public class MutableCallSite extends CallSite
MutableCallSite
is a CallSite
whose target variable
behaves like an ordinary field.
An invokedynamic
instruction linked to a MutableCallSite
delegates
all calls to the site's current target.
The dynamic invoker of a mutable call site
also delegates each call to the site's current target.
Here is an example of a mutable call site which introduces a state variable into a method handle chain.
MutableCallSite name = new MutableCallSite(MethodType.methodType(String.class)); MethodHandle MH_name = name.dynamicInvoker(); MethodType MT_str1 = MethodType.methodType(String.class); MethodHandle MH_upcase = MethodHandles.lookup() .findVirtual(String.class, "toUpperCase", MT_str1); MethodHandle worker1 = MethodHandles.filterReturnValue(MH_name, MH_upcase); name.setTarget(MethodHandles.constant(String.class, "Rocky")); assertEquals("ROCKY", (String) worker1.invokeExact()); name.setTarget(MethodHandles.constant(String.class, "Fred")); assertEquals("FRED", (String) worker1.invokeExact()); // (mutation can be continued indefinitely)
The same call site may be used in several places at once.
MethodType MT_str2 = MethodType.methodType(String.class, String.class); MethodHandle MH_cat = lookup().findVirtual(String.class, "concat", methodType(String.class, String.class)); MethodHandle MH_dear = MethodHandles.insertArguments(MH_cat, 1, ", dear?"); MethodHandle worker2 = MethodHandles.filterReturnValue(MH_name, MH_dear); assertEquals("Fred, dear?", (String) worker2.invokeExact()); name.setTarget(MethodHandles.constant(String.class, "Wilma")); assertEquals("WILMA", (String) worker1.invokeExact()); assertEquals("Wilma, dear?", (String) worker2.invokeExact());
Non-synchronization of target values: A write to a mutable call site's target does not force other threads to become aware of the updated value. Threads which do not perform suitable synchronization actions relative to the updated call site may cache the old target value and delay their use of the new target value indefinitely. (This is a normal consequence of the Java Memory Model as applied to object fields.)
The syncAll
operation provides a way to force threads
to accept a new target value, even if there is no other synchronization.
For target values which will be frequently updated, consider using a volatile call site instead.
Constructor and Description |
---|
MutableCallSite(MethodHandle target)
Creates a call site object with an initial target method handle.
|
MutableCallSite(MethodType type)
Creates a blank call site object with the given method type.
|
Modifier and Type | Method and Description |
---|---|
MethodHandle |
dynamicInvoker()
Produces a method handle equivalent to an invokedynamic instruction
which has been linked to this call site.
|
MethodHandle |
getTarget()
Returns the target method of the call site, which behaves
like a normal field of the
MutableCallSite . |
void |
setTarget(MethodHandle newTarget)
Updates the target method of this call site, as a normal variable.
|
static void |
syncAll(MutableCallSite[] sites)
Performs a synchronization operation on each call site in the given array,
forcing all other threads to throw away any cached values previously
loaded from the target of any of the call sites.
|
public MutableCallSite(MethodType type)
IllegalStateException
if called.
The type of the call site is permanently set to the given type.
Before this CallSite
object is returned from a bootstrap method,
or invoked in some other manner,
it is usually provided with a more useful target method,
via a call to setTarget
.
type
- the method type that this call site will haveNullPointerException
- if the proposed type is nullpublic MutableCallSite(MethodHandle target)
target
- the method handle that will be the initial target of the call siteNullPointerException
- if the proposed target is nullpublic final MethodHandle getTarget()
MutableCallSite
.
The interactions of getTarget
with memory are the same
as of a read from an ordinary variable, such as an array element or a
non-volatile, non-final field.
In particular, the current thread may choose to reuse the result of a previous read of the target from memory, and may fail to see a recent update to the target by another thread.
getTarget
in class CallSite
setTarget(java.lang.invoke.MethodHandle)
public void setTarget(MethodHandle newTarget)
The interactions with memory are the same as of a write to an ordinary variable, such as an array element or a non-volatile, non-final field.
In particular, unrelated threads may fail to see the updated target until they perform a read from memory. Stronger guarantees can be created by putting appropriate operations into the bootstrap method and/or the target methods used at any given call site.
setTarget
in class CallSite
newTarget
- the new targetNullPointerException
- if the proposed new target is nullWrongMethodTypeException
- if the proposed new target
has a method type that differs from the previous targetgetTarget()
public final MethodHandle dynamicInvoker()
This method is equivalent to the following code:
MethodHandle getTarget, invoker, result; getTarget = MethodHandles.publicLookup().bind(this, "getTarget", MethodType.methodType(MethodHandle.class)); invoker = MethodHandles.exactInvoker(this.type()); result = MethodHandles.foldArguments(invoker, getTarget)
dynamicInvoker
in class CallSite
public static void syncAll(MutableCallSite[] sites)
This operation does not reverse any calls that have already started on an old target value. (Java supports forward time travel only.)
The overall effect is to force all future readers of each call site's target
to accept the most recently stored value.
("Most recently" is reckoned relative to the syncAll
itself.)
Conversely, the syncAll
call may block until all readers have
(somehow) decached all previous versions of each call site's target.
To avoid race conditions, calls to setTarget
and syncAll
should generally be performed under some sort of mutual exclusion.
Note that reader threads may observe an updated target as early
as the setTarget
call that install the value
(and before the syncAll
that confirms the value).
On the other hand, reader threads may observe previous versions of
the target until the syncAll
call returns
(and after the setTarget
that attempts to convey the updated version).
This operation is likely to be expensive and should be used sparingly. If possible, it should be buffered for batch processing on sets of call sites.
If sites
contains a null element,
a NullPointerException
will be raised.
In this case, some non-null elements in the array may be
processed before the method returns abnormally.
Which elements these are (if any) is implementation-dependent.
The following effects are apparent, for each individual call site S
:
V
is created, and written by the current thread.
As defined by the JMM, this write is a global synchronization event.
V
.
(In some implementations, this means that the current thread
performs a global release operation.)
S
is
taken to happen before the volatile write to V
.
V
is placed
(in an implementation specific manner)
in the global synchronization order.
T
(other than the current thread).
If T
executes a synchronization action A
after the volatile write to V
(in the global synchronization order),
it is therefore required to see either the current target
of S
, or a later write to that target,
if it executes a read on the target of S
.
(This constraint is called "synchronization-order consistency".)
V
will not be elided, even though its written value is
indeterminate and its read value is not used.
V
were performed by T
immediately after its action A
. In the local ordering
of actions in T
, this read happens before any future
read of the target of S
. It is as if the
implementation arbitrarily picked a read of S
's target
by T
, and forced a read of V
to precede it,
thereby ensuring communication of the new target value.
As long as the constraints of the Java Memory Model are obeyed,
implementations may delay the completion of a syncAll
operation while other threads (T
above) continue to
use previous values of S
's target.
However, implementations are (as always) encouraged to avoid
livelock, and to eventually require all threads to take account
of the updated target.
Discussion:
For performance reasons, syncAll
is not a virtual method
on a single call site, but rather applies to a set of call sites.
Some implementations may incur a large fixed overhead cost
for processing one or more synchronization operations,
but a small incremental cost for each additional call site.
In any case, this operation is likely to be costly, since
other threads may have to be somehow interrupted
in order to make them notice the updated target value.
However, it may be observed that a single call to synchronize
several sites has the same formal effect as many calls,
each on just one of the sites.
Implementation Note:
Simple implementations of MutableCallSite
may use
a volatile variable for the target of a mutable call site.
In such an implementation, the syncAll
method can be a no-op,
and yet it will conform to the JMM behavior documented above.
sites
- an array of call sites to be synchronizedNullPointerException
- if the sites
array reference is null
or the array contains a null Submit a bug or feature
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.
Copyright © 1993, 2014, Oracle and/or its affiliates. All rights reserved.