8029799: vm/mlvm/anonloader/stress/oome prints warning: CodeHeap: # of free blocks > 10000
Summary: Double CodeCacheSegmentSize from 64 byte to 128 bytes if tiered compilation is enabled
Reviewed-by: kvn, twisti
/*
* Copyright (c) 2012, 2013, 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 "classfile/dictionary.hpp"
#include "classfile/loaderConstraints.hpp"
#include "classfile/placeholders.hpp"
#include "classfile/symbolTable.hpp"
#include "classfile/systemDictionary.hpp"
#include "code/codeCache.hpp"
#include "memory/filemap.hpp"
#include "memory/gcLocker.hpp"
#include "memory/metaspace.hpp"
#include "memory/metaspaceShared.hpp"
#include "oops/objArrayOop.hpp"
#include "oops/oop.inline.hpp"
#include "runtime/signature.hpp"
#include "runtime/vm_operations.hpp"
#include "runtime/vmThread.hpp"
#include "utilities/hashtable.inline.hpp"
int MetaspaceShared::_max_alignment = 0;
ReservedSpace* MetaspaceShared::_shared_rs = NULL;
// Read/write a data stream for restoring/preserving metadata pointers and
// miscellaneous data from/to the shared archive file.
void MetaspaceShared::serialize(SerializeClosure* soc) {
int tag = 0;
soc->do_tag(--tag);
// Verify the sizes of various metadata in the system.
soc->do_tag(sizeof(Method));
soc->do_tag(sizeof(ConstMethod));
soc->do_tag(arrayOopDesc::base_offset_in_bytes(T_BYTE));
soc->do_tag(sizeof(ConstantPool));
soc->do_tag(sizeof(ConstantPoolCache));
soc->do_tag(objArrayOopDesc::base_offset_in_bytes());
soc->do_tag(typeArrayOopDesc::base_offset_in_bytes(T_BYTE));
soc->do_tag(sizeof(Symbol));
// Dump/restore miscellaneous metadata.
Universe::serialize(soc, true);
soc->do_tag(--tag);
// Dump/restore references to commonly used names and signatures.
vmSymbols::serialize(soc);
soc->do_tag(--tag);
soc->do_tag(666);
}
// CDS code for dumping shared archive.
// Global object for holding classes that have been loaded. Since this
// is run at a safepoint just before exit, this is the entire set of classes.
static GrowableArray<Klass*>* _global_klass_objects;
static void collect_classes(Klass* k) {
_global_klass_objects->append_if_missing(k);
if (k->oop_is_instance()) {
// Add in the array classes too
InstanceKlass* ik = InstanceKlass::cast(k);
ik->array_klasses_do(collect_classes);
}
}
static void remove_unshareable_in_classes() {
for (int i = 0; i < _global_klass_objects->length(); i++) {
Klass* k = _global_klass_objects->at(i);
k->remove_unshareable_info();
}
}
// Walk all methods in the class list and assign a fingerprint.
// so that this part of the ConstMethod* is read only.
static void calculate_fingerprints() {
for (int i = 0; i < _global_klass_objects->length(); i++) {
Klass* k = _global_klass_objects->at(i);
if (k->oop_is_instance()) {
InstanceKlass* ik = InstanceKlass::cast(k);
for (int i = 0; i < ik->methods()->length(); i++) {
Method* m = ik->methods()->at(i);
Fingerprinter fp(m);
// The side effect of this call sets method's fingerprint field.
fp.fingerprint();
}
}
}
}
// Patch C++ vtable pointer in metadata.
// Klass and other metadata objects contain references to c++ vtables in the
// JVM library.
// Fix them to point to our constructed vtables. However, don't iterate
// across the space while doing this, as that causes the vtables to be
// patched, undoing our useful work. Instead, iterate to make a list,
// then use the list to do the fixing.
//
// Our constructed vtables:
// Dump time:
// 1. init_self_patching_vtbl_list: table of pointers to current virtual method addrs
// 2. generate_vtable_methods: create jump table, appended to above vtbl_list
// 3. patch_klass_vtables: for Klass list, patch the vtable entry in klass and
// associated metadata to point to jump table rather than to current vtbl
// Table layout: NOTE FIXED SIZE
// 1. vtbl pointers
// 2. #Klass X #virtual methods per Klass
// 1 entry for each, in the order:
// Klass1:method1 entry, Klass1:method2 entry, ... Klass1:method<num_virtuals> entry
// Klass2:method1 entry, Klass2:method2 entry, ... Klass2:method<num_virtuals> entry
// ...
// Klass<vtbl_list_size>:method1 entry, Klass<vtbl_list_size>:method2 entry,
// ... Klass<vtbl_list_size>:method<num_virtuals> entry
// Sample entry: (Sparc):
// save(sp, -256, sp)
// ba,pt common_code
// mov XXX, %L0 %L0 gets: Klass index <<8 + method index (note: max method index 255)
//
// Restore time:
// 1. initialize_shared_space: reserve space for table
// 2. init_self_patching_vtbl_list: update pointers to NEW virtual method addrs in text
//
// Execution time:
// First virtual method call for any object of these metadata types:
// 1. object->klass
// 2. vtable entry for that klass points to the jump table entries
// 3. branches to common_code with %O0/klass, %L0: Klass index <<8 + method index
// 4. common_code:
// Get address of new vtbl pointer for this Klass from updated table
// Update new vtbl pointer in the Klass: future virtual calls go direct
// Jump to method, using new vtbl pointer and method index
static void* find_matching_vtbl_ptr(void** vtbl_list, void* new_vtable_start, void* obj) {
void* old_vtbl_ptr = *(void**)obj;
for (int i = 0; i < MetaspaceShared::vtbl_list_size; i++) {
if (vtbl_list[i] == old_vtbl_ptr) {
return (void**)new_vtable_start + i * MetaspaceShared::num_virtuals;
}
}
ShouldNotReachHere();
return NULL;
}
// Assumes the vtable is in first slot in object.
static void patch_klass_vtables(void** vtbl_list, void* new_vtable_start) {
int n = _global_klass_objects->length();
for (int i = 0; i < n; i++) {
Klass* obj = _global_klass_objects->at(i);
// Note oop_is_instance() is a virtual call. After patching vtables
// all virtual calls on the dummy vtables will restore the original!
if (obj->oop_is_instance()) {
InstanceKlass* ik = InstanceKlass::cast(obj);
*(void**)ik = find_matching_vtbl_ptr(vtbl_list, new_vtable_start, ik);
ConstantPool* cp = ik->constants();
*(void**)cp = find_matching_vtbl_ptr(vtbl_list, new_vtable_start, cp);
for (int j = 0; j < ik->methods()->length(); j++) {
Method* m = ik->methods()->at(j);
*(void**)m = find_matching_vtbl_ptr(vtbl_list, new_vtable_start, m);
}
} else {
// Array klasses
Klass* k = obj;
*(void**)k = find_matching_vtbl_ptr(vtbl_list, new_vtable_start, k);
}
}
}
// Closure for serializing initialization data out to a data area to be
// written to the shared file.
class WriteClosure : public SerializeClosure {
private:
intptr_t* top;
char* end;
inline void check_space() {
if ((char*)top + sizeof(intptr_t) > end) {
report_out_of_shared_space(SharedMiscData);
}
}
public:
WriteClosure(char* md_top, char* md_end) {
top = (intptr_t*)md_top;
end = md_end;
}
char* get_top() { return (char*)top; }
void do_ptr(void** p) {
check_space();
*top = (intptr_t)*p;
++top;
}
void do_tag(int tag) {
check_space();
*top = (intptr_t)tag;
++top;
}
void do_region(u_char* start, size_t size) {
if ((char*)top + size > end) {
report_out_of_shared_space(SharedMiscData);
}
assert((intptr_t)start % sizeof(intptr_t) == 0, "bad alignment");
assert(size % sizeof(intptr_t) == 0, "bad size");
do_tag((int)size);
while (size > 0) {
*top = *(intptr_t*)start;
++top;
start += sizeof(intptr_t);
size -= sizeof(intptr_t);
}
}
bool reading() const { return false; }
};
// This is for dumping detailed statistics for the allocations
// in the shared spaces.
class DumpAllocClosure : public Metaspace::AllocRecordClosure {
public:
// Here's poor man's enum inheritance
#define SHAREDSPACE_OBJ_TYPES_DO(f) \
METASPACE_OBJ_TYPES_DO(f) \
f(SymbolHashentry) \
f(SymbolBuckets) \
f(Other)
#define SHAREDSPACE_OBJ_TYPE_DECLARE(name) name ## Type,
#define SHAREDSPACE_OBJ_TYPE_NAME_CASE(name) case name ## Type: return #name;
enum Type {
// Types are MetaspaceObj::ClassType, MetaspaceObj::SymbolType, etc
SHAREDSPACE_OBJ_TYPES_DO(SHAREDSPACE_OBJ_TYPE_DECLARE)
_number_of_types
};
static const char * type_name(Type type) {
switch(type) {
SHAREDSPACE_OBJ_TYPES_DO(SHAREDSPACE_OBJ_TYPE_NAME_CASE)
default:
ShouldNotReachHere();
return NULL;
}
}
public:
enum {
RO = 0,
RW = 1
};
int _counts[2][_number_of_types];
int _bytes [2][_number_of_types];
int _which;
DumpAllocClosure() {
memset(_counts, 0, sizeof(_counts));
memset(_bytes, 0, sizeof(_bytes));
};
void iterate_metaspace(Metaspace* space, int which) {
assert(which == RO || which == RW, "sanity");
_which = which;
space->iterate(this);
}
virtual void doit(address ptr, MetaspaceObj::Type type, int byte_size) {
assert(int(type) >= 0 && type < MetaspaceObj::_number_of_types, "sanity");
_counts[_which][type] ++;
_bytes [_which][type] += byte_size;
}
void dump_stats(int ro_all, int rw_all, int md_all, int mc_all);
};
void DumpAllocClosure::dump_stats(int ro_all, int rw_all, int md_all, int mc_all) {
rw_all += (md_all + mc_all); // md and mc are all mapped Read/Write
int other_bytes = md_all + mc_all;
// Calculate size of data that was not allocated by Metaspace::allocate()
int symbol_count = _counts[RO][MetaspaceObj::SymbolType];
int symhash_bytes = symbol_count * sizeof (HashtableEntry<Symbol*, mtSymbol>);
int symbuck_count = SymbolTable::the_table()->table_size();
int symbuck_bytes = symbuck_count * sizeof(HashtableBucket<mtSymbol>);
_counts[RW][SymbolHashentryType] = symbol_count;
_bytes [RW][SymbolHashentryType] = symhash_bytes;
other_bytes -= symhash_bytes;
_counts[RW][SymbolBucketsType] = symbuck_count;
_bytes [RW][SymbolBucketsType] = symbuck_bytes;
other_bytes -= symbuck_bytes;
// TODO: count things like dictionary, vtable, etc
_bytes[RW][OtherType] = other_bytes;
// prevent divide-by-zero
if (ro_all < 1) {
ro_all = 1;
}
if (rw_all < 1) {
rw_all = 1;
}
int all_ro_count = 0;
int all_ro_bytes = 0;
int all_rw_count = 0;
int all_rw_bytes = 0;
const char *fmt = "%-20s: %8d %10d %5.1f | %8d %10d %5.1f | %8d %10d %5.1f";
const char *sep = "--------------------+---------------------------+---------------------------+--------------------------";
const char *hdr = " ro_cnt ro_bytes % | rw_cnt rw_bytes % | all_cnt all_bytes %";
tty->print_cr("Detailed metadata info (rw includes md and mc):");
tty->print_cr(hdr);
tty->print_cr(sep);
for (int type = 0; type < int(_number_of_types); type ++) {
const char *name = type_name((Type)type);
int ro_count = _counts[RO][type];
int ro_bytes = _bytes [RO][type];
int rw_count = _counts[RW][type];
int rw_bytes = _bytes [RW][type];
int count = ro_count + rw_count;
int bytes = ro_bytes + rw_bytes;
double ro_perc = 100.0 * double(ro_bytes) / double(ro_all);
double rw_perc = 100.0 * double(rw_bytes) / double(rw_all);
double perc = 100.0 * double(bytes) / double(ro_all + rw_all);
tty->print_cr(fmt, name,
ro_count, ro_bytes, ro_perc,
rw_count, rw_bytes, rw_perc,
count, bytes, perc);
all_ro_count += ro_count;
all_ro_bytes += ro_bytes;
all_rw_count += rw_count;
all_rw_bytes += rw_bytes;
}
int all_count = all_ro_count + all_rw_count;
int all_bytes = all_ro_bytes + all_rw_bytes;
double all_ro_perc = 100.0 * double(all_ro_bytes) / double(ro_all);
double all_rw_perc = 100.0 * double(all_rw_bytes) / double(rw_all);
double all_perc = 100.0 * double(all_bytes) / double(ro_all + rw_all);
tty->print_cr(sep);
tty->print_cr(fmt, "Total",
all_ro_count, all_ro_bytes, all_ro_perc,
all_rw_count, all_rw_bytes, all_rw_perc,
all_count, all_bytes, all_perc);
assert(all_ro_bytes == ro_all, "everything should have been counted");
assert(all_rw_bytes == rw_all, "everything should have been counted");
}
// Populate the shared space.
class VM_PopulateDumpSharedSpace: public VM_Operation {
private:
ClassLoaderData* _loader_data;
GrowableArray<Klass*> *_class_promote_order;
VirtualSpace _md_vs;
VirtualSpace _mc_vs;
public:
VM_PopulateDumpSharedSpace(ClassLoaderData* loader_data,
GrowableArray<Klass*> *class_promote_order) :
_loader_data(loader_data) {
// Split up and initialize the misc code and data spaces
ReservedSpace* shared_rs = MetaspaceShared::shared_rs();
int metadata_size = SharedReadOnlySize+SharedReadWriteSize;
ReservedSpace shared_ro_rw = shared_rs->first_part(metadata_size);
ReservedSpace misc_section = shared_rs->last_part(metadata_size);
// Now split into misc sections.
ReservedSpace md_rs = misc_section.first_part(SharedMiscDataSize);
ReservedSpace mc_rs = misc_section.last_part(SharedMiscDataSize);
_md_vs.initialize(md_rs, SharedMiscDataSize);
_mc_vs.initialize(mc_rs, SharedMiscCodeSize);
_class_promote_order = class_promote_order;
}
VMOp_Type type() const { return VMOp_PopulateDumpSharedSpace; }
void doit(); // outline because gdb sucks
}; // class VM_PopulateDumpSharedSpace
void VM_PopulateDumpSharedSpace::doit() {
Thread* THREAD = VMThread::vm_thread();
NOT_PRODUCT(SystemDictionary::verify();)
// The following guarantee is meant to ensure that no loader constraints
// exist yet, since the constraints table is not shared. This becomes
// more important now that we don't re-initialize vtables/itables for
// shared classes at runtime, where constraints were previously created.
guarantee(SystemDictionary::constraints()->number_of_entries() == 0,
"loader constraints are not saved");
guarantee(SystemDictionary::placeholders()->number_of_entries() == 0,
"placeholders are not saved");
// Revisit and implement this if we prelink method handle call sites:
guarantee(SystemDictionary::invoke_method_table() == NULL ||
SystemDictionary::invoke_method_table()->number_of_entries() == 0,
"invoke method table is not saved");
// At this point, many classes have been loaded.
// Gather systemDictionary classes in a global array and do everything to
// that so we don't have to walk the SystemDictionary again.
_global_klass_objects = new GrowableArray<Klass*>(1000);
Universe::basic_type_classes_do(collect_classes);
SystemDictionary::classes_do(collect_classes);
tty->print_cr("Number of classes %d", _global_klass_objects->length());
// Update all the fingerprints in the shared methods.
tty->print("Calculating fingerprints ... ");
calculate_fingerprints();
tty->print_cr("done. ");
// Remove all references outside the metadata
tty->print("Removing unshareable information ... ");
remove_unshareable_in_classes();
tty->print_cr("done. ");
// Set up the share data and shared code segments.
char* md_low = _md_vs.low();
char* md_top = md_low;
char* md_end = _md_vs.high();
char* mc_low = _mc_vs.low();
char* mc_top = mc_low;
char* mc_end = _mc_vs.high();
// Reserve space for the list of Klass*s whose vtables are used
// for patching others as needed.
void** vtbl_list = (void**)md_top;
int vtbl_list_size = MetaspaceShared::vtbl_list_size;
Universe::init_self_patching_vtbl_list(vtbl_list, vtbl_list_size);
md_top += vtbl_list_size * sizeof(void*);
void* vtable = md_top;
// Reserve space for a new dummy vtable for klass objects in the
// heap. Generate self-patching vtable entries.
MetaspaceShared::generate_vtable_methods(vtbl_list, &vtable,
&md_top, md_end,
&mc_top, mc_end);
// Reorder the system dictionary. (Moving the symbols affects
// how the hash table indices are calculated.)
// Not doing this either.
SystemDictionary::reorder_dictionary();
NOT_PRODUCT(SystemDictionary::verify();)
// Copy the the symbol table, and the system dictionary to the shared
// space in usable form. Copy the hashtable
// buckets first [read-write], then copy the linked lists of entries
// [read-only].
SymbolTable::reverse(md_top);
NOT_PRODUCT(SymbolTable::verify());
SymbolTable::copy_buckets(&md_top, md_end);
SystemDictionary::reverse();
SystemDictionary::copy_buckets(&md_top, md_end);
ClassLoader::verify();
ClassLoader::copy_package_info_buckets(&md_top, md_end);
ClassLoader::verify();
SymbolTable::copy_table(&md_top, md_end);
SystemDictionary::copy_table(&md_top, md_end);
ClassLoader::verify();
ClassLoader::copy_package_info_table(&md_top, md_end);
ClassLoader::verify();
// Write the other data to the output array.
WriteClosure wc(md_top, md_end);
MetaspaceShared::serialize(&wc);
md_top = wc.get_top();
// Print shared spaces all the time
const char* fmt = "%s space: %9d [ %4.1f%% of total] out of %9d bytes [%4.1f%% used] at " PTR_FORMAT;
Metaspace* ro_space = _loader_data->ro_metaspace();
Metaspace* rw_space = _loader_data->rw_metaspace();
// Allocated size of each space (may not be all occupied)
const size_t ro_alloced = ro_space->capacity_bytes_slow(Metaspace::NonClassType);
const size_t rw_alloced = rw_space->capacity_bytes_slow(Metaspace::NonClassType);
const size_t md_alloced = md_end-md_low;
const size_t mc_alloced = mc_end-mc_low;
const size_t total_alloced = ro_alloced + rw_alloced + md_alloced + mc_alloced;
// Occupied size of each space.
const size_t ro_bytes = ro_space->used_bytes_slow(Metaspace::NonClassType);
const size_t rw_bytes = rw_space->used_bytes_slow(Metaspace::NonClassType);
const size_t md_bytes = size_t(md_top - md_low);
const size_t mc_bytes = size_t(mc_top - mc_low);
// Percent of total size
const size_t total_bytes = ro_bytes + rw_bytes + md_bytes + mc_bytes;
const double ro_t_perc = ro_bytes / double(total_bytes) * 100.0;
const double rw_t_perc = rw_bytes / double(total_bytes) * 100.0;
const double md_t_perc = md_bytes / double(total_bytes) * 100.0;
const double mc_t_perc = mc_bytes / double(total_bytes) * 100.0;
// Percent of fullness of each space
const double ro_u_perc = ro_bytes / double(ro_alloced) * 100.0;
const double rw_u_perc = rw_bytes / double(rw_alloced) * 100.0;
const double md_u_perc = md_bytes / double(md_alloced) * 100.0;
const double mc_u_perc = mc_bytes / double(mc_alloced) * 100.0;
const double total_u_perc = total_bytes / double(total_alloced) * 100.0;
tty->print_cr(fmt, "ro", ro_bytes, ro_t_perc, ro_alloced, ro_u_perc, ro_space->bottom());
tty->print_cr(fmt, "rw", rw_bytes, rw_t_perc, rw_alloced, rw_u_perc, rw_space->bottom());
tty->print_cr(fmt, "md", md_bytes, md_t_perc, md_alloced, md_u_perc, md_low);
tty->print_cr(fmt, "mc", mc_bytes, mc_t_perc, mc_alloced, mc_u_perc, mc_low);
tty->print_cr("total : %9d [100.0%% of total] out of %9d bytes [%4.1f%% used]",
total_bytes, total_alloced, total_u_perc);
// Update the vtable pointers in all of the Klass objects in the
// heap. They should point to newly generated vtable.
patch_klass_vtables(vtbl_list, vtable);
// dunno what this is for.
char* saved_vtbl = (char*)os::malloc(vtbl_list_size * sizeof(void*), mtClass);
memmove(saved_vtbl, vtbl_list, vtbl_list_size * sizeof(void*));
memset(vtbl_list, 0, vtbl_list_size * sizeof(void*));
// Create and write the archive file that maps the shared spaces.
FileMapInfo* mapinfo = new FileMapInfo();
mapinfo->populate_header(MetaspaceShared::max_alignment());
// Pass 1 - update file offsets in header.
mapinfo->write_header();
mapinfo->write_space(MetaspaceShared::ro, _loader_data->ro_metaspace(), true);
mapinfo->write_space(MetaspaceShared::rw, _loader_data->rw_metaspace(), false);
mapinfo->write_region(MetaspaceShared::md, _md_vs.low(),
pointer_delta(md_top, _md_vs.low(), sizeof(char)),
SharedMiscDataSize,
false, false);
mapinfo->write_region(MetaspaceShared::mc, _mc_vs.low(),
pointer_delta(mc_top, _mc_vs.low(), sizeof(char)),
SharedMiscCodeSize,
true, true);
// Pass 2 - write data.
mapinfo->open_for_write();
mapinfo->write_header();
mapinfo->write_space(MetaspaceShared::ro, _loader_data->ro_metaspace(), true);
mapinfo->write_space(MetaspaceShared::rw, _loader_data->rw_metaspace(), false);
mapinfo->write_region(MetaspaceShared::md, _md_vs.low(),
pointer_delta(md_top, _md_vs.low(), sizeof(char)),
SharedMiscDataSize,
false, false);
mapinfo->write_region(MetaspaceShared::mc, _mc_vs.low(),
pointer_delta(mc_top, _mc_vs.low(), sizeof(char)),
SharedMiscCodeSize,
true, true);
mapinfo->close();
memmove(vtbl_list, saved_vtbl, vtbl_list_size * sizeof(void*));
if (PrintSharedSpaces) {
DumpAllocClosure dac;
dac.iterate_metaspace(_loader_data->ro_metaspace(), DumpAllocClosure::RO);
dac.iterate_metaspace(_loader_data->rw_metaspace(), DumpAllocClosure::RW);
dac.dump_stats(int(ro_bytes), int(rw_bytes), int(md_bytes), int(mc_bytes));
}
}
static void link_shared_classes(Klass* obj, TRAPS) {
Klass* k = obj;
if (k->oop_is_instance()) {
InstanceKlass* ik = (InstanceKlass*) k;
// Link the class to cause the bytecodes to be rewritten and the
// cpcache to be created.
if (ik->init_state() < InstanceKlass::linked) {
ik->link_class(THREAD);
guarantee(!HAS_PENDING_EXCEPTION, "exception in class rewriting");
}
}
}
// Support for a simple checksum of the contents of the class list
// file to prevent trivial tampering. The algorithm matches that in
// the MakeClassList program used by the J2SE build process.
#define JSUM_SEED ((jlong)CONST64(0xcafebabebabecafe))
static jlong
jsum(jlong start, const char *buf, const int len)
{
jlong h = start;
char *p = (char *)buf, *e = p + len;
while (p < e) {
char c = *p++;
if (c <= ' ') {
/* Skip spaces and control characters */
continue;
}
h = 31 * h + c;
}
return h;
}
// Preload classes from a list, populate the shared spaces and dump to a
// file.
void MetaspaceShared::preload_and_dump(TRAPS) {
TraceTime timer("Dump Shared Spaces", TraceStartupTime);
ResourceMark rm;
// Lock out GC - is it necessary? I don't think we care.
No_GC_Verifier no_gc;
// Preload classes to be shared.
// Should use some os:: method rather than fopen() here. aB.
// Construct the path to the class list (in jre/lib)
// Walk up two directories from the location of the VM and
// optionally tack on "lib" (depending on platform)
char class_list_path[JVM_MAXPATHLEN];
os::jvm_path(class_list_path, sizeof(class_list_path));
for (int i = 0; i < 3; i++) {
char *end = strrchr(class_list_path, *os::file_separator());
if (end != NULL) *end = '\0';
}
int class_list_path_len = (int)strlen(class_list_path);
if (class_list_path_len >= 3) {
if (strcmp(class_list_path + class_list_path_len - 3, "lib") != 0) {
strcat(class_list_path, os::file_separator());
strcat(class_list_path, "lib");
}
}
strcat(class_list_path, os::file_separator());
strcat(class_list_path, "classlist");
FILE* file = fopen(class_list_path, "r");
if (file != NULL) {
jlong computed_jsum = JSUM_SEED;
jlong file_jsum = 0;
char class_name[256];
int class_count = 0;
GrowableArray<Klass*>* class_promote_order = new GrowableArray<Klass*>();
// sun.io.Converters
static const char obj_array_sig[] = "[[Ljava/lang/Object;";
SymbolTable::new_permanent_symbol(obj_array_sig, THREAD);
// java.util.HashMap
static const char map_entry_array_sig[] = "[Ljava/util/Map$Entry;";
SymbolTable::new_permanent_symbol(map_entry_array_sig, THREAD);
tty->print("Loading classes to share ... ");
while ((fgets(class_name, sizeof class_name, file)) != NULL) {
if (*class_name == '#') {
jint fsh, fsl;
if (sscanf(class_name, "# %8x%8x\n", &fsh, &fsl) == 2) {
file_jsum = ((jlong)(fsh) << 32) | (fsl & 0xffffffff);
}
continue;
}
// Remove trailing newline
size_t name_len = strlen(class_name);
class_name[name_len-1] = '\0';
computed_jsum = jsum(computed_jsum, class_name, (const int)name_len - 1);
// Got a class name - load it.
TempNewSymbol class_name_symbol = SymbolTable::new_permanent_symbol(class_name, THREAD);
guarantee(!HAS_PENDING_EXCEPTION, "Exception creating a symbol.");
Klass* klass = SystemDictionary::resolve_or_null(class_name_symbol,
THREAD);
guarantee(!HAS_PENDING_EXCEPTION, "Exception resolving a class.");
if (klass != NULL) {
if (PrintSharedSpaces && Verbose && WizardMode) {
tty->print_cr("Shared spaces preloaded: %s", class_name);
}
InstanceKlass* ik = InstanceKlass::cast(klass);
// Should be class load order as per -XX:+TraceClassLoadingPreorder
class_promote_order->append(ik);
// Link the class to cause the bytecodes to be rewritten and the
// cpcache to be created. The linking is done as soon as classes
// are loaded in order that the related data structures (klass and
// cpCache) are located together.
if (ik->init_state() < InstanceKlass::linked) {
ik->link_class(THREAD);
guarantee(!(HAS_PENDING_EXCEPTION), "exception in class rewriting");
}
// TODO: Resolve klasses in constant pool
ik->constants()->resolve_class_constants(THREAD);
class_count++;
} else {
if (PrintSharedSpaces && Verbose && WizardMode) {
tty->cr();
tty->print_cr(" Preload failed: %s", class_name);
}
}
file_jsum = 0; // Checksum must be on last line of file
}
if (computed_jsum != file_jsum) {
tty->cr();
tty->print_cr("Preload failed: checksum of class list was incorrect.");
exit(1);
}
tty->print_cr("done. ");
if (PrintSharedSpaces) {
tty->print_cr("Shared spaces: preloaded %d classes", class_count);
}
// Rewrite and unlink classes.
tty->print("Rewriting and linking classes ... ");
// Link any classes which got missed. (It's not quite clear why
// they got missed.) This iteration would be unsafe if we weren't
// single-threaded at this point; however we can't do it on the VM
// thread because it requires object allocation.
SystemDictionary::classes_do(link_shared_classes, CATCH);
tty->print_cr("done. ");
// Create and dump the shared spaces. Everything so far is loaded
// with the null class loader.
ClassLoaderData* loader_data = ClassLoaderData::the_null_class_loader_data();
VM_PopulateDumpSharedSpace op(loader_data, class_promote_order);
VMThread::execute(&op);
} else {
char errmsg[JVM_MAXPATHLEN];
os::lasterror(errmsg, JVM_MAXPATHLEN);
tty->print_cr("Loading classlist failed: %s", errmsg);
exit(1);
}
// Since various initialization steps have been undone by this process,
// it is not reasonable to continue running a java process.
exit(0);
}
// Closure for serializing initialization data in from a data area
// (ptr_array) read from the shared file.
class ReadClosure : public SerializeClosure {
private:
intptr_t** _ptr_array;
inline intptr_t nextPtr() {
return *(*_ptr_array)++;
}
public:
ReadClosure(intptr_t** ptr_array) { _ptr_array = ptr_array; }
void do_ptr(void** p) {
assert(*p == NULL, "initializing previous initialized pointer.");
intptr_t obj = nextPtr();
assert((intptr_t)obj >= 0 || (intptr_t)obj < -100,
"hit tag while initializing ptrs.");
*p = (void*)obj;
}
void do_tag(int tag) {
int old_tag;
old_tag = (int)(intptr_t)nextPtr();
// do_int(&old_tag);
assert(tag == old_tag, "old tag doesn't match");
FileMapInfo::assert_mark(tag == old_tag);
}
void do_region(u_char* start, size_t size) {
assert((intptr_t)start % sizeof(intptr_t) == 0, "bad alignment");
assert(size % sizeof(intptr_t) == 0, "bad size");
do_tag((int)size);
while (size > 0) {
*(intptr_t*)start = nextPtr();
start += sizeof(intptr_t);
size -= sizeof(intptr_t);
}
}
bool reading() const { return true; }
};
// Return true if given address is in the mapped shared space.
bool MetaspaceShared::is_in_shared_space(const void* p) {
return UseSharedSpaces && FileMapInfo::current_info()->is_in_shared_space(p);
}
void MetaspaceShared::print_shared_spaces() {
if (UseSharedSpaces) {
FileMapInfo::current_info()->print_shared_spaces();
}
}
// Map shared spaces at requested addresses and return if succeeded.
// Need to keep the bounds of the ro and rw space for the Metaspace::contains
// call, or is_in_shared_space.
bool MetaspaceShared::map_shared_spaces(FileMapInfo* mapinfo) {
size_t image_alignment = mapinfo->alignment();
#ifndef _WINDOWS
// Map in the shared memory and then map the regions on top of it.
// On Windows, don't map the memory here because it will cause the
// mappings of the regions to fail.
ReservedSpace shared_rs = mapinfo->reserve_shared_memory();
if (!shared_rs.is_reserved()) return false;
#endif
assert(!DumpSharedSpaces, "Should not be called with DumpSharedSpaces");
char* _ro_base = NULL;
char* _rw_base = NULL;
char* _md_base = NULL;
char* _mc_base = NULL;
// Map each shared region
if ((_ro_base = mapinfo->map_region(ro)) != NULL &&
(_rw_base = mapinfo->map_region(rw)) != NULL &&
(_md_base = mapinfo->map_region(md)) != NULL &&
(_mc_base = mapinfo->map_region(mc)) != NULL &&
(image_alignment == (size_t)max_alignment())) {
// Success (no need to do anything)
return true;
} else {
// If there was a failure in mapping any of the spaces, unmap the ones
// that succeeded
if (_ro_base != NULL) mapinfo->unmap_region(ro);
if (_rw_base != NULL) mapinfo->unmap_region(rw);
if (_md_base != NULL) mapinfo->unmap_region(md);
if (_mc_base != NULL) mapinfo->unmap_region(mc);
#ifndef _WINDOWS
// Release the entire mapped region
shared_rs.release();
#endif
// If -Xshare:on is specified, print out the error message and exit VM,
// otherwise, set UseSharedSpaces to false and continue.
if (RequireSharedSpaces) {
vm_exit_during_initialization("Unable to use shared archive.", NULL);
} else {
FLAG_SET_DEFAULT(UseSharedSpaces, false);
}
return false;
}
}
// Read the miscellaneous data from the shared file, and
// serialize it out to its various destinations.
void MetaspaceShared::initialize_shared_spaces() {
FileMapInfo *mapinfo = FileMapInfo::current_info();
char* buffer = mapinfo->region_base(md);
// Skip over (reserve space for) a list of addresses of C++ vtables
// for Klass objects. They get filled in later.
void** vtbl_list = (void**)buffer;
buffer += MetaspaceShared::vtbl_list_size * sizeof(void*);
Universe::init_self_patching_vtbl_list(vtbl_list, vtbl_list_size);
// Skip over (reserve space for) dummy C++ vtables Klass objects.
// They are used as is.
intptr_t vtable_size = *(intptr_t*)buffer;
buffer += sizeof(intptr_t);
buffer += vtable_size;
// Create the symbol table using the bucket array at this spot in the
// misc data space. Since the symbol table is often modified, this
// region (of mapped pages) will be copy-on-write.
int symbolTableLen = *(intptr_t*)buffer;
buffer += sizeof(intptr_t);
int number_of_entries = *(intptr_t*)buffer;
buffer += sizeof(intptr_t);
SymbolTable::create_table((HashtableBucket<mtSymbol>*)buffer, symbolTableLen,
number_of_entries);
buffer += symbolTableLen;
// Create the shared dictionary using the bucket array at this spot in
// the misc data space. Since the shared dictionary table is never
// modified, this region (of mapped pages) will be (effectively, if
// not explicitly) read-only.
int sharedDictionaryLen = *(intptr_t*)buffer;
buffer += sizeof(intptr_t);
number_of_entries = *(intptr_t*)buffer;
buffer += sizeof(intptr_t);
SystemDictionary::set_shared_dictionary((HashtableBucket<mtClass>*)buffer,
sharedDictionaryLen,
number_of_entries);
buffer += sharedDictionaryLen;
// Create the package info table using the bucket array at this spot in
// the misc data space. Since the package info table is never
// modified, this region (of mapped pages) will be (effectively, if
// not explicitly) read-only.
int pkgInfoLen = *(intptr_t*)buffer;
buffer += sizeof(intptr_t);
number_of_entries = *(intptr_t*)buffer;
buffer += sizeof(intptr_t);
ClassLoader::create_package_info_table((HashtableBucket<mtClass>*)buffer, pkgInfoLen,
number_of_entries);
buffer += pkgInfoLen;
ClassLoader::verify();
// The following data in the shared misc data region are the linked
// list elements (HashtableEntry objects) for the symbol table, string
// table, and shared dictionary. The heap objects referred to by the
// symbol table, string table, and shared dictionary are permanent and
// unmovable. Since new entries added to the string and symbol tables
// are always added at the beginning of the linked lists, THESE LINKED
// LIST ELEMENTS ARE READ-ONLY.
int len = *(intptr_t*)buffer; // skip over symbol table entries
buffer += sizeof(intptr_t);
buffer += len;
len = *(intptr_t*)buffer; // skip over shared dictionary entries
buffer += sizeof(intptr_t);
buffer += len;
len = *(intptr_t*)buffer; // skip over package info table entries
buffer += sizeof(intptr_t);
buffer += len;
len = *(intptr_t*)buffer; // skip over package info table char[] arrays.
buffer += sizeof(intptr_t);
buffer += len;
intptr_t* array = (intptr_t*)buffer;
ReadClosure rc(&array);
serialize(&rc);
// Close the mapinfo file
mapinfo->close();
}
// JVM/TI RedefineClasses() support:
bool MetaspaceShared::remap_shared_readonly_as_readwrite() {
assert(SafepointSynchronize::is_at_safepoint(), "must be at safepoint");
if (UseSharedSpaces) {
// remap the shared readonly space to shared readwrite, private
FileMapInfo* mapinfo = FileMapInfo::current_info();
if (!mapinfo->remap_shared_readonly_as_readwrite()) {
return false;
}
}
return true;
}