Mercurial > hg > graal-jvmci-8
view src/share/vm/classfile/dictionary.cpp @ 1091:6aa7255741f3
6906727: UseCompressedOops: some card-marking fixes related to object arrays
Summary: Introduced a new write_ref_array(HeapWords* start, size_t count) method that does the requisite MemRegion range calculation so (some of the) clients of the erstwhile write_ref_array(MemRegion mr) do not need to worry. This removed all external uses of array_size(), which was also simplified and made private. Asserts were added to catch other possible issues. Further, less essential, fixes stemming from this investigation are deferred to CR 6904516 (to follow shortly in hs17).
Reviewed-by: kvn, coleenp, jmasa
| author | ysr |
|---|---|
| date | Thu, 03 Dec 2009 15:01:57 -0800 |
| parents | e5b0439ef4ae |
| children | cff162798819 cd5dbf694d45 |
line wrap: on
line source
/* * Copyright 2003-2009 Sun Microsystems, Inc. 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 Sun Microsystems, Inc., 4150 Network Circle, Santa Clara, * CA 95054 USA or visit www.sun.com if you need additional information or * have any questions. * */ # include "incls/_precompiled.incl" # include "incls/_dictionary.cpp.incl" DictionaryEntry* Dictionary::_current_class_entry = NULL; int Dictionary::_current_class_index = 0; Dictionary::Dictionary(int table_size) : TwoOopHashtable(table_size, sizeof(DictionaryEntry)) { _current_class_index = 0; _current_class_entry = NULL; }; Dictionary::Dictionary(int table_size, HashtableBucket* t, int number_of_entries) : TwoOopHashtable(table_size, sizeof(DictionaryEntry), t, number_of_entries) { _current_class_index = 0; _current_class_entry = NULL; }; DictionaryEntry* Dictionary::new_entry(unsigned int hash, klassOop klass, oop loader) { DictionaryEntry* entry; entry = (DictionaryEntry*)Hashtable::new_entry(hash, klass); entry->set_loader(loader); entry->set_pd_set(NULL); return entry; } DictionaryEntry* Dictionary::new_entry() { DictionaryEntry* entry = (DictionaryEntry*)Hashtable::new_entry(0L, NULL); entry->set_loader(NULL); entry->set_pd_set(NULL); return entry; } void Dictionary::free_entry(DictionaryEntry* entry) { // avoid recursion when deleting linked list while (entry->pd_set() != NULL) { ProtectionDomainEntry* to_delete = entry->pd_set(); entry->set_pd_set(to_delete->next()); delete to_delete; } Hashtable::free_entry(entry); } bool DictionaryEntry::contains_protection_domain(oop protection_domain) const { #ifdef ASSERT if (protection_domain == instanceKlass::cast(klass())->protection_domain()) { // Ensure this doesn't show up in the pd_set (invariant) bool in_pd_set = false; for (ProtectionDomainEntry* current = _pd_set; current != NULL; current = current->next()) { if (current->protection_domain() == protection_domain) { in_pd_set = true; break; } } if (in_pd_set) { assert(false, "A klass's protection domain should not show up " "in its sys. dict. PD set"); } } #endif /* ASSERT */ if (protection_domain == instanceKlass::cast(klass())->protection_domain()) { // Succeeds trivially return true; } for (ProtectionDomainEntry* current = _pd_set; current != NULL; current = current->next()) { if (current->protection_domain() == protection_domain) return true; } return false; } void DictionaryEntry::add_protection_domain(oop protection_domain) { assert_locked_or_safepoint(SystemDictionary_lock); if (!contains_protection_domain(protection_domain)) { ProtectionDomainEntry* new_head = new ProtectionDomainEntry(protection_domain, _pd_set); // Warning: Preserve store ordering. The SystemDictionary is read // without locks. The new ProtectionDomainEntry must be // complete before other threads can be allowed to see it // via a store to _pd_set. OrderAccess::release_store_ptr(&_pd_set, new_head); } if (TraceProtectionDomainVerification && WizardMode) { print(); } } bool Dictionary::do_unloading(BoolObjectClosure* is_alive) { assert(SafepointSynchronize::is_at_safepoint(), "must be at safepoint") bool class_was_unloaded = false; int index = 0; // Defined here for portability! Do not move // Remove unloadable entries and classes from system dictionary // The placeholder array has been handled in always_strong_oops_do. DictionaryEntry* probe = NULL; for (index = 0; index < table_size(); index++) { for (DictionaryEntry** p = bucket_addr(index); *p != NULL; ) { probe = *p; klassOop e = probe->klass(); oop class_loader = probe->loader(); instanceKlass* ik = instanceKlass::cast(e); if (ik->previous_versions() != NULL) { // This klass has previous versions so see what we can cleanup // while it is safe to do so. int gc_count = 0; // leave debugging breadcrumbs int live_count = 0; // RC_TRACE macro has an embedded ResourceMark RC_TRACE(0x00000200, ("unload: %s: previous version length=%d", ik->external_name(), ik->previous_versions()->length())); for (int i = ik->previous_versions()->length() - 1; i >= 0; i--) { // check the previous versions array for GC'ed weak refs PreviousVersionNode * pv_node = ik->previous_versions()->at(i); jobject cp_ref = pv_node->prev_constant_pool(); assert(cp_ref != NULL, "cp ref was unexpectedly cleared"); if (cp_ref == NULL) { delete pv_node; ik->previous_versions()->remove_at(i); // Since we are traversing the array backwards, we don't have to // do anything special with the index. continue; // robustness } constantPoolOop pvcp = (constantPoolOop)JNIHandles::resolve(cp_ref); if (pvcp == NULL) { // this entry has been GC'ed so remove it delete pv_node; ik->previous_versions()->remove_at(i); // Since we are traversing the array backwards, we don't have to // do anything special with the index. gc_count++; continue; } else { RC_TRACE(0x00000200, ("unload: previous version @%d is alive", i)); if (is_alive->do_object_b(pvcp)) { live_count++; } else { guarantee(false, "sanity check"); } } GrowableArray<jweak>* method_refs = pv_node->prev_EMCP_methods(); if (method_refs != NULL) { RC_TRACE(0x00000200, ("unload: previous methods length=%d", method_refs->length())); for (int j = method_refs->length() - 1; j >= 0; j--) { jweak method_ref = method_refs->at(j); assert(method_ref != NULL, "weak method ref was unexpectedly cleared"); if (method_ref == NULL) { method_refs->remove_at(j); // Since we are traversing the array backwards, we don't have to // do anything special with the index. continue; // robustness } methodOop method = (methodOop)JNIHandles::resolve(method_ref); if (method == NULL) { // this method entry has been GC'ed so remove it JNIHandles::destroy_weak_global(method_ref); method_refs->remove_at(j); } else { // RC_TRACE macro has an embedded ResourceMark RC_TRACE(0x00000200, ("unload: %s(%s): prev method @%d in version @%d is alive", method->name()->as_C_string(), method->signature()->as_C_string(), j, i)); } } } } assert(ik->previous_versions()->length() == live_count, "sanity check"); RC_TRACE(0x00000200, ("unload: previous version stats: live=%d, GC'ed=%d", live_count, gc_count)); } // Non-unloadable classes were handled in always_strong_oops_do if (!is_strongly_reachable(class_loader, e)) { // Entry was not visited in phase1 (negated test from phase1) assert(class_loader != NULL, "unloading entry with null class loader"); oop k_def_class_loader = ik->class_loader(); // Do we need to delete this system dictionary entry? bool purge_entry = false; // Do we need to delete this system dictionary entry? if (!is_alive->do_object_b(class_loader)) { // If the loader is not live this entry should always be // removed (will never be looked up again). Note that this is // not the same as unloading the referred class. if (k_def_class_loader == class_loader) { // This is the defining entry, so the referred class is about // to be unloaded. // Notify the debugger and clean up the class. guarantee(!is_alive->do_object_b(e), "klass should not be live if defining loader is not"); class_was_unloaded = true; // notify the debugger if (JvmtiExport::should_post_class_unload()) { JvmtiExport::post_class_unload(ik->as_klassOop()); } // notify ClassLoadingService of class unload ClassLoadingService::notify_class_unloaded(ik); // Clean up C heap ik->release_C_heap_structures(); } // Also remove this system dictionary entry. purge_entry = true; } else { // The loader in this entry is alive. If the klass is dead, // the loader must be an initiating loader (rather than the // defining loader). Remove this entry. if (!is_alive->do_object_b(e)) { guarantee(!is_alive->do_object_b(k_def_class_loader), "defining loader should not be live if klass is not"); // If we get here, the class_loader must not be the defining // loader, it must be an initiating one. assert(k_def_class_loader != class_loader, "cannot have live defining loader and unreachable klass"); // Loader is live, but class and its defining loader are dead. // Remove the entry. The class is going away. purge_entry = true; } } if (purge_entry) { *p = probe->next(); if (probe == _current_class_entry) { _current_class_entry = NULL; } free_entry(probe); continue; } } p = probe->next_addr(); } } return class_was_unloaded; } void Dictionary::always_strong_classes_do(OopClosure* blk) { // Follow all system classes and temporary placeholders in dictionary for (int index = 0; index < table_size(); index++) { for (DictionaryEntry *probe = bucket(index); probe != NULL; probe = probe->next()) { oop e = probe->klass(); oop class_loader = probe->loader(); if (is_strongly_reachable(class_loader, e)) { blk->do_oop((oop*)probe->klass_addr()); if (class_loader != NULL) { blk->do_oop(probe->loader_addr()); } probe->protection_domain_set_oops_do(blk); } } } } // Just the classes from defining class loaders void Dictionary::classes_do(void f(klassOop)) { for (int index = 0; index < table_size(); index++) { for (DictionaryEntry* probe = bucket(index); probe != NULL; probe = probe->next()) { klassOop k = probe->klass(); if (probe->loader() == instanceKlass::cast(k)->class_loader()) { f(k); } } } } // Added for initialize_itable_for_klass to handle exceptions // Just the classes from defining class loaders void Dictionary::classes_do(void f(klassOop, TRAPS), TRAPS) { for (int index = 0; index < table_size(); index++) { for (DictionaryEntry* probe = bucket(index); probe != NULL; probe = probe->next()) { klassOop k = probe->klass(); if (probe->loader() == instanceKlass::cast(k)->class_loader()) { f(k, CHECK); } } } } // All classes, and their class loaders // (added for helpers that use HandleMarks and ResourceMarks) // Don't iterate over placeholders void Dictionary::classes_do(void f(klassOop, oop, TRAPS), TRAPS) { for (int index = 0; index < table_size(); index++) { for (DictionaryEntry* probe = bucket(index); probe != NULL; probe = probe->next()) { klassOop k = probe->klass(); f(k, probe->loader(), CHECK); } } } // All classes, and their class loaders // Don't iterate over placeholders void Dictionary::classes_do(void f(klassOop, oop)) { for (int index = 0; index < table_size(); index++) { for (DictionaryEntry* probe = bucket(index); probe != NULL; probe = probe->next()) { klassOop k = probe->klass(); f(k, probe->loader()); } } } void Dictionary::oops_do(OopClosure* f) { for (int index = 0; index < table_size(); index++) { for (DictionaryEntry* probe = bucket(index); probe != NULL; probe = probe->next()) { f->do_oop((oop*)probe->klass_addr()); if (probe->loader() != NULL) { f->do_oop(probe->loader_addr()); } probe->protection_domain_set_oops_do(f); } } } void Dictionary::methods_do(void f(methodOop)) { for (int index = 0; index < table_size(); index++) { for (DictionaryEntry* probe = bucket(index); probe != NULL; probe = probe->next()) { klassOop k = probe->klass(); if (probe->loader() == instanceKlass::cast(k)->class_loader()) { // only take klass is we have the entry with the defining class loader instanceKlass::cast(k)->methods_do(f); } } } } klassOop Dictionary::try_get_next_class() { while (true) { if (_current_class_entry != NULL) { klassOop k = _current_class_entry->klass(); _current_class_entry = _current_class_entry->next(); return k; } _current_class_index = (_current_class_index + 1) % table_size(); _current_class_entry = bucket(_current_class_index); } // never reached } // Add a loaded class to the system dictionary. // Readers of the SystemDictionary aren't always locked, so _buckets // is volatile. The store of the next field in the constructor is // also cast to volatile; we do this to ensure store order is maintained // by the compilers. void Dictionary::add_klass(symbolHandle class_name, Handle class_loader, KlassHandle obj) { assert_locked_or_safepoint(SystemDictionary_lock); assert(obj() != NULL, "adding NULL obj"); assert(Klass::cast(obj())->name() == class_name(), "sanity check on name"); unsigned int hash = compute_hash(class_name, class_loader); int index = hash_to_index(hash); DictionaryEntry* entry = new_entry(hash, obj(), class_loader()); add_entry(index, entry); } // This routine does not lock the system dictionary. // // Since readers don't hold a lock, we must make sure that system // dictionary entries are only removed at a safepoint (when only one // thread is running), and are added to in a safe way (all links must // be updated in an MT-safe manner). // // Callers should be aware that an entry could be added just after // _buckets[index] is read here, so the caller will not see the new entry. DictionaryEntry* Dictionary::get_entry(int index, unsigned int hash, symbolHandle class_name, Handle class_loader) { symbolOop name_ = class_name(); oop loader_ = class_loader(); debug_only(_lookup_count++); for (DictionaryEntry* entry = bucket(index); entry != NULL; entry = entry->next()) { if (entry->hash() == hash && entry->equals(name_, loader_)) { return entry; } debug_only(_lookup_length++); } return NULL; } klassOop Dictionary::find(int index, unsigned int hash, symbolHandle name, Handle loader, Handle protection_domain, TRAPS) { DictionaryEntry* entry = get_entry(index, hash, name, loader); if (entry != NULL && entry->is_valid_protection_domain(protection_domain)) { return entry->klass(); } else { return NULL; } } klassOop Dictionary::find_class(int index, unsigned int hash, symbolHandle name, Handle loader) { assert_locked_or_safepoint(SystemDictionary_lock); assert (index == index_for(name, loader), "incorrect index?"); DictionaryEntry* entry = get_entry(index, hash, name, loader); return (entry != NULL) ? entry->klass() : (klassOop)NULL; } // Variant of find_class for shared classes. No locking required, as // that table is static. klassOop Dictionary::find_shared_class(int index, unsigned int hash, symbolHandle name) { assert (index == index_for(name, Handle()), "incorrect index?"); DictionaryEntry* entry = get_entry(index, hash, name, Handle()); return (entry != NULL) ? entry->klass() : (klassOop)NULL; } void Dictionary::add_protection_domain(int index, unsigned int hash, instanceKlassHandle klass, Handle loader, Handle protection_domain, TRAPS) { symbolHandle klass_name(THREAD, klass->name()); DictionaryEntry* entry = get_entry(index, hash, klass_name, loader); assert(entry != NULL,"entry must be present, we just created it"); assert(protection_domain() != NULL, "real protection domain should be present"); entry->add_protection_domain(protection_domain()); assert(entry->contains_protection_domain(protection_domain()), "now protection domain should be present"); } bool Dictionary::is_valid_protection_domain(int index, unsigned int hash, symbolHandle name, Handle loader, Handle protection_domain) { DictionaryEntry* entry = get_entry(index, hash, name, loader); return entry->is_valid_protection_domain(protection_domain); } void Dictionary::reorder_dictionary() { // Copy all the dictionary entries into a single master list. DictionaryEntry* master_list = NULL; for (int i = 0; i < table_size(); ++i) { DictionaryEntry* p = bucket(i); while (p != NULL) { DictionaryEntry* tmp; tmp = p->next(); p->set_next(master_list); master_list = p; p = tmp; } set_entry(i, NULL); } // Add the dictionary entries back to the list in the correct buckets. Thread *thread = Thread::current(); while (master_list != NULL) { DictionaryEntry* p = master_list; master_list = master_list->next(); p->set_next(NULL); symbolHandle class_name (thread, instanceKlass::cast((klassOop)(p->klass()))->name()); unsigned int hash = compute_hash(class_name, Handle(thread, p->loader())); int index = hash_to_index(hash); p->set_hash(hash); p->set_next(bucket(index)); set_entry(index, p); } } SymbolPropertyTable::SymbolPropertyTable(int table_size) : Hashtable(table_size, sizeof(SymbolPropertyEntry)) { } SymbolPropertyTable::SymbolPropertyTable(int table_size, HashtableBucket* t, int number_of_entries) : Hashtable(table_size, sizeof(SymbolPropertyEntry), t, number_of_entries) { } SymbolPropertyEntry* SymbolPropertyTable::find_entry(int index, unsigned int hash, symbolHandle sym) { assert(index == index_for(sym), "incorrect index?"); for (SymbolPropertyEntry* p = bucket(index); p != NULL; p = p->next()) { if (p->hash() == hash && p->symbol() == sym()) { return p; } } return NULL; } SymbolPropertyEntry* SymbolPropertyTable::add_entry(int index, unsigned int hash, symbolHandle sym) { assert_locked_or_safepoint(SystemDictionary_lock); assert(index == index_for(sym), "incorrect index?"); assert(find_entry(index, hash, sym) == NULL, "no double entry"); SymbolPropertyEntry* p = new_entry(hash, sym()); Hashtable::add_entry(index, p); return p; } void SymbolPropertyTable::oops_do(OopClosure* f) { for (int index = 0; index < table_size(); index++) { for (SymbolPropertyEntry* p = bucket(index); p != NULL; p = p->next()) { f->do_oop((oop*) p->symbol_addr()); if (p->property_oop() != NULL) { f->do_oop(p->property_oop_addr()); } } } } void SymbolPropertyTable::methods_do(void f(methodOop)) { for (int index = 0; index < table_size(); index++) { for (SymbolPropertyEntry* p = bucket(index); p != NULL; p = p->next()) { oop prop = p->property_oop(); if (prop != NULL && prop->is_method()) { f((methodOop)prop); } } } } // ---------------------------------------------------------------------------- #ifndef PRODUCT void Dictionary::print() { ResourceMark rm; HandleMark hm; tty->print_cr("Java system dictionary (classes=%d)", number_of_entries()); tty->print_cr("^ indicates that initiating loader is different from " "defining loader"); for (int index = 0; index < table_size(); index++) { for (DictionaryEntry* probe = bucket(index); probe != NULL; probe = probe->next()) { if (Verbose) tty->print("%4d: ", index); klassOop e = probe->klass(); oop class_loader = probe->loader(); bool is_defining_class = (class_loader == instanceKlass::cast(e)->class_loader()); tty->print("%s%s", is_defining_class ? " " : "^", Klass::cast(e)->external_name()); if (class_loader != NULL) { tty->print(", loader "); class_loader->print_value(); } tty->cr(); } } } #endif void Dictionary::verify() { guarantee(number_of_entries() >= 0, "Verify of system dictionary failed"); int element_count = 0; for (int index = 0; index < table_size(); index++) { for (DictionaryEntry* probe = bucket(index); probe != NULL; probe = probe->next()) { klassOop e = probe->klass(); oop class_loader = probe->loader(); guarantee(Klass::cast(e)->oop_is_instance(), "Verify of system dictionary failed"); // class loader must be present; a null class loader is the // boostrap loader guarantee(class_loader == NULL || class_loader->is_instance(), "checking type of class_loader"); e->verify(); probe->verify_protection_domain_set(); element_count++; } } guarantee(number_of_entries() == element_count, "Verify of system dictionary failed"); debug_only(verify_lookup_length((double)number_of_entries() / table_size())); }