/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* Portions Copyright Norbert Lindenberg 2011-2012. */ #include "NumberingSystemsGenerated.h" /** * NumberFormat internal properties. * * Spec: ECMAScript Internationalization API Specification, 9.1 and 11.3.3. */ var numberFormatInternalProperties = { localeData: numberFormatLocaleData, relevantExtensionKeys: ["nu"], }; /** * Compute an internal properties object from |lazyNumberFormatData|. */ function resolveNumberFormatInternals(lazyNumberFormatData) { assert(IsObject(lazyNumberFormatData), "lazy data not an object?"); var internalProps = std_Object_create(null); var NumberFormat = numberFormatInternalProperties; // Compute effective locale. // Step 7. var localeData = NumberFormat.localeData; // Step 8. var r = ResolveLocale( "NumberFormat", lazyNumberFormatData.requestedLocales, lazyNumberFormatData.opt, NumberFormat.relevantExtensionKeys, localeData ); // Steps 9-10. (Step 11 is not relevant to our implementation.) internalProps.locale = r.locale; internalProps.numberingSystem = r.nu; // Compute formatting options. // Step 13. var style = lazyNumberFormatData.style; internalProps.style = style; // Steps 17, 19. if (style === "currency") { internalProps.currency = lazyNumberFormatData.currency; internalProps.currencyDisplay = lazyNumberFormatData.currencyDisplay; internalProps.currencySign = lazyNumberFormatData.currencySign; } // Intl.NumberFormat Unified API Proposal if (style === "unit") { internalProps.unit = lazyNumberFormatData.unit; internalProps.unitDisplay = lazyNumberFormatData.unitDisplay; } // Intl.NumberFormat Unified API Proposal var notation = lazyNumberFormatData.notation; internalProps.notation = notation; // Step 22. internalProps.minimumIntegerDigits = lazyNumberFormatData.minimumIntegerDigits; if ("minimumFractionDigits" in lazyNumberFormatData) { // Note: Intl.NumberFormat.prototype.resolvedOptions() exposes the // actual presence (versus undefined-ness) of these properties. assert( "maximumFractionDigits" in lazyNumberFormatData, "min/max frac digits mismatch" ); internalProps.minimumFractionDigits = lazyNumberFormatData.minimumFractionDigits; internalProps.maximumFractionDigits = lazyNumberFormatData.maximumFractionDigits; } if ("minimumSignificantDigits" in lazyNumberFormatData) { // Note: Intl.NumberFormat.prototype.resolvedOptions() exposes the // actual presence (versus undefined-ness) of these properties. assert( "maximumSignificantDigits" in lazyNumberFormatData, "min/max sig digits mismatch" ); internalProps.minimumSignificantDigits = lazyNumberFormatData.minimumSignificantDigits; internalProps.maximumSignificantDigits = lazyNumberFormatData.maximumSignificantDigits; } // Intl.NumberFormat v3 Proposal internalProps.trailingZeroDisplay = lazyNumberFormatData.trailingZeroDisplay; internalProps.roundingIncrement = lazyNumberFormatData.roundingIncrement; // Intl.NumberFormat Unified API Proposal if (notation === "compact") { internalProps.compactDisplay = lazyNumberFormatData.compactDisplay; } // Step 24. internalProps.useGrouping = lazyNumberFormatData.useGrouping; // Intl.NumberFormat Unified API Proposal internalProps.signDisplay = lazyNumberFormatData.signDisplay; // Intl.NumberFormat v3 Proposal internalProps.roundingMode = lazyNumberFormatData.roundingMode; // Intl.NumberFormat v3 Proposal internalProps.roundingPriority = lazyNumberFormatData.roundingPriority; // The caller is responsible for associating |internalProps| with the right // object using |setInternalProperties|. return internalProps; } /** * Returns an object containing the NumberFormat internal properties of |obj|. */ function getNumberFormatInternals(obj) { assert(IsObject(obj), "getNumberFormatInternals called with non-object"); assert( intl_GuardToNumberFormat(obj) !== null, "getNumberFormatInternals called with non-NumberFormat" ); var internals = getIntlObjectInternals(obj); assert( internals.type === "NumberFormat", "bad type escaped getIntlObjectInternals" ); // If internal properties have already been computed, use them. var internalProps = maybeInternalProperties(internals); if (internalProps) { return internalProps; } // Otherwise it's time to fully create them. internalProps = resolveNumberFormatInternals(internals.lazyData); setInternalProperties(internals, internalProps); return internalProps; } /** * 11.1.11 UnwrapNumberFormat( nf ) */ function UnwrapNumberFormat(nf) { // Steps 2 and 4 (error handling moved to caller). if ( IsObject(nf) && intl_GuardToNumberFormat(nf) === null && !intl_IsWrappedNumberFormat(nf) && callFunction( std_Object_isPrototypeOf, GetBuiltinPrototype("NumberFormat"), nf ) ) { nf = nf[intlFallbackSymbol()]; } return nf; } /** * Applies digit options used for number formatting onto the intl object. * * Spec: ECMAScript Internationalization API Specification, 11.1.1. */ function SetNumberFormatDigitOptions( lazyData, options, mnfdDefault, mxfdDefault, notation ) { // We skip step 1 because we set the properties on a lazyData object. // Steps 2-4. assert(IsObject(options), "SetNumberFormatDigitOptions"); assert(typeof mnfdDefault === "number", "SetNumberFormatDigitOptions"); assert(typeof mxfdDefault === "number", "SetNumberFormatDigitOptions"); assert(mnfdDefault <= mxfdDefault, "SetNumberFormatDigitOptions"); assert(typeof notation === "string", "SetNumberFormatDigitOptions"); // Steps 5-9. const mnid = GetNumberOption(options, "minimumIntegerDigits", 1, 21, 1); let mnfd = options.minimumFractionDigits; let mxfd = options.maximumFractionDigits; let mnsd = options.minimumSignificantDigits; let mxsd = options.maximumSignificantDigits; // Step 10. lazyData.minimumIntegerDigits = mnid; #ifdef NIGHTLY_BUILD // Intl.NumberFormat v3 Proposal var roundingPriority = GetOption( options, "roundingPriority", "string", ["auto", "morePrecision", "lessPrecision"], "auto" ); #else var roundingPriority = "auto"; #endif const hasSignificantDigits = mnsd !== undefined || mxsd !== undefined; const hasFractionDigits = mnfd !== undefined || mxfd !== undefined; const needSignificantDigits = roundingPriority !== "auto" || hasSignificantDigits; const needFractionalDigits = roundingPriority !== "auto" || !(hasSignificantDigits || (!hasFractionDigits && notation === "compact")); if (needSignificantDigits) { // Step 11. if (hasSignificantDigits) { // Step 11.a (Omitted). // Step 11.b. mnsd = DefaultNumberOption(mnsd, 1, 21, 1); // Step 11.c. mxsd = DefaultNumberOption(mxsd, mnsd, 21, 21); // Step 11.d. lazyData.minimumSignificantDigits = mnsd; // Step 11.e. lazyData.maximumSignificantDigits = mxsd; } else { lazyData.minimumSignificantDigits = 1; lazyData.maximumSignificantDigits = 21; } } if (needFractionalDigits) { // Step 12. if (hasFractionDigits) { // Step 12.a (Omitted). // Step 12.b. mnfd = DefaultNumberOption(mnfd, 0, 20, undefined); // Step 12.c. mxfd = DefaultNumberOption(mxfd, 0, 20, undefined); // Step 12.d. if (mnfd === undefined) { assert( mxfd !== undefined, "mxfd isn't undefined when mnfd is undefined" ); mnfd = std_Math_min(mnfdDefault, mxfd); } // Step 12.e. else if (mxfd === undefined) { mxfd = std_Math_max(mxfdDefault, mnfd); } // Step 12.f. else if (mnfd > mxfd) { ThrowRangeError(JSMSG_INVALID_DIGITS_VALUE, mxfd); } // Step 12.g. lazyData.minimumFractionDigits = mnfd; // Step 12.h. lazyData.maximumFractionDigits = mxfd; } else { // Step 14.a (Omitted). // Step 14.b. lazyData.minimumFractionDigits = mnfdDefault; // Step 14.c. lazyData.maximumFractionDigits = mxfdDefault; } } if (needSignificantDigits || needFractionalDigits) { lazyData.roundingPriority = roundingPriority; } else { assert(!hasSignificantDigits, "bad significant digits in fallback case"); assert( roundingPriority === "auto", `bad rounding in fallback case: ${roundingPriority}` ); assert( notation === "compact", `bad notation in fallback case: ${notation}` ); lazyData.roundingPriority = "morePrecision"; lazyData.minimumFractionDigits = 0; lazyData.maximumFractionDigits = 0; lazyData.minimumSignificantDigits = 1; lazyData.maximumSignificantDigits = 2; } } /** * Convert s to upper case, but limited to characters a-z. * * Spec: ECMAScript Internationalization API Specification, 6.1. */ function toASCIIUpperCase(s) { assert(typeof s === "string", "toASCIIUpperCase"); // String.prototype.toUpperCase may map non-ASCII characters into ASCII, // so go character by character (actually code unit by code unit, but // since we only care about ASCII characters here, that's OK). var result = ""; for (var i = 0; i < s.length; i++) { var c = callFunction(std_String_charCodeAt, s, i); result += 0x61 <= c && c <= 0x7a ? callFunction(std_String_fromCharCode, null, c & ~0x20) : s[i]; } return result; } /** * Verifies that the given string is a well-formed ISO 4217 currency code. * * Spec: ECMAScript Internationalization API Specification, 6.3.1. */ function IsWellFormedCurrencyCode(currency) { assert(typeof currency === "string", "currency is a string value"); return currency.length === 3 && IsASCIIAlphaString(currency); } /** * Verifies that the given string is a well-formed core unit identifier as * defined in UTS #35, Part 2, Section 6. In addition to obeying the UTS #35 * core unit identifier syntax, |unitIdentifier| must be one of the identifiers * sanctioned by UTS #35 or be a compound unit composed of two sanctioned simple * units. * * Intl.NumberFormat Unified API Proposal */ function IsWellFormedUnitIdentifier(unitIdentifier) { assert( typeof unitIdentifier === "string", "unitIdentifier is a string value" ); // Step 1. if (IsSanctionedSimpleUnitIdentifier(unitIdentifier)) { return true; } // Step 2. var pos = callFunction(std_String_indexOf, unitIdentifier, "-per-"); if (pos < 0) { return false; } var next = pos + "-per-".length; // Steps 3 and 5. var numerator = Substring(unitIdentifier, 0, pos); var denominator = Substring( unitIdentifier, next, unitIdentifier.length - next ); // Steps 4 and 6. return ( IsSanctionedSimpleUnitIdentifier(numerator) && IsSanctionedSimpleUnitIdentifier(denominator) ); } #if DEBUG || MOZ_SYSTEM_ICU var availableMeasurementUnits = { value: null, }; #endif /** * Verifies that the given string is a sanctioned simple core unit identifier. * * Intl.NumberFormat Unified API Proposal * * Also see: https://unicode.org/reports/tr35/tr35-general.html#Unit_Elements */ function IsSanctionedSimpleUnitIdentifier(unitIdentifier) { assert( typeof unitIdentifier === "string", "unitIdentifier is a string value" ); var isSanctioned = hasOwn(unitIdentifier, sanctionedSimpleUnitIdentifiers); #if DEBUG || MOZ_SYSTEM_ICU if (isSanctioned) { if (availableMeasurementUnits.value === null) { availableMeasurementUnits.value = intl_availableMeasurementUnits(); } var isSupported = hasOwn(unitIdentifier, availableMeasurementUnits.value); #if MOZ_SYSTEM_ICU // A system ICU may support fewer measurement units, so we need to make // sure the unit is actually supported. isSanctioned = isSupported; #else // Otherwise just assert that the sanctioned unit is also supported. assert( isSupported, `"${unitIdentifier}" is sanctioned but not supported. Did you forget to update intl/icu/data_filter.json to include the unit (and any implicit compound units)? For example "speed/kilometer-per-hour" is implied by "length/kilometer" and "duration/hour" and must therefore also be present.` ); #endif } #endif return isSanctioned; } /* eslint-disable complexity */ /** * Initializes an object as a NumberFormat. * * This method is complicated a moderate bit by its implementing initialization * as a *lazy* concept. Everything that must happen now, does -- but we defer * all the work we can until the object is actually used as a NumberFormat. * This later work occurs in |resolveNumberFormatInternals|; steps not noted * here occur there. * * Spec: ECMAScript Internationalization API Specification, 11.1.2. */ function InitializeNumberFormat(numberFormat, thisValue, locales, options) { assert( IsObject(numberFormat), "InitializeNumberFormat called with non-object" ); assert( intl_GuardToNumberFormat(numberFormat) !== null, "InitializeNumberFormat called with non-NumberFormat" ); // Lazy NumberFormat data has the following structure: // // { // requestedLocales: List of locales, // style: "decimal" / "percent" / "currency" / "unit", // // // fields present only if style === "currency": // currency: a well-formed currency code (IsWellFormedCurrencyCode), // currencyDisplay: "code" / "symbol" / "narrowSymbol" / "name", // currencySign: "standard" / "accounting", // // // fields present only if style === "unit": // unit: a well-formed unit identifier (IsWellFormedUnitIdentifier), // unitDisplay: "short" / "narrow" / "long", // // opt: // opt object computed in InitializeNumberFormat // { // localeMatcher: "lookup" / "best fit", // // nu: string matching a Unicode extension type, // optional // } // // minimumIntegerDigits: integer ∈ [1, 21], // // // optional, mutually exclusive with the significant-digits option // minimumFractionDigits: integer ∈ [0, 20], // maximumFractionDigits: integer ∈ [0, 20], // // // optional, mutually exclusive with the fraction-digits option // minimumSignificantDigits: integer ∈ [1, 21], // maximumSignificantDigits: integer ∈ [1, 21], // // roundingPriority: "auto" / "lessPrecision" / "morePrecision", // // // accepts different values when Intl.NumberFormat v3 proposal is enabled // useGrouping: true / false, // useGrouping: "auto" / "always" / "min2" / false, // // notation: "standard" / "scientific" / "engineering" / "compact", // // // optional, if notation is "compact" // compactDisplay: "short" / "long", // // signDisplay: "auto" / "never" / "always" / "exceptZero", // // trailingZeroDisplay: "auto" / "stripIfInteger", // // roundingIncrement: integer ∈ (1, 2, 5, // 10, 20, 25, 50, // 100, 200, 250, 500, // 1000, 2000, 2500, 5000), // // roundingMode: "ceil" / "floor" / "expand" / "trunc" / // "halfCeil" / "halfFloor" / "halfExpand" / "halfTrunc" / "halfEven", // } // // Note that lazy data is only installed as a final step of initialization, // so every NumberFormat lazy data object has *all* these properties, never a // subset of them. var lazyNumberFormatData = std_Object_create(null); // Step 1. var requestedLocales = CanonicalizeLocaleList(locales); lazyNumberFormatData.requestedLocales = requestedLocales; // Steps 2-3. // // If we ever need more speed here at startup, we should try to detect the // case where |options === undefined| and then directly use the default // value for each option. For now, just keep it simple. if (options === undefined) { options = std_Object_create(null); } else { options = ToObject(options); } // Compute options that impact interpretation of locale. // Step 4. var opt = new_Record(); lazyNumberFormatData.opt = opt; // Steps 5-6. var matcher = GetOption( options, "localeMatcher", "string", ["lookup", "best fit"], "best fit" ); opt.localeMatcher = matcher; var numberingSystem = GetOption( options, "numberingSystem", "string", undefined, undefined ); if (numberingSystem !== undefined) { numberingSystem = intl_ValidateAndCanonicalizeUnicodeExtensionType( numberingSystem, "numberingSystem", "nu" ); } opt.nu = numberingSystem; // Compute formatting options. // Step 12. var style = GetOption( options, "style", "string", ["decimal", "percent", "currency", "unit"], "decimal" ); lazyNumberFormatData.style = style; // Steps 14-17. var currency = GetOption(options, "currency", "string", undefined, undefined); // Per the Intl.NumberFormat Unified API Proposal, this check should only // happen for |style === "currency"|, which seems inconsistent, given that // we normally validate all options when present, even the ones which are // unused. // TODO: File issue at . if (currency !== undefined && !IsWellFormedCurrencyCode(currency)) { ThrowRangeError(JSMSG_INVALID_CURRENCY_CODE, currency); } var cDigits; if (style === "currency") { if (currency === undefined) { ThrowTypeError(JSMSG_UNDEFINED_CURRENCY); } // Steps 19.a-c. currency = toASCIIUpperCase(currency); lazyNumberFormatData.currency = currency; cDigits = CurrencyDigits(currency); } // Step 18. var currencyDisplay = GetOption( options, "currencyDisplay", "string", ["code", "symbol", "narrowSymbol", "name"], "symbol" ); if (style === "currency") { lazyNumberFormatData.currencyDisplay = currencyDisplay; } // Intl.NumberFormat Unified API Proposal var currencySign = GetOption( options, "currencySign", "string", ["standard", "accounting"], "standard" ); if (style === "currency") { lazyNumberFormatData.currencySign = currencySign; } // Intl.NumberFormat Unified API Proposal var unit = GetOption(options, "unit", "string", undefined, undefined); // Aligned with |currency| check from above, see note about spec issue there. if (unit !== undefined && !IsWellFormedUnitIdentifier(unit)) { ThrowRangeError(JSMSG_INVALID_UNIT_IDENTIFIER, unit); } var unitDisplay = GetOption( options, "unitDisplay", "string", ["short", "narrow", "long"], "short" ); if (style === "unit") { if (unit === undefined) { ThrowTypeError(JSMSG_UNDEFINED_UNIT); } lazyNumberFormatData.unit = unit; lazyNumberFormatData.unitDisplay = unitDisplay; } // Steps 20-21. var mnfdDefault, mxfdDefault; if (style === "currency") { mnfdDefault = cDigits; mxfdDefault = cDigits; } else { mnfdDefault = 0; mxfdDefault = style === "percent" ? 0 : 3; } // Intl.NumberFormat Unified API Proposal var notation = GetOption( options, "notation", "string", ["standard", "scientific", "engineering", "compact"], "standard" ); lazyNumberFormatData.notation = notation; // Step 22. SetNumberFormatDigitOptions( lazyNumberFormatData, options, mnfdDefault, mxfdDefault, notation ); #ifdef NIGHTLY_BUILD // Intl.NumberFormat v3 Proposal var roundingIncrement = GetNumberOption( options, "roundingIncrement", 1, 5000, 1 ); switch (roundingIncrement) { case 1: case 2: case 5: case 10: case 20: case 25: case 50: case 100: case 200: case 250: case 500: case 1000: case 2000: case 2500: case 5000: break; default: ThrowRangeError( JSMSG_INVALID_OPTION_VALUE, "roundingIncrement", roundingIncrement ); } lazyNumberFormatData.roundingIncrement = roundingIncrement; if (roundingIncrement !== 1) { // [[RoundingType]] must be `fractionDigits`. if (lazyNumberFormatData.roundingPriority !== "auto") { ThrowTypeError( JSMSG_INVALID_NUMBER_OPTION, "roundingIncrement", "roundingPriority" ); } if (hasOwn("minimumSignificantDigits", lazyNumberFormatData)) { ThrowTypeError( JSMSG_INVALID_NUMBER_OPTION, "roundingIncrement", "minimumSignificantDigits" ); } // Minimum and maximum fraction digits must be equal. if ( lazyNumberFormatData.minimumFractionDigits !== lazyNumberFormatData.maximumFractionDigits ) { ThrowRangeError(JSMSG_UNEQUAL_FRACTION_DIGITS); } } #else lazyNumberFormatData.roundingIncrement = 1; #endif #ifdef NIGHTLY_BUILD // Intl.NumberFormat v3 Proposal var trailingZeroDisplay = GetOption( options, "trailingZeroDisplay", "string", ["auto", "stripIfInteger"], "auto" ); lazyNumberFormatData.trailingZeroDisplay = trailingZeroDisplay; #else lazyNumberFormatData.trailingZeroDisplay = "auto"; #endif // Intl.NumberFormat Unified API Proposal var compactDisplay = GetOption( options, "compactDisplay", "string", ["short", "long"], "short" ); if (notation === "compact") { lazyNumberFormatData.compactDisplay = compactDisplay; } // Steps 23. #ifdef NIGHTLY_BUILD var defaultUseGrouping = notation !== "compact" ? "auto" : "min2"; var useGrouping = GetStringOrBooleanOption( options, "useGrouping", ["min2", "auto", "always"], "always", false, defaultUseGrouping ); #else var useGrouping = GetOption( options, "useGrouping", "boolean", undefined, true ); #endif lazyNumberFormatData.useGrouping = useGrouping; // Intl.NumberFormat Unified API Proposal var signDisplay = GetOption( options, "signDisplay", "string", #ifdef NIGHTLY_BUILD ["auto", "never", "always", "exceptZero", "negative"], #else ["auto", "never", "always", "exceptZero"], #endif "auto" ); lazyNumberFormatData.signDisplay = signDisplay; #ifdef NIGHTLY_BUILD // Intl.NumberFormat v3 Proposal var roundingMode = GetOption( options, "roundingMode", "string", [ "ceil", "floor", "expand", "trunc", "halfCeil", "halfFloor", "halfExpand", "halfTrunc", "halfEven", ], "halfExpand" ); lazyNumberFormatData.roundingMode = roundingMode; #else lazyNumberFormatData.roundingMode = "halfExpand"; #endif // Step 31. // // We've done everything that must be done now: mark the lazy data as fully // computed and install it. initializeIntlObject(numberFormat, "NumberFormat", lazyNumberFormatData); // 11.2.1, steps 4-5. if ( numberFormat !== thisValue && callFunction( std_Object_isPrototypeOf, GetBuiltinPrototype("NumberFormat"), thisValue ) ) { DefineDataProperty( thisValue, intlFallbackSymbol(), numberFormat, ATTR_NONENUMERABLE | ATTR_NONCONFIGURABLE | ATTR_NONWRITABLE ); return thisValue; } // 11.2.1, step 6. return numberFormat; } /* eslint-enable complexity */ /** * Returns the number of decimal digits to be used for the given currency. * * Spec: ECMAScript Internationalization API Specification, 11.1.3. */ function CurrencyDigits(currency) { assert(typeof currency === "string", "currency is a string value"); assert(IsWellFormedCurrencyCode(currency), "currency is well-formed"); assert(currency === toASCIIUpperCase(currency), "currency is all upper-case"); if (hasOwn(currency, currencyDigits)) { return currencyDigits[currency]; } return 2; } /** * Returns the subset of the given locale list for which this locale list has a * matching (possibly fallback) locale. Locales appear in the same order in the * returned list as in the input list. * * Spec: ECMAScript Internationalization API Specification, 11.3.2. */ function Intl_NumberFormat_supportedLocalesOf(locales /*, options*/) { var options = ArgumentsLength() > 1 ? GetArgument(1) : undefined; // Step 1. var availableLocales = "NumberFormat"; // Step 2. var requestedLocales = CanonicalizeLocaleList(locales); // Step 3. return SupportedLocales(availableLocales, requestedLocales, options); } function getNumberingSystems(locale) { // ICU doesn't have an API to determine the set of numbering systems // supported for a locale; it generally pretends that any numbering system // can be used with any locale. Supporting a decimal numbering system // (where only the digits are replaced) is easy, so we offer them all here. // Algorithmic numbering systems are typically tied to one locale, so for // lack of information we don't offer them. // The one thing we can find out from ICU is the default numbering system // for a locale. var defaultNumberingSystem = intl_numberingSystem(locale); return [defaultNumberingSystem, NUMBERING_SYSTEMS_WITH_SIMPLE_DIGIT_MAPPINGS]; } function numberFormatLocaleData() { return { nu: getNumberingSystems, default: { nu: intl_numberingSystem, }, }; } /** * Create function to be cached and returned by Intl.NumberFormat.prototype.format. * * Spec: ECMAScript Internationalization API Specification, 11.1.4. */ function createNumberFormatFormat(nf) { // This function is not inlined in $Intl_NumberFormat_format_get to avoid // creating a call-object on each call to $Intl_NumberFormat_format_get. return function(value) { // Step 1 (implicit). // Step 2. assert(IsObject(nf), "InitializeNumberFormat called with non-object"); assert( intl_GuardToNumberFormat(nf) !== null, "InitializeNumberFormat called with non-NumberFormat" ); #ifdef NIGHTLY_BUILD var x = value; #else // Steps 3-4. var x = ToNumeric(value); #endif // Step 5. return intl_FormatNumber(nf, x, /* formatToParts = */ false); }; } /** * Returns a function bound to this NumberFormat that returns a String value * representing the result of calling ToNumber(value) according to the * effective locale and the formatting options of this NumberFormat. * * Spec: ECMAScript Internationalization API Specification, 11.4.3. */ // Uncloned functions with `$` prefix are allocated as extended function // to store the original name in `SetCanonicalName`. function $Intl_NumberFormat_format_get() { // Steps 1-3. var thisArg = UnwrapNumberFormat(this); var nf = thisArg; if (!IsObject(nf) || (nf = intl_GuardToNumberFormat(nf)) === null) { return callFunction( intl_CallNumberFormatMethodIfWrapped, thisArg, "$Intl_NumberFormat_format_get" ); } var internals = getNumberFormatInternals(nf); // Step 4. if (internals.boundFormat === undefined) { // Steps 4.a-c. internals.boundFormat = createNumberFormatFormat(nf); } // Step 5. return internals.boundFormat; } SetCanonicalName($Intl_NumberFormat_format_get, "get format"); /** * 11.4.4 Intl.NumberFormat.prototype.formatToParts ( value ) */ function Intl_NumberFormat_formatToParts(value) { // Step 1. var nf = this; // Steps 2-3. if (!IsObject(nf) || (nf = intl_GuardToNumberFormat(nf)) === null) { return callFunction( intl_CallNumberFormatMethodIfWrapped, this, value, "Intl_NumberFormat_formatToParts" ); } #ifdef NIGHTLY_BUILD var x = value; #else // Step 4. var x = ToNumeric(value); #endif // Step 5. return intl_FormatNumber(nf, x, /* formatToParts = */ true); } /** * Intl.NumberFormat.prototype.formatRange ( start, end ) */ function Intl_NumberFormat_formatRange(start, end) { // Step 1. var nf = this; // Step 2. if (!IsObject(nf) || (nf = intl_GuardToNumberFormat(nf)) === null) { return callFunction( intl_CallNumberFormatMethodIfWrapped, this, start, end, "Intl_NumberFormat_formatRange" ); } // Step 3. if (start === undefined || end === undefined) { ThrowTypeError( JSMSG_UNDEFINED_NUMBER, start === undefined ? "start" : "end", "NumberFormat", "formatRange" ); } // Steps 4-6. return intl_FormatNumberRange(nf, start, end, /* formatToParts = */ false); } /** * Intl.NumberFormat.prototype.formatRangeToParts ( start, end ) */ function Intl_NumberFormat_formatRangeToParts(start, end) { // Step 1. var nf = this; // Step 2. if (!IsObject(nf) || (nf = intl_GuardToNumberFormat(nf)) === null) { return callFunction( intl_CallNumberFormatMethodIfWrapped, this, start, end, "Intl_NumberFormat_formatRangeToParts" ); } // Step 3. if (start === undefined || end === undefined) { ThrowTypeError( JSMSG_UNDEFINED_NUMBER, start === undefined ? "start" : "end", "NumberFormat", "formatRangeToParts" ); } // Steps 4-6. return intl_FormatNumberRange(nf, start, end, /* formatToParts = */ true); } /** * Returns the resolved options for a NumberFormat object. * * Spec: ECMAScript Internationalization API Specification, 11.4.5. */ function Intl_NumberFormat_resolvedOptions() { // Steps 1-3. var thisArg = UnwrapNumberFormat(this); var nf = thisArg; if (!IsObject(nf) || (nf = intl_GuardToNumberFormat(nf)) === null) { return callFunction( intl_CallNumberFormatMethodIfWrapped, thisArg, "Intl_NumberFormat_resolvedOptions" ); } var internals = getNumberFormatInternals(nf); // Steps 4-5. var result = { locale: internals.locale, numberingSystem: internals.numberingSystem, style: internals.style, }; // currency, currencyDisplay, and currencySign are only present for currency // formatters. assert( hasOwn("currency", internals) === (internals.style === "currency"), "currency is present iff style is 'currency'" ); assert( hasOwn("currencyDisplay", internals) === (internals.style === "currency"), "currencyDisplay is present iff style is 'currency'" ); assert( hasOwn("currencySign", internals) === (internals.style === "currency"), "currencySign is present iff style is 'currency'" ); if (hasOwn("currency", internals)) { DefineDataProperty(result, "currency", internals.currency); DefineDataProperty(result, "currencyDisplay", internals.currencyDisplay); DefineDataProperty(result, "currencySign", internals.currencySign); } // unit and unitDisplay are only present for unit formatters. assert( hasOwn("unit", internals) === (internals.style === "unit"), "unit is present iff style is 'unit'" ); assert( hasOwn("unitDisplay", internals) === (internals.style === "unit"), "unitDisplay is present iff style is 'unit'" ); if (hasOwn("unit", internals)) { DefineDataProperty(result, "unit", internals.unit); DefineDataProperty(result, "unitDisplay", internals.unitDisplay); } DefineDataProperty( result, "minimumIntegerDigits", internals.minimumIntegerDigits ); // Min/Max fraction digits are either both present or not present at all. assert( hasOwn("minimumFractionDigits", internals) === hasOwn("maximumFractionDigits", internals), "minimumFractionDigits is present iff maximumFractionDigits is present" ); if (hasOwn("minimumFractionDigits", internals)) { DefineDataProperty( result, "minimumFractionDigits", internals.minimumFractionDigits ); DefineDataProperty( result, "maximumFractionDigits", internals.maximumFractionDigits ); } // Min/Max significant digits are either both present or not present at all. assert( hasOwn("minimumSignificantDigits", internals) === hasOwn("maximumSignificantDigits", internals), "minimumSignificantDigits is present iff maximumSignificantDigits is present" ); if (hasOwn("minimumSignificantDigits", internals)) { DefineDataProperty( result, "minimumSignificantDigits", internals.minimumSignificantDigits ); DefineDataProperty( result, "maximumSignificantDigits", internals.maximumSignificantDigits ); } DefineDataProperty(result, "useGrouping", internals.useGrouping); var notation = internals.notation; DefineDataProperty(result, "notation", notation); if (notation === "compact") { DefineDataProperty(result, "compactDisplay", internals.compactDisplay); } DefineDataProperty(result, "signDisplay", internals.signDisplay); #ifdef NIGHTLY_BUILD DefineDataProperty(result, "roundingMode", internals.roundingMode); DefineDataProperty(result, "roundingIncrement", internals.roundingIncrement); DefineDataProperty( result, "trailingZeroDisplay", internals.trailingZeroDisplay ); DefineDataProperty(result, "roundingPriority", internals.roundingPriority); #endif // Step 6. return result; }