#include "RTC.h" #include "CMOS.h" #include namespace RTC { static time_t s_boot_time; void initialize() { byte cmos_mode = CMOS::read(0x0b); cmos_mode |= 2; // 24 hour mode cmos_mode |= 4; // No BCD mode CMOS::write(0x0b, cmos_mode); s_boot_time = now(); } time_t boot_time() { return s_boot_time; } static bool update_in_progress() { return CMOS::read(0x0a) & 0x80; } inline bool is_leap_year(unsigned year) { return ((year % 4 == 0) && ((year % 100 != 0) || (year % 400) == 0)); } static unsigned days_in_months_since_start_of_year(unsigned month, unsigned year) { switch (month) { case 11: return 30; case 10: return 31; case 9: return 30; case 8: return 31; case 7: return 31; case 6: return 30; case 5: return 31; case 4: return 30; case 3: return 31; case 2: if (is_leap_year(year)) return 29; return 28; case 1: return 31; default: return 0; } } static unsigned days_in_years_since_epoch(unsigned year) { unsigned days = 0; while (year > 1969) { days += 365; if (is_leap_year(year)) ++days; --year; } return days; } time_t now() { // FIXME: We should probably do something more robust here. // Perhaps read all the values twice and verify that they were identical. // We don't want to be caught in the middle of an RTC register update. while (update_in_progress()) ; unsigned year = (CMOS::read(0x32) * 100) + CMOS::read(0x09); unsigned month = CMOS::read(0x08); unsigned day = CMOS::read(0x07); unsigned hour = CMOS::read(0x04); unsigned minute = CMOS::read(0x02); unsigned second = CMOS::read(0x00); ASSERT(year >= 2018); return days_in_years_since_epoch(year - 1) * 86400 + days_in_months_since_start_of_year(month - 1, year) * 86400 + day * 86400 + hour * 3600 + minute * 60 + second; } }