8146801: Allocating short arrays of non-constant size is slow
Reviewed-by: kvn, twisti, vlivanov
/*
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* 2 along with this work; if not, write to the Free Software Foundation,
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#ifndef SHARE_VM_RUNTIME_TASK_HPP
#define SHARE_VM_RUNTIME_TASK_HPP
#include "utilities/top.hpp"
// A PeriodicTask has the sole purpose of executing its task
// function with regular intervals.
// Usage:
// PeriodicTask pf(10);
// pf.enroll();
// ...
// pf.disenroll();
class PeriodicTask: public CHeapObj<mtInternal> {
public:
// Useful constants.
// The interval constants are used to ensure the declared interval
// is appropriate; it must be between min_interval and max_interval,
// and have a granularity of interval_gran (all in millis).
enum { max_tasks = 10, // Max number of periodic tasks in system
interval_gran = 10,
min_interval = 10,
max_interval = 10000 };
static int num_tasks() { return _num_tasks; }
private:
int _counter;
const int _interval;
static int _num_tasks;
static PeriodicTask* _tasks[PeriodicTask::max_tasks];
// Can only be called by the WatcherThread
static void real_time_tick(int delay_time);
#ifndef PRODUCT
static elapsedTimer _timer; // measures time between ticks
static int _ticks; // total number of ticks
static int _intervalHistogram[max_interval]; // to check spacing of timer interrupts
public:
static void print_intervals();
#endif
// Only the WatcherThread can cause us to execute PeriodicTasks
friend class WatcherThread;
public:
PeriodicTask(size_t interval_time); // interval is in milliseconds of elapsed time
~PeriodicTask();
// Make the task active
// For dynamic enrollment at the time T, the task will execute somewhere
// between T and T + interval_time.
void enroll();
// Make the task deactive
void disenroll();
void execute_if_pending(int delay_time) {
// make sure we don't overflow
jlong tmp = (jlong) _counter + (jlong) delay_time;
if (tmp >= (jlong) _interval) {
_counter = 0;
task();
} else {
_counter += delay_time;
}
}
// Returns how long (time in milliseconds) before the next time we should
// execute this task.
int time_to_next_interval() const {
assert(_interval > _counter, "task counter greater than interval?");
return _interval - _counter;
}
// Calculate when the next periodic task will fire.
// Called by the WatcherThread's run method.
// Requires the PeriodicTask_lock.
static int time_to_wait();
// The task to perform at each period
virtual void task() = 0;
};
#endif // SHARE_VM_RUNTIME_TASK_HPP