/*
** time.c - Time class
**
** See Copyright Notice in mruby.h
*/
#ifndef MRB_NO_FLOAT
#include <math.h>
#endif
#include <mruby.h>
#include <mruby/class.h>
#include <mruby/data.h>
#include <mruby/numeric.h>
#include <mruby/time.h>
#include <mruby/string.h>
#include <mruby/presym.h>
#ifdef MRB_NO_STDIO
#include <string.h>
#endif
#include <stdlib.h>
#ifndef _WIN32
#include <unistd.h>
#endif
#define NDIV(x,y) (-(-((x)+1)/(y))-1)
#define TO_S_FMT "%Y-%m-%d %H:%M:%S "
#if defined(_MSC_VER) && _MSC_VER < 1800
double round(double x) {
return floor(x + 0.5);
}
#endif
#ifndef MRB_NO_FLOAT
# if !defined(__MINGW64__) && defined(_WIN32)
# define llround(x) round(x)
# endif
#endif
#if defined(__MINGW64__) || defined(__MINGW32__)
# include <sys/time.h>
#endif
/** Time class configuration */
/* gettimeofday(2) */
/* C99 does not have gettimeofday that is required to retrieve microseconds */
/* uncomment following macro on platforms without gettimeofday(2) */
/* #define NO_GETTIMEOFDAY */
/* gmtime(3) */
/* C99 does not have reentrant gmtime_r() so it might cause troubles under */
/* multi-threading environment. undef following macro on platforms that */
/* does not have gmtime_r() and localtime_r(). */
/* #define NO_GMTIME_R */
#ifdef _WIN32
#ifdef _MSC_VER
/* Win32 platform do not provide gmtime_r/localtime_r; emulate them using gmtime_s/localtime_s */
#define gmtime_r(tp, tm) ((gmtime_s((tm), (tp)) == 0) ? (tm) : NULL)
#define localtime_r(tp, tm) ((localtime_s((tm), (tp)) == 0) ? (tm) : NULL)
#else
#define NO_GMTIME_R
#endif
#endif
#ifdef __STRICT_ANSI__
/* Strict ANSI (e.g. -std=c99) do not provide gmtime_r/localtime_r */
#define NO_GMTIME_R
#endif
/* asctime(3) */
/* mruby usually use its own implementation of struct tm to string conversion */
/* except when MRB_NO_STDIO is set. In that case, it uses asctime() or asctime_r(). */
/* By default mruby tries to use asctime_r() which is reentrant. */
/* Undef following macro on platforms that does not have asctime_r(). */
/* #define NO_ASCTIME_R */
/* timegm(3) */
/* mktime() creates tm structure for localtime; timegm() is for UTC time */
/* define following macro to use probably faster timegm() on the platform */
/* #define USE_SYSTEM_TIMEGM */
/** end of Time class configuration */
#if (defined(_POSIX_TIMERS) && _POSIX_TIMERS > 0) && defined(CLOCK_REALTIME)
# define USE_CLOCK_GETTIME
#endif
#if !defined(NO_GETTIMEOFDAY)
# if defined(_WIN32) && !defined(USE_CLOCK_GETTIME)
# define WIN32_LEAN_AND_MEAN /* don't include winsock.h */
# include <windows.h>
# define gettimeofday my_gettimeofday
# ifdef _MSC_VER
# define UI64(x) x##ui64
# else
# define UI64(x) x##ull
# endif
typedef long suseconds_t;
# if (!defined __MINGW64__) && (!defined __MINGW32__)
struct timeval {
time_t tv_sec;
suseconds_t tv_usec;
};
# endif
static int
gettimeofday(struct timeval *tv, void *tz)
{
if (tz) {
mrb_assert(0); /* timezone is not supported */
}
if (tv) {
union {
FILETIME ft;
unsigned __int64 u64;
} t;
GetSystemTimeAsFileTime(&t.ft); /* 100 ns intervals since Windows epoch */
t.u64 -= UI64(116444736000000000); /* Unix epoch bias */
t.u64 /= 10; /* to microseconds */
tv->tv_sec = (time_t)(t.u64 / (1000 * 1000));
tv->tv_usec = t.u64 % (1000 * 1000);
}
return 0;
}
# else
# include <sys/time.h>
# endif
#endif
#ifdef NO_GMTIME_R
#define gmtime_r(t,r) gmtime(t)
#define localtime_r(t,r) localtime(t)
#endif
#ifndef USE_SYSTEM_TIMEGM
#define timegm my_timgm
static unsigned int
is_leapyear(unsigned int y)
{
return (y % 4) == 0 && ((y % 100) != 0 || (y % 400) == 0);
}
static time_t
timegm(struct tm *tm)
{
static const unsigned int ndays[2][12] = {
{31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31},
{31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31}
};
time_t r = 0;
int i;
unsigned int *nday = (unsigned int*) ndays[is_leapyear(tm->tm_year+1900)];
static const int epoch_year = 70;
if(tm->tm_year >= epoch_year) {
for (i = epoch_year; i < tm->tm_year; ++i)
r += is_leapyear(i+1900) ? 366*24*60*60 : 365*24*60*60;
} else {
for (i = tm->tm_year; i < epoch_year; ++i)
r -= is_leapyear(i+1900) ? 366*24*60*60 : 365*24*60*60;
}
for (i = 0; i < tm->tm_mon; ++i)
r += nday[i] * 24 * 60 * 60;
r += (tm->tm_mday - 1) * 24 * 60 * 60;
r += tm->tm_hour * 60 * 60;
r += tm->tm_min * 60;
r += tm->tm_sec;
return r;
}
#endif
/* Since we are limited to using ISO C99, this implementation is based
* on time_t. That means the resolution of time is only precise to the
* second level. Also, there are only 2 timezones, namely UTC and LOCAL.
*/
typedef struct mrb_timezone_name {
const char name[8];
size_t len;
} mrb_timezone_name;
static const mrb_timezone_name timezone_names[] = {
{ "none", sizeof("none") - 1 },
{ "UTC", sizeof("UTC") - 1 },
{ "LOCAL", sizeof("LOCAL") - 1 },
};
#ifndef MRB_NO_STDIO
static const char mon_names[12][4] = {
"Jan", "Feb", "Mar", "Apr", "May", "Jun", "Jul", "Aug", "Sep", "Oct", "Nov", "Dec",
};
static const char wday_names[7][4] = {
"Sun", "Mon", "Tue", "Wed", "Thu", "Fri", "Sat",
};
#endif
struct mrb_time {
time_t sec;
time_t usec;
enum mrb_timezone timezone;
struct tm datetime;
};
static const struct mrb_data_type mrb_time_type = { "Time", mrb_free };
#ifndef MRB_NO_FLOAT
void mrb_check_num_exact(mrb_state *mrb, mrb_float num);
typedef mrb_float mrb_sec;
#define mrb_sec_value(mrb, sec) mrb_float_value(mrb, sec)
#else
typedef mrb_int mrb_sec;
#define mrb_sec_value(mrb, sec) mrb_int_value(mrb, sec)
#endif
#define MRB_TIME_T_UINT (~(time_t)0 > 0)
#define MRB_TIME_MIN ( \
MRB_TIME_T_UINT ? 0 : \
(sizeof(time_t) <= 4 ? INT32_MIN : INT64_MIN) \
)
#define MRB_TIME_MAX (time_t)( \
MRB_TIME_T_UINT ? (sizeof(time_t) <= 4 ? UINT32_MAX : UINT64_MAX) : \
(sizeof(time_t) <= 4 ? INT32_MAX : INT64_MAX) \
)
#ifndef MRB_NO_FLOAT
/* return true if time_t is fit in mrb_int */
static mrb_bool
fixable_time_t_p(time_t v)
{
if (MRB_INT_MIN <= MRB_TIME_MIN && MRB_TIME_MAX <= MRB_INT_MAX) return TRUE;
if (v > (time_t)MRB_INT_MAX) return FALSE;
if (MRB_TIME_T_UINT) return TRUE;
if (MRB_INT_MIN > (mrb_int)v) return FALSE;
return TRUE;
}
#endif
static time_t
mrb_to_time_t(mrb_state *mrb, mrb_value obj, time_t *usec)
{
time_t t;
switch (mrb_type(obj)) {
#ifndef MRB_NO_FLOAT
case MRB_TT_FLOAT:
{
mrb_float f = mrb_float(obj);
mrb_check_num_exact(mrb, f);
if (f >= ((mrb_float)MRB_TIME_MAX-1.0) || f < ((mrb_float)MRB_TIME_MIN+1.0)) {
goto out_of_range;
}
if (usec) {
t = (time_t)f;
*usec = (time_t)llround((f - t) * 1.0e+6);
}
else {
t = (time_t)llround(f);
}
}
break;
#endif /* MRB_NO_FLOAT */
default:
case MRB_TT_INTEGER:
{
mrb_int i = mrb_integer(obj);
if ((MRB_INT_MAX > MRB_TIME_MAX && i > 0 && (time_t)i > MRB_TIME_MAX) ||
(0 > MRB_TIME_MIN && MRB_TIME_MIN > MRB_INT_MIN && MRB_TIME_MIN > i)) {
goto out_of_range;
}
t = (time_t)i;
if (usec) { *usec = 0; }
}
break;
}
return t;
out_of_range:
mrb_raisef(mrb, E_ARGUMENT_ERROR, "%v out of Time range", obj);
/* not reached */
if (usec) { *usec = 0; }
return 0;
}
/** Updates the datetime of a mrb_time based on it's timezone and
seconds setting. Returns self on success, NULL of failure.
if `dealloc` is set `true`, it frees `self` on error. */
static struct mrb_time*
time_update_datetime(mrb_state *mrb, struct mrb_time *self, int dealloc)
{
struct tm *aid;
time_t t = self->sec;
if (self->timezone == MRB_TIMEZONE_UTC) {
aid = gmtime_r(&t, &self->datetime);
}
else {
aid = localtime_r(&t, &self->datetime);
}
if (!aid) {
mrb_sec sec = (mrb_sec)t;
if (dealloc) mrb_free(mrb, self);
mrb_raisef(mrb, E_ARGUMENT_ERROR, "%v out of Time range", mrb_sec_value(mrb, sec));
/* not reached */
return NULL;
}
#ifdef NO_GMTIME_R
self->datetime = *aid; /* copy data */
#endif
return self;
}
static mrb_value
mrb_time_wrap(mrb_state *mrb, struct RClass *tc, struct mrb_time *tm)
{
return mrb_obj_value(Data_Wrap_Struct(mrb, tc, &mrb_time_type, tm));
}
/* Allocates a mrb_time object and initializes it. */
static struct mrb_time*
time_alloc_time(mrb_state *mrb, time_t sec, time_t usec, enum mrb_timezone timezone)
{
struct mrb_time *tm;
tm = (struct mrb_time *)mrb_malloc(mrb, sizeof(struct mrb_time));
tm->sec = sec;
tm->usec = usec;
if (MRB_TIME_T_UINT && tm->usec < 0) {
long sec2 = (long)NDIV(tm->usec,1000000); /* negative div */
tm->usec -= sec2 * 1000000;
tm->sec += sec2;
}
else if (tm->usec >= 1000000) {
long sec2 = (long)(tm->usec / 1000000);
tm->usec -= sec2 * 1000000;
tm->sec += sec2;
}
tm->timezone = timezone;
time_update_datetime(mrb, tm, TRUE);
return tm;
}
static struct mrb_time*
time_alloc(mrb_state *mrb, mrb_value sec, mrb_value usec, enum mrb_timezone timezone)
{
time_t tsec, tusec;
tsec = mrb_to_time_t(mrb, sec, &tusec);
tusec += mrb_to_time_t(mrb, usec, NULL);
return time_alloc_time(mrb, tsec, tusec, timezone);
}
static mrb_value
mrb_time_make_time(mrb_state *mrb, struct RClass *c, time_t sec, time_t usec, enum mrb_timezone timezone)
{
return mrb_time_wrap(mrb, c, time_alloc_time(mrb, sec, usec, timezone));
}
static mrb_value
mrb_time_make(mrb_state *mrb, struct RClass *c, mrb_value sec, mrb_value usec, enum mrb_timezone timezone)
{
return mrb_time_wrap(mrb, c, time_alloc(mrb, sec, usec, timezone));
}
static struct mrb_time*
current_mrb_time(mrb_state *mrb)
{
struct mrb_time tmzero = {0};
struct mrb_time *tm;
time_t sec, usec;
#if defined(TIME_UTC) && !defined(__ANDROID__)
{
struct timespec ts;
timespec_get(&ts, TIME_UTC);
sec = ts.tv_sec;
usec = ts.tv_nsec / 1000;
}
#elif defined(USE_CLOCK_GETTIME)
{
struct timespec ts;
clock_gettime(CLOCK_REALTIME, &ts);
sec = ts.tv_sec;
usec = ts.tv_nsec / 1000;
}
#elif defined(NO_GETTIMEOFDAY)
{
static time_t last_sec = 0, last_usec = 0;
sec = time(NULL);
if (sec != last_sec) {
last_sec = sec;
last_usec = 0;
}
else {
/* add 1 usec to differentiate two times */
last_usec += 1;
}
usec = last_usec;
}
#else
{
struct timeval tv;
gettimeofday(&tv, NULL);
sec = tv.tv_sec;
usec = tv.tv_usec;
}
#endif
tm = (struct mrb_time *)mrb_malloc(mrb, sizeof(*tm));
*tm = tmzero;
tm->sec = sec; tm->usec = usec;
tm->timezone = MRB_TIMEZONE_LOCAL;
time_update_datetime(mrb, tm, TRUE);
return tm;
}
/* Allocates a new Time object with given millis value. */
static mrb_value
mrb_time_now(mrb_state *mrb, mrb_value self)
{
return mrb_time_wrap(mrb, mrb_class_ptr(self), current_mrb_time(mrb));
}
MRB_API mrb_value
mrb_time_at(mrb_state *mrb, time_t sec, time_t usec, enum mrb_timezone zone)
{
return mrb_time_make_time(mrb, mrb_class_get_id(mrb, MRB_SYM(Time)), sec, usec, zone);
}
/* 15.2.19.6.1 */
/* Creates an instance of time at the given time in seconds, etc. */
static mrb_value
mrb_time_at_m(mrb_state *mrb, mrb_value self)
{
mrb_value sec;
mrb_value usec = mrb_fixnum_value(0);
mrb_get_args(mrb, "o|o", &sec, &usec);
return mrb_time_make(mrb, mrb_class_ptr(self), sec, usec, MRB_TIMEZONE_LOCAL);
}
static struct mrb_time*
time_mktime(mrb_state *mrb, mrb_int ayear, mrb_int amonth, mrb_int aday,
mrb_int ahour, mrb_int amin, mrb_int asec, mrb_int ausec,
enum mrb_timezone timezone)
{
time_t nowsecs;
struct tm nowtime = { 0 };
#if MRB_INT_MAX > INT_MAX
#define OUTINT(x) (((MRB_TIME_T_UINT ? 0 : INT_MIN) > (x)) || (x) > INT_MAX)
#else
#define OUTINT(x) 0
#endif
if (OUTINT(ayear-1900) ||
amonth < 1 || amonth > 12 ||
aday < 1 || aday > 31 ||
ahour < 0 || ahour > 24 ||
(ahour == 24 && (amin > 0 || asec > 0)) ||
amin < 0 || amin > 59 ||
asec < 0 || asec > 60)
mrb_raise(mrb, E_ARGUMENT_ERROR, "argument out of range");
nowtime.tm_year = (int)(ayear - 1900);
nowtime.tm_mon = (int)(amonth - 1);
nowtime.tm_mday = (int)aday;
nowtime.tm_hour = (int)ahour;
nowtime.tm_min = (int)amin;
nowtime.tm_sec = (int)asec;
nowtime.tm_isdst = -1;
if (timezone == MRB_TIMEZONE_UTC) {
nowsecs = timegm(&nowtime);
}
else {
nowsecs = mktime(&nowtime);
}
if (nowsecs == (time_t)-1) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "Not a valid time");
}
return time_alloc_time(mrb, nowsecs, ausec, timezone);
}
/* 15.2.19.6.2 */
/* Creates an instance of time at the given time in UTC. */
static mrb_value
mrb_time_gm(mrb_state *mrb, mrb_value self)
{
mrb_int ayear = 0, amonth = 1, aday = 1, ahour = 0, amin = 0, asec = 0, ausec = 0;
mrb_get_args(mrb, "i|iiiiii",
&ayear, &amonth, &aday, &ahour, &amin, &asec, &ausec);
return mrb_time_wrap(mrb, mrb_class_ptr(self),
time_mktime(mrb, ayear, amonth, aday, ahour, amin, asec, ausec, MRB_TIMEZONE_UTC));
}
/* 15.2.19.6.3 */
/* Creates an instance of time at the given time in local time zone. */
static mrb_value
mrb_time_local(mrb_state *mrb, mrb_value self)
{
mrb_int ayear = 0, amonth = 1, aday = 1, ahour = 0, amin = 0, asec = 0, ausec = 0;
mrb_get_args(mrb, "i|iiiiii",
&ayear, &amonth, &aday, &ahour, &amin, &asec, &ausec);
return mrb_time_wrap(mrb, mrb_class_ptr(self),
time_mktime(mrb, ayear, amonth, aday, ahour, amin, asec, ausec, MRB_TIMEZONE_LOCAL));
}
static struct mrb_time*
time_get_ptr(mrb_state *mrb, mrb_value time)
{
struct mrb_time *tm;
tm = DATA_GET_PTR(mrb, time, &mrb_time_type, struct mrb_time);
if (!tm) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "uninitialized time");
}
return tm;
}
static mrb_value
mrb_time_eq(mrb_state *mrb, mrb_value self)
{
mrb_value other = mrb_get_arg1(mrb);
struct mrb_time *tm1, *tm2;
mrb_bool eq_p;
tm1 = DATA_GET_PTR(mrb, self, &mrb_time_type, struct mrb_time);
tm2 = DATA_CHECK_GET_PTR(mrb, other, &mrb_time_type, struct mrb_time);
eq_p = tm1 && tm2 && tm1->sec == tm2->sec && tm1->usec == tm2->usec;
return mrb_bool_value(eq_p);
}
static mrb_value
mrb_time_cmp(mrb_state *mrb, mrb_value self)
{
mrb_value other = mrb_get_arg1(mrb);
struct mrb_time *tm1, *tm2;
tm1 = DATA_GET_PTR(mrb, self, &mrb_time_type, struct mrb_time);
tm2 = DATA_CHECK_GET_PTR(mrb, other, &mrb_time_type, struct mrb_time);
if (!tm1 || !tm2) return mrb_nil_value();
if (tm1->sec > tm2->sec) {
return mrb_fixnum_value(1);
}
else if (tm1->sec < tm2->sec) {
return mrb_fixnum_value(-1);
}
/* tm1->sec == tm2->sec */
if (tm1->usec > tm2->usec) {
return mrb_fixnum_value(1);
}
else if (tm1->usec < tm2->usec) {
return mrb_fixnum_value(-1);
}
return mrb_fixnum_value(0);
}
static mrb_noreturn void
int_overflow(mrb_state *mrb, const char *reason)
{
mrb_raisef(mrb, E_RANGE_ERROR, "time_t overflow in Time %s", reason);
}
static mrb_value
mrb_time_plus(mrb_state *mrb, mrb_value self)
{
mrb_value o = mrb_get_arg1(mrb);
struct mrb_time *tm;
time_t sec, usec;
tm = time_get_ptr(mrb, self);
sec = mrb_to_time_t(mrb, o, &usec);
#ifdef MRB_HAVE_TYPE_GENERIC_CHECKED_ARITHMETIC_BUILTINS
if (__builtin_add_overflow(tm->sec, sec, &sec)) {
int_overflow(mrb, "addition");
}
#else
if (sec >= 0) {
if (tm->sec > MRB_TIME_MAX - sec) {
int_overflow(mrb, "addition");
}
}
else {
if (tm->sec < MRB_TIME_MIN - sec) {
int_overflow(mrb, "addition");
}
}
sec = tm->sec + sec;
#endif
return mrb_time_make_time(mrb, mrb_obj_class(mrb, self), sec, tm->usec+usec, tm->timezone);
}
static mrb_value
mrb_time_minus(mrb_state *mrb, mrb_value self)
{
mrb_value other = mrb_get_arg1(mrb);
struct mrb_time *tm, *tm2;
tm = time_get_ptr(mrb, self);
tm2 = DATA_CHECK_GET_PTR(mrb, other, &mrb_time_type, struct mrb_time);
if (tm2) {
#ifndef MRB_NO_FLOAT
mrb_float f;
f = (mrb_sec)(tm->sec - tm2->sec)
+ (mrb_sec)(tm->usec - tm2->usec) / 1.0e6;
return mrb_float_value(mrb, f);
#else
mrb_int f;
f = tm->sec - tm2->sec;
if (tm->usec < tm2->usec) f--;
return mrb_int_value(mrb, f);
#endif
}
else {
time_t sec, usec;
sec = mrb_to_time_t(mrb, other, &usec);
#ifdef MRB_HAVE_TYPE_GENERIC_CHECKED_ARITHMETIC_BUILTINS
if (__builtin_sub_overflow(tm->sec, sec, &sec)) {
int_overflow(mrb, "subtraction");
}
#else
if (sec >= 0) {
if (tm->sec < MRB_TIME_MIN + sec) {
int_overflow(mrb, "subtraction");
}
}
else {
if (tm->sec > MRB_TIME_MAX + sec) {
int_overflow(mrb, "subtraction");
}
}
sec = tm->sec - sec;
#endif
return mrb_time_make_time(mrb, mrb_obj_class(mrb, self), sec, tm->usec-usec, tm->timezone);
}
}
/* 15.2.19.7.30 */
/* Returns week day number of time. */
static mrb_value
mrb_time_wday(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_fixnum_value(tm->datetime.tm_wday);
}
/* 15.2.19.7.31 */
/* Returns year day number of time. */
static mrb_value
mrb_time_yday(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_fixnum_value(tm->datetime.tm_yday + 1);
}
/* 15.2.19.7.32 */
/* Returns year of time. */
static mrb_value
mrb_time_year(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_fixnum_value(tm->datetime.tm_year + 1900);
}
/* 15.2.19.7.33 */
/* Returns name of time's timezone. */
static mrb_value
mrb_time_zone(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
if (tm->timezone <= MRB_TIMEZONE_NONE) return mrb_nil_value();
if (tm->timezone >= MRB_TIMEZONE_LAST) return mrb_nil_value();
return mrb_str_new_static(mrb,
timezone_names[tm->timezone].name,
timezone_names[tm->timezone].len);
}
/* 15.2.19.7.4 */
/* Returns a string that describes the time. */
static mrb_value
mrb_time_asctime(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm = time_get_ptr(mrb, self);
struct tm *d = &tm->datetime;
int len;
#if defined(MRB_NO_STDIO)
# ifdef NO_ASCTIME_R
char *buf = asctime(d);
# else
char buf[32], *s;
s = asctime_r(d, buf);
# endif
len = strlen(buf)-1; /* truncate the last newline */
#else
char buf[32];
len = snprintf(buf, sizeof(buf), "%s %s %2d %02d:%02d:%02d %.4d",
wday_names[d->tm_wday], mon_names[d->tm_mon], d->tm_mday,
d->tm_hour, d->tm_min, d->tm_sec,
d->tm_year + 1900);
#endif
return mrb_str_new(mrb, buf, len);
}
/* 15.2.19.7.6 */
/* Returns the day in the month of the time. */
static mrb_value
mrb_time_day(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_fixnum_value(tm->datetime.tm_mday);
}
/* 15.2.19.7.7 */
/* Returns true if daylight saving was applied for this time. */
static mrb_value
mrb_time_dst_p(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_bool_value(tm->datetime.tm_isdst);
}
/* 15.2.19.7.8 */
/* 15.2.19.7.10 */
/* Returns the Time object of the UTC(GMT) timezone. */
static mrb_value
mrb_time_getutc(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm, *tm2;
tm = time_get_ptr(mrb, self);
tm2 = (struct mrb_time *)mrb_malloc(mrb, sizeof(*tm));
*tm2 = *tm;
tm2->timezone = MRB_TIMEZONE_UTC;
time_update_datetime(mrb, tm2, TRUE);
return mrb_time_wrap(mrb, mrb_obj_class(mrb, self), tm2);
}
/* 15.2.19.7.9 */
/* Returns the Time object of the LOCAL timezone. */
static mrb_value
mrb_time_getlocal(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm, *tm2;
tm = time_get_ptr(mrb, self);
tm2 = (struct mrb_time *)mrb_malloc(mrb, sizeof(*tm));
*tm2 = *tm;
tm2->timezone = MRB_TIMEZONE_LOCAL;
time_update_datetime(mrb, tm2, TRUE);
return mrb_time_wrap(mrb, mrb_obj_class(mrb, self), tm2);
}
/* 15.2.19.7.15 */
/* Returns hour of time. */
static mrb_value
mrb_time_hour(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_fixnum_value(tm->datetime.tm_hour);
}
/* 15.2.19.7.16 */
/* Initializes a time by setting the amount of milliseconds since the epoch.*/
static mrb_value
mrb_time_initialize(mrb_state *mrb, mrb_value self)
{
mrb_int ayear = 0, amonth = 1, aday = 1, ahour = 0,
amin = 0, asec = 0, ausec = 0;
mrb_int n;
struct mrb_time *tm;
n = mrb_get_args(mrb, "|iiiiiii",
&ayear, &amonth, &aday, &ahour, &amin, &asec, &ausec);
tm = (struct mrb_time*)DATA_PTR(self);
if (tm) {
mrb_free(mrb, tm);
}
mrb_data_init(self, NULL, &mrb_time_type);
if (n == 0) {
tm = current_mrb_time(mrb);
}
else {
tm = time_mktime(mrb, ayear, amonth, aday, ahour, amin, asec, ausec, MRB_TIMEZONE_LOCAL);
}
mrb_data_init(self, tm, &mrb_time_type);
return self;
}
/* 15.2.19.7.17(x) */
/* Initializes a copy of this time object. */
static mrb_value
mrb_time_initialize_copy(mrb_state *mrb, mrb_value copy)
{
mrb_value src = mrb_get_arg1(mrb);
struct mrb_time *t1, *t2;
if (mrb_obj_equal(mrb, copy, src)) return copy;
if (!mrb_obj_is_instance_of(mrb, src, mrb_obj_class(mrb, copy))) {
mrb_raise(mrb, E_TYPE_ERROR, "wrong argument class");
}
t1 = (struct mrb_time *)DATA_PTR(copy);
t2 = (struct mrb_time *)DATA_PTR(src);
if (!t2) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "uninitialized time");
}
if (!t1) {
t1 = (struct mrb_time *)mrb_malloc(mrb, sizeof(struct mrb_time));
mrb_data_init(copy, t1, &mrb_time_type);
}
*t1 = *t2;
return copy;
}
/* 15.2.19.7.18 */
/* Sets the timezone attribute of the Time object to LOCAL. */
static mrb_value
mrb_time_localtime(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
tm->timezone = MRB_TIMEZONE_LOCAL;
time_update_datetime(mrb, tm, FALSE);
return self;
}
/* 15.2.19.7.19 */
/* Returns day of month of time. */
static mrb_value
mrb_time_mday(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_fixnum_value(tm->datetime.tm_mday);
}
/* 15.2.19.7.20 */
/* Returns minutes of time. */
static mrb_value
mrb_time_min(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_fixnum_value(tm->datetime.tm_min);
}
/* 15.2.19.7.21 and 15.2.19.7.22 */
/* Returns month of time. */
static mrb_value
mrb_time_mon(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_fixnum_value(tm->datetime.tm_mon + 1);
}
/* 15.2.19.7.23 */
/* Returns seconds in minute of time. */
static mrb_value
mrb_time_sec(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_fixnum_value(tm->datetime.tm_sec);
}
#ifndef MRB_NO_FLOAT
/* 15.2.19.7.24 */
/* Returns a Float with the time since the epoch in seconds. */
static mrb_value
mrb_time_to_f(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_float_value(mrb, (mrb_float)tm->sec + (mrb_float)tm->usec/1.0e6);
}
#endif
/* 15.2.19.7.25 */
/* Returns an Integer with the time since the epoch in seconds. */
static mrb_value
mrb_time_to_i(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
#ifndef MRB_NO_FLOAT
if (!fixable_time_t_p(tm->sec)) {
return mrb_float_value(mrb, (mrb_float)tm->sec);
}
#endif
return mrb_int_value(mrb, (mrb_int)tm->sec);
}
/* 15.2.19.7.26 */
/* Returns an Integer with the time since the epoch in microseconds. */
static mrb_value
mrb_time_usec(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_fixnum_value((mrb_int)tm->usec);
}
/* 15.2.19.7.27 */
/* Sets the timezone attribute of the Time object to UTC. */
static mrb_value
mrb_time_utc(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
tm->timezone = MRB_TIMEZONE_UTC;
time_update_datetime(mrb, tm, FALSE);
return self;
}
/* 15.2.19.7.28 */
/* Returns true if this time is in the UTC timezone false if not. */
static mrb_value
mrb_time_utc_p(mrb_state *mrb, mrb_value self)
{
struct mrb_time *tm;
tm = time_get_ptr(mrb, self);
return mrb_bool_value(tm->timezone == MRB_TIMEZONE_UTC);
}
static size_t
time_to_s_utc(mrb_state *mrb, struct mrb_time *tm, char *buf, size_t buf_len)
{
return strftime(buf, buf_len, TO_S_FMT "UTC", &tm->datetime);
}
static size_t
time_to_s_local(mrb_state *mrb, struct mrb_time *tm, char *buf, size_t buf_len)
{
#if defined(_MSC_VER) && _MSC_VER < 1900 || defined(__MINGW64__) || defined(__MINGW32__)
struct tm datetime = {0};
time_t utc_sec = timegm(&tm->datetime);
size_t len;
int offset;
if (utc_sec == (time_t)-1) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "Not a valid time");
}
offset = abs((int)(utc_sec - tm->sec) / 60);
datetime.tm_year = 100;
datetime.tm_hour = offset / 60;
datetime.tm_min = offset % 60;
len = strftime(buf, buf_len, TO_S_FMT, &tm->datetime);
buf[len++] = utc_sec < tm->sec ? '-' : '+';
return len + strftime(buf + len, buf_len - len, "%H%M", &datetime);
#else
return strftime(buf, buf_len, TO_S_FMT "%z", &tm->datetime);
#endif
}
static mrb_value
mrb_time_to_s(mrb_state *mrb, mrb_value self)
{
char buf[64];
struct mrb_time *tm = time_get_ptr(mrb, self);
mrb_bool utc = tm->timezone == MRB_TIMEZONE_UTC;
size_t len = (utc ? time_to_s_utc : time_to_s_local)(mrb, tm, buf, sizeof(buf));
mrb_value str = mrb_str_new(mrb, buf, len);
RSTR_SET_ASCII_FLAG(mrb_str_ptr(str));
return str;
}
void
mrb_mruby_time_gem_init(mrb_state* mrb)
{
struct RClass *tc;
/* ISO 15.2.19.2 */
tc = mrb_define_class(mrb, "Time", mrb->object_class);
MRB_SET_INSTANCE_TT(tc, MRB_TT_DATA);
mrb_include_module(mrb, tc, mrb_module_get(mrb, "Comparable"));
mrb_define_class_method(mrb, tc, "at", mrb_time_at_m, MRB_ARGS_ARG(1, 1)); /* 15.2.19.6.1 */
mrb_define_class_method(mrb, tc, "gm", mrb_time_gm, MRB_ARGS_ARG(1,6)); /* 15.2.19.6.2 */
mrb_define_class_method(mrb, tc, "local", mrb_time_local, MRB_ARGS_ARG(1,6)); /* 15.2.19.6.3 */
mrb_define_class_method(mrb, tc, "mktime", mrb_time_local, MRB_ARGS_ARG(1,6));/* 15.2.19.6.4 */
mrb_define_class_method(mrb, tc, "now", mrb_time_now, MRB_ARGS_NONE()); /* 15.2.19.6.5 */
mrb_define_class_method(mrb, tc, "utc", mrb_time_gm, MRB_ARGS_ARG(1,6)); /* 15.2.19.6.6 */
mrb_define_method(mrb, tc, "==" , mrb_time_eq , MRB_ARGS_REQ(1));
mrb_define_method(mrb, tc, "<=>" , mrb_time_cmp , MRB_ARGS_REQ(1)); /* 15.2.19.7.1 */
mrb_define_method(mrb, tc, "+" , mrb_time_plus , MRB_ARGS_REQ(1)); /* 15.2.19.7.2 */
mrb_define_method(mrb, tc, "-" , mrb_time_minus , MRB_ARGS_REQ(1)); /* 15.2.19.7.3 */
mrb_define_method(mrb, tc, "to_s" , mrb_time_to_s , MRB_ARGS_NONE());
mrb_define_method(mrb, tc, "inspect", mrb_time_to_s , MRB_ARGS_NONE());
mrb_define_method(mrb, tc, "asctime", mrb_time_asctime, MRB_ARGS_NONE()); /* 15.2.19.7.4 */
mrb_define_method(mrb, tc, "ctime" , mrb_time_asctime, MRB_ARGS_NONE()); /* 15.2.19.7.5 */
mrb_define_method(mrb, tc, "day" , mrb_time_day , MRB_ARGS_NONE()); /* 15.2.19.7.6 */
mrb_define_method(mrb, tc, "dst?" , mrb_time_dst_p , MRB_ARGS_NONE()); /* 15.2.19.7.7 */
mrb_define_method(mrb, tc, "getgm" , mrb_time_getutc , MRB_ARGS_NONE()); /* 15.2.19.7.8 */
mrb_define_method(mrb, tc, "getlocal",mrb_time_getlocal,MRB_ARGS_NONE()); /* 15.2.19.7.9 */
mrb_define_method(mrb, tc, "getutc" , mrb_time_getutc , MRB_ARGS_NONE()); /* 15.2.19.7.10 */
mrb_define_method(mrb, tc, "gmt?" , mrb_time_utc_p , MRB_ARGS_NONE()); /* 15.2.19.7.11 */
mrb_define_method(mrb, tc, "gmtime" , mrb_time_utc , MRB_ARGS_NONE()); /* 15.2.19.7.13 */
mrb_define_method(mrb, tc, "hour" , mrb_time_hour, MRB_ARGS_NONE()); /* 15.2.19.7.15 */
mrb_define_method(mrb, tc, "localtime", mrb_time_localtime, MRB_ARGS_NONE()); /* 15.2.19.7.18 */
mrb_define_method(mrb, tc, "mday" , mrb_time_mday, MRB_ARGS_NONE()); /* 15.2.19.7.19 */
mrb_define_method(mrb, tc, "min" , mrb_time_min, MRB_ARGS_NONE()); /* 15.2.19.7.20 */
mrb_define_method(mrb, tc, "mon" , mrb_time_mon, MRB_ARGS_NONE()); /* 15.2.19.7.21 */
mrb_define_method(mrb, tc, "month", mrb_time_mon, MRB_ARGS_NONE()); /* 15.2.19.7.22 */
mrb_define_method(mrb, tc, "sec" , mrb_time_sec, MRB_ARGS_NONE()); /* 15.2.19.7.23 */
mrb_define_method(mrb, tc, "to_i", mrb_time_to_i, MRB_ARGS_NONE()); /* 15.2.19.7.25 */
#ifndef MRB_NO_FLOAT
mrb_define_method(mrb, tc, "to_f", mrb_time_to_f, MRB_ARGS_NONE()); /* 15.2.19.7.24 */
#endif
mrb_define_method(mrb, tc, "usec", mrb_time_usec, MRB_ARGS_NONE()); /* 15.2.19.7.26 */
mrb_define_method(mrb, tc, "utc" , mrb_time_utc, MRB_ARGS_NONE()); /* 15.2.19.7.27 */
mrb_define_method(mrb, tc, "utc?", mrb_time_utc_p,MRB_ARGS_NONE()); /* 15.2.19.7.28 */
mrb_define_method(mrb, tc, "wday", mrb_time_wday, MRB_ARGS_NONE()); /* 15.2.19.7.30 */
mrb_define_method(mrb, tc, "yday", mrb_time_yday, MRB_ARGS_NONE()); /* 15.2.19.7.31 */
mrb_define_method(mrb, tc, "year", mrb_time_year, MRB_ARGS_NONE()); /* 15.2.19.7.32 */
mrb_define_method(mrb, tc, "zone", mrb_time_zone, MRB_ARGS_NONE()); /* 15.2.19.7.33 */
mrb_define_method(mrb, tc, "initialize", mrb_time_initialize, MRB_ARGS_REQ(1)); /* 15.2.19.7.16 */
mrb_define_method(mrb, tc, "initialize_copy", mrb_time_initialize_copy, MRB_ARGS_REQ(1)); /* 15.2.19.7.17 */
/*
methods not available:
gmt_offset(15.2.19.7.12)
gmtoff(15.2.19.7.14)
utc_offset(15.2.19.7.29)
*/
}
void
mrb_mruby_time_gem_final(mrb_state* mrb)
{
}