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ladybird/Userland/Libraries/LibJS/Runtime/Intl/RelativeTimeFormat.cpp
Andreas Kling 3c74dc9f4d LibJS: Segregate GC-allocated objects by type 
This patch adds two macros to declare per-type allocators:

- JS_DECLARE_ALLOCATOR(TypeName)
- JS_DEFINE_ALLOCATOR(TypeName)

When used, they add a type-specific CellAllocator that the Heap will
delegate allocation requests to.

The result of this is that GC objects of the same type always end up
within the same HeapBlock, drastically reducing the ability to perform
type confusion attacks.

It also improves HeapBlock utilization, since each block now has cells
sized exactly to the type used within that block. (Previously we only
had a handful of block sizes available, and most GC allocations ended
up with a large amount of slack in their tails.)

There is a small performance hit from this, but I'm sure we can make
up for it elsewhere.

Note that the old size-based allocators still exist, and we fall back
to them for any type that doesn't have its own CellAllocator.
2023-11-19 12:10:31 +01:00

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/*
* Copyright (c) 2022-2023, Tim Flynn <trflynn89@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/StringBuilder.h>
#include <LibJS/Runtime/AbstractOperations.h>
#include <LibJS/Runtime/Array.h>
#include <LibJS/Runtime/GlobalObject.h>
#include <LibJS/Runtime/Intl/NumberFormat.h>
#include <LibJS/Runtime/Intl/NumberFormatConstructor.h>
#include <LibJS/Runtime/Intl/PluralRules.h>
#include <LibJS/Runtime/Intl/RelativeTimeFormat.h>
namespace JS::Intl {
JS_DEFINE_ALLOCATOR(RelativeTimeFormat);
// 17 RelativeTimeFormat Objects, https://tc39.es/ecma402/#relativetimeformat-objects
RelativeTimeFormat::RelativeTimeFormat(Object& prototype)
: Object(ConstructWithPrototypeTag::Tag, prototype)
{
}
void RelativeTimeFormat::visit_edges(Cell::Visitor& visitor)
{
Base::visit_edges(visitor);
if (m_number_format)
visitor.visit(m_number_format);
if (m_plural_rules)
visitor.visit(m_plural_rules);
}
void RelativeTimeFormat::set_numeric(StringView numeric)
{
if (numeric == "always"sv) {
m_numeric = Numeric::Always;
} else if (numeric == "auto"sv) {
m_numeric = Numeric::Auto;
} else {
VERIFY_NOT_REACHED();
}
}
StringView RelativeTimeFormat::numeric_string() const
{
switch (m_numeric) {
case Numeric::Always:
return "always"sv;
case Numeric::Auto:
return "auto"sv;
default:
VERIFY_NOT_REACHED();
}
}
// 17.5.1 SingularRelativeTimeUnit ( unit ), https://tc39.es/ecma402/#sec-singularrelativetimeunit
ThrowCompletionOr<::Locale::TimeUnit> singular_relative_time_unit(VM& vm, StringView unit)
{
// 1. Assert: Type(unit) is String.
// 2. If unit is "seconds", return "second".
if (unit == "seconds"sv)
return ::Locale::TimeUnit::Second;
// 3. If unit is "minutes", return "minute".
if (unit == "minutes"sv)
return ::Locale::TimeUnit::Minute;
// 4. If unit is "hours", return "hour".
if (unit == "hours"sv)
return ::Locale::TimeUnit::Hour;
// 5. If unit is "days", return "day".
if (unit == "days"sv)
return ::Locale::TimeUnit::Day;
// 6. If unit is "weeks", return "week".
if (unit == "weeks"sv)
return ::Locale::TimeUnit::Week;
// 7. If unit is "months", return "month".
if (unit == "months"sv)
return ::Locale::TimeUnit::Month;
// 8. If unit is "quarters", return "quarter".
if (unit == "quarters"sv)
return ::Locale::TimeUnit::Quarter;
// 9. If unit is "years", return "year".
if (unit == "years"sv)
return ::Locale::TimeUnit::Year;
// 10. If unit is not one of "second", "minute", "hour", "day", "week", "month", "quarter", or "year", throw a RangeError exception.
// 11. Return unit.
if (auto time_unit = ::Locale::time_unit_from_string(unit); time_unit.has_value())
return *time_unit;
return vm.throw_completion<RangeError>(ErrorType::IntlInvalidUnit, unit);
}
// 17.5.2 PartitionRelativeTimePattern ( relativeTimeFormat, value, unit ), https://tc39.es/ecma402/#sec-PartitionRelativeTimePattern
ThrowCompletionOr<Vector<PatternPartitionWithUnit>> partition_relative_time_pattern(VM& vm, RelativeTimeFormat& relative_time_format, double value, StringView unit)
{
// 1. Assert: relativeTimeFormat has an [[InitializedRelativeTimeFormat]] internal slot.
// 2. Assert: Type(value) is Number.
// 3. Assert: Type(unit) is String.
// 4. If value is NaN, +∞𝔽, or -∞𝔽, throw a RangeError exception.
if (!Value(value).is_finite_number())
return vm.throw_completion<RangeError>(ErrorType::IntlNumberIsNaNOrInfinity);
// 5. Let unit be ? SingularRelativeTimeUnit(unit).
auto time_unit = TRY(singular_relative_time_unit(vm, unit));
// 6. Let localeData be %RelativeTimeFormat%.[[LocaleData]].
// 7. Let dataLocale be relativeTimeFormat.[[DataLocale]].
auto const& data_locale = relative_time_format.data_locale();
// 8. Let fields be localeData.[[<dataLocale>]].
// 9. Let style be relativeTimeFormat.[[Style]].
auto style = relative_time_format.style();
// NOTE: The next steps form a "key" based on combining various formatting options into a string,
// then filtering the large set of locale data down to the pattern we are looking for. Instead,
// LibUnicode expects the individual options as enumeration values, and returns the couple of
// patterns that match those options.
auto find_patterns_for_tense_or_number = [&](StringView tense_or_number) {
// 10. If style is equal to "short", then
// a. Let entry be the string-concatenation of unit and "-short".
// 11. Else if style is equal to "narrow", then
// a. Let entry be the string-concatenation of unit and "-narrow".
// 12. Else,
// a. Let entry be unit.
auto patterns = ::Locale::get_relative_time_format_patterns(data_locale, time_unit, tense_or_number, style);
// 13. If fields doesn't have a field [[<entry>]], then
if (patterns.is_empty()) {
// a. Let entry be unit.
// NOTE: In the CLDR, the lack of "short" or "narrow" in the key implies "long".
patterns = ::Locale::get_relative_time_format_patterns(data_locale, time_unit, tense_or_number, ::Locale::Style::Long);
}
// 14. Let patterns be fields.[[<entry>]].
return patterns;
};
// 15. Let numeric be relativeTimeFormat.[[Numeric]].
// 16. If numeric is equal to "auto", then
if (relative_time_format.numeric() == RelativeTimeFormat::Numeric::Auto) {
// a. Let valueString be ToString(value).
auto value_string = MUST(Value(value).to_string(vm));
// b. If patterns has a field [[<valueString>]], then
if (auto patterns = find_patterns_for_tense_or_number(value_string); !patterns.is_empty()) {
VERIFY(patterns.size() == 1);
// i. Let result be patterns.[[<valueString>]].
auto result = MUST(String::from_utf8(patterns[0].pattern));
// ii. Return a List containing the Record { [[Type]]: "literal", [[Value]]: result }.
return Vector<PatternPartitionWithUnit> { { "literal"sv, move(result) } };
}
}
// 17. If value is -0𝔽 or if value is less than 0, then
StringView tense;
if (Value(value).is_negative_zero() || (value < 0)) {
// a. Let tl be "past".
tense = "past"sv;
// FIXME: The spec does not say to do this, but nothing makes sense after this with a negative value.
value = fabs(value);
}
// 18. Else,
else {
// a. Let tl be "future".
tense = "future"sv;
}
// 19. Let po be patterns.[[<tl>]].
auto patterns = find_patterns_for_tense_or_number(tense);
// 20. Let fv be ! PartitionNumberPattern(relativeTimeFormat.[[NumberFormat]], value).
auto value_partitions = partition_number_pattern(vm, relative_time_format.number_format(), Value(value));
// 21. Let pr be ! ResolvePlural(relativeTimeFormat.[[PluralRules]], value).[[PluralCategory]].
auto plurality = resolve_plural(relative_time_format.plural_rules(), Value(value));
// 22. Let pattern be po.[[<pr>]].
auto pattern = patterns.find_if([&](auto& p) { return p.plurality == plurality.plural_category; });
if (pattern == patterns.end())
return Vector<PatternPartitionWithUnit> {};
// 23. Return ! MakePartsList(pattern, unit, fv).
return make_parts_list(pattern->pattern, ::Locale::time_unit_to_string(time_unit), move(value_partitions));
}
// 17.5.3 MakePartsList ( pattern, unit, parts ), https://tc39.es/ecma402/#sec-makepartslist
Vector<PatternPartitionWithUnit> make_parts_list(StringView pattern, StringView unit, Vector<PatternPartition> parts)
{
// 1. Let patternParts be PartitionPattern(pattern).
auto pattern_parts = partition_pattern(pattern);
// 2. Let result be a new empty List.
Vector<PatternPartitionWithUnit> result;
// 3. For each Record { [[Type]], [[Value]] } patternPart in patternParts, do
for (auto& pattern_part : pattern_parts) {
// a. If patternPart.[[Type]] is "literal", then
if (pattern_part.type == "literal"sv) {
// i. Append Record { [[Type]]: "literal", [[Value]]: patternPart.[[Value]], [[Unit]]: empty } to result.
result.empend("literal"sv, move(pattern_part.value));
}
// b. Else,
else {
// i. Assert: patternPart.[[Type]] is "0".
VERIFY(pattern_part.type == "0"sv);
// ii. For each Record { [[Type]], [[Value]] } part in parts, do
for (auto& part : parts) {
// 1. Append Record { [[Type]]: part.[[Type]], [[Value]]: part.[[Value]], [[Unit]]: unit } to result.
result.empend(part.type, move(part.value), unit);
}
}
}
// 4. Return result.
return result;
}
// 17.5.4 FormatRelativeTime ( relativeTimeFormat, value, unit ), https://tc39.es/ecma402/#sec-FormatRelativeTime
ThrowCompletionOr<String> format_relative_time(VM& vm, RelativeTimeFormat& relative_time_format, double value, StringView unit)
{
// 1. Let parts be ? PartitionRelativeTimePattern(relativeTimeFormat, value, unit).
auto parts = TRY(partition_relative_time_pattern(vm, relative_time_format, value, unit));
// 2. Let result be an empty String.
StringBuilder result;
// 3. For each Record { [[Type]], [[Value]], [[Unit]] } part in parts, do
for (auto& part : parts) {
// a. Set result to the string-concatenation of result and part.[[Value]].
result.append(part.value);
}
// 4. Return result.
return MUST(result.to_string());
}
// 17.5.5 FormatRelativeTimeToParts ( relativeTimeFormat, value, unit ), https://tc39.es/ecma402/#sec-FormatRelativeTimeToParts
ThrowCompletionOr<NonnullGCPtr<Array>> format_relative_time_to_parts(VM& vm, RelativeTimeFormat& relative_time_format, double value, StringView unit)
{
auto& realm = *vm.current_realm();
// 1. Let parts be ? PartitionRelativeTimePattern(relativeTimeFormat, value, unit).
auto parts = TRY(partition_relative_time_pattern(vm, relative_time_format, value, unit));
// 2. Let result be ! ArrayCreate(0).
auto result = MUST(Array::create(realm, 0));
// 3. Let n be 0.
size_t n = 0;
// 4. For each Record { [[Type]], [[Value]], [[Unit]] } part in parts, do
for (auto& part : parts) {
// a. Let O be OrdinaryObjectCreate(%Object.prototype%).
auto object = Object::create(realm, realm.intrinsics().object_prototype());
// b. Perform ! CreateDataPropertyOrThrow(O, "type", part.[[Type]]).
MUST(object->create_data_property_or_throw(vm.names.type, PrimitiveString::create(vm, part.type)));
// c. Perform ! CreateDataPropertyOrThrow(O, "value", part.[[Value]]).
MUST(object->create_data_property_or_throw(vm.names.value, PrimitiveString::create(vm, move(part.value))));
// d. If part.[[Unit]] is not empty, then
if (!part.unit.is_empty()) {
// i. Perform ! CreateDataPropertyOrThrow(O, "unit", part.[[Unit]]).
MUST(object->create_data_property_or_throw(vm.names.unit, PrimitiveString::create(vm, part.unit)));
}
// e. Perform ! CreateDataPropertyOrThrow(result, ! ToString(n), O).
MUST(result->create_data_property_or_throw(n, object));
// f. Increment n by 1.
++n;
}
// 5. Return result.
return result;
}
}
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