.class, char[].class)); assertEquals("[A, B, C]", (String) caToString.invokeExact("ABC".toCharArray())); MethodHandle caString3 = caToString.asCollector(char[].class, 3); assertEquals("[A, B, C]", (String) caString3.invokeExact('A', 'B', 'C')); MethodHandle caToString2 = caString3.asSpreader(char[].class, 2); assertEquals("[A, B, C]", (String) caToString2.invokeExact('A', "BC".toCharArray()));
arrayType
- usually Object[]
, the type of the array argument from which to extract the spread argumentsarrayLength
- the number of arguments to spread from an incoming array argumentNullPointerException
- if arrayType
is a null referenceIllegalArgumentException
- if arrayType
is not an array typeIllegalArgumentException
- if target does not have at least
arrayLength
parameter types,
or if arrayLength
is negativeWrongMethodTypeException
- if the implied asType
call failsasCollector(java.lang.Class<?>, int)
public MethodHandle asCollector(Class<?> arrayType, int arrayLength)
arrayType
) is replaced by
arrayLength
parameters whose type is element type of arrayType
.
If the array type differs from the final argument type on the original target,
the original target is adapted to take the array type directly,
as if by a call to asType
.
When called, the adapter replaces its trailing arrayLength
arguments by a single new array of type arrayType
, whose elements
comprise (in order) the replaced arguments.
Finally the target is called.
What the target eventually returns is returned unchanged by the adapter.
(The array may also be a shared constant when arrayLength
is zero.)
(Note: The arrayType
is often identical to the last
parameter type of the original target.
It is an explicit argument for symmetry with asSpreader
, and also
to allow the target to use a simple Object
as its last parameter type.)
In order to create a collecting adapter which is not restricted to a particular
number of collected arguments, use asVarargsCollector
instead.
Here are some examples of array-collecting method handles:
MethodHandle deepToString = publicLookup() .findStatic(Arrays.class, "deepToString", methodType(String.class, Object[].class)); assertEquals("[won]", (String) deepToString.invokeExact(new Object[]{"won"})); MethodHandle ts1 = deepToString.asCollector(Object[].class, 1); assertEquals(methodType(String.class, Object.class), ts1.type()); //assertEquals("[won]", (String) ts1.invokeExact( new Object[]{"won"})); //FAIL assertEquals("[[won]]", (String) ts1.invokeExact((Object) new Object[]{"won"})); // arrayType can be a subtype of Object[] MethodHandle ts2 = deepToString.asCollector(String[].class, 2); assertEquals(methodType(String.class, String.class, String.class), ts2.type()); assertEquals("[two, too]", (String) ts2.invokeExact("two", "too")); MethodHandle ts0 = deepToString.asCollector(Object[].class, 0); assertEquals("[]", (String) ts0.invokeExact()); // collectors can be nested, Lisp-style MethodHandle ts22 = deepToString.asCollector(Object[].class, 3).asCollector(String[].class, 2); assertEquals("[A, B, [C, D]]", ((String) ts22.invokeExact((Object)'A', (Object)"B", "C", "D"))); // arrayType can be any primitive array type MethodHandle bytesToString = publicLookup() .findStatic(Arrays.class, "toString", methodType(String.class, byte[].class)) .asCollector(byte[].class, 3); assertEquals("[1, 2, 3]", (String) bytesToString.invokeExact((byte)1, (byte)2, (byte)3)); MethodHandle longsToString = publicLookup() .findStatic(Arrays.class, "toString", methodType(String.class, long[].class)) .asCollector(long[].class, 1); assertEquals("[123]", (String) longsToString.invokeExact((long)123));
arrayType
- often Object[]
, the type of the array argument which will collect the argumentsarrayLength
- the number of arguments to collect into a new array argumentNullPointerException
- if arrayType
is a null referenceIllegalArgumentException
- if arrayType
is not an array type
or arrayType
is not assignable to this method handle's trailing parameter type,
or arrayLength
is not a legal array sizeWrongMethodTypeException
- if the implied asType
call failsasSpreader(java.lang.Class<?>, int)
,
asVarargsCollector(java.lang.Class<?>)
public MethodHandle asVarargsCollector(Class<?> arrayType)
The type and behavior of the adapter will be the same as
the type and behavior of the target, except that certain
invoke
and asType
requests can lead to
trailing positional arguments being collected into target's
trailing parameter.
Also, the last parameter type of the adapter will be
arrayType
, even if the target has a different
last parameter type.
This transformation may return this
if the method handle is
already of variable arity and its trailing parameter type
is identical to arrayType
.
When called with invokeExact
, the adapter invokes
the target with no argument changes.
(Note: This behavior is different from a
fixed arity collector,
since it accepts a whole array of indeterminate length,
rather than a fixed number of arguments.)
When called with plain, inexact invoke
, if the caller
type is the same as the adapter, the adapter invokes the target as with
invokeExact
.
(This is the normal behavior for invoke
when types match.)
Otherwise, if the caller and adapter arity are the same, and the
trailing parameter type of the caller is a reference type identical to
or assignable to the trailing parameter type of the adapter,
the arguments and return values are converted pairwise,
as if by asType
on a fixed arity
method handle.
Otherwise, the arities differ, or the adapter's trailing parameter
type is not assignable from the corresponding caller type.
In this case, the adapter replaces all trailing arguments from
the original trailing argument position onward, by
a new array of type arrayType
, whose elements
comprise (in order) the replaced arguments.
The caller type must provides as least enough arguments,
and of the correct type, to satisfy the target's requirement for
positional arguments before the trailing array argument.
Thus, the caller must supply, at a minimum, N-1
arguments,
where N
is the arity of the target.
Also, there must exist conversions from the incoming arguments
to the target's arguments.
As with other uses of plain invoke
, if these basic
requirements are not fulfilled, a WrongMethodTypeException
may be thrown.
In all cases, what the target eventually returns is returned unchanged by the adapter.
In the final case, it is exactly as if the target method handle were
temporarily adapted with a fixed arity collector
to the arity required by the caller type.
(As with asCollector
, if the array length is zero,
a shared constant may be used instead of a new array.
If the implied call to asCollector
would throw
an IllegalArgumentException
or WrongMethodTypeException
,
the call to the variable arity adapter must throw
WrongMethodTypeException
.)
The behavior of asType
is also specialized for
variable arity adapters, to maintain the invariant that
plain, inexact invoke
is always equivalent to an asType
call to adjust the target type, followed by invokeExact
.
Therefore, a variable arity adapter responds
to an asType
request by building a fixed arity collector,
if and only if the adapter and requested type differ either
in arity or trailing argument type.
The resulting fixed arity collector has its type further adjusted
(if necessary) to the requested type by pairwise conversion,
as if by another application of asType
.
When a method handle is obtained by executing an ldc
instruction
of a CONSTANT_MethodHandle
constant, and the target method is marked
as a variable arity method (with the modifier bit 0x0080
),
the method handle will accept multiple arities, as if the method handle
constant were created by means of a call to asVarargsCollector
.
In order to create a collecting adapter which collects a predetermined
number of arguments, and whose type reflects this predetermined number,
use asCollector
instead.
No method handle transformations produce new method handles with
variable arity, unless they are documented as doing so.
Therefore, besides asVarargsCollector
,
all methods in MethodHandle
and MethodHandles
will return a method handle with fixed arity,
except in the cases where they are specified to return their original
operand (e.g., asType
of the method handle's own type).
Calling asVarargsCollector
on a method handle which is already
of variable arity will produce a method handle with the same type and behavior.
It may (or may not) return the original variable arity method handle.
Here is an example, of a list-making variable arity method handle:
MethodHandle deepToString = publicLookup() .findStatic(Arrays.class, "deepToString", methodType(String.class, Object[].class)); MethodHandle ts1 = deepToString.asVarargsCollector(Object[].class); assertEquals("[won]", (String) ts1.invokeExact( new Object[]{"won"})); assertEquals("[won]", (String) ts1.invoke( new Object[]{"won"})); assertEquals("[won]", (String) ts1.invoke( "won" )); assertEquals("[[won]]", (String) ts1.invoke((Object) new Object[]{"won"})); // findStatic of Arrays.asList(...) produces a variable arity method handle: MethodHandle asList = publicLookup() .findStatic(Arrays.class, "asList", methodType(List.class, Object[].class)); assertEquals(methodType(List.class, Object[].class), asList.type()); assert(asList.isVarargsCollector()); assertEquals("[]", asList.invoke().toString()); assertEquals("[1]", asList.invoke(1).toString()); assertEquals("[two, too]", asList.invoke("two", "too").toString()); String[] argv = { "three", "thee", "tee" }; assertEquals("[three, thee, tee]", asList.invoke(argv).toString()); assertEquals("[three, thee, tee]", asList.invoke((Object[])argv).toString()); List ls = (List) asList.invoke((Object)argv); assertEquals(1, ls.size()); assertEquals("[three, thee, tee]", Arrays.toString((Object[])ls.get(0)));
Discussion: These rules are designed as a dynamically-typed variation of the Java rules for variable arity methods. In both cases, callers to a variable arity method or method handle can either pass zero or more positional arguments, or else pass pre-collected arrays of any length. Users should be aware of the special role of the final argument, and of the effect of a type match on that final argument, which determines whether or not a single trailing argument is interpreted as a whole array or a single element of an array to be collected. Note that the dynamic type of the trailing argument has no effect on this decision, only a comparison between the symbolic type descriptor of the call site and the type descriptor of the method handle.)
arrayType
- often Object[]
, the type of the array argument which will collect the argumentsNullPointerException
- if arrayType
is a null referenceIllegalArgumentException
- if arrayType
is not an array type
or arrayType
is not assignable to this method handle's trailing parameter typeasCollector(java.lang.Class<?>, int)
,
isVarargsCollector()
,
asFixedArity()
public boolean isVarargsCollector()
ldc
instruction of a CONSTANT_MethodHandle
which resolves to a variable arity Java method or constructor
invoke
callsasVarargsCollector(java.lang.Class<?>)
,
asFixedArity()
public MethodHandle asFixedArity()
If the current method handle is not of
variable arity,
the current method handle is returned.
This is true even if the current method handle
could not be a valid input to asVarargsCollector
.
Otherwise, the resulting fixed-arity method handle has the same
type and behavior of the current method handle,
except that isVarargsCollector
will be false.
The fixed-arity method handle may (or may not) be the
a previous argument to asVarargsCollector
.
Here is an example, of a list-making variable arity method handle:
MethodHandle asListVar = publicLookup() .findStatic(Arrays.class, "asList", methodType(List.class, Object[].class)) .asVarargsCollector(Object[].class); MethodHandle asListFix = asListVar.asFixedArity(); assertEquals("[1]", asListVar.invoke(1).toString()); Exception caught = null; try { asListFix.invoke((Object)1); } catch (Exception ex) { caught = ex; } assert(caught instanceof ClassCastException); assertEquals("[two, too]", asListVar.invoke("two", "too").toString()); try { asListFix.invoke("two", "too"); } catch (Exception ex) { caught = ex; } assert(caught instanceof WrongMethodTypeException); Object[] argv = { "three", "thee", "tee" }; assertEquals("[three, thee, tee]", asListVar.invoke(argv).toString()); assertEquals("[three, thee, tee]", asListFix.invoke(argv).toString()); assertEquals(1, ((List) asListVar.invoke((Object)argv)).size()); assertEquals("[three, thee, tee]", asListFix.invoke((Object)argv).toString());
asVarargsCollector(java.lang.Class<?>)
,
isVarargsCollector()
public MethodHandle bindTo(Object x)
x
to the first argument of a method handle, without invoking it.
The new method handle adapts, as its target,
the current method handle by binding it to the given argument.
The type of the bound handle will be
the same as the type of the target, except that a single leading
reference parameter will be omitted.
When called, the bound handle inserts the given value x
as a new leading argument to the target. The other arguments are
also passed unchanged.
What the target eventually returns is returned unchanged by the bound handle.
The reference x
must be convertible to the first parameter
type of the target.
(Note: Because method handles are immutable, the target method handle retains its original type and behavior.)
x
- the value to bind to the first argument of the targetIllegalArgumentException
- if the target does not have a
leading parameter type that is a reference typeClassCastException
- if x
cannot be converted
to the leading parameter type of the targetMethodHandles.insertArguments(java.lang.invoke.MethodHandle, int, java.lang.Object...)
public String toString()
"MethodHandle"
and
ending with the string representation of the method handle's type.
In other words, this method returns a string equal to the value of:
"MethodHandle" + type().toString()
(Note: Future releases of this API may add further information to the string representation. Therefore, the present syntax should not be parsed by applications.)
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