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Quellcode-Bibliothek© Kompilation durch diese Firma[Weder Korrektheit noch Funktionsfähigkeit der Software werden zugesichert.]Datei: JImageInfoTest.java Sprache: C |
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/*
* Copyright (c) 2012, 2022, 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 "cds/archiveBuilder.hpp" #include "cds/archiveHeapLoader.hpp" #include "cds/cds_globals.hpp" #include "cds/cdsProtectionDomain.hpp" #include "cds/classListWriter.hpp" #include "cds/classListParser.hpp" #include "cds/classPrelinker.hpp" #include "cds/cppVtables.hpp" #include "cds/dumpAllocStats.hpp" #include "cds/filemap.hpp" #include "cds/heapShared.hpp" #include "cds/lambdaFormInvokers.hpp" #include "cds/metaspaceShared.hpp" #include "classfile/classLoaderDataGraph.hpp" #include "classfile/classLoaderDataShared.hpp" #include "classfile/classLoaderExt.hpp" #include "classfile/javaClasses.inline.hpp" #include "classfile/loaderConstraints.hpp" #include "classfile/placeholders.hpp" #include "classfile/symbolTable.hpp" #include "classfile/stringTable.hpp" #include "classfile/systemDictionary.hpp" #include "classfile/systemDictionaryShared.hpp" #include "classfile/vmClasses.hpp" #include "classfile/vmSymbols.hpp" #include "code/codeCache.hpp" #include "gc/shared/gcVMOperations.hpp" #include "interpreter/bytecodeStream.hpp" #include "interpreter/bytecodes.hpp" #include "jvm_io.h" #include "logging/log.hpp" #include "logging/logMessage.hpp" #include "logging/logStream.hpp" #include "memory/metaspace.hpp" #include "memory/metaspaceClosure.hpp" #include "memory/resourceArea.hpp" #include "memory/universe.hpp" #include "oops/compressedOops.inline.hpp" #include "oops/instanceMirrorKlass.hpp" #include "oops/klass.inline.hpp" #include "oops/objArrayOop.hpp" #include "oops/oop.inline.hpp" #include "oops/oopHandle.hpp" #include "prims/jvmtiExport.hpp" #include "runtime/arguments.hpp" #include "runtime/globals_extension.hpp" #include "runtime/handles.inline.hpp" #include "runtime/os.inline.hpp" #include "runtime/safepointVerifiers.hpp" #include "runtime/sharedRuntime.hpp" #include "runtime/vmThread.hpp" #include "runtime/vmOperations.hpp" #include "services/memTracker.hpp" #include "utilities/align.hpp" #include "utilities/bitMap.inline.hpp" #include "utilities/ostream.hpp" #include "utilities/defaultStream.hpp" #include "utilities/resourceHash.hpp" #if INCLUDE_G1GC #include "gc/g1/g1CollectedHeap.inline.hpp" #endif ReservedSpace MetaspaceShared::_symbol_rs; VirtualSpace MetaspaceShared::_symbol_vs; bool MetaspaceShared::_has_error_classes; bool MetaspaceShared::_archive_loading_failed = false; bool MetaspaceShared::_remapped_readwrite = false; void* MetaspaceShared::_shared_metaspace_static_top = NULL; intx MetaspaceShared::_relocation_delta; char* MetaspaceShared::_requested_base_address; bool MetaspaceShared::_use_optimized_module_handling = true; bool MetaspaceShared::_use_full_module_graph = true; // The CDS archive is divided into the following regions: // rw - read-write metadata // ro - read-only metadata and read-only tables // // ca0 - closed archive heap space #0 // ca1 - closed archive heap space #1 (may be empty) // oa0 - open archive heap space #0 // oa1 - open archive heap space #1 (may be empty) // // bm - bitmap for relocating the above 7 regions. // // The rw and ro regions are linearly allocated, in the order of rw->ro. // These regions are aligned with MetaspaceShared::core_region_alignment(). // // These 2 regions are populated in the following steps: // [0] All classes are loaded in MetaspaceShared::preload_classes(). All metadata are // temporarily allocated outside of the shared regions. // [1] We enter a safepoint and allocate a buffer for the rw/ro regions. // [2] C++ vtables are copied into the rw region. // [3] ArchiveBuilder copies RW metadata into the rw region. // [4] ArchiveBuilder copies RO metadata into the ro region. // [5] SymbolTable, StringTable, SystemDictionary, and a few other read-only data // are copied into the ro region as read-only tables. // // The ca0/ca1 and oa0/oa1 regions are populated inside HeapShared::archive_objects. // Their layout is independent of the rw/ro regions. static DumpRegion _symbol_region("symbols"); char* MetaspaceShared::symbol_space_alloc(size_t num_bytes) { return _symbol_region.allocate(num_bytes); } // os::vm_allocation_granularity() is usually 4K for most OSes. However, some platforms // such as linux-aarch64 and macos-x64 ... // it can be either 4K or 64K and on macos-aarch64 it is 16K. To generate archives that are // compatible for both settings, an alternative cds core region alignment can be enabled // at building time: // --enable-compactible-cds-alignment // Upon successful configuration, the compactible alignment then can be defined in: // os_linux_aarch64.cpp // os_bsd_x86.cpp size_t MetaspaceShared::core_region_alignment() { return os::cds_core_region_alignment(); } static bool shared_base_valid(char* shared_base) { #ifdef _LP64 return CompressedKlassPointers::is_valid_base((address)shared_base); #else return true; #endif } class DumpClassListCLDClosure : public CLDClosure { static const int INITIAL_TABLE_SIZE = 1987; static const int MAX_TABLE_SIZE = 61333; fileStream *_stream; ResizeableResourceHashtable<InstanceKlass*, bool, AnyObj::C_HEAP, mtClassShared> _dumped_classes; void dump(InstanceKlass* ik) { bool created; _dumped_classes.put_if_absent(ik, &created); if (!created) { return; } if (_dumped_classes.maybe_grow()) { log_info(cds, hashtables)("Expanded _dumped_classes table to %d", _dumped_classes. } if (ik->java_super()) { dump(ik->java_super()); } Array<InstanceKlass*>* interfaces = ik->local_interfaces(); int len = interfaces->length(); for (int i = 0; i < len; i++) { dump(interfaces->at(i)); } ClassListWriter::write_to_stream(ik, _stream); } public: DumpClassListCLDClosure(fileStream* f) : CLDClosure(), _dumped_classes(INITIAL_TABLE_SIZE, MAX_TABLE_SIZE) { _stream = f; } void do_cld(ClassLoaderData* cld) { for (Klass* klass = cld->klasses(); klass != NULL; klass = klass->next_link()) { if (klass->is_instance_klass()) { dump(InstanceKlass::cast(klass)); } } } }; void MetaspaceShared::dump_loaded_classes(const char* file_name, TRAPS) { fileStream stream(file_name, "w"); if (stream.is_open()) { MutexLocker lock(ClassLoaderDataGraph_lock); MutexLocker lock2(ClassListFile_lock, Mutex::_no_safepoint_check_flag); DumpClassListCLDClosure collect_classes(&stream); ClassLoaderDataGraph::loaded_cld_do(&collect_classes); } else { THROW_MSG(vmSymbols::java_io_IOException(), "Failed to open file"); } } static bool shared_base_too_high(char* specified_base, char* aligned_base, size_t cds_m if (specified_base != NULL && aligned_base < specified_base) { // SharedBaseAddress is very high (e.g., 0xffffffffffffff00) so // align_up(SharedBaseAddress, MetaspaceShared::core_region_alignment()) has wrapped return true; } if (max_uintx - uintx(aligned_base) < uintx(cds_max)) { // The end of the archive will wrap around return true; } return false; } static char* compute_shared_base(size_t cds_max) { char* specified_base = (char*)SharedBaseAddress; char* aligned_base = align_up(specified_base, MetaspaceShared::core_region_alignment const char* err = NULL; if (shared_base_too_high(specified_base, aligned_base, cds_max)) { err = "too high"; } else if (!shared_base_valid(aligned_base)) { err = "invalid for this platform"; } else { return aligned_base; } log_warning(cds)("SharedBaseAddress (" INTPTR_FORMAT ") is %s. Reverted to " INTPTR p2i((void*)SharedBaseAddress), err, p2i((void*)Arguments::default_SharedBaseAddress())); specified_base = (char*)Arguments::default_SharedBaseAddress(); aligned_base = align_up(specified_base, MetaspaceShared::core_region_alignment()); // Make sure the default value of SharedBaseAddress specified in globals.hpp is sane. assert(!shared_base_too_high(specified_base, aligned_base, cds_max), "Sanity"); assert(shared_base_valid(aligned_base), "Sanity"); return aligned_base; } void MetaspaceShared::initialize_for_static_dump() { assert(DumpSharedSpaces, "should be called for dump time only"); log_info(cds)("Core region alignment: " SIZE_FORMAT, core_region_alignment()); // The max allowed size for CDS archive. We use this to limit SharedBaseAddress // to avoid address space wrap around. size_t cds_max; const size_t reserve_alignment = core_region_alignment(); #ifdef _LP64 const uint64_t UnscaledClassSpaceMax = (uint64_t(max_juint) + 1); cds_max = align_down(UnscaledClassSpaceMax, reserve_alignment); #else // We don't support archives larger than 256MB on 32-bit due to limited // virtual address space. cds_max = align_down(256*M, reserve_alignment); #endif _requested_base_address = compute_shared_base(cds_max); SharedBaseAddress = (size_t)_requested_base_address; size_t symbol_rs_size = LP64_ONLY(3 * G) NOT_LP64(128 * M); _symbol_rs = ReservedSpace(symbol_rs_size); if (!_symbol_rs.is_reserved()) { vm_exit_during_initialization("Unable to reserve memory for symbols", err_msg(SIZE_FORMAT " bytes.", symbol_rs_size)); } _symbol_region.init(&_symbol_rs, &_symbol_vs); } // Called by universe_post_init() void MetaspaceShared::post_initialize(TRAPS) { if (UseSharedSpaces) { int size = FileMapInfo::get_number_of_shared_paths(); if (size > 0) { CDSProtectionDomain::allocate_shared_data_arrays(size, CHECK); if (!DynamicDumpSharedSpaces) { FileMapInfo* info; if (FileMapInfo::dynamic_info() == NULL) { info = FileMapInfo::current_info(); } else { info = FileMapInfo::dynamic_info(); } ClassLoaderExt::init_paths_start_index(info->app_class_paths_start_index()); ClassLoaderExt::init_app_module_paths_start_index(info->app_module_paths_start_in } } } } static GrowableArrayCHeap<OopHandle, mtClassShared>* _extra_interned_strings = NULL; static GrowableArrayCHeap<Symbol*, mtClassShared>* _extra_symbols = NULL; void MetaspaceShared::read_extra_data(JavaThread* current, const char* filename) { _extra_interned_strings = new GrowableArrayCHeap<OopHandle, mtClassShared>(10000); _extra_symbols = new GrowableArrayCHeap<Symbol*, mtClassShared>(1000); HashtableTextDump reader(filename); reader.check_version("VERSION: 1.0"); while (reader.remain() > 0) { int utf8_length; int prefix_type = reader.scan_prefix(&utf8_length); ResourceMark rm(current); if (utf8_length == 0x7fffffff) { // buf_len will overflown 32-bit value. vm_exit_during_initialization(err_msg("string length too large: %d", utf8_length) } int buf_len = utf8_length+1; char* utf8_buffer = NEW_RESOURCE_ARRAY(char, buf_len); reader.get_utf8(utf8_buffer, utf8_length); utf8_buffer[utf8_length] = '\0'; if (prefix_type == HashtableTextDump::SymbolPrefix) { _extra_symbols->append(SymbolTable::new_permanent_symbol(utf8_buffer)); } else{ assert(prefix_type == HashtableTextDump::StringPrefix, "Sanity"); ExceptionMark em(current); JavaThread* THREAD = current; // For exception macros. oop str = StringTable::intern(utf8_buffer, THREAD); if (HAS_PENDING_EXCEPTION) { log_warning(cds, heap)("[line %d] extra interned string allocation failed; size t reader.last_line_no(), utf8_length); CLEAR_PENDING_EXCEPTION; } else { #if INCLUDE_G1GC if (UseG1GC) { typeArrayOop body = java_lang_String::value(str); const HeapRegion* hr = G1CollectedHeap::heap()->heap_region_containing(body); if (hr->is_humongous()) { // Don't keep it alive, so it will be GC'ed before we dump the strings, in order // to maximize free heap space and minimize fragmentation. log_warning(cds, heap)("[line %d] extra interned string ignored; size too large: reader.last_line_no(), utf8_length); continue; } } #endif // Make sure this string is included in the dumped interned string table. assert(str != NULL, "must succeed"); _extra_interned_strings->append(OopHandle(Universe::vm_global(), str)); } } } } // Read/write a data stream for restoring/preserving metadata pointers and // miscellaneous data from/to the shared archive file. void MetaspaceShared::serialize(SerializeClosure* soc) { int tag = 0; soc->do_tag(--tag); // Verify the sizes of various metadata in the system. soc->do_tag(sizeof(Method)); soc->do_tag(sizeof(ConstMethod)); soc->do_tag(arrayOopDesc::base_offset_in_bytes(T_BYTE)); soc->do_tag(sizeof(ConstantPool)); soc->do_tag(sizeof(ConstantPoolCache)); soc->do_tag(objArrayOopDesc::base_offset_in_bytes()); soc->do_tag(typeArrayOopDesc::base_offset_in_bytes(T_BYTE)); soc->do_tag(sizeof(Symbol)); // Need to do this first, as subsequent steps may call virtual functions // in archived Metadata objects. CppVtables::serialize(soc); soc->do_tag(--tag); // Dump/restore miscellaneous metadata. JavaClasses::serialize_offsets(soc); HeapShared::serialize_root(soc); Universe::serialize(soc); soc->do_tag(--tag); // Dump/restore references to commonly used names and signatures. vmSymbols::serialize(soc); soc->do_tag(--tag); // Dump/restore the symbol/string/subgraph_info tables SymbolTable::serialize_shared_table_header(soc); StringTable::serialize_shared_table_header(soc); HeapShared::serialize_tables(soc); SystemDictionaryShared::serialize_dictionary_headers(soc); InstanceMirrorKlass::serialize_offsets(soc); // Dump/restore well known classes (pointers) SystemDictionaryShared::serialize_vm_classes(soc); soc->do_tag(--tag); CDS_JAVA_HEAP_ONLY(ClassLoaderDataShared::serialize(soc);) LambdaFormInvokers::serialize(soc); soc->do_tag(666); } static void rewrite_nofast_bytecode(const methodHandle& method) { BytecodeStream bcs(method); while (!bcs.is_last_bytecode()) { Bytecodes::Code opcode = bcs.next(); switch (opcode) { case Bytecodes::_getfield: *bcs.bcp() = Bytecodes::_nofast_getfield; break; case Bytecodes::_putfield: *bcs.bcp() = Bytecodes::_nofast_putfield; break; case Bytecodes::_aload_0: *bcs.bcp() = Bytecodes::_nofast_aload_0; break; case Bytecodes::_iload: { if (!bcs.is_wide()) { *bcs.bcp() = Bytecodes::_nofast_iload; } break; } default: break; } } } // [1] Rewrite all bytecodes as needed, so that the ConstMethod* will not be modified // at run time by RewriteBytecodes/RewriteFrequentPairs // [2] Assign a fingerprint, so one doesn't need to be assigned at run-time. void MetaspaceShared::rewrite_nofast_bytecodes_and_calculate_fingerprints(Thread* for (int i = 0; i < ik->methods()->length(); i++) { methodHandle m(thread, ik->methods()->at(i)); if (ik->can_be_verified_at_dumptime() && ik->is_linked()) { rewrite_nofast_bytecode(m); } Fingerprinter fp(m); // The side effect of this call sets method's fingerprint field. fp.fingerprint(); } } class VM_PopulateDumpSharedSpace : public VM_GC_Operation { private: GrowableArray<MemRegion> *_closed_heap_regions; GrowableArray<MemRegion> *_open_heap_regions; GrowableArray<ArchiveHeapBitmapInfo> *_closed_heap_bitmaps; GrowableArray<ArchiveHeapBitmapInfo> *_open_heap_bitmaps; void dump_java_heap_objects(GrowableArray<Klass*>* klasses) NOT_CDS_JAVA_HEAP_RETURN; void dump_heap_bitmaps() NOT_CDS_JAVA_HEAP_RETURN; void dump_heap_bitmaps(GrowableArray<MemRegion>* regions, GrowableArray<ArchiveHeapBitmapInfo>* bitmaps); void dump_one_heap_bitmap(MemRegion region, GrowableArray<ArchiveHeapBitmapInfo>* bitm ResourceBitMap bitmap, bool is_oopmap); void dump_shared_symbol_table(GrowableArray<Symbol*>* symbols) { log_info(cds)("Dumping symbol table ..."); SymbolTable::write_to_archive(symbols); } char* dump_read_only_tables(); public: VM_PopulateDumpSharedSpace() : VM_GC_Operation(0 /* total collections, ignored */, GCCause::_archive_time_gc), _closed_heap_regions(NULL), _open_heap_regions(NULL), _closed_heap_bitmaps(NULL), _open_heap_bitmaps(NULL) {} bool skip_operation() const { return false; } VMOp_Type type() const { return VMOp_PopulateDumpSharedSpace; } void doit(); // outline because gdb sucks bool allow_nested_vm_operations() const { return true; } }; // class VM_PopulateDumpSharedSpace class StaticArchiveBuilder : public ArchiveBuilder { public: StaticArchiveBuilder() : ArchiveBuilder() {} virtual void iterate_roots(MetaspaceClosure* it, bool is_relocating_pointers) { FileMapInfo::metaspace_pointers_do(it, false); SystemDictionaryShared::dumptime_classes_do(it); Universe::metaspace_pointers_do(it); vmSymbols::metaspace_pointers_do(it); // The above code should find all the symbols that are referenced by the // archived classes. We just need to add the extra symbols which // may not be used by any of the archived classes -- these are usually // symbols that we anticipate to be used at run time, so we can store // them in the RO region, to be shared across multiple processes. if (_extra_symbols != NULL) { for (int i = 0; i < _extra_symbols->length(); i++) { it->push(_extra_symbols->adr_at(i)); } } } }; char* VM_PopulateDumpSharedSpace::dump_read_only_tables() { ArchiveBuilder::OtherROAllocMark mark; SystemDictionaryShared::write_to_archive(); // Write lambform lines into archive LambdaFormInvokers::dump_static_archive_invokers(); // Write the other data to the output array. DumpRegion* ro_region = ArchiveBuilder::current()->ro_region(); char* start = ro_region->top(); WriteClosure wc(ro_region); MetaspaceShared::serialize(&wc); // Write the bitmaps for patching the archive heap regions dump_heap_bitmaps(); return start; } void VM_PopulateDumpSharedSpace::doit() { HeapShared::run_full_gc_in_vm_thread(); DEBUG_ONLY(SystemDictionaryShared::NoClassLoadingMark nclm); FileMapInfo::check_nonempty_dir_in_shared_path_table(); NOT_PRODUCT(SystemDictionary::verify();) // Block concurrent class unloading from changing the _dumptime_table MutexLocker ml(DumpTimeTable_lock, Mutex::_no_safepoint_check_flag); SystemDictionaryShared::check_excluded_classes(); StaticArchiveBuilder builder; builder.gather_source_objs(); builder.reserve_buffer(); char* cloned_vtables = CppVtables::dumptime_init(&builder); builder.dump_rw_metadata(); builder.dump_ro_metadata(); builder.relocate_metaspaceobj_embedded_pointers(); // Dump supported java heap objects dump_java_heap_objects(builder.klasses()); builder.relocate_roots(); dump_shared_symbol_table(builder.symbols()); builder.relocate_vm_classes(); log_info(cds)("Make classes shareable"); builder.make_klasses_shareable(); char* serialized_data = dump_read_only_tables(); SystemDictionaryShared::adjust_lambda_proxy_class_dictionary(); // The vtable clones contain addresses of the current process. // We don't want to write these addresses into the archive. CppVtables::zero_archived_vtables(); // relocate the data so that it can be mapped to MetaspaceShared::requested_base_address() // without runtime relocation. builder.relocate_to_requested(); // Write the archive file const char* static_archive = Arguments::GetSharedArchivePath(); assert(static_archive != nullptr, "SharedArchiveFile not set?"); FileMapInfo* mapinfo = new FileMapInfo(static_archive, true); mapinfo->populate_header(MetaspaceShared::core_region_alignment()); mapinfo->set_serialized_data(serialized_data); mapinfo->set_cloned_vtables(cloned_vtables); mapinfo->open_for_write(); builder.write_archive(mapinfo, _closed_heap_regions, _open_heap_regions, _closed_heap_bitmaps, _open_heap_bitmaps); if (PrintSystemDictionaryAtExit) { SystemDictionary::print(); } if (AllowArchivingWithJavaAgent) { warning("This archive was created with AllowArchivingWithJavaAgent. It should be "for testing purposes only and should not be used in a production environment"); } // There may be pending VM operations. We have changed some global states // (such as vmClasses::_klasses) that may cause these VM operations // to fail. For safety, forget these operations and exit the VM directly. os::_exit(0); } class CollectCLDClosure : public CLDClosure { GrowableArray<ClassLoaderData*> _loaded_cld; GrowableArray<OopHandle> _loaded_cld_handles; // keep the CLDs alive Thread* _current_thread; public: CollectCLDClosure(Thread* thread) : _current_thread(thread) {} ~CollectCLDClosure() { for (int i = 0; i < _loaded_cld_handles.length(); i++) { _loaded_cld_handles.at(i).release(Universe::vm_global()); } } void do_cld(ClassLoaderData* cld) { assert(cld->is_alive(), "must be"); _loaded_cld.append(cld); _loaded_cld_handles.append(OopHandle(Universe::vm_global(), cld->holder())); } int nof_cld() const { return _loaded_cld.length(); } ClassLoaderData* cld_at(int index) { return _loaded_cld.at(index); } }; // Check if we can eagerly link this class at dump time, so we can avoid the // runtime linking overhead (especially verification) bool MetaspaceShared::may_be_eagerly_linked(InstanceKlass* ik) { if (!ik->can_be_verified_at_dumptime()) { // For old classes, try to leave them in the unlinked state, so // we can still store them in the archive. They must be // linked/verified at runtime. return false; } if (DynamicDumpSharedSpaces && ik->is_shared_unregistered_class()) { // Linking of unregistered classes at this stage may cause more // classes to be resolved, resulting in calls to ClassLoader.loadClass() // that may not be expected by custom class loaders. // // It's OK to do this for the built-in loaders as we know they can // tolerate this. (Note that unregistered classes are loaded by the NULL // loader during DumpSharedSpaces). return false; } return true; } bool MetaspaceShared::link_class_for_cds(InstanceKlass* ik, TRAPS) { // Link the class to cause the bytecodes to be rewritten and the // cpcache to be created. Class verification is done according // to -Xverify setting. bool res = MetaspaceShared::try_link_class(THREAD, ik); ClassPrelinker::dumptime_resolve_constants(ik, CHECK_(false)); return res; } void MetaspaceShared::link_shared_classes(bool jcmd_request, TRAPS) { ClassPrelinker::initialize(); if (!jcmd_request) { LambdaFormInvokers::regenerate_holder_classes(CHECK); } // Collect all loaded ClassLoaderData. CollectCLDClosure collect_cld(THREAD); { // ClassLoaderDataGraph::loaded_cld_do requires ClassLoaderDataGraph_lock. // We cannot link the classes while holding this lock (or else we may run into deadlock). // Therefore, we need to first collect all the CLDs, and then link their classes after // releasing the lock. MutexLocker lock(ClassLoaderDataGraph_lock); ClassLoaderDataGraph::loaded_cld_do(&collect_cld); } while (true) { bool has_linked = false; for (int i = 0; i < collect_cld.nof_cld(); i++) { ClassLoaderData* cld = collect_cld.cld_at(i); for (Klass* klass = cld->klasses(); klass != NULL; klass = klass->next_link()) { if (klass->is_instance_klass()) { InstanceKlass* ik = InstanceKlass::cast(klass); if (may_be_eagerly_linked(ik)) { has_linked |= link_class_for_cds(ik, CHECK); } } } } if (!has_linked) { break; } // Class linking includes verification which may load more classes. // Keep scanning until we have linked no more classes. } } void MetaspaceShared::prepare_for_dumping() { Arguments::assert_is_dumping_archive(); Arguments::check_unsupported_dumping_properties(); ClassLoader::initialize_shared_path(JavaThread::current()); } // Preload classes from a list, populate the shared spaces and dump to a // file. void MetaspaceShared::preload_and_dump() { EXCEPTION_MARK; ResourceMark rm(THREAD); preload_and_dump_impl(THREAD); if (HAS_PENDING_EXCEPTION) { if (PENDING_EXCEPTION->is_a(vmClasses::OutOfMemoryError_klass())) { vm_direct_exit(-1, err_msg("Out of memory. Please run with a larger Java heap, cu SIZE_FORMAT "M", MaxHeapSize/M)); } else { log_error(cds)("%s: %s", PENDING_EXCEPTION->klass()->external_name(), java_lang_String::as_utf8_string(java_lang_Throwable::message(PENDING_EXCEPTION) vm_direct_exit(-1, "VM exits due to exception, use -Xlog:cds,exceptions=trace for } } else { // On success, the VM_PopulateDumpSharedSpace op should have // exited the VM. ShouldNotReachHere(); } } #if INCLUDE_CDS_JAVA_HEAP && defined(_LP64) void MetaspaceShared::adjust_heap_sizes_for_dumping() { if (!DumpSharedSpaces || UseCompressedOops) { return; } // CDS heap dumping requires all string oops to have an offset // from the heap bottom that can be encoded in 32-bit. julong max_heap_size = (julong)(4 * G); if (MinHeapSize > max_heap_size) { log_debug(cds)("Setting MinHeapSize to 4G for CDS dumping, original size = " SIZE FLAG_SET_ERGO(MinHeapSize, max_heap_size); } if (InitialHeapSize > max_heap_size) { log_debug(cds)("Setting InitialHeapSize to 4G for CDS dumping, original size = " FLAG_SET_ERGO(InitialHeapSize, max_heap_size); } if (MaxHeapSize > max_heap_size) { log_debug(cds)("Setting MaxHeapSize to 4G for CDS dumping, original size = " SIZE FLAG_SET_ERGO(MaxHeapSize, max_heap_size); } } #endif // INCLUDE_CDS_JAVA_HEAP && _LP64 void MetaspaceShared::get_default_classlist(char* default_classlist, const size_t buf // Construct the path to the class list (in jre/lib) // Walk up two directories from the location of the VM and // optionally tack on "lib" (depending on platform) os::jvm_path(default_classlist, (jint)(buf_size)); for (int i = 0; i < 3; i++) { char *end = strrchr(default_classlist, *os::file_separator()); if (end != NULL) *end = '\0'; } size_t classlist_path_len = strlen(default_classlist); if (classlist_path_len >= 3) { if (strcmp(default_classlist + classlist_path_len - 3, "lib") != 0) { if (classlist_path_len < buf_size - 4) { jio_snprintf(default_classlist + classlist_path_len, buf_size - classlist_path_len, "%slib", os::file_separator()); classlist_path_len += 4; } } } if (classlist_path_len < buf_size - 10) { jio_snprintf(default_classlist + classlist_path_len, buf_size - classlist_path_len, "%sclasslist", os::file_separator()); } } void MetaspaceShared::preload_classes(TRAPS) { char default_classlist[JVM_MAXPATHLEN]; const char* classlist_path; get_default_classlist(default_classlist, sizeof(default_classlist)); if (SharedClassListFile == NULL) { classlist_path = default_classlist; } else { classlist_path = SharedClassListFile; } log_info(cds)("Loading classes to share ..."); _has_error_classes = false; int class_count = ClassListParser::parse_classlist(classlist_path, ClassListParser::_parse_all, CHECK); if (ExtraSharedClassListFile) { class_count += ClassListParser::parse_classlist(ExtraSharedClassListFile, ClassListParser::_parse_all, CHECK); } if (classlist_path != default_classlist) { struct stat statbuf; if (os::stat(default_classlist, &statbuf) == 0) { // File exists, let's use it. class_count += ClassListParser::parse_classlist(default_classlist, ClassListParser::_parse_lambda_forms_invokers_only, CHECK); } } // Exercise the manifest processing code to ensure classes used by CDS at runtime // are always archived const char* dummy = "Manifest-Version: 1.0\n"; CDSProtectionDomain::create_jar_manifest(dummy, strlen(dummy), CHECK); log_info(cds)("Loading classes to share: done."); log_info(cds)("Shared spaces: preloaded %d classes", class_count); } void MetaspaceShared::preload_and_dump_impl(TRAPS) { preload_classes(CHECK); if (SharedArchiveConfigFile) { log_info(cds)("Reading extra data from %s ...", SharedArchiveConfigFile); read_extra_data(THREAD, SharedArchiveConfigFile); log_info(cds)("Reading extra data: done."); } HeapShared::init_for_dumping(CHECK); // Rewrite and link classes log_info(cds)("Rewriting and linking classes ..."); // Link any classes which got missed. This would happen if we have loaded classes that // were not explicitly specified in the classlist. E.g., if an interface implemented by class K // fails verification, all other interfaces that were not specified in the classlist but // are implemented by K are not verified. link_shared_classes(false/*not from jcmd*/, CHECK); log_info(cds)("Rewriting and linking classes: done"); #if INCLUDE_CDS_JAVA_HEAP if (use_full_module_graph()) { HeapShared::reset_archived_object_states(CHECK); } #endif VM_PopulateDumpSharedSpace op; VMThread::execute(&op); } // Returns true if the class's status has changed. bool MetaspaceShared::try_link_class(JavaThread* current, InstanceKlass* ik) { ExceptionMark em(current); JavaThread* THREAD = current; // For exception macros. Arguments::assert_is_dumping_archive(); if (ik->is_loaded() && !ik->is_linked() && ik->can_be_verified_at_dumptime() && !SystemDictionaryShared::has_class_failed_verification(ik)) { bool saved = BytecodeVerificationLocal; if (ik->is_shared_unregistered_class() && ik->class_loader() == NULL) { // The verification decision is based on BytecodeVerificationRemote // for non-system classes. Since we are using the NULL classloader // to load non-system classes for customized class loaders during dumping, // we need to temporarily change BytecodeVerificationLocal to be the same as // BytecodeVerificationRemote. Note this can cause the parent system // classes also being verified. The extra overhead is acceptable during // dumping. BytecodeVerificationLocal = BytecodeVerificationRemote; } ik->link_class(THREAD); if (HAS_PENDING_EXCEPTION) { ResourceMark rm(THREAD); log_warning(cds)("Preload Warning: Verification failed for %s", ik->external_name()); CLEAR_PENDING_EXCEPTION; SystemDictionaryShared::set_class_has_failed_verification(ik); _has_error_classes = true; } BytecodeVerificationLocal = saved; return true; } else { return false; } } #if INCLUDE_CDS_JAVA_HEAP void VM_PopulateDumpSharedSpace::dump_java_heap_objects(GrowableArray<Klass*>* klass if(!HeapShared::can_write()) { log_info(cds)( "Archived java heap is not supported as UseG1GC " "and UseCompressedClassPointers are required." "Current settings: UseG1GC=%s, UseCompressedClassPointers=%s.", BOOL_TO_STR(UseG1GC), BOOL_TO_STR(UseCompressedClassPointers)); return; } // Find all the interned strings that should be dumped. int i; for (i = 0; i < klasses->length(); i++) { Klass* k = klasses->at(i); if (k->is_instance_klass()) { InstanceKlass* ik = InstanceKlass::cast(k); if (ik->is_linked()) { ik->constants()->add_dumped_interned_strings(); } } } if (_extra_interned_strings != NULL) { for (i = 0; i < _extra_interned_strings->length(); i ++) { OopHandle string = _extra_interned_strings->at(i); HeapShared::add_to_dumped_interned_strings(string.resolve()); } } // The closed and open archive heap space has maximum two regions. // See FileMapInfo::write_heap_regions() for details. _closed_heap_regions = new GrowableArray<MemRegion>(2); _open_heap_regions = new GrowableArray<MemRegion>(2); HeapShared::archive_objects(_closed_heap_regions, _open_heap_regions); ArchiveBuilder::OtherROAllocMark mark; HeapShared::write_subgraph_info_table(); } void VM_PopulateDumpSharedSpace::dump_heap_bitmaps() { if (HeapShared::can_write()) { _closed_heap_bitmaps = new GrowableArray<ArchiveHeapBitmapInfo>(2); dump_heap_bitmaps(_closed_heap_regions, _closed_heap_bitmaps); _open_heap_bitmaps = new GrowableArray<ArchiveHeapBitmapInfo>(2); dump_heap_bitmaps(_open_heap_regions, _open_heap_bitmaps); } } void VM_PopulateDumpSharedSpace::dump_heap_bitmaps(GrowableArray<MemRegion>* regions GrowableArray<ArchiveHeapBitmapInfo>* bitmaps) { for (int i = 0; i < regions->length(); i++) { MemRegion region = regions->at(i); ResourceBitMap oopmap = HeapShared::calculate_oopmap(region); ResourceBitMap ptrmap = HeapShared::calculate_ptrmap(region); dump_one_heap_bitmap(region, bitmaps, oopmap, true); dump_one_heap_bitmap(region, bitmaps, ptrmap, false); } } void VM_PopulateDumpSharedSpace::dump_one_heap_bitmap(MemRegion region, GrowableArray<ArchiveHeapBitmapInfo>* bitmaps, ResourceBitMap bitmap, bool is_oopmap) { size_t size_in_bits = bitmap.size(); size_t size_in_bytes; uintptr_t* buffer; if (size_in_bits > 0) { size_in_bytes = bitmap.size_in_bytes(); buffer = (uintptr_t*)NEW_C_HEAP_ARRAY(char, size_in_bytes, mtInternal); bitmap.write_to(buffer, size_in_bytes); } else { size_in_bytes = 0; buffer = NULL; } log_info(cds, heap)("%s = " INTPTR_FORMAT " (" SIZE_FORMAT_W(6) " bytes) for heap reg INTPTR_FORMAT " (" SIZE_FORMAT_W(8) " bytes)", is_oopmap ? "Oopmap" : "Ptrmap", p2i(buffer), size_in_bytes, p2i(region.start()), region.byte_size()); ArchiveHeapBitmapInfo info; info._map = (address)buffer; info._size_in_bits = size_in_bits; info._size_in_bytes = size_in_bytes; bitmaps->append(info); } #endif // INCLUDE_CDS_JAVA_HEAP void MetaspaceShared::set_shared_metaspace_range(void* base, void *static_top, void* t assert(base <= static_top && static_top <= top, "must be"); _shared_metaspace_static_top = static_top; MetaspaceObj::set_shared_metaspace_range(base, top); } bool MetaspaceShared::is_shared_dynamic(void* p) { if ((p < MetaspaceObj::shared_metaspace_top()) && (p >= _shared_metaspace_static_top)) { return true; } else { return false; } } void MetaspaceShared::initialize_runtime_shared_and_meta_spaces() { assert(UseSharedSpaces, "Must be called when UseSharedSpaces is enabled"); MapArchiveResult result = MAP_ARCHIVE_OTHER_FAILURE; FileMapInfo* static_mapinfo = open_static_archive(); FileMapInfo* dynamic_mapinfo = NULL; if (static_mapinfo != NULL) { log_info(cds)("Core region alignment: " SIZE_FORMAT, static_mapinfo->core_region_al dynamic_mapinfo = open_dynamic_archive(); // First try to map at the requested address result = map_archives(static_mapinfo, dynamic_mapinfo, true); if (result == MAP_ARCHIVE_MMAP_FAILURE) { // Mapping has failed (probably due to ASLR). Let's map at an address chosen // by the OS. log_info(cds)("Try to map archive(s) at an alternative address"); result = map_archives(static_mapinfo, dynamic_mapinfo, false); } } if (result == MAP_ARCHIVE_SUCCESS) { bool dynamic_mapped = (dynamic_mapinfo != NULL && dynamic_mapinfo->is_mapped()); char* cds_base = static_mapinfo->mapped_base(); char* cds_end = dynamic_mapped ? dynamic_mapinfo->mapped_end() : static_mapinfo->mapped_e set_shared_metaspace_range(cds_base, static_mapinfo->mapped_end(), cds_end); _relocation_delta = static_mapinfo->relocation_delta(); _requested_base_address = static_mapinfo->requested_base_address(); if (dynamic_mapped) { FileMapInfo::set_shared_path_table(dynamic_mapinfo); // turn AutoCreateSharedArchive off if successfully mapped AutoCreateSharedArchive = false; } else { FileMapInfo::set_shared_path_table(static_mapinfo); } } else { set_shared_metaspace_range(NULL, NULL, NULL); if (DynamicDumpSharedSpaces) { warning("-XX:ArchiveClassesAtExit is unsupported when base CDS archive is not lo } UseSharedSpaces = false; // The base archive cannot be mapped. We cannot dump the dynamic shared archive. AutoCreateSharedArchive = false; DynamicDumpSharedSpaces = false; FileMapInfo::fail_continue("Unable to map shared spaces"); if (PrintSharedArchiveAndExit) { vm_exit_during_initialization("Unable to use shared archive."); } } if (static_mapinfo != NULL && !static_mapinfo->is_mapped()) { delete static_mapinfo; } if (dynamic_mapinfo != NULL && !dynamic_mapinfo->is_mapped()) { delete dynamic_mapinfo; } } FileMapInfo* MetaspaceShared::open_static_archive() { const char* static_archive = Arguments::GetSharedArchivePath(); assert(static_archive != nullptr, "SharedArchivePath is NULL"); FileMapInfo* mapinfo = new FileMapInfo(static_archive, true); if (!mapinfo->initialize()) { delete(mapinfo); return NULL; } return mapinfo; } FileMapInfo* MetaspaceShared::open_dynamic_archive() { if (DynamicDumpSharedSpaces) { return NULL; } const char* dynamic_archive = Arguments::GetSharedDynamicArchivePath(); if (dynamic_archive == nullptr) { return NULL; } FileMapInfo* mapinfo = new FileMapInfo(dynamic_archive, false); if (!mapinfo->initialize()) { delete(mapinfo); return NULL; } return mapinfo; } // use_requested_addr: // true = map at FileMapHeader::_requested_base_address // false = map at an alternative address picked by OS. MapArchiveResult MetaspaceShared::map_archives(FileMapInfo* static_mapinfo, FileMap bool use_requested_addr) { if (use_requested_addr && static_mapinfo->requested_base_address() == NULL) { log_info(cds)("Archive(s) were created with -XX:SharedBaseAddress=0. Always map return MAP_ARCHIVE_MMAP_FAILURE; } PRODUCT_ONLY(if (ArchiveRelocationMode == 1 && use_requested_addr) { // For product build only -- this is for benchmarking the cost of doing relocation. // For debug builds, the check is done below, after reserving the space, for better test coverag // (see comment below). log_info(cds)("ArchiveRelocationMode == 1: always map archive(s) at an alternati return MAP_ARCHIVE_MMAP_FAILURE; }); if (ArchiveRelocationMode == 2 && !use_requested_addr) { log_info(cds)("ArchiveRelocationMode == 2: never map archive(s) at an alternativ return MAP_ARCHIVE_MMAP_FAILURE; }; if (dynamic_mapinfo != NULL) { // Ensure that the OS won't be able to allocate new memory spaces between the two // archives, or else it would mess up the simple comparison in MetaspaceObj::is_shared(). assert(static_mapinfo->mapping_end_offset() == dynamic_mapinfo->mapping_base_offset( } ReservedSpace total_space_rs, archive_space_rs, class_space_rs; MapArchiveResult result = MAP_ARCHIVE_OTHER_FAILURE; char* mapped_base_address = reserve_address_space_for_archives(static_mapinfo, dynamic_mapinfo, use_requested_addr, total_space_rs, archive_space_rs, class_space_rs); if (mapped_base_address == NULL) { result = MAP_ARCHIVE_MMAP_FAILURE; log_debug(cds)("Failed to reserve spaces (use_requested_addr=%u)", (unsigned)use_ } else { #ifdef ASSERT // Some sanity checks after reserving address spaces for archives // and class space. assert(archive_space_rs.is_reserved(), "Sanity"); if (Metaspace::using_class_space()) { // Class space must closely follow the archive space. Both spaces // must be aligned correctly. assert(class_space_rs.is_reserved(), "A class space should have been reserved"); assert(class_space_rs.base() >= archive_space_rs.end(), "class space should follow the cds archive space"); assert(is_aligned(archive_space_rs.base(), core_region_alignment()), "Archive space misaligned"); assert(is_aligned(class_space_rs.base(), Metaspace::reserve_alignment()), "class space misaligned"); } #endif // ASSERT log_info(cds)("Reserved archive_space_rs [" INTPTR_FORMAT " - " INTPTR_FORMAT "] (" S p2i(archive_space_rs.base()), p2i(archive_space_rs.end()), archive_space_rs.size() log_info(cds)("Reserved class_space_rs [" INTPTR_FORMAT " - " INTPTR_FORMAT "] (" S p2i(class_space_rs.base()), p2i(class_space_rs.end()), class_space_rs.size()); if (MetaspaceShared::use_windows_memory_mapping()) { // We have now reserved address space for the archives, and will map in // the archive files into this space. // // Special handling for Windows: on Windows we cannot map a file view // into an existing memory mapping. So, we unmap the address range we // just reserved again, which will make it available for mapping the // archives. // Reserving this range has not been for naught however since it makes // us reasonably sure the address range is available. // // But still it may fail, since between unmapping the range and mapping // in the archive someone else may grab the address space. Therefore // there is a fallback in FileMap::map_region() where we just read in // the archive files sequentially instead of mapping it in. We couple // this with use_requested_addr, since we're going to patch all the // pointers anyway so there's no benefit to mmap. if (use_requested_addr) { assert(!total_space_rs.is_reserved(), "Should not be reserved for Windows"); log_info(cds)("Windows mmap workaround: releasing archive space."); archive_space_rs.release(); } } MapArchiveResult static_result = map_archive(static_mapinfo, mapped_base_address, arc MapArchiveResult dynamic_result = (static_result == MAP_ARCHIVE_SUCCESS) ? map_archive(dynamic_mapinfo, mapped_base_address, archive_space_rs) : MAP_ARCHIVE_OT DEBUG_ONLY(if (ArchiveRelocationMode == 1 && use_requested_addr) { // This is for simulating mmap failures at the requested address. In // debug builds, we do it here (after all archives have possibly been // mapped), so we can thoroughly test the code for failure handling // (releasing all allocated resource, etc). log_info(cds)("ArchiveRelocationMode == 1: always map archive(s) at an alternati if (static_result == MAP_ARCHIVE_SUCCESS) { static_result = MAP_ARCHIVE_MMAP_FAILURE; } if (dynamic_result == MAP_ARCHIVE_SUCCESS) { dynamic_result = MAP_ARCHIVE_MMAP_FAILURE; } }); if (static_result == MAP_ARCHIVE_SUCCESS) { if (dynamic_result == MAP_ARCHIVE_SUCCESS) { result = MAP_ARCHIVE_SUCCESS; } else if (dynamic_result == MAP_ARCHIVE_OTHER_FAILURE) { assert(dynamic_mapinfo != NULL && !dynamic_mapinfo->is_mapped(), "must have failed"); // No need to retry mapping the dynamic archive again, as it will never succeed // (bad file, etc) -- just keep the base archive. log_warning(cds, dynamic)("Unable to use shared archive. The top archive failed t dynamic_mapinfo->full_path()); result = MAP_ARCHIVE_SUCCESS; // TODO, we can give the unused space for the dynamic archive to class_space_rs, but there's no // easy API to do that right now. } else { result = MAP_ARCHIVE_MMAP_FAILURE; } } else if (static_result == MAP_ARCHIVE_OTHER_FAILURE) { result = MAP_ARCHIVE_OTHER_FAILURE; } else { result = MAP_ARCHIVE_MMAP_FAILURE; } } if (result == MAP_ARCHIVE_SUCCESS) { SharedBaseAddress = (size_t)mapped_base_address; LP64_ONLY({ if (Metaspace::using_class_space()) { // Set up ccs in metaspace. Metaspace::initialize_class_space(class_space_rs); // Set up compressed Klass pointer encoding: the encoding range must // cover both archive and class space. address cds_base = (address)static_mapinfo->mapped_base(); address ccs_end = (address)class_space_rs.end(); assert(ccs_end > cds_base, "Sanity check"); CompressedKlassPointers::initialize(cds_base, ccs_end - cds_base); // map_heap_regions() compares the current narrow oop and klass encodings // with the archived ones, so it must be done after all encodings are determined. static_mapinfo->map_or_load_heap_regions(); } }); log_info(cds)("optimized module handling: %s", MetaspaceShared::use_optimized_mod log_info(cds)("full module graph: %s", MetaspaceShared::use_full_module_graph() ? " } else { unmap_archive(static_mapinfo); unmap_archive(dynamic_mapinfo); release_reserved_spaces(total_space_rs, archive_space_rs, class_space_rs); } return result; } // This will reserve two address spaces suitable to house Klass structures, one // for the cds archives (static archive and optionally dynamic archive) and // optionally one move for ccs. // // Since both spaces must fall within the compressed class pointer encoding // range, they are allocated close to each other. // // Space for archives will be reserved first, followed by a potential gap, // followed by the space for ccs: // // +-- Base address A B End // | | | | // v v v v // +-------------+--------------+ +----------------------+ // | static arc | [dyn. arch] | [gap] | compr. class space | // +-------------+--------------+ +----------------------+ // // (The gap may result from different alignment requirements between metaspace // and CDS) // // If UseCompressedClassPointers is disabled, only one address space will be // reserved: // // +-- Base address End // | | // v v // +-------------+--------------+ // | static arc | [dyn. arch] | // +-------------+--------------+ // // Base address: If use_archive_base_addr address is true, the Base address is // determined by the address stored in the static archive. If // use_archive_base_addr address is false, this base address is determined // by the platform. // // If UseCompressedClassPointers=1, the range encompassing both spaces will be // suitable to en/decode narrow Klass pointers: the base will be valid for // encoding, the range [Base, End) not surpass KlassEncodingMetaspaceMax. // // Return: // // - On success: // - total_space_rs will be reserved as whole for archive_space_rs and // class_space_rs if UseCompressedClassPointers is true. // On Windows, try reserve archive_space_rs and class_space_rs // separately first if use_archive_base_addr is true. // - archive_space_rs will be reserved and large enough to host static and // if needed dynamic archive: [Base, A). // archive_space_rs.base and size will be aligned to CDS reserve // granularity. // - class_space_rs: If UseCompressedClassPointers=1, class_space_rs will // be reserved. Its start address will be aligned to metaspace reserve // alignment, which may differ from CDS alignment. It will follow the cds // archive space, close enough such that narrow class pointer encoding // covers both spaces. // If UseCompressedClassPointers=0, class_space_rs remains unreserved. // - On error: NULL is returned and the spaces remain unreserved. char* MetaspaceShared::reserve_address_space_for_archives(FileMapInfo* static_mapi FileMapInfo* dynamic_mapinfo, bool use_archive_base_addr, ReservedSpace& total_space_rs, ReservedSpace& archive_space_rs, ReservedSpace& class_space_rs) { address const base_address = (address) (use_archive_base_addr ? static_mapinfo->requeste const size_t archive_space_alignment = core_region_alignment(); // Size and requested location of the archive_space_rs (for both static and dynamic archives) assert(static_mapinfo->mapping_base_offset() == 0, "Must be"); size_t archive_end_offset = (dynamic_mapinfo == NULL) ? static_mapinfo->mapping_end_offs size_t archive_space_size = align_up(archive_end_offset, archive_space_alignment); // If a base address is given, it must have valid alignment and be suitable as encoding base. if (base_address != NULL) { assert(is_aligned(base_address, archive_space_alignment), "Archive base address invalid: " PTR_FORMAT ".", p2i(base_address)); if (Metaspace::using_class_space()) { assert(CompressedKlassPointers::is_valid_base(base_address), "Archive base address invalid: " PTR_FORMAT ".", p2i(base_address)); } } if (!Metaspace::using_class_space()) { // Get the simple case out of the way first: // no compressed class space, simple allocation. archive_space_rs = ReservedSpace(archive_space_size, archive_space_alignment, os::vm_page_size(), (char*)base_address); if (archive_space_rs.is_reserved()) { assert(base_address == NULL || (address)archive_space_rs.base() == base_address, "Sanity"); // Register archive space with NMT. MemTracker::record_virtual_memory_type(archive_space_rs.base(), mtClassShared); return archive_space_rs.base(); } return NULL; } #ifdef _LP64 // Complex case: two spaces adjacent to each other, both to be addressable // with narrow class pointers. // We reserve the whole range spanning both spaces, then split that range up. const size_t class_space_alignment = Metaspace::reserve_alignment(); // To simplify matters, lets assume that metaspace alignment will always be // equal or a multiple of archive alignment. assert(is_power_of_2(class_space_alignment) && is_power_of_2(archive_space_alignment) && class_space_alignment >= archive_space_alignment, "Sanity"); const size_t class_space_size = CompressedClassSpaceSize; assert(CompressedClassSpaceSize > 0 && is_aligned(CompressedClassSpaceSize, class_space_alignment), "CompressedClassSpaceSize malformed: " SIZE_FORMAT, CompressedClassSpaceSize); const size_t ccs_begin_offset = align_up(base_address + archive_space_size, class_space_alignment) - base_address; const size_t gap_size = ccs_begin_offset - archive_space_size; const size_t total_range_size = align_up(archive_space_size + gap_size + class_space_size, core_region_alignment()); assert(total_range_size > ccs_begin_offset, "must be"); if (use_windows_memory_mapping() && use_archive_base_addr) { if (base_address != nullptr) { // On Windows, we cannot safely split a reserved memory space into two (see JDK-8255917). // Hence, we optimistically reserve archive space and class space side-by-side. We only // do this for use_archive_base_addr=true since for use_archive_base_addr=false case // caller will not split the combined space for mapping, instead read the archive data // via sequential file IO. address ccs_base = base_address + archive_space_size + gap_size; archive_space_rs = ReservedSpace(archive_space_size, archive_space_alignment, os::vm_page_size(), (char*)base_address); class_space_rs = ReservedSpace(class_space_size, class_space_alignment, os::vm_page_size(), (char*)ccs_base); } if (!archive_space_rs.is_reserved() || !class_space_rs.is_reserved()) { release_reserved_spaces(total_space_rs, archive_space_rs, class_space_rs); return NULL; } } else { if (use_archive_base_addr && base_address != nullptr) { total_space_rs = ReservedSpace(total_range_size, archive_space_alignment, os::vm_page_size(), (char*) base_address); } else { // Reserve at any address, but leave it up to the platform to choose a good one. total_space_rs = Metaspace::reserve_address_space_for_compressed_classes(total_ran } if (!total_space_rs.is_reserved()) { return NULL; } // Paranoid checks: assert(base_address == NULL || (address)total_space_rs.base() == base_address, "Sanity (" PTR_FORMAT " vs " PTR_FORMAT ")", p2i(base_address), p2i(total_space_rs.bas assert(is_aligned(total_space_rs.base(), archive_space_alignment), "Sanity"); assert(total_space_rs.size() == total_range_size, "Sanity"); assert(CompressedKlassPointers::is_valid_base((address)total_space_rs.base()), "S // Now split up the space into ccs and cds archive. For simplicity, just leave // the gap reserved at the end of the archive space. Do not do real splitting. archive_space_rs = total_space_rs.first_part(ccs_begin_offset, (size_t)archive_space_alignment); class_space_rs = total_space_rs.last_part(ccs_begin_offset); MemTracker::record_virtual_memory_split_reserved(total_space_rs.base(), total_spa ccs_begin_offset); } assert(is_aligned(archive_space_rs.base(), archive_space_alignment), "Sanity"); assert(is_aligned(archive_space_rs.size(), archive_space_alignment), "Sanity"); assert(is_aligned(class_space_rs.base(), class_space_alignment), "Sanity"); assert(is_aligned(class_space_rs.size(), class_space_alignment), "Sanity"); // NMT: fix up the space tags MemTracker::record_virtual_memory_type(archive_space_rs.base(), mtClassShared); MemTracker::record_virtual_memory_type(class_space_rs.base(), mtClass); return archive_space_rs.base(); #else ShouldNotReachHere(); return NULL; #endif } void MetaspaceShared::release_reserved_spaces(ReservedSpace& total_space_rs, ReservedSpace& archive_space_rs, ReservedSpace& class_space_rs) { if (total_space_rs.is_reserved()) { log_debug(cds)("Released shared space (archive + class) " INTPTR_FORMAT, p2i(total total_space_rs.release(); } else { if (archive_space_rs.is_reserved()) { log_debug(cds)("Released shared space (archive) " INTPTR_FORMAT, p2i(archive_space archive_space_rs.release(); } if (class_space_rs.is_reserved()) { log_debug(cds)("Released shared space (classes) " INTPTR_FORMAT, p2i(class_space_r class_space_rs.release(); } } } static int archive_regions[] = { MetaspaceShared::rw, MetaspaceShared::ro }; static int archive_regions_count = 2; MapArchiveResult MetaspaceShared::map_archive(FileMapInfo* mapinfo, char* mapped_bas assert(UseSharedSpaces, "must be runtime"); if (mapinfo == NULL) { return MAP_ARCHIVE_SUCCESS; // The dynamic archive has not been specified. No error has happe } mapinfo->set_is_mapped(false); if (mapinfo->core_region_alignment() != (size_t)core_region_alignment()) { log_info(cds)("Unable to map CDS archive -- core_region_alignment() expected: " S " actual: " SIZE_FORMAT, mapinfo->core_region_alignment(), core_region_alignment()); return MAP_ARCHIVE_OTHER_FAILURE; } MapArchiveResult result = mapinfo->map_regions(archive_regions, archive_regions_count, mapped_base_address, rs if (result != MAP_ARCHIVE_SUCCESS) { unmap_archive(mapinfo); return result; } if (!mapinfo->validate_shared_path_table()) { unmap_archive(mapinfo); return MAP_ARCHIVE_OTHER_FAILURE; } mapinfo->set_is_mapped(true); return MAP_ARCHIVE_SUCCESS; } void MetaspaceShared::unmap_archive(FileMapInfo* mapinfo) { assert(UseSharedSpaces, "must be runtime"); if (mapinfo != NULL) { mapinfo->unmap_regions(archive_regions, archive_regions_count); mapinfo->unmap_region(MetaspaceShared::bm); mapinfo->set_is_mapped(false); } } // For -XX:PrintSharedArchiveAndExit class CountSharedSymbols : public SymbolClosure { private: int _count; public: CountSharedSymbols() : _count(0) {} void do_symbol(Symbol** sym) { _count++; } int total() { return _count; } }; // Read the miscellaneous data from the shared file, and // serialize it out to its various destinations. void MetaspaceShared::initialize_shared_spaces() { FileMapInfo *static_mapinfo = FileMapInfo::current_info(); // Verify various attributes of the archive, plus initialize the // shared string/symbol tables. char* buffer = static_mapinfo->serialized_data(); intptr_t* array = (intptr_t*)buffer; ReadClosure rc(&array); serialize(&rc); // Initialize the run-time symbol table. SymbolTable::create_table(); // Finish up archived heap initialization. These must be // done after ReadClosure. static_mapinfo->patch_heap_embedded_pointers(); ArchiveHeapLoader::finish_initialization(); CDS_JAVA_HEAP_ONLY(Universe::update_archived_basic_type_mirrors()); // Close the mapinfo file static_mapinfo->close(); static_mapinfo->unmap_region(MetaspaceShared::bm); FileMapInfo *dynamic_mapinfo = FileMapInfo::dynamic_info(); if (dynamic_mapinfo != NULL) { intptr_t* buffer = (intptr_t*)dynamic_mapinfo->serialized_data(); ReadClosure rc(&buffer); SymbolTable::serialize_shared_table_header(&rc, false); SystemDictionaryShared::serialize_dictionary_headers(&rc, false); dynamic_mapinfo->close(); dynamic_mapinfo->unmap_region(MetaspaceShared::bm); } // Set up LambdaFormInvokers::_lambdaform_lines for dynamic dump if (DynamicDumpSharedSpaces) { // Read stored LF format lines stored in static archive LambdaFormInvokers::read_static_archive_invokers(); } if (PrintSharedArchiveAndExit) { // Print archive names if (dynamic_mapinfo != nullptr) { tty->print_cr("\n\nBase archive name: %s", Arguments::GetSharedArchivePath()); tty->print_cr("Base archive version %d", static_mapinfo->version()); } else { tty->print_cr("Static archive name: %s", static_mapinfo->full_path()); tty->print_cr("Static archive version %d", static_mapinfo->version()); } SystemDictionaryShared::print_shared_archive(tty); if (dynamic_mapinfo != nullptr) { tty->print_cr("\n\nDynamic archive name: %s", dynamic_mapinfo->full_path()); tty->print_cr("Dynamic archive version %d", dynamic_mapinfo->version()); SystemDictionaryShared::print_shared_archive(tty, false/*dynamic*/); } // collect shared symbols and strings CountSharedSymbols cl; SymbolTable::shared_symbols_do(&cl); tty->print_cr("Number of shared symbols: %d", cl.total()); tty->print_cr("Number of shared strings: %zu", StringTable::shared_entry_count()); tty->print_cr("VM version: %s\r\n", static_mapinfo->vm_version()); if (FileMapInfo::current_info() == NULL || _archive_loading_failed) { tty->print_cr("archive is invalid"); vm_exit(1); } else { tty->print_cr("archive is valid"); vm_exit(0); } } } // JVM/TI RedefineClasses() support: bool MetaspaceShared::remap_shared_readonly_as_readwrite() { assert(SafepointSynchronize::is_at_safepoint(), "must be at safepoint"); if (UseSharedSpaces) { // remap the shared readonly space to shared readwrite, private FileMapInfo* mapinfo = FileMapInfo::current_info(); if (!mapinfo->remap_shared_readonly_as_readwrite()) { return false; } if (FileMapInfo::dynamic_info() != NULL) { mapinfo = FileMapInfo::dynamic_info(); if (!mapinfo->remap_shared_readonly_as_readwrite()) { return false; } } _remapped_readwrite = true; } return true; } bool MetaspaceShared::use_full_module_graph() { #if INCLUDE_CDS_JAVA_HEAP if (ClassLoaderDataShared::is_full_module_graph_loaded()) { return true; } #endif bool result = _use_optimized_module_handling && _use_full_module_graph; if (DumpSharedSpaces) { result &= HeapShared::can_write(); } else if (UseSharedSpaces) { result &= ArchiveHeapLoader::can_use(); } else { result = false; } if (result && UseSharedSpaces) { // Classes used by the archived full module graph are loaded in JVMTI early phase. assert(!(JvmtiExport::should_post_class_file_load_hook() && JvmtiExport::has_early_c "CDS should be disabled if early class hooks are enabled"); } return result; } void MetaspaceShared::print_on(outputStream* st) { if (UseSharedSpaces) { st->print("CDS archive(s) mapped at: "); address base = (address)MetaspaceObj::shared_metaspace_base(); address static_top = (address)_shared_metaspace_static_top; address top = (address)MetaspaceObj::shared_metaspace_top(); st->print("[" PTR_FORMAT "-" PTR_FORMAT "-" PTR_FORMAT "), ", p2i(base), p2i(static_top), st->print("size " SIZE_FORMAT ", ", top - base); st->print("SharedBaseAddress: " PTR_FORMAT ", ArchiveRelocationMode: %d.", SharedBas } else { st->print("CDS archive(s) not mapped"); } st->cr(); } ¤ Dauer der Verarbeitung: 0.66 Sekunden (vorverarbeitet) ¤ |
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