/* * Copyright (c) 1997, 2019, 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 "jvm.h" #include "asm/assembler.inline.hpp" #include "code/codeCache.hpp" #include "code/compiledIC.hpp" #include "code/compiledMethod.inline.hpp" #include "code/dependencies.hpp" #include "code/nativeInst.hpp" #include "code/nmethod.hpp" #include "code/scopeDesc.hpp" #include "compiler/abstractCompiler.hpp" #include "compiler/compileBroker.hpp" #include "compiler/compileLog.hpp" #include "compiler/compilerDirectives.hpp" #include "compiler/directivesParser.hpp" #include "compiler/disassembler.hpp" #include "interpreter/bytecode.hpp" #include "logging/log.hpp" #include "logging/logStream.hpp" #include "memory/allocation.inline.hpp" #include "memory/resourceArea.hpp" #include "memory/universe.hpp" #include "oops/access.inline.hpp" #include "oops/method.inline.hpp" #include "oops/methodData.hpp" #include "oops/oop.inline.hpp" #include "prims/jvmtiImpl.hpp" #include "runtime/atomic.hpp" #include "runtime/flags/flagSetting.hpp" #include "runtime/frame.inline.hpp" #include "runtime/handles.inline.hpp" #include "runtime/jniHandles.inline.hpp" #include "runtime/orderAccess.hpp" #include "runtime/os.hpp" #include "runtime/safepointVerifiers.hpp" #include "runtime/sharedRuntime.hpp" #include "runtime/sweeper.hpp" #include "runtime/vmThread.hpp" #include "utilities/align.hpp" #include "utilities/dtrace.hpp" #include "utilities/events.hpp" #include "utilities/resourceHash.hpp" #include "utilities/xmlstream.hpp" #if INCLUDE_JVMCI #include "jvmci/jvmciRuntime.hpp" #endif #ifdef DTRACE_ENABLED // Only bother with this argument setup if dtrace is available #define DTRACE_METHOD_UNLOAD_PROBE(method) \ { \ Method* m = (method); \ if (m != NULL) { \ Symbol* klass_name = m->klass_name(); \ Symbol* name = m->name(); \ Symbol* signature = m->signature(); \ HOTSPOT_COMPILED_METHOD_UNLOAD( \ (char *) klass_name->bytes(), klass_name->utf8_length(), \ (char *) name->bytes(), name->utf8_length(), \ (char *) signature->bytes(), signature->utf8_length()); \ } \ } #else // ndef DTRACE_ENABLED #define DTRACE_METHOD_UNLOAD_PROBE(method) #endif //--------------------------------------------------------------------------------- // NMethod statistics // They are printed under various flags, including: // PrintC1Statistics, PrintOptoStatistics, LogVMOutput, and LogCompilation. // (In the latter two cases, they like other stats are printed to the log only.) #ifndef PRODUCT // These variables are put into one block to reduce relocations // and make it simpler to print from the debugger. struct java_nmethod_stats_struct { int nmethod_count; int total_size; int relocation_size; int consts_size; int insts_size; int stub_size; int scopes_data_size; int scopes_pcs_size; int dependencies_size; int handler_table_size; int nul_chk_table_size; #if INCLUDE_JVMCI int speculations_size; int jvmci_data_size; #endif int oops_size; int metadata_size; void note_nmethod(nmethod* nm) { nmethod_count += 1; total_size += nm->size(); relocation_size += nm->relocation_size(); consts_size += nm->consts_size(); insts_size += nm->insts_size(); stub_size += nm->stub_size(); oops_size += nm->oops_size(); metadata_size += nm->metadata_size(); scopes_data_size += nm->scopes_data_size(); scopes_pcs_size += nm->scopes_pcs_size(); dependencies_size += nm->dependencies_size(); handler_table_size += nm->handler_table_size(); nul_chk_table_size += nm->nul_chk_table_size(); #if INCLUDE_JVMCI speculations_size += nm->speculations_size(); jvmci_data_size += nm->jvmci_data_size(); #endif } void print_nmethod_stats(const char* name) { if (nmethod_count == 0) return; tty->print_cr("Statistics for %d bytecoded nmethods for %s:", nmethod_count, name); if (total_size != 0) tty->print_cr(" total in heap = %d", total_size); if (nmethod_count != 0) tty->print_cr(" header = " SIZE_FORMAT, nmethod_count * sizeof(nmethod)); if (relocation_size != 0) tty->print_cr(" relocation = %d", relocation_size); if (consts_size != 0) tty->print_cr(" constants = %d", consts_size); if (insts_size != 0) tty->print_cr(" main code = %d", insts_size); if (stub_size != 0) tty->print_cr(" stub code = %d", stub_size); if (oops_size != 0) tty->print_cr(" oops = %d", oops_size); if (metadata_size != 0) tty->print_cr(" metadata = %d", metadata_size); if (scopes_data_size != 0) tty->print_cr(" scopes data = %d", scopes_data_size); if (scopes_pcs_size != 0) tty->print_cr(" scopes pcs = %d", scopes_pcs_size); if (dependencies_size != 0) tty->print_cr(" dependencies = %d", dependencies_size); if (handler_table_size != 0) tty->print_cr(" handler table = %d", handler_table_size); if (nul_chk_table_size != 0) tty->print_cr(" nul chk table = %d", nul_chk_table_size); #if INCLUDE_JVMCI if (speculations_size != 0) tty->print_cr(" speculations = %d", speculations_size); if (jvmci_data_size != 0) tty->print_cr(" JVMCI data = %d", jvmci_data_size); #endif } }; struct native_nmethod_stats_struct { int native_nmethod_count; int native_total_size; int native_relocation_size; int native_insts_size; int native_oops_size; int native_metadata_size; void note_native_nmethod(nmethod* nm) { native_nmethod_count += 1; native_total_size += nm->size(); native_relocation_size += nm->relocation_size(); native_insts_size += nm->insts_size(); native_oops_size += nm->oops_size(); native_metadata_size += nm->metadata_size(); } void print_native_nmethod_stats() { if (native_nmethod_count == 0) return; tty->print_cr("Statistics for %d native nmethods:", native_nmethod_count); if (native_total_size != 0) tty->print_cr(" N. total size = %d", native_total_size); if (native_relocation_size != 0) tty->print_cr(" N. relocation = %d", native_relocation_size); if (native_insts_size != 0) tty->print_cr(" N. main code = %d", native_insts_size); if (native_oops_size != 0) tty->print_cr(" N. oops = %d", native_oops_size); if (native_metadata_size != 0) tty->print_cr(" N. metadata = %d", native_metadata_size); } }; struct pc_nmethod_stats_struct { int pc_desc_resets; // number of resets (= number of caches) int pc_desc_queries; // queries to nmethod::find_pc_desc int pc_desc_approx; // number of those which have approximate true int pc_desc_repeats; // number of _pc_descs[0] hits int pc_desc_hits; // number of LRU cache hits int pc_desc_tests; // total number of PcDesc examinations int pc_desc_searches; // total number of quasi-binary search steps int pc_desc_adds; // number of LUR cache insertions void print_pc_stats() { tty->print_cr("PcDesc Statistics: %d queries, %.2f comparisons per query", pc_desc_queries, (double)(pc_desc_tests + pc_desc_searches) / pc_desc_queries); tty->print_cr(" caches=%d queries=%d/%d, hits=%d+%d, tests=%d+%d, adds=%d", pc_desc_resets, pc_desc_queries, pc_desc_approx, pc_desc_repeats, pc_desc_hits, pc_desc_tests, pc_desc_searches, pc_desc_adds); } }; #ifdef COMPILER1 static java_nmethod_stats_struct c1_java_nmethod_stats; #endif #ifdef COMPILER2 static java_nmethod_stats_struct c2_java_nmethod_stats; #endif #if INCLUDE_JVMCI static java_nmethod_stats_struct jvmci_java_nmethod_stats; #endif static java_nmethod_stats_struct unknown_java_nmethod_stats; static native_nmethod_stats_struct native_nmethod_stats; static pc_nmethod_stats_struct pc_nmethod_stats; static void note_java_nmethod(nmethod* nm) { #ifdef COMPILER1 if (nm->is_compiled_by_c1()) { c1_java_nmethod_stats.note_nmethod(nm); } else #endif #ifdef COMPILER2 if (nm->is_compiled_by_c2()) { c2_java_nmethod_stats.note_nmethod(nm); } else #endif #if INCLUDE_JVMCI if (nm->is_compiled_by_jvmci()) { jvmci_java_nmethod_stats.note_nmethod(nm); } else #endif { unknown_java_nmethod_stats.note_nmethod(nm); } } #endif // !PRODUCT //--------------------------------------------------------------------------------- ExceptionCache::ExceptionCache(Handle exception, address pc, address handler) { assert(pc != NULL, "Must be non null"); assert(exception.not_null(), "Must be non null"); assert(handler != NULL, "Must be non null"); _count = 0; _exception_type = exception->klass(); _next = NULL; _purge_list_next = NULL; add_address_and_handler(pc,handler); } address ExceptionCache::match(Handle exception, address pc) { assert(pc != NULL,"Must be non null"); assert(exception.not_null(),"Must be non null"); if (exception->klass() == exception_type()) { return (test_address(pc)); } return NULL; } bool ExceptionCache::match_exception_with_space(Handle exception) { assert(exception.not_null(),"Must be non null"); if (exception->klass() == exception_type() && count() < cache_size) { return true; } return false; } address ExceptionCache::test_address(address addr) { int limit = count(); for (int i = 0; i < limit; i++) { if (pc_at(i) == addr) { return handler_at(i); } } return NULL; } bool ExceptionCache::add_address_and_handler(address addr, address handler) { if (test_address(addr) == handler) return true; int index = count(); if (index < cache_size) { set_pc_at(index, addr); set_handler_at(index, handler); increment_count(); return true; } return false; } ExceptionCache* ExceptionCache::next() { return Atomic::load(&_next); } void ExceptionCache::set_next(ExceptionCache *ec) { Atomic::store(ec, &_next); } //----------------------------------------------------------------------------- // Helper used by both find_pc_desc methods. static inline bool match_desc(PcDesc* pc, int pc_offset, bool approximate) { NOT_PRODUCT(++pc_nmethod_stats.pc_desc_tests); if (!approximate) return pc->pc_offset() == pc_offset; else return (pc-1)->pc_offset() < pc_offset && pc_offset <= pc->pc_offset(); } void PcDescCache::reset_to(PcDesc* initial_pc_desc) { if (initial_pc_desc == NULL) { _pc_descs[0] = NULL; // native method; no PcDescs at all return; } NOT_PRODUCT(++pc_nmethod_stats.pc_desc_resets); // reset the cache by filling it with benign (non-null) values assert(initial_pc_desc->pc_offset() < 0, "must be sentinel"); for (int i = 0; i < cache_size; i++) _pc_descs[i] = initial_pc_desc; } PcDesc* PcDescCache::find_pc_desc(int pc_offset, bool approximate) { NOT_PRODUCT(++pc_nmethod_stats.pc_desc_queries); NOT_PRODUCT(if (approximate) ++pc_nmethod_stats.pc_desc_approx); // Note: one might think that caching the most recently // read value separately would be a win, but one would be // wrong. When many threads are updating it, the cache // line it's in would bounce between caches, negating // any benefit. // In order to prevent race conditions do not load cache elements // repeatedly, but use a local copy: PcDesc* res; // Step one: Check the most recently added value. res = _pc_descs[0]; if (res == NULL) return NULL; // native method; no PcDescs at all if (match_desc(res, pc_offset, approximate)) { NOT_PRODUCT(++pc_nmethod_stats.pc_desc_repeats); return res; } // Step two: Check the rest of the LRU cache. for (int i = 1; i < cache_size; ++i) { res = _pc_descs[i]; if (res->pc_offset() < 0) break; // optimization: skip empty cache if (match_desc(res, pc_offset, approximate)) { NOT_PRODUCT(++pc_nmethod_stats.pc_desc_hits); return res; } } // Report failure. return NULL; } void PcDescCache::add_pc_desc(PcDesc* pc_desc) { NOT_PRODUCT(++pc_nmethod_stats.pc_desc_adds); // Update the LRU cache by shifting pc_desc forward. for (int i = 0; i < cache_size; i++) { PcDesc* next = _pc_descs[i]; _pc_descs[i] = pc_desc; pc_desc = next; } } // adjust pcs_size so that it is a multiple of both oopSize and // sizeof(PcDesc) (assumes that if sizeof(PcDesc) is not a multiple // of oopSize, then 2*sizeof(PcDesc) is) static int adjust_pcs_size(int pcs_size) { int nsize = align_up(pcs_size, oopSize); if ((nsize % sizeof(PcDesc)) != 0) { nsize = pcs_size + sizeof(PcDesc); } assert((nsize % oopSize) == 0, "correct alignment"); return nsize; } int nmethod::total_size() const { return consts_size() + insts_size() + stub_size() + scopes_data_size() + scopes_pcs_size() + handler_table_size() + nul_chk_table_size(); } address* nmethod::orig_pc_addr(const frame* fr) { return (address*) ((address)fr->unextended_sp() + _orig_pc_offset); } const char* nmethod::compile_kind() const { if (is_osr_method()) return "osr"; if (method() != NULL && is_native_method()) return "c2n"; return NULL; } // Fill in default values for various flag fields void nmethod::init_defaults() { _state = not_installed; _has_flushed_dependencies = 0; _lock_count = 0; _stack_traversal_mark = 0; _unload_reported = false; // jvmti state _is_far_code = false; // nmethods are located in CodeCache #ifdef ASSERT _oops_are_stale = false; #endif _oops_do_mark_link = NULL; _jmethod_id = NULL; _osr_link = NULL; #if INCLUDE_RTM_OPT _rtm_state = NoRTM; #endif } nmethod* nmethod::new_native_nmethod(const methodHandle& method, int compile_id, CodeBuffer *code_buffer, int vep_offset, int frame_complete, int frame_size, ByteSize basic_lock_owner_sp_offset, ByteSize basic_lock_sp_offset, OopMapSet* oop_maps) { code_buffer->finalize_oop_references(method); // create nmethod nmethod* nm = NULL; { MutexLocker mu(CodeCache_lock, Mutex::_no_safepoint_check_flag); int native_nmethod_size = CodeBlob::allocation_size(code_buffer, sizeof(nmethod)); CodeOffsets offsets; offsets.set_value(CodeOffsets::Verified_Entry, vep_offset); offsets.set_value(CodeOffsets::Frame_Complete, frame_complete); nm = new (native_nmethod_size, CompLevel_none) nmethod(method(), compiler_none, native_nmethod_size, compile_id, &offsets, code_buffer, frame_size, basic_lock_owner_sp_offset, basic_lock_sp_offset, oop_maps); NOT_PRODUCT(if (nm != NULL) native_nmethod_stats.note_native_nmethod(nm)); } if (nm != NULL) { // verify nmethod debug_only(nm->verify();) // might block nm->log_new_nmethod(); nm->make_in_use(); } return nm; } nmethod* nmethod::new_nmethod(const methodHandle& method, int compile_id, int entry_bci, CodeOffsets* offsets, int orig_pc_offset, DebugInformationRecorder* debug_info, Dependencies* dependencies, CodeBuffer* code_buffer, int frame_size, OopMapSet* oop_maps, ExceptionHandlerTable* handler_table, ImplicitExceptionTable* nul_chk_table, AbstractCompiler* compiler, int comp_level #if INCLUDE_JVMCI , char* speculations, int speculations_len, int nmethod_mirror_index, const char* nmethod_mirror_name, FailedSpeculation** failed_speculations #endif ) { assert(debug_info->oop_recorder() == code_buffer->oop_recorder(), "shared OR"); code_buffer->finalize_oop_references(method); // create nmethod nmethod* nm = NULL; { MutexLocker mu(CodeCache_lock, Mutex::_no_safepoint_check_flag); #if INCLUDE_JVMCI int jvmci_data_size = !compiler->is_jvmci() ? 0 : JVMCINMethodData::compute_size(nmethod_mirror_name); #endif int nmethod_size = CodeBlob::allocation_size(code_buffer, sizeof(nmethod)) + adjust_pcs_size(debug_info->pcs_size()) + align_up((int)dependencies->size_in_bytes(), oopSize) + align_up(handler_table->size_in_bytes() , oopSize) + align_up(nul_chk_table->size_in_bytes() , oopSize) #if INCLUDE_JVMCI + align_up(speculations_len , oopSize) + align_up(jvmci_data_size , oopSize) #endif + align_up(debug_info->data_size() , oopSize); nm = new (nmethod_size, comp_level) nmethod(method(), compiler->type(), nmethod_size, compile_id, entry_bci, offsets, orig_pc_offset, debug_info, dependencies, code_buffer, frame_size, oop_maps, handler_table, nul_chk_table, compiler, comp_level #if INCLUDE_JVMCI , speculations, speculations_len, jvmci_data_size #endif ); if (nm != NULL) { #if INCLUDE_JVMCI if (compiler->is_jvmci()) { // Initialize the JVMCINMethodData object inlined into nm nm->jvmci_nmethod_data()->initialize(nmethod_mirror_index, nmethod_mirror_name, failed_speculations); } #endif // To make dependency checking during class loading fast, record // the nmethod dependencies in the classes it is dependent on. // This allows the dependency checking code to simply walk the // class hierarchy above the loaded class, checking only nmethods // which are dependent on those classes. The slow way is to // check every nmethod for dependencies which makes it linear in // the number of methods compiled. For applications with a lot // classes the slow way is too slow. for (Dependencies::DepStream deps(nm); deps.next(); ) { if (deps.type() == Dependencies::call_site_target_value) { // CallSite dependencies are managed on per-CallSite instance basis. oop call_site = deps.argument_oop(0); MethodHandles::add_dependent_nmethod(call_site, nm); } else { Klass* klass = deps.context_type(); if (klass == NULL) { continue; // ignore things like evol_method } // record this nmethod as dependent on this klass InstanceKlass::cast(klass)->add_dependent_nmethod(nm); } } NOT_PRODUCT(if (nm != NULL) note_java_nmethod(nm)); } } // Do verification and logging outside CodeCache_lock. if (nm != NULL) { // Safepoints in nmethod::verify aren't allowed because nm hasn't been installed yet. DEBUG_ONLY(nm->verify();) nm->log_new_nmethod(); } return nm; } // For native wrappers nmethod::nmethod( Method* method, CompilerType type, int nmethod_size, int compile_id, CodeOffsets* offsets, CodeBuffer* code_buffer, int frame_size, ByteSize basic_lock_owner_sp_offset, ByteSize basic_lock_sp_offset, OopMapSet* oop_maps ) : CompiledMethod(method, "native nmethod", type, nmethod_size, sizeof(nmethod), code_buffer, offsets->value(CodeOffsets::Frame_Complete), frame_size, oop_maps, false), _is_unloading_state(0), _native_receiver_sp_offset(basic_lock_owner_sp_offset), _native_basic_lock_sp_offset(basic_lock_sp_offset) { { int scopes_data_offset = 0; int deoptimize_offset = 0; int deoptimize_mh_offset = 0; debug_only(NoSafepointVerifier nsv;) assert_locked_or_safepoint(CodeCache_lock); init_defaults(); _entry_bci = InvocationEntryBci; // We have no exception handler or deopt handler make the // values something that will never match a pc like the nmethod vtable entry _exception_offset = 0; _orig_pc_offset = 0; _consts_offset = data_offset(); _stub_offset = data_offset(); _oops_offset = data_offset(); _metadata_offset = _oops_offset + align_up(code_buffer->total_oop_size(), oopSize); scopes_data_offset = _metadata_offset + align_up(code_buffer->total_metadata_size(), wordSize); _scopes_pcs_offset = scopes_data_offset; _dependencies_offset = _scopes_pcs_offset; _handler_table_offset = _dependencies_offset; _nul_chk_table_offset = _handler_table_offset; #if INCLUDE_JVMCI _speculations_offset = _nul_chk_table_offset; _jvmci_data_offset = _speculations_offset; _nmethod_end_offset = _jvmci_data_offset; #else _nmethod_end_offset = _nul_chk_table_offset; #endif _compile_id = compile_id; _comp_level = CompLevel_none; _entry_point = code_begin() + offsets->value(CodeOffsets::Entry); _verified_entry_point = code_begin() + offsets->value(CodeOffsets::Verified_Entry); _osr_entry_point = NULL; _exception_cache = NULL; _pc_desc_container.reset_to(NULL); _hotness_counter = NMethodSweeper::hotness_counter_reset_val(); _scopes_data_begin = (address) this + scopes_data_offset; _deopt_handler_begin = (address) this + deoptimize_offset; _deopt_mh_handler_begin = (address) this + deoptimize_mh_offset; code_buffer->copy_code_and_locs_to(this); code_buffer->copy_values_to(this); clear_unloading_state(); Universe::heap()->register_nmethod(this); debug_only(Universe::heap()->verify_nmethod(this)); CodeCache::commit(this); } if (PrintNativeNMethods || PrintDebugInfo || PrintRelocations || PrintDependencies) { ttyLocker ttyl; // keep the following output all in one block // This output goes directly to the tty, not the compiler log. // To enable tools to match it up with the compilation activity, // be sure to tag this tty output with the compile ID. if (xtty != NULL) { xtty->begin_head("print_native_nmethod"); xtty->method(_method); xtty->stamp(); xtty->end_head(" address='" INTPTR_FORMAT "'", (intptr_t) this); } // Print the header part, then print the requested information. // This is both handled in decode2(), called via print_code() -> decode() if (PrintNativeNMethods) { tty->print_cr("-------------------------- Assembly (native nmethod) ---------------------------"); print_code(); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); #if defined(SUPPORT_DATA_STRUCTS) if (AbstractDisassembler::show_structs()) { if (oop_maps != NULL) { tty->print("oop maps:"); // oop_maps->print_on(tty) outputs a cr() at the beginning oop_maps->print_on(tty); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); } } #endif } else { print(); // print the header part only. } #if defined(SUPPORT_DATA_STRUCTS) if (AbstractDisassembler::show_structs()) { if (PrintRelocations) { print_relocations(); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); } } #endif if (xtty != NULL) { xtty->tail("print_native_nmethod"); } } } void* nmethod::operator new(size_t size, int nmethod_size, int comp_level) throw () { return CodeCache::allocate(nmethod_size, CodeCache::get_code_blob_type(comp_level)); } nmethod::nmethod( Method* method, CompilerType type, int nmethod_size, int compile_id, int entry_bci, CodeOffsets* offsets, int orig_pc_offset, DebugInformationRecorder* debug_info, Dependencies* dependencies, CodeBuffer *code_buffer, int frame_size, OopMapSet* oop_maps, ExceptionHandlerTable* handler_table, ImplicitExceptionTable* nul_chk_table, AbstractCompiler* compiler, int comp_level #if INCLUDE_JVMCI , char* speculations, int speculations_len, int jvmci_data_size #endif ) : CompiledMethod(method, "nmethod", type, nmethod_size, sizeof(nmethod), code_buffer, offsets->value(CodeOffsets::Frame_Complete), frame_size, oop_maps, false), _is_unloading_state(0), _native_receiver_sp_offset(in_ByteSize(-1)), _native_basic_lock_sp_offset(in_ByteSize(-1)) { assert(debug_info->oop_recorder() == code_buffer->oop_recorder(), "shared OR"); { debug_only(NoSafepointVerifier nsv;) assert_locked_or_safepoint(CodeCache_lock); _deopt_handler_begin = (address) this; _deopt_mh_handler_begin = (address) this; init_defaults(); _entry_bci = entry_bci; _compile_id = compile_id; _comp_level = comp_level; _orig_pc_offset = orig_pc_offset; _hotness_counter = NMethodSweeper::hotness_counter_reset_val(); // Section offsets _consts_offset = content_offset() + code_buffer->total_offset_of(code_buffer->consts()); _stub_offset = content_offset() + code_buffer->total_offset_of(code_buffer->stubs()); set_ctable_begin(header_begin() + _consts_offset); #if INCLUDE_JVMCI if (compiler->is_jvmci()) { // JVMCI might not produce any stub sections if (offsets->value(CodeOffsets::Exceptions) != -1) { _exception_offset = code_offset() + offsets->value(CodeOffsets::Exceptions); } else { _exception_offset = -1; } if (offsets->value(CodeOffsets::Deopt) != -1) { _deopt_handler_begin = (address) this + code_offset() + offsets->value(CodeOffsets::Deopt); } else { _deopt_handler_begin = NULL; } if (offsets->value(CodeOffsets::DeoptMH) != -1) { _deopt_mh_handler_begin = (address) this + code_offset() + offsets->value(CodeOffsets::DeoptMH); } else { _deopt_mh_handler_begin = NULL; } } else #endif { // Exception handler and deopt handler are in the stub section assert(offsets->value(CodeOffsets::Exceptions) != -1, "must be set"); assert(offsets->value(CodeOffsets::Deopt ) != -1, "must be set"); _exception_offset = _stub_offset + offsets->value(CodeOffsets::Exceptions); _deopt_handler_begin = (address) this + _stub_offset + offsets->value(CodeOffsets::Deopt); if (offsets->value(CodeOffsets::DeoptMH) != -1) { _deopt_mh_handler_begin = (address) this + _stub_offset + offsets->value(CodeOffsets::DeoptMH); } else { _deopt_mh_handler_begin = NULL; } } if (offsets->value(CodeOffsets::UnwindHandler) != -1) { _unwind_handler_offset = code_offset() + offsets->value(CodeOffsets::UnwindHandler); } else { _unwind_handler_offset = -1; } _oops_offset = data_offset(); _metadata_offset = _oops_offset + align_up(code_buffer->total_oop_size(), oopSize); int scopes_data_offset = _metadata_offset + align_up(code_buffer->total_metadata_size(), wordSize); _scopes_pcs_offset = scopes_data_offset + align_up(debug_info->data_size (), oopSize); _dependencies_offset = _scopes_pcs_offset + adjust_pcs_size(debug_info->pcs_size()); _handler_table_offset = _dependencies_offset + align_up((int)dependencies->size_in_bytes (), oopSize); _nul_chk_table_offset = _handler_table_offset + align_up(handler_table->size_in_bytes(), oopSize); #if INCLUDE_JVMCI _speculations_offset = _nul_chk_table_offset + align_up(nul_chk_table->size_in_bytes(), oopSize); _jvmci_data_offset = _speculations_offset + align_up(speculations_len, oopSize); _nmethod_end_offset = _jvmci_data_offset + align_up(jvmci_data_size, oopSize); #else _nmethod_end_offset = _nul_chk_table_offset + align_up(nul_chk_table->size_in_bytes(), oopSize); #endif _entry_point = code_begin() + offsets->value(CodeOffsets::Entry); _verified_entry_point = code_begin() + offsets->value(CodeOffsets::Verified_Entry); _osr_entry_point = code_begin() + offsets->value(CodeOffsets::OSR_Entry); _exception_cache = NULL; _scopes_data_begin = (address) this + scopes_data_offset; _pc_desc_container.reset_to(scopes_pcs_begin()); code_buffer->copy_code_and_locs_to(this); // Copy contents of ScopeDescRecorder to nmethod code_buffer->copy_values_to(this); debug_info->copy_to(this); dependencies->copy_to(this); clear_unloading_state(); Universe::heap()->register_nmethod(this); debug_only(Universe::heap()->verify_nmethod(this)); CodeCache::commit(this); // Copy contents of ExceptionHandlerTable to nmethod handler_table->copy_to(this); nul_chk_table->copy_to(this); #if INCLUDE_JVMCI // Copy speculations to nmethod if (speculations_size() != 0) { memcpy(speculations_begin(), speculations, speculations_len); } #endif // we use the information of entry points to find out if a method is // static or non static assert(compiler->is_c2() || compiler->is_jvmci() || _method->is_static() == (entry_point() == _verified_entry_point), " entry points must be same for static methods and vice versa"); } } // Print a short set of xml attributes to identify this nmethod. The // output should be embedded in some other element. void nmethod::log_identity(xmlStream* log) const { log->print(" compile_id='%d'", compile_id()); const char* nm_kind = compile_kind(); if (nm_kind != NULL) log->print(" compile_kind='%s'", nm_kind); log->print(" compiler='%s'", compiler_name()); if (TieredCompilation) { log->print(" level='%d'", comp_level()); } #if INCLUDE_JVMCI if (jvmci_nmethod_data() != NULL) { const char* jvmci_name = jvmci_nmethod_data()->name(); if (jvmci_name != NULL) { log->print(" jvmci_mirror_name='"); log->text("%s", jvmci_name); log->print("'"); } } #endif } #define LOG_OFFSET(log, name) \ if (p2i(name##_end()) - p2i(name##_begin())) \ log->print(" " XSTR(name) "_offset='" INTX_FORMAT "'" , \ p2i(name##_begin()) - p2i(this)) void nmethod::log_new_nmethod() const { if (LogCompilation && xtty != NULL) { ttyLocker ttyl; HandleMark hm; xtty->begin_elem("nmethod"); log_identity(xtty); xtty->print(" entry='" INTPTR_FORMAT "' size='%d'", p2i(code_begin()), size()); xtty->print(" address='" INTPTR_FORMAT "'", p2i(this)); LOG_OFFSET(xtty, relocation); LOG_OFFSET(xtty, consts); LOG_OFFSET(xtty, insts); LOG_OFFSET(xtty, stub); LOG_OFFSET(xtty, scopes_data); LOG_OFFSET(xtty, scopes_pcs); LOG_OFFSET(xtty, dependencies); LOG_OFFSET(xtty, handler_table); LOG_OFFSET(xtty, nul_chk_table); LOG_OFFSET(xtty, oops); LOG_OFFSET(xtty, metadata); xtty->method(method()); xtty->stamp(); xtty->end_elem(); } } #undef LOG_OFFSET // Print out more verbose output usually for a newly created nmethod. void nmethod::print_on(outputStream* st, const char* msg) const { if (st != NULL) { ttyLocker ttyl; if (WizardMode) { CompileTask::print(st, this, msg, /*short_form:*/ true); st->print_cr(" (" INTPTR_FORMAT ")", p2i(this)); } else { CompileTask::print(st, this, msg, /*short_form:*/ false); } } } void nmethod::maybe_print_nmethod(DirectiveSet* directive) { bool printnmethods = directive->PrintAssemblyOption || directive->PrintNMethodsOption; if (printnmethods || PrintDebugInfo || PrintRelocations || PrintDependencies || PrintExceptionHandlers) { print_nmethod(printnmethods); } } void nmethod::print_nmethod(bool printmethod) { ttyLocker ttyl; // keep the following output all in one block if (xtty != NULL) { xtty->begin_head("print_nmethod"); log_identity(xtty); xtty->stamp(); xtty->end_head(); } // Print the header part, then print the requested information. // This is both handled in decode2(). if (printmethod) { HandleMark hm; ResourceMark m; if (is_compiled_by_c1()) { tty->cr(); tty->print_cr("============================= C1-compiled nmethod =============================="); } if (is_compiled_by_jvmci()) { tty->cr(); tty->print_cr("=========================== JVMCI-compiled nmethod ============================="); } tty->print_cr("----------------------------------- Assembly -----------------------------------"); decode2(tty); #if defined(SUPPORT_DATA_STRUCTS) if (AbstractDisassembler::show_structs()) { // Print the oops from the underlying CodeBlob as well. tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); print_oops(tty); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); print_metadata(tty); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); print_pcs(); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); if (oop_maps() != NULL) { tty->print("oop maps:"); // oop_maps()->print_on(tty) outputs a cr() at the beginning oop_maps()->print_on(tty); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); } } #endif } else { print(); // print the header part only. } #if defined(SUPPORT_DATA_STRUCTS) if (AbstractDisassembler::show_structs()) { if (printmethod || PrintDebugInfo || CompilerOracle::has_option_string(_method, "PrintDebugInfo")) { print_scopes(); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); } if (printmethod || PrintRelocations || CompilerOracle::has_option_string(_method, "PrintRelocations")) { print_relocations(); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); } if (printmethod || PrintDependencies || CompilerOracle::has_option_string(_method, "PrintDependencies")) { print_dependencies(); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); } if (printmethod || PrintExceptionHandlers) { print_handler_table(); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); print_nul_chk_table(); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); } if (printmethod) { print_recorded_oops(); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); print_recorded_metadata(); tty->print_cr("- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - "); } } #endif if (xtty != NULL) { xtty->tail("print_nmethod"); } } // Promote one word from an assembly-time handle to a live embedded oop. inline void nmethod::initialize_immediate_oop(oop* dest, jobject handle) { if (handle == NULL || // As a special case, IC oops are initialized to 1 or -1. handle == (jobject) Universe::non_oop_word()) { (*dest) = (oop) handle; } else { (*dest) = JNIHandles::resolve_non_null(handle); } } // Have to have the same name because it's called by a template void nmethod::copy_values(GrowableArray* array) { int length = array->length(); assert((address)(oops_begin() + length) <= (address)oops_end(), "oops big enough"); oop* dest = oops_begin(); for (int index = 0 ; index < length; index++) { initialize_immediate_oop(&dest[index], array->at(index)); } // Now we can fix up all the oops in the code. We need to do this // in the code because the assembler uses jobjects as placeholders. // The code and relocations have already been initialized by the // CodeBlob constructor, so it is valid even at this early point to // iterate over relocations and patch the code. fix_oop_relocations(NULL, NULL, /*initialize_immediates=*/ true); } void nmethod::copy_values(GrowableArray* array) { int length = array->length(); assert((address)(metadata_begin() + length) <= (address)metadata_end(), "big enough"); Metadata** dest = metadata_begin(); for (int index = 0 ; index < length; index++) { dest[index] = array->at(index); } } void nmethod::fix_oop_relocations(address begin, address end, bool initialize_immediates) { // re-patch all oop-bearing instructions, just in case some oops moved RelocIterator iter(this, begin, end); while (iter.next()) { if (iter.type() == relocInfo::oop_type) { oop_Relocation* reloc = iter.oop_reloc(); if (initialize_immediates && reloc->oop_is_immediate()) { oop* dest = reloc->oop_addr(); initialize_immediate_oop(dest, (jobject) *dest); } // Refresh the oop-related bits of this instruction. reloc->fix_oop_relocation(); } else if (iter.type() == relocInfo::metadata_type) { metadata_Relocation* reloc = iter.metadata_reloc(); reloc->fix_metadata_relocation(); } } } void nmethod::verify_clean_inline_caches() { assert(CompiledICLocker::is_safe(this), "mt unsafe call"); ResourceMark rm; RelocIterator iter(this, oops_reloc_begin()); while(iter.next()) { switch(iter.type()) { case relocInfo::virtual_call_type: case relocInfo::opt_virtual_call_type: { CompiledIC *ic = CompiledIC_at(&iter); // Ok, to lookup references to zombies here CodeBlob *cb = CodeCache::find_blob_unsafe(ic->ic_destination()); assert(cb != NULL, "destination not in CodeBlob?"); nmethod* nm = cb->as_nmethod_or_null(); if( nm != NULL ) { // Verify that inline caches pointing to both zombie and not_entrant methods are clean if (!nm->is_in_use() || (nm->method()->code() != nm)) { assert(ic->is_clean(), "IC should be clean"); } } break; } case relocInfo::static_call_type: { CompiledStaticCall *csc = compiledStaticCall_at(iter.reloc()); CodeBlob *cb = CodeCache::find_blob_unsafe(csc->destination()); assert(cb != NULL, "destination not in CodeBlob?"); nmethod* nm = cb->as_nmethod_or_null(); if( nm != NULL ) { // Verify that inline caches pointing to both zombie and not_entrant methods are clean if (!nm->is_in_use() || (nm->method()->code() != nm)) { assert(csc->is_clean(), "IC should be clean"); } } break; } default: break; } } } // This is a private interface with the sweeper. void nmethod::mark_as_seen_on_stack() { assert(is_alive(), "Must be an alive method"); // Set the traversal mark to ensure that the sweeper does 2 // cleaning passes before moving to zombie. set_stack_traversal_mark(NMethodSweeper::traversal_count()); } // Tell if a non-entrant method can be converted to a zombie (i.e., // there are no activations on the stack, not in use by the VM, // and not in use by the ServiceThread) bool nmethod::can_convert_to_zombie() { // Note that this is called when the sweeper has observed the nmethod to be // not_entrant. However, with concurrent code cache unloading, the state // might have moved on to unloaded if it is_unloading(), due to racing // concurrent GC threads. assert(is_not_entrant() || is_unloading(), "must be a non-entrant method"); // Since the nmethod sweeper only does partial sweep the sweeper's traversal // count can be greater than the stack traversal count before it hits the // nmethod for the second time. // If an is_unloading() nmethod is still not_entrant, then it is not safe to // convert it to zombie due to GC unloading interactions. However, if it // has become unloaded, then it is okay to convert such nmethods to zombie. return stack_traversal_mark() + 1 < NMethodSweeper::traversal_count() && !is_locked_by_vm() && (!is_unloading() || is_unloaded()); } void nmethod::inc_decompile_count() { if (!is_compiled_by_c2() && !is_compiled_by_jvmci()) return; // Could be gated by ProfileTraps, but do not bother... Method* m = method(); if (m == NULL) return; MethodData* mdo = m->method_data(); if (mdo == NULL) return; // There is a benign race here. See comments in methodData.hpp. mdo->inc_decompile_count(); } bool nmethod::try_transition(int new_state_int) { signed char new_state = new_state_int; for (;;) { signed char old_state = Atomic::load(&_state); if (old_state >= new_state) { // Ensure monotonicity of transitions. return false; } if (Atomic::cmpxchg(new_state, &_state, old_state) == old_state) { return true; } } } void nmethod::make_unloaded() { post_compiled_method_unload(); // This nmethod is being unloaded, make sure that dependencies // recorded in instanceKlasses get flushed. // Since this work is being done during a GC, defer deleting dependencies from the // InstanceKlass. assert(Universe::heap()->is_gc_active() || Thread::current()->is_ConcurrentGC_thread(), "should only be called during gc"); flush_dependencies(/*delete_immediately*/false); // Break cycle between nmethod & method LogTarget(Trace, class, unload, nmethod) lt; if (lt.is_enabled()) { LogStream ls(lt); ls.print("making nmethod " INTPTR_FORMAT " unloadable, Method*(" INTPTR_FORMAT ") ", p2i(this), p2i(_method)); ls.cr(); } // Unlink the osr method, so we do not look this up again if (is_osr_method()) { // Invalidate the osr nmethod only once. Note that with concurrent // code cache unloading, OSR nmethods are invalidated before they // are made unloaded. Therefore, this becomes a no-op then. if (is_in_use()) { invalidate_osr_method(); } #ifdef ASSERT if (method() != NULL) { // Make sure osr nmethod is invalidated, i.e. not on the list bool found = method()->method_holder()->remove_osr_nmethod(this); assert(!found, "osr nmethod should have been invalidated"); } #endif } // If _method is already NULL the Method* is about to be unloaded, // so we don't have to break the cycle. Note that it is possible to // have the Method* live here, in case we unload the nmethod because // it is pointing to some oop (other than the Method*) being unloaded. if (_method != NULL) { // OSR methods point to the Method*, but the Method* does not // point back! if (_method->code() == this) { _method->clear_code(); // Break a cycle } } // Make the class unloaded - i.e., change state and notify sweeper assert(SafepointSynchronize::is_at_safepoint() || Thread::current()->is_ConcurrentGC_thread(), "must be at safepoint"); { // Clear ICStubs and release any CompiledICHolders. CompiledICLocker ml(this); clear_ic_callsites(); } // Unregister must be done before the state change { MutexLocker ml(SafepointSynchronize::is_at_safepoint() ? NULL : CodeCache_lock, Mutex::_no_safepoint_check_flag); Universe::heap()->unregister_nmethod(this); } // Clear the method of this dead nmethod set_method(NULL); // Log the unloading. log_state_change(); // The Method* is gone at this point assert(_method == NULL, "Tautology"); set_osr_link(NULL); NMethodSweeper::report_state_change(this); bool transition_success = try_transition(unloaded); // It is an important invariant that there exists no race between // the sweeper and GC thread competing for making the same nmethod // zombie and unloaded respectively. This is ensured by // can_convert_to_zombie() returning false for any is_unloading() // nmethod, informing the sweeper not to step on any GC toes. assert(transition_success, "Invalid nmethod transition to unloaded"); #if INCLUDE_JVMCI // Clear the link between this nmethod and a HotSpotNmethod mirror JVMCINMethodData* nmethod_data = jvmci_nmethod_data(); if (nmethod_data != NULL) { nmethod_data->invalidate_nmethod_mirror(this); nmethod_data->clear_nmethod_mirror(this); } #endif } void nmethod::invalidate_osr_method() { assert(_entry_bci != InvocationEntryBci, "wrong kind of nmethod"); // Remove from list of active nmethods if (method() != NULL) { method()->method_holder()->remove_osr_nmethod(this); } } void nmethod::log_state_change() const { if (LogCompilation) { if (xtty != NULL) { ttyLocker ttyl; // keep the following output all in one block if (_state == unloaded) { xtty->begin_elem("make_unloaded thread='" UINTX_FORMAT "'", os::current_thread_id()); } else { xtty->begin_elem("make_not_entrant thread='" UINTX_FORMAT "'%s", os::current_thread_id(), (_state == zombie ? " zombie='1'" : "")); } log_identity(xtty); xtty->stamp(); xtty->end_elem(); } } const char *state_msg = _state == zombie ? "made zombie" : "made not entrant"; CompileTask::print_ul(this, state_msg); if (PrintCompilation && _state != unloaded) { print_on(tty, state_msg); } } void nmethod::unlink_from_method(bool acquire_lock) { // We need to check if both the _code and _from_compiled_code_entry_point // refer to this nmethod because there is a race in setting these two fields // in Method* as seen in bugid 4947125. // If the vep() points to the zombie nmethod, the memory for the nmethod // could be flushed and the compiler and vtable stubs could still call // through it. if (method() != NULL && (method()->code() == this || method()->from_compiled_entry() == verified_entry_point())) { method()->clear_code(acquire_lock); } } /** * Common functionality for both make_not_entrant and make_zombie */ bool nmethod::make_not_entrant_or_zombie(int state) { assert(state == zombie || state == not_entrant, "must be zombie or not_entrant"); assert(!is_zombie(), "should not already be a zombie"); if (Atomic::load(&_state) >= state) { // Avoid taking the lock if already in required state. // This is safe from races because the state is an end-state, // which the nmethod cannot back out of once entered. // No need for fencing either. return false; } // Make sure neither the nmethod nor the method is flushed in case of a safepoint in code below. nmethodLocker nml(this); methodHandle the_method(method()); // This can be called while the system is already at a safepoint which is ok NoSafepointVerifier nsv; // during patching, depending on the nmethod state we must notify the GC that // code has been unloaded, unregistering it. We cannot do this right while // holding the Patching_lock because we need to use the CodeCache_lock. This // would be prone to deadlocks. // This flag is used to remember whether we need to later lock and unregister. bool nmethod_needs_unregister = false; { // invalidate osr nmethod before acquiring the patching lock since // they both acquire leaf locks and we don't want a deadlock. // This logic is equivalent to the logic below for patching the // verified entry point of regular methods. We check that the // nmethod is in use to ensure that it is invalidated only once. if (is_osr_method() && is_in_use()) { // this effectively makes the osr nmethod not entrant invalidate_osr_method(); } // Enter critical section. Does not block for safepoint. MutexLocker pl(Patching_lock, Mutex::_no_safepoint_check_flag); if (Atomic::load(&_state) >= state) { // another thread already performed this transition so nothing // to do, but return false to indicate this. return false; } // The caller can be calling the method statically or through an inline // cache call. if (!is_osr_method() && !is_not_entrant()) { NativeJump::patch_verified_entry(entry_point(), verified_entry_point(), SharedRuntime::get_handle_wrong_method_stub()); } if (is_in_use() && update_recompile_counts()) { // It's a true state change, so mark the method as decompiled. // Do it only for transition from alive. inc_decompile_count(); } // If the state is becoming a zombie, signal to unregister the nmethod with // the heap. // This nmethod may have already been unloaded during a full GC. if ((state == zombie) && !is_unloaded()) { nmethod_needs_unregister = true; } // Must happen before state change. Otherwise we have a race condition in // nmethod::can_not_entrant_be_converted(). I.e., a method can immediately // transition its state from 'not_entrant' to 'zombie' without having to wait // for stack scanning. if (state == not_entrant) { mark_as_seen_on_stack(); OrderAccess::storestore(); // _stack_traversal_mark and _state } // Change state if (!try_transition(state)) { // If the transition fails, it is due to another thread making the nmethod more // dead. In particular, one thread might be making the nmethod unloaded concurrently. // If so, having patched in the jump in the verified entry unnecessarily is fine. // The nmethod is no longer possible to call by Java threads. // Incrementing the decompile count is also fine as the caller of make_not_entrant() // had a valid reason to deoptimize the nmethod. // Marking the nmethod as seen on stack also has no effect, as the nmethod is now // !is_alive(), and the seen on stack value is only used to convert not_entrant // nmethods to zombie in can_convert_to_zombie(). return false; } // Log the transition once log_state_change(); // Remove nmethod from method. unlink_from_method(false /* already owns Patching_lock */); } // leave critical region under Patching_lock #if INCLUDE_JVMCI // Invalidate can't occur while holding the Patching lock JVMCINMethodData* nmethod_data = jvmci_nmethod_data(); if (nmethod_data != NULL) { nmethod_data->invalidate_nmethod_mirror(this); } #endif #ifdef ASSERT if (is_osr_method() && method() != NULL) { // Make sure osr nmethod is invalidated, i.e. not on the list bool found = method()->method_holder()->remove_osr_nmethod(this); assert(!found, "osr nmethod should have been invalidated"); } #endif // When the nmethod becomes zombie it is no longer alive so the // dependencies must be flushed. nmethods in the not_entrant // state will be flushed later when the transition to zombie // happens or they get unloaded. if (state == zombie) { { // Flushing dependencies must be done before any possible // safepoint can sneak in, otherwise the oops used by the // dependency logic could have become stale. MutexLocker mu(CodeCache_lock, Mutex::_no_safepoint_check_flag); if (nmethod_needs_unregister) { Universe::heap()->unregister_nmethod(this); } flush_dependencies(/*delete_immediately*/true); } #if INCLUDE_JVMCI // Now that the nmethod has been unregistered, it's // safe to clear the HotSpotNmethod mirror oop. if (nmethod_data != NULL) { nmethod_data->clear_nmethod_mirror(this); } #endif // Clear ICStubs to prevent back patching stubs of zombie or flushed // nmethods during the next safepoint (see ICStub::finalize), as well // as to free up CompiledICHolder resources. { CompiledICLocker ml(this); clear_ic_callsites(); } // zombie only - if a JVMTI agent has enabled the CompiledMethodUnload // event and it hasn't already been reported for this nmethod then // report it now. The event may have been reported earlier if the GC // marked it for unloading). JvmtiDeferredEventQueue support means // we no longer go to a safepoint here. post_compiled_method_unload(); #ifdef ASSERT // It's no longer safe to access the oops section since zombie // nmethods aren't scanned for GC. _oops_are_stale = true; #endif // the Method may be reclaimed by class unloading now that the // nmethod is in zombie state set_method(NULL); } else { assert(state == not_entrant, "other cases may need to be handled differently"); } if (TraceCreateZombies && state == zombie) { ResourceMark m; tty->print_cr("nmethod <" INTPTR_FORMAT "> %s code made %s", p2i(this), this->method() ? this->method()->name_and_sig_as_C_string() : "null", (state == not_entrant) ? "not entrant" : "zombie"); } NMethodSweeper::report_state_change(this); return true; } void nmethod::flush() { MutexLocker mu(CodeCache_lock, Mutex::_no_safepoint_check_flag); // Note that there are no valid oops in the nmethod anymore. assert(!is_osr_method() || is_unloaded() || is_zombie(), "osr nmethod must be unloaded or zombie before flushing"); assert(is_zombie() || is_osr_method(), "must be a zombie method"); assert (!is_locked_by_vm(), "locked methods shouldn't be flushed"); assert_locked_or_safepoint(CodeCache_lock); // completely deallocate this method Events::log(JavaThread::current(), "flushing nmethod " INTPTR_FORMAT, p2i(this)); if (PrintMethodFlushing) { tty->print_cr("*flushing %s nmethod %3d/" INTPTR_FORMAT ". Live blobs:" UINT32_FORMAT "/Free CodeCache:" SIZE_FORMAT "Kb", is_osr_method() ? "osr" : "",_compile_id, p2i(this), CodeCache::blob_count(), CodeCache::unallocated_capacity(CodeCache::get_code_blob_type(this))/1024); } // We need to deallocate any ExceptionCache data. // Note that we do not need to grab the nmethod lock for this, it // better be thread safe if we're disposing of it! ExceptionCache* ec = exception_cache(); set_exception_cache(NULL); while(ec != NULL) { ExceptionCache* next = ec->next(); delete ec; ec = next; } Universe::heap()->flush_nmethod(this); CodeCache::unregister_old_nmethod(this); CodeBlob::flush(); CodeCache::free(this); } oop nmethod::oop_at(int index) const { if (index == 0) { return NULL; } return NativeAccess::oop_load(oop_addr_at(index)); } oop nmethod::oop_at_phantom(int index) const { if (index == 0) { return NULL; } return NativeAccess::oop_load(oop_addr_at(index)); } // // Notify all classes this nmethod is dependent on that it is no // longer dependent. This should only be called in two situations. // First, when a nmethod transitions to a zombie all dependents need // to be clear. Since zombification happens at a safepoint there's no // synchronization issues. The second place is a little more tricky. // During phase 1 of mark sweep class unloading may happen and as a // result some nmethods may get unloaded. In this case the flushing // of dependencies must happen during phase 1 since after GC any // dependencies in the unloaded nmethod won't be updated, so // traversing the dependency information in unsafe. In that case this // function is called with a boolean argument and this function only // notifies instanceKlasses that are reachable void nmethod::flush_dependencies(bool delete_immediately) { DEBUG_ONLY(bool called_by_gc = Universe::heap()->is_gc_active() || Thread::current()->is_ConcurrentGC_thread();) assert(called_by_gc != delete_immediately, "delete_immediately is false if and only if we are called during GC"); if (!has_flushed_dependencies()) { set_has_flushed_dependencies(); for (Dependencies::DepStream deps(this); deps.next(); ) { if (deps.type() == Dependencies::call_site_target_value) { // CallSite dependencies are managed on per-CallSite instance basis. oop call_site = deps.argument_oop(0); if (delete_immediately) { assert_locked_or_safepoint(CodeCache_lock); MethodHandles::remove_dependent_nmethod(call_site, this); } else { MethodHandles::clean_dependency_context(call_site); } } else { Klass* klass = deps.context_type(); if (klass == NULL) { continue; // ignore things like evol_method } // During GC delete_immediately is false, and liveness // of dependee determines class that needs to be updated. if (delete_immediately) { assert_locked_or_safepoint(CodeCache_lock); InstanceKlass::cast(klass)->remove_dependent_nmethod(this); } else if (klass->is_loader_alive()) { // The GC may clean dependency contexts concurrently and in parallel. InstanceKlass::cast(klass)->clean_dependency_context(); } } } } } // ------------------------------------------------------------------ // post_compiled_method_load_event // new method for install_code() path // Transfer information from compilation to jvmti void nmethod::post_compiled_method_load_event() { Method* moop = method(); HOTSPOT_COMPILED_METHOD_LOAD( (char *) moop->klass_name()->bytes(), moop->klass_name()->utf8_length(), (char *) moop->name()->bytes(), moop->name()->utf8_length(), (char *) moop->signature()->bytes(), moop->signature()->utf8_length(), insts_begin(), insts_size()); if (JvmtiExport::should_post_compiled_method_load() || JvmtiExport::should_post_compiled_method_unload()) { get_and_cache_jmethod_id(); } if (JvmtiExport::should_post_compiled_method_load()) { // Let the Service thread (which is a real Java thread) post the event MutexLocker ml(Service_lock, Mutex::_no_safepoint_check_flag); JvmtiDeferredEventQueue::enqueue( JvmtiDeferredEvent::compiled_method_load_event(this)); } } jmethodID nmethod::get_and_cache_jmethod_id() { if (_jmethod_id == NULL) { // Cache the jmethod_id since it can no longer be looked up once the // method itself has been marked for unloading. _jmethod_id = method()->jmethod_id(); } return _jmethod_id; } void nmethod::post_compiled_method_unload() { if (unload_reported()) { // During unloading we transition to unloaded and then to zombie // and the unloading is reported during the first transition. return; } assert(_method != NULL && !is_unloaded(), "just checking"); DTRACE_METHOD_UNLOAD_PROBE(method()); // If a JVMTI agent has enabled the CompiledMethodUnload event then // post the event. Sometime later this nmethod will be made a zombie // by the sweeper but the Method* will not be valid at that point. // If the _jmethod_id is null then no load event was ever requested // so don't bother posting the unload. The main reason for this is // that the jmethodID is a weak reference to the Method* so if // it's being unloaded there's no way to look it up since the weak // ref will have been cleared. if (_jmethod_id != NULL && JvmtiExport::should_post_compiled_method_unload()) { assert(!unload_reported(), "already unloaded"); JvmtiDeferredEvent event = JvmtiDeferredEvent::compiled_method_unload_event(this, _jmethod_id, insts_begin()); MutexLocker ml(Service_lock, Mutex::_no_safepoint_check_flag); JvmtiDeferredEventQueue::enqueue(event); } // The JVMTI CompiledMethodUnload event can be enabled or disabled at // any time. As the nmethod is being unloaded now we mark it has // having the unload event reported - this will ensure that we don't // attempt to report the event in the unlikely scenario where the // event is enabled at the time the nmethod is made a zombie. set_unload_reported(); } // Iterate over metadata calling this function. Used by RedefineClasses void nmethod::metadata_do(MetadataClosure* f) { { // Visit all immediate references that are embedded in the instruction stream. RelocIterator iter(this, oops_reloc_begin()); while (iter.next()) { if (iter.type() == relocInfo::metadata_type) { metadata_Relocation* r = iter.metadata_reloc(); // In this metadata, we must only follow those metadatas directly embedded in // the code. Other metadatas (oop_index>0) are seen as part of // the metadata section below. assert(1 == (r->metadata_is_immediate()) + (r->metadata_addr() >= metadata_begin() && r->metadata_addr() < metadata_end()), "metadata must be found in exactly one place"); if (r->metadata_is_immediate() && r->metadata_value() != NULL) { Metadata* md = r->metadata_value(); if (md != _method) f->do_metadata(md); } } else if (iter.type() == relocInfo::virtual_call_type) { // Check compiledIC holders associated with this nmethod ResourceMark rm; CompiledIC *ic = CompiledIC_at(&iter); if (ic->is_icholder_call()) { CompiledICHolder* cichk = ic->cached_icholder(); f->do_metadata(cichk->holder_metadata()); f->do_metadata(cichk->holder_klass()); } else { Metadata* ic_oop = ic->cached_metadata(); if (ic_oop != NULL) { f->do_metadata(ic_oop); } } } } } // Visit the metadata section for (Metadata** p = metadata_begin(); p < metadata_end(); p++) { if (*p == Universe::non_oop_word() || *p == NULL) continue; // skip non-oops Metadata* md = *p; f->do_metadata(md); } // Visit metadata not embedded in the other places. if (_method != NULL) f->do_metadata(_method); } // The _is_unloading_state encodes a tuple comprising the unloading cycle // and the result of IsUnloadingBehaviour::is_unloading() fpr that cycle. // This is the bit layout of the _is_unloading_state byte: 00000CCU // CC refers to the cycle, which has 2 bits, and U refers to the result of // IsUnloadingBehaviour::is_unloading() for that unloading cycle. class IsUnloadingState: public AllStatic { static const uint8_t _is_unloading_mask = 1; static const uint8_t _is_unloading_shift = 0; static const uint8_t _unloading_cycle_mask = 6; static const uint8_t _unloading_cycle_shift = 1; static uint8_t set_is_unloading(uint8_t state, bool value) { state &= ~_is_unloading_mask; if (value) { state |= 1 << _is_unloading_shift; } assert(is_unloading(state) == value, "unexpected unloading cycle overflow"); return state; } static uint8_t set_unloading_cycle(uint8_t state, uint8_t value) { state &= ~_unloading_cycle_mask; state |= value << _unloading_cycle_shift; assert(unloading_cycle(state) == value, "unexpected unloading cycle overflow"); return state; } public: static bool is_unloading(uint8_t state) { return (state & _is_unloading_mask) >> _is_unloading_shift == 1; } static uint8_t unloading_cycle(uint8_t state) { return (state & _unloading_cycle_mask) >> _unloading_cycle_shift; } static uint8_t create(bool is_unloading, uint8_t unloading_cycle) { uint8_t state = 0; state = set_is_unloading(state, is_unloading); state = set_unloading_cycle(state, unloading_cycle); return state; } }; bool nmethod::is_unloading() { uint8_t state = RawAccess::load(&_is_unloading_state); bool state_is_unloading = IsUnloadingState::is_unloading(state); uint8_t state_unloading_cycle = IsUnloadingState::unloading_cycle(state); if (state_is_unloading) { return true; } uint8_t current_cycle = CodeCache::unloading_cycle(); if (state_unloading_cycle == current_cycle) { return false; } // The IsUnloadingBehaviour is responsible for checking if there are any dead // oops in the CompiledMethod, by calling oops_do on it. state_unloading_cycle = current_cycle; if (is_zombie()) { // Zombies without calculated unloading epoch are never unloading due to GC. // There are no races where a previously observed is_unloading() nmethod // suddenly becomes not is_unloading() due to here being observed as zombie. // With STW unloading, all is_alive() && is_unloading() nmethods are unlinked // and unloaded in the safepoint. That makes races where an nmethod is first // observed as is_alive() && is_unloading() and subsequently observed as // is_zombie() impossible. // With concurrent unloading, all references to is_unloading() nmethods are // first unlinked (e.g. IC caches and dependency contexts). Then a global // handshake operation is performed with all JavaThreads before finally // unloading the nmethods. The sweeper never converts is_alive() && is_unloading() // nmethods to zombies; it waits for them to become is_unloaded(). So before // the global handshake, it is impossible for is_unloading() nmethods to // racingly become is_zombie(). And is_unloading() is calculated for all is_alive() // nmethods before taking that global handshake, meaning that it will never // be recalculated after the handshake. // After that global handshake, is_unloading() nmethods are only observable // to the iterators, and they will never trigger recomputation of the cached // is_unloading_state, and hence may not suffer from such races. state_is_unloading = false; } else { state_is_unloading = IsUnloadingBehaviour::current()->is_unloading(this); } state = IsUnloadingState::create(state_is_unloading, state_unloading_cycle); RawAccess::store(&_is_unloading_state, state); return state_is_unloading; } void nmethod::clear_unloading_state() { uint8_t state = IsUnloadingState::create(false, CodeCache::unloading_cycle()); RawAccess::store(&_is_unloading_state, state); } // This is called at the end of the strong tracing/marking phase of a // GC to unload an nmethod if it contains otherwise unreachable // oops. void nmethod::do_unloading(bool unloading_occurred) { // Make sure the oop's ready to receive visitors assert(!is_zombie() && !is_unloaded(), "should not call follow on zombie or unloaded nmethod"); if (is_unloading()) { make_unloaded(); } else { guarantee(unload_nmethod_caches(unloading_occurred), "Should not need transition stubs"); } } void nmethod::oops_do(OopClosure* f, bool allow_dead) { // make sure the oops ready to receive visitors assert(allow_dead || is_alive(), "should not call follow on dead nmethod"); // Prevent extra code cache walk for platforms that don't have immediate oops. if (relocInfo::mustIterateImmediateOopsInCode()) { RelocIterator iter(this, oops_reloc_begin()); while (iter.next()) { if (iter.type() == relocInfo::oop_type ) { oop_Relocation* r = iter.oop_reloc(); // In this loop, we must only follow those oops directly embedded in // the code. Other oops (oop_index>0) are seen as part of scopes_oops. assert(1 == (r->oop_is_immediate()) + (r->oop_addr() >= oops_begin() && r->oop_addr() < oops_end()), "oop must be found in exactly one place"); if (r->oop_is_immediate() && r->oop_value() != NULL) { f->do_oop(r->oop_addr()); } } } } // Scopes // This includes oop constants not inlined in the code stream. for (oop* p = oops_begin(); p < oops_end(); p++) { if (*p == Universe::non_oop_word()) continue; // skip non-oops f->do_oop(p); } } #define NMETHOD_SENTINEL ((nmethod*)badAddress) nmethod* volatile nmethod::_oops_do_mark_nmethods; // An nmethod is "marked" if its _mark_link is set non-null. // Even if it is the end of the linked list, it will have a non-null link value, // as long as it is on the list. // This code must be MP safe, because it is used from parallel GC passes. bool nmethod::test_set_oops_do_mark() { assert(nmethod::oops_do_marking_is_active(), "oops_do_marking_prologue must be called"); if (_oops_do_mark_link == NULL) { // Claim this nmethod for this thread to mark. if (Atomic::replace_if_null(NMETHOD_SENTINEL, &_oops_do_mark_link)) { // Atomically append this nmethod (now claimed) to the head of the list: nmethod* observed_mark_nmethods = _oops_do_mark_nmethods; for (;;) { nmethod* required_mark_nmethods = observed_mark_nmethods; _oops_do_mark_link = required_mark_nmethods; observed_mark_nmethods = Atomic::cmpxchg(this, &_oops_do_mark_nmethods, required_mark_nmethods); if (observed_mark_nmethods == required_mark_nmethods) break; } // Mark was clear when we first saw this guy. LogTarget(Trace, gc, nmethod) lt; if (lt.is_enabled()) { LogStream ls(lt); CompileTask::print(&ls, this, "oops_do, mark", /*short_form:*/ true); } return false; } } // On fall through, another racing thread marked this nmethod before we did. return true; } void nmethod::oops_do_marking_prologue() { log_trace(gc, nmethod)("oops_do_marking_prologue"); assert(_oops_do_mark_nmethods == NULL, "must not call oops_do_marking_prologue twice in a row"); // We use cmpxchg instead of regular assignment here because the user // may fork a bunch of threads, and we need them all to see the same state. nmethod* observed = Atomic::cmpxchg(NMETHOD_SENTINEL, &_oops_do_mark_nmethods, (nmethod*)NULL); guarantee(observed == NULL, "no races in this sequential code"); } void nmethod::oops_do_marking_epilogue() { assert(_oops_do_mark_nmethods != NULL, "must not call oops_do_marking_epilogue twice in a row"); nmethod* cur = _oops_do_mark_nmethods; while (cur != NMETHOD_SENTINEL) { assert(cur != NULL, "not NULL-terminated"); nmethod* next = cur->_oops_do_mark_link; cur->_oops_do_mark_link = NULL; DEBUG_ONLY(cur->verify_oop_relocations()); LogTarget(Trace, gc, nmethod) lt; if (lt.is_enabled()) { LogStream ls(lt); CompileTask::print(&ls, cur, "oops_do, unmark", /*short_form:*/ true); } cur = next; } nmethod* required = _oops_do_mark_nmethods; nmethod* observed = Atomic::cmpxchg((nmethod*)NULL, &_oops_do_mark_nmethods, required); guarantee(observed == required, "no races in this sequential code"); log_trace(gc, nmethod)("oops_do_marking_epilogue"); } inline bool includes(void* p, void* from, void* to) { return from <= p && p < to; } void nmethod::copy_scopes_pcs(PcDesc* pcs, int count) { assert(count >= 2, "must be sentinel values, at least"); #ifdef ASSERT // must be sorted and unique; we do a binary search in find_pc_desc() int prev_offset = pcs[0].pc_offset(); assert(prev_offset == PcDesc::lower_offset_limit, "must start with a sentinel"); for (int i = 1; i < count; i++) { int this_offset = pcs[i].pc_offset(); assert(this_offset > prev_offset, "offsets must be sorted"); prev_offset = this_offset; } assert(prev_offset == PcDesc::upper_offset_limit, "must end with a sentinel"); #endif //ASSERT // Search for MethodHandle invokes and tag the nmethod. for (int i = 0; i < count; i++) { if (pcs[i].is_method_handle_invoke()) { set_has_method_handle_invokes(true); break; } } assert(has_method_handle_invokes() == (_deopt_mh_handler_begin != NULL), "must have deopt mh handler"); int size = count * sizeof(PcDesc); assert(scopes_pcs_size() >= size, "oob"); memcpy(scopes_pcs_begin(), pcs, size); // Adjust the final sentinel downward. PcDesc* last_pc = &scopes_pcs_begin()[count-1]; assert(last_pc->pc_offset() == PcDesc::upper_offset_limit, "sanity"); last_pc->set_pc_offset(content_size() + 1); for (; last_pc + 1 < scopes_pcs_end(); last_pc += 1) { // Fill any rounding gaps with copies of the last record. last_pc[1] = last_pc[0]; } // The following assert could fail if sizeof(PcDesc) is not // an integral multiple of oopSize (the rounding term). // If it fails, change the logic to always allocate a multiple // of sizeof(PcDesc), and fill unused words with copies of *last_pc. assert(last_pc + 1 == scopes_pcs_end(), "must match exactly"); } void nmethod::copy_scopes_data(u_char* buffer, int size) { assert(scopes_data_size() >= size, "oob"); memcpy(scopes_data_begin(), buffer, size); } #ifdef ASSERT static PcDesc* linear_search(const PcDescSearch& search, int pc_offset, bool approximate) { PcDesc* lower = search.scopes_pcs_begin(); PcDesc* upper = search.scopes_pcs_end(); lower += 1; // exclude initial sentinel PcDesc* res = NULL; for (PcDesc* p = lower; p < upper; p++) { NOT_PRODUCT(--pc_nmethod_stats.pc_desc_tests); // don't count this call to match_desc if (match_desc(p, pc_offset, approximate)) { if (res == NULL) res = p; else res = (PcDesc*) badAddress; } } return res; } #endif // Finds a PcDesc with real-pc equal to "pc" PcDesc* PcDescContainer::find_pc_desc_internal(address pc, bool approximate, const PcDescSearch& search) { address base_address = search.code_begin(); if ((pc < base_address) || (pc - base_address) >= (ptrdiff_t) PcDesc::upper_offset_limit) { return NULL; // PC is wildly out of range } int pc_offset = (int) (pc - base_address); // Check the PcDesc cache if it contains the desired PcDesc // (This as an almost 100% hit rate.) PcDesc* res = _pc_desc_cache.find_pc_desc(pc_offset, approximate); if (res != NULL) { assert(res == linear_search(search, pc_offset, approximate), "cache ok"); return res; } // Fallback algorithm: quasi-linear search for the PcDesc // Find the last pc_offset less than the given offset. // The successor must be the required match, if there is a match at all. // (Use a fixed radix to avoid expensive affine pointer arithmetic.) PcDesc* lower = search.scopes_pcs_begin(); PcDesc* upper = search.scopes_pcs_end(); upper -= 1; // exclude final sentinel if (lower >= upper) return NULL; // native method; no PcDescs at all #define assert_LU_OK \ /* invariant on lower..upper during the following search: */ \ assert(lower->pc_offset() < pc_offset, "sanity"); \ assert(upper->pc_offset() >= pc_offset, "sanity") assert_LU_OK; // Use the last successful return as a split point. PcDesc* mid = _pc_desc_cache.last_pc_desc(); NOT_PRODUCT(++pc_nmethod_stats.pc_desc_searches); if (mid->pc_offset() < pc_offset) { lower = mid; } else { upper = mid; } // Take giant steps at first (4096, then 256, then 16, then 1) const int LOG2_RADIX = 4 /*smaller steps in debug mode:*/ debug_only(-1); const int RADIX = (1 << LOG2_RADIX); for (int step = (1 << (LOG2_RADIX*3)); step > 1; step >>= LOG2_RADIX) { while ((mid = lower + step) < upper) { assert_LU_OK; NOT_PRODUCT(++pc_nmethod_stats.pc_desc_searches); if (mid->pc_offset() < pc_offset) { lower = mid; } else { upper = mid; break; } } assert_LU_OK; } // Sneak up on the value with a linear search of length ~16. while (true) { assert_LU_OK; mid = lower + 1; NOT_PRODUCT(++pc_nmethod_stats.pc_desc_searches); if (mid->pc_offset() < pc_offset) { lower = mid; } else { upper = mid; break; } } #undef assert_LU_OK if (match_desc(upper, pc_offset, approximate)) { assert(upper == linear_search(search, pc_offset, approximate), "search ok"); _pc_desc_cache.add_pc_desc(upper); return upper; } else { assert(NULL == linear_search(search, pc_offset, approximate), "search ok"); return NULL; } } void nmethod::check_all_dependencies(DepChange& changes) { // Checked dependencies are allocated into this ResourceMark ResourceMark rm; // Turn off dependency tracing while actually testing dependencies. NOT_PRODUCT( FlagSetting fs(TraceDependencies, false) ); typedef ResourceHashtable DepTable; DepTable* table = new DepTable(); // Iterate over live nmethods and check dependencies of all nmethods that are not // marked for deoptimization. A particular dependency is only checked once. NMethodIterator iter(NMethodIterator::only_alive_and_not_unloading); while(iter.next()) { nmethod* nm = iter.method(); // Only notify for live nmethods if (!nm->is_marked_for_deoptimization()) { for (Dependencies::DepStream deps(nm); deps.next(); ) { // Construct abstraction of a dependency. DependencySignature* current_sig = new DependencySignature(deps); // Determine if dependency is already checked. table->put(...) returns // 'true' if the dependency is added (i.e., was not in the hashtable). if (table->put(*current_sig, 1)) { if (deps.check_dependency() != NULL) { // Dependency checking failed. Print out information about the failed // dependency and finally fail with an assert. We can fail here, since // dependency checking is never done in a product build. tty->print_cr("Failed dependency:"); changes.print(); nm->print(); nm->print_dependencies(); assert(false, "Should have been marked for deoptimization"); } } } } } } bool nmethod::check_dependency_on(DepChange& changes) { // What has happened: // 1) a new class dependee has been added // 2) dependee and all its super classes have been marked bool found_check = false; // set true if we are upset for (Dependencies::DepStream deps(this); deps.next(); ) { // Evaluate only relevant dependencies. if (deps.spot_check_dependency_at(changes) != NULL) { found_check = true; NOT_DEBUG(break); } } return found_check; } // Called from mark_for_deoptimization, when dependee is invalidated. bool nmethod::is_dependent_on_method(Method* dependee) { for (Dependencies::DepStream deps(this); deps.next(); ) { if (deps.type() != Dependencies::evol_method) continue; Method* method = deps.method_argument(0); if (method == dependee) return true; } return false; } bool nmethod::is_patchable_at(address instr_addr) { assert(insts_contains(instr_addr), "wrong nmethod used"); if (is_zombie()) { // a zombie may never be patched return false; } return true; } void nmethod_init() { // make sure you didn't forget to adjust the filler fields assert(sizeof(nmethod) % oopSize == 0, "nmethod size must be multiple of a word"); } //------------------------------------------------------------------------------------------- // QQQ might we make this work from a frame?? nmethodLocker::nmethodLocker(address pc) { CodeBlob* cb = CodeCache::find_blob(pc); guarantee(cb != NULL && cb->is_compiled(), "bad pc for a nmethod found"); _nm = cb->as_compiled_method(); lock_nmethod(_nm); } // Only JvmtiDeferredEvent::compiled_method_unload_event() // should pass zombie_ok == true. void nmethodLocker::lock_nmethod(CompiledMethod* cm, bool zombie_ok) { if (cm == NULL) return; if (cm->is_aot()) return; // FIXME: Revisit once _lock_count is added to aot_method nmethod* nm = cm->as_nmethod(); Atomic::inc(&nm->_lock_count); assert(zombie_ok || !nm->is_zombie(), "cannot lock a zombie method: %p", nm); } void nmethodLocker::unlock_nmethod(CompiledMethod* cm) { if (cm == NULL) return; if (cm->is_aot()) return; // FIXME: Revisit once _lock_count is added to aot_method nmethod* nm = cm->as_nmethod(); Atomic::dec(&nm->_lock_count); assert(nm->_lock_count >= 0, "unmatched nmethod lock/unlock"); } // ----------------------------------------------------------------------------- // Verification class VerifyOopsClosure: public OopClosure { nmethod* _nm; bool _ok; public: VerifyOopsClosure(nmethod* nm) : _nm(nm), _ok(true) { } bool ok() { return _ok; } virtual void do_oop(oop* p) { if (oopDesc::is_oop_or_null(*p)) return; // Print diagnostic information before calling print_nmethod(). // Assertions therein might prevent call from returning. tty->print_cr("*** non-oop " PTR_FORMAT " found at " PTR_FORMAT " (offset %d)", p2i(*p), p2i(p), (int)((intptr_t)p - (intptr_t)_nm)); if (_ok) { _nm->print_nmethod(true); _ok = false; } } virtual void do_oop(narrowOop* p) { ShouldNotReachHere(); } }; void nmethod::verify() { // Hmm. OSR methods can be deopted but not marked as zombie or not_entrant // seems odd. if (is_zombie() || is_not_entrant() || is_unloaded()) return; // Make sure all the entry points are correctly aligned for patching. NativeJump::check_verified_entry_alignment(entry_point(), verified_entry_point()); // assert(oopDesc::is_oop(method()), "must be valid"); ResourceMark rm; if (!CodeCache::contains(this)) { fatal("nmethod at " INTPTR_FORMAT " not in zone", p2i(this)); } if(is_native_method() ) return; nmethod* nm = CodeCache::find_nmethod(verified_entry_point()); if (nm != this) { fatal("findNMethod did not find this nmethod (" INTPTR_FORMAT ")", p2i(this)); } for (PcDesc* p = scopes_pcs_begin(); p < scopes_pcs_end(); p++) { if (! p->verify(this)) { tty->print_cr("\t\tin nmethod at " INTPTR_FORMAT " (pcs)", p2i(this)); } } #ifdef ASSERT #if INCLUDE_JVMCI { // Verify that implicit exceptions that deoptimize have a PcDesc and OopMap ImmutableOopMapSet* oms = oop_maps(); ImplicitExceptionTable implicit_table(this); for (uint i = 0; i < implicit_table.len(); i++) { int exec_offset = (int) implicit_table.get_exec_offset(i); if (implicit_table.get_exec_offset(i) == implicit_table.get_cont_offset(i)) { assert(pc_desc_at(code_begin() + exec_offset) != NULL, "missing PcDesc"); bool found = false; for (int i = 0, imax = oms->count(); i < imax; i++) { if (oms->pair_at(i)->pc_offset() == exec_offset) { found = true; break; } } assert(found, "missing oopmap"); } } } #endif #endif VerifyOopsClosure voc(this); oops_do(&voc); assert(voc.ok(), "embedded oops must be OK"); Universe::heap()->verify_nmethod(this); verify_scopes(); } void nmethod::verify_interrupt_point(address call_site) { // Verify IC only when nmethod installation is finished. if (!is_not_installed()) { if (CompiledICLocker::is_safe(this)) { CompiledIC_at(this, call_site); CHECK_UNHANDLED_OOPS_ONLY(Thread::current()->clear_unhandled_oops()); } else { CompiledICLocker ml_verify(this); CompiledIC_at(this, call_site); } } PcDesc* pd = pc_desc_at(nativeCall_at(call_site)->return_address()); assert(pd != NULL, "PcDesc must exist"); for (ScopeDesc* sd = new ScopeDesc(this, pd->scope_decode_offset(), pd->obj_decode_offset(), pd->should_reexecute(), pd->rethrow_exception(), pd->return_oop()); !sd->is_top(); sd = sd->sender()) { sd->verify(); } } void nmethod::verify_scopes() { if( !method() ) return; // Runtime stubs have no scope if (method()->is_native()) return; // Ignore stub methods. // iterate through all interrupt point // and verify the debug information is valid. RelocIterator iter((nmethod*)this); while (iter.next()) { address stub = NULL; switch (iter.type()) { case relocInfo::virtual_call_type: verify_interrupt_point(iter.addr()); break; case relocInfo::opt_virtual_call_type: stub = iter.opt_virtual_call_reloc()->static_stub(false); verify_interrupt_point(iter.addr()); break; case relocInfo::static_call_type: stub = iter.static_call_reloc()->static_stub(false); //verify_interrupt_point(iter.addr()); break; case relocInfo::runtime_call_type: case relocInfo::runtime_call_w_cp_type: { address destination = iter.reloc()->value(); // Right now there is no way to find out which entries support // an interrupt point. It would be nice if we had this // information in a table. break; } default: break; } assert(stub == NULL || stub_contains(stub), "static call stub outside stub section"); } } // ----------------------------------------------------------------------------- // Printing operations void nmethod::print() const { ttyLocker ttyl; // keep the following output all in one block print(tty); } void nmethod::print(outputStream* st) const { ResourceMark rm; st->print("Compiled method "); if (is_compiled_by_c1()) { st->print("(c1) "); } else if (is_compiled_by_c2()) { st->print("(c2) "); } else if (is_compiled_by_jvmci()) { st->print("(JVMCI) "); } else { st->print("(n/a) "); } print_on(tty, NULL); if (WizardMode) { st->print("((nmethod*) " INTPTR_FORMAT ") ", p2i(this)); st->print(" for method " INTPTR_FORMAT , p2i(method())); st->print(" { "); st->print_cr("%s ", state()); st->print_cr("}:"); } if (size () > 0) st->print_cr(" total in heap [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(this), p2i(this) + size(), size()); if (relocation_size () > 0) st->print_cr(" relocation [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(relocation_begin()), p2i(relocation_end()), relocation_size()); if (consts_size () > 0) st->print_cr(" constants [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(consts_begin()), p2i(consts_end()), consts_size()); if (insts_size () > 0) st->print_cr(" main code [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(insts_begin()), p2i(insts_end()), insts_size()); if (stub_size () > 0) st->print_cr(" stub code [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(stub_begin()), p2i(stub_end()), stub_size()); if (oops_size () > 0) st->print_cr(" oops [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(oops_begin()), p2i(oops_end()), oops_size()); if (metadata_size () > 0) st->print_cr(" metadata [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(metadata_begin()), p2i(metadata_end()), metadata_size()); if (scopes_data_size () > 0) st->print_cr(" scopes data [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(scopes_data_begin()), p2i(scopes_data_end()), scopes_data_size()); if (scopes_pcs_size () > 0) st->print_cr(" scopes pcs [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(scopes_pcs_begin()), p2i(scopes_pcs_end()), scopes_pcs_size()); if (dependencies_size () > 0) st->print_cr(" dependencies [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(dependencies_begin()), p2i(dependencies_end()), dependencies_size()); if (handler_table_size() > 0) st->print_cr(" handler table [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(handler_table_begin()), p2i(handler_table_end()), handler_table_size()); if (nul_chk_table_size() > 0) st->print_cr(" nul chk table [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(nul_chk_table_begin()), p2i(nul_chk_table_end()), nul_chk_table_size()); #if INCLUDE_JVMCI if (speculations_size () > 0) st->print_cr(" speculations [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(speculations_begin()), p2i(speculations_end()), speculations_size()); if (jvmci_data_size () > 0) st->print_cr(" JVMCI data [" INTPTR_FORMAT "," INTPTR_FORMAT "] = %d", p2i(jvmci_data_begin()), p2i(jvmci_data_end()), jvmci_data_size()); #endif } void nmethod::print_code() { HandleMark hm; ResourceMark m; ttyLocker ttyl; // Call the specialized decode method of this class. decode(tty); } #ifndef PRODUCT // called InstanceKlass methods are available only then. Declared as PRODUCT_RETURN void nmethod::print_dependencies() { ResourceMark rm; ttyLocker ttyl; // keep the following output all in one block tty->print_cr("Dependencies:"); for (Dependencies::DepStream deps(this); deps.next(); ) { deps.print_dependency(); Klass* ctxk = deps.context_type(); if (ctxk != NULL) { if (ctxk->is_instance_klass() && InstanceKlass::cast(ctxk)->is_dependent_nmethod(this)) { tty->print_cr(" [nmethod<=klass]%s", ctxk->external_name()); } } deps.log_dependency(); // put it into the xml log also } } #endif #if defined(SUPPORT_DATA_STRUCTS) // Print the oops from the underlying CodeBlob. void nmethod::print_oops(outputStream* st) { HandleMark hm; ResourceMark m; st->print("Oops:"); if (oops_begin() < oops_end()) { st->cr(); for (oop* p = oops_begin(); p < oops_end(); p++) { Disassembler::print_location((unsigned char*)p, (unsigned char*)oops_begin(), (unsigned char*)oops_end(), st, true, false); st->print(PTR_FORMAT " ", *((uintptr_t*)p)); if (*p == Universe::non_oop_word()) { st->print_cr("NON_OOP"); continue; // skip non-oops } if (*p == NULL) { st->print_cr("NULL-oop"); continue; // skip non-oops } (*p)->print_value_on(st); st->cr(); } } else { st->print_cr(" "); } } // Print metadata pool. void nmethod::print_metadata(outputStream* st) { HandleMark hm; ResourceMark m; st->print("Metadata:"); if (metadata_begin() < metadata_end()) { st->cr(); for (Metadata** p = metadata_begin(); p < metadata_end(); p++) { Disassembler::print_location((unsigned char*)p, (unsigned char*)metadata_begin(), (unsigned char*)metadata_end(), st, true, false); st->print(PTR_FORMAT " ", *((uintptr_t*)p)); if (*p && *p != Universe::non_oop_word()) { (*p)->print_value_on(st); } st->cr(); } } else { st->print_cr(" "); } } #ifndef PRODUCT // ScopeDesc::print_on() is available only then. Declared as PRODUCT_RETURN void nmethod::print_scopes_on(outputStream* st) { // Find the first pc desc for all scopes in the code and print it. ResourceMark rm; st->print("scopes:"); if (scopes_pcs_begin() < scopes_pcs_end()) { st->cr(); for (PcDesc* p = scopes_pcs_begin(); p < scopes_pcs_end(); p++) { if (p->scope_decode_offset() == DebugInformationRecorder::serialized_null) continue; ScopeDesc* sd = scope_desc_at(p->real_pc(this)); while (sd != NULL) { sd->print_on(st, p); // print output ends with a newline sd = sd->sender(); } } } else { st->print_cr(" "); } } #endif #ifndef PRODUCT // RelocIterator does support printing only then. void nmethod::print_relocations() { ResourceMark m; // in case methods get printed via the debugger tty->print_cr("relocations:"); RelocIterator iter(this); iter.print(); } #endif void nmethod::print_pcs_on(outputStream* st) { ResourceMark m; // in case methods get printed via debugger st->print("pc-bytecode offsets:"); if (scopes_pcs_begin() < scopes_pcs_end()) { st->cr(); for (PcDesc* p = scopes_pcs_begin(); p < scopes_pcs_end(); p++) { p->print_on(st, this); // print output ends with a newline } } else { st->print_cr(" "); } } void nmethod::print_handler_table() { ExceptionHandlerTable(this).print(); } void nmethod::print_nul_chk_table() { ImplicitExceptionTable(this).print(code_begin()); } void nmethod::print_recorded_oops() { const int n = oops_count(); const int log_n = (n<10) ? 1 : (n<100) ? 2 : (n<1000) ? 3 : (n<10000) ? 4 : 6; tty->print("Recorded oops:"); if (n > 0) { tty->cr(); for (int i = 0; i < n; i++) { oop o = oop_at(i); tty->print("#%*d: " INTPTR_FORMAT " ", log_n, i, p2i(o)); if (o == (oop)Universe::non_oop_word()) { tty->print("non-oop word"); } else if (o == NULL) { tty->print("NULL-oop"); } else { o->print_value_on(tty); } tty->cr(); } } else { tty->print_cr(" "); } } void nmethod::print_recorded_metadata() { const int n = metadata_count(); const int log_n = (n<10) ? 1 : (n<100) ? 2 : (n<1000) ? 3 : (n<10000) ? 4 : 6; tty->print("Recorded metadata:"); if (n > 0) { tty->cr(); for (int i = 0; i < n; i++) { Metadata* m = metadata_at(i); tty->print("#%*d: " INTPTR_FORMAT " ", log_n, i, p2i(m)); if (m == (Metadata*)Universe::non_oop_word()) { tty->print("non-metadata word"); } else if (m == NULL) { tty->print("NULL-oop"); } else { Metadata::print_value_on_maybe_null(tty, m); } tty->cr(); } } else { tty->print_cr(" "); } } #endif #if defined(SUPPORT_ASSEMBLY) || defined(SUPPORT_ABSTRACT_ASSEMBLY) void nmethod::print_constant_pool(outputStream* st) { //----------------------------------- //---< Print the constant pool >--- //----------------------------------- int consts_size = this->consts_size(); if ( consts_size > 0 ) { unsigned char* cstart = this->consts_begin(); unsigned char* cp = cstart; unsigned char* cend = cp + consts_size; unsigned int bytes_per_line = 4; unsigned int CP_alignment = 8; unsigned int n; st->cr(); //---< print CP header to make clear what's printed >--- if( ((uintptr_t)cp&(CP_alignment-1)) == 0 ) { n = bytes_per_line; st->print_cr("[Constant Pool]"); Disassembler::print_location(cp, cstart, cend, st, true, true); Disassembler::print_hexdata(cp, n, st, true); st->cr(); } else { n = (uintptr_t)cp&(bytes_per_line-1); st->print_cr("[Constant Pool (unaligned)]"); } //---< print CP contents, bytes_per_line at a time >--- while (cp < cend) { Disassembler::print_location(cp, cstart, cend, st, true, false); Disassembler::print_hexdata(cp, n, st, false); cp += n; n = bytes_per_line; st->cr(); } //---< Show potential alignment gap between constant pool and code >--- cend = code_begin(); if( cp < cend ) { n = 4; st->print_cr("[Code entry alignment]"); while (cp < cend) { Disassembler::print_location(cp, cstart, cend, st, false, false); cp += n; st->cr(); } } } else { st->print_cr("[Constant Pool (empty)]"); } st->cr(); } #endif // Disassemble this nmethod. // Print additional debug information, if requested. This could be code // comments, block comments, profiling counters, etc. // The undisassembled format is useful no disassembler library is available. // The resulting hex dump (with markers) can be disassembled later, or on // another system, when/where a disassembler library is available. void nmethod::decode2(outputStream* ost) const { // Called from frame::back_trace_with_decode without ResourceMark. ResourceMark rm; // Make sure we have a valid stream to print on. outputStream* st = ost ? ost : tty; #if defined(SUPPORT_ABSTRACT_ASSEMBLY) && ! defined(SUPPORT_ASSEMBLY) const bool use_compressed_format = true; const bool compressed_with_comments = use_compressed_format && (AbstractDisassembler::show_comment() || AbstractDisassembler::show_block_comment()); #else const bool use_compressed_format = Disassembler::is_abstract(); const bool compressed_with_comments = use_compressed_format && (AbstractDisassembler::show_comment() || AbstractDisassembler::show_block_comment()); #endif st->cr(); this->print(st); st->cr(); #if defined(SUPPORT_ASSEMBLY) //---------------------------------- //---< Print real disassembly >--- //---------------------------------- if (! use_compressed_format) { Disassembler::decode(const_cast(this), st); return; } #endif #if defined(SUPPORT_ABSTRACT_ASSEMBLY) // Compressed undisassembled disassembly format. // The following stati are defined/supported: // = 0 - currently at bol() position, nothing printed yet on current line. // = 1 - currently at position after print_location(). // > 1 - in the midst of printing instruction stream bytes. int compressed_format_idx = 0; int code_comment_column = 0; const int instr_maxlen = Assembler::instr_maxlen(); const uint tabspacing = 8; unsigned char* start = this->code_begin(); unsigned char* p = this->code_begin(); unsigned char* end = this->code_end(); unsigned char* pss = p; // start of a code section (used for offsets) if ((start == NULL) || (end == NULL)) { st->print_cr("PrintAssembly not possible due to uninitialized section pointers"); return; } #endif #if defined(SUPPORT_ABSTRACT_ASSEMBLY) //---< plain abstract disassembly, no comments or anything, just section headers >--- if (use_compressed_format && ! compressed_with_comments) { const_cast(this)->print_constant_pool(st); //---< Open the output (Marker for post-mortem disassembler) >--- st->print_cr("[MachCode]"); const char* header = NULL; address p0 = p; while (p < end) { address pp = p; while ((p < end) && (header == NULL)) { header = nmethod_section_label(p); pp = p; p += Assembler::instr_len(p); } if (pp > p0) { AbstractDisassembler::decode_range_abstract(p0, pp, start, end, st, Assembler::instr_maxlen()); p0 = pp; p = pp; header = NULL; } else if (header != NULL) { st->bol(); st->print_cr("%s", header); header = NULL; } } //---< Close the output (Marker for post-mortem disassembler) >--- st->bol(); st->print_cr("[/MachCode]"); return; } #endif #if defined(SUPPORT_ABSTRACT_ASSEMBLY) //---< abstract disassembly with comments and section headers merged in >--- if (compressed_with_comments) { const_cast(this)->print_constant_pool(st); //---< Open the output (Marker for post-mortem disassembler) >--- st->print_cr("[MachCode]"); while ((p < end) && (p != NULL)) { const int instruction_size_in_bytes = Assembler::instr_len(p); //---< Block comments for nmethod. Interrupts instruction stream, if any. >--- // Outputs a bol() before and a cr() after, but only if a comment is printed. // Prints nmethod_section_label as well. if (AbstractDisassembler::show_block_comment()) { print_block_comment(st, p); if (st->position() == 0) { compressed_format_idx = 0; } } //---< New location information after line break >--- if (compressed_format_idx == 0) { code_comment_column = Disassembler::print_location(p, pss, end, st, false, false); compressed_format_idx = 1; } //---< Code comment for current instruction. Address range [p..(p+len)) >--- unsigned char* p_end = p + (ssize_t)instruction_size_in_bytes; S390_ONLY(if (p_end > end) p_end = end;) // avoid getting past the end if (AbstractDisassembler::show_comment() && const_cast(this)->has_code_comment(p, p_end)) { //---< interrupt instruction byte stream for code comment >--- if (compressed_format_idx > 1) { st->cr(); // interrupt byte stream st->cr(); // add an empty line code_comment_column = Disassembler::print_location(p, pss, end, st, false, false); } const_cast(this)->print_code_comment_on(st, code_comment_column, p, p_end ); st->bol(); compressed_format_idx = 0; } //---< New location information after line break >--- if (compressed_format_idx == 0) { code_comment_column = Disassembler::print_location(p, pss, end, st, false, false); compressed_format_idx = 1; } //---< Nicely align instructions for readability >--- if (compressed_format_idx > 1) { Disassembler::print_delimiter(st); } //---< Now, finally, print the actual instruction bytes >--- unsigned char* p0 = p; p = Disassembler::decode_instruction_abstract(p, st, instruction_size_in_bytes, instr_maxlen); compressed_format_idx += p - p0; if (Disassembler::start_newline(compressed_format_idx-1)) { st->cr(); compressed_format_idx = 0; } } //---< Close the output (Marker for post-mortem disassembler) >--- st->bol(); st->print_cr("[/MachCode]"); return; } #endif } #if defined(SUPPORT_ASSEMBLY) || defined(SUPPORT_ABSTRACT_ASSEMBLY) const char* nmethod::reloc_string_for(u_char* begin, u_char* end) { RelocIterator iter(this, begin, end); bool have_one = false; while (iter.next()) { have_one = true; switch (iter.type()) { case relocInfo::none: return "no_reloc"; case relocInfo::oop_type: { // Get a non-resizable resource-allocated stringStream. // Our callees make use of (nested) ResourceMarks. stringStream st(NEW_RESOURCE_ARRAY(char, 1024), 1024); oop_Relocation* r = iter.oop_reloc(); oop obj = r->oop_value(); st.print("oop("); if (obj == NULL) st.print("NULL"); else obj->print_value_on(&st); st.print(")"); return st.as_string(); } case relocInfo::metadata_type: { stringStream st; metadata_Relocation* r = iter.metadata_reloc(); Metadata* obj = r->metadata_value(); st.print("metadata("); if (obj == NULL) st.print("NULL"); else obj->print_value_on(&st); st.print(")"); return st.as_string(); } case relocInfo::runtime_call_type: case relocInfo::runtime_call_w_cp_type: { stringStream st; st.print("runtime_call"); CallRelocation* r = (CallRelocation*)iter.reloc(); address dest = r->destination(); CodeBlob* cb = CodeCache::find_blob(dest); if (cb != NULL) { st.print(" %s", cb->name()); } else { ResourceMark rm; const int buflen = 1024; char* buf = NEW_RESOURCE_ARRAY(char, buflen); int offset; if (os::dll_address_to_function_name(dest, buf, buflen, &offset)) { st.print(" %s", buf); if (offset != 0) { st.print("+%d", offset); } } } return st.as_string(); } case relocInfo::virtual_call_type: { stringStream st; st.print_raw("virtual_call"); virtual_call_Relocation* r = iter.virtual_call_reloc(); Method* m = r->method_value(); if (m != NULL) { assert(m->is_method(), ""); m->print_short_name(&st); } return st.as_string(); } case relocInfo::opt_virtual_call_type: { stringStream st; st.print_raw("optimized virtual_call"); opt_virtual_call_Relocation* r = iter.opt_virtual_call_reloc(); Method* m = r->method_value(); if (m != NULL) { assert(m->is_method(), ""); m->print_short_name(&st); } return st.as_string(); } case relocInfo::static_call_type: { stringStream st; st.print_raw("static_call"); static_call_Relocation* r = iter.static_call_reloc(); Method* m = r->method_value(); if (m != NULL) { assert(m->is_method(), ""); m->print_short_name(&st); } return st.as_string(); } case relocInfo::static_stub_type: return "static_stub"; case relocInfo::external_word_type: return "external_word"; case relocInfo::internal_word_type: return "internal_word"; case relocInfo::section_word_type: return "section_word"; case relocInfo::poll_type: return "poll"; case relocInfo::poll_return_type: return "poll_return"; case relocInfo::trampoline_stub_type: return "trampoline_stub"; case relocInfo::type_mask: return "type_bit_mask"; default: break; } } return have_one ? "other" : NULL; } // Return a the last scope in (begin..end] ScopeDesc* nmethod::scope_desc_in(address begin, address end) { PcDesc* p = pc_desc_near(begin+1); if (p != NULL && p->real_pc(this) <= end) { return new ScopeDesc(this, p->scope_decode_offset(), p->obj_decode_offset(), p->should_reexecute(), p->rethrow_exception(), p->return_oop()); } return NULL; } const char* nmethod::nmethod_section_label(address pos) const { const char* label = NULL; if (pos == code_begin()) label = "[Instructions begin]"; if (pos == entry_point()) label = "[Entry Point]"; if (pos == verified_entry_point()) label = "[Verified Entry Point]"; if (has_method_handle_invokes() && (pos == deopt_mh_handler_begin())) label = "[Deopt MH Handler Code]"; if (pos == consts_begin() && pos != insts_begin()) label = "[Constants]"; // Check stub_code before checking exception_handler or deopt_handler. if (pos == this->stub_begin()) label = "[Stub Code]"; if (JVMCI_ONLY(_exception_offset >= 0 &&) pos == exception_begin()) label = "[Exception Handler]"; if (JVMCI_ONLY(_deopt_handler_begin != NULL &&) pos == deopt_handler_begin()) label = "[Deopt Handler Code]"; return label; } void nmethod::print_nmethod_labels(outputStream* stream, address block_begin, bool print_section_labels) const { if (print_section_labels) { const char* label = nmethod_section_label(block_begin); if (label != NULL) { stream->bol(); stream->print_cr("%s", label); } } if (block_begin == entry_point()) { methodHandle m = method(); if (m.not_null()) { stream->print(" # "); m->print_value_on(stream); stream->cr(); } if (m.not_null() && !is_osr_method()) { ResourceMark rm; int sizeargs = m->size_of_parameters(); BasicType* sig_bt = NEW_RESOURCE_ARRAY(BasicType, sizeargs); VMRegPair* regs = NEW_RESOURCE_ARRAY(VMRegPair, sizeargs); { int sig_index = 0; if (!m->is_static()) sig_bt[sig_index++] = T_OBJECT; // 'this' for (SignatureStream ss(m->signature()); !ss.at_return_type(); ss.next()) { BasicType t = ss.type(); sig_bt[sig_index++] = t; if (type2size[t] == 2) { sig_bt[sig_index++] = T_VOID; } else { assert(type2size[t] == 1, "size is 1 or 2"); } } assert(sig_index == sizeargs, ""); } const char* spname = "sp"; // make arch-specific? intptr_t out_preserve = SharedRuntime::java_calling_convention(sig_bt, regs, sizeargs, false); int stack_slot_offset = this->frame_size() * wordSize; int tab1 = 14, tab2 = 24; int sig_index = 0; int arg_index = (m->is_static() ? 0 : -1); bool did_old_sp = false; for (SignatureStream ss(m->signature()); !ss.at_return_type(); ) { bool at_this = (arg_index == -1); bool at_old_sp = false; BasicType t = (at_this ? T_OBJECT : ss.type()); assert(t == sig_bt[sig_index], "sigs in sync"); if (at_this) stream->print(" # this: "); else stream->print(" # parm%d: ", arg_index); stream->move_to(tab1); VMReg fst = regs[sig_index].first(); VMReg snd = regs[sig_index].second(); if (fst->is_reg()) { stream->print("%s", fst->name()); if (snd->is_valid()) { stream->print(":%s", snd->name()); } } else if (fst->is_stack()) { int offset = fst->reg2stack() * VMRegImpl::stack_slot_size + stack_slot_offset; if (offset == stack_slot_offset) at_old_sp = true; stream->print("[%s+0x%x]", spname, offset); } else { stream->print("reg%d:%d??", (int)(intptr_t)fst, (int)(intptr_t)snd); } stream->print(" "); stream->move_to(tab2); stream->print("= "); if (at_this) { m->method_holder()->print_value_on(stream); } else { bool did_name = false; if (!at_this && ss.is_object()) { Symbol* name = ss.as_symbol_or_null(); if (name != NULL) { name->print_value_on(stream); did_name = true; } } if (!did_name) stream->print("%s", type2name(t)); } if (at_old_sp) { stream->print(" (%s of caller)", spname); did_old_sp = true; } stream->cr(); sig_index += type2size[t]; arg_index += 1; if (!at_this) ss.next(); } if (!did_old_sp) { stream->print(" # "); stream->move_to(tab1); stream->print("[%s+0x%x]", spname, stack_slot_offset); stream->print(" (%s of caller)", spname); stream->cr(); } } } } // Returns whether this nmethod has code comments. bool nmethod::has_code_comment(address begin, address end) { // scopes? ScopeDesc* sd = scope_desc_in(begin, end); if (sd != NULL) return true; // relocations? const char* str = reloc_string_for(begin, end); if (str != NULL) return true; // implicit exceptions? int cont_offset = ImplicitExceptionTable(this).continuation_offset(begin - code_begin()); if (cont_offset != 0) return true; return false; } void nmethod::print_code_comment_on(outputStream* st, int column, address begin, address end) { ImplicitExceptionTable implicit_table(this); int pc_offset = begin - code_begin(); int cont_offset = implicit_table.continuation_offset(pc_offset); bool oop_map_required = false; if (cont_offset != 0) { st->move_to(column, 6, 0); if (pc_offset == cont_offset) { st->print("; implicit exception: deoptimizes"); oop_map_required = true; } else { st->print("; implicit exception: dispatches to " INTPTR_FORMAT, p2i(code_begin() + cont_offset)); } } // Find an oopmap in (begin, end]. We use the odd half-closed // interval so that oop maps and scope descs which are tied to the // byte after a call are printed with the call itself. OopMaps // associated with implicit exceptions are printed with the implicit // instruction. address base = code_begin(); ImmutableOopMapSet* oms = oop_maps(); if (oms != NULL) { for (int i = 0, imax = oms->count(); i < imax; i++) { const ImmutableOopMapPair* pair = oms->pair_at(i); const ImmutableOopMap* om = pair->get_from(oms); address pc = base + pair->pc_offset(); if (pc >= begin) { #if INCLUDE_JVMCI bool is_implicit_deopt = implicit_table.continuation_offset(pair->pc_offset()) == (uint) pair->pc_offset(); #else bool is_implicit_deopt = false; #endif if (is_implicit_deopt ? pc == begin : pc > begin && pc <= end) { st->move_to(column, 6, 0); st->print("; "); om->print_on(st); oop_map_required = false; } } if (pc > end) { break; } } } assert(!oop_map_required, "missed oopmap"); // Print any debug info present at this pc. ScopeDesc* sd = scope_desc_in(begin, end); if (sd != NULL) { st->move_to(column, 6, 0); if (sd->bci() == SynchronizationEntryBCI) { st->print(";*synchronization entry"); } else if (sd->bci() == AfterBci) { st->print(";* method exit (unlocked if synchronized)"); } else if (sd->bci() == UnwindBci) { st->print(";* unwind (locked if synchronized)"); } else if (sd->bci() == AfterExceptionBci) { st->print(";* unwind (unlocked if synchronized)"); } else if (sd->bci() == UnknownBci) { st->print(";* unknown"); } else if (sd->bci() == InvalidFrameStateBci) { st->print(";* invalid frame state"); } else { if (sd->method() == NULL) { st->print("method is NULL"); } else if (sd->method()->is_native()) { st->print("method is native"); } else { Bytecodes::Code bc = sd->method()->java_code_at(sd->bci()); st->print(";*%s", Bytecodes::name(bc)); switch (bc) { case Bytecodes::_invokevirtual: case Bytecodes::_invokespecial: case Bytecodes::_invokestatic: case Bytecodes::_invokeinterface: { Bytecode_invoke invoke(sd->method(), sd->bci()); st->print(" "); if (invoke.name() != NULL) invoke.name()->print_symbol_on(st); else st->print(""); break; } case Bytecodes::_getfield: case Bytecodes::_putfield: case Bytecodes::_getstatic: case Bytecodes::_putstatic: { Bytecode_field field(sd->method(), sd->bci()); st->print(" "); if (field.name() != NULL) field.name()->print_symbol_on(st); else st->print(""); } default: break; } } st->print(" {reexecute=%d rethrow=%d return_oop=%d}", sd->should_reexecute(), sd->rethrow_exception(), sd->return_oop()); } // Print all scopes for (;sd != NULL; sd = sd->sender()) { st->move_to(column, 6, 0); st->print("; -"); if (sd->should_reexecute()) { st->print(" (reexecute)"); } if (sd->method() == NULL) { st->print("method is NULL"); } else { sd->method()->print_short_name(st); } int lineno = sd->method()->line_number_from_bci(sd->bci()); if (lineno != -1) { st->print("@%d (line %d)", sd->bci(), lineno); } else { st->print("@%d", sd->bci()); } st->cr(); } } // Print relocation information // Prevent memory leak: allocating without ResourceMark. ResourceMark rm; const char* str = reloc_string_for(begin, end); if (str != NULL) { if (sd != NULL) st->cr(); st->move_to(column, 6, 0); st->print("; {%s}", str); } } #endif class DirectNativeCallWrapper: public NativeCallWrapper { private: NativeCall* _call; public: DirectNativeCallWrapper(NativeCall* call) : _call(call) {} virtual address destination() const { return _call->destination(); } virtual address instruction_address() const { return _call->instruction_address(); } virtual address next_instruction_address() const { return _call->next_instruction_address(); } virtual address return_address() const { return _call->return_address(); } virtual address get_resolve_call_stub(bool is_optimized) const { if (is_optimized) { return SharedRuntime::get_resolve_opt_virtual_call_stub(); } return SharedRuntime::get_resolve_virtual_call_stub(); } virtual void set_destination_mt_safe(address dest) { #if INCLUDE_AOT if (UseAOT) { CodeBlob* callee = CodeCache::find_blob(dest); CompiledMethod* cm = callee->as_compiled_method_or_null(); if (cm != NULL && cm->is_far_code()) { // Temporary fix, see JDK-8143106 CompiledDirectStaticCall* csc = CompiledDirectStaticCall::at(instruction_address()); csc->set_to_far(methodHandle(cm->method()), dest); return; } } #endif _call->set_destination_mt_safe(dest); } virtual void set_to_interpreted(const methodHandle& method, CompiledICInfo& info) { CompiledDirectStaticCall* csc = CompiledDirectStaticCall::at(instruction_address()); #if INCLUDE_AOT if (info.to_aot()) { csc->set_to_far(method, info.entry()); } else #endif { csc->set_to_interpreted(method, info.entry()); } } virtual void verify() const { // make sure code pattern is actually a call imm32 instruction _call->verify(); _call->verify_alignment(); } virtual void verify_resolve_call(address dest) const { CodeBlob* db = CodeCache::find_blob_unsafe(dest); assert(db != NULL && !db->is_adapter_blob(), "must use stub!"); } virtual bool is_call_to_interpreted(address dest) const { CodeBlob* cb = CodeCache::find_blob(_call->instruction_address()); return cb->contains(dest); } virtual bool is_safe_for_patching() const { return false; } virtual NativeInstruction* get_load_instruction(virtual_call_Relocation* r) const { return nativeMovConstReg_at(r->cached_value()); } virtual void *get_data(NativeInstruction* instruction) const { return (void*)((NativeMovConstReg*) instruction)->data(); } virtual void set_data(NativeInstruction* instruction, intptr_t data) { ((NativeMovConstReg*) instruction)->set_data(data); } }; NativeCallWrapper* nmethod::call_wrapper_at(address call) const { return new DirectNativeCallWrapper((NativeCall*) call); } NativeCallWrapper* nmethod::call_wrapper_before(address return_pc) const { return new DirectNativeCallWrapper(nativeCall_before(return_pc)); } address nmethod::call_instruction_address(address pc) const { if (NativeCall::is_call_before(pc)) { NativeCall *ncall = nativeCall_before(pc); return ncall->instruction_address(); } return NULL; } CompiledStaticCall* nmethod::compiledStaticCall_at(Relocation* call_site) const { return CompiledDirectStaticCall::at(call_site); } CompiledStaticCall* nmethod::compiledStaticCall_at(address call_site) const { return CompiledDirectStaticCall::at(call_site); } CompiledStaticCall* nmethod::compiledStaticCall_before(address return_addr) const { return CompiledDirectStaticCall::before(return_addr); } #if defined(SUPPORT_DATA_STRUCTS) void nmethod::print_value_on(outputStream* st) const { st->print("nmethod"); print_on(st, NULL); } #endif #ifndef PRODUCT void nmethod::print_calls(outputStream* st) { RelocIterator iter(this); while (iter.next()) { switch (iter.type()) { case relocInfo::virtual_call_type: case relocInfo::opt_virtual_call_type: { CompiledICLocker ml_verify(this); CompiledIC_at(&iter)->print(); break; } case relocInfo::static_call_type: st->print_cr("Static call at " INTPTR_FORMAT, p2i(iter.reloc()->addr())); CompiledDirectStaticCall::at(iter.reloc())->print(); break; default: break; } } } void nmethod::print_statistics() { ttyLocker ttyl; if (xtty != NULL) xtty->head("statistics type='nmethod'"); native_nmethod_stats.print_native_nmethod_stats(); #ifdef COMPILER1 c1_java_nmethod_stats.print_nmethod_stats("C1"); #endif #ifdef COMPILER2 c2_java_nmethod_stats.print_nmethod_stats("C2"); #endif #if INCLUDE_JVMCI jvmci_java_nmethod_stats.print_nmethod_stats("JVMCI"); #endif unknown_java_nmethod_stats.print_nmethod_stats("Unknown"); DebugInformationRecorder::print_statistics(); #ifndef PRODUCT pc_nmethod_stats.print_pc_stats(); #endif Dependencies::print_statistics(); if (xtty != NULL) xtty->tail("statistics"); } #endif // !PRODUCT #if INCLUDE_JVMCI void nmethod::update_speculation(JavaThread* thread) { jlong speculation = thread->pending_failed_speculation(); if (speculation != 0) { guarantee(jvmci_nmethod_data() != NULL, "failed speculation in nmethod without failed speculation list"); jvmci_nmethod_data()->add_failed_speculation(this, speculation); thread->set_pending_failed_speculation(0); } } const char* nmethod::jvmci_name() { if (jvmci_nmethod_data() != NULL) { return jvmci_nmethod_data()->name(); } return NULL; } #endif