ladybird/Libraries/LibJS/Runtime/Date.cpp
Timothy Flynn c6fccc04e1
Some checks are pending
CI / Lagom (false, FUZZ, ubuntu-24.04, Linux, Clang) (push) Waiting to run
CI / Lagom (false, NO_FUZZ, macos-15, macOS, Clang) (push) Waiting to run
CI / Lagom (false, NO_FUZZ, ubuntu-24.04, Linux, GNU) (push) Waiting to run
CI / Lagom (true, NO_FUZZ, ubuntu-24.04, Linux, Clang) (push) Waiting to run
Package the js repl as a binary artifact / build-and-package (macos-14, macOS, macOS-universal2) (push) Waiting to run
Package the js repl as a binary artifact / build-and-package (ubuntu-24.04, Linux, Linux-x86_64) (push) Waiting to run
Run test262 and test-wasm / run_and_update_results (push) Waiting to run
Lint Code / lint (push) Waiting to run
Push notes / build (push) Waiting to run
LibJS: Use Temporal's ISO8601 parser to parse UTC offset strings
We now have the Temporal facilities to implement the Date AOs which
parse UTC offset strings using the ISO8601 parser. This patch updates
those AOs and their callers in accordance with the Temporal spec.
2024-11-21 19:24:25 -05:00

754 lines
31 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/*
* Copyright (c) 2020-2023, Linus Groh <linusg@serenityos.org>
* Copyright (c) 2022-2024, Tim Flynn <trflynn89@ladybird.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/NumericLimits.h>
#include <AK/StringBuilder.h>
#include <AK/Time.h>
#include <LibJS/Runtime/AbstractOperations.h>
#include <LibJS/Runtime/Date.h>
#include <LibJS/Runtime/GlobalObject.h>
#include <LibJS/Runtime/Intl/AbstractOperations.h>
#include <LibJS/Runtime/Temporal/ISO8601.h>
#include <LibJS/Runtime/Temporal/TimeZone.h>
#include <time.h>
namespace JS {
GC_DEFINE_ALLOCATOR(Date);
static Crypto::SignedBigInteger const s_one_billion_bigint { 1'000'000'000 };
static Crypto::SignedBigInteger const s_one_million_bigint { 1'000'000 };
static Crypto::SignedBigInteger const s_one_thousand_bigint { 1'000 };
Crypto::SignedBigInteger const ns_per_day_bigint { static_cast<i64>(ns_per_day) };
GC::Ref<Date> Date::create(Realm& realm, double date_value)
{
return realm.create<Date>(date_value, realm.intrinsics().date_prototype());
}
Date::Date(double date_value, Object& prototype)
: Object(ConstructWithPrototypeTag::Tag, prototype)
, m_date_value(date_value)
{
}
Date::~Date() = default;
ErrorOr<String> Date::iso_date_string() const
{
int year = year_from_time(m_date_value);
StringBuilder builder;
if (year < 0)
builder.appendff("-{:06}", -year);
else if (year > 9999)
builder.appendff("+{:06}", year);
else
builder.appendff("{:04}", year);
builder.append('-');
builder.appendff("{:02}", month_from_time(m_date_value) + 1);
builder.append('-');
builder.appendff("{:02}", date_from_time(m_date_value));
builder.append('T');
builder.appendff("{:02}", hour_from_time(m_date_value));
builder.append(':');
builder.appendff("{:02}", min_from_time(m_date_value));
builder.append(':');
builder.appendff("{:02}", sec_from_time(m_date_value));
builder.append('.');
builder.appendff("{:03}", ms_from_time(m_date_value));
builder.append('Z');
return builder.to_string();
}
// 21.4.1.3 Day ( t ), https://tc39.es/ecma262/#sec-day
double day(double time_value)
{
// 1. Return 𝔽(floor((t / msPerDay))).
return floor(time_value / ms_per_day);
}
// 21.4.1.4 TimeWithinDay ( t ), https://tc39.es/ecma262/#sec-timewithinday
double time_within_day(double time)
{
// 1. Return 𝔽((t) modulo (msPerDay)).
return modulo(time, ms_per_day);
}
// 21.4.1.5 DaysInYear ( y ), https://tc39.es/ecma262/#sec-daysinyear
u16 days_in_year(i32 y)
{
// 1. Let ry be (y).
auto ry = static_cast<double>(y);
// 2. If (ry modulo 400) = 0, return 366𝔽.
if (modulo(ry, 400.0) == 0)
return 366;
// 3. If (ry modulo 100) = 0, return 365𝔽.
if (modulo(ry, 100.0) == 0)
return 365;
// 4. If (ry modulo 4) = 0, return 366𝔽.
if (modulo(ry, 4.0) == 0)
return 366;
// 5. Return 365𝔽.
return 365;
}
// 21.4.1.6 DayFromYear ( y ), https://tc39.es/ecma262/#sec-dayfromyear
double day_from_year(i32 y)
{
// 1. Let ry be (y).
auto ry = static_cast<double>(y);
// 2. NOTE: In the following steps, each _numYearsN_ is the number of years divisible by N that occur between the
// epoch and the start of year y. (The number is negative if y is before the epoch.)
// 3. Let numYears1 be (ry - 1970).
auto num_years_1 = ry - 1970;
// 4. Let numYears4 be floor((ry - 1969) / 4).
auto num_years_4 = floor((ry - 1969) / 4.0);
// 5. Let numYears100 be floor((ry - 1901) / 100).
auto num_years_100 = floor((ry - 1901) / 100.0);
// 6. Let numYears400 be floor((ry - 1601) / 400).
auto num_years_400 = floor((ry - 1601) / 400.0);
// 7. Return 𝔽(365 × numYears1 + numYears4 - numYears100 + numYears400).
return 365.0 * num_years_1 + num_years_4 - num_years_100 + num_years_400;
}
// 21.4.1.7 TimeFromYear ( y ), https://tc39.es/ecma262/#sec-timefromyear
double time_from_year(i32 y)
{
// 1. Return msPerDay × DayFromYear(y).
return ms_per_day * day_from_year(y);
}
// 21.4.1.8 YearFromTime ( t ), https://tc39.es/ecma262/#sec-yearfromtime
i32 year_from_time(double t)
{
// 1. Return the largest integral Number y (closest to +∞) such that TimeFromYear(y) ≤ t.
if (!Value(t).is_finite_number())
return NumericLimits<i32>::max();
// Approximation using average number of milliseconds per year. We might have to adjust this guess afterwards.
auto year = static_cast<i32>(floor(t / (365.2425 * ms_per_day) + 1970));
auto year_t = time_from_year(year);
if (year_t > t)
year--;
else if (year_t + days_in_year(year) * ms_per_day <= t)
year++;
return year;
}
// 21.4.1.9 DayWithinYear ( t ), https://tc39.es/ecma262/#sec-daywithinyear
u16 day_within_year(double t)
{
if (!Value(t).is_finite_number())
return 0;
// 1. Return Day(t) - DayFromYear(YearFromTime(t)).
return static_cast<u16>(day(t) - day_from_year(year_from_time(t)));
}
// 21.4.1.10 InLeapYear ( t ), https://tc39.es/ecma262/#sec-inleapyear
bool in_leap_year(double t)
{
// 1. If DaysInYear(YearFromTime(t)) is 366𝔽, return 1𝔽; else return +0𝔽.
return days_in_year(year_from_time(t)) == 366;
}
// 21.4.1.11 MonthFromTime ( t ), https://tc39.es/ecma262/#sec-monthfromtime
u8 month_from_time(double t)
{
// 1. Let inLeapYear be InLeapYear(t).
auto in_leap_year = static_cast<unsigned>(JS::in_leap_year(t));
// 2. Let dayWithinYear be DayWithinYear(t).
auto day_within_year = JS::day_within_year(t);
// 3. If dayWithinYear < 31𝔽, return +0𝔽.
if (day_within_year < 31)
return 0;
// 4. If dayWithinYear < 59𝔽 + inLeapYear, return 1𝔽.
if (day_within_year < (59 + in_leap_year))
return 1;
// 5. If dayWithinYear < 90𝔽 + inLeapYear, return 2𝔽.
if (day_within_year < (90 + in_leap_year))
return 2;
// 6. If dayWithinYear < 120𝔽 + inLeapYear, return 3𝔽.
if (day_within_year < (120 + in_leap_year))
return 3;
// 7. If dayWithinYear < 151𝔽 + inLeapYear, return 4𝔽.
if (day_within_year < (151 + in_leap_year))
return 4;
// 8. If dayWithinYear < 181𝔽 + inLeapYear, return 5𝔽.
if (day_within_year < (181 + in_leap_year))
return 5;
// 9. If dayWithinYear < 212𝔽 + inLeapYear, return 6𝔽.
if (day_within_year < (212 + in_leap_year))
return 6;
// 10. If dayWithinYear < 243𝔽 + inLeapYear, return 7𝔽.
if (day_within_year < (243 + in_leap_year))
return 7;
// 11. If dayWithinYear < 273𝔽 + inLeapYear, return 8𝔽.
if (day_within_year < (273 + in_leap_year))
return 8;
// 12. If dayWithinYear < 304𝔽 + inLeapYear, return 9𝔽.
if (day_within_year < (304 + in_leap_year))
return 9;
// 13. If dayWithinYear < 334𝔽 + inLeapYear, return 10𝔽.
if (day_within_year < (334 + in_leap_year))
return 10;
// 14. Assert: dayWithinYear < 365𝔽 + inLeapYear.
VERIFY(day_within_year < (365 + in_leap_year));
// 15. Return 11𝔽.
return 11;
}
// 21.4.1.12 DateFromTime ( t ), https://tc39.es/ecma262/#sec-datefromtime
u8 date_from_time(double t)
{
// 1. Let inLeapYear be InLeapYear(t).
auto in_leap_year = static_cast<unsigned>(JS::in_leap_year(t));
// 2. Let dayWithinYear be DayWithinYear(t).
auto day_within_year = JS::day_within_year(t);
// 3. Let month be MonthFromTime(t).
auto month = month_from_time(t);
// 4. If month is +0𝔽, return dayWithinYear + 1𝔽.
if (month == 0)
return day_within_year + 1;
// 5. If month is 1𝔽, return dayWithinYear - 30𝔽.
if (month == 1)
return day_within_year - 30;
// 6. If month is 2𝔽, return dayWithinYear - 58𝔽 - inLeapYear.
if (month == 2)
return day_within_year - 58 - in_leap_year;
// 7. If month is 3𝔽, return dayWithinYear - 89𝔽 - inLeapYear.
if (month == 3)
return day_within_year - 89 - in_leap_year;
// 8. If month is 4𝔽, return dayWithinYear - 119𝔽 - inLeapYear.
if (month == 4)
return day_within_year - 119 - in_leap_year;
// 9. If month is 5𝔽, return dayWithinYear - 150𝔽 - inLeapYear.
if (month == 5)
return day_within_year - 150 - in_leap_year;
// 10. If month is 6𝔽, return dayWithinYear - 180𝔽 - inLeapYear.
if (month == 6)
return day_within_year - 180 - in_leap_year;
// 11. If month is 7𝔽, return dayWithinYear - 211𝔽 - inLeapYear.
if (month == 7)
return day_within_year - 211 - in_leap_year;
// 12. If month is 8𝔽, return dayWithinYear - 242𝔽 - inLeapYear.
if (month == 8)
return day_within_year - 242 - in_leap_year;
// 13. If month is 9𝔽, return dayWithinYear - 272𝔽 - inLeapYear.
if (month == 9)
return day_within_year - 272 - in_leap_year;
// 14. If month is 10𝔽, return dayWithinYear - 303𝔽 - inLeapYear.
if (month == 10)
return day_within_year - 303 - in_leap_year;
// 15. Assert: month is 11𝔽.
VERIFY(month == 11);
// 16. Return dayWithinYear - 333𝔽 - inLeapYear.
return day_within_year - 333 - in_leap_year;
}
// 21.4.1.13 WeekDay ( t ), https://tc39.es/ecma262/#sec-weekday
u8 week_day(double t)
{
if (!Value(t).is_finite_number())
return 0;
// 1. Return 𝔽((Day(t) + 4𝔽) modulo 7).
return static_cast<u8>(modulo(day(t) + 4, 7));
}
// 21.4.1.14 HourFromTime ( t ), https://tc39.es/ecma262/#sec-hourfromtime
u8 hour_from_time(double t)
{
if (!Value(t).is_finite_number())
return 0;
// 1. Return 𝔽(floor((t / msPerHour)) modulo HoursPerDay).
return static_cast<u8>(modulo(floor(t / ms_per_hour), hours_per_day));
}
// 21.4.1.15 MinFromTime ( t ), https://tc39.es/ecma262/#sec-minfromtime
u8 min_from_time(double t)
{
if (!Value(t).is_finite_number())
return 0;
// 1. Return 𝔽(floor((t / msPerMinute)) modulo MinutesPerHour).
return static_cast<u8>(modulo(floor(t / ms_per_minute), minutes_per_hour));
}
// 21.4.1.16 SecFromTime ( t ), https://tc39.es/ecma262/#sec-secfromtime
u8 sec_from_time(double t)
{
if (!Value(t).is_finite_number())
return 0;
// 1. Return 𝔽(floor((t / msPerSecond)) modulo SecondsPerMinute).
return static_cast<u8>(modulo(floor(t / ms_per_second), seconds_per_minute));
}
// 21.4.1.17 msFromTime ( t ), https://tc39.es/ecma262/#sec-msfromtime
u16 ms_from_time(double t)
{
if (!Value(t).is_finite_number())
return 0;
// 1. Return 𝔽((t) modulo (msPerSecond)).
return static_cast<u16>(modulo(t, ms_per_second));
}
// 21.4.1.18 GetUTCEpochNanoseconds ( year, month, day, hour, minute, second, millisecond, microsecond, nanosecond ), https://tc39.es/ecma262/#sec-getutcepochnanoseconds
Crypto::SignedBigInteger get_utc_epoch_nanoseconds(i32 year, u8 month, u8 day, u8 hour, u8 minute, u8 second, u16 millisecond, u16 microsecond, u16 nanosecond)
{
// 1. Let date be MakeDay(𝔽(year), 𝔽(month - 1), 𝔽(day)).
auto date = make_day(year, month - 1, day);
// 2. Let time be MakeTime(𝔽(hour), 𝔽(minute), 𝔽(second), 𝔽(millisecond)).
auto time = make_time(hour, minute, second, millisecond);
// 3. Let ms be MakeDate(date, time).
auto ms = make_date(date, time);
// 4. Assert: ms is an integral Number.
VERIFY(ms == trunc(ms));
// 5. Return ((ms) × 10^6 + microsecond × 10^3 + nanosecond).
auto result = Crypto::SignedBigInteger { ms }.multiplied_by(s_one_million_bigint);
result = result.plus(Crypto::SignedBigInteger { static_cast<i32>(microsecond) }.multiplied_by(s_one_thousand_bigint));
result = result.plus(Crypto::SignedBigInteger { static_cast<i32>(nanosecond) });
return result;
}
static i64 clip_bigint_to_sane_time(Crypto::SignedBigInteger const& value)
{
static Crypto::SignedBigInteger const min_bigint { NumericLimits<i64>::min() };
static Crypto::SignedBigInteger const max_bigint { NumericLimits<i64>::max() };
// The provided epoch (nano)seconds value is potentially out of range for AK::Duration and subsequently
// get_time_zone_offset(). We can safely assume that the TZDB has no useful information that far
// into the past and future anyway, so clamp it to the i64 range.
if (value < min_bigint)
return NumericLimits<i64>::min();
if (value > max_bigint)
return NumericLimits<i64>::max();
// FIXME: Can we do this without string conversion?
return value.to_base_deprecated(10).to_number<i64>().value();
}
static i64 clip_double_to_sane_time(double value)
{
static constexpr auto min_double = static_cast<double>(NumericLimits<i64>::min());
static constexpr auto max_double = static_cast<double>(NumericLimits<i64>::max());
// The provided epoch millseconds value is potentially out of range for AK::Duration and subsequently
// get_time_zone_offset(). We can safely assume that the TZDB has no useful information that far
// into the past and future anyway, so clamp it to the i64 range.
if (value < min_double)
return NumericLimits<i64>::min();
if (value > max_double)
return NumericLimits<i64>::max();
return static_cast<i64>(value);
}
// 21.4.1.20 GetNamedTimeZoneEpochNanoseconds ( timeZoneIdentifier, year, month, day, hour, minute, second, millisecond, microsecond, nanosecond ), https://tc39.es/ecma262/#sec-getnamedtimezoneepochnanoseconds
Vector<Crypto::SignedBigInteger> get_named_time_zone_epoch_nanoseconds(StringView time_zone_identifier, i32 year, u8 month, u8 day, u8 hour, u8 minute, u8 second, u16 millisecond, u16 microsecond, u16 nanosecond)
{
auto local_nanoseconds = get_utc_epoch_nanoseconds(year, month, day, hour, minute, second, millisecond, microsecond, nanosecond);
auto local_time = UnixDateTime::from_nanoseconds_since_epoch(clip_bigint_to_sane_time(local_nanoseconds));
// FIXME: LibUnicode does not behave exactly as the spec expects. It does not consider repeated or skipped time points.
auto offset = Unicode::time_zone_offset(time_zone_identifier, local_time);
// Can only fail if the time zone identifier is invalid, which cannot be the case here.
VERIFY(offset.has_value());
return { local_nanoseconds.minus(Crypto::SignedBigInteger { offset->offset.to_nanoseconds() }) };
}
// 21.4.1.21 GetNamedTimeZoneOffsetNanoseconds ( timeZoneIdentifier, epochNanoseconds ), https://tc39.es/ecma262/#sec-getnamedtimezoneoffsetnanoseconds
Unicode::TimeZoneOffset get_named_time_zone_offset_nanoseconds(StringView time_zone_identifier, Crypto::SignedBigInteger const& epoch_nanoseconds)
{
// Since UnixDateTime::from_seconds_since_epoch() and UnixDateTime::from_nanoseconds_since_epoch() both take an i64, converting to
// seconds first gives us a greater range. The TZDB doesn't have sub-second offsets.
auto seconds = epoch_nanoseconds.divided_by(s_one_billion_bigint).quotient;
auto time = UnixDateTime::from_seconds_since_epoch(clip_bigint_to_sane_time(seconds));
auto offset = Unicode::time_zone_offset(time_zone_identifier, time);
VERIFY(offset.has_value());
return offset.release_value();
}
// 21.4.1.21 GetNamedTimeZoneOffsetNanoseconds ( timeZoneIdentifier, epochNanoseconds ), https://tc39.es/ecma262/#sec-getnamedtimezoneoffsetnanoseconds
// OPTIMIZATION: This overload is provided to allow callers to avoid BigInt construction if they do not need infinitely precise nanosecond resolution.
Unicode::TimeZoneOffset get_named_time_zone_offset_milliseconds(StringView time_zone_identifier, double epoch_milliseconds)
{
auto seconds = epoch_milliseconds / 1000.0;
auto time = UnixDateTime::from_seconds_since_epoch(clip_double_to_sane_time(seconds));
auto offset = Unicode::time_zone_offset(time_zone_identifier, time);
VERIFY(offset.has_value());
return offset.release_value();
}
static Optional<String> cached_system_time_zone_identifier;
// 21.4.1.24 SystemTimeZoneIdentifier ( ), https://tc39.es/ecma262/#sec-systemtimezoneidentifier
String system_time_zone_identifier()
{
// OPTIMIZATION: We cache the system time zone to avoid the expensive lookups below.
if (cached_system_time_zone_identifier.has_value())
return *cached_system_time_zone_identifier;
// 1. If the implementation only supports the UTC time zone, return "UTC".
// 2. Let systemTimeZoneString be the String representing the host environment's current time zone, either a primary
// time zone identifier or an offset time zone identifier.
auto system_time_zone_string = Unicode::current_time_zone();
if (!is_offset_time_zone_identifier(system_time_zone_string)) {
auto time_zone_identifier = Intl::get_available_named_time_zone_identifier(system_time_zone_string);
if (!time_zone_identifier.has_value())
return "UTC"_string;
system_time_zone_string = time_zone_identifier->primary_identifier;
}
// 3. Return systemTimeZoneString.
cached_system_time_zone_identifier = move(system_time_zone_string);
return *cached_system_time_zone_identifier;
}
void clear_system_time_zone_cache()
{
cached_system_time_zone_identifier.clear();
}
// 21.4.1.25 LocalTime ( t ), https://tc39.es/ecma262/#sec-localtime
// 14.5.6 LocalTime ( t ), https://tc39.es/proposal-temporal/#sec-localtime
double local_time(double time)
{
// 1. Let systemTimeZoneIdentifier be SystemTimeZoneIdentifier().
auto system_time_zone_identifier = JS::system_time_zone_identifier();
// 2. Let parseResult be ! ParseTimeZoneIdentifier(systemTimeZoneIdentifier).
auto parse_result = Temporal::parse_time_zone_identifier(system_time_zone_identifier);
double offset_nanoseconds { 0 };
// 3. If parseResult.[[OffsetMinutes]] is not EMPTY, then
if (parse_result.offset_minutes.has_value()) {
// a. Let offsetNs be parseResult.[[OffsetMinutes]] × (60 × 10**9).
offset_nanoseconds = static_cast<double>(*parse_result.offset_minutes) * 60'000'000'000;
}
// 4. Else,
else {
// a. Let offsetNs be GetNamedTimeZoneOffsetNanoseconds(systemTimeZoneIdentifier, ((t) × 10^6)).
auto offset = get_named_time_zone_offset_milliseconds(system_time_zone_identifier, time);
offset_nanoseconds = static_cast<double>(offset.offset.to_nanoseconds());
}
// 5. Let offsetMs be truncate(offsetNs / 10^6).
auto offset_milliseconds = trunc(offset_nanoseconds / 1e6);
// 6. Return t + 𝔽(offsetMs).
return time + offset_milliseconds;
}
// 21.4.1.26 UTC ( t ), https://tc39.es/ecma262/#sec-utc-t
// 14.5.7 UTC ( t ), https://tc39.es/proposal-temporal/#sec-localtime
// FIXME: Update the rest of this AO for Temporal once we have the required Temporal objects.
double utc_time(double time)
{
// 1. Let systemTimeZoneIdentifier be SystemTimeZoneIdentifier().
auto system_time_zone_identifier = JS::system_time_zone_identifier();
// 2. Let parseResult be ! ParseTimeZoneIdentifier(systemTimeZoneIdentifier).
auto parse_result = Temporal::parse_time_zone_identifier(system_time_zone_identifier);
double offset_nanoseconds { 0 };
// 3. If parseResult.[[OffsetMinutes]] is not EMPTY, then
if (parse_result.offset_minutes.has_value()) {
// a. Let offsetNs be parseResult.[[OffsetMinutes]] × (60 × 10**9).
offset_nanoseconds = static_cast<double>(*parse_result.offset_minutes) * 60'000'000'000;
}
// 4. Else,
else {
// a. Let possibleInstants be GetNamedTimeZoneEpochNanoseconds(systemTimeZoneIdentifier, (YearFromTime(t)), (MonthFromTime(t)) + 1, (DateFromTime(t)), (HourFromTime(t)), (MinFromTime(t)), (SecFromTime(t)), (msFromTime(t)), 0, 0).
auto possible_instants = get_named_time_zone_epoch_nanoseconds(system_time_zone_identifier, year_from_time(time), month_from_time(time) + 1, date_from_time(time), hour_from_time(time), min_from_time(time), sec_from_time(time), ms_from_time(time), 0, 0);
// b. NOTE: The following steps ensure that when t represents local time repeating multiple times at a negative time zone transition (e.g. when the daylight saving time ends or the time zone offset is decreased due to a time zone rule change) or skipped local time at a positive time zone transition (e.g. when the daylight saving time starts or the time zone offset is increased due to a time zone rule change), t is interpreted using the time zone offset before the transition.
Crypto::SignedBigInteger disambiguated_instant;
// c. If possibleInstants is not empty, then
if (!possible_instants.is_empty()) {
// i. Let disambiguatedInstant be possibleInstants[0].
disambiguated_instant = move(possible_instants.first());
}
// d. Else,
else {
// i. NOTE: t represents a local time skipped at a positive time zone transition (e.g. due to daylight saving time starting or a time zone rule change increasing the UTC offset).
// ii. Let possibleInstantsBefore be GetNamedTimeZoneEpochNanoseconds(systemTimeZoneIdentifier, (YearFromTime(tBefore)), (MonthFromTime(tBefore)) + 1, (DateFromTime(tBefore)), (HourFromTime(tBefore)), (MinFromTime(tBefore)), (SecFromTime(tBefore)), (msFromTime(tBefore)), 0, 0), where tBefore is the largest integral Number < t for which possibleInstantsBefore is not empty (i.e., tBefore represents the last local time before the transition).
// iii. Let disambiguatedInstant be the last element of possibleInstantsBefore.
// FIXME: This branch currently cannot be reached with our implementation, because LibUnicode does not handle skipped time points.
// When GetNamedTimeZoneEpochNanoseconds is updated to use a LibUnicode API which does handle them, implement these steps.
VERIFY_NOT_REACHED();
}
// e. Let offsetNs be GetNamedTimeZoneOffsetNanoseconds(systemTimeZoneIdentifier, disambiguatedInstant).
auto offset = get_named_time_zone_offset_nanoseconds(system_time_zone_identifier, disambiguated_instant);
offset_nanoseconds = static_cast<double>(offset.offset.to_nanoseconds());
}
// 5. Let offsetMs be truncate(offsetNs / 10^6).
auto offset_milliseconds = trunc(offset_nanoseconds / 1e6);
// 6. Return t - 𝔽(offsetMs).
return time - offset_milliseconds;
}
// 21.4.1.27 MakeTime ( hour, min, sec, ms ), https://tc39.es/ecma262/#sec-maketime
double make_time(double hour, double min, double sec, double ms)
{
// 1. If hour is not finite or min is not finite or sec is not finite or ms is not finite, return NaN.
if (!isfinite(hour) || !isfinite(min) || !isfinite(sec) || !isfinite(ms))
return NAN;
// 2. Let h be 𝔽(! ToIntegerOrInfinity(hour)).
auto h = to_integer_or_infinity(hour);
// 3. Let m be 𝔽(! ToIntegerOrInfinity(min)).
auto m = to_integer_or_infinity(min);
// 4. Let s be 𝔽(! ToIntegerOrInfinity(sec)).
auto s = to_integer_or_infinity(sec);
// 5. Let milli be 𝔽(! ToIntegerOrInfinity(ms)).
auto milli = to_integer_or_infinity(ms);
// 6. Let t be ((h * msPerHour + m * msPerMinute) + s * msPerSecond) + milli, performing the arithmetic according to IEEE 754-2019 rules (that is, as if using the ECMAScript operators * and +).
// NOTE: C++ arithmetic abides by IEEE 754 rules
auto t = ((h * ms_per_hour + m * ms_per_minute) + s * ms_per_second) + milli;
// 7. Return t.
return t;
}
// 21.4.1.28 MakeDay ( year, month, date ), https://tc39.es/ecma262/#sec-makeday
double make_day(double year, double month, double date)
{
// 1. If year is not finite or month is not finite or date is not finite, return NaN.
if (!isfinite(year) || !isfinite(month) || !isfinite(date))
return NAN;
// 2. Let y be 𝔽(! ToIntegerOrInfinity(year)).
auto y = to_integer_or_infinity(year);
// 3. Let m be 𝔽(! ToIntegerOrInfinity(month)).
auto m = to_integer_or_infinity(month);
// 4. Let dt be 𝔽(! ToIntegerOrInfinity(date)).
auto dt = to_integer_or_infinity(date);
// 5. Let ym be y + 𝔽(floor((m) / 12)).
auto ym = y + floor(m / 12);
// 6. If ym is not finite, return NaN.
if (!isfinite(ym))
return NAN;
// 7. Let mn be 𝔽((m) modulo 12).
auto mn = modulo(m, 12);
// 8. Find a finite time value t such that YearFromTime(t) is ym and MonthFromTime(t) is mn and DateFromTime(t) is 1𝔽; but if this is not possible (because some argument is out of range), return NaN.
if (!AK::is_within_range<int>(ym) || !AK::is_within_range<int>(mn + 1))
return NAN;
auto t = days_since_epoch(static_cast<int>(ym), static_cast<int>(mn) + 1, 1) * ms_per_day;
// 9. Return Day(t) + dt - 1𝔽.
return day(static_cast<double>(t)) + dt - 1;
}
// 21.4.1.29 MakeDate ( day, time ), https://tc39.es/ecma262/#sec-makedate
double make_date(double day, double time)
{
// 1. If day is not finite or time is not finite, return NaN.
if (!isfinite(day) || !isfinite(time))
return NAN;
// 2. Let tv be day × msPerDay + time.
auto tv = day * ms_per_day + time;
// 3. If tv is not finite, return NaN.
if (!isfinite(tv))
return NAN;
// 4. Return tv.
return tv;
}
// 21.4.1.31 TimeClip ( time ), https://tc39.es/ecma262/#sec-timeclip
double time_clip(double time)
{
// 1. If time is not finite, return NaN.
if (!isfinite(time))
return NAN;
// 2. If abs((time)) > 8.64 × 10^15, return NaN.
if (fabs(time) > 8.64E15)
return NAN;
// 3. Return 𝔽(! ToIntegerOrInfinity(time)).
return to_integer_or_infinity(time);
}
// 21.4.1.33.1 IsTimeZoneOffsetString ( offsetString ), https://tc39.es/ecma262/#sec-istimezoneoffsetstring
// 14.5.10 IsOffsetTimeZoneIdentifier ( offsetString ), https://tc39.es/proposal-temporal/#sec-isoffsettimezoneidentifier
bool is_offset_time_zone_identifier(StringView offset_string)
{
// 1. Let parseResult be ParseText(StringToCodePoints(offsetString), UTCOffset[~SubMinutePrecision]).
auto parse_result = Temporal::parse_utc_offset(offset_string, Temporal::SubMinutePrecision::No);
// 2. If parseResult is a List of errors, return false.
// 3. Return true.
return parse_result.has_value();
}
// 21.4.1.33.2 ParseTimeZoneOffsetString ( offsetString ), https://tc39.es/ecma262/#sec-parsetimezoneoffsetstring
// 14.5.11 ParseDateTimeUTCOffset ( offsetString ), https://tc39.es/proposal-temporal/#sec-parsedatetimeutcoffset
ThrowCompletionOr<double> parse_date_time_utc_offset(VM& vm, StringView offset_string)
{
// 1. Let parseResult be ParseText(offsetString, UTCOffset[+SubMinutePrecision]).
auto parse_result = Temporal::parse_utc_offset(offset_string, Temporal::SubMinutePrecision::Yes);
// 2. If parseResult is a List of errors, throw a RangeError exception.
if (!parse_result.has_value())
return vm.throw_completion<RangeError>(ErrorType::TemporalInvalidTimeZoneString, offset_string);
return parse_date_time_utc_offset(*parse_result);
}
// 21.4.1.33.2 ParseTimeZoneOffsetString ( offsetString ), https://tc39.es/ecma262/#sec-parsetimezoneoffsetstring
// 14.5.11 ParseDateTimeUTCOffset ( offsetString ), https://tc39.es/proposal-temporal/#sec-parsedatetimeutcoffset
double parse_date_time_utc_offset(StringView offset_string)
{
// OPTIMIZATION: Some callers can assume that parsing will succeed.
// 1. Let parseResult be ParseText(offsetString, UTCOffset[+SubMinutePrecision]).
auto parse_result = Temporal::parse_utc_offset(offset_string, Temporal::SubMinutePrecision::Yes);
VERIFY(parse_result.has_value());
return parse_date_time_utc_offset(*parse_result);
}
// 21.4.1.33.2 ParseTimeZoneOffsetString ( offsetString ), https://tc39.es/ecma262/#sec-parsetimezoneoffsetstring
// 14.5.11 ParseDateTimeUTCOffset ( offsetString ), https://tc39.es/proposal-temporal/#sec-parsedatetimeutcoffset
double parse_date_time_utc_offset(Temporal::TimeZoneOffset const& parse_result)
{
// OPTIMIZATION: Some callers will have already parsed and validated the time zone identifier.
// 3. Assert: parseResult contains a ASCIISign Parse Node.
VERIFY(parse_result.sign.has_value());
// 4. Let parsedSign be the source text matched by the ASCIISign Parse Node contained within parseResult.
// 5. If parsedSign is the single code point U+002D (HYPHEN-MINUS), then
// a. Let sign be -1.
// 6. Else,
// a. Let sign be 1.
auto sign = parse_result.sign == '-' ? -1 : 1;
// 7. NOTE: Applications of StringToNumber below do not lose precision, since each of the parsed values is guaranteed
// to be a sufficiently short string of decimal digits.
// 8. Assert: parseResult contains an Hour Parse Node.
VERIFY(parse_result.hours.has_value());
// 9. Let parsedHours be the source text matched by the Hour Parse Node contained within parseResult.
// 10. Let hours be (StringToNumber(CodePointsToString(parsedHours))).
auto hours = parse_result.hours->to_number<u8>().value();
// 11. If parseResult does not contain a MinuteSecond Parse Node, then
// a. Let minutes be 0.
// 12. Else,
// a. Let parsedMinutes be the source text matched by the first MinuteSecond Parse Node contained within parseResult.
// b. Let minutes be (StringToNumber(CodePointsToString(parsedMinutes))).
double minutes = parse_result.minutes.has_value() ? parse_result.minutes->to_number<u8>().value() : 0;
// 13. If parseResult does not contain two MinuteSecond Parse Nodes, then
// a. Let seconds be 0.
// 14. Else,
// a. Let parsedSeconds be the source text matched by the second secondSecond Parse Node contained within parseResult.
// b. Let seconds be (StringToNumber(CodePointsToString(parsedSeconds))).
double seconds = parse_result.seconds.has_value() ? parse_result.seconds->to_number<u8>().value() : 0;
double nanoseconds = 0;
// 15. If parseResult does not contain a TemporalDecimalFraction Parse Node, then
if (!parse_result.fraction.has_value()) {
// a. Let nanoseconds be 0.
nanoseconds = 0;
}
// 16. Else,
else {
// a. Let parsedFraction be the source text matched by the TemporalDecimalFraction Parse Node contained within parseResult.
auto parsed_fraction = *parse_result.fraction;
// b. Let fraction be the string-concatenation of CodePointsToString(parsedFraction) and "000000000".
auto fraction = ByteString::formatted("{}000000000", parsed_fraction);
// c. Let nanosecondsString be the substring of fraction from 1 to 10.
auto nanoseconds_string = fraction.substring_view(1, 9);
// d. Let nanoseconds be (StringToNumber(nanosecondsString)).
nanoseconds = string_to_number(nanoseconds_string);
}
// 17. Return sign × (((hours × 60 + minutes) × 60 + seconds) × 10^9 + nanoseconds).
// NOTE: Using scientific notation (1e9) ensures the result of this expression is a double,
// which is important - otherwise it's all integers and the result overflows!
return sign * (((hours * 60 + minutes) * 60 + seconds) * 1e9 + nanoseconds);
}
}