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#ifndef SHARE_RUNTIME_MUTEX_HPP
#define SHARE_RUNTIME_MUTEX_HPP
#include "memory/allocation.hpp"
#include "runtime/os.hpp"
// A Mutex/Monitor is a simple wrapper around a native lock plus condition
// variable that supports lock ownership tracking, lock ranking for deadlock
// detection and coordinates with the safepoint protocol.
// The default length of mutex name was originally chosen to be 64 to avoid
// false sharing. Now, PaddedMutex and PaddedMonitor are available for this purpose.
// TODO: Check if _name[MUTEX_NAME_LEN] should better get replaced by const char*.
static const int MUTEX_NAME_LEN = 64;
class Mutex : public CHeapObj<mtSynchronizer> {
public:
// A special lock: Is a lock where you are guaranteed not to block while you are
// holding it, i.e., no vm operation can happen, taking other (blocking) locks, etc.
// The rank 'access' is similar to 'special' and has the same restrictions on usage.
// It is reserved for locks that may be required in order to perform memory accesses
// that require special barriers, e.g. SATB GC barriers, that in turn uses locks.
// The rank 'tty' is also similar to 'special' and has the same restrictions.
// It is reserved for the tty_lock.
// Since memory accesses should be able to be performed pretty much anywhere
// in the code, that requires locks required for performing accesses being
// inherently a bit more special than even locks of the 'special' rank.
// NOTE: It is critical that the rank 'special' be the lowest (earliest)
// (except for "event" and "access") for the deadlock detection to work correctly.
// The rank native was only for use in Mutexes created by JVM_RawMonitorCreate,
// which being external to the VM are not subject to deadlock detection,
// however it has now been used by other locks that don't fit into the
// deadlock detection scheme.
// While at a safepoint no mutexes of rank safepoint are held by any thread.
// The rank named "leaf" is probably historical (and should
// be changed) -- mutexes of this rank aren't really leaf mutexes
// at all.
enum lock_types {
event,
access = event + 1,
tty = access + 2,
special = tty + 2,
suspend_resume = special + 1,
oopstorage = suspend_resume + 2,
leaf = oopstorage + 2,
safepoint = leaf + 10,
barrier = safepoint + 1,
nonleaf = barrier + 1,
max_nonleaf = nonleaf + 900,
native = max_nonleaf + 1
};
protected: // Monitor-Mutex metadata
Thread * volatile _owner; // The owner of the lock
os::PlatformMonitor _lock; // Native monitor implementation
char _name[MUTEX_NAME_LEN]; // Name of mutex/monitor
// Debugging fields for naming, deadlock detection, etc. (some only used in debug mode)
#ifdef ASSERT
bool _allow_vm_block;
int _rank; // rank (to avoid/detect potential deadlocks)
Mutex* _next; // Used by a Thread to link up owned locks
Thread* _last_owner; // the last thread to own the lock
static bool contains(Mutex* locks, Mutex* lock);
static Mutex* get_least_ranked_lock(Mutex* locks);
Mutex* get_least_ranked_lock_besides_this(Mutex* locks);
#endif // ASSERT
void set_owner_implementation(Thread* owner) NOT_DEBUG({ _owner = owner;});
void check_block_state (Thread* thread) NOT_DEBUG_RETURN;
void check_safepoint_state (Thread* thread) NOT_DEBUG_RETURN;
void check_no_safepoint_state(Thread* thread) NOT_DEBUG_RETURN;
void assert_owner (Thread* expected) NOT_DEBUG_RETURN;
void no_safepoint_verifier (Thread* thread, bool enable) NOT_DEBUG_RETURN;
public:
enum {
_allow_vm_block_flag = true,
_as_suspend_equivalent_flag = true
};
// Locks can be acquired with or without a safepoint check. NonJavaThreads do not follow
// the safepoint protocol when acquiring locks.
// Each lock can be acquired by only JavaThreads, only NonJavaThreads, or shared between
// Java and NonJavaThreads. When the lock is initialized with _safepoint_check_always,
// that means that whenever the lock is acquired by a JavaThread, it will verify that
// it is done with a safepoint check. In corollary, when the lock is initialized with
// _safepoint_check_never, that means that whenever the lock is acquired by a JavaThread
// it will verify that it is done without a safepoint check.
// There are a couple of existing locks that will sometimes have a safepoint check and
// sometimes not when acquired by a JavaThread, but these locks are set up carefully
// to avoid deadlocks. TODO: Fix these locks and remove _safepoint_check_sometimes.
// TODO: Locks that are shared between JavaThreads and NonJavaThreads
// should never encounter a safepoint check while they are held, or else a
// deadlock can occur. We should check this by noting which
// locks are shared, and walk held locks during safepoint checking.
enum SafepointCheckFlag {
_safepoint_check_flag,
_no_safepoint_check_flag
};
enum SafepointCheckRequired {
_safepoint_check_never, // Mutexes with this value will cause errors
// when acquired by a JavaThread with a safepoint check.
_safepoint_check_sometimes, // A couple of special locks are acquired by JavaThreads sometimes
// with and sometimes without safepoint checks. These
// locks will not produce errors when locked.
_safepoint_check_always // Mutexes with this value will cause errors
// when acquired by a JavaThread without a safepoint check.
};
NOT_PRODUCT(SafepointCheckRequired _safepoint_check_required;)
public:
Mutex(int rank, const char *name, bool allow_vm_block = false,
SafepointCheckRequired safepoint_check_required = _safepoint_check_always);
~Mutex();
void lock(); // prints out warning if VM thread blocks
void lock(Thread *thread); // overloaded with current thread
void unlock();
bool is_locked() const { return _owner != NULL; }
bool try_lock(); // Like lock(), but unblocking. It returns false instead
private:
void lock_contended(Thread *thread); // contended slow-path
public:
void release_for_safepoint();
// Lock without safepoint check. Should ONLY be used by safepoint code and other code
// that is guaranteed not to block while running inside the VM.
void lock_without_safepoint_check();
void lock_without_safepoint_check(Thread* self);
// Current owner - not not MT-safe. Can only be used to guarantee that
// the current running thread owns the lock
Thread* owner() const { return _owner; }
bool owned_by_self() const;
const char *name() const { return _name; }
void print_on_error(outputStream* st) const;
#ifndef PRODUCT
void print_on(outputStream* st) const;
void print() const { print_on(::tty); }
#endif
#ifdef ASSERT
int rank() const { return _rank; }
bool allow_vm_block() { return _allow_vm_block; }
Mutex *next() const { return _next; }
void set_next(Mutex *next) { _next = next; }
#endif // ASSERT
void set_owner(Thread* owner) { set_owner_implementation(owner); }
};
class Monitor : public Mutex {
void assert_wait_lock_state (Thread* self) NOT_DEBUG_RETURN;
public:
Monitor(int rank, const char *name, bool allow_vm_block = false,
SafepointCheckRequired safepoint_check_required = _safepoint_check_always);
// default destructor
// Wait until monitor is notified (or times out).
// Defaults are to make safepoint checks, wait time is forever (i.e.,
// zero), and not a suspend-equivalent condition. Returns true if wait
// times out; otherwise returns false.
bool wait(long timeout = 0,
bool as_suspend_equivalent = !_as_suspend_equivalent_flag);
bool wait_without_safepoint_check(long timeout = 0);
void notify();
void notify_all();
};
class PaddedMutex : public Mutex {
enum {
CACHE_LINE_PADDING = (int)DEFAULT_CACHE_LINE_SIZE - (int)sizeof(Mutex),
PADDING_LEN = CACHE_LINE_PADDING > 0 ? CACHE_LINE_PADDING : 1
};
char _padding[PADDING_LEN];
public:
PaddedMutex(int rank, const char *name, bool allow_vm_block = false,
SafepointCheckRequired safepoint_check_required = _safepoint_check_always) :
Mutex(rank, name, allow_vm_block, safepoint_check_required) {};
};
class PaddedMonitor : public Monitor {
enum {
CACHE_LINE_PADDING = (int)DEFAULT_CACHE_LINE_SIZE - (int)sizeof(Monitor),
PADDING_LEN = CACHE_LINE_PADDING > 0 ? CACHE_LINE_PADDING : 1
};
char _padding[PADDING_LEN];
public:
PaddedMonitor(int rank, const char *name, bool allow_vm_block = false,
SafepointCheckRequired safepoint_check_required = _safepoint_check_always) :
Monitor(rank, name, allow_vm_block, safepoint_check_required) {};
};
#endif // SHARE_RUNTIME_MUTEX_HPP