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/*
* i386 CMOS starts out with 14 bytes clock data alpha has something
* similar, but with details depending on the machine type.
*
* byte 0: seconds 0-59
* byte 2: minutes 0-59
* byte 4: hours 0-23 in 24hr mode,
* 1-12 in 12hr mode, with high bit unset/set
* if am/pm.
* byte 6: weekday 1-7, Sunday=1
* byte 7: day of the month 1-31
* byte 8: month 1-12
* byte 9: year 0-99
*
* Numbers are stored in BCD/binary if bit 2 of byte 11 is unset/set The
* clock is in 12hr/24hr mode if bit 1 of byte 11 is unset/set The clock is
* undefined (being updated) if bit 7 of byte 10 is set. The clock is frozen
* (to be updated) by setting bit 7 of byte 11 Bit 7 of byte 14 indicates
* whether the CMOS clock is reliable: it is 1 if RTC power has been good
* since this bit was last read; it is 0 when the battery is dead and system
* power has been off.
*
* Avoid setting the RTC clock within 2 seconds of the day rollover that
* starts a new month or enters daylight saving time.
*
* The century situation is messy:
*
* Usually byte 50 (0x32) gives the century (in BCD, so 19 or 20 hex), but
* IBM PS/2 has (part of) a checksum there and uses byte 55 (0x37).
* Sometimes byte 127 (0x7f) or Bank 1, byte 0x48 gives the century. The
* original RTC will not access any century byte; some modern versions will.
* If a modern RTC or BIOS increments the century byte it may go from 0x19
* to 0x20, but in some buggy cases 0x1a is produced.
*/
/*
* A struct tm has int fields
* tm_sec 0-59, 60 or 61 only for leap seconds
* tm_min 0-59
* tm_hour 0-23
* tm_mday 1-31
* tm_mon 0-11
* tm_year number of years since 1900
* tm_wday 0-6, 0=Sunday
* tm_yday 0-365
* tm_isdst >0: yes, 0: no, <0: unknown
*/
#include <fcntl.h>
#include <stdio.h>
#include <string.h>
#include <time.h>
#include <unistd.h>
#include "c.h"
#include "nls.h"
#include "pathnames.h"
/* for inb, outb */
#if defined(__i386__) || defined(__x86_64__)
# ifdef HAVE_SYS_IO_H
# include <sys/io.h>
# elif defined(HAVE_ASM_IO_H)
# include <asm/io.h>
# else
# undef __i386__
# undef __x86_64__
# warning "disable cmos access - no sys/io.h or asm/io.h"
static void outb(int a __attribute__((__unused__)),
int b __attribute__((__unused__)))
{
}
static int inb(int c __attribute__((__unused__)))
{
return 0;
}
# endif /* __i386__ __x86_64__ */
#else
# warning "disable cmos access - not i386 or x86_64"
static void outb(int a __attribute__((__unused__)),
int b __attribute__((__unused__)))
{
}
static int inb(int c __attribute__((__unused__)))
{
return 0;
}
#endif /* for inb, outb */
#include "hwclock.h"
#define BCD_TO_BIN(val) ((val)=((val)&15) + ((val)>>4)*10)
#define BIN_TO_BCD(val) ((val)=(((val)/10)<<4) + (val)%10)
#define IOPL_NOT_IMPLEMENTED -2
/*
* POSIX uses 1900 as epoch for a struct tm, and 1970 for a time_t.
*/
#define TM_EPOCH 1900
static unsigned short clock_ctl_addr = 0x70;
static unsigned short clock_data_addr = 0x71;
/*
* Hmmh, this isn't very atomic. Maybe we should force an error instead?
*
* TODO: optimize the access to CMOS by mlockall(MCL_CURRENT) and SCHED_FIFO
*/
static unsigned long atomic(unsigned long (*op) (unsigned long),
unsigned long arg)
{
return (*op) (arg);
}
/*
* We only want to read CMOS data, but unfortunately writing to bit 7
* disables (1) or enables (0) NMI; since this bit is read-only we have
* to guess the old status. Various docs suggest that one should disable
* NMI while reading/writing CMOS data, and enable it again afterwards.
* This would yield the sequence
*
* outb (reg | 0x80, 0x70);
* val = inb(0x71);
* outb (0x0d, 0x70); // 0x0d: random read-only location
*
* Other docs state that "any write to 0x70 should be followed by an
* action to 0x71 or the RTC will be left in an unknown state". Most
* docs say that it doesn't matter at all what one does.
*
* bit 0x80: disable NMI while reading - should we? Let us follow the
* kernel and not disable. Called only with 0 <= reg < 128
*/
static inline unsigned long cmos_read(unsigned long reg)
{
outb(reg, clock_ctl_addr);
return inb(clock_data_addr);
}
static inline unsigned long cmos_write(unsigned long reg, unsigned long val)
{
outb(reg, clock_ctl_addr);
outb(val, clock_data_addr);
return 0;
}
static unsigned long cmos_set_time(unsigned long arg)
{
unsigned char save_control, save_freq_select, pmbit = 0;
struct tm tm = *(struct tm *)arg;
/*
* CMOS byte 10 (clock status register A) has 3 bitfields:
* bit 7: 1 if data invalid, update in progress (read-only bit)
* (this is raised 224 us before the actual update starts)
* 6-4 select base frequency
* 010: 32768 Hz time base (default)
* 111: reset
* all other combinations are manufacturer-dependent
* (e.g.: DS1287: 010 = start oscillator, anything else = stop)
* 3-0 rate selection bits for interrupt
* 0000 none (may stop RTC)
* 0001, 0010 give same frequency as 1000, 1001
* 0011 122 microseconds (minimum, 8192 Hz)
* .... each increase by 1 halves the frequency, doubles the period
* 1111 500 milliseconds (maximum, 2 Hz)
* 0110 976.562 microseconds (default 1024 Hz)
*/
save_control = cmos_read(11); /* tell the clock it's being set */
cmos_write(11, (save_control | 0x80));
save_freq_select = cmos_read(10); /* stop and reset prescaler */
cmos_write(10, (save_freq_select | 0x70));
tm.tm_year %= 100;
tm.tm_mon += 1;
tm.tm_wday += 1;
if (!(save_control & 0x02)) { /* 12hr mode; the default is 24hr mode */
if (tm.tm_hour == 0)
tm.tm_hour = 24;
if (tm.tm_hour > 12) {
tm.tm_hour -= 12;
pmbit = 0x80;
}
}
if (!(save_control & 0x04)) { /* BCD mode - the default */
BIN_TO_BCD(tm.tm_sec);
BIN_TO_BCD(tm.tm_min);
BIN_TO_BCD(tm.tm_hour);
BIN_TO_BCD(tm.tm_wday);
BIN_TO_BCD(tm.tm_mday);
BIN_TO_BCD(tm.tm_mon);
BIN_TO_BCD(tm.tm_year);
}
cmos_write(0, tm.tm_sec);
cmos_write(2, tm.tm_min);
cmos_write(4, tm.tm_hour | pmbit);
cmos_write(6, tm.tm_wday);
cmos_write(7, tm.tm_mday);
cmos_write(8, tm.tm_mon);
cmos_write(9, tm.tm_year);
/*
* The kernel sources, linux/arch/i386/kernel/time.c, have the
* following comment:
*
* 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(11, save_control);
cmos_write(10, save_freq_select);
return 0;
}
static int hclock_read(unsigned long reg)
{
return atomic(cmos_read, reg);
}
static void hclock_set_time(const struct tm *tm)
{
atomic(cmos_set_time, (unsigned long)(tm));
}
static inline int cmos_clock_busy(void)
{
return
/* poll bit 7 (UIP) of Control Register A */
(hclock_read(10) & 0x80);
}
static int synchronize_to_clock_tick_cmos(const struct hwclock_control *ctl
__attribute__((__unused__)))
{
int i;
/*
* Wait for rise. Should be within a second, but in case something
* weird happens, we have a limit on this loop to reduce the impact
* of this failure.
*/
for (i = 0; !cmos_clock_busy(); i++)
if (i >= 10000000)
return 1;
/* Wait for fall. Should be within 2.228 ms. */
for (i = 0; cmos_clock_busy(); i++)
if (i >= 1000000)
return 1;
return 0;
}
/*
* Read the hardware clock and return the current time via <tm> argument.
* Assume we have an ISA machine and read the clock directly with CPU I/O
* instructions.
*
* This function is not totally reliable. It takes a finite and
* unpredictable amount of time to execute the code below. During that time,
* the clock may change and we may even read an invalid value in the middle
* of an update. We do a few checks to minimize this possibility, but only
* the kernel can actually read the clock properly, since it can execute
* code in a short and predictable amount of time (by turning of
* interrupts).
*
* In practice, the chance of this function returning the wrong time is
* extremely remote.
*/
static int read_hardware_clock_cmos(const struct hwclock_control *ctl
__attribute__((__unused__)), struct tm *tm)
{
unsigned char status = 0, pmbit = 0;
while (1) {
/*
* Bit 7 of Byte 10 of the Hardware Clock value is the
* Update In Progress (UIP) bit, which is on while and 244
* uS before the Hardware Clock updates itself. It updates
* the counters individually, so reading them during an
* update would produce garbage. The update takes 2mS, so we
* could be spinning here that long waiting for this bit to
* turn off.
*
* Furthermore, it is pathologically possible for us to be
* in this code so long that even if the UIP bit is not on
* at first, the clock has changed while we were running. We
* check for that too, and if it happens, we start over.
*/
if (!cmos_clock_busy()) {
/* No clock update in progress, go ahead and read */
tm->tm_sec = hclock_read(0);
tm->tm_min = hclock_read(2);
tm->tm_hour = hclock_read(4);
tm->tm_wday = hclock_read(6);
tm->tm_mday = hclock_read(7);
tm->tm_mon = hclock_read(8);
tm->tm_year = hclock_read(9);
status = hclock_read(11);
/*
* Unless the clock changed while we were reading,
* consider this a good clock read .
*/
if (tm->tm_sec == hclock_read(0))
break;
}
/*
* Yes, in theory we could have been running for 60 seconds
* and the above test wouldn't work!
*/
}
if (!(status & 0x04)) { /* BCD mode - the default */
BCD_TO_BIN(tm->tm_sec);
BCD_TO_BIN(tm->tm_min);
pmbit = (tm->tm_hour & 0x80);
tm->tm_hour &= 0x7f;
BCD_TO_BIN(tm->tm_hour);
BCD_TO_BIN(tm->tm_wday);
BCD_TO_BIN(tm->tm_mday);
BCD_TO_BIN(tm->tm_mon);
BCD_TO_BIN(tm->tm_year);
}
/*
* We don't use the century byte of the Hardware Clock since we
* don't know its address (usually 50 or 55). Here, we follow the
* advice of the X/Open Base Working Group: "if century is not
* specified, then values in the range [69-99] refer to years in the
* twentieth century (1969 to 1999 inclusive), and values in the
* range [00-68] refer to years in the twenty-first century (2000 to
* 2068 inclusive)."
*/
tm->tm_wday -= 1;
tm->tm_mon -= 1;
if (tm->tm_year < 69)
tm->tm_year += 100;
if (pmbit) {
tm->tm_hour += 12;
if (tm->tm_hour == 24)
tm->tm_hour = 0;
}
tm->tm_isdst = -1; /* don't know whether it's daylight */
return 0;
}
static int set_hardware_clock_cmos(const struct hwclock_control *ctl
__attribute__((__unused__)),
const struct tm *new_broken_time)
{
hclock_set_time(new_broken_time);
return 0;
}
#if defined(__i386__) || defined(__x86_64__)
# if defined(HAVE_IOPL)
static int i386_iopl(const int level)
{
return iopl(level);
}
# else
static int i386_iopl(const int level __attribute__ ((__unused__)))
{
extern int ioperm(unsigned long from, unsigned long num, int turn_on);
return ioperm(clock_ctl_addr, 2, 1);
}
# endif
#else
static int i386_iopl(const int level __attribute__ ((__unused__)))
{
return IOPL_NOT_IMPLEMENTED;
}
#endif
static int get_permissions_cmos(void)
{
int rc;
rc = i386_iopl(3);
if (rc == IOPL_NOT_IMPLEMENTED) {
warnx(_("ISA port access is not implemented"));
} else if (rc != 0) {
warn(_("iopl() port access failed"));
}
return rc;
}
static const char *get_device_path(void)
{
return NULL;
}
static struct clock_ops cmos_interface = {
N_("Using direct ISA access to the clock"),
get_permissions_cmos,
read_hardware_clock_cmos,
set_hardware_clock_cmos,
synchronize_to_clock_tick_cmos,
get_device_path,
};
/*
* return &cmos if cmos clock present, NULL otherwise.
*/
struct clock_ops *probe_for_cmos_clock(void)
{
#if defined(__i386__) || defined(__x86_64__)
return &cmos_interface;
#else
return NULL;
#endif
}
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