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/* Long.java -- object wrapper for long

   Copyright (C) 1998, 1999, 2001, 2002, 2004, 2005 Free Software Foundation, Inc.

This file is part of GNU Classpath.

GNU Classpath is free software; you can redistribute it and/or modify

it under the terms of the GNU General Public License as published by

the Free Software Foundation; either version 2, or (at your option)

any later version.

GNU Classpath 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

General Public License for more details.

You should have received a copy of the GNU General Public License

along with GNU Classpath; see the file COPYING.  If not, write to the

Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA

02110-1301 USA.

Linking this library statically or dynamically with other modules is

making a combined work based on this library.  Thus, the terms and

conditions of the GNU General Public License cover the whole

combination.

As a special exception, the copyright holders of this library give you

permission to link this library with independent modules to produce an

executable, regardless of the license terms of these independent

modules, and to copy and distribute the resulting executable under

terms of your choice, provided that you also meet, for each linked

independent module, the terms and conditions of the license of that

module.  An independent module is a module which is not derived from

or based on this library.  If you modify this library, you may extend

this exception to your version of the library, but you are not

obligated to do so.  If you do not wish to do so, delete this

exception statement from your version. */

package java.lang;

/**

 * Instances of class <code>Long</code> represent primitive

 * <code>long</code> values.

 *

 * Additionally, this class provides various helper functions and variables

 * related to longs.

 *

 * @author Paul Fisher

 * @author John Keiser

 * @author Warren Levy

 * @author Eric Blake (ebb9@email.byu.edu)

 * @author Tom Tromey (tromey@redhat.com)

 * @author Andrew John Hughes (gnu_andrew@member.fsf.org)

 * @author Ian Rogers

 * @since 1.0

 * @status updated to 1.5

 */

public final class Long extends Number implements Comparable<Long>

{

  /**

   * Compatible with JDK 1.0.2+.

   */

  private static final long serialVersionUID = 4290774380558885855L;

  /**

   * The minimum value a <code>long</code> can represent is

   * -9223372036854775808L (or -2<sup>63</sup>).

   */

  public static final long MIN_VALUE = 0x8000000000000000L;

  /**

   * The maximum value a <code>long</code> can represent is

   * 9223372036854775807 (or 2<sup>63</sup> - 1).

   */

  public static final long MAX_VALUE = 0x7fffffffffffffffL;

  /**

   * The primitive type <code>long</code> is represented by this

   * <code>Class</code> object.

   * @since 1.1

   */

  public static final Class<Long> TYPE = (Class<Long>) VMClassLoader.getPrimitiveClass ('J');

  /**

   * The number of bits needed to represent a <code>long</code>.

   * @since 1.5

   */

  public static final int SIZE = 64;

  // This caches some Long values, and is used by boxing

  // conversions via valueOf().  We cache at least -128..127;

  // these constants control how much we actually cache.

  private static final int MIN_CACHE = -128;

  private static final int MAX_CACHE = 127;

  private static final Long[] longCache = new Long[MAX_CACHE - MIN_CACHE + 1];

  static

  {

    for (int i=MIN_CACHE; i <= MAX_CACHE; i++)

      longCache[i - MIN_CACHE] = new Long(i);

  }

  /**

   * The immutable value of this Long.

   *

   * @serial the wrapped long

   */

  private final long value;

  /**

   * Create a <code>Long</code> object representing the value of the

   * <code>long</code> argument.

   *

   * @param value the value to use

   */

  public Long(long value)

  {

    this.value = value;

  }

  /**

   * Create a <code>Long</code> object representing the value of the

   * argument after conversion to a <code>long</code>.

   *

   * @param s the string to convert

   * @throws NumberFormatException if the String does not contain a long

   * @see #valueOf(String)

   */

  public Long(String s)

  {

    value = parseLong(s, 10, false);

  }

  /**

   * Return the size of a string large enough to hold the given number

   *

   * @param num the number we want the string length for (must be positive)

   * @param radix the radix (base) that will be used for the string

   * @return a size sufficient for a string of num

   */

  private static int stringSize(long num, int radix) {

    int exp;

    if (radix < 4)

      {

        exp = 1;

      }

    else if (radix < 8)

      {

        exp = 2;

      }

    else if (radix < 16)

      {

        exp = 3;

      }

    else if (radix < 32)

      {

        exp = 4;

      }

    else

      {

        exp = 5;

      }

    int size=0;

    do

      {

        num >>>= exp;

        size++;

      }

    while(num != 0);

    return size;

  }

  /**

   * Converts the <code>long</code> to a <code>String</code> using

   * the specified radix (base). If the radix exceeds

   * <code>Character.MIN_RADIX</code> or <code>Character.MAX_RADIX</code>, 10

   * is used instead. If the result is negative, the leading character is

   * '-' ('\\u002D'). The remaining characters come from

   * <code>Character.forDigit(digit, radix)</code> ('0'-'9','a'-'z').

   *

   * @param num the <code>long</code> to convert to <code>String</code>

   * @param radix the radix (base) to use in the conversion

   * @return the <code>String</code> representation of the argument

   */

  public static String toString(long num, int radix)

  {

    if (radix < Character.MIN_RADIX || radix > Character.MAX_RADIX)

      radix = 10;

    // Is the value negative?

    boolean isNeg = num < 0;

    // Is the string a single character?

    if (!isNeg && num < radix)

      return new String(digits, (int)num, 1, true);

    // Compute string size and allocate buffer

    // account for a leading '-' if the value is negative

    int size;

    int i;

    char[] buffer;

    if (isNeg)

      {

        num = -num;

        // When the value is MIN_VALUE, it overflows when made positive

        if (num < 0)

          {

            i = size = stringSize(MAX_VALUE, radix) + 2;

            buffer = new char[size];

            buffer[--i] = digits[(int) (-(num + radix) % radix)];

            num = -(num / radix);

          }

        else

          {

            i = size = stringSize(num, radix) + 1;

            buffer = new char[size];

          }

      }

    else

      {

        i = size = stringSize(num, radix);

        buffer = new char[size];

      }

    do

      {

        buffer[--i] = digits[(int) (num % radix)];

        num /= radix;

      }

    while (num > 0);

    if (isNeg)

      buffer[--i] = '-';

    // Package constructor avoids an array copy.

    return new String(buffer, i, size - i, true);

  }

  /**

   * Converts the <code>long</code> to a <code>String</code> assuming it is

   * unsigned in base 16.

   *

   * @param l the <code>long</code> to convert to <code>String</code>

   * @return the <code>String</code> representation of the argument

   */

  public static String toHexString(long l)

  {

    return toUnsignedString(l, 4);

  }

  /**

   * Converts the <code>long</code> to a <code>String</code> assuming it is

   * unsigned in base 8.

   *

   * @param l the <code>long</code> to convert to <code>String</code>

   * @return the <code>String</code> representation of the argument

   */

  public static String toOctalString(long l)

  {

    return toUnsignedString(l, 3);

  }

  /**

   * Converts the <code>long</code> to a <code>String</code> assuming it is

   * unsigned in base 2.

   *

   * @param l the <code>long</code> to convert to <code>String</code>

   * @return the <code>String</code> representation of the argument

   */

  public static String toBinaryString(long l)

  {

    return toUnsignedString(l, 1);

  }

  /**

   * Converts the <code>long</code> to a <code>String</code> and assumes

   * a radix of 10.

   *

   * @param num the <code>long</code> to convert to <code>String</code>

   * @return the <code>String</code> representation of the argument

   * @see #toString(long, int)

   */

  public static String toString(long num)

  {

    return toString(num, 10);

  }

  /**

   * Converts the specified <code>String</code> into an <code>int</code>

   * using the specified radix (base). The string must not be <code>null</code>

   * or empty. It may begin with an optional '-', which will negate the answer,

   * provided that there are also valid digits. Each digit is parsed as if by

   * <code>Character.digit(d, radix)</code>, and must be in the range

   * <code>0</code> to <code>radix - 1</code>. Finally, the result must be

   * within <code>MIN_VALUE</code> to <code>MAX_VALUE</code>, inclusive.

   * Unlike Double.parseDouble, you may not have a leading '+'; and 'l' or

   * 'L' as the last character is only valid in radices 22 or greater, where

   * it is a digit and not a type indicator.

   *

   * @param str the <code>String</code> to convert

   * @param radix the radix (base) to use in the conversion

   * @return the <code>String</code> argument converted to <code>long</code>

   * @throws NumberFormatException if <code>s</code> cannot be parsed as a

   *         <code>long</code>

   */

  public static long parseLong(String str, int radix)

  {

    return parseLong(str, radix, false);

  }

  /**

   * Converts the specified <code>String</code> into a <code>long</code>.

   * This function assumes a radix of 10.

   *

   * @param s the <code>String</code> to convert

   * @return the <code>int</code> value of <code>s</code>

   * @throws NumberFormatException if <code>s</code> cannot be parsed as a

   *         <code>long</code>

   * @see #parseLong(String, int)

   */

  public static long parseLong(String s)

  {

    return parseLong(s, 10, false);

  }

  /**

   * Creates a new <code>Long</code> object using the <code>String</code>

   * and specified radix (base).

   *

   * @param s the <code>String</code> to convert

   * @param radix the radix (base) to convert with

   * @return the new <code>Long</code>

   * @throws NumberFormatException if <code>s</code> cannot be parsed as a

   *         <code>long</code>

   * @see #parseLong(String, int)

   */

  public static Long valueOf(String s, int radix)

  {

    return valueOf(parseLong(s, radix, false));

  }

  /**

   * Creates a new <code>Long</code> object using the <code>String</code>,

   * assuming a radix of 10.

   *

   * @param s the <code>String</code> to convert

   * @return the new <code>Long</code>

   * @throws NumberFormatException if <code>s</code> cannot be parsed as a

   *         <code>long</code>

   * @see #Long(String)

   * @see #parseLong(String)

   */

  public static Long valueOf(String s)

  {

    return valueOf(parseLong(s, 10, false));

  }

  /**

   * Returns a <code>Long</code> object wrapping the value.

   *

   * @param val the value to wrap

   * @return the <code>Long</code>

   * @since 1.5

   */

  public static Long valueOf(long val)

  {

    if (val < MIN_CACHE || val > MAX_CACHE)

      return new Long(val);

    else

      return longCache[((int)val) - MIN_CACHE];

  }

  /**

   * Convert the specified <code>String</code> into a <code>Long</code>.

   * The <code>String</code> may represent decimal, hexadecimal, or

   * octal numbers.

   *

   * <p>The extended BNF grammar is as follows:<br>

   * <pre>

   * <em>DecodableString</em>:

   *      ( [ <code>-</code> ] <em>DecimalNumber</em> )

   *    | ( [ <code>-</code> ] ( <code>0x</code> | <code>0X</code>

   *              | <code>#</code> ) <em>HexDigit</em> { <em>HexDigit</em> } )

   *    | ( [ <code>-</code> ] <code>0</code> { <em>OctalDigit</em> } )

   * <em>DecimalNumber</em>:

   *        <em>DecimalDigit except '0'</em> { <em>DecimalDigit</em> }

   * <em>DecimalDigit</em>:

   *        <em>Character.digit(d, 10) has value 0 to 9</em>

   * <em>OctalDigit</em>:

   *        <em>Character.digit(d, 8) has value 0 to 7</em>

   * <em>DecimalDigit</em>:

   *        <em>Character.digit(d, 16) has value 0 to 15</em>

   * </pre>

   * Finally, the value must be in the range <code>MIN_VALUE</code> to

   * <code>MAX_VALUE</code>, or an exception is thrown. Note that you cannot

   * use a trailing 'l' or 'L', unlike in Java source code.

   *

   * @param str the <code>String</code> to interpret

   * @return the value of the String as a <code>Long</code>

   * @throws NumberFormatException if <code>s</code> cannot be parsed as a

   *         <code>long</code>

   * @throws NullPointerException if <code>s</code> is null

   * @since 1.2

   */

  public static Long decode(String str)

  {

    return valueOf(parseLong(str, 10, true));

  }

  /**

   * Return the value of this <code>Long</code> as a <code>byte</code>.

   *

   * @return the byte value

   */

  public byte byteValue()

  {

    return (byte) value;

  }

  /**

   * Return the value of this <code>Long</code> as a <code>short</code>.

   *

   * @return the short value

   */

  public short shortValue()

  {

    return (short) value;

  }

  /**

   * Return the value of this <code>Long</code> as an <code>int</code>.

   *

   * @return the int value

   */

  public int intValue()

  {

    return (int) value;

  }

  /**

   * Return the value of this <code>Long</code>.

   *

   * @return the long value

   */

  public long longValue()

  {

    return value;

  }

  /**

   * Return the value of this <code>Long</code> as a <code>float</code>.

   *

   * @return the float value

   */

  public float floatValue()

  {

    return value;

  }

  /**

   * Return the value of this <code>Long</code> as a <code>double</code>.

   *

   * @return the double value

   */

  public double doubleValue()

  {

    return value;

  }

  /**

   * Converts the <code>Long</code> value to a <code>String</code> and

   * assumes a radix of 10.

   *

   * @return the <code>String</code> representation

   */

  public String toString()

  {

    return toString(value, 10);

  }

  /**

   * Return a hashcode representing this Object. <code>Long</code>'s hash

   * code is calculated by <code>(int) (value ^ (value &gt;&gt; 32))</code>.

   *

   * @return this Object's hash code

   */

  public int hashCode()

  {

    return (int) (value ^ (value >>> 32));

  }

  /**

   * Returns <code>true</code> if <code>obj</code> is an instance of

   * <code>Long</code> and represents the same long value.

   *

   * @param obj the object to compare

   * @return whether these Objects are semantically equal

   */

  public boolean equals(Object obj)

  {

    return obj instanceof Long && value == ((Long) obj).value;

  }

  /**

   * Get the specified system property as a <code>Long</code>. The

   * <code>decode()</code> method will be used to interpret the value of

   * the property.

   *

   * @param nm the name of the system property

   * @return the system property as a <code>Long</code>, or null if the

   *         property is not found or cannot be decoded

   * @throws SecurityException if accessing the system property is forbidden

   * @see System#getProperty(String)

   * @see #decode(String)

   */

  public static Long getLong(String nm)

  {

    return getLong(nm, null);

  }

  /**

   * Get the specified system property as a <code>Long</code>, or use a

   * default <code>long</code> value if the property is not found or is not

   * decodable. The <code>decode()</code> method will be used to interpret

   * the value of the property.

   *

   * @param nm the name of the system property

   * @param val the default value

   * @return the value of the system property, or the default

   * @throws SecurityException if accessing the system property is forbidden

   * @see System#getProperty(String)

   * @see #decode(String)

   */

  public static Long getLong(String nm, long val)

  {

    Long result = getLong(nm, null);

    return result == null ? valueOf(val) : result;

  }

  /**

   * Get the specified system property as a <code>Long</code>, or use a

   * default <code>Long</code> value if the property is not found or is

   * not decodable. The <code>decode()</code> method will be used to

   * interpret the value of the property.

   *

   * @param nm the name of the system property

   * @param def the default value

   * @return the value of the system property, or the default

   * @throws SecurityException if accessing the system property is forbidden

   * @see System#getProperty(String)

   * @see #decode(String)

   */

  public static Long getLong(String nm, Long def)

  {

    if (nm == null || "".equals(nm))

      return def;

    nm = System.getProperty(nm);

    if (nm == null)

      return def;

    try

      {

        return decode(nm);

      }

    catch (NumberFormatException e)

      {

        return def;

      }

  }

  /**

   * Compare two Longs numerically by comparing their <code>long</code>

   * values. The result is positive if the first is greater, negative if the

   * second is greater, and 0 if the two are equal.

   *

   * @param l the Long to compare

   * @return the comparison

   * @since 1.2

   */

  public int compareTo(Long l)

  {

    if (value == l.value)

      return 0;

    // Returns just -1 or 1 on inequality; doing math might overflow the long.

    return value > l.value ? 1 : -1;

  }

  /**

   * Return the number of bits set in x.

   * @param x value to examine

   * @since 1.5

   */

  public static int bitCount(long x)

  {

    // Successively collapse alternating bit groups into a sum.

    x = ((x >> 1) & 0x5555555555555555L) + (x & 0x5555555555555555L);

    x = ((x >> 2) & 0x3333333333333333L) + (x & 0x3333333333333333L);

    int v = (int) ((x >>> 32) + x);

    v = ((v >> 4) & 0x0f0f0f0f) + (v & 0x0f0f0f0f);

    v = ((v >> 8) & 0x00ff00ff) + (v & 0x00ff00ff);

    return ((v >> 16) & 0x0000ffff) + (v & 0x0000ffff);

  }

  /**

   * Rotate x to the left by distance bits.

   * @param x the value to rotate

   * @param distance the number of bits by which to rotate

   * @since 1.5

   */

  public static long rotateLeft(long x, int distance)

  {

    // This trick works because the shift operators implicitly mask

    // the shift count.

    return (x << distance) | (x >>> - distance);

  }

  /**

   * Rotate x to the right by distance bits.

   * @param x the value to rotate

   * @param distance the number of bits by which to rotate

   * @since 1.5

   */

  public static long rotateRight(long x, int distance)

  {

    // This trick works because the shift operators implicitly mask

    // the shift count.

    return (x << - distance) | (x >>> distance);

  }

  /**

   * Find the highest set bit in value, and return a new value

   * with only that bit set.

   * @param value the value to examine

   * @since 1.5

   */

  public static long highestOneBit(long value)

  {

    value |= value >>> 1;

    value |= value >>> 2;

    value |= value >>> 4;

    value |= value >>> 8;

    value |= value >>> 16;

    value |= value >>> 32;

    return value ^ (value >>> 1);

  }

  /**

   * Return the number of leading zeros in value.

   * @param value the value to examine

   * @since 1.5

   */

  public static int numberOfLeadingZeros(long value)

  {

    value |= value >>> 1;

    value |= value >>> 2;

    value |= value >>> 4;

    value |= value >>> 8;

    value |= value >>> 16;

    value |= value >>> 32;

    return bitCount(~value);

  }

  /**

   * Find the lowest set bit in value, and return a new value

   * with only that bit set.

   * @param value the value to examine

   * @since 1.5

   */

  public static long lowestOneBit(long value)

  {

    // Classic assembly trick.

    return value & - value;

  }

  /**

   * Find the number of trailing zeros in value.

   * @param value the value to examine

   * @since 1.5

   */

  public static int numberOfTrailingZeros(long value)

  {

    return bitCount((value & -value) - 1);

  }

  /**

   * Return 1 if x is positive, -1 if it is negative, and 0 if it is

   * zero.

   * @param x the value to examine

   * @since 1.5

   */

  public static int signum(long x)

  {

    return (int) ((x >> 63) | (-x >>> 63));

    // The LHS propagates the sign bit through every bit in the word;

    // if X < 0, every bit is set to 1, else 0.  if X > 0, the RHS

    // negates x and shifts the resulting 1 in the sign bit to the

    // LSB, leaving every other bit 0.

    // Hacker's Delight, Section 2-7

  }

  /**

   * Reverse the bytes in val.

   * @since 1.5

   */

  public static long reverseBytes(long val)

  {

    int hi = Integer.reverseBytes((int) val);

    int lo = Integer.reverseBytes((int) (val >>> 32));

    return (((long) hi) << 32) | lo;

  }

  /**

   * Reverse the bits in val.

   * @since 1.5

   */

  public static long reverse(long val)

  {

    long hi = Integer.reverse((int) val) & 0xffffffffL;

    long lo = Integer.reverse((int) (val >>> 32)) & 0xffffffffL;

    return (hi << 32) | lo;

  }

  /**

   * Helper for converting unsigned numbers to String.

   *

   * @param num the number

   * @param exp log2(digit) (ie. 1, 3, or 4 for binary, oct, hex)

   */

  private static String toUnsignedString(long num, int exp)

  {

    // Compute string length

    int size = 1;

    long copy = num >>> exp;

    while (copy != 0)

      {

        size++;

        copy >>>= exp;

      }

    // Quick path for single character strings

    if (size == 1)

      return new String(digits, (int)num, 1, true);

    // Encode into buffer

    int mask = (1 << exp) - 1;

    char[] buffer = new char[size];

    int i = size;

    do

      {

        buffer[--i] = digits[(int) num & mask];

        num >>>= exp;

      }

    while (num != 0);