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/*
 *  linux/arch/mips/kernel/time.c
 *
 *  Copyright (C) 1991, 1992, 1995  Linus Torvalds
 *
 * This file contains the time handling details for PC-style clocks as
 * found in some MIPS systems.
 *
 * $Id: time.c,v 1.9 1998/06/10 07:21:13 davem Exp $
 */
#include <linux/errno.h>
#include <linux/init.h>
#include <linux/sched.h>
#include <linux/kernel.h>
#include <linux/param.h>
#include <linux/string.h>
#include <linux/mm.h>
#include <linux/interrupt.h>

#include <asm/bootinfo.h>
#include <asm/mipsregs.h>
#include <asm/io.h>
#include <asm/irq.h>

#include <linux/mc146818rtc.h>
#include <linux/timex.h>

extern volatile unsigned long lost_ticks;

/*
 * Change this if you have some constant time drift
 */
/* This is the value for the PC-style PICs. */
/* #define USECS_PER_JIFFY (1000020/HZ) */

/* This is for machines which generate the exact clock. */
#define USECS_PER_JIFFY (1000000/HZ)

/* Cycle counter value at the previous timer interrupt.. */

static unsigned int timerhi = 0, timerlo = 0;

/*
 * On MIPS only R4000 and better have a cycle counter.
 *
 * FIXME: Does playing with the RP bit in c0_status interfere with this code?
 */
static unsigned long do_fast_gettimeoffset(void)
{
	u32 count;
	unsigned long res, tmp;

	/* Last jiffy when do_fast_gettimeoffset() was called. */
	static unsigned long last_jiffies=0;
	unsigned long quotient;

	/*
	 * Cached "1/(clocks per usec)*2^32" value.
	 * It has to be recalculated once each jiffy.
	 */
	static unsigned long cached_quotient=0;

	tmp = jiffies;

	quotient = cached_quotient;

	if (last_jiffies != tmp) {
		last_jiffies = tmp;
		__asm__(".set\tnoreorder\n\t"
			".set\tnoat\n\t"
			".set\tmips3\n\t"
			"lwu\t%0,%2\n\t"
			"dsll32\t$1,%1,0\n\t"
			"or\t$1,$1,%0\n\t"
			"ddivu\t$0,$1,%3\n\t"
			"mflo\t$1\n\t"
			"dsll32\t%0,%4,0\n\t"
			"nop\n\t"
			"ddivu\t$0,%0,$1\n\t"
			"mflo\t%0\n\t"
			".set\tmips0\n\t"
			".set\tat\n\t"
			".set\treorder"
			:"=&r" (quotient)
			:"r" (timerhi),
			 "m" (timerlo),
			 "r" (tmp),
			 "r" (USECS_PER_JIFFY)
			:"$1");
		cached_quotient = quotient;
	}

	/* Get last timer tick in absolute kernel time */
	count = read_32bit_cp0_register(CP0_COUNT);

	/* .. relative to previous jiffy (32 bits is enough) */
	count -= timerlo;
//printk("count: %08lx, %08lx:%08lx\n", count, timerhi, timerlo);

	__asm__("multu\t%1,%2\n\t"
		"mfhi\t%0"
		:"=r" (res)
		:"r" (count),
		 "r" (quotient));

	/*
 	 * Due to possible jiffies inconsistencies, we need to check 
	 * the result so that we'll get a timer that is monotonic.
	 */
	if (res >= USECS_PER_JIFFY)
		res = USECS_PER_JIFFY-1;

	return res;
}

/* This function must be called with interrupts disabled 
 * It was inspired by Steve McCanne's microtime-i386 for BSD.  -- jrs
 * 
 * However, the pc-audio speaker driver changes the divisor so that
 * it gets interrupted rather more often - it loads 64 into the
 * counter rather than 11932! This has an adverse impact on
 * do_gettimeoffset() -- it stops working! What is also not
 * good is that the interval that our timer function gets called
 * is no longer 10.0002 ms, but 9.9767 ms. To get around this
 * would require using a different timing source. Maybe someone
 * could use the RTC - I know that this can interrupt at frequencies
 * ranging from 8192Hz to 2Hz. If I had the energy, I'd somehow fix
 * it so that at startup, the timer code in sched.c would select
 * using either the RTC or the 8253 timer. The decision would be
 * based on whether there was any other device around that needed
 * to trample on the 8253. I'd set up the RTC to interrupt at 1024 Hz,
 * and then do some jiggery to have a version of do_timer that 
 * advanced the clock by 1/1024 s. Every time that reached over 1/100
 * of a second, then do all the old code. If the time was kept correct
 * then do_gettimeoffset could just return 0 - there is no low order
 * divider that can be accessed.
 *
 * Ideally, you would be able to use the RTC for the speaker driver,
 * but it appears that the speaker driver really needs interrupt more
 * often than every 120 us or so.
 *
 * Anyway, this needs more thought....		pjsg (1993-08-28)
 * 
 * If you are really that interested, you should be reading
 * comp.protocols.time.ntp!
 */

#define TICK_SIZE tick

static unsigned long do_slow_gettimeoffset(void)
{
	int count;

	static int count_p = LATCH;    /* for the first call after boot */
	static unsigned long jiffies_p = 0;

	/*
	 * cache volatile jiffies temporarily; we have IRQs turned off. 
	 */
	unsigned long jiffies_t;

	/* timer count may underflow right here */
	outb_p(0x00, 0x43);	/* latch the count ASAP */

	count = inb_p(0x40);	/* read the latched count */

	/*
	 * We do this guaranteed double memory access instead of a _p 
	 * postfix in the previous port access. Wheee, hackady hack
	 */
	jiffies_t = jiffies;

	count |= inb_p(0x40) << 8;

	/*
	 * avoiding timer inconsistencies (they are rare, but they happen)...
	 * there are two kinds of problems that must be avoided here:
	 *  1. the timer counter underflows
	 *  2. hardware problem with the timer, not giving us continuous time,
	 *     the counter does small "jumps" upwards on some Pentium systems,
	 *     (see c't 95/10 page 335 for Neptun bug.)
	 */

	if( jiffies_t == jiffies_p ) {
		if( count > count_p ) {
			/* the nutcase */

			outb_p(0x0A, 0x20);

			/* assumption about timer being IRQ1 */
			if (inb(0x20) & 0x01) {
				/*
				 * We cannot detect lost timer interrupts ... 
				 * well, that's why we call them lost, don't we? :)
				 * [hmm, on the Pentium and Alpha we can ... sort of]
				 */
				count -= LATCH;
			} else {
				printk("do_slow_gettimeoffset(): hardware timer problem?\n");
			}
		}
	} else
		jiffies_p = jiffies_t;

	count_p = count;

	count = ((LATCH-1) - count) * TICK_SIZE;
	count = (count + LATCH/2) / LATCH;

	return count;
}

static unsigned long (*do_gettimeoffset)(void) = do_slow_gettimeoffset;

/*
 * This version of gettimeofday has near microsecond resolution.
 */
void do_gettimeofday(struct timeval *tv)
{
	unsigned long flags;

	save_and_cli(flags);
	*tv = xtime;
	tv->tv_usec += do_gettimeoffset();

	/*
	 * xtime is atomically updated in timer_bh. lost_ticks is
	 * nonzero if the timer bottom half hasnt executed yet.
	 */
	if (lost_ticks)
		tv->tv_usec += USECS_PER_JIFFY;

	restore_flags(flags);

	if (tv->tv_usec >= 1000000) {
		tv->tv_usec -= 1000000;
		tv->tv_sec++;
	}
}

void do_settimeofday(struct timeval *tv)
{
	cli();
	/* This is revolting. We need to set the xtime.tv_usec
	 * correctly. However, the value in this location is
	 * is value at the last tick.
	 * Discover what correction gettimeofday
	 * would have done, and then undo it!
	 */
	tv->tv_usec -= do_gettimeoffset();

	if (tv->tv_usec < 0) {
		tv->tv_usec += 1000000;
		tv->tv_sec--;
	}

	xtime = *tv;
	time_state = TIME_BAD;
	time_maxerror = MAXPHASE;
	time_esterror = MAXPHASE;
	sti();
}

/*
 * In order to set the CMOS clock precisely, set_rtc_mmss has to be
 * called 500 ms after the second nowtime has started, because when
 * nowtime is written into the registers of the CMOS clock, it will
 * jump to the next second precisely 500 ms later. Check the Motorola
 * MC146818A or Dallas DS12887 data sheet for details.
 */
static int set_rtc_mmss(unsigned long nowtime)
{
	int retval = 0;
	int real_seconds, real_minutes, cmos_minutes;
	unsigned char save_control, save_freq_select;

	save_control = CMOS_READ(RTC_CONTROL); /* tell the clock it's being set */
	CMOS_WRITE((save_control|RTC_SET), RTC_CONTROL);

	save_freq_select = CMOS_READ(RTC_FREQ_SELECT); /* stop and reset prescaler */
	CMOS_WRITE((save_freq_select|RTC_DIV_RESET2), RTC_FREQ_SELECT);

	cmos_minutes = CMOS_READ(RTC_MINUTES);
	if (!(save_control & RTC_DM_BINARY) || RTC_ALWAYS_BCD)
		BCD_TO_BIN(cmos_minutes);

	/*
	 * since we're only adjusting minutes and seconds,
	 * don't interfere with hour overflow. This avoids
	 * messing with unknown time zones but requires your
	 * RTC not to be off by more than 15 minutes
	 */
	real_seconds = nowtime % 60;
	real_minutes = nowtime / 60;
	if (((abs(real_minutes - cmos_minutes) + 15)/30) & 1)
		real_minutes += 30;		/* correct for half hour time zone */
	real_minutes %= 60;

	if (abs(real_minutes - cmos_minutes) < 30) {
		if (!(save_control & RTC_DM_BINARY) || RTC_ALWAYS_BCD) {
			BIN_TO_BCD(real_seconds);
			BIN_TO_BCD(real_minutes);
		}
		CMOS_WRITE(real_seconds,RTC_SECONDS);
		CMOS_WRITE(real_minutes,RTC_MINUTES);
	} else
		retval = -1;

	/* The following flags have to be released exactly in this order,
	 * otherwise the DS12887 (popular MC146818A clone with integrated
	 * battery and quartz) will not reset the oscillator and will not
	 * update precisely 500 ms later. You won't find this mentioned in
	 * the Dallas Semiconductor data sheets, but who believes data
	 * sheets anyway ...                           -- Markus Kuhn
	 */
	CMOS_WRITE(save_control, RTC_CONTROL);
	CMOS_WRITE(save_freq_select, RTC_FREQ_SELECT);

	return retval;
}

/* last time the cmos clock got updated */
static long last_rtc_update = 0;

/*
 * timer_interrupt() needs to keep up the real-time clock,
 * as well as call the "do_timer()" routine every clocktick
 */
static void inline
timer_interrupt(int irq, void *dev_id, struct pt_regs * regs)
{
	do_timer(regs);

	/*
	 * If we have an externally synchronized Linux clock, then update
	 * CMOS clock accordingly every ~11 minutes. Set_rtc_mmss() has to be
	 * called as close as possible to 500 ms before the new second starts.
	 */
	if (time_state != TIME_BAD && xtime.tv_sec > last_rtc_update + 660 &&
	    xtime.tv_usec > 500000 - (tick >> 1) &&
	    xtime.tv_usec < 500000 + (tick >> 1))
	  if (set_rtc_mmss(xtime.tv_sec) == 0)
	    last_rtc_update = xtime.tv_sec;
	  else
	    last_rtc_update = xtime.tv_sec - 600; /* do it again in 60 s */
	/* As we return to user mode fire off the other CPU schedulers.. this is 
	   basically because we don't yet share IRQ's around. This message is
	   rigged to be safe on the 386 - basically it's a hack, so don't look
	   closely for now.. */
	/*smp_message_pass(MSG_ALL_BUT_SELF, MSG_RESCHEDULE, 0L, 0); */
}

static void r4k_timer_interrupt(int irq, void *dev_id, struct pt_regs * regs)
{
	unsigned int count;

	/*
	 * The cycle counter is only 32 bit which is good for about
	 * a minute at current count rates of upto 150MHz or so.
	 */
	count = read_32bit_cp0_register(CP0_COUNT);
	timerhi += (count < timerlo);	/* Wrap around */
	timerlo = count;

	timer_interrupt(irq, dev_id, regs);
}

/* Converts Gregorian date to seconds since 1970-01-01 00:00:00.
 * Assumes input in normal date format, i.e. 1980-12-31 23:59:59
 * => year=1980, mon=12, day=31, hour=23, min=59, sec=59.
 *
 * [For the Julian calendar (which was used in Russia before 1917,
 * Britain & colonies before 1752, anywhere else before 1582,
 * and is still in use by some communities) leave out the
 * -year/100+year/400 terms, and add 10.]
 *
 * This algorithm was first published by Gauss (I think).
 *
 * WARNING: this function will overflow on 2106-02-07 06:28:16 on
 * machines were long is 32-bit! (However, as time_t is signed, we
 * will already get problems at other places on 2038-01-19 03:14:08)
 */
static inline unsigned long mktime(unsigned int year, unsigned int mon,
	unsigned int day, unsigned int hour,
	unsigned int min, unsigned int sec)
{
	if (0 >= (int) (mon -= 2)) {	/* 1..12 -> 11,12,1..10 */
		mon += 12;	/* Puts Feb last since it has leap day */
		year -= 1;
	}
	return (((
	    (unsigned long)(year/4 - year/100 + year/400 + 367*mon/12 + day) +
	      year*365 - 719499
	    )*24 + hour /* now have hours */
	   )*60 + min /* now have minutes */
	  )*60 + sec; /* finally seconds */
}

char cyclecounter_available;

static inline void init_cycle_counter(void)
{
	switch(mips_cputype) {
	case CPU_UNKNOWN:
	case CPU_R2000:
	case CPU_R3000:
	case CPU_R3000A:
	case CPU_R3041:
	case CPU_R3051:
	case CPU_R3052:
	case CPU_R3081:
	case CPU_R3081E:
	case CPU_R6000:
	case CPU_R6000A:
	case CPU_R8000:		/* Not shure about that one, play safe */
		cyclecounter_available = 0;
		break;
	case CPU_R4000PC:
	case CPU_R4000SC:
	case CPU_R4000MC:
	case CPU_R4200:
	case CPU_R4400PC:
	case CPU_R4400SC:
	case CPU_R4400MC:
	case CPU_R4600:
	case CPU_R10000:
	case CPU_R4300:
	case CPU_R4650:
	case CPU_R4700:
	case CPU_R5000:
	case CPU_R5000A:
	case CPU_R4640:
	case CPU_NEVADA:
		cyclecounter_available = 1;
		break;
	}
}

struct irqaction irq0  = { timer_interrupt, SA_INTERRUPT, 0,
                                  "timer", NULL, NULL};


void (*board_time_init)(struct irqaction *irq);

__initfunc(void time_init(void))
{
	unsigned int year, mon, day, hour, min, sec;
	int i;

	/* The Linux interpretation of the CMOS clock register contents:
	 * When the Update-In-Progress (UIP) flag goes from 1 to 0, the
	 * RTC registers show the second which has precisely just started.
	 * Let's hope other operating systems interpret the RTC the same way.
	 */
	/* read RTC exactly on falling edge of update flag */
	for (i = 0 ; i < 1000000 ; i++)	/* may take up to 1 second... */
		if (CMOS_READ(RTC_FREQ_SELECT) & RTC_UIP)
			break;
	for (i = 0 ; i < 1000000 ; i++)	/* must try at least 2.228 ms */
		if (!(CMOS_READ(RTC_FREQ_SELECT) & RTC_UIP))
			break;
	do { /* Isn't this overkill ? UIP above should guarantee consistency */
		sec = CMOS_READ(RTC_SECONDS);
		min = CMOS_READ(RTC_MINUTES);
		hour = CMOS_READ(RTC_HOURS);
		day = CMOS_READ(RTC_DAY_OF_MONTH);
		mon = CMOS_READ(RTC_MONTH);
		year = CMOS_READ(RTC_YEAR);
	} while (sec != CMOS_READ(RTC_SECONDS));
	if (!(CMOS_READ(RTC_CONTROL) & RTC_DM_BINARY) || RTC_ALWAYS_BCD)
	  {
	    BCD_TO_BIN(sec);
	    BCD_TO_BIN(min);
	    BCD_TO_BIN(hour);
	    BCD_TO_BIN(day);
	    BCD_TO_BIN(mon);
	    BCD_TO_BIN(year);
	  }
#if 0	/* the IBM way */
	if ((year += 1900) < 1970)
		year += 100;
#else
	/* Acer PICA clock starts from 1980.  True for all MIPS machines?  */
	year += 1980;
#endif
	xtime.tv_sec = mktime(year, mon, day, hour, min, sec);
	xtime.tv_usec = 0;

	init_cycle_counter();

	if (cyclecounter_available) {
		write_32bit_cp0_register(CP0_COUNT, 0);
		do_gettimeoffset = do_fast_gettimeoffset;
		irq0.handler = r4k_timer_interrupt;
	}

	board_time_init(&irq0);
}