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/*
* The MIT License (MIT)
*
* Copyright (c) 2015-2019 Derick Rethans
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include "timelib.h"
#include "timelib_private.h"
/* dec jan feb mrt apr may jun jul aug sep oct nov dec */
static int days_in_month_leap[13] = { 31, 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 };
static int days_in_month[13] = { 31, 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 };
static void do_range_limit(timelib_sll start, timelib_sll end, timelib_sll adj, timelib_sll *a, timelib_sll *b)
{
if (*a < start) {
/* We calculate 'a + 1' first as 'start - *a - 1' causes an int64_t overflows if *a is
* LONG_MIN. 'start' is 0 in this context, and '0 - LONG_MIN > LONG_MAX'. */
timelib_sll a_plus_1 = *a + 1;
*b -= (start - a_plus_1) / adj + 1;
/* This code add the extra 'adj' separately, as otherwise this can overflow int64_t in
* situations where *b is near LONG_MIN. */
*a += adj * ((start - a_plus_1) / adj);
*a += adj;
}
if (*a >= end) {
*b += *a / adj;
*a -= adj * (*a / adj);
}
}
static void inc_month(timelib_sll *y, timelib_sll *m)
{
(*m)++;
if (*m > 12) {
*m -= 12;
(*y)++;
}
}
static void dec_month(timelib_sll *y, timelib_sll *m)
{
(*m)--;
if (*m < 1) {
*m += 12;
(*y)--;
}
}
static void do_range_limit_days_relative(timelib_sll *base_y, timelib_sll *base_m, timelib_sll *y, timelib_sll *m, timelib_sll *d, timelib_sll invert)
{
timelib_sll leapyear;
timelib_sll month, year;
timelib_sll days;
do_range_limit(1, 13, 12, base_m, base_y);
year = *base_y;
month = *base_m;
/*
printf( "S: Y%d M%d %d %d %d %d\n", year, month, *y, *m, *d, days);
*/
if (!invert) {
while (*d < 0) {
dec_month(&year, &month);
leapyear = timelib_is_leap(year);
days = leapyear ? days_in_month_leap[month] : days_in_month[month];
/* printf( "I Y%d M%d %d %d %d %d\n", year, month, *y, *m, *d, days); */
*d += days;
(*m)--;
}
} else {
while (*d < 0) {
leapyear = timelib_is_leap(year);
days = leapyear ? days_in_month_leap[month] : days_in_month[month];
/* printf( "I Y%d M%d %d %d %d %d\n", year, month, *y, *m, *d, days); */
*d += days;
(*m)--;
inc_month(&year, &month);
}
}
/*
printf( "E: Y%d M%d %d %d %d %d\n", year, month, *y, *m, *d, days);
*/
}
static int do_range_limit_days(timelib_sll *y, timelib_sll *m, timelib_sll *d)
{
timelib_sll leapyear;
timelib_sll previous_month, previous_year;
timelib_sll days_in_previous_month;
int retval = 0;
int *days_per_month_current_year;
/* can jump an entire leap year period quickly */
if (*d >= DAYS_PER_ERA || *d <= -DAYS_PER_ERA) {
*y += YEARS_PER_ERA * (*d / DAYS_PER_ERA);
*d -= DAYS_PER_ERA * (*d / DAYS_PER_ERA);
}
do_range_limit(1, 13, 12, m, y);
leapyear = timelib_is_leap(*y);
days_per_month_current_year = leapyear ? days_in_month_leap : days_in_month;
while (*d <= 0 && *m > 0) {
previous_month = (*m) - 1;
if (previous_month < 1) {
previous_month += 12;
previous_year = (*y) - 1;
} else {
previous_year = (*y);
}
leapyear = timelib_is_leap(previous_year);
days_in_previous_month = leapyear ? days_in_month_leap[previous_month] : days_in_month[previous_month];
*d += days_in_previous_month;
(*m)--;
retval = 1;
}
while (*d > 0 && *m <= 12 && *d > days_per_month_current_year[*m]) {
*d -= days_per_month_current_year[*m];
(*m)++;
retval = 1;
}
return retval;
}
static void do_adjust_for_weekday(timelib_time* time)
{
timelib_sll current_dow, difference;
current_dow = timelib_day_of_week(time->y, time->m, time->d);
if (time->relative.weekday_behavior == 2)
{
/* To make "this week" work, where the current DOW is a "sunday" */
if (current_dow == 0 && time->relative.weekday != 0) {
time->relative.weekday -= 7;
}
/* To make "sunday this week" work, where the current DOW is not a
* "sunday" */
if (time->relative.weekday == 0 && current_dow != 0) {
time->relative.weekday = 7;
}
time->d -= current_dow;
time->d += time->relative.weekday;
return;
}
difference = time->relative.weekday - current_dow;
if ((time->relative.d < 0 && difference < 0) || (time->relative.d >= 0 && difference <= -time->relative.weekday_behavior)) {
difference += 7;
}
if (time->relative.weekday >= 0) {
time->d += difference;
} else {
time->d -= (7 - (abs(time->relative.weekday) - current_dow));
}
time->relative.have_weekday_relative = 0;
}
void timelib_do_rel_normalize(timelib_time *base, timelib_rel_time *rt)
{
do_range_limit(0, 1000000, 1000000, &rt->us, &rt->s);
do_range_limit(0, 60, 60, &rt->s, &rt->i);
do_range_limit(0, 60, 60, &rt->i, &rt->h);
do_range_limit(0, 24, 24, &rt->h, &rt->d);
do_range_limit(0, 12, 12, &rt->m, &rt->y);
do_range_limit_days_relative(&base->y, &base->m, &rt->y, &rt->m, &rt->d, rt->invert);
do_range_limit(0, 12, 12, &rt->m, &rt->y);
}
static void magic_date_calc(timelib_time *time)
{
timelib_sll y, ddd, mi, mm, dd, g;
/* The algorithm doesn't work before the year 1 */
if (time->d < -719498) {
return;
}
g = time->d + HINNANT_EPOCH_SHIFT - 1;
y = (10000 * g + 14780) / 3652425;
ddd = g - ((365*y) + (y/4) - (y/100) + (y/400));
if (ddd < 0) {
y--;
ddd = g - ((365*y) + (y/4) - (y/100) + (y/400));
}
mi = (100 * ddd + 52) / 3060;
mm = ((mi + 2) % 12) + 1;
y = y + (mi + 2) / 12;
dd = ddd - ((mi * 306 + 5) / 10) + 1;
time->y = y;
time->m = mm;
time->d = dd;
}
void timelib_do_normalize(timelib_time* time)
{
if (time->us != TIMELIB_UNSET) do_range_limit(0, 1000000, 1000000, &time->us, &time->s);
if (time->s != TIMELIB_UNSET) do_range_limit(0, 60, 60, &time->s, &time->i);
if (time->s != TIMELIB_UNSET) do_range_limit(0, 60, 60, &time->i, &time->h);
if (time->s != TIMELIB_UNSET) do_range_limit(0, 24, 24, &time->h, &time->d);
do_range_limit(1, 13, 12, &time->m, &time->y);
/* Short cut if we're doing things against the Epoch */
if (time->y == 1970 && time->m == 1 && time->d != 1) {
magic_date_calc(time);
}
do {} while (do_range_limit_days(&time->y, &time->m, &time->d));
do_range_limit(1, 13, 12, &time->m, &time->y);
}
static void do_adjust_relative(timelib_time* time)
{
if (time->relative.have_weekday_relative) {
do_adjust_for_weekday(time);
}
timelib_do_normalize(time);
if (time->have_relative) {
time->us += time->relative.us;
time->s += time->relative.s;
time->i += time->relative.i;
time->h += time->relative.h;
time->d += time->relative.d;
time->m += time->relative.m;
time->y += time->relative.y;
}
switch (time->relative.first_last_day_of) {
case TIMELIB_SPECIAL_FIRST_DAY_OF_MONTH: /* first */
time->d = 1;
break;
case TIMELIB_SPECIAL_LAST_DAY_OF_MONTH: /* last */
time->d = 0;
time->m++;
break;
}
timelib_do_normalize(time);
}
static void do_adjust_special_weekday(timelib_time* time)
{
timelib_sll count, dow, rem;
count = time->relative.special.amount;
dow = timelib_day_of_week(time->y, time->m, time->d);
/* Add increments of 5 weekdays as a week, leaving the DOW unchanged. */
time->d += (count / 5) * 7;
/* Deal with the remainder. */
rem = (count % 5);
if (count > 0) {
if (rem == 0) {
/* Head back to Friday if we stop on the weekend. */
if (dow == 0) {
time->d -= 2;
} else if (dow == 6) {
time->d -= 1;
}
} else if (dow == 6) {
/* We ended up on Saturday, but there's still work to do, so move
* to Sunday and continue from there. */
time->d += 1;
} else if (dow + rem > 5) {
/* We're on a weekday, but we're going past Friday, so skip right
* over the weekend. */
time->d += 2;
}
} else {
/* Completely mirror the forward direction. This also covers the 0
* case, since if we start on the weekend, we want to move forward as
* if we stopped there while going backwards. */
if (rem == 0) {
if (dow == 6) {
time->d += 2;
} else if (dow == 0) {
time->d += 1;
}
} else if (dow == 0) {
time->d -= 1;
} else if (dow + rem < 1) {
time->d -= 2;
}
}
time->d += rem;
}
static void do_adjust_special(timelib_time* time)
{
if (time->relative.have_special_relative) {
switch (time->relative.special.type) {
case TIMELIB_SPECIAL_WEEKDAY:
do_adjust_special_weekday(time);
break;
}
}
timelib_do_normalize(time);
memset(&(time->relative.special), 0, sizeof(time->relative.special));
}
static void do_adjust_special_early(timelib_time* time)
{
if (time->relative.have_special_relative) {
switch (time->relative.special.type) {
case TIMELIB_SPECIAL_DAY_OF_WEEK_IN_MONTH:
time->d = 1;
time->m += time->relative.m;
time->relative.m = 0;
break;
case TIMELIB_SPECIAL_LAST_DAY_OF_WEEK_IN_MONTH:
time->d = 1;
time->m += time->relative.m + 1;
time->relative.m = 0;
break;
}
}
switch (time->relative.first_last_day_of) {
case TIMELIB_SPECIAL_FIRST_DAY_OF_MONTH: /* first */
time->d = 1;
break;
case TIMELIB_SPECIAL_LAST_DAY_OF_MONTH: /* last */
time->d = 0;
time->m++;
break;
}
timelib_do_normalize(time);
}
static void do_adjust_timezone(timelib_time *tz, timelib_tzinfo *tzi)
{
switch (tz->zone_type) {
case TIMELIB_ZONETYPE_OFFSET:
tz->is_localtime = 1;
tz->sse += -tz->z;
return;
case TIMELIB_ZONETYPE_ABBR: {
tz->is_localtime = 1;
tz->sse += (-tz->z - tz->dst * SECS_PER_HOUR);
return;
}
case TIMELIB_ZONETYPE_ID:
tzi = tz->tz_info;
TIMELIB_BREAK_INTENTIONALLY_MISSING
default: {
/* No timezone in struct, fallback to reference if possible */
int32_t current_offset = 0;
timelib_sll current_transition_time = 0;
unsigned int current_is_dst = 0;
int32_t after_offset = 0;
timelib_sll after_transition_time = 0;
timelib_sll adjustment;
int in_transition;
int32_t actual_offset;
timelib_sll actual_transition_time;
if (!tzi) {
return;
}
timelib_get_time_zone_offset_info(tz->sse, tzi, ¤t_offset, ¤t_transition_time, ¤t_is_dst);
timelib_get_time_zone_offset_info(tz->sse - current_offset, tzi, &after_offset, &after_transition_time, NULL);
actual_offset = after_offset;
actual_transition_time = after_transition_time;
if (current_offset == after_offset && tz->have_zone) {
/* Make sure we're not missing a DST change because we don't know the actual offset yet */
if (current_offset >= 0 && tz->dst && !current_is_dst) {
/* Timezone or its DST at or east of UTC, so the local time, interpreted as UTC, leaves DST (as defined in the actual timezone) before the actual local time */
int32_t earlier_offset;
timelib_sll earlier_transition_time;
timelib_get_time_zone_offset_info(tz->sse - current_offset - 7200, tzi, &earlier_offset, &earlier_transition_time, NULL);
if ((earlier_offset != after_offset) && (tz->sse - earlier_offset < after_transition_time)) {
/* Looking behind a bit clarified the actual offset to use */
actual_offset = earlier_offset;
actual_transition_time = earlier_transition_time;
}
} else if (current_offset <= 0 && current_is_dst && !tz->dst) {
/* Timezone west of UTC, so the local time, interpreted as UTC, leaves DST (as defined in the actual timezone) after the actual local time */
int32_t later_offset;
timelib_sll later_transition_time;
timelib_get_time_zone_offset_info(tz->sse - current_offset + 7200, tzi, &later_offset, &later_transition_time, NULL);
if ((later_offset != after_offset) && (tz->sse - later_offset >= later_transition_time)) {
/* Looking ahead a bit clarified the actual offset to use */
actual_offset = later_offset;
actual_transition_time = later_transition_time;
}
}
}
tz->is_localtime = 1;
in_transition = (
actual_transition_time != INT64_MIN &&
((tz->sse - actual_offset) >= (actual_transition_time + (current_offset - actual_offset))) &&
((tz->sse - actual_offset) < actual_transition_time)
);
if ((current_offset != actual_offset) && !in_transition) {
adjustment = -actual_offset;
} else {
adjustment = -current_offset;
}
tz->sse += adjustment;
timelib_set_timezone(tz, tzi);
return;
}
}
return;
}
timelib_sll timelib_epoch_days_from_time(timelib_time *time)
{
timelib_sll y = time->y; // Make copy, as we don't want to change the original one
timelib_sll era, year_of_era, day_of_year, day_of_era;
y -= time->m <= 2;
era = (y >= 0 ? y : y - 399) / YEARS_PER_ERA;
year_of_era = y - era * YEARS_PER_ERA; // [0, 399]
day_of_year = (153 * (time->m + (time->m > 2 ? -3 : 9)) + 2)/5 + time->d - 1; // [0, 365]
day_of_era = year_of_era * DAYS_PER_YEAR + year_of_era / 4 - year_of_era / 100 + day_of_year; // [0, 146096]
return era * DAYS_PER_ERA + day_of_era - HINNANT_EPOCH_SHIFT;
}
void timelib_update_ts(timelib_time* time, timelib_tzinfo* tzi)
{
do_adjust_special_early(time);
do_adjust_relative(time);
do_adjust_special(time);
/* You might be wondering, why this code does this in two steps. This is because
* timelib_epoch_days_from_time(time) * SECS_PER_DAY with the lowest limit of
* timelib_epoch_days_from_time() is less than the range of an int64_t. This then overflows. In
* order to be able to still allow for any time in that day that only halfly fits in the int64_t
* range, we add the time element first, which is always positive, and then twice half the value
* of the earliest day as expressed as unix timestamp. */
time->sse = timelib_hms_to_seconds(time->h, time->i, time->s);
time->sse += timelib_epoch_days_from_time(time) * (SECS_PER_DAY / 2);
time->sse += timelib_epoch_days_from_time(time) * (SECS_PER_DAY / 2);
// This modifies time->sse, if needed
do_adjust_timezone(time, tzi);
time->sse_uptodate = 1;
time->have_relative = time->relative.have_weekday_relative = time->relative.have_special_relative = time->relative.first_last_day_of = 0;
}
#if 0
int main(void)
{
timelib_sll res;
timelib_time time;
time = timelib_strtotime("10 Feb 2005 06:07:03 PM CET"); /* 1108055223 */
printf ("%04d-%02d-%02d %02d:%02d:%02d.%-5d %+04d %1d",
time.y, time.m, time.d, time.h, time.i, time.s, time.f, time.z, time.dst);
if (time.have_relative) {
printf ("%3dY %3dM %3dD / %3dH %3dM %3dS",
time.relative.y, time.relative.m, time.relative.d, time.relative.h, time.relative.i, time.relative.s);
}
if (time.have_weekday_relative) {
printf (" / %d", time.relative.weekday);
}
res = time2unixtime(&time);
printf("%Ld\n", res);
return 0;
}
#endif