/* * Copyright (c) 2019 TAOS Data, Inc. * * This program is free software: you can use, redistribute, and/or modify * it under the terms of the GNU Affero General Public License, version 3 * or later ("AGPL"), as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . */ #define ALLOW_FORBID_FUNC #define _BSD_SOURCE #ifdef DARWIN #define _XOPEN_SOURCE #else #define _XOPEN_SOURCE 500 #endif #define _DEFAULT_SOURCE #include "os.h" #ifdef WINDOWS #include #include #include //#define TM_YEAR_BASE 1970 //origin #define TM_YEAR_BASE 1900 // slguan // This magic number is the number of 100 nanosecond intervals since January 1, 1601 (UTC) // until 00:00:00 January 1, 1970 static const uint64_t TIMEEPOCH = ((uint64_t)116444736000000000ULL); /* * We do not implement alternate representations. However, we always * check whether a given modifier is allowed for a certain conversion. */ #define ALT_E 0x01 #define ALT_O 0x02 #define LEGAL_ALT(x) \ { \ if (alt_format & ~(x)) return (0); \ } static int conv_num(const char **buf, int *dest, int llim, int ulim) { int result = 0; /* The limit also determines the number of valid digits. */ int rulim = ulim; if (**buf < '0' || **buf > '9') return (0); do { result *= 10; result += *(*buf)++ - '0'; rulim /= 10; } while ((result * 10 <= ulim) && rulim && **buf >= '0' && **buf <= '9'); if (result < llim || result > ulim) return (0); *dest = result; return (1); } static const char *day[7] = {"Sunday", "Monday", "Tuesday", "Wednesday", "Thursday", "Friday", "Saturday"}; static const char *abday[7] = {"Sun", "Mon", "Tue", "Wed", "Thu", "Fri", "Sat"}; static const char *mon[12] = {"January", "February", "March", "April", "May", "June", "July", "August", "September", "October", "November", "December"}; static const char *abmon[12] = {"Jan", "Feb", "Mar", "Apr", "May", "Jun", "Jul", "Aug", "Sep", "Oct", "Nov", "Dec"}; static const char *am_pm[2] = {"AM", "PM"}; #else #include #endif char *taosStrpTime(const char *buf, const char *fmt, struct tm *tm) { #ifdef WINDOWS char c; const char *bp; size_t len = 0; int alt_format, i, split_year = 0; bp = buf; while ((c = *fmt) != '\0') { /* Clear `alternate' modifier prior to new conversion. */ alt_format = 0; /* Eat up white-space. */ if (isspace(c)) { while (isspace(*bp)) bp++; fmt++; continue; } if ((c = *fmt++) != '%') goto literal; again: switch (c = *fmt++) { case '%': /* "%%" is converted to "%". */ literal: if (c != *bp++) return (0); break; /* * "Alternative" modifiers. Just set the appropriate flag * and start over again. */ case 'E': /* "%E?" alternative conversion modifier. */ LEGAL_ALT(0); alt_format |= ALT_E; goto again; case 'O': /* "%O?" alternative conversion modifier. */ LEGAL_ALT(0); alt_format |= ALT_O; goto again; /* * "Complex" conversion rules, implemented through recursion. */ case 'c': /* Date and time, using the locale's format. */ LEGAL_ALT(ALT_E); if (!(bp = taosStrpTime(bp, "%x %X", tm))) return (0); break; case 'D': /* The date as "%m/%d/%y". */ LEGAL_ALT(0); if (!(bp = taosStrpTime(bp, "%m/%d/%y", tm))) return (0); break; case 'R': /* The time as "%H:%M". */ LEGAL_ALT(0); if (!(bp = taosStrpTime(bp, "%H:%M", tm))) return (0); break; case 'r': /* The time in 12-hour clock representation. */ LEGAL_ALT(0); if (!(bp = taosStrpTime(bp, "%I:%M:%S %p", tm))) return (0); break; case 'T': /* The time as "%H:%M:%S". */ LEGAL_ALT(0); if (!(bp = taosStrpTime(bp, "%H:%M:%S", tm))) return (0); break; case 'X': /* The time, using the locale's format. */ LEGAL_ALT(ALT_E); if (!(bp = taosStrpTime(bp, "%H:%M:%S", tm))) return (0); break; case 'x': /* The date, using the locale's format. */ LEGAL_ALT(ALT_E); if (!(bp = taosStrpTime(bp, "%m/%d/%y", tm))) return (0); break; /* * "Elementary" conversion rules. */ case 'A': /* The day of week, using the locale's form. */ case 'a': LEGAL_ALT(0); for (i = 0; i < 7; i++) { /* Full name. */ len = strlen(day[i]); if (strncmp(day[i], bp, len) == 0) break; /* Abbreviated name. */ len = strlen(abday[i]); if (strncmp(abday[i], bp, len) == 0) break; } /* Nothing matched. */ if (i == 7) return (0); tm->tm_wday = i; bp += len; break; case 'B': /* The month, using the locale's form. */ case 'b': case 'h': LEGAL_ALT(0); for (i = 0; i < 12; i++) { /* Full name. */ len = strlen(mon[i]); if (strncmp(mon[i], bp, len) == 0) break; /* Abbreviated name. */ len = strlen(abmon[i]); if (strncmp(abmon[i], bp, len) == 0) break; } /* Nothing matched. */ if (i == 12) return (0); tm->tm_mon = i; bp += len; break; case 'C': /* The century number. */ LEGAL_ALT(ALT_E); if (!(conv_num(&bp, &i, 0, 99))) return (0); if (split_year) { tm->tm_year = (tm->tm_year % 100) + (i * 100); } else { tm->tm_year = i * 100; split_year = 1; } break; case 'd': /* The day of month. */ case 'e': LEGAL_ALT(ALT_O); if (!(conv_num(&bp, &tm->tm_mday, 1, 31))) return (0); break; case 'k': /* The hour (24-hour clock representation). */ LEGAL_ALT(0); /* FALLTHROUGH */ case 'H': LEGAL_ALT(ALT_O); if (!(conv_num(&bp, &tm->tm_hour, 0, 23))) return (0); break; case 'l': /* The hour (12-hour clock representation). */ LEGAL_ALT(0); /* FALLTHROUGH */ case 'I': LEGAL_ALT(ALT_O); if (!(conv_num(&bp, &tm->tm_hour, 1, 12))) return (0); if (tm->tm_hour == 12) tm->tm_hour = 0; break; case 'j': /* The day of year. */ LEGAL_ALT(0); if (!(conv_num(&bp, &i, 1, 366))) return (0); tm->tm_yday = i - 1; break; case 'M': /* The minute. */ LEGAL_ALT(ALT_O); if (!(conv_num(&bp, &tm->tm_min, 0, 59))) return (0); break; case 'm': /* The month. */ LEGAL_ALT(ALT_O); if (!(conv_num(&bp, &i, 1, 12))) return (0); tm->tm_mon = i - 1; break; case 'p': /* The locale's equivalent of AM/PM. */ LEGAL_ALT(0); /* AM? */ if (strcmp(am_pm[0], bp) == 0) { if (tm->tm_hour > 11) return (0); bp += strlen(am_pm[0]); break; } /* PM? */ else if (strcmp(am_pm[1], bp) == 0) { if (tm->tm_hour > 11) return (0); tm->tm_hour += 12; bp += strlen(am_pm[1]); break; } /* Nothing matched. */ return (0); case 'S': /* The seconds. */ LEGAL_ALT(ALT_O); if (!(conv_num(&bp, &tm->tm_sec, 0, 61))) return (0); break; case 'U': /* The week of year, beginning on sunday. */ case 'W': /* The week of year, beginning on monday. */ LEGAL_ALT(ALT_O); /* * XXX This is bogus, as we can not assume any valid * information present in the tm structure at this * point to calculate a real value, so just check the * range for now. */ if (!(conv_num(&bp, &i, 0, 53))) return (0); break; case 'w': /* The day of week, beginning on sunday. */ LEGAL_ALT(ALT_O); if (!(conv_num(&bp, &tm->tm_wday, 0, 6))) return (0); break; case 'Y': /* The year. */ LEGAL_ALT(ALT_E); if (!(conv_num(&bp, &i, 0, 9999))) return (0); tm->tm_year = i - TM_YEAR_BASE; break; case 'y': /* The year within 100 years of the epoch. */ LEGAL_ALT(ALT_E | ALT_O); if (!(conv_num(&bp, &i, 0, 99))) return (0); if (split_year) { tm->tm_year = ((tm->tm_year / 100) * 100) + i; break; } split_year = 1; if (i <= 68) tm->tm_year = i + 2000 - TM_YEAR_BASE; else tm->tm_year = i + 1900 - TM_YEAR_BASE; break; /* * Miscellaneous conversions. */ case 'n': /* Any kind of white-space. */ case 't': LEGAL_ALT(0); while (isspace(*bp)) bp++; break; default: /* Unknown/unsupported conversion. */ return (0); } } /* LINTED functional specification */ return ((char *)bp); #else return strptime(buf, fmt, tm); #endif } int32_t taosGetTimeOfDay(struct timeval *tv) { #ifdef WINDOWS LARGE_INTEGER t; FILETIME f; GetSystemTimeAsFileTime(&f); t.QuadPart = f.dwHighDateTime; t.QuadPart <<= 32; t.QuadPart |= f.dwLowDateTime; t.QuadPart -= TIMEEPOCH; tv->tv_sec = t.QuadPart / 10000000; tv->tv_usec = (t.QuadPart % 10000000) / 10; #else return gettimeofday(tv, NULL); #endif } time_t taosTime(time_t *t) { return time(t); } time_t taosMktime(struct tm *timep) { #ifdef WINDOWS struct tm tm1 = {0}; LARGE_INTEGER t; FILETIME f; SYSTEMTIME s; FILETIME ff; SYSTEMTIME ss; LARGE_INTEGER offset; time_t tt = 0; localtime_s(&tm1, &tt); ss.wYear = tm1.tm_year + 1900; ss.wMonth = tm1.tm_mon + 1; ss.wDay = tm1.tm_mday; ss.wHour = tm1.tm_hour; ss.wMinute = tm1.tm_min; ss.wSecond = tm1.tm_sec; ss.wMilliseconds = 0; SystemTimeToFileTime(&ss, &ff); offset.QuadPart = ff.dwHighDateTime; offset.QuadPart <<= 32; offset.QuadPart |= ff.dwLowDateTime; s.wYear = timep->tm_year + 1900; s.wMonth = timep->tm_mon + 1; s.wDay = timep->tm_mday; s.wHour = timep->tm_hour; s.wMinute = timep->tm_min; s.wSecond = timep->tm_sec; s.wMilliseconds = 0; SystemTimeToFileTime(&s, &f); t.QuadPart = f.dwHighDateTime; t.QuadPart <<= 32; t.QuadPart |= f.dwLowDateTime; t.QuadPart -= offset.QuadPart; return (time_t)(t.QuadPart / 10000000); #else return mktime(timep); #endif } struct tm *taosLocalTime(const time_t *timep, struct tm *result) { if (result == NULL) { return localtime(timep); } #ifdef WINDOWS if (*timep < 0) { SYSTEMTIME ss, s; FILETIME ff, f; LARGE_INTEGER offset; struct tm tm1; time_t tt = 0; if (localtime_s(&tm1, &tt) != 0 ) { return NULL; } ss.wYear = tm1.tm_year + 1900; ss.wMonth = tm1.tm_mon + 1; ss.wDay = tm1.tm_mday; ss.wHour = tm1.tm_hour; ss.wMinute = tm1.tm_min; ss.wSecond = tm1.tm_sec; ss.wMilliseconds = 0; SystemTimeToFileTime(&ss, &ff); offset.QuadPart = ff.dwHighDateTime; offset.QuadPart <<= 32; offset.QuadPart |= ff.dwLowDateTime; offset.QuadPart += *timep * 10000000; f.dwLowDateTime = offset.QuadPart & 0xffffffff; f.dwHighDateTime = (offset.QuadPart >> 32) & 0xffffffff; FileTimeToSystemTime(&f, &s); result->tm_sec = s.wSecond; result->tm_min = s.wMinute; result->tm_hour = s.wHour; result->tm_mday = s.wDay; result->tm_mon = s.wMonth - 1; result->tm_year = s.wYear - 1900; result->tm_wday = s.wDayOfWeek; result->tm_yday = 0; result->tm_isdst = 0; } else { if (localtime_s(result, timep) != 0) { return NULL; } } #else localtime_r(timep, result); #endif return result; } static int isLeapYear(time_t year) { if (year % 4) return 0; else if (year % 100) return 1; else if (year % 400) return 0; else return 1; } struct tm *taosLocalTimeNolock(struct tm *result, const time_t *timep, int dst) { if (result == NULL) { return localtime(timep); } #ifdef WINDOWS if (*timep < 0) { SYSTEMTIME ss, s; FILETIME ff, f; LARGE_INTEGER offset; struct tm tm1; time_t tt = 0; if (localtime_s(&tm1, &tt) != 0) { return NULL; } ss.wYear = tm1.tm_year + 1900; ss.wMonth = tm1.tm_mon + 1; ss.wDay = tm1.tm_mday; ss.wHour = tm1.tm_hour; ss.wMinute = tm1.tm_min; ss.wSecond = tm1.tm_sec; ss.wMilliseconds = 0; SystemTimeToFileTime(&ss, &ff); offset.QuadPart = ff.dwHighDateTime; offset.QuadPart <<= 32; offset.QuadPart |= ff.dwLowDateTime; offset.QuadPart += *timep * 10000000; f.dwLowDateTime = offset.QuadPart & 0xffffffff; f.dwHighDateTime = (offset.QuadPart >> 32) & 0xffffffff; FileTimeToSystemTime(&f, &s); result->tm_sec = s.wSecond; result->tm_min = s.wMinute; result->tm_hour = s.wHour; result->tm_mday = s.wDay; result->tm_mon = s.wMonth - 1; result->tm_year = s.wYear - 1900; result->tm_wday = s.wDayOfWeek; result->tm_yday = 0; result->tm_isdst = 0; } else { if (localtime_s(result, timep) != 0) { return NULL; } } #elif defined(LINUX) time_t secsMin = 60, secsHour = 3600, secsDay = 3600 * 24; long tz = timezone; time_t t = *timep; t -= tz; /* Adjust for timezone. */ t += 3600 * dst; /* Adjust for daylight time. */ time_t days = t / secsDay; /* Days passed since epoch. */ time_t seconds = t % secsDay; /* Remaining seconds. */ result->tm_isdst = dst; result->tm_hour = seconds / secsHour; result->tm_min = (seconds % secsHour) / secsMin; result->tm_sec = (seconds % secsHour) % secsMin; /* 1/1/1970 was a Thursday, that is, day 4 from the POV of the tm structure * where sunday = 0, so to calculate the day of the week we have to add 4 * and take the modulo by 7. */ result->tm_wday = (days + 4) % 7; /* Calculate the current year. */ result->tm_year = 1970; while (1) { /* Leap years have one day more. */ time_t daysOfYear = 365 + isLeapYear(result->tm_year); if (daysOfYear > days) break; days -= daysOfYear; result->tm_year++; } result->tm_yday = days; /* Number of day of the current year. */ /* We need to calculate in which month and day of the month we are. To do * so we need to skip days according to how many days there are in each * month, and adjust for the leap year that has one more day in February. */ int mdays[12] = {31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31}; mdays[1] += isLeapYear(result->tm_year); result->tm_mon = 0; while (days >= mdays[result->tm_mon]) { days -= mdays[result->tm_mon]; result->tm_mon++; } result->tm_mday = days + 1; /* Add 1 since our 'days' is zero-based. */ result->tm_year -= 1900; /* Surprisingly tm_year is year-1900. */ #else localtime_r(timep, result); #endif return result; } int32_t taosGetTimestampSec() { return (int32_t)time(NULL); } int32_t taosClockGetTime(int clock_id, struct timespec *pTS) { #ifdef WINDOWS LARGE_INTEGER t; FILETIME f; GetSystemTimeAsFileTime(&f); t.QuadPart = f.dwHighDateTime; t.QuadPart <<= 32; t.QuadPart |= f.dwLowDateTime; t.QuadPart -= TIMEEPOCH; pTS->tv_sec = t.QuadPart / 10000000; pTS->tv_nsec = (t.QuadPart % 10000000) * 100; return (0); #else return clock_gettime(clock_id, pTS); #endif }