@Beta public final class Futures extends Object
Future
interface.
Many of these methods use the ListenableFuture
API; consult the
Guava User Guide article on
ListenableFuture
.
Modifier and Type | Method and Description |
---|---|
static <V> void |
addCallback(ListenableFuture<V> future,
FutureCallback<? super V> callback)
Registers separate success and failure callbacks to be run when the
Future 's computation is complete or, if the computation is already complete, immediately. |
static <V> void |
addCallback(ListenableFuture<V> future,
FutureCallback<? super V> callback,
Executor executor)
Registers separate success and failure callbacks to be run when the
Future 's computation is complete or, if the computation is already complete, immediately. |
static <V> ListenableFuture<List<V>> |
allAsList(Iterable<? extends ListenableFuture<? extends V>> futures)
Creates a new
ListenableFuture whose value is a list containing the
values of all its input futures, if all succeed. |
static <V> ListenableFuture<List<V>> |
allAsList(ListenableFuture<? extends V>... futures)
Creates a new
ListenableFuture whose value is a list containing the
values of all its input futures, if all succeed. |
static <V> ListenableFuture<V> |
dereference(ListenableFuture<? extends ListenableFuture<? extends V>> nested)
Returns a new
ListenableFuture whose result is the product of
calling get() on the Future nested within the given Future , effectively chaining the futures one after the other. |
static <V,X extends Exception> |
get(Future<V> future,
Class<X> exceptionClass)
Returns the result of
Future.get() , converting most exceptions to a
new instance of the given checked exception type. |
static <V,X extends Exception> |
get(Future<V> future,
long timeout,
TimeUnit unit,
Class<X> exceptionClass)
Returns the result of
Future.get(long, TimeUnit) , converting most
exceptions to a new instance of the given checked exception type. |
static <V> V |
getUnchecked(Future<V> future)
Returns the result of calling
Future.get() uninterruptibly on a
task known not to throw a checked exception. |
static <V> ListenableFuture<V> |
immediateCancelledFuture()
Creates a
ListenableFuture which is cancelled immediately upon
construction, so that isCancelled() always returns true . |
static <V,X extends Exception> |
immediateCheckedFuture(V value)
Returns a
CheckedFuture which has its value set immediately upon
construction. |
static <V,X extends Exception> |
immediateFailedCheckedFuture(X exception)
Returns a
CheckedFuture which has an exception set immediately upon
construction. |
static <V> ListenableFuture<V> |
immediateFailedFuture(Throwable throwable)
Returns a
ListenableFuture which has an exception set immediately
upon construction. |
static <V> ListenableFuture<V> |
immediateFuture(V value)
Creates a
ListenableFuture which has its value set immediately upon
construction. |
static <I,O> Future<O> |
lazyTransform(Future<I> input,
Function<? super I,? extends O> function)
Like
transform(ListenableFuture, Function) except that the
transformation function is invoked on each call to
get() on the returned future. |
static <V,X extends Exception> |
makeChecked(ListenableFuture<V> future,
Function<Exception,X> mapper)
Creates a
CheckedFuture out of a normal ListenableFuture
and a Function that maps from Exception instances into the
appropriate checked type. |
static <V> ListenableFuture<V> |
nonCancellationPropagating(ListenableFuture<V> future)
Creates a new
ListenableFuture whose result is set from the
supplied future when it completes. |
static <V> ListenableFuture<List<V>> |
successfulAsList(Iterable<? extends ListenableFuture<? extends V>> futures)
Creates a new
ListenableFuture whose value is a list containing the
values of all its successful input futures. |
static <V> ListenableFuture<List<V>> |
successfulAsList(ListenableFuture<? extends V>... futures)
Creates a new
ListenableFuture whose value is a list containing the
values of all its successful input futures. |
static <I,O> ListenableFuture<O> |
transform(ListenableFuture<I> input,
AsyncFunction<? super I,? extends O> function)
Returns a new
ListenableFuture whose result is asynchronously
derived from the result of the given Future . |
static <I,O> ListenableFuture<O> |
transform(ListenableFuture<I> input,
AsyncFunction<? super I,? extends O> function,
Executor executor)
Returns a new
ListenableFuture whose result is asynchronously
derived from the result of the given Future . |
static <I,O> ListenableFuture<O> |
transform(ListenableFuture<I> input,
Function<? super I,? extends O> function)
Returns a new
ListenableFuture whose result is the product of
applying the given Function to the result of the given Future . |
static <I,O> ListenableFuture<O> |
transform(ListenableFuture<I> input,
Function<? super I,? extends O> function,
Executor executor)
Returns a new
ListenableFuture whose result is the product of
applying the given Function to the result of the given Future . |
static <V> ListenableFuture<V> |
withFallback(ListenableFuture<? extends V> input,
FutureFallback<? extends V> fallback)
Returns a
Future whose result is taken from the given primary
input or, if the primary input fails, from the Future
provided by the fallback . |
static <V> ListenableFuture<V> |
withFallback(ListenableFuture<? extends V> input,
FutureFallback<? extends V> fallback,
Executor executor)
Returns a
Future whose result is taken from the given primary
input or, if the primary input fails, from the Future
provided by the fallback . |
public static <V,X extends Exception> CheckedFuture<V,X> makeChecked(ListenableFuture<V> future, Function<Exception,X> mapper)
CheckedFuture
out of a normal ListenableFuture
and a Function
that maps from Exception
instances into the
appropriate checked type.
The given mapping function will be applied to an
InterruptedException
, a CancellationException
, or an
ExecutionException
.
See Future.get()
for details on the exceptions thrown.
public static <V> ListenableFuture<V> immediateFuture(@Nullable V value)
ListenableFuture
which has its value set immediately upon
construction. The getters just return the value. This Future
can't
be canceled or timed out and its isDone()
method always returns
true
.public static <V,X extends Exception> CheckedFuture<V,X> immediateCheckedFuture(@Nullable V value)
CheckedFuture
which has its value set immediately upon
construction.
The returned Future
can't be cancelled, and its isDone()
method always returns true
. Calling get()
or checkedGet()
will immediately return the provided value.
public static <V> ListenableFuture<V> immediateFailedFuture(Throwable throwable)
ListenableFuture
which has an exception set immediately
upon construction.
The returned Future
can't be cancelled, and its isDone()
method always returns true
. Calling get()
will immediately
throw the provided Throwable
wrapped in an ExecutionException
.
public static <V> ListenableFuture<V> immediateCancelledFuture()
ListenableFuture
which is cancelled immediately upon
construction, so that isCancelled()
always returns true
.public static <V,X extends Exception> CheckedFuture<V,X> immediateFailedCheckedFuture(X exception)
CheckedFuture
which has an exception set immediately upon
construction.
The returned Future
can't be cancelled, and its isDone()
method always returns true
. Calling get()
will immediately
throw the provided Exception
wrapped in an ExecutionException
, and calling checkedGet()
will throw the
provided exception itself.
public static <V> ListenableFuture<V> withFallback(ListenableFuture<? extends V> input, FutureFallback<? extends V> fallback)
Future
whose result is taken from the given primary
input
or, if the primary input fails, from the Future
provided by the fallback
. FutureFallback.create(java.lang.Throwable)
is not
invoked until the primary input has failed, so if the primary input
succeeds, it is never invoked. If, during the invocation of fallback
, an exception is thrown, this exception is used as the result of
the output Future
.
Below is an example of a fallback that returns a default value if an exception occurs:
ListenableFuture<Integer> fetchCounterFuture = ...;
// Falling back to a zero counter in case an exception happens when
// processing the RPC to fetch counters.
ListenableFuture<Integer> faultTolerantFuture = Futures.withFallback(
fetchCounterFuture, new FutureFallback<Integer>() {
public ListenableFuture<Integer> create(Throwable t) {
// Returning "0" as the default for the counter when the
// exception happens.
return immediateFuture(0);
}
});
The fallback can also choose to propagate the original exception when desired:
ListenableFuture<Integer> fetchCounterFuture = ...;
// Falling back to a zero counter only in case the exception was a
// TimeoutException.
ListenableFuture<Integer> faultTolerantFuture = Futures.withFallback(
fetchCounterFuture, new FutureFallback<Integer>() {
public ListenableFuture<Integer> create(Throwable t) {
if (t instanceof TimeoutException) {
return immediateFuture(0);
}
return immediateFailedFuture(t);
}
});
Note: If the derived Future
is slow or heavyweight to create
(whether the Future
itself is slow or heavyweight to complete is
irrelevant), consider supplying an executor. If you do not supply an
executor, withFallback
will use sameThreadExecutor
, which carries some
caveats for heavier operations. For example, the call to fallback.create
may run on an unpredictable or undesirable thread:
Future
is done at the time withFallback
is called, withFallback
will call fallback.create
inline.
Future
is not yet done, withFallback
will
schedule fallback.create
to be run by the thread that completes
the input Future
, which may be an internal system thread such as
an RPC network thread.
Also note that, regardless of which thread executes the sameThreadExecutor
fallback.create
, all other registered but
unexecuted listeners are prevented from running during its execution, even
if those listeners are to run in other executors.
input
- the primary input Future
fallback
- the FutureFallback
implementation to be called if
input
failspublic static <V> ListenableFuture<V> withFallback(ListenableFuture<? extends V> input, FutureFallback<? extends V> fallback, Executor executor)
Future
whose result is taken from the given primary
input
or, if the primary input fails, from the Future
provided by the fallback
. FutureFallback.create(java.lang.Throwable)
is not
invoked until the primary input has failed, so if the primary input
succeeds, it is never invoked. If, during the invocation of fallback
, an exception is thrown, this exception is used as the result of
the output Future
.
Below is an example of a fallback that returns a default value if an exception occurs:
ListenableFuture<Integer> fetchCounterFuture = ...;
// Falling back to a zero counter in case an exception happens when
// processing the RPC to fetch counters.
ListenableFuture<Integer> faultTolerantFuture = Futures.withFallback(
fetchCounterFuture, new FutureFallback<Integer>() {
public ListenableFuture<Integer> create(Throwable t) {
// Returning "0" as the default for the counter when the
// exception happens.
return immediateFuture(0);
}
}, sameThreadExecutor());
The fallback can also choose to propagate the original exception when desired:
ListenableFuture<Integer> fetchCounterFuture = ...;
// Falling back to a zero counter only in case the exception was a
// TimeoutException.
ListenableFuture<Integer> faultTolerantFuture = Futures.withFallback(
fetchCounterFuture, new FutureFallback<Integer>() {
public ListenableFuture<Integer> create(Throwable t) {
if (t instanceof TimeoutException) {
return immediateFuture(0);
}
return immediateFailedFuture(t);
}
}, sameThreadExecutor());
When the execution of fallback.create
is fast and lightweight
(though the Future
it returns need not meet these criteria),
consider omitting the executor or explicitly specifying sameThreadExecutor
. However, be aware of the caveats documented in the
link above.
input
- the primary input Future
fallback
- the FutureFallback
implementation to be called if
input
failsexecutor
- the executor that runs fallback
if input
failspublic static <I,O> ListenableFuture<O> transform(ListenableFuture<I> input, AsyncFunction<? super I,? extends O> function)
ListenableFuture
whose result is asynchronously
derived from the result of the given Future
. More precisely, the
returned Future
takes its result from a Future
produced by
applying the given AsyncFunction
to the result of the original
Future
. Example:
ListenableFuture<RowKey> rowKeyFuture = indexService.lookUp(query);
AsyncFunction<RowKey, QueryResult> queryFunction =
new AsyncFunction<RowKey, QueryResult>() {
public ListenableFuture<QueryResult> apply(RowKey rowKey) {
return dataService.read(rowKey);
}
};
ListenableFuture<QueryResult> queryFuture =
transform(rowKeyFuture, queryFunction);
Note: If the derived Future
is slow or heavyweight to create
(whether the Future
itself is slow or heavyweight to complete is
irrelevant), consider supplying an executor. If you do not supply an
executor, transform
will use sameThreadExecutor
, which carries some
caveats for heavier operations. For example, the call to function.apply
may run on an unpredictable or undesirable thread:
Future
is done at the time transform
is
called, transform
will call function.apply
inline.
Future
is not yet done, transform
will
schedule function.apply
to be run by the thread that completes the
input Future
, which may be an internal system thread such as an
RPC network thread.
Also note that, regardless of which thread executes the sameThreadExecutor
function.apply
, all other registered but
unexecuted listeners are prevented from running during its execution, even
if those listeners are to run in other executors.
The returned Future
attempts to keep its cancellation state in
sync with that of the input future and that of the future returned by the
function. That is, if the returned Future
is cancelled, it will
attempt to cancel the other two, and if either of the other two is
cancelled, the returned Future
will receive a callback in which it
will attempt to cancel itself.
input
- The future to transformfunction
- A function to transform the result of the input future
to the result of the output futurepublic static <I,O> ListenableFuture<O> transform(ListenableFuture<I> input, AsyncFunction<? super I,? extends O> function, Executor executor)
ListenableFuture
whose result is asynchronously
derived from the result of the given Future
. More precisely, the
returned Future
takes its result from a Future
produced by
applying the given AsyncFunction
to the result of the original
Future
. Example:
ListenableFuture<RowKey> rowKeyFuture = indexService.lookUp(query);
AsyncFunction<RowKey, QueryResult> queryFunction =
new AsyncFunction<RowKey, QueryResult>() {
public ListenableFuture<QueryResult> apply(RowKey rowKey) {
return dataService.read(rowKey);
}
};
ListenableFuture<QueryResult> queryFuture =
transform(rowKeyFuture, queryFunction, executor);
The returned Future
attempts to keep its cancellation state in
sync with that of the input future and that of the future returned by the
chain function. That is, if the returned Future
is cancelled, it
will attempt to cancel the other two, and if either of the other two is
cancelled, the returned Future
will receive a callback in which it
will attempt to cancel itself.
When the execution of function.apply
is fast and lightweight
(though the Future
it returns need not meet these criteria),
consider omitting
the executor or explicitly specifying sameThreadExecutor
.
However, be aware of the caveats documented in the link above.
input
- The future to transformfunction
- A function to transform the result of the input future
to the result of the output futureexecutor
- Executor to run the function in.public static <I,O> ListenableFuture<O> transform(ListenableFuture<I> input, Function<? super I,? extends O> function)
ListenableFuture
whose result is the product of
applying the given Function
to the result of the given Future
. Example:
ListenableFuture<QueryResult> queryFuture = ...;
Function<QueryResult, List<Row>> rowsFunction =
new Function<QueryResult, List<Row>>() {
public List<Row> apply(QueryResult queryResult) {
return queryResult.getRows();
}
};
ListenableFuture<List<Row>> rowsFuture =
transform(queryFuture, rowsFunction);
Note: If the transformation is slow or heavyweight, consider supplying an executor.
If you do not supply an executor, transform
will use sameThreadExecutor
, which carries some
caveats for heavier operations. For example, the call to function.apply
may run on an unpredictable or undesirable thread:
Future
is done at the time transform
is
called, transform
will call function.apply
inline.
Future
is not yet done, transform
will
schedule function.apply
to be run by the thread that completes the
input Future
, which may be an internal system thread such as an
RPC network thread.
Also note that, regardless of which thread executes the sameThreadExecutor
function.apply
, all other registered but
unexecuted listeners are prevented from running during its execution, even
if those listeners are to run in other executors.
The returned Future
attempts to keep its cancellation state in
sync with that of the input future. That is, if the returned Future
is cancelled, it will attempt to cancel the input, and if the input is
cancelled, the returned Future
will receive a callback in which it
will attempt to cancel itself.
An example use of this method is to convert a serializable object returned from an RPC into a POJO.
input
- The future to transformfunction
- A Function to transform the results of the provided future
to the results of the returned future. This will be run in the thread
that notifies input it is complete.compose
)public static <I,O> ListenableFuture<O> transform(ListenableFuture<I> input, Function<? super I,? extends O> function, Executor executor)
ListenableFuture
whose result is the product of
applying the given Function
to the result of the given Future
. Example:
ListenableFuture<QueryResult> queryFuture = ...;
Function<QueryResult, List<Row>> rowsFunction =
new Function<QueryResult, List<Row>>() {
public List<Row> apply(QueryResult queryResult) {
return queryResult.getRows();
}
};
ListenableFuture<List<Row>> rowsFuture =
transform(queryFuture, rowsFunction, executor);
The returned Future
attempts to keep its cancellation state in
sync with that of the input future. That is, if the returned Future
is cancelled, it will attempt to cancel the input, and if the input is
cancelled, the returned Future
will receive a callback in which it
will attempt to cancel itself.
An example use of this method is to convert a serializable object returned from an RPC into a POJO.
When the transformation is fast and lightweight, consider omitting the executor or
explicitly specifying sameThreadExecutor
. However, be aware of the
caveats documented in the link above.
input
- The future to transformfunction
- A Function to transform the results of the provided future
to the results of the returned future.executor
- Executor to run the function in.compose
)public static <I,O> Future<O> lazyTransform(Future<I> input, Function<? super I,? extends O> function)
transform(ListenableFuture, Function)
except that the
transformation function
is invoked on each call to
get()
on the returned future.
The returned Future
reflects the input's cancellation
state directly, and any attempt to cancel the returned Future is likewise
passed through to the input Future.
Note that calls to timed get
only apply the timeout to the execution of the underlying Future
,
not to the execution of the transformation function.
The primary audience of this method is callers of transform
who don't have a ListenableFuture
available and
do not mind repeated, lazy function evaluation.
input
- The future to transformfunction
- A Function to transform the results of the provided future
to the results of the returned future.public static <V> ListenableFuture<V> dereference(ListenableFuture<? extends ListenableFuture<? extends V>> nested)
ListenableFuture
whose result is the product of
calling get()
on the Future
nested within the given Future
, effectively chaining the futures one after the other. Example:
SettableFuture<ListenableFuture<String>> nested = SettableFuture.create();
ListenableFuture<String> dereferenced = dereference(nested);
This call has the same cancellation and execution semantics as transform(ListenableFuture, AsyncFunction)
, in that the returned Future
attempts to keep its cancellation state in sync with both the
input Future
and the nested Future
. The transformation
is very lightweight and therefore takes place in the thread that called
dereference
.
nested
- The nested future to transform.@Beta public static <V> ListenableFuture<List<V>> allAsList(ListenableFuture<? extends V>... futures)
ListenableFuture
whose value is a list containing the
values of all its input futures, if all succeed. If any input fails, the
returned future fails.
The list of results is in the same order as the input list.
Canceling this future will attempt to cancel all the component futures, and if any of the provided futures fails or is canceled, this one is, too.
futures
- futures to combine@Beta public static <V> ListenableFuture<List<V>> allAsList(Iterable<? extends ListenableFuture<? extends V>> futures)
ListenableFuture
whose value is a list containing the
values of all its input futures, if all succeed. If any input fails, the
returned future fails.
The list of results is in the same order as the input list.
Canceling this future will attempt to cancel all the component futures, and if any of the provided futures fails or is canceled, this one is, too.
futures
- futures to combinepublic static <V> ListenableFuture<V> nonCancellationPropagating(ListenableFuture<V> future)
ListenableFuture
whose result is set from the
supplied future when it completes. Cancelling the supplied future
will also cancel the returned future, but cancelling the returned
future will have no effect on the supplied future.@Beta public static <V> ListenableFuture<List<V>> successfulAsList(ListenableFuture<? extends V>... futures)
ListenableFuture
whose value is a list containing the
values of all its successful input futures. The list of results is in the
same order as the input list, and if any of the provided futures fails or
is canceled, its corresponding position will contain null
(which is
indistinguishable from the future having a successful value of
null
).
Canceling this future will attempt to cancel all the component futures.
futures
- futures to combine@Beta public static <V> ListenableFuture<List<V>> successfulAsList(Iterable<? extends ListenableFuture<? extends V>> futures)
ListenableFuture
whose value is a list containing the
values of all its successful input futures. The list of results is in the
same order as the input list, and if any of the provided futures fails or
is canceled, its corresponding position will contain null
(which is
indistinguishable from the future having a successful value of
null
).
Canceling this future will attempt to cancel all the component futures.
futures
- futures to combinepublic static <V> void addCallback(ListenableFuture<V> future, FutureCallback<? super V> callback)
Future
's computation is complete or, if the computation is already complete, immediately.
There is no guaranteed ordering of execution of callbacks, but any callback added through this method is guaranteed to be called once the computation is complete. Example:
ListenableFuture<QueryResult> future = ...;
addCallback(future,
new FutureCallback<QueryResult> {
public void onSuccess(QueryResult result) {
storeInCache(result);
}
public void onFailure(Throwable t) {
reportError(t);
}
});
Note: If the callback is slow or heavyweight, consider supplying an
executor. If you do not supply an executor, addCallback
will use
sameThreadExecutor
, which carries
some caveats for heavier operations. For example, the callback may run on
an unpredictable or undesirable thread:
Future
is done at the time addCallback
is
called, addCallback
will execute the callback inline.
Future
is not yet done, addCallback
will
schedule the callback to be run by the thread that completes the input
Future
, which may be an internal system thread such as an RPC
network thread.
Also note that, regardless of which thread executes the sameThreadExecutor
callback, all other registered but unexecuted listeners
are prevented from running during its execution, even if those listeners
are to run in other executors.
For a more general interface to attach a completion listener to a
Future
, see addListener
.
future
- The future attach the callback to.callback
- The callback to invoke when future
is completed.public static <V> void addCallback(ListenableFuture<V> future, FutureCallback<? super V> callback, Executor executor)
Future
's computation is complete or, if the computation is already complete, immediately.
The callback is run in executor
.
There is no guaranteed ordering of execution of callbacks, but any
callback added through this method is guaranteed to be called once the
computation is complete.
Example:
ListenableFuture<QueryResult> future = ...;
Executor e = ...
addCallback(future, e,
new FutureCallback<QueryResult> {
public void onSuccess(QueryResult result) {
storeInCache(result);
}
public void onFailure(Throwable t) {
reportError(t);
}
});
When the callback is fast and lightweight, consider omitting the executor or
explicitly specifying sameThreadExecutor
. However, be aware of the
caveats documented in the link above.
For a more general interface to attach a completion listener to a
Future
, see addListener
.
future
- The future attach the callback to.callback
- The callback to invoke when future
is completed.executor
- The executor to run callback
when the future
completes.public static <V,X extends Exception> V get(Future<V> future, Class<X> exceptionClass) throws X extends Exception
Future.get()
, converting most exceptions to a
new instance of the given checked exception type. This reduces boilerplate
for a common use of Future
in which it is unnecessary to
programmatically distinguish between exception types or to extract other
information from the exception instance.
Exceptions from Future.get
are treated as follows:
ExecutionException
has its cause wrapped in an
X
if the cause is a checked exception, an UncheckedExecutionException
if the cause is a RuntimeException
, or an ExecutionError
if the cause is an
Error
.
InterruptedException
is wrapped in an X
(after
restoring the interrupt).
CancellationException
is propagated untouched, as is any
other RuntimeException
(though get
implementations are
discouraged from throwing such exceptions).
The overall principle is to continue to treat every checked exception as a
checked exception, every unchecked exception as an unchecked exception, and
every error as an error. In addition, the cause of any ExecutionException
is wrapped in order to ensure that the new stack trace
matches that of the current thread.
Instances of exceptionClass
are created by choosing an arbitrary
public constructor that accepts zero or more arguments, all of type String
or Throwable
(preferring constructors with at least one
String
) and calling the constructor via reflection. If the
exception did not already have a cause, one is set by calling Throwable.initCause(Throwable)
on it. If no such constructor exists, an
IllegalArgumentException
is thrown.
X
- if get
throws any checked exception except for an ExecutionException
whose cause is not itself a checked exceptionUncheckedExecutionException
- if get
throws an ExecutionException
with a RuntimeException
as its causeExecutionError
- if get
throws an ExecutionException
with an Error
as its causeCancellationException
- if get
throws a CancellationException
IllegalArgumentException
- if exceptionClass
extends RuntimeException
or does not have a suitable constructorX extends Exception
public static <V,X extends Exception> V get(Future<V> future, long timeout, TimeUnit unit, Class<X> exceptionClass) throws X extends Exception
Future.get(long, TimeUnit)
, converting most
exceptions to a new instance of the given checked exception type. This
reduces boilerplate for a common use of Future
in which it is
unnecessary to programmatically distinguish between exception types or to
extract other information from the exception instance.
Exceptions from Future.get
are treated as follows:
ExecutionException
has its cause wrapped in an
X
if the cause is a checked exception, an UncheckedExecutionException
if the cause is a RuntimeException
, or an ExecutionError
if the cause is an
Error
.
InterruptedException
is wrapped in an X
(after
restoring the interrupt).
TimeoutException
is wrapped in an X
.
CancellationException
is propagated untouched, as is any
other RuntimeException
(though get
implementations are
discouraged from throwing such exceptions).
The overall principle is to continue to treat every checked exception as a
checked exception, every unchecked exception as an unchecked exception, and
every error as an error. In addition, the cause of any ExecutionException
is wrapped in order to ensure that the new stack trace
matches that of the current thread.
Instances of exceptionClass
are created by choosing an arbitrary
public constructor that accepts zero or more arguments, all of type String
or Throwable
(preferring constructors with at least one
String
) and calling the constructor via reflection. If the
exception did not already have a cause, one is set by calling Throwable.initCause(Throwable)
on it. If no such constructor exists, an
IllegalArgumentException
is thrown.
X
- if get
throws any checked exception except for an ExecutionException
whose cause is not itself a checked exceptionUncheckedExecutionException
- if get
throws an ExecutionException
with a RuntimeException
as its causeExecutionError
- if get
throws an ExecutionException
with an Error
as its causeCancellationException
- if get
throws a CancellationException
IllegalArgumentException
- if exceptionClass
extends RuntimeException
or does not have a suitable constructorX extends Exception
public static <V> V getUnchecked(Future<V> future)
Future.get()
uninterruptibly on a
task known not to throw a checked exception. This makes Future
more
suitable for lightweight, fast-running tasks that, barring bugs in the
code, will not fail. This gives it exception-handling behavior similar to
that of ForkJoinTask.join
.
Exceptions from Future.get
are treated as follows:
ExecutionException
has its cause wrapped in an
UncheckedExecutionException
(if the cause is an Exception
) or ExecutionError
(if the cause is an Error
).
InterruptedException
causes a retry of the get
call. The interrupt is restored before getUnchecked
returns.
CancellationException
is propagated untouched. So is any
other RuntimeException
(get
implementations are
discouraged from throwing such exceptions).
The overall principle is to eliminate all checked exceptions: to loop to
avoid InterruptedException
, to pass through CancellationException
, and to wrap any exception from the underlying
computation in an UncheckedExecutionException
or ExecutionError
.
For an uninterruptible get
that preserves other exceptions, see
Uninterruptibles.getUninterruptibly(Future)
.
UncheckedExecutionException
- if get
throws an ExecutionException
with an Exception
as its causeExecutionError
- if get
throws an ExecutionException
with an Error
as its causeCancellationException
- if get
throws a CancellationException
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