src/third_party/WebKit/Source/JavaScriptCore/runtime/NumberPrototype.cpp - cobalt - Git at Google

 /*
  *  Copyright (C) 1999-2000,2003 Harri Porten (porten@kde.org)
  *  Copyright (C) 2007, 2008, 2011 Apple Inc. All rights reserved.
  *
  *  This library is free software; you can redistribute it and/or
  *  modify it under the terms of the GNU Lesser General Public
  *  License as published by the Free Software Foundation; either
  *  version 2 of the License, or (at your option) any later version.
  *
  *  This library is distributed in the hope that it will be useful,
  *  but WITHOUT ANY WARRANTY; without even the implied warranty of
  *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  *  Lesser General Public License for more details.
  *
  *  You should have received a copy of the GNU Lesser General Public
  *  License along with this library; if not, write to the Free Software
  *  Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301
  *  USA
  *
  */

 #include "config.h"
 #include "NumberPrototype.h"

 #include "BigInteger.h"
 #include "Error.h"
 #include "JSFunction.h"
 #include "JSGlobalObject.h"
 #include "JSString.h"
 #include "Operations.h"
 #include "Uint16WithFraction.h"
 #include <wtf/dtoa.h>
 #include <wtf/Assertions.h>
 #include <wtf/MathExtras.h>
 #include <wtf/Vector.h>
 #include <wtf/dtoa/double-conversion.h>

 using namespace WTF::double_conversion;

 // To avoid conflict with WTF::StringBuilder.
 typedef WTF::double_conversion::StringBuilder DoubleConversionStringBuilder;

 namespace JSC {

 static EncodedJSValue JSC_HOST_CALL numberProtoFuncToString(ExecState*);
 static EncodedJSValue JSC_HOST_CALL numberProtoFuncToLocaleString(ExecState*);
 static EncodedJSValue JSC_HOST_CALL numberProtoFuncValueOf(ExecState*);
 static EncodedJSValue JSC_HOST_CALL numberProtoFuncToFixed(ExecState*);
 static EncodedJSValue JSC_HOST_CALL numberProtoFuncToExponential(ExecState*);
 static EncodedJSValue JSC_HOST_CALL numberProtoFuncToPrecision(ExecState*);

 }

 #include "NumberPrototype.lut.h"

 namespace JSC {

 const ClassInfo NumberPrototype::s_info = { "Number", NumberObject::s_classinfo(), 0, ExecState::numberPrototypeTable, CREATE_METHOD_TABLE(NumberPrototype) };

 /* Source for NumberPrototype.lut.h
 @begin numberPrototypeTable
   toString          numberProtoFuncToString         DontEnum|Function 1
   toLocaleString    numberProtoFuncToLocaleString   DontEnum|Function 0
   valueOf           numberProtoFuncValueOf          DontEnum|Function 0
   toFixed           numberProtoFuncToFixed          DontEnum|Function 1
   toExponential     numberProtoFuncToExponential    DontEnum|Function 1
   toPrecision       numberProtoFuncToPrecision      DontEnum|Function 1
 @end
 */

 ASSERT_HAS_TRIVIAL_DESTRUCTOR(NumberPrototype);

 NumberPrototype::NumberPrototype(ExecState* exec, Structure* structure)
     : NumberObject(exec->globalData(), structure)
 {
 }

 void NumberPrototype::finishCreation(ExecState* exec, JSGlobalObject*)
 {
     Base::finishCreation(exec->globalData());
     setInternalValue(exec->globalData(), jsNumber(0));

     ASSERT(inherits(&s_info));
 }

 bool NumberPrototype::getOwnPropertySlot(JSCell* cell, ExecState* exec, PropertyName propertyName, PropertySlot &slot)
 {
     return getStaticFunctionSlot<NumberObject>(exec, ExecState::numberPrototypeTable(exec), jsCast<NumberPrototype*>(cell), propertyName, slot);
 }

 bool NumberPrototype::getOwnPropertyDescriptor(JSObject* object, ExecState* exec, PropertyName propertyName, PropertyDescriptor& descriptor)
 {
     return getStaticFunctionDescriptor<NumberObject>(exec, ExecState::numberPrototypeTable(exec), jsCast<NumberPrototype*>(object), propertyName, descriptor);
 }

 // ------------------------------ Functions ---------------------------

 static ALWAYS_INLINE bool toThisNumber(JSValue thisValue, double& x)
 {
     if (thisValue.isInt32()) {
         x = thisValue.asInt32();
         return true;
     }

     if (thisValue.isDouble()) {
         x = thisValue.asDouble();
         return true;
     }

     if (thisValue.isCell() && thisValue.asCell()->structure()->typeInfo().isNumberObject()) {
         x = static_cast<const NumberObject*>(thisValue.asCell())->internalValue().asNumber();
         return true;
     }

     return false;
 }

 static ALWAYS_INLINE bool getIntegerArgumentInRange(ExecState* exec, int low, int high, int& result, bool& isUndefined)
 {
     result = 0;
     isUndefined = false;

     JSValue argument0 = exec->argument(0);
     if (argument0.isUndefined()) {
         isUndefined = true;
         return true;
     }

     double asDouble = argument0.toInteger(exec);
     if (asDouble < low || asDouble > high)
         return false;

     result = static_cast<int>(asDouble);
     return true;
 }

 // The largest finite floating point number is 1.mantissa * 2^(0x7fe-0x3ff).
 // Since 2^N in binary is a one bit followed by N zero bits. 1 * 2^3ff requires
 // at most 1024 characters to the left of a decimal point, in base 2 (1025 if
 // we include a minus sign). For the fraction, a value with an exponent of 0
 // has up to 52 bits to the right of the decimal point. Each decrement of the
 // exponent down to a minimum of -0x3fe adds an additional digit to the length
 // of the fraction. As such the maximum fraction size is 1075 (1076 including
 // a point). We pick a buffer size such that can simply place the point in the
 // center of the buffer, and are guaranteed to have enough space in each direction
 // fo any number of digits an IEEE number may require to represent.
 typedef char RadixBuffer[2180];

 // Mapping from integers 0..35 to digit identifying this value, for radix 2..36.
 static const char radixDigits[] = "0123456789abcdefghijklmnopqrstuvwxyz";

 static char* toStringWithRadix(RadixBuffer& buffer, double number, unsigned radix)
 {
     ASSERT(isfinite(number));
     ASSERT(radix >= 2 && radix <= 36);

     // Position the decimal point at the center of the string, set
     // the startOfResultString pointer to point at the decimal point.
     char* decimalPoint = buffer + sizeof(buffer) / 2;
     char* startOfResultString = decimalPoint;

     // Extract the sign.
     bool isNegative = number < 0;
     if (signbit(number))
         number = -number;
     double integerPart = floor(number);

     // We use this to test for odd values in odd radix bases.
     // Where the base is even, (e.g. 10), to determine whether a value is even we need only
     // consider the least significant digit. For example, 124 in base 10 is even, because '4'
     // is even. if the radix is odd, then the radix raised to an integer power is also odd.
     // E.g. in base 5, 124 represents (1 * 125 + 2 * 25 + 4 * 5). Since each digit in the value
     // is multiplied by an odd number, the result is even if the sum of all digits is even.
     //
     // For the integer portion of the result, we only need test whether the integer value is
     // even or odd. For each digit of the fraction added, we should invert our idea of whether
     // the number is odd if the new digit is odd.
     //
     // Also initialize digit to this value; for even radix values we only need track whether
     // the last individual digit was odd.
     bool integerPartIsOdd = integerPart <= static_cast<double>(0x1FFFFFFFFFFFFFull) && static_cast<int64_t>(integerPart) & 1;
     ASSERT(integerPartIsOdd == static_cast<bool>(fmod(integerPart, 2)));
     bool isOddInOddRadix = integerPartIsOdd;
     uint32_t digit = integerPartIsOdd;

     // Check if the value has a fractional part to convert.
     double fractionPart = number - integerPart;
     if (fractionPart) {
         // Write the decimal point now.
         *decimalPoint = '.';

         // Higher precision representation of the fractional part.
         Uint16WithFraction fraction(fractionPart);

         bool needsRoundingUp = false;
         char* endOfResultString = decimalPoint + 1;

         // Calculate the delta from the current number to the next & previous possible IEEE numbers.
         double nextNumber = nextafter(number, std::numeric_limits<double>::infinity());
         double lastNumber = nextafter(number, -std::numeric_limits<double>::infinity());
         ASSERT(isfinite(nextNumber) && !signbit(nextNumber));
         ASSERT(isfinite(lastNumber) && !signbit(lastNumber));
         double deltaNextDouble = nextNumber - number;
         double deltaLastDouble = number - lastNumber;
         ASSERT(isfinite(deltaNextDouble) && !signbit(deltaNextDouble));
         ASSERT(isfinite(deltaLastDouble) && !signbit(deltaLastDouble));

         // We track the delta from the current value to the next, to track how many digits of the
         // fraction we need to write. For example, if the value we are converting is precisely
         // 1.2345, so far we have written the digits "1.23" to a string leaving a remainder of
         // 0.45, and we want to determine whether we can round off, or whether we need to keep
         // appending digits ('4'). We can stop adding digits provided that then next possible
         // lower IEEE value is further from 1.23 than the remainder we'd be rounding off (0.45),
         // which is to say, less than 1.2255. Put another way, the delta between the prior
         // possible value and this number must be more than 2x the remainder we'd be rounding off
         // (or more simply half the delta between numbers must be greater than the remainder).
         //
         // Similarly we need track the delta to the next possible value, to dertermine whether
         // to round up. In almost all cases (other than at exponent boundaries) the deltas to
         // prior and subsequent values are identical, so we don't need track then separately.
         if (deltaNextDouble != deltaLastDouble) {
             // Since the deltas are different track them separately. Pre-multiply by 0.5.
             Uint16WithFraction halfDeltaNext(deltaNextDouble, 1);
             Uint16WithFraction halfDeltaLast(deltaLastDouble, 1);

             while (true) {
                 // examine the remainder to determine whether we should be considering rounding
                 // up or down. If remainder is precisely 0.5 rounding is to even.
                 int dComparePoint5 = fraction.comparePoint5();
                 if (dComparePoint5 > 0 || (!dComparePoint5 && (radix & 1 ? isOddInOddRadix : digit & 1))) {
                     // Check for rounding up; are we closer to the value we'd round off to than
                     // the next IEEE value would be?
                     if (fraction.sumGreaterThanOne(halfDeltaNext)) {
                         needsRoundingUp = true;
                         break;
                     }
                 } else {
                     // Check for rounding down; are we closer to the value we'd round off to than
                     // the prior IEEE value would be?
                     if (fraction < halfDeltaLast)
                         break;
                 }

                 ASSERT(endOfResultString < (buffer + sizeof(buffer) - 1));
                 // Write a digit to the string.
                 fraction *= radix;
                 digit = fraction.floorAndSubtract();
                 *endOfResultString++ = radixDigits[digit];
                 // Keep track whether the portion written is currently even, if the radix is odd.
                 if (digit & 1)
                     isOddInOddRadix = !isOddInOddRadix;

                 // Shift the fractions by radix.
                 halfDeltaNext *= radix;
                 halfDeltaLast *= radix;
             }
         } else {
             // This code is identical to that above, except since deltaNextDouble != deltaLastDouble
             // we don't need to track these two values separately.
             Uint16WithFraction halfDelta(deltaNextDouble, 1);

             while (true) {
                 int dComparePoint5 = fraction.comparePoint5();
                 if (dComparePoint5 > 0 || (!dComparePoint5 && (radix & 1 ? isOddInOddRadix : digit & 1))) {
                     if (fraction.sumGreaterThanOne(halfDelta)) {
                         needsRoundingUp = true;
                         break;
                     }
                 } else if (fraction < halfDelta)
                     break;

                 ASSERT(endOfResultString < (buffer + sizeof(buffer) - 1));
                 fraction *= radix;
                 digit = fraction.floorAndSubtract();
                 if (digit & 1)
                     isOddInOddRadix = !isOddInOddRadix;
                 *endOfResultString++ = radixDigits[digit];

                 halfDelta *= radix;
             }
         }

         // Check if the fraction needs rounding off (flag set in the loop writing digits, above).
         if (needsRoundingUp) {
             // Whilst the last digit is the maximum in the current radix, remove it.
             // e.g. rounding up the last digit in "12.3999" is the same as rounding up the
             // last digit in "12.3" - both round up to "12.4".
             while (endOfResultString[-1] == radixDigits[radix - 1])
                 --endOfResultString;

             // Radix digits are sequential in ascii/unicode, except for '9' and 'a'.
             // E.g. the first 'if' case handles rounding 67.89 to 67.8a in base 16.
             // The 'else if' case handles rounding of all other digits.
             if (endOfResultString[-1] == '9')
                 endOfResultString[-1] = 'a';
             else if (endOfResultString[-1] != '.')
                 ++endOfResultString[-1];
             else {
                 // One other possibility - there may be no digits to round up in the fraction
                 // (or all may be been rounded off already), in which case we may need to
                 // round into the integer portion of the number. Remove the decimal point.
                 --endOfResultString;
                 // In order to get here there must have been a non-zero fraction, in which case
                 // there must be at least one bit of the value's mantissa not in use in the
                 // integer part of the number. As such, adding to the integer part should not
                 // be able to lose precision.
                 ASSERT((integerPart + 1) - integerPart == 1);
                 ++integerPart;
             }
         } else {
             // We only need to check for trailing zeros if the value does not get rounded up.
             while (endOfResultString[-1] == '0')
                 --endOfResultString;
         }

         *endOfResultString = '\0';
         ASSERT(endOfResultString < buffer + sizeof(buffer));
     } else
         *decimalPoint = '\0';

     BigInteger units(integerPart);

     // Always loop at least once, to emit at least '0'.
     do {
         ASSERT(buffer < startOfResultString);

         // Read a single digit and write it to the front of the string.
         // Divide by radix to remove one digit from the value.
         digit = units.divide(radix);
         *--startOfResultString = radixDigits[digit];
     } while (!!units);

     // If the number is negative, prepend '-'.
     if (isNegative)
         *--startOfResultString = '-';
     ASSERT(buffer <= startOfResultString);

     return startOfResultString;
 }

 static String toStringWithRadix(int32_t number, unsigned radix)
 {
     LChar buf[1 + 32]; // Worst case is radix == 2, which gives us 32 digits + sign.
     LChar* end = buf + WTF_ARRAY_LENGTH(buf);
     LChar* p = end;

     bool negative = false;
     uint32_t positiveNumber = number;
     if (number < 0) {
         negative = true;
         positiveNumber = -number;
     }

     while (positiveNumber) {
         uint32_t index = positiveNumber % radix;
         ASSERT(index < sizeof(radixDigits));
         *--p = static_cast<LChar>(radixDigits[index]);
         positiveNumber /= radix;
     }
     if (negative)
         *--p = '-';

     return String(p, static_cast<unsigned>(end - p));
 }

 // toExponential converts a number to a string, always formatting as an expoential.
 // This method takes an optional argument specifying a number of *decimal places*
 // to round the significand to (or, put another way, this method optionally rounds
 // to argument-plus-one significant figures).
 EncodedJSValue JSC_HOST_CALL numberProtoFuncToExponential(ExecState* exec)
 {
     double x;
     if (!toThisNumber(exec->hostThisValue(), x))
         return throwVMTypeError(exec);

     // Get the argument.
     int decimalPlacesInExponent;
     bool isUndefined;
     if (!getIntegerArgumentInRange(exec, 0, 20, decimalPlacesInExponent, isUndefined))
         return throwVMError(exec, createRangeError(exec, ASCIILiteral("toExponential() argument must be between 0 and 20")));

     // Handle NaN and Infinity.
     if (!isfinite(x))
         return JSValue::encode(jsString(exec, String::numberToStringECMAScript(x)));

     // Round if the argument is not undefined, always format as exponential.
     char buffer[WTF::NumberToStringBufferLength];
     DoubleConversionStringBuilder builder(buffer, WTF::NumberToStringBufferLength);
     const DoubleToStringConverter& converter = DoubleToStringConverter::EcmaScriptConverter();
     builder.Reset();
     isUndefined
         ? converter.ToExponential(x, -1, &builder)
         : converter.ToExponential(x, decimalPlacesInExponent, &builder);
     return JSValue::encode(jsString(exec, String(builder.Finalize())));
 }

 // toFixed converts a number to a string, always formatting as an a decimal fraction.
 // This method takes an argument specifying a number of decimal places to round the
 // significand to. However when converting large values (1e+21 and above) this
 // method will instead fallback to calling ToString.
 EncodedJSValue JSC_HOST_CALL numberProtoFuncToFixed(ExecState* exec)
 {
     double x;
     if (!toThisNumber(exec->hostThisValue(), x))
         return throwVMTypeError(exec);

     // Get the argument.
     int decimalPlaces;
     bool isUndefined; // This is ignored; undefined treated as 0.
     if (!getIntegerArgumentInRange(exec, 0, 20, decimalPlaces, isUndefined))
         return throwVMError(exec, createRangeError(exec, ASCIILiteral("toFixed() argument must be between 0 and 20")));

     // 15.7.4.5.7 states "If x >= 10^21, then let m = ToString(x)"
     // This also covers Ininity, and structure the check so that NaN
     // values are also handled by numberToString
     if (!(fabs(x) < 1e+21))
         return JSValue::encode(jsString(exec, String::numberToStringECMAScript(x)));

     // The check above will return false for NaN or Infinity, these will be
     // handled by numberToString.
     ASSERT(isfinite(x));

     NumberToStringBuffer buffer;
     return JSValue::encode(jsString(exec, String(numberToFixedWidthString(x, decimalPlaces, buffer))));
 }

 // toPrecision converts a number to a string, takeing an argument specifying a
 // number of significant figures to round the significand to. For positive
 // exponent, all values that can be represented using a decimal fraction will
 // be, e.g. when rounding to 3 s.f. any value up to 999 will be formated as a
 // decimal, whilst 1000 is converted to the exponential representation 1.00e+3.
 // For negative exponents values >= 1e-6 are formated as decimal fractions,
 // with smaller values converted to exponential representation.
 EncodedJSValue JSC_HOST_CALL numberProtoFuncToPrecision(ExecState* exec)
 {
     double x;
     if (!toThisNumber(exec->hostThisValue(), x))
         return throwVMTypeError(exec);

     // Get the argument.
     int significantFigures;
     bool isUndefined;
     if (!getIntegerArgumentInRange(exec, 1, 21, significantFigures, isUndefined))
         return throwVMError(exec, createRangeError(exec, ASCIILiteral("toPrecision() argument must be between 1 and 21")));

     // To precision called with no argument is treated as ToString.
     if (isUndefined)
         return JSValue::encode(jsString(exec, String::numberToStringECMAScript(x)));

     // Handle NaN and Infinity.
     if (!isfinite(x))
         return JSValue::encode(jsString(exec, String::numberToStringECMAScript(x)));

     NumberToStringBuffer buffer;
     return JSValue::encode(jsString(exec, String(numberToFixedPrecisionString(x, significantFigures, buffer))));
 }

 static inline int32_t extractRadixFromArgs(ExecState* exec)
 {
     JSValue radixValue = exec->argument(0);
     int32_t radix;
     if (radixValue.isInt32())
         radix = radixValue.asInt32();
     else if (radixValue.isUndefined())
         radix = 10;
     else
         radix = static_cast<int32_t>(radixValue.toInteger(exec)); // nan -> 0

     return radix;
 }

 static inline EncodedJSValue integerValueToString(ExecState* exec, int32_t radix, int32_t value)
 {
     // A negative value casted to unsigned would be bigger than 36 (the max radix).
     if (static_cast<unsigned>(value) < static_cast<unsigned>(radix)) {
         ASSERT(value <= 36);
         ASSERT(value >= 0);
         JSGlobalData* globalData = &exec->globalData();
         return JSValue::encode(globalData->smallStrings.singleCharacterString(globalData, radixDigits[value]));
     }

     if (radix == 10) {
         JSGlobalData* globalData = &exec->globalData();
         return JSValue::encode(jsString(globalData, globalData->numericStrings.add(value)));
     }

     return JSValue::encode(jsString(exec, toStringWithRadix(value, radix)));

 }

 EncodedJSValue JSC_HOST_CALL numberProtoFuncToString(ExecState* exec)
 {
     double doubleValue;
     if (!toThisNumber(exec->hostThisValue(), doubleValue))
         return throwVMTypeError(exec);

     int32_t radix = extractRadixFromArgs(exec);
     if (radix < 2 || radix > 36)
         return throwVMError(exec, createRangeError(exec, ASCIILiteral("toString() radix argument must be between 2 and 36")));

     int32_t integerValue = static_cast<int32_t>(doubleValue);
     if (integerValue == doubleValue)
         return integerValueToString(exec, radix, integerValue);

     if (radix == 10) {
         JSGlobalData* globalData = &exec->globalData();
         return JSValue::encode(jsString(globalData, globalData->numericStrings.add(doubleValue)));
     }

     if (!isfinite(doubleValue))
         return JSValue::encode(jsString(exec, String::numberToStringECMAScript(doubleValue)));

     RadixBuffer s;
     return JSValue::encode(jsString(exec, toStringWithRadix(s, doubleValue, radix)));
 }

 EncodedJSValue JSC_HOST_CALL numberProtoFuncToLocaleString(ExecState* exec)
 {
     double x;
     if (!toThisNumber(exec->hostThisValue(), x))
         return throwVMTypeError(exec);

     return JSValue::encode(jsNumber(x).toString(exec));
 }

 EncodedJSValue JSC_HOST_CALL numberProtoFuncValueOf(ExecState* exec)
 {
     double x;
     if (!toThisNumber(exec->hostThisValue(), x))
         return throwVMTypeError(exec);
     return JSValue::encode(jsNumber(x));
 }

 } // namespace JSC
	/*
	* Copyright (C) 1999-2000,2003 Harri Porten (porten@kde.org)
	* Copyright (C) 2007, 2008, 2011 Apple Inc. All rights reserved.
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Lesser General Public
	* License as published by the Free Software Foundation; either
	* version 2 of the License, or (at your option) any later version.
	*
	* This library is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this library; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301
	* USA
	*
	*/

	#include "config.h"
	#include "NumberPrototype.h"

	#include "BigInteger.h"
	#include "Error.h"
	#include "JSFunction.h"
	#include "JSGlobalObject.h"
	#include "JSString.h"
	#include "Operations.h"
	#include "Uint16WithFraction.h"
	#include <wtf/dtoa.h>
	#include <wtf/Assertions.h>
	#include <wtf/MathExtras.h>
	#include <wtf/Vector.h>
	#include <wtf/dtoa/double-conversion.h>

	using namespace WTF::double_conversion;

	// To avoid conflict with WTF::StringBuilder.
	typedef WTF::double_conversion::StringBuilder DoubleConversionStringBuilder;

	namespace JSC {

	static EncodedJSValue JSC_HOST_CALL numberProtoFuncToString(ExecState*);
	static EncodedJSValue JSC_HOST_CALL numberProtoFuncToLocaleString(ExecState*);
	static EncodedJSValue JSC_HOST_CALL numberProtoFuncValueOf(ExecState*);
	static EncodedJSValue JSC_HOST_CALL numberProtoFuncToFixed(ExecState*);
	static EncodedJSValue JSC_HOST_CALL numberProtoFuncToExponential(ExecState*);
	static EncodedJSValue JSC_HOST_CALL numberProtoFuncToPrecision(ExecState*);

	}

	#include "NumberPrototype.lut.h"

	namespace JSC {

	const ClassInfo NumberPrototype::s_info = { "Number", NumberObject::s_classinfo(), 0, ExecState::numberPrototypeTable, CREATE_METHOD_TABLE(NumberPrototype) };

	/* Source for NumberPrototype.lut.h
	@begin numberPrototypeTable
	toString numberProtoFuncToString DontEnum\|Function 1
	toLocaleString numberProtoFuncToLocaleString DontEnum\|Function 0
	valueOf numberProtoFuncValueOf DontEnum\|Function 0
	toFixed numberProtoFuncToFixed DontEnum\|Function 1
	toExponential numberProtoFuncToExponential DontEnum\|Function 1
	toPrecision numberProtoFuncToPrecision DontEnum\|Function 1
	@end
	*/

	ASSERT_HAS_TRIVIAL_DESTRUCTOR(NumberPrototype);

	NumberPrototype::NumberPrototype(ExecState* exec, Structure* structure)
	: NumberObject(exec->globalData(), structure)
	{
	}

	void NumberPrototype::finishCreation(ExecState* exec, JSGlobalObject*)
	{
	Base::finishCreation(exec->globalData());
	setInternalValue(exec->globalData(), jsNumber(0));

	ASSERT(inherits(&s_info));
	}

	bool NumberPrototype::getOwnPropertySlot(JSCell* cell, ExecState* exec, PropertyName propertyName, PropertySlot &slot)
	{
	return getStaticFunctionSlot<NumberObject>(exec, ExecState::numberPrototypeTable(exec), jsCast<NumberPrototype*>(cell), propertyName, slot);
	}

	bool NumberPrototype::getOwnPropertyDescriptor(JSObject* object, ExecState* exec, PropertyName propertyName, PropertyDescriptor& descriptor)
	{
	return getStaticFunctionDescriptor<NumberObject>(exec, ExecState::numberPrototypeTable(exec), jsCast<NumberPrototype*>(object), propertyName, descriptor);
	}

	// ------------------------------ Functions ---------------------------

	static ALWAYS_INLINE bool toThisNumber(JSValue thisValue, double& x)
	{
	if (thisValue.isInt32()) {
	x = thisValue.asInt32();
	return true;
	}

	if (thisValue.isDouble()) {
	x = thisValue.asDouble();
	return true;
	}

	if (thisValue.isCell() && thisValue.asCell()->structure()->typeInfo().isNumberObject()) {
	x = static_cast<const NumberObject*>(thisValue.asCell())->internalValue().asNumber();
	return true;
	}

	return false;
	}

	static ALWAYS_INLINE bool getIntegerArgumentInRange(ExecState* exec, int low, int high, int& result, bool& isUndefined)
	{
	result = 0;
	isUndefined = false;

	JSValue argument0 = exec->argument(0);
	if (argument0.isUndefined()) {
	isUndefined = true;
	return true;
	}

	double asDouble = argument0.toInteger(exec);
	if (asDouble < low \|\| asDouble > high)
	return false;

	result = static_cast<int>(asDouble);
	return true;
	}

	// The largest finite floating point number is 1.mantissa * 2^(0x7fe-0x3ff).
	// Since 2^N in binary is a one bit followed by N zero bits. 1 * 2^3ff requires
	// at most 1024 characters to the left of a decimal point, in base 2 (1025 if
	// we include a minus sign). For the fraction, a value with an exponent of 0
	// has up to 52 bits to the right of the decimal point. Each decrement of the
	// exponent down to a minimum of -0x3fe adds an additional digit to the length
	// of the fraction. As such the maximum fraction size is 1075 (1076 including
	// a point). We pick a buffer size such that can simply place the point in the
	// center of the buffer, and are guaranteed to have enough space in each direction
	// fo any number of digits an IEEE number may require to represent.
	typedef char RadixBuffer[2180];

	// Mapping from integers 0..35 to digit identifying this value, for radix 2..36.
	static const char radixDigits[] = "0123456789abcdefghijklmnopqrstuvwxyz";

	static char* toStringWithRadix(RadixBuffer& buffer, double number, unsigned radix)
	{
	ASSERT(isfinite(number));
	ASSERT(radix >= 2 && radix <= 36);

	// Position the decimal point at the center of the string, set
	// the startOfResultString pointer to point at the decimal point.
	char* decimalPoint = buffer + sizeof(buffer) / 2;
	char* startOfResultString = decimalPoint;

	// Extract the sign.
	bool isNegative = number < 0;
	if (signbit(number))
	number = -number;
	double integerPart = floor(number);

	// We use this to test for odd values in odd radix bases.
	// Where the base is even, (e.g. 10), to determine whether a value is even we need only
	// consider the least significant digit. For example, 124 in base 10 is even, because '4'
	// is even. if the radix is odd, then the radix raised to an integer power is also odd.
	// E.g. in base 5, 124 represents (1 * 125 + 2 * 25 + 4 * 5). Since each digit in the value
	// is multiplied by an odd number, the result is even if the sum of all digits is even.
	//
	// For the integer portion of the result, we only need test whether the integer value is
	// even or odd. For each digit of the fraction added, we should invert our idea of whether
	// the number is odd if the new digit is odd.
	//
	// Also initialize digit to this value; for even radix values we only need track whether
	// the last individual digit was odd.
	bool integerPartIsOdd = integerPart <= static_cast<double>(0x1FFFFFFFFFFFFFull) && static_cast<int64_t>(integerPart) & 1;
	ASSERT(integerPartIsOdd == static_cast<bool>(fmod(integerPart, 2)));
	bool isOddInOddRadix = integerPartIsOdd;
	uint32_t digit = integerPartIsOdd;

	// Check if the value has a fractional part to convert.
	double fractionPart = number - integerPart;
	if (fractionPart) {
	// Write the decimal point now.
	*decimalPoint = '.';

	// Higher precision representation of the fractional part.
	Uint16WithFraction fraction(fractionPart);

	bool needsRoundingUp = false;
	char* endOfResultString = decimalPoint + 1;

	// Calculate the delta from the current number to the next & previous possible IEEE numbers.
	double nextNumber = nextafter(number, std::numeric_limits<double>::infinity());
	double lastNumber = nextafter(number, -std::numeric_limits<double>::infinity());
	ASSERT(isfinite(nextNumber) && !signbit(nextNumber));
	ASSERT(isfinite(lastNumber) && !signbit(lastNumber));
	double deltaNextDouble = nextNumber - number;
	double deltaLastDouble = number - lastNumber;
	ASSERT(isfinite(deltaNextDouble) && !signbit(deltaNextDouble));
	ASSERT(isfinite(deltaLastDouble) && !signbit(deltaLastDouble));

	// We track the delta from the current value to the next, to track how many digits of the
	// fraction we need to write. For example, if the value we are converting is precisely
	// 1.2345, so far we have written the digits "1.23" to a string leaving a remainder of
	// 0.45, and we want to determine whether we can round off, or whether we need to keep
	// appending digits ('4'). We can stop adding digits provided that then next possible
	// lower IEEE value is further from 1.23 than the remainder we'd be rounding off (0.45),
	// which is to say, less than 1.2255. Put another way, the delta between the prior
	// possible value and this number must be more than 2x the remainder we'd be rounding off
	// (or more simply half the delta between numbers must be greater than the remainder).
	//
	// Similarly we need track the delta to the next possible value, to dertermine whether
	// to round up. In almost all cases (other than at exponent boundaries) the deltas to
	// prior and subsequent values are identical, so we don't need track then separately.
	if (deltaNextDouble != deltaLastDouble) {
	// Since the deltas are different track them separately. Pre-multiply by 0.5.
	Uint16WithFraction halfDeltaNext(deltaNextDouble, 1);
	Uint16WithFraction halfDeltaLast(deltaLastDouble, 1);

	while (true) {
	// examine the remainder to determine whether we should be considering rounding
	// up or down. If remainder is precisely 0.5 rounding is to even.
	int dComparePoint5 = fraction.comparePoint5();
	if (dComparePoint5 > 0 \|\| (!dComparePoint5 && (radix & 1 ? isOddInOddRadix : digit & 1))) {
	// Check for rounding up; are we closer to the value we'd round off to than
	// the next IEEE value would be?
	if (fraction.sumGreaterThanOne(halfDeltaNext)) {
	needsRoundingUp = true;
	break;
	}
	} else {
	// Check for rounding down; are we closer to the value we'd round off to than
	// the prior IEEE value would be?
	if (fraction < halfDeltaLast)
	break;
	}

	ASSERT(endOfResultString < (buffer + sizeof(buffer) - 1));
	// Write a digit to the string.
	fraction *= radix;
	digit = fraction.floorAndSubtract();
	*endOfResultString++ = radixDigits[digit];
	// Keep track whether the portion written is currently even, if the radix is odd.
	if (digit & 1)
	isOddInOddRadix = !isOddInOddRadix;

	// Shift the fractions by radix.
	halfDeltaNext *= radix;
	halfDeltaLast *= radix;
	}
	} else {
	// This code is identical to that above, except since deltaNextDouble != deltaLastDouble
	// we don't need to track these two values separately.
	Uint16WithFraction halfDelta(deltaNextDouble, 1);

	while (true) {
	int dComparePoint5 = fraction.comparePoint5();
	if (dComparePoint5 > 0 \|\| (!dComparePoint5 && (radix & 1 ? isOddInOddRadix : digit & 1))) {
	if (fraction.sumGreaterThanOne(halfDelta)) {
	needsRoundingUp = true;
	break;
	}
	} else if (fraction < halfDelta)
	break;

	ASSERT(endOfResultString < (buffer + sizeof(buffer) - 1));
	fraction *= radix;
	digit = fraction.floorAndSubtract();
	if (digit & 1)
	isOddInOddRadix = !isOddInOddRadix;
	*endOfResultString++ = radixDigits[digit];

	halfDelta *= radix;
	}
	}

	// Check if the fraction needs rounding off (flag set in the loop writing digits, above).
	if (needsRoundingUp) {
	// Whilst the last digit is the maximum in the current radix, remove it.
	// e.g. rounding up the last digit in "12.3999" is the same as rounding up the
	// last digit in "12.3" - both round up to "12.4".
	while (endOfResultString[-1] == radixDigits[radix - 1])
	--endOfResultString;

	// Radix digits are sequential in ascii/unicode, except for '9' and 'a'.
	// E.g. the first 'if' case handles rounding 67.89 to 67.8a in base 16.
	// The 'else if' case handles rounding of all other digits.
	if (endOfResultString[-1] == '9')
	endOfResultString[-1] = 'a';
	else if (endOfResultString[-1] != '.')
	++endOfResultString[-1];
	else {
	// One other possibility - there may be no digits to round up in the fraction
	// (or all may be been rounded off already), in which case we may need to
	// round into the integer portion of the number. Remove the decimal point.
	--endOfResultString;
	// In order to get here there must have been a non-zero fraction, in which case
	// there must be at least one bit of the value's mantissa not in use in the
	// integer part of the number. As such, adding to the integer part should not
	// be able to lose precision.
	ASSERT((integerPart + 1) - integerPart == 1);
	++integerPart;
	}
	} else {
	// We only need to check for trailing zeros if the value does not get rounded up.
	while (endOfResultString[-1] == '0')
	--endOfResultString;
	}

	*endOfResultString = '\0';
	ASSERT(endOfResultString < buffer + sizeof(buffer));
	} else
	*decimalPoint = '\0';

	BigInteger units(integerPart);

	// Always loop at least once, to emit at least '0'.
	do {
	ASSERT(buffer < startOfResultString);

	// Read a single digit and write it to the front of the string.
	// Divide by radix to remove one digit from the value.
	digit = units.divide(radix);
	*--startOfResultString = radixDigits[digit];
	} while (!!units);

	// If the number is negative, prepend '-'.
	if (isNegative)
	*--startOfResultString = '-';
	ASSERT(buffer <= startOfResultString);

	return startOfResultString;
	}

	static String toStringWithRadix(int32_t number, unsigned radix)
	{
	LChar buf[1 + 32]; // Worst case is radix == 2, which gives us 32 digits + sign.
	LChar* end = buf + WTF_ARRAY_LENGTH(buf);
	LChar* p = end;

	bool negative = false;
	uint32_t positiveNumber = number;
	if (number < 0) {
	negative = true;
	positiveNumber = -number;
	}

	while (positiveNumber) {
	uint32_t index = positiveNumber % radix;
	ASSERT(index < sizeof(radixDigits));
	*--p = static_cast<LChar>(radixDigits[index]);
	positiveNumber /= radix;
	}
	if (negative)
	*--p = '-';

	return String(p, static_cast<unsigned>(end - p));
	}

	// toExponential converts a number to a string, always formatting as an expoential.
	// This method takes an optional argument specifying a number of decimal places
	// to round the significand to (or, put another way, this method optionally rounds
	// to argument-plus-one significant figures).
	EncodedJSValue JSC_HOST_CALL numberProtoFuncToExponential(ExecState* exec)
	{
	double x;
	if (!toThisNumber(exec->hostThisValue(), x))
	return throwVMTypeError(exec);

	// Get the argument.
	int decimalPlacesInExponent;
	bool isUndefined;
	if (!getIntegerArgumentInRange(exec, 0, 20, decimalPlacesInExponent, isUndefined))
	return throwVMError(exec, createRangeError(exec, ASCIILiteral("toExponential() argument must be between 0 and 20")));

	// Handle NaN and Infinity.
	if (!isfinite(x))
	return JSValue::encode(jsString(exec, String::numberToStringECMAScript(x)));

	// Round if the argument is not undefined, always format as exponential.
	char buffer[WTF::NumberToStringBufferLength];
	DoubleConversionStringBuilder builder(buffer, WTF::NumberToStringBufferLength);
	const DoubleToStringConverter& converter = DoubleToStringConverter::EcmaScriptConverter();
	builder.Reset();
	isUndefined
	? converter.ToExponential(x, -1, &builder)
	: converter.ToExponential(x, decimalPlacesInExponent, &builder);
	return JSValue::encode(jsString(exec, String(builder.Finalize())));
	}

	// toFixed converts a number to a string, always formatting as an a decimal fraction.
	// This method takes an argument specifying a number of decimal places to round the
	// significand to. However when converting large values (1e+21 and above) this
	// method will instead fallback to calling ToString.
	EncodedJSValue JSC_HOST_CALL numberProtoFuncToFixed(ExecState* exec)
	{
	double x;
	if (!toThisNumber(exec->hostThisValue(), x))
	return throwVMTypeError(exec);

	// Get the argument.
	int decimalPlaces;
	bool isUndefined; // This is ignored; undefined treated as 0.
	if (!getIntegerArgumentInRange(exec, 0, 20, decimalPlaces, isUndefined))
	return throwVMError(exec, createRangeError(exec, ASCIILiteral("toFixed() argument must be between 0 and 20")));

	// 15.7.4.5.7 states "If x >= 10^21, then let m = ToString(x)"
	// This also covers Ininity, and structure the check so that NaN
	// values are also handled by numberToString
	if (!(fabs(x) < 1e+21))
	return JSValue::encode(jsString(exec, String::numberToStringECMAScript(x)));

	// The check above will return false for NaN or Infinity, these will be
	// handled by numberToString.
	ASSERT(isfinite(x));

	NumberToStringBuffer buffer;
	return JSValue::encode(jsString(exec, String(numberToFixedWidthString(x, decimalPlaces, buffer))));
	}

	// toPrecision converts a number to a string, takeing an argument specifying a
	// number of significant figures to round the significand to. For positive
	// exponent, all values that can be represented using a decimal fraction will
	// be, e.g. when rounding to 3 s.f. any value up to 999 will be formated as a
	// decimal, whilst 1000 is converted to the exponential representation 1.00e+3.
	// For negative exponents values >= 1e-6 are formated as decimal fractions,
	// with smaller values converted to exponential representation.
	EncodedJSValue JSC_HOST_CALL numberProtoFuncToPrecision(ExecState* exec)
	{
	double x;
	if (!toThisNumber(exec->hostThisValue(), x))
	return throwVMTypeError(exec);

	// Get the argument.
	int significantFigures;
	bool isUndefined;
	if (!getIntegerArgumentInRange(exec, 1, 21, significantFigures, isUndefined))
	return throwVMError(exec, createRangeError(exec, ASCIILiteral("toPrecision() argument must be between 1 and 21")));

	// To precision called with no argument is treated as ToString.
	if (isUndefined)
	return JSValue::encode(jsString(exec, String::numberToStringECMAScript(x)));

	// Handle NaN and Infinity.
	if (!isfinite(x))
	return JSValue::encode(jsString(exec, String::numberToStringECMAScript(x)));

	NumberToStringBuffer buffer;
	return JSValue::encode(jsString(exec, String(numberToFixedPrecisionString(x, significantFigures, buffer))));
	}

	static inline int32_t extractRadixFromArgs(ExecState* exec)
	{
	JSValue radixValue = exec->argument(0);
	int32_t radix;
	if (radixValue.isInt32())
	radix = radixValue.asInt32();
	else if (radixValue.isUndefined())
	radix = 10;
	else
	radix = static_cast<int32_t>(radixValue.toInteger(exec)); // nan -> 0

	return radix;
	}

	static inline EncodedJSValue integerValueToString(ExecState* exec, int32_t radix, int32_t value)
	{
	// A negative value casted to unsigned would be bigger than 36 (the max radix).
	if (static_cast<unsigned>(value) < static_cast<unsigned>(radix)) {
	ASSERT(value <= 36);
	ASSERT(value >= 0);
	JSGlobalData* globalData = &exec->globalData();
	return JSValue::encode(globalData->smallStrings.singleCharacterString(globalData, radixDigits[value]));
	}

	if (radix == 10) {
	JSGlobalData* globalData = &exec->globalData();
	return JSValue::encode(jsString(globalData, globalData->numericStrings.add(value)));
	}

	return JSValue::encode(jsString(exec, toStringWithRadix(value, radix)));

	}

	EncodedJSValue JSC_HOST_CALL numberProtoFuncToString(ExecState* exec)
	{
	double doubleValue;
	if (!toThisNumber(exec->hostThisValue(), doubleValue))
	return throwVMTypeError(exec);

	int32_t radix = extractRadixFromArgs(exec);
	if (radix < 2 \|\| radix > 36)
	return throwVMError(exec, createRangeError(exec, ASCIILiteral("toString() radix argument must be between 2 and 36")));

	int32_t integerValue = static_cast<int32_t>(doubleValue);
	if (integerValue == doubleValue)
	return integerValueToString(exec, radix, integerValue);

	if (radix == 10) {
	JSGlobalData* globalData = &exec->globalData();
	return JSValue::encode(jsString(globalData, globalData->numericStrings.add(doubleValue)));
	}

	if (!isfinite(doubleValue))
	return JSValue::encode(jsString(exec, String::numberToStringECMAScript(doubleValue)));

	RadixBuffer s;
	return JSValue::encode(jsString(exec, toStringWithRadix(s, doubleValue, radix)));
	}

	EncodedJSValue JSC_HOST_CALL numberProtoFuncToLocaleString(ExecState* exec)
	{
	double x;
	if (!toThisNumber(exec->hostThisValue(), x))
	return throwVMTypeError(exec);

	return JSValue::encode(jsNumber(x).toString(exec));
	}

	EncodedJSValue JSC_HOST_CALL numberProtoFuncValueOf(ExecState* exec)
	{
	double x;
	if (!toThisNumber(exec->hostThisValue(), x))
	return throwVMTypeError(exec);
	return JSValue::encode(jsNumber(x));
	}

	} // namespace JSC