private void addContractFlags(String chars) { char c0; int c; int len = chars.length(); for (int i = 0; i < len; i++) { c0 = chars.charAt(i); c = Character.isHighSurrogate(c0) ? Character.toCodePoint(c0, chars.charAt(++i)) : c0; contractFlags.put(c, 1); } }
/** * Create a new entry in the expansion table that contains the orderings for the given characers. * If anOrder is valid, it is added to the beginning of the expanded list of orders. */ private int addExpansion(int anOrder, String expandChars) { if (expandTable == null) { expandTable = new Vector(INITIALTABLESIZE); } // If anOrder is valid, we want to add it at the beginning of the list int offset = (anOrder == RBCollationTables.UNMAPPED) ? 0 : 1; int[] valueList = new int[expandChars.length() + offset]; if (offset == 1) { valueList[0] = anOrder; } int j = offset; for (int i = 0; i < expandChars.length(); i++) { char ch0 = expandChars.charAt(i); char ch1; int ch; if (Character.isHighSurrogate(ch0)) { if (++i == expandChars.length() || !Character.isLowSurrogate(ch1 = expandChars.charAt(i))) { // ether we are missing the low surrogate or the next char // is not a legal low surrogate, so stop loop break; } ch = Character.toCodePoint(ch0, ch1); } else { ch = ch0; } int mapValue = getCharOrder(ch); if (mapValue != RBCollationTables.UNMAPPED) { valueList[j++] = mapValue; } else { // can't find it in the table, will be filled in by commit(). valueList[j++] = CHARINDEX + ch; } } if (j < valueList.length) { // we had at least one supplementary character, the size of valueList // is bigger than it really needs... int[] tmpBuf = new int[j]; while (--j >= 0) { tmpBuf[j] = valueList[j]; } valueList = tmpBuf; } // Add the expanding char list into the expansion table. int tableIndex = RBCollationTables.EXPANDCHARINDEX + expandTable.size(); expandTable.addElement(valueList); return tableIndex; }
/** Adds the expanding string into the collation table. */ private final void addExpandOrder(String contractChars, String expandChars, int anOrder) throws ParseException { // Create an expansion table entry int tableIndex = addExpansion(anOrder, expandChars); // And add its index into the main mapping table if (contractChars.length() > 1) { char ch = contractChars.charAt(0); if (Character.isHighSurrogate(ch) && contractChars.length() == 2) { char ch2 = contractChars.charAt(1); if (Character.isLowSurrogate(ch2)) { // only add into table when it is a legal surrogate addOrder(Character.toCodePoint(ch, ch2), tableIndex); } } else { addContractOrder(contractChars, tableIndex); } } else { addOrder(contractChars.charAt(0), tableIndex); } }
/** * Create a table-based collation object with the given rules. This is the main function that * actually builds the tables and stores them back in the RBCollationTables object. It is called * ONLY by the RBCollationTables constructor. * * @see java.util.RuleBasedCollator#RuleBasedCollator * @exception ParseException If the rules format is incorrect. */ public void build(String pattern, int decmp) throws ParseException { boolean isSource = true; int i = 0; String expChars; String groupChars; if (pattern.length() == 0) throw new ParseException("Build rules empty.", 0); // This array maps Unicode characters to their collation ordering mapping = new UCompactIntArray((int) RBCollationTables.UNMAPPED); // Normalize the build rules. Find occurances of all decomposed characters // and normalize the rules before feeding into the builder. By "normalize", // we mean that all precomposed Unicode characters must be converted into // a base character and one or more combining characters (such as accents). // When there are multiple combining characters attached to a base character, // the combining characters must be in their canonical order // // sherman/Note: // (1)decmp will be NO_DECOMPOSITION only in ko locale to prevent decompose // hangual syllables to jamos, so we can actually just call decompose with // normalizer's IGNORE_HANGUL option turned on // // (2)just call the "special version" in NormalizerImpl directly // pattern = Normalizer.decompose(pattern, false, Normalizer.IGNORE_HANGUL, true); // // Normalizer.Mode mode = NormalizerUtilities.toNormalizerMode(decmp); // pattern = Normalizer.normalize(pattern, mode, 0, true); pattern = NormalizerImpl.canonicalDecomposeWithSingleQuotation(pattern); // Build the merged collation entries // Since rules can be specified in any order in the string // (e.g. "c , C < d , D < e , E .... C < CH") // this splits all of the rules in the string out into separate // objects and then sorts them. In the above example, it merges the // "C < CH" rule in just before the "C < D" rule. // mPattern = new MergeCollation(pattern); int order = 0; // Now walk though each entry and add it to my own tables for (i = 0; i < mPattern.getCount(); ++i) { PatternEntry entry = mPattern.getItemAt(i); if (entry != null) { groupChars = entry.getChars(); if (groupChars.length() > 1) { switch (groupChars.charAt(groupChars.length() - 1)) { case '@': frenchSec = true; groupChars = groupChars.substring(0, groupChars.length() - 1); break; case '!': seAsianSwapping = true; groupChars = groupChars.substring(0, groupChars.length() - 1); break; } } order = increment(entry.getStrength(), order); expChars = entry.getExtension(); if (expChars.length() != 0) { addExpandOrder(groupChars, expChars, order); } else if (groupChars.length() > 1) { char ch = groupChars.charAt(0); if (Character.isHighSurrogate(ch) && groupChars.length() == 2) { addOrder(Character.toCodePoint(ch, groupChars.charAt(1)), order); } else { addContractOrder(groupChars, order); } } else { char ch = groupChars.charAt(0); addOrder(ch, order); } } } addComposedChars(); commit(); mapping.compact(); /* System.out.println("mappingSize=" + mapping.getKSize()); for (int j = 0; j < 0xffff; j++) { int value = mapping.elementAt(j); if (value != RBCollationTables.UNMAPPED) System.out.println("index=" + Integer.toString(j, 16) + ", value=" + Integer.toString(value, 16)); } */ tables.fillInTables( frenchSec, seAsianSwapping, mapping, contractTable, expandTable, contractFlags, maxSecOrder, maxTerOrder); }
/** * Add expanding entries for pre-composed unicode characters so that this collator can be used * reasonably well with decomposition turned off. */ private void addComposedChars() throws ParseException { // Iterate through all of the pre-composed characters in Unicode ComposedCharIter iter = new ComposedCharIter(); int c; while ((c = iter.next()) != ComposedCharIter.DONE) { if (getCharOrder(c) == RBCollationTables.UNMAPPED) { // // We don't already have an ordering for this pre-composed character. // // First, see if the decomposed string is already in our // tables as a single contracting-string ordering. // If so, just map the precomposed character to that order. // // TODO: What we should really be doing here is trying to find the // longest initial substring of the decomposition that is present // in the tables as a contracting character sequence, and find its // ordering. Then do this recursively with the remaining chars // so that we build a list of orderings, and add that list to // the expansion table. // That would be more correct but also significantly slower, so // I'm not totally sure it's worth doing. // String s = iter.decomposition(); // sherman/Note: if this is 1 character decomposed string, the // only thing need to do is to check if this decomposed character // has an entry in our order table, this order is not necessary // to be a contraction order, if it does have one, add an entry // for the precomposed character by using the same order, the // previous impl unnecessarily adds a single character expansion // entry. if (s.length() == 1) { int order = getCharOrder(s.charAt(0)); if (order != RBCollationTables.UNMAPPED) { addOrder(c, order); } continue; } else if (s.length() == 2) { char ch0 = s.charAt(0); if (Character.isHighSurrogate(ch0)) { int order = getCharOrder(s.codePointAt(0)); if (order != RBCollationTables.UNMAPPED) { addOrder(c, order); } continue; } } int contractOrder = getContractOrder(s); if (contractOrder != RBCollationTables.UNMAPPED) { addOrder(c, contractOrder); } else { // // We don't have a contracting ordering for the entire string // that results from the decomposition, but if we have orders // for each individual character, we can add an expanding // table entry for the pre-composed character // boolean allThere = true; for (int i = 0; i < s.length(); i++) { if (getCharOrder(s.charAt(i)) == RBCollationTables.UNMAPPED) { allThere = false; break; } } if (allThere) { addExpandOrder(c, s, RBCollationTables.UNMAPPED); } } } } }