// Lock implementation #include "Python.h" #include "pycore_lock.h" #include "pycore_parking_lot.h" #include "pycore_semaphore.h" #ifdef MS_WINDOWS #define WIN32_LEAN_AND_MEAN #include // SwitchToThread() #elif defined(HAVE_SCHED_H) #include // sched_yield() #endif // If a thread waits on a lock for longer than TIME_TO_BE_FAIR_NS (1 ms), then // the unlocking thread directly hands off ownership of the lock. This avoids // starvation. static const _PyTime_t TIME_TO_BE_FAIR_NS = 1000*1000; // Spin for a bit before parking the thread. This is only enabled for // `--disable-gil` builds because it is unlikely to be helpful if the GIL is // enabled. #if Py_GIL_DISABLED static const int MAX_SPIN_COUNT = 40; #else static const int MAX_SPIN_COUNT = 0; #endif struct mutex_entry { // The time after which the unlocking thread should hand off lock ownership // directly to the waiting thread. Written by the waiting thread. _PyTime_t time_to_be_fair; // Set to 1 if the lock was handed off. Written by the unlocking thread. int handed_off; }; static void _Py_yield(void) { #ifdef MS_WINDOWS SwitchToThread(); #elif defined(HAVE_SCHED_H) sched_yield(); #endif } void _PyMutex_LockSlow(PyMutex *m) { _PyMutex_LockTimed(m, -1, _PY_LOCK_DETACH); } PyLockStatus _PyMutex_LockTimed(PyMutex *m, _PyTime_t timeout, _PyLockFlags flags) { uint8_t v = _Py_atomic_load_uint8_relaxed(&m->v); if ((v & _Py_LOCKED) == 0) { if (_Py_atomic_compare_exchange_uint8(&m->v, &v, v|_Py_LOCKED)) { return PY_LOCK_ACQUIRED; } } else if (timeout == 0) { return PY_LOCK_FAILURE; } _PyTime_t now = _PyTime_GetMonotonicClock(); _PyTime_t endtime = 0; if (timeout > 0) { endtime = _PyTime_Add(now, timeout); } struct mutex_entry entry = { .time_to_be_fair = now + TIME_TO_BE_FAIR_NS, .handed_off = 0, }; Py_ssize_t spin_count = 0; for (;;) { if ((v & _Py_LOCKED) == 0) { // The lock is unlocked. Try to grab it. if (_Py_atomic_compare_exchange_uint8(&m->v, &v, v|_Py_LOCKED)) { return PY_LOCK_ACQUIRED; } continue; } if (!(v & _Py_HAS_PARKED) && spin_count < MAX_SPIN_COUNT) { // Spin for a bit. _Py_yield(); spin_count++; continue; } if (timeout == 0) { return PY_LOCK_FAILURE; } uint8_t newv = v; if (!(v & _Py_HAS_PARKED)) { // We are the first waiter. Set the _Py_HAS_PARKED flag. newv = v | _Py_HAS_PARKED; if (!_Py_atomic_compare_exchange_uint8(&m->v, &v, newv)) { continue; } } int ret = _PyParkingLot_Park(&m->v, &newv, sizeof(newv), timeout, &entry, (flags & _PY_LOCK_DETACH) != 0); if (ret == Py_PARK_OK) { if (entry.handed_off) { // We own the lock now. assert(_Py_atomic_load_uint8_relaxed(&m->v) & _Py_LOCKED); return PY_LOCK_ACQUIRED; } } else if (ret == Py_PARK_INTR && (flags & _PY_LOCK_HANDLE_SIGNALS)) { if (Py_MakePendingCalls() < 0) { return PY_LOCK_INTR; } } else if (ret == Py_PARK_TIMEOUT) { assert(timeout >= 0); return PY_LOCK_FAILURE; } if (timeout > 0) { timeout = _PyDeadline_Get(endtime); if (timeout <= 0) { // Avoid negative values because those mean block forever. timeout = 0; } } v = _Py_atomic_load_uint8_relaxed(&m->v); } } static void mutex_unpark(PyMutex *m, struct mutex_entry *entry, int has_more_waiters) { uint8_t v = 0; if (entry) { _PyTime_t now = _PyTime_GetMonotonicClock(); int should_be_fair = now > entry->time_to_be_fair; entry->handed_off = should_be_fair; if (should_be_fair) { v |= _Py_LOCKED; } if (has_more_waiters) { v |= _Py_HAS_PARKED; } } _Py_atomic_store_uint8(&m->v, v); } int _PyMutex_TryUnlock(PyMutex *m) { uint8_t v = _Py_atomic_load_uint8(&m->v); for (;;) { if ((v & _Py_LOCKED) == 0) { // error: the mutex is not locked return -1; } else if ((v & _Py_HAS_PARKED)) { // wake up a single thread _PyParkingLot_Unpark(&m->v, (_Py_unpark_fn_t *)mutex_unpark, m); return 0; } else if (_Py_atomic_compare_exchange_uint8(&m->v, &v, _Py_UNLOCKED)) { // fast-path: no waiters return 0; } } } void _PyMutex_UnlockSlow(PyMutex *m) { if (_PyMutex_TryUnlock(m) < 0) { Py_FatalError("unlocking mutex that is not locked"); } } // _PyRawMutex stores a linked list of `struct raw_mutex_entry`, one for each // thread waiting on the mutex, directly in the mutex itself. struct raw_mutex_entry { struct raw_mutex_entry *next; _PySemaphore sema; }; void _PyRawMutex_LockSlow(_PyRawMutex *m) { struct raw_mutex_entry waiter; _PySemaphore_Init(&waiter.sema); uintptr_t v = _Py_atomic_load_uintptr(&m->v); for (;;) { if ((v & _Py_LOCKED) == 0) { // Unlocked: try to grab it (even if it has a waiter). if (_Py_atomic_compare_exchange_uintptr(&m->v, &v, v|_Py_LOCKED)) { break; } continue; } // Locked: try to add ourselves as a waiter. waiter.next = (struct raw_mutex_entry *)(v & ~1); uintptr_t desired = ((uintptr_t)&waiter)|_Py_LOCKED; if (!_Py_atomic_compare_exchange_uintptr(&m->v, &v, desired)) { continue; } // Wait for us to be woken up. Note that we still have to lock the // mutex ourselves: it is NOT handed off to us. _PySemaphore_Wait(&waiter.sema, -1, /*detach=*/0); } _PySemaphore_Destroy(&waiter.sema); } void _PyRawMutex_UnlockSlow(_PyRawMutex *m) { uintptr_t v = _Py_atomic_load_uintptr(&m->v); for (;;) { if ((v & _Py_LOCKED) == 0) { Py_FatalError("unlocking mutex that is not locked"); } struct raw_mutex_entry *waiter = (struct raw_mutex_entry *)(v & ~1); if (waiter) { uintptr_t next_waiter = (uintptr_t)waiter->next; if (_Py_atomic_compare_exchange_uintptr(&m->v, &v, next_waiter)) { _PySemaphore_Wakeup(&waiter->sema); return; } } else { if (_Py_atomic_compare_exchange_uintptr(&m->v, &v, _Py_UNLOCKED)) { return; } } } } void _PyEvent_Notify(PyEvent *evt) { uintptr_t v = _Py_atomic_exchange_uint8(&evt->v, _Py_LOCKED); if (v == _Py_UNLOCKED) { // no waiters return; } else if (v == _Py_LOCKED) { // event already set return; } else { assert(v == _Py_HAS_PARKED); _PyParkingLot_UnparkAll(&evt->v); } } void PyEvent_Wait(PyEvent *evt) { while (!PyEvent_WaitTimed(evt, -1)) ; } int PyEvent_WaitTimed(PyEvent *evt, _PyTime_t timeout_ns) { for (;;) { uint8_t v = _Py_atomic_load_uint8(&evt->v); if (v == _Py_LOCKED) { // event already set return 1; } if (v == _Py_UNLOCKED) { if (!_Py_atomic_compare_exchange_uint8(&evt->v, &v, _Py_HAS_PARKED)) { continue; } } uint8_t expected = _Py_HAS_PARKED; (void) _PyParkingLot_Park(&evt->v, &expected, sizeof(evt->v), timeout_ns, NULL, 1); return _Py_atomic_load_uint8(&evt->v) == _Py_LOCKED; } } static int unlock_once(_PyOnceFlag *o, int res) { // On success (res=0), we set the state to _Py_ONCE_INITIALIZED. // On failure (res=-1), we reset the state to _Py_UNLOCKED. uint8_t new_value; switch (res) { case -1: new_value = _Py_UNLOCKED; break; case 0: new_value = _Py_ONCE_INITIALIZED; break; default: { Py_FatalError("invalid result from _PyOnceFlag_CallOnce"); Py_UNREACHABLE(); break; } } uint8_t old_value = _Py_atomic_exchange_uint8(&o->v, new_value); if ((old_value & _Py_HAS_PARKED) != 0) { // wake up anyone waiting on the once flag _PyParkingLot_UnparkAll(&o->v); } return res; } int _PyOnceFlag_CallOnceSlow(_PyOnceFlag *flag, _Py_once_fn_t *fn, void *arg) { uint8_t v = _Py_atomic_load_uint8(&flag->v); for (;;) { if (v == _Py_UNLOCKED) { if (!_Py_atomic_compare_exchange_uint8(&flag->v, &v, _Py_LOCKED)) { continue; } int res = fn(arg); return unlock_once(flag, res); } if (v == _Py_ONCE_INITIALIZED) { return 0; } // The once flag is initializing (locked). assert((v & _Py_LOCKED)); if (!(v & _Py_HAS_PARKED)) { // We are the first waiter. Set the _Py_HAS_PARKED flag. uint8_t new_value = v | _Py_HAS_PARKED; if (!_Py_atomic_compare_exchange_uint8(&flag->v, &v, new_value)) { continue; } v = new_value; } // Wait for initialization to finish. _PyParkingLot_Park(&flag->v, &v, sizeof(v), -1, NULL, 1); v = _Py_atomic_load_uint8(&flag->v); } }