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/*
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//
// CHANGELOG
//      2005-05-19 Edward Wang
//          - copy this file from icu4jsrc_3_2/src/com/ibm/icu/text/StringPrep.java
//          - move from package com.ibm.icu.text to package sun.net.idn
//          - use ParseException instead of StringPrepParseException
//          - change 'Normalizer.getUnicodeVersion()' to 'NormalizerImpl.getUnicodeVersion()'
//          - remove all @deprecated tag to make compiler happy
//      2007-08-14 Martin Buchholz
//          - remove redundant casts
//
package sun.net.idn;

import java.io.BufferedInputStream;
import java.io.ByteArrayInputStream;
import java.io.IOException;
import java.io.InputStream;
import java.text.ParseException;

import sun.text.Normalizer;
import sun.text.normalizer.CharTrie;
import sun.text.normalizer.Trie;
import sun.text.normalizer.VersionInfo;
import sun.text.normalizer.UCharacter;
import sun.text.normalizer.UCharacterIterator;
import sun.text.normalizer.UTF16;
import sun.net.idn.UCharacterDirection;
import sun.net.idn.StringPrepDataReader;

StringPrep API implements the StingPrep framework as described by RFC 3454. StringPrep prepares Unicode strings for use in network protocols. Profiles of StingPrep are set of rules and data according to which the Unicode Strings are prepared. Each profiles contains tables which describe how a code point should be treated. The tables are broadly classied into
  • Unassigned Table: Contains code points that are unassigned in the Unicode Version supported by StringPrep. Currently RFC 3454 supports Unicode 3.2.
  • Prohibited Table: Contains code points that are prohibted from the output of the StringPrep processing function.
  • Mapping Table: Contains code ponts that are deleted from the output or case mapped.
The procedure for preparing Unicode strings:
  1. Map: For each character in the input, check if it has a mapping and, if so, replace it with its mapping.
  2. Normalize: Possibly normalize the result of step 1 using Unicode normalization.
  3. Prohibit: Check for any characters that are not allowed in the output. If any are found, return an error.
  4. Check bidi: Possibly check for right-to-left characters, and if any are found, make sure that the whole string satisfies the requirements for bidirectional strings. If the string does not satisfy the requirements for bidirectional strings, return an error.
Author:Ram Viswanadha
@draftICU 2.8
/** * StringPrep API implements the StingPrep framework as described by * <a href="http://www.ietf.org/rfc/rfc3454.txt">RFC 3454</a>. * StringPrep prepares Unicode strings for use in network protocols. * Profiles of StingPrep are set of rules and data according to which the * Unicode Strings are prepared. Each profiles contains tables which describe * how a code point should be treated. The tables are broadly classied into * <ul> * <li> Unassigned Table: Contains code points that are unassigned * in the Unicode Version supported by StringPrep. Currently * RFC 3454 supports Unicode 3.2. </li> * <li> Prohibited Table: Contains code points that are prohibted from * the output of the StringPrep processing function. </li> * <li> Mapping Table: Contains code ponts that are deleted from the output or case mapped. </li> * </ul> * * The procedure for preparing Unicode strings: * <ol> * <li> Map: For each character in the input, check if it has a mapping * and, if so, replace it with its mapping. </li> * <li> Normalize: Possibly normalize the result of step 1 using Unicode * normalization. </li> * <li> Prohibit: Check for any characters that are not allowed in the * output. If any are found, return an error.</li> * <li> Check bidi: Possibly check for right-to-left characters, and if * any are found, make sure that the whole string satisfies the * requirements for bidirectional strings. If the string does not * satisfy the requirements for bidirectional strings, return an * error. </li> * </ol> * @author Ram Viswanadha * @draft ICU 2.8 */
public final class StringPrep {
Option to prohibit processing of unassigned code points in the input
See Also:
  • prepare
@draftICU 2.8
/** * Option to prohibit processing of unassigned code points in the input * * @see #prepare * @draft ICU 2.8 */
public static final int DEFAULT = 0x0000;
Option to allow processing of unassigned code points in the input
See Also:
  • prepare
@draftICU 2.8
/** * Option to allow processing of unassigned code points in the input * * @see #prepare * @draft ICU 2.8 */
public static final int ALLOW_UNASSIGNED = 0x0001; private static final int UNASSIGNED = 0x0000; private static final int MAP = 0x0001; private static final int PROHIBITED = 0x0002; private static final int DELETE = 0x0003; private static final int TYPE_LIMIT = 0x0004; private static final int NORMALIZATION_ON = 0x0001; private static final int CHECK_BIDI_ON = 0x0002; private static final int TYPE_THRESHOLD = 0xFFF0; private static final int MAX_INDEX_VALUE = 0x3FBF; /*16139*/ private static final int MAX_INDEX_TOP_LENGTH = 0x0003; /* indexes[] value names */ private static final int INDEX_TRIE_SIZE = 0; /* number of bytes in normalization trie */ private static final int INDEX_MAPPING_DATA_SIZE = 1; /* The array that contains the mapping */ private static final int NORM_CORRECTNS_LAST_UNI_VERSION = 2; /* The index of Unicode version of last entry in NormalizationCorrections.txt */ private static final int ONE_UCHAR_MAPPING_INDEX_START = 3; /* The starting index of 1 UChar mapping index in the mapping data array */ private static final int TWO_UCHARS_MAPPING_INDEX_START = 4; /* The starting index of 2 UChars mapping index in the mapping data array */ private static final int THREE_UCHARS_MAPPING_INDEX_START = 5; private static final int FOUR_UCHARS_MAPPING_INDEX_START = 6; private static final int OPTIONS = 7; /* Bit set of options to turn on in the profile */ private static final int INDEX_TOP = 16; /* changing this requires a new formatVersion */
Default buffer size of datafile
/** * Default buffer size of datafile */
private static final int DATA_BUFFER_SIZE = 25000; /* Wrappers for Trie implementations */ private static final class StringPrepTrieImpl implements Trie.DataManipulate{ private CharTrie sprepTrie = null;
Called by com.ibm.icu.util.Trie to extract from a lead surrogate's data the index array offset of the indexes for that lead surrogate.
Params:
  • property – data value for a surrogate from the trie, including the folding offset
Returns:data offset or 0 if there is no data for the lead surrogate
/** * Called by com.ibm.icu.util.Trie to extract from a lead surrogate's * data the index array offset of the indexes for that lead surrogate. * @param property data value for a surrogate from the trie, including * the folding offset * @return data offset or 0 if there is no data for the lead surrogate */
public int getFoldingOffset(int value){ return value; } } // CharTrie implementation for reading the trie data private StringPrepTrieImpl sprepTrieImpl; // Indexes read from the data file private int[] indexes; // mapping data read from the data file private char[] mappingData; // format version of the data file private byte[] formatVersion; // the version of Unicode supported by the data file private VersionInfo sprepUniVer; // the Unicode version of last entry in the // NormalizationCorrections.txt file if normalization // is turned on private VersionInfo normCorrVer; // Option to turn on Normalization private boolean doNFKC; // Option to turn on checking for BiDi rules private boolean checkBiDi; private char getCodePointValue(int ch){ return sprepTrieImpl.sprepTrie.getCodePointValue(ch); } private static VersionInfo getVersionInfo(int comp){ int micro = comp & 0xFF; int milli =(comp >> 8) & 0xFF; int minor =(comp >> 16) & 0xFF; int major =(comp >> 24) & 0xFF; return VersionInfo.getInstance(major,minor,milli,micro); } private static VersionInfo getVersionInfo(byte[] version){ if(version.length != 4){ return null; } return VersionInfo.getInstance((int)version[0],(int) version[1],(int) version[2],(int) version[3]); }
Creates an StringPrep object after reading the input stream. The object does not hold a reference to the input steam, so the stream can be closed after the method returns.
Params:
  • inputStream – The stream for reading the StringPrep profile binarySun
Throws:
@draftICU 2.8
/** * Creates an StringPrep object after reading the input stream. * The object does not hold a reference to the input steam, so the stream can be * closed after the method returns. * * @param inputStream The stream for reading the StringPrep profile binarySun * @throws IOException * @draft ICU 2.8 */
public StringPrep(InputStream inputStream) throws IOException{ BufferedInputStream b = new BufferedInputStream(inputStream,DATA_BUFFER_SIZE); StringPrepDataReader reader = new StringPrepDataReader(b); // read the indexes indexes = reader.readIndexes(INDEX_TOP); byte[] sprepBytes = new byte[indexes[INDEX_TRIE_SIZE]]; //indexes[INDEX_MAPPING_DATA_SIZE] store the size of mappingData in bytes mappingData = new char[indexes[INDEX_MAPPING_DATA_SIZE]/2]; // load the rest of the data data and initialize the data members reader.read(sprepBytes,mappingData); sprepTrieImpl = new StringPrepTrieImpl(); sprepTrieImpl.sprepTrie = new CharTrie( new ByteArrayInputStream(sprepBytes),sprepTrieImpl ); // get the data format version formatVersion = reader.getDataFormatVersion(); // get the options doNFKC = ((indexes[OPTIONS] & NORMALIZATION_ON) > 0); checkBiDi = ((indexes[OPTIONS] & CHECK_BIDI_ON) > 0); sprepUniVer = getVersionInfo(reader.getUnicodeVersion()); normCorrVer = getVersionInfo(indexes[NORM_CORRECTNS_LAST_UNI_VERSION]); VersionInfo normUniVer = UCharacter.getUnicodeVersion(); if(normUniVer.compareTo(sprepUniVer) < 0 && /* the Unicode version of SPREP file must be less than the Unicode Vesion of the normalization data */ normUniVer.compareTo(normCorrVer) < 0 && /* the Unicode version of the NormalizationCorrections.txt file should be less than the Unicode Vesion of the normalization data */ ((indexes[OPTIONS] & NORMALIZATION_ON) > 0) /* normalization turned on*/ ){ throw new IOException("Normalization Correction version not supported"); } b.close(); } private static final class Values{ boolean isIndex; int value; int type; public void reset(){ isIndex = false; value = 0; type = -1; } } private static final void getValues(char trieWord,Values values){ values.reset(); if(trieWord == 0){ /* * Initial value stored in the mapping table * just return TYPE_LIMIT .. so that * the source codepoint is copied to the destination */ values.type = TYPE_LIMIT; }else if(trieWord >= TYPE_THRESHOLD){ values.type = (trieWord - TYPE_THRESHOLD); }else{ /* get the type */ values.type = MAP; /* ascertain if the value is index or delta */ if((trieWord & 0x02)>0){ values.isIndex = true; values.value = trieWord >> 2; //mask off the lower 2 bits and shift }else{ values.isIndex = false; values.value = (trieWord<<16)>>16; values.value = (values.value >> 2); } if((trieWord>>2) == MAX_INDEX_VALUE){ values.type = DELETE; values.isIndex = false; values.value = 0; } } } private StringBuffer map( UCharacterIterator iter, int options) throws ParseException { Values val = new Values(); char result = 0; int ch = UCharacterIterator.DONE; StringBuffer dest = new StringBuffer(); boolean allowUnassigned = ((options & ALLOW_UNASSIGNED)>0); while((ch=iter.nextCodePoint())!= UCharacterIterator.DONE){ result = getCodePointValue(ch); getValues(result,val); // check if the source codepoint is unassigned if(val.type == UNASSIGNED && allowUnassigned == false){ throw new ParseException("An unassigned code point was found in the input " + iter.getText(), iter.getIndex()); }else if((val.type == MAP)){ int index, length; if(val.isIndex){ index = val.value; if(index >= indexes[ONE_UCHAR_MAPPING_INDEX_START] && index < indexes[TWO_UCHARS_MAPPING_INDEX_START]){ length = 1; }else if(index >= indexes[TWO_UCHARS_MAPPING_INDEX_START] && index < indexes[THREE_UCHARS_MAPPING_INDEX_START]){ length = 2; }else if(index >= indexes[THREE_UCHARS_MAPPING_INDEX_START] && index < indexes[FOUR_UCHARS_MAPPING_INDEX_START]){ length = 3; }else{ length = mappingData[index++]; } /* copy mapping to destination */ dest.append(mappingData,index,length); continue; }else{ ch -= val.value; } }else if(val.type == DELETE){ // just consume the codepoint and contine continue; } //copy the source into destination UTF16.append(dest,ch); } return dest; } private StringBuffer normalize(StringBuffer src){ /* * Option UNORM_BEFORE_PRI_29: * * IDNA as interpreted by IETF members (see unicode mailing list 2004H1) * requires strict adherence to Unicode 3.2 normalization, * including buggy composition from before fixing Public Review Issue #29. * Note that this results in some valid but nonsensical text to be * either corrupted or rejected, depending on the text. * See http://www.unicode.org/review/resolved-pri.html#pri29 * See unorm.cpp and cnormtst.c */ return new StringBuffer( Normalizer.normalize( src.toString(), java.text.Normalizer.Form.NFKC, Normalizer.UNICODE_3_2)); } /* boolean isLabelSeparator(int ch){ int result = getCodePointValue(ch); if( (result & 0x07) == LABEL_SEPARATOR){ return true; } return false; } */ /* 1) Map -- For each character in the input, check if it has a mapping and, if so, replace it with its mapping. 2) Normalize -- Possibly normalize the result of step 1 using Unicode normalization. 3) Prohibit -- Check for any characters that are not allowed in the output. If any are found, return an error. 4) Check bidi -- Possibly check for right-to-left characters, and if any are found, make sure that the whole string satisfies the requirements for bidirectional strings. If the string does not satisfy the requirements for bidirectional strings, return an error. [Unicode3.2] defines several bidirectional categories; each character has one bidirectional category assigned to it. For the purposes of the requirements below, an "RandALCat character" is a character that has Unicode bidirectional categories "R" or "AL"; an "LCat character" is a character that has Unicode bidirectional category "L". Note that there are many characters which fall in neither of the above definitions; Latin digits (<U+0030> through <U+0039>) are examples of this because they have bidirectional category "EN". In any profile that specifies bidirectional character handling, all three of the following requirements MUST be met: 1) The characters in section 5.8 MUST be prohibited. 2) If a string contains any RandALCat character, the string MUST NOT contain any LCat character. 3) If a string contains any RandALCat character, a RandALCat character MUST be the first character of the string, and a RandALCat character MUST be the last character of the string. */
Prepare the input buffer for use in applications with the given profile. This operation maps, normalizes(NFKC), checks for prohited and BiDi characters in the order defined by RFC 3454 depending on the options specified in the profile.
Params:
  • src – A UCharacterIterator object containing the source string
  • options – A bit set of options: - StringPrep.NONE Prohibit processing of unassigned code points in the input - StringPrep.ALLOW_UNASSIGNED Treat the unassigned code points are in the input as normal Unicode code points.
Throws:
Returns:StringBuffer A StringBuffer containing the output
@draftICU 2.8
/** * Prepare the input buffer for use in applications with the given profile. This operation maps, normalizes(NFKC), * checks for prohited and BiDi characters in the order defined by RFC 3454 * depending on the options specified in the profile. * * @param src A UCharacterIterator object containing the source string * @param options A bit set of options: * * - StringPrep.NONE Prohibit processing of unassigned code points in the input * * - StringPrep.ALLOW_UNASSIGNED Treat the unassigned code points are in the input * as normal Unicode code points. * * @return StringBuffer A StringBuffer containing the output * @throws ParseException * @draft ICU 2.8 */
public StringBuffer prepare(UCharacterIterator src, int options) throws ParseException{ // map StringBuffer mapOut = map(src,options); StringBuffer normOut = mapOut;// initialize if(doNFKC){ // normalize normOut = normalize(mapOut); } int ch; char result; UCharacterIterator iter = UCharacterIterator.getInstance(normOut); Values val = new Values(); int direction=UCharacterDirection.CHAR_DIRECTION_COUNT, firstCharDir=UCharacterDirection.CHAR_DIRECTION_COUNT; int rtlPos=-1, ltrPos=-1; boolean rightToLeft=false, leftToRight=false; while((ch=iter.nextCodePoint())!= UCharacterIterator.DONE){ result = getCodePointValue(ch); getValues(result,val); if(val.type == PROHIBITED ){ throw new ParseException("A prohibited code point was found in the input" + iter.getText(), val.value); } direction = UCharacter.getDirection(ch); if(firstCharDir == UCharacterDirection.CHAR_DIRECTION_COUNT){ firstCharDir = direction; } if(direction == UCharacterDirection.LEFT_TO_RIGHT){ leftToRight = true; ltrPos = iter.getIndex()-1; } if(direction == UCharacterDirection.RIGHT_TO_LEFT || direction == UCharacterDirection.RIGHT_TO_LEFT_ARABIC){ rightToLeft = true; rtlPos = iter.getIndex()-1; } } if(checkBiDi == true){ // satisfy 2 if( leftToRight == true && rightToLeft == true){ throw new ParseException("The input does not conform to the rules for BiDi code points." + iter.getText(), (rtlPos>ltrPos) ? rtlPos : ltrPos); } //satisfy 3 if( rightToLeft == true && !((firstCharDir == UCharacterDirection.RIGHT_TO_LEFT || firstCharDir == UCharacterDirection.RIGHT_TO_LEFT_ARABIC) && (direction == UCharacterDirection.RIGHT_TO_LEFT || direction == UCharacterDirection.RIGHT_TO_LEFT_ARABIC)) ){ throw new ParseException("The input does not conform to the rules for BiDi code points." + iter.getText(), (rtlPos>ltrPos) ? rtlPos : ltrPos); } } return normOut; } }