/* $NetBSD: clock.c,v 1.17 2000/01/19 02:52:21 msaitoh Exp $ */ /* * Copyright (c) 1994 Gordon W. Ross * Copyright (c) 1993 Adam Glass * Copyright (c) 1988 University of Utah. * Copyright (c) 1982, 1990, 1993 * The Regents of the University of California. All rights reserved. * * This code is derived from software contributed to Berkeley by * the Systems Programming Group of the University of Utah Computer * Science Department. * * 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. * 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. * * from: Utah Hdr: clock.c 1.18 91/01/21$ * from: @(#)clock.c 8.2 (Berkeley) 1/12/94 */ /* * Machine-dependent clock routines. Sun3X machines may have * either the Mostek 48T02 or the Intersil 7170 clock. * * It is tricky to determine which you have, because there is * always something responding at the address where the Mostek * clock might be found: either a Mostek or plain-old EEPROM. * Therefore, we cheat. If we find an Intersil clock, assume * that what responds at the end of the EEPROM space is just * plain-old EEPROM (not a Mostek clock). Worse, there are * H/W problems with probing for an Intersil on the 3/80, so * on that machine we "know" there is a Mostek clock. * * Note that the probing algorithm described above requires * that we probe the intersil before we probe the mostek! */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define SUN3_470 Yes #define CLOCK_PRI 5 #define IREG_CLK_BITS (IREG_CLOCK_ENAB_7 | IREG_CLOCK_ENAB_5) /* * Only one of these two variables should be non-zero after * autoconfiguration determines which clock we have. */ static volatile void *intersil_va; static volatile void *mostek_clk_va; void _isr_clock __P((void)); /* in locore.s */ void clock_intr __P((struct clockframe)); static int clock_match __P((struct device *, struct cfdata *, void *args)); static void clock_attach __P((struct device *, struct device *, void *)); struct cfattach clock_ca = { sizeof(struct device), clock_match, clock_attach }; #ifdef SUN3_470 #define intersil_clock ((volatile struct intersil7170 *) intersil_va) #define intersil_command(run, interrupt) \ (run | interrupt | INTERSIL_CMD_FREQ_32K | INTERSIL_CMD_24HR_MODE | \ INTERSIL_CMD_NORMAL_MODE) #define intersil_clear() (void)intersil_clock->clk_intr_reg static int oclock_match __P((struct device *, struct cfdata *, void *args)); static void oclock_attach __P((struct device *, struct device *, void *)); struct cfattach oclock_ca = { sizeof(struct device), oclock_match, oclock_attach }; /* * Is there an intersil clock? */ static int oclock_match(parent, cf, args) struct device *parent; struct cfdata *cf; void *args; { struct confargs *ca = args; /* This driver only supports one unit. */ if (cf->cf_unit != 0) return (0); /* * The 3/80 can not probe the Intersil absent, * but it never has one, so "just say no." */ if (cpu_machine_id == SUN3X_MACH_80) return (0); /* OK, really probe for the Intersil. */ if (bus_peek(ca->ca_bustype, ca->ca_paddr, 1) == -1) return (0); /* Default interrupt priority. */ if (ca->ca_intpri == -1) ca->ca_intpri = CLOCK_PRI; return (1); } /* * Attach the intersil clock. */ static void oclock_attach(parent, self, args) struct device *parent; struct device *self; void *args; { struct confargs *ca = args; caddr_t va; printf("\n"); /* Get a mapping for it. */ va = bus_mapin(ca->ca_bustype, ca->ca_paddr, sizeof(struct intersil7170)); if (!va) panic("oclock_attach"); intersil_va = va; #ifdef DIAGNOSTIC /* Verify correct probe order... */ if (mostek_clk_va) { mostek_clk_va = 0; printf("%s: warning - mostek found also!\n", self->dv_xname); } #endif /* * Set the clock to the correct interrupt rate, but * do not enable the interrupt until cpu_initclocks. * XXX: Actually, the interrupt_reg should be zero * at this point, so the clock interrupts should not * affect us, but we need to set the rate... */ intersil_clock->clk_cmd_reg = intersil_command(INTERSIL_CMD_RUN, INTERSIL_CMD_IDISABLE); intersil_clear(); /* Set the clock to 100 Hz, but do not enable it yet. */ intersil_clock->clk_intr_reg = INTERSIL_INTER_CSECONDS; /* * Can not hook up the ISR until cpu_initclocks() * because hardclock is not ready until then. * For now, the handler is _isr_autovec(), which * will complain if it gets clock interrupts. */ } #endif /* SUN3_470 */ /* * Is there a Mostek clock? Hard to tell... * (See comment at top of this file.) */ static int clock_match(parent, cf, args) struct device *parent; struct cfdata *cf; void *args; { struct confargs *ca = args; /* This driver only supports one unit. */ if (cf->cf_unit != 0) return (0); /* If intersil was found, use that. */ if (intersil_va) return (0); /* Else assume a Mostek is there... */ /* Default interrupt priority. */ if (ca->ca_intpri == -1) ca->ca_intpri = CLOCK_PRI; return (1); } /* * Attach the mostek clock. */ static void clock_attach(parent, self, args) struct device *parent; struct device *self; void *args; { struct confargs *ca = args; caddr_t va; printf("\n"); /* Get a mapping for it. */ va = bus_mapin(ca->ca_bustype, ca->ca_paddr, sizeof(struct mostek_clkreg)); if (!va) panic("clock_attach"); mostek_clk_va = va; /* * Can not hook up the ISR until cpu_initclocks() * because hardclock is not ready until then. * For now, the handler is _isr_autovec(), which * will complain if it gets clock interrupts. */ } /* * Set and/or clear the desired clock bits in the interrupt * register. We have to be extremely careful that we do it * in such a manner that we don't get ourselves lost. * XXX: Watch out! It's really easy to break this! */ void set_clk_mode(on, off, enable_clk) u_char on, off; int enable_clk; { register u_char interreg; /* * If we have not yet mapped the register, * then we do not want to do any of this... */ if (!interrupt_reg) return; #ifdef DIAGNOSTIC /* Assertion: were are at splhigh! */ if ((getsr() & PSL_IPL) < PSL_IPL7) panic("set_clk_mode: bad ipl"); #endif /* * make sure that we are only playing w/ * clock interrupt register bits */ on &= IREG_CLK_BITS; off &= IREG_CLK_BITS; /* First, turn off the "master" enable bit. */ single_inst_bclr_b(*interrupt_reg, IREG_ALL_ENAB); /* * Save the current interrupt register clock bits, * and turn off/on the requested bits in the copy. */ interreg = *interrupt_reg & IREG_CLK_BITS; interreg &= ~off; interreg |= on; /* Clear the CLK5 and CLK7 bits to clear the flip-flops. */ single_inst_bclr_b(*interrupt_reg, IREG_CLK_BITS); #ifdef SUN3_470 if (intersil_va) { /* * Then disable clock interrupts, and read the clock's * interrupt register to clear any pending signals there. */ intersil_clock->clk_cmd_reg = intersil_command(INTERSIL_CMD_RUN, INTERSIL_CMD_IDISABLE); intersil_clear(); } #endif /* SUN3_470 */ /* Set the requested bits in the interrupt register. */ single_inst_bset_b(*interrupt_reg, interreg); #ifdef SUN3_470 /* Turn the clock back on (maybe) */ if (intersil_va && enable_clk) intersil_clock->clk_cmd_reg = intersil_command(INTERSIL_CMD_RUN, INTERSIL_CMD_IENABLE); #endif /* SUN3_470 */ /* Finally, turn the "master" enable back on. */ single_inst_bset_b(*interrupt_reg, IREG_ALL_ENAB); } /* * Set up the real-time clock (enable clock interrupts). * Leave stathz 0 since there is no secondary clock available. * Note that clock interrupts MUST STAY DISABLED until here. */ void cpu_initclocks(void) { int s; s = splhigh(); /* Install isr (in locore.s) that calls clock_intr(). */ isr_add_custom(CLOCK_PRI, (void*)_isr_clock); /* Now enable the clock at level 5 in the interrupt reg. */ set_clk_mode(IREG_CLOCK_ENAB_5, 0, 1); splx(s); } /* * This doesn't need to do anything, as we have only one timer and * profhz==stathz==hz. */ void setstatclockrate(newhz) int newhz; { /* nothing */ } /* * Clock interrupt handler (for both Intersil and Mostek). * XXX - Is it worth the trouble to save a few cycles here * by making two separate interrupt handlers? * * This is is called by the "custom" interrupt handler. * Note that we can get ZS interrupts while this runs, * and zshard may touch the interrupt_reg, so we must * be careful to use the single_inst_* macros to modify * the interrupt register atomically. */ void clock_intr(cf) struct clockframe cf; { extern char _Idle[]; /* locore.s */ #ifdef SUN3_470 if (intersil_va) { /* Read the clock interrupt register. */ intersil_clear(); } #endif /* SUN3_470 */ /* Pulse the clock intr. enable low. */ single_inst_bclr_b(*interrupt_reg, IREG_CLOCK_ENAB_5); single_inst_bset_b(*interrupt_reg, IREG_CLOCK_ENAB_5); #ifdef SUN3_470 if (intersil_va) { /* Read the clock intr. reg. AGAIN! */ intersil_clear(); } #endif /* SUN3_470 */ /* Entertainment! */ if (cf.cf_pc == (long)_Idle) leds_intr(); /* Call common clock interrupt handler. */ hardclock(&cf); } /* * 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) register struct timeval *tvp; { int s = splhigh(); static struct timeval lasttime; *tvp = time; tvp->tv_usec++; /* XXX */ while (tvp->tv_usec >= 1000000) { tvp->tv_sec++; tvp->tv_usec -= 1000000; } if (tvp->tv_sec == lasttime.tv_sec && tvp->tv_usec <= lasttime.tv_usec && (tvp->tv_usec = lasttime.tv_usec + 1) >= 1000000) { tvp->tv_sec++; tvp->tv_usec -= 1000000; } lasttime = *tvp; splx(s); } /* * Machine-dependent clock routines. * * Inittodr initializes the time of day hardware which provides * date functions. * * Resettodr restores the time of day hardware after a time change. */ static long clk_get_secs __P((void)); static void clk_set_secs __P((long)); /* * Initialize the time of day register, based on the time base * which is, e.g. from a filesystem. */ void inittodr(fs_time) time_t fs_time; { long diff, clk_time; long long_ago = (5 * SECYR); int clk_bad = 0; /* * Sanity check time from file system. * If it is zero,assume filesystem time is just unknown * instead of preposterous. Don't bark. */ if (fs_time < long_ago) { /* * If fs_time is zero, assume filesystem time is just * unknown instead of preposterous. Don't bark. */ if (fs_time != 0) printf("WARNING: preposterous time in file system\n"); /* 1991/07/01 12:00:00 */ fs_time = 21*SECYR + 186*SECDAY + SECDAY/2; } clk_time = clk_get_secs(); /* Sanity check time from clock. */ if (clk_time < long_ago) { printf("WARNING: bad date in battery clock"); clk_bad = 1; clk_time = fs_time; } else { /* Does the clock time jive with the file system? */ diff = clk_time - fs_time; if (diff < 0) diff = -diff; if (diff >= (SECDAY*2)) { printf("WARNING: clock %s %d days", (clk_time < fs_time) ? "lost" : "gained", (int) (diff / SECDAY)); clk_bad = 1; } } if (clk_bad) printf(" -- CHECK AND RESET THE DATE!\n"); time.tv_sec = clk_time; } /* * Resettodr restores the time of day hardware after a time change. */ void resettodr() { clk_set_secs(time.tv_sec); } /* * Now routines to get and set clock as POSIX time. * Our clock keeps "years since 1/1/1968". */ #define CLOCK_BASE_YEAR 1968 #ifdef SUN3_470 static void intersil_get_dt __P((struct clock_ymdhms *)); static void intersil_set_dt __P((struct clock_ymdhms *)); #endif /* SUN3_470 */ static void mostek_get_dt __P((struct clock_ymdhms *)); static void mostek_set_dt __P((struct clock_ymdhms *)); static long clk_get_secs() { struct clock_ymdhms dt; long secs; bzero(&dt, sizeof(dt)); #ifdef SUN3_470 if (intersil_va) intersil_get_dt(&dt); #endif /* SUN3_470 */ if (mostek_clk_va) { /* Read the Mostek. */ mostek_get_dt(&dt); /* Convert BCD values to binary. */ dt.dt_sec = FROMBCD(dt.dt_sec); dt.dt_min = FROMBCD(dt.dt_min); dt.dt_hour = FROMBCD(dt.dt_hour); dt.dt_day = FROMBCD(dt.dt_day); dt.dt_mon = FROMBCD(dt.dt_mon); dt.dt_year = FROMBCD(dt.dt_year); } if ((dt.dt_hour > 24) || (dt.dt_day > 31) || (dt.dt_mon > 12)) return (0); dt.dt_year += CLOCK_BASE_YEAR; secs = clock_ymdhms_to_secs(&dt); return (secs); } static void clk_set_secs(secs) long secs; { struct clock_ymdhms dt; clock_secs_to_ymdhms(secs, &dt); dt.dt_year -= CLOCK_BASE_YEAR; #ifdef SUN3_470 if (intersil_va) intersil_set_dt(&dt); #endif /* SUN3_470 */ if (mostek_clk_va) { /* Convert binary values to BCD. */ dt.dt_sec = TOBCD(dt.dt_sec); dt.dt_min = TOBCD(dt.dt_min); dt.dt_hour = TOBCD(dt.dt_hour); dt.dt_day = TOBCD(dt.dt_day); dt.dt_mon = TOBCD(dt.dt_mon); dt.dt_year = TOBCD(dt.dt_year); /* Write the Mostek. */ mostek_set_dt(&dt); } } #ifdef SUN3_470 /* * Routines to copy state into and out of the clock. * The intersil registers have to be read or written * in sequential order (or so it appears). -gwr */ static void intersil_get_dt(struct clock_ymdhms *dt) { volatile struct intersil_dt *isdt; int s; isdt = &intersil_clock->counters; s = splhigh(); /* Enable read (stop time) */ intersil_clock->clk_cmd_reg = intersil_command(INTERSIL_CMD_STOP, INTERSIL_CMD_IENABLE); /* Copy the info. Careful about the order! */ dt->dt_sec = isdt->dt_csec; /* throw-away */ dt->dt_hour = isdt->dt_hour; dt->dt_min = isdt->dt_min; dt->dt_sec = isdt->dt_sec; dt->dt_mon = isdt->dt_month; dt->dt_day = isdt->dt_day; dt->dt_year = isdt->dt_year; dt->dt_wday = isdt->dt_dow; /* Done reading (time wears on) */ intersil_clock->clk_cmd_reg = intersil_command(INTERSIL_CMD_RUN, INTERSIL_CMD_IENABLE); splx(s); } static void intersil_set_dt(struct clock_ymdhms *dt) { volatile struct intersil_dt *isdt; int s; isdt = &intersil_clock->counters; s = splhigh(); /* Enable write (stop time) */ intersil_clock->clk_cmd_reg = intersil_command(INTERSIL_CMD_STOP, INTERSIL_CMD_IENABLE); /* Copy the info. Careful about the order! */ isdt->dt_csec = 0; isdt->dt_hour = dt->dt_hour; isdt->dt_min = dt->dt_min; isdt->dt_sec = dt->dt_sec; isdt->dt_month= dt->dt_mon; isdt->dt_day = dt->dt_day; isdt->dt_year = dt->dt_year; isdt->dt_dow = dt->dt_wday; /* Done writing (time wears on) */ intersil_clock->clk_cmd_reg = intersil_command(INTERSIL_CMD_RUN, INTERSIL_CMD_IENABLE); splx(s); } #endif /* SUN3_470 */ /* * Routines to copy state into and out of the clock. * The clock CSR has to be set for read or write. */ static void mostek_get_dt(struct clock_ymdhms *dt) { volatile struct mostek_clkreg *cl = mostek_clk_va; int s; s = splhigh(); /* enable read (stop time) */ cl->cl_csr |= CLK_READ; /* Copy the info */ dt->dt_sec = cl->cl_sec; dt->dt_min = cl->cl_min; dt->dt_hour = cl->cl_hour; dt->dt_wday = cl->cl_wday; dt->dt_day = cl->cl_mday; dt->dt_mon = cl->cl_month; dt->dt_year = cl->cl_year; /* Done reading (time wears on) */ cl->cl_csr &= ~CLK_READ; splx(s); } static void mostek_set_dt(struct clock_ymdhms *dt) { volatile struct mostek_clkreg *cl = mostek_clk_va; int s; s = splhigh(); /* enable write */ cl->cl_csr |= CLK_WRITE; /* Copy the info */ cl->cl_sec = dt->dt_sec; cl->cl_min = dt->dt_min; cl->cl_hour = dt->dt_hour; cl->cl_wday = dt->dt_wday; cl->cl_mday = dt->dt_day; cl->cl_month = dt->dt_mon; cl->cl_year = dt->dt_year; /* load them up */ cl->cl_csr &= ~CLK_WRITE; splx(s); }