JVMTM Tool InterfaceVersion 1.0 |
jvmti.h.
To use these definitions add the J2SETM include directory
to your include path and add
#include <jvmti.h>
to your source code.
JavaVMInitArgs argument
to the JNI_CreateJavaVM function of the JNI
Invocation API.
One of the two following
command-line options is used on VM startup to
properly load and run agents.
These arguments identify the library containing
the agent as well as an options
string to be passed in at startup.
-agentlib:<agent-lib-name>=<options>
-agentlib: is the name of the
library to load. Lookup of the library, both its full name and location,
proceeds in a platform-specific manner.
Typically, the <agent-lib-name> is expanded to an
operating system specific file name.
The <options> will be passed to the agent on start-up.
For example, if the option
-agentlib:foo=opt1,opt2 is specified, the VM will attempt to
load the shared library foo.dll from the system PATH
under WindowsTM or libfoo.so from the
LD_LIBRARY_PATH under the SolarisTM operating environment.
-agentpath:<path-to-agent>=<options>
-agentpath: is the absolute path from which
to load the library.
No library name expansion will occur.
The <options> will be passed to the agent on start-up.
For example, if the option
-agentpath:c:\myLibs\foo.dll=opt1,opt2 is specified, the VM will attempt to
load the shared library c:\myLibs\foo.dll.
-agentlib: or -agentpath:
will be searched for JNI native method implementations to facilitate the
use of Java programming language code in tools, as is needed for
bytecode instrumentation.
The agent libraries will be searched after all other libraries have been
searched (agents wishing to override or intercept the native method
implementations of non-agent methods can use the
NativeMethodBind event).
These switches do the above and nothing more - they do not change the
state of the VM or JVM TI. No command line options are needed
to enable JVM TI
or aspects of JVM TI, this is handled programmatically
by the use of
capabilities.
This function will be called by the VM when the library is loaded. The VM should load the library early enough in VM initialization that:JNIEXPORT jint JNICALL Agent_OnLoad(JavaVM *vm, char *options, void *reserved)
Agent_OnLoad function with
<options> as the second argument -
that is, using the command-line option examples,
"opt1,opt2" will be passed to the char *options
argument of Agent_OnLoad.
The options argument is encoded as a
modified UTF-8 string.
If =<options> is not specified,
a zero length string is passed to options.
The lifespan of the options string is the Agent_OnLoad
call. If needed beyond this time the string or parts of the string must
be copied.
The period between when Agent_OnLoad is called and when it
returns is called the OnLoad phase.
Since the VM is not initialized during the OnLoad
phase,
the set of allowed operations
inside Agent_OnLoad is restricted (see the function descriptions for the
functionality available at this time).
The agent can safely process the options and set
event callbacks with SetEventCallbacks. Once
the VM initialization event is received
(that is, the VMInit
callback is invoked), the agent
can complete its initialization.
Rationale: Early startup is required so that agents can set the desired capabilities, many of which must be set before the VM is initialized. In JVMDI, the -Xdebug command-line option provides very coarse-grain control of capabilities. JVMPI implementations use various tricks to provide a single "JVMPI on" switch. No reasonable command-line option could provide the fine-grain of control required to balance needed capabilities vs performance impact. Early startup is also needed so that agents can control the execution environment - modifying the file system and system properties to install their functionality.
The return value fromAgent_OnLoad is used to indicate an error.
Any value other than zero indicates an error and causes termination of the VM.
This function will be called by the VM when the library is about to be unloaded. The library will be unloaded and this function will be called if some platform specific mechanism causes the unload (an unload mechanism is not specified in this document) or the library is (in effect) unloaded by the termination of the VM whether through normal termination or VM failure, including start-up failure. Uncontrolled shutdown is, of couse, an exception to this rule. Note the distinction between this function and the VM Death event: for the VM Death event to be sent, the VM must have run at least to the point of initialization and a valid JVM TI environment must exist which has set a callback for VMDeath and enabled the event None of these are required forJNIEXPORT void JNICALL Agent_OnUnload(JavaVM *vm)
Agent_OnUnload and this function
is also called if the library is unloaded for other reasons.
In the case that a VM Death event is sent, it will be sent before this
function is called (assuming this function is called due to VM termination).
This function can be used to clean-up resources allocated during
Agent_OnLoad.
JAVA_TOOL_OPTIONS variable is
provided so that agents may be launched in these cases.
Platforms which support environment variables or other named strings, may support the
JAVA_TOOL_OPTIONS variable. This variable will be broken into options at white-space
boundaries. White-space characters include space, tab, carriage-return, new-line,
vertical-tab, and form-feed. Sequences of white-space characters are considered
equivalent to a single white-space character. No white-space is included in the options
unless quoted. Quoting is as follows:
JNI_CreateJavaVM (in the JNI Invocation API) will prepend these options to the options supplied
in its JavaVMInitArgs argument. Platforms may disable this feature in cases where security is
a concern; for example, the Reference Implementation disables this feature on Unix systems when
the effective user or group ID differs from the real ID.
This feature is intended to support the initialization of tools -- specifically including the
launching of native or Java programming language agents. Multiple tools may wish to use this
feature, so the variable should not be overwritten, instead, options should be appended to
the variable. Note that since the variable is processed at the time of the JNI Invocation
API create VM call, options processed by a launcher (e.g., VM selection options) will not be handled.
GetEnv from
Agent_OnLoad.
MyProfiler.methodEntered().
Since the changes are purely additive, they do not modify application
state or behavior.
Because the inserted agent code is standard bytecodes, the VM can run at full speed,
optimizing not only the target program but also the instrumentation. If the
instrumentation does not involve switching from bytecode execution, no expensive
state transitions are needed. The result is high performance events.
This approach also provides complete control to the agent, instrumentation can be
restricted to "interesting" portions of the code (e.g., the end user's code) and
can be conditional. Instrumentation can run entirely in Java programming language
code or can call into the native agent. Instrumentation can simply maintain
counters or can statistically sample events.
Instrumentation can be inserted in one of three ways:
*.class files which have been modified to add the instrumentation.
This method is extremely awkward and, in general, an agent cannot know
the origin of the class files which will be loaded.
ClassFileLoadHook
event provides this functionality. This mechanism provides efficient
and complete access to one-time instrumentation.
RedefineClasses function.
Classes can be modified multiple times and can be returned to their
original state.
The mechanism allows instrumentation which changes during the
course of execution.
ClassFileLoadHook event
and the RedefineClasses function)
is intended to provide a mechanism for instrumentation (described above)
and, during development, for fix-and-continue debugging.
Care must be taken to avoid perturbing dependencies, especially when
instrumenting core classes. For example, an approach to getting notification
of every object allocation is to instrument the constructor on
Object. Assuming that the constructor is initially
empty, the constructor could be changed to:
public Object() {
MyProfiler.allocationTracker(this);
}
However, if this change was made using the
ClassFileLoadHook
event then this might impact a typical VM as follows:
the first created object will call the constructor causing a class load of
MyProfiler; which will then cause
object creation, and since MyProfiler isn't loaded yet,
infinite recursion; resulting in a stack overflow. A refinement of this
would be to delay invoking the tracking method until a safe time. For
example, trackAllocations could be set in the
handler for the VMInit event.
static boolean trackAllocations = false;
public Object() {
if (trackAllocations) {
MyProfiler.allocationTracker(this);
}
}
jvmtiEnv*.
An environment has information about its JVM TI connection.
The first value in the environment is a pointer to the function table.
The function table is an array of pointers to JVM TI functions.
Every function pointer is at a predefined offset inside the
array.
When used from the C language:
double indirection is used to access the functions;
the environment pointer provides context and is the first
parameter of each function call; for example:
jvmtiEnv *jvmti;
...
jvmtiError err = (*jvmti)->GetLoadedClasses(jvmti, &class_count, &classes);
When used from the C++ language:
functions are accessed as member functions of jvmtiEnv;
the environment pointer is not passed to the function call; for example:
jvmtiEnv *jvmti;
...
jvmtiError err = jvmti->GetLoadedClasses(&class_count, &classes);
Unless otherwise stated, all examples and declarations in this
specification use the C language.
A JVM TI environment can be obtained through the JNI Invocation API
GetEnv function:
jvmtiEnv *jvmti;
...
(*jvm)->GetEnv(jvm, &jvmti, JVMTI_VERSION_1_0);
Each call to GetEnv
creates a new JVM TI connection and thus
a new JVM TI environment.
The version argument of GetEnv must be
a JVM TI version.
The returned environment may have a different version than the
requested version but the returned environment must be compatible.
GetEnv will return JNI_EVERSION if a
compatible version is not available, if JVM TI is not supposed or
JVM TI is not supported in the current VM configuration.
Other interfaces may be added for creating JVM TI environments
in specific contexts.
Each environment has its own state (for example,
desired events,
event handling functions, and
capabilities).
An environment is released with
DisposeEnvironment.
Thus, unlike JNI which has one environment per thread, JVM TI environments work
across threads and are created dynamically.
jvmtiError function return value.
Some functions can return additional
values through pointers provided by the calling function.
In some cases, JVM TI functions allocate memory that your program must
explicitly deallocate. This is indicated in the individual JVM TI
function descriptions. Empty lists, arrays, sequences, etc are
returned as NULL.
In the event that the JVM TI function encounters
an error (any return value other than JVMTI_ERROR_NONE) the values
of memory referenced by argument pointers is undefined, but no memory
will have been allocated and no global references will have been allocated.
If the error occurs because of invalid input, no action will have occurred.
jobject and jclass)
and their derivatives
(jthread and jthreadGroup).
References passed to
JVM TI functions can be either global or local, but they must be
strong references. All references returned by JVM TI functions are
local references--these local references are created
during the JVM TI call.
Local references are a resource that must be managed (see the
JNI Documentation).
When threads return from native code all local references
are freed. Note that some threads, including typical
agent threads, will never return from native code.
A thread is ensured the ability to create sixteen local
references without the need for any explicit management.
For threads executing a limited number of JVM TI calls before
returning from native code
(for example, threads processing events),
it may be determined that no explicit management
is needed.
However, long running agent threads will need explicit
local reference management--usually with the JNI functions
PushLocalFrame and PopLocalFrame.
Conversely, to preserve references beyond the
return from native code, they must be converted to global references.
Allocate an area of memory through the JVM TI allocator.
The allocated
memory should be freed with Deallocate.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
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Deallocate mem using the JVM TI allocator.
This function should
be used to deallocate any memory allocated and returned
by a JVM TI function
(including memory allocated with Allocate).
All allocated memory must be deallocated
or the memory cannot be reclaimed.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
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jvmtiThreadInfo - Thread information structure
Get the state of a thread. The state of the thread is represented by the
answers to the hierarchical set of questions below:
The following definitions are used to convert JVM TI thread state to java.lang.Thread.State style states.
Rules There can be no more than one answer to a question, although there can be no answer (because the answer is unknown, does not apply, or none of the answers is correct). An answer is set only when the enclosing answers match. That is, no more than one of
JVMTI_THREAD_STATE_ALIVE is set).
And if any of these are set, the enclosing answer
JVMTI_THREAD_STATE_ALIVE is set.
No more than one of
JVMTI_THREAD_STATE_WAITING is set).
And if either is set, the enclosing answers
JVMTI_THREAD_STATE_ALIVE and
JVMTI_THREAD_STATE_WAITING are set.
No more than one of
JVMTI_THREAD_STATE_ALIVE and
JVMTI_THREAD_STATE_WAITING are set.
Also, if JVMTI_THREAD_STATE_SLEEPING is set,
then JVMTI_THREAD_STATE_WAITING_WITH_TIMEOUT is set.
If a state A is implemented using the mechanism of
state B then it is state A which
is returned by this function.
For example, if Thread.sleep(long)
is implemented using Object.wait(long)
then it is still JVMTI_THREAD_STATE_SLEEPING
which is returned.
More than one of
JVMTI_THREAD_STATE_ALIVE is set.
And finally,
JVMTI_THREAD_STATE_TERMINATED cannot be set unless
JVMTI_THREAD_STATE_ALIVE is not set.
The thread state representation is designed for extension in future versions
of the specification; thread state values should be used accordingly, that is
they should not be used as ordinals.
Most queries can be made by testing a single bit, if use in a switch statement is desired,
the state bits should be masked with the interesting bits.
All bits not defined above are reserved for future use.
A VM, compliant to the current specification, must set reserved bits to zero.
An agent should ignore reserved bits --
they should not be assumed to be zero and thus should not be included in comparisons.
Examples
Note that the values below exclude reserved and vendor bits.
The state of a thread blocked at a synchronized-statement would be:
The state of a thread which hasn't started yet would be:
The state of a thread at a Object.wait(3000) would be:
The state of a thread suspended while runnable would be:
Testing the State
In most cases, the thread state can be determined by testing the one bit corresponding
to that question. For example, the code to test if a thread is sleeping:
For waiting (that is, in Object.wait, parked, or sleeping) it would be:
For some states, more than one bit will need to be tested as is the case
when testing if a thread has not yet been started:
To distinguish timed from untimed Object.wait:
Relationship to java.lang.Thread.State
The thread state represented by java.lang.Thread.State
returned from java.lang.Thread.getState() is a subset of the
information returned from this function.
The corresponding java.lang.Thread.State can be determined
by using the provided conversion masks.
For example, this returns the name of the java.lang.Thread.State thread state:
This function may
only be called during the live
phase.
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Get all live threads.
The threads are Java programming language threads;
that is, threads that are attached to the VM.
A thread is live if java.lang.Thread.isAlive()
would return true, that is, the thread has
been started and has not yet died.
The universe of threads is determined by the context of the JVM TI
environment, which typically is all threads attached to the VM.
Note that this includes JVM TI agent threads
(see RunAgentThread).
This function may
only be called during the live
phase.
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Suspend the specified thread. If the calling thread is specified,
this function will not return until some other thread calls
ResumeThread.
If the thread is currently suspended, this function
does nothing and returns an error.
This function may
only be called during the live
phase.
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Suspend the request_count
threads specified in the
request_list array.
Threads may be resumed with
ResumeThreadList or
ResumeThread.
If the calling thread is specified in the
request_list array, this function will
not return until some other thread resumes it.
Errors encountered in the suspension of a thread
are returned in the results
array, not in the return value of this function.
Threads that are currently suspended are not suspended.
This function may
only be called during the live
phase.
|
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Resume a suspended thread.
Any threads currently suspended through
a JVM TI suspend function (eg.
SuspendThread)
or java.lang.Thread.suspend()
will resume execution;
all other threads are unaffected.
This function may
only be called during the live
phase.
|
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Resume the request_count
threads specified in the
request_list array.
Any thread suspended through
a JVM TI suspend function (eg.
SuspendThreadList)
or java.lang.Thread.suspend()
will resume execution.
This function may
only be called during the live
phase.
|
|||||||||||||||||||||||||||||||||||||
Send the specified asynchronous exception to the specified thread
(similar to java.lang.Thread.stop).
Normally, this function is used to kill the specified thread with an
instance of the exception ThreadDeath.
This function may
only be called during the live
phase.
|
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Interrupt the specified thread
(similar to java.lang.Thread.interrupt).
This function may
only be called during the live
phase.
|
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Get thread information. The fields of the jvmtiThreadInfo structure
are filled in with details of the specified thread.
This function may
only be called during the live
phase.
|
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Get information about the monitors owned by the
specified thread.
This function may
only be called during the live
phase.
|
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Get the object, if any, whose monitor the specified thread is waiting to
enter or waiting to regain through java.lang.Object.wait.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||
Agent supplied callback function.
This function is the entry point for an agent thread
started with
RunAgentThread.
|
|||||||||||||||
Starts the execution of an agent thread. with the specified native function.
The parameter arg is forwarded on to the
start function
(specified with proc) as its single argument.
This function allows the creation of agent threads
for handling communication with another process or for handling events
without the need to load a special subclass of java.lang.Thread or
implementer of java.lang.Runnable.
Instead, the created thread can run entirely in native code.
However, the created thread does require a newly created instance
of java.lang.Thread (referenced by the argument thread) to
which it will be associated.
The thread object can be created with JNI calls.
Ideally,
all calls to Java programming language
code should be done during the callback for the
VMInit event
to avoid any interaction with the target application.
The following thread priorities are useful:
The new thread is started as a daemon thread with the specified priority.
If enabled, a ThreadStart event will be sent.
Since the thread has been started, the thread will be live when this function
returns, unless the thread has died immediately.
The thread group of the thread is ignored -- specifically, the thread is not
added to the thread group and the thread is not seen on queries of the thread
group at either the Java programming language or JVM TI levels.
The thread is not visible to Java programming language queries but is
included in JVM TI queries (for example,
GetAllThreads and
GetAllStackTraces).
Upon execution of proc, the new thread will be attached to the
VM--see the JNI documentation on
Attaching to the VM.
This function may
only be called during the live
phase.
|
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The VM stores a pointer value associated with each environment-thread
pair. This pointer value is called thread-local storage.
This value is NULL unless set with this function.
Agents can allocate memory in which they store thread specific
information. By setting thread-local storage it can then be
accessed with
GetThreadLocalStorage.
This function is called by the agent to set the value of the JVM TI
thread-local storage. JVM TI supplies to the agent a pointer-size
thread-local storage that can be used to record per-thread
information.
This function may
only be called during the start or the live
phase.
|
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Called by the agent to get the value of the JVM TI thread-local
storage.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||||
jvmtiThreadGroupInfo - Thread group information structure
Return all top-level (parentless) thread groups in the VM.
This function may
only be called during the live
phase.
|
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Get information about the thread group. The fields of the jvmtiThreadGroupInfo structure
are filled in with details of the specified thread group.
This function may
only be called during the live
phase.
|
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Get the live threads and active subgroups in this thread group.
This function may
only be called during the live
phase.
|
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jvmtiFrameInfo - Stack frame information structurejvmtiStackInfo - Stack information structuretypedef struct {
jmethodID method;
jlocation location;
} jvmtiFrameInfo;
Information about a set of frames is returned in this structure:
typedef struct {
jthread thread;
jint state;
jvmtiFrameInfo* frame_buffer;
jint frame_count;
} jvmtiStackInfo;
jvmtiFrameInfo - Stack frame information structure |
||
| Field | Type | Description |
method | jmethodID | The method executing in this frame. |
location | jlocation |
The index of the instruction executing in this frame.
-1 if the frame is executing a native method.
|
jvmtiStackInfo - Stack information structure |
||
| Field | Type | Description |
thread | jthread | On return, the thread traced. |
state | jint |
On return, the thread state. See GetThreadState.
|
frame_buffer |
jvmtiFrameInfo
* | On return, this agent allocated buffer is filled with stack frame information. |
frame_count | jint |
On return, the number of records filled into
frame_buffer.
This will be
min(max_frame_count, stackDepth).
|
Get information about the stack of a thread.
If max_frame_count is less than the depth of the stack,
the max_frame_count deepest frames are returned,
otherwise the entire stack is returned.
Deepest frames are at the beginning of the returned buffer.
The following example causes up to five of the deepest frames
to be returned and (if there are any frames) the currently
executing method name to be printed.
The thread need not be suspended
to call this function.
The GetLineNumberTable
function can be used to map locations to line numbers. Note that
this mapping can be done lazily.
If platform dependent method invocations are used to launch a thread,
they may be included in the stack trace - that is, there may be frames
deeper than main() and run().
This function may
only be called during the live
phase.
|
|||||||||||||||||||||||||||||||||||||||||||
Get information about the stacks of all live threads
(including agent threads).
If max_frame_count is less than the depth of a stack,
the max_frame_count deepest frames are returned for that thread,
otherwise the entire stack is returned.
Deepest frames are at the beginning of the returned buffer.
All stacks are collected simultaneously, that is, no changes will occur to the
thread state or stacks between the sampling one thread and the next.
The threads need not be suspended.
This function may
only be called during the live
phase.
|
|||||||||||||||||||||||||||||||
Get information about the stacks of the supplied threads.
If max_frame_count is less than the depth of a stack,
the max_frame_count deepest frames are returned for that thread,
otherwise the entire stack is returned.
Deepest frames are at the beginning of the returned buffer.
All stacks are collected simultaneously, that is, no changes will occur to the
thread state or stacks between the sampling one thread and the next.
The threads need not be suspended.
If a thread terminates before the stack information is collected,
a zero length stack (jvmtiStackInfo.frame_count will be zero)
will be returned and the thread jvmtiStackInfo.state can be checked.
See the example for the similar function
GetAllStackTraces.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||
Get the number of frames currently in the specified thread's call stack.
If this function is called for a thread actively executing bytecodes (for example,
not the current thread and not suspended), the information returned is transient.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||
Pop the topmost stack frame of thread's stack.
Popping a frame takes you to the preceding frame.
When the thread is resumed, the execution
state of the thread is reset to the state
immediately before the called method was invoked.
That is (using
The Java Virtual Machine Specification terminology):
PopFrame and resuming the
thread the state of the stack is undefined.
To pop frames beyond the first,
these three steps must be repeated:
|
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For a Java programming language frame, return the location of the instruction
currently executing.
This function may
only be called during the live
phase.
|
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When the frame that is currently at depth
is popped from the stack, generate a
FramePop event. See the
FramePop event for details.
Only frames corresponding to non-native Java programming language
methods can receive notification.
The specified thread must either be the current thread
or the thread must be suspended.
This function may
only be called during the live
phase.
|
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SetTag function or by
callback functions such as jvmtiHeapObjectCallback
Tags are local to the environment; that is, the tags of one
environment are not visible in another.
Tags are jlong values which can be used
simply to mark an object or to store a pointer to more detailed
information. Objects which have not been tagged have an
tag of zero.
Setting a tag to zero makes the object untagged.
Heap Object Filter Enumeration ( jvmtiHeapObjectFilter)Constant Value Description JVMTI_HEAP_OBJECT_TAGGED1 Tagged objects only. JVMTI_HEAP_OBJECT_UNTAGGED2 Untagged objects only. JVMTI_HEAP_OBJECT_EITHER3 Either tagged or untagged objects.
Heap Root Kind Enumeration ( jvmtiHeapRootKind)Constant Value Description JVMTI_HEAP_ROOT_JNI_GLOBAL1 JNI global reference. JVMTI_HEAP_ROOT_SYSTEM_CLASS2 System class. JVMTI_HEAP_ROOT_MONITOR3 Monitor. JVMTI_HEAP_ROOT_STACK_LOCAL4 Stack local. JVMTI_HEAP_ROOT_JNI_LOCAL5 JNI local reference. JVMTI_HEAP_ROOT_THREAD6 Thread. JVMTI_HEAP_ROOT_OTHER7 Other.
Object Reference Enumeration ( jvmtiObjectReferenceKind)Constant Value Description JVMTI_REFERENCE_CLASS1 Reference from an object to its class. JVMTI_REFERENCE_FIELD2 Reference from an object to the value of one of its instance fields. For references of this kind the referrer_indexparameter to the jvmtiObjectReferenceCallback is the index of the the instance field. The index is based on the order of all the object's fields. This includes all fields of the directly declared static and instance fields in the class, and includes all fields (both public and private) fields declared in superclasses and superinterfaces. The index is thus calculated by summing the index of field in the directly declared class (seeGetClassFields), with the total number of fields (both public and private) declared in all superclasses and superinterfaces. The index starts at zero.JVMTI_REFERENCE_ARRAY_ELEMENT3 Reference from an array to one of its elements. For references of this kind the referrer_indexparameter to the jvmtiObjectReferenceCallback is the array index.JVMTI_REFERENCE_CLASS_LOADER4 Reference from a class to its class loader. JVMTI_REFERENCE_SIGNERS5 Reference from a class to its signers array. JVMTI_REFERENCE_PROTECTION_DOMAIN6 Reference from a class to its protection domain. JVMTI_REFERENCE_INTERFACE7 Reference from a class to one of its interfaces. JVMTI_REFERENCE_STATIC_FIELD8 Reference from a class to the value of one of its static fields. For references of this kind the referrer_indexparameter to the jvmtiObjectReferenceCallback is the index of the static field. The index is based on the order of the directly declared static and instance fields in the class (not inherited fields), starting at zero. SeeGetClassFields.JVMTI_REFERENCE_CONSTANT_POOL9 Reference from a class to a resolved entry in the constant pool. For references of this kind the referrer_indexparameter to the jvmtiObjectReferenceCallback is the index into constant pool table of the class, starting at 1. See The Constant Pool in the Java Virtual Machine Specification.
Iteration Control Enumeration ( jvmtiIterationControl)Constant Value Description JVMTI_ITERATION_CONTINUE1 Continue the iteration. If this is a reference iteration, follow the references of this object. JVMTI_ITERATION_IGNORE2 Continue the iteration. If this is a reference iteration, ignore the references of this object. JVMTI_ITERATION_ABORT0 Abort the iteration.
Rationale: The heap dumping functionality (below) uses a callback for each object. While it would seem that a buffered approach would provide better throughput, tests do not show this to be the case--possibly due to locality of memory reference or array access overhead.
Retrieve the tag associated with an object.
The tag is a long value typically used to store a
unique identifier or pointer to object information.
The tag is set with
SetTag.
Objects for which no tags have been set return a
tag value of zero.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||||||||
Set the tag associated with an object.
The tag is a long value typically used to store a
unique identifier or pointer to object information.
The tag is visible with
GetTag.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||||||
Force the VM to perform a garbage collection. The garbage collection is as complete as possible. This function does not cause finalizers to be run. This function does not return until the garbage collection is finished. Although garbage collection is as complete as possible there is no guarantee that alljvmtiError ForceGarbageCollection(jvmtiEnv* env) ObjectFree
events will have been
sent by the time that this function
returns. In particular, an object may be
prevented from being freed because it
is awaiting finalization.
This function may
only be called during the live
phase.
|
||||||||||||||
Agent supplied callback function.
Describes (but does not pass in) an object in the heap.
Return value should be JVMTI_ITERATION_CONTINUE to continue iteration,
or JVMTI_ITERATION_ABORT to stop iteration.
This callback must not use JNI functions.
This callback must not use JVM TI functions except those which
specifically allow such use (see the raw monitor, memory management,
and environment local storage functions).
An implementation may invoke this callback on an internal thread or
the thread which called the iteration function.
|
||||||||||||||||||
Agent supplied callback function.
Describes (but does not pass in) an object that is a root for the purposes
of garbage collection.
Return value should be JVMTI_ITERATION_CONTINUE to continue iteration,
JVMTI_ITERATION_IGNORE to continue iteration without pursuing
references from referree object or JVMTI_ITERATION_ABORT to stop iteration.
This callback must not use JNI functions.
This callback must not use JVM TI functions except those which
specifically allow such use (see the raw monitor, memory management,
and environment local storage functions).
An implementation may invoke this callback on an internal thread or
the thread which called the iteration function.
|
|||||||||||||||||||||
Agent supplied callback function.
Describes (but does not pass in) an object on the stack that is a root for
the purposes of garbage collection.
Return value should be JVMTI_ITERATION_CONTINUE to continue iteration,
JVMTI_ITERATION_IGNORE to continue iteration without pursuing
references from referree object or JVMTI_ITERATION_ABORT to stop iteration.
This callback must not use JNI functions.
This callback must not use JVM TI functions except those which
specifically allow such use (see the raw monitor, memory management,
and environment local storage functions).
An implementation may invoke this callback on an internal thread or
the thread which called the iteration function.
|
|||||||||||||||||||||||||||||||||
Agent supplied callback function.
Describes a reference from an object (the referrer) to another object
(the referree).
Return value should be JVMTI_ITERATION_CONTINUE to continue iteration,
JVMTI_ITERATION_IGNORE to continue iteration without pursuing
references from referree object or JVMTI_ITERATION_ABORT to stop iteration.
This callback must not use JNI functions.
This callback must not use JVM TI functions except those which
specifically allow such use (see the raw monitor, memory management,
and environment local storage functions).
An implementation may invoke this callback on an internal thread or
the thread which called the iteration function.
|
|||||||||||||||||||||||||||
This function iterates over all objects that are directly
and indirectly reachable from the specified object.
For each object A (known
as the referrer) with a reference to object B the specified
callback function is called to describe the object reference.
The callback is called exactly once for each reference from a referrer;
this is true even if there are reference cycles or multiple paths to
the referrer.
There may be more than one reference between a referrer and a referree,
These may be distinguished by the
jvmtiObjectReferenceCallback.reference_kind and
jvmtiObjectReferenceCallback.referrer_index.
The callback for an object will always occur after the callback for
its referrer.
During the execution of this function the state of the heap
does not change: no objects are allocated, no objects are
garbage collected, and the state of objects (including
held values) does not change.
As a result, threads executing Java
programming language code, threads attempting to resume the
execution of Java programming language code, and threads
attempting to execute JNI functions are typically stalled.
This function may
only be called during the live
phase.
|
|||||||||||||||||||||||||||||||||||
This function iterates over the root objects and all objects that
are directly and indirectly reachable from the root objects.
The root objects comprise the set of system classes,
JNI globals, references from thread stacks, and other objects used as roots
for the purposes of garbage collection.
For each root the heap_root_callback
or stack_ref_callback callback is called.
An object can be a root object for more than one reason and in that case
the appropriate callback is called for each reason.
For each object reference the object_ref_callback
callback function is called to describe the object reference.
The callback is called exactly once for each reference from a referrer;
this is true even if there are reference cycles or multiple paths to
the referrer.
There may be more than one reference between a referrer and a referree,
These may be distinguished by the
jvmtiObjectReferenceCallback.reference_kind and
jvmtiObjectReferenceCallback.referrer_index.
The callback for an object will always occur after the callback for
its referrer.
Roots are always reported to the profiler before any object references
are reported. In other words, the object_ref_callback
callback will not be called until the appropriate callback has been called
for all roots. If the object_ref_callback callback is
specified as NULL then this function returns after
reporting the root objects to the profiler.
During the execution of this function the state of the heap
does not change: no objects are allocated, no objects are
garbage collected, and the state of objects (including
held values) does not change.
As a result, threads executing Java
programming language code, threads attempting to resume the
execution of Java programming language code, and threads
attempting to execute JNI functions are typically stalled.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||
Iterate over all objects in the heap. This includes both reachable and
unreachable objects.
The object_filter parameter indicates the
objects for which the callback function is called. If this parameter
is JVMTI_HEAP_OBJECT_TAGGED then the callback will only be
called for every object that is tagged. If the parameter is
JVMTI_HEAP_OBJECT_UNTAGGED then the callback will only be
for objects that are not tagged. If the parameter
is JVMTI_HEAP_OBJECT_EITHER then the callback will be
called for every object in the heap, irrespective of whether it is
tagged or not.
During the execution of this function the state of the heap
does not change: no objects are allocated, no objects are
garbage collected, and the state of objects (including
held values) does not change.
As a result, threads executing Java
programming language code, threads attempting to resume the
execution of Java programming language code, and threads
attempting to execute JNI functions are typically stalled.
This function may
only be called during the live
phase.
|
|||||||||||||||||||||||||||||||||
Iterate over all objects in the heap that are instances of the specified class.
This includes both reachable and unreachable objects.
The object_filter parameter indicates the
objects for which the callback function is called. If this parameter
is JVMTI_HEAP_OBJECT_TAGGED then the callback will only be
called for every object that is tagged. If the parameter is
JVMTI_HEAP_OBJECT_UNTAGGED then the callback will only be
called for objects that are not tagged. If the parameter
is JVMTI_HEAP_OBJECT_EITHER then the callback will be
called for every object in the heap, irrespective of whether it is
tagged or not.
During the execution of this function the state of the heap
does not change: no objects are allocated, no objects are
garbage collected, and the state of objects (including
held values) does not change.
As a result, threads executing Java
programming language code, threads attempting to resume the
execution of Java programming language code, and threads
attempting to execute JNI functions are typically stalled.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||
Return objects in the heap with the specified tags.
The format is parallel arrays of objects and tags.
This function may
only be called during the live
phase.
|
|||||||||||||||||||||||||||||||||||||||||||||
GetLocalVariableTable.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||||
GetLocalInt can be used to retrieve int, char, byte, and
boolean values.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||||
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||||
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||||
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||||
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||||
SetLocalInt can be used to set int, char, byte, and
boolean values.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||
Set a breakpoint at the instruction indicated by
method and location.
An instruction can only have one breakpoint.
Whenever the designated instruction is about to be executed, a
Breakpoint event is generated.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||
Clear the breakpoint at the bytecode indicated by
method and location.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||
Generate a FieldAccess event
when the field specified
by klass and
field is about to be accessed.
An event will be generated for each access of the field
until it is canceled with
ClearFieldAccessWatch.
Field accesses from Java programming language code or from JNI code are watched,
fields modified by other means are not watched.
Note that JVM TI users should be aware that their own field accesses
will trigger the watch.
A field can only have one field access watch set.
Modification of a field is not considered an access--use
SetFieldModificationWatch
to monitor modifications.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||
Cancel a field access watch previously set by
SetFieldAccessWatch, on the
field specified
by klass and
field.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||
Generate a FieldModification event
when the field specified
by klass and
field is about to be modified.
An event will be generated for each modification of the field
until it is canceled with
ClearFieldModificationWatch.
Field modifications from Java programming language code or from JNI code are watched,
fields modified by other means are not watched.
Note that JVM TI users should be aware that their own field modifications
will trigger the watch.
A field can only have one field modification watch set.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||
Cancel a field modification watch previously set by
SetFieldModificationWatch, on the
field specified
by klass and
field.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||
jvmtiClassDefinition - Class redefinition description
Return an array of all classes loaded in the virtual machine.
The number of classes in the array is returned via
class_count_ptr, and the array itself via
classes_ptr.
Array classes of all types (including arrays of primitive types) are
included in the returned list. Primitive classes (for example,
java.lang.Integer.TYPE) are not included in this list.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||
Returns an array of those classes for which this class loader has
been recorded as an initiating loader. Each
class in the returned array was created by this class loader,
either by defining it directly or by delegation to another class loader.
See Creation and Loading
in the Java Virtual Machine Specification.
For JDK version 1.1 implementations that don't
recognize the distinction between initiating and defining class loaders,
this function should return all classes loaded in the virtual machine.
The number of classes in the array is returned via
class_count_ptr, and the array itself via
classes_ptr.
This function may
only be called during the live
phase.
|
|||||||||||||||||||||||||||||
For the class indicated by klass, return the
JNI
type signature
and the generic signature of the class.
For example, java.util.List is "Ljava/util/List;"
and int[] is "[I"
The returned name for primitive classes
is the type signature character of the corresponding primitive type.
For example, java.lang.Integer.TYPE is "I".
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||
Get the status of the class. Zero or more of the following bits can be
set.
This function may only be called during the start or the live phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||||
For the class indicated by klass, return the source file
name via source_name_ptr. The returned string
is a file name only and never contains a directory name.
For primitive classes (for example, java.lang.Integer.TYPE)
and for arrays this function returns
JVMTI_ERROR_ABSENT_INFORMATION.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||||||||||
For the class indicated by klass, return the access
flags
via modifiers_ptr.
Access flags are defined in the
Java Virtual Machine Specification.
If the class is an array class, then its public, private, and protected
modifiers are the same as those of its component type. For arrays of
primitives, this component type is represented by one of the primitive
classes (for example, java.lang.Integer.TYPE).
If the class is a primitive class, its public modifier is always true,
and its protected and private modifiers are always false.
If the class is an array class or a primitive class then its final
modifier is always true and its interface modifier is always false.
The values of its other modifiers are not determined by this specification.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||
For the class indicated by klass, return a count of
methods via method_count_ptr and a list of
method IDs via methods_ptr. The method list contains
constructors and static initializers as well as true methods.
Only directly declared methods are returned (not inherited methods).
An empty method list is returned for array classes and primitive classes
(for example, java.lang.Integer.TYPE).
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||||||||||||||
For the class indicated by klass, return a count of fields
via field_count_ptr and a list of field IDs via
fields_ptr.
Only directly declared fields are returned (not inherited fields).
Fields are returned in the order they occur in the class file.
An empty field list is returned for array classes and primitive classes
(for example, java.lang.Integer.TYPE).
Use JNI to determine the length of an array.
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||||||||
Return the direct super-interfaces of this class. For a class, this
function returns the interfaces declared in its implements
clause. For an interface, this function returns the interfaces declared in
its extends clause.
An empty interface list is returned for array classes and primitive classes
(for example, java.lang.Integer.TYPE).
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||||||||
Determines whether a class object reference represents an interface.
The jboolean result is
JNI_TRUE if the "class" is actually an interface,
JNI_FALSE otherwise.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||
Determines whether a class object reference represents an array.
The jboolean result is
JNI_TRUE if the class is an array,
JNI_FALSE otherwise.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||
For the class indicated by klass, return via
classloader_ptr a reference to the class loader for the
class.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||
For the class indicated by klass, return the debug
extension via source_debug_extension_ptr.
The returned string
contains exactly the debug extension information present in the
class file of klass.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||||||||||
All classes given are redefined according to the definitions supplied. See the description of bytecode instrumentation for usage information. An original version of method is considered equivalent to the new version if:
IsMethodObsolete.
The new method version will be used on new invokes.
If a method has active stack frames, those active frames continue to
run the bytecodes of the original method version.
If resetting of stack frames is desired, use
PopFrame
to pop frames with obsolete method versions.
This function does not cause any initialization except that which
would occur under the customary JVM semantics.
In other words, redefining a class does not cause its initializers to be
run. The values of static fields will remain as they were
prior to the call.
Threads need not be suspended.
All breakpoints in the class are cleared.
All attributes are updated.
Instances of the redefined class are not affected -- fields retain their
previous values.
Tags on the instances are
also unaffected.
In response to this call, the JVM TI event
Class File Load Hook
will be sent (if enabled), but no other JVM TI events will be sent.
The redefinition may change method bodies, the constant pool and attributes.
The redefinition must not add, remove or rename fields or methods, change the
signatures of methods, change modifiers, or change inheritance.
These restrictions may be lifted in future versions.
See the error return description below for information on error codes
returned if an unsupported redefinition is attempted.
This function may
only be called during the live
phase.
|
|||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
jvmtiMonitorUsage - Object monitor usage information
For the object indicated by object,
return via size_ptr the size of the object.
This size is an implementation-specific approximation of
the amount of storage consumed by this object.
It may include some or all of the object's overhead, and thus
is useful for comparison within an implementation but not
between implementations.
The estimate may change during a single invocation of the JVM.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||
For the object indicated by object,
return via hash_code_ptr a hash code.
This hash code could be used to maintain a hash table of object references,
however, on some implementations this can cause significant performance
impacts--in most cases
tags
will be a more efficient means of associating information with objects.
This function guarantees
the same hash code value for a particular object throughout its life
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||
Get information about the object's monitor. The fields of the jvmtiMonitorUsage structure
are filled in with information about usage of the monitor.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||||
For the field indicated by klass and field,
return the field name via name_ptr and field signature via
signature_ptr.
The field signatures are defined in the JNI Specification and in the
The Java Virtual Machine Specification
where they are referred to as
Field Descriptors.
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||||||||||
For the field indicated by klass and field
return the class that defined it via declaring_class_ptr.
The declaring class will either be klass, a superclass, or
an implemented interface.
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||||||
For the field indicated by klass and field
return the access flags via modifiers_ptr.
Access flags are defined in the
Java Virtual Machine Specification
.
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||||||
For the field indicated by klass and field, return a
value indicating whether the field is synthetic via is_synthetic_ptr.
Synthetic fields are generated by the compiler but not present in the
original source code.
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||||||||||||
jvmtiLineNumberEntry - Line number table entryjvmtiLocalVariableEntry - Local variable table entry
For the method indicated by method,
return the method name via name_ptr and method signature via
signature_ptr.
The method signatures are defined in the JNI Specification and in the
The Java Virtual Machine Specification
where they are referred to as
Method Descriptors.
Note this is different
than method signatures as defined in the Java Language Specification.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||||||
For the method indicated by method,
return the class that defined it via declaring_class_ptr.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||
For the method indicated by method,
return the access flags via modifiers_ptr.
Access flags are defined in the
Java Virtual Machine Specification
.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||
For the method indicated by method,
return the number of local variable slots used by the method,
including the local variables used to pass parameters to the
method on its invocation.
See max_locals in the
Code Attribute
section of the The JavaTM Virtual Machine Specification.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||||
For the method indicated by method,
return via max_ptr the number of local variable slots used
by the method's arguments.
Note that two-word arguments use two slots.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||||
For the method indicated by method,
return a table of source line number entries. The size of the table is
returned via entry_count_ptr and the table itself is
returned via table_ptr.
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||||||||||||||||||||||||||||
For the method indicated by method,
return the beginning and ending addresses through
start_location_ptr and end_location_ptr. In a
conventional byte code indexing scheme,
start_location_ptr will always point to zero
and end_location_ptr
will always point to the byte code count minus one.
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||||||||||
Return local variable information. This function may only be called during the live phase.
|
|||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
For the method indicated by method,
return the byte codes that implement the method. The number of
bytecodes is returned via bytecode_count_ptr. The byte codes
themselves are returned via bytecodes_ptr.
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||||||||||||||||||||
For the method indicated by method, return a
value indicating whether the method is native via is_native_ptr
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||
For the method indicated by method, return a
value indicating whether the method is synthetic via is_synthetic_ptr.
Synthetic methods are generated by the compiler but not present in the
original source code.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||||||||
Determine if a method ID refers to an obsolete method version.
See RedefineClasses for details.
This function may
only be called during the start or the live
phase.
|
||||||||||||||||||||||||||||||||
Create a raw monitor.
This function may
only be called during the OnLoad or the live
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
||||||||||||||||||||||||||
Destroy the raw monitor.
If the monitor being destroyed has been entered by this thread, it will be
exited before it is destroyed.
If the monitor being destroyed has been entered by another thread,
an error will be returned and the monitor will not be destroyed.
This function may
only be called during the OnLoad or the live
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||||||||
Gain exclusive ownership of a raw monitor.
The same thread may enter a monitor more then once.
The thread must
exit
the monitor the same number of times as it is entered.
If a monitor is entered during OnLoad (before attached threads exist)
and has not exited when attached threads come into existence, the enter
is considered to have occurred on the main thread.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||||||
Release exclusive ownership of a raw monitor.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||||||||
Wait for notification of the raw monitor.
Causes the current thread to wait until either another thread calls
RawMonitorNotify or
RawMonitorNotifyAll
for the specified raw monitor, or the specified
timeout
has elapsed.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
||||||||||||||||||||||||||||
Notify a single thread waiting on the raw monitor.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||||||||
Notify all threads waiting on the raw monitor.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||||||||
NewGlobalRef JNI call in order to count reference
creation.
JNIEnv original_jni_Functions;
JNIEnv redirected_jni_Functions;
int my_global_ref_count = 0;
jobject
MyNewGlobalRef(JNIEnv *jni_env, jobject lobj) {
++my_global_ref_count;
return originalJNIFunctions->NewGlobalRef(env, lobj);
}
void
myInit() {
jvmtiError err;
err = (*jvmti_env)->GetJNIFunctionTable(jvmti_env, &original_jni_Functions);
if (err != JVMTI_ERROR_NONE) {
die();
}
err = (*jvmti_env)->GetJNIFunctionTable(jvmti_env, &redirected_jni_Functions);
if (err != JVMTI_ERROR_NONE) {
die();
}
redirectedJNIFunctions->NewGlobalRef = MyNewGlobalRef;
err = (*jvmti_env)->SetJNIFunctionTable(jvmti_env, redirected_jni_Functions);
if (err != JVMTI_ERROR_NONE) {
die();
}
}
Sometime after myInit is called the user's JNI
code is executed which makes the call to create a new global
reference. Instead of going to the normal JNI implementation
the call goes to myNewGlobalRef. Note that a
copy of the original function table is kept so that the normal
JNI function can be called after the data is collected.
Note also that any JNI functions which are not overwritten
will behave normally.
Set the JNI function table
in all current and future JNI environments.
As a result, all future JNI calls are directed to the specified functions.
Use GetJNIFunctionTable to get the
function table to pass.
The table is copied--changes to the local copy of the
table have no effect.
This function affects only the function table, all other aspects of the environment are
unaffected.
See the examples above.
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||
Get the JNI function table.
The JNI function table is copied into allocated memory.
If SetJNIFunctionTable
has been called, the modified (not the original) function
table is returned.
Only the function table is copied, no other aspects of the environment
are copied.
See the examples above.
This function may
only be called during the start or the live
phase.
|
|||||||||||||||||||||
Set the functions to be called for each event.
The callbacks are specified by supplying a replacement function table.
The function table is copied--changes to the local copy of the
table have no effect.
This is an atomic action, all callbacks are set at once.
No events are sent before this function is called.
When an entry is NULL or when the event is beyond
size_of_callbacks no event is sent.
Details on events are
described later in this document.
An event must be enabled and have a callback in order to be
sent--the order in which this function and
SetEventNotificationMode
are called does not affect the result.
This function may
only be called during the OnLoad or the live
phase.
|
||||||||||||||||||||||||
Control the generation of events. If thread is NULL,
the event is enabled or disabled globally; otherwise, it is
enabled or disabled for a particular thread.
An event is generated for
a particular thread if it is enabled either at the thread or global
levels.
See below for information on specific events.
The following events cannot be controlled at the thread
level through this function.
|
||||||||||||||||||||||||||||||||||||||||||||||||
Generate events to represent the current state of the VM.
For example, if event_type is
JVMTI_EVENT_COMPILED_METHOD_LOAD,
a CompiledMethodLoad event will be
sent for each currently compiled method.
Methods that were loaded and now have been unloaded are not sent.
The history of what events have previous been sent does not
effect what events are sent--all currently compiled methods
will be sent each time this method is called.
This function is useful when
events may have been missed due to the agent attaching after program
execution begins, this function generates the missed events.
Attempts to execute Java programming language code or
JNI functions may be paused until this function returns -
so neither should be called from the thread sending the event.
This function returns only after the missed events have been
sent, processed and have returned.
The event may be sent on a different thread than the thread
on which the event occurred.
The callback for the event must be set with
SetEventCallbacks
and the event must be enabled with
SetEventNotificationMode
or the events will not occur.
If the VM no longer has the information to generate some or
all of the requested events, the events are simply not sent -
no error is returned.
Only the following events are supported:
This function may
only be called during the live
phase.
|
|||||||||||||||||||||||||||||||
jvmtiParamInfo - Extension Function/Event Parameter InfojvmtiExtensionFunctionInfo - Extension Function InfojvmtiExtensionEventInfo - Extension Event Info
Extension Function/Event Parameter Types ( jvmtiParamTypes)Constant Value Description JVMTI_TYPE_JBYTE101 Java programming language primitive type - byte. JNI typejbyte.JVMTI_TYPE_JCHAR102 Java programming language primitive type - char. JNI typejchar.JVMTI_TYPE_JSHORT103 Java programming language primitive type - short. JNI typejshort.JVMTI_TYPE_JINT104 Java programming language primitive type - int. JNI typejint.JVMTI_TYPE_JLONG105 Java programming language primitive type - long. JNI typejlong.JVMTI_TYPE_JFLOAT106 Java programming language primitive type - float. JNI typejfloat.JVMTI_TYPE_JDOUBLE107 Java programming language primitive type - double. JNI typejdouble.JVMTI_TYPE_JBOOLEAN108 Java programming language primitive type - boolean. JNI typejboolean.JVMTI_TYPE_JOBJECT109 Java programming language object type - java.lang.Object. JNI typejobject. Returned values are JNI local references and must be managed.JVMTI_TYPE_JTHREAD110 Java programming language object type - java.lang.Thread. JVM TI typejthread. Returned values are JNI local references and must be managed.JVMTI_TYPE_JCLASS111 Java programming language object type - java.lang.Class. JNI typejclass. Returned values are JNI local references and must be managed.JVMTI_TYPE_JVALUE112 Union of all Java programming language primitive and object types - JNI type jvalue. Returned values which represent object types are JNI local references and must be managed.JVMTI_TYPE_JFIELDID113 Java programming language field identifier - JNI type jfieldID.JVMTI_TYPE_JMETHODID114 Java programming language method identifier - JNI type jmethodID.JVMTI_TYPE_CCHAR115 C programming language type - char.JVMTI_TYPE_CVOID116 C programming language type - void.JVMTI_TYPE_JNIENV117 JNI environment - JNIEnv. Should be used with the correctjvmtiParamKindto make it a pointer type.
Extension Function/Event Parameter Kinds ( jvmtiParamKind)Constant Value Description JVMTI_KIND_IN91 Ingoing argument - foo.JVMTI_KIND_IN_PTR92 Ingoing pointer argument - const foo*.JVMTI_KIND_IN_BUF93 Ingoing array argument - const foo*.JVMTI_KIND_ALLOC_BUF94 Outgoing allocated array argument - foo**. Free withDeallocate.JVMTI_KIND_ALLOC_ALLOC_BUF95 Outgoing allocated array of allocated arrays argument - foo***. Free withDeallocate.JVMTI_KIND_OUT96 Outgoing argument - foo*.JVMTI_KIND_OUT_BUF97 Outgoing array argument (pre-allocated by agent) - foo*. Do notDeallocate.
typedef struct {
char* name;
jvmtiParamKind kind;
jvmtiParamTypes base_type;
jboolean null_ok;
} jvmtiParamInfo;
jvmtiParamInfo - Extension Function/Event Parameter Info |
||
| Field | Type | Description |
name | char* | The parameter name, encoded as a modified UTF-8 string |
kind | jvmtiParamKind | The kind of the parameter - type modifiers |
base_type | jvmtiParamTypes |
The base type of the parameter - modified by kind
|
null_ok | jboolean |
Is a NULL argument permitted? Applies only to pointer and object types.
|
This is the implementation-specific extension function.
|
||||||||||||
Returns the set of extension functions. This function may only be called during the OnLoad or the live phase.
|
|||||||||||||||||||||||||||||||||||||||||||||||||||||
Returns the set of extension events. This function may only be called during the OnLoad or the live phase.
|
|||||||||||||||||||||||||||||||||||||||||||||||
This is the implementation-specific event.
The event handler is set with
SetExtensionEventCallback.
Event handlers for extension events must be declared varargs to match this definition.
Failure to do so could result in calling convention mismatch and undefined behavior
on some platforms.
For example, if the jvmtiParamInfo
returned by GetExtensionEvents indicates that
there is a jint parameter, the event handler should be
declared:
Note the terminal "..." which indicates varargs.
|
||||||||||||
Sets the callback function for an extension event and
enables the event. Or, if the callback is NULL, disables
the event. Note that unlike standard events, setting
the callback and enabling the event are a single operation.
This function may
only be called during the OnLoad or the live
phase.
|
||||||||||||||||||||||||
jvmtiCapabilities - Capabilities of an EnvironmentOnLoad or live phase in any environmentOnLoad phaseOnLoad phaseOnLoad phase (before bytecode
execution begins) and would have a large impact on execution speed
even if single stepping was never used.OnLoad phase but the overhead (a test
and branch on each instruction) would be considerably less.OnLoad phase. For most
virtual machines certain capabilities require special set up for
the virtual machine and this set up must happen
during the OnLoad phase, before the virtual machine begins execution.
Once a capability is added, it can
only be removed if explicitly relinquished by the environment.
The agent can,
determine what
capabilities this VM can potentially provide,
add the capabilities
to be used,
release capabilities
which are no longer needed, and
examine the currently available
capabilities.
OnLoad function)
wants to enable all possible capabilities.
Note that, in general, this is not advisable as the agent may suffer
a performance penalty for functionality it is not using.
The code might look like this in C:
jvmtiCapabilities capa;
jvmtiError err;
err = (*jvmti)->GetPotentialCapabilities(jvmti, &capa);
if (err == JVMTI_ERROR_NONE) {
err = (*jvmti)->AddCapabilities(jvmti, &capa);
For example, if an agent wants to check if it can get
the bytecodes of a method (that is, it wants to check
if it previously added this capability and has not
relinquished it), the code might
look like this in C:
jvmtiCapabilities capa;
jvmtiError err;
err = (*jvmti)->GetCapabilities(jvmti, &capa);
if (err == JVMTI_ERROR_NONE) {
if (capa.can_get_bytecodes) { ... } }
jvmtiCapabilities)
which contains boolean flags corresponding to each capability:
typedef struct {
unsigned int can_tag_objects : 1;
unsigned int can_generate_field_modification_events : 1;
unsigned int can_generate_field_access_events : 1;
unsigned int can_get_bytecodes : 1;
unsigned int can_get_synthetic_attribute : 1;
unsigned int can_get_owned_monitor_info : 1;
unsigned int can_get_current_contended_monitor : 1;
unsigned int can_get_monitor_info : 1;
unsigned int can_pop_frame : 1;
unsigned int can_redefine_classes : 1;
unsigned int can_signal_thread : 1;
unsigned int can_get_source_file_name : 1;
unsigned int can_get_line_numbers : 1;
unsigned int can_get_source_debug_extension : 1;
unsigned int can_access_local_variables : 1;
unsigned int can_maintain_original_method_order : 1;
unsigned int can_generate_single_step_events : 1;
unsigned int can_generate_exception_events : 1;
unsigned int can_generate_frame_pop_events : 1;
unsigned int can_generate_breakpoint_events : 1;
unsigned int can_suspend : 1;
unsigned int can_redefine_any_class : 1;
unsigned int can_get_current_thread_cpu_time : 1;
unsigned int can_get_thread_cpu_time : 1;
unsigned int can_generate_method_entry_events : 1;
unsigned int can_generate_method_exit_events : 1;
unsigned int can_generate_all_class_hook_events : 1;
unsigned int can_generate_compiled_method_load_events : 1;
unsigned int can_generate_monitor_events : 1;
unsigned int can_generate_vm_object_alloc_events : 1;
unsigned int can_generate_native_method_bind_events : 1;
unsigned int can_generate_garbage_collection_events : 1;
unsigned int can_generate_object_free_events : 1;
unsigned int : 15;
unsigned int : 16;
unsigned int : 16;
unsigned int : 16;
unsigned int : 16;
unsigned int : 16;
} jvmtiCapabilities;
jvmtiCapabilities - Capabilities of an Environment |
||
All types are unsigned int : 1 |
||
| Field | Description | |
can_tag_objects | Can set and get tags, as described in the Heap category. | |
can_generate_field_modification_events |
Can set watchpoints on field modification -
SetFieldModificationWatch
| |
can_generate_field_access_events |
Can set watchpoints on field access -
SetFieldAccessWatch
| |
can_get_bytecodes |
Can get bytecodes of a method GetBytecodes
| |
can_get_synthetic_attribute |
Can test if a field or method is synthetic -
IsFieldSynthetic and
IsMethodSynthetic
| |
can_get_owned_monitor_info |
Can get information about ownership of monitors -
GetOwnedMonitorInfo
| |
can_get_current_contended_monitor |
Can GetCurrentContendedMonitor
| |
can_get_monitor_info |
Can GetObjectMonitorUsage
| |
can_pop_frame |
Can pop frames off the stack - PopFrame
| |
can_redefine_classes |
Can redefine classes with RedefineClasses.
Bytecodes of the original and redefined methods can be different.
The constant pool and attributes can also be different.
| |
can_signal_thread | Can send stop or interrupt to threads | |
can_get_source_file_name | Can get the source file name of a class | |
can_get_line_numbers | Can get the line number table of a method | |
can_get_source_debug_extension | Can get the source debug extension of a class | |
can_access_local_variables | Can set and get local variables | |
can_maintain_original_method_order | Can return methods in the order they occur in the class file | |
can_generate_single_step_events | Can get single step events | |
can_generate_exception_events | Can get exception thrown and exception catch events | |
can_generate_frame_pop_events |
Can set and thus get
FramePop events
| |
can_generate_breakpoint_events |
Can set and thus get
Breakpoint events
| |
can_suspend | Can suspend and resume threads | |
can_redefine_any_class | RedefineClasses can be called on any class (can_redefine_classes must also be set) | |
can_get_current_thread_cpu_time | Can get current thread CPU time | |
can_get_thread_cpu_time | Can get thread CPU time | |
can_generate | Can generate method entry events on entering a method | |
can_generate | Can generate method exit events on leaving a method | |
can_generate | Can generate ClassFileLoadHook events for every loaded class. | |
can_generate | Can generate events when a method is compiled or unloaded | |
can_generate | Can generate events on monitor activity | |
can_generate | Can generate events on VM allocation of an object | |
can_generate | Can generate events when a native method is bound to its implementation | |
can_generate | Can generate events when garbage collection begins or ends | |
can_generate | Can generate events when the garbage collector frees an object | |
Returns via capabilities_ptr the JVM TI
features that can potentially be possessed by this environment
at this time.
The returned capabilities differ from the complete set of capabilities
implemented by the VM in two cases: another environment possesses
capabilities that can only be possessed by one environment, or the
current phase is live,
and certain capabilities can only be added during the OnLoad phase.
The AddCapabilities function
may be used to set any or all or these capabilities.
Currently possessed capabilities are included.
Typically this function is used in the OnLoad function.
Some virtual machines may allow a limited set of capabilities to be
added in the live phase.
In this case, the set of potentially available capabilities
will likely differ from the OnLoad phase set.
See the
Capability Examples.
This function may
only be called during the OnLoad or the live
phase.
|
|||||||||||||||||||||
Set new capabilities by adding the capabilities pointed to by
capabilities_ptr.
All previous capabilities are retained.
Typically this function is used in the OnLoad function.
Some virtual machines may allow a limited set of capabilities to be
added in the live phase.
See the
Capability Examples.
This function may
only be called during the OnLoad or the live
phase.
|
|||||||||||||||||||||||
Relinquish the capabilities pointed to by
capabilities_ptr.
Some implementations may allow only one environment to have a capability
(see the capability introduction).
This function releases capabilities
so that they may be used by other agents.
All other capabilities are retained.
The capability will no longer be present in GetCapabilities.
Attempting to relinquish a capability that the agent does not possess is not an error.
This function may
only be called during the OnLoad or the live
phase.
|
|||||||||||||||||||||
Returns via capabilities_ptr the optional JVM TI
features which this environment currently possesses.
An environment does not possess a capability unless it has been successfully added with
AddCapabilities.
An environment only loses possession of a capability if it has been relinquished with
RelinquishCapabilities. Thus, this function returns the net result
of the AddCapabilities and RelinquishCapabilities calls which
have been made.
See the
Capability Examples.
This function may
be called during any
phase.
|
|||||||||||||||||||||
jvmtiTimerInfo - Timer Infotypedef struct {
jlong max_value;
jboolean may_skip_forward;
jboolean may_skip_backward;
jvmtiTimerKind kind;
jlong reserved1;
jlong reserved2;
} jvmtiTimerInfo;
Where the timer kind is --
Timer Kinds ( jvmtiTimerKind)Constant Value Description JVMTI_TIMER_USER_CPU30 CPU time that a thread is in user mode. JVMTI_TIMER_TOTAL_CPU31 CPU time that a thread is in user or system mode. JVMTI_TIMER_ELAPSED32 Elapsed time.
jvmtiTimerInfo - Timer Info |
||
| Field | Type | Description |
max_value | jlong | The maximum value the timer can reach. After this value is reached the timer wraps back to zero. This is an unsigned value. If tested or printed as a jlong (signed value) it may appear to be a negative number. |
may_skip_forward | jboolean | If true, the timer can be externally adjusted and as a result skip forward. If false, the timer value will never increase faster than real time. |
may_skip_backward | jboolean | If true, the timer can be externally adjusted and as a result skip backward. If false, the timer value will be monotonically increasing. |
kind | jvmtiTimerKind |
The kind of timer.
On a platform that does not distinguish between user and system time, JVMTI_TIMER_TOTAL_CPU
is returned.
|
reserved1 | jlong | Reserved for future use. |
reserved2 | jlong | Reserved for future use. |
Get information about the
GetCurrentThreadCpuTime timer.
The fields of the jvmtiTimerInfo structure
are filled in with details about the timer.
This information is specific to the platform and the implementation of
GetCurrentThreadCpuTime and thus
does not vary by thread nor does it vary
during a particular invocation of the VM.
Note that the implementations of GetCurrentThreadCpuTime
and GetThreadCpuTime may differ, and thus the values
returned by GetCurrentThreadCpuTimerInfo
and GetThreadCpuTimerInfo
may differ -- see GetCurrentThreadCpuTime for more information.
This function may
only be called during the start or the live
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||||||||||||
Return the CPU time utilized by the current thread.
Note that the GetThreadCpuTime
function provides CPU time for any thread, including
the current thread. GetCurrentThreadCpuTime
exists to support platforms which cannot
supply CPU time for threads other than the current
thread or which have more accurate information for
the current thread (see
GetCurrentThreadCpuTimerInfo vs
GetThreadCpuTimerInfo).
On many platforms this call will be equivalent to:
This function may only be called during the start or the live phase. This function may be called from the callbacks to the Heap iteration functions, or from the event handles for theGetThreadCpuTime(env, NULL, nanos_ptr) GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||||||||||||
Get information about the
GetThreadCpuTime timer.
The fields of the jvmtiTimerInfo structure
are filled in with details about the timer.
This information is specific to the platform and the implementation of
GetThreadCpuTime and thus
does not vary by thread nor does it vary
during a particular invocation of the VM.
Note that the implementations of GetCurrentThreadCpuTime
and GetThreadCpuTime may differ, and thus the values
returned by GetCurrentThreadCpuTimerInfo
and GetThreadCpuTimerInfo
may differ -- see GetCurrentThreadCpuTime for more information.
This function may
only be called during the live
phase.
|
|||||||||||||||||||||||||||
Return the CPU time utilized by the specified thread.
Get information about this timer with
GetThreadCpuTimerInfo.
This function may
only be called during the live
phase.
|
||||||||||||||||||||||||||||||||||
Get information about the
GetTime timer.
The fields of the jvmtiTimerInfo structure
are filled in with details about the timer.
This information will not change during a particular invocation of the VM.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||||||
Return the current value of the system timer, in nanoseconds.
The value returned represents nanoseconds since some fixed but
arbitrary time (perhaps in the future, so values may be
negative). This function provides nanosecond precision, but not
necessarily nanosecond accuracy. No guarantees are made about
how frequently values change.
Get information about this timer with
GetTimerInfo.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||||||
Returns the number of processors available to the Java virtual machine.
This value may change during a particular invocation of the virtual machine.
Applications that are sensitive to the number of available processors should
therefore occasionally poll this property.
This function may
be called during any
phase.
|
|||||||||||||||||||||
After the
bootstrap
class loader
unsuccessfully searches for a class,
the specified platform-dependent search path segment will be searched as well.
This function can be used to cause instrumentation classes to be
defined by the bootstrap class loader.
Only one segment (typically a directory or JAR file) may be specified in the segment.
This function may be called multiple times to add multiple segments, the segments
will be searched in the order that this function was called.
This function may
only be called during the OnLoad
phase.
|
|||||||||||||||||||||||
The list of VM system property keys which may be used with
GetSystemProperty is returned.
It is strongly recommended that virtual machines provide the
following property keys:
java.lang.System.getProperties.
JNI method invocation may be used to access
java.lang.System.getProperties.
The set of properties may grow during execution.
This function may
only be called during the OnLoad or the live
phase.
|
||||||||||||||||||||||||||
Return a VM system property value given the property key.
The function GetSystemProperties
returns the set of property keys which may be used.
The properties which can be retrieved may grow during
execution.
Since this is a VM view of system properties, the values
of properties may differ from that returned by
java.lang.System.getProperty(String).
A typical VM might copy the values of the VM system
properties into the Properties held by
java.lang.System during the initialization
of that class. Thereafter any changes to the VM system
properties (with SetSystemProperty)
or the java.lang.System system properties
(with java.lang.System.setProperty(String,String))
would cause the values to diverge.
JNI method invocation may be used to access
java.lang.System.getProperty(String).
This function may
only be called during the OnLoad or the live
phase.
|
||||||||||||||||||||||||||||
Set a VM system property value.
The function GetSystemProperties
returns the set of property keys, some of these may be settable.
See GetSystemProperty.
This function may
only be called during the OnLoad
phase.
|
||||||||||||||||||||||||||
Return the current phase of VM execution. The phases proceed in sequence: In the case of start-up failure the VM will proceed directly to the dead phase skipping intermediate phases and neither a VMInit nor
VMDeath event will be sent.
Most JVM TI functions operate only in the live phase.
The following functions operate in either the OnLoad or live phases:
OnLoad phase:
The following functions operate in the start or live phases:
|
||||||||||||||||||||||||||||||||||||||||||
Shutdown a JVM TI connection created with JNIjvmtiError DisposeEnvironment(jvmtiEnv* env) GetEnv
(see Environments).
Dispose of any resources held by the environment.
Suspended threads are not resumed, this must be done explicitly
by the agent.
Allocated memory is not released, this must be done explicitly
by the agent.
This environment may not be used after this call.
This call returns to the caller.
This function may
be called during any
phase.
|
||||||||||||||
The VM stores a pointer value associated with each environment.
This pointer value is called environment-local storage.
This value is NULL unless set with this function.
Agents can allocate memory in which they store environment specific
information. By setting environment-local storage it can then be
accessed with
GetEnvironmentLocalStorage.
Called by the agent to set the value of the JVM TI
environment-local storage. JVM TI supplies to the agent a pointer-size
environment-local storage that can be used to record per-environment
information.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||
Called by the agent to get the value of the JVM TI environment-local
storage.
This function may
be called during any
phase.
This function may be called from the callbacks to the
Heap iteration functions, or from the
event handles for the
GarbageCollectionStart,
GarbageCollectionFinish,
and ObjectFree events.
|
|||||||||||||||||||||
Return the JVM TI version via version_ptr.
The return value is the version identifier.
The version identifier includes major, minor and micro
version as well as the interface type.
This function may be called during any phase.
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Return the symbolic name for an
error code.
For example
GetErrorName(env, JVMTI_ERROR_NONE, &err_name)
would return in err_name the string
"JVMTI_ERROR_NONE".
This function may
be called during any
phase.
|
||||||||||||||||||||||||||
Control verbose output. This is the output which typically is sent to stderr.
This function may
be called during any
phase.
|
||||||||||||||||||||||||||||||||||||||||||
Although the greatest functionality is achieved with location information referencing the virtual machine bytecode index, the definition of jlocation has intentionally been left unconstrained to allow VM
implementations that do not have this information.
This function describes the representation of jlocation used in this VM.
If the returned format is JVMTI_JLOCATION_JVMBCI,
jlocations can
be used as in indices into the array returned by
GetBytecodes.
This function may be called during any phase.
|
||||||||||||||||||||||||||||||||||||
jvmtiError error code.
It is the responsibility of the agent to call JVM TI functions with
valid parameters and in the proper context (calling thread is attached,
phase is correct, etc.).
Detecting some error conditions may be difficult, inefficient, or
impossible for an implementation.
The errors listed in
Function Specific Required Errors
must be detected by the implementation.
All other errors represent the recommended response to the error
condition.
JVMTI_ERROR_NONE (0)
JVMTI_ERROR_NULL_POINTER (100)
NULL.
JVMTI_ERROR_OUT_OF_MEMORY (110)
JVMTI_ERROR_ACCESS_DENIED (111)
JVMTI_ERROR_UNATTACHED_THREAD (115)
AttachCurrentThread in the JNI invocation API.
JVMTI_ERROR_INVALID_ENVIRONMENT (116)
JVMTI_ERROR_WRONG_PHASE (112)
JVMTI_ERROR_INTERNAL (113)
JVMTI_ERROR_INVALID_PRIORITY (12)
JVMTI_ERROR_THREAD_NOT_SUSPENDED (13)
JVMTI_ERROR_THREAD_SUSPENDED (14)
JVMTI_ERROR_THREAD_NOT_ALIVE (15)
JVMTI_ERROR_CLASS_NOT_PREPARED (22)
JVMTI_ERROR_NO_MORE_FRAMES (31)
JVMTI_ERROR_OPAQUE_FRAME (32)
JVMTI_ERROR_DUPLICATE (40)
JVMTI_ERROR_NOT_FOUND (41)
JVMTI_ERROR_NOT_MONITOR_OWNER (51)
JVMTI_ERROR_INTERRUPT (52)
JVMTI_ERROR_UNMODIFIABLE_CLASS (79)
JVMTI_ERROR_NOT_AVAILABLE (98)
JVMTI_ERROR_ABSENT_INFORMATION (101)
JVMTI_ERROR_INVALID_EVENT_TYPE (102)
JVMTI_ERROR_NATIVE_METHOD (104)
JVMTI_ERROR_INVALID_THREAD (10)
JVMTI_ERROR_INVALID_FIELDID (25)
JVMTI_ERROR_INVALID_METHODID (23)
JVMTI_ERROR_INVALID_LOCATION (24)
JVMTI_ERROR_INVALID_OBJECT (20)
JVMTI_ERROR_INVALID_CLASS (21)
JVMTI_ERROR_TYPE_MISMATCH (34)
JVMTI_ERROR_INVALID_SLOT (35)
JVMTI_ERROR_MUST_POSSESS_CAPABILITY (99)
JVMTI_ERROR_INVALID_THREAD_GROUP (11)
JVMTI_ERROR_INVALID_MONITOR (50)
JVMTI_ERROR_ILLEGAL_ARGUMENT (103)
JVMTI_ERROR_INVALID_TYPESTATE (65)
JVMTI_ERROR_UNSUPPORTED_VERSION (68)
JVMTI_ERROR_INVALID_CLASS_FORMAT (60)
ClassFormatError).
JVMTI_ERROR_CIRCULAR_CLASS_DEFINITION (61)
ClassCircularityError).
JVMTI_ERROR_UNSUPPORTED_REDEFINITION_METHOD_ADDED (63)
JVMTI_ERROR_UNSUPPORTED_REDEFINITION_SCHEMA_CHANGED (64)
JVMTI_ERROR_FAILS_VERIFICATION (62)
JVMTI_ERROR_UNSUPPORTED_REDEFINITION_HIERARCHY_CHANGED (66)
JVMTI_ERROR_UNSUPPORTED_REDEFINITION_METHOD_DELETED (67)
JVMTI_ERROR_NAMES_DONT_MATCH (69)
JVMTI_ERROR_UNSUPPORTED_REDEFINITION_CLASS_MODIFIERS_CHANGED (70)
JVMTI_ERROR_UNSUPPORTED_REDEFINITION_METHOD_MODIFIERS_CHANGED (71)
| JVM Tool Interface Base Types | |
| Type | Description |
jvmtiEnv |
The JVM TI environment pointer.
See the Function Section.
jvmtiEnv points to the
function table pointer.
|
jthread |
Subtype of jobject that holds a thread.
|
typedef jobject jthread; |
|
jthreadGroup |
Subtype of jobject that holds a thread group.
|
typedef jobject jthreadGroup; |
|
jlocation |
A 64 bit value, representing a monotonically increasing
executable position within a method.
-1 indicates a native method.
See GetJLocationFormat for the format on a
given VM.
|
typedef jlong jlocation; |
|
jrawMonitorID | A raw monitor. |
struct _jrawMonitorID; typedef struct _jrawMonitorID *jrawMonitorID; |
|
jvmtiError |
Holds an error return code.
See the Error section for possible values.
|
jvmtiEvent |
An identifier for an event type.
See the Event section for possible values.
It is guaranteed that future versions of this specification will
never assign zero as an event type identifier.
|
jvmtiEventCallbacks |
The callbacks used for events.
See event callbacks
for the complete structure.
Where, for example, the VM initialization callback is defined:
See the individual events for the callback function definition.
|
jniNativeInterface |
Typedef for the JNI function table JNINativeInterface
defined in the
JNI Specification.
The JNI reference implementation defines this with an underscore.
|
typedef struct JNINativeInterface_ jniNativeInterface; |
|
| Structure Type Definitions | |
| Type | Description |
jvmtiAddrLocationMap | Native address to location entry |
jvmtiCapabilities | Capabilities of an Environment |
jvmtiClassDefinition | Class redefinition description |
jvmtiExtensionEventInfo | Extension Event Info |
jvmtiExtensionFunctionInfo | Extension Function Info |
jvmtiFrameInfo | Stack frame information structure |
jvmtiLineNumberEntry | Line number table entry |
jvmtiLocalVariableEntry | Local variable table entry |
jvmtiMonitorUsage | Object monitor usage information |
jvmtiParamInfo | Extension Function/Event Parameter Info |
jvmtiStackInfo | Stack information structure |
jvmtiThreadGroupInfo | Thread group information structure |
jvmtiThreadInfo | Thread information structure |
jvmtiTimerInfo | Timer Info |
| Function Type Definitions | |
| Type | Description |
jvmtiExtensionEvent | Extension Event |
jvmtiExtensionFunction | Extension Function |
jvmtiHeapObjectCallback | Heap Object Callback |
jvmtiHeapRootCallback | Heap Root Object Callback |
jvmtiObjectReferenceCallback | Object Reference Callback |
jvmtiStackReferenceCallback | Stack Reference Object Callback |
jvmtiStartFunction | Agent Start Function |
| Enumeration Definitions | |
| Type | Description |
jvmtiEventMode | Event Enable/Disable |
jvmtiHeapObjectFilter | Heap Object Filter Enumeration |
jvmtiHeapRootKind | Heap Root Kind Enumeration |
jvmtiIterationControl | Iteration Control Enumeration |
jvmtiJlocationFormat | JLocation Format Enumeration |
jvmtiObjectReferenceKind | Object Reference Enumeration |
jvmtiParamKind | Extension Function/Event Parameter Kinds |
jvmtiParamTypes | Extension Function/Event Parameter Types |
jvmtiPhase | Phases of execution |
jvmtiTimerKind | Timer Kinds |
jvmtiVerboseFlag | Verbose Flag Enumeration |
| Function Table Layout | ||
| Position | Function | Declaration |
| 1 | reserved |
void *reserved1; |
| 2 | Set Event Notification Mode |
jvmtiError (JNICALL *SetEventNotificationMode) (jvmtiEnv* env,
jvmtiEventMode mode,
jvmtiEvent event_type,
jthread event_thread,
...);
|
| 3 | reserved |
void *reserved3; |
| 4 | Get All Threads |
jvmtiError (JNICALL *GetAllThreads) (jvmtiEnv* env,
jint* threads_count_ptr,
jthread** threads_ptr);
|
| 5 | Suspend Thread |
jvmtiError (JNICALL *SuspendThread) (jvmtiEnv* env,
jthread thread);
|
| 6 | Resume Thread |
jvmtiError (JNICALL *ResumeThread) (jvmtiEnv* env,
jthread thread);
|
| 7 | Stop Thread |
jvmtiError (JNICALL *StopThread) (jvmtiEnv* env,
jthread thread,
jobject exception);
|
| 8 | Interrupt Thread |
jvmtiError (JNICALL *InterruptThread) (jvmtiEnv* env,
jthread thread);
|
| 9 | Get Thread Info |
jvmtiError (JNICALL *GetThreadInfo) (jvmtiEnv* env,
jthread thread,
jvmtiThreadInfo* info_ptr);
|
| 10 | Get Owned Monitor Info |
jvmtiError (JNICALL *GetOwnedMonitorInfo) (jvmtiEnv* env,
jthread thread,
jint* owned_monitor_count_ptr,
jobject** owned_monitors_ptr);
|
| 11 | Get Current Contended Monitor |
jvmtiError (JNICALL *GetCurrentContendedMonitor) (jvmtiEnv* env,
jthread thread,
jobject* monitor_ptr);
|
| 12 | Run Agent Thread |
jvmtiError (JNICALL *RunAgentThread) (jvmtiEnv* env,
jthread thread,
jvmtiStartFunction proc,
const void* arg,
jint priority);
|
| 13 | Get Top Thread Groups |
jvmtiError (JNICALL *GetTopThreadGroups) (jvmtiEnv* env,
jint* group_count_ptr,
jthreadGroup** groups_ptr);
|
| 14 | Get Thread Group Info |
jvmtiError (JNICALL *GetThreadGroupInfo) (jvmtiEnv* env,
jthreadGroup group,
jvmtiThreadGroupInfo* info_ptr);
|
| 15 | Get Thread Group Children |
jvmtiError (JNICALL *GetThreadGroupChildren) (jvmtiEnv* env,
jthreadGroup group,
jint* thread_count_ptr,
jthread** threads_ptr,
jint* group_count_ptr,
jthreadGroup** groups_ptr);
|
| 16 | Get Frame Count |
jvmtiError (JNICALL *GetFrameCount) (jvmtiEnv* env,
jthread thread,
jint* count_ptr);
|
| 17 | Get Thread State |
jvmtiError (JNICALL *GetThreadState) (jvmtiEnv* env,
jthread thread,
jint* thread_state_ptr);
|
| 18 | reserved |
void *reserved18; |
| 19 | Get Frame Location |
jvmtiError (JNICALL *GetFrameLocation) (jvmtiEnv* env,
jthread thread,
jint depth,
jmethodID* method_ptr,
jlocation* location_ptr);
|
| 20 | Notify Frame Pop |
jvmtiError (JNICALL *NotifyFramePop) (jvmtiEnv* env,
jthread thread,
jint depth);
|
| 21 | Get Local Variable - Object |
jvmtiError (JNICALL *GetLocalObject) (jvmtiEnv* env,
jthread thread,
jint depth,
jint slot,
jobject* value_ptr);
|
| 22 | Get Local Variable - Int |
jvmtiError (JNICALL *GetLocalInt) (jvmtiEnv* env,
jthread thread,
jint depth,
jint slot,
jint* value_ptr);
|
| 23 | Get Local Variable - Long |
jvmtiError (JNICALL *GetLocalLong) (jvmtiEnv* env,
jthread thread,
jint depth,
jint slot,
jlong* value_ptr);
|
| 24 | Get Local Variable - Float |
jvmtiError (JNICALL *GetLocalFloat) (jvmtiEnv* env,
jthread thread,
jint depth,
jint slot,
jfloat* value_ptr);
|
| 25 | Get Local Variable - Double |
jvmtiError (JNICALL *GetLocalDouble) (jvmtiEnv* env,
jthread thread,
jint depth,
jint slot,
jdouble* value_ptr);
|
| 26 | Set Local Variable - Object |
jvmtiError (JNICALL *SetLocalObject) (jvmtiEnv* env,
jthread thread,
jint depth,
jint slot,
jobject value);
|
| 27 | Set Local Variable - Int |
jvmtiError (JNICALL *SetLocalInt) (jvmtiEnv* env,
jthread thread,
jint depth,
jint slot,
jint value);
|
| 28 | Set Local Variable - Long |
jvmtiError (JNICALL *SetLocalLong) (jvmtiEnv* env,
jthread thread,
jint depth,
jint slot,
jlong value);
|
| 29 | Set Local Variable - Float |
jvmtiError (JNICALL *SetLocalFloat) (jvmtiEnv* env,
jthread thread,
jint depth,
jint slot,
jfloat value);
|
| 30 | Set Local Variable - Double |
jvmtiError (JNICALL *SetLocalDouble) (jvmtiEnv* env,
jthread thread,
jint depth,
jint slot,
jdouble value);
|
| 31 | Create Raw Monitor |
jvmtiError (JNICALL *CreateRawMonitor) (jvmtiEnv* env,
const char* name,
jrawMonitorID* monitor_ptr);
|
| 32 | Destroy Raw Monitor |
jvmtiError (JNICALL *DestroyRawMonitor) (jvmtiEnv* env,
jrawMonitorID monitor);
|
| 33 | Raw Monitor Enter |
jvmtiError (JNICALL *RawMonitorEnter) (jvmtiEnv* env,
jrawMonitorID monitor);
|
| 34 | Raw Monitor Exit |
jvmtiError (JNICALL *RawMonitorExit) (jvmtiEnv* env,
jrawMonitorID monitor);
|
| 35 | Raw Monitor Wait |
jvmtiError (JNICALL *RawMonitorWait) (jvmtiEnv* env,
jrawMonitorID monitor,
jlong millis);
|
| 36 | Raw Monitor Notify |
jvmtiError (JNICALL *RawMonitorNotify) (jvmtiEnv* env,
jrawMonitorID monitor);
|
| 37 | Raw Monitor Notify All |
jvmtiError (JNICALL *RawMonitorNotifyAll) (jvmtiEnv* env,
jrawMonitorID monitor);
|
| 38 | Set Breakpoint |
jvmtiError (JNICALL *SetBreakpoint) (jvmtiEnv* env,
jmethodID method,
jlocation location);
|
| 39 | Clear Breakpoint |
jvmtiError (JNICALL *ClearBreakpoint) (jvmtiEnv* env,
jmethodID method,
jlocation location);
|
| 40 | reserved |
void *reserved40; |
| 41 | Set Field Access Watch |
jvmtiError (JNICALL *SetFieldAccessWatch) (jvmtiEnv* env,
jclass klass,
jfieldID field);
|
| 42 | Clear Field Access Watch |
jvmtiError (JNICALL *ClearFieldAccessWatch) (jvmtiEnv* env,
jclass klass,
jfieldID field);
|
| 43 | Set Field Modification Watch |
jvmtiError (JNICALL *SetFieldModificationWatch) (jvmtiEnv* env,
jclass klass,
jfieldID field);
|
| 44 | Clear Field Modification Watch |
jvmtiError (JNICALL *ClearFieldModificationWatch) (jvmtiEnv* env,
jclass klass,
jfieldID field);
|
| 45 | reserved |
void *reserved45; |
| 46 | Allocate |
jvmtiError (JNICALL *Allocate) (jvmtiEnv* env,
jlong size,
unsigned char** mem_ptr);
|
| 47 | Deallocate |
jvmtiError (JNICALL *Deallocate) (jvmtiEnv* env,
unsigned char* mem);
|
| 48 | Get Class Signature |
jvmtiError (JNICALL *GetClassSignature) (jvmtiEnv* env,
jclass klass,
char** signature_ptr,
char** generic_ptr);
|
| 49 | Get Class Status |
jvmtiError (JNICALL *GetClassStatus) (jvmtiEnv* env,
jclass klass,
jint* status_ptr);
|
| 50 | Get Source File Name |
jvmtiError (JNICALL *GetSourceFileName) (jvmtiEnv* env,
jclass klass,
char** source_name_ptr);
|
| 51 | Get Class Modifiers |
jvmtiError (JNICALL *GetClassModifiers) (jvmtiEnv* env,
jclass klass,
jint* modifiers_ptr);
|
| 52 | Get Class Methods |
jvmtiError (JNICALL *GetClassMethods) (jvmtiEnv* env,
jclass klass,
jint* method_count_ptr,
jmethodID** methods_ptr);
|
| 53 | Get Class Fields |
jvmtiError (JNICALL *GetClassFields) (jvmtiEnv* env,
jclass klass,
jint* field_count_ptr,
jfieldID** fields_ptr);
|
| 54 | Get Implemented Interfaces |
jvmtiError (JNICALL *GetImplementedInterfaces) (jvmtiEnv* env,
jclass klass,
jint* interface_count_ptr,
jclass** interfaces_ptr);
|
| 55 | Is Interface |
jvmtiError (JNICALL *IsInterface) (jvmtiEnv* env,
jclass klass,
jboolean* is_interface_ptr);
|
| 56 | Is Array Class |
jvmtiError (JNICALL *IsArrayClass) (jvmtiEnv* env,
jclass klass,
jboolean* is_array_class_ptr);
|
| 57 | Get Class Loader |
jvmtiError (JNICALL *GetClassLoader) (jvmtiEnv* env,
jclass klass,
jobject* classloader_ptr);
|
| 58 | Get Object Hash Code |
jvmtiError (JNICALL *GetObjectHashCode) (jvmtiEnv* env,
jobject object,
jint* hash_code_ptr);
|
| 59 | Get Object Monitor Usage |
jvmtiError (JNICALL *GetObjectMonitorUsage) (jvmtiEnv* env,
jobject object,
jvmtiMonitorUsage* info_ptr);
|
| 60 | Get Field Name (and Signature) |
jvmtiError (JNICALL *GetFieldName) (jvmtiEnv* env,
jclass klass,
jfieldID field,
char** name_ptr,
char** signature_ptr,
char** generic_ptr);
|
| 61 | Get Field Declaring Class |
jvmtiError (JNICALL *GetFieldDeclaringClass) (jvmtiEnv* env,
jclass klass,
jfieldID field,
jclass* declaring_class_ptr);
|
| 62 | Get Field Modifiers |
jvmtiError (JNICALL *GetFieldModifiers) (jvmtiEnv* env,
jclass klass,
jfieldID field,
jint* modifiers_ptr);
|
| 63 | Is Field Synthetic |
jvmtiError (JNICALL *IsFieldSynthetic) (jvmtiEnv* env,
jclass klass,
jfieldID field,
jboolean* is_synthetic_ptr);
|
| 64 | Get Method Name (and Signature) |
jvmtiError (JNICALL *GetMethodName) (jvmtiEnv* env,
jmethodID method,
char** name_ptr,
char** signature_ptr,
char** generic_ptr);
|
| 65 | Get Method Declaring Class |
jvmtiError (JNICALL *GetMethodDeclaringClass) (jvmtiEnv* env,
jmethodID method,
jclass* declaring_class_ptr);
|
| 66 | Get Method Modifiers |
jvmtiError (JNICALL *GetMethodModifiers) (jvmtiEnv* env,
jmethodID method,
jint* modifiers_ptr);
|
| 67 | reserved |
void *reserved67; |
| 68 | Get Max Locals |
jvmtiError (JNICALL *GetMaxLocals) (jvmtiEnv* env,
jmethodID method,
jint* max_ptr);
|
| 69 | Get Arguments Size |
jvmtiError (JNICALL *GetArgumentsSize) (jvmtiEnv* env,
jmethodID method,
jint* size_ptr);
|
| 70 | Get Line Number Table |
jvmtiError (JNICALL *GetLineNumberTable) (jvmtiEnv* env,
jmethodID method,
jint* entry_count_ptr,
jvmtiLineNumberEntry** table_ptr);
|
| 71 | Get Method Location |
jvmtiError (JNICALL *GetMethodLocation) (jvmtiEnv* env,
jmethodID method,
jlocation* start_location_ptr,
jlocation* end_location_ptr);
|
| 72 | Get Local Variable Table |
jvmtiError (JNICALL *GetLocalVariableTable) (jvmtiEnv* env,
jmethodID method,
jint* entry_count_ptr,
jvmtiLocalVariableEntry** table_ptr);
|
| 73 | reserved |
void *reserved73; |
| 74 | reserved |
void *reserved74; |
| 75 | Get Bytecodes |
jvmtiError (JNICALL *GetBytecodes) (jvmtiEnv* env,
jmethodID method,
jint* bytecode_count_ptr,
unsigned char** bytecodes_ptr);
|
| 76 | Is Method Native |
jvmtiError (JNICALL *IsMethodNative) (jvmtiEnv* env,
jmethodID method,
jboolean* is_native_ptr);
|
| 77 | Is Method Synthetic |
jvmtiError (JNICALL *IsMethodSynthetic) (jvmtiEnv* env,
jmethodID method,
jboolean* is_synthetic_ptr);
|
| 78 | Get Loaded Classes |
jvmtiError (JNICALL *GetLoadedClasses) (jvmtiEnv* env,
jint* class_count_ptr,
jclass** classes_ptr);
|
| 79 | Get Classloader Classes |
jvmtiError (JNICALL *GetClassLoaderClasses) (jvmtiEnv* env,
jobject initiating_loader,
jint* class_count_ptr,
jclass** classes_ptr);
|
| 80 | Pop Frame |
jvmtiError (JNICALL *PopFrame) (jvmtiEnv* env,
jthread thread);
|
| 81 | reserved |
void *reserved81; |
| 82 | reserved |
void *reserved82; |
| 83 | reserved |
void *reserved83; |
| 84 | reserved |
void *reserved84; |
| 85 | reserved |
void *reserved85; |
| 86 | reserved |
void *reserved86; |
| 87 | Redefine Classes |
jvmtiError (JNICALL *RedefineClasses) (jvmtiEnv* env,
jint class_count,
const jvmtiClassDefinition* class_definitions);
|
| 88 | Get Version Number |
jvmtiError (JNICALL *GetVersionNumber) (jvmtiEnv* env,
jint* version_ptr);
|
| 89 | Get Capabilities |
jvmtiError (JNICALL *GetCapabilities) (jvmtiEnv* env,
jvmtiCapabilities* capabilities_ptr);
|
| 90 | Get Source Debug Extension |
jvmtiError (JNICALL *GetSourceDebugExtension) (jvmtiEnv* env,
jclass klass,
char** source_debug_extension_ptr);
|
| 91 | Is Method Obsolete |
jvmtiError (JNICALL *IsMethodObsolete) (jvmtiEnv* env,
jmethodID method,
jboolean* is_obsolete_ptr);
|
| 92 | Suspend Thread List |
jvmtiError (JNICALL *SuspendThreadList) (jvmtiEnv* env,
jint request_count,
const jthread* request_list,
jvmtiError* results);
|
| 93 | Resume Thread List |
jvmtiError (JNICALL *ResumeThreadList) (jvmtiEnv* env,
jint request_count,
const jthread* request_list,
jvmtiError* results);
|
| 94 | reserved |
void *reserved94; |
| 95 | reserved |
void *reserved95; |
| 96 | reserved |
void *reserved96; |
| 97 | reserved |
void *reserved97; |
| 98 | reserved |
void *reserved98; |
| 99 | reserved |
void *reserved99; |
| 100 | Get All Stack Traces |
jvmtiError (JNICALL *GetAllStackTraces) (jvmtiEnv* env,
jint max_frame_count,
jvmtiStackInfo** stack_info_ptr,
jint* thread_count_ptr);
|
| 101 | Get Thread List Stack Traces |
jvmtiError (JNICALL *GetThreadListStackTraces) (jvmtiEnv* env,
jint thread_count,
const jthread* thread_list,
jint max_frame_count,
jvmtiStackInfo** stack_info_ptr);
|
| 102 | Get Thread Local Storage |
jvmtiError (JNICALL *GetThreadLocalStorage) (jvmtiEnv* env,
jthread thread,
void** data_ptr);
|
| 103 | Set Thread Local Storage |
jvmtiError (JNICALL *SetThreadLocalStorage) (jvmtiEnv* env,
jthread thread,
const void* data);
|
| 104 | Get Stack Trace |
jvmtiError (JNICALL *GetStackTrace) (jvmtiEnv* env,
jthread thread,
jint start_depth,
jint max_frame_count,
jvmtiFrameInfo* frame_buffer,
jint* count_ptr);
|
| 105 | reserved |
void *reserved105; |
| 106 | Get Tag |
jvmtiError (JNICALL *GetTag) (jvmtiEnv* env,
jobject object,
jlong* tag_ptr);
|
| 107 | Set Tag |
jvmtiError (JNICALL *SetTag) (jvmtiEnv* env,
jobject object,
jlong tag);
|
| 108 | Force Garbage Collection |
jvmtiError (JNICALL *ForceGarbageCollection) (jvmtiEnv* env); |
| 109 | Iterate Over Objects Reachable From Object |
jvmtiError (JNICALL *IterateOverObjectsReachableFromObject) (jvmtiEnv* env,
jobject object,
jvmtiObjectReferenceCallback object_reference_callback,
void* user_data);
|
| 110 | Iterate Over Reachable Objects |
jvmtiError (JNICALL *IterateOverReachableObjects) (jvmtiEnv* env,
jvmtiHeapRootCallback heap_root_callback,
jvmtiStackReferenceCallback stack_ref_callback,
jvmtiObjectReferenceCallback object_ref_callback,
void* user_data);
|
| 111 | Iterate Over Heap |
jvmtiError (JNICALL *IterateOverHeap) (jvmtiEnv* env,
jvmtiHeapObjectFilter object_filter,
jvmtiHeapObjectCallback heap_object_callback,
void* user_data);
|
| 112 | Iterate Over Instances Of Class |
jvmtiError (JNICALL *IterateOverInstancesOfClass) (jvmtiEnv* env,
jclass klass,
jvmtiHeapObjectFilter object_filter,
jvmtiHeapObjectCallback heap_object_callback,
void* user_data);
|
| 113 | reserved |
void *reserved113; |
| 114 | Get Objects With Tags |
jvmtiError (JNICALL *GetObjectsWithTags) (jvmtiEnv* env,
jint tag_count,
const jlong* tags,
jint* count_ptr,
jobject** object_result_ptr,
jlong** tag_result_ptr);
|
| 115 | reserved |
void *reserved115; |
| 116 | reserved |
void *reserved116; |
| 117 | reserved |
void *reserved117; |
| 118 | reserved |
void *reserved118; |
| 119 | reserved |
void *reserved119; |
| 120 | Set JNI Function Table |
jvmtiError (JNICALL *SetJNIFunctionTable) (jvmtiEnv* env,
const jniNativeInterface* function_table);
|
| 121 | Get JNI Function Table |
jvmtiError (JNICALL *GetJNIFunctionTable) (jvmtiEnv* env,
jniNativeInterface** function_table);
|
| 122 | Set Event Callbacks |
jvmtiError (JNICALL *SetEventCallbacks) (jvmtiEnv* env,
const jvmtiEventCallbacks* callbacks,
jint size_of_callbacks);
|
| 123 | Generate Events |
jvmtiError (JNICALL *GenerateEvents) (jvmtiEnv* env,
jvmtiEvent event_type);
|
| 124 | Get Extension Functions |
jvmtiError (JNICALL *GetExtensionFunctions) (jvmtiEnv* env,
jint* extension_count_ptr,
jvmtiExtensionFunctionInfo** extensions);
|
| 125 | Get Extension Events |
jvmtiError (JNICALL *GetExtensionEvents) (jvmtiEnv* env,
jint* extension_count_ptr,
jvmtiExtensionEventInfo** extensions);
|
| 126 | Set Extension Event Callback |
jvmtiError (JNICALL *SetExtensionEventCallback) (jvmtiEnv* env,
jint extension_event_index,
jvmtiExtensionEvent callback);
|
| 127 | Dispose Environment |
jvmtiError (JNICALL *DisposeEnvironment) (jvmtiEnv* env); |
| 128 | Get Error Name |
jvmtiError (JNICALL *GetErrorName) (jvmtiEnv* env,
jvmtiError error,
char** name_ptr);
|
| 129 | Get JLocation Format |
jvmtiError (JNICALL *GetJLocationFormat) (jvmtiEnv* env,
jvmtiJlocationFormat* format_ptr);
|
| 130 | Get System Properties |
jvmtiError (JNICALL *GetSystemProperties) (jvmtiEnv* env,
jint* count_ptr,
char*** property_ptr);
|
| 131 | Get System Property |
jvmtiError (JNICALL *GetSystemProperty) (jvmtiEnv* env,
const char* property,
char** value_ptr);
|
| 132 | Set System Property |
jvmtiError (JNICALL *SetSystemProperty) (jvmtiEnv* env,
const char* property,
const char* value);
|
| 133 | Get Phase |
jvmtiError (JNICALL *GetPhase) (jvmtiEnv* env,
jvmtiPhase* phase_ptr);
|
| 134 | Get Current Thread CPU Timer Information |
jvmtiError (JNICALL *GetCurrentThreadCpuTimerInfo) (jvmtiEnv* env,
jvmtiTimerInfo* info_ptr);
|
| 135 | Get Current Thread CPU Time |
jvmtiError (JNICALL *GetCurrentThreadCpuTime) (jvmtiEnv* env,
jlong* nanos_ptr);
|
| 136 | Get Thread CPU Timer Information |
jvmtiError (JNICALL *GetThreadCpuTimerInfo) (jvmtiEnv* env,
jvmtiTimerInfo* info_ptr);
|
| 137 | Get Thread CPU Time |
jvmtiError (JNICALL *GetThreadCpuTime) (jvmtiEnv* env,
jthread thread,
jlong* nanos_ptr);
|
| 138 | Get Timer Information |
jvmtiError (JNICALL *GetTimerInfo) (jvmtiEnv* env,
jvmtiTimerInfo* info_ptr);
|
| 139 | Get Time |
jvmtiError (JNICALL *GetTime) (jvmtiEnv* env,
jlong* nanos_ptr);
|
| 140 | Get Potential Capabilities |
jvmtiError (JNICALL *GetPotentialCapabilities) (jvmtiEnv* env,
jvmtiCapabilities* capabilities_ptr);
|
| 141 | reserved |
void *reserved141; |
| 142 | Add Capabilities |
jvmtiError (JNICALL *AddCapabilities) (jvmtiEnv* env,
const jvmtiCapabilities* capabilities_ptr);
|
| 143 | Relinquish Capabilities |
jvmtiError (JNICALL *RelinquishCapabilities) (jvmtiEnv* env,
const jvmtiCapabilities* capabilities_ptr);
|
| 144 | Get Available Processors |
jvmtiError (JNICALL *GetAvailableProcessors) (jvmtiEnv* env,
jint* processor_count_ptr);
|
| 145 | reserved |
void *reserved145; |
| 146 | reserved |
void *reserved146; |
| 147 | Get Environment Local Storage |
jvmtiError (JNICALL *GetEnvironmentLocalStorage) (jvmtiEnv* env,
void** data_ptr);
|
| 148 | Set Environment Local Storage |
jvmtiError (JNICALL *SetEnvironmentLocalStorage) (jvmtiEnv* env,
const void* data);
|
| 149 | Add To Bootstrap Class Loader Search |
jvmtiError (JNICALL *AddToBootstrapClassLoaderSearch) (jvmtiEnv* env,
const char* segment);
|
| 150 | Set Verbose Flag |
jvmtiError (JNICALL *SetVerboseFlag) (jvmtiEnv* env,
jvmtiVerboseFlag flag,
jboolean value);
|
| 151 | reserved |
void *reserved151; |
| 152 | reserved |
void *reserved152; |
| 153 | reserved |
void *reserved153; |
| 154 | Get Object Size |
jvmtiError (JNICALL *GetObjectSize) (jvmtiEnv* env,
jobject object,
jlong* size_ptr);
|
SetEventCallbacks.
For each event the corresponding callback function will be
called.
Arguments to the callback function provides additional
information about the event.
The callback function is usually called from within application
threads and the JVM TI implementation does not
queue events in any way. This means
that event callback functions must be written
carefully. Here are some general guidelines. See
the individual event descriptions for further
suggestions.
SetEventNotificationMode.
All events are initially disabled. Thus, in order to receive any
event:
AddCapabilities.
SetEventCallbacks.
SetEventNotificationMode.
SuspendThread.
If an event is enabled in multiple environments, the event will be sent
to each agent in the order that the environments were created.
MethodEntry event is reported before
any other event at the current location in the same thread.
If an exception catch has been detected at the current location,
either because it is the beginning of a catch clause or a native method
that cleared a pending exception has returned, the
exceptionCatch event is reported before
any other event at the current location in the same thread.
If a singleStep event or
breakpoint event is triggered at the
current location, the event is defined to occur
immediately before the code at the current location is executed.
These events are reported before any events which are triggered
by the execution of code at the current location in the same
thread (specifically:
exception,
fieldAccess, and
fieldModification).
If both a step and breakpoint event are triggered for the same thread and
location, the step event is reported before the breakpoint event.
If the current location is the exit point of a method (that is, the last
location before returning to the caller), the
MethodExit event and
the FramePop event (if requested)
are reported after all other events at the current location in the same
thread. There is no specified ordering of these two events
with respect to each other.
Co-located events can be triggered during the processing of some other
event by the agent at the same location in the same thread.
If such an event, of type y, is triggered during the processing of
an event of type x, and if x
precedes y in the ordering specified above, the co-located event
y is reported for the current thread and location. If x does not precede
y, y is not reported for the current thread and location.
For example, if a breakpoint is set at the current location
during the processing of SingleStep,
that breakpoint will be reported before the thread moves off the current
location.
The following events are never considered to be co-located with
other events.
SetEventCallbacks function.
typedef struct {
jvmtiEventVMInit VMInit;
jvmtiEventVMDeath VMDeath;
jvmtiEventThreadStart ThreadStart;
jvmtiEventThreadEnd ThreadEnd;
jvmtiEventClassFileLoadHook ClassFileLoadHook;
jvmtiEventClassLoad ClassLoad;
jvmtiEventClassPrepare ClassPrepare;
jvmtiEventVMStart VMStart;
jvmtiEventException Exception;
jvmtiEventExceptionCatch ExceptionCatch;
jvmtiEventSingleStep SingleStep;
jvmtiEventFramePop FramePop;
jvmtiEventBreakpoint Breakpoint;
jvmtiEventFieldAccess FieldAccess;
jvmtiEventFieldModification FieldModification;
jvmtiEventMethodEntry MethodEntry;
jvmtiEventMethodExit MethodExit;
jvmtiEventNativeMethodBind NativeMethodBind;
jvmtiEventCompiledMethodLoad CompiledMethodLoad;
jvmtiEventCompiledMethodUnload CompiledMethodUnload;
jvmtiEventDynamicCodeGenerated DynamicCodeGenerated;
jvmtiEventDataDumpRequest DataDumpRequest;
jvmtiEventReserved reserved72;
jvmtiEventMonitorWait MonitorWait;
jvmtiEventMonitorWaited MonitorWaited;
jvmtiEventMonitorContendedEnter MonitorContendedEnter;
jvmtiEventMonitorContendedEntered MonitorContendedEntered;
jvmtiEventReserved reserved77;
jvmtiEventReserved reserved78;
jvmtiEventReserved reserved79;
jvmtiEventReserved reserved80;
jvmtiEventGarbageCollectionStart GarbageCollectionStart;
jvmtiEventGarbageCollectionFinish GarbageCollectionFinish;
jvmtiEventObjectFree ObjectFree;
jvmtiEventVMObjectAlloc VMObjectAlloc;
} jvmtiEventCallbacks;
void JNICALL
SingleStep(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jmethodID method,
jlocation location)
Single step events allow the agent to trace thread execution
at the finest granularity allowed by the VM. A single step event is
generated whenever a thread reaches a new location.
Typically, single step events represent the completion of one VM
instruction as defined the Java Virtual Machine Specification. However, some implementations
may define locations differently. In any case the
method and location
parameters uniquely identify the current location and allow
the mapping to source file and line number when that information is
available.
No single step events are generated from within native methods.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_SINGLE_STEP = 60
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_SINGLE_STEP, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_single_step_events | Can get single step events |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread about to execution a new instruction |
method | jmethodID | Method about to execute a new instruction |
location | jlocation | Location of the new instruction |
void JNICALL
Breakpoint(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jmethodID method,
jlocation location)
Breakpoint events are generated whenever a thread reaches a location
designated as a breakpoint with SetBreakpoint.
The method and location
parameters uniquely identify the current location and allow
the mapping to source file and line number when that information is
available.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_BREAKPOINT = 62
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_BREAKPOINT, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_breakpoint_events |
Can set and thus get
Breakpoint events
|
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread. |
thread | jthread | Thread that hit the breakpoint |
method | jmethodID | Method that hit the breakpoint |
location | jlocation | location of the breakpoint |
void JNICALL
FieldAccess(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jmethodID method,
jlocation location,
jclass field_klass,
jobject object,
jfieldID field)
Field access events are generated whenever a thread accesses
a field that was designated as a watchpoint
with SetFieldAccessWatch.
The method and location
parameters uniquely identify the current location and allow
the mapping to source file and line number when that information is
available.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_FIELD_ACCESS = 63
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_FIELD_ACCESS, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_field_access_events |
Can set watchpoints on field access -
SetFieldAccessWatch
|
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread accessing the field |
method | jmethodID | Method where the access is occurring |
location | jlocation | Location where the access is occurring |
field_klass | jclass | Class of the field being accessed |
object | jobject |
Object with the field being accessed if the field is an
instance field; NULL otherwise
|
field | jfieldID | Field being accessed |
void JNICALL
FieldModification(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jmethodID method,
jlocation location,
jclass field_klass,
jobject object,
jfieldID field,
char signature_type,
jvalue new_value)
Field modification events are generated whenever a thread modifies
a field that was designated as a watchpoint
with SetFieldModificationWatch.
The method and location
parameters uniquely identify the current location and allow
the mapping to source file and line number when that information is
available.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_FIELD_MODIFICATION = 64
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_FIELD_MODIFICATION, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_field_modification_events |
Can set watchpoints on field modification -
SetFieldModificationWatch
|
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread modifying the field |
method | jmethodID | Method where the modification is occurring |
location | jlocation | Location where the modification is occurring |
field_klass | jclass | Class of the field being modified |
object | jobject |
Object with the field being modified if the field is an
instance field; NULL otherwise
|
field | jfieldID | Field being modified |
signature_type | char | Signature type of the new value |
new_value | jvalue | The new value |
void JNICALL
FramePop(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jmethodID method,
jboolean was_popped_by_exception)
Frame pop events are generated upon exit from a single method
in a single frame as specified
in a call to NotifyFramePop.
This is true whether termination is caused by
executing its return instruction
or by throwing an exception to its caller
(see was_popped_by_exception).
However, frame pops caused by the PopFrame
function are not reported.
The location reported by GetFrameLocation
identifies the executable location in the returning method,
immediately prior to the return.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_FRAME_POP = 61
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_FRAME_POP, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_frame_pop_events |
Can set and thus get
FramePop events
|
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread that is popping the frame |
method | jmethodID | Method being popped |
was_popped_by_exception | jboolean | True if frame was popped by a thrown exception. False if method exited through its return instruction. |
void JNICALL
MethodEntry(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jmethodID method)
Method entry events are generated upon entry of Java
programming language methods (including native methods).
The location reported by GetFrameLocation
identifies the initial executable location in
the method.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_METHOD_ENTRY = 65
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_METHOD_ENTRY, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_method_entry_events | Can generate method entry events on entering a method |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread entering the method |
method | jmethodID | Method being entered |
void JNICALL
MethodExit(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jmethodID method,
jboolean was_popped_by_exception,
jvalue return_value)
Method exit events are generated upon exit from Java
programming language methods (including native methods).
This is true whether termination is caused by
executing its return instruction
or by throwing an exception to its caller
(see was_popped_by_exception).
The method field uniquely identifies the
method being entered or exited. The frame field provides
access to the stack frame for the method.
The location reported by GetFrameLocation
identifies the executable location in the returning method
immediately prior to the return.
Enabling method
entry or exit events will significantly degrade performance on many platforms and is thus
not advised for performance critical usage (such as profiling).
Bytecode instrumentation should be
used in these cases.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_METHOD_EXIT = 66
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_METHOD_EXIT, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_method_exit_events | Can generate method exit events on leaving a method |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread exiting the method |
method | jmethodID | Method being exited |
was_popped_by_exception | jboolean | True if frame was popped by a thrown exception. False if method exited through its return instruction. |
return_value | jvalue |
The return value of the method being exited.
Undefined and should not be used if
was_popped_by_exception
is true.
|
void JNICALL
NativeMethodBind(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jmethodID method,
void* address,
void** new_address_ptr)
A Native Method Bind event is sent when a VM binds a
Java programming language native method
to the address of a function that implements the native method.
This will occur when the native method is called for the first time
and also occurs when the JNI function RegisterNatives is called.
This event allows the bind to be redirected to an agent-specified
proxy function.
This event is not sent when the native method is unbound.
Typically, this proxy function will need to be specific to a
particular method or, to handle the general case, automatically
generated assembly code, since after instrumentation code is
executed the function at the original binding
address will usually be invoked.
The original binding can be restored or the redirection changed
by use of the JNI function RegisterNatives.
Some events may be sent during the primordial phase, JNI and
most of JVM TI cannot be used at this time but the method and
address can be save for use later.
This event is sent
during the primordial, start or live
phase.
Event ID:
JVMTI_EVENT_NATIVE_METHOD_BIND = 67
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_NATIVE_METHOD_BIND, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_native_method_bind_events | Can generate events when a native method is bound to its implementation |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* |
The JNI environment of the event (current) thread
Will be NULL if sent during the primordial
phase.
|
thread | jthread | Thread requesting the bind |
method | jmethodID | Native method being bound |
address | void* | The address the VM is about to bind to--that is, the address of the implementation of the native method |
new_address_ptr | void** |
if the referenced address is changed (that is, if
*new_address_ptr is set), the binding
will instead be made to the supplied address.
|
void JNICALL
Exception(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jmethodID method,
jlocation location,
jobject exception,
jmethodID catch_method,
jlocation catch_location)
Exception events are generated whenever an exception is first detected
in a Java programming language method. The exception may have been thrown by a Java programming language or native
method, but in the case of native methods, the event is not generated
until the exception is first seen by a Java programming language method. If an exception is
set and cleared in a native method (and thus is never visible to Java programming language code),
no exception event is generated.
The method and location
parameters uniquely identify the current location
(where the exception was detected) and allow
the mapping to source file and line number when that information is
available. The exception field identifies the thrown
exception object. The catch_method
and catch_location identify the location of the catch clause,
if any, that handles the thrown exception. If there is no such catch clause,
each field is set to 0. There is no guarantee that the thread will ever
reach this catch clause. If there are native methods on the call stack
between the throw location and the catch clause, the exception may
be reset by one of those native methods.
Similarly, exceptions that are reported as uncaught (catch_klass
et al. set to 0) may in fact be caught by native code.
Agents can check for these occurrences by monitoring
ExceptionCatch events.
Note that finally clauses are implemented as catch and re-throw. Therefore they
will be reported in the catch location.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_EXCEPTION = 58
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_EXCEPTION, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_exception_events | Can get exception thrown and exception catch events |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread generating the exception |
method | jmethodID | Method generating the exception |
location | jlocation | Location where exception occurred |
exception | jobject | The exception being thrown |
catch_method | jmethodID |
Method that will catch the exception, or NULL if no known catch
|
catch_location | jlocation | location which will catch the exception or zero if no known catch |
void JNICALL
ExceptionCatch(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jmethodID method,
jlocation location,
jobject exception)
Exception catch events are generated whenever a thrown exception is caught.
If the exception is caught in a Java programming language method, the event is generated
when the catch clause is reached. If the exception is caught in a native
method, the event is generated as soon as control is returned to a Java programming language
method. Exception catch events are generated for any exception for which
a throw was detected in a Java programming language method.
Note that finally clauses are implemented as catch and re-throw. Therefore they
will generate exception catch events.
The method and location
parameters uniquely identify the current location
and allow the mapping to source file and line number when that information is
available. For exceptions caught in a Java programming language method, the
exception object identifies the exception object. Exceptions
caught in native methods are not necessarily available by the time the
exception catch is reported, so the exception field is set
to NULL.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_EXCEPTION_CATCH = 59
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_EXCEPTION_CATCH, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_exception_events | Can get exception thrown and exception catch events |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread catching the exception |
method | jmethodID | Method catching the exception |
location | jlocation | Location where exception is being caught |
exception | jobject | Exception being caught |
void JNICALL
ThreadStart(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread)
Thread start events are generated by a new thread before its initial
method executes.
A thread may be listed in the array returned by
GetAllThreads
before its thread start event is generated.
It is possible for other events to be generated
on a thread before its thread start event.
The event is sent on the newly started thread.
This event is sent
during the start or live
phase.
Event ID:
JVMTI_EVENT_THREAD_START = 52
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_THREAD_START, NULL)
| Capabilities | |
| Required Functionality |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread. |
thread | jthread | Thread starting |
void JNICALL
ThreadEnd(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread)
Thread end events are generated by a terminating thread
after its initial method has finished execution.
A thread may be listed in the array returned by
GetAllThreads
after its thread end event is generated.
No events are generated on a thread
after its thread end event.
The event is sent on the dying thread.
This event is sent
during the start or live
phase.
Event ID:
JVMTI_EVENT_THREAD_END = 53
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_THREAD_END, NULL)
| Capabilities | |
| Required Functionality |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread. |
thread | jthread | Thread ending |
void JNICALL
ClassLoad(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jclass klass)
A class load event is generated when a class is first loaded. The order
of class load events generated by a particular thread are guaranteed
to match the order of class loading within that thread.
Array class creation does not generate a class load event.
The creation of a primitive class (for example, java.lang.Integer.TYPE)
does not generate a class load event.
This event is sent at an early stage in loading the class. As
a result the class should be used carefully. Note, for example,
that methods and fields are not yet loaded, so queries for methods,
fields, subclasses, and so on will not give correct results.
See "Loading of Classes and Interfaces" in the Java Language
Specification. For most
purposes the ClassPrepare event will
be more useful.
This event is sent
during the start or live
phase.
Event ID:
JVMTI_EVENT_CLASS_LOAD = 55
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_CLASS_LOAD, NULL)
| Capabilities | |
| Required Functionality |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread loading the class |
klass | jclass | Class being loaded |
void JNICALL
ClassPrepare(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jclass klass)
A class prepare event is generated when class preparation is complete.
At this point, class fields, methods, and implemented interfaces are
available, and no code from the class has been executed. Since array
classes never have fields or methods, class prepare events are not
generated for them. Class prepare events are not generated for
primitive classes (for example, java.lang.Integer.TYPE).
This event is sent
during the start or live
phase.
Event ID:
JVMTI_EVENT_CLASS_PREPARE = 56
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_CLASS_PREPARE, NULL)
| Capabilities | |
| Required Functionality |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread generating the class prepare |
klass | jclass | Class being prepared |
void JNICALL
ClassFileLoadHook(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jclass class_being_redefined,
jobject loader,
const char* name,
jobject protection_domain,
jint class_data_len,
const unsigned char* class_data,
jint* new_class_data_len,
unsigned char** new_class_data)
Sent when the VM obtains a class file data, but before it constructs
the in-memory representation for that class.
Also sent when RedefineClasses is
called in any JVM TI environment.
The agent can instrument
the existing class file data sent by the VM to include profiling/debugging hooks.
See the description of
bytecode instrumentation
for usage information.
This event may be sent before the VM is initialized. During this time
no VM resources should be created. Some classes might not be compatible
with the function (eg. ROMized classes) and this event will not be
generated for these classes.
The agent must allocate the space for the modified
class file data buffer
using the memory allocation function
Allocate because the
VM is responsible for freeing the new class file data buffer
using Deallocate.
If the agent wishes to modify the class file, it must set
new_class_data to point
to the newly instrumented class file data buffer and set
new_class_data_len to the length of that
buffer before returning
from this call. If no modification is desired, the agent simply
does not set new_class_data. If multiple agents
have enabled this event the results are chained. That is, if
new_class_data has been set, it becomes the
class_data for the next agent. As with all events,
agents are called in the order the environment was created.
This event is sent
during the primordial, start or live
phase.
Event ID:
JVMTI_EVENT_CLASS_FILE_LOAD_HOOK = 54
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_CLASS_FILE_LOAD_HOOK, NULL)
| Capabilities | |
| Required Functionality | |
| Optional Features | |
| Capability | Effect |
can_generate_all_class_hook_events | Can generate ClassFileLoadHook events for every loaded class. |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* |
The JNI environment of the event (current) thread.
Will be NULL if sent during the primordial
phase.
|
class_being_redefined | jclass |
The class being redefined with
RedefineClasses.
NULL if sent by class load.
|
loader | jobject |
The class loader loading the class.
NULL if the bootstrap class loader.
|
name | const char* |
Name of class being loaded as a VM internal qualified name
(for example, "java/util/List"), encoded as a
modified UTF-8 string.
Note: if the class is defined with a NULL name or
without a name specified, name will be NULL.
|
protection_domain | jobject |
The ProtectionDomain of the class.
|
class_data_len | jint | Length of current class file data buffer. |
class_data | const unsigned char* | Pointer to the current class file data buffer. |
new_class_data_len | jint* | Pointer to the length of the new class file data buffer. |
new_class_data | unsigned char** | Pointer to the pointer to the instrumented class file data buffer. |
void JNICALL
VMStart(jvmtiEnv *jvmti_env,
JNIEnv* jni_env)
The VM initialization event signals the start of the VM.
At this time JNI is live but the VM is not yet fully initialized.
Once this event is generated, the agent is free to call any JNI function.
This event signals the beginning of the start phase,
JVM TI functions permitted in the start phase may be called.
In the case of VM start-up failure, this event will not be sent.
This event is sent
during the start or live
phase.
Event ID:
JVMTI_EVENT_VM_START = 57
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_VM_START, NULL)
| Capabilities | |
| Required Functionality |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread. |
void JNICALL
VMInit(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread)
The VM initialization event signals the completion of VM initialization. Once
this event is generated, the agent is free to call any JNI or JVM TI
function. The VM initialization event can be preceded by or can be concurrent
with other events, but
the preceding events should be handled carefully, if at all, because the
VM has not completed its initialization. The thread start event for the
main application thread is guaranteed not to occur until after the
handler for the VM initialization event returns.
In the case of VM start-up failure, this event will not be sent.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_VM_INIT = 50
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_VM_INIT, NULL)
| Capabilities | |
| Required Functionality |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread. |
thread | jthread | The initial thread |
void JNICALL
VMDeath(jvmtiEnv *jvmti_env,
JNIEnv* jni_env)
The VM death event notifies the agent of the termination of the VM.
No events will occur after the VMDeath event.
In the case of VM start-up failure, this event will not be sent.
Note that Agent_OnUnload
will still be called in these cases.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_VM_DEATH = 51
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_VM_DEATH, NULL)
| Capabilities | |
| Required Functionality |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
Sent when a method is compiled and loaded into memory by the VM. If it is unloaded, thetypedef struct { const void* start_address; jlocation location; } jvmtiAddrLocationMap;void JNICALL CompiledMethodLoad(jvmtiEnv *jvmti_env, jmethodID method, jint code_size, const void* code_addr, jint map_length, const jvmtiAddrLocationMap* map, const void* compile_info)
CompiledMethodUnload event is sent.
If it is moved, the CompiledMethodUnload event is sent,
followed by a new CompiledMethodLoad event.
Note that a single method may have multiple compiled forms, and that
this event will be sent for each form.
Note also that several methods may be inlined into a single
address range, and that this event will be sent for each method.
These events can be sent after their initial occurrence with
GenerateEvents.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_COMPILED_METHOD_LOAD = 68
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_COMPILED_METHOD_LOAD, NULL)
jvmtiAddrLocationMap - Native address to location entry |
||
| Field | Type | Description |
start_address | const void* | Starting native address of code corresponding to a location |
location | jlocation |
Corresponding location. See
GetJLocationFormat
for the meaning of location.
|
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_compiled_method_load_events | Can generate events when a method is compiled or unloaded |
| Parameters | ||
| Name | Type | Description |
method | jmethodID | Method being compiled and loaded |
code_size | jint | Size of compiled code |
code_addr | const void* | Address where compiled method code is loaded |
map_length | jint |
Number of jvmtiAddrLocationMap
entries in the address map.
Zero if mapping information cannot be supplied.
|
map | const jvmtiAddrLocationMap* |
Map from native addresses to location.
The native address range of each entry is from
start_address
to start_address-1 of the next entry.
NULL if mapping information cannot be supplied.
|
compile_info | const void* | VM-specific compilation information. The referenced compile information is managed by the VM and must not depend on the agent for collection. A VM implementation defines the content and lifetime of the information. |
void JNICALL
CompiledMethodUnload(jvmtiEnv *jvmti_env,
jmethodID method,
const void* code_addr)
Sent when a compiled method is unloaded from memory.
This event might not be sent on the thread which performed the unload.
This event may be sent sometime after the unload occurs, but
will be sent before the memory is reused
by a newly generated compiled method. This event may be sent after
the class is unloaded.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_COMPILED_METHOD_UNLOAD = 69
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_COMPILED_METHOD_UNLOAD, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_compiled_method_load_events | Can generate events when a method is compiled or unloaded |
| Parameters | ||
| Name | Type | Description |
method | jmethodID | Compiled method being unloaded. For identification of the compiled method only -- the class may be unloaded and therefore the method should not be used as an argument to further JNI or JVM TI functions. |
code_addr | const void* | Address where compiled method code was loaded. For identification of the compiled method only -- the space may have been reclaimed. |
void JNICALL
DynamicCodeGenerated(jvmtiEnv *jvmti_env,
const char* name,
const void* address,
jint length)
Sent when a component of the virtual machine is generated dynamically.
This does not correspond to Java programming language code that is
compiled--see CompiledMethodLoad.
This is for native code--for example, an interpreter that is generated
differently depending on command-line options.
Note that this event has no controlling capability.
If a VM cannot generate these events, it simply does not send any.
These events can be sent after their initial occurrence with
GenerateEvents.
This event is sent
during the primordial, start or live
phase.
Event ID:
JVMTI_EVENT_DYNAMIC_CODE_GENERATED = 70
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_DYNAMIC_CODE_GENERATED, NULL)
| Capabilities | |
| Required Functionality |
| Parameters | ||
| Name | Type | Description |
name | const char* | Name of the code, encoded as a modified UTF-8 string. Intended for display to an end-user. The name might not be unique. |
address | const void* | Native address of the code |
length | jint | Length in bytes of the code |
Sent by the VM to request the agent to dump its data. This is just a hint and the agent need not react to this event. This is useful for processing command-line signals from users. For example, in the Java 2 SDK a CTRL-Break on Win32 and a CTRL-\ on Solaris causes the VM to send this event to the agent. This event is sent only during the live phase. Event ID:void JNICALL DataDumpRequest(jvmtiEnv *jvmti_env)
JVMTI_EVENT_DATA_DUMP_REQUEST = 71
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_DATA_DUMP_REQUEST, NULL)
| Capabilities | |
| Required Functionality |
| Parameters | ||
| Name | Type | Description |
void JNICALL
MonitorContendedEnter(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jobject object)
Sent when a thread is attempting to enter a Java programming language
monitor already acquired by another thread.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_MONITOR_CONTENDED_ENTER = 75
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_MONITOR_CONTENDED_ENTER, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_monitor_events | Can generate events on monitor activity |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | JNI local reference to the thread attempting to enter the monitor |
object | jobject | JNI local reference to the monitor |
void JNICALL
MonitorContendedEntered(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jobject object)
Sent when a thread enters a Java programming language
monitor after waiting for it to be released by another thread.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_MONITOR_CONTENDED_ENTERED = 76
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_MONITOR_CONTENDED_ENTERED, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_monitor_events | Can generate events on monitor activity |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | JNI local reference to the thread entering the monitor |
object | jobject | JNI local reference to the monitor |
void JNICALL
MonitorWait(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jobject object,
jlong timeout)
Sent when a thread is about to wait on an object.
That is, a thread is entering Object.wait().
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_MONITOR_WAIT = 73
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_MONITOR_WAIT, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_monitor_events | Can generate events on monitor activity |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | JNI local reference to the thread about to wait |
object | jobject | JNI local reference to the monitor |
timeout | jlong | The number of milliseconds the thread will wait |
void JNICALL
MonitorWaited(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jobject object,
jboolean timed_out)
Sent when a thread finishes waiting on an object.
That is, a thread is leaving Object.wait().
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_MONITOR_WAITED = 74
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_MONITOR_WAITED, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_monitor_events | Can generate events on monitor activity |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | JNI local reference to the thread that was finished waiting |
object | jobject | JNI local reference to the monitor. |
timed_out | jboolean | True if the monitor timed out |
void JNICALL
VMObjectAlloc(jvmtiEnv *jvmti_env,
JNIEnv* jni_env,
jthread thread,
jobject object,
jclass object_klass,
jlong size)
Sent when a method causes the virtual machine to allocate an
Object visible to Java programming language code and the
allocation is not detectable by other intrumentation mechanisms.
Generally object allocation should be detected by instrumenting
the bytecodes of allocating methods.
Object allocation generated in native code by JNI function
calls should be detected using
JNI function interception.
Some methods might not have associated bytecodes and are not
native methods, they instead are executed directly by the
VM. These methods should send this event.
Virtual machines which are incapable of bytecode instrumentation
for some or all of their methods can send this event.
Typical examples where this event might be sent:
java.lang.Class.newInstance()
new
and newarray VM instructionsAllocObject
JVMTI_EVENT_VM_OBJECT_ALLOC = 84
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_VM_OBJECT_ALLOC, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_vm_object_alloc_events | Can generate events on VM allocation of an object |
| Parameters | ||
| Name | Type | Description |
jni_env |
JNIEnv
* | The JNI environment of the event (current) thread |
thread | jthread | Thread allocating the object. |
object | jobject | JNI local reference to the object that was allocated |
object_klass | jclass | JNI local reference to the class of the object |
size | jlong |
Size of the object (in bytes). See GetObjectSize.
|
void JNICALL
ObjectFree(jvmtiEnv *jvmti_env,
jlong tag)
An Object Free event is sent when the garbage collector frees an object.
Events are only sent for tagged objects--see
heap functions.
The event handler must not use JNI functions and
must not use JVM TI functions except those which
specifically allow such use (see the raw monitor, memory management,
and environment local storage functions).
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_OBJECT_FREE = 83
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_OBJECT_FREE, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_object_free_events | Can generate events when the garbage collector frees an object |
| Parameters | ||
| Name | Type | Description |
tag | jlong | The freed object's tag |
A Garbage Collection Start event is sent when a full cycle garbage collection begins. Only stop-the-world collections are reported--that is, collections during which all threads cease to modify the state of the Java virtual machine. This means that some collectors will never generate these events. This event is sent while the VM is still stopped, thus the event handler must not use JNI functions and must not use JVM TI functions except those which specifically allow such use (see the raw monitor, memory management, and environment local storage functions). This event is always sent as a matched pair withvoid JNICALL GarbageCollectionStart(jvmtiEnv *jvmti_env)
GarbageCollectionFinish
(assuming both events are enabled) and no garbage collection
events will occur between them.
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_GARBAGE_COLLECTION_START = 81
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_GARBAGE_COLLECTION_START, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_garbage_collection_events | Can generate events when garbage collection begins or ends |
| Parameters | ||
| Name | Type | Description |
A Garbage Collection Finish event is sent when a full garbage collection cycle ends. This event is sent while the VM is still stopped, thus the event handler must not use JNI functions and must not use JVM TI functions except those which specifically allow such use (see the raw monitor, memory management, and environment local storage functions). Some agents may need to do post garbage collection operations that require the use of the disallowed JVM TI or JNI functions. For these cases an agent thread can be created which waits on a raw monitor, and the handler for the Garbage Collection Finish event simply notifies the raw monitor This event is always sent as a matched pair withvoid JNICALL GarbageCollectionFinish(jvmtiEnv *jvmti_env)
GarbageCollectionStart (assuming both events are enabled).
This event is sent
only during the live
phase.
Event ID:
JVMTI_EVENT_GARBAGE_COLLECTION_FINISH = 82
Enabling:
All events are initially disabled. Enable globally with
SetEventNotificationMode(JVMTI_ENABLE,
JVMTI_EVENT_GARBAGE_COLLECTION_FINISH, NULL)
| Capabilities | |
Optional Functionality: might not be implemented for all
virtual machines.
The following capability
(as returned by
GetCapabilities)
must be true to use this
event.
|
|
| Capability | Effect |
can_generate_garbage_collection_events | Can generate events when garbage collection begins or ends |
| Parameters | ||
| Name | Type | Description |
JVMTI_CLASS_STATUS_ARRAY
JVMTI_CLASS_STATUS_ERROR
JVMTI_CLASS_STATUS_INITIALIZED
JVMTI_CLASS_STATUS_PREPARED
JVMTI_CLASS_STATUS_PRIMITIVE
JVMTI_CLASS_STATUS_VERIFIED
JVMTI_DISABLE
JVMTI_ENABLE
JVMTI_HEAP_OBJECT_EITHER
JVMTI_HEAP_OBJECT_TAGGED
JVMTI_HEAP_OBJECT_UNTAGGED
JVMTI_HEAP_ROOT_JNI_GLOBAL
JVMTI_HEAP_ROOT_JNI_LOCAL
JVMTI_HEAP_ROOT_MONITOR
JVMTI_HEAP_ROOT_OTHER
JVMTI_HEAP_ROOT_STACK_LOCAL
JVMTI_HEAP_ROOT_SYSTEM_CLASS
JVMTI_HEAP_ROOT_THREAD
JVMTI_ITERATION_ABORT
JVMTI_ITERATION_CONTINUE
JVMTI_ITERATION_IGNORE
JVMTI_JAVA_LANG_THREAD_STATE_BLOCKED
JVMTI_JAVA_LANG_THREAD_STATE_MASK
JVMTI_JAVA_LANG_THREAD_STATE_NEW
JVMTI_JAVA_LANG_THREAD_STATE_RUNNABLE
JVMTI_JAVA_LANG_THREAD_STATE_TERMINATED
JVMTI_JAVA_LANG_THREAD_STATE_TIMED_WAITING
JVMTI_JAVA_LANG_THREAD_STATE_WAITING
JVMTI_JLOCATION_JVMBCI
JVMTI_JLOCATION_MACHINEPC
JVMTI_JLOCATION_OTHER
JVMTI_KIND_ALLOC_ALLOC_BUF
JVMTI_KIND_ALLOC_BUF
JVMTI_KIND_IN
JVMTI_KIND_IN_BUF
JVMTI_KIND_IN_PTR
JVMTI_KIND_OUT
JVMTI_KIND_OUT_BUF
JVMTI_PHASE_DEAD
JVMTI_PHASE_LIVE
JVMTI_PHASE_ONLOAD
JVMTI_PHASE_PRIMORDIAL
JVMTI_PHASE_START
JVMTI_REFERENCE_ARRAY_ELEMENT
JVMTI_REFERENCE_CLASS
JVMTI_REFERENCE_CLASS_LOADER
JVMTI_REFERENCE_CONSTANT_POOL
JVMTI_REFERENCE_FIELD
JVMTI_REFERENCE_INTERFACE
JVMTI_REFERENCE_PROTECTION_DOMAIN
JVMTI_REFERENCE_SIGNERS
JVMTI_REFERENCE_STATIC_FIELD
JVMTI_THREAD_MAX_PRIORITY
JVMTI_THREAD_MIN_PRIORITY
JVMTI_THREAD_NORM_PRIORITY
JVMTI_THREAD_STATE_ALIVE
JVMTI_THREAD_STATE_BLOCKED_ON_MONITOR_ENTER
JVMTI_THREAD_STATE_IN_NATIVE
JVMTI_THREAD_STATE_IN_OBJECT_WAIT
JVMTI_THREAD_STATE_INTERRUPTED
JVMTI_THREAD_STATE_PARKED
JVMTI_THREAD_STATE_RUNNABLE
JVMTI_THREAD_STATE_SLEEPING
JVMTI_THREAD_STATE_SUSPENDED
JVMTI_THREAD_STATE_TERMINATED
JVMTI_THREAD_STATE_VENDOR_1
JVMTI_THREAD_STATE_VENDOR_2
JVMTI_THREAD_STATE_VENDOR_3
JVMTI_THREAD_STATE_WAITING
JVMTI_THREAD_STATE_WAITING_INDEFINITELY
JVMTI_THREAD_STATE_WAITING_WITH_TIMEOUT
JVMTI_TIMER_ELAPSED
JVMTI_TIMER_TOTAL_CPU
JVMTI_TIMER_USER_CPU
JVMTI_TYPE_CCHAR
JVMTI_TYPE_CVOID
JVMTI_TYPE_JBOOLEAN
JVMTI_TYPE_JBYTE
JVMTI_TYPE_JCHAR
JVMTI_TYPE_JCLASS
JVMTI_TYPE_JDOUBLE
JVMTI_TYPE_JFIELDID
JVMTI_TYPE_JFLOAT
JVMTI_TYPE_JINT
JVMTI_TYPE_JLONG
JVMTI_TYPE_JMETHODID
JVMTI_TYPE_JNIENV
JVMTI_TYPE_JOBJECT
JVMTI_TYPE_JSHORT
JVMTI_TYPE_JTHREAD
JVMTI_TYPE_JVALUE
JVMTI_VERBOSE_CLASS
JVMTI_VERBOSE_GC
JVMTI_VERBOSE_JNI
JVMTI_VERBOSE_OTHER
JVMTI_VERSION_INTERFACE_JNI
JVMTI_VERSION_INTERFACE_JVMTI
JVMTI_VERSION_MASK_INTERFACE_TYPE
JVMTI_VERSION_MASK_MAJOR
JVMTI_VERSION_MASK_MICRO
JVMTI_VERSION_MASK_MINOR
JVMTI_VERSION_SHIFT_MAJOR
JVMTI_VERSION_SHIFT_MICRO
JVMTI_VERSION_SHIFT_MINOR
| Version
Date | Changes |
| 14 Nov 2002 | Converted to XML document. |
| 14 Nov 2002 | Elided heap dump functions (for now) since what was there was wrong. |
| 18 Nov 2002 | Added detail throughout. |
| 18 Nov 2002 | Changed JVMTI_THREAD_STATUS_RUNNING to JVMTI_THREAD_STATUS_RUNNABLE. |
| 19 Nov 2002 | Added AsyncGetStackTrace. |
| 19 Nov 2002 | Added jframeID return to GetStackTrace. |
| 19 Nov 2002 | Elided GetCurrentFrame and GetCallingFrame functions (for now) since what was there since they are redundant with GetStackTrace. |
| 19 Nov 2002 | Elided ClearAllBreakpoints since it has always been redundant. |
| 19 Nov 2002 | Added GetSystemProperties. |
| 19 Nov 2002 | Changed the thread local storage functions to use jthread. |
| 20 Nov 2002 | Added GetJLocationFormat. |
| 22 Nov 2002 | Added events and introductory text. |
| 22 Nov 2002 | Cross reference type and constant definitions. |
| 24 Nov 2002 | Added DTD. |
| 24 Nov 2002 | Added capabilities function section. |
| 29 Nov 2002 | Assign capabilities to each function and event. |
| 29 Nov 2002 | Add JNI interception functions. |
| 30 Nov 2002 | Auto generate SetEventNotificationMode capabilities. |
| 30 Nov 2002 |
Add VMObjectAlloc event.
|
| 30 Nov 2002 |
Add DynamicCodeGenerated event.
|
| 30 Nov 2002 | Add const to declarations. |
| 30 Nov 2002 | Change method exit and frame pop to send on exception. |
| 1 Dec 2002 | Add ForceGarbageCollection. |
| 2 Dec 2002 | Redo Xrun section; clarify GetStackTrace and add example; Fix width problems; use "agent" consistently. |
| 8 Dec 2002 | Remove previous start-up intro. Add Environments section. |
| 8 Dec 2002 |
Add DisposeEnvironment.
|
| 9 Dec 2002 | Numerous minor updates. |
| 15 Dec 2002 | Add heap profiling functions added: get/set annotation, iterate live objects/heap. Add heap profiling functions place holder added: heap roots. Heap profiling event added: object free. Heap profiling event redesigned: vm object allocation. Heap profiling event placeholders added: garbage collection start/finish. Native method bind event added. |
| 19 Dec 2002 | Revamp suspend/resume functions. Add origin information with jvmdi tag. Misc fixes. |
| 24 Dec 2002 | Add semantics to types. |
| 27 Dec 2002 | Add local reference section. Autogenerate parameter descriptions from types. |
| 28 Dec 2002 | Document that RunAgentThread sends threadStart. |
| 29 Dec 2002 | Remove redundant local ref and dealloc warning. Convert GetRawMonitorName to allocated buffer. Add GenerateEvents. |
| 30 Dec 2002 | Make raw monitors a type and rename to "jrawMonitorID". |
| 1 Jan 2003 | Include origin information. Clean-up JVMDI issue references. Remove Deallocate warnings which are now automatically generated. |
| 2 Jan 2003 | Fix representation issues for jthread. |
| 3 Jan 2003 | Make capabilities buffered out to 64 bits - and do it automatically. |
| 4 Jan 2003 | Make constants which are enumeration into enum types. Parameters now of enum type. Clean-up and index type section. Replace remaining datadef entities with callback. |
| 7 Jan 2003 | Correct GenerateEvents description. More internal semantics work. |
| 9 Jan 2003 | Replace previous GetSystemProperties with two functions which use allocated information instead fixed. Add SetSystemProperty. More internal semantics work. |
| 12 Jan 2003 | Add varargs to end of SetEventNotificationMode. |
| 20 Jan 2003 | Finish fixing spec to reflect that alloc sizes are jlong. |
| 22 Jan 2003 | Allow NULL as RunAgentThread arg. |
| 22 Jan 2003 | Fixed names to standardized naming convention Removed AsyncGetStackTrace. |
| 29 Jan 2003 | Since we are using jthread, removed GetThread. |
| 31 Jan 2003 | Change GetFieldName to allow NULLs like GetMethodName. |
| v40
29 Feb 2003 | Rewrite the introductory text, adding sections on start-up, environments and bytecode instrumentation. Change the command line arguments per EG discussions. Add an introduction to the capabilities section. Add the extension mechanism category and functions. Mark for deletion, but clarified anyhow, SuspendAllThreads. Rename IterateOverLiveObjects to IterateOverReachableObjects and change the text accordingly. Clarify IterateOverHeap. Clarify CompiledMethodLoad. Discuss prerequisite state for Calling Functions. Clarify SetAllocationHooks. Added issues ("To be resolved:") through-out. And so on... |
| v41
6 Mar 2003 | Remove struct from the call to GetOwnedMonitorInfo. Automatically generate most error documentation, remove (rather broken) hand written error doc. Better describe capability use (empty initial set). Add min value to jint params. Remove the capability can_access_thread_local_storage. Rename error JVMTI_ERROR_NOT_IMPLEMENTED to JVMTI_ERROR_MUST_POSSESS_CAPABILITY; same for *NOT_IMPLEMENTED. Description fixes. |
| v42
8 Mar 2003 | Rename GetClassSignature to GetClassName. Rename IterateOverClassObjects to IterateOverInstancesOfClass. Remove GetMaxStack (operand stack isn't used in JVM TI). Description fixes: define launch-time, remove native frame pop from PopFrame, and assorted clarifications. |
| v43
8 Mar 2003 | Fix minor editing problem. |
| v44
10 Mar 2003 | Add phase information. Remap (compact) event numbers. |
| v45
11 Mar 2003 | More phase information - allow "any". Elide raw monitor queries and events. Minor description fixes. |
| v46
12 Mar 2003 | Add GetPhase. Use "phase" through document. Elide GetRawMonitorName. Elide GetObjectMonitors. |
| v47
12 Mar 2003 | Fixes from link, XML, and spell checking. Auto-generate the callback structure. |
| v48
13 Mar 2003 | One character XML fix. |
| v49
13 Mar 2003 | Change function parameter names to be consistent with event parameters (fooBarBaz becomes foo_bar_baz). |
| v50
14 Mar 2003 | Fix broken link. Fix thread markers. |
| v51
14 Mar 2003 | Change constants so they are under 128 to workaround compiler problems. |
| v52
23 Mar 2003 | Overhaul capabilities. Separate GetStackTrace into GetStackTrace and GetStackFrames. |
| v54
8 Apr 2003 | Use depth instead of jframeID to reference frames. Remove the now irrelevant GetCurrentFrame, GetCallerFrame and GetStackFrames. Remove frame arg from events. |
| v55
9 Apr 2003 | Remove GetObjectWithAnnotation since tests show bufferred approach more efficient. Add missing annotation_count to GetObjectsWithAnnotations |
| v56
10 Apr 2003 | Remove confusing parenthetical statement in GetObjectsWithAnnotations |
| v58
13 Apr 2003 | Replace jclass/jmethodID representation of method with simply jmethodID; Pass JvmtiEnv* as first arg of every event; remove JNIEnv* where inappropriate. Replace can_access_frames with can_access_local_variables; remove from purely stack access. Use can_get_synthetic_attribute; fix description. Clarify that zero length arrays must be deallocated. Clarify RelinquishCapabilities. Generalize JVMTI_ERROR_VM_DEAD to JVMTI_ERROR_WRONG_PHASE. |
| v59
27 Apr 2003 | Remove lingering indirect references to OBSOLETE_METHOD_ID. |
| v60
4 May 2003 | Allow DestroyRawMonitor during OnLoad. |
| v61
7 May 2003 | Added not monitor owner error return to DestroyRawMonitor. |
| v62
13 May 2003 |
Clarify semantics of raw monitors.
Change flags on GetThreadStatus.
GetClassLoader return NULL for the bootstrap class loader.
Add GetClassName issue.
Define local variable signature.
Disallow zero in annotations array of GetObjectsWithAnnotations.
Remove over specification in GetObjectsWithAnnotations.
Elide SetAllocationHooks.
Elide SuspendAllThreads.
|
| v63
14 May 2003 |
Define the data type jvmtiEventCallbacks.
Zero length allocations return NULL.
Keep SetAllocationHooks in JVMDI, but remove from JVM TI.
Add JVMTI_THREAD_STATUS_FLAG_INTERRUPTED.
|
| v64
15 May 2003 | Better wording, per review. |
| v65
15 May 2003 | First Alpha. Make jmethodID and jfieldID unique, jclass not used. |
| v66
27 May 2003 | Fix minor XSLT errors. |
| v67
13 June 2003 | Undo making jfieldID unique (jmethodID still is). |
| v68
17 June 2003 | Changes per June 11th Expert Group meeting -- Overhaul Heap functionality: single callback, remove GetHeapRoots, add reachable iterators, and rename "annotation" to "tag". NULL thread parameter on most functions is current thread. Add timers. Remove ForceExit. Add GetEnvironmentLocalStorage. Add verbose flag and event. Add AddToBootstrapClassLoaderSearch. Update ClassFileLoadHook. |
| v69
18 June 2003 | Clean up issues sections. Rename GetClassName back to GetClassSignature and fix description. Add generic signature to GetClassSignature, GetFieldSignature, GetMethodSignature, and GetLocalVariableTable. Elide EstimateCostOfCapabilities. Clarify that the system property functions operate on the VM view of system properties. Clarify Agent_OnLoad. Remove "const" from JNIEnv* in events. Add metadata accessors. |
| v70
18 June 2003 | Add start_depth to GetStackTrace. Move system properties to a new category. Add GetObjectSize. Remove "X" from command line flags. XML, HTML, and spell check corrections. |
| v71
19 June 2003 | Fix JVMTI_HEAP_ROOT_THREAD to be 6. Make each synopsis match the function name. Fix unclear wording. |
| v72
26 June 2003 | SetThreadLocalStorage and SetEnvironmentLocalStorage should allow value to be set to NULL. NotifyFramePop, GetFrameLocationm and all the local variable operations needed to have their wording about frames fixed. Grammar and clarity need to be fixed throughout. Capitalization and puntuation need to be consistent. Need micro version number and masks for accessing major, minor, and micro. The error code lists should indicate which must be returned by an implementation. The command line properties should be visible in the properties functions. Disallow popping from the current thread. Allow implementations to return opaque frame error when they cannot pop. The NativeMethodBind event should be sent during any phase. The DynamicCodeGenerated event should be sent during any phase. The following functions should be allowed to operate before VMInit: Set/GetEnvironmentLocalStorage GetMethodDeclaringClass GetClassSignature GetClassModifiers IsInterface IsArrayClass GetMethodName GetMethodModifiers GetMaxLocals GetArgumentsSize GetLineNumberTable GetMethodLocation IsMethodNative IsMethodSynthetic. Other changes (to XSL): Argument description should show asterisk after not before pointers. NotifyFramePop, GetFrameLocationm and all the local variable operations should hsve the NO_MORE_FRAMES error added. Not alive threads should have a different error return than invalid thread. |
| v73
7 July 2003 | VerboseOutput event was missing message parameter. Minor fix-ups. |
| v74
14 July 2003 | Technical Publications Department corrections. Allow thread and environment local storage to be set to NULL. |
| v75
23 July 2003 | Use new Agent_OnLoad rather than overloaded JVM_OnLoad. Add JNICALL to callbacks (XSL). Document JNICALL requirement for both events and callbacks (XSL). Restrict RedefineClasses to methods and attributes. Elide the VerboseOutput event. VMObjectAlloc: restrict when event is sent and remove method parameter. Finish loose ends from Tech Pubs edit. |
| v76
24 July 2003 | Change ClassFileLoadHook event to send the class instead of a boolean of redefine. |
| v77
24 July 2003 | XML fixes. Minor text clarifications and corrections. |
| v78
24 July 2003 | Remove GetExceptionHandlerTable and GetThrownExceptions from JVM TI. Clarify that stack frames are JVM Spec frames. Split can_get_source_info into can_get_source_file_name, can_get_line_numbers, and can_get_source_debug_extension. PopFrame cannot have a native calling method. Removed incorrect statement in GetClassloaderClasses (see http://java.sun.com/docs/books/vmspec/2nd-edition/html/ConstantPool.doc.html#79383). |
| v79
24 July 2003 | XML and text fixes. Move stack frame description into Stack Frame category. |
| v80
26 July 2003 | Allow NULL (means bootstrap loader) for GetClassloaderClasses. Add new heap reference kinds for references from classes. Add timer information struct and query functions. Add AvailableProcessors. Rename GetOtherThreadCpuTime to GetThreadCpuTime. Explicitly add JVMTI_ERROR_INVALID_THREAD and JVMTI_ERROR_THREAD_NOT_ALIVE to SetEventNotification mode. Add initial thread to the VM_INIT event. Remove platform assumptions from AddToBootstrapClassLoaderSearch. |
| v81
26 July 2003 | Grammar and clarity changes per review. |
| v82
27 July 2003 | More grammar and clarity changes per review. Add Agent_OnUnload. |
| v83
28 July 2003 | Change return type of Agent_OnUnload to void. |
| v84
28 July 2003 | Rename JVMTI_REFERENCE_ARRAY to JVMTI_REFERENCE_ARRAY_ELEMENT. |
| v85
28 July 2003 | Steal java.lang.Runtime.availableProcessors() wording for AvailableProcessors(). Guarantee that zero will never be an event ID. Remove some issues which are no longer issues. Per review, rename and more completely document the timer information functions. |
| v86
29 July 2003 | Non-spec visible change to XML controlled implementation: SetThreadLocalStorage must run in VM mode. |
| 0.1.87
5 August 2003 | Add GetErrorName. Add varargs warning to jvmtiExtensionEvent. Remove "const" on the jvmtiEnv* of jvmtiExtensionEvent. Remove unused can_get_exception_info capability. Pass jvmtiEnv* and JNIEnv* to the jvmtiStartFunction. Fix jvmtiExtensionFunctionInfo.func declared type. Extension function returns error code. Use new version numbering. |
| 0.2.88
5 August 2003 | Remove the ClassUnload event. |
| 0.2.89
8 August 2003 | Heap reference iterator callbacks return an enum that allows outgoing object references to be ignored. Allow JNIEnv as a param type to extension events/functions. |
| 0.2.90
15 August 2003 | Fix a typo. |
| 0.2.91
2 September 2003 | Remove all metadata functions: GetClassMetadata, GetFieldMetadata, and GetMethodMetadata. |
| 0.2.92
1 October 2003 | Mark the functions Allocate. Deallocate, RawMonitor*, SetEnvironmentLocalStorage, and GetEnvironmentLocalStorage as safe for use in heap callbacks and GC events. |
| 0.2.93
24 November 2003 | Add pass through opaque user data pointer to heap iterate functions and callbacks. In the CompiledMethodUnload event, send the code address. Add GarbageCollectionOccurred event. Add constant pool reference kind. Mark the functions CreateRawMonitor and DestroyRawMonitor as safe for use in heap callbacks and GC events. Clarify: VMDeath, GetCurrentThreadCpuTimerInfo, GetThreadCpuTimerInfo, IterateOverReachableObjects, IterateOverObjectsReachableFromObject, GetTime and JVMTI_ERROR_NULL_POINTER. Add missing errors to: GenerateEvents and AddToBootstrapClassLoaderSearch. Fix description of ClassFileLoadHook name parameter. In heap callbacks and GC/ObjectFree events, specify that only explicitly allowed functions can be called. Allow GetCurrentThreadCpuTimerInfo, GetCurrentThreadCpuTime, GetTimerInfo, and GetTime during callback. Allow calling SetTag/GetTag during the onload phase. SetEventNotificationMode, add: error attempted inappropriate thread level control. Remove jvmtiExceptionHandlerEntry. Fix handling of native methods on the stack -- location_ptr param of GetFrameLocation, remove JVMTI_ERROR_OPAQUE_FRAME from GetFrameLocation, jvmtiFrameInfo.location, and jlocation. Remove typo (from JVMPI) implying that the MonitorWaited event is sent on sleep. |
| 0.2.94
25 November 2003 | Clarifications and typos. |
| 0.2.95
3 December 2003 | Allow NULL user_data in heap iterators. |
| 0.2.97
28 January 2004 | Add GetThreadState, deprecate GetThreadStatus. |
| 0.2.98
29 January 2004 | INVALID_SLOT and TYPE_MISMATCH errors should be optional. |
| 0.2.102
12 February 2004 | Remove MonitorContendedExit. Added JNIEnv parameter to VMObjectAlloc. Clarified definition of class_tag and referrer_index parameters to heap callbacks. |
| 0.2.103
16 Febuary 2004 | Document JAVA_TOOL_OPTIONS. |
| 0.2.105
17 Febuary 2004 | Divide start phase into primordial and start. Add VMStart event Change phase associations of functions and events. |
| 0.3.6
18 Febuary 2004 | Elide deprecated GetThreadStatus. Bump minor version, subtract 100 from micro version |
| 0.3.7
18 Febuary 2004 | Document that timer nanosecond values are unsigned. Clarify text having to do with native methods. |
| 0.3.8
19 Febuary 2004 | Fix typos. Remove elided deprecated GetThreadStatus. |
| 0.3.9
23 Febuary 2004 | Require NotifyFramePop to act on suspended threads. |
| 0.3.10
24 Febuary 2004 |
Add capabilities
(can_redefine_any_class
and
can_generate_all_class_hook_events)
and an error (JVMTI_ERROR_UNMODIFIABLE_CLASS)
which allow some classes to be unmodifiable.
|
| 0.3.11
28 Febuary 2004 | Add JVMTI_ERROR_MUST_POSSESS_CAPABILITY to SetEventNotificationMode. |
| 0.3.12
8 March 2004 | Clarified CompiledMethodUnload so that it is clear the event may be posted after the class has been unloaded. |
| 0.3.13
5 March 2004 | Change the size parameter of VMObjectAlloc to jlong to match GetObjectSize. |
| 0.3.14
13 March 2004 | Added guideline for the use of the JNI FindClass function in event callback functions. |
| 0.3.15
15 March 2004 | Add GetAllStackTraces and GetThreadListStackTraces. |
| 0.3.16
19 March 2004 | ClassLoad and ClassPrepare events can be posted during start phase. |
| 0.3.17
25 March 2004 | Add JVMTI_ERROR_NATIVE_METHOD to GetLineNumberTable, GetLocalVariableTable, GetMaxLocals, GetArgumentsSize, GetMethodLocation, GetBytecodes. |
| 0.3.18
29 March 2004 | Return the timer kind in the timer information structure. |
| 0.3.19
31 March 2004 | Spec clarifications: JVMTI_THREAD_STATE_IN_NATIVE might not include JNI or JVM TI. ForceGarbageCollection does not run finalizers. The context of the specification is the Java platform. Warn about early instrumentation. |
| 0.3.20
1 April 2004 | Refinements to the above clarifications and Clarify that an error returned by Agent_OnLoad terminates the VM. |
| 0.3.21
1 April 2004 | Array class creation does not generate a class load event. |
| 0.3.22
7 April 2004 | Align thread state hierarchy more closely with java.lang.Thread.State. |
| 0.3.23
12 April 2004 | Clarify the documentation of thread state. |
| 0.3.24
19 April 2004 | Remove GarbageCollectionOccurred event -- can be done by agent. |
| 0.3.25
22 April 2004 | Define "command-line option". |
| 0.3.26
29 April 2004 | Describe the intended use of bytecode instrumentation. Fix description of extension event first parameter. |
| 0.3.27
30 April 2004 | Clarification and typos. |
| 0.3.28
18 May 2004 | Remove DataDumpRequest event. |
| 0.3.29
18 May 2004 | Clarify RawMonitorWait with zero timeout. Clarify thread state after RunAgentThread. |
| 0.3.30
24 May 2004 | Clean-up: fix bad/old links, etc. |
| 0.3.31
30 May 2004 | Clarifications including: All character strings are modified UTF-8. Agent thread visibiity. Meaning of obsolete method version. Thread invoking heap callbacks, |
| 1.0.32
1 June 2004 | Bump major.minor version numbers to "1.0". |
| 1.0.33
2 June 2004 | Clarify interaction between ForceGarbageCollection and ObjectFree. |
| 1.0.34
6 June 2004 | Restrict AddToBootstrapClassLoaderSearch and SetSystemProperty to the OnLoad phase only. |
| 1.0.35
11 June 2004 | Fix typo in SetTag. |
| 1.0.36
18 June 2004 | Fix trademarks. Add missing parameter in example GetThreadState usage. |
| 1.0.37
5 November 2004 | Add missing function table layout. Add missing description of C++ member function format of functions. Clarify that name in CFLH can be NULL. |