/* * Copyright (c) 1997, 2024, 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. * */ #ifndef SHARE_CODE_CODECACHE_HPP #define SHARE_CODE_CODECACHE_HPP #include "code/codeBlob.hpp" #include "code/nmethod.hpp" #include "gc/shared/gcBehaviours.hpp" #include "memory/allocation.hpp" #include "memory/heap.hpp" #include "oops/instanceKlass.hpp" #include "oops/oopsHierarchy.hpp" #include "runtime/mutexLocker.hpp" #include "utilities/numberSeq.hpp" // The CodeCache implements the code cache for various pieces of generated // code, e.g., compiled java methods, runtime stubs, transition frames, etc. // The entries in the CodeCache are all CodeBlob's. // -- Implementation -- // The CodeCache consists of one or more CodeHeaps, each of which contains // CodeBlobs of a specific CodeBlobType. Currently heaps for the following // types are available: // - Non-nmethods: Non-nmethods like Buffers, Adapters and Runtime Stubs // - Profiled nmethods: nmethods that are profiled, i.e., those // executed at level 2 or 3 // - Non-Profiled nmethods: nmethods that are not profiled, i.e., those // executed at level 1 or 4 and native methods // - All: Used for code of all types if code cache segmentation is disabled. // // In the rare case of the non-nmethod code heap getting full, non-nmethod code // will be stored in the non-profiled code heap as a fallback solution. // // Depending on the availability of compilers and compilation mode there // may be fewer heaps. The size of the code heaps depends on the values of // ReservedCodeCacheSize, NonProfiledCodeHeapSize and ProfiledCodeHeapSize // (see CodeCache::heap_available(..) and CodeCache::initialize_heaps(..) // for details). // // Code cache segmentation is controlled by the flag SegmentedCodeCache. // If turned off, all code types are stored in a single code heap. By default // code cache segmentation is turned on if tiered mode is enabled and // ReservedCodeCacheSize >= 240 MB. // // All methods of the CodeCache accepting a CodeBlobType only apply to // CodeBlobs of the given type. For example, iteration over the // CodeBlobs of a specific type can be done by using CodeCache::first_blob(..) // and CodeCache::next_blob(..) and providing the corresponding CodeBlobType. // // IMPORTANT: If you add new CodeHeaps to the code cache or change the // existing ones, make sure to adapt the dtrace scripts (jhelper.d) for // Solaris and BSD. class ExceptionCache; class KlassDepChange; class OopClosure; class ShenandoahParallelCodeHeapIterator; class NativePostCallNop; class DeoptimizationScope; class ReservedSpace; #ifdef LINUX #define DEFAULT_PERFMAP_FILENAME "/tmp/perf-%p.map" #endif class CodeCache : AllStatic { friend class VMStructs; friend class JVMCIVMStructs; template friend class CodeBlobIterator; friend class WhiteBox; friend class ShenandoahParallelCodeHeapIterator; private: // CodeHeaps of the cache static GrowableArray* _heaps; static GrowableArray* _nmethod_heaps; static GrowableArray* _allocable_heaps; static address _low_bound; // Lower bound of CodeHeap addresses static address _high_bound; // Upper bound of CodeHeap addresses static volatile int _number_of_nmethods_with_dependencies; // Total number of nmethods with dependencies static uint8_t _unloading_cycle; // Global state for recognizing old nmethods that need to be unloaded static uint64_t _gc_epoch; // Global state for tracking when nmethods were found to be on-stack static uint64_t _cold_gc_count; // Global state for determining how many GCs are needed before an nmethod is cold static size_t _last_unloading_used; static double _last_unloading_time; static TruncatedSeq _unloading_gc_intervals; static TruncatedSeq _unloading_allocation_rates; static volatile bool _unloading_threshold_gc_requested; static ExceptionCache* volatile _exception_cache_purge_list; // CodeHeap management static void initialize_heaps(); // Initializes the CodeHeaps // Creates a new heap with the given name and size, containing CodeBlobs of the given type static void add_heap(ReservedSpace rs, const char* name, CodeBlobType code_blob_type); static CodeHeap* get_code_heap_containing(void* p); // Returns the CodeHeap containing the given pointer, or nullptr static CodeHeap* get_code_heap(const void* cb); // Returns the CodeHeap for the given CodeBlob static CodeHeap* get_code_heap(CodeBlobType code_blob_type); // Returns the CodeHeap for the given CodeBlobType // Returns the name of the VM option to set the size of the corresponding CodeHeap static const char* get_code_heap_flag_name(CodeBlobType code_blob_type); static ReservedSpace reserve_heap_memory(size_t size, size_t rs_ps); // Reserves one continuous chunk of memory for the CodeHeaps // Iteration static CodeBlob* first_blob(CodeHeap* heap); // Returns the first CodeBlob on the given CodeHeap static CodeBlob* first_blob(CodeBlobType code_blob_type); // Returns the first CodeBlob of the given type static CodeBlob* next_blob(CodeHeap* heap, CodeBlob* cb); // Returns the next CodeBlob on the given CodeHeap private: static size_t bytes_allocated_in_freelists(); static int allocated_segments(); static size_t freelists_length(); // Make private to prevent unsafe calls. Not all CodeBlob*'s are embedded in a CodeHeap. static bool contains(CodeBlob *p) { fatal("don't call me!"); return false; } public: // Initialization static void initialize(); static size_t page_size(bool aligned = true, size_t min_pages = 1); // Returns the page size used by the CodeCache static int code_heap_compare(CodeHeap* const &lhs, CodeHeap* const &rhs); static void add_heap(CodeHeap* heap); static const GrowableArray* heaps() { return _heaps; } static const GrowableArray* nmethod_heaps() { return _nmethod_heaps; } // Allocation/administration static CodeBlob* allocate(uint size, CodeBlobType code_blob_type, bool handle_alloc_failure = true, CodeBlobType orig_code_blob_type = CodeBlobType::All); // allocates a new CodeBlob static void commit(CodeBlob* cb); // called when the allocated CodeBlob has been filled static void free(CodeBlob* cb); // frees a CodeBlob static void free_unused_tail(CodeBlob* cb, size_t used); // frees the unused tail of a CodeBlob (only used by TemplateInterpreter::initialize()) static bool contains(void *p); // returns whether p is included static bool contains(nmethod* nm); // returns whether nm is included static void blobs_do(void f(CodeBlob* cb)); // iterates over all CodeBlobs static void nmethods_do(void f(nmethod* nm)); // iterates over all nmethods static void nmethods_do(NMethodClosure* cl); // iterates over all nmethods static void metadata_do(MetadataClosure* f); // iterates over metadata in alive nmethods // Lookup static CodeBlob* find_blob(void* start); // Returns the CodeBlob containing the given address static CodeBlob* find_blob_fast(void* start); // Returns the CodeBlob containing the given address static CodeBlob* find_blob_and_oopmap(void* start, int& slot); // Returns the CodeBlob containing the given address static int find_oopmap_slot_fast(void* start); // Returns a fast oopmap slot if there is any; -1 otherwise static nmethod* find_nmethod(void* start); // Returns the nmethod containing the given address static int blob_count(); // Returns the total number of CodeBlobs in the cache static int blob_count(CodeBlobType code_blob_type); static int adapter_count(); // Returns the total number of Adapters in the cache static int adapter_count(CodeBlobType code_blob_type); static int nmethod_count(); // Returns the total number of nmethods in the cache static int nmethod_count(CodeBlobType code_blob_type); // GC support static void verify_oops(); // Helper scope object managing code cache unlinking behavior, i.e. sets and // restores the closure that determines which nmethods are going to be removed // during the unlinking part of code cache unloading. class UnlinkingScope : StackObj { ClosureIsUnloadingBehaviour _is_unloading_behaviour; IsUnloadingBehaviour* _saved_behaviour; public: UnlinkingScope(BoolObjectClosure* is_alive); ~UnlinkingScope(); }; // Code cache unloading heuristics static uint64_t cold_gc_count(); static void update_cold_gc_count(); static void gc_on_allocation(); // The GC epoch and marking_cycle code below is there to support sweeping // nmethods in loom stack chunks. static uint64_t gc_epoch(); static bool is_gc_marking_cycle_active(); static uint64_t previous_completed_gc_marking_cycle(); static void on_gc_marking_cycle_start(); static void on_gc_marking_cycle_finish(); // Arm nmethods so that special actions are taken (nmethod_entry_barrier) for // on-stack nmethods. It's used in two places: // 1. Used before the start of concurrent marking so that oops inside // on-stack nmethods are visited. // 2. Used at the end of (stw/concurrent) marking so that nmethod::_gc_epoch // is up-to-date, which provides more accurate estimate of // nmethod::is_cold. static void arm_all_nmethods(); static void maybe_restart_compiler(size_t freed_memory); static void do_unloading(bool unloading_occurred); static uint8_t unloading_cycle() { return _unloading_cycle; } static void increment_unloading_cycle(); static void release_exception_cache(ExceptionCache* entry); static void purge_exception_caches(); // Printing/debugging static void print(); // prints summary static void print_internals(); static void print_memory_overhead(); static void verify(); // verifies the code cache static void print_trace(const char* event, CodeBlob* cb, uint size = 0) PRODUCT_RETURN; static void print_summary(outputStream* st, bool detailed = true); // Prints a summary of the code cache usage static void log_state(outputStream* st); LINUX_ONLY(static void write_perf_map(const char* filename, outputStream* st);) // Prints warnings and error messages to outputStream static const char* get_code_heap_name(CodeBlobType code_blob_type) { return (heap_available(code_blob_type) ? get_code_heap(code_blob_type)->name() : "Unused"); } static void report_codemem_full(CodeBlobType code_blob_type, bool print); // Dcmd (Diagnostic commands) static void print_codelist(outputStream* st); static void print_layout(outputStream* st); // The full limits of the codeCache static address low_bound() { return _low_bound; } static address low_bound(CodeBlobType code_blob_type); static address high_bound() { return _high_bound; } static address high_bound(CodeBlobType code_blob_type); // Profiling static size_t capacity(); static size_t unallocated_capacity(CodeBlobType code_blob_type); static size_t unallocated_capacity(); static size_t max_capacity(); static double reverse_free_ratio(); static size_t max_distance_to_non_nmethod(); static bool is_non_nmethod(address addr); static void clear_inline_caches(); // clear all inline caches static void cleanup_inline_caches_whitebox(); // clean bad nmethods from inline caches // Returns true if an own CodeHeap for the given CodeBlobType is available static bool heap_available(CodeBlobType code_blob_type); // Returns the CodeBlobType for the given nmethod static CodeBlobType get_code_blob_type(nmethod* nm) { return get_code_heap(nm)->code_blob_type(); } static bool code_blob_type_accepts_nmethod(CodeBlobType type) { return type == CodeBlobType::All || type <= CodeBlobType::MethodProfiled; } static bool code_blob_type_accepts_allocable(CodeBlobType type) { return type <= CodeBlobType::All; } // Returns the CodeBlobType for the given compilation level static CodeBlobType get_code_blob_type(int comp_level) { if (comp_level == CompLevel_none || comp_level == CompLevel_simple || comp_level == CompLevel_full_optimization) { // Non profiled methods return CodeBlobType::MethodNonProfiled; } else if (comp_level == CompLevel_limited_profile || comp_level == CompLevel_full_profile) { // Profiled methods return CodeBlobType::MethodProfiled; } ShouldNotReachHere(); return static_cast(0); } static void verify_clean_inline_caches(); // Deoptimization private: static void mark_for_deoptimization(DeoptimizationScope* deopt_scope, KlassDepChange& changes); public: static void mark_all_nmethods_for_deoptimization(DeoptimizationScope* deopt_scope); static void mark_for_deoptimization(DeoptimizationScope* deopt_scope, Method* dependee); static void make_marked_nmethods_deoptimized(); // Marks dependents during classloading static void mark_dependents_on(DeoptimizationScope* deopt_scope, InstanceKlass* dependee); // RedefineClasses support // Marks in case of evolution static void mark_dependents_for_evol_deoptimization(DeoptimizationScope* deopt_scope); static void mark_all_nmethods_for_evol_deoptimization(DeoptimizationScope* deopt_scope); static void old_nmethods_do(MetadataClosure* f) NOT_JVMTI_RETURN; static void unregister_old_nmethod(nmethod* c) NOT_JVMTI_RETURN; // Support for fullspeed debugging static void mark_dependents_on_method_for_breakpoint(const methodHandle& dependee); // tells if there are nmethods with dependencies static bool has_nmethods_with_dependencies(); static int get_codemem_full_count(CodeBlobType code_blob_type) { CodeHeap* heap = get_code_heap(code_blob_type); return (heap != nullptr) ? heap->full_count() : 0; } // CodeHeap State Analytics. // interface methods for CodeHeap printing, called by CompileBroker static void aggregate(outputStream *out, size_t granularity); static void discard(outputStream *out); static void print_usedSpace(outputStream *out); static void print_freeSpace(outputStream *out); static void print_count(outputStream *out); static void print_space(outputStream *out); static void print_age(outputStream *out); static void print_names(outputStream *out); }; // Iterator to iterate over code blobs in the CodeCache. // The relaxed iterators only hold the CodeCache_lock across next calls template class CodeBlobIterator : public StackObj { public: enum LivenessFilter { all, not_unloading }; private: CodeBlob* _code_blob; // Current CodeBlob GrowableArrayIterator _heap; GrowableArrayIterator _end; bool _not_unloading; // Those nmethods that are not unloading void initialize_iteration(T* nm) { } bool next_impl() { for (;;) { // Walk through heaps as required if (!next_blob()) { if (_heap == _end) { return false; } ++_heap; continue; } // Filter is_unloading as required if (_not_unloading) { nmethod* nm = _code_blob->as_nmethod_or_null(); if (nm != nullptr && nm->is_unloading()) { continue; } } return true; } } public: CodeBlobIterator(LivenessFilter filter, T* nm = nullptr) : _not_unloading(filter == not_unloading) { if (Filter::heaps() == nullptr) { // The iterator is supposed to shortcut since we have // _heap == _end, but make sure we do not have garbage // in other fields as well. _code_blob = nullptr; return; } _heap = Filter::heaps()->begin(); _end = Filter::heaps()->end(); // If set to nullptr, initialized by first call to next() _code_blob = nm; if (nm != nullptr) { while(!(*_heap)->contains(_code_blob)) { ++_heap; } assert((*_heap)->contains(_code_blob), "match not found"); } } // Advance iterator to next blob bool next() { if (is_relaxed) { MutexLocker ml(CodeCache_lock, Mutex::_no_safepoint_check_flag); return next_impl(); } else { assert_locked_or_safepoint(CodeCache_lock); return next_impl(); } } bool end() const { return _code_blob == nullptr; } T* method() const { return (T*)_code_blob; } private: // Advance iterator to the next blob in the current code heap bool next_blob() { if (_heap == _end) { return false; } CodeHeap *heap = *_heap; // Get first method CodeBlob if (_code_blob == nullptr) { _code_blob = CodeCache::first_blob(heap); if (_code_blob == nullptr) { return false; } else if (Filter::apply(_code_blob)) { return true; } } // Search for next method CodeBlob _code_blob = CodeCache::next_blob(heap, _code_blob); while (_code_blob != nullptr && !Filter::apply(_code_blob)) { _code_blob = CodeCache::next_blob(heap, _code_blob); } return _code_blob != nullptr; } }; struct NMethodFilter { static bool apply(CodeBlob* cb) { return cb->is_nmethod(); } static const GrowableArray* heaps() { return CodeCache::nmethod_heaps(); } }; struct AllCodeBlobsFilter { static bool apply(CodeBlob* cb) { return true; } static const GrowableArray* heaps() { return CodeCache::heaps(); } }; typedef CodeBlobIterator NMethodIterator; typedef CodeBlobIterator RelaxedNMethodIterator; typedef CodeBlobIterator AllCodeBlobsIterator; #endif // SHARE_CODE_CODECACHE_HPP