All Downloads are FREE. Search and download functionalities are using the official Maven repository.

org.bouncycastle.math.ec.SimpleBigDecimal Maven / Gradle / Ivy

Go to download

The Bouncy Castle Crypto package is a Java implementation of cryptographic algorithms. This jar contains JCE provider and lightweight API for the Bouncy Castle Cryptography APIs for JDK 1.4.

There is a newer version: 1.79
Show newest version
package org.bouncycastle.math.ec;

import java.math.BigInteger;

/**
 * Class representing a simple version of a big decimal. A
 *  SimpleBigDecimal is basically a
 * {@link java.math.BigInteger BigInteger} with a few digits on the right of
 * the decimal point. The number of (binary) digits on the right of the decimal
 * point is called the  scale of the  SimpleBigDecimal.
 * Unlike in {@link java.math.BigDecimal BigDecimal}, the scale is not adjusted
 * automatically, but must be set manually. All  SimpleBigDecimals
 * taking part in the same arithmetic operation must have equal scale. The
 * result of a multiplication of two  SimpleBigDecimals returns a
 *  SimpleBigDecimal with double scale.
 */
class SimpleBigDecimal
    //extends Number   // not in J2ME - add compatibility class?
{
    private static final long serialVersionUID = 1L;

    private final BigInteger bigInt;
    private final int scale;

    /**
     * Returns a  SimpleBigDecimal representing the same numerical
     * value as  value.
     * @param value The value of the  SimpleBigDecimal to be
     * created. 
     * @param scale The scale of the  SimpleBigDecimal to be
     * created. 
     * @return The such created  SimpleBigDecimal.
     */
    public static SimpleBigDecimal getInstance(BigInteger value, int scale)
    {
        return new SimpleBigDecimal(value.shiftLeft(scale), scale);
    }

    /**
     * Constructor for  SimpleBigDecimal. The value of the
     * constructed  SimpleBigDecimal equals  bigInt / 
     * 2 scale.
     * @param bigInt The  bigInt value parameter.
     * @param scale The scale of the constructed  SimpleBigDecimal.
     */
    public SimpleBigDecimal(BigInteger bigInt, int scale)
    {
        if (scale < 0)
        {
            throw new IllegalArgumentException("scale may not be negative");
        }

        this.bigInt = bigInt;
        this.scale = scale;
    }

    private void checkScale(SimpleBigDecimal b)
    {
        if (scale != b.scale)
        {
            throw new IllegalArgumentException("Only SimpleBigDecimal of " +
                "same scale allowed in arithmetic operations");
        }
    }

    public SimpleBigDecimal adjustScale(int newScale)
    {
        if (newScale < 0)
        {
            throw new IllegalArgumentException("scale may not be negative");
        }

        if (newScale == scale)
        {
            return this;
        }

        return new SimpleBigDecimal(bigInt.shiftLeft(newScale - scale),
                newScale);
    }

    public SimpleBigDecimal add(SimpleBigDecimal b)
    {
        checkScale(b);
        return new SimpleBigDecimal(bigInt.add(b.bigInt), scale);
    }

    public SimpleBigDecimal add(BigInteger b)
    {
        return new SimpleBigDecimal(bigInt.add(b.shiftLeft(scale)), scale);
    }

    public SimpleBigDecimal negate()
    {
        return new SimpleBigDecimal(bigInt.negate(), scale);
    }

    public SimpleBigDecimal subtract(SimpleBigDecimal b)
    {
        return add(b.negate());
    }

    public SimpleBigDecimal subtract(BigInteger b)
    {
        return new SimpleBigDecimal(bigInt.subtract(b.shiftLeft(scale)),
                scale);
    }

    public SimpleBigDecimal multiply(SimpleBigDecimal b)
    {
        checkScale(b);
        return new SimpleBigDecimal(bigInt.multiply(b.bigInt), scale + scale);
    }

    public SimpleBigDecimal multiply(BigInteger b)
    {
        return new SimpleBigDecimal(bigInt.multiply(b), scale);
    }

    public SimpleBigDecimal divide(SimpleBigDecimal b)
    {
        checkScale(b);
        BigInteger dividend = bigInt.shiftLeft(scale);
        return new SimpleBigDecimal(dividend.divide(b.bigInt), scale);
    }

    public SimpleBigDecimal divide(BigInteger b)
    {
        return new SimpleBigDecimal(bigInt.divide(b), scale);
    }

    public SimpleBigDecimal shiftLeft(int n)
    {
        return new SimpleBigDecimal(bigInt.shiftLeft(n), scale);
    }

    public int compareTo(SimpleBigDecimal val)
    {
        checkScale(val);
        return bigInt.compareTo(val.bigInt);
    }

    public int compareTo(BigInteger val)
    {
        return bigInt.compareTo(val.shiftLeft(scale));
    }

    public BigInteger floor()
    {
        return bigInt.shiftRight(scale);
    }

    public BigInteger round()
    {
        SimpleBigDecimal oneHalf = new SimpleBigDecimal(ECConstants.ONE, 1);
        return add(oneHalf.adjustScale(scale)).floor();
    }

    public int intValue()
    {
        return floor().intValue();
    }
    
    public long longValue()
    {
        return floor().longValue();
    }
          /* NON-J2ME compliant.
    public double doubleValue()
    {
        return Double.valueOf(toString()).doubleValue();
    }

    public float floatValue()
    {
        return Float.valueOf(toString()).floatValue();
    }
       */
    public int getScale()
    {
        return scale;
    }

    public String toString()
    {
        if (scale == 0)
        {
            return bigInt.toString();
        }

        BigInteger floorBigInt = floor();
        
        BigInteger fract = bigInt.subtract(floorBigInt.shiftLeft(scale));
        if (bigInt.signum() == -1)
        {
            fract = ECConstants.ONE.shiftLeft(scale).subtract(fract);
        }

        if ((floorBigInt.signum() == -1) && (!(fract.equals(ECConstants.ZERO))))
        {
            floorBigInt = floorBigInt.add(ECConstants.ONE);
        }
        String leftOfPoint = floorBigInt.toString();

        char[] fractCharArr = new char[scale];
        String fractStr = fract.toString(2);
        int fractLen = fractStr.length();
        int zeroes = scale - fractLen;
        for (int i = 0; i < zeroes; i++)
        {
            fractCharArr[i] = '0';
        }
        for (int j = 0; j < fractLen; j++)
        {
            fractCharArr[zeroes + j] = fractStr.charAt(j);
        }
        String rightOfPoint = new String(fractCharArr);

        StringBuffer sb = new StringBuffer(leftOfPoint);
        sb.append(".");
        sb.append(rightOfPoint);

        return sb.toString();
    }

    public boolean equals(Object o)
    {
        if (this == o)
        {
            return true;
        }

        if (!(o instanceof SimpleBigDecimal))
        {
            return false;
        }

        SimpleBigDecimal other = (SimpleBigDecimal)o;
        return ((bigInt.equals(other.bigInt)) && (scale == other.scale));
    }

    public int hashCode()
    {
        return bigInt.hashCode() ^ scale;
    }

}




© 2015 - 2024 Weber Informatics LLC | Privacy Policy