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/* Stax2 API extension for Streaming Api for Xml processing (StAX).
 *
 * Copyright (c) 2006- Tatu Saloranta, [email protected]
 *
 * Licensed under the License specified in the file LICENSE which is
 * included with the source code.
 * You may not use this file except in compliance with the License.
 *
 * 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.codehaus.stax2.ri;

import javax.xml.stream.XMLStreamConstants;

public final class Stax2Util
    implements XMLStreamConstants
{
    private Stax2Util() { } // no instantiation

    /**
     * Method that converts given standard Stax event type into
     * textual representation.
     */
    public static String eventTypeDesc(int type)
    {
        switch (type) {
        case START_ELEMENT:
            return "START_ELEMENT";
        case END_ELEMENT:
            return "END_ELEMENT";
        case START_DOCUMENT:
            return "START_DOCUMENT";
        case END_DOCUMENT:
            return "END_DOCUMENT";

        case CHARACTERS:
            return "CHARACTERS";
        case CDATA:
            return "CDATA";
        case SPACE:
            return "SPACE";

        case COMMENT:
            return "COMMENT";
        case PROCESSING_INSTRUCTION:
            return "PROCESSING_INSTRUCTION";
        case DTD:
            return "DTD";
        case ENTITY_REFERENCE:
            return "ENTITY_REFERENCE";
        }
        return "["+type+"]";
    }                                                                                
    /**
     * Method called to trim leading and/or trailing space that given
     * lexical value has.
     *
     * @return Trimmed value if lexical had at least one
     *   non-space character; null otherwise
     */
    public static String trimSpaces(String lexical)
    {
        int end = lexical.length();
        int start = 0;

        while (true) {
            if (start >= end) {
                return null;
            }
            if (!_isSpace(lexical.charAt(start))) {
                break;
            }
            ++start;
        }
        // No trailing space? Either original String as is, or just trim leading
        --end;
        if (!_isSpace(lexical.charAt(end))) {
            return (start == 0) ? lexical : lexical.substring(start);
        }

        // Otherwise, at least some trailing ws...
        while (--end > start && _isSpace(lexical.charAt(end))) { }

        return lexical.substring(start, end+1);
    }

    /**
     *

* Note that it is assumed that any "weird" white space * (xml 1.1 LSEP and NEL) have been replaced by canonical * alternatives (linefeed for element content, regular space * for attributes) */ private final static boolean _isSpace(char c) { return ((int) c) <= 0x0020; } /** * Helper class used to simplify text gathering while keeping * at as efficient as possible. */ public final static class TextBuffer { private String mText = null; /* !!! JDK 1.5: when we can upgrade to Java 5, can convert * to using StringBuilder instead. */ private StringBuffer mBuilder = null; public TextBuffer() { } public void reset() { mText = null; mBuilder = null; } public void append(String text) { int len = text.length(); if (len > 0) { // Any prior text? if (mText != null) { mBuilder = new StringBuffer(mText.length() + len); mBuilder.append(mText); mText = null; } if (mBuilder != null) { mBuilder.append(text); } else { mText = text; } } } public String get() { if (mText != null) { return mText; } if (mBuilder != null) { return mBuilder.toString(); } return ""; } public boolean isEmpty() { return (mText == null) && (mBuilder == null); } } /** * Helper class for efficiently reading and aggregating variable length * byte content. */ public final static class ByteAggregator { private final static byte[] NO_BYTES = new byte[0]; /** * Size of the first block we will allocate. */ private final static int INITIAL_BLOCK_SIZE = 500; /** * Maximum block size we will use for individual non-aggregated * blocks. Let's limit to using 256k chunks. */ //private final static int MAX_BLOCK_SIZE = (1 << 18); final static int DEFAULT_BLOCK_ARRAY_SIZE = 100; private byte[][] mBlocks; private int mBlockCount; private int mTotalLen; /** * Reusable byte buffer block; we retain biggest one from * {@link #mBlocks} after aggregation. */ private byte[] mSpareBlock; public ByteAggregator() { } /** * Method called to initialize aggregation process. * * @return Block that can be used to read in content */ public byte[] startAggregation() { mTotalLen = 0; mBlockCount = 0; byte[] result = mSpareBlock; if (result == null) { result = new byte[INITIAL_BLOCK_SIZE]; } else { mSpareBlock = null; } return result; } /** * Method used to add bufferful of data to the aggregator, and * get another buffer to read more data into. Returned buffer * is generally as big as or bigger than the given buffer, to try * to improve performance for larger aggregations. * * @return Buffer in which to read additional data */ public byte[] addFullBlock(byte[] block) { int blockLen = block.length; if (mBlocks == null) { mBlocks = new byte[DEFAULT_BLOCK_ARRAY_SIZE][]; } else { int oldLen = mBlocks.length; if (mBlockCount >= oldLen) { byte[][] old = mBlocks; mBlocks = new byte[oldLen + oldLen][]; System.arraycopy(old, 0, mBlocks, 0, oldLen); } } mBlocks[mBlockCount] = block; ++mBlockCount; mTotalLen += blockLen; /* Let's allocate block that's half the total size, except * never smaller than twice the initial block size. * The idea is just to grow with reasonable rate, to optimize * between minimal number of chunks and minimal amount of * wasted space. */ int newSize = Math.max((mTotalLen >> 1), (INITIAL_BLOCK_SIZE + INITIAL_BLOCK_SIZE)); return new byte[newSize]; } /** * Method called when results are finalized and we can get the * full aggregated result buffer to return to the caller */ public byte[] aggregateAll(byte[] lastBlock, int lastLen) { int totalLen = mTotalLen + lastLen; if (totalLen == 0) { // quick check: nothing aggregated? return NO_BYTES; } byte[] result = new byte[totalLen]; int offset = 0; if (mBlocks != null) { for (int i = 0; i < mBlockCount; ++i) { byte[] block = mBlocks[i]; int len = block.length; System.arraycopy(block, 0, result, offset, len); offset += len; } } System.arraycopy(lastBlock, 0, result, offset, lastLen); // can reuse the last block: should be the biggest one we've handed mSpareBlock = lastBlock; offset += lastLen; if (offset != totalLen) { // just a sanity check throw new RuntimeException("Internal error: total len assumed to be "+totalLen+", copied "+offset+" bytes"); } return result; } } }





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