/* sim_timer.c: simulator timer library | |
Copyright (c) 1993-2010, Robert M Supnik | |
Permission is hereby granted, free of charge, to any person obtaining a | |
copy of this software and associated documentation files (the "Software"), | |
to deal in the Software without restriction, including without limitation | |
the rights to use, copy, modify, merge, publish, distribute, sublicense, | |
and/or sell copies of the Software, and to permit persons to whom the | |
Software is furnished to do so, subject to the following conditions: | |
The above copyright notice and this permission notice shall be included in | |
all copies or substantial portions of the Software. | |
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR | |
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, | |
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL | |
ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER | |
IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN | |
CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. | |
Except as contained in this notice, the name of Robert M Supnik shall not be | |
used in advertising or otherwise to promote the sale, use or other dealings | |
in this Software without prior written authorization from Robert M Supnik. | |
21-Oct-11 MP Fixed throttling in several ways: | |
- Sleep for the observed clock tick size while throttling | |
- Recompute the throttling wait once every 10 seconds | |
to account for varying instruction mixes during | |
different phases of a simulator execution or to | |
accommodate the presence of other load on the host | |
system. | |
- Each of the pre-existing throttling modes (Kcps, | |
Mcps, and %) all compute the appropriate throttling | |
interval dynamically. These dynamic computations | |
assume that 100% of the host CPU is dedicated to | |
the current simulator during this computation. | |
This assumption may not always be true and under | |
certain conditions may never provide a way to | |
correctly determine the appropriate throttling | |
wait. An additional throttling mode has been added | |
which allows the simulator operator to explicitly | |
state the desired throttling wait parameters. | |
These are specified by: | |
SET THROT insts/delay | |
where 'insts' is the number of instructions to | |
execute before sleeping for 'delay' milliseconds. | |
22-Apr-11 MP Fixed Asynch I/O support to reasonably account cycles | |
when an idle wait is terminated by an external event | |
05-Jan-11 MP Added Asynch I/O support | |
29-Dec-10 MP Fixed clock resolution determination for Unix platforms | |
22-Sep-08 RMS Added "stability threshold" for idle routine | |
27-May-08 RMS Fixed bug in Linux idle routines (from Walter Mueller) | |
18-Jun-07 RMS Modified idle to exclude counted delays | |
22-Mar-07 RMS Added sim_rtcn_init_all | |
17-Oct-06 RMS Added idle support (based on work by Mark Pizzolato) | |
Added throttle support | |
16-Aug-05 RMS Fixed C++ declaration and cast problems | |
02-Jan-04 RMS Split out from SCP | |
This library includes the following routines: | |
sim_timer_init - initialize timing system | |
sim_rtc_init - initialize calibration | |
sim_rtc_calb - calibrate clock | |
sim_timer_init - initialize timing system | |
sim_idle - virtual machine idle | |
sim_os_msec - return elapsed time in msec | |
sim_os_sleep - sleep specified number of seconds | |
sim_os_ms_sleep - sleep specified number of milliseconds | |
sim_idle_ms_sleep - sleep specified number of milliseconds | |
or until awakened by an asynchronous | |
event | |
sim_timespec_diff subtract two timespec values | |
sim_timer_activate_after schedule unit for specific time | |
The calibration, idle, and throttle routines are OS-independent; the _os_ | |
routines are not. | |
*/ | |
#define NOT_MUX_USING_CODE /* sim_tmxr library provider or agnostic */ | |
#include "sim_defs.h" | |
#include <ctype.h> | |
#include <math.h> | |
t_bool sim_idle_enab = FALSE; /* global flag */ | |
volatile t_bool sim_idle_wait = FALSE; /* global flag */ | |
static int32 sim_calb_tmr = -1; /* the system calibrated timer */ | |
static uint32 sim_idle_rate_ms = 0; | |
static uint32 sim_os_sleep_min_ms = 0; | |
static uint32 sim_idle_stable = SIM_IDLE_STDFLT; | |
static t_bool sim_idle_idled = FALSE; | |
static uint32 sim_throt_ms_start = 0; | |
static uint32 sim_throt_ms_stop = 0; | |
static uint32 sim_throt_type = 0; | |
static uint32 sim_throt_val = 0; | |
static uint32 sim_throt_state = 0; | |
static uint32 sim_throt_sleep_time = 0; | |
static int32 sim_throt_wait = 0; | |
static UNIT *sim_clock_unit = NULL; | |
t_bool sim_asynch_timer = | |
#if defined (SIM_ASYNCH_CLOCKS) | |
TRUE; | |
#else | |
FALSE; | |
#endif | |
t_stat sim_throt_svc (UNIT *uptr); | |
UNIT sim_throt_unit = { UDATA (&sim_throt_svc, 0, 0) }; | |
#define DBG_IDL TIMER_DBG_IDLE /* idling */ | |
#define DBG_QUE TIMER_DBG_QUEUE /* queue activities */ | |
#define DBG_TRC 0x004 /* tracing */ | |
#define DBG_CAL 0x008 /* calibration activities */ | |
#define DBG_TIM 0x010 /* timer thread activities */ | |
DEBTAB sim_timer_debug[] = { | |
{"TRACE", DBG_TRC}, | |
{"IDLE", DBG_IDL}, | |
{"QUEUE", DBG_QUE}, | |
{"CALIB", DBG_CAL}, | |
{"TIME", DBG_TIM}, | |
{0} | |
}; | |
#if defined(SIM_ASYNCH_IO) | |
uint32 sim_idle_ms_sleep (unsigned int msec) | |
{ | |
uint32 start_time = sim_os_msec(); | |
struct timespec done_time; | |
t_bool timedout = FALSE; | |
clock_gettime(CLOCK_REALTIME, &done_time); | |
done_time.tv_sec += (msec/1000); | |
done_time.tv_nsec += 1000000*(msec%1000); | |
if (done_time.tv_nsec > 1000000000) { | |
done_time.tv_sec += done_time.tv_nsec/1000000000; | |
done_time.tv_nsec = done_time.tv_nsec%1000000000; | |
} | |
pthread_mutex_lock (&sim_asynch_lock); | |
sim_idle_wait = TRUE; | |
if (!pthread_cond_timedwait (&sim_asynch_wake, &sim_asynch_lock, &done_time)) | |
sim_asynch_check = 0; /* force check of asynch queue now */ | |
else | |
timedout = TRUE; | |
sim_idle_wait = FALSE; | |
pthread_mutex_unlock (&sim_asynch_lock); | |
if (!timedout) { | |
AIO_UPDATE_QUEUE; | |
} | |
return sim_os_msec() - start_time; | |
} | |
#define SIM_IDLE_MS_SLEEP sim_idle_ms_sleep | |
#else | |
#define SIM_IDLE_MS_SLEEP sim_os_ms_sleep | |
#endif | |
/* OS-dependent timer and clock routines */ | |
/* VMS */ | |
#if defined (VMS) | |
#if defined (__VAX) | |
#define sys$gettim SYS$GETTIM | |
#define sys$setimr SYS$SETIMR | |
#define lib$emul LIB$EMUL | |
#define sys$waitfr SYS$WAITFR | |
#define lib$subx LIB$SUBX | |
#define lib$ediv LIB$EDIV | |
#endif | |
#include <starlet.h> | |
#include <lib$routines.h> | |
#include <unistd.h> | |
const t_bool rtc_avail = TRUE; | |
uint32 sim_os_msec () | |
{ | |
uint32 quo, htod, tod[2]; | |
int32 i; | |
sys$gettim (tod); /* time 0.1usec */ | |
/* To convert to msec, must divide a 64b quantity by 10000. This is actually done | |
by dividing the 96b quantity 0'time by 10000, producing 64b of quotient, the | |
high 32b of which are discarded. This can probably be done by a clever multiply... | |
*/ | |
quo = htod = 0; | |
for (i = 0; i < 64; i++) { /* 64b quo */ | |
htod = (htod << 1) | ((tod[1] >> 31) & 1); /* shift divd */ | |
tod[1] = (tod[1] << 1) | ((tod[0] >> 31) & 1); | |
tod[0] = tod[0] << 1; | |
quo = quo << 1; /* shift quo */ | |
if (htod >= 10000) { /* divd work? */ | |
htod = htod - 10000; /* subtract */ | |
quo = quo | 1; /* set quo bit */ | |
} | |
} | |
return quo; | |
} | |
void sim_os_sleep (unsigned int sec) | |
{ | |
sleep (sec); | |
return; | |
} | |
uint32 sim_os_ms_sleep_init (void) | |
{ | |
#if defined (__VAX) | |
sim_os_sleep_min_ms = 10; /* VAX/VMS is 10ms */ | |
#else | |
sim_os_sleep_min_ms = 1; /* Alpha/VMS is 1ms */ | |
#endif | |
return sim_os_sleep_min_ms; | |
} | |
uint32 sim_os_ms_sleep (unsigned int msec) | |
{ | |
uint32 stime = sim_os_msec (); | |
uint32 qtime[2]; | |
int32 nsfactor = -10000; | |
static int32 zero = 0; | |
lib$emul (&msec, &nsfactor, &zero, qtime); | |
sys$setimr (2, qtime, 0, 0); | |
sys$waitfr (2); | |
return sim_os_msec () - stime; | |
} | |
#ifdef NEED_CLOCK_GETTIME | |
int clock_gettime(int clk_id, struct timespec *tp) | |
{ | |
uint32 secs, ns, tod[2], unixbase[2] = {0xd53e8000, 0x019db1de}; | |
if (clk_id != CLOCK_REALTIME) | |
return -1; | |
sys$gettim (tod); /* time 0.1usec */ | |
lib$subx(tod, unixbase, tod); /* convert to unix base */ | |
lib$ediv(&10000000, tod, &secs, &ns); /* isolate seconds & 100ns parts */ | |
tp->tv_sec = secs; | |
tp->tv_nsec = ns*100; | |
return 0; | |
} | |
#endif /* CLOCK_REALTIME */ | |
#elif defined (_WIN32) | |
/* Win32 routines */ | |
#include <windows.h> | |
const t_bool rtc_avail = TRUE; | |
uint32 sim_os_msec () | |
{ | |
if (sim_idle_rate_ms) | |
return timeGetTime (); | |
else return GetTickCount (); | |
} | |
void sim_os_sleep (unsigned int sec) | |
{ | |
Sleep (sec * 1000); | |
return; | |
} | |
void sim_timer_exit (void) | |
{ | |
timeEndPeriod (sim_idle_rate_ms); | |
return; | |
} | |
uint32 sim_os_ms_sleep_init (void) | |
{ | |
TIMECAPS timers; | |
if (timeGetDevCaps (&timers, sizeof (timers)) != TIMERR_NOERROR) | |
return 0; | |
sim_os_sleep_min_ms = timers.wPeriodMin; | |
if ((timers.wPeriodMin == 0) || (timers.wPeriodMin > SIM_IDLE_MAX)) | |
return 0; | |
if (timeBeginPeriod (timers.wPeriodMin) != TIMERR_NOERROR) | |
return 0; | |
atexit (sim_timer_exit); | |
Sleep (1); | |
Sleep (1); | |
Sleep (1); | |
Sleep (1); | |
Sleep (1); | |
return sim_os_sleep_min_ms; /* sim_idle_rate_ms */ | |
} | |
uint32 sim_os_ms_sleep (unsigned int msec) | |
{ | |
uint32 stime = sim_os_msec(); | |
Sleep (msec); | |
return sim_os_msec () - stime; | |
} | |
#if defined(NEED_CLOCK_GETTIME) | |
int clock_gettime(int clk_id, struct timespec *tp) | |
{ | |
t_uint64 now, unixbase; | |
if (clk_id != CLOCK_REALTIME) | |
return -1; | |
unixbase = 116444736; | |
unixbase *= 1000000000; | |
GetSystemTimeAsFileTime((FILETIME*)&now); | |
now -= unixbase; | |
tp->tv_sec = (long)(now/10000000); | |
tp->tv_nsec = (now%10000000)*100; | |
return 0; | |
} | |
#endif | |
#elif defined (__OS2__) | |
/* OS/2 routines, from Bruce Ray */ | |
const t_bool rtc_avail = FALSE; | |
uint32 sim_os_msec () | |
{ | |
return 0; | |
} | |
void sim_os_sleep (unsigned int sec) | |
{ | |
return; | |
} | |
uint32 sim_os_ms_sleep_init (void) | |
{ | |
return 0; | |
} | |
uint32 sim_os_ms_sleep (unsigned int msec) | |
{ | |
return 0; | |
} | |
/* Metrowerks CodeWarrior Macintosh routines, from Ben Supnik */ | |
#elif defined (__MWERKS__) && defined (macintosh) | |
#include <Timer.h> | |
#include <Mactypes.h> | |
#include <sioux.h> | |
#include <unistd.h> | |
#include <siouxglobals.h> | |
#define NANOS_PER_MILLI 1000000 | |
#define MILLIS_PER_SEC 1000 | |
const t_bool rtc_avail = TRUE; | |
uint32 sim_os_msec (void) | |
{ | |
unsigned long long micros; | |
UnsignedWide macMicros; | |
unsigned long millis; | |
Microseconds (&macMicros); | |
micros = *((unsigned long long *) &macMicros); | |
millis = micros / 1000LL; | |
return (uint32) millis; | |
} | |
void sim_os_sleep (unsigned int sec) | |
{ | |
sleep (sec); | |
return; | |
} | |
uint32 sim_os_ms_sleep_init (void) | |
{ | |
return sim_os_sleep_min_ms = 1; | |
} | |
uint32 sim_os_ms_sleep (unsigned int milliseconds) | |
{ | |
uint32 stime = sim_os_msec (); | |
struct timespec treq; | |
treq.tv_sec = milliseconds / MILLIS_PER_SEC; | |
treq.tv_nsec = (milliseconds % MILLIS_PER_SEC) * NANOS_PER_MILLI; | |
(void) nanosleep (&treq, NULL); | |
return sim_os_msec () - stime; | |
} | |
#if defined(NEED_CLOCK_GETTIME) | |
int clock_gettime(int clk_id, struct timespec *tp) | |
{ | |
struct timeval cur; | |
struct timezone foo; | |
if (clk_id != CLOCK_REALTIME) | |
return -1; | |
gettimeofday (&cur, &foo); | |
tp->tv_sec = cur.tv_sec; | |
tp->tv_nsec = cur.tv_usec*1000; | |
return 0; | |
} | |
#endif | |
#else | |
/* UNIX routines */ | |
#include <time.h> | |
#include <sys/time.h> | |
#include <unistd.h> | |
#define NANOS_PER_MILLI 1000000 | |
#define MILLIS_PER_SEC 1000 | |
#define sleep1Samples 100 | |
const t_bool rtc_avail = TRUE; | |
uint32 sim_os_msec () | |
{ | |
struct timeval cur; | |
struct timezone foo; | |
uint32 msec; | |
gettimeofday (&cur, &foo); | |
msec = (((uint32) cur.tv_sec) * 1000) + (((uint32) cur.tv_usec) / 1000); | |
return msec; | |
} | |
void sim_os_sleep (unsigned int sec) | |
{ | |
sleep (sec); | |
return; | |
} | |
uint32 sim_os_ms_sleep_init (void) | |
{ | |
uint32 i, t1, t2, tot, tim; | |
SIM_IDLE_MS_SLEEP (1); /* Start sampling on a tick boundary */ | |
for (i = 0, tot = 0; i < sleep1Samples; i++) { | |
t1 = sim_os_msec (); | |
SIM_IDLE_MS_SLEEP (1); | |
t2 = sim_os_msec (); | |
tot += (t2 - t1); | |
} | |
tim = (tot + (sleep1Samples - 1)) / sleep1Samples; | |
sim_os_sleep_min_ms = tim; | |
if (tim > SIM_IDLE_MAX) | |
tim = 0; | |
return tim; | |
} | |
#if !defined(_POSIX_SOURCE) | |
#ifdef NEED_CLOCK_GETTIME | |
typedef int clockid_t; | |
int clock_gettime(clockid_t clk_id, struct timespec *tp) | |
{ | |
struct timeval cur; | |
struct timezone foo; | |
if (clk_id != CLOCK_REALTIME) | |
return -1; | |
gettimeofday (&cur, &foo); | |
tp->tv_sec = cur.tv_sec; | |
tp->tv_nsec = cur.tv_usec*1000; | |
return 0; | |
} | |
#endif /* CLOCK_REALTIME */ | |
#endif /* !defined(_POSIX_SOURCE) && defined(SIM_ASYNCH_IO) */ | |
uint32 sim_os_ms_sleep (unsigned int milliseconds) | |
{ | |
uint32 stime = sim_os_msec (); | |
struct timespec treq; | |
treq.tv_sec = milliseconds / MILLIS_PER_SEC; | |
treq.tv_nsec = (milliseconds % MILLIS_PER_SEC) * NANOS_PER_MILLI; | |
(void) nanosleep (&treq, NULL); | |
return sim_os_msec () - stime; | |
} | |
#endif | |
/* diff = min - sub */ | |
void | |
sim_timespec_diff (struct timespec *diff, struct timespec *min, struct timespec *sub) | |
{ | |
/* move the minuend value to the difference and operate there. */ | |
*diff = *min; | |
/* Borrow as needed for the nsec value */ | |
while (sub->tv_nsec > diff->tv_nsec) { | |
--diff->tv_sec; | |
diff->tv_nsec += 1000000000; | |
} | |
diff->tv_nsec -= sub->tv_nsec; | |
diff->tv_sec -= sub->tv_sec; | |
/* Normalize the result */ | |
while (diff->tv_nsec > 1000000000) { | |
++diff->tv_sec; | |
diff->tv_nsec -= 1000000000; | |
} | |
} | |
static int sim_timespec_compare (struct timespec *a, struct timespec *b) | |
{ | |
while (a->tv_nsec > 1000000000) { | |
a->tv_nsec -= 1000000000; | |
++a->tv_sec; | |
} | |
while (b->tv_nsec > 1000000000) { | |
b->tv_nsec -= 1000000000; | |
++b->tv_sec; | |
} | |
if (a->tv_sec < b->tv_sec) | |
return -1; | |
if (a->tv_sec > b->tv_sec) | |
return 1; | |
if (a->tv_nsec < b->tv_nsec) | |
return -1; | |
if (a->tv_nsec > b->tv_nsec) | |
return 1; | |
else | |
return 0; | |
} | |
/* OS independent clock calibration package */ | |
static int32 rtc_ticks[SIM_NTIMERS] = { 0 }; /* ticks */ | |
static int32 rtc_hz[SIM_NTIMERS] = { 0 }; /* tick rate */ | |
static uint32 rtc_rtime[SIM_NTIMERS] = { 0 }; /* real time */ | |
static uint32 rtc_vtime[SIM_NTIMERS] = { 0 }; /* virtual time */ | |
static double rtc_gtime[SIM_NTIMERS] = { 0 }; /* instruction time */ | |
static uint32 rtc_nxintv[SIM_NTIMERS] = { 0 }; /* next interval */ | |
static int32 rtc_based[SIM_NTIMERS] = { 0 }; /* base delay */ | |
static int32 rtc_currd[SIM_NTIMERS] = { 0 }; /* current delay */ | |
static int32 rtc_initd[SIM_NTIMERS] = { 0 }; /* initial delay */ | |
static uint32 rtc_elapsed[SIM_NTIMERS] = { 0 }; /* sec since init */ | |
static uint32 rtc_calibrations[SIM_NTIMERS] = { 0 }; /* calibration count */ | |
static double rtc_clock_skew_max[SIM_NTIMERS] = { 0 }; /* asynchronous max skew */ | |
void sim_rtcn_init_all (void) | |
{ | |
uint32 i; | |
for (i = 0; i < SIM_NTIMERS; i++) { | |
if (rtc_initd[i] != 0) sim_rtcn_init (rtc_initd[i], i); | |
} | |
return; | |
} | |
int32 sim_rtcn_init (int32 time, int32 tmr) | |
{ | |
sim_debug (DBG_CAL, &sim_timer_dev, "sim_rtcn_init(time=%d, tmr=%d)\n", time, tmr); | |
if (time == 0) | |
time = 1; | |
if ((tmr < 0) || (tmr >= SIM_NTIMERS)) | |
return time; | |
rtc_rtime[tmr] = sim_os_msec (); | |
rtc_vtime[tmr] = rtc_rtime[tmr]; | |
rtc_nxintv[tmr] = 1000; | |
rtc_ticks[tmr] = 0; | |
rtc_hz[tmr] = 0; | |
rtc_based[tmr] = time; | |
rtc_currd[tmr] = time; | |
rtc_initd[tmr] = time; | |
rtc_elapsed[tmr] = 0; | |
rtc_calibrations[tmr] = 0; | |
if (sim_calb_tmr == -1) /* save first initialized clock as the system timer */ | |
sim_calb_tmr = tmr; | |
return time; | |
} | |
int32 sim_rtcn_calb (int32 ticksper, int32 tmr) | |
{ | |
uint32 new_rtime, delta_rtime; | |
int32 delta_vtime; | |
double new_gtime; | |
int32 new_currd; | |
if ((tmr < 0) || (tmr >= SIM_NTIMERS)) | |
return 10000; | |
rtc_hz[tmr] = ticksper; | |
rtc_ticks[tmr] = rtc_ticks[tmr] + 1; /* count ticks */ | |
if (rtc_ticks[tmr] < ticksper) { /* 1 sec yet? */ | |
return rtc_currd[tmr]; | |
} | |
rtc_ticks[tmr] = 0; /* reset ticks */ | |
rtc_elapsed[tmr] = rtc_elapsed[tmr] + 1; /* count sec */ | |
if (!rtc_avail) { /* no timer? */ | |
return rtc_currd[tmr]; | |
} | |
new_rtime = sim_os_msec (); /* wall time */ | |
sim_debug (DBG_TRC, &sim_timer_dev, "sim_rtcn_calb(ticksper=%d, tmr=%d) rtime=%d\n", ticksper, tmr, new_rtime); | |
if (sim_idle_idled) { | |
rtc_rtime[tmr] = new_rtime; /* save wall time */ | |
rtc_vtime[tmr] = rtc_vtime[tmr] + 1000; /* adv sim time */ | |
rtc_gtime[tmr] = sim_gtime(); /* save instruction time */ | |
sim_idle_idled = FALSE; /* reset idled flag */ | |
sim_debug (DBG_CAL, &sim_timer_dev, "skipping calibration due to idling - result: %d\n", rtc_currd[tmr]); | |
return rtc_currd[tmr]; /* avoid calibrating idle checks */ | |
} | |
if (new_rtime < rtc_rtime[tmr]) { /* time running backwards? */ | |
rtc_rtime[tmr] = new_rtime; /* reset wall time */ | |
sim_debug (DBG_CAL, &sim_timer_dev, "time running backwards - result: %d\n", rtc_currd[tmr]); | |
return rtc_currd[tmr]; /* can't calibrate */ | |
} | |
++rtc_calibrations[tmr]; /* count calibrations */ | |
delta_rtime = new_rtime - rtc_rtime[tmr]; /* elapsed wtime */ | |
rtc_rtime[tmr] = new_rtime; /* adv wall time */ | |
rtc_vtime[tmr] = rtc_vtime[tmr] + 1000; /* adv sim time */ | |
if (delta_rtime > 30000) { /* gap too big? */ | |
rtc_currd[tmr] = rtc_initd[tmr]; | |
rtc_gtime[tmr] = sim_gtime(); /* save instruction time */ | |
sim_debug (DBG_CAL, &sim_timer_dev, "gap too big: delta = %d - result: %d\n", delta_rtime, rtc_initd[tmr]); | |
return rtc_initd[tmr]; /* can't calibr */ | |
} | |
new_gtime = sim_gtime(); | |
if (sim_asynch_enabled && sim_asynch_timer) { | |
if (rtc_elapsed[tmr] > sim_idle_stable) { | |
/* An asynchronous clock, merely needs to divide the number of */ | |
/* instructions actually executed by the clock rate. */ | |
new_currd = (int32)((new_gtime - rtc_gtime[tmr])/ticksper); | |
/* avoid excessive swings in the calibrated result */ | |
if (new_currd > 10*rtc_currd[tmr]) /* don't swing big too fast */ | |
new_currd = 10*rtc_currd[tmr]; | |
else | |
if (new_currd < rtc_currd[tmr]/10) /* don't swing small too fast */ | |
new_currd = rtc_currd[tmr]/10; | |
rtc_currd[tmr] = new_currd; | |
rtc_gtime[tmr] = new_gtime; /* save instruction time */ | |
if (rtc_currd[tmr] == 127) { | |
sim_debug (DBG_CAL, &sim_timer_dev, "asynch calibration small: %d\n", rtc_currd[tmr]); | |
} | |
sim_debug (DBG_CAL, &sim_timer_dev, "asynch calibration result: %d\n", rtc_currd[tmr]); | |
return rtc_currd[tmr]; /* calibrated result */ | |
} | |
else { | |
rtc_currd[tmr] = rtc_initd[tmr]; | |
rtc_gtime[tmr] = new_gtime; /* save instruction time */ | |
sim_debug (DBG_CAL, &sim_timer_dev, "asynch not stable calibration result: %d\n", rtc_initd[tmr]); | |
return rtc_initd[tmr]; /* initial result until stable */ | |
} | |
} | |
rtc_gtime[tmr] = new_gtime; /* save instruction time */ | |
/* This self regulating algorithm depends directly on the assumption */ | |
/* that this routine is called back after processing the number of */ | |
/* instructions which was returned the last time it was called. */ | |
if (delta_rtime == 0) /* gap too small? */ | |
rtc_based[tmr] = rtc_based[tmr] * ticksper; /* slew wide */ | |
else rtc_based[tmr] = (int32) (((double) rtc_based[tmr] * (double) rtc_nxintv[tmr]) / | |
((double) delta_rtime)); /* new base rate */ | |
delta_vtime = rtc_vtime[tmr] - rtc_rtime[tmr]; /* gap */ | |
if (delta_vtime > SIM_TMAX) /* limit gap */ | |
delta_vtime = SIM_TMAX; | |
else if (delta_vtime < -SIM_TMAX) | |
delta_vtime = -SIM_TMAX; | |
rtc_nxintv[tmr] = 1000 + delta_vtime; /* next wtime */ | |
rtc_currd[tmr] = (int32) (((double) rtc_based[tmr] * (double) rtc_nxintv[tmr]) / | |
1000.0); /* next delay */ | |
if (rtc_based[tmr] <= 0) /* never negative or zero! */ | |
rtc_based[tmr] = 1; | |
if (rtc_currd[tmr] <= 0) /* never negative or zero! */ | |
rtc_currd[tmr] = 1; | |
sim_debug (DBG_CAL, &sim_timer_dev, "calibrated result: %d\n", rtc_currd[tmr]); | |
AIO_SET_INTERRUPT_LATENCY(rtc_currd[tmr]*ticksper); /* set interrrupt latency */ | |
return rtc_currd[tmr]; | |
} | |
/* Prior interfaces - default to timer 0 */ | |
int32 sim_rtc_init (int32 time) | |
{ | |
return sim_rtcn_init (time, 0); | |
} | |
int32 sim_rtc_calb (int32 ticksper) | |
{ | |
return sim_rtcn_calb (ticksper, 0); | |
} | |
/* sim_timer_init - get minimum sleep time available on this host */ | |
t_bool sim_timer_init (void) | |
{ | |
sim_debug (DBG_TRC, &sim_timer_dev, "sim_timer_init()\n"); | |
sim_register_internal_device (&sim_timer_dev); | |
sim_idle_enab = FALSE; /* init idle off */ | |
sim_idle_rate_ms = sim_os_ms_sleep_init (); /* get OS timer rate */ | |
return (sim_idle_rate_ms != 0); | |
} | |
/* sim_timer_idle_capable - tell if the host is Idle capable and what the host OS tick size is */ | |
uint32 sim_timer_idle_capable (uint32 *host_tick_ms) | |
{ | |
if (host_tick_ms) | |
*host_tick_ms = sim_os_sleep_min_ms; | |
return sim_idle_rate_ms; | |
} | |
/* sim_show_timers - show running timer information */ | |
t_stat sim_show_timers (FILE* st, DEVICE *dptr, UNIT* uptr, int32 val, char* desc) | |
{ | |
int tmr; | |
if (sim_clock_unit) | |
fprintf (st, "%s clock device is %s\n", sim_name, sim_uname(sim_clock_unit)); | |
else | |
fprintf (st, "%s clock device is not specified, co-scheduling is unavailable\n", sim_name); | |
for (tmr=0; tmr<SIM_NTIMERS; ++tmr) { | |
if (0 == rtc_initd[tmr]) | |
continue; | |
fprintf (st, "%s%sTimer %d:\n", (sim_asynch_enabled && sim_asynch_timer) ? "Asynchronous " : "", rtc_hz[tmr] ? "Calibrated " : "Uncalibrated ", tmr); | |
if (rtc_hz[tmr]) { | |
fprintf (st, " Running at: %dhz\n", rtc_hz[tmr]); | |
fprintf (st, " Ticks in current second: %d\n", rtc_ticks[tmr]); | |
} | |
fprintf (st, " Seconds Running: %u\n", rtc_elapsed[tmr]); | |
fprintf (st, " Calibrations: %u\n", rtc_calibrations[tmr]); | |
fprintf (st, " Instruction Time: %.0f\n", rtc_gtime[tmr]); | |
if (!(sim_asynch_enabled && sim_asynch_timer)) { | |
fprintf (st, " Real Time: %u\n", rtc_rtime[tmr]); | |
fprintf (st, " Virtual Time: %u\n", rtc_vtime[tmr]); | |
fprintf (st, " Next Interval: %u\n", rtc_nxintv[tmr]); | |
fprintf (st, " Base Tick Delay: %d\n", rtc_based[tmr]); | |
fprintf (st, " Initial Insts Per Tick: %d\n", rtc_initd[tmr]); | |
} | |
fprintf (st, " Current Insts Per Tick: %d\n", rtc_currd[tmr]); | |
if (rtc_clock_skew_max[tmr] != 0.0) | |
fprintf (st, " Peak Clock Skew: %.0fms\n", rtc_clock_skew_max[tmr]); | |
} | |
return SCPE_OK; | |
} | |
REG sim_timer_reg[] = { | |
{ DRDATAD (TICKS_PER_SEC, rtc_hz[0], 32, "Ticks Per Second"), PV_RSPC|REG_RO}, | |
{ DRDATAD (INSTS_PER_TICK, rtc_currd[0], 32, "Instructions Per Tick"), PV_RSPC|REG_RO}, | |
{ FLDATAD (IDLE_ENAB, sim_idle_enab, 0, "Idle Enabled"), REG_RO}, | |
{ DRDATAD (IDLE_RATE_MS, sim_idle_rate_ms, 32, "Idle Rate Milliseconds"), PV_RSPC|REG_RO}, | |
{ DRDATAD (OS_SLEEP_MIN_MS, sim_os_sleep_min_ms, 32, "Minimum Sleep Resolution"), PV_RSPC|REG_RO}, | |
{ DRDATAD (IDLE_STABLE, sim_idle_stable, 32, "Idle Stable"), PV_RSPC}, | |
{ FLDATAD (IDLE_IDLED, sim_idle_idled, 0, ""), REG_RO}, | |
{ DRDATAD (TMR, sim_calb_tmr, 32, ""), PV_RSPC|REG_RO}, | |
{ DRDATAD (THROT_MS_START, sim_throt_ms_start, 32, ""), PV_RSPC|REG_RO}, | |
{ DRDATAD (THROT_MS_STOP, sim_throt_ms_stop, 32, ""), PV_RSPC|REG_RO}, | |
{ DRDATAD (THROT_TYPE, sim_throt_type, 32, ""), PV_RSPC|REG_RO}, | |
{ DRDATAD (THROT_VAL, sim_throt_val, 32, ""), PV_RSPC|REG_RO}, | |
{ DRDATAD (THROT_STATE, sim_throt_state, 32, ""), PV_RSPC|REG_RO}, | |
{ DRDATAD (THROT_SLEEP_TIME, sim_throt_sleep_time, 32, ""), PV_RSPC|REG_RO}, | |
{ DRDATAD (THROT_WAIT, sim_throt_wait, 32, ""), PV_RSPC|REG_RO}, | |
{ NULL } | |
}; | |
/* Clear, Set and show asynch */ | |
/* Clear asynch */ | |
t_stat sim_timer_clr_async (UNIT *uptr, int32 val, char *cptr, void *desc) | |
{ | |
if (sim_asynch_timer) { | |
sim_asynch_timer = FALSE; | |
sim_timer_change_asynch (); | |
} | |
return SCPE_OK; | |
} | |
t_stat sim_timer_set_async (UNIT *uptr, int32 val, char *cptr, void *desc) | |
{ | |
if (!sim_asynch_timer) { | |
sim_asynch_timer = TRUE; | |
sim_timer_change_asynch (); | |
} | |
return SCPE_OK; | |
} | |
t_stat sim_timer_show_async (FILE *st, UNIT *uptr, int32 val, void *desc) | |
{ | |
fprintf (st, "%s", (sim_asynch_enabled && sim_asynch_timer) ? "Asynchronous" : "Synchronous"); | |
return SCPE_OK; | |
} | |
MTAB sim_timer_mod[] = { | |
#if defined (SIM_ASYNCH_IO) && defined (SIM_ASYNCH_CLOCKS) | |
{ MTAB_XTD|MTAB_VDV, 0, "ASYNC", "ASYNC", &sim_timer_set_async, &sim_timer_show_async }, | |
{ MTAB_XTD|MTAB_VDV, 0, NULL, "NOASYNC", &sim_timer_clr_async, NULL }, | |
#endif | |
{ 0 }, | |
}; | |
DEVICE sim_timer_dev = { | |
"TIMER", &sim_throt_unit, sim_timer_reg, sim_timer_mod, | |
1, 0, 0, 0, 0, 0, | |
NULL, NULL, NULL, NULL, NULL, NULL, | |
NULL, DEV_DEBUG, 0, sim_timer_debug}; | |
/* sim_idle - idle simulator until next event or for specified interval | |
Inputs: | |
tmr = calibrated timer to use | |
Must solve the linear equation | |
ms_to_wait = w * ms_per_wait | |
Or | |
w = ms_to_wait / ms_per_wait | |
*/ | |
t_bool sim_idle (uint32 tmr, t_bool sin_cyc) | |
{ | |
static uint32 cyc_ms = 0; | |
uint32 w_ms, w_idle, act_ms; | |
int32 act_cyc; | |
//sim_idle_idled = TRUE; /* record idle attempt */ | |
if ((!sim_idle_enab) || /* idling disabled */ | |
((sim_clock_queue == QUEUE_LIST_END) && /* or clock queue empty? */ | |
#if defined(SIM_ASYNCH_IO) && defined(SIM_ASYNCH_CLOCKS) | |
(!(sim_asynch_enabled && sim_asynch_timer)))|| /* and not asynch? */ | |
#else | |
(TRUE)) || | |
#endif | |
((sim_clock_queue != QUEUE_LIST_END) && | |
((sim_clock_queue->flags & UNIT_IDLE) == 0))|| /* or event not idle-able? */ | |
(rtc_elapsed[tmr] < sim_idle_stable)) { /* or timer not stable? */ | |
if (sin_cyc) | |
sim_interval = sim_interval - 1; | |
return FALSE; | |
} | |
sim_debug (DBG_TRC, &sim_timer_dev, "sim_idle(tmr=%d, sin_cyc=%d)\n", tmr, sin_cyc); | |
if (cyc_ms == 0) /* not computed yet? */ | |
cyc_ms = (rtc_currd[tmr] * rtc_hz[tmr]) / 1000; /* cycles per msec */ | |
if ((sim_idle_rate_ms == 0) || (cyc_ms == 0)) { /* not possible? */ | |
if (sin_cyc) | |
sim_interval = sim_interval - 1; | |
sim_debug (DBG_IDL, &sim_timer_dev, "not possible %d - %d\n", sim_idle_rate_ms, cyc_ms); | |
return FALSE; | |
} | |
w_ms = (uint32) sim_interval / cyc_ms; /* ms to wait */ | |
w_idle = w_ms / sim_idle_rate_ms; /* intervals to wait */ | |
if (w_idle == 0) { /* none? */ | |
if (sin_cyc) | |
sim_interval = sim_interval - 1; | |
sim_debug (DBG_IDL, &sim_timer_dev, "no wait\n"); | |
return FALSE; | |
} | |
if (sim_clock_queue == QUEUE_LIST_END) | |
sim_debug (DBG_IDL, &sim_timer_dev, "sleeping for %d ms - pending event in %d instructions\n", w_ms, sim_interval); | |
else | |
sim_debug (DBG_IDL, &sim_timer_dev, "sleeping for %d ms - pending event on %s in %d instructions\n", w_ms, sim_uname(sim_clock_queue), sim_interval); | |
act_ms = SIM_IDLE_MS_SLEEP (w_ms); /* wait */ | |
act_cyc = act_ms * cyc_ms; | |
if (act_ms < w_ms) /* awakened early? */ | |
act_cyc += (cyc_ms * sim_idle_rate_ms) / 2; /* account for half an interval's worth of cycles */ | |
if (sim_interval > act_cyc) | |
sim_interval = sim_interval - act_cyc; /* count down sim_interval */ | |
else sim_interval = 0; /* or fire immediately */ | |
if (sim_clock_queue == QUEUE_LIST_END) | |
sim_debug (DBG_IDL, &sim_timer_dev, "slept for %d ms - pending event in %d instructions\n", act_ms, sim_interval); | |
else | |
sim_debug (DBG_IDL, &sim_timer_dev, "slept for %d ms - pending event on %s in %d instructions\n", act_ms, sim_uname(sim_clock_queue), sim_interval); | |
return TRUE; | |
} | |
/* Set idling - implicitly disables throttling */ | |
t_stat sim_set_idle (UNIT *uptr, int32 val, char *cptr, void *desc) | |
{ | |
t_stat r; | |
uint32 v; | |
if (sim_idle_rate_ms == 0) { | |
printf ("Idling is not available, Minimum OS sleep time is %dms\n", sim_os_sleep_min_ms); | |
if (sim_log) | |
fprintf (sim_log, "Idling is not available, Minimum OS sleep time is %dms\n", sim_os_sleep_min_ms); | |
return SCPE_NOFNC; | |
} | |
if ((val != 0) && (sim_idle_rate_ms > (uint32) val)) { | |
printf ("Idling is not available, Minimum OS sleep time is %dms, Requied minimum OS sleep is %dms\n", sim_os_sleep_min_ms, val); | |
if (sim_log) | |
fprintf (sim_log, "Idling is not available, Minimum OS sleep time is %dms, Requied minimum OS sleep is %dms\n", sim_os_sleep_min_ms, val); | |
return SCPE_NOFNC; | |
} | |
if (cptr) { | |
v = (uint32) get_uint (cptr, 10, SIM_IDLE_STMAX, &r); | |
if ((r != SCPE_OK) || (v < SIM_IDLE_STMIN)) | |
return SCPE_ARG; | |
sim_idle_stable = v; | |
} | |
sim_idle_enab = TRUE; | |
if (sim_throt_type != SIM_THROT_NONE) { | |
sim_set_throt (0, NULL); | |
printf ("Throttling disabled\n"); | |
if (sim_log) | |
fprintf (sim_log, "Throttling disabled\n"); | |
} | |
return SCPE_OK; | |
} | |
/* Clear idling */ | |
t_stat sim_clr_idle (UNIT *uptr, int32 val, char *cptr, void *desc) | |
{ | |
sim_idle_enab = FALSE; | |
return SCPE_OK; | |
} | |
/* Show idling */ | |
t_stat sim_show_idle (FILE *st, UNIT *uptr, int32 val, void *desc) | |
{ | |
if (sim_idle_enab) | |
fprintf (st, "idle enabled"); | |
else | |
fprintf (st, "idle disabled"); | |
if (sim_switches & SWMASK ('D')) | |
fprintf (st, ", stability wait = %ds, minimum sleep resolution = %dms", sim_idle_stable, sim_os_sleep_min_ms); | |
return SCPE_OK; | |
} | |
/* Throttling package */ | |
t_stat sim_set_throt (int32 arg, char *cptr) | |
{ | |
char *tptr, c; | |
t_value val, val2 = 0; | |
if (arg == 0) { | |
if ((cptr != 0) && (*cptr != 0)) | |
return SCPE_ARG; | |
sim_throt_type = SIM_THROT_NONE; | |
sim_throt_cancel (); | |
} | |
else if (sim_idle_rate_ms == 0) { | |
printf ("Throttling is not available, Minimum OS sleep time is %dms\n", sim_os_sleep_min_ms); | |
if (sim_log) | |
fprintf (sim_log, "Throttling is not available, Minimum OS sleep time is %dms\n", sim_os_sleep_min_ms); | |
return SCPE_NOFNC; | |
} | |
else { | |
val = strtotv (cptr, &tptr, 10); | |
if (cptr == tptr) | |
return SCPE_ARG; | |
sim_throt_sleep_time = sim_idle_rate_ms; | |
c = toupper (*tptr++); | |
if (c == '/') | |
val2 = strtotv (tptr, &tptr, 10); | |
if ((*tptr != 0) || (val == 0)) | |
return SCPE_ARG; | |
if (c == 'M') | |
sim_throt_type = SIM_THROT_MCYC; | |
else if (c == 'K') | |
sim_throt_type = SIM_THROT_KCYC; | |
else if ((c == '%') && (val > 0) && (val < 100)) | |
sim_throt_type = SIM_THROT_PCT; | |
else if ((c == '/') && (val2 != 0)) { | |
sim_throt_type = SIM_THROT_SPC; | |
} | |
else return SCPE_ARG; | |
if (sim_idle_enab) { | |
printf ("Idling disabled\n"); | |
if (sim_log) | |
fprintf (sim_log, "Idling disabled\n"); | |
sim_clr_idle (NULL, 0, NULL, NULL); | |
} | |
sim_throt_val = (uint32) val; | |
if (sim_throt_type == SIM_THROT_SPC) { | |
if (val2 >= sim_idle_rate_ms) | |
sim_throt_sleep_time = (uint32) val2; | |
else { | |
sim_throt_sleep_time = (uint32) (val2 * sim_idle_rate_ms); | |
sim_throt_val = (uint32) (val * sim_idle_rate_ms); | |
} | |
} | |
} | |
return SCPE_OK; | |
} | |
t_stat sim_show_throt (FILE *st, DEVICE *dnotused, UNIT *unotused, int32 flag, char *cptr) | |
{ | |
if (sim_idle_rate_ms == 0) | |
fprintf (st, "Throttling not available\n"); | |
else { | |
switch (sim_throt_type) { | |
case SIM_THROT_MCYC: | |
fprintf (st, "Throttle = %d megacycles\n", sim_throt_val); | |
break; | |
case SIM_THROT_KCYC: | |
fprintf (st, "Throttle = %d kilocycles\n", sim_throt_val); | |
break; | |
case SIM_THROT_PCT: | |
fprintf (st, "Throttle = %d%%\n", sim_throt_val); | |
break; | |
case SIM_THROT_SPC: | |
fprintf (st, "Throttle = %d ms every %d cycles\n", sim_throt_sleep_time, sim_throt_val); | |
break; | |
default: | |
fprintf (st, "Throttling disabled\n"); | |
break; | |
} | |
if (sim_switches & SWMASK ('D')) { | |
if (sim_throt_type != 0) | |
fprintf (st, "Throttle interval = %d cycles\n", sim_throt_wait); | |
} | |
} | |
if (sim_switches & SWMASK ('D')) | |
fprintf (st, "minimum sleep resolution = %d ms\n", sim_os_sleep_min_ms); | |
return SCPE_OK; | |
} | |
void sim_throt_sched (void) | |
{ | |
sim_throt_state = 0; | |
if (sim_throt_type) | |
sim_activate (&sim_throt_unit, SIM_THROT_WINIT); | |
} | |
void sim_throt_cancel (void) | |
{ | |
sim_cancel (&sim_throt_unit); | |
} | |
/* Throttle service | |
Throttle service has three distinct states used while dynamically | |
determining a throttling interval: | |
0 take initial measurement | |
1 take final measurement, calculate wait values | |
2 periodic waits to slow down the CPU | |
*/ | |
t_stat sim_throt_svc (UNIT *uptr) | |
{ | |
uint32 delta_ms; | |
double a_cps, d_cps; | |
if (sim_throt_type == SIM_THROT_SPC) { /* Non dynamic? */ | |
sim_throt_state = 2; /* force state */ | |
sim_throt_wait = sim_throt_val; | |
} | |
switch (sim_throt_state) { | |
case 0: /* take initial reading */ | |
sim_throt_ms_start = sim_os_msec (); | |
sim_throt_wait = SIM_THROT_WST; | |
sim_throt_state = 1; /* next state */ | |
break; /* reschedule */ | |
case 1: /* take final reading */ | |
sim_throt_ms_stop = sim_os_msec (); | |
delta_ms = sim_throt_ms_stop - sim_throt_ms_start; | |
if (delta_ms < SIM_THROT_MSMIN) { /* not enough time? */ | |
if (sim_throt_wait >= 100000000) { /* too many inst? */ | |
sim_throt_state = 0; /* fails in 32b! */ | |
return SCPE_OK; | |
} | |
sim_throt_wait = sim_throt_wait * SIM_THROT_WMUL; | |
sim_throt_ms_start = sim_throt_ms_stop; | |
} | |
else { /* long enough */ | |
a_cps = ((double) sim_throt_wait) * 1000.0 / (double) delta_ms; | |
if (sim_throt_type == SIM_THROT_MCYC) /* calc desired cps */ | |
d_cps = (double) sim_throt_val * 1000000.0; | |
else if (sim_throt_type == SIM_THROT_KCYC) | |
d_cps = (double) sim_throt_val * 1000.0; | |
else d_cps = (a_cps * ((double) sim_throt_val)) / 100.0; | |
if (d_cps >= a_cps) { | |
sim_throt_sched (); /* start over */ | |
return SCPE_OK; | |
} | |
sim_throt_wait = (int32) /* time between waits */ | |
((a_cps * d_cps * ((double) sim_idle_rate_ms)) / | |
(1000.0 * (a_cps - d_cps))); | |
if (sim_throt_wait < SIM_THROT_WMIN) { /* not long enough? */ | |
sim_throt_sched (); /* start over */ | |
return SCPE_OK; | |
} | |
sim_throt_ms_start = sim_throt_ms_stop; | |
sim_throt_state = 2; | |
// fprintf (stderr, "Throttle values a_cps = %f, d_cps = %f, wait = %d\n", | |
// a_cps, d_cps, sim_throt_wait); | |
} | |
break; | |
case 2: /* throttling */ | |
SIM_IDLE_MS_SLEEP (sim_throt_sleep_time); | |
delta_ms = sim_os_msec () - sim_throt_ms_start; | |
if ((sim_throt_type != SIM_THROT_SPC) && /* when dynamic throttling */ | |
(delta_ms >= 10000)) { /* recompute every 10 sec */ | |
sim_throt_ms_start = sim_os_msec (); | |
sim_throt_wait = SIM_THROT_WST; | |
sim_throt_state = 1; /* next state */ | |
} | |
break; | |
} | |
sim_activate (uptr, sim_throt_wait); /* reschedule */ | |
return SCPE_OK; | |
} | |
#if defined(SIM_ASYNCH_IO) && defined(SIM_ASYNCH_CLOCKS) | |
static double _timespec_to_double (struct timespec *time) | |
{ | |
return ((double)time->tv_sec)+(double)(time->tv_nsec)/1000000000.0; | |
} | |
static void _double_to_timespec (struct timespec *time, double dtime) | |
{ | |
time->tv_sec = (time_t)floor(dtime); | |
time->tv_nsec = (long)((dtime-floor(dtime))*1000000000.0); | |
} | |
double sim_timenow_double (void) | |
{ | |
struct timespec now; | |
clock_gettime(CLOCK_REALTIME, &now); | |
return _timespec_to_double (&now); | |
} | |
extern int32 sim_is_running; | |
extern UNIT * volatile sim_wallclock_queue; | |
extern UNIT * volatile sim_wallclock_entry; | |
pthread_t sim_timer_thread; /* Wall Clock Timing Thread Id */ | |
pthread_cond_t sim_timer_startup_cond; | |
t_bool sim_timer_thread_running = FALSE; | |
t_bool sim_timer_event_canceled = FALSE; | |
static void * | |
_timer_thread(void *arg) | |
{ | |
int sched_policy; | |
struct sched_param sched_priority; | |
/* Boost Priority for this I/O thread vs the CPU instruction execution | |
thread which, in general, won't be readily yielding the processor when | |
this thread needs to run */ | |
pthread_getschedparam (pthread_self(), &sched_policy, &sched_priority); | |
++sched_priority.sched_priority; | |
pthread_setschedparam (pthread_self(), sched_policy, &sched_priority); | |
sim_debug (DBG_TIM, &sim_timer_dev, "_timer_thread() - starting\n"); | |
pthread_mutex_lock (&sim_timer_lock); | |
pthread_cond_signal (&sim_timer_startup_cond); /* Signal we're ready to go */ | |
while (sim_asynch_enabled && sim_asynch_timer && sim_is_running) { | |
struct timespec start_time, stop_time; | |
struct timespec due_time; | |
double wait_usec; | |
int32 inst_delay; | |
double inst_per_sec; | |
UNIT *uptr; | |
if (sim_wallclock_entry) { /* something to insert in queue? */ | |
UNIT *cptr, *prvptr; | |
sim_debug (DBG_TIM, &sim_timer_dev, "_timer_thread() - timing %s for %d usec\n", | |
sim_uname(sim_wallclock_entry), sim_wallclock_entry->time); | |
uptr = sim_wallclock_entry; | |
sim_wallclock_entry = NULL; | |
prvptr = NULL; | |
for (cptr = sim_wallclock_queue; cptr != QUEUE_LIST_END; cptr = cptr->next) { | |
if (uptr->a_due_time < cptr->a_due_time) | |
break; | |
prvptr = cptr; | |
} | |
if (prvptr == NULL) { /* insert at head */ | |
cptr = uptr->next = sim_wallclock_queue; | |
sim_wallclock_queue = uptr; | |
} | |
else { | |
cptr = uptr->next = prvptr->next; /* insert at prvptr */ | |
prvptr->next = uptr; | |
} | |
} | |
/* determine wait time */ | |
if (sim_wallclock_queue != QUEUE_LIST_END) { | |
/* due time adjusted by 1/2 a minimal sleep interval */ | |
/* the goal being to let the last fractional part of the due time */ | |
/* be done by counting instructions */ | |
_double_to_timespec (&due_time, sim_wallclock_queue->a_due_time-(((double)sim_idle_rate_ms)*0.0005)); | |
} | |
else { | |
due_time.tv_sec = 0x7FFFFFFF; /* Sometime when 32 bit time_t wraps */ | |
due_time.tv_nsec = 0; | |
} | |
clock_gettime(CLOCK_REALTIME, &start_time); | |
wait_usec = floor(1000000.0*(_timespec_to_double (&due_time) - _timespec_to_double (&start_time))); | |
if (sim_wallclock_queue == QUEUE_LIST_END) | |
sim_debug (DBG_TIM, &sim_timer_dev, "_timer_thread() - waiting forever\n"); | |
else | |
sim_debug (DBG_TIM, &sim_timer_dev, "_timer_thread() - waiting for %.0f usecs until %.6f\n", wait_usec, sim_wallclock_queue->a_due_time); | |
if ((wait_usec <= 0.0) || | |
(0 != pthread_cond_timedwait (&sim_timer_wake, &sim_timer_lock, &due_time))) { | |
if (sim_wallclock_queue == QUEUE_LIST_END) /* queue empty? */ | |
continue; /* wait again */ | |
inst_per_sec = sim_timer_inst_per_sec (); | |
uptr = sim_wallclock_queue; | |
sim_wallclock_queue = uptr->next; | |
uptr->next = NULL; /* hygiene */ | |
clock_gettime(CLOCK_REALTIME, &stop_time); | |
if (1 != sim_timespec_compare (&due_time, &stop_time)) { | |
inst_delay = 0; | |
uptr->a_last_fired_time = _timespec_to_double(&stop_time); | |
} | |
else { | |
inst_delay = (int32)(inst_per_sec*(_timespec_to_double(&due_time)-_timespec_to_double(&stop_time))); | |
uptr->a_last_fired_time = uptr->a_due_time; | |
} | |
sim_debug (DBG_TIM, &sim_timer_dev, "_timer_thread() - slept %.0fms - activating(%s,%d)\n", | |
1000.0*(_timespec_to_double (&stop_time)-_timespec_to_double (&start_time)), sim_uname(uptr), inst_delay); | |
sim_activate (uptr, inst_delay); | |
if (sim_clock_unit == uptr) | |
while (sim_clock_cosched_queue != QUEUE_LIST_END) { | |
uptr = sim_clock_cosched_queue; | |
sim_clock_cosched_queue = uptr->next; | |
uptr->next = NULL; | |
sim_activate (uptr, inst_delay); | |
} | |
} | |
else /* Something wants to adjust the queue */ | |
if (sim_timer_event_canceled) | |
sim_timer_event_canceled = FALSE; /* reset flag and continue */ | |
else | |
if (sim_wallclock_entry == NULL) /* nothing to insert? */ | |
break; /* stop processing entries */ | |
} | |
pthread_mutex_unlock (&sim_timer_lock); | |
sim_debug (DBG_TIM, &sim_timer_dev, "_timer_thread() - exiting\n"); | |
return NULL; | |
} | |
#endif /* defined(SIM_ASYNCH_IO) && defined(SIM_ASYNCH_CLOCKS) */ | |
void sim_start_timer_services (void) | |
{ | |
#if defined(SIM_ASYNCH_IO) && defined(SIM_ASYNCH_CLOCKS) | |
pthread_mutex_lock (&sim_timer_lock); | |
if (sim_asynch_enabled && sim_asynch_timer) { | |
pthread_attr_t attr; | |
UNIT *cptr; | |
double delta_due_time = 0; | |
/* when restarting after being manually stopped the due times for all */ | |
/* timer events needs to slide so they fire in the future. (clock ticks */ | |
/* don't accumulate when the simulator is stopped) */ | |
for (cptr = sim_wallclock_queue; cptr != QUEUE_LIST_END; cptr = cptr->next) { | |
if (cptr == sim_wallclock_queue) { /* Handle first entry */ | |
struct timespec now; | |
double due_time; | |
clock_gettime(CLOCK_REALTIME, &now); | |
due_time = _timespec_to_double(&now) + ((double)(cptr->a_usec_delay)/1000000.0); | |
delta_due_time = due_time - cptr->a_due_time; | |
} | |
cptr->a_due_time += delta_due_time; | |
} | |
sim_debug (DBG_TRC, &sim_timer_dev, "sim_start_timer_services() - starting\n"); | |
pthread_cond_init (&sim_timer_startup_cond, NULL); | |
pthread_attr_init (&attr); | |
pthread_attr_setscope (&attr, PTHREAD_SCOPE_SYSTEM); | |
pthread_create (&sim_timer_thread, &attr, _timer_thread, NULL); | |
pthread_attr_destroy( &attr); | |
pthread_cond_wait (&sim_timer_startup_cond, &sim_timer_lock); /* Wait for thread to stabilize */ | |
pthread_cond_destroy (&sim_timer_startup_cond); | |
sim_timer_thread_running = TRUE; | |
} | |
pthread_mutex_unlock (&sim_timer_lock); | |
#endif | |
} | |
void sim_stop_timer_services (void) | |
{ | |
#if defined(SIM_ASYNCH_IO) && defined(SIM_ASYNCH_CLOCKS) | |
pthread_mutex_lock (&sim_timer_lock); | |
if (sim_timer_thread_running) { | |
sim_debug (DBG_TRC, &sim_timer_dev, "sim_stop_timer_services() - stopping\n"); | |
pthread_cond_signal (&sim_timer_wake); | |
pthread_mutex_unlock (&sim_timer_lock); | |
pthread_join (sim_timer_thread, NULL); | |
sim_timer_thread_running = FALSE; | |
} | |
else | |
pthread_mutex_unlock (&sim_timer_lock); | |
#endif | |
} | |
t_stat sim_timer_change_asynch (void) | |
{ | |
#if defined(SIM_ASYNCH_IO) && defined(SIM_ASYNCH_CLOCKS) | |
if (sim_asynch_enabled && sim_asynch_timer) | |
sim_start_timer_services (); | |
else { | |
UNIT *uptr; | |
int32 accum = 0; | |
sim_stop_timer_services (); | |
while (1) { | |
uptr = sim_wallclock_queue; | |
if (uptr == QUEUE_LIST_END) | |
break; | |
sim_wallclock_queue = uptr->next; | |
accum += uptr->time; | |
uptr->next = NULL; | |
uptr->a_due_time = 0; | |
uptr->a_usec_delay = 0; | |
sim_activate_after (uptr, accum); | |
} | |
} | |
#endif | |
return SCPE_OK; | |
} | |
/* Instruction Execution rate. */ | |
/* returns a double since it is mostly used in double expressions and | |
to avoid overflow if/when strange timing delays might produce unexpected results */ | |
double sim_timer_inst_per_sec (void) | |
{ | |
double inst_per_sec = SIM_INITIAL_IPS; | |
if (sim_calb_tmr == -1) | |
return inst_per_sec; | |
inst_per_sec = ((double)rtc_currd[sim_calb_tmr])*rtc_hz[sim_calb_tmr]; | |
if (0 == inst_per_sec) | |
inst_per_sec = SIM_INITIAL_IPS; | |
return inst_per_sec; | |
} | |
t_stat sim_timer_activate_after (UNIT *uptr, int32 usec_delay) | |
{ | |
int32 inst_delay; | |
double inst_per_sec; | |
AIO_VALIDATE; | |
if (sim_is_active (uptr)) /* already active? */ | |
return SCPE_OK; | |
inst_per_sec = sim_timer_inst_per_sec (); | |
inst_delay = (int32)((inst_per_sec*usec_delay)/1000000.0); | |
#if defined(SIM_ASYNCH_IO) && defined(SIM_ASYNCH_CLOCKS) | |
if ((sim_calb_tmr == -1) || /* if No timer initialized */ | |
(inst_delay < rtc_currd[sim_calb_tmr]) || /* or sooner than next clock tick? */ | |
(rtc_elapsed[sim_calb_tmr] < sim_idle_stable) || /* or not idle stable yet */ | |
(!(sim_asynch_enabled && sim_asynch_timer))) { /* or asynch disabled */ | |
sim_debug (DBG_TIM, &sim_timer_dev, "sim_timer_activate_after() - activating %s after %d instructions\n", | |
sim_uname(uptr), inst_delay); | |
return _sim_activate (uptr, inst_delay); /* queue it now */ | |
} | |
if (1) { | |
struct timespec now; | |
double d_now; | |
clock_gettime (CLOCK_REALTIME, &now); | |
d_now = _timespec_to_double (&now); | |
/* Determine if this is a clock tick like invocation | |
or an ocaisional measured device delay */ | |
if ((uptr->a_usec_delay == usec_delay) && | |
(uptr->a_due_time != 0.0) && | |
(1)) { | |
double d_delay = ((double)usec_delay)/1000000.0; | |
uptr->a_due_time += d_delay; | |
if (uptr->a_due_time < (d_now + d_delay*0.1)) { /* Accumulate lost time */ | |
uptr->a_skew += (d_now + d_delay*0.1) - uptr->a_due_time; | |
uptr->a_due_time = d_now + d_delay/10.0; | |
if (uptr->a_skew > 30.0) { /* Gap too big? */ | |
uptr->a_usec_delay = usec_delay; | |
uptr->a_skew = uptr->a_last_fired_time = 0.0; | |
uptr->a_due_time = d_now + (double)(usec_delay)/1000000.0; | |
} | |
if (uptr->a_skew > rtc_clock_skew_max[sim_calb_tmr]) | |
rtc_clock_skew_max[sim_calb_tmr] = uptr->a_skew; | |
} | |
else { | |
if (uptr->a_skew > 0.0) { /* Lost time to make up? */ | |
if (uptr->a_skew > d_delay*0.9) { | |
uptr->a_skew -= d_delay*0.9; | |
uptr->a_due_time -= d_delay*0.9; | |
} | |
else { | |
uptr->a_due_time -= uptr->a_skew; | |
uptr->a_skew = 0.0; | |
} | |
} | |
} | |
} | |
else { | |
uptr->a_usec_delay = usec_delay; | |
uptr->a_skew = uptr->a_last_fired_time = 0.0; | |
uptr->a_due_time = d_now + (double)(usec_delay)/1000000.0; | |
} | |
uptr->time = usec_delay; | |
sim_debug (DBG_TIM, &sim_timer_dev, "sim_timer_activate_after() - queue addition %s at %.6f\n", | |
sim_uname(uptr), uptr->a_due_time); | |
} | |
pthread_mutex_lock (&sim_timer_lock); | |
sim_wallclock_entry = uptr; | |
pthread_mutex_unlock (&sim_timer_lock); | |
pthread_cond_signal (&sim_timer_wake); /* wake the timer thread to deal with it */ | |
return SCPE_OK; | |
#else | |
return _sim_activate (uptr, inst_delay); /* queue it now */ | |
#endif | |
} | |
/* Clock coscheduling routines */ | |
t_stat sim_register_clock_unit (UNIT *uptr) | |
{ | |
sim_clock_unit = uptr; | |
return SCPE_OK; | |
} | |
t_stat sim_clock_coschedule (UNIT *uptr, int32 interval) | |
{ | |
if (NULL == sim_clock_unit) | |
return sim_activate (uptr, interval); | |
else | |
if (sim_asynch_enabled && sim_asynch_timer) { | |
if (!sim_is_active (uptr)) { /* already active? */ | |
#if defined(SIM_ASYNCH_IO) && defined(SIM_ASYNCH_CLOCKS) | |
sim_debug (DBG_TIM, &sim_timer_dev, "sim_clock_coschedule() - queueing %s for clock co-schedule\n", sim_uname (uptr)); | |
pthread_mutex_lock (&sim_timer_lock); | |
uptr->next = sim_clock_cosched_queue; | |
sim_clock_cosched_queue = uptr; | |
pthread_mutex_unlock (&sim_timer_lock); | |
#else | |
int32 t; | |
t = sim_activate_time (sim_clock_unit); | |
return sim_activate (uptr, t? t - 1: interval); | |
#endif | |
} | |
return SCPE_OK; | |
} | |
else { | |
int32 t; | |
t = sim_activate_time (sim_clock_unit); | |
return sim_activate (uptr, t? t - 1: interval); | |
} | |
} | |