public class Timer extends Object
Corresponding to each Timer object is a single background thread that is used to execute all of the timer's tasks, sequentially. Timer tasks should complete quickly. If a timer task takes excessive time to complete, it "hogs" the timer's task execution thread. This can, in turn, delay the execution of subsequent tasks, which may "bunch up" and execute in rapid succession when (and if) the offending task finally completes.
After the last live reference to a Timer object goes away and all outstanding tasks have completed execution, the timer's task execution thread terminates gracefully (and becomes subject to garbage collection). However, this can take arbitrarily long to occur. By default, the task execution thread does not run as a daemon thread, so it is capable of keeping an application from terminating. If a caller wants to terminate a timer's task execution thread rapidly, the caller should invoke the timer's cancel method.
If the timer's task execution thread terminates unexpectedly, for example, because its stop method is invoked, any further attempt to schedule a task on the timer will result in an IllegalStateException, as if the timer's cancel method had been invoked.
This class is thread-safe: multiple threads can share a single Timer object without the need for external synchronization.
This class does not offer real-time guarantees: it schedules tasks using the Object.wait(long) method.
Java 5.0 introduced the java.util.concurrent
package and
one of the concurrency utilities therein is the ScheduledThreadPoolExecutor
which is a thread pool for repeatedly
executing tasks at a given rate or delay. It is effectively a more
versatile replacement for the Timer
/TimerTask
combination, as it allows multiple service threads, accepts various
time units, and doesn't require subclassing TimerTask
(just
implement Runnable
). Configuring ScheduledThreadPoolExecutor
with one thread makes it equivalent to
Timer
.
Implementation note: This class scales to large numbers of concurrently scheduled tasks (thousands should present no problem). Internally, it uses a binary heap to represent its task queue, so the cost to schedule a task is O(log n), where n is the number of concurrently scheduled tasks.
Implementation note: All constructors start a timer thread.
TimerTask
,
Object.wait(long)
Constructor and Description |
---|
Timer()
Creates a new timer.
|
Timer(boolean isDaemon)
Creates a new timer whose associated thread may be specified to
run as a daemon.
|
Timer(String name)
Creates a new timer whose associated thread has the specified name.
|
Timer(String name,
boolean isDaemon)
Creates a new timer whose associated thread has the specified name,
and may be specified to
run as a daemon.
|
Modifier and Type | Method and Description |
---|---|
void |
cancel()
Terminates this timer, discarding any currently scheduled tasks.
|
int |
purge()
Removes all cancelled tasks from this timer's task queue.
|
void |
schedule(TimerTask task,
Date time)
Schedules the specified task for execution at the specified time.
|
void |
schedule(TimerTask task,
Date firstTime,
long period)
Schedules the specified task for repeated fixed-delay execution,
beginning at the specified time.
|
void |
schedule(TimerTask task,
long delay)
Schedules the specified task for execution after the specified delay.
|
void |
schedule(TimerTask task,
long delay,
long period)
Schedules the specified task for repeated fixed-delay execution,
beginning after the specified delay.
|
void |
scheduleAtFixedRate(TimerTask task,
Date firstTime,
long period)
Schedules the specified task for repeated fixed-rate execution,
beginning at the specified time.
|
void |
scheduleAtFixedRate(TimerTask task,
long delay,
long period)
Schedules the specified task for repeated fixed-rate execution,
beginning after the specified delay.
|
public Timer()
public Timer(boolean isDaemon)
isDaemon
- true if the associated thread should run as a daemon.public Timer(String name)
name
- the name of the associated threadNullPointerException
- if name
is nullpublic Timer(String name, boolean isDaemon)
name
- the name of the associated threadisDaemon
- true if the associated thread should run as a daemonNullPointerException
- if name
is nullpublic void schedule(TimerTask task, long delay)
task
- task to be scheduled.delay
- delay in milliseconds before task is to be executed.IllegalArgumentException
- if delay is negative, or
delay + System.currentTimeMillis() is negative.IllegalStateException
- if task was already scheduled or
cancelled, timer was cancelled, or timer thread terminated.NullPointerException
- if task
is nullpublic void schedule(TimerTask task, Date time)
task
- task to be scheduled.time
- time at which task is to be executed.IllegalArgumentException
- if time.getTime() is negative.IllegalStateException
- if task was already scheduled or
cancelled, timer was cancelled, or timer thread terminated.NullPointerException
- if task
or time
is nullpublic void schedule(TimerTask task, long delay, long period)
In fixed-delay execution, each execution is scheduled relative to the actual execution time of the previous execution. If an execution is delayed for any reason (such as garbage collection or other background activity), subsequent executions will be delayed as well. In the long run, the frequency of execution will generally be slightly lower than the reciprocal of the specified period (assuming the system clock underlying Object.wait(long) is accurate).
Fixed-delay execution is appropriate for recurring activities that require "smoothness." In other words, it is appropriate for activities where it is more important to keep the frequency accurate in the short run than in the long run. This includes most animation tasks, such as blinking a cursor at regular intervals. It also includes tasks wherein regular activity is performed in response to human input, such as automatically repeating a character as long as a key is held down.
task
- task to be scheduled.delay
- delay in milliseconds before task is to be executed.period
- time in milliseconds between successive task executions.IllegalArgumentException
- if delay < 0
, or
delay + System.currentTimeMillis() < 0
, or
period <= 0
IllegalStateException
- if task was already scheduled or
cancelled, timer was cancelled, or timer thread terminated.NullPointerException
- if task
is nullpublic void schedule(TimerTask task, Date firstTime, long period)
In fixed-delay execution, each execution is scheduled relative to the actual execution time of the previous execution. If an execution is delayed for any reason (such as garbage collection or other background activity), subsequent executions will be delayed as well. In the long run, the frequency of execution will generally be slightly lower than the reciprocal of the specified period (assuming the system clock underlying Object.wait(long) is accurate). As a consequence of the above, if the scheduled first time is in the past, it is scheduled for immediate execution.
Fixed-delay execution is appropriate for recurring activities that require "smoothness." In other words, it is appropriate for activities where it is more important to keep the frequency accurate in the short run than in the long run. This includes most animation tasks, such as blinking a cursor at regular intervals. It also includes tasks wherein regular activity is performed in response to human input, such as automatically repeating a character as long as a key is held down.
task
- task to be scheduled.firstTime
- First time at which task is to be executed.period
- time in milliseconds between successive task executions.IllegalArgumentException
- if firstTime.getTime() < 0
, or
period <= 0
IllegalStateException
- if task was already scheduled or
cancelled, timer was cancelled, or timer thread terminated.NullPointerException
- if task
or firstTime
is nullpublic void scheduleAtFixedRate(TimerTask task, long delay, long period)
In fixed-rate execution, each execution is scheduled relative to the scheduled execution time of the initial execution. If an execution is delayed for any reason (such as garbage collection or other background activity), two or more executions will occur in rapid succession to "catch up." In the long run, the frequency of execution will be exactly the reciprocal of the specified period (assuming the system clock underlying Object.wait(long) is accurate).
Fixed-rate execution is appropriate for recurring activities that are sensitive to absolute time, such as ringing a chime every hour on the hour, or running scheduled maintenance every day at a particular time. It is also appropriate for recurring activities where the total time to perform a fixed number of executions is important, such as a countdown timer that ticks once every second for ten seconds. Finally, fixed-rate execution is appropriate for scheduling multiple repeating timer tasks that must remain synchronized with respect to one another.
task
- task to be scheduled.delay
- delay in milliseconds before task is to be executed.period
- time in milliseconds between successive task executions.IllegalArgumentException
- if delay < 0
, or
delay + System.currentTimeMillis() < 0
, or
period <= 0
IllegalStateException
- if task was already scheduled or
cancelled, timer was cancelled, or timer thread terminated.NullPointerException
- if task
is nullpublic void scheduleAtFixedRate(TimerTask task, Date firstTime, long period)
In fixed-rate execution, each execution is scheduled relative to the scheduled execution time of the initial execution. If an execution is delayed for any reason (such as garbage collection or other background activity), two or more executions will occur in rapid succession to "catch up." In the long run, the frequency of execution will be exactly the reciprocal of the specified period (assuming the system clock underlying Object.wait(long) is accurate). As a consequence of the above, if the scheduled first time is in the past, then any "missed" executions will be scheduled for immediate "catch up" execution.
Fixed-rate execution is appropriate for recurring activities that are sensitive to absolute time, such as ringing a chime every hour on the hour, or running scheduled maintenance every day at a particular time. It is also appropriate for recurring activities where the total time to perform a fixed number of executions is important, such as a countdown timer that ticks once every second for ten seconds. Finally, fixed-rate execution is appropriate for scheduling multiple repeating timer tasks that must remain synchronized with respect to one another.
task
- task to be scheduled.firstTime
- First time at which task is to be executed.period
- time in milliseconds between successive task executions.IllegalArgumentException
- if firstTime.getTime() < 0
or
period <= 0
IllegalStateException
- if task was already scheduled or
cancelled, timer was cancelled, or timer thread terminated.NullPointerException
- if task
or firstTime
is nullpublic void cancel()
Note that calling this method from within the run method of a timer task that was invoked by this timer absolutely guarantees that the ongoing task execution is the last task execution that will ever be performed by this timer.
This method may be called repeatedly; the second and subsequent calls have no effect.
public int purge()
Most programs will have no need to call this method. It is designed for use by the rare application that cancels a large number of tasks. Calling this method trades time for space: the runtime of the method may be proportional to n + c log n, where n is the number of tasks in the queue and c is the number of cancelled tasks.
Note that it is permissible to call this method from within a a task scheduled on this timer.
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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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