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binutils-gdb/sim/ppc/events.c

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/* This file is part of the program psim.
Copyright (C) 1994-1995, Andrew Cagney <cagney@highland.com.au>
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.
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.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
#ifndef _EVENTS_C_
#define _EVENTS_C_
#ifndef STATIC_INLINE_EVENTS
#define STATIC_INLINE_EVENTS STATIC_INLINE
#endif
#include "basics.h"
#include "events.h"
/* The event queue maintains a single absolute time using two
variables.
TIME_OF_EVENT: this holds the time at which the next event is ment
to occure. If no next event it will hold the time of the last
event. The first event occures at time 0 - system start.
TIME_FROM_EVENT: The current distance from TIME_OF_EVENT. If an
event is pending, this will be positive. If no future event is
pending this will be negative. This variable is decremented once
for each iteration of a clock cycle.
Clearly there is a bug in that this code assumes that the absolute
time counter will never become greater than 2^62. */
typedef struct _event_entry event_entry;
struct _event_entry {
void *data;
event_handler *handler;
signed64 time_of_event;
event_entry *next;
};
struct _event_queue {
event_entry *queue;
event_entry *volatile held;
event_entry *volatile *volatile held_end;
signed64 time_of_event;
signed64 time_from_event;
};
INLINE_EVENTS event_queue *
event_queue_create(void)
{
event_queue *new_event_queue = ZALLOC(event_queue);
new_event_queue->queue = NULL;
new_event_queue->held = NULL;
new_event_queue->held_end = &new_event_queue->held;
/* both times are already zero */
return new_event_queue;
}
STATIC_INLINE_EVENTS void
insert_event_entry(event_queue *events,
event_entry *new_event,
signed64 delta)
{
event_entry *curr;
event_entry **last;
signed64 time_of_event;
if (delta <= 0)
error("can not schedule event for current time\n");
/* compute when the event should occure */
time_of_event = (events->time_of_event
- events->time_from_event
+ delta);
/* find the queue insertion point - things are time ordered */
last = &events->queue;
curr = events->queue;
while (curr != NULL && time_of_event >= curr->time_of_event) {
last = &curr->next;
curr = curr->next;
}
/* insert it */
new_event->next = curr;
*last = new_event;
new_event->time_of_event = time_of_event;
/* adjust the time until the first event */
events->time_from_event = (events->queue->time_of_event
- (events->time_of_event
- events->time_from_event));
events->time_of_event = events->queue->time_of_event;
}
INLINE_EVENTS event_entry_tag
event_queue_schedule(event_queue *events,
signed64 delta_time,
event_handler *handler,
void *data)
{
event_entry *new_event = ZALLOC(event_entry);
new_event->data = data;
new_event->handler = handler;
insert_event_entry(events, new_event, delta_time);
return new_event;
}
INLINE_EVENTS event_entry_tag
event_queue_schedule_after_signal(event_queue *events,
signed64 delta_time,
event_handler *handler,
void *data)
{
event_entry *new_event = ZALLOC(event_entry);
new_event->data = data;
new_event->handler = handler;
new_event->time_of_event = delta_time; /* work it out later */
new_event->next = NULL;
/*-LOCK-*/
if (events->held == NULL) {
events->held = new_event;
}
else {
*events->held_end = new_event;
}
events->held_end = &new_event->next;
/*-UNLOCK-*/
return new_event;
}
INLINE_EVENTS void
event_queue_deschedule(event_queue *events,
event_entry_tag event_to_remove)
{
if (event_to_remove != NULL) {
event_entry *current;
event_entry **ptr_to_current;
for (ptr_to_current = &events->queue, current = *ptr_to_current;
current != NULL && current != event_to_remove;
ptr_to_current = &current->next, current = *ptr_to_current);
if (current == event_to_remove) {
*ptr_to_current = current->next;
zfree(current);
/* Just forget to recompute the delay to the next event */
}
}
}
INLINE_EVENTS int
event_queue_tick(event_queue *events)
{
/* remove things from the asynchronous event queue onto the real one */
if (events->held != NULL) {
event_entry *held_events;
event_entry *curr_event;
/*-LOCK-*/
held_events = events->held;
events->held = NULL;
events->held_end = &events->held;
/*-UNLOCK-*/
do {
curr_event = held_events;
held_events = curr_event->next;
insert_event_entry(events, curr_event, curr_event->time_of_event);
} while (held_events != NULL);
}
/* advance time, checking to see if we've reached time zero which
would indicate the time for the next event has arrived */
events->time_from_event -= 1;
return events->time_from_event == 0;
}
INLINE_EVENTS void
event_queue_process(event_queue *events)
{
if (events->time_from_event == 0) {
/* consume all events for this or earlier times */
do {
event_entry *to_do = events->queue;
events->queue = to_do->next;
to_do->handler(events,
to_do->data);
zfree(to_do);
} while (events->queue != NULL
&& events->queue->time_of_event <= events->time_of_event);
/* re-caculate time for new events */
if (events->queue != NULL) {
events->time_from_event = (events->queue->time_of_event
- events->time_of_event);
events->time_of_event = events->queue->time_of_event;
}
else {
/* nothing to do, time_from_event will go negative */
}
}
}
INLINE_EVENTS signed64
event_queue_time(event_queue *queue)
{
return queue->time_of_event - queue->time_from_event;
}
#endif /* _EVENTS_C_ */
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