// Attach to pid and perform a thread dump
private static void runThreadDump(String pid, String args[]) throws Exception {
VirtualMachine vm = null;
try {
vm = VirtualMachine.attach(pid);
} catch (Exception x) {
String msg = x.getMessage();
if (msg != null) {
System.err.println(pid + ": " + msg);
} else {
x.printStackTrace();
}
if ((x instanceof AttachNotSupportedException) && (loadSAClass() != null)) {
System.err.println(
"The -F option can be used when the target " + "process is not responding");
}
System.exit(1);
}
// Cast to HotSpotVirtualMachine as this is implementation specific
// method.
InputStream in = ((HotSpotVirtualMachine) vm).remoteDataDump((Object[]) args);
// read to EOF and just print output
byte b[] = new byte[256];
int n;
do {
n = in.read(b);
if (n > 0) {
String s = new String(b, 0, n, "UTF-8");
System.out.print(s);
}
} while (n > 0);
in.close();
vm.detach();
}
public SF2Soundbank(URL url) throws IOException {
InputStream is = url.openStream();
try {
readSoundbank(is);
} finally {
is.close();
}
}
public SF2Soundbank(File file) throws IOException {
largeFormat = true;
sampleFile = file;
InputStream is = new FileInputStream(file);
try {
readSoundbank(is);
} finally {
is.close();
}
}
private void fill() throws IOException {
if (!seenEOF) {
if (pos > 0 && pos < limit) {
System.arraycopy(inbuf, pos, inbuf, 0, limit - pos);
limit = limit - pos;
pos = 0;
} else if (pos >= limit) {
pos = 0;
limit = 0;
}
int bsize = inbuf.length;
while (limit < bsize) {
int n = underlyingInputStream.read(inbuf, limit, bsize - limit);
if (n <= 0) {
seenEOF = true;
break;
}
limit += n;
}
}
}
/**
* Constructs a MessageToken from an InputStream. Bytes will be read on demand and the thread
* might block if there are not enough bytes to complete the token. Please note there is no
* accurate way to find out the size of a token, but we try our best to make sure there is enough
* bytes to construct one.
*
* @param tokenId the token id that should be contained in this token as it is read.
* @param context the Kerberos context associated with this token
* @param is the InputStream from which to read
* @param prop the MessageProp structure in which the properties of the token should be stored.
* @throws GSSException if there is a problem reading from the InputStream or parsing the token
*/
MessageToken_v2(int tokenId, Krb5Context context, InputStream is, MessageProp prop)
throws GSSException {
init(tokenId, context);
try {
if (!confState) {
prop.setPrivacy(false);
}
tokenHeader = new MessageTokenHeader(is, prop, tokenId);
// set key_usage
if (tokenId == Krb5Token.WRAP_ID_v2) {
key_usage = (!initiator ? KG_USAGE_INITIATOR_SEAL : KG_USAGE_ACCEPTOR_SEAL);
} else if (tokenId == Krb5Token.MIC_ID_v2) {
key_usage = (!initiator ? KG_USAGE_INITIATOR_SIGN : KG_USAGE_ACCEPTOR_SIGN);
}
int minSize = 0; // minimal size for token data
if (tokenId == Krb5Token.WRAP_ID_v2 && prop.getPrivacy()) {
minSize = CONFOUNDER_SIZE + TOKEN_HEADER_SIZE + cipherHelper.getChecksumLength();
} else {
minSize = cipherHelper.getChecksumLength();
}
// Read token data
if (tokenId == Krb5Token.MIC_ID_v2) {
// The only case we can precisely predict the token data length
tokenDataLen = minSize;
tokenData = new byte[minSize];
readFully(is, tokenData);
} else {
tokenDataLen = is.available();
if (tokenDataLen >= minSize) { // read in one shot
tokenData = new byte[tokenDataLen];
readFully(is, tokenData);
} else {
byte[] tmp = new byte[minSize];
readFully(is, tmp);
// Hope while blocked in the read above, more data would
// come and is.available() below contains the whole token.
int more = is.available();
tokenDataLen = minSize + more;
tokenData = Arrays.copyOf(tmp, tokenDataLen);
readFully(is, tokenData, minSize, more);
}
}
if (tokenId == Krb5Token.WRAP_ID_v2) {
rotate();
}
if (tokenId == Krb5Token.MIC_ID_v2
|| (tokenId == Krb5Token.WRAP_ID_v2 && !prop.getPrivacy())) {
// Read checksum
int chkLen = cipherHelper.getChecksumLength();
checksum = new byte[chkLen];
System.arraycopy(tokenData, tokenDataLen - chkLen, checksum, 0, chkLen);
// validate EC for Wrap tokens without confidentiality
if (tokenId == Krb5Token.WRAP_ID_v2 && !prop.getPrivacy()) {
if (chkLen != ec) {
throw new GSSException(
GSSException.DEFECTIVE_TOKEN, -1, getTokenName(tokenId) + ":" + "EC incorrect!");
}
}
}
} catch (IOException e) {
throw new GSSException(
GSSException.DEFECTIVE_TOKEN, -1, getTokenName(tokenId) + ":" + e.getMessage());
}
}
/* this is changed
public void run() {
*/
public void produceImage() throws IOException, ImageFormatException {
/* this is not needed
ImageConsumer t = target;
if(t!=null) try {
*/
try {
for (int i = 0; i < signature.length; i++)
if ((signature[i] & 0xFF) != underlyingInputStream.read())
throw new PNGException("Chunk signature mismatch");
InputStream is =
new BufferedInputStream(new InflaterInputStream(inputStream, new Inflater()));
getData();
byte[] bPixels = null;
int[] wPixels = null;
int pixSize = width;
int rowStride;
int logDepth = 0;
switch (bitDepth) {
case 1:
logDepth = 0;
break;
case 2:
logDepth = 1;
break;
case 4:
logDepth = 2;
break;
case 8:
logDepth = 3;
break;
case 16:
logDepth = 4;
break;
default:
throw new PNGException("invalid depth");
}
if (interlaceMethod != 0) {
pixSize *= height;
rowStride = width;
} else rowStride = 0;
int combinedType = colorType | (bitDepth << 3);
int bitMask = (1 << (bitDepth >= 8 ? 8 : bitDepth)) - 1;
// Figure out the color model
switch (colorType) {
case COLOR | PALETTE:
case COLOR | PALETTE | ALPHA:
if (red_map == null) throw new PNGException("palette expected");
if (alpha_map == null)
cm = new IndexColorModel(bitDepth, red_map.length, red_map, green_map, blue_map);
else
cm =
new IndexColorModel(
bitDepth, red_map.length, red_map, green_map, blue_map, alpha_map);
bPixels = new byte[pixSize];
break;
case GRAY:
{
int llog = logDepth >= 4 ? 3 : logDepth;
if ((cm = greyModels[llog]) == null) {
int size = 1 << (1 << llog);
byte ramp[] = new byte[size];
for (int i = 0; i < size; i++) ramp[i] = (byte) (255 * i / (size - 1));
if (transparentPixel == -1) {
cm = new IndexColorModel(bitDepth, ramp.length, ramp, ramp, ramp);
} else {
cm =
new IndexColorModel(
bitDepth, ramp.length, ramp, ramp, ramp, (transparentPixel & 0xFF));
}
greyModels[llog] = cm;
}
}
bPixels = new byte[pixSize];
break;
case COLOR:
case COLOR | ALPHA:
case GRAY | ALPHA:
cm = ColorModel.getRGBdefault();
wPixels = new int[pixSize];
break;
default:
throw new PNGException("invalid color type");
}
/* this is going to be set in the pixel store
t.setColorModel(cm);
t.setHints(interlaceMethod !=0
? ImageConsumer.TOPDOWNLEFTRIGHT | ImageConsumer.COMPLETESCANLINES
: ImageConsumer.TOPDOWNLEFTRIGHT | ImageConsumer.COMPLETESCANLINES |
ImageConsumer.SINGLEPASS | ImageConsumer.SINGLEFRAME);
*/
// code added to make it work with ImageDecoder architecture
setDimensions(width, height);
setColorModel(cm);
int flags =
(interlaceMethod != 0
? ImageConsumer.TOPDOWNLEFTRIGHT | ImageConsumer.COMPLETESCANLINES
: ImageConsumer.TOPDOWNLEFTRIGHT
| ImageConsumer.COMPLETESCANLINES
| ImageConsumer.SINGLEPASS
| ImageConsumer.SINGLEFRAME);
setHints(flags);
headerComplete();
// end of adding
int samplesPerPixel =
((colorType & PALETTE) != 0
? 1
: ((colorType & COLOR) != 0 ? 3 : 1) + ((colorType & ALPHA) != 0 ? 1 : 0));
int bitsPerPixel = samplesPerPixel * bitDepth;
int bytesPerPixel = (bitsPerPixel + 7) >> 3;
int pass, passLimit;
if (interlaceMethod == 0) {
pass = -1;
passLimit = 0;
} else {
pass = 0;
passLimit = 7;
}
// These loops are far from being tuned. They're this way to make them easy to
// debug. Tuning comes later.
/* code changed. target not needed here
while(++pass<=passLimit && (t=target)!=null) {
*/
while (++pass <= passLimit) {
int row = startingRow[pass];
int rowInc = rowIncrement[pass];
int colInc = colIncrement[pass];
int bWidth = blockWidth[pass];
int bHeight = blockHeight[pass];
int sCol = startingCol[pass];
int rowPixelWidth = (width - sCol + (colInc - 1)) / colInc;
int rowByteWidth = ((rowPixelWidth * bitsPerPixel) + 7) >> 3;
if (rowByteWidth == 0) continue;
int pixelBufferInc = interlaceMethod == 0 ? rowInc * width : 0;
int rowOffset = rowStride * row;
boolean firstRow = true;
byte[] rowByteBuffer = new byte[rowByteWidth];
byte[] prevRowByteBuffer = new byte[rowByteWidth];
/* code changed. target not needed here
while (row < height && (t=target)!=null) {
*/
while (row < height) {
int rowFilter = is.read();
for (int rowFillPos = 0; rowFillPos < rowByteWidth; ) {
int n = is.read(rowByteBuffer, rowFillPos, rowByteWidth - rowFillPos);
if (n <= 0) throw new PNGException("missing data");
rowFillPos += n;
}
filterRow(
rowByteBuffer,
firstRow ? null : prevRowByteBuffer,
rowFilter,
rowByteWidth,
bytesPerPixel);
int col = sCol;
int spos = 0;
int pixel = 0;
while (col < width) {
if (wPixels != null) {
switch (combinedType) {
case COLOR | ALPHA | (8 << 3):
wPixels[col + rowOffset] =
((rowByteBuffer[spos] & 0xFF) << 16)
| ((rowByteBuffer[spos + 1] & 0xFF) << 8)
| ((rowByteBuffer[spos + 2] & 0xFF))
| ((rowByteBuffer[spos + 3] & 0xFF) << 24);
spos += 4;
break;
case COLOR | ALPHA | (16 << 3):
wPixels[col + rowOffset] =
((rowByteBuffer[spos] & 0xFF) << 16)
| ((rowByteBuffer[spos + 2] & 0xFF) << 8)
| ((rowByteBuffer[spos + 4] & 0xFF))
| ((rowByteBuffer[spos + 6] & 0xFF) << 24);
spos += 8;
break;
case COLOR | (8 << 3):
pixel =
((rowByteBuffer[spos] & 0xFF) << 16)
| ((rowByteBuffer[spos + 1] & 0xFF) << 8)
| ((rowByteBuffer[spos + 2] & 0xFF));
if (pixel != transparentPixel) {
pixel |= 0xff000000;
}
wPixels[col + rowOffset] = pixel;
spos += 3;
break;
case COLOR | (16 << 3):
pixel =
((rowByteBuffer[spos] & 0xFF) << 16)
| ((rowByteBuffer[spos + 2] & 0xFF) << 8)
| ((rowByteBuffer[spos + 4] & 0xFF));
boolean isTransparent = (transparentPixel_16 != null);
for (int i = 0; isTransparent && (i < 6); i++) {
isTransparent &=
(rowByteBuffer[spos + i] & 0xFF) == (transparentPixel_16[i] & 0xFF);
}
if (!isTransparent) {
pixel |= 0xff000000;
}
wPixels[col + rowOffset] = pixel;
spos += 6;
break;
case GRAY | ALPHA | (8 << 3):
{
int tx = rowByteBuffer[spos] & 0xFF;
wPixels[col + rowOffset] =
(tx << 16) | (tx << 8) | tx | ((rowByteBuffer[spos + 1] & 0xFF) << 24);
}
spos += 2;
break;
case GRAY | ALPHA | (16 << 3):
{
int tx = rowByteBuffer[spos] & 0xFF;
wPixels[col + rowOffset] =
(tx << 16) | (tx << 8) | tx | ((rowByteBuffer[spos + 2] & 0xFF) << 24);
}
spos += 4;
break;
default:
throw new PNGException("illegal type/depth");
}
} else
switch (bitDepth) {
case 1:
bPixels[col + rowOffset] =
(byte) ((rowByteBuffer[spos >> 3] >> (7 - (spos & 7))) & 1);
spos++;
break;
case 2:
bPixels[col + rowOffset] =
(byte) ((rowByteBuffer[spos >> 2] >> ((3 - (spos & 3)) * 2)) & 3);
spos++;
break;
case 4:
bPixels[col + rowOffset] =
(byte) ((rowByteBuffer[spos >> 1] >> ((1 - (spos & 1)) * 4)) & 15);
spos++;
break;
case 8:
bPixels[col + rowOffset] = rowByteBuffer[spos++];
break;
case 16:
bPixels[col + rowOffset] = rowByteBuffer[spos];
spos += 2;
break;
default:
throw new PNGException("illegal type/depth");
}
/*visit (row, col,
min (bHeight, height - row),
min (bWidth, width - col)); */
col += colInc;
}
if (interlaceMethod == 0)
if (wPixels != null) {
/* code changed. target not needed here
t.setPixels(0,row,width,1,cm,wPixels,0,width);
*/
// code added to make it work with ImageDecoder arch
sendPixels(0, row, width, 1, wPixels, 0, width);
// end of adding
} else {
/* code changed. target not needed here
t.setPixels(0,row,width,1,cm,bPixels,0,width);
*/
// code added to make it work with ImageDecoder arch
sendPixels(0, row, width, 1, bPixels, 0, width);
// end of adding
}
row += rowInc;
rowOffset += rowInc * rowStride;
byte[] T = rowByteBuffer;
rowByteBuffer = prevRowByteBuffer;
prevRowByteBuffer = T;
firstRow = false;
}
if (interlaceMethod != 0)
if (wPixels != null) {
/* code changed. target not needed here
t.setPixels(0,0,width,height,cm,wPixels,0,width);
*/
// code added to make it work with ImageDecoder arch
sendPixels(0, 0, width, height, wPixels, 0, width);
// end of adding
} else {
/* code changed. target not needed here
t.setPixels(0,0,width,height,cm,bPixels,0,width);
*/
// code added to make it work with ImageDecoder arch
sendPixels(0, 0, width, height, bPixels, 0, width);
// end of adding
}
}
/* Here, the function "visit(row,column,height,width)" obtains the
next transmitted pixel and paints a rectangle of the specified
height and width, whose upper-left corner is at the specified row
and column, using the color indicated by the pixel. Note that row
and column are measured from 0,0 at the upper left corner. */
/* code not needed, don't deal with target
if((t=target)!=null) {
if(properties!=null) t.setProperties(properties);
t.imageComplete(ImageConsumer.STATICIMAGEDONE);
*/
imageComplete(ImageConsumer.STATICIMAGEDONE, true);
/* code not needed }
is.close();
*/
} catch (IOException e) {
if (!aborted) {
/* code not needed
if((t=target)!=null) {
PNGEncoder.prChunk(e.toString(),inbuf,pos,limit-pos,true);
*/
property("error", e);
/* code not needed
t.setProperties(properties);
t.imageComplete(ImageConsumer.IMAGEERROR|ImageConsumer.STATICIMAGEDONE);
*/
imageComplete(ImageConsumer.IMAGEERROR | ImageConsumer.STATICIMAGEDONE, true);
throw e;
}
} finally {
try {
close();
} catch (Throwable e) {
}
/* code not needed
target = null;
endTurn();
*/
}
}