8232365: Implementation for JEP 363: Remove the Concurrent Mark Sweep (CMS) Garbage Collector
Reviewed-by: kbarrett, tschatzl, erikj, coleenp, dholmes
/*
* 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.
*
*/
#ifndef SHARE_OOPS_MARKWORD_HPP
#define SHARE_OOPS_MARKWORD_HPP
#include "metaprogramming/integralConstant.hpp"
#include "metaprogramming/primitiveConversions.hpp"
#include "oops/oopsHierarchy.hpp"
#include "runtime/globals.hpp"
// The markWord describes the header of an object.
//
// Bit-format of an object header (most significant first, big endian layout below):
//
// 32 bits:
// --------
// hash:25 ------------>| age:4 biased_lock:1 lock:2 (normal object)
// JavaThread*:23 epoch:2 age:4 biased_lock:1 lock:2 (biased object)
//
// 64 bits:
// --------
// unused:25 hash:31 -->| unused_gap:1 age:4 biased_lock:1 lock:2 (normal object)
// JavaThread*:54 epoch:2 unused_gap:1 age:4 biased_lock:1 lock:2 (biased object)
//
// - hash contains the identity hash value: largest value is
// 31 bits, see os::random(). Also, 64-bit vm's require
// a hash value no bigger than 32 bits because they will not
// properly generate a mask larger than that: see library_call.cpp
// and c1_CodePatterns_sparc.cpp.
//
// - the biased lock pattern is used to bias a lock toward a given
// thread. When this pattern is set in the low three bits, the lock
// is either biased toward a given thread or "anonymously" biased,
// indicating that it is possible for it to be biased. When the
// lock is biased toward a given thread, locking and unlocking can
// be performed by that thread without using atomic operations.
// When a lock's bias is revoked, it reverts back to the normal
// locking scheme described below.
//
// Note that we are overloading the meaning of the "unlocked" state
// of the header. Because we steal a bit from the age we can
// guarantee that the bias pattern will never be seen for a truly
// unlocked object.
//
// Note also that the biased state contains the age bits normally
// contained in the object header. Large increases in scavenge
// times were seen when these bits were absent and an arbitrary age
// assigned to all biased objects, because they tended to consume a
// significant fraction of the eden semispaces and were not
// promoted promptly, causing an increase in the amount of copying
// performed. The runtime system aligns all JavaThread* pointers to
// a very large value (currently 128 bytes (32bVM) or 256 bytes (64bVM))
// to make room for the age bits & the epoch bits (used in support of
// biased locking).
//
// [JavaThread* | epoch | age | 1 | 01] lock is biased toward given thread
// [0 | epoch | age | 1 | 01] lock is anonymously biased
//
// - the two lock bits are used to describe three states: locked/unlocked and monitor.
//
// [ptr | 00] locked ptr points to real header on stack
// [header | 0 | 01] unlocked regular object header
// [ptr | 10] monitor inflated lock (header is wapped out)
// [ptr | 11] marked used by markSweep to mark an object
// not valid at any other time
//
// We assume that stack/thread pointers have the lowest two bits cleared.
class BasicLock;
class ObjectMonitor;
class JavaThread;
class markWord {
private:
uintptr_t _value;
public:
explicit markWord(uintptr_t value) : _value(value) {}
markWord() { /* uninitialized */}
// It is critical for performance that this class be trivially
// destructable, copyable, and assignable.
static markWord from_pointer(void* ptr) {
return markWord((uintptr_t)ptr);
}
void* to_pointer() const {
return (void*)_value;
}
bool operator==(const markWord& other) const {
return _value == other._value;
}
bool operator!=(const markWord& other) const {
return !operator==(other);
}
// Conversion
uintptr_t value() const { return _value; }
// Constants
static const int age_bits = 4;
static const int lock_bits = 2;
static const int biased_lock_bits = 1;
static const int max_hash_bits = BitsPerWord - age_bits - lock_bits - biased_lock_bits;
static const int hash_bits = max_hash_bits > 31 ? 31 : max_hash_bits;
static const int unused_gap_bits = LP64_ONLY(1) NOT_LP64(0);
static const int epoch_bits = 2;
// The biased locking code currently requires that the age bits be
// contiguous to the lock bits.
static const int lock_shift = 0;
static const int biased_lock_shift = lock_bits;
static const int age_shift = lock_bits + biased_lock_bits;
static const int unused_gap_shift = age_shift + age_bits;
static const int hash_shift = unused_gap_shift + unused_gap_bits;
static const int epoch_shift = hash_shift;
static const uintptr_t lock_mask = right_n_bits(lock_bits);
static const uintptr_t lock_mask_in_place = lock_mask << lock_shift;
static const uintptr_t biased_lock_mask = right_n_bits(lock_bits + biased_lock_bits);
static const uintptr_t biased_lock_mask_in_place= biased_lock_mask << lock_shift;
static const uintptr_t biased_lock_bit_in_place = 1 << biased_lock_shift;
static const uintptr_t age_mask = right_n_bits(age_bits);
static const uintptr_t age_mask_in_place = age_mask << age_shift;
static const uintptr_t epoch_mask = right_n_bits(epoch_bits);
static const uintptr_t epoch_mask_in_place = epoch_mask << epoch_shift;
static const uintptr_t hash_mask = right_n_bits(hash_bits);
static const uintptr_t hash_mask_in_place = hash_mask << hash_shift;
// Alignment of JavaThread pointers encoded in object header required by biased locking
static const size_t biased_lock_alignment = 2 << (epoch_shift + epoch_bits);
static const uintptr_t locked_value = 0;
static const uintptr_t unlocked_value = 1;
static const uintptr_t monitor_value = 2;
static const uintptr_t marked_value = 3;
static const uintptr_t biased_lock_pattern = 5;
static const uintptr_t no_hash = 0 ; // no hash value assigned
static const uintptr_t no_hash_in_place = (address_word)no_hash << hash_shift;
static const uintptr_t no_lock_in_place = unlocked_value;
static const uint max_age = age_mask;
static const int max_bias_epoch = epoch_mask;
// Creates a markWord with all bits set to zero.
static markWord zero() { return markWord(uintptr_t(0)); }
// Biased Locking accessors.
// These must be checked by all code which calls into the
// ObjectSynchronizer and other code. The biasing is not understood
// by the lower-level CAS-based locking code, although the runtime
// fixes up biased locks to be compatible with it when a bias is
// revoked.
bool has_bias_pattern() const {
return (mask_bits(value(), biased_lock_mask_in_place) == biased_lock_pattern);
}
JavaThread* biased_locker() const {
assert(has_bias_pattern(), "should not call this otherwise");
return (JavaThread*) mask_bits(value(), ~(biased_lock_mask_in_place | age_mask_in_place | epoch_mask_in_place));
}
// Indicates that the mark has the bias bit set but that it has not
// yet been biased toward a particular thread
bool is_biased_anonymously() const {
return (has_bias_pattern() && (biased_locker() == NULL));
}
// Indicates epoch in which this bias was acquired. If the epoch
// changes due to too many bias revocations occurring, the biases
// from the previous epochs are all considered invalid.
int bias_epoch() const {
assert(has_bias_pattern(), "should not call this otherwise");
return (mask_bits(value(), epoch_mask_in_place) >> epoch_shift);
}
markWord set_bias_epoch(int epoch) {
assert(has_bias_pattern(), "should not call this otherwise");
assert((epoch & (~epoch_mask)) == 0, "epoch overflow");
return markWord(mask_bits(value(), ~epoch_mask_in_place) | (epoch << epoch_shift));
}
markWord incr_bias_epoch() {
return set_bias_epoch((1 + bias_epoch()) & epoch_mask);
}
// Prototype mark for initialization
static markWord biased_locking_prototype() {
return markWord( biased_lock_pattern );
}
// lock accessors (note that these assume lock_shift == 0)
bool is_locked() const {
return (mask_bits(value(), lock_mask_in_place) != unlocked_value);
}
bool is_unlocked() const {
return (mask_bits(value(), biased_lock_mask_in_place) == unlocked_value);
}
bool is_marked() const {
return (mask_bits(value(), lock_mask_in_place) == marked_value);
}
bool is_neutral() const { return (mask_bits(value(), biased_lock_mask_in_place) == unlocked_value); }
// Special temporary state of the markWord while being inflated.
// Code that looks at mark outside a lock need to take this into account.
bool is_being_inflated() const { return (value() == 0); }
// Distinguished markword value - used when inflating over
// an existing stacklock. 0 indicates the markword is "BUSY".
// Lockword mutators that use a LD...CAS idiom should always
// check for and avoid overwriting a 0 value installed by some
// other thread. (They should spin or block instead. The 0 value
// is transient and *should* be short-lived).
static markWord INFLATING() { return zero(); } // inflate-in-progress
// Should this header be preserved during GC?
template <typename KlassProxy>
inline bool must_be_preserved(KlassProxy klass) const;
// Should this header (including its age bits) be preserved in the
// case of a promotion failure during scavenge?
// Note that we special case this situation. We want to avoid
// calling BiasedLocking::preserve_marks()/restore_marks() (which
// decrease the number of mark words that need to be preserved
// during GC) during each scavenge. During scavenges in which there
// is no promotion failure, we actually don't need to call the above
// routines at all, since we don't mutate and re-initialize the
// marks of promoted objects using init_mark(). However, during
// scavenges which result in promotion failure, we do re-initialize
// the mark words of objects, meaning that we should have called
// these mark word preservation routines. Currently there's no good
// place in which to call them in any of the scavengers (although
// guarded by appropriate locks we could make one), but the
// observation is that promotion failures are quite rare and
// reducing the number of mark words preserved during them isn't a
// high priority.
template <typename KlassProxy>
inline bool must_be_preserved_for_promotion_failure(KlassProxy klass) const;
// WARNING: The following routines are used EXCLUSIVELY by
// synchronization functions. They are not really gc safe.
// They must get updated if markWord layout get changed.
markWord set_unlocked() const {
return markWord(value() | unlocked_value);
}
bool has_locker() const {
return ((value() & lock_mask_in_place) == locked_value);
}
BasicLock* locker() const {
assert(has_locker(), "check");
return (BasicLock*) value();
}
bool has_monitor() const {
return ((value() & monitor_value) != 0);
}
ObjectMonitor* monitor() const {
assert(has_monitor(), "check");
// Use xor instead of &~ to provide one extra tag-bit check.
return (ObjectMonitor*) (value() ^ monitor_value);
}
bool has_displaced_mark_helper() const {
return ((value() & unlocked_value) == 0);
}
markWord displaced_mark_helper() const {
assert(has_displaced_mark_helper(), "check");
uintptr_t ptr = (value() & ~monitor_value);
return *(markWord*)ptr;
}
void set_displaced_mark_helper(markWord m) const {
assert(has_displaced_mark_helper(), "check");
uintptr_t ptr = (value() & ~monitor_value);
((markWord*)ptr)->_value = m._value;
}
markWord copy_set_hash(intptr_t hash) const {
uintptr_t tmp = value() & (~hash_mask_in_place);
tmp |= ((hash & hash_mask) << hash_shift);
return markWord(tmp);
}
// it is only used to be stored into BasicLock as the
// indicator that the lock is using heavyweight monitor
static markWord unused_mark() {
return markWord(marked_value);
}
// the following two functions create the markWord to be
// stored into object header, it encodes monitor info
static markWord encode(BasicLock* lock) {
return from_pointer(lock);
}
static markWord encode(ObjectMonitor* monitor) {
uintptr_t tmp = (uintptr_t) monitor;
return markWord(tmp | monitor_value);
}
static markWord encode(JavaThread* thread, uint age, int bias_epoch) {
uintptr_t tmp = (uintptr_t) thread;
assert(UseBiasedLocking && ((tmp & (epoch_mask_in_place | age_mask_in_place | biased_lock_mask_in_place)) == 0), "misaligned JavaThread pointer");
assert(age <= max_age, "age too large");
assert(bias_epoch <= max_bias_epoch, "bias epoch too large");
return markWord(tmp | (bias_epoch << epoch_shift) | (age << age_shift) | biased_lock_pattern);
}
// used to encode pointers during GC
markWord clear_lock_bits() { return markWord(value() & ~lock_mask_in_place); }
// age operations
markWord set_marked() { return markWord((value() & ~lock_mask_in_place) | marked_value); }
markWord set_unmarked() { return markWord((value() & ~lock_mask_in_place) | unlocked_value); }
uint age() const { return mask_bits(value() >> age_shift, age_mask); }
markWord set_age(uint v) const {
assert((v & ~age_mask) == 0, "shouldn't overflow age field");
return markWord((value() & ~age_mask_in_place) | ((v & age_mask) << age_shift));
}
markWord incr_age() const { return age() == max_age ? markWord(_value) : set_age(age() + 1); }
// hash operations
intptr_t hash() const {
return mask_bits(value() >> hash_shift, hash_mask);
}
bool has_no_hash() const {
return hash() == no_hash;
}
// Prototype mark for initialization
static markWord prototype() {
return markWord( no_hash_in_place | no_lock_in_place );
}
// Helper function for restoration of unmarked mark oops during GC
static inline markWord prototype_for_klass(const Klass* klass);
// Debugging
void print_on(outputStream* st) const;
// Prepare address of oop for placement into mark
inline static markWord encode_pointer_as_mark(void* p) { return from_pointer(p).set_marked(); }
// Recover address of oop from encoded form used in mark
inline void* decode_pointer() { if (UseBiasedLocking && has_bias_pattern()) return NULL; return (void*)clear_lock_bits().value(); }
};
// Support atomic operations.
template<>
struct PrimitiveConversions::Translate<markWord> : public TrueType {
typedef markWord Value;
typedef uintptr_t Decayed;
static Decayed decay(const Value& x) { return x.value(); }
static Value recover(Decayed x) { return Value(x); }
};
#endif // SHARE_OOPS_MARKWORD_HPP