src/com/sun/org/apache/xerces/internal/impl/dv/xs/PrecisionDecimalDV.java - platform/external/jetbrains/jdk8u_jaxp - Git at Google

 /*
  * reserved comment block
  * DO NOT REMOVE OR ALTER!
  */
 /*
  * Copyright 2004 The Apache Software Foundation.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */
 package com.sun.org.apache.xerces.internal.impl.dv.xs;

 import com.sun.org.apache.xerces.internal.impl.dv.InvalidDatatypeValueException;
 import com.sun.org.apache.xerces.internal.impl.dv.ValidationContext;

 /**
  * Validator for <precisionDecimal> datatype (W3C Schema 1.1)
  *
  * @xerces.experimental
  *
  * @author Ankit Pasricha, IBM
  *
  */
 class PrecisionDecimalDV extends TypeValidator {

     static final class XPrecisionDecimal {

         // sign: 0 for absent; 1 for positive values; -1 for negative values (except in case of INF, -INF)
         int sign = 1;
         // total digits. >= 1
         int totalDigits = 0;
         // integer digits when sign != 0
         int intDigits = 0;
         // fraction digits when sign != 0
         int fracDigits = 0;
         //precision
         //int precision = 0;
         // the string representing the integer part
         String ivalue = "";
         // the string representing the fraction part
         String fvalue = "";

         int pvalue = 0;


         XPrecisionDecimal(String content) throws NumberFormatException {
             if(content.equals("NaN")) {
                 ivalue = content;
                 sign = 0;
             }
             if(content.equals("+INF") || content.equals("INF") || content.equals("-INF")) {
                 ivalue = content.charAt(0) == '+' ? content.substring(1) : content;
                 return;
             }
             initD(content);
         }

         void initD(String content) throws NumberFormatException {
             int len = content.length();
             if (len == 0)
                 throw new NumberFormatException();

             // these 4 variables are used to indicate where the integre/fraction
             // parts start/end.
             int intStart = 0, intEnd = 0, fracStart = 0, fracEnd = 0;

             // Deal with leading sign symbol if present
             if (content.charAt(0) == '+') {
                 // skip '+', so intStart should be 1
                 intStart = 1;
             }
             else if (content.charAt(0) == '-') {
                 intStart = 1;
                 sign = -1;
             }

             // skip leading zeroes in integer part
             int actualIntStart = intStart;
             while (actualIntStart < len && content.charAt(actualIntStart) == '0') {
                 actualIntStart++;
             }

             // Find the ending position of the integer part
             for (intEnd = actualIntStart; intEnd < len && TypeValidator.isDigit(content.charAt(intEnd)); intEnd++);

             // Not reached the end yet
             if (intEnd < len) {
                 // the remaining part is not ".DDD" or "EDDD" or "eDDD", error
                 if (content.charAt(intEnd) != '.' && content.charAt(intEnd) != 'E' && content.charAt(intEnd) != 'e')
                     throw new NumberFormatException();

                 if(content.charAt(intEnd) == '.') {
                     // fraction part starts after '.', and ends at the end of the input
                     fracStart = intEnd + 1;

                     // find location of E or e (if present)
                     // Find the ending position of the fracion part
                     for (fracEnd = fracStart;
                     fracEnd < len && TypeValidator.isDigit(content.charAt(fracEnd));
                     fracEnd++);
                 }
                 else {
                     pvalue = Integer.parseInt(content.substring(intEnd + 1, len));
                 }
             }

             // no integer part, no fraction part, error.
             if (intStart == intEnd && fracStart == fracEnd)
                 throw new NumberFormatException();

             // ignore trailing zeroes in fraction part
             /*while (fracEnd > fracStart && content.charAt(fracEnd-1) == '0') {
              fracEnd--;
              }*/

             // check whether there is non-digit characters in the fraction part
             for (int fracPos = fracStart; fracPos < fracEnd; fracPos++) {
                 if (!TypeValidator.isDigit(content.charAt(fracPos)))
                     throw new NumberFormatException();
             }

             intDigits = intEnd - actualIntStart;
             fracDigits = fracEnd - fracStart;

             if (intDigits > 0) {
                 ivalue = content.substring(actualIntStart, intEnd);
             }

             if (fracDigits > 0) {
                 fvalue = content.substring(fracStart, fracEnd);
                 if(fracEnd < len) {
                     pvalue = Integer.parseInt(content.substring(fracEnd + 1, len));
                 }
             }
             totalDigits = intDigits + fracDigits;
         }

         // Construct a canonical String representation of this number
         // for the purpose of deriving a hashCode value compliant with
         // equals.
         // The toString representation will be:
         // NaN for NaN, INF for +infinity, -INF for -infinity, 0 for zero,
         // and [1-9].[0-9]*[1-9]?(E[1-9][0-9]*)? for other numbers.
         private static String canonicalToStringForHashCode(String ivalue, String fvalue, int sign, int pvalue) {
             if ("NaN".equals(ivalue)) {
                 return "NaN";
             }
             if ("INF".equals(ivalue)) {
                 return sign < 0 ? "-INF" : "INF";
             }
             final StringBuilder builder = new StringBuilder();
             final int ilen = ivalue.length();
             final int flen0 = fvalue.length();
             int lastNonZero;
             for (lastNonZero = flen0; lastNonZero > 0 ; lastNonZero--) {
                 if (fvalue.charAt(lastNonZero -1 ) != '0') break;
             }
             final int flen = lastNonZero;
             int iStart;
             int exponent = pvalue;
             for (iStart = 0; iStart < ilen; iStart++) {
                 if (ivalue.charAt(iStart) != '0') break;
             }
             int fStart = 0;
             if (iStart < ivalue.length()) {
                 builder.append(sign == -1 ? "-" : "");
                 builder.append(ivalue.charAt(iStart));
                 iStart++;
             } else {
                 if (flen > 0) {
                     for (fStart = 0; fStart < flen; fStart++) {
                         if (fvalue.charAt(fStart) != '0') break;
                     }
                     if (fStart < flen) {
                         builder.append(sign == -1 ? "-" : "");
                         builder.append(fvalue.charAt(fStart));
                         exponent -= ++fStart;
                     } else {
                         return "0";
                     }
                 } else {
                     return "0";
                 }
             }

             if (iStart < ilen || fStart < flen) {
                 builder.append('.');
             }
             while (iStart < ilen) {
                 builder.append(ivalue.charAt(iStart++));
                 exponent++;
             }
             while (fStart < flen) {
                 builder.append(fvalue.charAt(fStart++));
             }
             if (exponent != 0) {
                 builder.append("E").append(exponent);
             }
             return builder.toString();
         }

         @Override
         public boolean equals(Object val) {
             if (val == this)
                 return true;

             if (!(val instanceof XPrecisionDecimal))
                 return false;
             XPrecisionDecimal oval = (XPrecisionDecimal)val;

             return this.compareTo(oval) == EQUAL;
         }

         @Override
         public int hashCode() {
             // There's nothing else we can use easily, because equals could
             // return true for widely different representation of the
             // same number - and we don't have any canonical representation.
             // The problem here is that we must ensure that if two numbers
             // are equals then their hash code must also be equals.
             // hashCode for 1.01E1 should be the same as hashCode for 0.101E2
             // So we call cannonicalToStringForHashCode - which implements an
             // algorithm that invents a normalized string representation
             // for this number, and we return a hash for that.
             return canonicalToStringForHashCode(ivalue, fvalue, sign, pvalue).hashCode();
         }

         /**
          * @return
          */
         private int compareFractionalPart(XPrecisionDecimal oval) {
             if(fvalue.equals(oval.fvalue))
                 return EQUAL;

             StringBuffer temp1 = new StringBuffer(fvalue);
             StringBuffer temp2 = new StringBuffer(oval.fvalue);

             truncateTrailingZeros(temp1, temp2);
             return temp1.toString().compareTo(temp2.toString());
         }

         private void truncateTrailingZeros(StringBuffer fValue, StringBuffer otherFValue) {
             for(int i = fValue.length() - 1;i >= 0; i--)
                 if(fValue.charAt(i) == '0')
                     fValue.deleteCharAt(i);
                 else
                     break;

             for(int i = otherFValue.length() - 1;i >= 0; i--)
                 if(otherFValue.charAt(i) == '0')
                     otherFValue.deleteCharAt(i);
                 else
                     break;
         }

         public int compareTo(XPrecisionDecimal val) {

             // seen NaN
             if(sign == 0)
                 return INDETERMINATE;

             //INF is greater than everything and equal to itself
             if(ivalue.equals("INF") || val.ivalue.equals("INF")) {
                 if(ivalue.equals(val.ivalue))
                     return EQUAL;
                 else if(ivalue.equals("INF"))
                     return GREATER_THAN;
                 return LESS_THAN;
             }

             //-INF is smaller than everything and equal itself
             if(ivalue.equals("-INF") || val.ivalue.equals("-INF")) {
                 if(ivalue.equals(val.ivalue))
                     return EQUAL;
                 else if(ivalue.equals("-INF"))
                     return LESS_THAN;
                 return GREATER_THAN;
             }

             if (sign != val.sign)
                 return sign > val.sign ? GREATER_THAN : LESS_THAN;

             return sign * compare(val);
         }

         // To enable comparison - the exponent part of the decimal will be limited
         // to the max value of int.
         private int compare(XPrecisionDecimal val) {

             if(pvalue != 0 || val.pvalue != 0) {
                 if(pvalue == val.pvalue)
                     return intComp(val);
                 else {

                     if(intDigits + pvalue != val.intDigits + val.pvalue)
                         return intDigits + pvalue > val.intDigits + val.pvalue ? GREATER_THAN : LESS_THAN;

                     //otherwise the 2 combined values are the same
                     if(pvalue > val.pvalue) {
                         int expDiff = pvalue - val.pvalue;
                         StringBuffer buffer = new StringBuffer(ivalue);
                         StringBuffer fbuffer = new StringBuffer(fvalue);
                         for(int i = 0;i < expDiff; i++) {
                             if(i < fracDigits) {
                                 buffer.append(fvalue.charAt(i));
                                 fbuffer.deleteCharAt(i);
                             }
                             else
                                 buffer.append('0');
                         }
                         return compareDecimal(buffer.toString(), val.ivalue, fbuffer.toString(), val.fvalue);
                     }
                     else {
                         int expDiff = val.pvalue - pvalue;
                         StringBuffer buffer = new StringBuffer(val.ivalue);
                         StringBuffer fbuffer = new StringBuffer(val.fvalue);
                         for(int i = 0;i < expDiff; i++) {
                             if(i < val.fracDigits) {
                                 buffer.append(val.fvalue.charAt(i));
                                 fbuffer.deleteCharAt(i);
                             }
                             else
                                 buffer.append('0');
                         }
                         return compareDecimal(ivalue, buffer.toString(), fvalue, fbuffer.toString());
                     }
                 }
             }
             else {
                 return intComp(val);
             }
         }

         /**
          * @param val
          * @return
          */
         private int intComp(XPrecisionDecimal val) {
             if (intDigits != val.intDigits)
                 return intDigits > val.intDigits ? GREATER_THAN : LESS_THAN;

             return compareDecimal(ivalue, val.ivalue, fvalue, val.fvalue);
         }

         /**
          * @param val
          * @return
          */
         private int compareDecimal(String iValue, String fValue, String otherIValue, String otherFValue) {
             int ret = iValue.compareTo(otherIValue);
             if (ret != 0)
                 return ret > 0 ? GREATER_THAN : LESS_THAN;

             if(fValue.equals(otherFValue))
                 return EQUAL;

             StringBuffer temp1=new StringBuffer(fValue);
             StringBuffer temp2=new StringBuffer(otherFValue);

             truncateTrailingZeros(temp1, temp2);
             ret = temp1.toString().compareTo(temp2.toString());
             return ret == 0 ? EQUAL : (ret > 0 ? GREATER_THAN : LESS_THAN);
         }

         private String canonical;

         @Override
         public synchronized String toString() {
             if (canonical == null) {
                 makeCanonical();
             }
             return canonical;
         }

         private void makeCanonical() {
             // REVISIT: to be determined by working group
             canonical = "TBD by Working Group";
         }

         /**
          * @param decimal
          * @return
          */
         public boolean isIdentical(XPrecisionDecimal decimal) {
             if(ivalue.equals(decimal.ivalue) && (ivalue.equals("INF") || ivalue.equals("-INF") || ivalue.equals("NaN")))
                 return true;

             if(sign == decimal.sign && intDigits == decimal.intDigits && fracDigits == decimal.fracDigits && pvalue == decimal.pvalue
                     && ivalue.equals(decimal.ivalue) && fvalue.equals(decimal.fvalue))
                 return true;
             return false;
         }

     }
     /* (non-Javadoc)
      * @see com.sun.org.apache.xerces.internal.impl.dv.xs.TypeValidator#getAllowedFacets()
      */
     @Override
     public short getAllowedFacets() {
         return ( XSSimpleTypeDecl.FACET_PATTERN | XSSimpleTypeDecl.FACET_WHITESPACE | XSSimpleTypeDecl.FACET_ENUMERATION |XSSimpleTypeDecl.FACET_MAXINCLUSIVE |XSSimpleTypeDecl.FACET_MININCLUSIVE | XSSimpleTypeDecl.FACET_MAXEXCLUSIVE  | XSSimpleTypeDecl.FACET_MINEXCLUSIVE | XSSimpleTypeDecl.FACET_TOTALDIGITS | XSSimpleTypeDecl.FACET_FRACTIONDIGITS);
     }

     /* (non-Javadoc)
      * @see com.sun.org.apache.xerces.internal.impl.dv.xs.TypeValidator#getActualValue(java.lang.String, com.sun.org.apache.xerces.internal.impl.dv.ValidationContext)
      */
     @Override
     public Object getActualValue(String content, ValidationContext context)
     throws InvalidDatatypeValueException {
         try {
             return new XPrecisionDecimal(content);
         } catch (NumberFormatException nfe) {
             throw new InvalidDatatypeValueException("cvc-datatype-valid.1.2.1", new Object[]{content, "precisionDecimal"});
         }
     }

     @Override
     public int compare(Object value1, Object value2) {
         return ((XPrecisionDecimal)value1).compareTo((XPrecisionDecimal)value2);
     }

     @Override
     public int getFractionDigits(Object value) {
         return ((XPrecisionDecimal)value).fracDigits;
     }

     @Override
     public int getTotalDigits(Object value) {
         return ((XPrecisionDecimal)value).totalDigits;
     }

     @Override
     public boolean isIdentical(Object value1, Object value2) {
         if(!(value2 instanceof XPrecisionDecimal) || !(value1 instanceof XPrecisionDecimal))
             return false;
         return ((XPrecisionDecimal)value1).isIdentical((XPrecisionDecimal)value2);
     }
 }
	/*
	* reserved comment block
	* DO NOT REMOVE OR ALTER!
	*/
	/*
	* Copyright 2004 The Apache Software Foundation.
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/
	package com.sun.org.apache.xerces.internal.impl.dv.xs;

	import com.sun.org.apache.xerces.internal.impl.dv.InvalidDatatypeValueException;
	import com.sun.org.apache.xerces.internal.impl.dv.ValidationContext;

	/**
	* Validator for <precisionDecimal> datatype (W3C Schema 1.1)
	*
	* @xerces.experimental
	*
	* @author Ankit Pasricha, IBM
	*
	*/
	class PrecisionDecimalDV extends TypeValidator {

	static final class XPrecisionDecimal {

	// sign: 0 for absent; 1 for positive values; -1 for negative values (except in case of INF, -INF)
	int sign = 1;
	// total digits. >= 1
	int totalDigits = 0;
	// integer digits when sign != 0
	int intDigits = 0;
	// fraction digits when sign != 0
	int fracDigits = 0;
	//precision
	//int precision = 0;
	// the string representing the integer part
	String ivalue = "";
	// the string representing the fraction part
	String fvalue = "";

	int pvalue = 0;


	XPrecisionDecimal(String content) throws NumberFormatException {
	if(content.equals("NaN")) {
	ivalue = content;
	sign = 0;
	}
	if(content.equals("+INF") \|\| content.equals("INF") \|\| content.equals("-INF")) {
	ivalue = content.charAt(0) == '+' ? content.substring(1) : content;
	return;
	}
	initD(content);
	}

	void initD(String content) throws NumberFormatException {
	int len = content.length();
	if (len == 0)
	throw new NumberFormatException();

	// these 4 variables are used to indicate where the integre/fraction
	// parts start/end.
	int intStart = 0, intEnd = 0, fracStart = 0, fracEnd = 0;

	// Deal with leading sign symbol if present
	if (content.charAt(0) == '+') {
	// skip '+', so intStart should be 1
	intStart = 1;
	}
	else if (content.charAt(0) == '-') {
	intStart = 1;
	sign = -1;
	}

	// skip leading zeroes in integer part
	int actualIntStart = intStart;
	while (actualIntStart < len && content.charAt(actualIntStart) == '0') {
	actualIntStart++;
	}

	// Find the ending position of the integer part
	for (intEnd = actualIntStart; intEnd < len && TypeValidator.isDigit(content.charAt(intEnd)); intEnd++);

	// Not reached the end yet
	if (intEnd < len) {
	// the remaining part is not ".DDD" or "EDDD" or "eDDD", error
	if (content.charAt(intEnd) != '.' && content.charAt(intEnd) != 'E' && content.charAt(intEnd) != 'e')
	throw new NumberFormatException();

	if(content.charAt(intEnd) == '.') {
	// fraction part starts after '.', and ends at the end of the input
	fracStart = intEnd + 1;

	// find location of E or e (if present)
	// Find the ending position of the fracion part
	for (fracEnd = fracStart;
	fracEnd < len && TypeValidator.isDigit(content.charAt(fracEnd));
	fracEnd++);
	}
	else {
	pvalue = Integer.parseInt(content.substring(intEnd + 1, len));
	}
	}

	// no integer part, no fraction part, error.
	if (intStart == intEnd && fracStart == fracEnd)
	throw new NumberFormatException();

	// ignore trailing zeroes in fraction part
	/*while (fracEnd > fracStart && content.charAt(fracEnd-1) == '0') {
	fracEnd--;
	}*/

	// check whether there is non-digit characters in the fraction part
	for (int fracPos = fracStart; fracPos < fracEnd; fracPos++) {
	if (!TypeValidator.isDigit(content.charAt(fracPos)))
	throw new NumberFormatException();
	}

	intDigits = intEnd - actualIntStart;
	fracDigits = fracEnd - fracStart;

	if (intDigits > 0) {
	ivalue = content.substring(actualIntStart, intEnd);
	}

	if (fracDigits > 0) {
	fvalue = content.substring(fracStart, fracEnd);
	if(fracEnd < len) {
	pvalue = Integer.parseInt(content.substring(fracEnd + 1, len));
	}
	}
	totalDigits = intDigits + fracDigits;
	}

	// Construct a canonical String representation of this number
	// for the purpose of deriving a hashCode value compliant with
	// equals.
	// The toString representation will be:
	// NaN for NaN, INF for +infinity, -INF for -infinity, 0 for zero,
	// and [1-9].[0-9][1-9]?(E[1-9][0-9])? for other numbers.
	private static String canonicalToStringForHashCode(String ivalue, String fvalue, int sign, int pvalue) {
	if ("NaN".equals(ivalue)) {
	return "NaN";
	}
	if ("INF".equals(ivalue)) {
	return sign < 0 ? "-INF" : "INF";
	}
	final StringBuilder builder = new StringBuilder();
	final int ilen = ivalue.length();
	final int flen0 = fvalue.length();
	int lastNonZero;
	for (lastNonZero = flen0; lastNonZero > 0 ; lastNonZero--) {
	if (fvalue.charAt(lastNonZero -1 ) != '0') break;
	}
	final int flen = lastNonZero;
	int iStart;
	int exponent = pvalue;
	for (iStart = 0; iStart < ilen; iStart++) {
	if (ivalue.charAt(iStart) != '0') break;
	}
	int fStart = 0;
	if (iStart < ivalue.length()) {
	builder.append(sign == -1 ? "-" : "");
	builder.append(ivalue.charAt(iStart));
	iStart++;
	} else {
	if (flen > 0) {
	for (fStart = 0; fStart < flen; fStart++) {
	if (fvalue.charAt(fStart) != '0') break;
	}
	if (fStart < flen) {
	builder.append(sign == -1 ? "-" : "");
	builder.append(fvalue.charAt(fStart));
	exponent -= ++fStart;
	} else {
	return "0";
	}
	} else {
	return "0";
	}
	}

	if (iStart < ilen \|\| fStart < flen) {
	builder.append('.');
	}
	while (iStart < ilen) {
	builder.append(ivalue.charAt(iStart++));
	exponent++;
	}
	while (fStart < flen) {
	builder.append(fvalue.charAt(fStart++));
	}
	if (exponent != 0) {
	builder.append("E").append(exponent);
	}
	return builder.toString();
	}

	@Override
	public boolean equals(Object val) {
	if (val == this)
	return true;

	if (!(val instanceof XPrecisionDecimal))
	return false;
	XPrecisionDecimal oval = (XPrecisionDecimal)val;

	return this.compareTo(oval) == EQUAL;
	}

	@Override
	public int hashCode() {
	// There's nothing else we can use easily, because equals could
	// return true for widely different representation of the
	// same number - and we don't have any canonical representation.
	// The problem here is that we must ensure that if two numbers
	// are equals then their hash code must also be equals.
	// hashCode for 1.01E1 should be the same as hashCode for 0.101E2
	// So we call cannonicalToStringForHashCode - which implements an
	// algorithm that invents a normalized string representation
	// for this number, and we return a hash for that.
	return canonicalToStringForHashCode(ivalue, fvalue, sign, pvalue).hashCode();
	}

	/**
	* @return
	*/
	private int compareFractionalPart(XPrecisionDecimal oval) {
	if(fvalue.equals(oval.fvalue))
	return EQUAL;

	StringBuffer temp1 = new StringBuffer(fvalue);
	StringBuffer temp2 = new StringBuffer(oval.fvalue);

	truncateTrailingZeros(temp1, temp2);
	return temp1.toString().compareTo(temp2.toString());
	}

	private void truncateTrailingZeros(StringBuffer fValue, StringBuffer otherFValue) {
	for(int i = fValue.length() - 1;i >= 0; i--)
	if(fValue.charAt(i) == '0')
	fValue.deleteCharAt(i);
	else
	break;

	for(int i = otherFValue.length() - 1;i >= 0; i--)
	if(otherFValue.charAt(i) == '0')
	otherFValue.deleteCharAt(i);
	else
	break;
	}

	public int compareTo(XPrecisionDecimal val) {

	// seen NaN
	if(sign == 0)
	return INDETERMINATE;

	//INF is greater than everything and equal to itself
	if(ivalue.equals("INF") \|\| val.ivalue.equals("INF")) {
	if(ivalue.equals(val.ivalue))
	return EQUAL;
	else if(ivalue.equals("INF"))
	return GREATER_THAN;
	return LESS_THAN;
	}

	//-INF is smaller than everything and equal itself
	if(ivalue.equals("-INF") \|\| val.ivalue.equals("-INF")) {
	if(ivalue.equals(val.ivalue))
	return EQUAL;
	else if(ivalue.equals("-INF"))
	return LESS_THAN;
	return GREATER_THAN;
	}

	if (sign != val.sign)
	return sign > val.sign ? GREATER_THAN : LESS_THAN;

	return sign * compare(val);
	}

	// To enable comparison - the exponent part of the decimal will be limited
	// to the max value of int.
	private int compare(XPrecisionDecimal val) {

	if(pvalue != 0 \|\| val.pvalue != 0) {
	if(pvalue == val.pvalue)
	return intComp(val);
	else {

	if(intDigits + pvalue != val.intDigits + val.pvalue)
	return intDigits + pvalue > val.intDigits + val.pvalue ? GREATER_THAN : LESS_THAN;

	//otherwise the 2 combined values are the same
	if(pvalue > val.pvalue) {
	int expDiff = pvalue - val.pvalue;
	StringBuffer buffer = new StringBuffer(ivalue);
	StringBuffer fbuffer = new StringBuffer(fvalue);
	for(int i = 0;i < expDiff; i++) {
	if(i < fracDigits) {
	buffer.append(fvalue.charAt(i));
	fbuffer.deleteCharAt(i);
	}
	else
	buffer.append('0');
	}
	return compareDecimal(buffer.toString(), val.ivalue, fbuffer.toString(), val.fvalue);
	}
	else {
	int expDiff = val.pvalue - pvalue;
	StringBuffer buffer = new StringBuffer(val.ivalue);
	StringBuffer fbuffer = new StringBuffer(val.fvalue);
	for(int i = 0;i < expDiff; i++) {
	if(i < val.fracDigits) {
	buffer.append(val.fvalue.charAt(i));
	fbuffer.deleteCharAt(i);
	}
	else
	buffer.append('0');
	}
	return compareDecimal(ivalue, buffer.toString(), fvalue, fbuffer.toString());
	}
	}
	}
	else {
	return intComp(val);
	}
	}

	/**
	* @param val
	* @return
	*/
	private int intComp(XPrecisionDecimal val) {
	if (intDigits != val.intDigits)
	return intDigits > val.intDigits ? GREATER_THAN : LESS_THAN;

	return compareDecimal(ivalue, val.ivalue, fvalue, val.fvalue);
	}

	/**
	* @param val
	* @return
	*/
	private int compareDecimal(String iValue, String fValue, String otherIValue, String otherFValue) {
	int ret = iValue.compareTo(otherIValue);
	if (ret != 0)
	return ret > 0 ? GREATER_THAN : LESS_THAN;

	if(fValue.equals(otherFValue))
	return EQUAL;

	StringBuffer temp1=new StringBuffer(fValue);
	StringBuffer temp2=new StringBuffer(otherFValue);

	truncateTrailingZeros(temp1, temp2);
	ret = temp1.toString().compareTo(temp2.toString());
	return ret == 0 ? EQUAL : (ret > 0 ? GREATER_THAN : LESS_THAN);
	}

	private String canonical;

	@Override
	public synchronized String toString() {
	if (canonical == null) {
	makeCanonical();
	}
	return canonical;
	}

	private void makeCanonical() {
	// REVISIT: to be determined by working group
	canonical = "TBD by Working Group";
	}

	/**
	* @param decimal
	* @return
	*/
	public boolean isIdentical(XPrecisionDecimal decimal) {
	if(ivalue.equals(decimal.ivalue) && (ivalue.equals("INF") \|\| ivalue.equals("-INF") \|\| ivalue.equals("NaN")))
	return true;

	if(sign == decimal.sign && intDigits == decimal.intDigits && fracDigits == decimal.fracDigits && pvalue == decimal.pvalue
	&& ivalue.equals(decimal.ivalue) && fvalue.equals(decimal.fvalue))
	return true;
	return false;
	}

	}
	/* (non-Javadoc)
	* @see com.sun.org.apache.xerces.internal.impl.dv.xs.TypeValidator#getAllowedFacets()
	*/
	@Override
	public short getAllowedFacets() {
	return ( XSSimpleTypeDecl.FACET_PATTERN \| XSSimpleTypeDecl.FACET_WHITESPACE \| XSSimpleTypeDecl.FACET_ENUMERATION \|XSSimpleTypeDecl.FACET_MAXINCLUSIVE \|XSSimpleTypeDecl.FACET_MININCLUSIVE \| XSSimpleTypeDecl.FACET_MAXEXCLUSIVE \| XSSimpleTypeDecl.FACET_MINEXCLUSIVE \| XSSimpleTypeDecl.FACET_TOTALDIGITS \| XSSimpleTypeDecl.FACET_FRACTIONDIGITS);
	}

	/* (non-Javadoc)
	* @see com.sun.org.apache.xerces.internal.impl.dv.xs.TypeValidator#getActualValue(java.lang.String, com.sun.org.apache.xerces.internal.impl.dv.ValidationContext)
	*/
	@Override
	public Object getActualValue(String content, ValidationContext context)
	throws InvalidDatatypeValueException {
	try {
	return new XPrecisionDecimal(content);
	} catch (NumberFormatException nfe) {
	throw new InvalidDatatypeValueException("cvc-datatype-valid.1.2.1", new Object[]{content, "precisionDecimal"});
	}
	}

	@Override
	public int compare(Object value1, Object value2) {
	return ((XPrecisionDecimal)value1).compareTo((XPrecisionDecimal)value2);
	}

	@Override
	public int getFractionDigits(Object value) {
	return ((XPrecisionDecimal)value).fracDigits;
	}

	@Override
	public int getTotalDigits(Object value) {
	return ((XPrecisionDecimal)value).totalDigits;
	}

	@Override
	public boolean isIdentical(Object value1, Object value2) {
	if(!(value2 instanceof XPrecisionDecimal) \|\| !(value1 instanceof XPrecisionDecimal))
	return false;
	return ((XPrecisionDecimal)value1).isIdentical((XPrecisionDecimal)value2);
	}
	}