/* The common simulator framework for GDB, the GNU Debugger.
Copyright 2002-2024 Free Software Foundation, Inc.
Contributed by Andrew Cagney and Red Hat.
This file is part of GDB.
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 3 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, see . */
#ifndef _SIM_EVENTS_C_
#define _SIM_EVENTS_C_
/* This must come before any other includes. */
#include "defs.h"
#include /* For SIGPROCMASK et al. */
#include
#include
#include
#include "libiberty.h"
#include "sim-main.h"
#include "sim-assert.h"
#include "sim-cpu.h"
typedef enum {
watch_invalid,
/* core - target byte order */
watch_core_targ_1,
watch_core_targ_2,
watch_core_targ_4,
watch_core_targ_8,
/* core - big-endian */
watch_core_be_1,
watch_core_be_2,
watch_core_be_4,
watch_core_be_8,
/* core - little-endian */
watch_core_le_1,
watch_core_le_2,
watch_core_le_4,
watch_core_le_8,
/* sim - host byte order */
watch_sim_host_1,
watch_sim_host_2,
watch_sim_host_4,
watch_sim_host_8,
/* sim - big-endian */
watch_sim_be_1,
watch_sim_be_2,
watch_sim_be_4,
watch_sim_be_8,
/* sim - little-endian */
watch_sim_le_1,
watch_sim_le_2,
watch_sim_le_4,
watch_sim_le_8,
/* pc */
watch_pc,
/* wallclock */
watch_clock,
/* timer */
watch_timer,
} sim_event_watchpoints;
struct _sim_event {
sim_event_watchpoints watching;
void *data;
sim_event_handler *handler;
/* timer event */
int64_t time_of_event;
/* watch wallclock event */
unsigned wallclock;
/* watch core address */
address_word core_addr;
unsigned core_map;
/* watch sim addr */
void *host_addr;
/* watch core/sim range */
int is_within; /* 0/1 */
unsigned ub;
unsigned lb;
uint64_t ub64;
uint64_t lb64;
/* trace info (if any) */
char *trace;
/* list */
sim_event *next;
};
/* 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 occur. If no next event it will hold the time of the last
event.
TIME_FROM_EVENT: The current distance from TIME_OF_EVENT. A value
<= 0 (except when poll-event is being processed) indicates that
event processing is due. This variable is decremented once for
each iteration of a clock cycle.
Initially, the clock is started at time one (0) with TIME_OF_EVENT
== 0 and TIME_FROM_EVENT == 0 and with NR_TICKS_TO_PROCESS == 1.
Clearly there is a bug in that this code assumes that the absolute
time counter will never become greater than 2^62.
To avoid the need to use 64bit arithmetic, the event queue always
contains at least one event scheduled every 16 000 ticks. This
limits the time from event counter to values less than
16 000. */
#if !defined (SIM_EVENTS_POLL_RATE)
#define SIM_EVENTS_POLL_RATE 0x1000
#endif
#define _ETRACE sd, NULL
#undef ETRACE
#define ETRACE(ARGS) \
do \
{ \
if (STRACE_EVENTS_P (sd)) \
{ \
if (STRACE_DEBUG_P (sd)) \
trace_printf (sd, NULL, "%s:%d: ", lbasename (__FILE__), __LINE__); \
trace_printf ARGS; \
} \
} \
while (0)
/* event queue iterator - don't iterate over the held queue. */
#if EXTERN_SIM_EVENTS_P
static sim_event **
next_event_queue (SIM_DESC sd,
sim_event **queue)
{
if (queue == NULL)
return &STATE_EVENTS (sd)->queue;
else if (queue == &STATE_EVENTS (sd)->queue)
return &STATE_EVENTS (sd)->watchpoints;
else if (queue == &STATE_EVENTS (sd)->watchpoints)
return &STATE_EVENTS (sd)->watchedpoints;
else if (queue == &STATE_EVENTS (sd)->watchedpoints)
return NULL;
else
sim_io_error (sd, "next_event_queue - bad queue");
return NULL;
}
#endif
STATIC_INLINE_SIM_EVENTS\
(void)
sim_events_poll (SIM_DESC sd,
void *data)
{
/* just re-schedule in 1000 million ticks time */
sim_events_schedule (sd, SIM_EVENTS_POLL_RATE, sim_events_poll, sd);
sim_io_poll_quit (sd);
}
/* "events" module install handler.
This is called via sim_module_install to install the "events" subsystem
into the simulator. */
#if EXTERN_SIM_EVENTS_P
STATIC_SIM_EVENTS (MODULE_UNINSTALL_FN) sim_events_uninstall;
STATIC_SIM_EVENTS (MODULE_INIT_FN) sim_events_init;
STATIC_SIM_EVENTS (MODULE_RESUME_FN) sim_events_resume;
STATIC_SIM_EVENTS (MODULE_SUSPEND_FN) sim_events_suspend;
#endif
#if EXTERN_SIM_EVENTS_P
SIM_RC
sim_events_install (SIM_DESC sd)
{
SIM_ASSERT (STATE_MAGIC (sd) == SIM_MAGIC_NUMBER);
sim_module_add_uninstall_fn (sd, sim_events_uninstall);
sim_module_add_init_fn (sd, sim_events_init);
sim_module_add_resume_fn (sd, sim_events_resume);
sim_module_add_suspend_fn (sd, sim_events_suspend);
return SIM_RC_OK;
}
#endif
/* Suspend/resume the event queue manager when the simulator is not
running */
#if EXTERN_SIM_EVENTS_P
static SIM_RC
sim_events_resume (SIM_DESC sd)
{
sim_events *events = STATE_EVENTS (sd);
SIM_ASSERT (STATE_MAGIC (sd) == SIM_MAGIC_NUMBER);
SIM_ASSERT (events->resume_wallclock == 0);
events->resume_wallclock = sim_elapsed_time_get ();
return SIM_RC_OK;
}
#endif
#if EXTERN_SIM_EVENTS_P
static SIM_RC
sim_events_suspend (SIM_DESC sd)
{
sim_events *events = STATE_EVENTS (sd);
SIM_ASSERT (STATE_MAGIC (sd) == SIM_MAGIC_NUMBER);
SIM_ASSERT (events->resume_wallclock != 0);
events->elapsed_wallclock += sim_elapsed_time_since (events->resume_wallclock);
events->resume_wallclock = 0;
return SIM_RC_OK;
}
#endif
/* Uninstall the "events" subsystem from the simulator. */
#if EXTERN_SIM_EVENTS_P
static void
sim_events_uninstall (SIM_DESC sd)
{
SIM_ASSERT (STATE_MAGIC (sd) == SIM_MAGIC_NUMBER);
/* FIXME: free buffers, etc. */
}
#endif
/* malloc/free */
#if EXTERN_SIM_EVENTS_P
static sim_event *
sim_events_zalloc (SIM_DESC sd)
{
sim_events *events = STATE_EVENTS (sd);
sim_event *new = events->free_list;
if (new != NULL)
{
events->free_list = new->next;
memset (new, 0, sizeof (*new));
}
else
{
#if defined (HAVE_SIGPROCMASK) && defined (SIG_SETMASK)
/*-LOCK-*/
sigset_t old_mask;
sigset_t new_mask;
sigfillset (&new_mask);
sigprocmask (SIG_SETMASK, &new_mask, &old_mask);
#endif
new = ZALLOC (sim_event);
#if defined (HAVE_SIGPROCMASK) && defined (SIG_SETMASK)
/*-UNLOCK-*/
sigprocmask (SIG_SETMASK, &old_mask, NULL);
#endif
}
return new;
}
#endif
STATIC_INLINE_SIM_EVENTS\
(void)
sim_events_free (SIM_DESC sd,
sim_event *dead)
{
sim_events *events = STATE_EVENTS (sd);
dead->next = events->free_list;
events->free_list = dead;
if (dead->trace != NULL)
{
free (dead->trace); /* NB: asprintf returns a `free' buf */
dead->trace = NULL;
}
}
/* Initialize the simulator event manager */
#if EXTERN_SIM_EVENTS_P
SIM_RC
sim_events_init (SIM_DESC sd)
{
sim_events *events = STATE_EVENTS (sd);
/* drain the interrupt queue */
events->nr_held = 0;
if (events->held == NULL)
events->held = NZALLOC (sim_event, MAX_NR_SIGNAL_SIM_EVENTS);
/* drain the normal queues */
{
sim_event **queue = NULL;
while ((queue = next_event_queue (sd, queue)) != NULL)
{
if (queue == NULL) break;
while (*queue != NULL)
{
sim_event *dead = *queue;
*queue = dead->next;
sim_events_free (sd, dead);
}
*queue = NULL;
}
}
/* wind time back to zero */
events->nr_ticks_to_process = 1; /* start by doing queue */
events->time_of_event = 0;
events->time_from_event = 0;
events->elapsed_wallclock = 0;
events->resume_wallclock = 0;
/* schedule our initial counter event */
sim_events_schedule (sd, 0, sim_events_poll, sd);
/* from now on, except when the large-int event is being processed
the event queue is non empty */
SIM_ASSERT (events->queue != NULL);
return SIM_RC_OK;
}
#endif
INLINE_SIM_EVENTS\
(int64_t)
sim_events_time (SIM_DESC sd)
{
sim_events *events = STATE_EVENTS (sd);
return (events->time_of_event - events->time_from_event);
}
INLINE_SIM_EVENTS\
(unsigned long)
sim_events_elapsed_time (SIM_DESC sd)
{
unsigned long elapsed = STATE_EVENTS (sd)->elapsed_wallclock;
/* Are we being called inside sim_resume?
(Is there a simulation in progress?) */
if (STATE_EVENTS (sd)->resume_wallclock != 0)
elapsed += sim_elapsed_time_since (STATE_EVENTS (sd)->resume_wallclock);
return elapsed;
}
/* Returns the time that remains before the event is raised. */
INLINE_SIM_EVENTS\
(int64_t)
sim_events_remain_time (SIM_DESC sd, sim_event *event)
{
if (event == 0)
return 0;
return (event->time_of_event - sim_events_time (sd));
}
STATIC_INLINE_SIM_EVENTS\
(void)
update_time_from_event (SIM_DESC sd)
{
sim_events *events = STATE_EVENTS (sd);
int64_t current_time = sim_events_time (sd);
if (events->queue != NULL)
{
events->time_of_event = events->queue->time_of_event;
events->time_from_event = (events->queue->time_of_event - current_time);
}
else
{
events->time_of_event = current_time - 1;
events->time_from_event = -1;
}
if (STRACE_EVENTS_P (sd))
{
sim_event *event;
int i;
for (event = events->queue, i = 0;
event != NULL;
event = event->next, i++)
{
ETRACE ((_ETRACE,
"event time-from-event - "
"time %" PRIi64 ", delta %" PRIi64 " - "
"event %i, tag %p, time %" PRIi64 ", handler %p, data "
"%p%s%s\n",
current_time,
events->time_from_event,
i,
event,
event->time_of_event,
event->handler,
event->data,
(event->trace != NULL) ? ", " : "",
(event->trace != NULL) ? event->trace : ""));
}
}
SIM_ASSERT (current_time == sim_events_time (sd));
}
#if EXTERN_SIM_EVENTS_P
static void
insert_sim_event (SIM_DESC sd,
sim_event *new_event,
int64_t delta)
{
sim_events *events = STATE_EVENTS (sd);
sim_event *curr;
sim_event **prev;
int64_t time_of_event;
if (delta < 0)
sim_io_error (sd, "what is past is past!\n");
/* compute when the event should occur */
time_of_event = sim_events_time (sd) + delta;
/* find the queue insertion point - things are time ordered */
prev = &events->queue;
curr = events->queue;
while (curr != NULL && time_of_event >= curr->time_of_event)
{
SIM_ASSERT (curr->next == NULL
|| curr->time_of_event <= curr->next->time_of_event);
prev = &curr->next;
curr = curr->next;
}
SIM_ASSERT (curr == NULL || time_of_event < curr->time_of_event);
/* insert it */
new_event->next = curr;
*prev = new_event;
new_event->time_of_event = time_of_event;
/* adjust the time until the first event */
update_time_from_event (sd);
}
#endif
#if EXTERN_SIM_EVENTS_P
sim_event *
sim_events_schedule (SIM_DESC sd,
int64_t delta_time,
sim_event_handler *handler,
void *data)
{
return sim_events_schedule_tracef (sd, delta_time, handler, data, NULL);
}
#endif
#if EXTERN_SIM_EVENTS_P
sim_event *
sim_events_schedule_tracef (SIM_DESC sd,
int64_t delta_time,
sim_event_handler *handler,
void *data,
const char *fmt,
...)
{
sim_event *new_event;
va_list ap;
va_start (ap, fmt);
new_event = sim_events_schedule_vtracef (sd, delta_time, handler, data, fmt, ap);
va_end (ap);
return new_event;
}
#endif
#if EXTERN_SIM_EVENTS_P
sim_event *
sim_events_schedule_vtracef (SIM_DESC sd,
int64_t delta_time,
sim_event_handler *handler,
void *data,
const char *fmt,
va_list ap)
{
sim_event *new_event = sim_events_zalloc (sd);
new_event->data = data;
new_event->handler = handler;
new_event->watching = watch_timer;
if (fmt == NULL || !STRACE_EVENTS_P (sd) || vasprintf (&new_event->trace, fmt, ap) < 0)
new_event->trace = NULL;
insert_sim_event (sd, new_event, delta_time);
ETRACE ((_ETRACE,
"event scheduled at %" PRIi64 " - "
"tag %p - time %" PRIi64 ", handler %p, data %p%s%s\n",
sim_events_time (sd),
new_event,
new_event->time_of_event,
new_event->handler,
new_event->data,
(new_event->trace != NULL) ? ", " : "",
(new_event->trace != NULL) ? new_event->trace : ""));
return new_event;
}
#endif
#if EXTERN_SIM_EVENTS_P
void
sim_events_schedule_after_signal (SIM_DESC sd,
int64_t delta_time,
sim_event_handler *handler,
void *data)
{
sim_events *events = STATE_EVENTS (sd);
sim_event *new_event;
#if defined (HAVE_SIGPROCMASK) && defined (SIG_SETMASK)
/*-LOCK-*/
sigset_t old_mask;
sigset_t new_mask;
sigfillset (&new_mask);
sigprocmask (SIG_SETMASK, &new_mask, &old_mask);
#endif
/* allocate an event entry from the signal buffer */
new_event = &events->held [events->nr_held];
events->nr_held ++;
if (events->nr_held > MAX_NR_SIGNAL_SIM_EVENTS)
{
sim_engine_abort (NULL, NULL, NULL_CIA,
"sim_events_schedule_after_signal - buffer overflow");
}
new_event->data = data;
new_event->handler = handler;
new_event->time_of_event = delta_time; /* work it out later */
new_event->next = NULL;
events->work_pending = 1; /* notify main process */
#if defined (HAVE_SIGPROCMASK) && defined (SIG_SETMASK)
/*-UNLOCK-*/
sigprocmask (SIG_SETMASK, &old_mask, NULL);
#endif
ETRACE ((_ETRACE,
"signal scheduled at %" PRIi64 " - "
"tag %p - time %" PRIi64 ", handler %p, data %p\n",
sim_events_time (sd),
new_event,
new_event->time_of_event,
new_event->handler,
new_event->data));
}
#endif
#if EXTERN_SIM_EVENTS_P
sim_event *
sim_events_watch_clock (SIM_DESC sd,
unsigned delta_ms_time,
sim_event_handler *handler,
void *data)
{
sim_events *events = STATE_EVENTS (sd);
sim_event *new_event = sim_events_zalloc (sd);
/* type */
new_event->watching = watch_clock;
/* handler */
new_event->data = data;
new_event->handler = handler;
/* data */
if (events->resume_wallclock == 0)
new_event->wallclock = (events->elapsed_wallclock + delta_ms_time);
else
new_event->wallclock = (events->elapsed_wallclock
+ sim_elapsed_time_since (events->resume_wallclock)
+ delta_ms_time);
/* insert */
new_event->next = events->watchpoints;
events->watchpoints = new_event;
events->work_pending = 1;
ETRACE ((_ETRACE,
"event watching clock at %" PRIi64 " - "
"tag %p - wallclock %u, handler %p, data %p\n",
sim_events_time (sd),
new_event,
new_event->wallclock,
new_event->handler,
new_event->data));
return new_event;
}
#endif
#if EXTERN_SIM_EVENTS_P
sim_event *
sim_events_watch_pc (SIM_DESC sd,
int is_within,
uint64_t lb,
uint64_t ub,
sim_event_handler *handler,
void *data)
{
sim_events *events = STATE_EVENTS (sd);
sim_event *new_event = sim_events_zalloc (sd);
/* type */
new_event->watching = watch_pc;
/* handler */
new_event->data = data;
new_event->handler = handler;
/* data */
new_event->lb = lb;
new_event->lb64 = lb;
new_event->ub = ub;
new_event->ub64 = ub;
new_event->is_within = (is_within != 0);
/* insert */
new_event->next = events->watchpoints;
events->watchpoints = new_event;
events->work_pending = 1;
ETRACE ((_ETRACE,
"event watching pc at %" PRIi64 " - "
"tag %p - pc 0x%x..0x%x, handler %p, data %p\n",
sim_events_time (sd),
new_event,
new_event->lb,
new_event->ub,
new_event->handler,
new_event->data));
return new_event;
}
#endif
#if EXTERN_SIM_EVENTS_P
sim_event *
sim_events_watch_sim (SIM_DESC sd,
void *host_addr,
int nr_bytes,
enum bfd_endian byte_order,
int is_within,
uint64_t lb,
uint64_t ub,
sim_event_handler *handler,
void *data)
{
sim_events *events = STATE_EVENTS (sd);
sim_event *new_event = sim_events_zalloc (sd);
/* type */
switch (byte_order)
{
case BFD_ENDIAN_UNKNOWN:
switch (nr_bytes)
{
case 1: new_event->watching = watch_sim_host_1; break;
case 2: new_event->watching = watch_sim_host_2; break;
case 4: new_event->watching = watch_sim_host_4; break;
case 8: new_event->watching = watch_sim_host_8; break;
default: sim_io_error (sd, "sim_events_watch_sim - invalid nr bytes");
}
break;
case BFD_ENDIAN_BIG:
switch (nr_bytes)
{
case 1: new_event->watching = watch_sim_be_1; break;
case 2: new_event->watching = watch_sim_be_2; break;
case 4: new_event->watching = watch_sim_be_4; break;
case 8: new_event->watching = watch_sim_be_8; break;
default: sim_io_error (sd, "sim_events_watch_sim - invalid nr bytes");
}
break;
case BFD_ENDIAN_LITTLE:
switch (nr_bytes)
{
case 1: new_event->watching = watch_sim_le_1; break;
case 2: new_event->watching = watch_sim_le_2; break;
case 4: new_event->watching = watch_sim_le_4; break;
case 8: new_event->watching = watch_sim_le_8; break;
default: sim_io_error (sd, "sim_events_watch_sim - invalid nr bytes");
}
break;
default:
sim_io_error (sd, "sim_events_watch_sim - invalid byte order");
}
/* handler */
new_event->data = data;
new_event->handler = handler;
/* data */
new_event->host_addr = host_addr;
new_event->lb = lb;
new_event->lb64 = lb;
new_event->ub = ub;
new_event->ub64 = ub;
new_event->is_within = (is_within != 0);
/* insert */
new_event->next = events->watchpoints;
events->watchpoints = new_event;
events->work_pending = 1;
ETRACE ((_ETRACE,
"event watching host at %" PRIi64 " - "
"tag %p - host-addr %p, 0x%x..0x%x, handler %p, data %p\n",
sim_events_time (sd),
new_event,
new_event->host_addr,
new_event->lb,
new_event->ub,
new_event->handler,
new_event->data));
return new_event;
}
#endif
#if EXTERN_SIM_EVENTS_P
sim_event *
sim_events_watch_core (SIM_DESC sd,
address_word core_addr,
unsigned core_map,
int nr_bytes,
enum bfd_endian byte_order,
int is_within,
uint64_t lb,
uint64_t ub,
sim_event_handler *handler,
void *data)
{
sim_events *events = STATE_EVENTS (sd);
sim_event *new_event = sim_events_zalloc (sd);
/* type */
switch (byte_order)
{
case BFD_ENDIAN_UNKNOWN:
switch (nr_bytes)
{
case 1: new_event->watching = watch_core_targ_1; break;
case 2: new_event->watching = watch_core_targ_2; break;
case 4: new_event->watching = watch_core_targ_4; break;
case 8: new_event->watching = watch_core_targ_8; break;
default: sim_io_error (sd, "sim_events_watch_core - invalid nr bytes");
}
break;
case BFD_ENDIAN_BIG:
switch (nr_bytes)
{
case 1: new_event->watching = watch_core_be_1; break;
case 2: new_event->watching = watch_core_be_2; break;
case 4: new_event->watching = watch_core_be_4; break;
case 8: new_event->watching = watch_core_be_8; break;
default: sim_io_error (sd, "sim_events_watch_core - invalid nr bytes");
}
break;
case BFD_ENDIAN_LITTLE:
switch (nr_bytes)
{
case 1: new_event->watching = watch_core_le_1; break;
case 2: new_event->watching = watch_core_le_2; break;
case 4: new_event->watching = watch_core_le_4; break;
case 8: new_event->watching = watch_core_le_8; break;
default: sim_io_error (sd, "sim_events_watch_core - invalid nr bytes");
}
break;
default:
sim_io_error (sd, "sim_events_watch_core - invalid byte order");
}
/* handler */
new_event->data = data;
new_event->handler = handler;
/* data */
new_event->core_addr = core_addr;
new_event->core_map = core_map;
new_event->lb = lb;
new_event->lb64 = lb;
new_event->ub = ub;
new_event->ub64 = ub;
new_event->is_within = (is_within != 0);
/* insert */
new_event->next = events->watchpoints;
events->watchpoints = new_event;
events->work_pending = 1;
ETRACE ((_ETRACE,
"event watching host at %" PRIi64 " - "
"tag %p - host-addr %p, 0x%x..0x%x, handler %p, data %p\n",
sim_events_time (sd),
new_event,
new_event->host_addr,
new_event->lb,
new_event->ub,
new_event->handler,
new_event->data));
return new_event;
}
#endif
#if EXTERN_SIM_EVENTS_P
void
sim_events_deschedule (SIM_DESC sd,
sim_event *event_to_remove)
{
sim_events *events = STATE_EVENTS (sd);
sim_event *to_remove = (sim_event*)event_to_remove;
if (event_to_remove != NULL)
{
sim_event **queue = NULL;
while ((queue = next_event_queue (sd, queue)) != NULL)
{
sim_event **ptr_to_current;
for (ptr_to_current = queue;
*ptr_to_current != NULL && *ptr_to_current != to_remove;
ptr_to_current = &(*ptr_to_current)->next);
if (*ptr_to_current == to_remove)
{
sim_event *dead = *ptr_to_current;
*ptr_to_current = dead->next;
ETRACE ((_ETRACE,
"event/watch descheduled at %" PRIi64 " - "
"tag %p - time %" PRIi64 ", handler %p, data %p%s%s\n",
sim_events_time (sd),
event_to_remove,
dead->time_of_event,
dead->handler,
dead->data,
(dead->trace != NULL) ? ", " : "",
(dead->trace != NULL) ? dead->trace : ""));
sim_events_free (sd, dead);
update_time_from_event (sd);
SIM_ASSERT ((events->time_from_event >= 0) == (events->queue != NULL));
return;
}
}
}
ETRACE ((_ETRACE,
"event/watch descheduled at %" PRIi64 " - tag %p - not found\n",
sim_events_time (sd),
event_to_remove));
}
#endif
STATIC_INLINE_SIM_EVENTS\
(int)
sim_watch_valid (SIM_DESC sd,
sim_event *to_do)
{
switch (to_do->watching)
{
#define WATCH_CORE(N,OP,EXT) \
int ok; \
unsigned_##N word = 0; \
int nr_read = sim_core_read_buffer (sd, NULL, to_do->core_map, &word, \
to_do->core_addr, sizeof (word)); \
OP (word); \
ok = (nr_read == sizeof (unsigned_##N) \
&& (to_do->is_within \
== (word >= to_do->lb##EXT \
&& word <= to_do->ub##EXT)));
case watch_core_targ_1:
{
WATCH_CORE (1, T2H,);
return ok;
}
case watch_core_targ_2:
{
WATCH_CORE (2, T2H,);
return ok;
}
case watch_core_targ_4:
{
WATCH_CORE (4, T2H,);
return ok;
}
case watch_core_targ_8:
{
WATCH_CORE (8, T2H,64);
return ok;
}
case watch_core_be_1:
{
WATCH_CORE (1, BE2H,);
return ok;
}
case watch_core_be_2:
{
WATCH_CORE (2, BE2H,);
return ok;
}
case watch_core_be_4:
{
WATCH_CORE (4, BE2H,);
return ok;
}
case watch_core_be_8:
{
WATCH_CORE (8, BE2H,64);
return ok;
}
case watch_core_le_1:
{
WATCH_CORE (1, LE2H,);
return ok;
}
case watch_core_le_2:
{
WATCH_CORE (2, LE2H,);
return ok;
}
case watch_core_le_4:
{
WATCH_CORE (4, LE2H,);
return ok;
}
case watch_core_le_8:
{
WATCH_CORE (8, LE2H,64);
return ok;
}
#undef WATCH_CORE
#define WATCH_SIM(N,OP,EXT) \
int ok; \
unsigned_##N word = *(unsigned_##N*)to_do->host_addr; \
OP (word); \
ok = (to_do->is_within \
== (word >= to_do->lb##EXT \
&& word <= to_do->ub##EXT));
case watch_sim_host_1:
{
WATCH_SIM (1, word = ,);
return ok;
}
case watch_sim_host_2:
{
WATCH_SIM (2, word = ,);
return ok;
}
case watch_sim_host_4:
{
WATCH_SIM (4, word = ,);
return ok;
}
case watch_sim_host_8:
{
WATCH_SIM (8, word = ,64);
return ok;
}
case watch_sim_be_1:
{
WATCH_SIM (1, BE2H,);
return ok;
}
case watch_sim_be_2:
{
WATCH_SIM (2, BE2H,);
return ok;
}
case watch_sim_be_4:
{
WATCH_SIM (4, BE2H,);
return ok;
}
case watch_sim_be_8:
{
WATCH_SIM (8, BE2H,64);
return ok;
}
case watch_sim_le_1:
{
WATCH_SIM (1, LE2H,);
return ok;
}
case watch_sim_le_2:
{
WATCH_SIM (1, LE2H,);
return ok;
}
case watch_sim_le_4:
{
WATCH_SIM (1, LE2H,);
return ok;
}
case watch_sim_le_8:
{
WATCH_SIM (1, LE2H,64);
return ok;
}
#undef WATCH_SIM
case watch_pc:
{
int c;
for (c = 0; c < MAX_NR_PROCESSORS; ++c)
{
sim_cpu *cpu = STATE_CPU (sd, c);
sim_cia cia = sim_pc_get (cpu);
if (to_do->is_within == (cia >= to_do->lb64 && cia <= to_do->ub64))
return 1;
}
return 0;
}
case watch_clock: /* wallclock */
{
unsigned long elapsed_time = sim_events_elapsed_time (sd);
return (elapsed_time >= to_do->wallclock);
}
default:
sim_io_error (sd, "sim_watch_valid - bad switch");
break;
}
return 1;
}
INLINE_SIM_EVENTS\
(int)
sim_events_tick (SIM_DESC sd)
{
sim_events *events = STATE_EVENTS (sd);
/* this should only be called after the previous ticks have been
fully processed */
/* Advance the time but *only* if there is nothing to process */
if (events->work_pending
|| events->time_from_event == 0)
{
events->nr_ticks_to_process += 1;
return 1;
}
else
{
events->time_from_event -= 1;
return 0;
}
}
INLINE_SIM_EVENTS\
(int)
sim_events_tickn (SIM_DESC sd,
int n)
{
sim_events *events = STATE_EVENTS (sd);
SIM_ASSERT (n > 0);
/* this should only be called after the previous ticks have been
fully processed */
/* Advance the time but *only* if there is nothing to process */
if (events->work_pending || events->time_from_event < n)
{
events->nr_ticks_to_process += n;
return 1;
}
else
{
events->time_from_event -= n;
return 0;
}
}
INLINE_SIM_EVENTS\
(void)
sim_events_slip (SIM_DESC sd,
int slip)
{
sim_events *events = STATE_EVENTS (sd);
SIM_ASSERT (slip > 0);
/* Flag a ready event with work_pending instead of number of ticks
to process so that the time continues to be correct */
if (events->time_from_event < slip)
{
events->work_pending = 1;
}
events->time_from_event -= slip;
}
INLINE_SIM_EVENTS\
(void)
sim_events_preprocess (SIM_DESC sd,
int events_were_last,
int events_were_next)
{
sim_events *events = STATE_EVENTS (sd);
if (events_were_last)
{
/* Halted part way through event processing */
ASSERT (events->nr_ticks_to_process != 0);
/* The external world can't tell if the event that stopped the
simulator was the last event to process. */
ASSERT (events_were_next);
sim_events_process (sd);
}
else if (events_were_next)
{
/* Halted by the last processor */
if (sim_events_tick (sd))
sim_events_process (sd);
}
}
INLINE_SIM_EVENTS\
(void)
sim_events_process (SIM_DESC sd)
{
sim_events *events = STATE_EVENTS (sd);
int64_t event_time = sim_events_time (sd);
/* Clear work_pending before checking nr_held. Clearing
work_pending after nr_held (with out a lock could loose an
event). */
events->work_pending = 0;
/* move any events that were asynchronously queued by any signal
handlers onto the real event queue. */
if (events->nr_held > 0)
{
int i;
#if defined(HAVE_SIGPROCMASK) && defined(SIG_SETMASK)
/*-LOCK-*/
sigset_t old_mask;
sigset_t new_mask;
sigfillset (&new_mask);
sigprocmask (SIG_SETMASK, &new_mask, &old_mask);
#endif
for (i = 0; i < events->nr_held; i++)
{
sim_event *entry = &events->held [i];
sim_events_schedule (sd,
entry->time_of_event,
entry->handler,
entry->data);
}
events->nr_held = 0;
#if defined(HAVE_SIGPROCMASK) && defined(SIG_SETMASK)
/*-UNLOCK-*/
sigprocmask (SIG_SETMASK, &old_mask, NULL);
#endif
}
/* Process any watchpoints. Be careful to allow a watchpoint to
appear/disappear under our feet.
To ensure that watchpoints are processed only once per cycle,
they are moved onto a watched queue, this returned to the
watchpoint queue when all queue processing has been
completed. */
while (events->watchpoints != NULL)
{
sim_event *to_do = events->watchpoints;
events->watchpoints = to_do->next;
if (sim_watch_valid (sd, to_do))
{
sim_event_handler *handler = to_do->handler;
void *data = to_do->data;
ETRACE ((_ETRACE,
"event issued at %" PRIi64 " - "
"tag %p - handler %p, data %p%s%s\n",
event_time,
to_do,
handler,
data,
(to_do->trace != NULL) ? ", " : "",
(to_do->trace != NULL) ? to_do->trace : ""));
sim_events_free (sd, to_do);
handler (sd, data);
}
else
{
to_do->next = events->watchedpoints;
events->watchedpoints = to_do;
}
}
/* consume all events for this or earlier times. Be careful to
allow an event to appear/disappear under our feet */
while (events->queue->time_of_event <
(event_time + events->nr_ticks_to_process))
{
sim_event *to_do = events->queue;
sim_event_handler *handler = to_do->handler;
void *data = to_do->data;
events->queue = to_do->next;
update_time_from_event (sd);
ETRACE ((_ETRACE,
"event issued at %" PRIi64 " - tag %p - handler %p, data %p%s%s\n",
event_time,
to_do,
handler,
data,
(to_do->trace != NULL) ? ", " : "",
(to_do->trace != NULL) ? to_do->trace : ""));
sim_events_free (sd, to_do);
handler (sd, data);
}
/* put things back where they belong ready for the next iteration */
events->watchpoints = events->watchedpoints;
events->watchedpoints = NULL;
if (events->watchpoints != NULL)
events->work_pending = 1;
/* advance the time */
SIM_ASSERT (events->time_from_event >= events->nr_ticks_to_process);
SIM_ASSERT (events->queue != NULL); /* always poll event */
events->time_from_event -= events->nr_ticks_to_process;
/* this round of processing complete */
events->nr_ticks_to_process = 0;
}
#endif