src/hotspot/share/memory/heapInspection.cpp - platform/libcore - Git at Google

 /*
  * Copyright (c) 2002, 2020, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */

 #include "precompiled.hpp"
 #include "classfile/classLoaderData.inline.hpp"
 #include "classfile/classLoaderDataGraph.hpp"
 #include "classfile/moduleEntry.hpp"
 #include "classfile/systemDictionary.hpp"
 #include "gc/shared/collectedHeap.hpp"
 #include "logging/log.hpp"
 #include "logging/logTag.hpp"
 #include "memory/heapInspection.hpp"
 #include "memory/resourceArea.hpp"
 #include "memory/universe.hpp"
 #include "oops/oop.inline.hpp"
 #include "oops/reflectionAccessorImplKlassHelper.hpp"
 #include "runtime/os.hpp"
 #include "utilities/globalDefinitions.hpp"
 #include "utilities/macros.hpp"
 #include "utilities/stack.inline.hpp"

 // HeapInspection

 inline KlassInfoEntry::~KlassInfoEntry() {
   if (_subclasses != NULL) {
     delete _subclasses;
   }
 }

 inline void KlassInfoEntry::add_subclass(KlassInfoEntry* cie) {
   if (_subclasses == NULL) {
     _subclasses = new  (ResourceObj::C_HEAP, mtInternal) GrowableArray<KlassInfoEntry*>(4, true);
   }
   _subclasses->append(cie);
 }

 int KlassInfoEntry::compare(KlassInfoEntry* e1, KlassInfoEntry* e2) {
   if(e1->_instance_words > e2->_instance_words) {
     return -1;
   } else if(e1->_instance_words < e2->_instance_words) {
     return 1;
   }
   // Sort alphabetically, note 'Z' < '[' < 'a', but it's better to group
   // the array classes before all the instance classes.
   ResourceMark rm;
   const char* name1 = e1->klass()->external_name();
   const char* name2 = e2->klass()->external_name();
   bool d1 = (name1[0] == JVM_SIGNATURE_ARRAY);
   bool d2 = (name2[0] == JVM_SIGNATURE_ARRAY);
   if (d1 && !d2) {
     return -1;
   } else if (d2 && !d1) {
     return 1;
   } else {
     return strcmp(name1, name2);
   }
 }

 const char* KlassInfoEntry::name() const {
   const char* name;
   if (_klass->name() != NULL) {
     name = _klass->external_name();
   } else {
     if (_klass == Universe::boolArrayKlassObj())         name = "<boolArrayKlass>";         else
     if (_klass == Universe::charArrayKlassObj())         name = "<charArrayKlass>";         else
     if (_klass == Universe::floatArrayKlassObj())        name = "<floatArrayKlass>";        else
     if (_klass == Universe::doubleArrayKlassObj())       name = "<doubleArrayKlass>";       else
     if (_klass == Universe::byteArrayKlassObj())         name = "<byteArrayKlass>";         else
     if (_klass == Universe::shortArrayKlassObj())        name = "<shortArrayKlass>";        else
     if (_klass == Universe::intArrayKlassObj())          name = "<intArrayKlass>";          else
     if (_klass == Universe::longArrayKlassObj())         name = "<longArrayKlass>";         else
       name = "<no name>";
   }
   return name;
 }

 void KlassInfoEntry::print_on(outputStream* st) const {
   ResourceMark rm;

   // simplify the formatting (ILP32 vs LP64) - always cast the numbers to 64-bit
   ModuleEntry* module = _klass->module();
   if (module->is_named()) {
     st->print_cr(INT64_FORMAT_W(13) "  " UINT64_FORMAT_W(13) "  %s (%s@%s)",
                  (int64_t)_instance_count,
                  (uint64_t)_instance_words * HeapWordSize,
                  name(),
                  module->name()->as_C_string(),
                  module->version() != NULL ? module->version()->as_C_string() : "");
   } else {
     st->print_cr(INT64_FORMAT_W(13) "  " UINT64_FORMAT_W(13) "  %s",
                  (int64_t)_instance_count,
                  (uint64_t)_instance_words * HeapWordSize,
                  name());
   }
 }

 KlassInfoEntry* KlassInfoBucket::lookup(Klass* const k) {
   // Can happen if k is an archived class that we haven't loaded yet.
   if (k->java_mirror_no_keepalive() == NULL) {
     return NULL;
   }

   KlassInfoEntry* elt = _list;
   while (elt != NULL) {
     if (elt->is_equal(k)) {
       return elt;
     }
     elt = elt->next();
   }
   elt = new (std::nothrow) KlassInfoEntry(k, list());
   // We may be out of space to allocate the new entry.
   if (elt != NULL) {
     set_list(elt);
   }
   return elt;
 }

 void KlassInfoBucket::iterate(KlassInfoClosure* cic) {
   KlassInfoEntry* elt = _list;
   while (elt != NULL) {
     cic->do_cinfo(elt);
     elt = elt->next();
   }
 }

 void KlassInfoBucket::empty() {
   KlassInfoEntry* elt = _list;
   _list = NULL;
   while (elt != NULL) {
     KlassInfoEntry* next = elt->next();
     delete elt;
     elt = next;
   }
 }

 class KlassInfoTable::AllClassesFinder : public LockedClassesDo {
   KlassInfoTable *_table;
 public:
   AllClassesFinder(KlassInfoTable* table) : _table(table) {}
   virtual void do_klass(Klass* k) {
     // This has the SIDE EFFECT of creating a KlassInfoEntry
     // for <k>, if one doesn't exist yet.
     _table->lookup(k);
   }
 };


 KlassInfoTable::KlassInfoTable(bool add_all_classes) {
   _size_of_instances_in_words = 0;
   _ref = (HeapWord*) Universe::boolArrayKlassObj();
   _buckets =
     (KlassInfoBucket*)  AllocateHeap(sizeof(KlassInfoBucket) * _num_buckets,
        mtInternal, CURRENT_PC, AllocFailStrategy::RETURN_NULL);
   if (_buckets != NULL) {
     for (int index = 0; index < _num_buckets; index++) {
       _buckets[index].initialize();
     }
     if (add_all_classes) {
       AllClassesFinder finder(this);
       ClassLoaderDataGraph::classes_do(&finder);
     }
   }
 }

 KlassInfoTable::~KlassInfoTable() {
   if (_buckets != NULL) {
     for (int index = 0; index < _num_buckets; index++) {
       _buckets[index].empty();
     }
     FREE_C_HEAP_ARRAY(KlassInfoBucket, _buckets);
     _buckets = NULL;
   }
 }

 uint KlassInfoTable::hash(const Klass* p) {
   return (uint)(((uintptr_t)p - (uintptr_t)_ref) >> 2);
 }

 KlassInfoEntry* KlassInfoTable::lookup(Klass* k) {
   uint         idx = hash(k) % _num_buckets;
   assert(_buckets != NULL, "Allocation failure should have been caught");
   KlassInfoEntry*  e   = _buckets[idx].lookup(k);
   // Lookup may fail if this is a new klass for which we
   // could not allocate space for an new entry, or if it's
   // an archived class that we haven't loaded yet.
   assert(e == NULL || k == e->klass(), "must be equal");
   return e;
 }

 // Return false if the entry could not be recorded on account
 // of running out of space required to create a new entry.
 bool KlassInfoTable::record_instance(const oop obj) {
   Klass*        k = obj->klass();
   KlassInfoEntry* elt = lookup(k);
   // elt may be NULL if it's a new klass for which we
   // could not allocate space for a new entry in the hashtable.
   if (elt != NULL) {
     elt->set_count(elt->count() + 1);
     elt->set_words(elt->words() + obj->size());
     _size_of_instances_in_words += obj->size();
     return true;
   } else {
     return false;
   }
 }

 void KlassInfoTable::iterate(KlassInfoClosure* cic) {
   assert(_buckets != NULL, "Allocation failure should have been caught");
   for (int index = 0; index < _num_buckets; index++) {
     _buckets[index].iterate(cic);
   }
 }

 size_t KlassInfoTable::size_of_instances_in_words() const {
   return _size_of_instances_in_words;
 }

 int KlassInfoHisto::sort_helper(KlassInfoEntry** e1, KlassInfoEntry** e2) {
   return (*e1)->compare(*e1,*e2);
 }

 KlassInfoHisto::KlassInfoHisto(KlassInfoTable* cit) :
   _cit(cit) {
   _elements = new (ResourceObj::C_HEAP, mtInternal) GrowableArray<KlassInfoEntry*>(_histo_initial_size, true);
 }

 KlassInfoHisto::~KlassInfoHisto() {
   delete _elements;
 }

 void KlassInfoHisto::add(KlassInfoEntry* cie) {
   elements()->append(cie);
 }

 void KlassInfoHisto::sort() {
   elements()->sort(KlassInfoHisto::sort_helper);
 }

 void KlassInfoHisto::print_elements(outputStream* st) const {
   // simplify the formatting (ILP32 vs LP64) - store the sum in 64-bit
   int64_t total = 0;
   uint64_t totalw = 0;
   for(int i=0; i < elements()->length(); i++) {
     st->print("%4d: ", i+1);
     elements()->at(i)->print_on(st);
     total += elements()->at(i)->count();
     totalw += elements()->at(i)->words();
   }
   st->print_cr("Total " INT64_FORMAT_W(13) "  " UINT64_FORMAT_W(13),
                total, totalw * HeapWordSize);
 }

 class HierarchyClosure : public KlassInfoClosure {
 private:
   GrowableArray<KlassInfoEntry*> *_elements;
 public:
   HierarchyClosure(GrowableArray<KlassInfoEntry*> *_elements) : _elements(_elements) {}

   void do_cinfo(KlassInfoEntry* cie) {
     // ignore array classes
     if (cie->klass()->is_instance_klass()) {
       _elements->append(cie);
     }
   }
 };

 void KlassHierarchy::print_class_hierarchy(outputStream* st, bool print_interfaces,
                                            bool print_subclasses, char* classname) {
   ResourceMark rm;
   Stack <KlassInfoEntry*, mtClass> class_stack;
   GrowableArray<KlassInfoEntry*> elements;

   // Add all classes to the KlassInfoTable, which allows for quick lookup.
   // A KlassInfoEntry will be created for each class.
   KlassInfoTable cit(true);
   if (cit.allocation_failed()) {
     st->print_cr("ERROR: Ran out of C-heap; hierarchy not generated");
     return;
   }

   // Add all created KlassInfoEntry instances to the elements array for easy
   // iteration, and to allow each KlassInfoEntry instance to have a unique index.
   HierarchyClosure hc(&elements);
   cit.iterate(&hc);

   for(int i = 0; i < elements.length(); i++) {
     KlassInfoEntry* cie = elements.at(i);
     Klass* super = cie->klass()->super();

     // Set the index for the class.
     cie->set_index(i + 1);

     // Add the class to the subclass array of its superclass.
     if (super != NULL) {
       KlassInfoEntry* super_cie = cit.lookup(super);
       assert(super_cie != NULL, "could not lookup superclass");
       super_cie->add_subclass(cie);
     }
   }

   // Set the do_print flag for each class that should be printed.
   for(int i = 0; i < elements.length(); i++) {
     KlassInfoEntry* cie = elements.at(i);
     if (classname == NULL) {
       // We are printing all classes.
       cie->set_do_print(true);
     } else {
       // We are only printing the hierarchy of a specific class.
       if (strcmp(classname, cie->klass()->external_name()) == 0) {
         KlassHierarchy::set_do_print_for_class_hierarchy(cie, &cit, print_subclasses);
       }
     }
   }

   // Now we do a depth first traversal of the class hierachry. The class_stack will
   // maintain the list of classes we still need to process. Start things off
   // by priming it with java.lang.Object.
   KlassInfoEntry* jlo_cie = cit.lookup(SystemDictionary::Object_klass());
   assert(jlo_cie != NULL, "could not lookup java.lang.Object");
   class_stack.push(jlo_cie);

   // Repeatedly pop the top item off the stack, print its class info,
   // and push all of its subclasses on to the stack. Do this until there
   // are no classes left on the stack.
   while (!class_stack.is_empty()) {
     KlassInfoEntry* curr_cie = class_stack.pop();
     if (curr_cie->do_print()) {
       print_class(st, curr_cie, print_interfaces);
       if (curr_cie->subclasses() != NULL) {
         // Current class has subclasses, so push all of them onto the stack.
         for (int i = 0; i < curr_cie->subclasses()->length(); i++) {
           KlassInfoEntry* cie = curr_cie->subclasses()->at(i);
           if (cie->do_print()) {
             class_stack.push(cie);
           }
         }
       }
     }
   }

   st->flush();
 }

 // Sets the do_print flag for every superclass and subclass of the specified class.
 void KlassHierarchy::set_do_print_for_class_hierarchy(KlassInfoEntry* cie, KlassInfoTable* cit,
                                                       bool print_subclasses) {
   // Set do_print for all superclasses of this class.
   Klass* super = ((InstanceKlass*)cie->klass())->java_super();
   while (super != NULL) {
     KlassInfoEntry* super_cie = cit->lookup(super);
     super_cie->set_do_print(true);
     super = super->super();
   }

   // Set do_print for this class and all of its subclasses.
   Stack <KlassInfoEntry*, mtClass> class_stack;
   class_stack.push(cie);
   while (!class_stack.is_empty()) {
     KlassInfoEntry* curr_cie = class_stack.pop();
     curr_cie->set_do_print(true);
     if (print_subclasses && curr_cie->subclasses() != NULL) {
       // Current class has subclasses, so push all of them onto the stack.
       for (int i = 0; i < curr_cie->subclasses()->length(); i++) {
         KlassInfoEntry* cie = curr_cie->subclasses()->at(i);
         class_stack.push(cie);
       }
     }
   }
 }

 static void print_indent(outputStream* st, int indent) {
   while (indent != 0) {
     st->print("|");
     indent--;
     if (indent != 0) {
       st->print("  ");
     }
   }
 }

 // Print the class name and its unique ClassLoader identifer.
 static void print_classname(outputStream* st, Klass* klass) {
   oop loader_oop = klass->class_loader_data()->class_loader();
   st->print("%s/", klass->external_name());
   if (loader_oop == NULL) {
     st->print("null");
   } else {
     st->print(INTPTR_FORMAT, p2i(klass->class_loader_data()));
   }
 }

 static void print_interface(outputStream* st, InstanceKlass* intf_klass, const char* intf_type, int indent) {
   print_indent(st, indent);
   st->print("  implements ");
   print_classname(st, intf_klass);
   st->print(" (%s intf)\n", intf_type);
 }

 void KlassHierarchy::print_class(outputStream* st, KlassInfoEntry* cie, bool print_interfaces) {
   ResourceMark rm;
   InstanceKlass* klass = (InstanceKlass*)cie->klass();
   int indent = 0;

   // Print indentation with proper indicators of superclass.
   Klass* super = klass->super();
   while (super != NULL) {
     super = super->super();
     indent++;
   }
   print_indent(st, indent);
   if (indent != 0) st->print("--");

   // Print the class name, its unique ClassLoader identifer, and if it is an interface.
   print_classname(st, klass);
   if (klass->is_interface()) {
     st->print(" (intf)");
   }
   // Special treatment for generated core reflection accessor classes: print invocation target.
   if (ReflectionAccessorImplKlassHelper::is_generated_accessor(klass)) {
     st->print(" (invokes: ");
     ReflectionAccessorImplKlassHelper::print_invocation_target(st, klass);
     st->print(")");
   }
   st->print("\n");

   // Print any interfaces the class has.
   if (print_interfaces) {
     Array<InstanceKlass*>* local_intfs = klass->local_interfaces();
     Array<InstanceKlass*>* trans_intfs = klass->transitive_interfaces();
     for (int i = 0; i < local_intfs->length(); i++) {
       print_interface(st, local_intfs->at(i), "declared", indent);
     }
     for (int i = 0; i < trans_intfs->length(); i++) {
       InstanceKlass* trans_interface = trans_intfs->at(i);
       // Only print transitive interfaces if they are not also declared.
       if (!local_intfs->contains(trans_interface)) {
         print_interface(st, trans_interface, "inherited", indent);
       }
     }
   }
 }

 void KlassInfoHisto::print_histo_on(outputStream* st) {
   st->print_cr(" num     #instances         #bytes  class name (module)");
   st->print_cr("-------------------------------------------------------");
   print_elements(st);
 }

 class HistoClosure : public KlassInfoClosure {
  private:
   KlassInfoHisto* _cih;
  public:
   HistoClosure(KlassInfoHisto* cih) : _cih(cih) {}

   void do_cinfo(KlassInfoEntry* cie) {
     _cih->add(cie);
   }
 };

 class RecordInstanceClosure : public ObjectClosure {
  private:
   KlassInfoTable* _cit;
   size_t _missed_count;
   BoolObjectClosure* _filter;
  public:
   RecordInstanceClosure(KlassInfoTable* cit, BoolObjectClosure* filter) :
     _cit(cit), _missed_count(0), _filter(filter) {}

   void do_object(oop obj) {
     if (should_visit(obj)) {
       if (!_cit->record_instance(obj)) {
         _missed_count++;
       }
     }
   }

   size_t missed_count() { return _missed_count; }

  private:
   bool should_visit(oop obj) {
     return _filter == NULL || _filter->do_object_b(obj);
   }
 };

 size_t HeapInspection::populate_table(KlassInfoTable* cit, BoolObjectClosure *filter) {
   ResourceMark rm;

   RecordInstanceClosure ric(cit, filter);
   Universe::heap()->object_iterate(&ric);
   return ric.missed_count();
 }

 void HeapInspection::heap_inspection(outputStream* st) {
   ResourceMark rm;

   KlassInfoTable cit(false);
   if (!cit.allocation_failed()) {
     // populate table with object allocation info
     size_t missed_count = populate_table(&cit);
     if (missed_count != 0) {
       log_info(gc, classhisto)("WARNING: Ran out of C-heap; undercounted " SIZE_FORMAT
                                " total instances in data below",
                                missed_count);
     }

     // Sort and print klass instance info
     KlassInfoHisto histo(&cit);
     HistoClosure hc(&histo);

     cit.iterate(&hc);

     histo.sort();
     histo.print_histo_on(st);
   } else {
     st->print_cr("ERROR: Ran out of C-heap; histogram not generated");
   }
   st->flush();
 }

 class FindInstanceClosure : public ObjectClosure {
  private:
   Klass* _klass;
   GrowableArray<oop>* _result;

  public:
   FindInstanceClosure(Klass* k, GrowableArray<oop>* result) : _klass(k), _result(result) {};

   void do_object(oop obj) {
     if (obj->is_a(_klass)) {
       // obj was read with AS_NO_KEEPALIVE, or equivalent.
       // The object needs to be kept alive when it is published.
       Universe::heap()->keep_alive(obj);

       _result->append(obj);
     }
   }
 };

 void HeapInspection::find_instances_at_safepoint(Klass* k, GrowableArray<oop>* result) {
   assert(SafepointSynchronize::is_at_safepoint(), "all threads are stopped");
   assert(Heap_lock->is_locked(), "should have the Heap_lock");

   // Ensure that the heap is parsable
   Universe::heap()->ensure_parsability(false);  // no need to retire TALBs

   // Iterate over objects in the heap
   FindInstanceClosure fic(k, result);
   Universe::heap()->object_iterate(&fic);
 }
	/*
	* Copyright (c) 2002, 2020, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*
	*/

	#include "precompiled.hpp"
	#include "classfile/classLoaderData.inline.hpp"
	#include "classfile/classLoaderDataGraph.hpp"
	#include "classfile/moduleEntry.hpp"
	#include "classfile/systemDictionary.hpp"
	#include "gc/shared/collectedHeap.hpp"
	#include "logging/log.hpp"
	#include "logging/logTag.hpp"
	#include "memory/heapInspection.hpp"
	#include "memory/resourceArea.hpp"
	#include "memory/universe.hpp"
	#include "oops/oop.inline.hpp"
	#include "oops/reflectionAccessorImplKlassHelper.hpp"
	#include "runtime/os.hpp"
	#include "utilities/globalDefinitions.hpp"
	#include "utilities/macros.hpp"
	#include "utilities/stack.inline.hpp"

	// HeapInspection

	inline KlassInfoEntry::~KlassInfoEntry() {
	if (_subclasses != NULL) {
	delete _subclasses;
	}
	}

	inline void KlassInfoEntry::add_subclass(KlassInfoEntry* cie) {
	if (_subclasses == NULL) {
	_subclasses = new (ResourceObj::C_HEAP, mtInternal) GrowableArray<KlassInfoEntry*>(4, true);
	}
	_subclasses->append(cie);
	}

	int KlassInfoEntry::compare(KlassInfoEntry* e1, KlassInfoEntry* e2) {
	if(e1->_instance_words > e2->_instance_words) {
	return -1;
	} else if(e1->_instance_words < e2->_instance_words) {
	return 1;
	}
	// Sort alphabetically, note 'Z' < '[' < 'a', but it's better to group
	// the array classes before all the instance classes.
	ResourceMark rm;
	const char* name1 = e1->klass()->external_name();
	const char* name2 = e2->klass()->external_name();
	bool d1 = (name1[0] == JVM_SIGNATURE_ARRAY);
	bool d2 = (name2[0] == JVM_SIGNATURE_ARRAY);
	if (d1 && !d2) {
	return -1;
	} else if (d2 && !d1) {
	return 1;
	} else {
	return strcmp(name1, name2);
	}
	}

	const char* KlassInfoEntry::name() const {
	const char* name;
	if (_klass->name() != NULL) {
	name = _klass->external_name();
	} else {
	if (_klass == Universe::boolArrayKlassObj()) name = "<boolArrayKlass>"; else
	if (_klass == Universe::charArrayKlassObj()) name = "<charArrayKlass>"; else
	if (_klass == Universe::floatArrayKlassObj()) name = "<floatArrayKlass>"; else
	if (_klass == Universe::doubleArrayKlassObj()) name = "<doubleArrayKlass>"; else
	if (_klass == Universe::byteArrayKlassObj()) name = "<byteArrayKlass>"; else
	if (_klass == Universe::shortArrayKlassObj()) name = "<shortArrayKlass>"; else
	if (_klass == Universe::intArrayKlassObj()) name = "<intArrayKlass>"; else
	if (_klass == Universe::longArrayKlassObj()) name = "<longArrayKlass>"; else
	name = "<no name>";
	}
	return name;
	}

	void KlassInfoEntry::print_on(outputStream* st) const {
	ResourceMark rm;

	// simplify the formatting (ILP32 vs LP64) - always cast the numbers to 64-bit
	ModuleEntry* module = _klass->module();
	if (module->is_named()) {
	st->print_cr(INT64_FORMAT_W(13) " " UINT64_FORMAT_W(13) " %s (%s@%s)",
	(int64_t)_instance_count,
	(uint64_t)_instance_words * HeapWordSize,
	name(),
	module->name()->as_C_string(),
	module->version() != NULL ? module->version()->as_C_string() : "");
	} else {
	st->print_cr(INT64_FORMAT_W(13) " " UINT64_FORMAT_W(13) " %s",
	(int64_t)_instance_count,
	(uint64_t)_instance_words * HeapWordSize,
	name());
	}
	}

	KlassInfoEntry* KlassInfoBucket::lookup(Klass* const k) {
	// Can happen if k is an archived class that we haven't loaded yet.
	if (k->java_mirror_no_keepalive() == NULL) {
	return NULL;
	}

	KlassInfoEntry* elt = _list;
	while (elt != NULL) {
	if (elt->is_equal(k)) {
	return elt;
	}
	elt = elt->next();
	}
	elt = new (std::nothrow) KlassInfoEntry(k, list());
	// We may be out of space to allocate the new entry.
	if (elt != NULL) {
	set_list(elt);
	}
	return elt;
	}

	void KlassInfoBucket::iterate(KlassInfoClosure* cic) {
	KlassInfoEntry* elt = _list;
	while (elt != NULL) {
	cic->do_cinfo(elt);
	elt = elt->next();
	}
	}

	void KlassInfoBucket::empty() {
	KlassInfoEntry* elt = _list;
	_list = NULL;
	while (elt != NULL) {
	KlassInfoEntry* next = elt->next();
	delete elt;
	elt = next;
	}
	}

	class KlassInfoTable::AllClassesFinder : public LockedClassesDo {
	KlassInfoTable *_table;
	public:
	AllClassesFinder(KlassInfoTable* table) : _table(table) {}
	virtual void do_klass(Klass* k) {
	// This has the SIDE EFFECT of creating a KlassInfoEntry
	// for <k>, if one doesn't exist yet.
	_table->lookup(k);
	}
	};


	KlassInfoTable::KlassInfoTable(bool add_all_classes) {
	_size_of_instances_in_words = 0;
	_ref = (HeapWord*) Universe::boolArrayKlassObj();
	_buckets =
	(KlassInfoBucket) AllocateHeap(sizeof(KlassInfoBucket) _num_buckets,
	mtInternal, CURRENT_PC, AllocFailStrategy::RETURN_NULL);
	if (_buckets != NULL) {
	for (int index = 0; index < _num_buckets; index++) {
	_buckets[index].initialize();
	}
	if (add_all_classes) {
	AllClassesFinder finder(this);
	ClassLoaderDataGraph::classes_do(&finder);
	}
	}
	}

	KlassInfoTable::~KlassInfoTable() {
	if (_buckets != NULL) {
	for (int index = 0; index < _num_buckets; index++) {
	_buckets[index].empty();
	}
	FREE_C_HEAP_ARRAY(KlassInfoBucket, _buckets);
	_buckets = NULL;
	}
	}

	uint KlassInfoTable::hash(const Klass* p) {
	return (uint)(((uintptr_t)p - (uintptr_t)_ref) >> 2);
	}

	KlassInfoEntry* KlassInfoTable::lookup(Klass* k) {
	uint idx = hash(k) % _num_buckets;
	assert(_buckets != NULL, "Allocation failure should have been caught");
	KlassInfoEntry* e = _buckets[idx].lookup(k);
	// Lookup may fail if this is a new klass for which we
	// could not allocate space for an new entry, or if it's
	// an archived class that we haven't loaded yet.
	assert(e == NULL \|\| k == e->klass(), "must be equal");
	return e;
	}

	// Return false if the entry could not be recorded on account
	// of running out of space required to create a new entry.
	bool KlassInfoTable::record_instance(const oop obj) {
	Klass* k = obj->klass();
	KlassInfoEntry* elt = lookup(k);
	// elt may be NULL if it's a new klass for which we
	// could not allocate space for a new entry in the hashtable.
	if (elt != NULL) {
	elt->set_count(elt->count() + 1);
	elt->set_words(elt->words() + obj->size());
	_size_of_instances_in_words += obj->size();
	return true;
	} else {
	return false;
	}
	}

	void KlassInfoTable::iterate(KlassInfoClosure* cic) {
	assert(_buckets != NULL, "Allocation failure should have been caught");
	for (int index = 0; index < _num_buckets; index++) {
	_buckets[index].iterate(cic);
	}
	}

	size_t KlassInfoTable::size_of_instances_in_words() const {
	return _size_of_instances_in_words;
	}

	int KlassInfoHisto::sort_helper(KlassInfoEntry e1, KlassInfoEntry e2) {
	return (e1)->compare(e1,*e2);
	}

	KlassInfoHisto::KlassInfoHisto(KlassInfoTable* cit) :
	_cit(cit) {
	_elements = new (ResourceObj::C_HEAP, mtInternal) GrowableArray<KlassInfoEntry*>(_histo_initial_size, true);
	}

	KlassInfoHisto::~KlassInfoHisto() {
	delete _elements;
	}

	void KlassInfoHisto::add(KlassInfoEntry* cie) {
	elements()->append(cie);
	}

	void KlassInfoHisto::sort() {
	elements()->sort(KlassInfoHisto::sort_helper);
	}

	void KlassInfoHisto::print_elements(outputStream* st) const {
	// simplify the formatting (ILP32 vs LP64) - store the sum in 64-bit
	int64_t total = 0;
	uint64_t totalw = 0;
	for(int i=0; i < elements()->length(); i++) {
	st->print("%4d: ", i+1);
	elements()->at(i)->print_on(st);
	total += elements()->at(i)->count();
	totalw += elements()->at(i)->words();
	}
	st->print_cr("Total " INT64_FORMAT_W(13) " " UINT64_FORMAT_W(13),
	total, totalw * HeapWordSize);
	}

	class HierarchyClosure : public KlassInfoClosure {
	private:
	GrowableArray<KlassInfoEntry> _elements;
	public:
	HierarchyClosure(GrowableArray<KlassInfoEntry> _elements) : _elements(_elements) {}

	void do_cinfo(KlassInfoEntry* cie) {
	// ignore array classes
	if (cie->klass()->is_instance_klass()) {
	_elements->append(cie);
	}
	}
	};

	void KlassHierarchy::print_class_hierarchy(outputStream* st, bool print_interfaces,
	bool print_subclasses, char* classname) {
	ResourceMark rm;
	Stack <KlassInfoEntry*, mtClass> class_stack;
	GrowableArray<KlassInfoEntry*> elements;

	// Add all classes to the KlassInfoTable, which allows for quick lookup.
	// A KlassInfoEntry will be created for each class.
	KlassInfoTable cit(true);
	if (cit.allocation_failed()) {
	st->print_cr("ERROR: Ran out of C-heap; hierarchy not generated");
	return;
	}

	// Add all created KlassInfoEntry instances to the elements array for easy
	// iteration, and to allow each KlassInfoEntry instance to have a unique index.
	HierarchyClosure hc(&elements);
	cit.iterate(&hc);

	for(int i = 0; i < elements.length(); i++) {
	KlassInfoEntry* cie = elements.at(i);
	Klass* super = cie->klass()->super();

	// Set the index for the class.
	cie->set_index(i + 1);

	// Add the class to the subclass array of its superclass.
	if (super != NULL) {
	KlassInfoEntry* super_cie = cit.lookup(super);
	assert(super_cie != NULL, "could not lookup superclass");
	super_cie->add_subclass(cie);
	}
	}

	// Set the do_print flag for each class that should be printed.
	for(int i = 0; i < elements.length(); i++) {
	KlassInfoEntry* cie = elements.at(i);
	if (classname == NULL) {
	// We are printing all classes.
	cie->set_do_print(true);
	} else {
	// We are only printing the hierarchy of a specific class.
	if (strcmp(classname, cie->klass()->external_name()) == 0) {
	KlassHierarchy::set_do_print_for_class_hierarchy(cie, &cit, print_subclasses);
	}
	}
	}

	// Now we do a depth first traversal of the class hierachry. The class_stack will
	// maintain the list of classes we still need to process. Start things off
	// by priming it with java.lang.Object.
	KlassInfoEntry* jlo_cie = cit.lookup(SystemDictionary::Object_klass());
	assert(jlo_cie != NULL, "could not lookup java.lang.Object");
	class_stack.push(jlo_cie);

	// Repeatedly pop the top item off the stack, print its class info,
	// and push all of its subclasses on to the stack. Do this until there
	// are no classes left on the stack.
	while (!class_stack.is_empty()) {
	KlassInfoEntry* curr_cie = class_stack.pop();
	if (curr_cie->do_print()) {
	print_class(st, curr_cie, print_interfaces);
	if (curr_cie->subclasses() != NULL) {
	// Current class has subclasses, so push all of them onto the stack.
	for (int i = 0; i < curr_cie->subclasses()->length(); i++) {
	KlassInfoEntry* cie = curr_cie->subclasses()->at(i);
	if (cie->do_print()) {
	class_stack.push(cie);
	}
	}
	}
	}
	}

	st->flush();
	}

	// Sets the do_print flag for every superclass and subclass of the specified class.
	void KlassHierarchy::set_do_print_for_class_hierarchy(KlassInfoEntry* cie, KlassInfoTable* cit,
	bool print_subclasses) {
	// Set do_print for all superclasses of this class.
	Klass* super = ((InstanceKlass*)cie->klass())->java_super();
	while (super != NULL) {
	KlassInfoEntry* super_cie = cit->lookup(super);
	super_cie->set_do_print(true);
	super = super->super();
	}

	// Set do_print for this class and all of its subclasses.
	Stack <KlassInfoEntry*, mtClass> class_stack;
	class_stack.push(cie);
	while (!class_stack.is_empty()) {
	KlassInfoEntry* curr_cie = class_stack.pop();
	curr_cie->set_do_print(true);
	if (print_subclasses && curr_cie->subclasses() != NULL) {
	// Current class has subclasses, so push all of them onto the stack.
	for (int i = 0; i < curr_cie->subclasses()->length(); i++) {
	KlassInfoEntry* cie = curr_cie->subclasses()->at(i);
	class_stack.push(cie);
	}
	}
	}
	}

	static void print_indent(outputStream* st, int indent) {
	while (indent != 0) {
	st->print("\|");
	indent--;
	if (indent != 0) {
	st->print(" ");
	}
	}
	}

	// Print the class name and its unique ClassLoader identifer.
	static void print_classname(outputStream* st, Klass* klass) {
	oop loader_oop = klass->class_loader_data()->class_loader();
	st->print("%s/", klass->external_name());
	if (loader_oop == NULL) {
	st->print("null");
	} else {
	st->print(INTPTR_FORMAT, p2i(klass->class_loader_data()));
	}
	}

	static void print_interface(outputStream* st, InstanceKlass* intf_klass, const char* intf_type, int indent) {
	print_indent(st, indent);
	st->print(" implements ");
	print_classname(st, intf_klass);
	st->print(" (%s intf)\n", intf_type);
	}

	void KlassHierarchy::print_class(outputStream* st, KlassInfoEntry* cie, bool print_interfaces) {
	ResourceMark rm;
	InstanceKlass* klass = (InstanceKlass*)cie->klass();
	int indent = 0;

	// Print indentation with proper indicators of superclass.
	Klass* super = klass->super();
	while (super != NULL) {
	super = super->super();
	indent++;
	}
	print_indent(st, indent);
	if (indent != 0) st->print("--");

	// Print the class name, its unique ClassLoader identifer, and if it is an interface.
	print_classname(st, klass);
	if (klass->is_interface()) {
	st->print(" (intf)");
	}
	// Special treatment for generated core reflection accessor classes: print invocation target.
	if (ReflectionAccessorImplKlassHelper::is_generated_accessor(klass)) {
	st->print(" (invokes: ");
	ReflectionAccessorImplKlassHelper::print_invocation_target(st, klass);
	st->print(")");
	}
	st->print("\n");

	// Print any interfaces the class has.
	if (print_interfaces) {
	Array<InstanceKlass> local_intfs = klass->local_interfaces();
	Array<InstanceKlass> trans_intfs = klass->transitive_interfaces();
	for (int i = 0; i < local_intfs->length(); i++) {
	print_interface(st, local_intfs->at(i), "declared", indent);
	}
	for (int i = 0; i < trans_intfs->length(); i++) {
	InstanceKlass* trans_interface = trans_intfs->at(i);
	// Only print transitive interfaces if they are not also declared.
	if (!local_intfs->contains(trans_interface)) {
	print_interface(st, trans_interface, "inherited", indent);
	}
	}
	}
	}

	void KlassInfoHisto::print_histo_on(outputStream* st) {
	st->print_cr(" num #instances #bytes class name (module)");
	st->print_cr("-------------------------------------------------------");
	print_elements(st);
	}

	class HistoClosure : public KlassInfoClosure {
	private:
	KlassInfoHisto* _cih;
	public:
	HistoClosure(KlassInfoHisto* cih) : _cih(cih) {}

	void do_cinfo(KlassInfoEntry* cie) {
	_cih->add(cie);
	}
	};

	class RecordInstanceClosure : public ObjectClosure {
	private:
	KlassInfoTable* _cit;
	size_t _missed_count;
	BoolObjectClosure* _filter;
	public:
	RecordInstanceClosure(KlassInfoTable* cit, BoolObjectClosure* filter) :
	_cit(cit), _missed_count(0), _filter(filter) {}

	void do_object(oop obj) {
	if (should_visit(obj)) {
	if (!_cit->record_instance(obj)) {
	_missed_count++;
	}
	}
	}

	size_t missed_count() { return _missed_count; }

	private:
	bool should_visit(oop obj) {
	return _filter == NULL \|\| _filter->do_object_b(obj);
	}
	};

	size_t HeapInspection::populate_table(KlassInfoTable* cit, BoolObjectClosure *filter) {
	ResourceMark rm;

	RecordInstanceClosure ric(cit, filter);
	Universe::heap()->object_iterate(&ric);
	return ric.missed_count();
	}

	void HeapInspection::heap_inspection(outputStream* st) {
	ResourceMark rm;

	KlassInfoTable cit(false);
	if (!cit.allocation_failed()) {
	// populate table with object allocation info
	size_t missed_count = populate_table(&cit);
	if (missed_count != 0) {
	log_info(gc, classhisto)("WARNING: Ran out of C-heap; undercounted " SIZE_FORMAT
	" total instances in data below",
	missed_count);
	}

	// Sort and print klass instance info
	KlassInfoHisto histo(&cit);
	HistoClosure hc(&histo);

	cit.iterate(&hc);

	histo.sort();
	histo.print_histo_on(st);
	} else {
	st->print_cr("ERROR: Ran out of C-heap; histogram not generated");
	}
	st->flush();
	}

	class FindInstanceClosure : public ObjectClosure {
	private:
	Klass* _klass;
	GrowableArray<oop>* _result;

	public:
	FindInstanceClosure(Klass* k, GrowableArray<oop>* result) : _klass(k), _result(result) {};

	void do_object(oop obj) {
	if (obj->is_a(_klass)) {
	// obj was read with AS_NO_KEEPALIVE, or equivalent.
	// The object needs to be kept alive when it is published.
	Universe::heap()->keep_alive(obj);

	_result->append(obj);
	}
	}
	};

	void HeapInspection::find_instances_at_safepoint(Klass* k, GrowableArray<oop>* result) {
	assert(SafepointSynchronize::is_at_safepoint(), "all threads are stopped");
	assert(Heap_lock->is_locked(), "should have the Heap_lock");

	// Ensure that the heap is parsable
	Universe::heap()->ensure_parsability(false); // no need to retire TALBs

	// Iterate over objects in the heap
	FindInstanceClosure fic(k, result);
	Universe::heap()->object_iterate(&fic);
	}