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package sun.jvmstat.perfdata.monitor.v1_0;
import sun.jvmstat.monitor.*;
import sun.jvmstat.perfdata.monitor.*;
import java.util.*;
import java.util.regex.*;
import java.nio.*;
/**
* The concrete implementation of version 1.0 of the HotSpot PerfData
* Instrumentation buffer. This class is responsible for parsing the
* instrumentation memory and constructing the necessary objects to
* represent and access the instrumentation objects contained in the
* memory buffer.
*
* @author Brian Doherty
* @since 1.5
* @see AbstractPerfDataBuffer
*/
public class PerfDataBuffer extends PerfDataBufferImpl {
private static final boolean DEBUG = false;
private static final int syncWaitMs =
Integer.getInteger("sun.jvmstat.perdata.syncWaitMs", 5000);
private static final ArrayList EMPTY_LIST = new ArrayList(0);
/*
* the following constants must be kept in sync with struct
* PerfDataEntry in perfMemory.hpp
*/
private final static int PERFDATA_ENTRYLENGTH_OFFSET=0;
private final static int PERFDATA_ENTRYLENGTH_SIZE=4; // sizeof(int)
private final static int PERFDATA_NAMELENGTH_OFFSET=4;
private final static int PERFDATA_NAMELENGTH_SIZE=4; // sizeof(int)
private final static int PERFDATA_VECTORLENGTH_OFFSET=8;
private final static int PERFDATA_VECTORLENGTH_SIZE=4; // sizeof(int)
private final static int PERFDATA_DATATYPE_OFFSET=12;
private final static int PERFDATA_DATATYPE_SIZE=1; // sizeof(byte)
private final static int PERFDATA_FLAGS_OFFSET=13;
private final static int PERFDATA_FLAGS_SIZE=1; // sizeof(byte)
private final static int PERFDATA_DATAUNITS_OFFSET=14;
private final static int PERFDATA_DATAUNITS_SIZE=1; // sizeof(byte)
private final static int PERFDATA_DATAATTR_OFFSET=15;
private final static int PERFDATA_DATAATTR_SIZE=1; // sizeof(byte)
private final static int PERFDATA_NAME_OFFSET=16;
PerfDataBufferPrologue prologue;
int nextEntry;
int pollForEntry;
int perfDataItem;
long lastModificationTime;
int lastUsed;
IntegerMonitor overflow;
ArrayList<Monitor> insertedMonitors;
/**
* Construct a PerfDataBufferImpl instance.
* <p>
* This class is dynamically loaded by
* {@link AbstractPerfDataBuffer#createPerfDataBuffer}, and this
* constructor is called to instantiate the instance.
*
* @param buffer the buffer containing the instrumentation data
* @param lvmid the Local Java Virtual Machine Identifier for this
* instrumentation buffer.
*/
public PerfDataBuffer(ByteBuffer buffer, int lvmid)
throws MonitorException {
super(buffer, lvmid);
prologue = new PerfDataBufferPrologue(buffer);
this.buffer.order(prologue.getByteOrder());
}
/**
* {@inheritDoc}
*/
protected void buildMonitorMap(Map<String, Monitor> map) throws MonitorException {
assert Thread.holdsLock(this);
// start at the beginning of the buffer
buffer.rewind();
// create pseudo monitors
buildPseudoMonitors(map);
// position buffer to start of the data section
buffer.position(prologue.getSize());
nextEntry = buffer.position();
perfDataItem = 0;
int used = prologue.getUsed();
long modificationTime = prologue.getModificationTimeStamp();
Monitor m = getNextMonitorEntry();
while (m != null) {
map.put(m.getName(), m);
m = getNextMonitorEntry();
}
/*
* set the last modification data. These are set to the values
* recorded before parsing the data structure. This allows the
* the data structure to be modified while the Map is being built.
* The Map may contain more entries than indicated based on the
* time stamp, but this is handled by ignoring duplicate entries
* when the Map is updated in getNewMonitors().
*/
lastUsed = used;
lastModificationTime = modificationTime;
// synchronize with the target jvm
synchWithTarget(map);
// work around 1.4.2 counter inititization bugs
kludge(map);
insertedMonitors = new ArrayList<Monitor>(map.values());
}
/**
* {@inheritDoc}
*/
protected void getNewMonitors(Map<String, Monitor> map) throws MonitorException {
assert Thread.holdsLock(this);
int used = prologue.getUsed();
long modificationTime = prologue.getModificationTimeStamp();
if ((used > lastUsed) || (lastModificationTime > modificationTime)) {
lastUsed = used;
lastModificationTime = modificationTime;
Monitor monitor = getNextMonitorEntry();
while (monitor != null) {
String name = monitor.getName();
// guard against duplicate entries
if (!map.containsKey(name)) {
map.put(name, monitor);
/*
* insertedMonitors is null when called from pollFor()
* via buildMonitorMap(). Since we update insertedMonitors
* at the end of buildMonitorMap(), it's ok to skip the
* add here.
*/
if (insertedMonitors != null) {
insertedMonitors.add(monitor);
}
}
monitor = getNextMonitorEntry();
}
}
}
/**
* {@inheritDoc}
*/
protected MonitorStatus getMonitorStatus(Map<String, Monitor> map) throws MonitorException {
assert Thread.holdsLock(this);
assert insertedMonitors != null;
// load any new monitors
getNewMonitors(map);
// current implementation doesn't support deletion or reuse of entries
ArrayList removed = EMPTY_LIST;
ArrayList inserted = insertedMonitors;
insertedMonitors = new ArrayList<Monitor>();
return new MonitorStatus(inserted, removed);
}
/**
* Build the pseudo monitors used to map the prolog data into counters.
*/
protected void buildPseudoMonitors(Map<String, Monitor> map) {
Monitor monitor = null;
String name = null;
IntBuffer ib = null;
name = PerfDataBufferPrologue.PERFDATA_MAJOR_NAME;
ib = prologue.majorVersionBuffer();
monitor = new PerfIntegerMonitor(name, Units.NONE,
Variability.CONSTANT, false, ib);
map.put(name, monitor);
name = PerfDataBufferPrologue.PERFDATA_MINOR_NAME;
ib = prologue.minorVersionBuffer();
monitor = new PerfIntegerMonitor(name, Units.NONE,
Variability.CONSTANT, false, ib);
map.put(name, monitor);
name = PerfDataBufferPrologue.PERFDATA_BUFFER_SIZE_NAME;
ib = prologue.sizeBuffer();
monitor = new PerfIntegerMonitor(name, Units.BYTES,
Variability.MONOTONIC, false, ib);
map.put(name, monitor);
name = PerfDataBufferPrologue.PERFDATA_BUFFER_USED_NAME;
ib = prologue.usedBuffer();
monitor = new PerfIntegerMonitor(name, Units.BYTES,
Variability.MONOTONIC, false, ib);
map.put(name, monitor);
name = PerfDataBufferPrologue.PERFDATA_OVERFLOW_NAME;
ib = prologue.overflowBuffer();
monitor = new PerfIntegerMonitor(name, Units.BYTES,
Variability.MONOTONIC, false, ib);
map.put(name, monitor);
this.overflow = (IntegerMonitor)monitor;
name = PerfDataBufferPrologue.PERFDATA_MODTIMESTAMP_NAME;
LongBuffer lb = prologue.modificationTimeStampBuffer();
monitor = new PerfLongMonitor(name, Units.TICKS,
Variability.MONOTONIC, false, lb);
map.put(name, monitor);
}
/**
* Method to provide a gross level of synchronization with the
* target monitored jvm.
*
* gross synchronization works by polling for the hotspot.rt.hrt.ticks
* counter, which is the last counter created by the StatSampler
* initialization code. The counter is updated when the watcher thread
* starts scheduling tasks, which is the last thing done in vm
* initialization.
*/
protected void synchWithTarget(Map<String, Monitor> map) throws MonitorException {
/*
* synch must happen with syncWaitMs from now. Default is 5 seconds,
* which is reasonabally generous and should provide for extreme
* situations like startup delays due to allocation of large ISM heaps.
*/
long timeLimit = System.currentTimeMillis() + syncWaitMs;
String name = "hotspot.rt.hrt.ticks";
LongMonitor ticks = (LongMonitor)pollFor(map, name, timeLimit);
/*
* loop waiting for the ticks counter to be non zero. This is
* an indication that the jvm is initialized.
*/
log("synchWithTarget: " + lvmid + " ");
while (ticks.longValue() == 0) {
log(".");
try { Thread.sleep(20); } catch (InterruptedException e) { }
if (System.currentTimeMillis() > timeLimit) {
lognl("failed: " + lvmid);
throw new MonitorException("Could Not Synchronize with target");
}
}
lognl("success: " + lvmid);
}
/**
* Method to poll the instrumentation memory for a counter with
* the given name. The polling period is bounded by the timeLimit
* argument.
*/
protected Monitor pollFor(Map<String, Monitor> map, String name, long timeLimit)
throws MonitorException {
Monitor monitor = null;
log("polling for: " + lvmid + "," + name + " ");
pollForEntry = nextEntry;
while ((monitor = map.get(name)) == null) {
log(".");
try { Thread.sleep(20); } catch (InterruptedException e) { }
long t = System.currentTimeMillis();
if ((t > timeLimit) || (overflow.intValue() > 0)) {
lognl("failed: " + lvmid + "," + name);
dumpAll(map, lvmid);
throw new MonitorException("Could not find expected counter");
}
getNewMonitors(map);
}
lognl("success: " + lvmid + "," + name);
return monitor;
}
/**
* method to make adjustments for known counter problems. This
* method depends on the availability of certain counters, which
* is generally guaranteed by the synchWithTarget() method.
*/
protected void kludge(Map<String, Monitor> map) {
if (Boolean.getBoolean("sun.jvmstat.perfdata.disableKludge")) {
// bypass all kludges
return;
}
String name = "java.vm.version";
StringMonitor jvm_version = (StringMonitor)map.get(name);
if (jvm_version == null) {
jvm_version = (StringMonitor)findByAlias(name);
}
name = "java.vm.name";
StringMonitor jvm_name = (StringMonitor)map.get(name);
if (jvm_name == null) {
jvm_name = (StringMonitor)findByAlias(name);
}
name = "hotspot.vm.args";
StringMonitor args = (StringMonitor)map.get(name);
if (args == null) {
args = (StringMonitor)findByAlias(name);
}
assert ((jvm_name != null) && (jvm_version != null) && (args != null));
if (jvm_name.stringValue().indexOf("HotSpot") >= 0) {
if (jvm_version.stringValue().startsWith("1.4.2")) {
kludgeMantis(map, args);
}
}
}
/**
* method to repair the 1.4.2 parallel scavenge counters that are
* incorrectly initialized by the JVM when UseAdaptiveSizePolicy
* is set. This bug couldn't be fixed for 1.4.2 FCS due to putback
* restrictions.
*/
private void kludgeMantis(Map<String, Monitor> map, StringMonitor args) {
/*
* the HotSpot 1.4.2 JVM with the +UseParallelGC option along
* with its default +UseAdaptiveSizePolicy option has a bug with
* the initialization of the sizes of the eden and survivor spaces.
* See bugid 4890736.
*
* note - use explicit 1.4.2 counter names here - don't update
* to latest counter names or attempt to find aliases.
*/
String cname = "hotspot.gc.collector.0.name";
StringMonitor collector = (StringMonitor)map.get(cname);
if (collector.stringValue().compareTo("PSScavenge") == 0) {
boolean adaptiveSizePolicy = true;
/*
* HotSpot processes the -XX:Flags/.hotspotrc arguments prior to
* processing the command line arguments. This allows the command
* line arguments to override any defaults set in .hotspotrc
*/
cname = "hotspot.vm.flags";
StringMonitor flags = (StringMonitor)map.get(cname);
String allArgs = flags.stringValue() + " " + args.stringValue();
/*
* ignore the -XX: prefix as it only applies to the arguments
* passed from the command line (i.e. the invocation api).
* arguments passed through .hotspotrc omit the -XX: prefix.
*/
int ahi = allArgs.lastIndexOf("+AggressiveHeap");
int aspi = allArgs.lastIndexOf("-UseAdaptiveSizePolicy");
if (ahi != -1) {
/*
* +AggressiveHeap was set, check if -UseAdaptiveSizePolicy
* is set after +AggressiveHeap.
*/
//
if ((aspi != -1) && (aspi > ahi)) {
adaptiveSizePolicy = false;
}
} else {
/*
* +AggressiveHeap not set, must be +UseParallelGC. The
* relative position of -UseAdaptiveSizePolicy is not
* important in this case, as it will override the
* UseParallelGC default (+UseAdaptiveSizePolicy) if it
* appears anywhere in the JVM arguments.
*/
if (aspi != -1) {
adaptiveSizePolicy = false;
}
}
if (adaptiveSizePolicy) {
// adjust the buggy AdaptiveSizePolicy size counters.
// first remove the real counters.
String eden_size = "hotspot.gc.generation.0.space.0.size";
String s0_size = "hotspot.gc.generation.0.space.1.size";
String s1_size = "hotspot.gc.generation.0.space.2.size";
map.remove(eden_size);
map.remove(s0_size);
map.remove(s1_size);
// get the maximum new generation size
String new_max_name = "hotspot.gc.generation.0.capacity.max";
LongMonitor new_max = (LongMonitor)map.get(new_max_name);
/*
* replace the real counters with pseudo counters that are
* initialized to to the correct values. The maximum size of
* the eden and survivor spaces are supposed to be:
* max_eden_size = new_size - (2*alignment).
* max_survivor_size = new_size - (2*alignment).
* since we don't know the alignment value used, and because
* of other parallel scavenge bugs that result in oversized
* spaces, we just set the maximum size of each space to the
* full new gen size.
*/
Monitor monitor = null;
LongBuffer lb = LongBuffer.allocate(1);
lb.put(new_max.longValue());
monitor = new PerfLongMonitor(eden_size, Units.BYTES,
Variability.CONSTANT, false, lb);
map.put(eden_size, monitor);
monitor = new PerfLongMonitor(s0_size, Units.BYTES,
Variability.CONSTANT, false, lb);
map.put(s0_size, monitor);
monitor = new PerfLongMonitor(s1_size, Units.BYTES,
Variability.CONSTANT, false, lb);
map.put(s1_size, monitor);
}
}
}
/**
* method to extract the next monitor entry from the instrumentation memory.
* assumes that nextEntry is the offset into the byte array
* at which to start the search for the next entry. method leaves
* next entry pointing to the next entry or to the end of data.
*/
protected Monitor getNextMonitorEntry() throws MonitorException {
Monitor monitor = null;
// entries are always 4 byte aligned.
if ((nextEntry % 4) != 0) {
throw new MonitorStructureException(
"Entry index not properly aligned: " + nextEntry);
}
// protect against a corrupted shared memory region.
if ((nextEntry < 0) || (nextEntry > buffer.limit())) {
throw new MonitorStructureException(
"Entry index out of bounds: nextEntry = " + nextEntry
+ ", limit = " + buffer.limit());
}
// check for the end of the buffer
if (nextEntry == buffer.limit()) {
lognl("getNextMonitorEntry():"
+ " nextEntry == buffer.limit(): returning");
return null;
}
buffer.position(nextEntry);
int entryStart = buffer.position();
int entryLength = buffer.getInt();
// check for valid entry length
if ((entryLength < 0) || (entryLength > buffer.limit())) {
throw new MonitorStructureException(
"Invalid entry length: entryLength = " + entryLength);
}
// check if last entry occurs before the eof.
if ((entryStart + entryLength) > buffer.limit()) {
throw new MonitorStructureException(
"Entry extends beyond end of buffer: "
+ " entryStart = " + entryStart
+ " entryLength = " + entryLength
+ " buffer limit = " + buffer.limit());
}
if (entryLength == 0) {
// end of data
return null;
}
int nameLength = buffer.getInt();
int vectorLength = buffer.getInt();
byte dataType = buffer.get();
byte flags = buffer.get();
Units u = Units.toUnits(buffer.get());
Variability v = Variability.toVariability(buffer.get());
boolean supported = (flags & 0x01) != 0;
// defend against corrupt entries
if ((nameLength <= 0) || (nameLength > entryLength)) {
throw new MonitorStructureException(
"Invalid Monitor name length: " + nameLength);
}
if ((vectorLength < 0) || (vectorLength > entryLength)) {
throw new MonitorStructureException(
"Invalid Monitor vector length: " + vectorLength);
}
// read in the perfData item name, casting bytes to chars. skip the
// null terminator
//
byte[] nameBytes = new byte[nameLength-1];
for (int i = 0; i < nameLength-1; i++) {
nameBytes[i] = buffer.get();
}
// convert name into a String
String name = new String(nameBytes, 0, nameLength-1);
if (v == Variability.INVALID) {
throw new MonitorDataException("Invalid variability attribute:"
+ " entry index = " + perfDataItem
+ " name = " + name);
}
if (u == Units.INVALID) {
throw new MonitorDataException("Invalid units attribute: "
+ " entry index = " + perfDataItem
+ " name = " + name);
}
int offset;
if (vectorLength == 0) {
// scalar Types
if (dataType == BasicType.LONG.intValue()) {
offset = entryStart + entryLength - 8; /* 8 = sizeof(long) */
buffer.position(offset);
LongBuffer lb = buffer.asLongBuffer();
lb.limit(1);
monitor = new PerfLongMonitor(name, u, v, supported, lb);
perfDataItem++;
} else {
// bad data types.
throw new MonitorTypeException("Invalid Monitor type:"
+ " entry index = " + perfDataItem
+ " name = " + name
+ " type = " + dataType);
}
} else {
// vector types
if (dataType == BasicType.BYTE.intValue()) {
if (u != Units.STRING) {
// only byte arrays of type STRING are currently supported
throw new MonitorTypeException("Invalid Monitor type:"
+ " entry index = " + perfDataItem
+ " name = " + name
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