/* $OpenBSD: clock.c,v 1.15 2001/11/06 19:53:16 miod Exp $ */ /* $NetBSD: clock.c,v 1.52 1997/05/24 20:16:05 pk Exp $ */ /* * Copyright (c) 1992, 1993 * The Regents of the University of California. All rights reserved. * Copyright (c) 1994 Gordon W. Ross * Copyright (c) 1993 Adam Glass * Copyright (c) 1996 Paul Kranenburg * Copyright (c) 1996 * The President and Fellows of Harvard College. All rights reserved. * * This software was developed by the Computer Systems Engineering group * at Lawrence Berkeley Laboratory under DARPA contract BG 91-66 and * contributed to Berkeley. * * All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Harvard University. * This product includes software developed by the University of * California, Lawrence Berkeley Laboratory. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * This product includes software developed by Paul Kranenburg. * This product includes software developed by Harvard University. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * @(#)clock.c 8.1 (Berkeley) 6/11/93 * */ /* * Clock driver. This is the id prom and eeprom driver as well * and includes the timer register functions too. */ #include #include #include #include #include #include #include #ifdef GPROF #include #endif #include #include #include #include #include #include #include #include #include /* * Statistics clock interval and variance, in usec. Variance must be a * power of two. Since this gives us an even number, not an odd number, * we discard one case and compensate. That is, a variance of 1024 would * give us offsets in [0..1023]. Instead, we take offsets in [1..1023]. * This is symmetric about the point 512, or statvar/2, and thus averages * to that value (assuming uniform random numbers). */ /* XXX fix comment to match value */ int statvar = 8192; int statmin; /* statclock interval - 1/2*variance */ int timerok; #include extern struct idprom idprom; #define intersil_command(run, interrupt) \ (run | interrupt | INTERSIL_CMD_FREQ_32K | INTERSIL_CMD_24HR_MODE | \ INTERSIL_CMD_NORMAL_MODE) #define intersil_disable(CLOCK) \ CLOCK->clk_cmd_reg = \ intersil_command(INTERSIL_CMD_RUN, INTERSIL_CMD_IDISABLE) #define intersil_enable(CLOCK) \ CLOCK->clk_cmd_reg = \ intersil_command(INTERSIL_CMD_RUN, INTERSIL_CMD_IENABLE) #define intersil_clear(CLOCK) CLOCK->clk_intr_reg #if defined(SUN4) /* * OCLOCK support: 4/100's and 4/200's have the old clock. */ static int oldclk = 0; struct intersil7170 *i7; long oclk_get_secs __P((void)); void oclk_get_dt __P((struct intersil_dt *)); void dt_to_gmt __P((struct intersil_dt *, long *)); void oclk_set_dt __P((struct intersil_dt *)); void oclk_set_secs __P((long)); void gmt_to_dt __P((long *, struct intersil_dt *)); #endif int oclockmatch __P((struct device *, void *, void *)); void oclockattach __P((struct device *, struct device *, void *)); struct cfattach oclock_ca = { sizeof(struct device), oclockmatch, oclockattach }; struct cfdriver oclock_cd = { NULL, "oclock", DV_DULL }; /* * Sun 4 machines use the old-style (a'la Sun 3) EEPROM. On the * 4/100's and 4/200's, this is at a separate obio space. On the * 4/300's and 4/400's, however, it is the cl_nvram[] chunk of the * Mostek chip. Therefore, eeprom_match will only return true on * the 100/200 models, and the eeprom will be attached separately. * On the 300/400 models, the eeprom will be dealt with when the clock is * attached. */ char *eeprom_va = NULL; #if defined(SUN4) static int eeprom_busy = 0; static int eeprom_wanted = 0; static int eeprom_nvram = 0; /* non-zero if eeprom is on Mostek */ int eeprom_take __P((void)); void eeprom_give __P((void)); int eeprom_update __P((char *, int, int)); #endif int eeprom_match __P((struct device *, void *, void *)); void eeprom_attach __P((struct device *, struct device *, void *)); struct cfattach eeprom_ca = { sizeof(struct device), eeprom_match, eeprom_attach }; struct cfdriver eeprom_cd = { NULL, "eeprom", DV_DULL }; int clockmatch __P((struct device *, void *, void *)); void clockattach __P((struct device *, struct device *, void *)); struct cfattach clock_ca = { sizeof(struct device), clockmatch, clockattach }; struct cfdriver clock_cd = { NULL, "clock", DV_DULL }; int timermatch __P((struct device *, void *, void *)); void timerattach __P((struct device *, struct device *, void *)); struct timer_4m *timerreg_4m; /* XXX - need more cleanup */ struct counter_4m *counterreg_4m; #define timerreg4 ((struct timerreg_4 *)TIMERREG_VA) struct cfattach timer_ca = { sizeof(struct device), timermatch, timerattach }; struct cfdriver timer_cd = { NULL, "timer", DV_DULL }; struct chiptime; void clk_wenable __P((int)); void myetheraddr __P((u_char *)); int chiptotime __P((int, int, int, int, int, int)); void timetochip __P((struct chiptime *)); int timerblurb = 10; /* Guess a value; used before clock is attached */ /* * old clock match routine */ int oclockmatch(parent, vcf, aux) struct device *parent; void *vcf, *aux; { struct confargs *ca = aux; /* Only these sun4s have oclock */ if (!CPU_ISSUN4 || (cpuinfo.cpu_type != CPUTYP_4_100 && cpuinfo.cpu_type != CPUTYP_4_200)) return (0); /* Check configuration name */ if (strcmp(oclock_cd.cd_name, ca->ca_ra.ra_name) != 0) return (0); /* Make sure there is something there */ if (probeget(ca->ca_ra.ra_vaddr, 1) == -1) return (0); return (1); } /* ARGSUSED */ void oclockattach(parent, self, aux) struct device *parent, *self; void *aux; { #if defined(SUN4) struct confargs *ca = aux; struct romaux *ra = &ca->ca_ra; struct idprom *idp; int h; oldclk = 1; /* we've got an oldie! */ i7 = (struct intersil7170 *) mapiodev(ra->ra_reg, 0, sizeof(*i7)); idp = &idprom; h = idp->id_machine << 24; h |= idp->id_hostid[0] << 16; h |= idp->id_hostid[1] << 8; h |= idp->id_hostid[2]; hostid = h; /* * calibrate delay() */ ienab_bic(IE_L14 | IE_L10); /* disable all clock intrs */ for (timerblurb = 1; ; timerblurb++) { volatile register char *ireg = &i7->clk_intr_reg; int ival; *ireg = INTERSIL_INTER_CSECONDS; /* 1/100 sec */ intersil_enable(i7); /* enable clock */ while ((*ireg & INTERSIL_INTER_PENDING) == 0) /* sync with interrupt */; while ((*ireg & INTERSIL_INTER_PENDING) == 0) /* XXX: do it again, seems to need it */; delay(10000); /* Probe 1/100 sec delay */ ival = *ireg; /* clear, save value */ intersil_disable(i7); /* disable clock */ if (ival & INTERSIL_INTER_PENDING) { printf(" delay constant %d%s\n", timerblurb, (timerblurb == 1) ? " [TOO SMALL?]" : ""); break; } if (timerblurb > 10) { printf("\noclock: calibration failing; clamped at %d\n", timerblurb); break; } } #endif /* SUN4 */ } /* * Sun 4/100, 4/200 EEPROM match routine. */ int eeprom_match(parent, vcf, aux) struct device *parent; void *vcf, *aux; { struct cfdata *cf = vcf; struct confargs *ca = aux; if (!CPU_ISSUN4) return (0); if (cf->cf_unit != 0) return (0); if (cpuinfo.cpu_type != CPUTYP_4_100 && cpuinfo.cpu_type != CPUTYP_4_200) return (0); if (strcmp(eeprom_cd.cd_name, ca->ca_ra.ra_name) != 0) return (0); /* * Make sure there's something there... * This is especially important if we want to * use the same kernel on a 4/100 as a 4/200. */ if (probeget(ca->ca_ra.ra_vaddr, 1) == -1) return (0); /* Passed all tests */ return (1); } void eeprom_attach(parent, self, aux) struct device *parent, *self; void *aux; { #if defined(SUN4) struct confargs *ca = aux; struct romaux *ra = &ca->ca_ra; printf("\n"); eeprom_va = (char *)mapiodev(ra->ra_reg, 0, EEPROM_SIZE); eeprom_nvram = 0; #endif /* SUN4 */ } /* * The OPENPROM calls the clock the "eeprom", so we have to have our * own special match function to call it the "clock". */ int clockmatch(parent, vcf, aux) struct device *parent; void *vcf, *aux; { struct confargs *ca = aux; if (CPU_ISSUN4) { /* Only these sun4s have "clock" (others have "oclock") */ if (cpuinfo.cpu_type != CPUTYP_4_300 && cpuinfo.cpu_type != CPUTYP_4_400) return (0); if (strcmp(clock_cd.cd_name, ca->ca_ra.ra_name) != 0) return (0); /* Make sure there is something there */ if (probeget(ca->ca_ra.ra_vaddr, 1) == -1) return (0); return (1); } return (strcmp("eeprom", ca->ca_ra.ra_name) == 0); } /* ARGSUSED */ void clockattach(parent, self, aux) struct device *parent, *self; void *aux; { int h; struct clockreg *cl; struct idprom *idp; struct confargs *ca = aux; struct romaux *ra = &ca->ca_ra; char *prop = NULL; if (CPU_ISSUN4) prop = "mk48t02"; if (CPU_ISSUN4COR4M) prop = getpropstring(ra->ra_node, "model"); #ifdef DIAGNOSTIC if (prop == NULL) panic("no prop"); #endif printf(": %s (eeprom)\n", prop); /* * We ignore any existing virtual address as we need to map * this read-only and make it read-write only temporarily, * whenever we read or write the clock chip. The clock also * contains the ID ``PROM'', and I have already had the pleasure * of reloading the cpu type, Ethernet address, etc, by hand from * the console FORTH interpreter. I intend not to enjoy it again. */ if (strcmp(prop, "mk48t08") == 0) { /* * the MK48T08 is 8K */ cl = (struct clockreg *)mapiodev(ra->ra_reg, 0, 8192); pmap_changeprot(pmap_kernel(), (vaddr_t)cl, VM_PROT_READ, 1); pmap_changeprot(pmap_kernel(), (vaddr_t)cl + 4096, VM_PROT_READ, 1); cl = (struct clockreg *)((int)cl + CLK_MK48T08_OFF); } else { /* * the MK48T02 is 2K */ cl = (struct clockreg *)mapiodev(ra->ra_reg, 0, sizeof *clockreg); pmap_changeprot(pmap_kernel(), (vaddr_t)cl, VM_PROT_READ, 1); } idp = &cl->cl_idprom; #if defined(SUN4) if (CPU_ISSUN4) { idp = &idprom; if (cpuinfo.cpu_type == CPUTYP_4_300 || cpuinfo.cpu_type == CPUTYP_4_400) { eeprom_va = (char *)cl->cl_nvram; eeprom_nvram = 1; } } #endif h = idp->id_machine << 24; h |= idp->id_hostid[0] << 16; h |= idp->id_hostid[1] << 8; h |= idp->id_hostid[2]; hostid = h; clockreg = cl; } /* * The OPENPROM calls the timer the "counter-timer". */ int timermatch(parent, vcf, aux) struct device *parent; void *vcf, *aux; { struct confargs *ca = aux; if (CPU_ISSUN4) { if (cpuinfo.cpu_type != CPUTYP_4_300 && cpuinfo.cpu_type != CPUTYP_4_400) return (0); if (strcmp("timer", ca->ca_ra.ra_name) != 0) return (0); /* Make sure there is something there */ if (probeget(ca->ca_ra.ra_vaddr, 4) == -1) return (0); return (1); } if (CPU_ISSUN4C) { return (strcmp("counter-timer", ca->ca_ra.ra_name) == 0); } if (CPU_ISSUN4M) { return (strcmp("counter", ca->ca_ra.ra_name) == 0); } return (0); } /* ARGSUSED */ void timerattach(parent, self, aux) struct device *parent, *self; void *aux; { struct confargs *ca = aux; struct romaux *ra = &ca->ca_ra; volatile int *cnt = NULL, *lim = NULL; /* XXX: must init to NULL to avoid stupid gcc -Wall warning */ if (CPU_ISSUN4M) { (void)mapdev(&ra->ra_reg[ra->ra_nreg-1], TIMERREG_VA, 0, sizeof(struct timer_4m)); (void)mapdev(&ra->ra_reg[0], COUNTERREG_VA, 0, sizeof(struct counter_4m)); timerreg_4m = (struct timer_4m *)TIMERREG_VA; counterreg_4m = (struct counter_4m *)COUNTERREG_VA; /* Put processor counter in "timer" mode */ timerreg_4m->t_cfg = 0; cnt = &counterreg_4m->t_counter; lim = &counterreg_4m->t_limit; } if (CPU_ISSUN4OR4C) { /* * This time, we ignore any existing virtual address because * we have a fixed virtual address for the timer, to make * microtime() faster (in SUN4/SUN4C kernel only). */ (void)mapdev(ra->ra_reg, TIMERREG_VA, 0, sizeof(struct timerreg_4)); cnt = &timerreg4->t_c14.t_counter; lim = &timerreg4->t_c14.t_limit; } timerok = 1; /* * Calibrate delay() by tweaking the magic constant * until a delay(100) actually reads (at least) 100 us on the clock. * Note: sun4m clocks tick with 500ns periods. */ for (timerblurb = 1; ; timerblurb++) { volatile int discard; int t0, t1; /* Reset counter register by writing some large limit value */ discard = *lim; *lim = tmr_ustolim(TMR_MASK-1); t0 = *cnt; delay(100); t1 = *cnt; if (t1 & TMR_LIMIT) panic("delay calibration"); t0 = (t0 >> TMR_SHIFT) & TMR_MASK; t1 = (t1 >> TMR_SHIFT) & TMR_MASK; if (t1 >= t0 + 100) break; } printf(" delay constant %d\n", timerblurb); /* should link interrupt handlers here, rather than compiled-in? */ } /* * Write en/dis-able clock registers. We coordinate so that several * writers can run simultaneously. */ void clk_wenable(onoff) int onoff; { int s; vm_prot_t prot;/* nonzero => change prot */ static int writers; s = splhigh(); if (onoff) prot = writers++ == 0 ? VM_PROT_READ|VM_PROT_WRITE : 0; else prot = --writers == 0 ? VM_PROT_READ : 0; splx(s); if (prot) pmap_changeprot(pmap_kernel(), (vaddr_t)clockreg & ~(NBPG-1), prot, 1); } /* * XXX this belongs elsewhere */ void myetheraddr(cp) u_char *cp; { struct clockreg *cl = clockreg; struct idprom *idp = &cl->cl_idprom; #if defined(SUN4) if (CPU_ISSUN4) idp = &idprom; #endif cp[0] = idp->id_ether[0]; cp[1] = idp->id_ether[1]; cp[2] = idp->id_ether[2]; cp[3] = idp->id_ether[3]; cp[4] = idp->id_ether[4]; cp[5] = idp->id_ether[5]; } /* * Set up the real-time and statistics clocks. Leave stathz 0 only if * no alternative timer is available. * * The frequencies of these clocks must be an even number of microseconds. */ void cpu_initclocks() { int statint, minint; #if defined(SUN4) if (oldclk) { int dummy; if (hz != 100) { printf("oclock0: cannot get %d Hz clock; using 100 Hz\n", hz); } profhz = hz = 100; tick = 1000000 / hz; i7->clk_intr_reg = INTERSIL_INTER_CSECONDS; /* 1/100 sec */ ienab_bic(IE_L14 | IE_L10); /* disable all clock intrs */ intersil_disable(i7); /* disable clock */ dummy = intersil_clear(i7); /* clear interrupts */ ienab_bis(IE_L10); /* enable l10 interrupt */ intersil_enable(i7); /* enable clock */ return; } #endif /* SUN4 */ if (1000000 % hz) { printf("clock0: cannot get %d Hz clock; using 100 Hz\n", hz); hz = 100; tick = 1000000 / hz; } if (stathz == 0) stathz = hz; if (1000000 % stathz) { printf("clock0: cannot get %d Hz statclock; using 100 Hz\n", stathz); stathz = 100; } profhz = stathz; /* always */ statint = 1000000 / stathz; minint = statint / 2 + 100; while (statvar > minint) statvar >>= 1; if (CPU_ISSUN4M) { timerreg_4m->t_limit = tmr_ustolim4m(tick); counterreg_4m->t_limit = tmr_ustolim4m(statint); } if (CPU_ISSUN4OR4C) { timerreg4->t_c10.t_limit = tmr_ustolim(tick); timerreg4->t_c14.t_limit = tmr_ustolim(statint); } statmin = statint - (statvar >> 1); #if defined(SUN4M) if (CPU_ISSUN4M) ienab_bic(SINTR_T); #endif if (CPU_ISSUN4OR4C) ienab_bis(IE_L14 | IE_L10); } /* * Dummy setstatclockrate(), since we know profhz==hz. */ /* ARGSUSED */ void setstatclockrate(newhz) int newhz; { /* nothing */ } /* * Level 10 (clock) interrupts. If we are using the FORTH PROM for * console input, we need to check for that here as well, and generate * a software interrupt to read it. */ int clockintr(cap) void *cap; { volatile int discard; int s; extern int rom_console_input; /* * Protect the clearing of the clock interrupt. If we don't * do this, and we're interrupted (by the zs, for example), * the clock stops! * XXX WHY DOES THIS HAPPEN? */ s = splhigh(); #if defined(SUN4) if (oldclk) { discard = intersil_clear(i7); ienab_bic(IE_L10); /* clear interrupt */ ienab_bis(IE_L10); /* enable interrupt */ goto forward; } #endif #if defined(SUN4M) /* read the limit register to clear the interrupt */ if (CPU_ISSUN4M) { discard = timerreg_4m->t_limit; } #endif #if defined(SUN4) || defined(SUN4C) if (CPU_ISSUN4OR4C) { discard = timerreg4->t_c10.t_limit; } #endif #if defined(SUN4) forward: #endif splx(s); hardclock((struct clockframe *)cap); if (rom_console_input && cnrom()) setsoftint(); return (1); } /* * Level 14 (stat clock) interrupt handler. */ int statintr(cap) void *cap; { volatile int discard; u_long newint, r, var; #if defined(SUN4) if (oldclk) { panic("oldclk statintr"); return (1); } #endif /* read the limit register to clear the interrupt */ if (CPU_ISSUN4M) { discard = counterreg_4m->t_limit; if (timerok == 0) { /* Stop the clock */ counterreg_4m->t_limit = 0; counterreg_4m->t_ss = 0; timerreg_4m->t_cfg = TMR_CFG_USER; return 1; } } if (CPU_ISSUN4OR4C) { discard = timerreg4->t_c14.t_limit; } statclock((struct clockframe *)cap); /* * Compute new randomized interval. The intervals are uniformly * distributed on [statint - statvar / 2, statint + statvar / 2], * and therefore have mean statint, giving a stathz frequency clock. */ var = statvar; do { r = random() & (var - 1); } while (r == 0); newint = statmin + r; if (CPU_ISSUN4M) { counterreg_4m->t_limit = tmr_ustolim4m(newint); } if (CPU_ISSUN4OR4C) { timerreg4->t_c14.t_limit = tmr_ustolim(newint); } return (1); } /* * BCD to decimal and decimal to BCD. */ #define FROMBCD(x) (((x) >> 4) * 10 + ((x) & 0xf)) #define TOBCD(x) (((x) / 10 * 16) + ((x) % 10)) #define SECDAY (24 * 60 * 60) #define SECYR (SECDAY * 365) /* * should use something like * #define LEAPYEAR(y) ((((y) % 4) == 0 && ((y) % 100) != 0) || ((y) % 400) == 0) * but it's unlikely that we'll still be around in 2100. */ #define LEAPYEAR(y) (((y) & 3) == 0) /* * This code is defunct after 2068. * Will Unix still be here then?? */ const short dayyr[12] = { 0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334 }; int chiptotime(sec, min, hour, day, mon, year) int sec, min, hour, day, mon, year; { int days, yr; sec = FROMBCD(sec); min = FROMBCD(min); hour = FROMBCD(hour); day = FROMBCD(day); mon = FROMBCD(mon); year = FROMBCD(year) + YEAR0; /* simple sanity checks */ if (year < 70 || mon < 1 || mon > 12 || day < 1 || day > 31) return (0); days = 0; for (yr = 70; yr < year; yr++) days += LEAPYEAR(yr) ? 366 : 365; days += dayyr[mon - 1] + day - 1; if (LEAPYEAR(yr) && mon > 2) days++; /* now have days since Jan 1, 1970; the rest is easy... */ return (days * SECDAY + hour * 3600 + min * 60 + sec); } struct chiptime { int sec; int min; int hour; int wday; int day; int mon; int year; }; void timetochip(c) struct chiptime *c; { int t, t2, t3, now = time.tv_sec; /* compute the year */ t2 = now / SECDAY; t3 = (t2 + 2) % 7; /* day of week */ c->wday = TOBCD(t3 + 1); t = 69; while (t2 >= 0) { /* whittle off years */ t3 = t2; t++; t2 -= LEAPYEAR(t) ? 366 : 365; } c->year = t; /* t3 = month + day; separate */ t = LEAPYEAR(t); for (t2 = 1; t2 < 12; t2++) if (t3 < dayyr[t2] + (t && t2 > 1)) break; /* t2 is month */ c->mon = t2; c->day = t3 - dayyr[t2 - 1] + 1; if (t && t2 > 2) c->day--; /* the rest is easy */ t = now % SECDAY; c->hour = t / 3600; t %= 3600; c->min = t / 60; c->sec = t % 60; c->sec = TOBCD(c->sec); c->min = TOBCD(c->min); c->hour = TOBCD(c->hour); c->day = TOBCD(c->day); c->mon = TOBCD(c->mon); c->year = TOBCD(c->year - YEAR0); } /* * Set up the system's time, given a `reasonable' time value. */ void inittodr(base) time_t base; { struct clockreg *cl = clockreg; int sec, min, hour, day, mon, year; int badbase = 0, waszero = base == 0; if (base < 5 * SECYR) { /* * If base is 0, assume filesystem time is just unknown * in stead of preposterous. Don't bark. */ if (base != 0) printf("WARNING: preposterous time in file system\n"); /* not going to use it anyway, if the chip is readable */ base = 21*SECYR + 186*SECDAY + SECDAY/2; badbase = 1; } #if defined(SUN4) if (oldclk) { time.tv_sec = oclk_get_secs(); goto forward; } #endif clk_wenable(1); cl->cl_csr |= CLK_READ; /* enable read (stop time) */ sec = cl->cl_sec; min = cl->cl_min; hour = cl->cl_hour; day = cl->cl_mday; mon = cl->cl_month; year = cl->cl_year; cl->cl_csr &= ~CLK_READ; /* time wears on */ clk_wenable(0); time.tv_sec = chiptotime(sec, min, hour, day, mon, year); #if defined(SUN4) forward: #endif if (time.tv_sec == 0) { printf("WARNING: bad date in battery clock"); /* * Believe the time in the file system for lack of * anything better, resetting the clock. */ time.tv_sec = base; if (!badbase) resettodr(); } else { int deltat = time.tv_sec - base; if (deltat < 0) deltat = -deltat; if (waszero || deltat < 2 * SECDAY) return; printf("WARNING: clock %s %d days", time.tv_sec < base ? "lost" : "gained", deltat / SECDAY); } printf(" -- CHECK AND RESET THE DATE!\n"); } /* * Reset the clock based on the current time. * Used when the current clock is preposterous, when the time is changed, * and when rebooting. Do nothing if the time is not yet known, e.g., * when crashing during autoconfig. */ void resettodr() { struct clockreg *cl; struct chiptime c; #if defined(SUN4) if (oldclk) { if (!time.tv_sec || i7 == NULL) return; oclk_set_secs(time.tv_sec); return; } #endif if (!time.tv_sec || (cl = clockreg) == NULL) return; timetochip(&c); clk_wenable(1); cl->cl_csr |= CLK_WRITE; /* enable write */ cl->cl_sec = c.sec; cl->cl_min = c.min; cl->cl_hour = c.hour; cl->cl_wday = c.wday; cl->cl_mday = c.day; cl->cl_month = c.mon; cl->cl_year = c.year; cl->cl_csr &= ~CLK_WRITE; /* load them up */ clk_wenable(0); } #if defined(SUN4) /* * Now routines to get and set clock as POSIX time. */ long oclk_get_secs() { struct intersil_dt dt; long gmt; oclk_get_dt(&dt); dt_to_gmt(&dt, &gmt); return (gmt); } void oclk_set_secs(secs) long secs; { struct intersil_dt dt; long gmt; gmt = secs; gmt_to_dt(&gmt, &dt); oclk_set_dt(&dt); } /* * Routine to copy state into and out of the clock. * The clock registers have to be read or written * in sequential order (or so it appears). -gwr */ void oclk_get_dt(dt) struct intersil_dt *dt; { int s; register volatile char *src, *dst; src = (char *) &i7->counters; s = splhigh(); i7->clk_cmd_reg = intersil_command(INTERSIL_CMD_STOP, INTERSIL_CMD_IENABLE); dst = (char *) dt; dt++; /* end marker */ do { *dst++ = *src++; } while (dst < (char*)dt); i7->clk_cmd_reg = intersil_command(INTERSIL_CMD_RUN, INTERSIL_CMD_IENABLE); splx(s); } void oclk_set_dt(dt) struct intersil_dt *dt; { int s; register volatile char *src, *dst; dst = (char *) &i7->counters; s = splhigh(); i7->clk_cmd_reg = intersil_command(INTERSIL_CMD_STOP, INTERSIL_CMD_IENABLE); src = (char *) dt; dt++; /* end marker */ do { *dst++ = *src++; } while (src < (char *)dt); i7->clk_cmd_reg = intersil_command(INTERSIL_CMD_RUN, INTERSIL_CMD_IENABLE); splx(s); } /* * Machine dependent base year: * Note: must be < 1970 */ #define CLOCK_BASE_YEAR 1968 /* Traditional UNIX base year */ #define POSIX_BASE_YEAR 1970 #define FEBRUARY 2 #define leapyear(year) ((year) % 4 == 0) #define days_in_year(a) (leapyear(a) ? 366 : 365) #define days_in_month(a) (month_days[(a) - 1]) static int month_days[12] = { 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 }; void gmt_to_dt(tp, dt) long *tp; struct intersil_dt *dt; { int i; long days, secs; days = *tp / SECDAY; secs = *tp % SECDAY; /* Hours, minutes, seconds are easy */ dt->dt_hour = secs / 3600; secs = secs % 3600; dt->dt_min = secs / 60; secs = secs % 60; dt->dt_sec = secs; /* Day of week (Note: 1/1/1970 was a Thursday) */ dt->dt_dow = (days + 4) % 7; /* Number of years in days */ i = POSIX_BASE_YEAR; while (days >= days_in_year(i)) { days -= days_in_year(i); i++; } dt->dt_year = i - CLOCK_BASE_YEAR; /* Number of months in days left */ if (leapyear(i)) days_in_month(FEBRUARY) = 29; for (i = 1; days >= days_in_month(i); i++) days -= days_in_month(i); days_in_month(FEBRUARY) = 28; dt->dt_month = i; /* Days are what is left over (+1) from all that. */ dt->dt_day = days + 1; } void dt_to_gmt(dt, tp) struct intersil_dt *dt; long *tp; { int i; long tmp; int year; /* * Hours are different for some reason. Makes no sense really. */ tmp = 0; if (dt->dt_hour >= 24) goto out; if (dt->dt_day > 31) goto out; if (dt->dt_month > 12) goto out; year = dt->dt_year + CLOCK_BASE_YEAR; /* * Compute days since start of time * First from years, then from months. */ for (i = POSIX_BASE_YEAR; i < year; i++) tmp += days_in_year(i); if (leapyear(year) && dt->dt_month > FEBRUARY) tmp++; /* Months */ for (i = 1; i < dt->dt_month; i++) tmp += days_in_month(i); tmp += (dt->dt_day - 1); /* Now do hours */ tmp = tmp * 24 + dt->dt_hour; /* Now do minutes */ tmp = tmp * 60 + dt->dt_min; /* Now do seconds */ tmp = tmp * 60 + dt->dt_sec; out: *tp = tmp; } #endif /* SUN4 */ #if defined(SUN4) /* * Return the best possible estimate of the time in the timeval * to which tvp points. We do this by returning the current time * plus the amount of time since the last clock interrupt. * * Check that this time is no less than any previously-reported time, * which could happen around the time of a clock adjustment. Just for * fun, we guarantee that the time will be greater than the value * obtained by a previous call. */ void microtime(tvp) struct timeval *tvp; { int s; static struct timeval lasttime; static struct timeval oneusec = {0, 1}; if (!oldclk) { lo_microtime(tvp); return; } s = splhigh(); *tvp = time; splx(s); if (timercmp(tvp, &lasttime, <=)) timeradd(&lasttime, &oneusec, tvp); lasttime = *tvp; } #endif /* SUN4 */ /* * XXX: these may actually belong somewhere else, but since the * EEPROM is so closely tied to the clock on some models, perhaps * it needs to stay here... */ int eeprom_uio(uio) struct uio *uio; { #if defined(SUN4) int error; int off; /* NOT off_t */ u_int cnt, bcnt; caddr_t buf = NULL; if (!CPU_ISSUN4) return (ENODEV); off = uio->uio_offset; if (off > EEPROM_SIZE) return (EFAULT); cnt = uio->uio_resid; if (cnt > (EEPROM_SIZE - off)) cnt = (EEPROM_SIZE - off); if ((error = eeprom_take()) != 0) return (error); if (eeprom_va == NULL) { error = ENXIO; goto out; } /* * The EEPROM can only be accessed one byte at a time, yet * uiomove() will attempt long-word access. To circumvent * this, we byte-by-byte copy the eeprom contents into a * temporary buffer. */ buf = malloc(EEPROM_SIZE, M_DEVBUF, M_WAITOK); if (uio->uio_rw == UIO_READ) for (bcnt = 0; bcnt < EEPROM_SIZE; ++bcnt) *(char *)(buf + bcnt) = *(char *)(eeprom_va + bcnt); if ((error = uiomove(buf + off, (int)cnt, uio)) != 0) goto out; if (uio->uio_rw != UIO_READ) error = eeprom_update(buf, off, cnt); out: if (buf) free(buf, M_DEVBUF); eeprom_give(); return (error); #else /* ! SUN4 */ return (ENODEV); #endif /* SUN4 */ } #if defined(SUN4) /* * Update the EEPROM from the passed buf. */ int eeprom_update(buf, off, cnt) char *buf; int off, cnt; { int error = 0; volatile char *ep; char *bp; if (eeprom_va == NULL) return (ENXIO); ep = eeprom_va + off; bp = buf + off; if (eeprom_nvram) clk_wenable(1); while (cnt > 0) { /* * DO NOT WRITE IT UNLESS WE HAVE TO because the * EEPROM has a limited number of write cycles. * After some number of writes it just fails! */ if (*ep != *bp) { *ep = *bp; /* * We have written the EEPROM, so now we must * sleep for at least 10 milliseconds while * holding the lock to prevent all access to * the EEPROM while it recovers. */ (void)tsleep(eeprom_va, PZERO - 1, "eeprom", hz/50); } /* Make sure the write worked. */ if (*ep != *bp) { error = EIO; goto out; } ++ep; ++bp; --cnt; } out: if (eeprom_nvram) clk_wenable(0); return (error); } /* Take a lock on the eeprom. */ int eeprom_take() { int error = 0; while (eeprom_busy) { eeprom_wanted = 1; error = tsleep(&eeprom_busy, PZERO | PCATCH, "eeprom", 0); eeprom_wanted = 0; if (error) /* interrupted */ goto out; } eeprom_busy = 1; out: return (error); } /* Give a lock on the eeprom away. */ void eeprom_give() { eeprom_busy = 0; if (eeprom_wanted) { eeprom_wanted = 0; wakeup(&eeprom_busy); } } #endif /* SUN4 */