* Copyright 2005-2007, Axel DΓΆrfler, axeld@pinc-software.de
* Copyright 2003, Jeff Ward, jeff@r2d2.stcloudstate.edu. All rights reserved.
*
* Distributed under the terms of the MIT License.
*/
#include <arch/real_time_clock.h>
#include <arch/cpu.h>
#include <boot/kernel_args.h>
#include <real_time_clock.h>
#include <real_time_data.h>
#define CMOS_ADDR_PORT 0x70
#define CMOS_DATA_PORT 0x71
typedef struct {
uint8 second;
uint8 minute;
uint8 hour;
uint8 day;
uint8 month;
uint8 year;
uint8 century;
} cmos_time;
static uint32
bcd_to_int(uint8 bcd)
{
uint32 numl;
uint32 numh;
numl = bcd & 0x0f;
numh = (bcd & 0xf0) >> 4;
return numh * 10 + numl;
}
static uint8
int_to_bcd(uint32 number)
{
uint8 low;
uint8 high;
if (number > 99)
return 0;
high = number / 10;
low = number % 10;
return (high << 4) | low;
}
static int
same_time(const cmos_time *time1, const cmos_time *time2)
{
return time1->second == time2->second
&& time1->minute == time2->minute
&& time1->hour == time2->hour
&& time1->day == time2->day
&& time1->month == time2->month
&& time1->year == time2->year
&& time1->century == time2->century;
}
static uint8
cmos_read(uint8 addr)
{
int waitTime = 10000;
if (addr < 0x0a) {
out8(0x0a, CMOS_ADDR_PORT);
while ((in8(CMOS_DATA_PORT) & 0x80) && --waitTime);
}
out8(addr, CMOS_ADDR_PORT);
return in8(CMOS_DATA_PORT);
}
static void
cmos_write(uint8 addr, uint8 data)
{
out8(addr, CMOS_ADDR_PORT);
out8(data, CMOS_DATA_PORT);
}
static void
set_24_hour_mode(void)
{
uint8 status_b;
status_b = cmos_read(0x0b);
status_b |= 0x02;
cmos_write(0x0b, status_b);
}
static void
read_cmos_clock(cmos_time *cmos)
{
set_24_hour_mode();
cmos->century = cmos_read(0x32);
cmos->year = cmos_read(0x09);
cmos->month = cmos_read(0x08);
cmos->day = cmos_read(0x07);
cmos->hour = cmos_read(0x04);
cmos->minute = cmos_read(0x02);
cmos->second = cmos_read(0x00);
}
static void
write_cmos_clock(cmos_time *cmos)
{
set_24_hour_mode();
cmos_write(0x32, cmos->century);
cmos_write(0x09, cmos->year);
cmos_write(0x08, cmos->month);
cmos_write(0x07, cmos->day);
cmos_write(0x04, cmos->hour);
cmos_write(0x02, cmos->minute);
cmos_write(0x00, cmos->second);
}
static uint32
cmos_to_secs(const cmos_time *cmos)
{
struct tm t;
t.tm_year = bcd_to_int(cmos->century) * 100 + bcd_to_int(cmos->year)
- RTC_EPOCH_BASE_YEAR;
t.tm_mon = bcd_to_int(cmos->month) - 1;
t.tm_mday = bcd_to_int(cmos->day);
t.tm_hour = bcd_to_int(cmos->hour);
t.tm_min = bcd_to_int(cmos->minute);
t.tm_sec = bcd_to_int(cmos->second);
return rtc_tm_to_secs(&t);
}
static void
secs_to_cmos(uint32 seconds, cmos_time *cmos)
{
int wholeYear;
struct tm t;
rtc_secs_to_tm(seconds, &t);
wholeYear = t.tm_year + RTC_EPOCH_BASE_YEAR;
cmos->century = int_to_bcd(wholeYear / 100);
cmos->year = int_to_bcd(wholeYear % 100);
cmos->month = int_to_bcd(t.tm_mon + 1);
cmos->day = int_to_bcd(t.tm_mday);
cmos->hour = int_to_bcd(t.tm_hour);
cmos->minute = int_to_bcd(t.tm_min);
cmos->second = int_to_bcd(t.tm_sec);
}
status_t
arch_rtc_init(struct kernel_args *args, struct real_time_data *data)
{
data->arch_data.system_time_conversion_factor
= args->arch_args.system_time_cv_factor;
return B_OK;
}
uint32
arch_rtc_get_hw_time(void)
{
int waitTime;
cmos_time cmos1;
cmos_time cmos2;
waitTime = 1000;
do {
read_cmos_clock(&cmos1);
read_cmos_clock(&cmos2);
} while (!same_time(&cmos1, &cmos2) && --waitTime);
return cmos_to_secs(&cmos1);
}
void
arch_rtc_set_hw_time(uint32 seconds)
{
cmos_time cmos;
secs_to_cmos(seconds, &cmos);
write_cmos_clock(&cmos);
}
void
arch_rtc_set_system_time_offset(struct real_time_data *data, bigtime_t offset)
{
atomic_set64(&data->arch_data.system_time_offset, offset);
}
bigtime_t
arch_rtc_get_system_time_offset(struct real_time_data *data)
{
return atomic_get64(&data->arch_data.system_time_offset);
}
