/* * rtc.c - Use /dev/rtc for clock access */ #include #include #include #include #include #include #include #include #include #include #include "monotonic.h" #include "nls.h" #include "hwclock.h" /* * Get defines for rtc stuff. * * Getting the rtc defines is nontrivial. The obvious way is by including * but that again includes which again * includes ... and on sparc and alpha this gives compilation errors for * many kernel versions. So, we give the defines ourselves here. Moreover, * some Sparc person decided to be incompatible, and used a struct rtc_time * different from that used in mc146818rtc.h. */ /* * On Sparcs, there is a that defines different ioctls (that are * required on my machine). However, this include file does not exist on * other architectures. */ /* One might do: #ifdef __sparc__ # include #endif */ #ifdef __sparc__ /* The following is roughly equivalent */ struct sparc_rtc_time { int sec; /* Seconds 0-59 */ int min; /* Minutes 0-59 */ int hour; /* Hour 0-23 */ int dow; /* Day of the week 1-7 */ int dom; /* Day of the month 1-31 */ int month; /* Month of year 1-12 */ int year; /* Year 0-99 */ }; #define RTCGET _IOR('p', 20, struct sparc_rtc_time) #define RTCSET _IOW('p', 21, struct sparc_rtc_time) #endif /* * struct rtc_time is present since 1.3.99. * Earlier (since 1.3.89), a struct tm was used. */ struct linux_rtc_time { int tm_sec; int tm_min; int tm_hour; int tm_mday; int tm_mon; int tm_year; int tm_wday; int tm_yday; int tm_isdst; }; /* RTC_RD_TIME etc have this definition since 1.99.9 (pre2.0-9) */ #ifndef RTC_RD_TIME # define RTC_RD_TIME _IOR('p', 0x09, struct linux_rtc_time) # define RTC_SET_TIME _IOW('p', 0x0a, struct linux_rtc_time) # define RTC_UIE_ON _IO('p', 0x03) /* Update int. enable on */ # define RTC_UIE_OFF _IO('p', 0x04) /* Update int. enable off */ #endif /* RTC_EPOCH_READ and RTC_EPOCH_SET are present since 2.0.34 and 2.1.89 */ #ifndef RTC_EPOCH_READ # define RTC_EPOCH_READ _IOR('p', 0x0d, unsigned long) /* Read epoch */ # define RTC_EPOCH_SET _IOW('p', 0x0e, unsigned long) /* Set epoch */ #endif /* * /dev/rtc is conventionally chardev 10/135 * ia64 uses /dev/efirtc, chardev 10/136 * devfs (obsolete) used /dev/misc/... for miscdev * new RTC framework + udev uses dynamic major and /dev/rtc0.../dev/rtcN * ... so we need an overridable default */ /* default or user defined dev (by hwclock --rtc=) */ static const char *rtc_dev_name; static int rtc_dev_fd = -1; static void close_rtc(void) { if (rtc_dev_fd != -1) close(rtc_dev_fd); rtc_dev_fd = -1; } static int open_rtc(const struct hwclock_control *ctl) { static const char *fls[] = { #ifdef __ia64__ "/dev/efirtc", "/dev/misc/efirtc", #endif "/dev/rtc0", "/dev/rtc", "/dev/misc/rtc" }; size_t i; if (rtc_dev_fd != -1) return rtc_dev_fd; /* --rtc option has been given */ if (ctl->rtc_dev_name) { rtc_dev_name = ctl->rtc_dev_name; rtc_dev_fd = open(rtc_dev_name, O_RDONLY); } else { for (i = 0; i < ARRAY_SIZE(fls); i++) { if (ctl->verbose) printf(_("Trying to open: %s\n"), fls[i]); rtc_dev_fd = open(fls[i], O_RDONLY); if (rtc_dev_fd < 0 && (errno == ENOENT || errno == ENODEV)) continue; rtc_dev_name = fls[i]; break; } if (rtc_dev_fd < 0) rtc_dev_name = *fls; /* default for error messages */ } if (rtc_dev_fd != -1) atexit(close_rtc); return rtc_dev_fd; } static int open_rtc_or_exit(const struct hwclock_control *ctl) { int rtc_fd = open_rtc(ctl); if (rtc_fd < 0) { warn(_("cannot open rtc device")); hwclock_exit(ctl, EXIT_FAILURE); } return rtc_fd; } static int do_rtc_read_ioctl(int rtc_fd, struct tm *tm) { int rc = -1; char *ioctlname; #ifdef __sparc__ /* some but not all sparcs use a different ioctl and struct */ struct sparc_rtc_time stm; #endif ioctlname = "RTC_RD_TIME"; rc = ioctl(rtc_fd, RTC_RD_TIME, tm); #ifdef __sparc__ if (rc == -1) { /* sparc sbus */ ioctlname = "RTCGET"; rc = ioctl(rtc_fd, RTCGET, &stm); if (rc == 0) { tm->tm_sec = stm.sec; tm->tm_min = stm.min; tm->tm_hour = stm.hour; tm->tm_mday = stm.dom; tm->tm_mon = stm.month - 1; tm->tm_year = stm.year - 1900; tm->tm_wday = stm.dow - 1; tm->tm_yday = -1; /* day in the year */ } } #endif if (rc == -1) { warn(_("ioctl(%s) to %s to read the time failed"), ioctlname, rtc_dev_name); return -1; } tm->tm_isdst = -1; /* don't know whether it's dst */ return 0; } /* * Wait for the top of a clock tick by reading /dev/rtc in a busy loop * until we see it. This function is used for rtc drivers without ioctl * interrupts. This is typical on an Alpha, where the Hardware Clock * interrupts are used by the kernel for the system clock, so aren't at * the user's disposal. */ static int busywait_for_rtc_clock_tick(const struct hwclock_control *ctl, const int rtc_fd) { struct tm start_time; /* The time when we were called (and started waiting) */ struct tm nowtime; int rc; struct timeval begin, now; if (ctl->verbose) { printf("ioctl(%d, RTC_UIE_ON, 0): %s\n", rtc_fd, strerror(errno)); printf(_("Waiting in loop for time from %s to change\n"), rtc_dev_name); } if (do_rtc_read_ioctl(rtc_fd, &start_time)) return 1; /* * Wait for change. Should be within a second, but in case * something weird happens, we have a time limit (1.5s) on this loop * to reduce the impact of this failure. */ gettime_monotonic(&begin); do { rc = do_rtc_read_ioctl(rtc_fd, &nowtime); if (rc || start_time.tm_sec != nowtime.tm_sec) break; gettime_monotonic(&now); if (time_diff(now, begin) > 1.5) { warnx(_("Timed out waiting for time change.")); return 1; } } while (1); if (rc) return 1; return 0; } /* * Same as synchronize_to_clock_tick(), but just for /dev/rtc. */ static int synchronize_to_clock_tick_rtc(const struct hwclock_control *ctl) { int rtc_fd; /* File descriptor of /dev/rtc */ int ret = 1; rtc_fd = open_rtc(ctl); if (rtc_fd == -1) { warn(_("cannot open rtc device")); return ret; } else { /* Turn on update interrupts (one per second) */ int rc = ioctl(rtc_fd, RTC_UIE_ON, 0); if (rc != -1) { /* * Just reading rtc_fd fails on broken hardware: no * update interrupt comes and a bootscript with a * hwclock call hangs */ fd_set rfds; struct timeval tv; /* * Wait up to ten seconds for the next update * interrupt */ FD_ZERO(&rfds); FD_SET(rtc_fd, &rfds); tv.tv_sec = 10; tv.tv_usec = 0; rc = select(rtc_fd + 1, &rfds, NULL, NULL, &tv); if (0 < rc) ret = 0; else if (rc == 0) { warnx(_("select() to %s to wait for clock tick timed out"), rtc_dev_name); } else warn(_("select() to %s to wait for clock tick failed"), rtc_dev_name); /* Turn off update interrupts */ rc = ioctl(rtc_fd, RTC_UIE_OFF, 0); if (rc == -1) warn(_("ioctl() to %s to turn off update interrupts failed"), rtc_dev_name); } else if (errno == ENOTTY || errno == EINVAL) { /* rtc ioctl interrupts are unimplemented */ ret = busywait_for_rtc_clock_tick(ctl, rtc_fd); } else warn(_("ioctl(%d, RTC_UIE_ON, 0) to %s failed"), rtc_fd, rtc_dev_name); } return ret; } static int read_hardware_clock_rtc(const struct hwclock_control *ctl, struct tm *tm) { int rtc_fd, rc; rtc_fd = open_rtc_or_exit(ctl); /* Read the RTC time/date, return answer via tm */ rc = do_rtc_read_ioctl(rtc_fd, tm); return rc; } /* * Set the Hardware Clock to the broken down time . Use * ioctls to "rtc" device /dev/rtc. */ static int set_hardware_clock_rtc(const struct hwclock_control *ctl, const struct tm *new_broken_time) { int rc = -1; int rtc_fd; char *ioctlname; rtc_fd = open_rtc_or_exit(ctl); ioctlname = "RTC_SET_TIME"; rc = ioctl(rtc_fd, RTC_SET_TIME, new_broken_time); #ifdef __sparc__ if (rc == -1) { /* sparc sbus */ struct sparc_rtc_time stm; stm.sec = new_broken_time->tm_sec; stm.min = new_broken_time->tm_min; stm.hour = new_broken_time->tm_hour; stm.dom = new_broken_time->tm_mday; stm.month = new_broken_time->tm_mon + 1; stm.year = new_broken_time->tm_year + 1900; stm.dow = new_broken_time->tm_wday + 1; ioctlname = "RTCSET"; rc = ioctl(rtc_fd, RTCSET, &stm); } #endif if (rc == -1) { warn(_("ioctl(%s) to %s to set the time failed"), ioctlname, rtc_dev_name); hwclock_exit(ctl, EXIT_FAILURE); } if (ctl->verbose) printf(_("ioctl(%s) was successful.\n"), ioctlname); return 0; } static int get_permissions_rtc(void) { return 0; } static const char *get_device_path(void) { return rtc_dev_name; } static struct clock_ops rtc_interface = { N_("Using the rtc interface to the clock."), get_permissions_rtc, read_hardware_clock_rtc, set_hardware_clock_rtc, synchronize_to_clock_tick_rtc, get_device_path, }; /* return &rtc if /dev/rtc can be opened, NULL otherwise */ struct clock_ops *probe_for_rtc_clock(const struct hwclock_control *ctl) { const int rtc_fd = open_rtc(ctl); if (rtc_fd < 0) return NULL; return &rtc_interface; } #ifdef __alpha__ /* * Get the Hardware Clock epoch setting from the kernel. */ int get_epoch_rtc(const struct hwclock_control *ctl, unsigned long *epoch_p) { int rtc_fd; rtc_fd = open_rtc(ctl); if (rtc_fd < 0) { warn(_("cannot open %s"), rtc_dev_name); return 1; } if (ioctl(rtc_fd, RTC_EPOCH_READ, epoch_p) == -1) { warn(_("ioctl(%d, RTC_EPOCH_READ, epoch_p) to %s failed"), rtc_fd, rtc_dev_name); return 1; } if (ctl->verbose) printf(_("ioctl(%d, RTC_EPOCH_READ, epoch_p) to %s succeeded.\n"), rtc_fd, rtc_dev_name); return 0; } /* * Set the Hardware Clock epoch in the kernel. */ int set_epoch_rtc(const struct hwclock_control *ctl) { int rtc_fd; unsigned long epoch; epoch = strtoul(ctl->epoch_option, NULL, 10); /* There were no RTC clocks before 1900. */ if (epoch < 1900 || epoch == ULONG_MAX) { warnx(_("invalid epoch '%s'."), ctl->epoch_option); return 1; } rtc_fd = open_rtc(ctl); if (rtc_fd < 0) { warn(_("cannot open %s"), rtc_dev_name); return 1; } if (ioctl(rtc_fd, RTC_EPOCH_SET, epoch) == -1) { warn(_("ioctl(%d, RTC_EPOCH_SET, %lu) to %s failed"), rtc_fd, epoch, rtc_dev_name); return 1; } if (ctl->verbose) printf(_("ioctl(%d, RTC_EPOCH_SET, %lu) to %s succeeded.\n"), rtc_fd, epoch, rtc_dev_name); return 0; } #endif /* __alpha__ */