void javaVFrame::print() {
ResourceMark rm;
vframe::print();
tty->print("\t");
method()->print_value();
tty->cr();
tty->print_cr("\tbci: %d", bci());
print_stack_values("locals", locals());
print_stack_values("expressions", expressions());
GrowableArray<MonitorInfo*>* list = monitors();
if (list->is_empty()) return;
tty->print_cr("\tmonitor list:");
for (int index = (list->length()-1); index >= 0; index--) {
MonitorInfo* monitor = list->at(index);
tty->print("\t obj\t");
if (monitor->owner_is_scalar_replaced()) {
Klass* k = java_lang_Class::as_Klass(monitor->owner_klass());
tty->print("( is scalar replaced %s)", k->external_name());
} else if (monitor->owner() == NULL) {
tty->print("( null )");
} else {
monitor->owner()->print_value();
tty->print("(" INTPTR_FORMAT ")", (address)monitor->owner());
}
if (monitor->eliminated() && is_compiled_frame())
tty->print(" ( lock is eliminated )");
tty->cr();
tty->print("\t ");
monitor->lock()->print_on(tty);
tty->cr();
}
}
//
// Count the number of objects for a lightweight monitor. The hobj
// parameter is object that owns the monitor so this routine will
// count the number of times the same object was locked by frames
// in java_thread.
//
jint
JvmtiEnvBase::count_locked_objects(JavaThread *java_thread, Handle hobj) {
jint ret = 0;
if (!java_thread->has_last_Java_frame()) {
return ret; // no Java frames so no monitors
}
ResourceMark rm;
HandleMark hm;
RegisterMap reg_map(java_thread);
for(javaVFrame *jvf=java_thread->last_java_vframe(®_map); jvf != NULL;
jvf = jvf->java_sender()) {
GrowableArray<MonitorInfo*>* mons = jvf->monitors();
if (!mons->is_empty()) {
for (int i = 0; i < mons->length(); i++) {
MonitorInfo *mi = mons->at(i);
if (mi->owner_is_scalar_replaced()) continue;
// see if owner of the monitor is our object
if (mi->owner() != NULL && mi->owner() == hobj()) {
ret++;
}
}
}
}
return ret;
}
void javaVFrame::print_lock_info_on(outputStream* st, int frame_count) {
ResourceMark rm;
// If this is the first frame, and java.lang.Object.wait(...) then print out the receiver.
if (frame_count == 0) {
if (method()->name() == vmSymbols::wait_name() &&
method()->method_holder()->name() == vmSymbols::java_lang_Object()) {
StackValueCollection* locs = locals();
if (!locs->is_empty()) {
StackValue* sv = locs->at(0);
if (sv->type() == T_OBJECT) {
Handle o = locs->at(0)->get_obj();
print_locked_object_class_name(st, o, "waiting on");
}
}
} else if (thread()->current_park_blocker() != NULL) {
oop obj = thread()->current_park_blocker();
Klass* k = obj->klass();
st->print_cr("\t- %s <" INTPTR_FORMAT "> (a %s)", "parking to wait for ", (address)obj, k->external_name());
}
}
// Print out all monitors that we have locked or are trying to lock
GrowableArray<MonitorInfo*>* mons = monitors();
if (!mons->is_empty()) {
bool found_first_monitor = false;
for (int index = (mons->length()-1); index >= 0; index--) {
MonitorInfo* monitor = mons->at(index);
if (monitor->eliminated() && is_compiled_frame()) { // Eliminated in compiled code
if (monitor->owner_is_scalar_replaced()) {
Klass* k = java_lang_Class::as_Klass(monitor->owner_klass());
st->print("\t- eliminated <owner is scalar replaced> (a %s)", k->external_name());
} else {
oop obj = monitor->owner();
if (obj != NULL) {
print_locked_object_class_name(st, obj, "eliminated");
}
}
continue;
}
if (monitor->owner() != NULL) {
// First, assume we have the monitor locked. If we haven't found an
// owned monitor before and this is the first frame, then we need to
// see if we have completed the lock or we are blocked trying to
// acquire it - we can only be blocked if the monitor is inflated
const char *lock_state = "locked"; // assume we have the monitor locked
if (!found_first_monitor && frame_count == 0) {
markOop mark = monitor->owner()->mark();
if (mark->has_monitor() &&
mark->monitor() == thread()->current_pending_monitor()) {
lock_state = "waiting to lock";
}
}
found_first_monitor = true;
print_locked_object_class_name(st, monitor->owner(), lock_state);
}
}
}
}
void vframeArrayElement::fill_in(compiledVFrame* vf) {
// Copy the information from the compiled vframe to the
// interpreter frame we will be creating to replace vf
_method = vf->method();
_bci = vf->raw_bci();
_reexecute = vf->should_reexecute();
int index;
// Get the monitors off-stack
GrowableArray<MonitorInfo*>* list = vf->monitors();
if (list->is_empty()) {
_monitors = NULL;
} else {
// Allocate monitor chunk
_monitors = new MonitorChunk(list->length());
vf->thread()->add_monitor_chunk(_monitors);
// Migrate the BasicLocks from the stack to the monitor chunk
for (index = 0; index < list->length(); index++) {
MonitorInfo* monitor = list->at(index);
assert(!monitor->owner_is_scalar_replaced(), "object should be reallocated already");
assert(monitor->owner() == NULL || (!monitor->owner()->is_unlocked() && !monitor->owner()->has_bias_pattern()), "object must be null or locked, and unbiased");
BasicObjectLock* dest = _monitors->at(index);
dest->set_obj(monitor->owner());
monitor->lock()->move_to(monitor->owner(), dest->lock());
}
}
// Convert the vframe locals and expressions to off stack
// values. Because we will not gc all oops can be converted to
// intptr_t (i.e. a stack slot) and we are fine. This is
// good since we are inside a HandleMark and the oops in our
// collection would go away between packing them here and
// unpacking them in unpack_on_stack.
// First the locals go off-stack
// FIXME this seems silly it creates a StackValueCollection
// in order to get the size to then copy them and
// convert the types to intptr_t size slots. Seems like it
// could do it in place... Still uses less memory than the
// old way though
StackValueCollection *locs = vf->locals();
_locals = new StackValueCollection(locs->size());
for(index = 0; index < locs->size(); index++) {
StackValue* value = locs->at(index);
switch(value->type()) {
case T_OBJECT:
assert(!value->obj_is_scalar_replaced(), "object should be reallocated already");
// preserve object type
_locals->add( new StackValue((intptr_t) (value->get_obj()()), T_OBJECT ));
break;
case T_CONFLICT:
// A dead local. Will be initialized to null/zero.
_locals->add( new StackValue());
break;
case T_INT:
_locals->add( new StackValue(value->get_int()));
break;
default:
ShouldNotReachHere();
}
}
// Now the expressions off-stack
// Same silliness as above
StackValueCollection *exprs = vf->expressions();
_expressions = new StackValueCollection(exprs->size());
for(index = 0; index < exprs->size(); index++) {
StackValue* value = exprs->at(index);
switch(value->type()) {
case T_OBJECT:
assert(!value->obj_is_scalar_replaced(), "object should be reallocated already");
// preserve object type
_expressions->add( new StackValue((intptr_t) (value->get_obj()()), T_OBJECT ));
break;
case T_CONFLICT:
// A dead stack element. Will be initialized to null/zero.
// This can occur when the compiler emits a state in which stack
// elements are known to be dead (because of an imminent exception).
_expressions->add( new StackValue());
break;
case T_INT:
_expressions->add( new StackValue(value->get_int()));
break;
default:
ShouldNotReachHere();
}
}
}
// Save JNI local handles for any objects that this frame owns.
jvmtiError
JvmtiEnvBase::get_locked_objects_in_frame(JavaThread* calling_thread, JavaThread* java_thread,
javaVFrame *jvf, GrowableArray<jvmtiMonitorStackDepthInfo*>* owned_monitors_list, int stack_depth) {
jvmtiError err = JVMTI_ERROR_NONE;
ResourceMark rm;
GrowableArray<MonitorInfo*>* mons = jvf->monitors();
if (mons->is_empty()) {
return err; // this javaVFrame holds no monitors
}
HandleMark hm;
oop wait_obj = NULL;
{
// save object of current wait() call (if any) for later comparison
ObjectMonitor *mon = java_thread->current_waiting_monitor();
if (mon != NULL) {
wait_obj = (oop)mon->object();
}
}
oop pending_obj = NULL;
{
// save object of current enter() call (if any) for later comparison
ObjectMonitor *mon = java_thread->current_pending_monitor();
if (mon != NULL) {
pending_obj = (oop)mon->object();
}
}
for (int i = 0; i < mons->length(); i++) {
MonitorInfo *mi = mons->at(i);
if (mi->owner_is_scalar_replaced()) continue;
oop obj = mi->owner();
if (obj == NULL) {
// this monitor doesn't have an owning object so skip it
continue;
}
if (wait_obj == obj) {
// the thread is waiting on this monitor so it isn't really owned
continue;
}
if (pending_obj == obj) {
// the thread is pending on this monitor so it isn't really owned
continue;
}
if (owned_monitors_list->length() > 0) {
// Our list has at least one object on it so we have to check
// for recursive object locking
bool found = false;
for (int j = 0; j < owned_monitors_list->length(); j++) {
jobject jobj = ((jvmtiMonitorStackDepthInfo*)owned_monitors_list->at(j))->monitor;
oop check = JNIHandles::resolve(jobj);
if (check == obj) {
found = true; // we found the object
break;
}
}
if (found) {
// already have this object so don't include it
continue;
}
}
// add the owning object to our list
jvmtiMonitorStackDepthInfo *jmsdi;
err = allocate(sizeof(jvmtiMonitorStackDepthInfo), (unsigned char **)&jmsdi);
if (err != JVMTI_ERROR_NONE) {
return err;
}
Handle hobj(obj);
jmsdi->monitor = jni_reference(calling_thread, hobj);
jmsdi->stack_depth = stack_depth;
owned_monitors_list->append(jmsdi);
}
return err;
}
