8072911: Remove includes of oop.inline.hpp from .hpp files
Reviewed-by: brutisso, coleenp, jwilhelm, simonis, dholmes
/*
* Copyright (c) 1997, 2015, 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/altHashing.hpp"
#include "classfile/compactHashtable.hpp"
#include "classfile/javaClasses.hpp"
#include "classfile/symbolTable.hpp"
#include "classfile/systemDictionary.hpp"
#include "gc_interface/collectedHeap.inline.hpp"
#include "memory/allocation.inline.hpp"
#include "memory/filemap.hpp"
#include "memory/gcLocker.inline.hpp"
#include "oops/oop.inline.hpp"
#include "runtime/atomic.inline.hpp"
#include "runtime/mutexLocker.hpp"
#include "utilities/hashtable.inline.hpp"
PRAGMA_FORMAT_MUTE_WARNINGS_FOR_GCC
// --------------------------------------------------------------------------
// the number of buckets a thread claims
const int ClaimChunkSize = 32;
SymbolTable* SymbolTable::_the_table = NULL;
// Static arena for symbols that are not deallocated
Arena* SymbolTable::_arena = NULL;
bool SymbolTable::_needs_rehashing = false;
bool SymbolTable::_lookup_shared_first = false;
CompactHashtable<Symbol*, char> SymbolTable::_shared_table;
Symbol* SymbolTable::allocate_symbol(const u1* name, int len, bool c_heap, TRAPS) {
assert (len <= Symbol::max_length(), "should be checked by caller");
Symbol* sym;
if (DumpSharedSpaces) {
// Allocate all symbols to CLD shared metaspace
sym = new (len, ClassLoaderData::the_null_class_loader_data(), THREAD) Symbol(name, len, -1);
} else if (c_heap) {
// refcount starts as 1
sym = new (len, THREAD) Symbol(name, len, 1);
assert(sym != NULL, "new should call vm_exit_out_of_memory if C_HEAP is exhausted");
} else {
// Allocate to global arena
sym = new (len, arena(), THREAD) Symbol(name, len, -1);
}
return sym;
}
void SymbolTable::initialize_symbols(int arena_alloc_size) {
// Initialize the arena for global symbols, size passed in depends on CDS.
if (arena_alloc_size == 0) {
_arena = new (mtSymbol) Arena(mtSymbol);
} else {
_arena = new (mtSymbol) Arena(mtSymbol, arena_alloc_size);
}
}
// Call function for all symbols in the symbol table.
void SymbolTable::symbols_do(SymbolClosure *cl) {
// all symbols from shared table
_shared_table.symbols_do(cl);
// all symbols from the dynamic table
const int n = the_table()->table_size();
for (int i = 0; i < n; i++) {
for (HashtableEntry<Symbol*, mtSymbol>* p = the_table()->bucket(i);
p != NULL;
p = p->next()) {
cl->do_symbol(p->literal_addr());
}
}
}
int SymbolTable::_symbols_removed = 0;
int SymbolTable::_symbols_counted = 0;
volatile int SymbolTable::_parallel_claimed_idx = 0;
void SymbolTable::buckets_unlink(int start_idx, int end_idx, int* processed, int* removed, size_t* memory_total) {
for (int i = start_idx; i < end_idx; ++i) {
HashtableEntry<Symbol*, mtSymbol>** p = the_table()->bucket_addr(i);
HashtableEntry<Symbol*, mtSymbol>* entry = the_table()->bucket(i);
while (entry != NULL) {
// Shared entries are normally at the end of the bucket and if we run into
// a shared entry, then there is nothing more to remove. However, if we
// have rehashed the table, then the shared entries are no longer at the
// end of the bucket.
if (entry->is_shared() && !use_alternate_hashcode()) {
break;
}
Symbol* s = entry->literal();
(*memory_total) += s->size();
(*processed)++;
assert(s != NULL, "just checking");
// If reference count is zero, remove.
if (s->refcount() == 0) {
assert(!entry->is_shared(), "shared entries should be kept live");
delete s;
(*removed)++;
*p = entry->next();
the_table()->free_entry(entry);
} else {
p = entry->next_addr();
}
// get next entry
entry = (HashtableEntry<Symbol*, mtSymbol>*)HashtableEntry<Symbol*, mtSymbol>::make_ptr(*p);
}
}
}
// Remove unreferenced symbols from the symbol table
// This is done late during GC.
void SymbolTable::unlink(int* processed, int* removed) {
size_t memory_total = 0;
buckets_unlink(0, the_table()->table_size(), processed, removed, &memory_total);
_symbols_removed += *removed;
_symbols_counted += *processed;
// Exclude printing for normal PrintGCDetails because people parse
// this output.
if (PrintGCDetails && Verbose && WizardMode) {
gclog_or_tty->print(" [Symbols=%d size=" SIZE_FORMAT "K] ", *processed,
(memory_total*HeapWordSize)/1024);
}
}
void SymbolTable::possibly_parallel_unlink(int* processed, int* removed) {
const int limit = the_table()->table_size();
size_t memory_total = 0;
for (;;) {
// Grab next set of buckets to scan
int start_idx = Atomic::add(ClaimChunkSize, &_parallel_claimed_idx) - ClaimChunkSize;
if (start_idx >= limit) {
// End of table
break;
}
int end_idx = MIN2(limit, start_idx + ClaimChunkSize);
buckets_unlink(start_idx, end_idx, processed, removed, &memory_total);
}
Atomic::add(*processed, &_symbols_counted);
Atomic::add(*removed, &_symbols_removed);
// Exclude printing for normal PrintGCDetails because people parse
// this output.
if (PrintGCDetails && Verbose && WizardMode) {
gclog_or_tty->print(" [Symbols: scanned=%d removed=%d size=" SIZE_FORMAT "K] ", *processed, *removed,
(memory_total*HeapWordSize)/1024);
}
}
// Create a new table and using alternate hash code, populate the new table
// with the existing strings. Set flag to use the alternate hash code afterwards.
void SymbolTable::rehash_table() {
assert(SafepointSynchronize::is_at_safepoint(), "must be at safepoint");
// This should never happen with -Xshare:dump but it might in testing mode.
if (DumpSharedSpaces) return;
// Create a new symbol table
SymbolTable* new_table = new SymbolTable();
the_table()->move_to(new_table);
// Delete the table and buckets (entries are reused in new table).
delete _the_table;
// Don't check if we need rehashing until the table gets unbalanced again.
// Then rehash with a new global seed.
_needs_rehashing = false;
_the_table = new_table;
}
// Lookup a symbol in a bucket.
Symbol* SymbolTable::lookup_dynamic(int index, const char* name,
int len, unsigned int hash) {
int count = 0;
for (HashtableEntry<Symbol*, mtSymbol>* e = bucket(index); e != NULL; e = e->next()) {
count++; // count all entries in this bucket, not just ones with same hash
if (e->hash() == hash) {
Symbol* sym = e->literal();
if (sym->equals(name, len)) {
// something is referencing this symbol now.
sym->increment_refcount();
return sym;
}
}
}
// If the bucket size is too deep check if this hash code is insufficient.
if (count >= rehash_count && !needs_rehashing()) {
_needs_rehashing = check_rehash_table(count);
}
return NULL;
}
Symbol* SymbolTable::lookup_shared(const char* name,
int len, unsigned int hash) {
return _shared_table.lookup(name, hash, len);
}
Symbol* SymbolTable::lookup(int index, const char* name,
int len, unsigned int hash) {
Symbol* sym;
if (_lookup_shared_first) {
sym = lookup_shared(name, len, hash);
if (sym != NULL) {
return sym;
}
_lookup_shared_first = false;
return lookup_dynamic(index, name, len, hash);
} else {
sym = lookup_dynamic(index, name, len, hash);
if (sym != NULL) {
return sym;
}
sym = lookup_shared(name, len, hash);
if (sym != NULL) {
_lookup_shared_first = true;
}
return sym;
}
}
// Pick hashing algorithm.
unsigned int SymbolTable::hash_symbol(const char* s, int len) {
return use_alternate_hashcode() ?
AltHashing::murmur3_32(seed(), (const jbyte*)s, len) :
java_lang_String::hash_code(s, len);
}
// We take care not to be blocking while holding the
// SymbolTable_lock. Otherwise, the system might deadlock, since the
// symboltable is used during compilation (VM_thread) The lock free
// synchronization is simplified by the fact that we do not delete
// entries in the symbol table during normal execution (only during
// safepoints).
Symbol* SymbolTable::lookup(const char* name, int len, TRAPS) {
unsigned int hashValue = hash_symbol(name, len);
int index = the_table()->hash_to_index(hashValue);
Symbol* s = the_table()->lookup(index, name, len, hashValue);
// Found
if (s != NULL) return s;
// Grab SymbolTable_lock first.
MutexLocker ml(SymbolTable_lock, THREAD);
// Otherwise, add to symbol to table
return the_table()->basic_add(index, (u1*)name, len, hashValue, true, THREAD);
}
Symbol* SymbolTable::lookup(const Symbol* sym, int begin, int end, TRAPS) {
char* buffer;
int index, len;
unsigned int hashValue;
char* name;
{
debug_only(No_Safepoint_Verifier nsv;)
name = (char*)sym->base() + begin;
len = end - begin;
hashValue = hash_symbol(name, len);
index = the_table()->hash_to_index(hashValue);
Symbol* s = the_table()->lookup(index, name, len, hashValue);
// Found
if (s != NULL) return s;
}
// Otherwise, add to symbol to table. Copy to a C string first.
char stack_buf[128];
ResourceMark rm(THREAD);
if (len <= 128) {
buffer = stack_buf;
} else {
buffer = NEW_RESOURCE_ARRAY_IN_THREAD(THREAD, char, len);
}
for (int i=0; i<len; i++) {
buffer[i] = name[i];
}
// Make sure there is no safepoint in the code above since name can't move.
// We can't include the code in No_Safepoint_Verifier because of the
// ResourceMark.
// Grab SymbolTable_lock first.
MutexLocker ml(SymbolTable_lock, THREAD);
return the_table()->basic_add(index, (u1*)buffer, len, hashValue, true, THREAD);
}
Symbol* SymbolTable::lookup_only(const char* name, int len,
unsigned int& hash) {
hash = hash_symbol(name, len);
int index = the_table()->hash_to_index(hash);
Symbol* s = the_table()->lookup(index, name, len, hash);
return s;
}
// Look up the address of the literal in the SymbolTable for this Symbol*
// Do not create any new symbols
// Do not increment the reference count to keep this alive
Symbol** SymbolTable::lookup_symbol_addr(Symbol* sym){
unsigned int hash = hash_symbol((char*)sym->bytes(), sym->utf8_length());
int index = the_table()->hash_to_index(hash);
for (HashtableEntry<Symbol*, mtSymbol>* e = the_table()->bucket(index); e != NULL; e = e->next()) {
if (e->hash() == hash) {
Symbol* literal_sym = e->literal();
if (sym == literal_sym) {
return e->literal_addr();
}
}
}
return NULL;
}
// Suggestion: Push unicode-based lookup all the way into the hashing
// and probing logic, so there is no need for convert_to_utf8 until
// an actual new Symbol* is created.
Symbol* SymbolTable::lookup_unicode(const jchar* name, int utf16_length, TRAPS) {
int utf8_length = UNICODE::utf8_length((jchar*) name, utf16_length);
char stack_buf[128];
if (utf8_length < (int) sizeof(stack_buf)) {
char* chars = stack_buf;
UNICODE::convert_to_utf8(name, utf16_length, chars);
return lookup(chars, utf8_length, THREAD);
} else {
ResourceMark rm(THREAD);
char* chars = NEW_RESOURCE_ARRAY(char, utf8_length + 1);;
UNICODE::convert_to_utf8(name, utf16_length, chars);
return lookup(chars, utf8_length, THREAD);
}
}
Symbol* SymbolTable::lookup_only_unicode(const jchar* name, int utf16_length,
unsigned int& hash) {
int utf8_length = UNICODE::utf8_length((jchar*) name, utf16_length);
char stack_buf[128];
if (utf8_length < (int) sizeof(stack_buf)) {
char* chars = stack_buf;
UNICODE::convert_to_utf8(name, utf16_length, chars);
return lookup_only(chars, utf8_length, hash);
} else {
ResourceMark rm;
char* chars = NEW_RESOURCE_ARRAY(char, utf8_length + 1);;
UNICODE::convert_to_utf8(name, utf16_length, chars);
return lookup_only(chars, utf8_length, hash);
}
}
void SymbolTable::add(ClassLoaderData* loader_data, constantPoolHandle cp,
int names_count,
const char** names, int* lengths, int* cp_indices,
unsigned int* hashValues, TRAPS) {
// Grab SymbolTable_lock first.
MutexLocker ml(SymbolTable_lock, THREAD);
SymbolTable* table = the_table();
bool added = table->basic_add(loader_data, cp, names_count, names, lengths,
cp_indices, hashValues, CHECK);
if (!added) {
// do it the hard way
for (int i=0; i<names_count; i++) {
int index = table->hash_to_index(hashValues[i]);
bool c_heap = !loader_data->is_the_null_class_loader_data();
Symbol* sym = table->basic_add(index, (u1*)names[i], lengths[i], hashValues[i], c_heap, CHECK);
cp->symbol_at_put(cp_indices[i], sym);
}
}
}
Symbol* SymbolTable::new_permanent_symbol(const char* name, TRAPS) {
unsigned int hash;
Symbol* result = SymbolTable::lookup_only((char*)name, (int)strlen(name), hash);
if (result != NULL) {
return result;
}
// Grab SymbolTable_lock first.
MutexLocker ml(SymbolTable_lock, THREAD);
SymbolTable* table = the_table();
int index = table->hash_to_index(hash);
return table->basic_add(index, (u1*)name, (int)strlen(name), hash, false, THREAD);
}
Symbol* SymbolTable::basic_add(int index_arg, u1 *name, int len,
unsigned int hashValue_arg, bool c_heap, TRAPS) {
assert(!Universe::heap()->is_in_reserved(name),
"proposed name of symbol must be stable");
// Don't allow symbols to be created which cannot fit in a Symbol*.
if (len > Symbol::max_length()) {
THROW_MSG_0(vmSymbols::java_lang_InternalError(),
"name is too long to represent");
}
// Cannot hit a safepoint in this function because the "this" pointer can move.
No_Safepoint_Verifier nsv;
// Check if the symbol table has been rehashed, if so, need to recalculate
// the hash value and index.
unsigned int hashValue;
int index;
if (use_alternate_hashcode()) {
hashValue = hash_symbol((const char*)name, len);
index = hash_to_index(hashValue);
} else {
hashValue = hashValue_arg;
index = index_arg;
}
// Since look-up was done lock-free, we need to check if another
// thread beat us in the race to insert the symbol.
Symbol* test = lookup(index, (char*)name, len, hashValue);
if (test != NULL) {
// A race occurred and another thread introduced the symbol.
assert(test->refcount() != 0, "lookup should have incremented the count");
return test;
}
// Create a new symbol.
Symbol* sym = allocate_symbol(name, len, c_heap, CHECK_NULL);
assert(sym->equals((char*)name, len), "symbol must be properly initialized");
HashtableEntry<Symbol*, mtSymbol>* entry = new_entry(hashValue, sym);
add_entry(index, entry);
return sym;
}
// This version of basic_add adds symbols in batch from the constant pool
// parsing.
bool SymbolTable::basic_add(ClassLoaderData* loader_data, constantPoolHandle cp,
int names_count,
const char** names, int* lengths,
int* cp_indices, unsigned int* hashValues,
TRAPS) {
// Check symbol names are not too long. If any are too long, don't add any.
for (int i = 0; i< names_count; i++) {
if (lengths[i] > Symbol::max_length()) {
THROW_MSG_0(vmSymbols::java_lang_InternalError(),
"name is too long to represent");
}
}
// Cannot hit a safepoint in this function because the "this" pointer can move.
No_Safepoint_Verifier nsv;
for (int i=0; i<names_count; i++) {
// Check if the symbol table has been rehashed, if so, need to recalculate
// the hash value.
unsigned int hashValue;
if (use_alternate_hashcode()) {
hashValue = hash_symbol(names[i], lengths[i]);
} else {
hashValue = hashValues[i];
}
// Since look-up was done lock-free, we need to check if another
// thread beat us in the race to insert the symbol.
int index = hash_to_index(hashValue);
Symbol* test = lookup(index, names[i], lengths[i], hashValue);
if (test != NULL) {
// A race occurred and another thread introduced the symbol, this one
// will be dropped and collected. Use test instead.
cp->symbol_at_put(cp_indices[i], test);
assert(test->refcount() != 0, "lookup should have incremented the count");
} else {
// Create a new symbol. The null class loader is never unloaded so these
// are allocated specially in a permanent arena.
bool c_heap = !loader_data->is_the_null_class_loader_data();
Symbol* sym = allocate_symbol((const u1*)names[i], lengths[i], c_heap, CHECK_(false));
assert(sym->equals(names[i], lengths[i]), "symbol must be properly initialized"); // why wouldn't it be???
HashtableEntry<Symbol*, mtSymbol>* entry = new_entry(hashValue, sym);
add_entry(index, entry);
cp->symbol_at_put(cp_indices[i], sym);
}
}
return true;
}
void SymbolTable::verify() {
for (int i = 0; i < the_table()->table_size(); ++i) {
HashtableEntry<Symbol*, mtSymbol>* p = the_table()->bucket(i);
for ( ; p != NULL; p = p->next()) {
Symbol* s = (Symbol*)(p->literal());
guarantee(s != NULL, "symbol is NULL");
unsigned int h = hash_symbol((char*)s->bytes(), s->utf8_length());
guarantee(p->hash() == h, "broken hash in symbol table entry");
guarantee(the_table()->hash_to_index(h) == i,
"wrong index in symbol table");
}
}
}
void SymbolTable::dump(outputStream* st, bool verbose) {
if (!verbose) {
the_table()->dump_table(st, "SymbolTable");
} else {
st->print_cr("VERSION: 1.0");
for (int i = 0; i < the_table()->table_size(); ++i) {
HashtableEntry<Symbol*, mtSymbol>* p = the_table()->bucket(i);
for ( ; p != NULL; p = p->next()) {
Symbol* s = (Symbol*)(p->literal());
const char* utf8_string = (const char*)s->bytes();
int utf8_length = s->utf8_length();
st->print("%d %d: ", utf8_length, s->refcount());
HashtableTextDump::put_utf8(st, utf8_string, utf8_length);
st->cr();
}
}
}
}
bool SymbolTable::copy_compact_table(char** top, char*end) {
#if INCLUDE_CDS
CompactHashtableWriter ch_table("symbol", the_table()->number_of_entries(),
&MetaspaceShared::stats()->symbol);
if (*top + ch_table.get_required_bytes() > end) {
// not enough space left
return false;
}
for (int i = 0; i < the_table()->table_size(); ++i) {
HashtableEntry<Symbol*, mtSymbol>* p = the_table()->bucket(i);
for ( ; p != NULL; p = p->next()) {
Symbol* s = (Symbol*)(p->literal());
unsigned int fixed_hash = hash_symbol((char*)s->bytes(), s->utf8_length());
assert(fixed_hash == p->hash(), "must not rehash during dumping");
ch_table.add(fixed_hash, s);
}
}
char* old_top = *top;
ch_table.dump(top, end);
*top = (char*)align_pointer_up(*top, sizeof(void*));
#endif
return true;
}
const char* SymbolTable::init_shared_table(const char* buffer) {
const char* end = _shared_table.init(buffer);
return (const char*)align_pointer_up(end, sizeof(void*));
}
//---------------------------------------------------------------------------
// Non-product code
#ifndef PRODUCT
void SymbolTable::print_histogram() {
MutexLocker ml(SymbolTable_lock);
const int results_length = 100;
int counts[results_length];
int sizes[results_length];
int i,j;
// initialize results to zero
for (j = 0; j < results_length; j++) {
counts[j] = 0;
sizes[j] = 0;
}
int total_size = 0;
int total_count = 0;
int total_length = 0;
int max_length = 0;
int out_of_range_count = 0;
int out_of_range_size = 0;
for (i = 0; i < the_table()->table_size(); i++) {
HashtableEntry<Symbol*, mtSymbol>* p = the_table()->bucket(i);
for ( ; p != NULL; p = p->next()) {
int size = p->literal()->size();
int len = p->literal()->utf8_length();
if (len < results_length) {
counts[len]++;
sizes[len] += size;
} else {
out_of_range_count++;
out_of_range_size += size;
}
total_count++;
total_size += size;
total_length += len;
max_length = MAX2(max_length, len);
}
}
tty->print_cr("Symbol Table Histogram:");
tty->print_cr(" Total number of symbols %7d", total_count);
tty->print_cr(" Total size in memory %7dK",
(total_size*HeapWordSize)/1024);
tty->print_cr(" Total counted %7d", _symbols_counted);
tty->print_cr(" Total removed %7d", _symbols_removed);
if (_symbols_counted > 0) {
tty->print_cr(" Percent removed %3.2f",
((float)_symbols_removed/(float)_symbols_counted)* 100);
}
tty->print_cr(" Reference counts %7d", Symbol::_total_count);
tty->print_cr(" Symbol arena used %7dK", arena()->used()/1024);
tty->print_cr(" Symbol arena size %7dK", arena()->size_in_bytes()/1024);
tty->print_cr(" Total symbol length %7d", total_length);
tty->print_cr(" Maximum symbol length %7d", max_length);
tty->print_cr(" Average symbol length %7.2f", ((float) total_length / (float) total_count));
tty->print_cr(" Symbol length histogram:");
tty->print_cr(" %6s %10s %10s", "Length", "#Symbols", "Size");
for (i = 0; i < results_length; i++) {
if (counts[i] > 0) {
tty->print_cr(" %6d %10d %10dK", i, counts[i], (sizes[i]*HeapWordSize)/1024);
}
}
tty->print_cr(" >=%6d %10d %10dK\n", results_length,
out_of_range_count, (out_of_range_size*HeapWordSize)/1024);
}
void SymbolTable::print() {
for (int i = 0; i < the_table()->table_size(); ++i) {
HashtableEntry<Symbol*, mtSymbol>** p = the_table()->bucket_addr(i);
HashtableEntry<Symbol*, mtSymbol>* entry = the_table()->bucket(i);
if (entry != NULL) {
while (entry != NULL) {
tty->print(PTR_FORMAT " ", entry->literal());
entry->literal()->print();
tty->print(" %d", entry->literal()->refcount());
p = entry->next_addr();
entry = (HashtableEntry<Symbol*, mtSymbol>*)HashtableEntry<Symbol*, mtSymbol>::make_ptr(*p);
}
tty->cr();
}
}
}
#endif // PRODUCT
// Utility for dumping symbols
SymboltableDCmd::SymboltableDCmd(outputStream* output, bool heap) :
DCmdWithParser(output, heap),
_verbose("-verbose", "Dump the content of each symbol in the table",
"BOOLEAN", false, "false") {
_dcmdparser.add_dcmd_option(&_verbose);
}
void SymboltableDCmd::execute(DCmdSource source, TRAPS) {
VM_DumpHashtable dumper(output(), VM_DumpHashtable::DumpSymbols,
_verbose.value());
VMThread::execute(&dumper);
}
int SymboltableDCmd::num_arguments() {
ResourceMark rm;
SymboltableDCmd* dcmd = new SymboltableDCmd(NULL, false);
if (dcmd != NULL) {
DCmdMark mark(dcmd);
return dcmd->_dcmdparser.num_arguments();
} else {
return 0;
}
}