Beispiel #1
0
  // Writes a C string and expands the frame if necessary
  // FIXME: Property strings containing nul ('\0') characters will corrupt the frame when they are
  // written.
  //        Figure out how to throw an exception here if any nul chars are encountered
  private static ByteBuffer writeCString(ByteBuffer frame, String string) {
    Byte b = propertyAbbreviations.get(string);
    if (b != null) {
      if (frame.remaining() < 2)
        frame = ByteBuffer.allocate(frame.capacity() << 1).put((ByteBuffer) frame.rewind());
      frame.put(b);
      frame.put((byte) 0);
    } else {
      CharsetEncoder cStringEncoder = cStringCharset.newEncoder();

      CharBuffer chars = CharBuffer.wrap(string);
      for (int size = frame.capacity(); ; cStringEncoder.flush(frame)) {
        cStringEncoder.reset();
        if (cStringEncoder.encode(chars, frame, true) == CoderResult.OVERFLOW) {
          // debug output
          // System.out.println("overflow, reallocating to size " + (size << 1) + " (printing \"" +
          // string + "\")");
          frame = ByteBuffer.allocate(size = (size << 1)).put((ByteBuffer) frame.rewind());
        } else break;
      }
      cStringEncoder.flush(frame);
      frame.put((byte) 0);
    }
    return frame;
  }
Beispiel #2
0
 public SVNCharsetConvertor reset() {
   myEncoder = myEncoder.reset();
   myDecoder = myDecoder.reset();
   myCharBuffer = null;
   myInputByteBuffer = null;
   return this;
 }
Beispiel #3
0
 static byte[] encode(char[] cc, Charset cs, boolean testDirect, Time t) throws Exception {
   ByteBuffer bbf;
   CharBuffer cbf;
   CharsetEncoder enc = cs.newEncoder();
   String csn = cs.name();
   if (testDirect) {
     bbf = ByteBuffer.allocateDirect(cc.length * 4);
     cbf = ByteBuffer.allocateDirect(cc.length * 2).asCharBuffer();
     cbf.put(cc).flip();
   } else {
     bbf = ByteBuffer.allocate(cc.length * 4);
     cbf = CharBuffer.wrap(cc);
   }
   CoderResult cr = null;
   long t1 = System.nanoTime() / 1000;
   for (int i = 0; i < iteration; i++) {
     cbf.rewind();
     bbf.clear();
     enc.reset();
     cr = enc.encode(cbf, bbf, true);
   }
   long t2 = System.nanoTime() / 1000;
   t.t = (t2 - t1) / iteration;
   if (cr != CoderResult.UNDERFLOW) {
     System.out.println("ENC-----------------");
     int pos = cbf.position();
     System.out.printf("  cr=%s, cbf.pos=%d, cc[pos]=%x%n", cr.toString(), pos, cc[pos] & 0xffff);
     throw new RuntimeException("Encoding err: " + csn);
   }
   byte[] bb = new byte[bbf.position()];
   bbf.flip();
   bbf.get(bb);
   return bb;
 }
Beispiel #4
0
 public static int encode(
     final CharsetEncoder ce,
     final char[] ca,
     final int off,
     final int len,
     final byte[] targetArray) {
   if (len == 0) {
     return 0;
   }
   if (ce instanceof ArrayEncoder) {
     return ((ArrayEncoder) ce).encode(ca, off, len, targetArray);
   } else {
     ce.reset();
     ByteBuffer bb = ByteBuffer.wrap(targetArray);
     CharBuffer cb = CharBuffer.wrap(ca, off, len);
     try {
       CoderResult cr = ce.encode(cb, bb, true);
       if (!cr.isUnderflow()) {
         cr.throwException();
       }
       cr = ce.flush(bb);
       if (!cr.isUnderflow()) {
         cr.throwException();
       }
     } catch (CharacterCodingException x) {
       throw new Error(x);
     }
     return bb.position();
   }
 }
Beispiel #5
0
  public static void write(ICharsetCodec cc, CharBuffer cb, IUnitChain unitChain) {
    final CharsetEncoder encoder = cc.getEncoder();
    try {
      IUnit unit = Util.lastUnit(unitChain);
      ByteBuffer bb = unit.getByteBufferForWrite();

      boolean flush = false;
      encoder.reset();
      for (; ; ) {
        CoderResult cr = flush ? encoder.flush(bb) : encoder.encode(cb, bb, true);
        unit.size(bb.position() - unit.start());
        if (cr.isOverflow()) {
          unit = Util.appendNewUnit(unitChain);
          bb = unit.getByteBufferForWrite();
          continue;
        }

        if (!cr.isUnderflow()) cr.throwException();

        if (flush) break;
        else flush = true;
      }
    } catch (CharacterCodingException e) {
      throw new RuntimeException(e);
    } finally {
      cc.releaseEncoder(encoder);
    }
  }
Beispiel #6
0
    byte[] encode(char[] ca, int off, int len) {

      int en = (int) (ce.maxBytesPerChar() * len);

      byte[] ba = new byte[en];

      if (len == 0) return ba;

      ce.reset();

      ByteBuffer bb = ByteBuffer.wrap(ba);

      CharBuffer cb = CharBuffer.wrap(ca, off, len);

      try {

        CoderResult cr = ce.encode(cb, bb, true);

        if (!cr.isUnderflow()) cr.throwException();

        cr = ce.flush(bb);

        if (!cr.isUnderflow()) cr.throwException();

      } catch (CharacterCodingException x) {

        // Substitution is always enabled,

        // so this shouldn't happen

        throw new Error(x);
      }

      return trim(ba, bb.position());
    }
Beispiel #7
0
  private static void writeEntry(
      OutputStream os, Attributes.Name name, String value, CharsetEncoder encoder, ByteBuffer bBuf)
      throws IOException {
    byte[] out = name.getBytes();
    if (out.length > LINE_LENGTH_LIMIT) {
      throw new IOException(
          Messages.getString(
              "archive.33", name, Integer.valueOf(LINE_LENGTH_LIMIT))); // $NON-NLS-1$
    }

    os.write(out);
    os.write(VALUE_SEPARATOR);

    encoder.reset();
    bBuf.clear().limit(LINE_LENGTH_LIMIT - out.length - 2);

    CharBuffer cBuf = CharBuffer.wrap(value);
    CoderResult r;

    while (true) {
      r = encoder.encode(cBuf, bBuf, true);
      if (CoderResult.UNDERFLOW == r) {
        r = encoder.flush(bBuf);
      }
      os.write(bBuf.array(), bBuf.arrayOffset(), bBuf.position());
      os.write(LINE_SEPARATOR);
      if (CoderResult.UNDERFLOW == r) {
        break;
      }
      os.write(' ');
      bBuf.clear().limit(LINE_LENGTH_LIMIT - 1);
    }
  }
  @JRubyMethod
  public IRubyObject convert(ThreadContext context, IRubyObject srcBuffer) {
    if (!(srcBuffer instanceof RubyString)) {
      throw context.runtime.newTypeError(srcBuffer, context.runtime.getString());
    }

    RubyString srcString = (RubyString) srcBuffer;

    ByteList srcBL = srcString.getByteList();

    if (srcBL.getRealSize() == 0) return context.runtime.newSymbol("source_buffer_empty");

    ByteBuffer srcBB = ByteBuffer.wrap(srcBL.getUnsafeBytes(), srcBL.begin(), srcBL.getRealSize());
    try {
      CharBuffer srcCB =
          CharBuffer.allocate((int) (srcDecoder.maxCharsPerByte() * srcBL.getRealSize()) + 1);
      CoderResult decodeResult = srcDecoder.decode(srcBB, srcCB, true);
      srcCB.flip();

      ByteBuffer destBB =
          ByteBuffer.allocate((int) (destEncoder.maxBytesPerChar() * srcCB.limit()) + 1);
      CoderResult encodeResult = destEncoder.encode(srcCB, destBB, true);
      destBB.flip();

      byte[] destBytes = new byte[destBB.limit()];
      destBB.get(destBytes);

      srcDecoder.reset();
      destEncoder.reset();

      return context.runtime.newString(new ByteList(destBytes, destEncoding.getEncoding(), false));
    } catch (Exception e) {
      throw context.runtime.newRuntimeError(e.getLocalizedMessage());
    }
  }
Beispiel #9
0
  private IRubyObject iconv(IRubyObject str, int start, int end) {
    if (str.isNil()) {
      fromEncoding.reset();
      toEncoding.reset();
      return RubyString.newEmptyString(getRuntime());
    }

    return _iconv(str.convertToString(), start, end);
  }
  public byte[] encode(char[] chars, int off, int len) {
    if (len == 0) {
      return new byte[0];
    }

    encoder.reset();

    int bytesLength = scale(len, encoder.maxBytesPerChar());

    byte[] bytes = ThreadLocalCache.getBytes(bytesLength);

    return encode(chars, off, len, bytes);
  }
Beispiel #11
0
 /** Encode a string into a ByteBuffer : on return position is the end of the encoding */
 public static int toByteBuffer(CharSequence s, ByteBuffer bb, CharsetEncoder enc) {
   int start = bb.position();
   CharBuffer cBuff = CharBuffer.wrap(s);
   enc.reset();
   CoderResult r = enc.encode(cBuff, bb, true);
   if (r.isOverflow()) throw new InternalErrorException("Bytes.toByteBuffer: encode overflow (1)");
   r = enc.flush(bb);
   if (r.isOverflow()) throw new InternalErrorException("Bytes.toByteBuffer: encode overflow (2)");
   //        if ( r.isUnderflow() )
   //            throw new InternalErrorException("Bytes.toByteBuffer: encode underflow") ;
   int finish = bb.position();
   return finish - start;
 }
  static void testMixed(Charset cs) throws Throwable {
    CharsetDecoder dec =
        cs.newDecoder()
            .onMalformedInput(CodingErrorAction.REPLACE)
            .onUnmappableCharacter(CodingErrorAction.REPLACE);
    CharsetEncoder enc =
        cs.newEncoder()
            .onMalformedInput(CodingErrorAction.REPLACE)
            .onUnmappableCharacter(CodingErrorAction.REPLACE);
    List<Integer> cps = new ArrayList<>(0x10000);
    int off = 0;
    int cp = 0;
    while (cp < 0x10000) {
      if (enc.canEncode((char) cp)) {
        cps.add(cp);
      }
      cp++;
    }
    Collections.shuffle(cps);
    char[] bmpCA = new char[cps.size()];
    for (int i = 0; i < cps.size(); i++) bmpCA[i] = (char) (int) cps.get(i);
    String bmpStr = new String(bmpCA);
    // getBytes(csn);
    byte[] bmpBA = bmpStr.getBytes(cs.name());
    ByteBuffer bf = enc.reset().encode(CharBuffer.wrap(bmpCA));
    byte[] baNIO = new byte[bf.limit()];
    bf.get(baNIO, 0, baNIO.length);
    if (!Arrays.equals(bmpBA, baNIO)) {
      throw new RuntimeException("getBytes(csn) failed  -> " + cs.name());
    }

    // getBytes(cs);
    bmpBA = bmpStr.getBytes(cs);
    if (!Arrays.equals(bmpBA, baNIO))
      throw new RuntimeException("getBytes(cs) failed  -> " + cs.name());

    // new String(csn);
    String strSC = new String(bmpBA, cs.name());
    String strNIO = dec.reset().decode(ByteBuffer.wrap(bmpBA)).toString();
    if (!strNIO.equals(strSC)) {
      throw new RuntimeException("new String(csn) failed  -> " + cs.name());
    }

    // new String(cs);
    strSC = new String(bmpBA, cs);
    if (!strNIO.equals(strSC)) throw new RuntimeException("new String(cs) failed  -> " + cs.name());
  }
Beispiel #13
0
  /**
   * Encodes any String into a buffer to send it with a message
   *
   * @param content the String to encode into a buffer
   * @return a buffer containing the (encoded) String.
   */
  public static Buffer encodeString(String content) {
    if (content == null) {
      return null;
    }

    ByteBuffer byteBuffer;
    synchronized (encoder) {
      encoder.reset();
      try {
        byteBuffer = encoder.encode(CharBuffer.wrap(content));
      } catch (CharacterCodingException e) {
        return null;
      }
      encoder.flush(byteBuffer);
    }
    ByteBuf wrappedBuffer = Unpooled.wrappedBuffer(byteBuffer);
    return new Buffer(wrappedBuffer);
  }
  private void fillBuffer() throws IOException {
    _byteBuf.clear();
    _charBuf.clear();

    while (_byteBuf.position() == 0) {
      fillCharBuf();
      if (_charBuf.limit() == 0) {
        _byteBuf.limit(0);
        return;
      }

      _encoder.reset();
      CoderResult rslt = _encoder.encode(_charBuf, _byteBuf, true);
      // FIXME - optionally throw on malformed input
      _encoder.flush(_byteBuf);
    }

    _byteBuf.limit(_byteBuf.position());
    _byteBuf.position(0);
  }
Beispiel #15
0
 static CoderResult encodeCR(char[] cc, Charset cs, boolean testDirect) throws Exception {
   ByteBuffer bbf;
   CharBuffer cbf;
   CharsetEncoder enc = cs.newEncoder();
   if (testDirect) {
     bbf = ByteBuffer.allocateDirect(cc.length * 4);
     cbf = ByteBuffer.allocateDirect(cc.length * 2).asCharBuffer();
     cbf.put(cc).flip();
   } else {
     bbf = ByteBuffer.allocate(cc.length * 4);
     cbf = CharBuffer.wrap(cc);
   }
   CoderResult cr = null;
   for (int i = 0; i < iteration; i++) {
     cbf.rewind();
     bbf.clear();
     enc.reset();
     cr = enc.encode(cbf, bbf, true);
   }
   return cr;
 }
  /**
   * Write the UTF-8 representation of a single Unicode code point to the terminal output. The
   * written data will be consumed by the emulation client as input.
   *
   * <p>This implementation encodes the code point and then calls {@link #write(byte[], int, int)}
   * to do the actual writing. It should therefore usually be unnecessary to override this method;
   * override {@link #write(byte[], int, int)} instead.
   *
   * @param codePoint The Unicode code point to write to the terminal.
   */
  public void write(int codePoint) {
    ByteBuffer byteBuf = mWriteByteBuffer;
    if (codePoint < 128) {
      // Fast path for ASCII characters
      byte[] buf = byteBuf.array();
      buf[0] = (byte) codePoint;
      write(buf, 0, 1);
      return;
    }

    CharBuffer charBuf = mWriteCharBuffer;
    CharsetEncoder encoder = mUTF8Encoder;

    charBuf.clear();
    byteBuf.clear();
    Character.toChars(codePoint, charBuf.array(), 0);
    encoder.reset();
    encoder.encode(charBuf, byteBuf, true);
    encoder.flush(byteBuf);
    write(byteBuf.array(), 0, byteBuf.position() - 1);
  }
 byte[] encode(char[] ca, int off, int len) {
   int en = scale(len, ce.maxBytesPerChar());
   byte[] ba = new byte[en];
   if (len == 0) return ba;
   if (ce instanceof ArrayEncoder) {
     int blen = ((ArrayEncoder) ce).encode(ca, off, len, ba);
     return safeTrim(ba, blen, cs, isTrusted);
   } else {
     ce.reset();
     ByteBuffer bb = ByteBuffer.wrap(ba);
     CharBuffer cb = CharBuffer.wrap(ca, off, len);
     try {
       CoderResult cr = ce.encode(cb, bb, true);
       if (!cr.isUnderflow()) cr.throwException();
       cr = ce.flush(bb);
       if (!cr.isUnderflow()) cr.throwException();
     } catch (CharacterCodingException x) {
       // Substitution is always enabled,
       // so this shouldn't happen
       throw new Error(x);
     }
     return safeTrim(ba, bb.position(), cs, isTrusted);
   }
 }
  /**
   * Write out as many pages as possible.
   *
   * @param force Should we write non-full pages?
   * @throws ShutdownException
   */
  private void writeOutPages(boolean force) throws ShutdownException {
    int sz = 0;
    int size = EMPTY_SIZE + 3 * current_offset;
    int currIdx = 0;
    short totalStringsLength = 0;
    string2index.clear();
    boolean stopped = false;
    for (int i = 0; i < current_offset; i++) {
      String s = strings[i];
      if (!string2index.containsKey(s)) {
        string2index.put(s, null);
        encoder.reset();
        size += 2;
        if (s != null) {
          try {
            int len = encoder.encode(CharBuffer.wrap(s)).limit();
            if (len > Short.MAX_VALUE)
              throw new ShutdownException("Cannot store strings larger than " + Short.MAX_VALUE);
            string_lengths[currIdx++] = (short) s.length();
            size += len;
            totalStringsLength += len;
          } catch (CharacterCodingException cce) {
            throw new ShutdownException("Cannot encode string " + s + " in UTF-8");
          }
        } else string_lengths[currIdx++] = 0;
        if (size >= PAGE_SIZE) {
          sz = i;
          stopped = true;
          break;
        }
      }
    }
    if (!stopped) sz = current_offset;

    if (!force && sz == current_offset && current_offset < MAX_EVENTS) return;

    string2index.clear();
    index2string.clear();

    // Index of the next string we'll add to the buffer
    short current_index = 0;
    // Number of events we can write out
    short writableEvents;
    for (writableEvents = 0; writableEvents < sz; writableEvents++) {
      // An event costs at least 3 bytes
      String s = strings[writableEvents];
      boolean newString = !string2index.containsKey(s);
      if (newString) {
        string2index.put(s, new Short(current_index));
        index2string.add(s);
        current_index++;
      }
    }

    assert writableEvents > 0;

    // Write the page at last
    // Number of events
    buffer.putShort((short) (writableEvents));
    // The event type array
    buffer.put(types, 0, writableEvents);
    // The event string array
    for (int i = 0; i < writableEvents; i++)
      buffer.putShort(((Short) string2index.get(strings[i])).shortValue());

    // The number of strings
    buffer.putShort((short) (current_index));
    buffer.putShort(totalStringsLength);
    // The string contents
    for (int i = 0; i < current_index; i++) {
      String s = (String) index2string.get(i);
      if (s == null || s.length() == 0) continue;
      encoder.encode(CharBuffer.wrap(s), sbuf, true);
      encoder.reset();
      sbuf.flip();
      buffer.put(sbuf);
      sbuf.clear();
    }
    // The string lengths
    buffer.asShortBuffer().put(string_lengths, 0, current_index);
    buffer.position(buffer.position() + 2 * current_index);

    try {
      buffer.flip();
      channel.write(buffer);
      buffer.clear();
    } catch (IOException ioe) {
      throw new ShutdownException("IO Exception while storing SAXDOM data: " + ioe.getMessage());
    }

    for (int i = writableEvents; i < current_offset; i++) {
      types[i - writableEvents] = types[i];
      strings[i - writableEvents] = strings[i];
    }
    current_offset -= writableEvents;

    if (current_offset > 0) writeOutPages(force);
  }
Beispiel #19
0
 public void startDocument() throws SAXException {
   charBuff.clear();
   byteBuff.clear();
   charEncoder.reset();
 }
Beispiel #20
0
 /**
  * Constructs a writer that encodes characters using the given encoder and writes the resulting
  * bytes to the given channel.
  *
  * <p>The resulting stream will contain an internal output buffer of at least {@code minBufferCap}
  * bytes. The stream's {@code write} methods will, as needed, flush the buffer by writing bytes to
  * the underlying channel; if the channel is in non-blocking mode when bytes are to be written
  * then an {@link IllegalBlockingModeException} will be thrown. The resulting stream will not
  * otherwise be buffered. Closing the stream will in turn cause the channel to be closed.
  *
  * @param ch The channel to which bytes will be written
  * @param enc The charset encoder to be used
  * @param minBufferCap The minimum capacity of the internal byte buffer, or {@code -1} if an
  *     implementation-dependent default capacity is to be used
  * @return A new writer
  */
 public static Writer newWriter(WritableByteChannel ch, CharsetEncoder enc, int minBufferCap) {
   Objects.requireNonNull(ch, "ch");
   return StreamEncoder.forEncoder(ch, enc.reset(), minBufferCap);
 }
  protected long buildResponseStringBuf(String s, long r, final long preChain) {
    if (s == null) {
      return 0;
    }

    if (s.length() == 0) {
      return -NGX_HTTP_NO_CONTENT;
    }

    CharsetEncoder charsetEncoder =
        ThreadLocalCoders.encoderFor(DEFAULT_ENCODING)
            .onMalformedInput(CodingErrorAction.REPLACE)
            .onUnmappableCharacter(CodingErrorAction.REPLACE);
    ByteBuffer bb = pickByteBuffer();
    CharBuffer cb = CharBuffer.wrap((char[]) UNSAFE.getObject(s, STRING_CHAR_ARRAY_OFFSET));
    charsetEncoder.reset();
    CoderResult result = CoderResult.UNDERFLOW;
    long first = 0;
    long chain = preChain;
    do {
      result = charsetEncoder.encode(cb, bb, true);
      if (result == CoderResult.OVERFLOW) {
        bb.flip();
        chain =
            ngx_http_clojure_mem_build_temp_chain(
                r, chain, bb.array(), BYTE_ARRAY_OFFSET, bb.remaining());
        if (chain <= 0) {
          return chain;
        }
        bb.clear();
        if (first == 0) {
          first = chain;
        }
      } else if (result == CoderResult.UNDERFLOW) {
        break;
      } else {
        log.error("%s can not decode string : %s", result.toString(), s);
        return -NGX_HTTP_INTERNAL_SERVER_ERROR;
      }
    } while (true);

    while (charsetEncoder.flush(bb) == CoderResult.OVERFLOW) {
      bb.flip();
      chain =
          ngx_http_clojure_mem_build_temp_chain(
              r, chain, bb.array(), BYTE_ARRAY_OFFSET, bb.remaining());
      if (chain <= 0) {
        return chain;
      }
      if (first == 0) {
        first = chain;
      }
      bb.clear();
    }

    if (bb.hasRemaining()) {
      bb.flip();
      chain =
          ngx_http_clojure_mem_build_temp_chain(
              r, chain, bb.array(), BYTE_ARRAY_OFFSET, bb.remaining());
      if (chain <= 0) {
        return chain;
      }
      if (first == 0) {
        first = chain;
      }
      bb.clear();
    }

    return preChain == 0 ? first : chain;
  }
  static void test(Charset cs, char[] bmpCA, byte[] sbBA) throws Throwable {
    String bmpStr = new String(bmpCA);
    CharsetDecoder dec =
        cs.newDecoder()
            .onMalformedInput(CodingErrorAction.REPLACE)
            .onUnmappableCharacter(CodingErrorAction.REPLACE);
    CharsetEncoder enc =
        cs.newEncoder()
            .onMalformedInput(CodingErrorAction.REPLACE)
            .onUnmappableCharacter(CodingErrorAction.REPLACE);

    // getBytes(csn);
    byte[] baSC = bmpStr.getBytes(cs.name());
    ByteBuffer bf = enc.reset().encode(CharBuffer.wrap(bmpCA));
    byte[] baNIO = new byte[bf.limit()];
    bf.get(baNIO, 0, baNIO.length);
    if (!Arrays.equals(baSC, baNIO))
      throw new RuntimeException("getBytes(csn) failed  -> " + cs.name());

    // getBytes(cs);
    baSC = bmpStr.getBytes(cs);
    if (!Arrays.equals(baSC, baNIO))
      throw new RuntimeException("getBytes(cs) failed  -> " + cs.name());

    // new String(csn);
    String strSC = new String(sbBA, cs.name());
    String strNIO = dec.reset().decode(ByteBuffer.wrap(sbBA)).toString();

    if (!strNIO.equals(strSC))
      throw new RuntimeException("new String(csn) failed  -> " + cs.name());

    // new String(cs);
    strSC = new String(sbBA, cs);
    if (!strNIO.equals(strSC)) throw new RuntimeException("new String(cs) failed  -> " + cs.name());

    // encode unmappable surrogates
    if (enc instanceof sun.nio.cs.ArrayEncoder && cs.contains(Charset.forName("ASCII"))) {
      if (cs.name().equals("UTF-8")
          || // utf8 handles surrogates
          cs.name().equals("CESU-8")) // utf8 handles surrogates
      return;
      enc.replaceWith(new byte[] {(byte) 'A'});
      sun.nio.cs.ArrayEncoder cae = (sun.nio.cs.ArrayEncoder) enc;

      String str = "ab\uD800\uDC00\uD800\uDC00cd";
      byte[] ba = new byte[str.length() - 2];
      int n = cae.encode(str.toCharArray(), 0, str.length(), ba);
      if (n != 6 || !"abAAcd".equals(new String(ba, cs.name())))
        throw new RuntimeException("encode1(surrogates) failed  -> " + cs.name());

      ba = new byte[str.length()];
      n = cae.encode(str.toCharArray(), 0, str.length(), ba);
      if (n != 6 || !"abAAcd".equals(new String(ba, 0, n, cs.name())))
        throw new RuntimeException("encode2(surrogates) failed  -> " + cs.name());
      str = "ab\uD800B\uDC00Bcd";
      ba = new byte[str.length()];
      n = cae.encode(str.toCharArray(), 0, str.length(), ba);
      if (n != 8 || !"abABABcd".equals(new String(ba, 0, n, cs.name())))
        throw new RuntimeException("encode3(surrogates) failed  -> " + cs.name());
      /* sun.nio.cs.ArrayDeEncoder works on the assumption that the
         invoker (StringCoder) allocates enough output buf, utf8
         and double-byte coder does not check the output buffer limit.
      ba = new byte[str.length() - 1];
      n = cae.encode(str.toCharArray(), 0, str.length(), ba);
      if (n != 7 || !"abABABc".equals(new String(ba, 0, n, cs.name()))) {
          throw new RuntimeException("encode4(surrogates) failed  -> "
                                     + cs.name());
      }
      */
    }
  }