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/*
* Copyright (C) 2021 Apple Inc.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. AND ITS CONTRIBUTORS ``AS IS''
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
* THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR ITS CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
* THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "TemporalPlainTime.h"
#include "AbstractSlotVisitor.h"
#include "IntlObjectInlines.h"
#include "JSCInlines.h"
#include "LazyPropertyInlines.h"
#include "TemporalDuration.h"
#include "VMTrapsInlines.h"
namespace JSC {
namespace TemporalPlainTimeInternal {
static constexpr bool verbose = false;
}
const ClassInfo TemporalPlainTime::s_info = { "Object", &Base::s_info, nullptr, nullptr, CREATE_METHOD_TABLE(TemporalPlainTime) };
TemporalPlainTime* TemporalPlainTime::create(VM& vm, Structure* structure, ISO8601::PlainTime&& plainTime)
{
auto* object = new (NotNull, allocateCell<TemporalPlainTime>(vm)) TemporalPlainTime(vm, structure, WTFMove(plainTime));
object->finishCreation(vm);
return object;
}
Structure* TemporalPlainTime::createStructure(VM& vm, JSGlobalObject* globalObject, JSValue prototype)
{
return Structure::create(vm, globalObject, prototype, TypeInfo(ObjectType, StructureFlags), info());
}
TemporalPlainTime::TemporalPlainTime(VM& vm, Structure* structure, ISO8601::PlainTime&& plainTime)
: Base(vm, structure)
, m_plainTime(WTFMove(plainTime))
{
}
void TemporalPlainTime::finishCreation(VM& vm)
{
Base::finishCreation(vm);
ASSERT(inherits(vm, info()));
m_calendar.initLater(
[] (const auto& init) {
VM& vm = init.vm;
auto* plainTime = jsCast<TemporalPlainTime*>(init.owner);
auto* globalObject = plainTime->globalObject(vm);
auto* calendar = TemporalCalendar::create(vm, globalObject->calendarStructure(), iso8601CalendarID());
init.set(calendar);
});
}
template<typename Visitor>
void TemporalPlainTime::visitChildrenImpl(JSCell* cell, Visitor& visitor)
{
Base::visitChildren(cell, visitor);
auto* thisObject = jsCast<TemporalPlainTime*>(cell);
thisObject->m_calendar.visit(visitor);
}
DEFINE_VISIT_CHILDREN(TemporalPlainTime);
// https://tc39.es/proposal-temporal/#sec-temporal-isvalidtime
static ISO8601::PlainTime toPlainTime(JSGlobalObject* globalObject, ISO8601::Duration&& duration)
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
double hour = duration.hours();
double minute = duration.minutes();
double second = duration.seconds();
double millisecond = duration.milliseconds();
double microsecond = duration.microseconds();
double nanosecond = duration.nanoseconds();
if (!(hour >= 0 && hour <= 23)) {
throwRangeError(globalObject, scope, "hour is out of range"_s);
return { };
}
if (!(minute >= 0 && minute <= 59)) {
throwRangeError(globalObject, scope, "minute is out of range"_s);
return { };
}
if (!(second >= 0 && second <= 59)) {
throwRangeError(globalObject, scope, "second is out of range"_s);
return { };
}
if (!(millisecond >= 0 && millisecond <= 999)) {
throwRangeError(globalObject, scope, "millisecond is out of range"_s);
return { };
}
if (!(microsecond >= 0 && microsecond <= 999)) {
throwRangeError(globalObject, scope, "microsecond is out of range"_s);
return { };
}
if (!(nanosecond >= 0 && nanosecond <= 999)) {
throwRangeError(globalObject, scope, "nanosecond is out of range"_s);
return { };
}
return ISO8601::PlainTime {
static_cast<unsigned>(hour),
static_cast<unsigned>(minute),
static_cast<unsigned>(second),
static_cast<unsigned>(millisecond),
static_cast<unsigned>(microsecond),
static_cast<unsigned>(nanosecond)
};
}
// CreateTemporalPlainTime ( years, months, weeks, days, hours, minutes, seconds, milliseconds, microseconds, nanoseconds [ , newTarget ] )
// https://tc39.es/proposal-temporal/#sec-temporal-createtemporalplainTime
TemporalPlainTime* TemporalPlainTime::tryCreateIfValid(JSGlobalObject* globalObject, Structure* structure, ISO8601::Duration&& duration)
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
auto plainTime = toPlainTime(globalObject, WTFMove(duration));
RETURN_IF_EXCEPTION(scope, { });
return TemporalPlainTime::create(vm, structure, WTFMove(plainTime));
}
static double nonNegativeModulo(double x, double y)
{
double result = std::fmod(x, y);
if (!result)
return 0;
if (result < 0)
result += y;
return result;
}
// https://tc39.es/proposal-temporal/#sec-temporal-balancetime
static ISO8601::Duration balanceTime(double hour, double minute, double second, double millisecond, double microsecond, double nanosecond)
{
// https://github.com/tc39/proposal-temporal/issues/1804
// Use non-negative modulo operation.
microsecond += std::floor(nanosecond / 1000);
nanosecond = nonNegativeModulo(nanosecond, 1000);
millisecond += std::floor(microsecond / 1000);
microsecond = nonNegativeModulo(microsecond, 1000);
second += std::floor(millisecond / 1000);
millisecond = nonNegativeModulo(millisecond, 1000);
minute += std::floor(second / 60);
second = nonNegativeModulo(second, 60);
hour += std::floor(minute / 60);
minute = nonNegativeModulo(minute, 60);
double days = std::floor(hour / 24);
hour = nonNegativeModulo(hour, 24);
return ISO8601::Duration(0, 0, 0, days, hour, minute, second, millisecond, microsecond, nanosecond);
}
// https://tc39.es/proposal-temporal/#sec-temporal-roundtime
static ISO8601::Duration roundTime(ISO8601::PlainTime plainTime, double increment, TemporalUnit unit, RoundingMode roundingMode, std::optional<double> dayLengthNs)
{
auto fractionalSecond = [](ISO8601::PlainTime plainTime) -> double {
return plainTime.second() + plainTime.millisecond() * 1e-3 + plainTime.microsecond() * 1e-6 + plainTime.nanosecond() * 1e-9;
};
double quantity = 0;
switch (unit) {
case TemporalUnit::Day: {
double length = dayLengthNs.value_or(8.64 * 1e+13);
quantity = ((((plainTime.hour() * 60.0 + plainTime.minute()) * 60.0 + plainTime.second()) * 1000.0 + plainTime.millisecond()) * 1000.0 + plainTime.nanosecond()) / length;
auto result = roundNumberToIncrement(quantity, increment, roundingMode);
return ISO8601::Duration(0, 0, 0, result, 0, 0, 0, 0, 0, 0);
}
case TemporalUnit::Hour: {
quantity = (fractionalSecond(plainTime) / 60.0 + plainTime.minute()) / 60.0 + plainTime.hour();
auto result = roundNumberToIncrement(quantity, increment, roundingMode);
return balanceTime(result, 0, 0, 0, 0, 0);
}
case TemporalUnit::Minute: {
quantity = fractionalSecond(plainTime) / 60.0 + plainTime.minute();
auto result = roundNumberToIncrement(quantity, increment, roundingMode);
return balanceTime(plainTime.hour(), result, 0, 0, 0, 0);
}
case TemporalUnit::Second: {
quantity = fractionalSecond(plainTime);
auto result = roundNumberToIncrement(quantity, increment, roundingMode);
return balanceTime(plainTime.hour(), plainTime.minute(), result, 0, 0, 0);
}
case TemporalUnit::Millisecond: {
quantity = plainTime.millisecond() + plainTime.microsecond() * 1e-3 + plainTime.nanosecond() * 1e-6;
auto result = roundNumberToIncrement(quantity, increment, roundingMode);
return balanceTime(plainTime.hour(), plainTime.minute(), plainTime.second(), result, 0, 0);
}
case TemporalUnit::Microsecond: {
quantity = plainTime.microsecond() + plainTime.nanosecond() * 1e-3;
auto result = roundNumberToIncrement(quantity, increment, roundingMode);
return balanceTime(plainTime.hour(), plainTime.minute(), plainTime.second(), plainTime.millisecond(), result, 0);
}
case TemporalUnit::Nanosecond: {
quantity = plainTime.nanosecond();
auto result = roundNumberToIncrement(quantity, increment, roundingMode);
return balanceTime(plainTime.hour(), plainTime.minute(), plainTime.second(), plainTime.millisecond(), plainTime.microsecond(), result);
}
default:
RELEASE_ASSERT_NOT_REACHED();
break;
}
}
ISO8601::PlainTime TemporalPlainTime::round(JSGlobalObject* globalObject, JSValue optionsValue) const
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
JSObject* options = intlGetOptionsObject(globalObject, optionsValue);
RETURN_IF_EXCEPTION(scope, { });
auto smallest = temporalSmallestUnit(globalObject, options, { TemporalUnit::Year, TemporalUnit::Month, TemporalUnit::Week, TemporalUnit::Day });
RETURN_IF_EXCEPTION(scope, { });
if (!smallest) {
throwRangeError(globalObject, scope, "Cannot round without a smallestUnit option"_s);
return { };
}
TemporalUnit smallestUnit = smallest.value();
auto roundingMode = temporalRoundingMode(globalObject, options, RoundingMode::HalfExpand);
RETURN_IF_EXCEPTION(scope, { });
auto increment = temporalRoundingIncrement(globalObject, options, maximumRoundingIncrement(smallestUnit), false);
RETURN_IF_EXCEPTION(scope, { });
auto duration = roundTime(m_plainTime, increment, smallestUnit, roundingMode, std::nullopt);
RELEASE_AND_RETURN(scope, toPlainTime(globalObject, WTFMove(duration)));
}
String TemporalPlainTime::toString(JSGlobalObject* globalObject, JSValue optionsValue) const
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
JSObject* options = intlGetOptionsObject(globalObject, optionsValue);
RETURN_IF_EXCEPTION(scope, { });
if (!options)
return toString();
PrecisionData data = secondsStringPrecision(globalObject, options);
RETURN_IF_EXCEPTION(scope, { });
auto roundingMode = temporalRoundingMode(globalObject, options, RoundingMode::Trunc);
RETURN_IF_EXCEPTION(scope, { });
// No need to make a new object if we were given explicit defaults.
if (std::get<0>(data.precision) == Precision::Auto && roundingMode == RoundingMode::Trunc)
return toString();
auto duration = roundTime(m_plainTime, data.increment, data.unit, roundingMode, std::nullopt);
auto plainTime = toPlainTime(globalObject, WTFMove(duration));
RETURN_IF_EXCEPTION(scope, { });
return ISO8601::temporalTimeToString(plainTime, data.precision);
}
static ISO8601::Duration toTemporalTimeRecord(JSGlobalObject* globalObject, JSObject* temporalTimeLike)
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
ISO8601::Duration duration { };
for (TemporalUnit unit : temporalUnitsInTableOrder) {
if (unit < TemporalUnit::Hour)
continue;
auto name = temporalUnitSingularPropertyName(vm, unit);
JSValue value = temporalTimeLike->get(globalObject, name);
RETURN_IF_EXCEPTION(scope, { });
// We are throwing an error here, but probably this is a spec bug.
// Tracked in https://github.com/tc39/proposal-temporal/issues/1803.
if (value.isUndefined()) {
throwTypeError(globalObject, scope, makeString('"', StringView(name.uid()), "\" field is missing"_s));
return { };
}
double integer = value.toIntegerOrInfinity(globalObject);
RETURN_IF_EXCEPTION(scope, { });
if (!std::isfinite(integer)) {
throwRangeError(globalObject, scope, "Temporal.PlainTime properties must be finite"_s);
return { };
}
duration[unit] = integer;
}
return duration;
}
static std::array<std::optional<double>, numberOfTemporalPlainTimeUnits> toPartialTime(JSGlobalObject* globalObject, JSObject* temporalTimeLike)
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
bool hasAnyFields = false;
std::array<std::optional<double>, numberOfTemporalPlainTimeUnits> partialTime { };
for (TemporalUnit unit : temporalUnitsInTableOrder) {
if (unit < TemporalUnit::Hour)
continue;
auto name = temporalUnitSingularPropertyName(vm, unit);
JSValue value = temporalTimeLike->get(globalObject, name);
RETURN_IF_EXCEPTION(scope, { });
if (!value.isUndefined()) {
hasAnyFields = true;
double doubleValue = value.toIntegerOrInfinity(globalObject);
RETURN_IF_EXCEPTION(scope, { });
if (!std::isfinite(doubleValue)) {
throwRangeError(globalObject, scope, "toPartialTime properties must be finite"_s);
return { };
}
partialTime[static_cast<unsigned>(unit) - static_cast<unsigned>(TemporalUnit::Hour)] = doubleValue;
}
}
if (!hasAnyFields) {
throwTypeError(globalObject, scope, "toPartialTime requires at least one property"_s);
return { };
}
return partialTime;
}
static ISO8601::PlainTime constrainTime(ISO8601::Duration&& duration)
{
auto constrainToRange = [](double value, unsigned minimum, unsigned maximum) -> unsigned {
if (std::isnan(value))
return 0;
return static_cast<unsigned>(std::min<double>(std::max<double>(value, minimum), maximum));
};
return ISO8601::PlainTime(
constrainToRange(duration.hours(), 0, 23),
constrainToRange(duration.minutes(), 0, 59),
constrainToRange(duration.seconds(), 0, 59),
constrainToRange(duration.milliseconds(), 0, 1000),
constrainToRange(duration.microseconds(), 0, 1000),
constrainToRange(duration.nanoseconds(), 0, 1000));
}
static ISO8601::PlainTime regulateTime(JSGlobalObject* globalObject, ISO8601::Duration&& duration, TemporalOverflow overflow)
{
switch (overflow) {
case TemporalOverflow::Constrain:
return constrainTime(WTFMove(duration));
case TemporalOverflow::Reject:
return toPlainTime(globalObject, WTFMove(duration));
}
return { };
}
static JSObject* toTemporalCalendarWithISODefault(JSGlobalObject* globalObject, JSValue temporalCalendarLike)
{
if (temporalCalendarLike.isUndefined())
return TemporalCalendar::create(globalObject->vm(), globalObject->calendarStructure(), iso8601CalendarID());
return TemporalCalendar::from(globalObject, temporalCalendarLike);
}
static JSObject* getTemporalCalendarWithISODefault(JSGlobalObject* globalObject, JSValue itemValue)
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
if (itemValue.inherits<TemporalPlainTime>(vm))
return jsCast<TemporalPlainTime*>(itemValue)->calendar();
JSValue calendar = itemValue.get(globalObject, vm.propertyNames->calendar);
RETURN_IF_EXCEPTION(scope, { });
RELEASE_AND_RETURN(scope, toTemporalCalendarWithISODefault(globalObject, calendar));
}
// https://tc39.es/proposal-temporal/#sec-temporal-totemporaltime
TemporalPlainTime* TemporalPlainTime::from(JSGlobalObject* globalObject, JSValue itemValue, std::optional<TemporalOverflow> overflowValue)
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
auto overflow = overflowValue.value_or(TemporalOverflow::Constrain);
if (itemValue.isObject()) {
if (itemValue.inherits<TemporalPlainTime>(vm))
return jsCast<TemporalPlainTime*>(itemValue);
JSObject* calendar = getTemporalCalendarWithISODefault(globalObject, itemValue);
RETURN_IF_EXCEPTION(scope, { });
JSString* calendarString = calendar->toString(globalObject);
RETURN_IF_EXCEPTION(scope, { });
String calendarWTFString = calendarString->value(globalObject);
RETURN_IF_EXCEPTION(scope, { });
if (calendarWTFString != "iso8601"_s) {
throwRangeError(globalObject, scope, "calendar is not iso8601"_s);
return { };
}
auto duration = toTemporalTimeRecord(globalObject, jsCast<JSObject*>(itemValue));
RETURN_IF_EXCEPTION(scope, { });
auto plainTime = regulateTime(globalObject, WTFMove(duration), overflow);
RETURN_IF_EXCEPTION(scope, { });
return TemporalPlainTime::create(vm, globalObject->plainTimeStructure(), WTFMove(plainTime));
}
auto string = itemValue.toWTFString(globalObject);
RETURN_IF_EXCEPTION(scope, { });
auto time = ISO8601::parseTime(string);
if (time) {
auto [plainTime, timeZoneOptional] = time.value();
return TemporalPlainTime::create(vm, globalObject->plainTimeStructure(), WTFMove(plainTime));
}
auto dateTime = ISO8601::parseDateTime(string);
if (dateTime) {
auto [plainDate, plainTimeOptional, timeZoneOptional] = dateTime.value();
if (plainTimeOptional)
return TemporalPlainTime::create(vm, globalObject->plainTimeStructure(), WTFMove(plainTimeOptional.value()));
}
throwRangeError(globalObject, scope, "invalid time string"_s);
return { };
}
// https://tc39.es/proposal-temporal/#sec-temporal-comparetemporaltime
int32_t TemporalPlainTime::compare(TemporalPlainTime* plainTime1, TemporalPlainTime* plainTime2)
{
ISO8601::PlainTime t1 = plainTime1->plainTime();
ISO8601::PlainTime t2 = plainTime2->plainTime();
if (t1.hour() > t2.hour())
return 1;
if (t1.hour() < t2.hour())
return -1;
if (t1.minute() > t2.minute())
return 1;
if (t1.minute() < t2.minute())
return -1;
if (t1.second() > t2.second())
return 1;
if (t1.second() < t2.second())
return -1;
if (t1.millisecond() > t2.millisecond())
return 1;
if (t1.millisecond() < t2.millisecond())
return -1;
if (t1.microsecond() > t2.microsecond())
return 1;
if (t1.microsecond() < t2.microsecond())
return -1;
if (t1.nanosecond() > t2.nanosecond())
return 1;
if (t1.nanosecond() < t2.nanosecond())
return -1;
return 0;
}
static ISO8601::Duration addTime(const ISO8601::PlainTime& plainTime, const ISO8601::Duration& duration)
{
return balanceTime(
plainTime.hour() + duration.hours(),
plainTime.minute() + duration.minutes(),
plainTime.second() + duration.seconds(),
plainTime.millisecond() + duration.milliseconds(),
plainTime.microsecond() + duration.microseconds(),
plainTime.nanosecond() + duration.nanoseconds());
}
ISO8601::PlainTime TemporalPlainTime::add(JSGlobalObject* globalObject, JSValue temporalDurationLike) const
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
auto duration = TemporalDuration::toISO8601Duration(globalObject, temporalDurationLike);
RETURN_IF_EXCEPTION(scope, { });
RELEASE_AND_RETURN(scope, toPlainTime(globalObject, addTime(m_plainTime, duration)));
}
ISO8601::PlainTime TemporalPlainTime::subtract(JSGlobalObject* globalObject, JSValue temporalDurationLike) const
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
auto duration = TemporalDuration::toISO8601Duration(globalObject, temporalDurationLike);
RETURN_IF_EXCEPTION(scope, { });
RELEASE_AND_RETURN(scope, toPlainTime(globalObject, addTime(m_plainTime, -duration)));
}
ISO8601::PlainTime TemporalPlainTime::with(JSGlobalObject* globalObject, JSObject* temporalTimeLike, JSValue optionsValue) const
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
if (temporalTimeLike->inherits<TemporalPlainTime>(vm)) {
throwTypeError(globalObject, scope, "argument object must not carry calendar"_s);
return { };
}
JSValue calendarProperty = temporalTimeLike->get(globalObject, vm.propertyNames->calendar);
RETURN_IF_EXCEPTION(scope, { });
if (!calendarProperty.isUndefined()) {
throwTypeError(globalObject, scope, "argument object must not carry calendar"_s);
return { };
}
JSValue timeZoneProperty = temporalTimeLike->get(globalObject, vm.propertyNames->timeZone);
RETURN_IF_EXCEPTION(scope, { });
if (!timeZoneProperty.isUndefined()) {
throwTypeError(globalObject, scope, "argument object must not carry time zone"_s);
return { };
}
auto [hourOptional, minuteOptional, secondOptional, millisecondOptional, microsecondOptional, nanosecondOptional] = toPartialTime(globalObject, temporalTimeLike);
RETURN_IF_EXCEPTION(scope, { });
JSObject* options = intlGetOptionsObject(globalObject, optionsValue);
RETURN_IF_EXCEPTION(scope, { });
TemporalOverflow overflow = toTemporalOverflow(globalObject, options);
RETURN_IF_EXCEPTION(scope, { });
ISO8601::Duration duration { };
duration.setHours(hourOptional.value_or(hour()));
duration.setMinutes(minuteOptional.value_or(minute()));
duration.setSeconds(secondOptional.value_or(second()));
duration.setMilliseconds(millisecondOptional.value_or(millisecond()));
duration.setMicroseconds(microsecondOptional.value_or(microsecond()));
duration.setNanoseconds(nanosecondOptional.value_or(nanosecond()));
RELEASE_AND_RETURN(scope, regulateTime(globalObject, WTFMove(duration), overflow));
}
static ISO8601::Duration differenceTime(ISO8601::PlainTime time1, ISO8601::PlainTime time2)
{
double hours = static_cast<double>(time2.hour()) - static_cast<double>(time1.hour());
double minutes = static_cast<double>(time2.minute()) - static_cast<double>(time1.minute());
double seconds = static_cast<double>(time2.second()) - static_cast<double>(time1.second());
double milliseconds = static_cast<double>(time2.millisecond()) - static_cast<double>(time1.millisecond());
double microseconds = static_cast<double>(time2.microsecond()) - static_cast<double>(time1.microsecond());
double nanoseconds = static_cast<double>(time2.nanosecond()) - static_cast<double>(time1.nanosecond());
dataLogLnIf(TemporalPlainTimeInternal::verbose, "Diff ", hours, " ", minutes, " ", seconds, " ", milliseconds, " ", microseconds, " ", nanoseconds);
int32_t sign = TemporalDuration::sign(ISO8601::Duration(0, 0, 0, 0, hours, minutes, seconds, milliseconds, microseconds, nanoseconds));
auto duration = balanceTime(hours * sign, minutes * sign, seconds * sign, milliseconds * sign, microseconds * sign, nanoseconds * sign);
dataLogLnIf(TemporalPlainTimeInternal::verbose, "Balanced ", duration.days(), " ", duration.hours(), " ", duration.minutes(), " ", duration.seconds(), " ", duration.milliseconds(), " ", duration.microseconds(), " ", duration.nanoseconds());
if (sign == -1)
return -duration;
return duration;
}
static std::tuple<TemporalUnit, TemporalUnit, RoundingMode, double> extractDifferenceOptions(JSGlobalObject* globalObject, JSValue optionsValue)
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
JSObject* options = intlGetOptionsObject(globalObject, optionsValue);
RETURN_IF_EXCEPTION(scope, { });
auto smallest = temporalSmallestUnit(globalObject, options, { TemporalUnit::Year, TemporalUnit::Month, TemporalUnit::Week, TemporalUnit::Day });
RETURN_IF_EXCEPTION(scope, { });
TemporalUnit smallestUnit = smallest.value_or(TemporalUnit::Nanosecond);
auto largest = temporalLargestUnit(globalObject, options, { TemporalUnit::Year, TemporalUnit::Month, TemporalUnit::Week, TemporalUnit::Day }, TemporalUnit::Hour);
RETURN_IF_EXCEPTION(scope, { });
TemporalUnit largestUnit = largest.value_or(TemporalUnit::Hour);
if (smallestUnit < largestUnit) {
throwRangeError(globalObject, scope, "smallestUnit must be smaller than largestUnit"_s);
return { };
}
auto roundingMode = temporalRoundingMode(globalObject, options, RoundingMode::Trunc);
RETURN_IF_EXCEPTION(scope, { });
auto increment = temporalRoundingIncrement(globalObject, options, maximumRoundingIncrement(smallestUnit), false);
RETURN_IF_EXCEPTION(scope, { });
return { smallestUnit, largestUnit, roundingMode, increment };
}
ISO8601::Duration TemporalPlainTime::until(JSGlobalObject* globalObject, TemporalPlainTime* other, JSValue optionsValue) const
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
auto [smallestUnit, largestUnit, roundingMode, increment] = extractDifferenceOptions(globalObject, optionsValue);
RETURN_IF_EXCEPTION(scope, { });
auto result = differenceTime(plainTime(), other->plainTime());
result.setYears(0);
result.setMonths(0);
result.setWeeks(0);
result.setDays(0);
TemporalDuration::round(result, increment, smallestUnit, roundingMode);
TemporalDuration::balance(result, largestUnit);
return result;
}
ISO8601::Duration TemporalPlainTime::since(JSGlobalObject* globalObject, TemporalPlainTime* other, JSValue optionsValue) const
{
VM& vm = globalObject->vm();
auto scope = DECLARE_THROW_SCOPE(vm);
auto [smallestUnit, largestUnit, roundingMode, increment] = extractDifferenceOptions(globalObject, optionsValue);
RETURN_IF_EXCEPTION(scope, { });
auto result = differenceTime(other->plainTime(), plainTime());
result = -result;
result.setYears(0);
result.setMonths(0);
result.setWeeks(0);
result.setDays(0);
TemporalDuration::round(result, increment, smallestUnit, roundingMode);
result = -result;
result.setDays(0);
TemporalDuration::balance(result, largestUnit);
return result;
}
} // namespace JSC