/*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The ASF licenses this file to You 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 net.yacy.cora.language.phonetic;
import org.apache.commons.codec.EncoderException;
import org.apache.commons.codec.StringEncoder;
/**
* Encodes a string into a Metaphone value.
* <p>
* Initial Java implementation by <CITE>William B. Brogden. December, 1997</CITE>.
* Permission given by <CITE>wbrogden</CITE> for code to be used anywhere.
* </p>
* <p>
* <CITE>Hanging on the Metaphone</CITE> by <CITE>Lawrence Philips</CITE> in <CITE>Computer Language of Dec. 1990, p
* 39.</CITE>
* </p>
* <p>
* Note, that this does not match the algorithm that ships with PHP, or the algorithm
* found in the Perl <a href="http://search.cpan.org/~mschwern/Text-Metaphone-1.96/Metaphone.pm">Text:Metaphone-1.96</a>.
* They have had undocumented changes from the originally published algorithm.
* For more information, see <a href="https://issues.apache.org/jira/browse/CODEC-57">CODEC-57</a>.
* </p>
*
* @author Apache Software Foundation
* @version $Id: Metaphone.java 1157192 2011-08-12 17:27:38Z ggregory $
*/
public class Metaphone implements StringEncoder {
/**
* Five values in the English language
*/
private static final String VOWELS = "AEIOU" ;
/**
* Variable used in Metaphone algorithm
*/
private static final String FRONTV = "EIY" ;
/**
* Variable used in Metaphone algorithm
*/
private static final String VARSON = "CSPTG" ;
/**
* The max code length for metaphone is 4
*/
private int maxCodeLen = 4 ;
/**
* Creates an instance of the Metaphone encoder
*/
public Metaphone() {
super();
}
/**
* Find the metaphone value of a String. This is similar to the
* soundex algorithm, but better at finding similar sounding words.
* All input is converted to upper case.
* Limitations: Input format is expected to be a single ASCII word
* with only characters in the A - Z range, no punctuation or numbers.
*
* @param txt String to find the metaphone code for
* @return A metaphone code corresponding to the String supplied
*/
public String metaphone(String txt) {
boolean hard = false ;
if ((txt == null) || (txt.isEmpty())) {
return "" ;
}
// single character is itself
if (txt.length() == 1) {
return txt.toUpperCase(java.util.Locale.ENGLISH) ;
}
char[] inwd = txt.toUpperCase(java.util.Locale.ENGLISH).toCharArray() ;
StringBuilder local = new StringBuilder(40); // manipulate
StringBuilder code = new StringBuilder(10) ; // output
// handle initial 2 characters exceptions
switch(inwd[0]) {
case 'K' :
case 'G' :
case 'P' : /* looking for KN, etc*/
if (inwd[1] == 'N') {
local.append(inwd, 1, inwd.length - 1);
} else {
local.append(inwd);
}
break;
case 'A': /* looking for AE */
if (inwd[1] == 'E') {
local.append(inwd, 1, inwd.length - 1);
} else {
local.append(inwd);
}
break;
case 'W' : /* looking for WR or WH */
if (inwd[1] == 'R') { // WR -> R
local.append(inwd, 1, inwd.length - 1);
break ;
}
if (inwd[1] == 'H') {
local.append(inwd, 1, inwd.length - 1);
local.setCharAt(0, 'W'); // WH -> W
} else {
local.append(inwd);
}
break;
case 'X' : /* initial X becomes S */
inwd[0] = 'S';
local.append(inwd);
break ;
default :
local.append(inwd);
} // now local has working string with initials fixed
int wdsz = local.length();
int n = 0 ;
while ((code.length() < this.getMaxCodeLen()) &&
(n < wdsz) ) { // max code size of 4 works well
char symb = local.charAt(n) ;
// remove duplicate letters except C
if ((symb != 'C') && (isPreviousChar( local, n, symb )) ) {
n++ ;
} else { // not dup
switch(symb) {
case 'A' : case 'E' : case 'I' : case 'O' : case 'U' :
if (n == 0) {
code.append(symb);
}
break ; // only use vowel if leading char
case 'B' :
if ( isPreviousChar(local, n, 'M') &&
isLastChar(wdsz, n) ) { // B is silent if word ends in MB
break;
}
code.append(symb);
break;
case 'C' : // lots of C special cases
/* discard if SCI, SCE or SCY */
if ( isPreviousChar(local, n, 'S') &&
!isLastChar(wdsz, n) &&
(FRONTV.indexOf(local.charAt(n + 1)) >= 0) ) {
break;
}
if (regionMatch(local, n, "CIA")) { // "CIA" -> X
code.append('X');
break;
}
if (!isLastChar(wdsz, n) &&
(FRONTV.indexOf(local.charAt(n + 1)) >= 0)) {
code.append('S');
break; // CI,CE,CY -> S
}
if (isPreviousChar(local, n, 'S') &&
isNextChar(local, n, 'H') ) { // SCH->sk
code.append('K') ;
break ;
}
if (isNextChar(local, n, 'H')) { // detect CH
if ((n == 0) &&
(wdsz >= 3) &&
isVowel(local,2) ) { // CH consonant -> K consonant
code.append('K');
} else {
code.append('X'); // CHvowel -> X
}
} else {
code.append('K');
}
break ;
case 'D' :
if (!isLastChar(wdsz, n + 1) &&
isNextChar(local, n, 'G') &&
(FRONTV.indexOf(local.charAt(n + 2)) >= 0)) { // DGE DGI DGY -> J
code.append('J'); n += 2 ;
} else {
code.append('T');
}
break ;
case 'G' : // GH silent at end or before consonant
if (isLastChar(wdsz, n + 1) &&
isNextChar(local, n, 'H')) {
break;
}
if (!isLastChar(wdsz, n + 1) &&
isNextChar(local,n,'H') &&
!isVowel(local,n+2)) {
break;
}
if ((n > 0) &&
( regionMatch(local, n, "GN") ||
regionMatch(local, n, "GNED") ) ) {
break; // silent G
}
if (isPreviousChar(local, n, 'G')) {
// NOTE: Given that duplicated chars are removed, I don't see how this can ever be true
hard = true ;
} else {
hard = false ;
}
if (!isLastChar(wdsz, n) &&
(FRONTV.indexOf(local.charAt(n + 1)) >= 0) &&
(!hard)) {
code.append('J');
} else {
code.append('K');
}
break ;
case 'H':
if (isLastChar(wdsz, n)) {
break ; // terminal H
}
if ((n > 0) &&
(VARSON.indexOf(local.charAt(n - 1)) >= 0)) {
break;
}
if (isVowel(local,n+1)) {
code.append('H'); // Hvowel
}
break;
case 'F':
case 'J' :
case 'L' :
case 'M':
case 'N' :
case 'R' :
code.append(symb);
break;
case 'K' :
if (n > 0) { // not initial
if (!isPreviousChar(local, n, 'C')) {
code.append(symb);
}
} else {
code.append(symb); // initial K
}
break ;
case 'P' :
if (isNextChar(local,n,'H')) {
// PH -> F
code.append('F');
} else {
code.append(symb);
}
break ;
case 'Q' :
code.append('K');
break;
case 'S' :
if (regionMatch(local,n,"SH") ||
regionMatch(local,n,"SIO") ||
regionMatch(local,n,"SIA")) {
code.append('X');
} else {
code.append('S');
}
break;
case 'T' :
if (regionMatch(local,n,"TIA") ||
regionMatch(local,n,"TIO")) {
code.append('X');
break;
}
if (regionMatch(local,n,"TCH")) {
// Silent if in "TCH"
break;
}
// substitute numeral 0 for TH (resembles theta after all)
if (regionMatch(local,n,"TH")) {
code.append('0');
} else {
code.append('T');
}
break ;
case 'V' :
code.append('F'); break ;
case 'W' : case 'Y' : // silent if not followed by vowel
if (!isLastChar(wdsz,n) &&
isVowel(local,n+1)) {
code.append(symb);
}
break ;
case 'X' :
code.append('K'); code.append('S');
break ;
case 'Z' :
code.append('S'); break ;
} // end switch
n++ ;
} // end else from symb != 'C'
if (code.length() > this.getMaxCodeLen()) {
code.setLength(this.getMaxCodeLen());
}
}
return code.toString();
}
private boolean isVowel(StringBuilder string, int index) {
return VOWELS.indexOf(string.charAt(index)) >= 0;
}
private boolean isPreviousChar(StringBuilder string, int index, char c) {
boolean matches = false;
if( index > 0 &&
index < string.length() ) {
matches = string.charAt(index - 1) == c;
}
return matches;
}
private boolean isNextChar(StringBuilder string, int index, char c) {
boolean matches = false;
if( index >= 0 &&
index < string.length() - 1 ) {
matches = string.charAt(index + 1) == c;
}
return matches;
}
private boolean regionMatch(StringBuilder string, int index, String test) {
boolean matches = false;
if( index >= 0 &&
(index + test.length() - 1) < string.length() ) {
String substring = string.substring( index, index + test.length());
matches = substring.equals( test );
}
return matches;
}
private boolean isLastChar(int wdsz, int n) {
return n + 1 == wdsz;
}
/**
* Encodes an Object using the metaphone algorithm. This method
* is provided in order to satisfy the requirements of the
* Encoder interface, and will throw an EncoderException if the
* supplied object is not of type java.lang.String.
*
* @param pObject Object to encode
* @return An object (or type java.lang.String) containing the
* metaphone code which corresponds to the String supplied.
* @throws EncoderException if the parameter supplied is not
* of type java.lang.String
*/
@Override
public Object encode(Object pObject) throws EncoderException {
if (!(pObject instanceof String)) {
throw new EncoderException("Parameter supplied to Metaphone encode is not of type java.lang.String");
}
return metaphone((String) pObject);
}
/**
* Encodes a String using the Metaphone algorithm.
*
* @param pString String object to encode
* @return The metaphone code corresponding to the String supplied
*/
@Override
public String encode(String pString) {
return metaphone(pString);
}
/**
* Tests is the metaphones of two strings are identical.
*
* @param str1 First of two strings to compare
* @param str2 Second of two strings to compare
* @return <code>true</code> if the metaphones of these strings are identical,
* <code>false</code> otherwise.
*/
public boolean isMetaphoneEqual(String str1, String str2) {
return metaphone(str1).equals(metaphone(str2));
}
/**
* Returns the maxCodeLen.
* @return int
*/
public int getMaxCodeLen() { return this.maxCodeLen; }
/**
* Sets the maxCodeLen.
* @param maxCodeLen The maxCodeLen to set
*/
public void setMaxCodeLen(int maxCodeLen) { this.maxCodeLen = maxCodeLen; }
}