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v8/src/date.cc
Hannu Trey f781f522af Re-detect the host time zone if requested by an embedder 
Add an enum argument to DateTimeConfigurationChangeNotification to
control whether or not to redetect the host time zone. The default value
kSkip doesn't cause redetecting so that callers do not need to change if
they want the current behavior (e.g. Chromium).

Note that the host time zone detection does not work when v8 is run
inside a sandbox as in Chromium so that Chromium detects the host time
zone outside the sandbox before calling
DateTimeConfigurationChangeNotification. OTOH, other v8 embedders may
find it more convenient for v8 to do the host time zone detection on
their behalf. In that case, they can call the function with the new
argument set to value kRedetect.

Test:
With PHP+V8Js on linux, execute:
php -r '
  putenv("TZ=Europe/Helsinki");
  $v8 = new V8Js();
  $v8->executeString("print((new Date(0)).toString()+\"\\n\");");
  putenv("TZ=America/New_York");
  $v8->executeString("print((new Date(0)).toString()+\"\\n\");");'

Result before modification:
Thu Jan 01 1970 02:00:00 GMT+0200 (Eastern European Standard Time)
Thu Jan 01 1970 02:00:00 GMT+0200 (Eastern European Standard Time)

Result after modification:
Thu Jan 01 1970 02:00:00 GMT+0200 (Eastern European Standard Time)
Thu Jan 01 1970 02:00:00 GMT+0200 (Eastern European Standard Time)

Result after V8JS is modified to use value kRedetect when calling

Thu Jan 01 1970 02:00:00 GMT+0200 (Eastern European Standard Time)
Wed Dec 31 1969 19:00:00 GMT-0500 (Eastern Standard Time)

DateTimeConfigurationChangeNotification: 
Change-Id: I005192dd42669a94f606a49baa9eafad3475b9fd
Reviewed-on: https://chromium-review.googlesource.com/c/1449637
Reviewed-by: Ulan Degenbaev <ulan@chromium.org>
Reviewed-by: Jungshik Shin <jshin@chromium.org>
Commit-Queue: Jungshik Shin <jshin@chromium.org>
Cr-Commit-Position: refs/heads/master@{#59613}
2019-02-14 23:40:23 +00:00

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// Copyright 2012 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "src/date.h"
#include "src/base/overflowing-math.h"
#include "src/conversions.h"
#include "src/objects-inl.h"
#ifdef V8_INTL_SUPPORT
#include "src/objects/intl-objects.h"
#endif
namespace v8 {
namespace internal {
static const int kDaysIn4Years = 4 * 365 + 1;
static const int kDaysIn100Years = 25 * kDaysIn4Years - 1;
static const int kDaysIn400Years = 4 * kDaysIn100Years + 1;
static const int kDays1970to2000 = 30 * 365 + 7;
static const int kDaysOffset = 1000 * kDaysIn400Years + 5 * kDaysIn400Years -
kDays1970to2000;
static const int kYearsOffset = 400000;
static const char kDaysInMonths[] =
{31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
DateCache::DateCache()
: stamp_(kNullAddress),
tz_cache_(
#ifdef V8_INTL_SUPPORT
Intl::CreateTimeZoneCache()
#else
base::OS::CreateTimezoneCache()
#endif
) {
ResetDateCache(base::TimezoneCache::TimeZoneDetection::kSkip);
}
void DateCache::ResetDateCache(
base::TimezoneCache::TimeZoneDetection time_zone_detection) {
if (stamp_->value() >= Smi::kMaxValue) {
stamp_ = Smi::zero();
} else {
stamp_ = Smi::FromInt(stamp_->value() + 1);
}
DCHECK(stamp_ != Smi::FromInt(kInvalidStamp));
for (int i = 0; i < kDSTSize; ++i) {
ClearSegment(&dst_[i]);
}
dst_usage_counter_ = 0;
before_ = &dst_[0];
after_ = &dst_[1];
ymd_valid_ = false;
#ifdef V8_INTL_SUPPORT
if (!FLAG_icu_timezone_data) {
#endif
local_offset_ms_ = kInvalidLocalOffsetInMs;
#ifdef V8_INTL_SUPPORT
}
#endif
tz_cache_->Clear(time_zone_detection);
tz_name_ = nullptr;
dst_tz_name_ = nullptr;
}
// ECMA 262 - ES#sec-timeclip TimeClip (time)
double DateCache::TimeClip(double time) {
if (-kMaxTimeInMs <= time && time <= kMaxTimeInMs) {
return DoubleToInteger(time) + 0.0;
}
return std::numeric_limits<double>::quiet_NaN();
}
void DateCache::ClearSegment(DST* segment) {
segment->start_sec = kMaxEpochTimeInSec;
segment->end_sec = -kMaxEpochTimeInSec;
segment->offset_ms = 0;
segment->last_used = 0;
}
void DateCache::YearMonthDayFromDays(
int days, int* year, int* month, int* day) {
if (ymd_valid_) {
// Check conservatively if the given 'days' has
// the same year and month as the cached 'days'.
int new_day = ymd_day_ + (days - ymd_days_);
if (new_day >= 1 && new_day <= 28) {
ymd_day_ = new_day;
ymd_days_ = days;
*year = ymd_year_;
*month = ymd_month_;
*day = new_day;
return;
}
}
int save_days = days;
days += kDaysOffset;
*year = 400 * (days / kDaysIn400Years) - kYearsOffset;
days %= kDaysIn400Years;
DCHECK_EQ(save_days, DaysFromYearMonth(*year, 0) + days);
days--;
int yd1 = days / kDaysIn100Years;
days %= kDaysIn100Years;
*year += 100 * yd1;
days++;
int yd2 = days / kDaysIn4Years;
days %= kDaysIn4Years;
*year += 4 * yd2;
days--;
int yd3 = days / 365;
days %= 365;
*year += yd3;
bool is_leap = (!yd1 || yd2) && !yd3;
DCHECK_GE(days, -1);
DCHECK(is_leap || (days >= 0));
DCHECK((days < 365) || (is_leap && (days < 366)));
DCHECK(is_leap == ((*year % 4 == 0) && (*year % 100 || (*year % 400 == 0))));
DCHECK(is_leap || ((DaysFromYearMonth(*year, 0) + days) == save_days));
DCHECK(!is_leap || ((DaysFromYearMonth(*year, 0) + days + 1) == save_days));
days += is_leap;
// Check if the date is after February.
if (days >= 31 + 28 + BoolToInt(is_leap)) {
days -= 31 + 28 + BoolToInt(is_leap);
// Find the date starting from March.
for (int i = 2; i < 12; i++) {
if (days < kDaysInMonths[i]) {
*month = i;
*day = days + 1;
break;
}
days -= kDaysInMonths[i];
}
} else {
// Check January and February.
if (days < 31) {
*month = 0;
*day = days + 1;
} else {
*month = 1;
*day = days - 31 + 1;
}
}
DCHECK(DaysFromYearMonth(*year, *month) + *day - 1 == save_days);
ymd_valid_ = true;
ymd_year_ = *year;
ymd_month_ = *month;
ymd_day_ = *day;
ymd_days_ = save_days;
}
int DateCache::DaysFromYearMonth(int year, int month) {
static const int day_from_month[] = {0, 31, 59, 90, 120, 151,
181, 212, 243, 273, 304, 334};
static const int day_from_month_leap[] = {0, 31, 60, 91, 121, 152,
182, 213, 244, 274, 305, 335};
year += month / 12;
month %= 12;
if (month < 0) {
year--;
month += 12;
}
DCHECK_GE(month, 0);
DCHECK_LT(month, 12);
// year_delta is an arbitrary number such that:
// a) year_delta = -1 (mod 400)
// b) year + year_delta > 0 for years in the range defined by
// ECMA 262 - 15.9.1.1, i.e. upto 100,000,000 days on either side of
// Jan 1 1970. This is required so that we don't run into integer
// division of negative numbers.
// c) there shouldn't be an overflow for 32-bit integers in the following
// operations.
static const int year_delta = 399999;
static const int base_day = 365 * (1970 + year_delta) +
(1970 + year_delta) / 4 -
(1970 + year_delta) / 100 +
(1970 + year_delta) / 400;
int year1 = year + year_delta;
int day_from_year = 365 * year1 +
year1 / 4 -
year1 / 100 +
year1 / 400 -
base_day;
if ((year % 4 != 0) || (year % 100 == 0 && year % 400 != 0)) {
return day_from_year + day_from_month[month];
}
return day_from_year + day_from_month_leap[month];
}
void DateCache::BreakDownTime(int64_t time_ms, int* year, int* month, int* day,
int* weekday, int* hour, int* min, int* sec,
int* ms) {
int const days = DaysFromTime(time_ms);
int const time_in_day_ms = TimeInDay(time_ms, days);
YearMonthDayFromDays(days, year, month, day);
*weekday = Weekday(days);
*hour = time_in_day_ms / (60 * 60 * 1000);
*min = (time_in_day_ms / (60 * 1000)) % 60;
*sec = (time_in_day_ms / 1000) % 60;
*ms = time_in_day_ms % 1000;
}
// Implements LocalTimeZonedjustment(t, isUTC)
// ECMA 262 - ES#sec-local-time-zone-adjustment
int DateCache::GetLocalOffsetFromOS(int64_t time_ms, bool is_utc) {
double offset;
#ifdef V8_INTL_SUPPORT
if (FLAG_icu_timezone_data) {
offset = tz_cache_->LocalTimeOffset(static_cast<double>(time_ms), is_utc);
} else {
#endif
// When ICU timezone data is not used, we need to compute the timezone
// offset for a given local time.
//
// The following shows that using DST for (t - LocalTZA - hour) produces
// correct conversion where LocalTZA is the timezone offset in winter (no
// DST) and the timezone offset is assumed to have no historical change.
// Note that it does not work for the past and the future if LocalTZA (no
// DST) is different from the current LocalTZA (no DST). For instance,
// this will break for Europe/Moscow in 2012 ~ 2013 because LocalTZA was
// 4h instead of the current 3h (as of 2018).
//
// Consider transition to DST at local time L1.
// Let L0 = L1 - hour, L2 = L1 + hour,
// U1 = UTC time that corresponds to L1,
// U0 = U1 - hour.
// Transitioning to DST moves local clock one hour forward L1 => L2, so
// U0 = UTC time that corresponds to L0 = L0 - LocalTZA,
// U1 = UTC time that corresponds to L1 = L1 - LocalTZA,
// U1 = UTC time that corresponds to L2 = L2 - LocalTZA - hour.
// Note that DST(U0 - hour) = 0, DST(U0) = 0, DST(U1) = 1.
// U0 = L0 - LocalTZA - DST(L0 - LocalTZA - hour),
// U1 = L1 - LocalTZA - DST(L1 - LocalTZA - hour),
// U1 = L2 - LocalTZA - DST(L2 - LocalTZA - hour).
//
// Consider transition from DST at local time L1.
// Let L0 = L1 - hour,
// U1 = UTC time that corresponds to L1,
// U0 = U1 - hour, U2 = U1 + hour.
// Transitioning from DST moves local clock one hour back L1 => L0, so
// U0 = UTC time that corresponds to L0 (before transition)
// = L0 - LocalTZA - hour.
// U1 = UTC time that corresponds to L0 (after transition)
// = L0 - LocalTZA = L1 - LocalTZA - hour
// U2 = UTC time that corresponds to L1 = L1 - LocalTZA.
// Note that DST(U0) = 1, DST(U1) = 0, DST(U2) = 0.
// U0 = L0 - LocalTZA - DST(L0 - LocalTZA - hour) = L0 - LocalTZA - DST(U0).
// U2 = L1 - LocalTZA - DST(L1 - LocalTZA - hour) = L1 - LocalTZA - DST(U1).
// It is impossible to get U1 from local time.
if (local_offset_ms_ == kInvalidLocalOffsetInMs) {
// This gets the constant LocalTZA (arguments are ignored).
local_offset_ms_ =
tz_cache_->LocalTimeOffset(static_cast<double>(time_ms), is_utc);
}
offset = local_offset_ms_;
if (!is_utc) {
const int kMsPerHour = 3600 * 1000;
time_ms -= (offset + kMsPerHour);
}
offset += DaylightSavingsOffsetInMs(time_ms);
#ifdef V8_INTL_SUPPORT
}
#endif
DCHECK_LT(offset, kInvalidLocalOffsetInMs);
return static_cast<int>(offset);
}
void DateCache::ExtendTheAfterSegment(int time_sec, int offset_ms) {
if (after_->offset_ms == offset_ms &&
after_->start_sec - kDefaultDSTDeltaInSec <= time_sec &&
time_sec <= after_->end_sec) {
// Extend the after_ segment.
after_->start_sec = time_sec;
} else {
// The after_ segment is either invalid or starts too late.
if (!InvalidSegment(after_)) {
// If the after_ segment is valid, replace it with a new segment.
after_ = LeastRecentlyUsedDST(before_);
}
after_->start_sec = time_sec;
after_->end_sec = time_sec;
after_->offset_ms = offset_ms;
after_->last_used = ++dst_usage_counter_;
}
}
int DateCache::DaylightSavingsOffsetInMs(int64_t time_ms) {
int time_sec = (time_ms >= 0 && time_ms <= kMaxEpochTimeInMs)
? static_cast<int>(time_ms / 1000)
: static_cast<int>(EquivalentTime(time_ms) / 1000);
// Invalidate cache if the usage counter is close to overflow.
// Note that dst_usage_counter is incremented less than ten times
// in this function.
if (dst_usage_counter_ >= kMaxInt - 10) {
dst_usage_counter_ = 0;
for (int i = 0; i < kDSTSize; ++i) {
ClearSegment(&dst_[i]);
}
}
// Optimistic fast check.
if (before_->start_sec <= time_sec &&
time_sec <= before_->end_sec) {
// Cache hit.
before_->last_used = ++dst_usage_counter_;
return before_->offset_ms;
}
ProbeDST(time_sec);
DCHECK(InvalidSegment(before_) || before_->start_sec <= time_sec);
DCHECK(InvalidSegment(after_) || time_sec < after_->start_sec);
if (InvalidSegment(before_)) {
// Cache miss.
before_->start_sec = time_sec;
before_->end_sec = time_sec;
before_->offset_ms = GetDaylightSavingsOffsetFromOS(time_sec);
before_->last_used = ++dst_usage_counter_;
return before_->offset_ms;
}
if (time_sec <= before_->end_sec) {
// Cache hit.
before_->last_used = ++dst_usage_counter_;
return before_->offset_ms;
}
if (time_sec - kDefaultDSTDeltaInSec > before_->end_sec) {
// If the before_ segment ends too early, then just
// query for the offset of the time_sec
int offset_ms = GetDaylightSavingsOffsetFromOS(time_sec);
ExtendTheAfterSegment(time_sec, offset_ms);
// This swap helps the optimistic fast check in subsequent invocations.
DST* temp = before_;
before_ = after_;
after_ = temp;
return offset_ms;
}
// Now the time_sec is between
// before_->end_sec and before_->end_sec + default DST delta.
// Update the usage counter of before_ since it is going to be used.
before_->last_used = ++dst_usage_counter_;
// Check if after_ segment is invalid or starts too late.
// Note that start_sec of invalid segments is kMaxEpochTimeInSec.
int new_after_start_sec =
before_->end_sec < kMaxEpochTimeInSec - kDefaultDSTDeltaInSec
? before_->end_sec + kDefaultDSTDeltaInSec
: kMaxEpochTimeInSec;
if (new_after_start_sec <= after_->start_sec) {
int new_offset_ms = GetDaylightSavingsOffsetFromOS(new_after_start_sec);
ExtendTheAfterSegment(new_after_start_sec, new_offset_ms);
} else {
DCHECK(!InvalidSegment(after_));
// Update the usage counter of after_ since it is going to be used.
after_->last_used = ++dst_usage_counter_;
}
// Now the time_sec is between before_->end_sec and after_->start_sec.
// Only one daylight savings offset change can occur in this interval.
if (before_->offset_ms == after_->offset_ms) {
// Merge two segments if they have the same offset.
before_->end_sec = after_->end_sec;
ClearSegment(after_);
return before_->offset_ms;
}
// Binary search for daylight savings offset change point,
// but give up if we don't find it in five iterations.
for (int i = 4; i >= 0; --i) {
int delta = after_->start_sec - before_->end_sec;
int middle_sec = (i == 0) ? time_sec : before_->end_sec + delta / 2;
int offset_ms = GetDaylightSavingsOffsetFromOS(middle_sec);
if (before_->offset_ms == offset_ms) {
before_->end_sec = middle_sec;
if (time_sec <= before_->end_sec) {
return offset_ms;
}
} else {
DCHECK(after_->offset_ms == offset_ms);
after_->start_sec = middle_sec;
if (time_sec >= after_->start_sec) {
// This swap helps the optimistic fast check in subsequent invocations.
DST* temp = before_;
before_ = after_;
after_ = temp;
return offset_ms;
}
}
}
return 0;
}
void DateCache::ProbeDST(int time_sec) {
DST* before = nullptr;
DST* after = nullptr;
DCHECK(before_ != after_);
for (int i = 0; i < kDSTSize; ++i) {
if (dst_[i].start_sec <= time_sec) {
if (before == nullptr || before->start_sec < dst_[i].start_sec) {
before = &dst_[i];
}
} else if (time_sec < dst_[i].end_sec) {
if (after == nullptr || after->end_sec > dst_[i].end_sec) {
after = &dst_[i];
}
}
}
// If before or after segments were not found,
// then set them to any invalid segment.
if (before == nullptr) {
before = InvalidSegment(before_) ? before_ : LeastRecentlyUsedDST(after);
}
if (after == nullptr) {
after = InvalidSegment(after_) && before != after_
? after_ : LeastRecentlyUsedDST(before);
}
DCHECK_NOT_NULL(before);
DCHECK_NOT_NULL(after);
DCHECK(before != after);
DCHECK(InvalidSegment(before) || before->start_sec <= time_sec);
DCHECK(InvalidSegment(after) || time_sec < after->start_sec);
DCHECK(InvalidSegment(before) || InvalidSegment(after) ||
before->end_sec < after->start_sec);
before_ = before;
after_ = after;
}
DateCache::DST* DateCache::LeastRecentlyUsedDST(DST* skip) {
DST* result = nullptr;
for (int i = 0; i < kDSTSize; ++i) {
if (&dst_[i] == skip) continue;
if (result == nullptr || result->last_used > dst_[i].last_used) {
result = &dst_[i];
}
}
ClearSegment(result);
return result;
}
} // namespace internal
} // namespace v8
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