/* This file contains a device driver that can access the CMOS chip to * get or set the system time. It drives the special file: * * /dev/cmos - CMOS chip * * Changes: * Aug 04, 2005 Created. Read CMOS time. (Jorrit N. Herder) * * Manufacturers usually use the ID value of the IBM model they emulate. * However some manufacturers, notably HP and COMPAQ, have had different * ideas in the past. * * Machine ID byte information source: * _The Programmer's PC Sourcebook_ by Thom Hogan, * published by Microsoft Press */ #include "../drivers.h" #include #include #include #include extern int errno; /* error number for PM calls */ FORWARD _PROTOTYPE( int gettime, (int who, int y2kflag, vir_bytes dst_time)); FORWARD _PROTOTYPE( void reply, (int reply, int replyee, int proc, int s)); FORWARD _PROTOTYPE( int read_register, (int register_address)); FORWARD _PROTOTYPE( int get_cmostime, (struct tm *tmp, int y2kflag)); FORWARD _PROTOTYPE( int dec_to_bcd, (int dec)); FORWARD _PROTOTYPE( int bcd_to_dec, (int bcd)); /*===========================================================================* * main * *===========================================================================*/ PUBLIC void main(void) { message m; int y2kflag; int result; int suspended = NONE; int s; while(TRUE) { /* Get work. */ if (OK != (s=receive(ANY, &m))) panic("CMOS", "attempt to receive work failed", s); /* Handle request. */ switch(m.m_type) { case DEV_OPEN: case DEV_CLOSE: case CANCEL: reply(TASK_REPLY, m.m_source, m.IO_ENDPT, OK); break; case DEV_PING: notify(m.m_source); break; case DEV_IOCTL: /* Probably best to SUSPEND the caller, CMOS I/O has nasty timeouts. * This way we don't block the rest of the system. First check if * another process is already suspended. We cannot handle multiple * requests at a time. */ if (suspended != NONE) { reply(TASK_REPLY, m.m_source, m.IO_ENDPT, EBUSY); break; } suspended = m.IO_ENDPT; reply(TASK_REPLY, m.m_source, m.IO_ENDPT, SUSPEND); switch(m.REQUEST) { case CIOCGETTIME: /* get CMOS time */ case CIOCGETTIMEY2K: y2kflag = (m.REQUEST = CIOCGETTIME) ? 0 : 1; result = gettime(m.IO_ENDPT, y2kflag, (vir_bytes) m.ADDRESS); break; case CIOCSETTIME: case CIOCSETTIMEY2K: default: /* unsupported ioctl */ result = ENOSYS; } /* Request completed. Tell the caller to check our status. */ notify(m.m_source); break; case DEV_STATUS: /* The FS calls back to get our status. Revive the suspended * processes and return the status of reading the CMOS. */ if (suspended == NONE) reply(DEV_NO_STATUS, m.m_source, NONE, OK); else reply(DEV_REVIVE, m.m_source, suspended, result); suspended = NONE; break; case SYN_ALARM: /* shouldn't happen */ case SYS_SIG: /* ignore system events */ continue; default: reply(TASK_REPLY, m.m_source, m.IO_ENDPT, EINVAL); } } } /*===========================================================================* * reply * *===========================================================================*/ PRIVATE void reply(int code, int replyee, int process, int status) { message m; int s; m.m_type = code; /* TASK_REPLY or REVIVE */ m.REP_STATUS = status; /* result of device operation */ m.REP_ENDPT = process; /* which user made the request */ if (OK != (s=send(replyee, &m))) panic("CMOS", "sending reply failed", s); } /*===========================================================================* * gettime * *===========================================================================*/ PRIVATE int gettime(int who, int y2kflag, vir_bytes dst_time) { unsigned char mach_id, cmos_state; struct tm time1; int i, s; /* First obtain the machine ID to see if we can read the CMOS clock. Only * for PS_386 and PC_AT this is possible. Otherwise, return an error. */ sys_vircopy(SELF, BIOS_SEG, (vir_bytes) MACHINE_ID_ADDR, SELF, D, (vir_bytes) &mach_id, MACHINE_ID_SIZE); if (mach_id != PS_386_MACHINE && mach_id != PC_AT_MACHINE) { printf("IS: Machine ID unknown. ID byte = %02x.\n", mach_id); return(EFAULT); } /* Now check the CMOS' state to see if we can read a proper time from it. * If the state is crappy, return an error. */ cmos_state = read_register(CMOS_STATUS); if (cmos_state & (CS_LOST_POWER | CS_BAD_CHKSUM | CS_BAD_TIME)) { printf( "IS: CMOS RAM error(s) found. State = 0x%02x\n", cmos_state ); if (cmos_state & CS_LOST_POWER) printf("IS: RTC lost power. Reset CMOS RAM with SETUP." ); if (cmos_state & CS_BAD_CHKSUM) printf("IS: CMOS RAM checksum is bad. Run SETUP." ); if (cmos_state & CS_BAD_TIME) printf("IS: Time invalid in CMOS RAM. Reset clock." ); return(EFAULT); } /* Everything seems to be OK. Read the CMOS real time clock and copy the * result back to the caller. */ if (get_cmostime(&time1, y2kflag) != 0) return(EFAULT); sys_datacopy(SELF, (vir_bytes) &time1, who, dst_time, sizeof(struct tm)); return(OK); } PRIVATE int get_cmostime(struct tm *t, int y2kflag) { /* Update the structure pointed to by time with the current time as read * from CMOS RAM of the RTC. If necessary, the time is converted into a * binary format before being stored in the structure. */ int osec, n; unsigned long i; clock_t t0,t1; /* Start a timer to keep us from getting stuck on a dead clock. */ getuptime(&t0); do { osec = -1; n = 0; do { getuptime(&t1); if (t1-t0 > 5*HZ) { printf("readclock: CMOS clock appears dead\n"); return(1); } /* Clock update in progress? */ if (read_register(RTC_REG_A) & RTC_A_UIP) continue; t->tm_sec = read_register(RTC_SEC); if (t->tm_sec != osec) { /* Seconds changed. First from -1, then because the * clock ticked, which is what we're waiting for to * get a precise reading. */ osec = t->tm_sec; n++; } } while (n < 2); /* Read the other registers. */ t->tm_min = read_register(RTC_MIN); t->tm_hour = read_register(RTC_HOUR); t->tm_mday = read_register(RTC_MDAY); t->tm_mon = read_register(RTC_MONTH); t->tm_year = read_register(RTC_YEAR); /* Time stable? */ } while (read_register(RTC_SEC) != t->tm_sec || read_register(RTC_MIN) != t->tm_min || read_register(RTC_HOUR) != t->tm_hour || read_register(RTC_MDAY) != t->tm_mday || read_register(RTC_MONTH) != t->tm_mon || read_register(RTC_YEAR) != t->tm_year); if ((read_register(RTC_REG_B) & RTC_B_DM_BCD) == 0) { /* Convert BCD to binary (default RTC mode). */ t->tm_year = bcd_to_dec(t->tm_year); t->tm_mon = bcd_to_dec(t->tm_mon); t->tm_mday = bcd_to_dec(t->tm_mday); t->tm_hour = bcd_to_dec(t->tm_hour); t->tm_min = bcd_to_dec(t->tm_min); t->tm_sec = bcd_to_dec(t->tm_sec); } t->tm_mon--; /* Counts from 0. */ /* Correct the year, good until 2080. */ if (t->tm_year < 80) t->tm_year += 100; if (y2kflag) { /* Clock with Y2K bug, interpret 1980 as 2000, good until 2020. */ if (t->tm_year < 100) t->tm_year += 20; } return 0; } PRIVATE int read_register(int reg_addr) { /* Read a single CMOS register value. */ unsigned long r; sys_outb(RTC_INDEX, reg_addr); sys_inb(RTC_IO, &r); return r; } PRIVATE int bcd_to_dec(int n) { return ((n >> 4) & 0x0F) * 10 + (n & 0x0F); } PRIVATE int dec_to_bcd(int n) { return ((n / 10) << 4) | (n % 10); }