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See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ /* ******************************************************************************* * Copyright (C) 2009-2014, International Business Machines * Corporation and others. All Rights Reserved. ******************************************************************************* */ package sun.text.normalizer; import java.io.IOException; import java.nio.ByteBuffer; import java.text.Normalizer; // Original filename in ICU4J: Normalizer2Impl.java public final class NormalizerImpl { public static final class Hangul { /* Korean Hangul and Jamo constants */ public static final int JAMO_L_BASE=0x1100; /* "lead" jamo */ public static final int JAMO_V_BASE=0x1161; /* "vowel" jamo */ public static final int JAMO_T_BASE=0x11a7; /* "trail" jamo */ public static final int HANGUL_BASE=0xac00; public static final int HANGUL_END=0xd7a3; public static final int JAMO_L_COUNT=19; public static final int JAMO_V_COUNT=21; public static final int JAMO_T_COUNT=28; public static final int HANGUL_COUNT=JAMO_L_COUNT*JAMO_V_COUNT*JAMO_T_COUNT; public static final int HANGUL_LIMIT=HANGUL_BASE+HANGUL_COUNT; public static boolean isHangul(int c) { return HANGUL_BASE<=c && c * If dest is a StringBuilder, then the buffer writes directly to it. * Otherwise, the buffer maintains a StringBuilder for intermediate text segments * until no further changes are necessary and whole segments are appended. * append() methods that take combining-class values always write to the StringBuilder. * Other append() methods flush and append to the Appendable. */ public static final class ReorderingBuffer implements Appendable { public ReorderingBuffer(NormalizerImpl ni, Appendable dest, int destCapacity) { impl=ni; app=dest; if (app instanceof StringBuilder) { appIsStringBuilder=true; str=(StringBuilder)dest; // In Java, the constructor subsumes public void init(int destCapacity) str.ensureCapacity(destCapacity); reorderStart=0; if(str.length()==0) { lastCC=0; } else { setIterator(); lastCC=previousCC(); // Set reorderStart after the last code point with cc<=1 if there is one. if(lastCC>1) { while(previousCC()>1) {} } reorderStart=codePointLimit; } } else { appIsStringBuilder=false; str=new StringBuilder(); reorderStart=0; lastCC=0; } } public boolean isEmpty() { return str.length()==0; } public int length() { return str.length(); } public int getLastCC() { return lastCC; } public StringBuilder getStringBuilder() { return str; } public boolean equals(CharSequence s, int start, int limit) { return UTF16Plus.equal(str, 0, str.length(), s, start, limit); } public void append(int c, int cc) { if(lastCC<=cc || cc==0) { str.appendCodePoint(c); lastCC=cc; if(cc<=1) { reorderStart=str.length(); } } else { insert(c, cc); } } // s must be in NFD, otherwise change the implementation. public void append(CharSequence s, int start, int limit, int leadCC, int trailCC) { if(start==limit) { return; } if(lastCC<=leadCC || leadCC==0) { if(trailCC<=1) { reorderStart=str.length()+(limit-start); } else if(leadCC<=1) { reorderStart=str.length()+1; // Ok if not a code point boundary. } str.append(s, start, limit); lastCC=trailCC; } else { int c=Character.codePointAt(s, start); start+=Character.charCount(c); insert(c, leadCC); // insert first code point while(startcc;) {} // insert c at codePointLimit, after the character with prevCC<=cc if(c<=0xffff) { str.insert(codePointLimit, (char)c); if(cc<=1) { reorderStart=codePointLimit+1; } } else { str.insert(codePointLimit, Character.toChars(c)); if(cc<=1) { reorderStart=codePointLimit+2; } } } private final NormalizerImpl impl; private final Appendable app; private final StringBuilder str; private final boolean appIsStringBuilder; private int reorderStart; private int lastCC; // private backward iterator private void setIterator() { codePointStart=str.length(); } private void skipPrevious() { // Requires 0=codePointStart) { return 0; } int c=str.codePointBefore(codePointStart); codePointStart-=Character.charCount(c); return impl.getCCFromYesOrMaybeCP(c); } private int codePointStart, codePointLimit; } // TODO: Propose as public API on the UTF16 class. // TODO: Propose widening UTF16 methods that take char to take int. // TODO: Propose widening UTF16 methods that take String to take CharSequence. public static final class UTF16Plus { /** * Assuming c is a surrogate code point (UTF16.isSurrogate(c)), * is it a lead surrogate? * @param c code unit or code point * @return true or false */ public static boolean isSurrogateLead(int c) { return (c&0x400)==0; } /** * Compares two CharSequence subsequences for binary equality. * @param s1 first sequence * @param start1 start offset in first sequence * @param limit1 limit offset in first sequence * @param s2 second sequence * @param start2 start offset in second sequence * @param limit2 limit offset in second sequence * @return true if s1.subSequence(start1, limit1) contains the same text * as s2.subSequence(start2, limit2) */ public static boolean equal(CharSequence s1, int start1, int limit1, CharSequence s2, int start2, int limit2) { if((limit1-start1)!=(limit2-start2)) { return false; } if(s1==s2 && start1==start2) { return true; } while(start1>DELTA_SHIFT)-MAX_DELTA-1; // Read the normTrie. int offset=inIndexes[IX_NORM_TRIE_OFFSET]; int nextOffset=inIndexes[IX_EXTRA_DATA_OFFSET]; normTrie=Trie2_16.createFromSerialized(bytes); int trieLength=normTrie.getSerializedLength(); if(trieLength>(nextOffset-offset)) { throw new InternalError("Normalizer2 data: not enough bytes for normTrie"); } ICUBinary.skipBytes(bytes, (nextOffset-offset)-trieLength); // skip padding after trie bytes // Read the composition and mapping data. offset=nextOffset; nextOffset=inIndexes[IX_SMALL_FCD_OFFSET]; int numChars=(nextOffset-offset)/2; char[] chars; if(numChars!=0) { chars=new char[numChars]; for(int i=0; i>OFFSET_SHIFT); } // smallFCD: new in formatVersion 2 offset=nextOffset; smallFCD=new byte[0x100]; bytes.get(smallFCD); return this; } catch(IOException e) { throw new InternalError(e); } } public NormalizerImpl load(String name) { return load(ICUBinary.getRequiredData(name)); } public int getNorm16(int c) { return normTrie.get(c); } public boolean isAlgorithmicNoNo(int norm16) { return limitNoNo<=norm16 && norm16=MIN_NORMAL_MAYBE_YES) { return getCCFromNormalYesOrMaybe(norm16); } if(norm16> OFFSET_SHIFT) & 0xff; } public static int getCCFromYesOrMaybe(int norm16) { return norm16>=MIN_NORMAL_MAYBE_YES ? getCCFromNormalYesOrMaybe(norm16) : 0; } public int getCCFromYesOrMaybeCP(int c) { if (c < minCompNoMaybeCP) { return 0; } return getCCFromYesOrMaybe(getNorm16(c)); } /** * Returns the FCD data for code point c. * @param c A Unicode code point. * @return The lccc(c) in bits 15..8 and tccc(c) in bits 7..0. */ public int getFCD16(int c) { if(c>8]; if(bits==0) { return false; } return ((bits>>((lead>>5)&7))&1)!=0; } /** Gets the FCD value from the regular normalization data. */ public int getFCD16FromNormData(int c) { int norm16=getNorm16(c); if (norm16 >= limitNoNo) { if(norm16>=MIN_NORMAL_MAYBE_YES) { // combining mark norm16=getCCFromNormalYesOrMaybe(norm16); return norm16|(norm16<<8); } else if(norm16>=minMaybeYes) { return 0; } else { // isDecompNoAlgorithmic(norm16) int deltaTrailCC = norm16 & DELTA_TCCC_MASK; if (deltaTrailCC <= DELTA_TCCC_1) { return deltaTrailCC >> OFFSET_SHIFT; } // Maps to an isCompYesAndZeroCC. c=mapAlgorithmic(c, norm16); norm16=getNorm16(c); } } if(norm16<=minYesNo || isHangulLVT(norm16)) { // no decomposition or Hangul syllable, all zeros return 0; } // c decomposes, get everything from the variable-length extra data int mapping=norm16>>OFFSET_SHIFT; int firstUnit=extraData.charAt(mapping); int fcd16=firstUnit>>8; // tccc if((firstUnit&MAPPING_HAS_CCC_LCCC_WORD)!=0) { fcd16|=extraData.charAt(mapping-1)&0xff00; // lccc } return fcd16; } /** * Gets the decomposition for one code point. * @param c code point * @return c's decomposition, if it has one; returns null if it does not have a decomposition */ public String getDecomposition(int c) { int norm16; if(c>OFFSET_SHIFT; int length=extraData.charAt(mapping++)&MAPPING_LENGTH_MASK; return extraData.substring(mapping, mapping+length); } // Fixed norm16 values. public static final int MIN_YES_YES_WITH_CC=0xfe02; public static final int JAMO_VT=0xfe00; public static final int MIN_NORMAL_MAYBE_YES=0xfc00; public static final int JAMO_L=2; // offset=1 hasCompBoundaryAfter=FALSE public static final int INERT=1; // offset=0 hasCompBoundaryAfter=TRUE // norm16 bit 0 is comp-boundary-after. public static final int HAS_COMP_BOUNDARY_AFTER=1; public static final int OFFSET_SHIFT=1; // For algorithmic one-way mappings, norm16 bits 2..1 indicate the // tccc (0, 1, >1) for quick FCC boundary-after tests. public static final int DELTA_TCCC_0=0; public static final int DELTA_TCCC_1=2; public static final int DELTA_TCCC_GT_1=4; public static final int DELTA_TCCC_MASK=6; public static final int DELTA_SHIFT=3; public static final int MAX_DELTA=0x40; // Byte offsets from the start of the data, after the generic header. public static final int IX_NORM_TRIE_OFFSET=0; public static final int IX_EXTRA_DATA_OFFSET=1; public static final int IX_SMALL_FCD_OFFSET=2; public static final int IX_RESERVED3_OFFSET=3; public static final int IX_TOTAL_SIZE=7; public static final int MIN_CCC_LCCC_CP=0x300; // Code point thresholds for quick check codes. public static final int IX_MIN_DECOMP_NO_CP=8; public static final int IX_MIN_COMP_NO_MAYBE_CP=9; // Norm16 value thresholds for quick check combinations and types of extra data. /** Mappings & compositions in [minYesNo..minYesNoMappingsOnly[. */ public static final int IX_MIN_YES_NO=10; /** Mappings are comp-normalized. */ public static final int IX_MIN_NO_NO=11; public static final int IX_LIMIT_NO_NO=12; public static final int IX_MIN_MAYBE_YES=13; /** Mappings only in [minYesNoMappingsOnly..minNoNo[. */ public static final int IX_MIN_YES_NO_MAPPINGS_ONLY=14; /** Mappings are not comp-normalized but have a comp boundary before. */ public static final int IX_MIN_NO_NO_COMP_BOUNDARY_BEFORE=15; /** Mappings do not have a comp boundary before. */ public static final int IX_MIN_NO_NO_COMP_NO_MAYBE_CC=16; /** Mappings to the empty string. */ public static final int IX_MIN_NO_NO_EMPTY=17; public static final int IX_MIN_LCCC_CP=18; public static final int IX_COUNT=20; public static final int MAPPING_HAS_CCC_LCCC_WORD=0x80; public static final int MAPPING_HAS_RAW_MAPPING=0x40; // unused bit 0x20; public static final int MAPPING_LENGTH_MASK=0x1f; public static final int COMP_1_LAST_TUPLE=0x8000; public static final int COMP_1_TRIPLE=1; public static final int COMP_1_TRAIL_LIMIT=0x3400; public static final int COMP_1_TRAIL_MASK=0x7ffe; public static final int COMP_1_TRAIL_SHIFT=9; // 10-1 for the "triple" bit public static final int COMP_2_TRAIL_SHIFT=6; public static final int COMP_2_TRAIL_MASK=0xffc0; // higher-level functionality ------------------------------------------ *** /** * Decomposes s[src, limit[ and writes the result to dest. * limit can be NULL if src is NUL-terminated. * destLengthEstimate is the initial dest buffer capacity and can be -1. */ public void decompose(CharSequence s, int src, int limit, StringBuilder dest, int destLengthEstimate) { if(destLengthEstimate<0) { destLengthEstimate=limit-src; } dest.setLength(0); ReorderingBuffer buffer=new ReorderingBuffer(this, dest, destLengthEstimate); decompose(s, src, limit, buffer); } // Dual functionality: // buffer!=NULL: normalize // buffer==NULL: isNormalized/quickCheck/spanQuickCheckYes public int decompose(CharSequence s, int src, int limit, ReorderingBuffer buffer) { int minNoCP=minDecompNoCP; int prevSrc; int c=0; int norm16=0; // only for quick check int prevBoundary=src; int prevCC=0; for(;;) { // count code units below the minimum or with irrelevant data for the quick check for(prevSrc=src; src!=limit;) { if( (c=s.charAt(src))=limit) { break; } c=Character.codePointAt(s, src); cc=getCC(getNorm16(c)); }; buffer.append(s, 0, src, firstCC, prevCC); buffer.append(s, src, limit); } // Very similar to composeQuickCheck(): Make the same changes in both places if relevant. // doCompose: normalize // !doCompose: isNormalized (buffer must be empty and initialized) public boolean compose(CharSequence s, int src, int limit, boolean onlyContiguous, boolean doCompose, ReorderingBuffer buffer) { int prevBoundary=src; int minNoMaybeCP=minCompNoMaybeCP; for (;;) { // Fast path: Scan over a sequence of characters below the minimum "no or maybe" code point, // or with (compYes && ccc==0) properties. int prevSrc; int c = 0; int norm16 = 0; for (;;) { if (src == limit) { if (prevBoundary != limit && doCompose) { buffer.append(s, prevBoundary, limit); } return true; } if( (c=s.charAt(src))=minNoNo. // The current character is either a "noNo" (has a mapping) // or a "maybeYes" (combines backward) // or a "yesYes" with ccc!=0. // It is not a Hangul syllable or Jamo L because those have "yes" properties. // Medium-fast path: Handle cases that do not require full decomposition and recomposition. if (!isMaybeOrNonZeroCC(norm16)) { // minNoNo <= norm16 < minMaybeYes if (!doCompose) { return false; } // Fast path for mapping a character that is immediately surrounded by boundaries. // In this case, we need not decompose around the current character. if (isDecompNoAlgorithmic(norm16)) { // Maps to a single isCompYesAndZeroCC character // which also implies hasCompBoundaryBefore. if (norm16HasCompBoundaryAfter(norm16, onlyContiguous) || hasCompBoundaryBefore(s, src, limit)) { if (prevBoundary != prevSrc) { buffer.append(s, prevBoundary, prevSrc); } buffer.append(mapAlgorithmic(c, norm16), 0); prevBoundary = src; continue; } } else if (norm16 < minNoNoCompBoundaryBefore) { // The mapping is comp-normalized which also implies hasCompBoundaryBefore. if (norm16HasCompBoundaryAfter(norm16, onlyContiguous) || hasCompBoundaryBefore(s, src, limit)) { if (prevBoundary != prevSrc) { buffer.append(s, prevBoundary, prevSrc); } int mapping = norm16 >> OFFSET_SHIFT; int length = extraData.charAt(mapping++) & MAPPING_LENGTH_MASK; buffer.append(extraData, mapping, mapping + length); prevBoundary = src; continue; } } else if (norm16 >= minNoNoEmpty) { // The current character maps to nothing. // Simply omit it from the output if there is a boundary before _or_ after it. // The character itself implies no boundaries. if (hasCompBoundaryBefore(s, src, limit) || hasCompBoundaryAfter(s, prevBoundary, prevSrc, onlyContiguous)) { if (prevBoundary != prevSrc) { buffer.append(s, prevBoundary, prevSrc); } prevBoundary = src; continue; } } // Other "noNo" type, or need to examine more text around this character: // Fall through to the slow path. } else if (isJamoVT(norm16) && prevBoundary != prevSrc) { char prev=s.charAt(prevSrc-1); if(c= 0) { int syllable = Hangul.HANGUL_BASE + (l*Hangul.JAMO_V_COUNT + (c-Hangul.JAMO_V_BASE)) * Hangul.JAMO_T_COUNT + t; --prevSrc; // Replace the Jamo L as well. if (prevBoundary != prevSrc) { buffer.append(s, prevBoundary, prevSrc); } buffer.append((char)syllable); prevBoundary = src; continue; } // If we see L+V+x where x!=T then we drop to the slow path, // decompose and recompose. // This is to deal with NFKC finding normal L and V but a // compatibility variant of a T. // We need to either fully compose that combination here // (which would complicate the code and may not work with strange custom data) // or use the slow path. } } else if (Hangul.isHangulLV(prev)) { // The current character is a Jamo Trailing consonant, // compose with previous Hangul LV that does not contain a Jamo T. if (!doCompose) { return false; } int syllable = prev + c - Hangul.JAMO_T_BASE; --prevSrc; // Replace the Hangul LV as well. if (prevBoundary != prevSrc) { buffer.append(s, prevBoundary, prevSrc); } buffer.append((char)syllable); prevBoundary = src; continue; } // No matching context, or may need to decompose surrounding text first: // Fall through to the slow path. } else if (norm16 > JAMO_VT) { // norm16 >= MIN_YES_YES_WITH_CC // One or more combining marks that do not combine-back: // Check for canonical order, copy unchanged if ok and // if followed by a character with a boundary-before. int cc = getCCFromNormalYesOrMaybe(norm16); // cc!=0 if (onlyContiguous /* FCC */ && getPreviousTrailCC(s, prevBoundary, prevSrc) > cc) { // Fails FCD test, need to decompose and contiguously recompose. if (!doCompose) { return false; } } else { // If !onlyContiguous (not FCC), then we ignore the tccc of // the previous character which passed the quick check "yes && ccc==0" test. int n16; for (;;) { if (src == limit) { if (doCompose) { buffer.append(s, prevBoundary, limit); } return true; } int prevCC = cc; c = Character.codePointAt(s, src); n16 = normTrie.get(c); if (n16 >= MIN_YES_YES_WITH_CC) { cc = getCCFromNormalYesOrMaybe(n16); if (prevCC > cc) { if (!doCompose) { return false; } break; } } else { break; } src += Character.charCount(c); } // p is after the last in-order combining mark. // If there is a boundary here, then we continue with no change. if (norm16HasCompBoundaryBefore(n16)) { if (isCompYesAndZeroCC(n16)) { src += Character.charCount(c); } continue; } // Use the slow path. There is no boundary in [prevSrc, src[. } } // Slow path: Find the nearest boundaries around the current character, // decompose and recompose. if (prevBoundary != prevSrc && !norm16HasCompBoundaryBefore(norm16)) { c = Character.codePointBefore(s, prevSrc); norm16 = normTrie.get(c); if (!norm16HasCompBoundaryAfter(norm16, onlyContiguous)) { prevSrc -= Character.charCount(c); } } if (doCompose && prevBoundary != prevSrc) { buffer.append(s, prevBoundary, prevSrc); } int recomposeStartIndex=buffer.length(); // We know there is not a boundary here. decomposeShort(s, prevSrc, src, false /* !stopAtCompBoundary */, onlyContiguous, buffer); // Decompose until the next boundary. src = decomposeShort(s, src, limit, true /* stopAtCompBoundary */, onlyContiguous, buffer); recompose(buffer, recomposeStartIndex, onlyContiguous); if(!doCompose) { if(!buffer.equals(s, prevSrc, src)) { return false; } buffer.remove(); } prevBoundary=src; } } /** * Very similar to compose(): Make the same changes in both places if relevant. * doSpan: spanQuickCheckYes (ignore bit 0 of the return value) * !doSpan: quickCheck * @return bits 31..1: spanQuickCheckYes (==s.length() if "yes") and * bit 0: set if "maybe"; otherwise, if the span length<s.length() * then the quick check result is "no" */ public int composeQuickCheck(CharSequence s, int src, int limit, boolean onlyContiguous, boolean doSpan) { int qcResult=0; int prevBoundary=src; int minNoMaybeCP=minCompNoMaybeCP; for(;;) { // Fast path: Scan over a sequence of characters below the minimum "no or maybe" code point, // or with (compYes && ccc==0) properties. int prevSrc; int c = 0; int norm16 = 0; for (;;) { if(src==limit) { return (src<<1)|qcResult; // "yes" or "maybe" } if( (c=s.charAt(src))=minNoNo. // The current character is either a "noNo" (has a mapping) // or a "maybeYes" (combines backward) // or a "yesYes" with ccc!=0. // It is not a Hangul syllable or Jamo L because those have "yes" properties. int prevNorm16 = INERT; if (prevBoundary != prevSrc) { prevBoundary = prevSrc; if (!norm16HasCompBoundaryBefore(norm16)) { c = Character.codePointBefore(s, prevSrc); int n16 = getNorm16(c); if (!norm16HasCompBoundaryAfter(n16, onlyContiguous)) { prevBoundary -= Character.charCount(c); prevNorm16 = n16; } } } if(isMaybeOrNonZeroCC(norm16)) { int cc=getCCFromYesOrMaybe(norm16); if (onlyContiguous /* FCC */ && cc != 0 && getTrailCCFromCompYesAndZeroCC(prevNorm16) > cc) { // The [prevBoundary..prevSrc[ character // passed the quick check "yes && ccc==0" test // but is out of canonical order with the current combining mark. } else { // If !onlyContiguous (not FCC), then we ignore the tccc of // the previous character which passed the quick check "yes && ccc==0" test. for (;;) { if (norm16 < MIN_YES_YES_WITH_CC) { if (!doSpan) { qcResult = 1; } else { return prevBoundary << 1; // spanYes does not care to know it's "maybe" } } if (src == limit) { return (src<<1) | qcResult; // "yes" or "maybe" } int prevCC = cc; c = Character.codePointAt(s, src); norm16 = getNorm16(c); if (isMaybeOrNonZeroCC(norm16)) { cc = getCCFromYesOrMaybe(norm16); if (!(prevCC <= cc || cc == 0)) { break; } } else { break; } src += Character.charCount(c); } // src is after the last in-order combining mark. if (isCompYesAndZeroCC(norm16)) { prevBoundary = src; src += Character.charCount(c); continue; } } } return prevBoundary<<1; // "no" } } public void composeAndAppend(CharSequence s, boolean doCompose, boolean onlyContiguous, ReorderingBuffer buffer) { int src=0, limit=s.length(); if(!buffer.isEmpty()) { int firstStarterInSrc=findNextCompBoundary(s, 0, limit, onlyContiguous); if(0!=firstStarterInSrc) { int lastStarterInDest=findPreviousCompBoundary(buffer.getStringBuilder(), buffer.length(), onlyContiguous); StringBuilder middle=new StringBuilder((buffer.length()-lastStarterInDest)+ firstStarterInSrc+16); middle.append(buffer.getStringBuilder(), lastStarterInDest, buffer.length()); buffer.removeSuffix(buffer.length()-lastStarterInDest); middle.append(s, 0, firstStarterInSrc); compose(middle, 0, middle.length(), onlyContiguous, true, buffer); src=firstStarterInSrc; } } if(doCompose) { compose(s, src, limit, onlyContiguous, true, buffer); } else { buffer.append(s, src, limit); } } // Dual functionality: // buffer!=NULL: normalize // buffer==NULL: isNormalized/quickCheck/spanQuickCheckYes public int makeFCD(CharSequence s, int src, int limit, ReorderingBuffer buffer) { // Note: In this function we use buffer->appendZeroCC() because we track // the lead and trail combining classes here, rather than leaving it to // the ReorderingBuffer. // The exception is the call to decomposeShort() which uses the buffer // in the normal way. // Tracks the last FCD-safe boundary, before lccc=0 or after properly-ordered tccc<=1. // Similar to the prevBoundary in the compose() implementation. int prevBoundary=src; int prevSrc; int c=0; int prevFCD16=0; int fcd16=0; for(;;) { // count code units with lccc==0 for(prevSrc=src; src!=limit;) { if((c=s.charAt(src))1) { --prevBoundary; } } } else { int p=src-1; if( Character.isLowSurrogate(s.charAt(p)) && prevSrc

1) { prevBoundary=p; } } if(buffer!=null) { // The last lccc==0 character is excluded from the // flush-and-append call in case it needs to be modified. buffer.flushAndAppendZeroCC(s, prevSrc, prevBoundary); buffer.append(s, prevBoundary, src); } // The start of the current character (c). prevSrc=src; } else if(src==limit) { break; } src+=Character.charCount(c); // The current character (c) at [prevSrc..src[ has a non-zero lead combining class. // Check for proper order, and decompose locally if necessary. if((prevFCD16&0xff)<=(fcd16>>8)) { // proper order: prev tccc <= current lccc if((fcd16&0xff)<=1) { prevBoundary=src; } if(buffer!=null) { buffer.appendZeroCC(c); } prevFCD16=fcd16; continue; } else if(buffer==null) { return prevBoundary; // quick check "no" } else { /* * Back out the part of the source that we copied or appended * already but is now going to be decomposed. * prevSrc is set to after what was copied/appended. */ buffer.removeSuffix(prevSrc-prevBoundary); /* * Find the part of the source that needs to be decomposed, * up to the next safe boundary. */ src=findNextFCDBoundary(s, src, limit); /* * The source text does not fulfill the conditions for FCD. * Decompose and reorder a limited piece of the text. */ decomposeShort(s, prevBoundary, src, false, false, buffer); prevBoundary=src; prevFCD16=0; } } return src; } public boolean hasDecompBoundaryBefore(int c) { return c < minLcccCP || (c <= 0xffff && !singleLeadMightHaveNonZeroFCD16(c)) || norm16HasDecompBoundaryBefore(getNorm16(c)); } public boolean norm16HasDecompBoundaryBefore(int norm16) { if (norm16 < minNoNoCompNoMaybeCC) { return true; } if (norm16 >= limitNoNo) { return norm16 <= MIN_NORMAL_MAYBE_YES || norm16 == JAMO_VT; } // c decomposes, get everything from the variable-length extra data int mapping=norm16>>OFFSET_SHIFT; int firstUnit=extraData.charAt(mapping); // true if leadCC==0 (hasFCDBoundaryBefore()) return (firstUnit&MAPPING_HAS_CCC_LCCC_WORD)==0 || (extraData.charAt(mapping-1)&0xff00)==0; } public boolean hasDecompBoundaryAfter(int c) { if (c < minDecompNoCP) { return true; } if (c <= 0xffff && !singleLeadMightHaveNonZeroFCD16(c)) { return true; } return norm16HasDecompBoundaryAfter(getNorm16(c)); } public boolean norm16HasDecompBoundaryAfter(int norm16) { if(norm16 <= minYesNo || isHangulLVT(norm16)) { return true; } if (norm16 >= limitNoNo) { if (isMaybeOrNonZeroCC(norm16)) { return norm16 <= MIN_NORMAL_MAYBE_YES || norm16 == JAMO_VT; } // Maps to an isCompYesAndZeroCC. return (norm16 & DELTA_TCCC_MASK) <= DELTA_TCCC_1; } // c decomposes, get everything from the variable-length extra data int mapping=norm16>>OFFSET_SHIFT; int firstUnit=extraData.charAt(mapping); // decomp after-boundary: same as hasFCDBoundaryAfter(), // fcd16<=1 || trailCC==0 if(firstUnit>0x1ff) { return false; // trailCC>1 } if(firstUnit<=0xff) { return true; // trailCC==0 } // if(trailCC==1) test leadCC==0, same as checking for before-boundary // true if leadCC==0 (hasFCDBoundaryBefore()) return (firstUnit&MAPPING_HAS_CCC_LCCC_WORD)==0 || (extraData.charAt(mapping-1)&0xff00)==0; } public boolean isDecompInert(int c) { return isDecompYesAndZeroCC(getNorm16(c)); } public boolean hasCompBoundaryBefore(int c) { return c=minMaybeYes; } private static boolean isInert(int norm16) { return norm16==INERT; } private static boolean isJamoVT(int norm16) { return norm16==JAMO_VT; } private int hangulLVT() { return minYesNoMappingsOnly|HAS_COMP_BOUNDARY_AFTER; } private boolean isHangulLV(int norm16) { return norm16==minYesNo; } private boolean isHangulLVT(int norm16) { return norm16==hangulLVT(); } private boolean isCompYesAndZeroCC(int norm16) { return norm16=MIN_YES_YES_WITH_CC || norm16=limitNoNo; } // For use with isCompYes(). // Perhaps the compiler can combine the two tests for MIN_YES_YES_WITH_CC. // static uint8_t getCCFromYes(uint16_t norm16) { // return norm16>=MIN_YES_YES_WITH_CC ? getCCFromNormalYesOrMaybe(norm16) : 0; // } private int getCCFromNoNo(int norm16) { int mapping=norm16>>OFFSET_SHIFT; if((extraData.charAt(mapping)&MAPPING_HAS_CCC_LCCC_WORD)!=0) { return extraData.charAt(mapping-1)&0xff; } else { return 0; } } int getTrailCCFromCompYesAndZeroCC(int norm16) { if(norm16<=minYesNo) { return 0; // yesYes and Hangul LV have ccc=tccc=0 } else { // For Hangul LVT we harmlessly fetch a firstUnit with tccc=0 here. return extraData.charAt(norm16>>OFFSET_SHIFT)>>8; // tccc from yesNo } } // Requires algorithmic-NoNo. private int mapAlgorithmic(int c, int norm16) { return c+(norm16>>DELTA_SHIFT)-centerNoNoDelta; } // Requires minYesNo>OFFSET_SHIFT); } /** * @return index into maybeYesCompositions, or -1 */ private int getCompositionsListForDecompYes(int norm16) { if(norm16>OFFSET_SHIFT; } } /** * @return index into maybeYesCompositions */ private int getCompositionsListForComposite(int norm16) { // A composite has both mapping & compositions list. int list=((MIN_NORMAL_MAYBE_YES-minMaybeYes)+norm16)>>OFFSET_SHIFT; int firstUnit=maybeYesCompositions.charAt(list); return list+ // mapping in maybeYesCompositions 1+ // +1 to skip the first unit with the mapping length (firstUnit&MAPPING_LENGTH_MASK); // + mapping length } // Decompose a short piece of text which is likely to contain characters that // fail the quick check loop and/or where the quick check loop's overhead // is unlikely to be amortized. // Called by the compose() and makeFCD() implementations. // Public in Java for collation implementation code. private int decomposeShort( CharSequence s, int src, int limit, boolean stopAtCompBoundary, boolean onlyContiguous, ReorderingBuffer buffer) { while(src= limitNoNo) { if (isMaybeOrNonZeroCC(norm16)) { buffer.append(c, getCCFromYesOrMaybe(norm16)); return; } // Maps to an isCompYesAndZeroCC. c=mapAlgorithmic(c, norm16); norm16=getNorm16(c); } if (norm16 < minYesNo) { // c does not decompose buffer.append(c, 0); } else if(isHangulLV(norm16) || isHangulLVT(norm16)) { // Hangul syllable: decompose algorithmically Hangul.decompose(c, buffer); } else { // c decomposes, get everything from the variable-length extra data int mapping=norm16>>OFFSET_SHIFT; int firstUnit=extraData.charAt(mapping); int length=firstUnit&MAPPING_LENGTH_MASK; int leadCC, trailCC; trailCC=firstUnit>>8; if((firstUnit&MAPPING_HAS_CCC_LCCC_WORD)!=0) { leadCC=extraData.charAt(mapping-1)>>8; } else { leadCC=0; } ++mapping; // skip over the firstUnit buffer.append(extraData, mapping, mapping+length, leadCC, trailCC); } } /** * Finds the recomposition result for * a forward-combining "lead" character, * specified with a pointer to its compositions list, * and a backward-combining "trail" character. * *

If the lead and trail characters combine, then this function returns * the following "compositeAndFwd" value: *

     * Bits 21..1  composite character
     * Bit      0  set if the composite is a forward-combining starter
     *

* otherwise it returns -1. * *

The compositions list has (trail, compositeAndFwd) pair entries, * encoded as either pairs or triples of 16-bit units. * The last entry has the high bit of its first unit set. * *

The list is sorted by ascending trail characters (there are no duplicates). * A linear search is used. * *

See normalizer2impl.h for a more detailed description * of the compositions list format. */ private static int combine(String compositions, int list, int trail) { int key1, firstUnit; if(trail(firstUnit=compositions.charAt(list))) { list+=2+(firstUnit&COMP_1_TRIPLE); } if(key1==(firstUnit&COMP_1_TRAIL_MASK)) { if((firstUnit&COMP_1_TRIPLE)!=0) { return (compositions.charAt(list+1)<<16)|compositions.charAt(list+2); } else { return compositions.charAt(list+1); } } } else { // trail character is 3400..10FFFF // result entry has 3 units key1=COMP_1_TRAIL_LIMIT+(((trail>>COMP_1_TRAIL_SHIFT))&~COMP_1_TRIPLE); int key2=(trail<(firstUnit=compositions.charAt(list))) { list+=2+(firstUnit&COMP_1_TRIPLE); } else if(key1==(firstUnit&COMP_1_TRAIL_MASK)) { if(key2>(secondUnit=compositions.charAt(list+1))) { if((firstUnit&COMP_1_LAST_TUPLE)!=0) { break; } else { list+=3; } } else if(key2==(secondUnit&COMP_2_TRAIL_MASK)) { return ((secondUnit&~COMP_2_TRAIL_MASK)<<16)|compositions.charAt(list+2); } else { break; } } else { break; } } } return -1; } /* * Recomposes the buffer text starting at recomposeStartIndex * (which is in NFD - decomposed and canonically ordered), * and truncates the buffer contents. * * Note that recomposition never lengthens the text: * Any character consists of either one or two code units; * a composition may contain at most one more code unit than the original starter, * while the combining mark that is removed has at least one code unit. */ private void recompose(ReorderingBuffer buffer, int recomposeStartIndex, boolean onlyContiguous) { StringBuilder sb=buffer.getStringBuilder(); int p=recomposeStartIndex; if(p==sb.length()) { return; } int starter, pRemove; int compositionsList; int c, compositeAndFwd; int norm16; int cc, prevCC; boolean starterIsSupplementary; // Some of the following variables are not used until we have a forward-combining starter // and are only initialized now to avoid compiler warnings. compositionsList=-1; // used as indicator for whether we have a forward-combining starter starter=-1; starterIsSupplementary=false; prevCC=0; for(;;) { c=sb.codePointAt(p); p+=Character.charCount(c); norm16=getNorm16(c); cc=getCCFromYesOrMaybe(norm16); if( // this character combines backward and isMaybe(norm16) && // we have seen a starter that combines forward and compositionsList>=0 && // the backward-combining character is not blocked (prevCC=0) { // The starter and the combining mark (c) do combine. int composite=compositeAndFwd>>1; // Remove the combining mark. pRemove=p-Character.charCount(c); // pRemove & p: start & limit of the combining mark sb.delete(pRemove, p); p=pRemove; // Replace the starter with the composite. if(starterIsSupplementary) { if(composite>0xffff) { // both are supplementary sb.setCharAt(starter, UTF16.getLeadSurrogate(composite)); sb.setCharAt(starter+1, UTF16.getTrailSurrogate(composite)); } else { sb.setCharAt(starter, (char)c); sb.deleteCharAt(starter+1); // The composite is shorter than the starter, // move the intermediate characters forward one. starterIsSupplementary=false; --p; } } else if(composite>0xffff) { // The composite is longer than the starter, // move the intermediate characters back one. starterIsSupplementary=true; sb.setCharAt(starter, UTF16.getLeadSurrogate(composite)); sb.insert(starter+1, UTF16.getTrailSurrogate(composite)); ++p; } else { // both are on the BMP sb.setCharAt(starter, (char)composite); } // Keep prevCC because we removed the combining mark. if(p==sb.length()) { break; } // Is the composite a starter that combines forward? if((compositeAndFwd&1)!=0) { compositionsList= getCompositionsListForComposite(getNorm16(composite)); } else { compositionsList=-1; } // We combined; continue with looking for compositions. continue; } } // no combination this time prevCC=cc; if(p==sb.length()) { break; } // If c did not combine, then check if it is a starter. if(cc==0) { // Found a new starter. if((compositionsList=getCompositionsListForDecompYes(norm16))>=0) { // It may combine with something, prepare for it. if(c<=0xffff) { starterIsSupplementary=false; starter=p-1; } else { starterIsSupplementary=true; starter=p-2; } } } else if(onlyContiguous) { // FCC: no discontiguous compositions; any intervening character blocks. compositionsList=-1; } } buffer.flush(); } /** * Does c have a composition boundary before it? * True if its decomposition begins with a character that has * ccc=0 && NFC_QC=Yes (isCompYesAndZeroCC()). * As a shortcut, this is true if c itself has ccc=0 && NFC_QC=Yes * (isCompYesAndZeroCC()) so we need not decompose. */ private boolean hasCompBoundaryBefore(int c, int norm16) { return c> OFFSET_SHIFT) <= 0x1ff); } private int findPreviousCompBoundary(CharSequence s, int p, boolean onlyContiguous) { while(p>0) { int c=Character.codePointBefore(s, p); int norm16 = getNorm16(c); if (norm16HasCompBoundaryAfter(norm16, onlyContiguous)) { break; } p-=Character.charCount(c); if(hasCompBoundaryBefore(c, norm16)) { break; } } return p; } private int findNextCompBoundary(CharSequence s, int p, int limit, boolean onlyContiguous) { while(p= 0x0009 && c <= 0x000D) || (c >= 0x0020 && c <= 0x002F) || (c >= 0x003A && c <= 0x0040) || (c >= 0x005B && c <= 0x0060) || (c >= 0x007B && c <= 0x007E); } public static String canonicalDecomposeWithSingleQuotation(String string) { Normalizer2 impl = Normalizer2.getNFDInstance(); char[] src = string.toCharArray(); int srcIndex = 0; int srcLimit = src.length; char[] dest = new char[src.length * 3]; //MAX_BUF_SIZE_DECOMPOSE = 3 int destIndex = 0; int destLimit = dest.length; int prevSrc; String norm; int reorderStartIndex, length; char c1, c2; int cp; int minNoMaybe = 0x00c0; int cc, prevCC, trailCC; char[] p; int pStart; // initialize reorderStartIndex = 0; prevCC = 0; norm = null; cp = 0; pStart = 0; cc = trailCC = -1; // initialize to bogus value c1 = 0; for (;;) { prevSrc=srcIndex; //quick check (1)less than minNoMaybe (2)no decomp (3)hangual while (srcIndex != srcLimit && ((c1 = src[srcIndex]) < minNoMaybe || (norm = impl.getDecomposition(cp = string.codePointAt(srcIndex))) == null || (c1 >= '\uac00' && c1 <= '\ud7a3'))) { // Hangul Syllables prevCC = 0; srcIndex += (cp < 0x10000) ? 1 : 2; } // copy these code units all at once if (srcIndex != prevSrc) { length = srcIndex - prevSrc; if ((destIndex + length) <= destLimit) { System.arraycopy(src,prevSrc,dest,destIndex,length); } destIndex += length; reorderStartIndex = destIndex; } // end of source reached? if (srcIndex == srcLimit) { break; } // cp already contains *src and norm32 is set for it, increment src srcIndex += (cp < 0x10000) ? 1 : 2; if (cp < Character.MIN_SUPPLEMENTARY_CODE_POINT) { c2 = 0; length = 1; if (Character.isHighSurrogate(c1) || Character.isLowSurrogate(c1)) { norm = null; } } else { length = 2; c2 = src[srcIndex-1]; } // get the decomposition and the lead and trail cc's if (norm == null) { // cp does not decompose cc = trailCC = UCharacter.getCombiningClass(cp); p = null; pStart = -1; } else { pStart = 0; p = norm.toCharArray(); length = p.length; int cpNum = norm.codePointCount(0, length); cc= UCharacter.getCombiningClass(norm.codePointAt(0)); trailCC= UCharacter.getCombiningClass(norm.codePointAt(cpNum-1)); if (length == 1) { // fastpath a single code unit from decomposition c1 = p[pStart]; c2 = 0; p = null; pStart = -1; } } if((destIndex + length * 3) >= destLimit) { // 2 SingleQuotations // buffer overflow char[] tmpBuf = new char[destLimit * 2]; System.arraycopy(dest, 0, tmpBuf, 0, destIndex); dest = tmpBuf; destLimit = dest.length; } // append the decomposition to the destination buffer, assume length>0 { int reorderSplit = destIndex; if (p == null) { // fastpath: single code point if (needSingleQuotation(c1)) { //if we need single quotation, no need to consider "prevCC" //and it must NOT be a supplementary pair dest[destIndex++] = '\''; dest[destIndex++] = c1; dest[destIndex++] = '\''; trailCC = 0; } else if(cc != 0 && cc < prevCC) { // (c1, c2) is out of order with respect to the preceding // text destIndex += length; trailCC = insertOrdered(dest, reorderStartIndex, reorderSplit, destIndex, c1, c2, cc); } else { // just append (c1, c2) dest[destIndex++] = c1; if(c2 != 0) { dest[destIndex++] = c2; } } } else { // general: multiple code points (ordered by themselves) // from decomposition if (needSingleQuotation(p[pStart])) { dest[destIndex++] = '\''; dest[destIndex++] = p[pStart++]; dest[destIndex++] = '\''; length--; do { dest[destIndex++] = p[pStart++]; } while(--length > 0); } else if (cc != 0 && cc < prevCC) { destIndex += length; trailCC = mergeOrdered(dest, reorderStartIndex, reorderSplit, p, pStart, pStart+length); } else { // just append the decomposition do { dest[destIndex++] = p[pStart++]; } while (--length > 0); } } } prevCC = trailCC; if(prevCC == 0) { reorderStartIndex = destIndex; } } return new String(dest, 0, destIndex); } /** * simpler, single-character version of mergeOrdered() - * bubble-insert one single code point into the preceding string * which is already canonically ordered * (c, c2) may or may not yet have been inserted at src[current]..src[p] * * it must be p=current+lengthof(c, c2) i.e. p=current+(c2==0 ? 1 : 2) * * before: src[start]..src[current] is already ordered, and * src[current]..src[p] may or may not hold (c, c2) but * must be exactly the same length as (c, c2) * after: src[start]..src[p] is ordered * * @return the trailing combining class */ private static int/*unsigned byte*/ insertOrdered(char[] source, int start, int current, int p, char c1, char c2, int/*unsigned byte*/ cc) { int back, preBack; int r; int prevCC, trailCC=cc; if (start=prevCC preBack=back=current; PrevArgs prevArgs = new PrevArgs(); prevArgs.current = current; prevArgs.start = start; prevArgs.src = source; prevArgs.c1 = c1; prevArgs.c2 = c2; // get the prevCC prevCC=getPrevCC(prevArgs); preBack = prevArgs.current; if(cc=prevCC) { break; } back=preBack; } // this is where we are right now with all these indicies: // [start]..[pPreBack] 0..? code points that we can ignore // [pPreBack]..[pBack] 0..1 code points with prevCC<=cc // [pBack]..[current] 0..n code points with >cc, move up to insert (c, c2) // [current]..[p] 1 code point (c, c2) with cc // move the code units in between up r=p; do { source[--r]=source[--current]; } while (back!=current); } } // insert (c1, c2) source[current] = c1; if (c2!=0) { source[(current+1)] = c2; } // we know the cc of the last code point return trailCC; } /** * merge two UTF-16 string parts together * to canonically order (order by combining classes) their concatenation * * the two strings may already be adjacent, so that the merging is done * in-place if the two strings are not adjacent, then the buffer holding the * first one must be large enough * the second string may or may not be ordered in itself * * before: [start]..[current] is already ordered, and * [next]..[limit] may be ordered in itself, but * is not in relation to [start..current[ * after: [start..current+(limit-next)[ is ordered * * the algorithm is a simple bubble-sort that takes the characters from * src[next++] and inserts them in correct combining class order into the * preceding part of the string * * since this function is called much less often than the single-code point * insertOrdered(), it just uses that for easier maintenance * * @return the trailing combining class */ private static int /*unsigned byte*/ mergeOrdered(char[] source, int start, int current, char[] data, int next, int limit) { int r; int /*unsigned byte*/ cc, trailCC=0; boolean adjacent; adjacent= current==next; NextCCArgs ncArgs = new NextCCArgs(); ncArgs.source = data; ncArgs.next = next; ncArgs.limit = limit; if(start!=current) { while(ncArgs.next