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This artifact provides a single jar that contains all classes required to use remote EJB and JMS, including all dependencies. It is intended for use by those not using maven, maven users should just import the EJB and JMS BOM's instead (shaded JAR's cause lots of problems with maven, as it is very easy to inadvertently end up with different versions on classes on the class path).

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/*
 * JBoss, Home of Professional Open Source.
 * Copyright 2014 Red Hat, Inc., and individual contributors
 * as indicated by the @author tags.
 *
 * Licensed 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 io.undertow.util;

import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.lang.reflect.Constructor;
import java.nio.ByteBuffer;
import java.nio.charset.StandardCharsets;
import java.security.AccessController;
import java.security.PrivilegedExceptionAction;

/**
 * An efficient and flexible Base64 implementation.
 *
 * This class can deal with both MIME Base64 and Base64url.
 *
 * @author Jason T. Greene
 */
public class FlexBase64 {
    /*
     * Note that this code heavily favors performance over reuse and clean style.
     */

    private static final byte[] STANDARD_ENCODING_TABLE;
    private static final byte[] STANDARD_DECODING_TABLE = new byte[80];
    private static final byte[] URL_ENCODING_TABLE;
    private static final byte[] URL_DECODING_TABLE = new byte[80];
    private static final Constructor STRING_CONSTRUCTOR;

    static {
        STANDARD_ENCODING_TABLE = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/".getBytes(StandardCharsets.US_ASCII);
        URL_ENCODING_TABLE = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-_".getBytes(StandardCharsets.US_ASCII);

        for (int i = 0; i < STANDARD_ENCODING_TABLE.length; i++) {
            int v = (STANDARD_ENCODING_TABLE[i] & 0xFF) - 43;
            STANDARD_DECODING_TABLE[v] = (byte)(i + 1);  // zero = illegal
        }

        for (int i = 0; i < URL_ENCODING_TABLE.length; i++) {
            int v = (URL_ENCODING_TABLE[i] & 0xFF) - 43;
            URL_DECODING_TABLE[v] = (byte)(i + 1);  // zero = illegal
        }


        Constructor c = null;
        try {
            PrivilegedExceptionAction> runnable = new PrivilegedExceptionAction>() {
                @Override
                public Constructor run() throws Exception {
                    Constructor c;
                    c = String.class.getDeclaredConstructor(char[].class, boolean.class);
                    c.setAccessible(true);
                    return c;
                }
            };
            if (System.getSecurityManager() != null) {
                c = AccessController.doPrivileged(runnable);
            } else {
                c = runnable.run();
            }
        } catch (Throwable t) {
        }

        STRING_CONSTRUCTOR = c;
    }

    /**
     * Creates a state driven base64 encoder.
     *
     * 

The Encoder instance is not thread-safe, and must not be shared between threads without establishing a * happens-before relationship.

* * @param wrap whether or not to wrap at 76 characters with CRLF * @return an createEncoder instance */ public static Encoder createEncoder(boolean wrap) { return new Encoder(wrap, false); } /** * Creates a state driven base64url encoder. * *

The Encoder instance is not thread-safe, and must not be shared between threads without establishing a * happens-before relationship.

* * @param wrap whether or not to wrap at 76 characters with CRLF * @return an createEncoder instance */ public static Encoder createURLEncoder(boolean wrap) { return new Encoder(wrap, true); } /** * Creates a state driven base64 decoder. * *

The Decoder instance is not thread-safe, and must not be shared between threads without establishing a * happens-before relationship.

* * @return a new createDecoder instance */ public static Decoder createDecoder() { return new Decoder(false); } /** * Creates a state driven base64url decoder. * *

The Decoder instance is not thread-safe, and must not be shared between threads without establishing a * happens-before relationship.

* * @return a new createDecoder instance */ public static Decoder createURLDecoder() { return new Decoder(true); } /** * Encodes a fixed and complete byte array into a Base64 String. * *

This method is only useful for applications which require a String and have all data to be encoded up-front. * Note that byte arrays or buffers are almost always a better storage choice. They consume half the memory and * can be reused (modified). In other words, it is almost always better to use {@link #encodeBytes}, * {@link #createEncoder}, or {@link #createEncoderOutputStream} instead. * instead. * * @param source the byte array to encode from * @param wrap whether or not to wrap the output at 76 chars with CRLFs * @return a new String representing the Base64 output */ public static String encodeString(byte[] source, boolean wrap) { return Encoder.encodeString(source, 0, source.length, wrap, false); } /** * Encodes a fixed and complete byte array into a Base64url String. * *

This method is only useful for applications which require a String and have all data to be encoded up-front. * Note that byte arrays or buffers are almost always a better storage choice. They consume half the memory and * can be reused (modified). In other words, it is almost always better to use {@link #encodeBytes}, * {@link #createEncoder}, or {@link #createEncoderOutputStream} instead. * instead. * * @param source the byte array to encode from * @param wrap whether or not to wrap the output at 76 chars with CRLFs * @return a new String representing the Base64url output */ public static String encodeStringURL(byte[] source, boolean wrap) { return Encoder.encodeString(source, 0, source.length, wrap, true); } /** * Encodes a fixed and complete byte array into a Base64 String. * *

This method is only useful for applications which require a String and have all data to be encoded up-front. * Note that byte arrays or buffers are almost always a better storage choice. They consume half the memory and * can be reused (modified). In other words, it is almost always better to use {@link #encodeBytes}, * {@link #createEncoder}, or {@link #createEncoderOutputStream} instead.

* *

     *    // Encodes "ell"
     *    FlexBase64.encodeString("hello".getBytes("US-ASCII"), 1, 4);
     * 
* * @param source the byte array to encode from * @param pos the position to start encoding from * @param limit the position to halt encoding at (exclusive) * @param wrap whether or not to wrap the output at 76 chars with CRLFs * @return a new String representing the Base64 output */ public static String encodeString(byte[] source, int pos, int limit, boolean wrap) { return Encoder.encodeString(source, pos, limit, wrap, false); } /** * Encodes a fixed and complete byte array into a Base64url String. * *

This method is only useful for applications which require a String and have all data to be encoded up-front. * Note that byte arrays or buffers are almost always a better storage choice. They consume half the memory and * can be reused (modified). In other words, it is almost always better to use {@link #encodeBytes}, * {@link #createEncoder}, or {@link #createEncoderOutputStream} instead.

* *

     *    // Encodes "ell"
     *    FlexBase64.encodeStringURL("hello".getBytes("US-ASCII"), 1, 4);
     * 
* * @param source the byte array to encode from * @param pos the position to start encoding from * @param limit the position to halt encoding at (exclusive) * @param wrap whether or not to wrap the output at 76 chars with CRLFs * @return a new String representing the Base64url output */ public static String encodeStringURL(byte[] source, int pos, int limit, boolean wrap) { return Encoder.encodeString(source, pos, limit, wrap, true); } /** * Encodes a fixed and complete byte buffer into a Base64 String. * *

This method is only useful for applications which require a String and have all data to be encoded up-front. * Note that byte arrays or buffers are almost always a better storage choice. They consume half the memory and * can be reused (modified). In other words, it is almost always better to use {@link #encodeBytes}, * {@link #createEncoder}, or {@link #createEncoderOutputStream} instead.

* *

     *    // Encodes "hello"
     *    FlexBase64.encodeString(ByteBuffer.wrap("hello".getBytes("US-ASCII")), false);
     * 
* * @param source the byte buffer to encode from * @param wrap whether or not to wrap the output at 76 chars with CRLFs * @return a new String representing the Base64 output */ public static String encodeString(ByteBuffer source, boolean wrap) { return Encoder.encodeString(source, wrap, false); } /** * Encodes a fixed and complete byte buffer into a Base64url String. * *

This method is only useful for applications which require a String and have all data to be encoded up-front. * Note that byte arrays or buffers are almost always a better storage choice. They consume half the memory and * can be reused (modified). In other words, it is almost always better to use {@link #encodeBytes}, * {@link #createEncoder}, or {@link #createEncoderOutputStream} instead.

* *

     *    // Encodes "hello"
     *    FlexBase64.encodeStringURL(ByteBuffer.wrap("hello".getBytes("US-ASCII")), false);
     * 
* * @param source the byte buffer to encode from * @param wrap whether or not to wrap the output at 76 chars with CRLFs * @return a new String representing the Base64url output */ public static String encodeStringURL(ByteBuffer source, boolean wrap) { return Encoder.encodeString(source, wrap, true); } /** * Encodes a fixed and complete byte buffer into a Base64 byte array. * *

     *    // Encodes "ell"
     *    FlexBase64.encodeString("hello".getBytes("US-ASCII"), 1, 4, false);
     * 
* * @param source the byte array to encode from * @param pos the position to start encoding at * @param limit the position to halt encoding at (exclusive) * @param wrap whether or not to wrap at 76 characters with CRLFs * @return a new byte array containing the encoded ASCII values */ public static byte[] encodeBytes(byte[] source, int pos, int limit, boolean wrap) { return Encoder.encodeBytes(source, pos, limit, wrap, false); } /** * Encodes a fixed and complete byte buffer into a Base64url byte array. * *

     *    // Encodes "ell"
     *    FlexBase64.encodeStringURL("hello".getBytes("US-ASCII"), 1, 4, false);
     * 
* * @param source the byte array to encode from * @param pos the position to start encoding at * @param limit the position to halt encoding at (exclusive) * @param wrap whether or not to wrap at 76 characters with CRLFs * @return a new byte array containing the encoded ASCII values */ public static byte[] encodeBytesURL(byte[] source, int pos, int limit, boolean wrap) { return Encoder.encodeBytes(source, pos, limit, wrap, true); } /** * Decodes a Base64 encoded string into a new byte buffer. The returned byte buffer is a heap buffer, * and it is therefor possible to retrieve the backing array using {@link java.nio.ByteBuffer#array()}, * {@link java.nio.ByteBuffer#arrayOffset()} and {@link java.nio.ByteBuffer#limit()}. The latter is very * important since the decoded array may be larger than the decoded data. This is due to length estimation which * avoids an unnecessary array copy. * * @param source the Base64 string to decode * @return a byte buffer containing the decoded output * @throws IOException if the encoding is invalid or corrupted */ public static ByteBuffer decode(String source) throws IOException { return Decoder.decode(source, false); } /** * Decodes a Base64url encoded string into a new byte buffer. The returned byte buffer is a heap buffer, * and it is therefor possible to retrieve the backing array using {@link java.nio.ByteBuffer#array()}, * {@link java.nio.ByteBuffer#arrayOffset()} and {@link java.nio.ByteBuffer#limit()}. The latter is very * important since the decoded array may be larger than the decoded data. This is due to length estimation which * avoids an unnecessary array copy. * * @param source the Base64 string to decode * @return a byte buffer containing the decoded output * @throws IOException if the encoding is invalid or corrupted */ public static ByteBuffer decodeURL(String source) throws IOException { return Decoder.decode(source, true); } /** * Decodes a Base64 encoded byte buffer into a new byte buffer. The returned byte buffer is a heap buffer, * and it is therefor possible to retrieve the backing array using {@link java.nio.ByteBuffer#array()}, * {@link java.nio.ByteBuffer#arrayOffset()} and {@link java.nio.ByteBuffer#limit()}. The latter is very * important since the decoded array may be larger than the decoded data. This is due to length estimation which * avoids an unnecessary array copy. * * @param source the Base64 content to decode * @return a byte buffer containing the decoded output * @throws IOException if the encoding is invalid or corrupted */ public static ByteBuffer decode(ByteBuffer source) throws IOException { return Decoder.decode(source, false); } /** * Decodes a Base64url encoded byte buffer into a new byte buffer. The returned byte buffer is a heap buffer, * and it is therefor possible to retrieve the backing array using {@link java.nio.ByteBuffer#array()}, * {@link java.nio.ByteBuffer#arrayOffset()} and {@link java.nio.ByteBuffer#limit()}. The latter is very * important since the decoded array may be larger than the decoded data. This is due to length estimation which * avoids an unnecessary array copy. * * @param source the Base64 content to decode * @return a byte buffer containing the decoded output * @throws IOException if the encoding is invalid or corrupted */ public static ByteBuffer decodeURL(ByteBuffer source) throws IOException { return Decoder.decode(source, true); } /** * Decodes a Base64 encoded byte array into a new byte buffer. The returned byte buffer is a heap buffer, * and it is therefor possible to retrieve the backing array using {@link java.nio.ByteBuffer#array()}, * {@link java.nio.ByteBuffer#arrayOffset()} and {@link java.nio.ByteBuffer#limit()}. The latter is very * important since the decoded array may be larger than the decoded data. This is due to length estimation which * avoids an unnecessary array copy. * * @param source the Base64 content to decode * @param off position to start decoding from in source * @param limit position to stop decoding in source (exclusive) * @return a byte buffer containing the decoded output * @throws IOException if the encoding is invalid or corrupted */ public static ByteBuffer decode(byte[] source, int off, int limit) throws IOException { return Decoder.decode(source, off, limit, false); } /** * Decodes a Base64url encoded byte array into a new byte buffer. The returned byte buffer is a heap buffer, * and it is therefor possible to retrieve the backing array using {@link java.nio.ByteBuffer#array()}, * {@link java.nio.ByteBuffer#arrayOffset()} and {@link java.nio.ByteBuffer#limit()}. The latter is very * important since the decoded array may be larger than the decoded data. This is due to length estimation which * avoids an unnecessary array copy. * * @param source the Base64url content to decode * @param off position to start decoding from in source * @param limit position to stop decoding in source (exclusive) * @return a byte buffer containing the decoded output * @throws IOException if the encoding is invalid or corrupted */ public static ByteBuffer decodeURL(byte[] source, int off, int limit) throws IOException { return Decoder.decode(source, off, limit, true); } /** * Creates an InputStream wrapper which encodes a source into base64 as it is read, until the source hits EOF. * Upon hitting EOF, a standard base64 termination sequence will be readable. Clients can simply treat this input * stream as if they were reading from a base64 encoded file. This stream attempts to read and encode in buffer * size chunks from the source, in order to improve overall performance. Thus, BufferInputStream is not necessary * and will lead to double buffering. * *

This stream is not thread-safe, and should not be shared between threads, without establishing a * happens-before relationship.

* * @param source an input source to read from * @param bufferSize the chunk size to buffer from the source * @param wrap whether or not the stream should wrap base64 output at 76 characters * @return an encoded input stream instance. */ public static EncoderInputStream createEncoderInputStream(InputStream source, int bufferSize, boolean wrap) { return new EncoderInputStream(source, bufferSize, wrap, false); } /** * Creates an InputStream wrapper which encodes a source into base64 as it is read, until the source hits EOF. * Upon hitting EOF, a standard base64 termination sequence will be readable. Clients can simply treat this input * stream as if they were reading from a base64 encoded file. This stream attempts to read and encode in 8192 byte * chunks. Thus, BufferedInputStream is not necessary as a source and will lead to double buffering. * *

This stream is not thread-safe, and should not be shared between threads, without establishing a * happens-before relationship.

* * @param source an input source to read from * @return an encoded input stream instance. */ public static EncoderInputStream createEncoderInputStream(InputStream source) { return new EncoderInputStream(source); } /** * Creates an InputStream wrapper which decodes a base64 input source into the decoded content as it is read, * until the source hits EOF. Upon hitting EOF, a standard base64 termination sequence will be readable. * Clients can simply treat this input stream as if they were reading from a base64 encoded file. This stream * attempts to read and encode in buffer size byte chunks. Thus, BufferedInputStream is not necessary * as a source and will lead to double buffering. * *

Note that the end of a base64 stream can not reliably be detected, so if multiple base64 streams exist on the * wire, the source stream will need to simulate an EOF when the boundary mechanism is detected.

* *

This stream is not thread-safe, and should not be shared between threads, without establishing a * happens-before relationship.

* * @param source an input source to read from * @param bufferSize the chunk size to buffer before when reading from the target * @return a decoded input stream instance. */ public static DecoderInputStream createDecoderInputStream(InputStream source, int bufferSize) { return new DecoderInputStream(source, bufferSize); } /** * Creates an InputStream wrapper which decodes a base64 input source into the decoded content as it is read, * until the source hits EOF. Upon hitting EOF, a standard base64 termination sequence will be readable. * Clients can simply treat this input stream as if they were reading from a base64 encoded file. This stream * attempts to read and encode in 8192 byte chunks. Thus, BufferedInputStream is not necessary * as a source and will lead to double buffering. * *

Note that the end of a base64 stream can not reliably be detected, so if multiple base64 streams exist on the * wire, the source stream will need to simulate an EOF when the boundary mechanism is detected.

* *

This stream is not thread-safe, and should not be shared between threads, without establishing a * happens-before relationship.

* * @param source an input source to read from * @return a decoded input stream instance. */ public static DecoderInputStream createDecoderInputStream(InputStream source) { return new DecoderInputStream(source); } /** * Creates an OutputStream wrapper which base64 encodes and writes to the passed OutputStream target. When this * stream is closed base64 padding will be added if needed. Alternatively if this represents an "inner stream", * the {@link FlexBase64.EncoderOutputStream#complete()} method can be called to close out * the inner stream without closing the wrapped target. * *

All bytes written will be queued to a buffer in the specified size. This stream, therefore, does not require * BufferedOutputStream, which would lead to double buffering. * * @param target an output target to write to * @param bufferSize the chunk size to buffer before writing to the target * @param wrap whether or not the stream should wrap base64 output at 76 characters * @return an encoded output stream instance. */ public static EncoderOutputStream createEncoderOutputStream(OutputStream target, int bufferSize, boolean wrap) { return new EncoderOutputStream(target, bufferSize, wrap); } /** * Creates an OutputStream wrapper which base64 encodes and writes to the passed OutputStream target. When this * stream is closed base64 padding will be added if needed. Alternatively if this represents an "inner stream", * the {@link FlexBase64.EncoderOutputStream#complete()} method can be called to close out * the inner stream without closing the wrapped target. * *

All bytes written will be queued to an 8192 byte buffer. This stream, therefore, does not require * BufferedOutputStream, which would lead to double buffering.

* *

This stream is not thread-safe, and should not be shared between threads, without establishing a * happens-before relationship.

* * @param output the output stream to write encoded output to * @return an encoded output stream instance. */ public static EncoderOutputStream createEncoderOutputStream(OutputStream output) { return new EncoderOutputStream(output); } /** * Creates an OutputStream wrapper which decodes base64 content before writing to the passed OutputStream target. * *

All bytes written will be queued to a buffer using the specified buffer size. This stream, therefore, does * not require BufferedOutputStream, which would lead to double buffering.

* *

This stream is not thread-safe, and should not be shared between threads, without establishing a * happens-before relationship.

* * @param output the output stream to write decoded output to * @param bufferSize the buffer size to buffer writes to * @return a decoded output stream instance. */ public static DecoderOutputStream createDecoderOutputStream(OutputStream output, int bufferSize) { return new DecoderOutputStream(output, bufferSize); } /** * Creates an OutputStream wrapper which decodes base64 content before writing to the passed OutputStream target. * *

All bytes written will be queued to an 8192 byte buffer. This stream, therefore, does * not require BufferedOutputStream, which would lead to double buffering.

* *

This stream is not thread-safe, and should not be shared between threads, without establishing a * happens-before relationship.

* * @param output the output stream to write decoded output to * @return a decoded output stream instance. */ public static DecoderOutputStream createDecoderOutputStream(OutputStream output) { return new DecoderOutputStream(output); } /** * Controls the encoding process. */ public static final class Encoder { private int state; private int last; private int count; private final boolean wrap; private int lastPos; private final byte[] encodingTable; private Encoder(boolean wrap, boolean url) { this.wrap = wrap; this.encodingTable = url ? URL_ENCODING_TABLE : STANDARD_ENCODING_TABLE; } /** * Encodes bytes read from source and writes them in base64 format to target. If the source limit is hit, this * method will return and save the current state, such that future calls can resume the encoding process. * In addition, if the target does not have the capacity to fit an entire quad of bytes, this method will also * return and save state for subsequent calls to this method. Once all bytes have been encoded to the target, * {@link #complete(java.nio.ByteBuffer)} should be called to add the necessary padding characters. * * @param source the byte buffer to read from * @param target the byte buffer to write to */ public void encode(ByteBuffer source, ByteBuffer target) { if (target == null) throw new IllegalStateException(); int last = this.last; int state = this.state; boolean wrap = this.wrap; int count = this.count; final byte[] ENCODING_TABLE = encodingTable; int remaining = source.remaining(); while (remaining > 0) { // Unrolled state machine for performance (resumes and executes all states in one iteration) int require = 4 - state; require = wrap && (count >= 72) ? require + 2 : require; if (target.remaining() < require) { break; } // ( 6 | 2) (4 | 4) (2 | 6) int b = source.get() & 0xFF; if (state == 0) { target.put(ENCODING_TABLE[b >>> 2]); last = (b & 0x3) << 4; state++; if (--remaining <= 0) { break; } b = source.get() & 0xFF; } if (state == 1) { target.put(ENCODING_TABLE[last | (b >>> 4)]); last = (b & 0x0F) << 2; state++; if (--remaining <= 0) { break; } b = source.get() & 0xFF; } if (state == 2) { target.put(ENCODING_TABLE[last | (b >>> 6)]); target.put(ENCODING_TABLE[b & 0x3F]); last = state = 0; remaining--; } if (wrap) { count += 4; if (count >= 76) { count = 0; target.putShort((short)0x0D0A); } } } this.count = count; this.last = last; this.state = state; this.lastPos = source.position(); } /** * Encodes bytes read from source and writes them in base64 format to target. If the source limit is hit, this * method will return and save the current state, such that future calls can resume the encoding process. * In addition, if the target does not have the capacity to fit an entire quad of bytes, this method will also * return and save state for subsequent calls to this method. Once all bytes have been encoded to the target, * {@link #complete(byte[], int)} should be called to add the necessary padding characters. In order to * determine the last read position, the {@link #getLastInputPosition()} can be used. * *

Note that the limit values are not lengths, they are positions similar to * {@link java.nio.ByteBuffer#limit()}. To calculate a length simply subtract position from limit.

* *

         *  Encoder encoder = FlexBase64.createEncoder(false);
         *  byte[] outBuffer = new byte[10];
         *  // Encode "ell"
         *  int outPosition = encoder.encode("hello".getBytes("US-ASCII"), 1, 4, outBuffer, 5, 10);
         *  // Prints "9 : ZWxs"
         *  System.out.println(outPosition + " : " + new String(outBuffer, 0, 5, outPosition - 5));
         * 
* * @param source the byte array to read from * @param pos ths position in the byte array to start reading from * @param limit the position in the byte array that is after the end of the source data * @param target the byte array to write base64 bytes to * @param opos the position to start writing to the target array at * @param olimit the position in the target byte array that makes the end of the writable area (exclusive) * @return the position in the target array immediately following the last byte written */ public int encode(byte[] source, int pos, int limit, byte[] target, int opos, int olimit) { if (target == null) throw new IllegalStateException(); int last = this.last; int state = this.state; int count = this.count; boolean wrap = this.wrap; final byte[] ENCODING_TABLE = encodingTable; while (limit > pos) { // Unrolled state machine for performance (resumes and executes all states in one iteration) int require = 4 - state; require = wrap && count >= 72 ? require + 2 : require; if ((require + opos) > olimit) { break; } // ( 6 | 2) (4 | 4) (2 | 6) int b = source[pos++] & 0xFF; if (state == 0) { target[opos++] = ENCODING_TABLE[b >>> 2]; last = (b & 0x3) << 4; state++; if (pos >= limit) { break; } b = source[pos++] & 0xFF; } if (state == 1) { target[opos++] = ENCODING_TABLE[last | (b >>> 4)]; last = (b & 0x0F) << 2; state++; if (pos >= limit) { break; } b = source[pos++] & 0xFF; } if (state == 2) { target[opos++] = ENCODING_TABLE[last | (b >>> 6)]; target[opos++] = ENCODING_TABLE[b & 0x3F]; last = state = 0; } if (wrap) { count += 4; if (count >= 76) { count = 0; target[opos++] = 0x0D; target[opos++] = 0x0A; } } } this.count = count; this.last = last; this.state = state; this.lastPos = pos; return opos; } private static String encodeString(byte[] source, int pos, int limit, boolean wrap, boolean url) { int olimit = (limit - pos); int remainder = olimit % 3; olimit = (olimit + (remainder == 0 ? 0 : 3 - remainder)) / 3 * 4; olimit += (wrap ? (olimit / 76) * 2 + 2 : 0); char[] target = new char[olimit]; int opos = 0; int last = 0; int count = 0; int state = 0; final byte[] ENCODING_TABLE = url ? URL_ENCODING_TABLE : STANDARD_ENCODING_TABLE; while (limit > pos) { // ( 6 | 2) (4 | 4) (2 | 6) int b = source[pos++] & 0xFF; target[opos++] = (char) ENCODING_TABLE[b >>> 2]; last = (b & 0x3) << 4; if (pos >= limit) { state = 1; break; } b = source[pos++] & 0xFF; target[opos++] = (char) ENCODING_TABLE[last | (b >>> 4)]; last = (b & 0x0F) << 2; if (pos >= limit) { state = 2; break; } b = source[pos++] & 0xFF; target[opos++] = (char) ENCODING_TABLE[last | (b >>> 6)]; target[opos++] = (char) ENCODING_TABLE[b & 0x3F]; if (wrap) { count += 4; if (count >= 76) { count = 0; target[opos++] = 0x0D; target[opos++] = 0x0A; } } } complete(target, opos, state, last, wrap, url); try { // Eliminate copying on Open/Oracle JDK if (STRING_CONSTRUCTOR != null) { return STRING_CONSTRUCTOR.newInstance(target, Boolean.TRUE); } } catch (Exception e) { // Ignoring on purpose } return new String(target); } private static byte[] encodeBytes(byte[] source, int pos, int limit, boolean wrap, boolean url) { int olimit = (limit - pos); int remainder = olimit % 3; olimit = (olimit + (remainder == 0 ? 0 : 3 - remainder)) / 3 * 4; olimit += (wrap ? (olimit / 76) * 2 + 2 : 0); byte[] target = new byte[olimit]; int opos = 0; int count = 0; int last = 0; int state = 0; final byte[] ENCODING_TABLE = url ? URL_ENCODING_TABLE : STANDARD_ENCODING_TABLE; while (limit > pos) { // ( 6 | 2) (4 | 4) (2 | 6) int b = source[pos++] & 0xFF; target[opos++] = ENCODING_TABLE[b >>> 2]; last = (b & 0x3) << 4; if (pos >= limit) { state = 1; break; } b = source[pos++] & 0xFF; target[opos++] = ENCODING_TABLE[last | (b >>> 4)]; last = (b & 0x0F) << 2; if (pos >= limit) { state = 2; break; } b = source[pos++] & 0xFF; target[opos++] = ENCODING_TABLE[last | (b >>> 6)]; target[opos++] = ENCODING_TABLE[b & 0x3F]; if (wrap) { count += 4; if (count >= 76) { count = 0; target[opos++] = 0x0D; target[opos++] = 0x0A; } } } complete(target, opos, state, last, wrap, url); return target; } private static String encodeString(ByteBuffer source, boolean wrap, boolean url) { int remaining = source.remaining(); int remainder = remaining % 3; int olimit = (remaining + (remainder == 0 ? 0 : 3 - remainder)) / 3 * 4; olimit += (wrap ? olimit / 76 * 2 + 2 : 0); char[] target = new char[olimit]; int opos = 0; int last = 0; int state = 0; int count = 0; final byte[] ENCODING_TABLE = url ? URL_ENCODING_TABLE : STANDARD_ENCODING_TABLE; while (remaining > 0) { // ( 6 | 2) (4 | 4) (2 | 6) int b = source.get() & 0xFF; target[opos++] = (char) ENCODING_TABLE[b >>> 2]; last = (b & 0x3) << 4; if (--remaining <= 0) { state = 1; break; } b = source.get() & 0xFF; target[opos++] = (char) ENCODING_TABLE[last | (b >>> 4)]; last = (b & 0x0F) << 2; if (--remaining <= 0) { state = 2; break; } b = source.get() & 0xFF; target[opos++] = (char) ENCODING_TABLE[last | (b >>> 6)]; target[opos++] = (char) ENCODING_TABLE[b & 0x3F]; remaining--; if (wrap) { count += 4; if (count >= 76) { count = 0; target[opos++] = 0x0D; target[opos++] = 0x0A; } } } complete(target, opos, state, last, wrap, url); try { // Eliminate copying on Open/Oracle JDK if (STRING_CONSTRUCTOR != null) { return STRING_CONSTRUCTOR.newInstance(target, Boolean.TRUE); } } catch (Exception e) { // Ignoring on purpose } return new String(target); } /** * Gets the last position where encoding left off in the last byte array that was used. * If the target for encoded content does not have the necessary capacity, this method should be used to * determine where to start from on subsequent reads. * * @return the last known read position */ public int getLastInputPosition() { return lastPos; } /** * Completes an encoding session by writing out the necessary padding. This is essential to complying * with the Base64 format. This method will write at most 4 or 2 bytes starting at pos,depending on * whether or not wrapping is enabled. * *

         *  Encoder encoder = FlexBase64.createEncoder(false);
         *  byte[] outBuffer = new byte[13];
         *
         *  // Encodes "ello"
         *  int outPosition = encoder.encode("hello".getBytes("US-ASCII"), 0, 4, outBuffer, 5, 13);
         *  outPosition = encoder.complete(outBuffer, outPosition);
         *
         *  // Prints "13 : aGVsbA=="
         *  System.out.println(outPosition + " : " + new String(outBuffer, 0, 5, outPosition - 5));
         * 
* * @param target the byte array to write to * @param pos the position to start writing at * @return the position after the last byte written */ public int complete(byte[] target, int pos) { if (state > 0) { target[pos++] = encodingTable[last]; for (int i = state; i < 3; i++) { target[pos++] = (byte)'='; } last = state = 0; } if (wrap) { target[pos++] = 0x0D; target[pos++] = 0x0A; } return pos; } private static int complete(char[] target, int pos, int state, int last, boolean wrap, boolean url) { if (state > 0) { target[pos++] = (char) (url ? URL_ENCODING_TABLE : STANDARD_ENCODING_TABLE)[last]; for (int i = state; i < 3; i++) { target[pos++] = '='; } } if (wrap) { target[pos++] = 0x0D; target[pos++] = 0x0A; } return pos; } private static int complete(byte[] target, int pos, int state, int last, boolean wrap, boolean url) { if (state > 0) { target[pos++] = (url ? URL_ENCODING_TABLE : STANDARD_ENCODING_TABLE)[last]; for (int i = state; i < 3; i++) { target[pos++] = '='; } } if (wrap) { target[pos++] = 0x0D; target[pos++] = 0x0A; } return pos; } /** * Completes an encoding session by writing out the necessary padding. This is essential to complying * with the Base64 format. This method will write at most 4 or 2 bytes, depending on whether or not wrapping * is enabled. * * @param target the byte buffer to write to */ public void complete(ByteBuffer target) { if (state > 0) { target.put(encodingTable[last]); for (int i = state; i < 3; i++) { target.put((byte)'='); } last = state = 0; } if (wrap) { target.putShort((short)0x0D0A); } count = 0; } } /** * Controls the decoding process. */ public static final class Decoder { private int state; private int last; private int lastPos; private final byte[] decodingTable; private static final int SKIP = 0x0FD00; private static final int MARK = 0x0FE00; private static final int DONE = 0x0FF00; private static final int ERROR = 0xF0000; private Decoder(boolean url) { this.decodingTable = url ? URL_DECODING_TABLE : STANDARD_DECODING_TABLE; } private int nextByte(ByteBuffer buffer, int state, int last, boolean ignoreErrors) throws IOException { return nextByte(buffer.get() & 0xFF, state, last, ignoreErrors); } private int nextByte(Object source, int pos, int state, int last, boolean ignoreErrors) throws IOException { int c; if (source instanceof byte[]) { c = ((byte[])source)[pos] & 0xFF; } else if (source instanceof String) { c = ((String)source).charAt(pos) & 0xFF; } else { throw new IllegalArgumentException(); } return nextByte(c, state, last, ignoreErrors); } private int nextByte(int c, int state, int last, boolean ignoreErrors) throws IOException { if (last == MARK) { if (c != '=') { throw new IOException("Expected padding character"); } return DONE; } if (c == '=') { if (state == 2) { return MARK; } else if (state == 3) { return DONE; } else { throw new IOException("Unexpected padding character"); } } if (c == ' ' || c == '\t' || c == '\r' || c == '\n') { return SKIP; } if (c < 43 || c > 122) { if (ignoreErrors) { return ERROR; } throw new IOException("Invalid base64 character encountered: " + c); } int b = (decodingTable[c - 43] & 0xFF) - 1; if (b < 0) { if (ignoreErrors) { return ERROR; } throw new IOException("Invalid base64 character encountered: " + c); } return b; } /** * Decodes one Base64 byte buffer into another. This method will return and save state * if the target does not have the required capacity. Subsequent calls with a new target will * resume reading where it last left off (the source buffer's position). Similarly not all of the * source data need be available, this method can be repetitively called as data is made available. * *

The decoder will skip white space, but will error if it detects corruption.

* * @param source the byte buffer to read encoded data from * @param target the byte buffer to write decoded data to * @throws IOException if the encoded data is corrupted */ public void decode(ByteBuffer source, ByteBuffer target) throws IOException { if (target == null) throw new IllegalStateException(); int last = this.last; int state = this.state; int remaining = source.remaining(); int targetRemaining = target.remaining(); int b = 0; while (remaining-- > 0 && targetRemaining > 0) { b = nextByte(source, state, last, false); if (b == MARK) { last = MARK; if (--remaining <= 0) { break; } b = nextByte(source, state, last, false); } if (b == DONE) { last = state = 0; break; } if (b == SKIP) { continue; } // ( 6 | 2) (4 | 4) (2 | 6) if (state == 0) { last = b << 2; state++; if (remaining-- <= 0) { break; } b = nextByte(source, state, last, false); if ((b & 0xF000) != 0) { source.position(source.position() - 1); continue; } } if (state == 1) { target.put((byte)(last | (b >>> 4))); last = (b & 0x0F) << 4; state++; if (remaining-- <= 0 || --targetRemaining <= 0) { break; } b = nextByte(source, state, last, false); if ((b & 0xF000) != 0) { source.position(source.position() - 1); continue; } } if (state == 2) { target.put((byte) (last | (b >>> 2))); last = (b & 0x3) << 6; state++; if (remaining-- <= 0 || --targetRemaining <= 0) { break; } b = nextByte(source, state, last, false); if ((b & 0xF000) != 0) { source.position(source.position() - 1); continue; } } if (state == 3) { target.put((byte)(last | b)); last = state = 0; targetRemaining--; } } if (remaining > 0) { drain(source, b, state, last); } this.last = last; this.state = state; this.lastPos = source.position(); } private void drain(ByteBuffer source, int b, int state, int last) { while (b != DONE && source.remaining() > 0) { try { b = nextByte(source, state, last, true); } catch (IOException e) { b = 0; } if (b == MARK) { last = MARK; continue; } // Not WS/pad if ((b & 0xF000) == 0) { source.position(source.position() - 1); break; } } if (b == DONE) { // SKIP one line of trailing whitespace while (source.remaining() > 0) { b = source.get(); if (b == '\n') { break; } else if (b != ' ' && b != '\t' && b != '\r') { source.position(source.position() - 1); break; } } } } private int drain(Object source, int pos, int limit, int b, int state, int last) { while (b != DONE && limit > pos) { try { b = nextByte(source, pos++, state, last, true); } catch (IOException e) { b = 0; } if (b == MARK) { last = MARK; continue; } // Not WS/pad if ((b & 0xF000) == 0) { pos--; break; } } if (b == DONE) { // SKIP one line of trailing whitespace while (limit > pos) { if (source instanceof byte[]) { b = ((byte[])source)[pos++] & 0xFF; } else if (source instanceof String) { b = ((String)source).charAt(pos++) & 0xFF; } else { throw new IllegalArgumentException(); } if (b == '\n') { break; } else if (b != ' ' && b != '\t' && b != '\r') { pos--; break; } } } return pos; } private int decode(Object source, int sourcePos, int sourceLimit, byte[] target, int targetPos, int targetLimit) throws IOException { if (target == null) throw new IllegalStateException(); int last = this.last; int state = this.state; int pos = sourcePos; int opos = targetPos; int limit = sourceLimit; int olimit = targetLimit; int b = 0; while (limit > pos && olimit > opos) { b = nextByte(source, pos++, state, last, false); if (b == MARK) { last = MARK; if (pos >= limit) { break; } b = nextByte(source, pos++, state, last, false); } if (b == DONE) { last = state = 0; break; } if (b == SKIP) { continue; } // ( 6 | 2) (4 | 4) (2 | 6) if (state == 0) { last = b << 2; state++; if (pos >= limit) { break; } b = nextByte(source, pos++, state, last, false); if ((b & 0xF000) != 0) { pos--; continue; } } if (state == 1) { target[opos++] = ((byte)(last | (b >>> 4))); last = (b & 0x0F) << 4; state++; if (pos >= limit || opos >= olimit) { break; } b = nextByte(source, pos++, state, last, false); if ((b & 0xF000) != 0) { pos--; continue; } } if (state == 2) { target[opos++] = ((byte) (last | (b >>> 2))); last = (b & 0x3) << 6; state++; if (pos >= limit || opos >= olimit) { break; } b = nextByte(source, pos++, state, last, false); if ((b & 0xF000) != 0) { pos--; continue; } } if (state == 3) { target[opos++] = ((byte)(last | b)); last = state = 0; } } if (limit > pos) { pos = drain(source, pos, limit, b, state, last); } this.last = last; this.state = state; this.lastPos = pos; return opos; } /** * Gets the last position where decoding left off in the last byte array that was used for reading. * If the target for decoded content does not have the necessary capacity, this method should be used to * determine where to start from on subsequent decode calls. * * @return the last known read position */ public int getLastInputPosition() { return lastPos; } /** * Decodes one Base64 byte array into another byte array. If the source limit is hit, this method will * return and save the current state, such that future calls can resume the decoding process. Likewise, * if the target does not have the capacity, this method will also return and save state for subsequent * calls to this method. * *

When multiple calls are made, {@link #getLastInputPosition()} should be used to determine what value * should be set for sourcePos. Likewise, the returned target position should be used as the targetPos * in a subsequent call.

* *

The decoder will skip white space, but will error if it detects corruption.

* * @param source a Base64 encoded string to decode data from * @param sourcePos the position in the source array to start decoding from * @param sourceLimit the position in the source array to halt decoding when hit (exclusive) * @param target the byte buffer to write decoded data to * @param targetPos the position in the target byte array to begin writing at * @param targetLimit the position in the target byte array to halt writing (exclusive) * @throws IOException if the encoded data is corrupted * @return the position in the target array immediately following the last byte written * */ public int decode(String source, int sourcePos, int sourceLimit, byte[] target, int targetPos, int targetLimit) throws IOException { return decode((Object)source, sourcePos, sourceLimit, target, targetPos, targetLimit); } /** * Decodes a Base64 encoded string into the passed byte array. This method will return and save state * if the target does not have the required capacity. Subsequent calls with a new target will * resume reading where it last left off (the source buffer's position). Similarly not all of the * source data need be available, this method can be repetitively called as data is made available. * *

Since this method variant assumes a position of 0 and a limit of the item length, * repeated calls will need fresh source and target values. {@link #decode(String, int, int, byte[], int, int)} * would be a better fit if you need reuse

* *

The decoder will skip white space, but will error if it detects corruption.

* * @param source a base64 encoded string to decode from * @param target a byte array to write to * @throws java.io.IOException if the base64 content is malformed * @return output position following the last written byte */ public int decode(String source, byte[] target) throws IOException { return decode(source, 0, source.length(), target, 0, target.length); } /** * Decodes one Base64 byte array into another byte array. If the source limit is hit, this method will * return and save the current state, such that future calls can resume the decoding process. Likewise, * if the target does not have the capacity, this method will also return and save state for subsequent * calls to this method. * *

When multiple calls are made, {@link #getLastInputPosition()} should be used to determine what value * should be set for sourcePos. Likewise, the returned target position should be used as the targetPos * in a subsequent call.

* *

The decoder will skip white space, but will error if it detects corruption.

* *

         *  Decoder decoder = FlexBase64.createDecoder();
         *  byte[] outBuffer = new byte[10];
         *  byte[] bytes = "aGVsbG8=".getBytes("US-ASCII");
         *  // Decode only 2 bytes
         *  int outPosition = decoder.decode(bytes, 0, 8, outBuffer, 5, 7);
         *  // Resume where we left off and get the rest
         *  outPosition = decoder.decode(bytes, decoder.getLastInputPosition(), 8, outBuffer, outPosition, 10);
         *  // Prints "10 : Hello"
         *  System.out.println(outPosition + " : " + new String(outBuffer, 0, 5, outPosition - 5));
         * 
* * * @param source the byte array to read encoded data from * @param sourcePos the position in the source array to start decoding from * @param sourceLimit the position in the source array to halt decoding when hit (exclusive) * @param target the byte buffer to write decoded data to * @param targetPos the position in the target byte array to begin writing at * @param targetLimit the position in the target byte array to halt writing (exclusive) * @throws IOException if the encoded data is corrupted * @return the position in the target array immediately following the last byte written */ public int decode(byte[] source, int sourcePos, int sourceLimit, byte[] target, int targetPos, int targetLimit) throws IOException { return decode((Object)source, sourcePos, sourceLimit, target, targetPos, targetLimit); } private static ByteBuffer decode(String source, boolean url) throws IOException { int remainder = source.length() % 4; int size = ((source.length() / 4) + (remainder == 0 ? 0 : 4 - remainder)) * 3; byte[] buffer = new byte[size]; int actual = new Decoder(url).decode(source, 0, source.length(), buffer, 0, size); return ByteBuffer.wrap(buffer, 0, actual); } private static ByteBuffer decode(byte[] source, int off, int limit, boolean url) throws IOException { int len = limit - off; int remainder = len % 4; int size = ((len / 4) + (remainder == 0 ? 0 : 4 - remainder)) * 3; byte[] buffer = new byte[size]; int actual = new Decoder(url).decode(source, off, limit, buffer, 0, size); return ByteBuffer.wrap(buffer, 0, actual); } private static ByteBuffer decode(ByteBuffer source, boolean url) throws IOException { int len = source.remaining(); int remainder = len % 4; int size = ((len / 4) + (remainder == 0 ? 0 : 4 - remainder)) * 3; ByteBuffer buffer = ByteBuffer.allocate(size); new Decoder(url).decode(source, buffer); buffer.flip(); return buffer; } } /** * An input stream which decodes bytes as they are read from a stream with Base64 encoded data. */ public static class DecoderInputStream extends InputStream { private final InputStream input; private final byte[] buffer; private final Decoder decoder = createDecoder(); private int pos = 0; private int limit = 0; private byte[] one; private DecoderInputStream(InputStream input) { this(input, 8192); } private DecoderInputStream(InputStream input, int bufferSize) { this.input = input; buffer = new byte[bufferSize]; } private int fill() throws IOException { byte[] buffer = this.buffer; int read = input.read(buffer, 0, buffer.length); pos = 0; limit = read; return read; } /** * {@inheritDoc} */ @Override public int read(byte[] b, int off, int len) throws IOException { for (;;) { byte[] source = buffer; int pos = this.pos; int limit = this.limit; boolean setPos = true; if (pos >= limit) { if (len > source.length) { source = new byte[len]; limit = input.read(source, 0, len); pos = 0; setPos = false; } else { limit = fill(); pos = 0; } if (limit == -1) { return -1; } } int requested = len + pos; limit = limit > requested ? requested : limit; int read = decoder.decode(source, pos, limit, b, off, off+len) - off; if (setPos) { this.pos = decoder.getLastInputPosition(); } if (read > 0) { return read; } } } /** * {@inheritDoc} */ @Override public int read() throws IOException { byte[] one = this.one; if (one == null) { one = this.one = new byte[1]; } int read = this.read(one, 0, 1); return read > 0 ? one[0] & 0xFF : -1; } /** * {@inheritDoc} */ @Override public void close() throws IOException { input.close(); } } /** * An input stream which encodes bytes as they are read from a stream. */ public static class EncoderInputStream extends InputStream { private final InputStream input; private final byte[] buffer; private final byte[] overflow = new byte[6]; private int overflowPos; private int overflowLimit; private final Encoder encoder; private int pos = 0; private int limit = 0; private byte[] one; private boolean complete; private EncoderInputStream(InputStream input) { this(input, 8192, true, false); } private EncoderInputStream(InputStream input, int bufferSize, boolean wrap, boolean url) { this.input = input; buffer = new byte[bufferSize]; this.encoder = new Encoder(wrap, url); } private int fill() throws IOException { byte[] buffer = this.buffer; int read = input.read(buffer, 0, buffer.length); pos = 0; limit = read; return read; } /** * {@inheritDoc} */ @Override public int read() throws IOException { byte[] one = this.one; if (one == null) { one = this.one = new byte[1]; } int read = this.read(one, 0, 1); return read > 0 ? one[0] & 0xFF : -1; } /** * {@inheritDoc} */ @Override public int read(byte[] b, int off, int len) throws IOException { byte[] buffer = this.buffer; byte[] overflow = this.overflow; int overflowPos = this.overflowPos; int overflowLimit = this.overflowLimit; boolean complete = this.complete; boolean wrap = encoder.wrap; int copy = 0; if (overflowPos < overflowLimit) { copy = copyOverflow(b, off, len, overflow, overflowPos, overflowLimit); if (len <= copy || complete) { return copy; } len -= copy; off += copy; } else if (complete) { return -1; } for (;;) { byte[] source = buffer; int pos = this.pos; int limit = this.limit; boolean setPos = true; if (pos >= limit) { if (len > source.length) { // If requested length exceeds buffer, allocate a new temporary buffer that will be // one block less than an exact encoded output. This is to handle partial quad carryover // from an earlier read. int adjust = (len / 4 * 3) - 3; if (wrap) { adjust -= adjust / 76 * 2 + 2; } source = new byte[adjust]; limit = input.read(source, 0, adjust); pos = 0; setPos = false; } else { limit = fill(); pos = 0; } if (limit <= 0) { this.complete = true; if (len < (wrap ? 4 : 2)) { overflowLimit = encoder.complete(overflow, 0); this.overflowLimit = overflowLimit; int ret = copyOverflow(b, off, len, overflow, 0, overflowLimit) + copy; return ret == 0 ? -1 : ret; } int ret = encoder.complete(b, off) - off + copy; return ret == 0 ? -1 : ret; } } if (len < (wrap ? 6 : 4)) { overflowLimit = encoder.encode(source, pos, limit, overflow, 0, overflow.length); this.overflowLimit = overflowLimit; this.pos = encoder.getLastInputPosition(); return copyOverflow(b, off, len, overflow, 0, overflowLimit) + copy; } int read = encoder.encode(source, pos, limit, b, off, off+len) - off; if (setPos) { this.pos = encoder.getLastInputPosition(); } if (read > 0) { return read + copy; } } } private int copyOverflow(byte[] b, int off, int len, byte[] overflow, int pos, int limit) { limit -= pos; len = limit <= len ? limit : len; System.arraycopy(overflow, pos, b, off, len); this.overflowPos = pos + len; return len; } } /** * An output stream which base64 encodes all passed data and writes it to the wrapped target output stream. * *

Closing this stream will result in the correct padding sequence being written. However, as * required by the OutputStream contract, the wrapped stream will also be closed. If this is not desired, * the {@link #complete()} method should be used.

*/ public static class EncoderOutputStream extends OutputStream { private final OutputStream output; private final byte[] buffer; private final Encoder encoder; private int pos = 0; private byte[] one; private EncoderOutputStream(OutputStream output) { this(output, 8192, true); } private EncoderOutputStream(OutputStream output, int bufferSize, boolean wrap) { this.output = output; this.buffer = new byte[bufferSize]; this.encoder = createEncoder(wrap); } /** * {@inheritDoc} */ @Override public void write(byte[] b, int off, int len) throws IOException { byte[] buffer = this.buffer; Encoder encoder = this.encoder; int pos = this.pos; int limit = off + len; int ipos = off; while (ipos < limit) { pos = encoder.encode(b, ipos, limit, buffer, pos, buffer.length); int last = encoder.getLastInputPosition(); if (last == ipos || pos >= buffer.length) { output.write(buffer, 0, pos); pos = 0; } ipos = last; } this.pos = pos; } /** * {@inheritDoc} */ @Override public void write(int b) throws IOException { byte[] one = this.one; if (one == null) { this.one = one = new byte[1]; } one[0] = (byte)b; write(one, 0, 1); } /** * {@inheritDoc} */ @Override public void flush() throws IOException { OutputStream output = this.output; output.write(buffer, 0, pos); output.flush(); } /** * Completes the stream, writing out base64 padding characters if needed. * * @throws IOException if the underlying stream throws one */ public void complete() throws IOException { OutputStream output = this.output; byte[] buffer = this.buffer; int pos = this.pos; boolean completed = false; if (buffer.length - pos >= (encoder.wrap ? 2 : 4)) { this.pos = encoder.complete(buffer, pos); completed = true; } flush(); if (!completed) { int len = encoder.complete(buffer, 0); output.write(buffer, 0, len); output.flush(); } } /** * {@inheritDoc} */ @Override public void close() throws IOException { try { complete(); } catch (IOException e) { // eat } try { output.flush(); } catch (IOException e) { // eat } output.close(); } } /** * An output stream which decodes base64 data written to it, and writes the decoded output to the * wrapped inner stream. */ public static class DecoderOutputStream extends OutputStream { private final OutputStream output; private final byte[] buffer; private final Decoder decoder; private int pos = 0; private byte[] one; private DecoderOutputStream(OutputStream output) { this(output, 8192); } private DecoderOutputStream(OutputStream output, int bufferSize) { this.output = output; this.buffer = new byte[bufferSize]; this.decoder = createDecoder(); } /** * {@inheritDoc} */ @Override public void write(byte[] b, int off, int len) throws IOException { byte[] buffer = this.buffer; Decoder decoder = this.decoder; int pos = this.pos; int limit = off + len; int ipos = off; while (ipos < limit) { pos = decoder.decode(b, ipos, limit, buffer, pos, buffer.length); int last = decoder.getLastInputPosition(); if (last == ipos || pos >= buffer.length) { output.write(buffer, 0, pos); pos = 0; } ipos = last; } this.pos = pos; } /** * {@inheritDoc} */ @Override public void write(int b) throws IOException { byte[] one = this.one; if (one == null) { this.one = one = new byte[1]; } one[0] = (byte)b; write(one, 0, 1); } /** * {@inheritDoc} */ @Override public void flush() throws IOException { OutputStream output = this.output; output.write(buffer, 0, pos); output.flush(); } /** * {@inheritDoc} */ @Override public void close() throws IOException { try { flush(); } catch (IOException e) { // eat } try { output.flush(); } catch (IOException e) { // eat } output.close(); } } }




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