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/**********************************************************************
time.c -
$Author$
created at: Tue Dec 28 14:31:59 JST 1993
* encoding.c: provide basic features for M17N. * parse.y: encoding aware parsing. * parse.y (pragma_encoding): encoding specification pragma. * parse.y (rb_intern3): encoding specified symbols. * string.c (rb_str_length): length based on characters. for older behavior, bytesize method added. * string.c (rb_str_index_m): index based on characters. rindex as well. * string.c (succ_char): encoding aware succeeding string. * string.c (rb_str_reverse): reverse based on characters. * string.c (rb_str_inspect): encoding aware string description. * string.c (rb_str_upcase_bang): encoding aware case conversion. downcase, capitalize, swapcase as well. * string.c (rb_str_tr_bang): tr based on characters. delete, squeeze, tr_s, count as well. * string.c (rb_str_split_m): split based on characters. * string.c (rb_str_each_line): encoding aware each_line. * string.c (rb_str_each_char): added. iteration based on characters. * string.c (rb_str_strip_bang): encoding aware whitespace stripping. lstrip, rstrip as well. * string.c (rb_str_justify): encoding aware justifying (ljust, rjust, center). * string.c (str_encoding): get encoding attribute from a string. * re.c (rb_reg_initialize): encoding aware regular expression * sprintf.c (rb_str_format): formatting (i.e. length count) based on characters. * io.c (rb_io_getc): getc to return one-character string. for older behavior, getbyte method added. * ext/stringio/stringio.c (strio_getc): ditto. * io.c (rb_io_ungetc): allow pushing arbitrary string at the current reading point. * ext/stringio/stringio.c (strio_ungetc): ditto. * ext/strscan/strscan.c: encoding support. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@13261 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2007-08-24 23:29:39 -04:00
Copyright (C) 1993-2007 Yukihiro Matsumoto
**********************************************************************/
#include "internal.h"
#include <sys/types.h>
#include <time.h>
#include <errno.h>
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#include <float.h>
#include <math.h>
#ifdef HAVE_STRINGS_H
#include <strings.h>
#endif
#if defined(HAVE_SYS_TIME_H)
#include <sys/time.h>
#endif
#include "timev.h"
static ID id_divmod, id_mul, id_submicro, id_nano_num, id_nano_den, id_offset, id_zone;
static ID id_eq, id_ne, id_quo, id_div, id_cmp;
#define NDIV(x,y) (-(-((x)+1)/(y))-1)
#define NMOD(x,y) ((y)-(-((x)+1)%(y))-1)
#define DIV(n,d) ((n)<0 ? NDIV((n),(d)) : (n)/(d))
#define MOD(n,d) ((n)<0 ? NMOD((n),(d)) : (n)%(d))
#define VTM_WDAY_INITVAL (7)
#define VTM_ISDST_INITVAL (3)
#define TO_GMT_INITVAL (3)
static int
eq(VALUE x, VALUE y)
{
if (FIXNUM_P(x) && FIXNUM_P(y)) {
return x == y;
}
return RTEST(rb_funcall(x, id_eq, 1, y));
}
static int
cmp(VALUE x, VALUE y)
{
if (FIXNUM_P(x) && FIXNUM_P(y)) {
if ((long)x < (long)y)
return -1;
if ((long)x > (long)y)
return 1;
return 0;
}
return rb_cmpint(rb_funcall(x, id_cmp, 1, y), x, y);
}
#define ne(x,y) (!eq((x),(y)))
#define lt(x,y) (cmp((x),(y)) < 0)
#define gt(x,y) (cmp((x),(y)) > 0)
#define le(x,y) (cmp((x),(y)) <= 0)
#define ge(x,y) (cmp((x),(y)) >= 0)
static VALUE
add(VALUE x, VALUE y)
{
if (FIXNUM_P(x) && FIXNUM_P(y)) {
long l = FIX2LONG(x) + FIX2LONG(y);
if (FIXABLE(l)) return LONG2FIX(l);
return LONG2NUM(l);
}
if (RB_TYPE_P(x, T_BIGNUM)) return rb_big_plus(x, y);
return rb_funcall(x, '+', 1, y);
}
static VALUE
sub(VALUE x, VALUE y)
{
if (FIXNUM_P(x) && FIXNUM_P(y)) {
long l = FIX2LONG(x) - FIX2LONG(y);
if (FIXABLE(l)) return LONG2FIX(l);
return LONG2NUM(l);
}
if (RB_TYPE_P(x, T_BIGNUM)) return rb_big_minus(x, y);
return rb_funcall(x, '-', 1, y);
}
#if !(HAVE_LONG_LONG && SIZEOF_LONG * 2 <= SIZEOF_LONG_LONG)
static int
long_mul(long x, long y, long *z)
{
unsigned long a, b, c;
int s;
if (x == 0 || y == 0) {
*z = 0;
return 1;
}
if (x < 0) {
s = -1;
a = (unsigned long)-x;
}
else {
s = 1;
a = (unsigned long)x;
}
if (y < 0) {
s = -s;
b = (unsigned long)-y;
}
else {
b = (unsigned long)y;
}
if (a <= ULONG_MAX / b) {
c = a * b;
if (s < 0) {
if (c <= (unsigned long)LONG_MAX + 1) {
*z = -(long)c;
return 1;
}
}
else {
if (c <= (unsigned long)LONG_MAX) {
*z = (long)c;
return 1;
}
}
}
return 0;
}
#endif
static VALUE
mul(VALUE x, VALUE y)
{
if (FIXNUM_P(x) && FIXNUM_P(y)) {
#if HAVE_LONG_LONG && SIZEOF_LONG * 2 <= SIZEOF_LONG_LONG
LONG_LONG ll = (LONG_LONG)FIX2LONG(x) * FIX2LONG(y);
if (FIXABLE(ll))
return LONG2FIX(ll);
return LL2NUM(ll);
#else
long z;
if (long_mul(FIX2LONG(x), FIX2LONG(y), &z))
return LONG2NUM(z);
#endif
}
if (RB_TYPE_P(x, T_BIGNUM))
return rb_big_mul(x, y);
return rb_funcall(x, '*', 1, y);
}
#define div(x,y) (rb_funcall((x), id_div, 1, (y)))
static VALUE
mod(VALUE x, VALUE y)
{
switch (TYPE(x)) {
case T_BIGNUM: return rb_big_modulo(x, y);
default: return rb_funcall(x, '%', 1, y);
}
}
#define neg(x) (sub(INT2FIX(0), (x)))
static VALUE
quo(VALUE x, VALUE y)
{
VALUE ret;
if (FIXNUM_P(x) && FIXNUM_P(y)) {
long a, b, c;
a = FIX2LONG(x);
b = FIX2LONG(y);
if (b == 0) rb_num_zerodiv();
c = a / b;
if (c * b == a) {
return LONG2NUM(c);
}
}
ret = rb_funcall(x, id_quo, 1, y);
if (RB_TYPE_P(ret, T_RATIONAL) &&
RRATIONAL(ret)->den == INT2FIX(1)) {
ret = RRATIONAL(ret)->num;
}
return ret;
}
#define mulquo(x,y,z) (((y) == (z)) ? (x) : quo(mul((x),(y)),(z)))
static void
divmodv(VALUE n, VALUE d, VALUE *q, VALUE *r)
{
VALUE tmp, ary;
tmp = rb_funcall(n, id_divmod, 1, d);
ary = rb_check_array_type(tmp);
if (NIL_P(ary)) {
rb_raise(rb_eTypeError, "unexpected divmod result: into %"PRIsVALUE,
rb_obj_class(tmp));
}
*q = rb_ary_entry(ary, 0);
*r = rb_ary_entry(ary, 1);
}
#if SIZEOF_LONG == 8
# define INT64toNUM(x) LONG2NUM(x)
#elif defined(HAVE_LONG_LONG) && SIZEOF_LONG_LONG == 8
# define INT64toNUM(x) LL2NUM(x)
#endif
#if defined(HAVE_UINT64_T) && SIZEOF_LONG*2 <= SIZEOF_UINT64_T
typedef uint64_t uwideint_t;
typedef int64_t wideint_t;
typedef uint64_t WIDEVALUE;
typedef int64_t SIGNED_WIDEVALUE;
# define WIDEVALUE_IS_WIDER 1
# define UWIDEINT_MAX UINT64_MAX
# define WIDEINT_MAX INT64_MAX
# define WIDEINT_MIN INT64_MIN
# define FIXWINT_P(tv) ((tv) & 1)
# define FIXWVtoINT64(tv) RSHIFT((SIGNED_WIDEVALUE)(tv), 1)
# define INT64toFIXWV(wi) ((WIDEVALUE)((SIGNED_WIDEVALUE)(wi) << 1 | FIXNUM_FLAG))
# define FIXWV_MAX (((int64_t)1 << 62) - 1)
# define FIXWV_MIN (-((int64_t)1 << 62))
# define FIXWVABLE(wi) (POSFIXWVABLE(wi) && NEGFIXWVABLE(wi))
# define WINT2FIXWV(i) WIDEVAL_WRAP(INT64toFIXWV(i))
# define FIXWV2WINT(w) FIXWVtoINT64(WIDEVAL_GET(w))
#else
typedef unsigned long uwideint_t;
typedef long wideint_t;
typedef VALUE WIDEVALUE;
typedef SIGNED_VALUE SIGNED_WIDEVALUE;
# define WIDEVALUE_IS_WIDER 0
# define UWIDEINT_MAX ULONG_MAX
# define WIDEINT_MAX LONG_MAX
# define WIDEINT_MIN LONG_MIN
# define FIXWINT_P(v) FIXNUM_P(v)
# define FIXWV_MAX FIXNUM_MAX
# define FIXWV_MIN FIXNUM_MIN
# define FIXWVABLE(i) FIXABLE(i)
# define WINT2FIXWV(i) WIDEVAL_WRAP(LONG2FIX(i))
# define FIXWV2WINT(w) FIX2LONG(WIDEVAL_GET(w))
#endif
#define POSFIXWVABLE(wi) ((wi) < FIXWV_MAX+1)
#define NEGFIXWVABLE(wi) ((wi) >= FIXWV_MIN)
#define FIXWV_P(w) FIXWINT_P(WIDEVAL_GET(w))
/* #define STRUCT_WIDEVAL */
#ifdef STRUCT_WIDEVAL
/* for type checking */
typedef struct {
WIDEVALUE value;
} wideval_t;
static inline wideval_t WIDEVAL_WRAP(WIDEVALUE v) { wideval_t w = { v }; return w; }
# define WIDEVAL_GET(w) ((w).value)
#else
typedef WIDEVALUE wideval_t;
# define WIDEVAL_WRAP(v) (v)
# define WIDEVAL_GET(w) (w)
#endif
#if WIDEVALUE_IS_WIDER
static inline wideval_t
wint2wv(wideint_t wi)
{
if (FIXWVABLE(wi))
return WINT2FIXWV(wi);
else
return WIDEVAL_WRAP(INT64toNUM(wi));
}
# define WINT2WV(wi) wint2wv(wi)
#else
# define WINT2WV(wi) WIDEVAL_WRAP(LONG2NUM(wi))
#endif
static inline VALUE
w2v(wideval_t w)
{
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(w))
return INT64toNUM(FIXWV2WINT(w));
return (VALUE)WIDEVAL_GET(w);
#else
return WIDEVAL_GET(w);
#endif
}
#if WIDEVALUE_IS_WIDER
static wideval_t
v2w_bignum(VALUE v)
{
int sign;
uwideint_t u;
sign = rb_integer_pack(v, &u, 1, sizeof(u), 0,
INTEGER_PACK_NATIVE_BYTE_ORDER);
if (sign == 0)
return WINT2FIXWV(0);
else if (sign == -1) {
if (u <= -FIXWV_MIN)
return WINT2FIXWV(-(wideint_t)u);
}
else if (sign == +1) {
if (u <= FIXWV_MAX)
return WINT2FIXWV((wideint_t)u);
}
return WIDEVAL_WRAP(v);
}
#endif
static inline wideval_t
v2w(VALUE v)
{
if (RB_TYPE_P(v, T_RATIONAL)) {
if (RRATIONAL(v)->den != LONG2FIX(1))
return v;
v = RRATIONAL(v)->num;
}
#if WIDEVALUE_IS_WIDER
if (FIXNUM_P(v)) {
return WIDEVAL_WRAP((WIDEVALUE)(SIGNED_WIDEVALUE)(long)v);
}
else if (RB_TYPE_P(v, T_BIGNUM) &&
rb_absint_size(v, NULL) <= sizeof(WIDEVALUE)) {
return v2w_bignum(v);
}
#endif
return WIDEVAL_WRAP(v);
}
static int
weq(wideval_t wx, wideval_t wy)
{
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(wx) && FIXWV_P(wy)) {
return WIDEVAL_GET(wx) == WIDEVAL_GET(wy);
}
return RTEST(rb_funcall(w2v(wx), id_eq, 1, w2v(wy)));
#else
return eq(WIDEVAL_GET(wx), WIDEVAL_GET(wy));
#endif
}
static int
wcmp(wideval_t wx, wideval_t wy)
{
VALUE x, y;
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(wx) && FIXWV_P(wy)) {
wideint_t a, b;
a = FIXWV2WINT(wx);
b = FIXWV2WINT(wy);
if (a < b)
return -1;
if (a > b)
return 1;
return 0;
}
#endif
x = w2v(wx);
y = w2v(wy);
return rb_cmpint(rb_funcall(x, id_cmp, 1, y), x, y);
}
#define wne(x,y) (!weq((x),(y)))
#define wlt(x,y) (wcmp((x),(y)) < 0)
#define wgt(x,y) (wcmp((x),(y)) > 0)
#define wle(x,y) (wcmp((x),(y)) <= 0)
#define wge(x,y) (wcmp((x),(y)) >= 0)
static wideval_t
wadd(wideval_t wx, wideval_t wy)
{
VALUE x;
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(wx) && FIXWV_P(wy)) {
wideint_t r = FIXWV2WINT(wx) + FIXWV2WINT(wy);
return WINT2WV(r);
}
else
#endif
x = w2v(wx);
if (RB_TYPE_P(x, T_BIGNUM)) return v2w(rb_big_plus(x, w2v(wy)));
return v2w(rb_funcall(x, '+', 1, w2v(wy)));
}
static wideval_t
wsub(wideval_t wx, wideval_t wy)
{
VALUE x;
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(wx) && FIXWV_P(wy)) {
wideint_t r = FIXWV2WINT(wx) - FIXWV2WINT(wy);
return WINT2WV(r);
}
else
#endif
x = w2v(wx);
if (RB_TYPE_P(x, T_BIGNUM)) return v2w(rb_big_minus(x, w2v(wy)));
return v2w(rb_funcall(x, '-', 1, w2v(wy)));
}
static int
wi_mul(wideint_t x, wideint_t y, wideint_t *z)
{
uwideint_t a, b, c;
int s;
if (x == 0 || y == 0) {
*z = 0;
return 1;
}
if (x < 0) {
s = -1;
a = (uwideint_t)-x;
}
else {
s = 1;
a = (uwideint_t)x;
}
if (y < 0) {
s = -s;
b = (uwideint_t)-y;
}
else {
b = (uwideint_t)y;
}
if (a <= UWIDEINT_MAX / b) {
c = a * b;
if (s < 0) {
if (c <= (uwideint_t)WIDEINT_MAX + 1) {
*z = -(wideint_t)c;
return 1;
}
}
else {
if (c <= (uwideint_t)WIDEINT_MAX) {
*z = (wideint_t)c;
return 1;
}
}
}
return 0;
}
static wideval_t
wmul(wideval_t wx, wideval_t wy)
{
VALUE x, z;
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(wx) && FIXWV_P(wy)) {
wideint_t z;
if (wi_mul(FIXWV2WINT(wx), FIXWV2WINT(wy), &z))
return WINT2WV(z);
}
#endif
x = w2v(wx);
if (RB_TYPE_P(x, T_BIGNUM)) return v2w(rb_big_mul(x, w2v(wy)));
z = rb_funcall(x, '*', 1, w2v(wy));
if (RB_TYPE_P(z, T_RATIONAL) && RRATIONAL(z)->den == INT2FIX(1)) {
z = RRATIONAL(z)->num;
}
return v2w(z);
}
static wideval_t
wquo(wideval_t wx, wideval_t wy)
{
VALUE x, y, ret;
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(wx) && FIXWV_P(wy)) {
wideint_t a, b, c;
a = FIXWV2WINT(wx);
b = FIXWV2WINT(wy);
if (b == 0) rb_num_zerodiv();
c = a / b;
if (c * b == a) {
return WINT2WV(c);
}
}
#endif
x = w2v(wx);
y = w2v(wy);
ret = rb_funcall(x, id_quo, 1, y);
if (RB_TYPE_P(ret, T_RATIONAL) &&
RRATIONAL(ret)->den == INT2FIX(1)) {
ret = RRATIONAL(ret)->num;
}
return v2w(ret);
}
#define wmulquo(x,y,z) ((WIDEVAL_GET(y) == WIDEVAL_GET(z)) ? (x) : wquo(wmul((x),(y)),(z)))
#define wmulquoll(x,y,z) (((y) == (z)) ? (x) : wquo(wmul((x),WINT2WV(y)),WINT2WV(z)))
static void
wdivmod(wideval_t wn, wideval_t wd, wideval_t *wq, wideval_t *wr)
{
VALUE tmp, ary;
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(wn) && FIXWV_P(wd)) {
wideint_t n, d, q, r;
d = FIXWV2WINT(wd);
if (d == 0) rb_num_zerodiv();
if (d == 1) {
*wq = wn;
*wr = WINT2FIXWV(0);
return;
}
if (d == -1) {
wideint_t xneg = -FIXWV2WINT(wn);
*wq = WINT2WV(xneg);
*wr = WINT2FIXWV(0);
return;
}
n = FIXWV2WINT(wn);
if (n == 0) {
*wq = WINT2FIXWV(0);
*wr = WINT2FIXWV(0);
return;
}
if (d < 0) {
if (n < 0) {
q = ((-n) / (-d));
r = ((-n) % (-d));
if (r != 0) {
q -= 1;
r += d;
}
}
else { /* 0 < n */
q = -(n / (-d));
r = -(n % (-d));
}
}
else { /* 0 < d */
if (n < 0) {
q = -((-n) / d);
r = -((-n) % d);
if (r != 0) {
q -= 1;
r += d;
}
}
else { /* 0 < n */
q = n / d;
r = n % d;
}
}
*wq = WINT2FIXWV(q);
*wr = WINT2FIXWV(r);
return;
}
#endif
tmp = rb_funcall(w2v(wn), id_divmod, 1, w2v(wd));
ary = rb_check_array_type(tmp);
if (NIL_P(ary)) {
rb_raise(rb_eTypeError, "unexpected divmod result: into %"PRIsVALUE,
rb_obj_class(tmp));
}
*wq = v2w(rb_ary_entry(ary, 0));
*wr = v2w(rb_ary_entry(ary, 1));
}
static void
wmuldivmod(wideval_t wx, wideval_t wy, wideval_t wz, wideval_t *wq, wideval_t *wr)
{
if (WIDEVAL_GET(wy) == WIDEVAL_GET(wz)) {
*wq = wx;
*wr = WINT2FIXWV(0);
return;
}
wdivmod(wmul(wx,wy), wz, wq, wr);
}
static wideval_t
wdiv(wideval_t wx, wideval_t wy)
{
wideval_t q, r;
wdivmod(wx, wy, &q, &r);
return q;
}
static wideval_t
wmod(wideval_t wx, wideval_t wy)
{
wideval_t q, r;
wdivmod(wx, wy, &q, &r);
return r;
}
static VALUE
num_exact(VALUE v)
{
VALUE tmp;
int t;
t = TYPE(v);
switch (t) {
case T_FIXNUM:
case T_BIGNUM:
return v;
case T_RATIONAL:
break;
case T_STRING:
case T_NIL:
goto typeerror;
default:
if ((tmp = rb_check_funcall(v, rb_intern("to_r"), 0, NULL)) != Qundef) {
/* test to_int method availability to reject non-Numeric
* objects such as String, Time, etc which have to_r method. */
if (!rb_respond_to(v, rb_intern("to_int"))) goto typeerror;
v = tmp;
break;
}
if (!NIL_P(tmp = rb_check_to_integer(v, "to_int"))) {
v = tmp;
break;
}
goto typeerror;
}
t = TYPE(v);
switch (t) {
case T_FIXNUM:
case T_BIGNUM:
return v;
case T_RATIONAL:
if (RRATIONAL(v)->den == INT2FIX(1))
v = RRATIONAL(v)->num;
break;
default:
typeerror:
if (NIL_P(v))
rb_raise(rb_eTypeError, "can't convert nil into an exact number");
rb_raise(rb_eTypeError, "can't convert %"PRIsVALUE" into an exact number",
rb_obj_class(v));
}
return v;
}
/* time_t */
static wideval_t
rb_time_magnify(wideval_t w)
{
if (FIXWV_P(w)) {
wideint_t z;
if (wi_mul(FIXWV2WINT(w), TIME_SCALE, &z))
return WINT2WV(z);
}
return wmul(w, WINT2FIXWV(TIME_SCALE));
}
static wideval_t
rb_time_unmagnify(wideval_t w)
{
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(w)) {
wideint_t a, b, c;
a = FIXWV2WINT(w);
b = TIME_SCALE;
c = a / b;
if (c * b == a) {
return WINT2FIXWV(c);
}
}
#endif
return wquo(w, WINT2FIXWV(TIME_SCALE));
}
static VALUE
rb_time_unmagnify_to_float(wideval_t w)
{
VALUE v;
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(w)) {
wideint_t a, b, c;
a = FIXWV2WINT(w);
b = TIME_SCALE;
c = a / b;
if (c * b == a) {
return DBL2NUM((double)c);
}
v = DBL2NUM((double)FIXWV2WINT(w));
return quo(v, DBL2NUM(TIME_SCALE));
}
#endif
v = w2v(w);
if (RB_TYPE_P(v, T_RATIONAL))
return rb_Float(quo(v, INT2FIX(TIME_SCALE)));
else
return quo(v, DBL2NUM(TIME_SCALE));
}
static void
split_second(wideval_t timew, wideval_t *timew_p, VALUE *subsecx_p)
{
wideval_t q, r;
wdivmod(timew, WINT2FIXWV(TIME_SCALE), &q, &r);
*timew_p = q;
*subsecx_p = w2v(r);
}
static wideval_t
timet2wv(time_t t)
{
#if WIDEVALUE_IS_WIDER
if (TIMET_MIN == 0) {
uwideint_t wi = (uwideint_t)t;
if (wi <= FIXWV_MAX) {
return WINT2FIXWV(wi);
}
}
else {
wideint_t wi = (wideint_t)t;
if (FIXWV_MIN <= wi && wi <= FIXWV_MAX) {
return WINT2FIXWV(wi);
}
}
#endif
return v2w(TIMET2NUM(t));
}
#define TIMET2WV(t) timet2wv(t)
static time_t
wv2timet(wideval_t w)
{
#if WIDEVALUE_IS_WIDER
if (FIXWV_P(w)) {
wideint_t wi = FIXWV2WINT(w);
if (TIMET_MIN == 0) {
if (wi < 0)
rb_raise(rb_eRangeError, "negative value to convert into `time_t'");
if (TIMET_MAX < (uwideint_t)wi)
rb_raise(rb_eRangeError, "too big to convert into `time_t'");
}
else {
if (wi < TIMET_MIN || TIMET_MAX < wi)
rb_raise(rb_eRangeError, "too big to convert into `time_t'");
}
return (time_t)wi;
}
#endif
return NUM2TIMET(w2v(w));
}
#define WV2TIMET(t) wv2timet(t)
VALUE rb_cTime;
static VALUE time_utc_offset _((VALUE));
static int obj2int(VALUE obj);
static uint32_t obj2ubits(VALUE obj, size_t bits);
static VALUE obj2vint(VALUE obj);
static uint32_t month_arg(VALUE arg);
static VALUE validate_utc_offset(VALUE utc_offset);
static VALUE validate_zone_name(VALUE zone_name);
static void validate_vtm(struct vtm *vtm);
static uint32_t obj2subsecx(VALUE obj, VALUE *subsecx);
static VALUE time_gmtime(VALUE);
static VALUE time_localtime(VALUE);
static VALUE time_fixoff(VALUE);
static time_t timegm_noleapsecond(struct tm *tm);
static int tmcmp(struct tm *a, struct tm *b);
static int vtmcmp(struct vtm *a, struct vtm *b);
static const char *find_time_t(struct tm *tptr, int utc_p, time_t *tp);
static struct vtm *localtimew(wideval_t timew, struct vtm *result);
static int leap_year_p(long y);
#define leap_year_v_p(y) leap_year_p(NUM2LONG(mod((y), INT2FIX(400))))
#ifdef HAVE_GMTIME_R
#define rb_gmtime_r(t, tm) gmtime_r((t), (tm))
#define rb_localtime_r(t, tm) localtime_r((t), (tm))
#else
static inline struct tm *
rb_gmtime_r(const time_t *tp, struct tm *result)
{
struct tm *t = gmtime(tp);
if (t) *result = *t;
return t;
}
static inline struct tm *
rb_localtime_r(const time_t *tp, struct tm *result)
{
struct tm *t = localtime(tp);
if (t) *result = *t;
return t;
}
#endif
static struct tm *
rb_localtime_r2(const time_t *t, struct tm *result)
{
#if defined __APPLE__ && defined __LP64__
if (*t != (time_t)(int)*t) return NULL;
#endif
result = rb_localtime_r(t, result);
#if defined(HAVE_MKTIME) && defined(LOCALTIME_OVERFLOW_PROBLEM)
if (result) {
long gmtoff1 = 0;
long gmtoff2 = 0;
struct tm tmp = *result;
time_t t2;
# if defined(HAVE_STRUCT_TM_TM_GMTOFF)
gmtoff1 = result->tm_gmtoff;
# endif
t2 = mktime(&tmp);
# if defined(HAVE_STRUCT_TM_TM_GMTOFF)
gmtoff2 = tmp.tm_gmtoff;
# endif
if (*t + gmtoff1 != t2 + gmtoff2)
result = NULL;
}
#endif
return result;
}
#define LOCALTIME(tm, result) (tzset(),rb_localtime_r2((tm), &(result)))
#if !defined(HAVE_STRUCT_TM_TM_GMTOFF)
static struct tm *
rb_gmtime_r2(const time_t *t, struct tm *result)
{
result = rb_gmtime_r(t, result);
#if defined(HAVE_TIMEGM) && defined(LOCALTIME_OVERFLOW_PROBLEM)
if (result) {
struct tm tmp = *result;
time_t t2 = timegm(&tmp);
if (*t != t2)
result = NULL;
}
#endif
return result;
}
# define GMTIME(tm, result) rb_gmtime_r2((tm), &(result))
#endif
static const int common_year_yday_offset[] = {
-1,
-1 + 31,
-1 + 31 + 28,
-1 + 31 + 28 + 31,
-1 + 31 + 28 + 31 + 30,
-1 + 31 + 28 + 31 + 30 + 31,
-1 + 31 + 28 + 31 + 30 + 31 + 30,
-1 + 31 + 28 + 31 + 30 + 31 + 30 + 31,
-1 + 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31,
-1 + 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31 + 30,
-1 + 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31,
-1 + 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31 + 30
/* 1 2 3 4 5 6 7 8 9 10 11 */
};
static const int leap_year_yday_offset[] = {
-1,
-1 + 31,
-1 + 31 + 29,
-1 + 31 + 29 + 31,
-1 + 31 + 29 + 31 + 30,
-1 + 31 + 29 + 31 + 30 + 31,
-1 + 31 + 29 + 31 + 30 + 31 + 30,
-1 + 31 + 29 + 31 + 30 + 31 + 30 + 31,
-1 + 31 + 29 + 31 + 30 + 31 + 30 + 31 + 31,
-1 + 31 + 29 + 31 + 30 + 31 + 30 + 31 + 31 + 30,
-1 + 31 + 29 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31,
-1 + 31 + 29 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31 + 30
/* 1 2 3 4 5 6 7 8 9 10 11 */
};
static const int common_year_days_in_month[] = {
31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31
};
static const int leap_year_days_in_month[] = {
31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31
};
static int
calc_tm_yday(long tm_year, int tm_mon, int tm_mday)
{
int tm_year_mod400 = (int)MOD(tm_year, 400);
int tm_yday = tm_mday;
if (leap_year_p(tm_year_mod400 + 1900))
tm_yday += leap_year_yday_offset[tm_mon];
else
tm_yday += common_year_yday_offset[tm_mon];
return tm_yday;
}
static wideval_t
timegmw_noleapsecond(struct vtm *vtm)
{
VALUE year1900;
VALUE q400, r400;
int year_mod400;
int yday;
long days_in400;
VALUE vdays, ret;
wideval_t wret;
year1900 = sub(vtm->year, INT2FIX(1900));
divmodv(year1900, INT2FIX(400), &q400, &r400);
year_mod400 = NUM2INT(r400);
yday = calc_tm_yday(year_mod400, vtm->mon-1, vtm->mday);
/*
* `Seconds Since the Epoch' in SUSv3:
* tm_sec + tm_min*60 + tm_hour*3600 + tm_yday*86400 +
* (tm_year-70)*31536000 + ((tm_year-69)/4)*86400 -
* ((tm_year-1)/100)*86400 + ((tm_year+299)/400)*86400
*/
ret = LONG2NUM(vtm->sec
+ vtm->min*60
+ vtm->hour*3600);
days_in400 = yday
- 70*365
+ DIV(year_mod400 - 69, 4)
- DIV(year_mod400 - 1, 100)
+ (year_mod400 + 299) / 400;
vdays = LONG2NUM(days_in400);
vdays = add(vdays, mul(q400, INT2FIX(97)));
vdays = add(vdays, mul(year1900, INT2FIX(365)));
wret = wadd(rb_time_magnify(v2w(ret)), wmul(rb_time_magnify(v2w(vdays)), WINT2FIXWV(86400)));
wret = wadd(wret, v2w(vtm->subsecx));
return wret;
}
static st_table *zone_table;
static int
zone_str_update(st_data_t *key, st_data_t *value, st_data_t arg, int existing)
{
const char *s = (const char *)*key;
const char **ret = (const char **)arg;
if (existing) {
*ret = (const char *)*value;
return ST_STOP;
}
*ret = s = strdup(s);
*key = *value = (st_data_t)s;
return ST_CONTINUE;
}
static const char *
zone_str(const char *s)
{
if (!zone_table)
zone_table = st_init_strtable();
st_update(zone_table, (st_data_t)s, zone_str_update, (st_data_t)&s);
return s;
}
static void
gmtimew_noleapsecond(wideval_t timew, struct vtm *vtm)
{
VALUE v;
int i, n, x, y;
const int *yday_offset;
int wday;
VALUE timev;
wideval_t timew2, w, w2;
vtm->isdst = 0;
split_second(timew, &timew2, &vtm->subsecx);
wdivmod(timew2, WINT2FIXWV(86400), &w2, &w);
timev = w2v(w2);
v = w2v(w);
wday = NUM2INT(mod(timev, INT2FIX(7)));
vtm->wday = (wday + 4) % 7;
n = NUM2INT(v);
vtm->sec = n % 60; n = n / 60;
vtm->min = n % 60; n = n / 60;
vtm->hour = n;
/* 97 leap days in the 400 year cycle */
divmodv(timev, INT2FIX(400*365 + 97), &timev, &v);
vtm->year = mul(timev, INT2FIX(400));
/* n is the days in the 400 year cycle.
* the start of the cycle is 1970-01-01. */
n = NUM2INT(v);
y = 1970;
/* 30 years including 7 leap days (1972, 1976, ... 1996),
* 31 days in January 2000 and
* 29 days in February 2000
* from 1970-01-01 to 2000-02-29 */
if (30*365+7+31+29-1 <= n) {
/* 2000-02-29 or after */
if (n < 31*365+8) {
/* 2000-02-29 to 2000-12-31 */
y += 30;
n -= 30*365+7;
goto found;
}
else {
/* 2001-01-01 or after */
n -= 1;
}
}
x = n / (365*100 + 24);
n = n % (365*100 + 24);
y += x * 100;
if (30*365+7+31+29-1 <= n) {
if (n < 31*365+7) {
y += 30;
n -= 30*365+7;
goto found;
}
else
n += 1;
}
x = n / (365*4 + 1);
n = n % (365*4 + 1);
y += x * 4;
if (365*2+31+29-1 <= n) {
if (n < 365*2+366) {
y += 2;
n -= 365*2;
goto found;
}
else
n -= 1;
}
x = n / 365;
n = n % 365;
y += x;
found:
vtm->yday = n+1;
vtm->year = add(vtm->year, INT2NUM(y));
if (leap_year_p(y))
yday_offset = leap_year_yday_offset;
else
yday_offset = common_year_yday_offset;
for (i = 0; i < 12; i++) {
if (yday_offset[i] < n) {
vtm->mon = i+1;
vtm->mday = n - yday_offset[i];
}
else
break;
}
vtm->utc_offset = INT2FIX(0);
vtm->zone = "UTC";
}
static struct tm *
gmtime_with_leapsecond(const time_t *timep, struct tm *result)
{
#if defined(HAVE_STRUCT_TM_TM_GMTOFF)
/* 4.4BSD counts leap seconds only with localtime, not with gmtime. */
struct tm *t;
int sign;
int gmtoff_sec, gmtoff_min, gmtoff_hour, gmtoff_day;
long gmtoff;
t = LOCALTIME(timep, *result);
if (t == NULL)
return NULL;
/* subtract gmtoff */
if (t->tm_gmtoff < 0) {
sign = 1;
gmtoff = -t->tm_gmtoff;
}
else {
sign = -1;
gmtoff = t->tm_gmtoff;
}
gmtoff_sec = (int)(gmtoff % 60);
gmtoff = gmtoff / 60;
gmtoff_min = (int)(gmtoff % 60);
gmtoff = gmtoff / 60;
gmtoff_hour = (int)gmtoff; /* <= 12 */
gmtoff_sec *= sign;
gmtoff_min *= sign;
gmtoff_hour *= sign;
gmtoff_day = 0;
if (gmtoff_sec) {
/* If gmtoff_sec == 0, don't change result->tm_sec.
* It may be 60 which is a leap second. */
result->tm_sec += gmtoff_sec;
if (result->tm_sec < 0) {
result->tm_sec += 60;
gmtoff_min -= 1;
}
if (60 <= result->tm_sec) {
result->tm_sec -= 60;
gmtoff_min += 1;
}
}
if (gmtoff_min) {
result->tm_min += gmtoff_min;
if (result->tm_min < 0) {
result->tm_min += 60;
gmtoff_hour -= 1;
}
if (60 <= result->tm_min) {
result->tm_min -= 60;
gmtoff_hour += 1;
}
}
if (gmtoff_hour) {
result->tm_hour += gmtoff_hour;
if (result->tm_hour < 0) {
result->tm_hour += 24;
gmtoff_day = -1;
}
if (24 <= result->tm_hour) {
result->tm_hour -= 24;
gmtoff_day = 1;
}
}
if (gmtoff_day) {
if (gmtoff_day < 0) {
if (result->tm_yday == 0) {
result->tm_mday = 31;
result->tm_mon = 11; /* December */
result->tm_year--;
result->tm_yday = leap_year_p(result->tm_year + 1900) ? 365 : 364;
}
else if (result->tm_mday == 1) {
const int *days_in_month = leap_year_p(result->tm_year + 1900) ?
leap_year_days_in_month :
common_year_days_in_month;
result->tm_mon--;
result->tm_mday = days_in_month[result->tm_mon];
result->tm_yday--;
}
else {
result->tm_mday--;
result->tm_yday--;
}
result->tm_wday = (result->tm_wday + 6) % 7;
}
else {
int leap = leap_year_p(result->tm_year + 1900);
if (result->tm_yday == (leap ? 365 : 364)) {
result->tm_year++;
result->tm_mon = 0; /* January */
result->tm_mday = 1;
result->tm_yday = 0;
}
else if (result->tm_mday == (leap ? leap_year_days_in_month :
common_year_days_in_month)[result->tm_mon]) {
result->tm_mon++;
result->tm_mday = 1;
result->tm_yday++;
}
else {
result->tm_mday++;
result->tm_yday++;
}
result->tm_wday = (result->tm_wday + 1) % 7;
}
}
result->tm_isdst = 0;
result->tm_gmtoff = 0;
#if defined(HAVE_TM_ZONE)
result->tm_zone = (char *)"UTC";
#endif
return result;
#else
return GMTIME(timep, *result);
#endif
}
static long this_year = 0;
static time_t known_leap_seconds_limit;
static int number_of_leap_seconds_known;
static void
init_leap_second_info(void)
{
/*
* leap seconds are determined by IERS.
* It is announced 6 months before the leap second.
* So no one knows leap seconds in the future after the next year.
*/
if (this_year == 0) {
time_t now;
struct tm *tm, result;
struct vtm vtm;
wideval_t timew;
now = time(NULL);
gmtime(&now);
tm = gmtime_with_leapsecond(&now, &result);
if (!tm) return;
this_year = tm->tm_year;
if (TIMET_MAX - now < (time_t)(366*86400))
known_leap_seconds_limit = TIMET_MAX;
else
known_leap_seconds_limit = now + (time_t)(366*86400);
if (!gmtime_with_leapsecond(&known_leap_seconds_limit, &result))
return;
vtm.year = LONG2NUM(result.tm_year + 1900);
vtm.mon = result.tm_mon + 1;
vtm.mday = result.tm_mday;
vtm.hour = result.tm_hour;
vtm.min = result.tm_min;
vtm.sec = result.tm_sec;
vtm.subsecx = INT2FIX(0);
vtm.utc_offset = INT2FIX(0);
timew = timegmw_noleapsecond(&vtm);
number_of_leap_seconds_known = NUM2INT(w2v(wsub(TIMET2WV(known_leap_seconds_limit), rb_time_unmagnify(timew))));
}
}
static wideval_t
timegmw(struct vtm *vtm)
{
wideval_t timew;
struct tm tm;
time_t t;
const char *errmsg;
/* The first leap second is 1972-06-30 23:59:60 UTC.
* No leap seconds before. */
if (gt(INT2FIX(1972), vtm->year))
return timegmw_noleapsecond(vtm);
init_leap_second_info();
timew = timegmw_noleapsecond(vtm);
if (wlt(rb_time_magnify(TIMET2WV(known_leap_seconds_limit)), timew)) {
return wadd(timew, rb_time_magnify(WINT2WV(number_of_leap_seconds_known)));
}
tm.tm_year = rb_long2int(NUM2LONG(vtm->year) - 1900);
tm.tm_mon = vtm->mon - 1;
tm.tm_mday = vtm->mday;
tm.tm_hour = vtm->hour;
tm.tm_min = vtm->min;
tm.tm_sec = vtm->sec;
tm.tm_isdst = 0;
errmsg = find_time_t(&tm, 1, &t);
if (errmsg)
rb_raise(rb_eArgError, "%s", errmsg);
return wadd(rb_time_magnify(TIMET2WV(t)), v2w(vtm->subsecx));
}
static struct vtm *
gmtimew(wideval_t timew, struct vtm *result)
{
time_t t;
struct tm tm;
VALUE subsecx;
wideval_t timew2;
if (wlt(timew, WINT2FIXWV(0))) {
gmtimew_noleapsecond(timew, result);
return result;
}
init_leap_second_info();
if (wlt(rb_time_magnify(TIMET2WV(known_leap_seconds_limit)), timew)) {
timew = wsub(timew, rb_time_magnify(WINT2WV(number_of_leap_seconds_known)));
gmtimew_noleapsecond(timew, result);
return result;
}
split_second(timew, &timew2, &subsecx);
t = WV2TIMET(timew2);
if (!gmtime_with_leapsecond(&t, &tm))
return NULL;
result->year = LONG2NUM((long)tm.tm_year + 1900);
result->mon = tm.tm_mon + 1;
result->mday = tm.tm_mday;
result->hour = tm.tm_hour;
result->min = tm.tm_min;
result->sec = tm.tm_sec;
result->subsecx = subsecx;
result->utc_offset = INT2FIX(0);
result->wday = tm.tm_wday;
result->yday = tm.tm_yday+1;
result->isdst = tm.tm_isdst;
result->zone = "UTC";
return result;
}
static struct tm *localtime_with_gmtoff_zone(const time_t *t, struct tm *result, long *gmtoff, const char **zone);
/*
* The idea is borrowed from Perl:
* http://web.archive.org/web/20080211114141/http://use.perl.org/articles/08/02/07/197204.shtml
*
* compat_common_month_table is generated by the following program.
* This table finds the last month which starts at the same day of a week.
* The year 2037 is not used because:
* http://bugs.debian.org/cgi-bin/bugreport.cgi?bug=522949
*
* #!/usr/bin/ruby
*
* require 'date'
*
* h = {}
* 2036.downto(2010) {|y|
* 1.upto(12) {|m|
* next if m == 2 && y % 4 == 0
* d = Date.new(y,m,1)
* h[m] ||= {}
* h[m][d.wday] ||= y
* }
* }
*
* 1.upto(12) {|m|
* print "{"
* 0.upto(6) {|w|
* y = h[m][w]
* print " #{y},"
* }
* puts "},"
* }
*
*/
static int compat_common_month_table[12][7] = {
/* Sun Mon Tue Wed Thu Fri Sat */
{ 2034, 2035, 2036, 2031, 2032, 2027, 2033 }, /* January */
{ 2026, 2027, 2033, 2034, 2035, 2030, 2031 }, /* February */
{ 2026, 2032, 2033, 2034, 2035, 2030, 2036 }, /* March */
{ 2035, 2030, 2036, 2026, 2032, 2033, 2034 }, /* April */
{ 2033, 2034, 2035, 2030, 2036, 2026, 2032 }, /* May */
{ 2036, 2026, 2032, 2033, 2034, 2035, 2030 }, /* June */
{ 2035, 2030, 2036, 2026, 2032, 2033, 2034 }, /* July */
{ 2032, 2033, 2034, 2035, 2030, 2036, 2026 }, /* August */
{ 2030, 2036, 2026, 2032, 2033, 2034, 2035 }, /* September */
{ 2034, 2035, 2030, 2036, 2026, 2032, 2033 }, /* October */
{ 2026, 2032, 2033, 2034, 2035, 2030, 2036 }, /* November */
{ 2030, 2036, 2026, 2032, 2033, 2034, 2035 }, /* December */
};
/*
* compat_leap_month_table is generated by following program.
*
* #!/usr/bin/ruby
*
* require 'date'
*
* h = {}
* 2037.downto(2010) {|y|
* 1.upto(12) {|m|
* next unless m == 2 && y % 4 == 0
* d = Date.new(y,m,1)
* h[m] ||= {}
* h[m][d.wday] ||= y
* }
* }
*
* 2.upto(2) {|m|
* 0.upto(6) {|w|
* y = h[m][w]
* print " #{y},"
* }
* puts
* }
*/
static int compat_leap_month_table[7] = {
/* Sun Mon Tue Wed Thu Fri Sat */
2032, 2016, 2028, 2012, 2024, 2036, 2020, /* February */
};
static int
calc_wday(int year, int month, int day)
{
int a, y, m;
int wday;
a = (14 - month) / 12;
y = year + 4800 - a;
m = month + 12 * a - 3;
wday = day + (153*m+2)/5 + 365*y + y/4 - y/100 + y/400 + 2;
wday = wday % 7;
return wday;
}
static VALUE
guess_local_offset(struct vtm *vtm_utc, int *isdst_ret, const char **zone_ret)
{
struct tm tm;
long gmtoff;
const char *zone;
time_t t;
struct vtm vtm2;
VALUE timev;
int y, wday;
/* Daylight Saving Time was introduced in 1916.
* So we don't need to care about DST before that. */
if (lt(vtm_utc->year, INT2FIX(1916))) {
VALUE off = INT2FIX(0);
int isdst = 0;
zone = "UTC";
# if defined(NEGATIVE_TIME_T)
# if SIZEOF_TIME_T <= 4
/* 1901-12-13 20:45:52 UTC : The oldest time in 32-bit signed time_t. */
# define THE_TIME_OLD_ENOUGH ((time_t)0x80000000)
# else
/* Since the Royal Greenwich Observatory was commissioned in 1675,
no timezone defined using GMT at 1600. */
# define THE_TIME_OLD_ENOUGH ((time_t)(1600-1970)*366*24*60*60)
# endif
if (localtime_with_gmtoff_zone((t = THE_TIME_OLD_ENOUGH, &t), &tm, &gmtoff, &zone)) {
off = LONG2FIX(gmtoff);
isdst = tm.tm_isdst;
}
else
# endif
/* 1970-01-01 00:00:00 UTC : The Unix epoch - the oldest time in portable time_t. */
if (localtime_with_gmtoff_zone((t = 0, &t), &tm, &gmtoff, &zone)) {
off = LONG2FIX(gmtoff);
isdst = tm.tm_isdst;
}
if (isdst_ret)
*isdst_ret = isdst;
if (zone_ret)
*zone_ret = zone;
return off;
}
/* It is difficult to guess the future. */
vtm2 = *vtm_utc;
/* guess using a year before 2038. */
y = NUM2INT(mod(vtm_utc->year, INT2FIX(400)));
wday = calc_wday(y, vtm_utc->mon, 1);
if (vtm_utc->mon == 2 && leap_year_p(y))
vtm2.year = INT2FIX(compat_leap_month_table[wday]);
else
vtm2.year = INT2FIX(compat_common_month_table[vtm_utc->mon-1][wday]);
timev = w2v(rb_time_unmagnify(timegmw(&vtm2)));
t = NUM2TIMET(timev);
zone = "UTC";
if (localtime_with_gmtoff_zone(&t, &tm, &gmtoff, &zone)) {
if (isdst_ret)
*isdst_ret = tm.tm_isdst;
if (zone_ret)
*zone_ret = zone;
return LONG2FIX(gmtoff);
}
{
/* Use the current time offset as a last resort. */
static time_t now = 0;
static long now_gmtoff = 0;
static const char *now_zone = "UTC";
if (now == 0) {
now = time(NULL);
localtime_with_gmtoff_zone(&now, &tm, &now_gmtoff, &now_zone);
}
if (isdst_ret)
*isdst_ret = tm.tm_isdst;
if (zone_ret)
*zone_ret = now_zone;
return LONG2FIX(now_gmtoff);
}
}
static VALUE
small_vtm_sub(struct vtm *vtm1, struct vtm *vtm2)
{
int off;
off = vtm1->sec - vtm2->sec;
off += (vtm1->min - vtm2->min) * 60;
off += (vtm1->hour - vtm2->hour) * 3600;
if (ne(vtm1->year, vtm2->year))
off += lt(vtm1->year, vtm2->year) ? -24*3600 : 24*3600;
else if (vtm1->mon != vtm2->mon)
off += vtm1->mon < vtm2->mon ? -24*3600 : 24*3600;
else if (vtm1->mday != vtm2->mday)
off += vtm1->mday < vtm2->mday ? -24*3600 : 24*3600;
return INT2FIX(off);
}
static wideval_t
timelocalw(struct vtm *vtm)
{
time_t t;
struct tm tm;
VALUE v;
wideval_t timew1, timew2;
struct vtm vtm1, vtm2;
int n;
if (FIXNUM_P(vtm->year)) {
long l = FIX2LONG(vtm->year) - 1900;
if (l < INT_MIN || INT_MAX < l)
goto no_localtime;
tm.tm_year = (int)l;
}
else {
v = sub(vtm->year, INT2FIX(1900));
if (lt(v, INT2NUM(INT_MIN)) || lt(INT2NUM(INT_MAX), v))
goto no_localtime;
tm.tm_year = NUM2INT(v);
}
tm.tm_mon = vtm->mon-1;
tm.tm_mday = vtm->mday;
tm.tm_hour = vtm->hour;
tm.tm_min = vtm->min;
tm.tm_sec = vtm->sec;
tm.tm_isdst = vtm->isdst == VTM_ISDST_INITVAL ? -1 : vtm->isdst;
if (find_time_t(&tm, 0, &t))
goto no_localtime;
return wadd(rb_time_magnify(TIMET2WV(t)), v2w(vtm->subsecx));
no_localtime:
timew1 = timegmw(vtm);
if (!localtimew(timew1, &vtm1))
rb_raise(rb_eArgError, "localtimew error");
n = vtmcmp(vtm, &vtm1);
if (n == 0) {
timew1 = wsub(timew1, rb_time_magnify(WINT2FIXWV(12*3600)));
if (!localtimew(timew1, &vtm1))
rb_raise(rb_eArgError, "localtimew error");
n = 1;
}
if (n < 0) {
timew2 = timew1;
vtm2 = vtm1;
timew1 = wsub(timew1, rb_time_magnify(WINT2FIXWV(24*3600)));
if (!localtimew(timew1, &vtm1))
rb_raise(rb_eArgError, "localtimew error");
}
else {
timew2 = wadd(timew1, rb_time_magnify(WINT2FIXWV(24*3600)));
if (!localtimew(timew2, &vtm2))
rb_raise(rb_eArgError, "localtimew error");
}
timew1 = wadd(timew1, rb_time_magnify(v2w(small_vtm_sub(vtm, &vtm1))));
timew2 = wadd(timew2, rb_time_magnify(v2w(small_vtm_sub(vtm, &vtm2))));
if (weq(timew1, timew2))
return timew1;
if (!localtimew(timew1, &vtm1))
rb_raise(rb_eArgError, "localtimew error");
if (vtm->hour != vtm1.hour || vtm->min != vtm1.min || vtm->sec != vtm1.sec)
return timew2;
if (!localtimew(timew2, &vtm2))
rb_raise(rb_eArgError, "localtimew error");
if (vtm->hour != vtm2.hour || vtm->min != vtm2.min || vtm->sec != vtm2.sec)
return timew1;
if (vtm->isdst)
return lt(vtm1.utc_offset, vtm2.utc_offset) ? timew2 : timew1;
else
return lt(vtm1.utc_offset, vtm2.utc_offset) ? timew1 : timew2;
}
static struct tm *
localtime_with_gmtoff_zone(const time_t *t, struct tm *result, long *gmtoff, const char **zone)
{
struct tm tm;
if (LOCALTIME(t, tm)) {
#if defined(HAVE_STRUCT_TM_TM_GMTOFF)
*gmtoff = tm.tm_gmtoff;
#else
struct tm *u, *l;
long off;
struct tm tmbuf;
l = &tm;
u = GMTIME(t, tmbuf);
if (!u)
return NULL;
if (l->tm_year != u->tm_year)
off = l->tm_year < u->tm_year ? -1 : 1;
else if (l->tm_mon != u->tm_mon)
off = l->tm_mon < u->tm_mon ? -1 : 1;
else if (l->tm_mday != u->tm_mday)
off = l->tm_mday < u->tm_mday ? -1 : 1;
else
off = 0;
off = off * 24 + l->tm_hour - u->tm_hour;
off = off * 60 + l->tm_min - u->tm_min;
off = off * 60 + l->tm_sec - u->tm_sec;
*gmtoff = off;
#endif
if (zone) {
#if defined(HAVE_TM_ZONE)
if (tm.tm_zone)
*zone = zone_str(tm.tm_zone);
else
*zone = zone_str("(NO-TIMEZONE-ABBREVIATION)");
#elif defined(HAVE_TZNAME) && defined(HAVE_DAYLIGHT)
# if RUBY_MSVCRT_VERSION >= 140
# define tzname _tzname
# define daylight _daylight
# endif
/* this needs tzset or localtime, instead of localtime_r */
*zone = zone_str(tzname[daylight && tm.tm_isdst]);
#else
{
char buf[64];
strftime(buf, sizeof(buf), "%Z", &tm);
*zone = zone_str(buf);
}
#endif
}
*result = tm;
return result;
}
return NULL;
}
static int
timew_out_of_timet_range(wideval_t timew)
{
VALUE timexv;
#if WIDEVALUE_IS_WIDER && SIZEOF_TIME_T < SIZEOF_INT64_T
if (FIXWV_P(timew)) {
wideint_t t = FIXWV2WINT(timew);
if (t < TIME_SCALE * (wideint_t)TIMET_MIN ||
TIME_SCALE * (1 + (wideint_t)TIMET_MAX) <= t)
return 1;
return 0;
}
#endif
#if SIZEOF_TIME_T == SIZEOF_INT64_T
if (FIXWV_P(timew)) {
wideint_t t = FIXWV2WINT(timew);
if (~(time_t)0 <= 0) {
return 0;
}
else {
if (t < 0)
return 1;
return 0;
}
}
#endif
timexv = w2v(timew);
if (lt(timexv, mul(INT2FIX(TIME_SCALE), TIMET2NUM(TIMET_MIN))) ||
le(mul(INT2FIX(TIME_SCALE), add(TIMET2NUM(TIMET_MAX), INT2FIX(1))), timexv))
return 1;
return 0;
}
static struct vtm *
localtimew(wideval_t timew, struct vtm *result)
{
VALUE subsecx, offset;
const char *zone;
int isdst;
if (!timew_out_of_timet_range(timew)) {
time_t t;
struct tm tm;
long gmtoff;
wideval_t timew2;
split_second(timew, &timew2, &subsecx);
t = WV2TIMET(timew2);
if (localtime_with_gmtoff_zone(&t, &tm, &gmtoff, &zone)) {
result->year = LONG2NUM((long)tm.tm_year + 1900);
result->mon = tm.tm_mon + 1;
result->mday = tm.tm_mday;
result->hour = tm.tm_hour;
result->min = tm.tm_min;
result->sec = tm.tm_sec;
result->subsecx = subsecx;
result->wday = tm.tm_wday;
result->yday = tm.tm_yday+1;
result->isdst = tm.tm_isdst;
result->utc_offset = LONG2NUM(gmtoff);
result->zone = zone;
return result;
}
}
if (!gmtimew(timew, result))
return NULL;
offset = guess_local_offset(result, &isdst, &zone);
if (!gmtimew(wadd(timew, rb_time_magnify(v2w(offset))), result))
return NULL;
result->utc_offset = offset;
result->isdst = isdst;
result->zone = zone;
return result;
}
PACKED_STRUCT_UNALIGNED(struct time_object {
wideval_t timew; /* time_t value * TIME_SCALE. possibly Rational. */
struct vtm vtm;
uint8_t gmt:3; /* 0:localtime 1:utc 2:fixoff 3:init */
uint8_t tm_got:1;
});
#define GetTimeval(obj, tobj) ((tobj) = get_timeval(obj))
#define GetNewTimeval(obj, tobj) ((tobj) = get_new_timeval(obj))
#define IsTimeval(obj) rb_typeddata_is_kind_of((obj), &time_data_type)
#define TIME_INIT_P(tobj) ((tobj)->gmt != TO_GMT_INITVAL)
#define TIME_UTC_P(tobj) ((tobj)->gmt == 1)
#define TIME_SET_UTC(tobj) ((tobj)->gmt = 1)
#define TIME_LOCALTIME_P(tobj) ((tobj)->gmt == 0)
#define TIME_SET_LOCALTIME(tobj) ((tobj)->gmt = 0)
#define TIME_FIXOFF_P(tobj) ((tobj)->gmt == 2)
#define TIME_SET_FIXOFF(tobj, off) \
((tobj)->gmt = 2, \
(tobj)->vtm.utc_offset = (off), \
(tobj)->vtm.zone = NULL)
#define TIME_COPY_GMT(tobj1, tobj2) \
((tobj1)->gmt = (tobj2)->gmt, \
(tobj1)->vtm.utc_offset = (tobj2)->vtm.utc_offset, \
(tobj1)->vtm.zone = (tobj2)->vtm.zone)
static VALUE time_get_tm(VALUE, struct time_object *);
#define MAKE_TM(time, tobj) \
do { \
if ((tobj)->tm_got == 0) { \
time_get_tm((time), (tobj)); \
} \
} while (0)
static void
time_mark(void *ptr)
{
struct time_object *tobj = ptr;
if (!FIXWV_P(tobj->timew))
rb_gc_mark(w2v(tobj->timew));
rb_gc_mark(tobj->vtm.year);
rb_gc_mark(tobj->vtm.subsecx);
rb_gc_mark(tobj->vtm.utc_offset);
}
static size_t
time_memsize(const void *tobj)
{
return sizeof(struct time_object);
}
static const rb_data_type_t time_data_type = {
"time",
{time_mark, RUBY_TYPED_DEFAULT_FREE, time_memsize,},
0, 0, RUBY_TYPED_FREE_IMMEDIATELY
};
static VALUE
time_s_alloc(VALUE klass)
{
VALUE obj;
struct time_object *tobj;
obj = TypedData_Make_Struct(klass, struct time_object, &time_data_type, tobj);
tobj->gmt = TO_GMT_INITVAL;
tobj->tm_got=0;
tobj->timew = WINT2FIXWV(0);
return obj;
}
static struct time_object *
get_timeval(VALUE obj)
{
struct time_object *tobj;
TypedData_Get_Struct(obj, struct time_object, &time_data_type, tobj);
if (!TIME_INIT_P(tobj)) {
rb_raise(rb_eTypeError, "uninitialized %"PRIsVALUE, rb_obj_class(obj));
}
return tobj;
}
static struct time_object *
get_new_timeval(VALUE obj)
{
struct time_object *tobj;
TypedData_Get_Struct(obj, struct time_object, &time_data_type, tobj);
if (TIME_INIT_P(tobj)) {
rb_raise(rb_eTypeError, "already initialized %"PRIsVALUE, rb_obj_class(obj));
}
return tobj;
}
static void
time_modify(VALUE time)
{
rb_check_frozen(time);
rb_check_trusted(time);
}
static wideval_t
timespec2timew(struct timespec *ts)
{
wideval_t timew;
timew = rb_time_magnify(TIMET2WV(ts->tv_sec));
if (ts->tv_nsec)
timew = wadd(timew, wmulquoll(WINT2WV(ts->tv_nsec), TIME_SCALE, 1000000000));
return timew;
}
static struct timespec
timew2timespec(wideval_t timew)
{
VALUE subsecx;
struct timespec ts;
wideval_t timew2;
if (timew_out_of_timet_range(timew))
rb_raise(rb_eArgError, "time out of system range");
split_second(timew, &timew2, &subsecx);
ts.tv_sec = WV2TIMET(timew2);
ts.tv_nsec = NUM2LONG(mulquo(subsecx, INT2FIX(1000000000), INT2FIX(TIME_SCALE)));
return ts;
}
static struct timespec *
timew2timespec_exact(wideval_t timew, struct timespec *ts)
{
VALUE subsecx;
wideval_t timew2;
VALUE nsecv;
if (timew_out_of_timet_range(timew))
return NULL;
split_second(timew, &timew2, &subsecx);
ts->tv_sec = WV2TIMET(timew2);
nsecv = mulquo(subsecx, INT2FIX(1000000000), INT2FIX(TIME_SCALE));
if (!FIXNUM_P(nsecv))
return NULL;
ts->tv_nsec = NUM2LONG(nsecv);
return ts;
}
void
rb_timespec_now(struct timespec *ts)
{
#ifdef HAVE_CLOCK_GETTIME
if (clock_gettime(CLOCK_REALTIME, ts) == -1) {
rb_sys_fail("clock_gettime");
}
#else
{
struct timeval tv;
if (gettimeofday(&tv, 0) < 0) {
rb_sys_fail("gettimeofday");
}
ts->tv_sec = tv.tv_sec;
ts->tv_nsec = tv.tv_usec * 1000;
}
#endif
}
static VALUE
time_init_0(VALUE time)
{
struct time_object *tobj;
struct timespec ts;
time_modify(time);
GetNewTimeval(time, tobj);
tobj->gmt = 0;
tobj->tm_got=0;
tobj->timew = WINT2FIXWV(0);
rb_timespec_now(&ts);
tobj->timew = timespec2timew(&ts);
return time;
}
static VALUE
time_set_utc_offset(VALUE time, VALUE off)
{
struct time_object *tobj;
off = num_exact(off);
time_modify(time);
GetTimeval(time, tobj);
tobj->tm_got = 0;
TIME_SET_FIXOFF(tobj, off);
return time;
}
static void
vtm_add_offset(struct vtm *vtm, VALUE off)
{
int sign;
VALUE subsec, v;
int sec, min, hour;
int day;
vtm->utc_offset = sub(vtm->utc_offset, off);
if (lt(off, INT2FIX(0))) {
sign = -1;
off = neg(off);
}
else {
sign = 1;
}
divmodv(off, INT2FIX(1), &off, &subsec);
divmodv(off, INT2FIX(60), &off, &v);
sec = NUM2INT(v);
divmodv(off, INT2FIX(60), &off, &v);
min = NUM2INT(v);
divmodv(off, INT2FIX(24), &off, &v);
hour = NUM2INT(v);
if (sign < 0) {
subsec = neg(subsec);
sec = -sec;
min = -min;
hour = -hour;
}
day = 0;
if (!rb_equal(subsec, INT2FIX(0))) {
vtm->subsecx = add(vtm->subsecx, w2v(rb_time_magnify(v2w(subsec))));
if (lt(vtm->subsecx, INT2FIX(0))) {
vtm->subsecx = add(vtm->subsecx, INT2FIX(TIME_SCALE));
sec -= 1;
}
if (le(INT2FIX(TIME_SCALE), vtm->subsecx)) {
vtm->subsecx = sub(vtm->subsecx, INT2FIX(TIME_SCALE));
sec += 1;
}
goto not_zero_sec;
}
if (sec) {
not_zero_sec:
/* If sec + subsec == 0, don't change vtm->sec.
* It may be 60 which is a leap second. */
sec += vtm->sec;
if (sec < 0) {
sec += 60;
min -= 1;
}
if (60 <= sec) {
sec -= 60;
min += 1;
}
vtm->sec = sec;
}
if (min) {
min += vtm->min;
if (min < 0) {
min += 60;
hour -= 1;
}
if (60 <= min) {
min -= 60;
hour += 1;
}
vtm->min = min;
}
if (hour) {
hour += vtm->hour;
if (hour < 0) {
hour += 24;
day = -1;
}
if (24 <= hour) {
hour -= 24;
day = 1;
}
vtm->hour = hour;
}
if (day) {
if (day < 0) {
if (vtm->mon == 1 && vtm->mday == 1) {
vtm->mday = 31;
vtm->mon = 12; /* December */
vtm->year = sub(vtm->year, INT2FIX(1));
vtm->yday = leap_year_v_p(vtm->year) ? 365 : 364;
}
else if (vtm->mday == 1) {
const int *days_in_month = leap_year_v_p(vtm->year) ?
leap_year_days_in_month :
common_year_days_in_month;
vtm->mon--;
vtm->mday = days_in_month[vtm->mon-1];
vtm->yday--;
}
else {
vtm->mday--;
vtm->yday--;
}
vtm->wday = (vtm->wday + 6) % 7;
}
else {
int leap = leap_year_v_p(vtm->year);
if (vtm->mon == 12 && vtm->mday == 31) {
vtm->year = add(vtm->year, INT2FIX(1));
vtm->mon = 1; /* January */
vtm->mday = 1;
vtm->yday = 1;
}
else if (vtm->mday == (leap ? leap_year_days_in_month :
common_year_days_in_month)[vtm->mon-1]) {
vtm->mon++;
vtm->mday = 1;
vtm->yday++;
}
else {
vtm->mday++;
vtm->yday++;
}
vtm->wday = (vtm->wday + 1) % 7;
}
}
}
static VALUE
utc_offset_arg(VALUE arg)
{
VALUE tmp;
if (!NIL_P(tmp = rb_check_string_type(arg))) {
int n = 0;
char *s = RSTRING_PTR(tmp);
if (!rb_enc_str_asciicompat_p(tmp)) {
invalid_utc_offset:
rb_raise(rb_eArgError, "\"+HH:MM\" or \"-HH:MM\" expected for utc_offset");
}
switch (RSTRING_LEN(tmp)) {
case 9:
if (s[6] != ':') goto invalid_utc_offset;
if (!ISDIGIT(s[7]) || !ISDIGIT(s[8])) goto invalid_utc_offset;
n += (s[7] * 10 + s[8] - '0' * 11);
case 6:
if (s[0] != '+' && s[0] != '-') goto invalid_utc_offset;
if (!ISDIGIT(s[1]) || !ISDIGIT(s[2])) goto invalid_utc_offset;
if (s[3] != ':') goto invalid_utc_offset;
if (!ISDIGIT(s[4]) || !ISDIGIT(s[5])) goto invalid_utc_offset;
if (s[4] > '5') goto invalid_utc_offset;
break;
default:
goto invalid_utc_offset;
}
n += (s[1] * 10 + s[2] - '0' * 11) * 3600;
n += (s[4] * 10 + s[5] - '0' * 11) * 60;
if (s[0] == '-')
n = -n;
return INT2FIX(n);
}
else {
return num_exact(arg);
}
}
static VALUE
time_init_1(int argc, VALUE *argv, VALUE time)
{
struct vtm vtm;
VALUE v[7];
struct time_object *tobj;
vtm.wday = VTM_WDAY_INITVAL;
vtm.yday = 0;
vtm.zone = "";
/* year mon mday hour min sec off */
rb_scan_args(argc, argv, "16", &v[0],&v[1],&v[2],&v[3],&v[4],&v[5],&v[6]);
vtm.year = obj2vint(v[0]);
vtm.mon = NIL_P(v[1]) ? 1 : month_arg(v[1]);
vtm.mday = NIL_P(v[2]) ? 1 : obj2ubits(v[2], 5);
vtm.hour = NIL_P(v[3]) ? 0 : obj2ubits(v[3], 5);
vtm.min = NIL_P(v[4]) ? 0 : obj2ubits(v[4], 6);
vtm.subsecx = INT2FIX(0);
vtm.sec = NIL_P(v[5]) ? 0 : obj2subsecx(v[5], &vtm.subsecx);
vtm.isdst = VTM_ISDST_INITVAL;
vtm.utc_offset = Qnil;
if (!NIL_P(v[6])) {
VALUE arg = v[6];
if (arg == ID2SYM(rb_intern("dst")))
vtm.isdst = 1;
else if (arg == ID2SYM(rb_intern("std")))
vtm.isdst = 0;
else
vtm.utc_offset = utc_offset_arg(arg);
}
validate_vtm(&vtm);
time_modify(time);
GetNewTimeval(time, tobj);
tobj->gmt = 0;
tobj->tm_got=0;
tobj->timew = WINT2FIXWV(0);
if (!NIL_P(vtm.utc_offset)) {
VALUE off = vtm.utc_offset;
vtm_add_offset(&vtm, neg(off));
vtm.utc_offset = Qnil;
tobj->timew = timegmw(&vtm);
return time_set_utc_offset(time, off);
}
else {
tobj->timew = timelocalw(&vtm);
return time_localtime(time);
}
}
/*
* call-seq:
* Time.new -> time
* Time.new(year, month=nil, day=nil, hour=nil, min=nil, sec=nil, utc_offset=nil) -> time
*
* Returns a Time object.
*
* It is initialized to the current system time if no argument is given.
*
* *Note:* The new object will use the resolution available on your
* system clock, and may include fractional seconds.
*
* If one or more arguments specified, the time is initialized to the specified
* time.
*
* +sec+ may have fraction if it is a rational.
*
* +utc_offset+ is the offset from UTC.
* It can be a string such as "+09:00" or a number of seconds such as 32400.
*
* a = Time.new #=> 2007-11-19 07:50:02 -0600
* b = Time.new #=> 2007-11-19 07:50:02 -0600
* a == b #=> false
* "%.6f" % a.to_f #=> "1195480202.282373"
* "%.6f" % b.to_f #=> "1195480202.283415"
*
* Time.new(2008,6,21, 13,30,0, "+09:00") #=> 2008-06-21 13:30:00 +0900
*
* # A trip for RubyConf 2007
* t1 = Time.new(2007,11,1,15,25,0, "+09:00") # JST (Narita)
* t2 = Time.new(2007,11,1,12, 5,0, "-05:00") # CDT (Minneapolis)
* t3 = Time.new(2007,11,1,13,25,0, "-05:00") # CDT (Minneapolis)
* t4 = Time.new(2007,11,1,16,53,0, "-04:00") # EDT (Charlotte)
* t5 = Time.new(2007,11,5, 9,24,0, "-05:00") # EST (Charlotte)
* t6 = Time.new(2007,11,5,11,21,0, "-05:00") # EST (Detroit)
* t7 = Time.new(2007,11,5,13,45,0, "-05:00") # EST (Detroit)
* t8 = Time.new(2007,11,6,17,10,0, "+09:00") # JST (Narita)
* p((t2-t1)/3600.0) #=> 10.666666666666666
* p((t4-t3)/3600.0) #=> 2.466666666666667
* p((t6-t5)/3600.0) #=> 1.95
* p((t8-t7)/3600.0) #=> 13.416666666666666
*
*/
static VALUE
time_init(int argc, VALUE *argv, VALUE time)
{
if (argc == 0)
return time_init_0(time);
else
return time_init_1(argc, argv, time);
}
static void
time_overflow_p(time_t *secp, long *nsecp)
{
time_t sec = *secp;
long nsec = *nsecp;
long sec2;
if (nsec >= 1000000000) { /* nsec positive overflow */
sec2 = nsec / 1000000000;
if (TIMET_MAX - sec2 < sec) {
rb_raise(rb_eRangeError, "out of Time range");
}
nsec -= sec2 * 1000000000;
sec += sec2;
}
else if (nsec < 0) { /* nsec negative overflow */
sec2 = NDIV(nsec,1000000000); /* negative div */
if (sec < TIMET_MIN - sec2) {
rb_raise(rb_eRangeError, "out of Time range");
}
nsec -= sec2 * 1000000000;
sec += sec2;
}
#ifndef NEGATIVE_TIME_T
if (sec < 0)
rb_raise(rb_eArgError, "time must be positive");
#endif
*secp = sec;
*nsecp = nsec;
}
static wideval_t
nsec2timew(time_t sec, long nsec)
{
struct timespec ts;
time_overflow_p(&sec, &nsec);
ts.tv_sec = sec;
ts.tv_nsec = nsec;
return timespec2timew(&ts);
}
static VALUE
time_new_timew(VALUE klass, wideval_t timew)
{
VALUE time = time_s_alloc(klass);
struct time_object *tobj;
tobj = DATA_PTR(time); /* skip type check */
tobj->gmt = 0;
tobj->timew = timew;
return time;
}
VALUE
rb_time_new(time_t sec, long usec)
{
wideval_t timew;
if (usec >= 1000000) {
long sec2 = usec / 1000000;
if (sec > TIMET_MAX - sec2) {
rb_raise(rb_eRangeError, "out of Time range");
}
usec -= sec2 * 1000000;
sec += sec2;
}
else if (usec < 0) {
long sec2 = NDIV(usec,1000000); /* negative div */
if (sec < TIMET_MIN - sec2) {
rb_raise(rb_eRangeError, "out of Time range");
}
usec -= sec2 * 1000000;
sec += sec2;
}
timew = nsec2timew(sec, usec * 1000);
return time_new_timew(rb_cTime, timew);
}
/* returns localtime time object */
VALUE
rb_time_nano_new(time_t sec, long nsec)
{
return time_new_timew(rb_cTime, nsec2timew(sec, nsec));
}
/**
* Returns a time object with UTC/localtime/fixed offset
*
* offset is -86400 < fixoff < 86400 or INT_MAX (localtime) or INT_MAX-1 (utc)
*/
VALUE
rb_time_timespec_new(const struct timespec *ts, int offset)
{
struct time_object *tobj;
VALUE time = time_new_timew(rb_cTime, nsec2timew(ts->tv_sec, ts->tv_nsec));
if (-86400 < offset && offset < 86400) { /* fixoff */
GetTimeval(time, tobj);
TIME_SET_FIXOFF(tobj, INT2FIX(offset));
}
else if (offset == INT_MAX) { /* localtime */
}
else if (offset == INT_MAX-1) { /* UTC */
GetTimeval(time, tobj);
TIME_SET_UTC(tobj);
}
else {
rb_raise(rb_eArgError, "utc_offset out of range");
}
return time;
}
VALUE
rb_time_num_new(VALUE timev, VALUE off)
{
VALUE time = time_new_timew(rb_cTime, rb_time_magnify(v2w(timev)));
if (!NIL_P(off)) {
off = utc_offset_arg(off);
validate_utc_offset(off);
time_set_utc_offset(time, off);
return time;
}
return time;
}
static struct timespec
time_timespec(VALUE num, int interval)
{
struct timespec t;
const char *const tstr = interval ? "time interval" : "time";
VALUE i, f, ary;
#ifndef NEGATIVE_TIME_T
interval = 1;
#endif
switch (TYPE(num)) {
case T_FIXNUM:
t.tv_sec = NUM2TIMET(num);
if (interval && t.tv_sec < 0)
rb_raise(rb_eArgError, "%s must be positive", tstr);
t.tv_nsec = 0;
break;
case T_FLOAT:
if (interval && RFLOAT_VALUE(num) < 0.0)
rb_raise(rb_eArgError, "%s must be positive", tstr);
else {
double f, d;
d = modf(RFLOAT_VALUE(num), &f);
if (d >= 0) {
t.tv_nsec = (int)(d*1e9+0.5);
if (t.tv_nsec >= 1000000000) {
t.tv_nsec -= 1000000000;
f += 1;
}
}
else if ((t.tv_nsec = (int)(-d*1e9+0.5)) > 0) {
t.tv_nsec = 1000000000 - t.tv_nsec;
f -= 1;
}
t.tv_sec = (time_t)f;
if (f != t.tv_sec) {
rb_raise(rb_eRangeError, "%f out of Time range", RFLOAT_VALUE(num));
}
}
break;
case T_BIGNUM:
t.tv_sec = NUM2TIMET(num);
if (interval && t.tv_sec < 0)
rb_raise(rb_eArgError, "%s must be positive", tstr);
t.tv_nsec = 0;
break;
default:
i = INT2FIX(1);
ary = rb_check_funcall(num, id_divmod, 1, &i);
if (ary != Qundef && !NIL_P(ary = rb_check_array_type(ary))) {
i = rb_ary_entry(ary, 0);
f = rb_ary_entry(ary, 1);
t.tv_sec = NUM2TIMET(i);
if (interval && t.tv_sec < 0)
rb_raise(rb_eArgError, "%s must be positive", tstr);
f = rb_funcall(f, id_mul, 1, INT2FIX(1000000000));
t.tv_nsec = NUM2LONG(f);
}
else {
rb_raise(rb_eTypeError, "can't convert %"PRIsVALUE" into %s",
rb_obj_class(num), tstr);
}
break;
}
return t;
}
static struct timeval
time_timeval(VALUE num, int interval)
{
struct timespec ts;
struct timeval tv;
ts = time_timespec(num, interval);
tv.tv_sec = (TYPEOF_TIMEVAL_TV_SEC)ts.tv_sec;
tv.tv_usec = (TYPEOF_TIMEVAL_TV_USEC)(ts.tv_nsec / 1000);
return tv;
}
struct timeval
rb_time_interval(VALUE num)
{
return time_timeval(num, TRUE);
}
struct timeval
rb_time_timeval(VALUE time)
{
struct time_object *tobj;
struct timeval t;
struct timespec ts;
if (IsTimeval(time)) {
GetTimeval(time, tobj);
ts = timew2timespec(tobj->timew);
t.tv_sec = (TYPEOF_TIMEVAL_TV_SEC)ts.tv_sec;
t.tv_usec = (TYPEOF_TIMEVAL_TV_USEC)(ts.tv_nsec / 1000);
return t;
}
return time_timeval(time, FALSE);
}
struct timespec
rb_time_timespec(VALUE time)
{
struct time_object *tobj;
struct timespec t;
if (IsTimeval(time)) {
GetTimeval(time, tobj);
t = timew2timespec(tobj->timew);
return t;
}
return time_timespec(time, FALSE);
}
/*
* call-seq:
* Time.now -> time
*
* Creates a new Time object for the current time.
* This is same as Time.new without arguments.
*
* Time.now #=> 2009-06-24 12:39:54 +0900
*/
static VALUE
time_s_now(VALUE klass)
{
return rb_class_new_instance(0, NULL, klass);
}
/*
* call-seq:
* Time.at(time) -> time
* Time.at(seconds_with_frac) -> time
* Time.at(seconds, microseconds_with_frac) -> time
*
* Creates a new Time object with the value given by +time+,
* the given number of +seconds_with_frac+, or
* +seconds+ and +microseconds_with_frac+ since the Epoch.
* +seconds_with_frac+ and +microseconds_with_frac+
* can be an Integer, Float, Rational, or other Numeric.
* non-portable feature allows the offset to be negative on some systems.
*
* If a numeric argument is given, the result is in local time.
*
* Time.at(0) #=> 1969-12-31 18:00:00 -0600
* Time.at(Time.at(0)) #=> 1969-12-31 18:00:00 -0600
* Time.at(946702800) #=> 1999-12-31 23:00:00 -0600
* Time.at(-284061600) #=> 1960-12-31 00:00:00 -0600
* Time.at(946684800.2).usec #=> 200000
* Time.at(946684800, 123456.789).nsec #=> 123456789
*/
static VALUE
time_s_at(int argc, VALUE *argv, VALUE klass)
{
VALUE time, t;
wideval_t timew;
if (rb_scan_args(argc, argv, "11", &time, &t) == 2) {
time = num_exact(time);
t = num_exact(t);
timew = wadd(rb_time_magnify(v2w(time)), wmulquoll(v2w(t), TIME_SCALE, 1000000));
t = time_new_timew(klass, timew);
}
else if (IsTimeval(time)) {
struct time_object *tobj, *tobj2;
GetTimeval(time, tobj);
t = time_new_timew(klass, tobj->timew);
GetTimeval(t, tobj2);
TIME_COPY_GMT(tobj2, tobj);
}
else {
timew = rb_time_magnify(v2w(num_exact(time)));
t = time_new_timew(klass, timew);
}
return t;
}
static const char months[][4] = {
"jan", "feb", "mar", "apr", "may", "jun",
"jul", "aug", "sep", "oct", "nov", "dec",
};
static int
obj2int(VALUE obj)
{
if (RB_TYPE_P(obj, T_STRING)) {
obj = rb_str_to_inum(obj, 10, FALSE);
}
return NUM2INT(obj);
}
static uint32_t
obj2ubits(VALUE obj, size_t bits)
{
static const uint32_t u32max = (uint32_t)-1;
const uint32_t usable_mask = ~(u32max << bits);
uint32_t rv;
int tmp = obj2int(obj);
if (tmp < 0)
rb_raise(rb_eArgError, "argument out of range");
rv = tmp;
if ((rv & usable_mask) != rv)
rb_raise(rb_eArgError, "argument out of range");
return rv;
}
static VALUE
obj2vint(VALUE obj)
{
if (RB_TYPE_P(obj, T_STRING)) {
obj = rb_str_to_inum(obj, 10, FALSE);
}
else {
obj = rb_to_int(obj);
}
return obj;
}
static uint32_t
obj2subsecx(VALUE obj, VALUE *subsecx)
{
VALUE subsec;
if (RB_TYPE_P(obj, T_STRING)) {
obj = rb_str_to_inum(obj, 10, FALSE);
*subsecx = INT2FIX(0);
}
else {
divmodv(num_exact(obj), INT2FIX(1), &obj, &subsec);
*subsecx = w2v(rb_time_magnify(v2w(subsec)));
}
return obj2ubits(obj, 6); /* vtm->sec */
}
static long
usec2subsecx(VALUE obj)
{
if (RB_TYPE_P(obj, T_STRING)) {
obj = rb_str_to_inum(obj, 10, FALSE);
}
return mulquo(num_exact(obj), INT2FIX(TIME_SCALE), INT2FIX(1000000));
}
static uint32_t
month_arg(VALUE arg)
{
int i, mon;
VALUE s = rb_check_string_type(arg);
if (!NIL_P(s) && RSTRING_LEN(s) > 0) {
mon = 0;
for (i=0; i<12; i++) {
if (RSTRING_LEN(s) == 3 &&
STRNCASECMP(months[i], RSTRING_PTR(s), 3) == 0) {
mon = i+1;
break;
}
}
if (mon == 0) {
char c = RSTRING_PTR(s)[0];
if ('0' <= c && c <= '9') {
mon = obj2ubits(s, 4);
}
}
}
else {
mon = obj2ubits(arg, 4);
}
return mon;
}
static VALUE
validate_utc_offset(VALUE utc_offset)
{
if (le(utc_offset, INT2FIX(-86400)) || ge(utc_offset, INT2FIX(86400)))
rb_raise(rb_eArgError, "utc_offset out of range");
return utc_offset;
}
static VALUE
validate_zone_name(VALUE zone_name)
{
StringValueCStr(zone_name);
return zone_name;
}
static void
validate_vtm(struct vtm *vtm)
{
if ( vtm->mon < 1 || vtm->mon > 12
|| vtm->mday < 1 || vtm->mday > 31
|| vtm->hour < 0 || vtm->hour > 24
|| (vtm->hour == 24 && (vtm->min > 0 || vtm->sec > 0))
|| vtm->min < 0 || vtm->min > 59
|| vtm->sec < 0 || vtm->sec > 60
|| lt(vtm->subsecx, INT2FIX(0)) || ge(vtm->subsecx, INT2FIX(TIME_SCALE))
|| (!NIL_P(vtm->utc_offset) && (validate_utc_offset(vtm->utc_offset), 0)))
rb_raise(rb_eArgError, "argument out of range");
}
static void
time_arg(int argc, VALUE *argv, struct vtm *vtm)
{
VALUE v[8];
vtm->year = INT2FIX(0);
vtm->mon = 0;
vtm->mday = 0;
vtm->hour = 0;
vtm->min = 0;
vtm->sec = 0;
vtm->subsecx = INT2FIX(0);
vtm->utc_offset = Qnil;
vtm->wday = 0;
vtm->yday = 0;
vtm->isdst = 0;
vtm->zone = "";
if (argc == 10) {
v[0] = argv[5];
v[1] = argv[4];
v[2] = argv[3];
v[3] = argv[2];
v[4] = argv[1];
v[5] = argv[0];
v[6] = Qnil;
vtm->isdst = RTEST(argv[8]) ? 1 : 0;
}
else {
rb_scan_args(argc, argv, "17", &v[0],&v[1],&v[2],&v[3],&v[4],&v[5],&v[6],&v[7]);
/* v[6] may be usec or zone (parsedate) */
/* v[7] is wday (parsedate; ignored) */
vtm->wday = VTM_WDAY_INITVAL;
vtm->isdst = VTM_ISDST_INITVAL;
}
vtm->year = obj2vint(v[0]);
if (NIL_P(v[1])) {
vtm->mon = 1;
}
else {
vtm->mon = month_arg(v[1]);
}
if (NIL_P(v[2])) {
vtm->mday = 1;
}
else {
vtm->mday = obj2ubits(v[2], 5);
}
vtm->hour = NIL_P(v[3])?0:obj2ubits(v[3], 5);
vtm->min = NIL_P(v[4])?0:obj2ubits(v[4], 6);
if (!NIL_P(v[6]) && argc == 7) {
vtm->sec = NIL_P(v[5])?0:obj2ubits(v[5],6);
vtm->subsecx = usec2subsecx(v[6]);
}
else {
/* when argc == 8, v[6] is timezone, but ignored */
vtm->sec = NIL_P(v[5])?0:obj2subsecx(v[5], &vtm->subsecx);
}
validate_vtm(vtm);
}
static int
leap_year_p(long y)
{
return ((y % 4 == 0) && (y % 100 != 0)) || (y % 400 == 0);
}
static time_t
timegm_noleapsecond(struct tm *tm)
{
long tm_year = tm->tm_year;
int tm_yday = tm->tm_mday;
if (leap_year_p(tm_year + 1900))
tm_yday += leap_year_yday_offset[tm->tm_mon];
else
tm_yday += common_year_yday_offset[tm->tm_mon];
/*
* `Seconds Since the Epoch' in SUSv3:
* tm_sec + tm_min*60 + tm_hour*3600 + tm_yday*86400 +
* (tm_year-70)*31536000 + ((tm_year-69)/4)*86400 -
* ((tm_year-1)/100)*86400 + ((tm_year+299)/400)*86400
*/
return tm->tm_sec + tm->tm_min*60 + tm->tm_hour*3600 +
(time_t)(tm_yday +
(tm_year-70)*365 +
DIV(tm_year-69,4) -
DIV(tm_year-1,100) +
DIV(tm_year+299,400))*86400;
}
#if 0
#define DEBUG_FIND_TIME_NUMGUESS
#define DEBUG_GUESSRANGE
#endif
#ifdef DEBUG_GUESSRANGE
#define DEBUG_REPORT_GUESSRANGE fprintf(stderr, "find time guess range: %ld - %ld : %"PRI_TIMET_PREFIX"u\n", guess_lo, guess_hi, (unsigned_time_t)(guess_hi-guess_lo))
#else
#define DEBUG_REPORT_GUESSRANGE
#endif
#ifdef DEBUG_FIND_TIME_NUMGUESS
#define DEBUG_FIND_TIME_NUMGUESS_INC find_time_numguess++,
static unsigned long long find_time_numguess;
static VALUE find_time_numguess_getter(void)
{
return ULL2NUM(find_time_numguess);
}
#else
#define DEBUG_FIND_TIME_NUMGUESS_INC
#endif
static const char *
find_time_t(struct tm *tptr, int utc_p, time_t *tp)
{
time_t guess, guess0, guess_lo, guess_hi;
struct tm *tm, tm0, tm_lo, tm_hi;
int d;
int find_dst;
struct tm result;
int status;
int tptr_tm_yday;
#define GUESS(p) (DEBUG_FIND_TIME_NUMGUESS_INC (utc_p ? gmtime_with_leapsecond((p), &result) : LOCALTIME((p), result)))
guess_lo = TIMET_MIN;
guess_hi = TIMET_MAX;
find_dst = 0 < tptr->tm_isdst;
#if defined(HAVE_MKTIME)
tm0 = *tptr;
if (!utc_p && (guess = mktime(&tm0)) != -1) {
tm = GUESS(&guess);
if (tm && tmcmp(tptr, tm) == 0) {
goto found;
}
}
#endif
tm0 = *tptr;
if (tm0.tm_mon < 0) {
tm0.tm_mon = 0;
tm0.tm_mday = 1;
tm0.tm_hour = 0;
tm0.tm_min = 0;
tm0.tm_sec = 0;
}
else if (11 < tm0.tm_mon) {
tm0.tm_mon = 11;
tm0.tm_mday = 31;
tm0.tm_hour = 23;
tm0.tm_min = 59;
tm0.tm_sec = 60;
}
else if (tm0.tm_mday < 1) {
tm0.tm_mday = 1;
tm0.tm_hour = 0;
tm0.tm_min = 0;
tm0.tm_sec = 0;
}
else if ((d = (leap_year_p(1900 + tm0.tm_year) ?
leap_year_days_in_month :
common_year_days_in_month)[tm0.tm_mon]) < tm0.tm_mday) {
tm0.tm_mday = d;
tm0.tm_hour = 23;
tm0.tm_min = 59;
tm0.tm_sec = 60;
}
else if (tm0.tm_hour < 0) {
tm0.tm_hour = 0;
tm0.tm_min = 0;
tm0.tm_sec = 0;
}
else if (23 < tm0.tm_hour) {
tm0.tm_hour = 23;
tm0.tm_min = 59;
tm0.tm_sec = 60;
}
else if (tm0.tm_min < 0) {
tm0.tm_min = 0;
tm0.tm_sec = 0;
}
else if (59 < tm0.tm_min) {
tm0.tm_min = 59;
tm0.tm_sec = 60;
}
else if (tm0.tm_sec < 0) {
tm0.tm_sec = 0;
}
else if (60 < tm0.tm_sec) {
tm0.tm_sec = 60;
}
DEBUG_REPORT_GUESSRANGE;
guess0 = guess = timegm_noleapsecond(&tm0);
tm = GUESS(&guess);
if (tm) {
d = tmcmp(tptr, tm);
if (d == 0) { goto found; }
if (d < 0) {
guess_hi = guess;
guess -= 24 * 60 * 60;
}
else {
guess_lo = guess;
guess += 24 * 60 * 60;
}
DEBUG_REPORT_GUESSRANGE;
if (guess_lo < guess && guess < guess_hi && (tm = GUESS(&guess)) != NULL) {
d = tmcmp(tptr, tm);
if (d == 0) { goto found; }
if (d < 0)
guess_hi = guess;
else
guess_lo = guess;
DEBUG_REPORT_GUESSRANGE;
}
}
tm = GUESS(&guess_lo);
if (!tm) goto error;
d = tmcmp(tptr, tm);
if (d < 0) goto out_of_range;
if (d == 0) { guess = guess_lo; goto found; }
tm_lo = *tm;
* eval.c (block_pass): should not downgrade safe level. * ext/dbm/extconf.rb: allow specifying dbm-type explicitly. * ext/dbm/extconf.rb: avoid gdbm if possible, because it leaks memory, whereas gdbm.so doesn't. potential incompatibility. * string.c (rb_str_insert): new method. * parse.y (yylex): lex_state after RESCUE_MOD should be EXPR_BEG. * array.c (rb_ary_insert): new method. * array.c (rb_ary_update): new utility function. * io.c (set_outfile): should check if closed before assignment. * eval.c (rb_eval): should preserve value of ruby_errinfo. * eval.c (rb_thread_schedule): infinite sleep should not cause dead lock. * array.c (rb_ary_flatten_bang): proper recursive detection. * eval.c (yield_under): need not to prohibit at safe level 4. * pack.c (pack_pack): p/P packs nil into NULL. * pack.c (pack_unpack): p/P unpacks NULL into nil. * pack.c (pack_pack): size check for P template. * ruby.c (set_arg0): wrong predicate when new $0 value is bigger than original space. * gc.c (id2ref): should use NUM2ULONG() * object.c (rb_mod_const_get): check whether name is a class variable name. * object.c (rb_mod_const_set): ditto. * object.c (rb_mod_const_defined): ditto. * marshal.c (w_float): precision changed to "%.16g" * eval.c (rb_call0): wrong retry behavior. * numeric.c (fix_aref): a bug on long>int architecture. * eval.c (rb_eval_string_wrap): should restore ruby_wrapper. * regex.c (re_compile_pattern): char class at either edge of range should be invalid. * eval.c (handle_rescue): use === to compare exception match. * error.c (syserr_eqq): comparison between SytemCallErrors should based on their error numbers. * eval.c (safe_getter): should use INT2NUM(). * bignum.c (rb_big2long): 2**31 cannot fit in 31 bit long. * regex.c (calculate_must_string): wrong length calculation. * eval.c (rb_thread_start_0): fixed memory leak. * parse.y (none): should clear cmdarg_stack too. * io.c (rb_fopen): use setvbuf() to avoid recursive malloc() on some platforms. * file.c (rb_stat_dev): device functions should honor stat field types (except long long such as dev_t). * eval.c (rb_mod_nesting): should not push nil for nesting array. * eval.c (rb_mod_s_constants): should not search array by rb_mod_const_at() for nil (happens for singleton class). * class.c (rb_singleton_class_attached): should modify iv_tbl by itself, no longer use rb_iv_set() to avoid freeze check error. * variable.c (rb_const_get): error message "uninitialized constant Foo at Bar::Baz" instead of "uninitialized constantBar::Baz::Foo". * eval.c (rb_mod_included): new hook called from rb_mod_include(). * io.c (opt_i_set): should strdup() inplace_edit string. * eval.c (exec_under): need to push cref too. * eval.c (rb_f_missing): raise NameError for "undefined local variable or method". * error.c (Init_Exception): new exception NoMethodError. NameError moved under ScriptError again. * eval.c (rb_f_missing): use NoMethodError instead of NameError. * file.c (Init_File): should redifine "new" class method. * eval.c (PUSH_CREF): sharing cref node was problematic. maintain runtime cref list instead. * eval.c (rb_eval): copy defn node before registering. * eval.c (rb_load): clear ruby_cref before loading. * variable.c (rb_const_get): no recursion to show full class path for modules. * eval.c (rb_set_safe_level): should set safe level in curr_thread as well. * eval.c (safe_setter): ditto. * object.c (rb_obj_is_instance_of): nil belongs to false, not true. * time.c (make_time_t): proper (I hope) daylight saving time handling for both US and Europe. I HATE DST! * eval.c (rb_thread_wait_for): non blocked signal interrupt should stop the interval. * eval.c (proc_eq): class check aded. * eval.c (proc_eq): typo fixed ("return" was ommitted). * error.c (Init_Exception): move NameError under StandardError. * class.c (rb_mod_clone): should copy method bodies too. * bignum.c (bigdivrem): should trim trailing zero bdigits of remainder, even if dd == 0. * file.c (check3rdbyte): safe string check moved here. * time.c (make_time_t): remove HAVE_TM_ZONE code since it sometimes reports wrong time. * time.c (make_time_t): remove unnecessary range check for platforms where negative time_t is available. * process.c (proc_waitall): should push Process::Status instead of Finuxm status. * process.c (waitall_each): should add all entries in pid_tbl. these changes are inspired by Koji Arai. Thanks. * process.c (proc_wait): should not iterate if pid_tbl is 0. * process.c (proc_waitall): ditto. * numeric.c (flodivmod): a bug in no fmod case. * process.c (pst_wifsignaled): should apply WIFSIGNALED for status (int), not st (VALUE). * io.c (Init_IO): value of $/ and $\ are no longer restricted to strings. type checks are done on demand. * class.c (rb_include_module): module inclusion should be check taints. * ruby.h (STR2CSTR): replace to StringType() and StringTypePtr(). * ruby.h (rb_str2cstr): ditto. * eval.c (rb_load): should not copy topleve local variables. It cause variable/method ambiguity. Thanks to L. Peter Deutsch. * class.c (rb_include_module): freeze check at first. * eval.c (rb_attr): sprintf() and rb_intern() moved into conditional body. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1356 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-05-02 00:22:21 -04:00
tm = GUESS(&guess_hi);
if (!tm) goto error;
d = tmcmp(tptr, tm);
if (d > 0) goto out_of_range;
if (d == 0) { guess = guess_hi; goto found; }
tm_hi = *tm;
DEBUG_REPORT_GUESSRANGE;
status = 1;
while (guess_lo + 1 < guess_hi) {
if (status == 0) {
binsearch:
guess = guess_lo / 2 + guess_hi / 2;
if (guess <= guess_lo)
guess = guess_lo + 1;
else if (guess >= guess_hi)
guess = guess_hi - 1;
status = 1;
}
else {
if (status == 1) {
time_t guess0_hi = timegm_noleapsecond(&tm_hi);
guess = guess_hi - (guess0_hi - guess0);
if (guess == guess_hi) /* hh:mm:60 tends to cause this condition. */
guess--;
status = 2;
}
else if (status == 2) {
time_t guess0_lo = timegm_noleapsecond(&tm_lo);
guess = guess_lo + (guess0 - guess0_lo);
if (guess == guess_lo)
guess++;
status = 0;
}
if (guess <= guess_lo || guess_hi <= guess) {
/* Precious guess is invalid. try binary search. */
#ifdef DEBUG_GUESSRANGE
if (guess <= guess_lo) fprintf(stderr, "too small guess: %ld <= %ld\n", guess, guess_lo);
if (guess_hi <= guess) fprintf(stderr, "too big guess: %ld <= %ld\n", guess_hi, guess);
#endif
goto binsearch;
}
}
tm = GUESS(&guess);
if (!tm) goto error;
d = tmcmp(tptr, tm);
if (d < 0) {
guess_hi = guess;
tm_hi = *tm;
DEBUG_REPORT_GUESSRANGE;
}
else if (d > 0) {
guess_lo = guess;
tm_lo = *tm;
DEBUG_REPORT_GUESSRANGE;
}
else {
found:
if (!utc_p) {
/* If localtime is nonmonotonic, another result may exist. */
time_t guess2;
if (find_dst) {
guess2 = guess - 2 * 60 * 60;
tm = LOCALTIME(&guess2, result);
if (tm) {
if (tptr->tm_hour != (tm->tm_hour + 2) % 24 ||
tptr->tm_min != tm->tm_min ||
tptr->tm_sec != tm->tm_sec) {
guess2 -= (tm->tm_hour - tptr->tm_hour) * 60 * 60 +
(tm->tm_min - tptr->tm_min) * 60 +
(tm->tm_sec - tptr->tm_sec);
if (tptr->tm_mday != tm->tm_mday)
guess2 += 24 * 60 * 60;
if (guess != guess2) {
tm = LOCALTIME(&guess2, result);
if (tm && tmcmp(tptr, tm) == 0) {
if (guess < guess2)
*tp = guess;
else
*tp = guess2;
return NULL;
}
}
}
}
}
else {
guess2 = guess + 2 * 60 * 60;
tm = LOCALTIME(&guess2, result);
if (tm) {
if ((tptr->tm_hour + 2) % 24 != tm->tm_hour ||
tptr->tm_min != tm->tm_min ||
tptr->tm_sec != tm->tm_sec) {
guess2 -= (tm->tm_hour - tptr->tm_hour) * 60 * 60 +
(tm->tm_min - tptr->tm_min) * 60 +
(tm->tm_sec - tptr->tm_sec);
if (tptr->tm_mday != tm->tm_mday)
guess2 -= 24 * 60 * 60;
if (guess != guess2) {
tm = LOCALTIME(&guess2, result);
if (tm && tmcmp(tptr, tm) == 0) {
if (guess < guess2)
*tp = guess2;
else
*tp = guess;
return NULL;
}
}
}
}
}
}
*tp = guess;
return NULL;
}
}
/* Given argument has no corresponding time_t. Let's extrapolate. */
/*
* `Seconds Since the Epoch' in SUSv3:
* tm_sec + tm_min*60 + tm_hour*3600 + tm_yday*86400 +
* (tm_year-70)*31536000 + ((tm_year-69)/4)*86400 -
* ((tm_year-1)/100)*86400 + ((tm_year+299)/400)*86400
*/
tptr_tm_yday = calc_tm_yday(tptr->tm_year, tptr->tm_mon, tptr->tm_mday);
*tp = guess_lo +
((tptr->tm_year - tm_lo.tm_year) * 365 +
((tptr->tm_year-69)/4) -
((tptr->tm_year-1)/100) +
((tptr->tm_year+299)/400) -
((tm_lo.tm_year-69)/4) +
((tm_lo.tm_year-1)/100) -
((tm_lo.tm_year+299)/400) +
tptr_tm_yday -
tm_lo.tm_yday) * 86400 +
(tptr->tm_hour - tm_lo.tm_hour) * 3600 +
(tptr->tm_min - tm_lo.tm_min) * 60 +
(tptr->tm_sec - (tm_lo.tm_sec == 60 ? 59 : tm_lo.tm_sec));
return NULL;
out_of_range:
return "time out of range";
error:
return "gmtime/localtime error";
}
static int
vtmcmp(struct vtm *a, struct vtm *b)
{
if (ne(a->year, b->year))
return lt(a->year, b->year) ? -1 : 1;
else if (a->mon != b->mon)
return a->mon < b->mon ? -1 : 1;
else if (a->mday != b->mday)
return a->mday < b->mday ? -1 : 1;
else if (a->hour != b->hour)
return a->hour < b->hour ? -1 : 1;
else if (a->min != b->min)
return a->min < b->min ? -1 : 1;
else if (a->sec != b->sec)
return a->sec < b->sec ? -1 : 1;
else if (ne(a->subsecx, b->subsecx))
return lt(a->subsecx, b->subsecx) ? -1 : 1;
else
return 0;
}
static int
tmcmp(struct tm *a, struct tm *b)
{
if (a->tm_year != b->tm_year)
return a->tm_year < b->tm_year ? -1 : 1;
else if (a->tm_mon != b->tm_mon)
return a->tm_mon < b->tm_mon ? -1 : 1;
else if (a->tm_mday != b->tm_mday)
return a->tm_mday < b->tm_mday ? -1 : 1;
else if (a->tm_hour != b->tm_hour)
return a->tm_hour < b->tm_hour ? -1 : 1;
else if (a->tm_min != b->tm_min)
return a->tm_min < b->tm_min ? -1 : 1;
else if (a->tm_sec != b->tm_sec)
return a->tm_sec < b->tm_sec ? -1 : 1;
else
return 0;
}
static VALUE
time_utc_or_local(int argc, VALUE *argv, int utc_p, VALUE klass)
{
struct vtm vtm;
VALUE time;
time_arg(argc, argv, &vtm);
if (utc_p)
time = time_new_timew(klass, timegmw(&vtm));
else
time = time_new_timew(klass, timelocalw(&vtm));
if (utc_p) return time_gmtime(time);
return time_localtime(time);
}
/*
* call-seq:
* Time.utc(year) -> time
* Time.utc(year, month) -> time
* Time.utc(year, month, day) -> time
* Time.utc(year, month, day, hour) -> time
* Time.utc(year, month, day, hour, min) -> time
* Time.utc(year, month, day, hour, min, sec_with_frac) -> time
* Time.utc(year, month, day, hour, min, sec, usec_with_frac) -> time
* Time.utc(sec, min, hour, day, month, year, dummy, dummy, dummy, dummy) -> time
* Time.gm(year) -> time
* Time.gm(year, month) -> time
* Time.gm(year, month, day) -> time
* Time.gm(year, month, day, hour) -> time
* Time.gm(year, month, day, hour, min) -> time
* Time.gm(year, month, day, hour, min, sec_with_frac) -> time
* Time.gm(year, month, day, hour, min, sec, usec_with_frac) -> time
* Time.gm(sec, min, hour, day, month, year, dummy, dummy, dummy, dummy) -> time
*
* Creates a Time object based on given values, interpreted as UTC (GMT). The
* year must be specified. Other values default to the minimum value
* for that field (and may be +nil+ or omitted). Months may
* be specified by numbers from 1 to 12, or by the three-letter English
* month names. Hours are specified on a 24-hour clock (0..23). Raises
* an ArgumentError if any values are out of range. Will
* also accept ten arguments in the order output by Time#to_a.
*
* +sec_with_frac+ and +usec_with_frac+ can have a fractional part.
*
* Time.utc(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 UTC
* Time.gm(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 UTC
*/
static VALUE
time_s_mkutc(int argc, VALUE *argv, VALUE klass)
{
return time_utc_or_local(argc, argv, TRUE, klass);
}
/*
* call-seq:
* Time.local(year) -> time
* Time.local(year, month) -> time
* Time.local(year, month, day) -> time
* Time.local(year, month, day, hour) -> time
* Time.local(year, month, day, hour, min) -> time
* Time.local(year, month, day, hour, min, sec_with_frac) -> time
* Time.local(year, month, day, hour, min, sec, usec_with_frac) -> time
* Time.local(sec, min, hour, day, month, year, dummy, dummy, isdst, dummy) -> time
* Time.mktime(year) -> time
* Time.mktime(year, month) -> time
* Time.mktime(year, month, day) -> time
* Time.mktime(year, month, day, hour) -> time
* Time.mktime(year, month, day, hour, min) -> time
* Time.mktime(year, month, day, hour, min, sec_with_frac) -> time
* Time.mktime(year, month, day, hour, min, sec, usec_with_frac) -> time
* Time.mktime(sec, min, hour, day, month, year, dummy, dummy, isdst, dummy) -> time
*
* Same as Time::gm, but interprets the values in the
* local time zone.
*
* Time.local(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 -0600
*/
static VALUE
time_s_mktime(int argc, VALUE *argv, VALUE klass)
{
return time_utc_or_local(argc, argv, FALSE, klass);
}
/*
* call-seq:
* time.to_i -> int
* time.tv_sec -> int
*
* Returns the value of _time_ as an integer number of seconds
* since the Epoch.
*
* t = Time.now
* "%10.5f" % t.to_f #=> "1270968656.89607"
* t.to_i #=> 1270968656
*/
static VALUE
time_to_i(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return w2v(wdiv(tobj->timew, WINT2FIXWV(TIME_SCALE)));
}
/*
* call-seq:
* time.to_f -> float
*
* Returns the value of _time_ as a floating point number of
* seconds since the Epoch.
*
* t = Time.now
* "%10.5f" % t.to_f #=> "1270968744.77658"
* t.to_i #=> 1270968744
*
* Note that IEEE 754 double is not accurate enough to represent
* the number of nanoseconds since the Epoch.
*/
static VALUE
time_to_f(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return rb_Float(rb_time_unmagnify_to_float(tobj->timew));
}
/*
* call-seq:
* time.to_r -> a_rational
*
* Returns the value of _time_ as a rational number of seconds
* since the Epoch.
*
* t = Time.now
* p t.to_r #=> (1270968792716287611/1000000000)
*
* This methods is intended to be used to get an accurate value
* representing the nanoseconds since the Epoch. You can use this method
* to convert _time_ to another Epoch.
*/
static VALUE
time_to_r(VALUE time)
{
struct time_object *tobj;
VALUE v;
GetTimeval(time, tobj);
v = w2v(rb_time_unmagnify(tobj->timew));
if (!RB_TYPE_P(v, T_RATIONAL)) {
v = rb_Rational1(v);
}
return v;
}
/*
* call-seq:
* time.usec -> int
* time.tv_usec -> int
*
* Returns the number of microseconds for _time_.
*
* t = Time.now #=> 2007-11-19 08:03:26 -0600
* "%10.6f" % t.to_f #=> "1195481006.775195"
* t.usec #=> 775195
*/
static VALUE
time_usec(VALUE time)
{
struct time_object *tobj;
wideval_t w, q, r;
GetTimeval(time, tobj);
w = wmod(tobj->timew, WINT2WV(TIME_SCALE));
wmuldivmod(w, WINT2FIXWV(1000000), WINT2FIXWV(TIME_SCALE), &q, &r);
return rb_to_int(w2v(q));
}
/*
* call-seq:
* time.nsec -> int
* time.tv_nsec -> int
*
* Returns the number of nanoseconds for _time_.
*
* t = Time.now #=> 2007-11-17 15:18:03 +0900
* "%10.9f" % t.to_f #=> "1195280283.536151409"
* t.nsec #=> 536151406
*
* The lowest digits of #to_f and #nsec are different because
* IEEE 754 double is not accurate enough to represent
* the exact number of nanoseconds since the Epoch.
*
* The more accurate value is returned by #nsec.
*/
static VALUE
time_nsec(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return rb_to_int(w2v(wmulquoll(wmod(tobj->timew, WINT2WV(TIME_SCALE)), 1000000000, TIME_SCALE)));
}
/*
* call-seq:
* time.subsec -> number
*
* Returns the fraction for _time_.
*
* The return value can be a rational number.
*
* t = Time.now #=> 2009-03-26 22:33:12 +0900
* "%10.9f" % t.to_f #=> "1238074392.940563917"
* t.subsec #=> (94056401/100000000)
*
* The lowest digits of #to_f and #subsec are different because
* IEEE 754 double is not accurate enough to represent
* the rational number.
*
* The more accurate value is returned by #subsec.
*/
static VALUE
time_subsec(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return quo(w2v(wmod(tobj->timew, WINT2FIXWV(TIME_SCALE))), INT2FIX(TIME_SCALE));
}
/*
* call-seq:
* time <=> other_time -> -1, 0, +1 or nil
*
* Comparison---Compares +time+ with +other_time+.
*
* -1, 0, +1 or nil depending on whether +time+ is less than, equal to, or
* greater than +other_time+.
*
* +nil+ is returned if the two values are incomparable.
*
* t = Time.now #=> 2007-11-19 08:12:12 -0600
* t2 = t + 2592000 #=> 2007-12-19 08:12:12 -0600
* t <=> t2 #=> -1
* t2 <=> t #=> 1
*
* t = Time.now #=> 2007-11-19 08:13:38 -0600
* t2 = t + 0.1 #=> 2007-11-19 08:13:38 -0600
* t.nsec #=> 98222999
* t2.nsec #=> 198222999
* t <=> t2 #=> -1
* t2 <=> t #=> 1
* t <=> t #=> 0
*/
static VALUE
time_cmp(VALUE time1, VALUE time2)
{
struct time_object *tobj1, *tobj2;
int n;
GetTimeval(time1, tobj1);
if (IsTimeval(time2)) {
GetTimeval(time2, tobj2);
n = wcmp(tobj1->timew, tobj2->timew);
}
else {
return rb_invcmp(time1, time2);
}
if (n == 0) return INT2FIX(0);
if (n > 0) return INT2FIX(1);
return INT2FIX(-1);
}
/*
* call-seq:
* time.eql?(other_time)
*
* Returns +true+ if _time_ and +other_time+ are
* both Time objects with the same seconds and fractional seconds.
*/
static VALUE
time_eql(VALUE time1, VALUE time2)
{
struct time_object *tobj1, *tobj2;
GetTimeval(time1, tobj1);
if (IsTimeval(time2)) {
GetTimeval(time2, tobj2);
return rb_equal(w2v(tobj1->timew), w2v(tobj2->timew));
}
return Qfalse;
}
/*
* call-seq:
* time.utc? -> true or false
* time.gmt? -> true or false
*
* Returns +true+ if _time_ represents a time in UTC (GMT).
*
* t = Time.now #=> 2007-11-19 08:15:23 -0600
* t.utc? #=> false
* t = Time.gm(2000,"jan",1,20,15,1) #=> 2000-01-01 20:15:01 UTC
* t.utc? #=> true
*
* t = Time.now #=> 2007-11-19 08:16:03 -0600
* t.gmt? #=> false
* t = Time.gm(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 UTC
* t.gmt? #=> true
*/
static VALUE
time_utc_p(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
if (TIME_UTC_P(tobj)) return Qtrue;
return Qfalse;
}
/*
* call-seq:
* time.hash -> fixnum
*
* Returns a hash code for this Time object.
*
* See also Object#hash.
*/
static VALUE
time_hash(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
return rb_hash(w2v(tobj->timew));
}
/* :nodoc: */
static VALUE
time_init_copy(VALUE copy, VALUE time)
{
struct time_object *tobj, *tcopy;
if (!OBJ_INIT_COPY(copy, time)) return copy;
GetTimeval(time, tobj);
GetNewTimeval(copy, tcopy);
MEMCPY(tcopy, tobj, struct time_object, 1);
return copy;
}
static VALUE
time_dup(VALUE time)
{
VALUE dup = time_s_alloc(rb_obj_class(time));
time_init_copy(dup, time);
return dup;
}
static VALUE
time_localtime(VALUE time)
{
struct time_object *tobj;
struct vtm vtm;
GetTimeval(time, tobj);
if (TIME_LOCALTIME_P(tobj)) {
if (tobj->tm_got)
return time;
}
else {
time_modify(time);
}
if (!localtimew(tobj->timew, &vtm))
rb_raise(rb_eArgError, "localtime error");
tobj->vtm = vtm;
tobj->tm_got = 1;
TIME_SET_LOCALTIME(tobj);
return time;
}
/*
* call-seq:
* time.localtime -> time
* time.localtime(utc_offset) -> time
*
* Converts _time_ to local time (using the local time zone in
* effect for this process) modifying the receiver.
*
* If +utc_offset+ is given, it is used instead of the local time.
*
* t = Time.utc(2000, "jan", 1, 20, 15, 1) #=> 2000-01-01 20:15:01 UTC
* t.utc? #=> true
*
* t.localtime #=> 2000-01-01 14:15:01 -0600
* t.utc? #=> false
*
* t.localtime("+09:00") #=> 2000-01-02 05:15:01 +0900
* t.utc? #=> false
*/
static VALUE
time_localtime_m(int argc, VALUE *argv, VALUE time)
{
VALUE off;
rb_scan_args(argc, argv, "01", &off);
if (!NIL_P(off)) {
off = utc_offset_arg(off);
validate_utc_offset(off);
time_set_utc_offset(time, off);
return time_fixoff(time);
}
return time_localtime(time);
}
/*
* call-seq:
* time.gmtime -> time
* time.utc -> time
*
* Converts _time_ to UTC (GMT), modifying the receiver.
*
* t = Time.now #=> 2007-11-19 08:18:31 -0600
* t.gmt? #=> false
* t.gmtime #=> 2007-11-19 14:18:31 UTC
* t.gmt? #=> true
*
* t = Time.now #=> 2007-11-19 08:18:51 -0600
* t.utc? #=> false
* t.utc #=> 2007-11-19 14:18:51 UTC
* t.utc? #=> true
*/
static VALUE
time_gmtime(VALUE time)
{
struct time_object *tobj;
struct vtm vtm;
GetTimeval(time, tobj);
if (TIME_UTC_P(tobj)) {
if (tobj->tm_got)
return time;
}
else {
time_modify(time);
}
if (!gmtimew(tobj->timew, &vtm))
rb_raise(rb_eArgError, "gmtime error");
tobj->vtm = vtm;
tobj->tm_got = 1;
TIME_SET_UTC(tobj);
return time;
}
static VALUE
time_fixoff(VALUE time)
{
struct time_object *tobj;
struct vtm vtm;
VALUE off;
GetTimeval(time, tobj);
if (TIME_FIXOFF_P(tobj)) {
if (tobj->tm_got)
return time;
}
else {
time_modify(time);
}
if (TIME_FIXOFF_P(tobj))
off = tobj->vtm.utc_offset;
else
off = INT2FIX(0);
if (!gmtimew(tobj->timew, &vtm))
rb_raise(rb_eArgError, "gmtime error");
tobj->vtm = vtm;
vtm_add_offset(&tobj->vtm, off);
tobj->tm_got = 1;
TIME_SET_FIXOFF(tobj, off);
return time;
}
/*
* call-seq:
* time.getlocal -> new_time
* time.getlocal(utc_offset) -> new_time
*
* Returns a new Time object representing _time_ in
* local time (using the local time zone in effect for this process).
*
* If +utc_offset+ is given, it is used instead of the local time.
* +utc_offset+ can be given as a human-readable string (eg. <code>"+09:00"</code>)
* or as a number of seconds (eg. <code>32400</code>).
*
* t = Time.utc(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 UTC
* t.utc? #=> true
*
* l = t.getlocal #=> 2000-01-01 14:15:01 -0600
* l.utc? #=> false
* t == l #=> true
*
* j = t.getlocal("+09:00") #=> 2000-01-02 05:15:01 +0900
* j.utc? #=> false
* t == j #=> true
*
* k = t.getlocal(9*60*60) #=> 2000-01-02 05:15:01 +0900
* k.utc? #=> false
* t == k #=> true
*/
* array.c (rb_ary_modify): should copy the internal buffer if the modifying buffer is shared. * array.c (ary_make_shared): make an internal buffer of an array to be shared. * array.c (rb_ary_shift): avoid sliding an internal buffer by using shared buffer. * array.c (rb_ary_subseq): avoid copying the buffer. * parse.y (gettable): should freeze __LINE__ string. * io.c (rb_io_puts): old behavoir restored. rationale: a) if you want to call to_s for arrays, you can just call print a, "\n". b) to_s wastes memory if array (and sum of its contents) is huge. c) now any object that has to_ary is treated as an array, using rb_check_convert_type(). * hash.c (rb_hash_initialize): now accepts a block to calculate the default value. [new] * hash.c (rb_hash_aref): call "default" method to get the value corrensponding to the non existing key. * hash.c (rb_hash_default): get the default value based on the block given to 'new'. Now it takes an optinal "key" argument. "default" became the method to get the value for non existing key. Users may override "default" method to change the hash behavior. * hash.c (rb_hash_set_default): clear the flag if a block is given to 'new' * object.c (Init_Object): undef Data.allocate, left Data.new. * ext/curses/curses.c (window_scrollok): use RTEST(). * ext/curses/curses.c (window_idlok): ditto. * ext/curses/curses.c (window_keypad): ditto. * ext/curses/curses.c (window_idlok): idlok() may return void on some platforms; so don't use return value. * ext/curses/curses.c (window_scrollok): ditto for consistency. * ext/curses/curses.c: replace FIX2INT() by typechecking NUM2INT(). * parse.y (str_extend): should not process immature #$x and #@x interpolation, e.g #@#@ etc. * enum.c (enum_sort_by): sort_by does not have to be stable always. * enum.c (enum_sort_by): call qsort directly to gain performance. * util.c (ruby_qsort): ruby_qsort(qs6) is now native thread safe. * error.c (rb_sys_fail): it must be a bug if it's called when errno == 0. * regex.c (WC2MBC1ST): should not pass through > 0x80 number in UTF-8. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1896 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-12-10 02:18:16 -05:00
static VALUE
time_getlocaltime(int argc, VALUE *argv, VALUE time)
* array.c (rb_ary_modify): should copy the internal buffer if the modifying buffer is shared. * array.c (ary_make_shared): make an internal buffer of an array to be shared. * array.c (rb_ary_shift): avoid sliding an internal buffer by using shared buffer. * array.c (rb_ary_subseq): avoid copying the buffer. * parse.y (gettable): should freeze __LINE__ string. * io.c (rb_io_puts): old behavoir restored. rationale: a) if you want to call to_s for arrays, you can just call print a, "\n". b) to_s wastes memory if array (and sum of its contents) is huge. c) now any object that has to_ary is treated as an array, using rb_check_convert_type(). * hash.c (rb_hash_initialize): now accepts a block to calculate the default value. [new] * hash.c (rb_hash_aref): call "default" method to get the value corrensponding to the non existing key. * hash.c (rb_hash_default): get the default value based on the block given to 'new'. Now it takes an optinal "key" argument. "default" became the method to get the value for non existing key. Users may override "default" method to change the hash behavior. * hash.c (rb_hash_set_default): clear the flag if a block is given to 'new' * object.c (Init_Object): undef Data.allocate, left Data.new. * ext/curses/curses.c (window_scrollok): use RTEST(). * ext/curses/curses.c (window_idlok): ditto. * ext/curses/curses.c (window_keypad): ditto. * ext/curses/curses.c (window_idlok): idlok() may return void on some platforms; so don't use return value. * ext/curses/curses.c (window_scrollok): ditto for consistency. * ext/curses/curses.c: replace FIX2INT() by typechecking NUM2INT(). * parse.y (str_extend): should not process immature #$x and #@x interpolation, e.g #@#@ etc. * enum.c (enum_sort_by): sort_by does not have to be stable always. * enum.c (enum_sort_by): call qsort directly to gain performance. * util.c (ruby_qsort): ruby_qsort(qs6) is now native thread safe. * error.c (rb_sys_fail): it must be a bug if it's called when errno == 0. * regex.c (WC2MBC1ST): should not pass through > 0x80 number in UTF-8. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1896 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-12-10 02:18:16 -05:00
{
VALUE off;
rb_scan_args(argc, argv, "01", &off);
if (!NIL_P(off)) {
off = utc_offset_arg(off);
validate_utc_offset(off);
time = time_dup(time);
time_set_utc_offset(time, off);
return time_fixoff(time);
}
* array.c (rb_ary_modify): should copy the internal buffer if the modifying buffer is shared. * array.c (ary_make_shared): make an internal buffer of an array to be shared. * array.c (rb_ary_shift): avoid sliding an internal buffer by using shared buffer. * array.c (rb_ary_subseq): avoid copying the buffer. * parse.y (gettable): should freeze __LINE__ string. * io.c (rb_io_puts): old behavoir restored. rationale: a) if you want to call to_s for arrays, you can just call print a, "\n". b) to_s wastes memory if array (and sum of its contents) is huge. c) now any object that has to_ary is treated as an array, using rb_check_convert_type(). * hash.c (rb_hash_initialize): now accepts a block to calculate the default value. [new] * hash.c (rb_hash_aref): call "default" method to get the value corrensponding to the non existing key. * hash.c (rb_hash_default): get the default value based on the block given to 'new'. Now it takes an optinal "key" argument. "default" became the method to get the value for non existing key. Users may override "default" method to change the hash behavior. * hash.c (rb_hash_set_default): clear the flag if a block is given to 'new' * object.c (Init_Object): undef Data.allocate, left Data.new. * ext/curses/curses.c (window_scrollok): use RTEST(). * ext/curses/curses.c (window_idlok): ditto. * ext/curses/curses.c (window_keypad): ditto. * ext/curses/curses.c (window_idlok): idlok() may return void on some platforms; so don't use return value. * ext/curses/curses.c (window_scrollok): ditto for consistency. * ext/curses/curses.c: replace FIX2INT() by typechecking NUM2INT(). * parse.y (str_extend): should not process immature #$x and #@x interpolation, e.g #@#@ etc. * enum.c (enum_sort_by): sort_by does not have to be stable always. * enum.c (enum_sort_by): call qsort directly to gain performance. * util.c (ruby_qsort): ruby_qsort(qs6) is now native thread safe. * error.c (rb_sys_fail): it must be a bug if it's called when errno == 0. * regex.c (WC2MBC1ST): should not pass through > 0x80 number in UTF-8. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1896 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-12-10 02:18:16 -05:00
return time_localtime(time_dup(time));
}
/*
* call-seq:
* time.getgm -> new_time
* time.getutc -> new_time
*
* Returns a new Time object representing _time_ in UTC.
*
* t = Time.local(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 -0600
* t.gmt? #=> false
* y = t.getgm #=> 2000-01-02 02:15:01 UTC
* y.gmt? #=> true
* t == y #=> true
*/
* array.c (rb_ary_modify): should copy the internal buffer if the modifying buffer is shared. * array.c (ary_make_shared): make an internal buffer of an array to be shared. * array.c (rb_ary_shift): avoid sliding an internal buffer by using shared buffer. * array.c (rb_ary_subseq): avoid copying the buffer. * parse.y (gettable): should freeze __LINE__ string. * io.c (rb_io_puts): old behavoir restored. rationale: a) if you want to call to_s for arrays, you can just call print a, "\n". b) to_s wastes memory if array (and sum of its contents) is huge. c) now any object that has to_ary is treated as an array, using rb_check_convert_type(). * hash.c (rb_hash_initialize): now accepts a block to calculate the default value. [new] * hash.c (rb_hash_aref): call "default" method to get the value corrensponding to the non existing key. * hash.c (rb_hash_default): get the default value based on the block given to 'new'. Now it takes an optinal "key" argument. "default" became the method to get the value for non existing key. Users may override "default" method to change the hash behavior. * hash.c (rb_hash_set_default): clear the flag if a block is given to 'new' * object.c (Init_Object): undef Data.allocate, left Data.new. * ext/curses/curses.c (window_scrollok): use RTEST(). * ext/curses/curses.c (window_idlok): ditto. * ext/curses/curses.c (window_keypad): ditto. * ext/curses/curses.c (window_idlok): idlok() may return void on some platforms; so don't use return value. * ext/curses/curses.c (window_scrollok): ditto for consistency. * ext/curses/curses.c: replace FIX2INT() by typechecking NUM2INT(). * parse.y (str_extend): should not process immature #$x and #@x interpolation, e.g #@#@ etc. * enum.c (enum_sort_by): sort_by does not have to be stable always. * enum.c (enum_sort_by): call qsort directly to gain performance. * util.c (ruby_qsort): ruby_qsort(qs6) is now native thread safe. * error.c (rb_sys_fail): it must be a bug if it's called when errno == 0. * regex.c (WC2MBC1ST): should not pass through > 0x80 number in UTF-8. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1896 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-12-10 02:18:16 -05:00
static VALUE
time_getgmtime(VALUE time)
* array.c (rb_ary_modify): should copy the internal buffer if the modifying buffer is shared. * array.c (ary_make_shared): make an internal buffer of an array to be shared. * array.c (rb_ary_shift): avoid sliding an internal buffer by using shared buffer. * array.c (rb_ary_subseq): avoid copying the buffer. * parse.y (gettable): should freeze __LINE__ string. * io.c (rb_io_puts): old behavoir restored. rationale: a) if you want to call to_s for arrays, you can just call print a, "\n". b) to_s wastes memory if array (and sum of its contents) is huge. c) now any object that has to_ary is treated as an array, using rb_check_convert_type(). * hash.c (rb_hash_initialize): now accepts a block to calculate the default value. [new] * hash.c (rb_hash_aref): call "default" method to get the value corrensponding to the non existing key. * hash.c (rb_hash_default): get the default value based on the block given to 'new'. Now it takes an optinal "key" argument. "default" became the method to get the value for non existing key. Users may override "default" method to change the hash behavior. * hash.c (rb_hash_set_default): clear the flag if a block is given to 'new' * object.c (Init_Object): undef Data.allocate, left Data.new. * ext/curses/curses.c (window_scrollok): use RTEST(). * ext/curses/curses.c (window_idlok): ditto. * ext/curses/curses.c (window_keypad): ditto. * ext/curses/curses.c (window_idlok): idlok() may return void on some platforms; so don't use return value. * ext/curses/curses.c (window_scrollok): ditto for consistency. * ext/curses/curses.c: replace FIX2INT() by typechecking NUM2INT(). * parse.y (str_extend): should not process immature #$x and #@x interpolation, e.g #@#@ etc. * enum.c (enum_sort_by): sort_by does not have to be stable always. * enum.c (enum_sort_by): call qsort directly to gain performance. * util.c (ruby_qsort): ruby_qsort(qs6) is now native thread safe. * error.c (rb_sys_fail): it must be a bug if it's called when errno == 0. * regex.c (WC2MBC1ST): should not pass through > 0x80 number in UTF-8. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1896 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-12-10 02:18:16 -05:00
{
return time_gmtime(time_dup(time));
}
static VALUE
time_get_tm(VALUE time, struct time_object *tobj)
{
if (TIME_UTC_P(tobj)) return time_gmtime(time);
if (TIME_FIXOFF_P(tobj)) return time_fixoff(time);
return time_localtime(time);
}
static VALUE strftimev(const char *fmt, VALUE time, rb_encoding *enc);
/*
* call-seq:
* time.asctime -> string
* time.ctime -> string
*
* Returns a canonical string representation of _time_.
*
* Time.now.asctime #=> "Wed Apr 9 08:56:03 2003"
*/
static VALUE
time_asctime(VALUE time)
{
return strftimev("%a %b %e %T %Y", time, rb_usascii_encoding());
}
/*
* call-seq:
* time.inspect -> string
* time.to_s -> string
*
* Returns a string representing _time_. Equivalent to calling
* #strftime with the appropriate format string.
*
* t = Time.now
* t.to_s => "2012-11-10 18:16:12 +0100"
* t.strftime "%Y-%m-%d %H:%M:%S %z" => "2012-11-10 18:16:12 +0100"
*
* t.utc.to_s => "2012-11-10 17:16:12 UTC"
* t.strftime "%Y-%m-%d %H:%M:%S UTC" => "2012-11-10 17:16:12 UTC"
*/
static VALUE
time_to_s(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
if (TIME_UTC_P(tobj))
return strftimev("%Y-%m-%d %H:%M:%S UTC", time, rb_usascii_encoding());
else
return strftimev("%Y-%m-%d %H:%M:%S %z", time, rb_usascii_encoding());
}
static VALUE
time_add(struct time_object *tobj, VALUE offset, int sign)
{
VALUE result;
offset = num_exact(offset);
if (sign < 0)
result = time_new_timew(rb_cTime, wsub(tobj->timew, rb_time_magnify(v2w(offset))));
else
result = time_new_timew(rb_cTime, wadd(tobj->timew, rb_time_magnify(v2w(offset))));
if (TIME_UTC_P(tobj)) {
GetTimeval(result, tobj);
TIME_SET_UTC(tobj);
}
else if (TIME_FIXOFF_P(tobj)) {
VALUE off = tobj->vtm.utc_offset;
GetTimeval(result, tobj);
TIME_SET_FIXOFF(tobj, off);
}
return result;
}
/*
* call-seq:
* time + numeric -> time
*
* Addition --- Adds some number of seconds (possibly fractional) to
* _time_ and returns that value as a new Time object.
*
* t = Time.now #=> 2007-11-19 08:22:21 -0600
* t + (60 * 60 * 24) #=> 2007-11-20 08:22:21 -0600
*/
static VALUE
time_plus(VALUE time1, VALUE time2)
{
struct time_object *tobj;
GetTimeval(time1, tobj);
if (IsTimeval(time2)) {
rb_raise(rb_eTypeError, "time + time?");
}
return time_add(tobj, time2, 1);
}
/*
* call-seq:
* time - other_time -> float
* time - numeric -> time
*
* Difference --- Returns a new Time object that represents the difference
* between _time_ and +other_time+, or subtracts the given number
* of seconds in +numeric+ from _time_.
*
* t = Time.now #=> 2007-11-19 08:23:10 -0600
* t2 = t + 2592000 #=> 2007-12-19 08:23:10 -0600
* t2 - t #=> 2592000.0
* t2 - 2592000 #=> 2007-11-19 08:23:10 -0600
*/
static VALUE
time_minus(VALUE time1, VALUE time2)
{
struct time_object *tobj;
GetTimeval(time1, tobj);
if (IsTimeval(time2)) {
struct time_object *tobj2;
GetTimeval(time2, tobj2);
return rb_Float(rb_time_unmagnify_to_float(wsub(tobj->timew, tobj2->timew)));
}
return time_add(tobj, time2, -1);
}
/*
* call-seq:
* time.succ -> new_time
*
* Returns a new Time object, one second later than _time_.
* Time#succ is obsolete since 1.9.2 for time is not a discrete value.
*
* t = Time.now #=> 2007-11-19 08:23:57 -0600
* t.succ #=> 2007-11-19 08:23:58 -0600
*
* Use instead <code>time + 1</code>
*
* t + 1 #=> 2007-11-19 08:23:58 -0600
*/
VALUE
rb_time_succ(VALUE time)
{
struct time_object *tobj;
struct time_object *tobj2;
rb_warn("Time#succ is obsolete; use time + 1");
GetTimeval(time, tobj);
time = time_new_timew(rb_cTime, wadd(tobj->timew, WINT2FIXWV(TIME_SCALE)));
GetTimeval(time, tobj2);
TIME_COPY_GMT(tobj2, tobj);
return time;
}
#define time_succ rb_time_succ
/*
* call-seq:
* time.round([ndigits]) -> new_time
*
* Rounds sub seconds to a given precision in decimal digits (0 digits by default).
* It returns a new Time object.
* +ndigits+ should be zero or positive integer.
*
* require 'time'
*
* t = Time.utc(2010,3,30, 5,43,"25.123456789".to_r)
* p t.iso8601(10) #=> "2010-03-30T05:43:25.1234567890Z"
* p t.round.iso8601(10) #=> "2010-03-30T05:43:25.0000000000Z"
* p t.round(0).iso8601(10) #=> "2010-03-30T05:43:25.0000000000Z"
* p t.round(1).iso8601(10) #=> "2010-03-30T05:43:25.1000000000Z"
* p t.round(2).iso8601(10) #=> "2010-03-30T05:43:25.1200000000Z"
* p t.round(3).iso8601(10) #=> "2010-03-30T05:43:25.1230000000Z"
* p t.round(4).iso8601(10) #=> "2010-03-30T05:43:25.1235000000Z"
* p t.round(5).iso8601(10) #=> "2010-03-30T05:43:25.1234600000Z"
* p t.round(6).iso8601(10) #=> "2010-03-30T05:43:25.1234570000Z"
* p t.round(7).iso8601(10) #=> "2010-03-30T05:43:25.1234568000Z"
* p t.round(8).iso8601(10) #=> "2010-03-30T05:43:25.1234567900Z"
* p t.round(9).iso8601(10) #=> "2010-03-30T05:43:25.1234567890Z"
* p t.round(10).iso8601(10) #=> "2010-03-30T05:43:25.1234567890Z"
*
* t = Time.utc(1999,12,31, 23,59,59)
* p((t + 0.4).round.iso8601(3)) #=> "1999-12-31T23:59:59.000Z"
* p((t + 0.49).round.iso8601(3)) #=> "1999-12-31T23:59:59.000Z"
* p((t + 0.5).round.iso8601(3)) #=> "2000-01-01T00:00:00.000Z"
* p((t + 1.4).round.iso8601(3)) #=> "2000-01-01T00:00:00.000Z"
* p((t + 1.49).round.iso8601(3)) #=> "2000-01-01T00:00:00.000Z"
* p((t + 1.5).round.iso8601(3)) #=> "2000-01-01T00:00:01.000Z"
*
* t = Time.utc(1999,12,31, 23,59,59)
* p (t + 0.123456789).round(4).iso8601(6) #=> "1999-12-31T23:59:59.123500Z"
*/
static VALUE
time_round(int argc, VALUE *argv, VALUE time)
{
VALUE ndigits, v, a, b, den;
long nd;
struct time_object *tobj;
rb_scan_args(argc, argv, "01", &ndigits);
if (NIL_P(ndigits))
ndigits = INT2FIX(0);
else
ndigits = rb_to_int(ndigits);
nd = NUM2LONG(ndigits);
if (nd < 0)
rb_raise(rb_eArgError, "negative ndigits given");
GetTimeval(time, tobj);
v = w2v(rb_time_unmagnify(tobj->timew));
a = INT2FIX(1);
b = INT2FIX(10);
while (0 < nd) {
if (nd & 1)
a = mul(a, b);
b = mul(b, b);
nd = nd >> 1;
}
den = quo(INT2FIX(1), a);
v = mod(v, den);
if (lt(v, quo(den, INT2FIX(2))))
return time_add(tobj, v, -1);
else
return time_add(tobj, sub(den, v), 1);
}
/*
* call-seq:
* time.sec -> fixnum
*
* Returns the second of the minute (0..60) for _time_.
*
* *Note:* Seconds range from zero to 60 to allow the system to inject
* leap seconds. See http://en.wikipedia.org/wiki/Leap_second for further
* details.
*
* t = Time.now #=> 2007-11-19 08:25:02 -0600
* t.sec #=> 2
*/
static VALUE
time_sec(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.sec);
}
/*
* call-seq:
* time.min -> fixnum
*
* Returns the minute of the hour (0..59) for _time_.
*
* t = Time.now #=> 2007-11-19 08:25:51 -0600
* t.min #=> 25
*/
static VALUE
time_min(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.min);
}
/*
* call-seq:
* time.hour -> fixnum
*
* Returns the hour of the day (0..23) for _time_.
*
* t = Time.now #=> 2007-11-19 08:26:20 -0600
* t.hour #=> 8
*/
static VALUE
time_hour(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.hour);
}
/*
* call-seq:
* time.day -> fixnum
* time.mday -> fixnum
*
* Returns the day of the month (1..n) for _time_.
*
* t = Time.now #=> 2007-11-19 08:27:03 -0600
* t.day #=> 19
* t.mday #=> 19
*/
static VALUE
time_mday(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.mday);
}
/*
* call-seq:
* time.mon -> fixnum
* time.month -> fixnum
*
* Returns the month of the year (1..12) for _time_.
*
* t = Time.now #=> 2007-11-19 08:27:30 -0600
* t.mon #=> 11
* t.month #=> 11
*/
static VALUE
time_mon(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.mon);
}
/*
* call-seq:
* time.year -> fixnum
*
* Returns the year for _time_ (including the century).
*
* t = Time.now #=> 2007-11-19 08:27:51 -0600
* t.year #=> 2007
*/
static VALUE
time_year(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return tobj->vtm.year;
}
/*
* call-seq:
* time.wday -> fixnum
*
* Returns an integer representing the day of the week, 0..6, with
* Sunday == 0.
*
* t = Time.now #=> 2007-11-20 02:35:35 -0600
* t.wday #=> 2
* t.sunday? #=> false
* t.monday? #=> false
* t.tuesday? #=> true
* t.wednesday? #=> false
* t.thursday? #=> false
* t.friday? #=> false
* t.saturday? #=> false
*/
static VALUE
time_wday(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX((int)tobj->vtm.wday);
}
#define wday_p(n) {\
struct time_object *tobj;\
GetTimeval(time, tobj);\
MAKE_TM(time, tobj);\
return (tobj->vtm.wday == (n)) ? Qtrue : Qfalse;\
}
/*
* call-seq:
* time.sunday? -> true or false
*
* Returns +true+ if _time_ represents Sunday.
*
* t = Time.local(1990, 4, 1) #=> 1990-04-01 00:00:00 -0600
* t.sunday? #=> true
*/
static VALUE
time_sunday(VALUE time)
{
wday_p(0);
}
/*
* call-seq:
* time.monday? -> true or false
*
* Returns +true+ if _time_ represents Monday.
*
* t = Time.local(2003, 8, 4) #=> 2003-08-04 00:00:00 -0500
* p t.monday? #=> true
*/
static VALUE
time_monday(VALUE time)
{
wday_p(1);
}
/*
* call-seq:
* time.tuesday? -> true or false
*
* Returns +true+ if _time_ represents Tuesday.
*
* t = Time.local(1991, 2, 19) #=> 1991-02-19 00:00:00 -0600
* p t.tuesday? #=> true
*/
static VALUE
time_tuesday(VALUE time)
{
wday_p(2);
}
/*
* call-seq:
* time.wednesday? -> true or false
*
* Returns +true+ if _time_ represents Wednesday.
*
* t = Time.local(1993, 2, 24) #=> 1993-02-24 00:00:00 -0600
* p t.wednesday? #=> true
*/
static VALUE
time_wednesday(VALUE time)
{
wday_p(3);
}
/*
* call-seq:
* time.thursday? -> true or false
*
* Returns +true+ if _time_ represents Thursday.
*
* t = Time.local(1995, 12, 21) #=> 1995-12-21 00:00:00 -0600
* p t.thursday? #=> true
*/
static VALUE
time_thursday(VALUE time)
{
wday_p(4);
}
/*
* call-seq:
* time.friday? -> true or false
*
* Returns +true+ if _time_ represents Friday.
*
* t = Time.local(1987, 12, 18) #=> 1987-12-18 00:00:00 -0600
* t.friday? #=> true
*/
static VALUE
time_friday(VALUE time)
{
wday_p(5);
}
/*
* call-seq:
* time.saturday? -> true or false
*
* Returns +true+ if _time_ represents Saturday.
*
* t = Time.local(2006, 6, 10) #=> 2006-06-10 00:00:00 -0500
* t.saturday? #=> true
*/
static VALUE
time_saturday(VALUE time)
{
wday_p(6);
}
/*
* call-seq:
* time.yday -> fixnum
*
* Returns an integer representing the day of the year, 1..366.
*
* t = Time.now #=> 2007-11-19 08:32:31 -0600
* t.yday #=> 323
*/
static VALUE
time_yday(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return INT2FIX(tobj->vtm.yday);
}
/*
* call-seq:
* time.isdst -> true or false
* time.dst? -> true or false
*
* Returns +true+ if _time_ occurs during Daylight
* Saving Time in its time zone.
*
* # CST6CDT:
* Time.local(2000, 1, 1).zone #=> "CST"
* Time.local(2000, 1, 1).isdst #=> false
* Time.local(2000, 1, 1).dst? #=> false
* Time.local(2000, 7, 1).zone #=> "CDT"
* Time.local(2000, 7, 1).isdst #=> true
* Time.local(2000, 7, 1).dst? #=> true
*
* # Asia/Tokyo:
* Time.local(2000, 1, 1).zone #=> "JST"
* Time.local(2000, 1, 1).isdst #=> false
* Time.local(2000, 1, 1).dst? #=> false
* Time.local(2000, 7, 1).zone #=> "JST"
* Time.local(2000, 7, 1).isdst #=> false
* Time.local(2000, 7, 1).dst? #=> false
*/
static VALUE
time_isdst(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return tobj->vtm.isdst ? Qtrue : Qfalse;
}
static VALUE
time_zone_name(const char *zone)
{
VALUE name = rb_str_new_cstr(zone);
if (!rb_enc_str_asciionly_p(name)) {
name = rb_external_str_with_enc(name, rb_locale_encoding());
}
else {
rb_enc_associate(name, rb_usascii_encoding());
}
return name;
}
/*
* call-seq:
* time.zone -> string
*
* Returns the name of the time zone used for _time_. As of Ruby
* 1.8, returns ``UTC'' rather than ``GMT'' for UTC times.
*
* t = Time.gm(2000, "jan", 1, 20, 15, 1)
* t.zone #=> "UTC"
* t = Time.local(2000, "jan", 1, 20, 15, 1)
* t.zone #=> "CST"
*/
static VALUE
time_zone(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
if (TIME_UTC_P(tobj)) {
return rb_usascii_str_new_cstr("UTC");
}
if (tobj->vtm.zone == NULL)
return Qnil;
return time_zone_name(tobj->vtm.zone);
}
/*
* call-seq:
* time.gmt_offset -> fixnum
* time.gmtoff -> fixnum
* time.utc_offset -> fixnum
*
* Returns the offset in seconds between the timezone of _time_
* and UTC.
*
* t = Time.gm(2000,1,1,20,15,1) #=> 2000-01-01 20:15:01 UTC
* t.gmt_offset #=> 0
* l = t.getlocal #=> 2000-01-01 14:15:01 -0600
* l.gmt_offset #=> -21600
*/
static VALUE
time_utc_offset(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
if (TIME_UTC_P(tobj)) {
return INT2FIX(0);
}
else {
return tobj->vtm.utc_offset;
}
}
/*
* call-seq:
* time.to_a -> array
*
* Returns a ten-element _array_ of values for _time_:
*
* [sec, min, hour, day, month, year, wday, yday, isdst, zone]
*
* See the individual methods for an explanation of the
* valid ranges of each value. The ten elements can be passed directly
* to Time::utc or Time::local to create a
* new Time object.
*
* t = Time.now #=> 2007-11-19 08:36:01 -0600
* now = t.to_a #=> [1, 36, 8, 19, 11, 2007, 1, 323, false, "CST"]
*/
static VALUE
time_to_a(VALUE time)
{
struct time_object *tobj;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
return rb_ary_new3(10,
INT2FIX(tobj->vtm.sec),
INT2FIX(tobj->vtm.min),
INT2FIX(tobj->vtm.hour),
INT2FIX(tobj->vtm.mday),
INT2FIX(tobj->vtm.mon),
tobj->vtm.year,
INT2FIX(tobj->vtm.wday),
INT2FIX(tobj->vtm.yday),
tobj->vtm.isdst?Qtrue:Qfalse,
time_zone(time));
}
#define SMALLBUF 100
static size_t
rb_strftime_alloc(char **buf, VALUE formatv, const char *format, rb_encoding *enc,
struct vtm *vtm, wideval_t timew, int gmt)
{
size_t size, len, flen;
VALUE timev = Qnil;
struct timespec ts;
if (!timew2timespec_exact(timew, &ts))
timev = w2v(rb_time_unmagnify(timew));
(*buf)[0] = '\0';
flen = strlen(format);
if (flen == 0) {
return 0;
}
errno = 0;
if (timev == Qnil)
len = rb_strftime_timespec(*buf, SMALLBUF, format, enc, vtm, &ts, gmt);
else
len = rb_strftime(*buf, SMALLBUF, format, enc, vtm, timev, gmt);
if (len != 0 || (**buf == '\0' && errno != ERANGE)) return len;
for (size=1024; ; size*=2) {
*buf = xmalloc(size);
(*buf)[0] = '\0';
if (timev == Qnil)
len = rb_strftime_timespec(*buf, size, format, enc, vtm, &ts, gmt);
else
len = rb_strftime(*buf, size, format, enc, vtm, timev, gmt);
/*
* buflen can be zero EITHER because there's not enough
* room in the string, or because the control command
* goes to the empty string. Make a reasonable guess that
* if the buffer is 1024 times bigger than the length of the
* format string, it's not failing for lack of room.
*/
if (len > 0) break;
xfree(*buf);
if (size >= 1024 * flen) {
if (!NIL_P(formatv)) rb_sys_fail_str(formatv);
rb_sys_fail(format);
break;
}
}
return len;
}
static VALUE
strftimev(const char *fmt, VALUE time, rb_encoding *enc)
{
struct time_object *tobj;
char buffer[SMALLBUF], *buf = buffer;
long len;
VALUE str;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
len = rb_strftime_alloc(&buf, Qnil, fmt, enc, &tobj->vtm, tobj->timew, TIME_UTC_P(tobj));
str = rb_enc_str_new(buf, len, enc);
if (buf != buffer) xfree(buf);
return str;
}
/*
* call-seq:
* time.strftime( string ) -> string
*
* Formats _time_ according to the directives in the given format string.
*
* The directives begin with a percent (%) character.
* Any text not listed as a directive will be passed through to the
* output string.
*
* The directive consists of a percent (%) character,
* zero or more flags, optional minimum field width,
* optional modifier and a conversion specifier
* as follows:
*
* %<flags><width><modifier><conversion>
*
* Flags:
* - don't pad a numerical output
* _ use spaces for padding
* 0 use zeros for padding
* ^ upcase the result string
* # change case
* : use colons for %z
*
* The minimum field width specifies the minimum width.
*
* The modifiers are "E" and "O".
* They are ignored.
*
* Format directives:
*
* Date (Year, Month, Day):
* %Y - Year with century if provided, will pad result at least 4 digits.
* -0001, 0000, 1995, 2009, 14292, etc.
* %C - year / 100 (rounded down such as 20 in 2009)
* %y - year % 100 (00..99)
*
* %m - Month of the year, zero-padded (01..12)
* %_m blank-padded ( 1..12)
* %-m no-padded (1..12)
* %B - The full month name (``January'')
* %^B uppercased (``JANUARY'')
* %b - The abbreviated month name (``Jan'')
* %^b uppercased (``JAN'')
* %h - Equivalent to %b
*
* %d - Day of the month, zero-padded (01..31)
* %-d no-padded (1..31)
* %e - Day of the month, blank-padded ( 1..31)
*
* %j - Day of the year (001..366)
*
* Time (Hour, Minute, Second, Subsecond):
* %H - Hour of the day, 24-hour clock, zero-padded (00..23)
* %k - Hour of the day, 24-hour clock, blank-padded ( 0..23)
* %I - Hour of the day, 12-hour clock, zero-padded (01..12)
* %l - Hour of the day, 12-hour clock, blank-padded ( 1..12)
* %P - Meridian indicator, lowercase (``am'' or ``pm'')
* %p - Meridian indicator, uppercase (``AM'' or ``PM'')
*
* %M - Minute of the hour (00..59)
*
* %S - Second of the minute (00..60)
*
* %L - Millisecond of the second (000..999)
* The digits under millisecond are truncated to not produce 1000.
* %N - Fractional seconds digits, default is 9 digits (nanosecond)
* %3N millisecond (3 digits)
* %6N microsecond (6 digits)
* %9N nanosecond (9 digits)
* %12N picosecond (12 digits)
* %15N femtosecond (15 digits)
* %18N attosecond (18 digits)
* %21N zeptosecond (21 digits)
* %24N yoctosecond (24 digits)
* The digits under the specified length are truncated to avoid
* carry up.
*
* Time zone:
* %z - Time zone as hour and minute offset from UTC (e.g. +0900)
* %:z - hour and minute offset from UTC with a colon (e.g. +09:00)
* %::z - hour, minute and second offset from UTC (e.g. +09:00:00)
* %Z - Abbreviated time zone name or similar information. (OS dependent)
*
* Weekday:
* %A - The full weekday name (``Sunday'')
* %^A uppercased (``SUNDAY'')
* %a - The abbreviated name (``Sun'')
* %^a uppercased (``SUN'')
* %u - Day of the week (Monday is 1, 1..7)
* %w - Day of the week (Sunday is 0, 0..6)
*
* ISO 8601 week-based year and week number:
* The first week of YYYY starts with a Monday and includes YYYY-01-04.
* The days in the year before the first week are in the last week of
* the previous year.
* %G - The week-based year
* %g - The last 2 digits of the week-based year (00..99)
* %V - Week number of the week-based year (01..53)
*
* Week number:
* The first week of YYYY that starts with a Sunday or Monday (according to %U
* or %W). The days in the year before the first week are in week 0.
* %U - Week number of the year. The week starts with Sunday. (00..53)
* %W - Week number of the year. The week starts with Monday. (00..53)
*
* Seconds since the Epoch:
* %s - Number of seconds since 1970-01-01 00:00:00 UTC.
*
* Literal string:
* %n - Newline character (\n)
* %t - Tab character (\t)
* %% - Literal ``%'' character
*
* Combination:
* %c - date and time (%a %b %e %T %Y)
* %D - Date (%m/%d/%y)
* %F - The ISO 8601 date format (%Y-%m-%d)
* %v - VMS date (%e-%^b-%4Y)
* %x - Same as %D
* %X - Same as %T
* %r - 12-hour time (%I:%M:%S %p)
* %R - 24-hour time (%H:%M)
* %T - 24-hour time (%H:%M:%S)
*
* This method is similar to strftime() function defined in ISO C and POSIX.
*
* While all directives are locale independent since Ruby 1.9, %Z is platform
* dependent.
* So, the result may differ even if the same format string is used in other
* systems such as C.
*
* %z is recommended over %Z.
* %Z doesn't identify the timezone.
* For example, "CST" is used at America/Chicago (-06:00),
* America/Havana (-05:00), Asia/Harbin (+08:00), Australia/Darwin (+09:30)
* and Australia/Adelaide (+10:30).
* Also, %Z is highly dependent on the operating system.
* For example, it may generate a non ASCII string on Japanese Windows.
* i.e. the result can be different to "JST".
* So the numeric time zone offset, %z, is recommended.
*
* Examples:
*
* t = Time.new(2007,11,19,8,37,48,"-06:00") #=> 2007-11-19 08:37:48 -0600
* t.strftime("Printed on %m/%d/%Y") #=> "Printed on 11/19/2007"
* t.strftime("at %I:%M%p") #=> "at 08:37AM"
*
* Various ISO 8601 formats:
* %Y%m%d => 20071119 Calendar date (basic)
* %F => 2007-11-19 Calendar date (extended)
* %Y-%m => 2007-11 Calendar date, reduced accuracy, specific month
* %Y => 2007 Calendar date, reduced accuracy, specific year
* %C => 20 Calendar date, reduced accuracy, specific century
* %Y%j => 2007323 Ordinal date (basic)
* %Y-%j => 2007-323 Ordinal date (extended)
* %GW%V%u => 2007W471 Week date (basic)
* %G-W%V-%u => 2007-W47-1 Week date (extended)
* %GW%V => 2007W47 Week date, reduced accuracy, specific week (basic)
* %G-W%V => 2007-W47 Week date, reduced accuracy, specific week (extended)
* %H%M%S => 083748 Local time (basic)
* %T => 08:37:48 Local time (extended)
* %H%M => 0837 Local time, reduced accuracy, specific minute (basic)
* %H:%M => 08:37 Local time, reduced accuracy, specific minute (extended)
* %H => 08 Local time, reduced accuracy, specific hour
* %H%M%S,%L => 083748,000 Local time with decimal fraction, comma as decimal sign (basic)
* %T,%L => 08:37:48,000 Local time with decimal fraction, comma as decimal sign (extended)
* %H%M%S.%L => 083748.000 Local time with decimal fraction, full stop as decimal sign (basic)
* %T.%L => 08:37:48.000 Local time with decimal fraction, full stop as decimal sign (extended)
* %H%M%S%z => 083748-0600 Local time and the difference from UTC (basic)
* %T%:z => 08:37:48-06:00 Local time and the difference from UTC (extended)
* %Y%m%dT%H%M%S%z => 20071119T083748-0600 Date and time of day for calendar date (basic)
* %FT%T%:z => 2007-11-19T08:37:48-06:00 Date and time of day for calendar date (extended)
* %Y%jT%H%M%S%z => 2007323T083748-0600 Date and time of day for ordinal date (basic)
* %Y-%jT%T%:z => 2007-323T08:37:48-06:00 Date and time of day for ordinal date (extended)
* %GW%V%uT%H%M%S%z => 2007W471T083748-0600 Date and time of day for week date (basic)
* %G-W%V-%uT%T%:z => 2007-W47-1T08:37:48-06:00 Date and time of day for week date (extended)
* %Y%m%dT%H%M => 20071119T0837 Calendar date and local time (basic)
* %FT%R => 2007-11-19T08:37 Calendar date and local time (extended)
* %Y%jT%H%MZ => 2007323T0837Z Ordinal date and UTC of day (basic)
* %Y-%jT%RZ => 2007-323T08:37Z Ordinal date and UTC of day (extended)
* %GW%V%uT%H%M%z => 2007W471T0837-0600 Week date and local time and difference from UTC (basic)
* %G-W%V-%uT%R%:z => 2007-W47-1T08:37-06:00 Week date and local time and difference from UTC (extended)
*
*/
static VALUE
time_strftime(VALUE time, VALUE format)
{
struct time_object *tobj;
char buffer[SMALLBUF], *buf = buffer;
const char *fmt;
long len;
rb_encoding *enc;
VALUE str;
GetTimeval(time, tobj);
MAKE_TM(time, tobj);
* eval.c (block_pass): should not downgrade safe level. * ext/dbm/extconf.rb: allow specifying dbm-type explicitly. * ext/dbm/extconf.rb: avoid gdbm if possible, because it leaks memory, whereas gdbm.so doesn't. potential incompatibility. * string.c (rb_str_insert): new method. * parse.y (yylex): lex_state after RESCUE_MOD should be EXPR_BEG. * array.c (rb_ary_insert): new method. * array.c (rb_ary_update): new utility function. * io.c (set_outfile): should check if closed before assignment. * eval.c (rb_eval): should preserve value of ruby_errinfo. * eval.c (rb_thread_schedule): infinite sleep should not cause dead lock. * array.c (rb_ary_flatten_bang): proper recursive detection. * eval.c (yield_under): need not to prohibit at safe level 4. * pack.c (pack_pack): p/P packs nil into NULL. * pack.c (pack_unpack): p/P unpacks NULL into nil. * pack.c (pack_pack): size check for P template. * ruby.c (set_arg0): wrong predicate when new $0 value is bigger than original space. * gc.c (id2ref): should use NUM2ULONG() * object.c (rb_mod_const_get): check whether name is a class variable name. * object.c (rb_mod_const_set): ditto. * object.c (rb_mod_const_defined): ditto. * marshal.c (w_float): precision changed to "%.16g" * eval.c (rb_call0): wrong retry behavior. * numeric.c (fix_aref): a bug on long>int architecture. * eval.c (rb_eval_string_wrap): should restore ruby_wrapper. * regex.c (re_compile_pattern): char class at either edge of range should be invalid. * eval.c (handle_rescue): use === to compare exception match. * error.c (syserr_eqq): comparison between SytemCallErrors should based on their error numbers. * eval.c (safe_getter): should use INT2NUM(). * bignum.c (rb_big2long): 2**31 cannot fit in 31 bit long. * regex.c (calculate_must_string): wrong length calculation. * eval.c (rb_thread_start_0): fixed memory leak. * parse.y (none): should clear cmdarg_stack too. * io.c (rb_fopen): use setvbuf() to avoid recursive malloc() on some platforms. * file.c (rb_stat_dev): device functions should honor stat field types (except long long such as dev_t). * eval.c (rb_mod_nesting): should not push nil for nesting array. * eval.c (rb_mod_s_constants): should not search array by rb_mod_const_at() for nil (happens for singleton class). * class.c (rb_singleton_class_attached): should modify iv_tbl by itself, no longer use rb_iv_set() to avoid freeze check error. * variable.c (rb_const_get): error message "uninitialized constant Foo at Bar::Baz" instead of "uninitialized constantBar::Baz::Foo". * eval.c (rb_mod_included): new hook called from rb_mod_include(). * io.c (opt_i_set): should strdup() inplace_edit string. * eval.c (exec_under): need to push cref too. * eval.c (rb_f_missing): raise NameError for "undefined local variable or method". * error.c (Init_Exception): new exception NoMethodError. NameError moved under ScriptError again. * eval.c (rb_f_missing): use NoMethodError instead of NameError. * file.c (Init_File): should redifine "new" class method. * eval.c (PUSH_CREF): sharing cref node was problematic. maintain runtime cref list instead. * eval.c (rb_eval): copy defn node before registering. * eval.c (rb_load): clear ruby_cref before loading. * variable.c (rb_const_get): no recursion to show full class path for modules. * eval.c (rb_set_safe_level): should set safe level in curr_thread as well. * eval.c (safe_setter): ditto. * object.c (rb_obj_is_instance_of): nil belongs to false, not true. * time.c (make_time_t): proper (I hope) daylight saving time handling for both US and Europe. I HATE DST! * eval.c (rb_thread_wait_for): non blocked signal interrupt should stop the interval. * eval.c (proc_eq): class check aded. * eval.c (proc_eq): typo fixed ("return" was ommitted). * error.c (Init_Exception): move NameError under StandardError. * class.c (rb_mod_clone): should copy method bodies too. * bignum.c (bigdivrem): should trim trailing zero bdigits of remainder, even if dd == 0. * file.c (check3rdbyte): safe string check moved here. * time.c (make_time_t): remove HAVE_TM_ZONE code since it sometimes reports wrong time. * time.c (make_time_t): remove unnecessary range check for platforms where negative time_t is available. * process.c (proc_waitall): should push Process::Status instead of Finuxm status. * process.c (waitall_each): should add all entries in pid_tbl. these changes are inspired by Koji Arai. Thanks. * process.c (proc_wait): should not iterate if pid_tbl is 0. * process.c (proc_waitall): ditto. * numeric.c (flodivmod): a bug in no fmod case. * process.c (pst_wifsignaled): should apply WIFSIGNALED for status (int), not st (VALUE). * io.c (Init_IO): value of $/ and $\ are no longer restricted to strings. type checks are done on demand. * class.c (rb_include_module): module inclusion should be check taints. * ruby.h (STR2CSTR): replace to StringType() and StringTypePtr(). * ruby.h (rb_str2cstr): ditto. * eval.c (rb_load): should not copy topleve local variables. It cause variable/method ambiguity. Thanks to L. Peter Deutsch. * class.c (rb_include_module): freeze check at first. * eval.c (rb_attr): sprintf() and rb_intern() moved into conditional body. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1356 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-05-02 00:22:21 -04:00
StringValue(format);
if (!rb_enc_str_asciicompat_p(format)) {
rb_raise(rb_eArgError, "format should have ASCII compatible encoding");
}
* array.c: replace rb_protect_inspect() and rb_inspecting_p() by rb_exec_recursive() in eval.c. * eval.c (rb_exec_recursive): new function. * array.c (rb_ary_join): use rb_exec_recursive(). * array.c (rb_ary_inspect, rb_ary_hash): ditto. * file.c (rb_file_join): ditto. * hash.c (rb_hash_inspect, rb_hash_to_s, rb_hash_hash): ditto. * io.c (rb_io_puts): ditto. * object.c (rb_obj_inspect): ditto * struct.c (rb_struct_inspect): ditto. * lib/set.rb (SortedSet::setup): a hack to shut up warning. [ruby-talk:132866] * lib/time.rb (Time::strptime): add new function. inspired by [ruby-talk:132815]. * lib/parsedate.rb (ParseDate::strptime): ditto. * regparse.c: move st_*_strend() functions from st.c. fixed some potential memory leaks. * exception error messages updated. [ruby-core:04497] * ext/socket/socket.c (Init_socket): add bunch of Socket constants. Patch from Sam Roberts <sroberts@uniserve.com>. [ruby-core:04409] * array.c (rb_ary_s_create): no need for negative argc check. [ruby-core:04463] * array.c (rb_ary_unshift_m): ditto. * lib/xmlrpc/parser.rb (XMLRPC::FaultException): make it subclass of StandardError class, not Exception class. [ruby-core:04429] * parse.y (fcall_gen): lvar(arg) will be evaluated as lvar.call(arg) when lvar is a defined local variable. [new] * object.c (rb_class_initialize): call inherited method before calling initializing block. * eval.c (rb_thread_start_1): initialize newly pushed frame. * lib/open3.rb (Open3::popen3): $? should not be EXIT_FAILURE. fixed: [ruby-core:04444] * eval.c (is_defined): NODE_IASGN is an assignment. * ext/readline/readline.c (Readline.readline): use rl_outstream and rl_instream. [ruby-dev:25699] * ext/etc/etc.c (Init_etc): sGroup needs HAVE_ST_GR_PASSWD check [ruby-dev:25675] * misc/ruby-mode.el: [ruby-core:04415] * lib/rdoc/generators/html_generator.rb: [ruby-core:04412] * lib/rdoc/generators/ri_generator.rb: ditto. * struct.c (make_struct): fixed: [ruby-core:04402] * ext/curses/curses.c (window_color_set): [ruby-core:04393] * ext/socket/socket.c (Init_socket): SO_REUSEPORT added. [ruby-talk:130092] * object.c: [ruby-doc:818] * parse.y (open_args): fix too verbose warnings for the space before argument parentheses. [ruby-dev:25492] * parse.y (parser_yylex): ditto. * parse.y (parser_yylex): the first expression in the parentheses should not be a command. [ruby-dev:25492] * lib/irb/context.rb (IRB::Context::initialize): [ruby-core:04330] * object.c (Init_Object): remove Object#type. [ruby-core:04335] * st.c (st_foreach): report success/failure by return value. [ruby-Bugs-1396] * parse.y: forgot to initialize parser struct. [ruby-dev:25492] * parse.y (parser_yylex): no tLABEL on EXPR_BEG. [ruby-talk:127711] * document updates - [ruby-core:04296], [ruby-core:04301], [ruby-core:04302], [ruby-core:04307] * dir.c (rb_push_glob): should work for NUL delimited patterns. * dir.c (rb_glob2): should aware of offset in the pattern. * string.c (rb_str_new4): should propagate taintedness. * env.h: rename member names in struct FRAME; last_func -> callee, orig_func -> this_func, last_class -> this_class. * struct.c (rb_struct_set): use original method name, not callee name, to retrieve member slot. [ruby-core:04268] * time.c (time_strftime): protect from format modification from GC finalizers. * object.c (Init_Object): remove rb_obj_id_obsolete() * eval.c (rb_mod_define_method): incomplete subclass check. [ruby-dev:25464] * gc.c (rb_data_object_alloc): klass may be NULL. [ruby-list:40498] * bignum.c (rb_big_rand): should return positive random number. [ruby-dev:25401] * bignum.c (rb_big_rand): do not use rb_big_modulo to generate random bignums. [ruby-dev:25396] * variable.c (rb_autoload): [ruby-dev:25373] * eval.c (svalue_to_avalue): [ruby-dev:25366] * string.c (rb_str_justify): [ruby-dev:25367] * io.c (rb_f_select): [ruby-dev:25312] * ext/socket/socket.c (sock_s_getservbyport): [ruby-talk:124072] * struct.c (make_struct): [ruby-dev:25249] * dir.c (dir_open_dir): new function. [ruby-dev:25242] * io.c (rb_f_open): add type check for return value from to_open. * lib/pstore.rb (PStore#transaction): Use the empty content when a file is not found. [ruby-dev:24561] git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@8068 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2005-03-04 01:47:45 -05:00
format = rb_str_new4(format);
fmt = RSTRING_PTR(format);
len = RSTRING_LEN(format);
enc = rb_enc_get(format);
if (len == 0) {
rb_warning("strftime called with empty format string");
}
else if (fmt[len] || memchr(fmt, '\0', len)) {
/* Ruby string may contain \0's. */
const char *p = fmt, *pe = fmt + len;
str = rb_str_new(0, 0);
while (p < pe) {
len = rb_strftime_alloc(&buf, format, p, enc,
&tobj->vtm, tobj->timew, TIME_UTC_P(tobj));
rb_str_cat(str, buf, len);
p += strlen(p);
* array.c (rb_ary_modify): should copy the internal buffer if the modifying buffer is shared. * array.c (ary_make_shared): make an internal buffer of an array to be shared. * array.c (rb_ary_shift): avoid sliding an internal buffer by using shared buffer. * array.c (rb_ary_subseq): avoid copying the buffer. * parse.y (gettable): should freeze __LINE__ string. * io.c (rb_io_puts): old behavoir restored. rationale: a) if you want to call to_s for arrays, you can just call print a, "\n". b) to_s wastes memory if array (and sum of its contents) is huge. c) now any object that has to_ary is treated as an array, using rb_check_convert_type(). * hash.c (rb_hash_initialize): now accepts a block to calculate the default value. [new] * hash.c (rb_hash_aref): call "default" method to get the value corrensponding to the non existing key. * hash.c (rb_hash_default): get the default value based on the block given to 'new'. Now it takes an optinal "key" argument. "default" became the method to get the value for non existing key. Users may override "default" method to change the hash behavior. * hash.c (rb_hash_set_default): clear the flag if a block is given to 'new' * object.c (Init_Object): undef Data.allocate, left Data.new. * ext/curses/curses.c (window_scrollok): use RTEST(). * ext/curses/curses.c (window_idlok): ditto. * ext/curses/curses.c (window_keypad): ditto. * ext/curses/curses.c (window_idlok): idlok() may return void on some platforms; so don't use return value. * ext/curses/curses.c (window_scrollok): ditto for consistency. * ext/curses/curses.c: replace FIX2INT() by typechecking NUM2INT(). * parse.y (str_extend): should not process immature #$x and #@x interpolation, e.g #@#@ etc. * enum.c (enum_sort_by): sort_by does not have to be stable always. * enum.c (enum_sort_by): call qsort directly to gain performance. * util.c (ruby_qsort): ruby_qsort(qs6) is now native thread safe. * error.c (rb_sys_fail): it must be a bug if it's called when errno == 0. * regex.c (WC2MBC1ST): should not pass through > 0x80 number in UTF-8. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1896 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-12-10 02:18:16 -05:00
if (buf != buffer) {
xfree(buf);
* array.c (rb_ary_modify): should copy the internal buffer if the modifying buffer is shared. * array.c (ary_make_shared): make an internal buffer of an array to be shared. * array.c (rb_ary_shift): avoid sliding an internal buffer by using shared buffer. * array.c (rb_ary_subseq): avoid copying the buffer. * parse.y (gettable): should freeze __LINE__ string. * io.c (rb_io_puts): old behavoir restored. rationale: a) if you want to call to_s for arrays, you can just call print a, "\n". b) to_s wastes memory if array (and sum of its contents) is huge. c) now any object that has to_ary is treated as an array, using rb_check_convert_type(). * hash.c (rb_hash_initialize): now accepts a block to calculate the default value. [new] * hash.c (rb_hash_aref): call "default" method to get the value corrensponding to the non existing key. * hash.c (rb_hash_default): get the default value based on the block given to 'new'. Now it takes an optinal "key" argument. "default" became the method to get the value for non existing key. Users may override "default" method to change the hash behavior. * hash.c (rb_hash_set_default): clear the flag if a block is given to 'new' * object.c (Init_Object): undef Data.allocate, left Data.new. * ext/curses/curses.c (window_scrollok): use RTEST(). * ext/curses/curses.c (window_idlok): ditto. * ext/curses/curses.c (window_keypad): ditto. * ext/curses/curses.c (window_idlok): idlok() may return void on some platforms; so don't use return value. * ext/curses/curses.c (window_scrollok): ditto for consistency. * ext/curses/curses.c: replace FIX2INT() by typechecking NUM2INT(). * parse.y (str_extend): should not process immature #$x and #@x interpolation, e.g #@#@ etc. * enum.c (enum_sort_by): sort_by does not have to be stable always. * enum.c (enum_sort_by): call qsort directly to gain performance. * util.c (ruby_qsort): ruby_qsort(qs6) is now native thread safe. * error.c (rb_sys_fail): it must be a bug if it's called when errno == 0. * regex.c (WC2MBC1ST): should not pass through > 0x80 number in UTF-8. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1896 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-12-10 02:18:16 -05:00
buf = buffer;
}
for (fmt = p; p < pe && !*p; ++p);
if (p > fmt) rb_str_cat(str, fmt, p - fmt);
}
return str;
}
else {
len = rb_strftime_alloc(&buf, format, RSTRING_PTR(format), enc,
&tobj->vtm, tobj->timew, TIME_UTC_P(tobj));
}
str = rb_enc_str_new(buf, len, enc);
if (buf != buffer) xfree(buf);
return str;
}
/* :nodoc: */
static VALUE
time_mdump(VALUE time)
{
struct time_object *tobj;
unsigned long p, s;
char buf[8];
int i;
VALUE str;
struct vtm vtm;
long year;
long usec, nsec;
VALUE subsecx, nano, subnano, v;
GetTimeval(time, tobj);
gmtimew(tobj->timew, &vtm);
if (FIXNUM_P(vtm.year)) {
year = FIX2LONG(vtm.year);
if (year < 1900 || 1900+0xffff < year)
rb_raise(rb_eArgError, "year too big to marshal: %ld UTC", year);
}
else {
rb_raise(rb_eArgError, "year too big to marshal");
}
subsecx = vtm.subsecx;
nano = mulquo(subsecx, INT2FIX(1000000000), INT2FIX(TIME_SCALE));
divmodv(nano, INT2FIX(1), &v, &subnano);
nsec = FIX2LONG(v);
usec = nsec / 1000;
nsec = nsec % 1000;
nano = add(LONG2FIX(nsec), subnano);
p = 0x1UL << 31 | /* 1 */
TIME_UTC_P(tobj) << 30 | /* 1 */
(year-1900) << 14 | /* 16 */
(vtm.mon-1) << 10 | /* 4 */
vtm.mday << 5 | /* 5 */
vtm.hour; /* 5 */
s = (unsigned long)vtm.min << 26 | /* 6 */
vtm.sec << 20 | /* 6 */
usec; /* 20 */
for (i=0; i<4; i++) {
buf[i] = (unsigned char)p;
p = RSHIFT(p, 8);
}
for (i=4; i<8; i++) {
buf[i] = (unsigned char)s;
s = RSHIFT(s, 8);
}
str = rb_str_new(buf, 8);
rb_copy_generic_ivar(str, time);
if (!rb_equal(nano, INT2FIX(0))) {
if (RB_TYPE_P(nano, T_RATIONAL)) {
rb_ivar_set(str, id_nano_num, RRATIONAL(nano)->num);
rb_ivar_set(str, id_nano_den, RRATIONAL(nano)->den);
}
else {
rb_ivar_set(str, id_nano_num, nano);
rb_ivar_set(str, id_nano_den, INT2FIX(1));
}
}
if (nsec) { /* submicro is only for Ruby 1.9.1 compatibility */
/*
* submicro is formatted in fixed-point packed BCD (without sign).
* It represent digits under microsecond.
* For nanosecond resolution, 3 digits (2 bytes) are used.
* However it can be longer.
* Extra digits are ignored for loading.
*/
char buf[2];
int len = (int)sizeof(buf);
buf[1] = (char)((nsec % 10) << 4);
nsec /= 10;
buf[0] = (char)(nsec % 10);
nsec /= 10;
buf[0] |= (char)((nsec % 10) << 4);
if (buf[1] == 0)
len = 1;
rb_ivar_set(str, id_submicro, rb_str_new(buf, len));
}
if (!TIME_UTC_P(tobj)) {
VALUE off = time_utc_offset(time), div, mod;
divmodv(off, INT2FIX(1), &div, &mod);
if (rb_equal(mod, INT2FIX(0)))
off = rb_Integer(div);
rb_ivar_set(str, id_offset, off);
}
if (tobj->vtm.zone) {
rb_ivar_set(str, id_zone, time_zone_name(tobj->vtm.zone));
}
return str;
}
/* :nodoc: */
static VALUE
time_dump(int argc, VALUE *argv, VALUE time)
{
VALUE str;
rb_scan_args(argc, argv, "01", 0);
str = time_mdump(time);
return str;
}
/* :nodoc: */
static VALUE
time_mload(VALUE time, VALUE str)
{
struct time_object *tobj;
unsigned long p, s;
time_t sec;
long usec;
unsigned char *buf;
struct vtm vtm;
int i, gmt;
long nsec;
VALUE submicro, nano_num, nano_den, offset, zone;
wideval_t timew;
time_modify(time);
#define get_attr(attr, iffound) \
attr = rb_attr_delete(str, id_##attr); \
if (!NIL_P(attr)) { \
iffound; \
}
get_attr(nano_num, {});
get_attr(nano_den, {});
get_attr(submicro, {});
get_attr(offset, (offset = rb_rescue(validate_utc_offset, offset, NULL, Qnil)));
get_attr(zone, (zone = rb_rescue(validate_zone_name, zone, NULL, Qnil)));
#undef get_attr
rb_copy_generic_ivar(time, str);
* eval.c (block_pass): should not downgrade safe level. * ext/dbm/extconf.rb: allow specifying dbm-type explicitly. * ext/dbm/extconf.rb: avoid gdbm if possible, because it leaks memory, whereas gdbm.so doesn't. potential incompatibility. * string.c (rb_str_insert): new method. * parse.y (yylex): lex_state after RESCUE_MOD should be EXPR_BEG. * array.c (rb_ary_insert): new method. * array.c (rb_ary_update): new utility function. * io.c (set_outfile): should check if closed before assignment. * eval.c (rb_eval): should preserve value of ruby_errinfo. * eval.c (rb_thread_schedule): infinite sleep should not cause dead lock. * array.c (rb_ary_flatten_bang): proper recursive detection. * eval.c (yield_under): need not to prohibit at safe level 4. * pack.c (pack_pack): p/P packs nil into NULL. * pack.c (pack_unpack): p/P unpacks NULL into nil. * pack.c (pack_pack): size check for P template. * ruby.c (set_arg0): wrong predicate when new $0 value is bigger than original space. * gc.c (id2ref): should use NUM2ULONG() * object.c (rb_mod_const_get): check whether name is a class variable name. * object.c (rb_mod_const_set): ditto. * object.c (rb_mod_const_defined): ditto. * marshal.c (w_float): precision changed to "%.16g" * eval.c (rb_call0): wrong retry behavior. * numeric.c (fix_aref): a bug on long>int architecture. * eval.c (rb_eval_string_wrap): should restore ruby_wrapper. * regex.c (re_compile_pattern): char class at either edge of range should be invalid. * eval.c (handle_rescue): use === to compare exception match. * error.c (syserr_eqq): comparison between SytemCallErrors should based on their error numbers. * eval.c (safe_getter): should use INT2NUM(). * bignum.c (rb_big2long): 2**31 cannot fit in 31 bit long. * regex.c (calculate_must_string): wrong length calculation. * eval.c (rb_thread_start_0): fixed memory leak. * parse.y (none): should clear cmdarg_stack too. * io.c (rb_fopen): use setvbuf() to avoid recursive malloc() on some platforms. * file.c (rb_stat_dev): device functions should honor stat field types (except long long such as dev_t). * eval.c (rb_mod_nesting): should not push nil for nesting array. * eval.c (rb_mod_s_constants): should not search array by rb_mod_const_at() for nil (happens for singleton class). * class.c (rb_singleton_class_attached): should modify iv_tbl by itself, no longer use rb_iv_set() to avoid freeze check error. * variable.c (rb_const_get): error message "uninitialized constant Foo at Bar::Baz" instead of "uninitialized constantBar::Baz::Foo". * eval.c (rb_mod_included): new hook called from rb_mod_include(). * io.c (opt_i_set): should strdup() inplace_edit string. * eval.c (exec_under): need to push cref too. * eval.c (rb_f_missing): raise NameError for "undefined local variable or method". * error.c (Init_Exception): new exception NoMethodError. NameError moved under ScriptError again. * eval.c (rb_f_missing): use NoMethodError instead of NameError. * file.c (Init_File): should redifine "new" class method. * eval.c (PUSH_CREF): sharing cref node was problematic. maintain runtime cref list instead. * eval.c (rb_eval): copy defn node before registering. * eval.c (rb_load): clear ruby_cref before loading. * variable.c (rb_const_get): no recursion to show full class path for modules. * eval.c (rb_set_safe_level): should set safe level in curr_thread as well. * eval.c (safe_setter): ditto. * object.c (rb_obj_is_instance_of): nil belongs to false, not true. * time.c (make_time_t): proper (I hope) daylight saving time handling for both US and Europe. I HATE DST! * eval.c (rb_thread_wait_for): non blocked signal interrupt should stop the interval. * eval.c (proc_eq): class check aded. * eval.c (proc_eq): typo fixed ("return" was ommitted). * error.c (Init_Exception): move NameError under StandardError. * class.c (rb_mod_clone): should copy method bodies too. * bignum.c (bigdivrem): should trim trailing zero bdigits of remainder, even if dd == 0. * file.c (check3rdbyte): safe string check moved here. * time.c (make_time_t): remove HAVE_TM_ZONE code since it sometimes reports wrong time. * time.c (make_time_t): remove unnecessary range check for platforms where negative time_t is available. * process.c (proc_waitall): should push Process::Status instead of Finuxm status. * process.c (waitall_each): should add all entries in pid_tbl. these changes are inspired by Koji Arai. Thanks. * process.c (proc_wait): should not iterate if pid_tbl is 0. * process.c (proc_waitall): ditto. * numeric.c (flodivmod): a bug in no fmod case. * process.c (pst_wifsignaled): should apply WIFSIGNALED for status (int), not st (VALUE). * io.c (Init_IO): value of $/ and $\ are no longer restricted to strings. type checks are done on demand. * class.c (rb_include_module): module inclusion should be check taints. * ruby.h (STR2CSTR): replace to StringType() and StringTypePtr(). * ruby.h (rb_str2cstr): ditto. * eval.c (rb_load): should not copy topleve local variables. It cause variable/method ambiguity. Thanks to L. Peter Deutsch. * class.c (rb_include_module): freeze check at first. * eval.c (rb_attr): sprintf() and rb_intern() moved into conditional body. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1356 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-05-02 00:22:21 -04:00
StringValue(str);
buf = (unsigned char *)RSTRING_PTR(str);
if (RSTRING_LEN(str) != 8) {
rb_raise(rb_eTypeError, "marshaled time format differ");
}
p = s = 0;
for (i=0; i<4; i++) {
p |= (unsigned long)buf[i]<<(8*i);
}
for (i=4; i<8; i++) {
s |= (unsigned long)buf[i]<<(8*(i-4));
}
if ((p & (1UL<<31)) == 0) {
gmt = 0;
offset = Qnil;
sec = p;
usec = s;
nsec = usec * 1000;
timew = wadd(rb_time_magnify(TIMET2WV(sec)), wmulquoll(WINT2FIXWV(usec), TIME_SCALE, 1000000));
}
else {
p &= ~(1UL<<31);
gmt = (int)((p >> 30) & 0x1);
vtm.year = INT2FIX(((int)(p >> 14) & 0xffff) + 1900);
vtm.mon = ((int)(p >> 10) & 0xf) + 1;
vtm.mday = (int)(p >> 5) & 0x1f;
vtm.hour = (int) p & 0x1f;
vtm.min = (int)(s >> 26) & 0x3f;
vtm.sec = (int)(s >> 20) & 0x3f;
vtm.utc_offset = INT2FIX(0);
vtm.yday = vtm.wday = 0;
vtm.isdst = 0;
vtm.zone = "";
usec = (long)(s & 0xfffff);
nsec = usec * 1000;
vtm.subsecx = mulquo(LONG2FIX(nsec), INT2FIX(TIME_SCALE), LONG2FIX(1000000000));
if (nano_num != Qnil) {
VALUE nano = quo(num_exact(nano_num), num_exact(nano_den));
vtm.subsecx = add(vtm.subsecx, mulquo(nano, INT2FIX(TIME_SCALE), LONG2FIX(1000000000)));
}
else if (submicro != Qnil) { /* for Ruby 1.9.1 compatibility */
unsigned char *ptr;
long len;
int digit;
ptr = (unsigned char*)StringValuePtr(submicro);
len = RSTRING_LEN(submicro);
nsec = 0;
if (0 < len) {
if (10 <= (digit = ptr[0] >> 4)) goto end_submicro;
nsec += digit * 100;
if (10 <= (digit = ptr[0] & 0xf)) goto end_submicro;
nsec += digit * 10;
}
if (1 < len) {
if (10 <= (digit = ptr[1] >> 4)) goto end_submicro;
nsec += digit;
}
vtm.subsecx = add(vtm.subsecx, mulquo(LONG2FIX(nsec), INT2FIX(TIME_SCALE), LONG2FIX(1000000000)));
end_submicro: ;
}
timew = timegmw(&vtm);
}
GetNewTimeval(time, tobj);
tobj->gmt = 0;
tobj->tm_got = 0;
tobj->timew = timew;
if (gmt) {
TIME_SET_UTC(tobj);
}
else if (!NIL_P(offset)) {
time_set_utc_offset(time, offset);
time_fixoff(time);
}
if (!NIL_P(zone)) {
zone = rb_str_new_frozen(zone);
tobj->vtm.zone = StringValueCStr(zone);
rb_ivar_set(time, id_zone, zone);
}
return time;
}
/* :nodoc: */
static VALUE
time_load(VALUE klass, VALUE str)
{
VALUE time = time_s_alloc(klass);
time_mload(time, str);
return time;
}
/*
* Time is an abstraction of dates and times. Time is stored internally as
* the number of seconds with fraction since the _Epoch_, January 1, 1970
* 00:00 UTC. Also see the library module Date. The Time class treats GMT
* (Greenwich Mean Time) and UTC (Coordinated Universal Time) as equivalent.
* GMT is the older way of referring to these baseline times but persists in
* the names of calls on POSIX systems.
*
* All times may have fraction. Be aware of this fact when comparing times
* with each other -- times that are apparently equal when displayed may be
* different when compared.
*
* Since Ruby 1.9.2, Time implementation uses a signed 63 bit integer,
* Bignum or Rational.
* The integer is a number of nanoseconds since the _Epoch_ which can
* represent 1823-11-12 to 2116-02-20.
* When Bignum or Rational is used (before 1823, after 2116, under
* nanosecond), Time works slower as when integer is used.
*
* = Examples
*
* All of these examples were done using the EST timezone which is GMT-5.
*
* == Creating a new Time instance
*
* You can create a new instance of Time with Time::new. This will use the
* current system time. Time::now is an alias for this. You can also
* pass parts of the time to Time::new such as year, month, minute, etc. When
* you want to construct a time this way you must pass at least a year. If you
* pass the year with nothing else time will default to January 1 of that year
* at 00:00:00 with the current system timezone. Here are some examples:
*
* Time.new(2002) #=> 2002-01-01 00:00:00 -0500
* Time.new(2002, 10) #=> 2002-10-01 00:00:00 -0500
* Time.new(2002, 10, 31) #=> 2002-10-31 00:00:00 -0500
* Time.new(2002, 10, 31, 2, 2, 2, "+02:00") #=> 2002-10-31 02:02:02 +0200
*
* You can also use #gm, #local and
* #utc to infer GMT, local and UTC timezones instead of using
* the current system setting.
*
* You can also create a new time using Time::at which takes the number of
* seconds (or fraction of seconds) since the {Unix
* Epoch}[http://en.wikipedia.org/wiki/Unix_time].
*
* Time.at(628232400) #=> 1989-11-28 00:00:00 -0500
*
* == Working with an instance of Time
*
* Once you have an instance of Time there is a multitude of things you can
* do with it. Below are some examples. For all of the following examples, we
* will work on the assumption that you have done the following:
*
* t = Time.new(1993, 02, 24, 12, 0, 0, "+09:00")
*
* Was that a monday?
*
* t.monday? #=> false
*
* What year was that again?
*
* t.year #=> 1993
*
* Was is daylight savings at the time?
*
* t.dst? #=> false
*
* What's the day a year later?
*
* t + (60*60*24*365) #=> 1994-02-24 12:00:00 +0900
*
* How many seconds was that since the Unix Epoch?
*
* t.to_i #=> 730522800
*
* You can also do standard functions like compare two times.
*
* t1 = Time.new(2010)
* t2 = Time.new(2011)
*
* t1 == t2 #=> false
* t1 == t1 #=> true
* t1 < t2 #=> true
* t1 > t2 #=> false
*
* Time.new(2010,10,31).between?(t1, t2) #=> true
*/
void
Init_Time(void)
{
#undef rb_intern
#define rb_intern(str) rb_intern_const(str)
id_eq = rb_intern("==");
id_ne = rb_intern("!=");
id_quo = rb_intern("quo");
id_div = rb_intern("div");
id_cmp = rb_intern("<=>");
id_divmod = rb_intern("divmod");
id_mul = rb_intern("*");
id_submicro = rb_intern("submicro");
id_nano_num = rb_intern("nano_num");
id_nano_den = rb_intern("nano_den");
id_offset = rb_intern("offset");
id_zone = rb_intern("zone");
rb_cTime = rb_define_class("Time", rb_cObject);
rb_include_module(rb_cTime, rb_mComparable);
rb_define_alloc_func(rb_cTime, time_s_alloc);
rb_define_singleton_method(rb_cTime, "now", time_s_now, 0);
rb_define_singleton_method(rb_cTime, "at", time_s_at, -1);
rb_define_singleton_method(rb_cTime, "utc", time_s_mkutc, -1);
rb_define_singleton_method(rb_cTime, "gm", time_s_mkutc, -1);
rb_define_singleton_method(rb_cTime, "local", time_s_mktime, -1);
rb_define_singleton_method(rb_cTime, "mktime", time_s_mktime, -1);
rb_define_method(rb_cTime, "to_i", time_to_i, 0);
rb_define_method(rb_cTime, "to_f", time_to_f, 0);
rb_define_method(rb_cTime, "to_r", time_to_r, 0);
rb_define_method(rb_cTime, "<=>", time_cmp, 1);
rb_define_method(rb_cTime, "eql?", time_eql, 1);
rb_define_method(rb_cTime, "hash", time_hash, 0);
rb_define_method(rb_cTime, "initialize", time_init, -1);
rb_define_method(rb_cTime, "initialize_copy", time_init_copy, 1);
rb_define_method(rb_cTime, "localtime", time_localtime_m, -1);
rb_define_method(rb_cTime, "gmtime", time_gmtime, 0);
rb_define_method(rb_cTime, "utc", time_gmtime, 0);
rb_define_method(rb_cTime, "getlocal", time_getlocaltime, -1);
* array.c (rb_ary_modify): should copy the internal buffer if the modifying buffer is shared. * array.c (ary_make_shared): make an internal buffer of an array to be shared. * array.c (rb_ary_shift): avoid sliding an internal buffer by using shared buffer. * array.c (rb_ary_subseq): avoid copying the buffer. * parse.y (gettable): should freeze __LINE__ string. * io.c (rb_io_puts): old behavoir restored. rationale: a) if you want to call to_s for arrays, you can just call print a, "\n". b) to_s wastes memory if array (and sum of its contents) is huge. c) now any object that has to_ary is treated as an array, using rb_check_convert_type(). * hash.c (rb_hash_initialize): now accepts a block to calculate the default value. [new] * hash.c (rb_hash_aref): call "default" method to get the value corrensponding to the non existing key. * hash.c (rb_hash_default): get the default value based on the block given to 'new'. Now it takes an optinal "key" argument. "default" became the method to get the value for non existing key. Users may override "default" method to change the hash behavior. * hash.c (rb_hash_set_default): clear the flag if a block is given to 'new' * object.c (Init_Object): undef Data.allocate, left Data.new. * ext/curses/curses.c (window_scrollok): use RTEST(). * ext/curses/curses.c (window_idlok): ditto. * ext/curses/curses.c (window_keypad): ditto. * ext/curses/curses.c (window_idlok): idlok() may return void on some platforms; so don't use return value. * ext/curses/curses.c (window_scrollok): ditto for consistency. * ext/curses/curses.c: replace FIX2INT() by typechecking NUM2INT(). * parse.y (str_extend): should not process immature #$x and #@x interpolation, e.g #@#@ etc. * enum.c (enum_sort_by): sort_by does not have to be stable always. * enum.c (enum_sort_by): call qsort directly to gain performance. * util.c (ruby_qsort): ruby_qsort(qs6) is now native thread safe. * error.c (rb_sys_fail): it must be a bug if it's called when errno == 0. * regex.c (WC2MBC1ST): should not pass through > 0x80 number in UTF-8. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@1896 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2001-12-10 02:18:16 -05:00
rb_define_method(rb_cTime, "getgm", time_getgmtime, 0);
rb_define_method(rb_cTime, "getutc", time_getgmtime, 0);
rb_define_method(rb_cTime, "ctime", time_asctime, 0);
rb_define_method(rb_cTime, "asctime", time_asctime, 0);
rb_define_method(rb_cTime, "to_s", time_to_s, 0);
rb_define_method(rb_cTime, "inspect", time_to_s, 0);
rb_define_method(rb_cTime, "to_a", time_to_a, 0);
rb_define_method(rb_cTime, "+", time_plus, 1);
rb_define_method(rb_cTime, "-", time_minus, 1);
rb_define_method(rb_cTime, "succ", time_succ, 0);
rb_define_method(rb_cTime, "round", time_round, -1);
rb_define_method(rb_cTime, "sec", time_sec, 0);
rb_define_method(rb_cTime, "min", time_min, 0);
rb_define_method(rb_cTime, "hour", time_hour, 0);
rb_define_method(rb_cTime, "mday", time_mday, 0);
rb_define_method(rb_cTime, "day", time_mday, 0);
rb_define_method(rb_cTime, "mon", time_mon, 0);
rb_define_method(rb_cTime, "month", time_mon, 0);
rb_define_method(rb_cTime, "year", time_year, 0);
rb_define_method(rb_cTime, "wday", time_wday, 0);
rb_define_method(rb_cTime, "yday", time_yday, 0);
rb_define_method(rb_cTime, "isdst", time_isdst, 0);
rb_define_method(rb_cTime, "dst?", time_isdst, 0);
rb_define_method(rb_cTime, "zone", time_zone, 0);
rb_define_method(rb_cTime, "gmtoff", time_utc_offset, 0);
rb_define_method(rb_cTime, "gmt_offset", time_utc_offset, 0);
rb_define_method(rb_cTime, "utc_offset", time_utc_offset, 0);
rb_define_method(rb_cTime, "utc?", time_utc_p, 0);
rb_define_method(rb_cTime, "gmt?", time_utc_p, 0);
rb_define_method(rb_cTime, "sunday?", time_sunday, 0);
rb_define_method(rb_cTime, "monday?", time_monday, 0);
rb_define_method(rb_cTime, "tuesday?", time_tuesday, 0);
rb_define_method(rb_cTime, "wednesday?", time_wednesday, 0);
rb_define_method(rb_cTime, "thursday?", time_thursday, 0);
rb_define_method(rb_cTime, "friday?", time_friday, 0);
rb_define_method(rb_cTime, "saturday?", time_saturday, 0);
rb_define_method(rb_cTime, "tv_sec", time_to_i, 0);
rb_define_method(rb_cTime, "tv_usec", time_usec, 0);
rb_define_method(rb_cTime, "usec", time_usec, 0);
rb_define_method(rb_cTime, "tv_nsec", time_nsec, 0);
rb_define_method(rb_cTime, "nsec", time_nsec, 0);
rb_define_method(rb_cTime, "subsec", time_subsec, 0);
rb_define_method(rb_cTime, "strftime", time_strftime, 1);
/* methods for marshaling */
rb_define_private_method(rb_cTime, "_dump", time_dump, -1);
rb_define_private_method(rb_singleton_class(rb_cTime), "_load", time_load, 1);
#if 0
/* Time will support marshal_dump and marshal_load in the future (1.9 maybe) */
rb_define_private_method(rb_cTime, "marshal_dump", time_mdump, 0);
rb_define_private_method(rb_cTime, "marshal_load", time_mload, 1);
#endif
#ifdef DEBUG_FIND_TIME_NUMGUESS
rb_define_virtual_variable("$find_time_numguess", find_time_numguess_getter, NULL);
#endif
}