8168503: JEP 297: Unified arm32/arm64 Port
Reviewed-by: kvn, enevill, ihse, dholmes, erikj, coleenp, cjplummer
/*
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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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* version 2 for more details (a copy is included in the LICENSE file that
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* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
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#ifndef SHARE_VM_CODE_CODECACHE_HPP
#define SHARE_VM_CODE_CODECACHE_HPP
#include "code/codeBlob.hpp"
#include "code/nmethod.hpp"
#include "memory/allocation.hpp"
#include "memory/heap.hpp"
#include "oops/instanceKlass.hpp"
#include "oops/oopsHierarchy.hpp"
#include "runtime/mutexLocker.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 TieredCompilation 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 TieredCompilation 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 OopClosure;
class KlassDepChange;
class CodeCache : AllStatic {
friend class VMStructs;
friend class JVMCIVMStructs;
template <class T, class Filter> friend class CodeBlobIterator;
friend class WhiteBox;
friend class CodeCacheLoader;
private:
// CodeHeaps of the cache
static GrowableArray<CodeHeap*>* _heaps;
static GrowableArray<CodeHeap*>* _compiled_heaps;
static GrowableArray<CodeHeap*>* _nmethod_heaps;
static address _low_bound; // Lower bound of CodeHeap addresses
static address _high_bound; // Upper bound of CodeHeap addresses
static int _number_of_nmethods_with_dependencies; // Total number of nmethods with dependencies
static bool _needs_cache_clean; // True if inline caches of the nmethods needs to be flushed
static nmethod* _scavenge_root_nmethods; // linked via nm->scavenge_root_link()
static void mark_scavenge_root_nmethods() PRODUCT_RETURN;
static void verify_perm_nmethods(CodeBlobClosure* f_or_null) PRODUCT_RETURN;
// CodeHeap management
static void initialize_heaps(); // Initializes the CodeHeaps
// Check the code heap sizes set by the user via command line
static void check_heap_sizes(size_t non_nmethod_size, size_t profiled_size, size_t non_profiled_size, size_t cache_size, bool all_set);
// 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, int code_blob_type);
static CodeHeap* get_code_heap(const CodeBlob* cb); // Returns the CodeHeap for the given CodeBlob
static CodeHeap* get_code_heap(int 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(int code_blob_type);
static size_t heap_alignment(); // Returns the alignment of the CodeHeaps in bytes
static ReservedCodeSpace reserve_heap_memory(size_t size); // 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(int 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
static size_t bytes_allocated_in_freelists();
static int allocated_segments();
static size_t freelists_length();
static void set_scavenge_root_nmethods(nmethod* nm) { _scavenge_root_nmethods = nm; }
static void prune_scavenge_root_nmethods();
static void unlink_scavenge_root_nmethod(nmethod* nm, nmethod* prev);
// 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 int code_heap_compare(CodeHeap* const &lhs, CodeHeap* const &rhs);
static void add_heap(CodeHeap* heap);
static const GrowableArray<CodeHeap*>* heaps() { return _heaps; }
static const GrowableArray<CodeHeap*>* compiled_heaps() { return _compiled_heaps; }
static const GrowableArray<CodeHeap*>* nmethod_heaps() { return _nmethod_heaps; }
// Allocation/administration
static CodeBlob* allocate(int size, int code_blob_type, int orig_code_blob_type = CodeBlobType::All); // allocates a new CodeBlob
static void commit(CodeBlob* cb); // called when the allocated CodeBlob has been filled
static int alignment_unit(); // guaranteed alignment of all CodeBlobs
static int alignment_offset(); // guaranteed offset of first CodeBlob byte within alignment unit (i.e., allocation header)
static void free(CodeBlob* cb); // frees a CodeBlob
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 blobs_do(CodeBlobClosure* f); // iterates over all CodeBlobs
static void nmethods_do(void f(nmethod* nm)); // iterates over all nmethods
static void metadata_do(void f(Metadata* m)); // iterates over metadata in alive nmethods
// Lookup
static CodeBlob* find_blob(void* start); // Returns the CodeBlob containing the given address
static CodeBlob* find_blob_unsafe(void* start); // Same as find_blob but does not fail if looking up a zombie method
static nmethod* find_nmethod(void* start); // Returns the nmethod containing the given address
static CompiledMethod* find_compiled(void* start);
static int blob_count(); // Returns the total number of CodeBlobs in the cache
static int blob_count(int code_blob_type);
static int adapter_count(); // Returns the total number of Adapters in the cache
static int adapter_count(int code_blob_type);
static int nmethod_count(); // Returns the total number of nmethods in the cache
static int nmethod_count(int code_blob_type);
// GC support
static void gc_epilogue();
static void gc_prologue();
static void verify_oops();
// If "unloading_occurred" is true, then unloads (i.e., breaks root links
// to) any unmarked codeBlobs in the cache. Sets "marked_for_unloading"
// to "true" iff some code got unloaded.
static void do_unloading(BoolObjectClosure* is_alive, bool unloading_occurred);
static void asserted_non_scavengable_nmethods_do(CodeBlobClosure* f = NULL) PRODUCT_RETURN;
// Apply f to every live code blob in scavengable nmethods. Prune nmethods
// from the list of scavengable nmethods if f->fix_relocations() and a nmethod
// no longer has scavengable oops. If f->fix_relocations(), then f must copy
// objects to their new location immediately to avoid fixing nmethods on the
// basis of the old object locations.
static void scavenge_root_nmethods_do(CodeBlobToOopClosure* f);
static nmethod* scavenge_root_nmethods() { return _scavenge_root_nmethods; }
static void add_scavenge_root_nmethod(nmethod* nm);
static void drop_scavenge_root_nmethod(nmethod* nm);
// 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, int 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);
static const char* get_code_heap_name(int code_blob_type) { return (heap_available(code_blob_type) ? get_code_heap(code_blob_type)->name() : "Unused"); }
static void report_codemem_full(int 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(int code_blob_type);
static address high_bound() { return _high_bound; }
static address high_bound(int code_blob_type);
// Have to use far call instructions to call this pc.
static bool is_far_target(address pc);
// Profiling
static size_t capacity();
static size_t unallocated_capacity(int code_blob_type);
static size_t unallocated_capacity();
static size_t max_capacity();
static double reverse_free_ratio(int code_blob_type);
static bool needs_cache_clean() { return _needs_cache_clean; }
static void set_needs_cache_clean(bool v) { _needs_cache_clean = v; }
static void clear_inline_caches(); // clear all inline caches
static void cleanup_inline_caches();
// Returns true if an own CodeHeap for the given CodeBlobType is available
static bool heap_available(int code_blob_type);
// Returns the CodeBlobType for the given CompiledMethod
static int get_code_blob_type(CompiledMethod* cm) {
return get_code_heap(cm)->code_blob_type();
}
static bool code_blob_type_accepts_compiled(int type) {
bool result = type == CodeBlobType::All || type <= CodeBlobType::MethodProfiled;
AOT_ONLY( result = result || type == CodeBlobType::AOT; )
return result;
}
static bool code_blob_type_accepts_nmethod(int type) {
return type == CodeBlobType::All || type <= CodeBlobType::MethodProfiled;
}
// Returns the CodeBlobType for the given compilation level
static int 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 0;
}
static void verify_clean_inline_caches();
static void verify_icholder_relocations();
// Deoptimization
private:
static int mark_for_deoptimization(KlassDepChange& changes);
#ifdef HOTSWAP
static int mark_for_evol_deoptimization(instanceKlassHandle dependee);
#endif // HOTSWAP
public:
static void mark_all_nmethods_for_deoptimization();
static int mark_for_deoptimization(Method* dependee);
static void make_marked_nmethods_not_entrant();
// Flushing and deoptimization
static void flush_dependents_on(instanceKlassHandle dependee);
#ifdef HOTSWAP
// Flushing and deoptimization in case of evolution
static void flush_evol_dependents_on(instanceKlassHandle dependee);
#endif // HOTSWAP
// Support for fullspeed debugging
static void flush_dependents_on_method(methodHandle dependee);
// tells how many nmethods have dependencies
static int number_of_nmethods_with_dependencies();
static int get_codemem_full_count(int code_blob_type) {
CodeHeap* heap = get_code_heap(code_blob_type);
return (heap != NULL) ? heap->full_count() : 0;
}
};
// Iterator to iterate over nmethods in the CodeCache.
template <class T, class Filter> class CodeBlobIterator : public StackObj {
private:
CodeBlob* _code_blob; // Current CodeBlob
GrowableArrayIterator<CodeHeap*> _heap;
GrowableArrayIterator<CodeHeap*> _end;
public:
CodeBlobIterator(T* nm = NULL) {
if (Filter::heaps() == NULL) {
return;
}
_heap = Filter::heaps()->begin();
_end = Filter::heaps()->end();
// If set to NULL, initialized by first call to next()
_code_blob = (CodeBlob*)nm;
if (nm != NULL) {
address start = nm->code_begin();
while(!(*_heap)->contains(start)) {
++_heap;
}
assert((*_heap)->contains(start), "match not found");
}
}
// Advance iterator to next blob
bool next() {
assert_locked_or_safepoint(CodeCache_lock);
bool result = next_blob();
while (!result && _heap != _end) {
// Advance to next code heap of segmented code cache
if (++_heap == _end) {
break;
}
result = next_blob();
}
return result;
}
// Advance iterator to next alive blob
bool next_alive() {
bool result = next();
while(result && !_code_blob->is_alive()) {
result = next();
}
return result;
}
bool end() const { return _code_blob == NULL; }
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 == NULL) {
_code_blob = CodeCache::first_blob(heap);
if (_code_blob == NULL) {
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 != NULL && !Filter::apply(_code_blob)) {
_code_blob = CodeCache::next_blob(heap, _code_blob);
}
return _code_blob != NULL;
}
};
struct CompiledMethodFilter {
static bool apply(CodeBlob* cb) { return cb->is_compiled(); }
static const GrowableArray<CodeHeap*>* heaps() { return CodeCache::compiled_heaps(); }
};
struct NMethodFilter {
static bool apply(CodeBlob* cb) { return cb->is_nmethod(); }
static const GrowableArray<CodeHeap*>* heaps() { return CodeCache::nmethod_heaps(); }
};
typedef CodeBlobIterator<CompiledMethod, CompiledMethodFilter> CompiledMethodIterator;
typedef CodeBlobIterator<nmethod, NMethodFilter> NMethodIterator;
#endif // SHARE_VM_CODE_CODECACHE_HPP