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/*
* Copyright (C) 2008 Tobias Brunner
* Copyright (C) 2005-2006 Martin Willi
* Copyright (C) 2005 Jan Hutter
* Hochschule fuer Technik Rapperswil
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation; either version 2 of the License, or (at your
* option) any later version. See <http://www.fsf.org/copyleft/gpl.txt>.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
* or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* for more details.
*/
#include <stdlib.h>
#include <pthread.h>
#include "scheduler.h"
#include <daemon.h>
#include <processing/processor.h>
#include <processing/jobs/callback_job.h>
#include <utils/mutex.h>
/* the initial size of the heap */
#define HEAP_SIZE_DEFAULT 64
typedef struct event_t event_t;
/**
* Event containing a job and a schedule time
*/
struct event_t {
/**
* Time to fire the event.
*/
timeval_t time;
/**
* Every event has its assigned job.
*/
job_t *job;
};
/**
* destroy an event and its job
*/
static void event_destroy(event_t *event)
{
event->job->destroy(event->job);
free(event);
}
typedef struct private_scheduler_t private_scheduler_t;
/**
* Private data of a scheduler_t object.
*/
struct private_scheduler_t {
/**
* Public part of a scheduler_t object.
*/
scheduler_t public;
/**
* Job which queues scheduled jobs to the processor.
*/
callback_job_t *job;
/**
* The heap in which the events are stored.
*/
event_t **heap;
/**
* The size of the heap.
*/
u_int heap_size;
/**
* The number of scheduled events.
*/
u_int event_count;
/**
* Exclusive access to list
*/
mutex_t *mutex;
/**
* Condvar to wait for next job.
*/
condvar_t *condvar;
};
/**
* Comparse two timevals, return >0 if a > b, <0 if a < b and =0 if equal
*/
static int timeval_cmp(timeval_t *a, timeval_t *b)
{
if (a->tv_sec > b->tv_sec)
{
return 1;
}
if (a->tv_sec < b->tv_sec)
{
return -1;
}
if (a->tv_usec > b->tv_usec)
{
return 1;
}
if (a->tv_usec < b->tv_usec)
{
return -1;
}
return 0;
}
/**
* Returns the top event without removing it. Returns NULL if the heap is empty.
*/
static event_t *peek_event(private_scheduler_t *this)
{
return this->event_count > 0 ? this->heap[1] : NULL;
}
/**
* Removes the top event from the heap and returns it. Returns NULL if the heap
* is empty.
*/
static event_t *remove_event(private_scheduler_t *this)
{
event_t *event, *top;
if (!this->event_count)
{
return NULL;
}
/* store the value to return */
event = this->heap[1];
/* move the bottom event to the top */
top = this->heap[1] = this->heap[this->event_count];
if (--this->event_count > 1)
{
/* seep down the top event */
u_int position = 1;
while ((position << 1) <= this->event_count)
{
u_int child = position << 1;
if ((child + 1) <= this->event_count &&
timeval_cmp(&this->heap[child + 1]->time,
&this->heap[child]->time) < 0)
{
/* the "right" child is smaller */
child++;
}
if (timeval_cmp(&top->time, &this->heap[child]->time) <= 0)
{
/* the top event fires before the smaller of the two children,
* stop */
break;
}
/* swap with the smaller child */
this->heap[position] = this->heap[child];
position = child;
}
this->heap[position] = top;
}
return event;
}
/**
* Get events from the queue and pass it to the processor
*/
static job_requeue_t schedule(private_scheduler_t * this)
{
timeval_t now;
event_t *event;
int oldstate;
bool timed = FALSE;
this->mutex->lock(this->mutex);
gettimeofday(&now, NULL);
if ((event = peek_event(this)) != NULL)
{
if (timeval_cmp(&now, &event->time) >= 0)
{
remove_event(this);
this->mutex->unlock(this->mutex);
DBG2(DBG_JOB, "got event, queuing job for execution");
charon->processor->queue_job(charon->processor, event->job);
free(event);
return JOB_REQUEUE_DIRECT;
}
timersub(&event->time, &now, &now);
if (now.tv_sec)
{
DBG2(DBG_JOB, "next event in %ds %dms, waiting",
now.tv_sec, now.tv_usec/1000);
}
else
{
DBG2(DBG_JOB, "next event in %dms, waiting", now.tv_usec/1000);
}
timed = TRUE;
}
pthread_cleanup_push((void*)this->mutex->unlock, this->mutex);
pthread_setcancelstate(PTHREAD_CANCEL_ENABLE, &oldstate);
if (timed)
{
this->condvar->timed_wait_abs(this->condvar, this->mutex, event->time);
}
else
{
DBG2(DBG_JOB, "no events, waiting");
this->condvar->wait(this->condvar, this->mutex);
}
pthread_setcancelstate(oldstate, NULL);
pthread_cleanup_pop(TRUE);
return JOB_REQUEUE_DIRECT;
}
/**
* Implements scheduler_t.get_job_load
*/
static u_int get_job_load(private_scheduler_t *this)
{
int count;
this->mutex->lock(this->mutex);
count = this->event_count;
this->mutex->unlock(this->mutex);
return count;
}
/**
* Implements scheduler_t.schedule_job_tv.
*/
static void schedule_job_tv(private_scheduler_t *this, job_t *job, timeval_t tv)
{
event_t *event;
u_int position;
event = malloc_thing(event_t);
event->job = job;
event->time = tv;
this->mutex->lock(this->mutex);
this->event_count++;
if (this->event_count > this->heap_size)
{
/* double the size of the heap */
this->heap_size <<= 1;
this->heap = (event_t**)realloc(this->heap,
(this->heap_size + 1) * sizeof(event_t*));
}
/* "put" the event to the bottom */
position = this->event_count;
/* then bubble it up */
while (position > 1 && timeval_cmp(&this->heap[position >> 1]->time,
&event->time) > 0)
{
/* parent has to be fired after the new event, move up */
this->heap[position] = this->heap[position >> 1];
position >>= 1;
}
this->heap[position] = event;
this->condvar->signal(this->condvar);
this->mutex->unlock(this->mutex);
}
/**
* Implements scheduler_t.schedule_job.
*/
static void schedule_job(private_scheduler_t *this, job_t *job, u_int32_t s)
{
timeval_t tv;
gettimeofday(&tv, NULL);
tv.tv_sec += s;
schedule_job_tv(this, job, tv);
}
/**
* Implements scheduler_t.schedule_job_ms.
*/
static void schedule_job_ms(private_scheduler_t *this, job_t *job, u_int32_t ms)
{
timeval_t tv, add;
gettimeofday(&tv, NULL);
add.tv_sec = ms / 1000;
add.tv_usec = (ms % 1000) * 1000;
timeradd(&tv, &add, &tv);
schedule_job_tv(this, job, tv);
}
/**
* Implementation of scheduler_t.destroy.
*/
static void destroy(private_scheduler_t *this)
{
event_t *event;
this->job->cancel(this->job);
this->condvar->destroy(this->condvar);
this->mutex->destroy(this->mutex);
while ((event = remove_event(this)) != NULL)
{
event_destroy(event);
}
free(this->heap);
free(this);
}
/*
* Described in header.
*/
scheduler_t * scheduler_create()
{
private_scheduler_t *this = malloc_thing(private_scheduler_t);
this->public.get_job_load = (u_int (*) (scheduler_t *this)) get_job_load;
this->public.schedule_job = (void (*) (scheduler_t *this, job_t *job, u_int32_t s)) schedule_job;
this->public.schedule_job_ms = (void (*) (scheduler_t *this, job_t *job, u_int32_t ms)) schedule_job_ms;
this->public.schedule_job_tv = (void (*) (scheduler_t *this, job_t *job, timeval_t tv)) schedule_job_tv;
this->public.destroy = (void(*)(scheduler_t*)) destroy;
/* Note: the root of the heap is at index 1 */
this->event_count = 0;
this->heap_size = HEAP_SIZE_DEFAULT;
this->heap = (event_t**)calloc(this->heap_size + 1, sizeof(event_t*));
this->mutex = mutex_create(MUTEX_TYPE_DEFAULT);
this->condvar = condvar_create(CONDVAR_TYPE_DEFAULT);
this->job = callback_job_create((callback_job_cb_t)schedule, this, NULL, NULL);
charon->processor->queue_job(charon->processor, (job_t*)this->job);
return &this->public;
}
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