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Rhino is an open-source implementation of JavaScript written entirely in Java. It is typically embedded into Java applications to provide scripting to end users.
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/* -*- Mode: java; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
*
* ***** BEGIN LICENSE BLOCK *****
* Version: MPL 1.1/GPL 2.0
*
* The contents of this file are subject to the Mozilla Public License Version
* 1.1 (the "License"); you may not use this file except in compliance with
* the License. You may obtain a copy of the License at
* http://www.mozilla.org/MPL/
*
* Software distributed under the License is distributed on an "AS IS" basis,
* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
* for the specific language governing rights and limitations under the
* License.
*
* The Original Code is Rhino code, released
* May 6, 1999.
*
* The Initial Developer of the Original Code is
* Netscape Communications Corporation.
* Portions created by the Initial Developer are Copyright (C) 1997-1999
* the Initial Developer. All Rights Reserved.
*
* Contributor(s):
* Peter Annema
* Norris Boyd
* Mike McCabe
* Ilya Frank
*
*
* Alternatively, the contents of this file may be used under the terms of
* the GNU General Public License Version 2 or later (the "GPL"), in which
* case the provisions of the GPL are applicable instead of those above. If
* you wish to allow use of your version of this file only under the terms of
* the GPL and not to allow others to use your version of this file under the
* MPL, indicate your decision by deleting the provisions above and replacing
* them with the notice and other provisions required by the GPL. If you do
* not delete the provisions above, a recipient may use your version of this
* file under either the MPL or the GPL.
*
* ***** END LICENSE BLOCK ***** */
package org.mozilla.javascript;
import java.util.Date;
import java.text.DateFormat;
/**
* This class implements the Date native object.
* See ECMA 15.9.
* @author Mike McCabe
*/
final class NativeDate extends IdScriptableObject
{
static final long serialVersionUID = -8307438915861678966L;
private static final Object DATE_TAG = "Date";
private static final String js_NaN_date_str = "Invalid Date";
static void init(Scriptable scope, boolean sealed)
{
NativeDate obj = new NativeDate();
// Set the value of the prototype Date to NaN ('invalid date');
obj.date = ScriptRuntime.NaN;
obj.exportAsJSClass(MAX_PROTOTYPE_ID, scope, sealed);
}
private NativeDate()
{
if (thisTimeZone == null) {
// j.u.TimeZone is synchronized, so setting class statics from it
// should be OK.
thisTimeZone = java.util.TimeZone.getDefault();
LocalTZA = thisTimeZone.getRawOffset();
}
}
@Override
public String getClassName()
{
return "Date";
}
@Override
public Object getDefaultValue(Class> typeHint)
{
if (typeHint == null)
typeHint = ScriptRuntime.StringClass;
return super.getDefaultValue(typeHint);
}
double getJSTimeValue()
{
return date;
}
@Override
protected void fillConstructorProperties(IdFunctionObject ctor)
{
addIdFunctionProperty(ctor, DATE_TAG, ConstructorId_now,
"now", 0);
addIdFunctionProperty(ctor, DATE_TAG, ConstructorId_parse,
"parse", 1);
addIdFunctionProperty(ctor, DATE_TAG, ConstructorId_UTC,
"UTC", 1);
super.fillConstructorProperties(ctor);
}
@Override
protected void initPrototypeId(int id)
{
String s;
int arity;
switch (id) {
case Id_constructor: arity=1; s="constructor"; break;
case Id_toString: arity=0; s="toString"; break;
case Id_toTimeString: arity=0; s="toTimeString"; break;
case Id_toDateString: arity=0; s="toDateString"; break;
case Id_toLocaleString: arity=0; s="toLocaleString"; break;
case Id_toLocaleTimeString: arity=0; s="toLocaleTimeString"; break;
case Id_toLocaleDateString: arity=0; s="toLocaleDateString"; break;
case Id_toUTCString: arity=0; s="toUTCString"; break;
case Id_toSource: arity=0; s="toSource"; break;
case Id_valueOf: arity=0; s="valueOf"; break;
case Id_getTime: arity=0; s="getTime"; break;
case Id_getYear: arity=0; s="getYear"; break;
case Id_getFullYear: arity=0; s="getFullYear"; break;
case Id_getUTCFullYear: arity=0; s="getUTCFullYear"; break;
case Id_getMonth: arity=0; s="getMonth"; break;
case Id_getUTCMonth: arity=0; s="getUTCMonth"; break;
case Id_getDate: arity=0; s="getDate"; break;
case Id_getUTCDate: arity=0; s="getUTCDate"; break;
case Id_getDay: arity=0; s="getDay"; break;
case Id_getUTCDay: arity=0; s="getUTCDay"; break;
case Id_getHours: arity=0; s="getHours"; break;
case Id_getUTCHours: arity=0; s="getUTCHours"; break;
case Id_getMinutes: arity=0; s="getMinutes"; break;
case Id_getUTCMinutes: arity=0; s="getUTCMinutes"; break;
case Id_getSeconds: arity=0; s="getSeconds"; break;
case Id_getUTCSeconds: arity=0; s="getUTCSeconds"; break;
case Id_getMilliseconds: arity=0; s="getMilliseconds"; break;
case Id_getUTCMilliseconds: arity=0; s="getUTCMilliseconds"; break;
case Id_getTimezoneOffset: arity=0; s="getTimezoneOffset"; break;
case Id_setTime: arity=1; s="setTime"; break;
case Id_setMilliseconds: arity=1; s="setMilliseconds"; break;
case Id_setUTCMilliseconds: arity=1; s="setUTCMilliseconds"; break;
case Id_setSeconds: arity=2; s="setSeconds"; break;
case Id_setUTCSeconds: arity=2; s="setUTCSeconds"; break;
case Id_setMinutes: arity=3; s="setMinutes"; break;
case Id_setUTCMinutes: arity=3; s="setUTCMinutes"; break;
case Id_setHours: arity=4; s="setHours"; break;
case Id_setUTCHours: arity=4; s="setUTCHours"; break;
case Id_setDate: arity=1; s="setDate"; break;
case Id_setUTCDate: arity=1; s="setUTCDate"; break;
case Id_setMonth: arity=2; s="setMonth"; break;
case Id_setUTCMonth: arity=2; s="setUTCMonth"; break;
case Id_setFullYear: arity=3; s="setFullYear"; break;
case Id_setUTCFullYear: arity=3; s="setUTCFullYear"; break;
case Id_setYear: arity=1; s="setYear"; break;
default: throw new IllegalArgumentException(String.valueOf(id));
}
initPrototypeMethod(DATE_TAG, id, s, arity);
}
@Override
public Object execIdCall(IdFunctionObject f, Context cx, Scriptable scope,
Scriptable thisObj, Object[] args)
{
if (!f.hasTag(DATE_TAG)) {
return super.execIdCall(f, cx, scope, thisObj, args);
}
int id = f.methodId();
switch (id) {
case ConstructorId_now:
return ScriptRuntime.wrapNumber(now());
case ConstructorId_parse:
{
String dataStr = ScriptRuntime.toString(args, 0);
return ScriptRuntime.wrapNumber(date_parseString(dataStr));
}
case ConstructorId_UTC:
return ScriptRuntime.wrapNumber(jsStaticFunction_UTC(args));
case Id_constructor:
{
// if called as a function, just return a string
// representing the current time.
if (thisObj != null)
return date_format(now(), Id_toString);
return jsConstructor(args);
}
}
// The rest of Date.prototype methods require thisObj to be Date
if (!(thisObj instanceof NativeDate))
throw incompatibleCallError(f);
NativeDate realThis = (NativeDate)thisObj;
double t = realThis.date;
switch (id) {
case Id_toString:
case Id_toTimeString:
case Id_toDateString:
if (t == t) {
return date_format(t, id);
}
return js_NaN_date_str;
case Id_toLocaleString:
case Id_toLocaleTimeString:
case Id_toLocaleDateString:
if (t == t) {
return toLocale_helper(t, id);
}
return js_NaN_date_str;
case Id_toUTCString:
if (t == t) {
return js_toUTCString(t);
}
return js_NaN_date_str;
case Id_toSource:
return "(new Date("+ScriptRuntime.toString(t)+"))";
case Id_valueOf:
case Id_getTime:
return ScriptRuntime.wrapNumber(t);
case Id_getYear:
case Id_getFullYear:
case Id_getUTCFullYear:
if (t == t) {
if (id != Id_getUTCFullYear) t = LocalTime(t);
t = YearFromTime(t);
if (id == Id_getYear) {
if (cx.hasFeature(Context.FEATURE_NON_ECMA_GET_YEAR)) {
if (1900 <= t && t < 2000) {
t -= 1900;
}
} else {
t -= 1900;
}
}
}
return ScriptRuntime.wrapNumber(t);
case Id_getMonth:
case Id_getUTCMonth:
if (t == t) {
if (id == Id_getMonth) t = LocalTime(t);
t = MonthFromTime(t);
}
return ScriptRuntime.wrapNumber(t);
case Id_getDate:
case Id_getUTCDate:
if (t == t) {
if (id == Id_getDate) t = LocalTime(t);
t = DateFromTime(t);
}
return ScriptRuntime.wrapNumber(t);
case Id_getDay:
case Id_getUTCDay:
if (t == t) {
if (id == Id_getDay) t = LocalTime(t);
t = WeekDay(t);
}
return ScriptRuntime.wrapNumber(t);
case Id_getHours:
case Id_getUTCHours:
if (t == t) {
if (id == Id_getHours) t = LocalTime(t);
t = HourFromTime(t);
}
return ScriptRuntime.wrapNumber(t);
case Id_getMinutes:
case Id_getUTCMinutes:
if (t == t) {
if (id == Id_getMinutes) t = LocalTime(t);
t = MinFromTime(t);
}
return ScriptRuntime.wrapNumber(t);
case Id_getSeconds:
case Id_getUTCSeconds:
if (t == t) {
if (id == Id_getSeconds) t = LocalTime(t);
t = SecFromTime(t);
}
return ScriptRuntime.wrapNumber(t);
case Id_getMilliseconds:
case Id_getUTCMilliseconds:
if (t == t) {
if (id == Id_getMilliseconds) t = LocalTime(t);
t = msFromTime(t);
}
return ScriptRuntime.wrapNumber(t);
case Id_getTimezoneOffset:
if (t == t) {
t = (t - LocalTime(t)) / msPerMinute;
}
return ScriptRuntime.wrapNumber(t);
case Id_setTime:
t = TimeClip(ScriptRuntime.toNumber(args, 0));
realThis.date = t;
return ScriptRuntime.wrapNumber(t);
case Id_setMilliseconds:
case Id_setUTCMilliseconds:
case Id_setSeconds:
case Id_setUTCSeconds:
case Id_setMinutes:
case Id_setUTCMinutes:
case Id_setHours:
case Id_setUTCHours:
t = makeTime(t, args, id);
realThis.date = t;
return ScriptRuntime.wrapNumber(t);
case Id_setDate:
case Id_setUTCDate:
case Id_setMonth:
case Id_setUTCMonth:
case Id_setFullYear:
case Id_setUTCFullYear:
t = makeDate(t, args, id);
realThis.date = t;
return ScriptRuntime.wrapNumber(t);
case Id_setYear:
{
double year = ScriptRuntime.toNumber(args, 0);
if (year != year || Double.isInfinite(year)) {
t = ScriptRuntime.NaN;
} else {
if (t != t) {
t = 0;
} else {
t = LocalTime(t);
}
if (year >= 0 && year <= 99)
year += 1900;
double day = MakeDay(year, MonthFromTime(t),
DateFromTime(t));
t = MakeDate(day, TimeWithinDay(t));
t = internalUTC(t);
t = TimeClip(t);
}
}
realThis.date = t;
return ScriptRuntime.wrapNumber(t);
default: throw new IllegalArgumentException(String.valueOf(id));
}
}
/* ECMA helper functions */
private static final double HalfTimeDomain = 8.64e15;
private static final double HoursPerDay = 24.0;
private static final double MinutesPerHour = 60.0;
private static final double SecondsPerMinute = 60.0;
private static final double msPerSecond = 1000.0;
private static final double MinutesPerDay = (HoursPerDay * MinutesPerHour);
private static final double SecondsPerDay = (MinutesPerDay * SecondsPerMinute);
private static final double SecondsPerHour = (MinutesPerHour * SecondsPerMinute);
private static final double msPerDay = (SecondsPerDay * msPerSecond);
private static final double msPerHour = (SecondsPerHour * msPerSecond);
private static final double msPerMinute = (SecondsPerMinute * msPerSecond);
private static double Day(double t)
{
return Math.floor(t / msPerDay);
}
private static double TimeWithinDay(double t)
{
double result;
result = t % msPerDay;
if (result < 0)
result += msPerDay;
return result;
}
private static boolean IsLeapYear(int year)
{
return year % 4 == 0 && (year % 100 != 0 || year % 400 == 0);
}
/* math here has to be f.p, because we need
* floor((1968 - 1969) / 4) == -1
*/
private static double DayFromYear(double y)
{
return ((365 * ((y)-1970) + Math.floor(((y)-1969)/4.0)
- Math.floor(((y)-1901)/100.0) + Math.floor(((y)-1601)/400.0)));
}
private static double TimeFromYear(double y)
{
return DayFromYear(y) * msPerDay;
}
private static int YearFromTime(double t)
{
int lo = (int) Math.floor((t / msPerDay) / 366) + 1970;
int hi = (int) Math.floor((t / msPerDay) / 365) + 1970;
int mid;
/* above doesn't work for negative dates... */
if (hi < lo) {
int temp = lo;
lo = hi;
hi = temp;
}
/* Use a simple binary search algorithm to find the right
year. This seems like brute force... but the computation
of hi and lo years above lands within one year of the
correct answer for years within a thousand years of
1970; the loop below only requires six iterations
for year 270000. */
while (hi > lo) {
mid = (hi + lo) / 2;
if (TimeFromYear(mid) > t) {
hi = mid - 1;
} else {
lo = mid + 1;
if (TimeFromYear(lo) > t) {
return mid;
}
}
}
return lo;
}
private static double DayFromMonth(int m, int year)
{
int day = m * 30;
if (m >= 7) { day += m / 2 - 1; }
else if (m >= 2) { day += (m - 1) / 2 - 1; }
else { day += m; }
if (m >= 2 && IsLeapYear(year)) { ++day; }
return day;
}
private static int MonthFromTime(double t)
{
int year = YearFromTime(t);
int d = (int)(Day(t) - DayFromYear(year));
d -= 31 + 28;
if (d < 0) {
return (d < -28) ? 0 : 1;
}
if (IsLeapYear(year)) {
if (d == 0)
return 1; // 29 February
--d;
}
// d: date count from 1 March
int estimate = d / 30; // approx number of month since March
int mstart;
switch (estimate) {
case 0: return 2;
case 1: mstart = 31; break;
case 2: mstart = 31+30; break;
case 3: mstart = 31+30+31; break;
case 4: mstart = 31+30+31+30; break;
case 5: mstart = 31+30+31+30+31; break;
case 6: mstart = 31+30+31+30+31+31; break;
case 7: mstart = 31+30+31+30+31+31+30; break;
case 8: mstart = 31+30+31+30+31+31+30+31; break;
case 9: mstart = 31+30+31+30+31+31+30+31+30; break;
case 10: return 11; //Late december
default: throw Kit.codeBug();
}
// if d < mstart then real month since March == estimate - 1
return (d >= mstart) ? estimate + 2 : estimate + 1;
}
private static int DateFromTime(double t)
{
int year = YearFromTime(t);
int d = (int)(Day(t) - DayFromYear(year));
d -= 31 + 28;
if (d < 0) {
return (d < -28) ? d + 31 + 28 + 1 : d + 28 + 1;
}
if (IsLeapYear(year)) {
if (d == 0)
return 29; // 29 February
--d;
}
// d: date count from 1 March
int mdays, mstart;
switch (d / 30) { // approx number of month since March
case 0: return d + 1;
case 1: mdays = 31; mstart = 31; break;
case 2: mdays = 30; mstart = 31+30; break;
case 3: mdays = 31; mstart = 31+30+31; break;
case 4: mdays = 30; mstart = 31+30+31+30; break;
case 5: mdays = 31; mstart = 31+30+31+30+31; break;
case 6: mdays = 31; mstart = 31+30+31+30+31+31; break;
case 7: mdays = 30; mstart = 31+30+31+30+31+31+30; break;
case 8: mdays = 31; mstart = 31+30+31+30+31+31+30+31; break;
case 9: mdays = 30; mstart = 31+30+31+30+31+31+30+31+30; break;
case 10:
return d - (31+30+31+30+31+31+30+31+30) + 1; //Late december
default: throw Kit.codeBug();
}
d -= mstart;
if (d < 0) {
// wrong estimate: sfhift to previous month
d += mdays;
}
return d + 1;
}
private static int WeekDay(double t)
{
double result;
result = Day(t) + 4;
result = result % 7;
if (result < 0)
result += 7;
return (int) result;
}
private static double now()
{
return System.currentTimeMillis();
}
/* Should be possible to determine the need for this dynamically
* if we go with the workaround... I'm not using it now, because I
* can't think of any clean way to make toLocaleString() and the
* time zone (comment) in toString match the generated string
* values. Currently it's wrong-but-consistent in all but the
* most recent betas of the JRE - seems to work in 1.1.7.
*/
private final static boolean TZO_WORKAROUND = false;
private static double DaylightSavingTA(double t)
{
// Another workaround! The JRE doesn't seem to know about DST
// before year 1 AD, so we map to equivalent dates for the
// purposes of finding dst. To be safe, we do this for years
// outside 1970-2038.
if (t < 0.0 || t > 2145916800000.0) {
int year = EquivalentYear(YearFromTime(t));
double day = MakeDay(year, MonthFromTime(t), DateFromTime(t));
t = MakeDate(day, TimeWithinDay(t));
}
if (!TZO_WORKAROUND) {
Date date = new Date((long) t);
if (thisTimeZone.inDaylightTime(date))
return msPerHour;
else
return 0;
} else {
/* Use getOffset if inDaylightTime() is broken, because it
* seems to work acceptably. We don't switch over to it
* entirely, because it requires (expensive) exploded date arguments,
* and the api makes it impossible to handle dst
* changeovers cleanly.
*/
// Hardcode the assumption that the changeover always
// happens at 2:00 AM:
t += LocalTZA + (HourFromTime(t) <= 2 ? msPerHour : 0);
int year = YearFromTime(t);
double offset = thisTimeZone.getOffset(year > 0 ? 1 : 0,
year,
MonthFromTime(t),
DateFromTime(t),
WeekDay(t),
(int)TimeWithinDay(t));
if ((offset - LocalTZA) != 0)
return msPerHour;
else
return 0;
// return offset - LocalTZA;
}
}
/*
* Find a year for which any given date will fall on the same weekday.
*
* This function should be used with caution when used other than
* for determining DST; it hasn't been proven not to produce an
* incorrect year for times near year boundaries.
*/
private static int EquivalentYear(int year)
{
int day = (int) DayFromYear(year) + 4;
day = day % 7;
if (day < 0)
day += 7;
// Years and leap years on which Jan 1 is a Sunday, Monday, etc.
if (IsLeapYear(year)) {
switch (day) {
case 0: return 1984;
case 1: return 1996;
case 2: return 1980;
case 3: return 1992;
case 4: return 1976;
case 5: return 1988;
case 6: return 1972;
}
} else {
switch (day) {
case 0: return 1978;
case 1: return 1973;
case 2: return 1974;
case 3: return 1975;
case 4: return 1981;
case 5: return 1971;
case 6: return 1977;
}
}
// Unreachable
throw Kit.codeBug();
}
private static double LocalTime(double t)
{
return t + LocalTZA + DaylightSavingTA(t);
}
private static double internalUTC(double t)
{
return t - LocalTZA - DaylightSavingTA(t - LocalTZA);
}
private static int HourFromTime(double t)
{
double result;
result = Math.floor(t / msPerHour) % HoursPerDay;
if (result < 0)
result += HoursPerDay;
return (int) result;
}
private static int MinFromTime(double t)
{
double result;
result = Math.floor(t / msPerMinute) % MinutesPerHour;
if (result < 0)
result += MinutesPerHour;
return (int) result;
}
private static int SecFromTime(double t)
{
double result;
result = Math.floor(t / msPerSecond) % SecondsPerMinute;
if (result < 0)
result += SecondsPerMinute;
return (int) result;
}
private static int msFromTime(double t)
{
double result;
result = t % msPerSecond;
if (result < 0)
result += msPerSecond;
return (int) result;
}
private static double MakeTime(double hour, double min,
double sec, double ms)
{
return ((hour * MinutesPerHour + min) * SecondsPerMinute + sec)
* msPerSecond + ms;
}
private static double MakeDay(double year, double month, double date)
{
year += Math.floor(month / 12);
month = month % 12;
if (month < 0)
month += 12;
double yearday = Math.floor(TimeFromYear(year) / msPerDay);
double monthday = DayFromMonth((int)month, (int)year);
return yearday + monthday + date - 1;
}
private static double MakeDate(double day, double time)
{
return day * msPerDay + time;
}
private static double TimeClip(double d)
{
if (d != d ||
d == Double.POSITIVE_INFINITY ||
d == Double.NEGATIVE_INFINITY ||
Math.abs(d) > HalfTimeDomain)
{
return ScriptRuntime.NaN;
}
if (d > 0.0)
return Math.floor(d + 0.);
else
return Math.ceil(d + 0.);
}
/* end of ECMA helper functions */
/* find UTC time from given date... no 1900 correction! */
private static double date_msecFromDate(double year, double mon,
double mday, double hour,
double min, double sec,
double msec)
{
double day;
double time;
double result;
day = MakeDay(year, mon, mday);
time = MakeTime(hour, min, sec, msec);
result = MakeDate(day, time);
return result;
}
/* compute the time in msec (unclipped) from the given args */
private static final int MAXARGS = 7;
private static double date_msecFromArgs(Object[] args)
{
double array[] = new double[MAXARGS];
int loop;
double d;
for (loop = 0; loop < MAXARGS; loop++) {
if (loop < args.length) {
d = ScriptRuntime.toNumber(args[loop]);
if (d != d || Double.isInfinite(d)) {
return ScriptRuntime.NaN;
}
array[loop] = ScriptRuntime.toInteger(args[loop]);
} else {
if (loop == 2) {
array[loop] = 1; /* Default the date argument to 1. */
} else {
array[loop] = 0;
}
}
}
/* adjust 2-digit years into the 20th century */
if (array[0] >= 0 && array[0] <= 99)
array[0] += 1900;
return date_msecFromDate(array[0], array[1], array[2],
array[3], array[4], array[5], array[6]);
}
private static double jsStaticFunction_UTC(Object[] args)
{
return TimeClip(date_msecFromArgs(args));
}
private static double date_parseString(String s)
{
int year = -1;
int mon = -1;
int mday = -1;
int hour = -1;
int min = -1;
int sec = -1;
char c = 0;
char si = 0;
int i = 0;
int n = -1;
double tzoffset = -1;
char prevc = 0;
int limit = 0;
boolean seenplusminus = false;
limit = s.length();
while (i < limit) {
c = s.charAt(i);
i++;
if (c <= ' ' || c == ',' || c == '-') {
if (i < limit) {
si = s.charAt(i);
if (c == '-' && '0' <= si && si <= '9') {
prevc = c;
}
}
continue;
}
if (c == '(') { /* comments) */
int depth = 1;
while (i < limit) {
c = s.charAt(i);
i++;
if (c == '(')
depth++;
else if (c == ')')
if (--depth <= 0)
break;
}
continue;
}
if ('0' <= c && c <= '9') {
n = c - '0';
while (i < limit && '0' <= (c = s.charAt(i)) && c <= '9') {
n = n * 10 + c - '0';
i++;
}
/* allow TZA before the year, so
* 'Wed Nov 05 21:49:11 GMT-0800 1997'
* works */
/* uses of seenplusminus allow : in TZA, so Java
* no-timezone style of GMT+4:30 works
*/
if ((prevc == '+' || prevc == '-')/* && year>=0 */) {
/* make ':' case below change tzoffset */
seenplusminus = true;
/* offset */
if (n < 24)
n = n * 60; /* EG. "GMT-3" */
else
n = n % 100 + n / 100 * 60; /* eg "GMT-0430" */
if (prevc == '+') /* plus means east of GMT */
n = -n;
if (tzoffset != 0 && tzoffset != -1)
return ScriptRuntime.NaN;
tzoffset = n;
} else if (n >= 70 ||
(prevc == '/' && mon >= 0 && mday >= 0
&& year < 0))
{
if (year >= 0)
return ScriptRuntime.NaN;
else if (c <= ' ' || c == ',' || c == '/' || i >= limit)
year = n < 100 ? n + 1900 : n;
else
return ScriptRuntime.NaN;
} else if (c == ':') {
if (hour < 0)
hour = /*byte*/ n;
else if (min < 0)
min = /*byte*/ n;
else
return ScriptRuntime.NaN;
} else if (c == '/') {
if (mon < 0)
mon = /*byte*/ n-1;
else if (mday < 0)
mday = /*byte*/ n;
else
return ScriptRuntime.NaN;
} else if (i < limit && c != ',' && c > ' ' && c != '-') {
return ScriptRuntime.NaN;
} else if (seenplusminus && n < 60) { /* handle GMT-3:30 */
if (tzoffset < 0)
tzoffset -= n;
else
tzoffset += n;
} else if (hour >= 0 && min < 0) {
min = /*byte*/ n;
} else if (min >= 0 && sec < 0) {
sec = /*byte*/ n;
} else if (mday < 0) {
mday = /*byte*/ n;
} else {
return ScriptRuntime.NaN;
}
prevc = 0;
} else if (c == '/' || c == ':' || c == '+' || c == '-') {
prevc = c;
} else {
int st = i - 1;
while (i < limit) {
c = s.charAt(i);
if (!(('A' <= c && c <= 'Z') || ('a' <= c && c <= 'z')))
break;
i++;
}
int letterCount = i - st;
if (letterCount < 2)
return ScriptRuntime.NaN;
/*
* Use ported code from jsdate.c rather than the locale-specific
* date-parsing code from Java, to keep js and rhino consistent.
* Is this the right strategy?
*/
String wtb = "am;pm;"
+"monday;tuesday;wednesday;thursday;friday;"
+"saturday;sunday;"
+"january;february;march;april;may;june;"
+"july;august;september;october;november;december;"
+"gmt;ut;utc;est;edt;cst;cdt;mst;mdt;pst;pdt;";
int index = 0;
for (int wtbOffset = 0; ;) {
int wtbNext = wtb.indexOf(';', wtbOffset);
if (wtbNext < 0)
return ScriptRuntime.NaN;
if (wtb.regionMatches(true, wtbOffset, s, st, letterCount))
break;
wtbOffset = wtbNext + 1;
++index;
}
if (index < 2) {
/*
* AM/PM. Count 12:30 AM as 00:30, 12:30 PM as
* 12:30, instead of blindly adding 12 if PM.
*/
if (hour > 12 || hour < 0) {
return ScriptRuntime.NaN;
} else if (index == 0) {
// AM
if (hour == 12)
hour = 0;
} else {
// PM
if (hour != 12)
hour += 12;
}
} else if ((index -= 2) < 7) {
// ignore week days
} else if ((index -= 7) < 12) {
// month
if (mon < 0) {
mon = index;
} else {
return ScriptRuntime.NaN;
}
} else {
index -= 12;
// timezones
switch (index) {
case 0 /* gmt */: tzoffset = 0; break;
case 1 /* ut */: tzoffset = 0; break;
case 2 /* utc */: tzoffset = 0; break;
case 3 /* est */: tzoffset = 5 * 60; break;
case 4 /* edt */: tzoffset = 4 * 60; break;
case 5 /* cst */: tzoffset = 6 * 60; break;
case 6 /* cdt */: tzoffset = 5 * 60; break;
case 7 /* mst */: tzoffset = 7 * 60; break;
case 8 /* mdt */: tzoffset = 6 * 60; break;
case 9 /* pst */: tzoffset = 8 * 60; break;
case 10 /* pdt */:tzoffset = 7 * 60; break;
default: Kit.codeBug();
}
}
}
}
if (year < 0 || mon < 0 || mday < 0)
return ScriptRuntime.NaN;
if (sec < 0)
sec = 0;
if (min < 0)
min = 0;
if (hour < 0)
hour = 0;
double msec = date_msecFromDate(year, mon, mday, hour, min, sec, 0);
if (tzoffset == -1) { /* no time zone specified, have to use local */
return internalUTC(msec);
} else {
return msec + tzoffset * msPerMinute;
}
}
private static String date_format(double t, int methodId)
{
StringBuffer result = new StringBuffer(60);
double local = LocalTime(t);
/* Tue Oct 31 09:41:40 GMT-0800 (PST) 2000 */
/* Tue Oct 31 2000 */
/* 09:41:40 GMT-0800 (PST) */
if (methodId != Id_toTimeString) {
appendWeekDayName(result, WeekDay(local));
result.append(' ');
appendMonthName(result, MonthFromTime(local));
result.append(' ');
append0PaddedUint(result, DateFromTime(local), 2);
result.append(' ');
int year = YearFromTime(local);
if (year < 0) {
result.append('-');
year = -year;
}
append0PaddedUint(result, year, 4);
if (methodId != Id_toDateString)
result.append(' ');
}
if (methodId != Id_toDateString) {
append0PaddedUint(result, HourFromTime(local), 2);
result.append(':');
append0PaddedUint(result, MinFromTime(local), 2);
result.append(':');
append0PaddedUint(result, SecFromTime(local), 2);
// offset from GMT in minutes. The offset includes daylight
// savings, if it applies.
int minutes = (int) Math.floor((LocalTZA + DaylightSavingTA(t))
/ msPerMinute);
// map 510 minutes to 0830 hours
int offset = (minutes / 60) * 100 + minutes % 60;
if (offset > 0) {
result.append(" GMT+");
} else {
result.append(" GMT-");
offset = -offset;
}
append0PaddedUint(result, offset, 4);
if (timeZoneFormatter == null)
timeZoneFormatter = new java.text.SimpleDateFormat("zzz");
// Find an equivalent year before getting the timezone
// comment. See DaylightSavingTA.
if (t < 0.0 || t > 2145916800000.0) {
int equiv = EquivalentYear(YearFromTime(local));
double day = MakeDay(equiv, MonthFromTime(t), DateFromTime(t));
t = MakeDate(day, TimeWithinDay(t));
}
result.append(" (");
java.util.Date date = new Date((long) t);
synchronized (timeZoneFormatter) {
result.append(timeZoneFormatter.format(date));
}
result.append(')');
}
return result.toString();
}
/* the javascript constructor */
private static Object jsConstructor(Object[] args)
{
NativeDate obj = new NativeDate();
// if called as a constructor with no args,
// return a new Date with the current time.
if (args.length == 0) {
obj.date = now();
return obj;
}
// if called with just one arg -
if (args.length == 1) {
Object arg0 = args[0];
if (arg0 instanceof Scriptable)
arg0 = ((Scriptable) arg0).getDefaultValue(null);
double date;
if (arg0 instanceof String) {
// it's a string; parse it.
date = date_parseString((String)arg0);
} else {
// if it's not a string, use it as a millisecond date
date = ScriptRuntime.toNumber(arg0);
}
obj.date = TimeClip(date);
return obj;
}
double time = date_msecFromArgs(args);
if (!Double.isNaN(time) && !Double.isInfinite(time))
time = TimeClip(internalUTC(time));
obj.date = time;
return obj;
}
private static String toLocale_helper(double t, int methodId)
{
java.text.DateFormat formatter;
switch (methodId) {
case Id_toLocaleString:
if (localeDateTimeFormatter == null) {
localeDateTimeFormatter
= DateFormat.getDateTimeInstance(DateFormat.LONG,
DateFormat.LONG);
}
formatter = localeDateTimeFormatter;
break;
case Id_toLocaleTimeString:
if (localeTimeFormatter == null) {
localeTimeFormatter
= DateFormat.getTimeInstance(DateFormat.LONG);
}
formatter = localeTimeFormatter;
break;
case Id_toLocaleDateString:
if (localeDateFormatter == null) {
localeDateFormatter
= DateFormat.getDateInstance(DateFormat.LONG);
}
formatter = localeDateFormatter;
break;
default: formatter = null; // unreachable
}
synchronized (formatter) {
return formatter.format(new Date((long) t));
}
}
private static String js_toUTCString(double date)
{
StringBuffer result = new StringBuffer(60);
appendWeekDayName(result, WeekDay(date));
result.append(", ");
append0PaddedUint(result, DateFromTime(date), 2);
result.append(' ');
appendMonthName(result, MonthFromTime(date));
result.append(' ');
int year = YearFromTime(date);
if (year < 0) {
result.append('-'); year = -year;
}
append0PaddedUint(result, year, 4);
result.append(' ');
append0PaddedUint(result, HourFromTime(date), 2);
result.append(':');
append0PaddedUint(result, MinFromTime(date), 2);
result.append(':');
append0PaddedUint(result, SecFromTime(date), 2);
result.append(" GMT");
return result.toString();
}
private static void append0PaddedUint(StringBuffer sb, int i, int minWidth)
{
if (i < 0) Kit.codeBug();
int scale = 1;
--minWidth;
if (i >= 10) {
if (i < 1000 * 1000 * 1000) {
for (;;) {
int newScale = scale * 10;
if (i < newScale) { break; }
--minWidth;
scale = newScale;
}
} else {
// Separated case not to check against 10 * 10^9 overflow
minWidth -= 9;
scale = 1000 * 1000 * 1000;
}
}
while (minWidth > 0) {
sb.append('0');
--minWidth;
}
while (scale != 1) {
sb.append((char)('0' + (i / scale)));
i %= scale;
scale /= 10;
}
sb.append((char)('0' + i));
}
private static void appendMonthName(StringBuffer sb, int index)
{
// Take advantage of the fact that all month abbreviations
// have the same length to minimize amount of strings runtime has
// to keep in memory
String months = "Jan"+"Feb"+"Mar"+"Apr"+"May"+"Jun"
+"Jul"+"Aug"+"Sep"+"Oct"+"Nov"+"Dec";
index *= 3;
for (int i = 0; i != 3; ++i) {
sb.append(months.charAt(index + i));
}
}
private static void appendWeekDayName(StringBuffer sb, int index)
{
String days = "Sun"+"Mon"+"Tue"+"Wed"+"Thu"+"Fri"+"Sat";
index *= 3;
for (int i = 0; i != 3; ++i) {
sb.append(days.charAt(index + i));
}
}
private static double makeTime(double date, Object[] args, int methodId)
{
int maxargs;
boolean local = true;
switch (methodId) {
case Id_setUTCMilliseconds:
local = false;
// fallthrough
case Id_setMilliseconds:
maxargs = 1;
break;
case Id_setUTCSeconds:
local = false;
// fallthrough
case Id_setSeconds:
maxargs = 2;
break;
case Id_setUTCMinutes:
local = false;
// fallthrough
case Id_setMinutes:
maxargs = 3;
break;
case Id_setUTCHours:
local = false;
// fallthrough
case Id_setHours:
maxargs = 4;
break;
default:
Kit.codeBug();
maxargs = 0;
}
int i;
double conv[] = new double[4];
double hour, min, sec, msec;
double lorutime; /* Local or UTC version of date */
double time;
double result;
/* just return NaN if the date is already NaN */
if (date != date)
return date;
/* Satisfy the ECMA rule that if a function is called with
* fewer arguments than the specified formal arguments, the
* remaining arguments are set to undefined. Seems like all
* the Date.setWhatever functions in ECMA are only varargs
* beyond the first argument; this should be set to undefined
* if it's not given. This means that "d = new Date();
* d.setMilliseconds()" returns NaN. Blech.
*/
if (args.length == 0)
args = ScriptRuntime.padArguments(args, 1);
for (i = 0; i < args.length && i < maxargs; i++) {
conv[i] = ScriptRuntime.toNumber(args[i]);
// limit checks that happen in MakeTime in ECMA.
if (conv[i] != conv[i] || Double.isInfinite(conv[i])) {
return ScriptRuntime.NaN;
}
conv[i] = ScriptRuntime.toInteger(conv[i]);
}
if (local)
lorutime = LocalTime(date);
else
lorutime = date;
i = 0;
int stop = args.length;
if (maxargs >= 4 && i < stop)
hour = conv[i++];
else
hour = HourFromTime(lorutime);
if (maxargs >= 3 && i < stop)
min = conv[i++];
else
min = MinFromTime(lorutime);
if (maxargs >= 2 && i < stop)
sec = conv[i++];
else
sec = SecFromTime(lorutime);
if (maxargs >= 1 && i < stop)
msec = conv[i++];
else
msec = msFromTime(lorutime);
time = MakeTime(hour, min, sec, msec);
result = MakeDate(Day(lorutime), time);
if (local)
result = internalUTC(result);
date = TimeClip(result);
return date;
}
private static double makeDate(double date, Object[] args, int methodId)
{
int maxargs;
boolean local = true;
switch (methodId) {
case Id_setUTCDate:
local = false;
// fallthrough
case Id_setDate:
maxargs = 1;
break;
case Id_setUTCMonth:
local = false;
// fallthrough
case Id_setMonth:
maxargs = 2;
break;
case Id_setUTCFullYear:
local = false;
// fallthrough
case Id_setFullYear:
maxargs = 3;
break;
default:
Kit.codeBug();
maxargs = 0;
}
int i;
double conv[] = new double[3];
double year, month, day;
double lorutime; /* local or UTC version of date */
double result;
/* See arg padding comment in makeTime.*/
if (args.length == 0)
args = ScriptRuntime.padArguments(args, 1);
for (i = 0; i < args.length && i < maxargs; i++) {
conv[i] = ScriptRuntime.toNumber(args[i]);
// limit checks that happen in MakeDate in ECMA.
if (conv[i] != conv[i] || Double.isInfinite(conv[i])) {
return ScriptRuntime.NaN;
}
conv[i] = ScriptRuntime.toInteger(conv[i]);
}
/* return NaN if date is NaN and we're not setting the year,
* If we are, use 0 as the time. */
if (date != date) {
if (args.length < 3) {
return ScriptRuntime.NaN;
} else {
lorutime = 0;
}
} else {
if (local)
lorutime = LocalTime(date);
else
lorutime = date;
}
i = 0;
int stop = args.length;
if (maxargs >= 3 && i < stop)
year = conv[i++];
else
year = YearFromTime(lorutime);
if (maxargs >= 2 && i < stop)
month = conv[i++];
else
month = MonthFromTime(lorutime);
if (maxargs >= 1 && i < stop)
day = conv[i++];
else
day = DateFromTime(lorutime);
day = MakeDay(year, month, day); /* day within year */
result = MakeDate(day, TimeWithinDay(lorutime));
if (local)
result = internalUTC(result);
date = TimeClip(result);
return date;
}
// #string_id_map#
@Override
protected int findPrototypeId(String s)
{
int id;
// #generated# Last update: 2007-05-09 08:15:38 EDT
L0: { id = 0; String X = null; int c;
L: switch (s.length()) {
case 6: X="getDay";id=Id_getDay; break L;
case 7: switch (s.charAt(3)) {
case 'D': c=s.charAt(0);
if (c=='g') { X="getDate";id=Id_getDate; }
else if (c=='s') { X="setDate";id=Id_setDate; }
break L;
case 'T': c=s.charAt(0);
if (c=='g') { X="getTime";id=Id_getTime; }
else if (c=='s') { X="setTime";id=Id_setTime; }
break L;
case 'Y': c=s.charAt(0);
if (c=='g') { X="getYear";id=Id_getYear; }
else if (c=='s') { X="setYear";id=Id_setYear; }
break L;
case 'u': X="valueOf";id=Id_valueOf; break L;
} break L;
case 8: switch (s.charAt(3)) {
case 'H': c=s.charAt(0);
if (c=='g') { X="getHours";id=Id_getHours; }
else if (c=='s') { X="setHours";id=Id_setHours; }
break L;
case 'M': c=s.charAt(0);
if (c=='g') { X="getMonth";id=Id_getMonth; }
else if (c=='s') { X="setMonth";id=Id_setMonth; }
break L;
case 'o': X="toSource";id=Id_toSource; break L;
case 't': X="toString";id=Id_toString; break L;
} break L;
case 9: X="getUTCDay";id=Id_getUTCDay; break L;
case 10: c=s.charAt(3);
if (c=='M') {
c=s.charAt(0);
if (c=='g') { X="getMinutes";id=Id_getMinutes; }
else if (c=='s') { X="setMinutes";id=Id_setMinutes; }
}
else if (c=='S') {
c=s.charAt(0);
if (c=='g') { X="getSeconds";id=Id_getSeconds; }
else if (c=='s') { X="setSeconds";id=Id_setSeconds; }
}
else if (c=='U') {
c=s.charAt(0);
if (c=='g') { X="getUTCDate";id=Id_getUTCDate; }
else if (c=='s') { X="setUTCDate";id=Id_setUTCDate; }
}
break L;
case 11: switch (s.charAt(3)) {
case 'F': c=s.charAt(0);
if (c=='g') { X="getFullYear";id=Id_getFullYear; }
else if (c=='s') { X="setFullYear";id=Id_setFullYear; }
break L;
case 'M': X="toGMTString";id=Id_toGMTString; break L;
case 'T': X="toUTCString";id=Id_toUTCString; break L;
case 'U': c=s.charAt(0);
if (c=='g') {
c=s.charAt(9);
if (c=='r') { X="getUTCHours";id=Id_getUTCHours; }
else if (c=='t') { X="getUTCMonth";id=Id_getUTCMonth; }
}
else if (c=='s') {
c=s.charAt(9);
if (c=='r') { X="setUTCHours";id=Id_setUTCHours; }
else if (c=='t') { X="setUTCMonth";id=Id_setUTCMonth; }
}
break L;
case 's': X="constructor";id=Id_constructor; break L;
} break L;
case 12: c=s.charAt(2);
if (c=='D') { X="toDateString";id=Id_toDateString; }
else if (c=='T') { X="toTimeString";id=Id_toTimeString; }
break L;
case 13: c=s.charAt(0);
if (c=='g') {
c=s.charAt(6);
if (c=='M') { X="getUTCMinutes";id=Id_getUTCMinutes; }
else if (c=='S') { X="getUTCSeconds";id=Id_getUTCSeconds; }
}
else if (c=='s') {
c=s.charAt(6);
if (c=='M') { X="setUTCMinutes";id=Id_setUTCMinutes; }
else if (c=='S') { X="setUTCSeconds";id=Id_setUTCSeconds; }
}
break L;
case 14: c=s.charAt(0);
if (c=='g') { X="getUTCFullYear";id=Id_getUTCFullYear; }
else if (c=='s') { X="setUTCFullYear";id=Id_setUTCFullYear; }
else if (c=='t') { X="toLocaleString";id=Id_toLocaleString; }
break L;
case 15: c=s.charAt(0);
if (c=='g') { X="getMilliseconds";id=Id_getMilliseconds; }
else if (c=='s') { X="setMilliseconds";id=Id_setMilliseconds; }
break L;
case 17: X="getTimezoneOffset";id=Id_getTimezoneOffset; break L;
case 18: c=s.charAt(0);
if (c=='g') { X="getUTCMilliseconds";id=Id_getUTCMilliseconds; }
else if (c=='s') { X="setUTCMilliseconds";id=Id_setUTCMilliseconds; }
else if (c=='t') {
c=s.charAt(8);
if (c=='D') { X="toLocaleDateString";id=Id_toLocaleDateString; }
else if (c=='T') { X="toLocaleTimeString";id=Id_toLocaleTimeString; }
}
break L;
}
if (X!=null && X!=s && !X.equals(s)) id = 0;
break L0;
}
// #/generated#
return id;
}
private static final int
ConstructorId_now = -3,
ConstructorId_parse = -2,
ConstructorId_UTC = -1,
Id_constructor = 1,
Id_toString = 2,
Id_toTimeString = 3,
Id_toDateString = 4,
Id_toLocaleString = 5,
Id_toLocaleTimeString = 6,
Id_toLocaleDateString = 7,
Id_toUTCString = 8,
Id_toSource = 9,
Id_valueOf = 10,
Id_getTime = 11,
Id_getYear = 12,
Id_getFullYear = 13,
Id_getUTCFullYear = 14,
Id_getMonth = 15,
Id_getUTCMonth = 16,
Id_getDate = 17,
Id_getUTCDate = 18,
Id_getDay = 19,
Id_getUTCDay = 20,
Id_getHours = 21,
Id_getUTCHours = 22,
Id_getMinutes = 23,
Id_getUTCMinutes = 24,
Id_getSeconds = 25,
Id_getUTCSeconds = 26,
Id_getMilliseconds = 27,
Id_getUTCMilliseconds = 28,
Id_getTimezoneOffset = 29,
Id_setTime = 30,
Id_setMilliseconds = 31,
Id_setUTCMilliseconds = 32,
Id_setSeconds = 33,
Id_setUTCSeconds = 34,
Id_setMinutes = 35,
Id_setUTCMinutes = 36,
Id_setHours = 37,
Id_setUTCHours = 38,
Id_setDate = 39,
Id_setUTCDate = 40,
Id_setMonth = 41,
Id_setUTCMonth = 42,
Id_setFullYear = 43,
Id_setUTCFullYear = 44,
Id_setYear = 45,
MAX_PROTOTYPE_ID = 45;
private static final int
Id_toGMTString = Id_toUTCString; // Alias, see Ecma B.2.6
// #/string_id_map#
/* cached values */
private static java.util.TimeZone thisTimeZone;
private static double LocalTZA;
private static java.text.DateFormat timeZoneFormatter;
private static java.text.DateFormat localeDateTimeFormatter;
private static java.text.DateFormat localeDateFormatter;
private static java.text.DateFormat localeTimeFormatter;
private double date;
}