/* * 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. */ /* * $Id: FastStringBuffer.java 469279 2006-10-30 21:18:02Z minchau $ */ package org.apache.xml.utils; /** * Bare-bones, unsafe, fast string buffer. No thread-safety, no * parameter range checking, exposed fields. Note that in typical * applications, thread-safety of a StringBuffer is a somewhat * dubious concept in any case. *

* Note that Stree and DTM used a single FastStringBuffer as a string pool, * by recording start and length indices within this single buffer. This * minimizes heap overhead, but of course requires more work when retrieving * the data. *

* FastStringBuffer operates as a "chunked buffer". Doing so * reduces the need to recopy existing information when an append * exceeds the space available; we just allocate another chunk and * flow across to it. (The array of chunks may need to grow, * admittedly, but that's a much smaller object.) Some excess * recopying may arise when we extract Strings which cross chunk * boundaries; larger chunks make that less frequent. *

* The size values are parameterized, to allow tuning this code. In * theory, Result Tree Fragments might want to be tuned differently * from the main document's text. *

* %REVIEW% An experiment in self-tuning is * included in the code (using nested FastStringBuffers to achieve * variation in chunk sizes), but this implementation has proven to * be problematic when data may be being copied from the FSB into itself. * We should either re-architect that to make this safe (if possible) * or remove that code and clean up for performance/maintainability reasons. *

*/ public class FastStringBuffer { // If nonzero, forces the inial chunk size. /**/static final int DEBUG_FORCE_INIT_BITS=0; // %BUG% %REVIEW% *****PROBLEM SUSPECTED: If data from an FSB is being copied // back into the same FSB (variable set from previous variable, for example) // and blocksize changes in mid-copy... there's risk of severe malfunction in // the read process, due to how the resizing code re-jiggers storage. Arggh. // If we want to retain the variable-size-block feature, we need to reconsider // that issue. For now, I have forced us into fixed-size mode. static final boolean DEBUG_FORCE_FIXED_CHUNKSIZE=true; /** Manifest constant: Suppress leading whitespace. * This should be used when normalize-to-SAX is called for the first chunk of a * multi-chunk output, or one following unsuppressed whitespace in a previous * chunk. * @see #sendNormalizedSAXcharacters(org.xml.sax.ContentHandler,int,int) */ public static final int SUPPRESS_LEADING_WS=0x01; /** Manifest constant: Suppress trailing whitespace. * This should be used when normalize-to-SAX is called for the last chunk of a * multi-chunk output; it may have to be or'ed with SUPPRESS_LEADING_WS. */ public static final int SUPPRESS_TRAILING_WS=0x02; /** Manifest constant: Suppress both leading and trailing whitespace. * This should be used when normalize-to-SAX is called for a complete string. * (I'm not wild about the name of this one. Ideas welcome.) * @see #sendNormalizedSAXcharacters(org.xml.sax.ContentHandler,int,int) */ public static final int SUPPRESS_BOTH = SUPPRESS_LEADING_WS | SUPPRESS_TRAILING_WS; /** Manifest constant: Carry trailing whitespace of one chunk as leading * whitespace of the next chunk. Used internally; I don't see any reason * to make it public right now. */ private static final int CARRY_WS=0x04; /** * Field m_chunkBits sets our chunking strategy, by saying how many * bits of index can be used within a single chunk before flowing over * to the next chunk. For example, if m_chunkbits is set to 15, each * chunk can contain up to 2^15 (32K) characters */ int m_chunkBits = 15; /** * Field m_maxChunkBits affects our chunk-growth strategy, by saying what * the largest permissible chunk size is in this particular FastStringBuffer * hierarchy. */ int m_maxChunkBits = 15; /** * Field m_rechunkBits affects our chunk-growth strategy, by saying how * many chunks should be allocated at one size before we encapsulate them * into the first chunk of the next size up. For example, if m_rechunkBits * is set to 3, then after 8 chunks at a given size we will rebundle * them as the first element of a FastStringBuffer using a chunk size * 8 times larger (chunkBits shifted left three bits). */ int m_rebundleBits = 2; /** * Field m_chunkSize establishes the maximum size of one chunk of the array * as 2**chunkbits characters. * (Which may also be the minimum size if we aren't tuning for storage) */ int m_chunkSize; // =1<<(m_chunkBits-1); /** * Field m_chunkMask is m_chunkSize-1 -- in other words, m_chunkBits * worth of low-order '1' bits, useful for shift-and-mask addressing * within the chunks. */ int m_chunkMask; // =m_chunkSize-1; /** * Field m_array holds the string buffer's text contents, using an * array-of-arrays. Note that this array, and the arrays it contains, may be * reallocated when necessary in order to allow the buffer to grow; * references to them should be considered to be invalidated after any * append. However, the only time these arrays are directly exposed * is in the sendSAXcharacters call. */ char[][] m_array; /** * Field m_lastChunk is an index into m_array[], pointing to the last * chunk of the Chunked Array currently in use. Note that additional * chunks may actually be allocated, eg if the FastStringBuffer had * previously been truncated or if someone issued an ensureSpace request. *

* The insertion point for append operations is addressed by the combination * of m_lastChunk and m_firstFree. */ int m_lastChunk = 0; /** * Field m_firstFree is an index into m_array[m_lastChunk][], pointing to * the first character in the Chunked Array which is not part of the * FastStringBuffer's current content. Since m_array[][] is zero-based, * the length of that content can be calculated as * (m_lastChunk< * For coding convenience, I've expressed both allocation sizes in terms of * a number of bits. That's needed for the final size of a chunk, * to permit fast and efficient shift-and-mask addressing. It's less critical * for the inital size, and may be reconsidered. *

* An alternative would be to accept integer sizes and round to powers of two; * that really doesn't seem to buy us much, if anything. * * @param initChunkBits Length in characters of the initial allocation * of a chunk, expressed in log-base-2. (That is, 10 means allocate 1024 * characters.) Later chunks will use larger allocation units, to trade off * allocation speed of large document against storage efficiency of small * ones. * @param maxChunkBits Number of character-offset bits that should be used for * addressing within a chunk. Maximum length of a chunk is 2^chunkBits * characters. * @param rebundleBits Number of character-offset bits that addressing should * advance before we attempt to take a step from initChunkBits to maxChunkBits */ public FastStringBuffer(int initChunkBits, int maxChunkBits, int rebundleBits) { if(DEBUG_FORCE_INIT_BITS!=0) initChunkBits=DEBUG_FORCE_INIT_BITS; // %REVIEW% // Should this force to larger value, or smaller? Smaller less efficient, but if // someone requested variable mode it's because they care about storage space. // On the other hand, given the other changes I'm making, odds are that we should // adopt the larger size. Dither, dither, dither... This is just stopgap workaround // anyway; we need a permanant solution. // if(DEBUG_FORCE_FIXED_CHUNKSIZE) maxChunkBits=initChunkBits; //if(DEBUG_FORCE_FIXED_CHUNKSIZE) initChunkBits=maxChunkBits; m_array = new char[16][]; // Don't bite off more than we're prepared to swallow! if (initChunkBits > maxChunkBits) initChunkBits = maxChunkBits; m_chunkBits = initChunkBits; m_maxChunkBits = maxChunkBits; m_rebundleBits = rebundleBits; m_chunkSize = 1 << (initChunkBits); m_chunkMask = m_chunkSize - 1; m_array[0] = new char[m_chunkSize]; } /** * Construct a FastStringBuffer, using a default rebundleBits value. * * NEEDSDOC @param initChunkBits * NEEDSDOC @param maxChunkBits */ public FastStringBuffer(int initChunkBits, int maxChunkBits) { this(initChunkBits, maxChunkBits, 2); } /** * Construct a FastStringBuffer, using default maxChunkBits and * rebundleBits values. *

* ISSUE: Should this call assert initial size, or fixed size? * Now configured as initial, with a default for fixed. * * NEEDSDOC @param initChunkBits */ public FastStringBuffer(int initChunkBits) { this(initChunkBits, 15, 2); } /** * Construct a FastStringBuffer, using a default allocation policy. */ public FastStringBuffer() { // 10 bits is 1K. 15 bits is 32K. Remember that these are character // counts, so actual memory allocation unit is doubled for UTF-16 chars. // // For reference: In the original FastStringBuffer, we simply // overallocated by blocksize (default 1KB) on each buffer-growth. this(10, 15, 2); } /** * Get the length of the list. Synonym for length(). * * @return the number of characters in the FastStringBuffer's content. */ public final int size() { return (m_lastChunk << m_chunkBits) + m_firstFree; } /** * Get the length of the list. Synonym for size(). * * @return the number of characters in the FastStringBuffer's content. */ public final int length() { return (m_lastChunk << m_chunkBits) + m_firstFree; } /** * Discard the content of the FastStringBuffer, and most of the memory * that was allocated by it, restoring the initial state. Note that this * may eventually be different from setLength(0), which see. */ public final void reset() { m_lastChunk = 0; m_firstFree = 0; // Recover the original chunk size FastStringBuffer innermost = this; while (innermost.m_innerFSB != null) { innermost = innermost.m_innerFSB; } m_chunkBits = innermost.m_chunkBits; m_chunkSize = innermost.m_chunkSize; m_chunkMask = innermost.m_chunkMask; // Discard the hierarchy m_innerFSB = null; m_array = new char[16][0]; m_array[0] = new char[m_chunkSize]; } /** * Directly set how much of the FastStringBuffer's storage is to be * considered part of its content. This is a fast but hazardous * operation. It is not protected against negative values, or values * greater than the amount of storage currently available... and even * if additional storage does exist, its contents are unpredictable. * The only safe use for our setLength() is to truncate the FastStringBuffer * to a shorter string. * * @param l New length. If l<0 or l>=getLength(), this operation will * not report an error but future operations will almost certainly fail. */ public final void setLength(int l) { m_lastChunk = l >>> m_chunkBits; if (m_lastChunk == 0 && m_innerFSB != null) { // Replace this FSB with the appropriate inner FSB, truncated m_innerFSB.setLength(l, this); } else { m_firstFree = l & m_chunkMask; // There's an edge case if l is an exact multiple of m_chunkBits, which risks leaving // us pointing at the start of a chunk which has not yet been allocated. Rather than // pay the cost of dealing with that in the append loops (more scattered and more // inner-loop), we correct it here by moving to the safe side of that // line -- as we would have left the indexes had we appended up to that point. if(m_firstFree==0 && m_lastChunk>0) { --m_lastChunk; m_firstFree=m_chunkSize; } } } /** * Subroutine for the public setLength() method. Deals with the fact * that truncation may require restoring one of the innerFSBs * * NEEDSDOC @param l * NEEDSDOC @param rootFSB */ private final void setLength(int l, FastStringBuffer rootFSB) { m_lastChunk = l >>> m_chunkBits; if (m_lastChunk == 0 && m_innerFSB != null) { m_innerFSB.setLength(l, rootFSB); } else { // Undo encapsulation -- pop the innerFSB data back up to root. // Inefficient, but attempts to keep the code simple. rootFSB.m_chunkBits = m_chunkBits; rootFSB.m_maxChunkBits = m_maxChunkBits; rootFSB.m_rebundleBits = m_rebundleBits; rootFSB.m_chunkSize = m_chunkSize; rootFSB.m_chunkMask = m_chunkMask; rootFSB.m_array = m_array; rootFSB.m_innerFSB = m_innerFSB; rootFSB.m_lastChunk = m_lastChunk; // Finally, truncate this sucker. rootFSB.m_firstFree = l & m_chunkMask; } } /** * Note that this operation has been somewhat deoptimized by the shift to a * chunked array, as there is no factory method to produce a String object * directly from an array of arrays and hence a double copy is needed. * By using ensureCapacity we hope to minimize the heap overhead of building * the intermediate StringBuffer. *

* (It really is a pity that Java didn't design String as a final subclass * of MutableString, rather than having StringBuffer be a separate hierarchy. * We'd avoid a lot of double-buffering.) * * @return the contents of the FastStringBuffer as a standard Java string. */ public final String toString() { int length = (m_lastChunk << m_chunkBits) + m_firstFree; return getString(new StringBuffer(length), 0, 0, length).toString(); } /** * Append a single character onto the FastStringBuffer, growing the * storage if necessary. *

* NOTE THAT after calling append(), previously obtained * references to m_array[][] may no longer be valid.... * though in fact they should be in this instance. * * @param value character to be appended. */ public final void append(char value) { char[] chunk; // We may have preallocated chunks. If so, all but last should // be at full size. if (m_firstFree < m_chunkSize) // Simplified test single-character-fits chunk = m_array[m_lastChunk]; else { // Extend array? int i = m_array.length; if (m_lastChunk + 1 == i) { char[][] newarray = new char[i + 16][]; System.arraycopy(m_array, 0, newarray, 0, i); m_array = newarray; } // Advance one chunk chunk = m_array[++m_lastChunk]; if (chunk == null) { // Hierarchical encapsulation if (m_lastChunk == 1 << m_rebundleBits && m_chunkBits < m_maxChunkBits) { // Should do all the work of both encapsulating // existing data and establishing new sizes/offsets m_innerFSB = new FastStringBuffer(this); } // Add a chunk. chunk = m_array[m_lastChunk] = new char[m_chunkSize]; } m_firstFree = 0; } // Space exists in the chunk. Append the character. chunk[m_firstFree++] = value; } /** * Append the contents of a String onto the FastStringBuffer, * growing the storage if necessary. *

* NOTE THAT after calling append(), previously obtained * references to m_array[] may no longer be valid. * * @param value String whose contents are to be appended. */ public final void append(String value) { if (value == null) return; int strlen = value.length(); if (0 == strlen) return; int copyfrom = 0; char[] chunk = m_array[m_lastChunk]; int available = m_chunkSize - m_firstFree; // Repeat while data remains to be copied while (strlen > 0) { // Copy what fits if (available > strlen) available = strlen; value.getChars(copyfrom, copyfrom + available, m_array[m_lastChunk], m_firstFree); strlen -= available; copyfrom += available; // If there's more left, allocate another chunk and continue if (strlen > 0) { // Extend array? int i = m_array.length; if (m_lastChunk + 1 == i) { char[][] newarray = new char[i + 16][]; System.arraycopy(m_array, 0, newarray, 0, i); m_array = newarray; } // Advance one chunk chunk = m_array[++m_lastChunk]; if (chunk == null) { // Hierarchical encapsulation if (m_lastChunk == 1 << m_rebundleBits && m_chunkBits < m_maxChunkBits) { // Should do all the work of both encapsulating // existing data and establishing new sizes/offsets m_innerFSB = new FastStringBuffer(this); } // Add a chunk. chunk = m_array[m_lastChunk] = new char[m_chunkSize]; } available = m_chunkSize; m_firstFree = 0; } } // Adjust the insert point in the last chunk, when we've reached it. m_firstFree += available; } /** * Append the contents of a StringBuffer onto the FastStringBuffer, * growing the storage if necessary. *

* NOTE THAT after calling append(), previously obtained * references to m_array[] may no longer be valid. * * @param value StringBuffer whose contents are to be appended. */ public final void append(StringBuffer value) { if (value == null) return; int strlen = value.length(); if (0 == strlen) return; int copyfrom = 0; char[] chunk = m_array[m_lastChunk]; int available = m_chunkSize - m_firstFree; // Repeat while data remains to be copied while (strlen > 0) { // Copy what fits if (available > strlen) available = strlen; value.getChars(copyfrom, copyfrom + available, m_array[m_lastChunk], m_firstFree); strlen -= available; copyfrom += available; // If there's more left, allocate another chunk and continue if (strlen > 0) { // Extend array? int i = m_array.length; if (m_lastChunk + 1 == i) { char[][] newarray = new char[i + 16][]; System.arraycopy(m_array, 0, newarray, 0, i); m_array = newarray; } // Advance one chunk chunk = m_array[++m_lastChunk]; if (chunk == null) { // Hierarchical encapsulation if (m_lastChunk == 1 << m_rebundleBits && m_chunkBits < m_maxChunkBits) { // Should do all the work of both encapsulating // existing data and establishing new sizes/offsets m_innerFSB = new FastStringBuffer(this); } // Add a chunk. chunk = m_array[m_lastChunk] = new char[m_chunkSize]; } available = m_chunkSize; m_firstFree = 0; } } // Adjust the insert point in the last chunk, when we've reached it. m_firstFree += available; } /** * Append part of the contents of a Character Array onto the * FastStringBuffer, growing the storage if necessary. *

* NOTE THAT after calling append(), previously obtained * references to m_array[] may no longer be valid. * * @param chars character array from which data is to be copied * @param start offset in chars of first character to be copied, * zero-based. * @param length number of characters to be copied */ public final void append(char[] chars, int start, int length) { int strlen = length; if (0 == strlen) return; int copyfrom = start; char[] chunk = m_array[m_lastChunk]; int available = m_chunkSize - m_firstFree; // Repeat while data remains to be copied while (strlen > 0) { // Copy what fits if (available > strlen) available = strlen; System.arraycopy(chars, copyfrom, m_array[m_lastChunk], m_firstFree, available); strlen -= available; copyfrom += available; // If there's more left, allocate another chunk and continue if (strlen > 0) { // Extend array? int i = m_array.length; if (m_lastChunk + 1 == i) { char[][] newarray = new char[i + 16][]; System.arraycopy(m_array, 0, newarray, 0, i); m_array = newarray; } // Advance one chunk chunk = m_array[++m_lastChunk]; if (chunk == null) { // Hierarchical encapsulation if (m_lastChunk == 1 << m_rebundleBits && m_chunkBits < m_maxChunkBits) { // Should do all the work of both encapsulating // existing data and establishing new sizes/offsets m_innerFSB = new FastStringBuffer(this); } // Add a chunk. chunk = m_array[m_lastChunk] = new char[m_chunkSize]; } available = m_chunkSize; m_firstFree = 0; } } // Adjust the insert point in the last chunk, when we've reached it. m_firstFree += available; } /** * Append the contents of another FastStringBuffer onto * this FastStringBuffer, growing the storage if necessary. *

* NOTE THAT after calling append(), previously obtained * references to m_array[] may no longer be valid. * * @param value FastStringBuffer whose contents are * to be appended. */ public final void append(FastStringBuffer value) { // Complicating factor here is that the two buffers may use // different chunk sizes, and even if they're the same we're // probably on a different alignment due to previously appended // data. We have to work through the source in bite-sized chunks. if (value == null) return; int strlen = value.length(); if (0 == strlen) return; int copyfrom = 0; char[] chunk = m_array[m_lastChunk]; int available = m_chunkSize - m_firstFree; // Repeat while data remains to be copied while (strlen > 0) { // Copy what fits if (available > strlen) available = strlen; int sourcechunk = (copyfrom + value.m_chunkSize - 1) >>> value.m_chunkBits; int sourcecolumn = copyfrom & value.m_chunkMask; int runlength = value.m_chunkSize - sourcecolumn; if (runlength > available) runlength = available; System.arraycopy(value.m_array[sourcechunk], sourcecolumn, m_array[m_lastChunk], m_firstFree, runlength); if (runlength != available) System.arraycopy(value.m_array[sourcechunk + 1], 0, m_array[m_lastChunk], m_firstFree + runlength, available - runlength); strlen -= available; copyfrom += available; // If there's more left, allocate another chunk and continue if (strlen > 0) { // Extend array? int i = m_array.length; if (m_lastChunk + 1 == i) { char[][] newarray = new char[i + 16][]; System.arraycopy(m_array, 0, newarray, 0, i); m_array = newarray; } // Advance one chunk chunk = m_array[++m_lastChunk]; if (chunk == null) { // Hierarchical encapsulation if (m_lastChunk == 1 << m_rebundleBits && m_chunkBits < m_maxChunkBits) { // Should do all the work of both encapsulating // existing data and establishing new sizes/offsets m_innerFSB = new FastStringBuffer(this); } // Add a chunk. chunk = m_array[m_lastChunk] = new char[m_chunkSize]; } available = m_chunkSize; m_firstFree = 0; } } // Adjust the insert point in the last chunk, when we've reached it. m_firstFree += available; } /** * @return true if the specified range of characters are all whitespace, * as defined by XMLCharacterRecognizer. *

* CURRENTLY DOES NOT CHECK FOR OUT-OF-RANGE. * * @param start Offset of first character in the range. * @param length Number of characters to send. */ public boolean isWhitespace(int start, int length) { int sourcechunk = start >>> m_chunkBits; int sourcecolumn = start & m_chunkMask; int available = m_chunkSize - sourcecolumn; boolean chunkOK; while (length > 0) { int runlength = (length <= available) ? length : available; if (sourcechunk == 0 && m_innerFSB != null) chunkOK = m_innerFSB.isWhitespace(sourcecolumn, runlength); else chunkOK = org.apache.xml.utils.XMLCharacterRecognizer.isWhiteSpace( m_array[sourcechunk], sourcecolumn, runlength); if (!chunkOK) return false; length -= runlength; ++sourcechunk; sourcecolumn = 0; available = m_chunkSize; } return true; } /** * @param start Offset of first character in the range. * @param length Number of characters to send. * @return a new String object initialized from the specified range of * characters. */ public String getString(int start, int length) { int startColumn = start & m_chunkMask; int startChunk = start >>> m_chunkBits; if (startColumn + length < m_chunkMask && m_innerFSB == null) { return getOneChunkString(startChunk, startColumn, length); } return getString(new StringBuffer(length), startChunk, startColumn, length).toString(); } protected String getOneChunkString(int startChunk, int startColumn, int length) { return new String(m_array[startChunk], startColumn, length); } /** * @param sb StringBuffer to be appended to * @param start Offset of first character in the range. * @param length Number of characters to send. * @return sb with the requested text appended to it */ StringBuffer getString(StringBuffer sb, int start, int length) { return getString(sb, start >>> m_chunkBits, start & m_chunkMask, length); } /** * Internal support for toString() and getString(). * PLEASE NOTE SIGNATURE CHANGE from earlier versions; it now appends into * and returns a StringBuffer supplied by the caller. This simplifies * m_innerFSB support. *

* Note that this operation has been somewhat deoptimized by the shift to a * chunked array, as there is no factory method to produce a String object * directly from an array of arrays and hence a double copy is needed. * By presetting length we hope to minimize the heap overhead of building * the intermediate StringBuffer. *

* (It really is a pity that Java didn't design String as a final subclass * of MutableString, rather than having StringBuffer be a separate hierarchy. * We'd avoid a lot of double-buffering.) * * * @param sb * @param startChunk * @param startColumn * @param length * * @return the contents of the FastStringBuffer as a standard Java string. */ StringBuffer getString(StringBuffer sb, int startChunk, int startColumn, int length) { int stop = (startChunk << m_chunkBits) + startColumn + length; int stopChunk = stop >>> m_chunkBits; int stopColumn = stop & m_chunkMask; // Factored out //StringBuffer sb=new StringBuffer(length); for (int i = startChunk; i < stopChunk; ++i) { if (i == 0 && m_innerFSB != null) m_innerFSB.getString(sb, startColumn, m_chunkSize - startColumn); else sb.append(m_array[i], startColumn, m_chunkSize - startColumn); startColumn = 0; // after first chunk } if (stopChunk == 0 && m_innerFSB != null) m_innerFSB.getString(sb, startColumn, stopColumn - startColumn); else if (stopColumn > startColumn) sb.append(m_array[stopChunk], startColumn, stopColumn - startColumn); return sb; } /** * Get a single character from the string buffer. * * * @param pos character position requested. * @return A character from the requested position. */ public char charAt(int pos) { int startChunk = pos >>> m_chunkBits; if (startChunk == 0 && m_innerFSB != null) return m_innerFSB.charAt(pos & m_chunkMask); else return m_array[startChunk][pos & m_chunkMask]; } /** * Sends the specified range of characters as one or more SAX characters() * events. * Note that the buffer reference passed to the ContentHandler may be * invalidated if the FastStringBuffer is edited; it's the user's * responsibility to manage access to the FastStringBuffer to prevent this * problem from arising. *

* Note too that there is no promise that the output will be sent as a * single call. As is always true in SAX, one logical string may be split * across multiple blocks of memory and hence delivered as several * successive events. * * @param ch SAX ContentHandler object to receive the event. * @param start Offset of first character in the range. * @param length Number of characters to send. * @exception org.xml.sax.SAXException may be thrown by handler's * characters() method. */ public void sendSAXcharacters( org.xml.sax.ContentHandler ch, int start, int length) throws org.xml.sax.SAXException { int startChunk = start >>> m_chunkBits; int startColumn = start & m_chunkMask; if (startColumn + length < m_chunkMask && m_innerFSB == null) { ch.characters(m_array[startChunk], startColumn, length); return; } int stop = start + length; int stopChunk = stop >>> m_chunkBits; int stopColumn = stop & m_chunkMask; for (int i = startChunk; i < stopChunk; ++i) { if (i == 0 && m_innerFSB != null) m_innerFSB.sendSAXcharacters(ch, startColumn, m_chunkSize - startColumn); else ch.characters(m_array[i], startColumn, m_chunkSize - startColumn); startColumn = 0; // after first chunk } // Last, or only, chunk if (stopChunk == 0 && m_innerFSB != null) m_innerFSB.sendSAXcharacters(ch, startColumn, stopColumn - startColumn); else if (stopColumn > startColumn) { ch.characters(m_array[stopChunk], startColumn, stopColumn - startColumn); } } /** * Sends the specified range of characters as one or more SAX characters() * events, normalizing the characters according to XSLT rules. * * @param ch SAX ContentHandler object to receive the event. * @param start Offset of first character in the range. * @param length Number of characters to send. * @return normalization status to apply to next chunk (because we may * have been called recursively to process an inner FSB): *

*
0
*
if this output did not end in retained whitespace, and thus whitespace * at the start of the following chunk (if any) should be converted to a * single space. *
SUPPRESS_LEADING_WS
*
if this output ended in retained whitespace, and thus whitespace * at the start of the following chunk (if any) should be completely * suppressed.
* *
* @exception org.xml.sax.SAXException may be thrown by handler's * characters() method. */ public int sendNormalizedSAXcharacters( org.xml.sax.ContentHandler ch, int start, int length) throws org.xml.sax.SAXException { // This call always starts at the beginning of the // string being written out, either because it was called directly or // because it was an m_innerFSB recursion. This is important since // it gives us a well-known initial state for this flag: int stateForNextChunk=SUPPRESS_LEADING_WS; int stop = start + length; int startChunk = start >>> m_chunkBits; int startColumn = start & m_chunkMask; int stopChunk = stop >>> m_chunkBits; int stopColumn = stop & m_chunkMask; for (int i = startChunk; i < stopChunk; ++i) { if (i == 0 && m_innerFSB != null) stateForNextChunk= m_innerFSB.sendNormalizedSAXcharacters(ch, startColumn, m_chunkSize - startColumn); else stateForNextChunk= sendNormalizedSAXcharacters(m_array[i], startColumn, m_chunkSize - startColumn, ch,stateForNextChunk); startColumn = 0; // after first chunk } // Last, or only, chunk if (stopChunk == 0 && m_innerFSB != null) stateForNextChunk= // %REVIEW% Is this update really needed? m_innerFSB.sendNormalizedSAXcharacters(ch, startColumn, stopColumn - startColumn); else if (stopColumn > startColumn) { stateForNextChunk= // %REVIEW% Is this update really needed? sendNormalizedSAXcharacters(m_array[stopChunk], startColumn, stopColumn - startColumn, ch, stateForNextChunk | SUPPRESS_TRAILING_WS); } return stateForNextChunk; } static final char[] SINGLE_SPACE = {' '}; /** * Internal method to directly normalize and dispatch the character array. * This version is aware of the fact that it may be called several times * in succession if the data is made up of multiple "chunks", and thus * must actively manage the handling of leading and trailing whitespace. * * Note: The recursion is due to the possible recursion of inner FSBs. * * @param ch The characters from the XML document. * @param start The start position in the array. * @param length The number of characters to read from the array. * @param handler SAX ContentHandler object to receive the event. * @param edgeTreatmentFlags How leading/trailing spaces should be handled. * This is a bitfield contining two flags, bitwise-ORed together: *
*
SUPPRESS_LEADING_WS
*
When false, causes leading whitespace to be converted to a single * space; when true, causes it to be discarded entirely. * Should be set TRUE for the first chunk, and (in multi-chunk output) * whenever the previous chunk ended in retained whitespace.
*
SUPPRESS_TRAILING_WS
*
When false, causes trailing whitespace to be converted to a single * space; when true, causes it to be discarded entirely. * Should be set TRUE for the last or only chunk. *
*
* @return normalization status, as in the edgeTreatmentFlags parameter: *
*
0
*
if this output did not end in retained whitespace, and thus whitespace * at the start of the following chunk (if any) should be converted to a * single space. *
SUPPRESS_LEADING_WS
*
if this output ended in retained whitespace, and thus whitespace * at the start of the following chunk (if any) should be completely * suppressed.
* *
* * * @exception org.xml.sax.SAXException Any SAX exception, possibly * wrapping another exception. */ static int sendNormalizedSAXcharacters(char ch[], int start, int length, org.xml.sax.ContentHandler handler, int edgeTreatmentFlags) throws org.xml.sax.SAXException { boolean processingLeadingWhitespace = ((edgeTreatmentFlags & SUPPRESS_LEADING_WS) != 0); boolean seenWhitespace = ((edgeTreatmentFlags & CARRY_WS) != 0); int currPos = start; int limit = start+length; // Strip any leading spaces first, if required if (processingLeadingWhitespace) { for (; currPos < limit && XMLCharacterRecognizer.isWhiteSpace(ch[currPos]); currPos++) { } // If we've only encountered leading spaces, the // current state remains unchanged if (currPos == limit) { return edgeTreatmentFlags; } } // If we get here, there are no more leading spaces to strip while (currPos < limit) { int startNonWhitespace = currPos; // Grab a chunk of non-whitespace characters for (; currPos < limit && !XMLCharacterRecognizer.isWhiteSpace(ch[currPos]); currPos++) { } // Non-whitespace seen - emit them, along with a single // space for any preceding whitespace characters if (startNonWhitespace != currPos) { if (seenWhitespace) { handler.characters(SINGLE_SPACE, 0, 1); seenWhitespace = false; } handler.characters(ch, startNonWhitespace, currPos - startNonWhitespace); } int startWhitespace = currPos; // Consume any whitespace characters for (; currPos < limit && XMLCharacterRecognizer.isWhiteSpace(ch[currPos]); currPos++) { } if (startWhitespace != currPos) { seenWhitespace = true; } } return (seenWhitespace ? CARRY_WS : 0) | (edgeTreatmentFlags & SUPPRESS_TRAILING_WS); } /** * Directly normalize and dispatch the character array. * * @param ch The characters from the XML document. * @param start The start position in the array. * @param length The number of characters to read from the array. * @param handler SAX ContentHandler object to receive the event. * @exception org.xml.sax.SAXException Any SAX exception, possibly * wrapping another exception. */ public static void sendNormalizedSAXcharacters(char ch[], int start, int length, org.xml.sax.ContentHandler handler) throws org.xml.sax.SAXException { sendNormalizedSAXcharacters(ch, start, length, handler, SUPPRESS_BOTH); } /** * Sends the specified range of characters as sax Comment. *

* Note that, unlike sendSAXcharacters, this has to be done as a single * call to LexicalHandler#comment. * * @param ch SAX LexicalHandler object to receive the event. * @param start Offset of first character in the range. * @param length Number of characters to send. * @exception org.xml.sax.SAXException may be thrown by handler's * characters() method. */ public void sendSAXComment( org.xml.sax.ext.LexicalHandler ch, int start, int length) throws org.xml.sax.SAXException { // %OPT% Do it this way for now... String comment = getString(start, length); ch.comment(comment.toCharArray(), 0, length); } /** * Copies characters from this string into the destination character * array. * * @param srcBegin index of the first character in the string * to copy. * @param srcEnd index after the last character in the string * to copy. * @param dst the destination array. * @param dstBegin the start offset in the destination array. * @exception IndexOutOfBoundsException If any of the following * is true: *

* @exception NullPointerException if dst is null */ private void getChars(int srcBegin, int srcEnd, char dst[], int dstBegin) { // %TBD% Joe needs to write this function. Make public when implemented. } /** * Encapsulation c'tor. After this is called, the source FastStringBuffer * will be reset to use the new object as its m_innerFSB, and will have * had its chunk size reset appropriately. IT SHOULD NEVER BE CALLED * EXCEPT WHEN source.length()==1<<(source.m_chunkBits+source.m_rebundleBits) * * NEEDSDOC @param source */ private FastStringBuffer(FastStringBuffer source) { // Copy existing information into new encapsulation m_chunkBits = source.m_chunkBits; m_maxChunkBits = source.m_maxChunkBits; m_rebundleBits = source.m_rebundleBits; m_chunkSize = source.m_chunkSize; m_chunkMask = source.m_chunkMask; m_array = source.m_array; m_innerFSB = source.m_innerFSB; // These have to be adjusted because we're calling just at the time // when we would be about to allocate another chunk m_lastChunk = source.m_lastChunk - 1; m_firstFree = source.m_chunkSize; // Establish capsule as the Inner FSB, reset chunk sizes/addressing source.m_array = new char[16][]; source.m_innerFSB = this; // Since we encapsulated just as we were about to append another // chunk, return ready to create the chunk after the innerFSB // -- 1, not 0. source.m_lastChunk = 1; source.m_firstFree = 0; source.m_chunkBits += m_rebundleBits; source.m_chunkSize = 1 << (source.m_chunkBits); source.m_chunkMask = source.m_chunkSize - 1; } }