/*
* Copyright (c) 2021, Tim Flynn <trflynn89@pm.me>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Array.h>
#include <AK/Utf8View.h>
#include <LibJS/Runtime/Array.h>
#include <LibJS/Runtime/GlobalObject.h>
#include <LibJS/Runtime/Intl/NumberFormat.h>
#include <LibJS/Runtime/Intl/NumberFormatFunction.h>
#include <LibUnicode/CurrencyCode.h>
#include <LibUnicode/Locale.h>
#include <math.h>
#include <stdlib.h>
namespace JS::Intl {
Vector<StringView> const& NumberFormat::relevant_extension_keys()
{
// 15.3.3 Internal slots, https://tc39.es/ecma402/#sec-intl.numberformat-internal-slots
// The value of the [[RelevantExtensionKeys]] internal slot is « "nu" ».
static Vector<StringView> relevant_extension_keys { "nu"sv };
return relevant_extension_keys;
}
// 15 NumberFormat Objects, https://tc39.es/ecma402/#numberformat-objects
NumberFormat::NumberFormat(Object& prototype)
: Object(prototype)
{
}
void NumberFormat::visit_edges(Cell::Visitor& visitor)
{
Base::visit_edges(visitor);
if (m_bound_format)
visitor.visit(m_bound_format);
}
void NumberFormat::set_style(StringView style)
{
if (style == "decimal"sv)
m_style = Style::Decimal;
else if (style == "percent"sv)
m_style = Style::Percent;
else if (style == "currency"sv)
m_style = Style::Currency;
else if (style == "unit"sv)
m_style = Style::Unit;
else
VERIFY_NOT_REACHED();
}
StringView NumberFormat::style_string() const
{
switch (m_style) {
case Style::Decimal:
return "decimal"sv;
case Style::Percent:
return "percent"sv;
case Style::Currency:
return "currency"sv;
case Style::Unit:
return "unit"sv;
default:
VERIFY_NOT_REACHED();
}
}
void NumberFormat::set_currency_display(StringView currency_display)
{
m_resolved_currency_display.clear();
if (currency_display == "code"sv)
m_currency_display = CurrencyDisplay::Code;
else if (currency_display == "symbol"sv)
m_currency_display = CurrencyDisplay::Symbol;
else if (currency_display == "narrowSymbol"sv)
m_currency_display = CurrencyDisplay::NarrowSymbol;
else if (currency_display == "name"sv)
m_currency_display = CurrencyDisplay::Name;
else
VERIFY_NOT_REACHED();
}
StringView NumberFormat::resolve_currency_display()
{
if (m_resolved_currency_display.has_value())
return *m_resolved_currency_display;
switch (currency_display()) {
case NumberFormat::CurrencyDisplay::Code:
m_resolved_currency_display = currency();
break;
case NumberFormat::CurrencyDisplay::Symbol:
m_resolved_currency_display = Unicode::get_locale_currency_mapping(data_locale(), currency(), Unicode::Style::Short);
break;
case NumberFormat::CurrencyDisplay::NarrowSymbol:
m_resolved_currency_display = Unicode::get_locale_currency_mapping(data_locale(), currency(), Unicode::Style::Narrow);
break;
case NumberFormat::CurrencyDisplay::Name:
m_resolved_currency_display = Unicode::get_locale_currency_mapping(data_locale(), currency(), Unicode::Style::Numeric);
break;
default:
VERIFY_NOT_REACHED();
}
if (!m_resolved_currency_display.has_value())
m_resolved_currency_display = currency();
return *m_resolved_currency_display;
}
StringView NumberFormat::currency_display_string() const
{
VERIFY(m_currency_display.has_value());
switch (*m_currency_display) {
case CurrencyDisplay::Code:
return "code"sv;
case CurrencyDisplay::Symbol:
return "symbol"sv;
case CurrencyDisplay::NarrowSymbol:
return "narrowSymbol"sv;
case CurrencyDisplay::Name:
return "name"sv;
default:
VERIFY_NOT_REACHED();
}
}
void NumberFormat::set_currency_sign(StringView currency_sign)
{
if (currency_sign == "standard"sv)
m_currency_sign = CurrencySign::Standard;
else if (currency_sign == "accounting"sv)
m_currency_sign = CurrencySign::Accounting;
else
VERIFY_NOT_REACHED();
}
StringView NumberFormat::currency_sign_string() const
{
VERIFY(m_currency_sign.has_value());
switch (*m_currency_sign) {
case CurrencySign::Standard:
return "standard"sv;
case CurrencySign::Accounting:
return "accounting"sv;
default:
VERIFY_NOT_REACHED();
}
}
void NumberFormat::set_unit_display(StringView unit_display)
{
if (unit_display == "short"sv)
m_unit_display = UnitDisplay::Short;
else if (unit_display == "narrow"sv)
m_unit_display = UnitDisplay::Narrow;
else if (unit_display == "long"sv)
m_unit_display = UnitDisplay::Long;
else
VERIFY_NOT_REACHED();
}
StringView NumberFormat::unit_display_string() const
{
VERIFY(m_unit_display.has_value());
switch (*m_unit_display) {
case UnitDisplay::Short:
return "short"sv;
case UnitDisplay::Narrow:
return "narrow"sv;
case UnitDisplay::Long:
return "long"sv;
default:
VERIFY_NOT_REACHED();
}
}
StringView NumberFormat::rounding_type_string() const
{
switch (m_rounding_type) {
case RoundingType::SignificantDigits:
return "significantDigits"sv;
case RoundingType::FractionDigits:
return "fractionDigits"sv;
case RoundingType::CompactRounding:
return "compactRounding"sv;
default:
VERIFY_NOT_REACHED();
}
}
void NumberFormat::set_notation(StringView notation)
{
if (notation == "standard"sv)
m_notation = Notation::Standard;
else if (notation == "scientific"sv)
m_notation = Notation::Scientific;
else if (notation == "engineering"sv)
m_notation = Notation::Engineering;
else if (notation == "compact"sv)
m_notation = Notation::Compact;
else
VERIFY_NOT_REACHED();
}
StringView NumberFormat::notation_string() const
{
switch (m_notation) {
case Notation::Standard:
return "standard"sv;
case Notation::Scientific:
return "scientific"sv;
case Notation::Engineering:
return "engineering"sv;
case Notation::Compact:
return "compact"sv;
default:
VERIFY_NOT_REACHED();
}
}
void NumberFormat::set_compact_display(StringView compact_display)
{
if (compact_display == "short"sv)
m_compact_display = CompactDisplay::Short;
else if (compact_display == "long"sv)
m_compact_display = CompactDisplay::Long;
else
VERIFY_NOT_REACHED();
}
StringView NumberFormat::compact_display_string() const
{
VERIFY(m_compact_display.has_value());
switch (*m_compact_display) {
case CompactDisplay::Short:
return "short"sv;
case CompactDisplay::Long:
return "long"sv;
default:
VERIFY_NOT_REACHED();
}
}
void NumberFormat::set_sign_display(StringView sign_display)
{
if (sign_display == "auto"sv)
m_sign_display = SignDisplay::Auto;
else if (sign_display == "never"sv)
m_sign_display = SignDisplay::Never;
else if (sign_display == "always"sv)
m_sign_display = SignDisplay::Always;
else if (sign_display == "exceptZero"sv)
m_sign_display = SignDisplay::ExceptZero;
else
VERIFY_NOT_REACHED();
}
StringView NumberFormat::sign_display_string() const
{
switch (m_sign_display) {
case SignDisplay::Auto:
return "auto"sv;
case SignDisplay::Never:
return "never"sv;
case SignDisplay::Always:
return "always"sv;
case SignDisplay::ExceptZero:
return "exceptZero"sv;
default:
VERIFY_NOT_REACHED();
}
}
static ALWAYS_INLINE int log10floor(double value)
{
return static_cast<int>(floor(log10(value)));
}
// 15.1.1 SetNumberFormatDigitOptions ( intlObj, options, mnfdDefault, mxfdDefault, notation ), https://tc39.es/ecma402/#sec-setnfdigitoptions
ThrowCompletionOr<void> set_number_format_digit_options(GlobalObject& global_object, NumberFormat& intl_object, Object const& options, int default_min_fraction_digits, int default_max_fraction_digits, NumberFormat::Notation notation)
{
auto& vm = global_object.vm();
// 1. Assert: Type(intlObj) is Object.
// 2. Assert: Type(options) is Object.
// 3. Assert: Type(mnfdDefault) is Number.
// 4. Assert: Type(mxfdDefault) is Number.
// 5. Let mnid be ? GetNumberOption(options, "minimumIntegerDigits,", 1, 21, 1).
auto min_integer_digits = TRY(get_number_option(global_object, options, vm.names.minimumIntegerDigits, 1, 21, 1));
// 6. Let mnfd be ? Get(options, "minimumFractionDigits").
auto min_fraction_digits = TRY(options.get(vm.names.minimumFractionDigits));
// 7. Let mxfd be ? Get(options, "maximumFractionDigits").
auto max_fraction_digits = TRY(options.get(vm.names.maximumFractionDigits));
// 8. Let mnsd be ? Get(options, "minimumSignificantDigits").
auto min_significant_digits = TRY(options.get(vm.names.minimumSignificantDigits));
// 9. Let mxsd be ? Get(options, "maximumSignificantDigits").
auto max_significant_digits = TRY(options.get(vm.names.maximumSignificantDigits));
// 10. Set intlObj.[[MinimumIntegerDigits]] to mnid.
intl_object.set_min_integer_digits(*min_integer_digits);
// 11. If mnsd is not undefined or mxsd is not undefined, then
if (!min_significant_digits.is_undefined() || !max_significant_digits.is_undefined()) {
// a. Set intlObj.[[RoundingType]] to significantDigits.
intl_object.set_rounding_type(NumberFormat::RoundingType::SignificantDigits);
// b. Let mnsd be ? DefaultNumberOption(mnsd, 1, 21, 1).
auto min_digits = TRY(default_number_option(global_object, min_significant_digits, 1, 21, 1));
// c. Let mxsd be ? DefaultNumberOption(mxsd, mnsd, 21, 21).
auto max_digits = TRY(default_number_option(global_object, max_significant_digits, *min_digits, 21, 21));
// d. Set intlObj.[[MinimumSignificantDigits]] to mnsd.
intl_object.set_min_significant_digits(*min_digits);
// e. Set intlObj.[[MaximumSignificantDigits]] to mxsd.
intl_object.set_max_significant_digits(*max_digits);
}
// 12. Else if mnfd is not undefined or mxfd is not undefined, then
else if (!min_fraction_digits.is_undefined() || !max_fraction_digits.is_undefined()) {
// a. Set intlObj.[[RoundingType]] to fractionDigits.
intl_object.set_rounding_type(NumberFormat::RoundingType::FractionDigits);
// b. Let mnfd be ? DefaultNumberOption(mnfd, 0, 20, undefined).
auto min_digits = TRY(default_number_option(global_object, min_fraction_digits, 0, 20, {}));
// c. Let mxfd be ? DefaultNumberOption(mxfd, 0, 20, undefined).
auto max_digits = TRY(default_number_option(global_object, max_fraction_digits, 0, 20, {}));
// d. If mnfd is undefined, set mnfd to min(mnfdDefault, mxfd).
if (!min_digits.has_value())
min_digits = min(default_min_fraction_digits, *max_digits);
// e. Else if mxfd is undefined, set mxfd to max(mxfdDefault, mnfd).
else if (!max_digits.has_value())
max_digits = max(default_max_fraction_digits, *min_digits);
// f. Else if mnfd is greater than mxfd, throw a RangeError exception.
else if (*min_digits > *max_digits)
return vm.throw_completion<RangeError>(global_object, ErrorType::IntlMinimumExceedsMaximum, *min_digits, *max_digits);
// g. Set intlObj.[[MinimumFractionDigits]] to mnfd.
intl_object.set_min_fraction_digits(*min_digits);
// h. Set intlObj.[[MaximumFractionDigits]] to mxfd.
intl_object.set_max_fraction_digits(*max_digits);
}
// 13. Else if notation is "compact", then
else if (notation == NumberFormat::Notation::Compact) {
// a. Set intlObj.[[RoundingType]] to compactRounding.
intl_object.set_rounding_type(NumberFormat::RoundingType::CompactRounding);
}
// 14. Else,
else {
// a. Set intlObj.[[RoundingType]] to fractionDigits.
intl_object.set_rounding_type(NumberFormat::RoundingType::FractionDigits);
// b. Set intlObj.[[MinimumFractionDigits]] to mnfdDefault.
intl_object.set_min_fraction_digits(default_min_fraction_digits);
// c. Set intlObj.[[MaximumFractionDigits]] to mxfdDefault.
intl_object.set_max_fraction_digits(default_max_fraction_digits);
}
return {};
}
// 15.1.2 InitializeNumberFormat ( numberFormat, locales, options ), https://tc39.es/ecma402/#sec-initializenumberformat
ThrowCompletionOr<NumberFormat*> initialize_number_format(GlobalObject& global_object, NumberFormat& number_format, Value locales_value, Value options_value)
{
auto& vm = global_object.vm();
// 1. Let requestedLocales be ? CanonicalizeLocaleList(locales).
auto requested_locales = TRY(canonicalize_locale_list(global_object, locales_value));
// 2. Set options to ? CoerceOptionsToObject(options).
auto* options = TRY(coerce_options_to_object(global_object, options_value));
// 3. Let opt be a new Record.
LocaleOptions opt {};
// 4. Let matcher be ? GetOption(options, "localeMatcher", "string", « "lookup", "best fit" », "best fit").
auto matcher = TRY(get_option(global_object, *options, vm.names.localeMatcher, Value::Type::String, { "lookup"sv, "best fit"sv }, "best fit"sv));
// 5. Set opt.[[localeMatcher]] to matcher.
opt.locale_matcher = matcher;
// 6. Let numberingSystem be ? GetOption(options, "numberingSystem", "string", undefined, undefined).
auto numbering_system = TRY(get_option(global_object, *options, vm.names.numberingSystem, Value::Type::String, {}, Empty {}));
// 7. If numberingSystem is not undefined, then
if (!numbering_system.is_undefined()) {
// a. If numberingSystem does not match the Unicode Locale Identifier type nonterminal, throw a RangeError exception.
if (!Unicode::is_type_identifier(numbering_system.as_string().string()))
return vm.throw_completion<RangeError>(global_object, ErrorType::OptionIsNotValidValue, numbering_system, "numberingSystem"sv);
// 8. Set opt.[[nu]] to numberingSystem.
opt.nu = numbering_system.as_string().string();
}
// 9. Let localeData be %NumberFormat%.[[LocaleData]].
// 10. Let r be ResolveLocale(%NumberFormat%.[[AvailableLocales]], requestedLocales, opt, %NumberFormat%.[[RelevantExtensionKeys]], localeData).
auto result = resolve_locale(requested_locales, opt, NumberFormat::relevant_extension_keys());
// 11. Set numberFormat.[[Locale]] to r.[[locale]].
number_format.set_locale(move(result.locale));
// 12. Set numberFormat.[[DataLocale]] to r.[[dataLocale]].
number_format.set_data_locale(move(result.data_locale));
// 13. Set numberFormat.[[NumberingSystem]] to r.[[nu]].
number_format.set_numbering_system(result.nu.release_value());
// 14. Perform ? SetNumberFormatUnitOptions(numberFormat, options).
TRY(set_number_format_unit_options(global_object, number_format, *options));
// 15. Let style be numberFormat.[[Style]].
auto style = number_format.style();
int default_min_fraction_digits = 0;
int default_max_fraction_digits = 0;
// 16. If style is "currency", then
if (style == NumberFormat::Style::Currency) {
// a. Let currency be numberFormat.[[Currency]].
auto const& currency = number_format.currency();
// b. Let cDigits be CurrencyDigits(currency).
int digits = currency_digits(currency);
// c. Let mnfdDefault be cDigits.
default_min_fraction_digits = digits;
// d. Let mxfdDefault be cDigits.
default_max_fraction_digits = digits;
}
// 17. Else,
else {
// a. Let mnfdDefault be 0.
default_min_fraction_digits = 0;
// b. If style is "percent", then
// i. Let mxfdDefault be 0.
// c. Else,
// i. Let mxfdDefault be 3.
default_max_fraction_digits = style == NumberFormat::Style::Percent ? 0 : 3;
}
// 18. Let notation be ? GetOption(options, "notation", "string", « "standard", "scientific", "engineering", "compact" », "standard").
auto notation = TRY(get_option(global_object, *options, vm.names.notation, Value::Type::String, { "standard"sv, "scientific"sv, "engineering"sv, "compact"sv }, "standard"sv));
// 19. Set numberFormat.[[Notation]] to notation.
number_format.set_notation(notation.as_string().string());
// 20. Perform ? SetNumberFormatDigitOptions(numberFormat, options, mnfdDefault, mxfdDefault, notation).
TRY(set_number_format_digit_options(global_object, number_format, *options, default_min_fraction_digits, default_max_fraction_digits, number_format.notation()));
// 21. Let compactDisplay be ? GetOption(options, "compactDisplay", "string", « "short", "long" », "short").
auto compact_display = TRY(get_option(global_object, *options, vm.names.compactDisplay, Value::Type::String, { "short"sv, "long"sv }, "short"sv));
// 22. If notation is "compact", then
if (number_format.notation() == NumberFormat::Notation::Compact) {
// a. Set numberFormat.[[CompactDisplay]] to compactDisplay.
number_format.set_compact_display(compact_display.as_string().string());
}
// 23. Let useGrouping be ? GetOption(options, "useGrouping", "boolean", undefined, true).
auto use_grouping = TRY(get_option(global_object, *options, vm.names.useGrouping, Value::Type::Boolean, {}, true));
// 24. Set numberFormat.[[UseGrouping]] to useGrouping.
number_format.set_use_grouping(use_grouping.as_bool());
// 25. Let signDisplay be ? GetOption(options, "signDisplay", "string", « "auto", "never", "always", "exceptZero" », "auto").
auto sign_display = TRY(get_option(global_object, *options, vm.names.signDisplay, Value::Type::String, { "auto"sv, "never"sv, "always"sv, "exceptZero"sv }, "auto"sv));
// 26. Set numberFormat.[[SignDisplay]] to signDisplay.
number_format.set_sign_display(sign_display.as_string().string());
// 27. Return numberFormat.
return &number_format;
}
// 15.1.3 CurrencyDigits ( currency ), https://tc39.es/ecma402/#sec-currencydigits
int currency_digits(StringView currency)
{
// 1. If the ISO 4217 currency and funds code list contains currency as an alphabetic code, return the minor
// unit value corresponding to the currency from the list; otherwise, return 2.
if (auto currency_code = Unicode::get_currency_code(currency); currency_code.has_value())
return currency_code->minor_unit.value_or(2);
return 2;
}
// 15.1.5 FormatNumericToString ( intlObject, x ), https://tc39.es/ecma402/#sec-formatnumberstring
FormatResult format_numeric_to_string(NumberFormat& number_format, double number)
{
// 1. If x < 0 or x is -0𝔽, let isNegative be true; else let isNegative be false.
bool is_negative = (number < 0.0) || Value(number).is_negative_zero();
// 2. If isNegative, then
if (is_negative) {
// a. Let x be -x.
number *= -1;
}
RawFormatResult result {};
switch (number_format.rounding_type()) {
// 3. If intlObject.[[RoundingType]] is significantDigits, then
case NumberFormat::RoundingType::SignificantDigits:
// a. Let result be ToRawPrecision(x, intlObject.[[MinimumSignificantDigits]], intlObject.[[MaximumSignificantDigits]]).
result = to_raw_precision(number, number_format.min_significant_digits(), number_format.max_significant_digits());
break;
// 4. Else if intlObject.[[RoundingType]] is fractionDigits, then
case NumberFormat::RoundingType::FractionDigits:
// a. Let result be ToRawFixed(x, intlObject.[[MinimumFractionDigits]], intlObject.[[MaximumFractionDigits]]).
result = to_raw_fixed(number, number_format.min_fraction_digits(), number_format.max_fraction_digits());
break;
// 5. Else,
case NumberFormat::RoundingType::CompactRounding:
// a. Assert: intlObject.[[RoundingType]] is compactRounding.
// b. Let result be ToRawPrecision(x, 1, 2).
result = to_raw_precision(number, 1, 2);
// c. If result.[[IntegerDigitsCount]] > 1, then
if (result.digits > 1) {
// i. Let result be ToRawFixed(x, 0, 0).
result = to_raw_fixed(number, 0, 0);
}
break;
default:
VERIFY_NOT_REACHED();
}
// 6. Let x be result.[[RoundedNumber]].
number = result.rounded_number;
// 7. Let string be result.[[FormattedString]].
auto string = move(result.formatted_string);
// 8. Let int be result.[[IntegerDigitsCount]].
int digits = result.digits;
// 9. Let minInteger be intlObject.[[MinimumIntegerDigits]].
int min_integer = number_format.min_integer_digits();
// 10. If int < minInteger, then
if (digits < min_integer) {
// a. Let forwardZeros be the String consisting of minInteger–int occurrences of the character "0".
auto forward_zeros = String::repeated('0', min_integer - digits);
// b. Set string to the string-concatenation of forwardZeros and string.
string = String::formatted("{}{}", forward_zeros, string);
}
// 11. If isNegative, then
if (is_negative) {
// a. Let x be -x.
number *= -1;
}
// 12. Return the Record { [[RoundedNumber]]: x, [[FormattedString]]: string }.
return { move(string), number };
}
// 15.1.6 PartitionNumberPattern ( numberFormat, x ), https://tc39.es/ecma402/#sec-partitionnumberpattern
Vector<PatternPartition> partition_number_pattern(NumberFormat& number_format, double number)
{
// 1. Let exponent be 0.
int exponent = 0;
String formatted_string;
// 2. If x is NaN, then
if (Value(number).is_nan()) {
// a. Let n be an implementation- and locale-dependent (ILD) String value indicating the NaN value.
formatted_string = Unicode::get_number_system_symbol(number_format.data_locale(), number_format.numbering_system(), "nan"sv).value_or("NaN"sv);
}
// 3. Else if x is a non-finite Number, then
else if (!Value(number).is_finite_number()) {
// a. Let n be an ILD String value indicating infinity.
formatted_string = Unicode::get_number_system_symbol(number_format.data_locale(), number_format.numbering_system(), "infinity"sv).value_or("infinity"sv);
}
// 4. Else,
else {
// a. If numberFormat.[[Style]] is "percent", let x be 100 × x.
if (number_format.style() == NumberFormat::Style::Percent)
number = number * 100;
// b. Let exponent be ComputeExponent(numberFormat, x).
exponent = compute_exponent(number_format, number);
// c. Let x be x × 10^(-exponent).
number *= pow(10, -exponent);
// d. Let formatNumberResult be FormatNumericToString(numberFormat, x).
auto format_number_result = format_numeric_to_string(number_format, number);
// e. Let n be formatNumberResult.[[FormattedString]].
formatted_string = move(format_number_result.formatted_string);
// f. Let x be formatNumberResult.[[RoundedNumber]].
number = format_number_result.rounded_number;
}
// 5. Let pattern be GetNumberFormatPattern(numberFormat, x).
auto pattern = get_number_format_pattern(number_format, number);
if (!pattern.has_value())
return {};
// 6. Let result be a new empty List.
Vector<PatternPartition> result;
// 7. Let patternParts be PartitionPattern(pattern).
auto pattern_parts = pattern->visit([](auto const& p) { return partition_pattern(p); });
// 8. For each Record { [[Type]], [[Value]] } patternPart of patternParts, do
for (auto& pattern_part : pattern_parts) {
// a. Let p be patternPart.[[Type]].
auto part = pattern_part.type;
// b. If p is "literal", then
if (part == "literal"sv) {
// i. Append a new Record { [[Type]]: "literal", [[Value]]: patternPart.[[Value]] } as the last element of result.
result.append({ "literal"sv, move(pattern_part.value) });
}
// c. Else if p is equal to "number", then
else if (part == "number"sv) {
// i. Let notationSubParts be PartitionNotationSubPattern(numberFormat, x, n, exponent).
auto notation_sub_parts = partition_notation_sub_pattern(number_format, number, formatted_string, exponent);
// ii. Append all elements of notationSubParts to result.
result.extend(move(notation_sub_parts));
}
// d. Else if p is equal to "plusSign", then
else if (part == "plusSign"sv) {
// i. Let plusSignSymbol be the ILND String representing the plus sign.
auto plus_sign_symbol = Unicode::get_number_system_symbol(number_format.data_locale(), number_format.numbering_system(), "plusSign"sv).value_or("+"sv);
// ii. Append a new Record { [[Type]]: "plusSign", [[Value]]: plusSignSymbol } as the last element of result.
result.append({ "plusSign"sv, plus_sign_symbol });
}
// e. Else if p is equal to "minusSign", then
else if (part == "minusSign"sv) {
// i. Let minusSignSymbol be the ILND String representing the minus sign.
auto minus_sign_symbol = Unicode::get_number_system_symbol(number_format.data_locale(), number_format.numbering_system(), "minusSign"sv).value_or("-"sv);
// ii. Append a new Record { [[Type]]: "minusSign", [[Value]]: minusSignSymbol } as the last element of result.
result.append({ "minusSign"sv, minus_sign_symbol });
}
// f. Else if p is equal to "percentSign" and numberFormat.[[Style]] is "percent", then
else if ((part == "percentSign"sv) && (number_format.style() == NumberFormat::Style::Percent)) {
// i. Let percentSignSymbol be the ILND String representing the percent sign.
auto percent_sign_symbol = Unicode::get_number_system_symbol(number_format.data_locale(), number_format.numbering_system(), "percentSign"sv).value_or("%"sv);
// ii. Append a new Record { [[Type]]: "percentSign", [[Value]]: percentSignSymbol } as the last element of result.
result.append({ "percentSign"sv, percent_sign_symbol });
}
// g. Else if p is equal to "unitPrefix" and numberFormat.[[Style]] is "unit", then
else if ((part == "unitPrefix"sv) && (number_format.style() == NumberFormat::Style::Unit)) {
// i. Let unit be numberFormat.[[Unit]].
// ii. Let unitDisplay be numberFormat.[[UnitDisplay]].
// iii. Let mu be an ILD String value representing unit before x in unitDisplay form, which may depend on x in languages having different plural forms.
// iv. Append a new Record { [[Type]]: "unit", [[Value]]: mu } as the last element of result.
// FIXME: LibUnicode will need to parse the cldr-units package.
}
// h. Else if p is equal to "unitSuffix" and numberFormat.[[Style]] is "unit", then
else if ((part == "unitSuffix"sv) && (number_format.style() == NumberFormat::Style::Unit)) {
// i. Let unit be numberFormat.[[Unit]].
// ii. Let unitDisplay be numberFormat.[[UnitDisplay]].
// iii. Let mu be an ILD String value representing unit after x in unitDisplay form, which may depend on x in languages having different plural forms.
// iv. Append a new Record { [[Type]]: "unit", [[Value]]: mu } as the last element of result.
// FIXME: LibUnicode will need to parse the cldr-units package.
}
// i. Else if p is equal to "currencyCode" and numberFormat.[[Style]] is "currency", then
// j. Else if p is equal to "currencyPrefix" and numberFormat.[[Style]] is "currency", then
// k. Else if p is equal to "currencySuffix" and numberFormat.[[Style]] is "currency", then
//
// Note: Our implementation manipulates the format string to inject/remove spacing around the
// currency code during GetNumberFormatPattern so that we do not have to do currency
// display / plurality lookups more than once.
else if ((part == "currency"sv) && (number_format.style() == NumberFormat::Style::Currency)) {
result.append({ "currency"sv, number_format.resolve_currency_display() });
}
// l. Else,
else {
// i. Let unknown be an ILND String based on x and p.
// ii. Append a new Record { [[Type]]: "unknown", [[Value]]: unknown } as the last element of result.
// LibUnicode doesn't generate any "unknown" patterns.
VERIFY_NOT_REACHED();
}
}
// 9. Return result.
return result;
}
static String replace_digits_for_number_format(NumberFormat& number_format, String formatted_string)
{
// https://tc39.es/ecma402/#table-numbering-system-digits
static HashMap<StringView, AK::Array<u32, 10>> s_numbering_system_digits = {
{ "adlm"sv, { 0x1e950, 0x1e951, 0x1e952, 0x1e953, 0x1e954, 0x1e955, 0x1e956, 0x1e957, 0x1e958, 0x1e959 } },
{ "ahom"sv, { 0x11730, 0x11731, 0x11732, 0x11733, 0x11734, 0x11735, 0x11736, 0x11737, 0x11738, 0x11739 } },
{ "arab"sv, { 0x660, 0x661, 0x662, 0x663, 0x664, 0x665, 0x666, 0x667, 0x668, 0x669 } },
{ "arabext"sv, { 0x6f0, 0x6f1, 0x6f2, 0x6f3, 0x6f4, 0x6f5, 0x6f6, 0x6f7, 0x6f8, 0x6f9 } },
{ "bali"sv, { 0x1b50, 0x1b51, 0x1b52, 0x1b53, 0x1b54, 0x1b55, 0x1b56, 0x1b57, 0x1b58, 0x1b59 } },
{ "beng"sv, { 0x9e6, 0x9e7, 0x9e8, 0x9e9, 0x9ea, 0x9eb, 0x9ec, 0x9ed, 0x9ee, 0x9ef } },
{ "bhks"sv, { 0x11c50, 0x11c51, 0x11c52, 0x11c53, 0x11c54, 0x11c55, 0x11c56, 0x11c57, 0x11c58, 0x11c59 } },
{ "brah"sv, { 0x11066, 0x11067, 0x11068, 0x11069, 0x1106a, 0x1106b, 0x1106c, 0x1106d, 0x1106e, 0x1106f } },
{ "cakm"sv, { 0x11136, 0x11137, 0x11138, 0x11139, 0x1113a, 0x1113b, 0x1113c, 0x1113d, 0x1113e, 0x1113f } },
{ "cham"sv, { 0xaa50, 0xaa51, 0xaa52, 0xaa53, 0xaa54, 0xaa55, 0xaa56, 0xaa57, 0xaa58, 0xaa59 } },
{ "deva"sv, { 0x966, 0x967, 0x968, 0x969, 0x96a, 0x96b, 0x96c, 0x96d, 0x96e, 0x96f } },
{ "diak"sv, { 0x11950, 0x11951, 0x11952, 0x11953, 0x11954, 0x11955, 0x11956, 0x11957, 0x11958, 0x11959 } },
{ "fullwide"sv, { 0xff10, 0xff11, 0xff12, 0xff13, 0xff14, 0xff15, 0xff16, 0xff17, 0xff18, 0xff19 } },
{ "gong"sv, { 0x11da0, 0x11da1, 0x11da2, 0x11da3, 0x11da4, 0x11da5, 0x11da6, 0x11da7, 0x11da8, 0x11da9 } },
{ "gonm"sv, { 0x11d50, 0x11d51, 0x11d52, 0x11d53, 0x11d54, 0x11d55, 0x11d56, 0x11d57, 0x11d58, 0x11d59 } },
{ "gujr"sv, { 0xae6, 0xae7, 0xae8, 0xae9, 0xaea, 0xaeb, 0xaec, 0xaed, 0xaee, 0xaef } },
{ "guru"sv, { 0xa66, 0xa67, 0xa68, 0xa69, 0xa6a, 0xa6b, 0xa6c, 0xa6d, 0xa6e, 0xa6f } },
{ "hanidec"sv, { 0x3007, 0x4e00, 0x4e8c, 0x4e09, 0x56db, 0x4e94, 0x516d, 0x4e03, 0x516b, 0x4e5d } },
{ "hmng"sv, { 0x16b50, 0x16b51, 0x16b52, 0x16b53, 0x16b54, 0x16b55, 0x16b56, 0x16b57, 0x16b58, 0x16b59 } },
{ "hmnp"sv, { 0x1e140, 0x1e141, 0x1e142, 0x1e143, 0x1e144, 0x1e145, 0x1e146, 0x1e147, 0x1e148, 0x1e149 } },
{ "java"sv, { 0xa9d0, 0xa9d1, 0xa9d2, 0xa9d3, 0xa9d4, 0xa9d5, 0xa9d6, 0xa9d7, 0xa9d8, 0xa9d9 } },
{ "kali"sv, { 0xa900, 0xa901, 0xa902, 0xa903, 0xa904, 0xa905, 0xa906, 0xa907, 0xa908, 0xa909 } },
{ "khmr"sv, { 0x17e0, 0x17e1, 0x17e2, 0x17e3, 0x17e4, 0x17e5, 0x17e6, 0x17e7, 0x17e8, 0x17e9 } },
{ "knda"sv, { 0xce6, 0xce7, 0xce8, 0xce9, 0xcea, 0xceb, 0xcec, 0xced, 0xcee, 0xcef } },
{ "lana"sv, { 0x1a80, 0x1a81, 0x1a82, 0x1a83, 0x1a84, 0x1a85, 0x1a86, 0x1a87, 0x1a88, 0x1a89 } },
{ "lanatham"sv, { 0x1a90, 0x1a91, 0x1a92, 0x1a93, 0x1a94, 0x1a95, 0x1a96, 0x1a97, 0x1a98, 0x1a99 } },
{ "laoo"sv, { 0xed0, 0xed1, 0xed2, 0xed3, 0xed4, 0xed5, 0xed6, 0xed7, 0xed8, 0xed9 } },
{ "latn"sv, { 0x30, 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39 } },
{ "lepc"sv, { 0x1c40, 0x1c41, 0x1c42, 0x1c43, 0x1c44, 0x1c45, 0x1c46, 0x1c47, 0x1c48, 0x1c49 } },
{ "limb"sv, { 0x1946, 0x1947, 0x1948, 0x1949, 0x194a, 0x194b, 0x194c, 0x194d, 0x194e, 0x194f } },
{ "mathbold"sv, { 0x1d7ce, 0x1d7cf, 0x1d7d0, 0x1d7d1, 0x1d7d2, 0x1d7d3, 0x1d7d4, 0x1d7d5, 0x1d7d6, 0x1d7d7 } },
{ "mathdbl"sv, { 0x1d7d8, 0x1d7d9, 0x1d7da, 0x1d7db, 0x1d7dc, 0x1d7dd, 0x1d7de, 0x1d7df, 0x1d7e0, 0x1d7e1 } },
{ "mathmono"sv, { 0x1d7f6, 0x1d7f7, 0x1d7f8, 0x1d7f9, 0x1d7fa, 0x1d7fb, 0x1d7fc, 0x1d7fd, 0x1d7fe, 0x1d7ff } },
{ "mathsanb"sv, { 0x1d7ec, 0x1d7ed, 0x1d7ee, 0x1d7ef, 0x1d7f0, 0x1d7f1, 0x1d7f2, 0x1d7f3, 0x1d7f4, 0x1d7f5 } },
{ "mathsans"sv, { 0x1d7e2, 0x1d7e3, 0x1d7e4, 0x1d7e5, 0x1d7e6, 0x1d7e7, 0x1d7e8, 0x1d7e9, 0x1d7ea, 0x1d7eb } },
{ "mlym"sv, { 0xd66, 0xd67, 0xd68, 0xd69, 0xd6a, 0xd6b, 0xd6c, 0xd6d, 0xd6e, 0xd6f } },
{ "modi"sv, { 0x11650, 0x11651, 0x11652, 0x11653, 0x11654, 0x11655, 0x11656, 0x11657, 0x11658, 0x11659 } },
{ "mong"sv, { 0x1810, 0x1811, 0x1812, 0x1813, 0x1814, 0x1815, 0x1816, 0x1817, 0x1818, 0x1819 } },
{ "mroo"sv, { 0x16a60, 0x16a61, 0x16a62, 0x16a63, 0x16a64, 0x16a65, 0x16a66, 0x16a67, 0x16a68, 0x16a69 } },
{ "mtei"sv, { 0xabf0, 0xabf1, 0xabf2, 0xabf3, 0xabf4, 0xabf5, 0xabf6, 0xabf7, 0xabf8, 0xabf9 } },
{ "mymr"sv, { 0x1040, 0x1041, 0x1042, 0x1043, 0x1044, 0x1045, 0x1046, 0x1047, 0x1048, 0x1049 } },
{ "mymrshan"sv, { 0x1090, 0x1091, 0x1092, 0x1093, 0x1094, 0x1095, 0x1096, 0x1097, 0x1098, 0x1099 } },
{ "mymrtlng"sv, { 0xa9f0, 0xa9f1, 0xa9f2, 0xa9f3, 0xa9f4, 0xa9f5, 0xa9f6, 0xa9f7, 0xa9f8, 0xa9f9 } },
{ "newa"sv, { 0x11450, 0x11451, 0x11452, 0x11453, 0x11454, 0x11455, 0x11456, 0x11457, 0x11458, 0x11459 } },
{ "nkoo"sv, { 0x7c0, 0x7c1, 0x7c2, 0x7c3, 0x7c4, 0x7c5, 0x7c6, 0x7c7, 0x7c8, 0x7c9 } },
{ "olck"sv, { 0x1c50, 0x1c51, 0x1c52, 0x1c53, 0x1c54, 0x1c55, 0x1c56, 0x1c57, 0x1c58, 0x1c59 } },
{ "orya"sv, { 0xb66, 0xb67, 0xb68, 0xb69, 0xb6a, 0xb6b, 0xb6c, 0xb6d, 0xb6e, 0xb6f } },
{ "osma"sv, { 0x104a0, 0x104a1, 0x104a2, 0x104a3, 0x104a4, 0x104a5, 0x104a6, 0x104a7, 0x104a8, 0x104a9 } },
{ "rohg"sv, { 0x10d30, 0x10d31, 0x10d32, 0x10d33, 0x10d34, 0x10d35, 0x10d36, 0x10d37, 0x10d38, 0x10d39 } },
{ "saur"sv, { 0xa8d0, 0xa8d1, 0xa8d2, 0xa8d3, 0xa8d4, 0xa8d5, 0xa8d6, 0xa8d7, 0xa8d8, 0xa8d9 } },
{ "segment"sv, { 0x1fbf0, 0x1fbf1, 0x1fbf2, 0x1fbf3, 0x1fbf4, 0x1fbf5, 0x1fbf6, 0x1fbf7, 0x1fbf8, 0x1fbf9 } },
{ "shrd"sv, { 0x111d0, 0x111d1, 0x111d2, 0x111d3, 0x111d4, 0x111d5, 0x111d6, 0x111d7, 0x111d8, 0x111d9 } },
{ "sind"sv, { 0x112f0, 0x112f1, 0x112f2, 0x112f3, 0x112f4, 0x112f5, 0x112f6, 0x112f7, 0x112f8, 0x112f9 } },
{ "sinh"sv, { 0xde6, 0xde7, 0xde8, 0xde9, 0xdea, 0xdeb, 0xdec, 0xded, 0xdee, 0xdef } },
{ "sora"sv, { 0x110f0, 0x110f1, 0x110f2, 0x110f3, 0x110f4, 0x110f5, 0x110f6, 0x110f7, 0x110f8, 0x110f9 } },
{ "sund"sv, { 0x1bb0, 0x1bb1, 0x1bb2, 0x1bb3, 0x1bb4, 0x1bb5, 0x1bb6, 0x1bb7, 0x1bb8, 0x1bb9 } },
{ "takr"sv, { 0x116c0, 0x116c1, 0x116c2, 0x116c3, 0x116c4, 0x116c5, 0x116c6, 0x116c7, 0x116c8, 0x116c9 } },
{ "talu"sv, { 0x19d0, 0x19d1, 0x19d2, 0x19d3, 0x19d4, 0x19d5, 0x19d6, 0x19d7, 0x19d8, 0x19d9 } },
{ "tamldec"sv, { 0xbe6, 0xbe7, 0xbe8, 0xbe9, 0xbea, 0xbeb, 0xbec, 0xbed, 0xbee, 0xbef } },
{ "telu"sv, { 0xc66, 0xc67, 0xc68, 0xc69, 0xc6a, 0xc6b, 0xc6c, 0xc6d, 0xc6e, 0xc6f } },
{ "thai"sv, { 0xe50, 0xe51, 0xe52, 0xe53, 0xe54, 0xe55, 0xe56, 0xe57, 0xe58, 0xe59 } },
{ "tibt"sv, { 0xf20, 0xf21, 0xf22, 0xf23, 0xf24, 0xf25, 0xf26, 0xf27, 0xf28, 0xf29 } },
{ "tirh"sv, { 0x114d0, 0x114d1, 0x114d2, 0x114d3, 0x114d4, 0x114d5, 0x114d6, 0x114d7, 0x114d8, 0x114d9 } },
{ "vaii"sv, { 0xa620, 0xa621, 0xa622, 0xa623, 0xa624, 0xa625, 0xa626, 0xa627, 0xa628, 0xa629 } },
{ "wara"sv, { 0x118e0, 0x118e1, 0x118e2, 0x118e3, 0x118e4, 0x118e5, 0x118e6, 0x118e7, 0x118e8, 0x118e9 } },
{ "wcho"sv, { 0x1e2f0, 0x1e2f1, 0x1e2f2, 0x1e2f3, 0x1e2f4, 0x1e2f5, 0x1e2f6, 0x1e2f7, 0x1e2f8, 0x1e2f9 } },
};
auto digits = s_numbering_system_digits.get(number_format.numbering_system());
if (!digits.has_value())
digits = s_numbering_system_digits.get("latn"sv);
VERIFY(digits.has_value());
StringBuilder builder;
for (auto& ch : formatted_string) {
if (is_ascii_digit(ch)) {
u32 digit = digits->at(parse_ascii_digit(ch));
builder.append_code_point(digit);
} else {
builder.append(ch);
}
}
return builder.build();
}
static Vector<StringView> separate_integer_into_groups(Unicode::NumberGroupings const& grouping_sizes, StringView integer)
{
Utf8View utf8_integer { integer };
Vector<StringView> groups;
auto add_group = [&](size_t index, size_t length) {
groups.prepend(utf8_integer.unicode_substring_view(index, length).as_string());
};
if (utf8_integer.length() > grouping_sizes.primary_grouping_size) {
size_t index = utf8_integer.length() - grouping_sizes.primary_grouping_size;
add_group(index, grouping_sizes.primary_grouping_size);
while (index > grouping_sizes.secondary_grouping_size) {
index -= grouping_sizes.secondary_grouping_size;
add_group(index, grouping_sizes.secondary_grouping_size);
}
if (index > 0)
add_group(0, index);
} else {
groups.append(integer);
}
return groups;
}
// 15.1.7 PartitionNotationSubPattern ( numberFormat, x, n, exponent ), https://tc39.es/ecma402/#sec-partitionnotationsubpattern
Vector<PatternPartition> partition_notation_sub_pattern(NumberFormat& number_format, double number, String formatted_string, int exponent)
{
// 1. Let result be a new empty List.
Vector<PatternPartition> result;
auto grouping_sizes = Unicode::get_number_system_groupings(number_format.data_locale(), number_format.numbering_system());
if (!grouping_sizes.has_value())
return {};
// 2. If x is NaN, then
if (Value(number).is_nan()) {
// a. Append a new Record { [[Type]]: "nan", [[Value]]: n } as the last element of result.
result.append({ "nan"sv, move(formatted_string) });
}
// 3. Else if x is a non-finite Number, then
else if (!Value(number).is_finite_number()) {
// a. Append a new Record { [[Type]]: "infinity", [[Value]]: n } as the last element of result.
result.append({ "infinity"sv, move(formatted_string) });
}
// 4. Else,
else {
// a. Let notationSubPattern be GetNotationSubPattern(numberFormat, exponent).
auto notation_sub_pattern = get_notation_sub_pattern(number_format, exponent);
// b. Let patternParts be PartitionPattern(notationSubPattern).
auto pattern_parts = partition_pattern(notation_sub_pattern);
// c. For each Record { [[Type]], [[Value]] } patternPart of patternParts, do
for (auto& pattern_part : pattern_parts) {
// i. Let p be patternPart.[[Type]].
auto part = pattern_part.type;
// ii. If p is "literal", then
if (part == "literal"sv) {
// 1. Append a new Record { [[Type]]: "literal", [[Value]]: patternPart.[[Value]] } as the last element of result.
result.append({ "literal"sv, move(pattern_part.value) });
}
// iii. Else if p is equal to "number", then
else if (part == "number"sv) {
// 1. If the numberFormat.[[NumberingSystem]] matches one of the values in the "Numbering System" column of Table 10 below, then
// a. Let digits be a List whose 10 String valued elements are the UTF-16 string representations of the 10 digits specified in the "Digits" column of the matching row in Table 10.
// b. Replace each digit in n with the value of digits[digit].
// 2. Else use an implementation dependent algorithm to map n to the appropriate representation of n in the given numbering system.
formatted_string = replace_digits_for_number_format(number_format, move(formatted_string));
// 3. Let decimalSepIndex be ! StringIndexOf(n, ".", 0).
auto decimal_sep_index = formatted_string.find('.');
StringView integer;
Optional<StringView> fraction;
// 4. If decimalSepIndex > 0, then
if (decimal_sep_index.has_value() && (*decimal_sep_index > 0)) {
// a. Let integer be the substring of n from position 0, inclusive, to position decimalSepIndex, exclusive.
integer = formatted_string.substring_view(0, *decimal_sep_index);
// b. Let fraction be the substring of n from position decimalSepIndex, exclusive, to the end of n.
fraction = formatted_string.substring_view(*decimal_sep_index + 1);
}
// 5. Else,
else {
// a. Let integer be n.
integer = formatted_string;
// b. Let fraction be undefined.
}
// 6. If the numberFormat.[[UseGrouping]] is true, then
if (number_format.use_grouping()) {
// a. Let groupSepSymbol be the implementation-, locale-, and numbering system-dependent (ILND) String representing the grouping separator.
auto group_sep_symbol = Unicode::get_number_system_symbol(number_format.data_locale(), number_format.numbering_system(), "group"sv).value_or(","sv);
// b. Let groups be a List whose elements are, in left to right order, the substrings defined by ILND set of locations within the integer.
auto groups = separate_integer_into_groups(*grouping_sizes, integer);
// c. Assert: The number of elements in groups List is greater than 0.
VERIFY(!groups.is_empty());
// d. Repeat, while groups List is not empty,
while (!groups.is_empty()) {
// i. Remove the first element from groups and let integerGroup be the value of that element.
auto integer_group = groups.take_first();
// ii. Append a new Record { [[Type]]: "integer", [[Value]]: integerGroup } as the last element of result.
result.append({ "integer"sv, integer_group });
// iii. If groups List is not empty, then
if (!groups.is_empty()) {
// i. Append a new Record { [[Type]]: "group", [[Value]]: groupSepSymbol } as the last element of result.
result.append({ "group"sv, group_sep_symbol });
}
}
}
// 7. Else,
else {
// a. Append a new Record { [[Type]]: "integer", [[Value]]: integer } as the last element of result.
result.append({ "integer"sv, integer });
}
// 8. If fraction is not undefined, then
if (fraction.has_value()) {
// a. Let decimalSepSymbol be the ILND String representing the decimal separator.
auto decimal_sep_symbol = Unicode::get_number_system_symbol(number_format.data_locale(), number_format.numbering_system(), "decimal"sv).value_or("."sv);
// b. Append a new Record { [[Type]]: "decimal", [[Value]]: decimalSepSymbol } as the last element of result.
result.append({ "decimal"sv, decimal_sep_symbol });
// c. Append a new Record { [[Type]]: "fraction", [[Value]]: fraction } as the last element of result.
result.append({ "fraction"sv, fraction.release_value() });
}
}
// iv. Else if p is equal to "compactSymbol", then
else if (part == "compactSymbol"sv) {
// 1. Let compactSymbol be an ILD string representing exponent in short form, which may depend on x in languages having different plural forms. The implementation must be able to provide this string, or else the pattern would not have a "{compactSymbol}" placeholder.
// 2. Append a new Record { [[Type]]: "compact", [[Value]]: compactSymbol } as the last element of result.
// FIXME: Implement this when GetNotationSubPattern is fully implemented.
}
// v. Else if p is equal to "compactName", then
else if (part == "compactName"sv) {
// 1. Let compactName be an ILD string representing exponent in long form, which may depend on x in languages having different plural forms. The implementation must be able to provide this string, or else the pattern would not have a "{compactName}" placeholder.
// 2. Append a new Record { [[Type]]: "compact", [[Value]]: compactName } as the last element of result.
// FIXME: Implement this when GetNotationSubPattern is fully implemented.
}
// vi. Else if p is equal to "scientificSeparator", then
else if (part == "scientificSeparator"sv) {
// 1. Let scientificSeparator be the ILND String representing the exponent separator.
// 2. Append a new Record { [[Type]]: "exponentSeparator", [[Value]]: scientificSeparator } as the last element of result.
// FIXME: Implement this when GetNotationSubPattern is fully implemented.
}
// vii. Else if p is equal to "scientificExponent", then
else if (part == "scientificExponent"sv) {
// 1. If exponent < 0, then
// a. Let minusSignSymbol be the ILND String representing the minus sign.
// b. Append a new Record { [[Type]]: "exponentMinusSign", [[Value]]: minusSignSymbol } as the last element of result.
// c. Let exponent be -exponent.
// 2. Let exponentResult be ToRawFixed(exponent, 1, 0, 0).
// 3. Append a new Record { [[Type]]: "exponentInteger", [[Value]]: exponentResult.[[FormattedString]] } as the last element of result.
// FIXME: Implement this when GetNotationSubPattern is fully implemented.
}
// viii. Else,
else {
// 1. Let unknown be an ILND String based on x and p.
// 2. Append a new Record { [[Type]]: "unknown", [[Value]]: unknown } as the last element of result.
// FIXME: Implement this when GetNotationSubPattern is fully implemented.
}
}
}
// 5. Return result.
return result;
}
// 15.1.8 FormatNumeric ( numberFormat, x ), https://tc39.es/ecma402/#sec-formatnumber
String format_numeric(NumberFormat& number_format, double number)
{
// 1. Let parts be ? PartitionNumberPattern(numberFormat, x).
// Note: Our implementation of PartitionNumberPattern does not throw.
auto parts = partition_number_pattern(number_format, number);
// 2. Let result be the empty String.
StringBuilder result;
// 3. For each Record { [[Type]], [[Value]] } part in parts, do
for (auto& part : parts) {
// a. Set result to the string-concatenation of result and part.[[Value]].
result.append(move(part.value));
}
// 4. Return result.
return result.build();
}
// 15.1.9 FormatNumericToParts ( numberFormat, x ), https://tc39.es/ecma402/#sec-formatnumbertoparts
Array* format_numeric_to_parts(GlobalObject& global_object, NumberFormat& number_format, double number)
{
auto& vm = global_object.vm();
// 1. Let parts be ? PartitionNumberPattern(numberFormat, x).
// Note: Our implementation of PartitionNumberPattern does not throw.
auto parts = partition_number_pattern(number_format, number);
// 2. Let result be ArrayCreate(0).
auto* result = MUST(Array::create(global_object, 0));
// 3. Let n be 0.
size_t n = 0;
// 4. For each Record { [[Type]], [[Value]] } part in parts, do
for (auto& part : parts) {
// a. Let O be OrdinaryObjectCreate(%Object.prototype%).
auto* object = Object::create(global_object, global_object.object_prototype());
// b. Perform ! CreateDataPropertyOrThrow(O, "type", part.[[Type]]).
MUST(object->create_data_property_or_throw(vm.names.type, js_string(vm, part.type)));
// c. Perform ! CreateDataPropertyOrThrow(O, "value", part.[[Value]]).
MUST(object->create_data_property_or_throw(vm.names.value, js_string(vm, move(part.value))));
// d. Perform ! CreateDataPropertyOrThrow(result, ! ToString(n), O).
MUST(result->create_data_property_or_throw(n, object));
// e. Increment n by 1.
++n;
}
// 5. Return result.
return result;
}
static String cut_trailing_zeroes(StringView string, int cut)
{
// These steps are exactly the same between ToRawPrecision and ToRawFixed.
// Repeat, while cut > 0 and the last character of m is "0",
while ((cut > 0) && string.ends_with('0')) {
// Remove the last character from m.
string = string.substring_view(0, string.length() - 1);
// Decrease cut by 1.
--cut;
}
// If the last character of m is ".", then
if (string.ends_with('.')) {
// Remove the last character from m.
string = string.substring_view(0, string.length() - 1);
}
return string.to_string();
}
// 15.1.10 ToRawPrecision ( x, minPrecision, maxPrecision ), https://tc39.es/ecma402/#sec-torawprecision
RawFormatResult to_raw_precision(double number, int min_precision, int max_precision)
{
RawFormatResult result {};
// 1. Let p be maxPrecision.
int precision = max_precision;
int exponent = 0;
// 2. If x = 0, then
if (number == 0.0) {
// a. Let m be the String consisting of p occurrences of the character "0".
result.formatted_string = String::repeated('0', precision);
// b. Let e be 0.
exponent = 0;
// c. Let xFinal be 0.
result.rounded_number = 0;
}
// 3. Else,
else {
// FIXME: The result of these steps isn't entirely accurate for large values of 'p' (which
// defaults to 21, resulting in numbers on the order of 10^21). Either AK::format or
// our Number::toString AO (double_to_string in Value.cpp) will need to be improved
// to produce more accurate results.
// a. Let e be the base 10 logarithm of x rounded down to the nearest integer.
exponent = log10floor(number);
double power = pow(10, exponent - precision + 1);
// b. Let n be an integer such that 10^(p–1) ≤ n < 10^p and for which the exact mathematical value of n × 10^(e–p+1) – x
// is as close to zero as possible. If there is more than one such n, pick the one for which n × 10^(e–p+1) is larger.
double n = round(number / power);
// c. Let m be the String consisting of the digits of the decimal representation of n (in order, with no leading zeroes).
result.formatted_string = Value(n).to_string_without_side_effects();
// d. Let xFinal be n × 10^(e–p+1).
result.rounded_number = n * power;
}
// 4. If e ≥ p–1, then
if (exponent >= (precision - 1)) {
// a. Let m be the string-concatenation of m and e–p+1 occurrences of the character "0".
result.formatted_string = String::formatted(
"{}{}",
result.formatted_string,
String::repeated('0', exponent - precision + 1));
// b. Let int be e+1.
result.digits = exponent + 1;
}
// 5. Else if e ≥ 0, then
else if (exponent >= 0) {
// a. Let m be the string-concatenation of the first e+1 characters of m, the character ".", and the remaining p–(e+1) characters of m.
result.formatted_string = String::formatted(
"{}.{}",
result.formatted_string.substring_view(0, exponent + 1),
result.formatted_string.substring_view(exponent + 1));
// b. Let int be e+1.
result.digits = exponent + 1;
}
// 6. Else,
else {
// a. Assert: e < 0.
// b. Let m be the string-concatenation of the String value "0.", –(e+1) occurrences of the character "0", and m.
result.formatted_string = String::formatted(
"0.{}{}",
String::repeated('0', -1 * (exponent + 1)),
result.formatted_string);
// c. Let int be 1.
result.digits = 1;
}
// 7. If m contains the character ".", and maxPrecision > minPrecision, then
if (result.formatted_string.contains('.') && (max_precision > min_precision)) {
// a. Let cut be maxPrecision – minPrecision.
int cut = max_precision - min_precision;
result.formatted_string = cut_trailing_zeroes(result.formatted_string, cut);
}
// 8. Return the Record { [[FormattedString]]: m, [[RoundedNumber]]: xFinal, [[IntegerDigitsCount]]: int }.
return result;
}
// 15.1.11 ToRawFixed ( x, minInteger, minFraction, maxFraction ), https://tc39.es/ecma402/#sec-torawfixed
// NOTE: The spec has a mistake here. The minInteger parameter is unused and is not provided by FormatNumericToString.
RawFormatResult to_raw_fixed(double number, int min_fraction, int max_fraction)
{
RawFormatResult result {};
// 1. Let f be maxFraction.
int fraction = max_fraction;
double power = pow(10, fraction);
// 2. Let n be an integer for which the exact mathematical value of n / 10^f – x is as close to zero as possible. If there are two such n, pick the larger n.
double n = round(number * power);
// 3. Let xFinal be n / 10^f.
result.rounded_number = n / power;
// 4. If n = 0, let m be the String "0". Otherwise, let m be the String consisting of the digits of the decimal representation of n (in order, with no leading zeroes).
result.formatted_string = n == 0.0 ? String("0"sv) : Value(n).to_string_without_side_effects();
// 5. If f ≠ 0, then
if (fraction != 0) {
// a. Let k be the number of characters in m.
auto decimals = result.formatted_string.length();
// b. If k ≤ f, then
if (decimals <= static_cast<size_t>(fraction)) {
// i. Let z be the String value consisting of f+1–k occurrences of the character "0".
auto zeroes = String::repeated('0', fraction + 1 - decimals);
// ii. Let m be the string-concatenation of z and m.
result.formatted_string = String::formatted("{}{}", zeroes, result.formatted_string);
// iii. Let k be f+1.
decimals = fraction + 1;
}
// c. Let a be the first k–f characters of m, and let b be the remaining f characters of m.
auto a = result.formatted_string.substring_view(0, decimals - fraction);
auto b = result.formatted_string.substring_view(decimals - fraction, fraction);
// d. Let m be the string-concatenation of a, ".", and b.
result.formatted_string = String::formatted("{}.{}", a, b);
// e. Let int be the number of characters in a.
result.digits = a.length();
}
// 6. Else, let int be the number of characters in m.
else {
result.digits = result.formatted_string.length();
}
// 7. Let cut be maxFraction – minFraction.
int cut = max_fraction - min_fraction;
result.formatted_string = cut_trailing_zeroes(result.formatted_string, cut);
// 10. Return the Record { [[FormattedString]]: m, [[RoundedNumber]]: xFinal, [[IntegerDigitsCount]]: int }.
return result;
}
// 15.1.13 SetNumberFormatUnitOptions ( intlObj, options ), https://tc39.es/ecma402/#sec-setnumberformatunitoptions
ThrowCompletionOr<void> set_number_format_unit_options(GlobalObject& global_object, NumberFormat& intl_object, Object const& options)
{
auto& vm = global_object.vm();
// 1. Assert: Type(intlObj) is Object.
// 2. Assert: Type(options) is Object.
// 3. Let style be ? GetOption(options, "style", "string", « "decimal", "percent", "currency", "unit" », "decimal").
auto style = TRY(get_option(global_object, options, vm.names.style, Value::Type::String, { "decimal"sv, "percent"sv, "currency"sv, "unit"sv }, "decimal"sv));
// 4. Set intlObj.[[Style]] to style.
intl_object.set_style(style.as_string().string());
// 5. Let currency be ? GetOption(options, "currency", "string", undefined, undefined).
auto currency = TRY(get_option(global_object, options, vm.names.currency, Value::Type::String, {}, Empty {}));
// 6. If currency is undefined, then
if (currency.is_undefined()) {
// a. If style is "currency", throw a TypeError exception.
if (intl_object.style() == NumberFormat::Style::Currency)
return vm.throw_completion<TypeError>(global_object, ErrorType::IntlOptionUndefined, "currency"sv, "style"sv, style);
}
// 7. Else,
// a. If the result of IsWellFormedCurrencyCode(currency) is false, throw a RangeError exception.
else if (!is_well_formed_currency_code(currency.as_string().string()))
return vm.throw_completion<RangeError>(global_object, ErrorType::OptionIsNotValidValue, currency, "currency"sv);
// 8. Let currencyDisplay be ? GetOption(options, "currencyDisplay", "string", « "code", "symbol", "narrowSymbol", "name" », "symbol").
auto currency_display = TRY(get_option(global_object, options, vm.names.currencyDisplay, Value::Type::String, { "code"sv, "symbol"sv, "narrowSymbol"sv, "name"sv }, "symbol"sv));
// 9. Let currencySign be ? GetOption(options, "currencySign", "string", « "standard", "accounting" », "standard").
auto currency_sign = TRY(get_option(global_object, options, vm.names.currencySign, Value::Type::String, { "standard"sv, "accounting"sv }, "standard"sv));
// 10. Let unit be ? GetOption(options, "unit", "string", undefined, undefined).
auto unit = TRY(get_option(global_object, options, vm.names.unit, Value::Type::String, {}, Empty {}));
// 11. If unit is undefined, then
if (unit.is_undefined()) {
// a. If style is "unit", throw a TypeError exception.
if (intl_object.style() == NumberFormat::Style::Unit)
return vm.throw_completion<TypeError>(global_object, ErrorType::IntlOptionUndefined, "unit"sv, "style"sv, style);
}
// 12. Else,
// a. If the result of IsWellFormedUnitIdentifier(unit) is false, throw a RangeError exception.
else if (!is_well_formed_unit_identifier(unit.as_string().string()))
return vm.throw_completion<RangeError>(global_object, ErrorType::OptionIsNotValidValue, unit, "unit"sv);
// 13. Let unitDisplay be ? GetOption(options, "unitDisplay", "string", « "short", "narrow", "long" », "short").
auto unit_display = TRY(get_option(global_object, options, vm.names.unitDisplay, Value::Type::String, { "short"sv, "narrow"sv, "long"sv }, "short"sv));
// 14. If style is "currency", then
if (intl_object.style() == NumberFormat::Style::Currency) {
// a. Let currency be the result of converting currency to upper case as specified in 6.1.
// b. Set intlObj.[[Currency]] to currency.
intl_object.set_currency(currency.as_string().string().to_uppercase());
// c. Set intlObj.[[CurrencyDisplay]] to currencyDisplay.
intl_object.set_currency_display(currency_display.as_string().string());
// d. Set intlObj.[[CurrencySign]] to currencySign.
intl_object.set_currency_sign(currency_sign.as_string().string());
}
// 15. If style is "unit", then
if (intl_object.style() == NumberFormat::Style::Unit) {
// a. Set intlObj.[[Unit]] to unit.
intl_object.set_unit(unit.as_string().string());
// b. Set intlObj.[[UnitDisplay]] to unitDisplay.
intl_object.set_unit_display(unit_display.as_string().string());
}
return {};
}
// 15.1.14 GetNumberFormatPattern ( numberFormat, x ), https://tc39.es/ecma402/#sec-getnumberformatpattern
Optional<Variant<StringView, String>> get_number_format_pattern(NumberFormat& number_format, double number)
{
// 1. Let localeData be %NumberFormat%.[[LocaleData]].
// 2. Let dataLocale be numberFormat.[[DataLocale]].
// 3. Let dataLocaleData be localeData.[[<dataLocale>]].
// 4. Let patterns be dataLocaleData.[[patterns]].
// 5. Assert: patterns is a Record (see 15.3.3).
Optional<Unicode::NumberFormat> patterns;
// 6. Let style be numberFormat.[[Style]].
switch (number_format.style()) {
// 7. If style is "percent", then
case NumberFormat::Style::Percent:
// a. Let patterns be patterns.[[percent]].
patterns = Unicode::get_standard_number_system_format(number_format.data_locale(), number_format.numbering_system(), Unicode::StandardNumberFormatType::Percent);
break;
// 8. Else if style is "unit", then
case NumberFormat::Style::Unit:
// a. Let unit be numberFormat.[[Unit]].
// b. Let unitDisplay be numberFormat.[[UnitDisplay]].
// c. Let patterns be patterns.[[unit]].
// d. If patterns doesn't have a field [[<unit>]], then
// i. Let unit be "fallback".
// e. Let patterns be patterns.[[<unit>]].
// f. Let patterns be patterns.[[<unitDisplay>]].
// FIXME: LibUnicode will need to parse the cldr-units package.
break;
// 9. Else if style is "currency", then
case NumberFormat::Style::Currency:
// a. Let currency be numberFormat.[[Currency]].
// b. Let currencyDisplay be numberFormat.[[CurrencyDisplay]].
// c. Let currencySign be numberFormat.[[CurrencySign]].
// d. Let patterns be patterns.[[currency]].
// e. If patterns doesn't have a field [[<currency>]], then
// i. Let currency be "fallback".
// f. Let patterns be patterns.[[<currency>]].
// g. Let patterns be patterns.[[<currencyDisplay>]].
// h. Let patterns be patterns.[[<currencySign>]].
// Handling of other [[CurrencyDisplay]] options will occur after [[SignDisplay]].
if (number_format.currency_display() == NumberFormat::CurrencyDisplay::Name) {
auto maybe_patterns = Unicode::select_currency_unit_pattern(number_format.data_locale(), number_format.numbering_system(), number);
if (maybe_patterns.has_value()) {
patterns = maybe_patterns.release_value();
break;
}
}
switch (number_format.currency_sign()) {
case NumberFormat::CurrencySign::Standard:
patterns = Unicode::get_standard_number_system_format(number_format.data_locale(), number_format.numbering_system(), Unicode::StandardNumberFormatType::Currency);
break;
case NumberFormat::CurrencySign::Accounting:
patterns = Unicode::get_standard_number_system_format(number_format.data_locale(), number_format.numbering_system(), Unicode::StandardNumberFormatType::Accounting);
break;
}
break;
// 10. Else,
case NumberFormat::Style::Decimal:
// a. Assert: style is "decimal".
// b. Let patterns be patterns.[[decimal]].
patterns = Unicode::get_standard_number_system_format(number_format.data_locale(), number_format.numbering_system(), Unicode::StandardNumberFormatType::Decimal);
break;
default:
VERIFY_NOT_REACHED();
}
if (!patterns.has_value())
return {};
StringView pattern;
Value number_value(number);
bool is_positive_zero = number_value.is_positive_zero();
bool is_negative_zero = number_value.is_negative_zero();
bool is_nan = number_value.is_nan();
// 11. Let signDisplay be numberFormat.[[SignDisplay]].
switch (number_format.sign_display()) {
// 12. If signDisplay is "never", then
case NumberFormat::SignDisplay::Never:
// a. Let pattern be patterns.[[zeroPattern]].
pattern = patterns->zero_format;
break;
// 13. Else if signDisplay is "auto", then
case NumberFormat::SignDisplay::Auto:
// a. If x is 0 or x > 0 or x is NaN, then
if (is_positive_zero || (number > 0) || is_nan) {
// i. Let pattern be patterns.[[zeroPattern]].
pattern = patterns->zero_format;
}
// b. Else,
else {
// i. Let pattern be patterns.[[negativePattern]].
pattern = patterns->negative_format;
}
break;
// 14. Else if signDisplay is "always", then
case NumberFormat::SignDisplay::Always:
// a. If x is 0 or x > 0 or x is NaN, then
if (is_positive_zero || (number > 0) || is_nan) {
// i. Let pattern be patterns.[[positivePattern]].
pattern = patterns->positive_format;
}
// b. Else,
else {
// i. Let pattern be patterns.[[negativePattern]].
pattern = patterns->negative_format;
}
break;
// 15. Else,
case NumberFormat::SignDisplay::ExceptZero:
// a. Assert: signDisplay is "exceptZero".
// b. If x is 0 or x is -0 or x is NaN, then
if (is_positive_zero || is_negative_zero || is_nan) {
// i. Let pattern be patterns.[[zeroPattern]].
pattern = patterns->zero_format;
}
// c. Else if x > 0, then
else if (number > 0) {
// i. Let pattern be patterns.[[positivePattern]].
pattern = patterns->positive_format;
}
// d. Else,
else {
// i. Let pattern be patterns.[[negativePattern]].
pattern = patterns->negative_format;
}
break;
default:
VERIFY_NOT_REACHED();
}
// Handling of steps 9b/9g: Depending on the currency display and the format pattern found above,
// we might need to mutate the format pattern to inject a space between the currency display and
// the currency number.
if (number_format.style() == NumberFormat::Style::Currency) {
auto modified_pattern = Unicode::augment_currency_format_pattern(number_format.resolve_currency_display(), pattern);
if (modified_pattern.has_value())
return modified_pattern.release_value();
}
// 16. Return pattern.
return pattern;
}
// 15.1.15 GetNotationSubPattern ( numberFormat, exponent ), https://tc39.es/ecma402/#sec-getnotationsubpattern
StringView get_notation_sub_pattern([[maybe_unused]] NumberFormat& number_format, [[maybe_unused]] int exponent)
{
// FIXME: Implement this.
// 1. Let localeData be %NumberFormat%.[[LocaleData]].
// 2. Let dataLocale be numberFormat.[[DataLocale]].
// 3. Let dataLocaleData be localeData.[[<dataLocale>]].
// 4. Let notationSubPatterns be dataLocaleData.[[notationSubPatterns]].
// 5. Assert: notationSubPatterns is a Record (see 15.3.3).
// 6. Let notation be numberFormat.[[Notation]].
// 7. If notation is "scientific" or notation is "engineering", then
// a. Return notationSubPatterns.[[scientific]].
// 8. Else if exponent is not 0, then
// a. Assert: notation is "compact".
// b. Let compactDisplay be numberFormat.[[CompactDisplay]].
// c. Let compactPatterns be notationSubPatterns.[[compact]].[[<compactDisplay>]].
// d. Return compactPatterns.[[<exponent>]].
// 9. Else,
// a. Return "{number}".
return "{number}"sv;
}
// 15.1.16 ComputeExponent ( numberFormat, x ), https://tc39.es/ecma402/#sec-computeexponent
int compute_exponent(NumberFormat& number_format, double number)
{
// 1. If x = 0, then
if (number == 0.0) {
// a. Return 0.
return 0;
}
// 2. If x < 0, then
if (number < 0) {
// a. Let x = -x.
number *= -1;
}
// 3. Let magnitude be the base 10 logarithm of x rounded down to the nearest integer.
int magnitude = log10floor(number);
// 4. Let exponent be ComputeExponentForMagnitude(numberFormat, magnitude).
int exponent = compute_exponent_for_magniude(number_format, magnitude);
// 5. Let x be x × 10^(-exponent).
number *= pow(10, -exponent);
// 6. Let formatNumberResult be FormatNumericToString(numberFormat, x).
auto format_number_result = format_numeric_to_string(number_format, number);
// 7. If formatNumberResult.[[RoundedNumber]] = 0, then
if (format_number_result.rounded_number == 0) {
// a. Return exponent.
return exponent;
}
// 8. Let newMagnitude be the base 10 logarithm of formatNumberResult.[[RoundedNumber]] rounded down to the nearest integer.
int new_magnitude = log10floor(format_number_result.rounded_number);
// 9. If newMagnitude is magnitude – exponent, then
if (new_magnitude == magnitude - exponent) {
// a. Return exponent.
return exponent;
}
// 10. Return ComputeExponentForMagnitude(numberFormat, magnitude + 1).
return compute_exponent_for_magniude(number_format, magnitude + 1);
}
// 15.1.17 ComputeExponentForMagnitude ( numberFormat, magnitude ), https://tc39.es/ecma402/#sec-computeexponentformagnitude
int compute_exponent_for_magniude(NumberFormat& number_format, int magnitude)
{
// 1. Let notation be numberFormat.[[Notation]].
switch (number_format.notation()) {
// 2. If notation is "standard", then
case NumberFormat::Notation::Standard:
// a. Return 0.
return 0;
// 3. Else if notation is "scientific", then
case NumberFormat::Notation::Scientific:
// a. Return magnitude.
return magnitude;
// 4. Else if notation is "engineering", then
case NumberFormat::Notation::Engineering: {
// a. Let thousands be the greatest integer that is not greater than magnitude / 3.
double thousands = floor(static_cast<double>(magnitude) / 3.0);
// b. Return thousands × 3.
return static_cast<int>(thousands) * 3;
}
// 5. Else,
case NumberFormat::Notation::Compact: {
// a. Assert: notation is "compact".
VERIFY(number_format.has_compact_display());
// b. Let exponent be an implementation- and locale-dependent (ILD) integer by which to scale a number of the given magnitude in compact notation for the current locale.
// c. Return exponent.
Vector<Unicode::NumberFormat> format_rules;
if (number_format.style() == NumberFormat::Style::Currency)
format_rules = Unicode::get_compact_number_system_formats(number_format.data_locale(), number_format.numbering_system(), Unicode::CompactNumberFormatType::CurrencyShort);
else if (number_format.compact_display() == NumberFormat::CompactDisplay::Long)
format_rules = Unicode::get_compact_number_system_formats(number_format.data_locale(), number_format.numbering_system(), Unicode::CompactNumberFormatType::DecimalLong);
else
format_rules = Unicode::get_compact_number_system_formats(number_format.data_locale(), number_format.numbering_system(), Unicode::CompactNumberFormatType::DecimalShort);
Unicode::NumberFormat const* best_number_format = nullptr;
for (auto const& format_rule : format_rules) {
if (format_rule.magnitude > magnitude)
break;
best_number_format = &format_rule;
}
return best_number_format ? best_number_format->compact_scale : 0;
}
default:
VERIFY_NOT_REACHED();
}
}
}