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author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-19 00:47:55 +0000 |
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committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-19 00:47:55 +0000 |
commit | 26a029d407be480d791972afb5975cf62c9360a6 (patch) | |
tree | f435a8308119effd964b339f76abb83a57c29483 /js/src/vm/DateTime.h | |
parent | Initial commit. (diff) | |
download | firefox-26a029d407be480d791972afb5975cf62c9360a6.tar.xz firefox-26a029d407be480d791972afb5975cf62c9360a6.zip |
Adding upstream version 124.0.1.upstream/124.0.1
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'js/src/vm/DateTime.h')
-rw-r--r-- | js/src/vm/DateTime.h | 387 |
1 files changed, 387 insertions, 0 deletions
diff --git a/js/src/vm/DateTime.h b/js/src/vm/DateTime.h new file mode 100644 index 0000000000..fd6d7ae078 --- /dev/null +++ b/js/src/vm/DateTime.h @@ -0,0 +1,387 @@ +/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- + * vim: set ts=8 sts=2 et sw=2 tw=80: + * This Source Code Form is subject to the terms of the Mozilla Public + * License, v. 2.0. If a copy of the MPL was not distributed with this + * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ + +#ifndef vm_DateTime_h +#define vm_DateTime_h + +#include "mozilla/UniquePtr.h" + +#include <stdint.h> + +#include "js/Utility.h" +#include "threading/ExclusiveData.h" + +#if JS_HAS_INTL_API +# include "mozilla/intl/ICU4CGlue.h" +# include "mozilla/intl/TimeZone.h" +#endif + +namespace JS { +class Realm; +} + +namespace js { + +/* Constants defined by ES5 15.9.1.10. */ +constexpr double HoursPerDay = 24; +constexpr double MinutesPerHour = 60; +constexpr double SecondsPerMinute = 60; +constexpr double msPerSecond = 1000; +constexpr double msPerMinute = msPerSecond * SecondsPerMinute; +constexpr double msPerHour = msPerMinute * MinutesPerHour; + +/* ES5 15.9.1.2. */ +constexpr double msPerDay = msPerHour * HoursPerDay; + +/* + * Additional quantities not mentioned in the spec. Be careful using these! + * They aren't doubles and aren't defined in terms of all the other constants. + * If you need constants that trigger floating point semantics, you'll have to + * manually cast to get it. + */ +constexpr unsigned SecondsPerHour = 60 * 60; +constexpr unsigned SecondsPerDay = SecondsPerHour * 24; + +constexpr double StartOfTime = -8.64e15; +constexpr double EndOfTime = 8.64e15; + +extern bool InitDateTimeState(); + +extern void FinishDateTimeState(); + +enum class ResetTimeZoneMode : bool { + DontResetIfOffsetUnchanged, + ResetEvenIfOffsetUnchanged, +}; + +/** + * Engine-internal variant of JS::ResetTimeZone with an additional flag to + * control whether to forcibly reset all time zone data (this is the default + * behavior when calling JS::ResetTimeZone) or to try to reuse the previous + * time zone data. + */ +extern void ResetTimeZoneInternal(ResetTimeZoneMode mode); + +/** + * Stores date/time information, particularly concerning the current local + * time zone, and implements a small cache for daylight saving time offset + * computation. + * + * The basic idea is premised upon this fact: the DST offset never changes more + * than once in any thirty-day period. If we know the offset at t_0 is o_0, + * the offset at [t_1, t_2] is also o_0, where t_1 + 3_0 days == t_2, + * t_1 <= t_0, and t0 <= t2. (In other words, t_0 is always somewhere within a + * thirty-day range where the DST offset is constant: DST changes never occur + * more than once in any thirty-day period.) Therefore, if we intelligently + * retain knowledge of the offset for a range of dates (which may vary over + * time), and if requests are usually for dates within that range, we can often + * provide a response without repeated offset calculation. + * + * Our caching strategy is as follows: on the first request at date t_0 compute + * the requested offset o_0. Save { start: t_0, end: t_0, offset: o_0 } as the + * cache's state. Subsequent requests within that range are straightforwardly + * handled. If a request for t_i is far outside the range (more than thirty + * days), compute o_i = dstOffset(t_i) and save { start: t_i, end: t_i, + * offset: t_i }. Otherwise attempt to *overextend* the range to either + * [start - 30d, end] or [start, end + 30d] as appropriate to encompass + * t_i. If the offset o_i30 is the same as the cached offset, extend the + * range. Otherwise the over-guess crossed a DST change -- compute + * o_i = dstOffset(t_i) and either extend the original range (if o_i == offset) + * or start a new one beneath/above the current one with o_i30 as the offset. + * + * This cache strategy results in 0 to 2 DST offset computations. The naive + * always-compute strategy is 1 computation, and since cache maintenance is a + * handful of integer arithmetic instructions the speed difference between + * always-1 and 1-with-cache is negligible. Caching loses if two computations + * happen: when the date is within 30 days of the cached range and when that + * 30-day range crosses a DST change. This is relatively uncommon. Further, + * instances of such are often dominated by in-range hits, so caching is an + * overall slight win. + * + * Why 30 days? For correctness the duration must be smaller than any possible + * duration between DST changes. Past that, note that 1) a large duration + * increases the likelihood of crossing a DST change while reducing the number + * of cache misses, and 2) a small duration decreases the size of the cached + * range while producing more misses. Using a month as the interval change is + * a balance between these two that tries to optimize for the calendar month at + * a time that a site might display. (One could imagine an adaptive duration + * that accommodates near-DST-change dates better; we don't believe the + * potential win from better caching offsets the loss from extra complexity.) + */ +class DateTimeInfo { + public: + // For realms that force the UTC time zone (for fingerprinting protection) a + // separate DateTimeInfo instance is used that is always in the UTC time zone. + enum class ForceUTC { No, Yes }; + + private: + static ExclusiveData<DateTimeInfo>* instance; + static ExclusiveData<DateTimeInfo>* instanceUTC; + + friend class ExclusiveData<DateTimeInfo>; + + friend bool InitDateTimeState(); + friend void FinishDateTimeState(); + + explicit DateTimeInfo(bool forceUTC); + ~DateTimeInfo(); + + static auto acquireLockWithValidTimeZone(ForceUTC forceUTC) { + auto guard = + forceUTC == ForceUTC::Yes ? instanceUTC->lock() : instance->lock(); + if (guard->timeZoneStatus_ != TimeZoneStatus::Valid) { + guard->updateTimeZone(); + } + return guard; + } + + public: + static ForceUTC forceUTC(JS::Realm* realm); + + // The spec implicitly assumes DST and time zone adjustment information + // never change in the course of a function -- sometimes even across + // reentrancy. So make critical sections as narrow as possible. + + /** + * Get the DST offset in milliseconds at a UTC time. This is usually + * either 0 or |msPerSecond * SecondsPerHour|, but at least one exotic time + * zone (Lord Howe Island, Australia) has a fractional-hour offset, just to + * keep things interesting. + */ + static int32_t getDSTOffsetMilliseconds(ForceUTC forceUTC, + int64_t utcMilliseconds) { + auto guard = acquireLockWithValidTimeZone(forceUTC); + return guard->internalGetDSTOffsetMilliseconds(utcMilliseconds); + } + + /** + * The offset in seconds from the current UTC time to the current local + * standard time (i.e. not including any offset due to DST) as computed by the + * operating system. + */ + static int32_t utcToLocalStandardOffsetSeconds(ForceUTC forceUTC) { + auto guard = acquireLockWithValidTimeZone(forceUTC); + return guard->utcToLocalStandardOffsetSeconds_; + } + +#if JS_HAS_INTL_API + enum class TimeZoneOffset { UTC, Local }; + + /** + * Return the time zone offset, including DST, in milliseconds at the + * given time. The input time can be either at UTC or at local time. + */ + static int32_t getOffsetMilliseconds(ForceUTC forceUTC, int64_t milliseconds, + TimeZoneOffset offset) { + auto guard = acquireLockWithValidTimeZone(forceUTC); + return guard->internalGetOffsetMilliseconds(milliseconds, offset); + } + + /** + * Copy the display name for the current time zone at the given time, + * localized for the specified locale, into the supplied buffer. If the + * buffer is too small, an empty string is stored. The stored display name + * is null-terminated in any case. + */ + static bool timeZoneDisplayName(ForceUTC forceUTC, char16_t* buf, + size_t buflen, int64_t utcMilliseconds, + const char* locale) { + auto guard = acquireLockWithValidTimeZone(forceUTC); + return guard->internalTimeZoneDisplayName(buf, buflen, utcMilliseconds, + locale); + } + + /** + * Copy the identifier for the current time zone to the provided resizable + * buffer. + */ + template <typename B> + static mozilla::intl::ICUResult timeZoneId(ForceUTC forceUTC, B& buffer) { + auto guard = acquireLockWithValidTimeZone(forceUTC); + return guard->timeZone()->GetId(buffer); + } + + /** + * A number indicating the raw offset from GMT in milliseconds. + */ + static mozilla::Result<int32_t, mozilla::intl::ICUError> getRawOffsetMs( + ForceUTC forceUTC) { + auto guard = acquireLockWithValidTimeZone(forceUTC); + return guard->timeZone()->GetRawOffsetMs(); + } +#else + /** + * Return the local time zone adjustment (ES2019 20.3.1.7) as computed by + * the operating system. + */ + static int32_t localTZA(ForceUTC forceUTC) { + return utcToLocalStandardOffsetSeconds(forceUTC) * msPerSecond; + } +#endif /* JS_HAS_INTL_API */ + + private: + // The method below should only be called via js::ResetTimeZoneInternal(). + friend void js::ResetTimeZoneInternal(ResetTimeZoneMode); + + static void resetTimeZone(ResetTimeZoneMode mode) { + { + auto guard = instance->lock(); + guard->internalResetTimeZone(mode); + } + { + // Only needed to initialize the default state and any later call will + // perform an unnecessary reset. + auto guard = instanceUTC->lock(); + guard->internalResetTimeZone(mode); + } + } + + struct RangeCache { + // Start and end offsets in seconds describing the current and the + // last cached range. + int64_t startSeconds, endSeconds; + int64_t oldStartSeconds, oldEndSeconds; + + // The current and the last cached offset in milliseconds. + int32_t offsetMilliseconds; + int32_t oldOffsetMilliseconds; + + void reset(); + + void sanityCheck(); + }; + + bool forceUTC_; + + enum class TimeZoneStatus : uint8_t { Valid, NeedsUpdate, UpdateIfChanged }; + + TimeZoneStatus timeZoneStatus_; + + /** + * The offset in seconds from the current UTC time to the current local + * standard time (i.e. not including any offset due to DST) as computed by the + * operating system. + * + * Cached because retrieving this dynamically is Slow, and a certain venerable + * benchmark which shall not be named depends on it being fast. + * + * SpiderMonkey occasionally and arbitrarily updates this value from the + * system time zone to attempt to keep this reasonably up-to-date. If + * temporary inaccuracy can't be tolerated, JSAPI clients may call + * JS::ResetTimeZone to forcibly sync this with the system time zone. + * + * In most cases this value is consistent with the raw time zone offset as + * returned by the ICU default time zone (`icu::TimeZone::getRawOffset()`), + * but it is possible to create cases where the operating system default time + * zone differs from the ICU default time zone. For example ICU doesn't + * support the full range of TZ environment variable settings, which can + * result in <ctime> returning a different time zone than what's returned by + * ICU. One example is "TZ=WGT3WGST,M3.5.0/-2,M10.5.0/-1", where <ctime> + * returns -3 hours as the local offset, but ICU flat out rejects the TZ value + * and instead infers the default time zone via "/etc/localtime" (on Unix). + * This offset can also differ from ICU when the operating system and ICU use + * different tzdata versions and the time zone rules of the current system + * time zone have changed. Or, on Windows, when the Windows default time zone + * can't be mapped to a IANA time zone, see for example + * <https://unicode-org.atlassian.net/browse/ICU-13845>. + * + * When ICU is exclusively used for time zone computations, that means when + * |JS_HAS_INTL_API| is true, this field is only used to detect system default + * time zone changes. It must not be used to convert between local and UTC + * time, because, as outlined above, this could lead to different results when + * compared to ICU. + */ + int32_t utcToLocalStandardOffsetSeconds_; + + RangeCache dstRange_; // UTC-based ranges + +#if JS_HAS_INTL_API + // Use the full date-time range when we can use mozilla::intl::TimeZone. + static constexpr int64_t MinTimeT = + static_cast<int64_t>(StartOfTime / msPerSecond); + static constexpr int64_t MaxTimeT = + static_cast<int64_t>(EndOfTime / msPerSecond); + + RangeCache utcRange_; // localtime-based ranges + RangeCache localRange_; // UTC-based ranges + + /** + * The current time zone. Lazily constructed to avoid potential I/O access + * when initializing this class. + */ + mozilla::UniquePtr<mozilla::intl::TimeZone> timeZone_; + + /** + * Cached names of the standard and daylight savings display names of the + * current time zone for the default locale. + */ + JS::UniqueChars locale_; + JS::UniqueTwoByteChars standardName_; + JS::UniqueTwoByteChars daylightSavingsName_; +#else + // Restrict the data-time range to the minimum required time_t range as + // specified in POSIX. Most operating systems support 64-bit time_t + // values, but we currently still have some configurations which use + // 32-bit time_t, e.g. the ARM simulator on 32-bit Linux (bug 1406993). + // Bug 1406992 explores to use 64-bit time_t when supported by the + // underlying operating system. + static constexpr int64_t MinTimeT = 0; /* time_t 01/01/1970 */ + static constexpr int64_t MaxTimeT = 2145830400; /* time_t 12/31/2037 */ +#endif /* JS_HAS_INTL_API */ + + static constexpr int64_t RangeExpansionAmount = 30 * SecondsPerDay; + + void internalResetTimeZone(ResetTimeZoneMode mode); + + void updateTimeZone(); + + void internalResyncICUDefaultTimeZone(); + + int64_t toClampedSeconds(int64_t milliseconds); + + using ComputeFn = int32_t (DateTimeInfo::*)(int64_t); + + /** + * Get or compute an offset value for the requested seconds value. + */ + int32_t getOrComputeValue(RangeCache& range, int64_t seconds, + ComputeFn compute); + + /** + * Compute the DST offset at the given UTC time in seconds from the epoch. + * (getDSTOffsetMilliseconds attempts to return a cached value from the + * dstRange_ member, but in case of a cache miss it calls this method.) + */ + int32_t computeDSTOffsetMilliseconds(int64_t utcSeconds); + + int32_t internalGetDSTOffsetMilliseconds(int64_t utcMilliseconds); + +#if JS_HAS_INTL_API + /** + * Compute the UTC offset in milliseconds for the given local time. Called + * by internalGetOffsetMilliseconds on a cache miss. + */ + int32_t computeUTCOffsetMilliseconds(int64_t localSeconds); + + /** + * Compute the local time offset in milliseconds for the given UTC time. + * Called by internalGetOffsetMilliseconds on a cache miss. + */ + int32_t computeLocalOffsetMilliseconds(int64_t utcSeconds); + + int32_t internalGetOffsetMilliseconds(int64_t milliseconds, + TimeZoneOffset offset); + + bool internalTimeZoneDisplayName(char16_t* buf, size_t buflen, + int64_t utcMilliseconds, const char* locale); + + mozilla::intl::TimeZone* timeZone(); +#endif /* JS_HAS_INTL_API */ +}; + +} /* namespace js */ + +#endif /* vm_DateTime_h */ |