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Xerces2 is the next generation of high performance, fully compliant XML parsers in the Apache Xerces family. This new version of Xerces introduces the Xerces Native Interface (XNI), a complete framework for building parser components and configurations that is extremely modular and easy to program. The Apache Xerces2 parser is the reference implementation of XNI but other parser components, configurations, and parsers can be written using the Xerces Native Interface. For complete design and implementation documents, refer to the XNI Manual. Xerces2 is a fully conforming XML Schema 1.0 processor. A partial experimental implementation of the XML Schema 1.1 Structures and Datatypes Working Drafts (December 2009) and an experimental implementation of the XML Schema Definition Language (XSD): Component Designators (SCD) Candidate Recommendation (January 2010) are provided for evaluation. For more information, refer to the XML Schema page. Xerces2 also provides a complete implementation of the Document Object Model Level 3 Core and Load/Save W3C Recommendations and provides a complete implementation of the XML Inclusions (XInclude) W3C Recommendation. It also provides support for OASIS XML Catalogs v1.1. Xerces2 is able to parse documents written according to the XML 1.1 Recommendation, except that it does not yet provide an option to enable normalization checking as described in section 2.13 of this specification. It also handles namespaces according to the XML Namespaces 1.1 Recommendation, and will correctly serialize XML 1.1 documents if the DOM level 3 load/save APIs are in use.

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/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 * 
 *      http://www.apache.org/licenses/LICENSE-2.0
 * 
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

package org.apache.xerces.impl.io;

import java.io.IOException;
import java.io.InputStream;
import java.io.Reader;
import java.util.Locale;

import org.apache.xerces.impl.msg.XMLMessageFormatter;
import org.apache.xerces.util.MessageFormatter;

/**
 * 

A UTF-8 reader.

* * @xerces.internal * * @author Andy Clark, IBM * * @version $Id: UTF8Reader.java 718095 2008-11-16 20:00:14Z mrglavas $ */ public final class UTF8Reader extends Reader { // // Constants // /** Default byte buffer size (2048). */ public static final int DEFAULT_BUFFER_SIZE = 2048; // debugging /** Debug read. */ private static final boolean DEBUG_READ = false; // // Data // /** Input stream. */ protected final InputStream fInputStream; /** Byte buffer. */ protected final byte[] fBuffer; /** Offset into buffer. */ protected int fOffset; /** Surrogate character. */ private int fSurrogate = -1; // message formatter; used to produce localized // exception messages private final MessageFormatter fFormatter; //Locale to use for messages private final Locale fLocale; // // Constructors // /** * Constructs a UTF-8 reader from the specified input stream * using the default buffer size. Primarily for testing. * * @param inputStream The input stream. */ public UTF8Reader(InputStream inputStream) { this(inputStream, DEFAULT_BUFFER_SIZE, new XMLMessageFormatter(), Locale.getDefault()); } // (InputStream, MessageFormatter) /** * Constructs a UTF-8 reader from the specified input stream * using the default buffer size and the given MessageFormatter. * * @param inputStream The input stream. * @param messageFormatter given MessageFormatter * @param locale Locale to use for messages */ public UTF8Reader(InputStream inputStream, MessageFormatter messageFormatter, Locale locale) { this(inputStream, DEFAULT_BUFFER_SIZE, messageFormatter, locale); } // (InputStream, MessageFormatter, Locale) /** * Constructs a UTF-8 reader from the specified input stream, * buffer size and MessageFormatter. * * @param inputStream The input stream. * @param size The initial buffer size. * @param messageFormatter the formatter for localizing/formatting errors. * @param locale the Locale to use for messages */ public UTF8Reader(InputStream inputStream, int size, MessageFormatter messageFormatter, Locale locale) { this(inputStream, new byte[size], messageFormatter, locale); } // (InputStream, int, MessageFormatter, Locale) /** * Constructs a UTF-8 reader from the specified input stream, * buffer and MessageFormatter. * * @param inputStream The input stream. * @param buffer The byte buffer. * @param messageFormatter the formatter for localizing/formatting errors. * @param locale the Locale to use for messages */ public UTF8Reader(InputStream inputStream, byte [] buffer, MessageFormatter messageFormatter, Locale locale) { fInputStream = inputStream; fBuffer = buffer; fFormatter = messageFormatter; fLocale = locale; } // (InputStream, byte[], MessageFormatter, Locale) // // Reader methods // /** * Read a single character. This method will block until a character is * available, an I/O error occurs, or the end of the stream is reached. * *

Subclasses that intend to support efficient single-character input * should override this method. * * @return The character read, as an integer in the range 0 to 16383 * (0x00-0xffff), or -1 if the end of the stream has * been reached * * @exception IOException If an I/O error occurs */ public int read() throws IOException { // decode character int c = fSurrogate; if (fSurrogate == -1) { // NOTE: We use the index into the buffer if there are remaining // bytes from the last block read. -Ac int index = 0; // get first byte int b0 = index == fOffset ? fInputStream.read() : fBuffer[index++] & 0x00FF; if (b0 == -1) { return -1; } // UTF-8: [0xxx xxxx] // Unicode: [0000 0000] [0xxx xxxx] if (b0 < 0x80) { c = (char)b0; } // UTF-8: [110y yyyy] [10xx xxxx] // Unicode: [0000 0yyy] [yyxx xxxx] else if ((b0 & 0xE0) == 0xC0 && (b0 & 0x1E) != 0) { int b1 = index == fOffset ? fInputStream.read() : fBuffer[index++] & 0x00FF; if (b1 == -1) { expectedByte(2, 2); } if ((b1 & 0xC0) != 0x80) { invalidByte(2, 2, b1); } c = ((b0 << 6) & 0x07C0) | (b1 & 0x003F); } // UTF-8: [1110 zzzz] [10yy yyyy] [10xx xxxx] // Unicode: [zzzz yyyy] [yyxx xxxx] else if ((b0 & 0xF0) == 0xE0) { int b1 = index == fOffset ? fInputStream.read() : fBuffer[index++] & 0x00FF; if (b1 == -1) { expectedByte(2, 3); } if ((b1 & 0xC0) != 0x80 || (b0 == 0xED && b1 >= 0xA0) || ((b0 & 0x0F) == 0 && (b1 & 0x20) == 0)) { invalidByte(2, 3, b1); } int b2 = index == fOffset ? fInputStream.read() : fBuffer[index++] & 0x00FF; if (b2 == -1) { expectedByte(3, 3); } if ((b2 & 0xC0) != 0x80) { invalidByte(3, 3, b2); } c = ((b0 << 12) & 0xF000) | ((b1 << 6) & 0x0FC0) | (b2 & 0x003F); } // UTF-8: [1111 0uuu] [10uu zzzz] [10yy yyyy] [10xx xxxx]* // Unicode: [1101 10ww] [wwzz zzyy] (high surrogate) // [1101 11yy] [yyxx xxxx] (low surrogate) // * uuuuu = wwww + 1 else if ((b0 & 0xF8) == 0xF0) { int b1 = index == fOffset ? fInputStream.read() : fBuffer[index++] & 0x00FF; if (b1 == -1) { expectedByte(2, 4); } if ((b1 & 0xC0) != 0x80 || ((b1 & 0x30) == 0 && (b0 & 0x07) == 0)) { invalidByte(2, 3, b1); } int b2 = index == fOffset ? fInputStream.read() : fBuffer[index++] & 0x00FF; if (b2 == -1) { expectedByte(3, 4); } if ((b2 & 0xC0) != 0x80) { invalidByte(3, 3, b2); } int b3 = index == fOffset ? fInputStream.read() : fBuffer[index++] & 0x00FF; if (b3 == -1) { expectedByte(4, 4); } if ((b3 & 0xC0) != 0x80) { invalidByte(4, 4, b3); } int uuuuu = ((b0 << 2) & 0x001C) | ((b1 >> 4) & 0x0003); if (uuuuu > 0x10) { invalidSurrogate(uuuuu); } int wwww = uuuuu - 1; int hs = 0xD800 | ((wwww << 6) & 0x03C0) | ((b1 << 2) & 0x003C) | ((b2 >> 4) & 0x0003); int ls = 0xDC00 | ((b2 << 6) & 0x03C0) | (b3 & 0x003F); c = hs; fSurrogate = ls; } // error else { invalidByte(1, 1, b0); } } // use surrogate else { fSurrogate = -1; } // return character if (DEBUG_READ) { System.out.println("read(): 0x"+Integer.toHexString(c)); } return c; } // read():int /** * Read characters into a portion of an array. This method will block * until some input is available, an I/O error occurs, or the end of the * stream is reached. * * @param ch Destination buffer * @param offset Offset at which to start storing characters * @param length Maximum number of characters to read * * @return The number of characters read, or -1 if the end of the * stream has been reached * * @exception IOException If an I/O error occurs */ public int read(char ch[], int offset, int length) throws IOException { // read bytes int out = offset; int count = 0; if (fOffset == 0) { // adjust length to read if (length > fBuffer.length) { length = fBuffer.length; } // handle surrogate if (fSurrogate != -1) { ch[out++] = (char)fSurrogate; fSurrogate = -1; length--; } // perform read operation count = fInputStream.read(fBuffer, 0, length); if (count == -1) { return -1; } count += out - offset; } // skip read; last character was in error // NOTE: Having an offset value other than zero means that there was // an error in the last character read. In this case, we have // skipped the read so we don't consume any bytes past the // error. By signalling the error on the next block read we // allow the method to return the most valid characters that // it can on the previous block read. -Ac else { count = fOffset; fOffset = 0; } // convert bytes to characters final int total = count; int in; byte byte1; final byte byte0 = 0; for (in = 0; in < total; in++) { byte1 = fBuffer[in]; if (byte1 >= byte0) { ch[out++] = (char)byte1; } else { break; } } for ( ; in < total; in++) { byte1 = fBuffer[in]; // UTF-8: [0xxx xxxx] // Unicode: [0000 0000] [0xxx xxxx] if (byte1 >= byte0) { ch[out++] = (char)byte1; continue; } // UTF-8: [110y yyyy] [10xx xxxx] // Unicode: [0000 0yyy] [yyxx xxxx] int b0 = byte1 & 0x0FF; if ((b0 & 0xE0) == 0xC0 && (b0 & 0x1E) != 0) { int b1 = -1; if (++in < total) { b1 = fBuffer[in] & 0x00FF; } else { b1 = fInputStream.read(); if (b1 == -1) { if (out > offset) { fBuffer[0] = (byte)b0; fOffset = 1; return out - offset; } expectedByte(2, 2); } count++; } if ((b1 & 0xC0) != 0x80) { if (out > offset) { fBuffer[0] = (byte)b0; fBuffer[1] = (byte)b1; fOffset = 2; return out - offset; } invalidByte(2, 2, b1); } int c = ((b0 << 6) & 0x07C0) | (b1 & 0x003F); ch[out++] = (char)c; count -= 1; continue; } // UTF-8: [1110 zzzz] [10yy yyyy] [10xx xxxx] // Unicode: [zzzz yyyy] [yyxx xxxx] if ((b0 & 0xF0) == 0xE0) { int b1 = -1; if (++in < total) { b1 = fBuffer[in] & 0x00FF; } else { b1 = fInputStream.read(); if (b1 == -1) { if (out > offset) { fBuffer[0] = (byte)b0; fOffset = 1; return out - offset; } expectedByte(2, 3); } count++; } if ((b1 & 0xC0) != 0x80 || (b0 == 0xED && b1 >= 0xA0) || ((b0 & 0x0F) == 0 && (b1 & 0x20) == 0)) { if (out > offset) { fBuffer[0] = (byte)b0; fBuffer[1] = (byte)b1; fOffset = 2; return out - offset; } invalidByte(2, 3, b1); } int b2 = -1; if (++in < total) { b2 = fBuffer[in] & 0x00FF; } else { b2 = fInputStream.read(); if (b2 == -1) { if (out > offset) { fBuffer[0] = (byte)b0; fBuffer[1] = (byte)b1; fOffset = 2; return out - offset; } expectedByte(3, 3); } count++; } if ((b2 & 0xC0) != 0x80) { if (out > offset) { fBuffer[0] = (byte)b0; fBuffer[1] = (byte)b1; fBuffer[2] = (byte)b2; fOffset = 3; return out - offset; } invalidByte(3, 3, b2); } int c = ((b0 << 12) & 0xF000) | ((b1 << 6) & 0x0FC0) | (b2 & 0x003F); ch[out++] = (char)c; count -= 2; continue; } // UTF-8: [1111 0uuu] [10uu zzzz] [10yy yyyy] [10xx xxxx]* // Unicode: [1101 10ww] [wwzz zzyy] (high surrogate) // [1101 11yy] [yyxx xxxx] (low surrogate) // * uuuuu = wwww + 1 if ((b0 & 0xF8) == 0xF0) { int b1 = -1; if (++in < total) { b1 = fBuffer[in] & 0x00FF; } else { b1 = fInputStream.read(); if (b1 == -1) { if (out > offset) { fBuffer[0] = (byte)b0; fOffset = 1; return out - offset; } expectedByte(2, 4); } count++; } if ((b1 & 0xC0) != 0x80 || ((b1 & 0x30) == 0 && (b0 & 0x07) == 0)) { if (out > offset) { fBuffer[0] = (byte)b0; fBuffer[1] = (byte)b1; fOffset = 2; return out - offset; } invalidByte(2, 4, b1); } int b2 = -1; if (++in < total) { b2 = fBuffer[in] & 0x00FF; } else { b2 = fInputStream.read(); if (b2 == -1) { if (out > offset) { fBuffer[0] = (byte)b0; fBuffer[1] = (byte)b1; fOffset = 2; return out - offset; } expectedByte(3, 4); } count++; } if ((b2 & 0xC0) != 0x80) { if (out > offset) { fBuffer[0] = (byte)b0; fBuffer[1] = (byte)b1; fBuffer[2] = (byte)b2; fOffset = 3; return out - offset; } invalidByte(3, 4, b2); } int b3 = -1; if (++in < total) { b3 = fBuffer[in] & 0x00FF; } else { b3 = fInputStream.read(); if (b3 == -1) { if (out > offset) { fBuffer[0] = (byte)b0; fBuffer[1] = (byte)b1; fBuffer[2] = (byte)b2; fOffset = 3; return out - offset; } expectedByte(4, 4); } count++; } if ((b3 & 0xC0) != 0x80) { if (out > offset) { fBuffer[0] = (byte)b0; fBuffer[1] = (byte)b1; fBuffer[2] = (byte)b2; fBuffer[3] = (byte)b3; fOffset = 4; return out - offset; } invalidByte(4, 4, b2); } // decode bytes into surrogate characters int uuuuu = ((b0 << 2) & 0x001C) | ((b1 >> 4) & 0x0003); if (uuuuu > 0x10) { invalidSurrogate(uuuuu); } int wwww = uuuuu - 1; int zzzz = b1 & 0x000F; int yyyyyy = b2 & 0x003F; int xxxxxx = b3 & 0x003F; int hs = 0xD800 | ((wwww << 6) & 0x03C0) | (zzzz << 2) | (yyyyyy >> 4); int ls = 0xDC00 | ((yyyyyy << 6) & 0x03C0) | xxxxxx; // set characters ch[out++] = (char)hs; if ((count -= 2) <= length) { ch[out++] = (char)ls; } // reached the end of the char buffer; save low surrogate for the next read else { fSurrogate = ls; --count; } continue; } // error if (out > offset) { fBuffer[0] = (byte)b0; fOffset = 1; return out - offset; } invalidByte(1, 1, b0); } // return number of characters converted if (DEBUG_READ) { System.out.println("read(char[],"+offset+','+length+"): count="+count); } return count; } // read(char[],int,int) /** * Skip characters. This method will block until some characters are * available, an I/O error occurs, or the end of the stream is reached. * * @param n The number of characters to skip * * @return The number of characters actually skipped * * @exception IOException If an I/O error occurs */ public long skip(long n) throws IOException { long remaining = n; final char[] ch = new char[fBuffer.length]; do { int length = ch.length < remaining ? ch.length : (int)remaining; int count = read(ch, 0, length); if (count > 0) { remaining -= count; } else { break; } } while (remaining > 0); long skipped = n - remaining; return skipped; } // skip(long):long /** * Tell whether this stream is ready to be read. * * @return True if the next read() is guaranteed not to block for input, * false otherwise. Note that returning false does not guarantee that the * next read will block. * * @exception IOException If an I/O error occurs */ public boolean ready() throws IOException { return false; } // ready() /** * Tell whether this stream supports the mark() operation. */ public boolean markSupported() { return false; } // markSupported() /** * Mark the present position in the stream. Subsequent calls to reset() * will attempt to reposition the stream to this point. Not all * character-input streams support the mark() operation. * * @param readAheadLimit Limit on the number of characters that may be * read while still preserving the mark. After * reading this many characters, attempting to * reset the stream may fail. * * @exception IOException If the stream does not support mark(), * or if some other I/O error occurs */ public void mark(int readAheadLimit) throws IOException { throw new IOException(fFormatter.formatMessage(fLocale, "OperationNotSupported", new Object[]{"mark()", "UTF-8"})); } // mark(int) /** * Reset the stream. If the stream has been marked, then attempt to * reposition it at the mark. If the stream has not been marked, then * attempt to reset it in some way appropriate to the particular stream, * for example by repositioning it to its starting point. Not all * character-input streams support the reset() operation, and some support * reset() without supporting mark(). * * @exception IOException If the stream has not been marked, * or if the mark has been invalidated, * or if the stream does not support reset(), * or if some other I/O error occurs */ public void reset() throws IOException { fOffset = 0; fSurrogate = -1; } // reset() /** * Close the stream. Once a stream has been closed, further read(), * ready(), mark(), or reset() invocations will throw an IOException. * Closing a previously-closed stream, however, has no effect. * * @exception IOException If an I/O error occurs */ public void close() throws IOException { fInputStream.close(); } // close() // // Private methods // /** Throws an exception for expected byte. */ private void expectedByte(int position, int count) throws MalformedByteSequenceException { throw new MalformedByteSequenceException(fFormatter, fLocale, XMLMessageFormatter.XML_DOMAIN, "ExpectedByte", new Object[] {Integer.toString(position), Integer.toString(count)}); } // expectedByte(int,int) /** Throws an exception for invalid byte. */ private void invalidByte(int position, int count, int c) throws MalformedByteSequenceException { throw new MalformedByteSequenceException(fFormatter, fLocale, XMLMessageFormatter.XML_DOMAIN, "InvalidByte", new Object [] {Integer.toString(position), Integer.toString(count)}); } // invalidByte(int,int,int) /** Throws an exception for invalid surrogate bits. */ private void invalidSurrogate(int uuuuu) throws MalformedByteSequenceException { throw new MalformedByteSequenceException(fFormatter, fLocale, XMLMessageFormatter.XML_DOMAIN, "InvalidHighSurrogate", new Object[] {Integer.toHexString(uuuuu)}); } // invalidSurrogate(int) } // class UTF8Reader





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