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|
/*-------------------------------------------------------------------------
*
* proc.c
* routines to manage per-process shared memory data structure
*
* Portions Copyright (c) 1996-2022, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* src/backend/storage/lmgr/proc.c
*
*-------------------------------------------------------------------------
*/
/*
* Interface (a):
* ProcSleep(), ProcWakeup(),
* ProcQueueAlloc() -- create a shm queue for sleeping processes
* ProcQueueInit() -- create a queue without allocing memory
*
* Waiting for a lock causes the backend to be put to sleep. Whoever releases
* the lock wakes the process up again (and gives it an error code so it knows
* whether it was awoken on an error condition).
*
* Interface (b):
*
* ProcReleaseLocks -- frees the locks associated with current transaction
*
* ProcKill -- destroys the shared memory state (and locks)
* associated with the process.
*/
#include "postgres.h"
#include <signal.h>
#include <unistd.h>
#include <sys/time.h>
#include "access/transam.h"
#include "access/twophase.h"
#include "access/xlogutils.h"
#include "miscadmin.h"
#include "pgstat.h"
#include "postmaster/autovacuum.h"
#include "replication/slot.h"
#include "replication/syncrep.h"
#include "replication/walsender.h"
#include "storage/condition_variable.h"
#include "storage/ipc.h"
#include "storage/lmgr.h"
#include "storage/pmsignal.h"
#include "storage/proc.h"
#include "storage/procarray.h"
#include "storage/procsignal.h"
#include "storage/spin.h"
#include "storage/standby.h"
#include "utils/timeout.h"
#include "utils/timestamp.h"
/* GUC variables */
int DeadlockTimeout = 1000;
int StatementTimeout = 0;
int LockTimeout = 0;
int IdleInTransactionSessionTimeout = 0;
int IdleSessionTimeout = 0;
bool log_lock_waits = false;
/* Pointer to this process's PGPROC struct, if any */
PGPROC *MyProc = NULL;
/*
* This spinlock protects the freelist of recycled PGPROC structures.
* We cannot use an LWLock because the LWLock manager depends on already
* having a PGPROC and a wait semaphore! But these structures are touched
* relatively infrequently (only at backend startup or shutdown) and not for
* very long, so a spinlock is okay.
*/
NON_EXEC_STATIC slock_t *ProcStructLock = NULL;
/* Pointers to shared-memory structures */
PROC_HDR *ProcGlobal = NULL;
NON_EXEC_STATIC PGPROC *AuxiliaryProcs = NULL;
PGPROC *PreparedXactProcs = NULL;
/* If we are waiting for a lock, this points to the associated LOCALLOCK */
static LOCALLOCK *lockAwaited = NULL;
static DeadLockState deadlock_state = DS_NOT_YET_CHECKED;
/* Is a deadlock check pending? */
static volatile sig_atomic_t got_deadlock_timeout;
static void RemoveProcFromArray(int code, Datum arg);
static void ProcKill(int code, Datum arg);
static void AuxiliaryProcKill(int code, Datum arg);
static void CheckDeadLock(void);
/*
* Report shared-memory space needed by InitProcGlobal.
*/
Size
ProcGlobalShmemSize(void)
{
Size size = 0;
Size TotalProcs =
add_size(MaxBackends, add_size(NUM_AUXILIARY_PROCS, max_prepared_xacts));
/* ProcGlobal */
size = add_size(size, sizeof(PROC_HDR));
size = add_size(size, mul_size(TotalProcs, sizeof(PGPROC)));
size = add_size(size, sizeof(slock_t));
size = add_size(size, mul_size(TotalProcs, sizeof(*ProcGlobal->xids)));
size = add_size(size, mul_size(TotalProcs, sizeof(*ProcGlobal->subxidStates)));
size = add_size(size, mul_size(TotalProcs, sizeof(*ProcGlobal->statusFlags)));
return size;
}
/*
* Report number of semaphores needed by InitProcGlobal.
*/
int
ProcGlobalSemas(void)
{
/*
* We need a sema per backend (including autovacuum), plus one for each
* auxiliary process.
*/
return MaxBackends + NUM_AUXILIARY_PROCS;
}
/*
* InitProcGlobal -
* Initialize the global process table during postmaster or standalone
* backend startup.
*
* We also create all the per-process semaphores we will need to support
* the requested number of backends. We used to allocate semaphores
* only when backends were actually started up, but that is bad because
* it lets Postgres fail under load --- a lot of Unix systems are
* (mis)configured with small limits on the number of semaphores, and
* running out when trying to start another backend is a common failure.
* So, now we grab enough semaphores to support the desired max number
* of backends immediately at initialization --- if the sysadmin has set
* MaxConnections, max_worker_processes, max_wal_senders, or
* autovacuum_max_workers higher than his kernel will support, he'll
* find out sooner rather than later.
*
* Another reason for creating semaphores here is that the semaphore
* implementation typically requires us to create semaphores in the
* postmaster, not in backends.
*
* Note: this is NOT called by individual backends under a postmaster,
* not even in the EXEC_BACKEND case. The ProcGlobal and AuxiliaryProcs
* pointers must be propagated specially for EXEC_BACKEND operation.
*/
void
InitProcGlobal(void)
{
PGPROC *procs;
int i,
j;
bool found;
uint32 TotalProcs = MaxBackends + NUM_AUXILIARY_PROCS + max_prepared_xacts;
/* Create the ProcGlobal shared structure */
ProcGlobal = (PROC_HDR *)
ShmemInitStruct("Proc Header", sizeof(PROC_HDR), &found);
Assert(!found);
/*
* Initialize the data structures.
*/
ProcGlobal->spins_per_delay = DEFAULT_SPINS_PER_DELAY;
ProcGlobal->freeProcs = NULL;
ProcGlobal->autovacFreeProcs = NULL;
ProcGlobal->bgworkerFreeProcs = NULL;
ProcGlobal->walsenderFreeProcs = NULL;
ProcGlobal->startupBufferPinWaitBufId = -1;
ProcGlobal->walwriterLatch = NULL;
ProcGlobal->checkpointerLatch = NULL;
pg_atomic_init_u32(&ProcGlobal->procArrayGroupFirst, INVALID_PGPROCNO);
pg_atomic_init_u32(&ProcGlobal->clogGroupFirst, INVALID_PGPROCNO);
/*
* Create and initialize all the PGPROC structures we'll need. There are
* five separate consumers: (1) normal backends, (2) autovacuum workers
* and the autovacuum launcher, (3) background workers, (4) auxiliary
* processes, and (5) prepared transactions. Each PGPROC structure is
* dedicated to exactly one of these purposes, and they do not move
* between groups.
*/
procs = (PGPROC *) ShmemAlloc(TotalProcs * sizeof(PGPROC));
MemSet(procs, 0, TotalProcs * sizeof(PGPROC));
ProcGlobal->allProcs = procs;
/* XXX allProcCount isn't really all of them; it excludes prepared xacts */
ProcGlobal->allProcCount = MaxBackends + NUM_AUXILIARY_PROCS;
/*
* Allocate arrays mirroring PGPROC fields in a dense manner. See
* PROC_HDR.
*
* XXX: It might make sense to increase padding for these arrays, given
* how hotly they are accessed.
*/
ProcGlobal->xids =
(TransactionId *) ShmemAlloc(TotalProcs * sizeof(*ProcGlobal->xids));
MemSet(ProcGlobal->xids, 0, TotalProcs * sizeof(*ProcGlobal->xids));
ProcGlobal->subxidStates = (XidCacheStatus *) ShmemAlloc(TotalProcs * sizeof(*ProcGlobal->subxidStates));
MemSet(ProcGlobal->subxidStates, 0, TotalProcs * sizeof(*ProcGlobal->subxidStates));
ProcGlobal->statusFlags = (uint8 *) ShmemAlloc(TotalProcs * sizeof(*ProcGlobal->statusFlags));
MemSet(ProcGlobal->statusFlags, 0, TotalProcs * sizeof(*ProcGlobal->statusFlags));
for (i = 0; i < TotalProcs; i++)
{
/* Common initialization for all PGPROCs, regardless of type. */
/*
* Set up per-PGPROC semaphore, latch, and fpInfoLock. Prepared xact
* dummy PGPROCs don't need these though - they're never associated
* with a real process
*/
if (i < MaxBackends + NUM_AUXILIARY_PROCS)
{
procs[i].sem = PGSemaphoreCreate();
InitSharedLatch(&(procs[i].procLatch));
LWLockInitialize(&(procs[i].fpInfoLock), LWTRANCHE_LOCK_FASTPATH);
}
procs[i].pgprocno = i;
/*
* Newly created PGPROCs for normal backends, autovacuum and bgworkers
* must be queued up on the appropriate free list. Because there can
* only ever be a small, fixed number of auxiliary processes, no free
* list is used in that case; InitAuxiliaryProcess() instead uses a
* linear search. PGPROCs for prepared transactions are added to a
* free list by TwoPhaseShmemInit().
*/
if (i < MaxConnections)
{
/* PGPROC for normal backend, add to freeProcs list */
procs[i].links.next = (SHM_QUEUE *) ProcGlobal->freeProcs;
ProcGlobal->freeProcs = &procs[i];
procs[i].procgloballist = &ProcGlobal->freeProcs;
}
else if (i < MaxConnections + autovacuum_max_workers + 1)
{
/* PGPROC for AV launcher/worker, add to autovacFreeProcs list */
procs[i].links.next = (SHM_QUEUE *) ProcGlobal->autovacFreeProcs;
ProcGlobal->autovacFreeProcs = &procs[i];
procs[i].procgloballist = &ProcGlobal->autovacFreeProcs;
}
else if (i < MaxConnections + autovacuum_max_workers + 1 + max_worker_processes)
{
/* PGPROC for bgworker, add to bgworkerFreeProcs list */
procs[i].links.next = (SHM_QUEUE *) ProcGlobal->bgworkerFreeProcs;
ProcGlobal->bgworkerFreeProcs = &procs[i];
procs[i].procgloballist = &ProcGlobal->bgworkerFreeProcs;
}
else if (i < MaxBackends)
{
/* PGPROC for walsender, add to walsenderFreeProcs list */
procs[i].links.next = (SHM_QUEUE *) ProcGlobal->walsenderFreeProcs;
ProcGlobal->walsenderFreeProcs = &procs[i];
procs[i].procgloballist = &ProcGlobal->walsenderFreeProcs;
}
/* Initialize myProcLocks[] shared memory queues. */
for (j = 0; j < NUM_LOCK_PARTITIONS; j++)
SHMQueueInit(&(procs[i].myProcLocks[j]));
/* Initialize lockGroupMembers list. */
dlist_init(&procs[i].lockGroupMembers);
/*
* Initialize the atomic variables, otherwise, it won't be safe to
* access them for backends that aren't currently in use.
*/
pg_atomic_init_u32(&(procs[i].procArrayGroupNext), INVALID_PGPROCNO);
pg_atomic_init_u32(&(procs[i].clogGroupNext), INVALID_PGPROCNO);
pg_atomic_init_u64(&(procs[i].waitStart), 0);
}
/*
* Save pointers to the blocks of PGPROC structures reserved for auxiliary
* processes and prepared transactions.
*/
AuxiliaryProcs = &procs[MaxBackends];
PreparedXactProcs = &procs[MaxBackends + NUM_AUXILIARY_PROCS];
/* Create ProcStructLock spinlock, too */
ProcStructLock = (slock_t *) ShmemAlloc(sizeof(slock_t));
SpinLockInit(ProcStructLock);
}
/*
* InitProcess -- initialize a per-process data structure for this backend
*/
void
InitProcess(void)
{
PGPROC *volatile *procgloballist;
/*
* ProcGlobal should be set up already (if we are a backend, we inherit
* this by fork() or EXEC_BACKEND mechanism from the postmaster).
*/
if (ProcGlobal == NULL)
elog(PANIC, "proc header uninitialized");
if (MyProc != NULL)
elog(ERROR, "you already exist");
/* Decide which list should supply our PGPROC. */
if (IsAnyAutoVacuumProcess())
procgloballist = &ProcGlobal->autovacFreeProcs;
else if (IsBackgroundWorker)
procgloballist = &ProcGlobal->bgworkerFreeProcs;
else if (am_walsender)
procgloballist = &ProcGlobal->walsenderFreeProcs;
else
procgloballist = &ProcGlobal->freeProcs;
/*
* Try to get a proc struct from the appropriate free list. If this
* fails, we must be out of PGPROC structures (not to mention semaphores).
*
* While we are holding the ProcStructLock, also copy the current shared
* estimate of spins_per_delay to local storage.
*/
SpinLockAcquire(ProcStructLock);
set_spins_per_delay(ProcGlobal->spins_per_delay);
MyProc = *procgloballist;
if (MyProc != NULL)
{
*procgloballist = (PGPROC *) MyProc->links.next;
SpinLockRelease(ProcStructLock);
}
else
{
/*
* If we reach here, all the PGPROCs are in use. This is one of the
* possible places to detect "too many backends", so give the standard
* error message. XXX do we need to give a different failure message
* in the autovacuum case?
*/
SpinLockRelease(ProcStructLock);
if (am_walsender)
ereport(FATAL,
(errcode(ERRCODE_TOO_MANY_CONNECTIONS),
errmsg("number of requested standby connections exceeds max_wal_senders (currently %d)",
max_wal_senders)));
ereport(FATAL,
(errcode(ERRCODE_TOO_MANY_CONNECTIONS),
errmsg("sorry, too many clients already")));
}
/*
* Cross-check that the PGPROC is of the type we expect; if this were not
* the case, it would get returned to the wrong list.
*/
Assert(MyProc->procgloballist == procgloballist);
/*
* Now that we have a PGPROC, mark ourselves as an active postmaster
* child; this is so that the postmaster can detect it if we exit without
* cleaning up. (XXX autovac launcher currently doesn't participate in
* this; it probably should.)
*/
if (IsUnderPostmaster && !IsAutoVacuumLauncherProcess())
MarkPostmasterChildActive();
/*
* Initialize all fields of MyProc, except for those previously
* initialized by InitProcGlobal.
*/
SHMQueueElemInit(&(MyProc->links));
MyProc->waitStatus = PROC_WAIT_STATUS_OK;
MyProc->lxid = InvalidLocalTransactionId;
MyProc->fpVXIDLock = false;
MyProc->fpLocalTransactionId = InvalidLocalTransactionId;
MyProc->xid = InvalidTransactionId;
MyProc->xmin = InvalidTransactionId;
MyProc->pid = MyProcPid;
/* backendId, databaseId and roleId will be filled in later */
MyProc->backendId = InvalidBackendId;
MyProc->databaseId = InvalidOid;
MyProc->roleId = InvalidOid;
MyProc->tempNamespaceId = InvalidOid;
MyProc->isBackgroundWorker = IsBackgroundWorker;
MyProc->delayChkptFlags = 0;
MyProc->statusFlags = 0;
/* NB -- autovac launcher intentionally does not set IS_AUTOVACUUM */
if (IsAutoVacuumWorkerProcess())
MyProc->statusFlags |= PROC_IS_AUTOVACUUM;
MyProc->lwWaiting = LW_WS_NOT_WAITING;
MyProc->lwWaitMode = 0;
MyProc->waitLock = NULL;
MyProc->waitProcLock = NULL;
pg_atomic_write_u64(&MyProc->waitStart, 0);
#ifdef USE_ASSERT_CHECKING
{
int i;
/* Last process should have released all locks. */
for (i = 0; i < NUM_LOCK_PARTITIONS; i++)
Assert(SHMQueueEmpty(&(MyProc->myProcLocks[i])));
}
#endif
MyProc->recoveryConflictPending = false;
/* Initialize fields for sync rep */
MyProc->waitLSN = 0;
MyProc->syncRepState = SYNC_REP_NOT_WAITING;
SHMQueueElemInit(&(MyProc->syncRepLinks));
/* Initialize fields for group XID clearing. */
MyProc->procArrayGroupMember = false;
MyProc->procArrayGroupMemberXid = InvalidTransactionId;
Assert(pg_atomic_read_u32(&MyProc->procArrayGroupNext) == INVALID_PGPROCNO);
/* Check that group locking fields are in a proper initial state. */
Assert(MyProc->lockGroupLeader == NULL);
Assert(dlist_is_empty(&MyProc->lockGroupMembers));
/* Initialize wait event information. */
MyProc->wait_event_info = 0;
/* Initialize fields for group transaction status update. */
MyProc->clogGroupMember = false;
MyProc->clogGroupMemberXid = InvalidTransactionId;
MyProc->clogGroupMemberXidStatus = TRANSACTION_STATUS_IN_PROGRESS;
MyProc->clogGroupMemberPage = -1;
MyProc->clogGroupMemberLsn = InvalidXLogRecPtr;
Assert(pg_atomic_read_u32(&MyProc->clogGroupNext) == INVALID_PGPROCNO);
/*
* Acquire ownership of the PGPROC's latch, so that we can use WaitLatch
* on it. That allows us to repoint the process latch, which so far
* points to process local one, to the shared one.
*/
OwnLatch(&MyProc->procLatch);
SwitchToSharedLatch();
/* now that we have a proc, report wait events to shared memory */
pgstat_set_wait_event_storage(&MyProc->wait_event_info);
/*
* We might be reusing a semaphore that belonged to a failed process. So
* be careful and reinitialize its value here. (This is not strictly
* necessary anymore, but seems like a good idea for cleanliness.)
*/
PGSemaphoreReset(MyProc->sem);
/*
* Arrange to clean up at backend exit.
*/
on_shmem_exit(ProcKill, 0);
/*
* Now that we have a PGPROC, we could try to acquire locks, so initialize
* local state needed for LWLocks, and the deadlock checker.
*/
InitLWLockAccess();
InitDeadLockChecking();
}
/*
* InitProcessPhase2 -- make MyProc visible in the shared ProcArray.
*
* This is separate from InitProcess because we can't acquire LWLocks until
* we've created a PGPROC, but in the EXEC_BACKEND case ProcArrayAdd won't
* work until after we've done CreateSharedMemoryAndSemaphores.
*/
void
InitProcessPhase2(void)
{
Assert(MyProc != NULL);
/*
* Add our PGPROC to the PGPROC array in shared memory.
*/
ProcArrayAdd(MyProc);
/*
* Arrange to clean that up at backend exit.
*/
on_shmem_exit(RemoveProcFromArray, 0);
}
/*
* InitAuxiliaryProcess -- create a per-auxiliary-process data structure
*
* This is called by bgwriter and similar processes so that they will have a
* MyProc value that's real enough to let them wait for LWLocks. The PGPROC
* and sema that are assigned are one of the extra ones created during
* InitProcGlobal.
*
* Auxiliary processes are presently not expected to wait for real (lockmgr)
* locks, so we need not set up the deadlock checker. They are never added
* to the ProcArray or the sinval messaging mechanism, either. They also
* don't get a VXID assigned, since this is only useful when we actually
* hold lockmgr locks.
*
* Startup process however uses locks but never waits for them in the
* normal backend sense. Startup process also takes part in sinval messaging
* as a sendOnly process, so never reads messages from sinval queue. So
* Startup process does have a VXID and does show up in pg_locks.
*/
void
InitAuxiliaryProcess(void)
{
PGPROC *auxproc;
int proctype;
/*
* ProcGlobal should be set up already (if we are a backend, we inherit
* this by fork() or EXEC_BACKEND mechanism from the postmaster).
*/
if (ProcGlobal == NULL || AuxiliaryProcs == NULL)
elog(PANIC, "proc header uninitialized");
if (MyProc != NULL)
elog(ERROR, "you already exist");
/*
* We use the ProcStructLock to protect assignment and releasing of
* AuxiliaryProcs entries.
*
* While we are holding the ProcStructLock, also copy the current shared
* estimate of spins_per_delay to local storage.
*/
SpinLockAcquire(ProcStructLock);
set_spins_per_delay(ProcGlobal->spins_per_delay);
/*
* Find a free auxproc ... *big* trouble if there isn't one ...
*/
for (proctype = 0; proctype < NUM_AUXILIARY_PROCS; proctype++)
{
auxproc = &AuxiliaryProcs[proctype];
if (auxproc->pid == 0)
break;
}
if (proctype >= NUM_AUXILIARY_PROCS)
{
SpinLockRelease(ProcStructLock);
elog(FATAL, "all AuxiliaryProcs are in use");
}
/* Mark auxiliary proc as in use by me */
/* use volatile pointer to prevent code rearrangement */
((volatile PGPROC *) auxproc)->pid = MyProcPid;
MyProc = auxproc;
SpinLockRelease(ProcStructLock);
/*
* Initialize all fields of MyProc, except for those previously
* initialized by InitProcGlobal.
*/
SHMQueueElemInit(&(MyProc->links));
MyProc->waitStatus = PROC_WAIT_STATUS_OK;
MyProc->lxid = InvalidLocalTransactionId;
MyProc->fpVXIDLock = false;
MyProc->fpLocalTransactionId = InvalidLocalTransactionId;
MyProc->xid = InvalidTransactionId;
MyProc->xmin = InvalidTransactionId;
MyProc->backendId = InvalidBackendId;
MyProc->databaseId = InvalidOid;
MyProc->roleId = InvalidOid;
MyProc->tempNamespaceId = InvalidOid;
MyProc->isBackgroundWorker = IsBackgroundWorker;
MyProc->delayChkptFlags = 0;
MyProc->statusFlags = 0;
MyProc->lwWaiting = LW_WS_NOT_WAITING;
MyProc->lwWaitMode = 0;
MyProc->waitLock = NULL;
MyProc->waitProcLock = NULL;
pg_atomic_write_u64(&MyProc->waitStart, 0);
#ifdef USE_ASSERT_CHECKING
{
int i;
/* Last process should have released all locks. */
for (i = 0; i < NUM_LOCK_PARTITIONS; i++)
Assert(SHMQueueEmpty(&(MyProc->myProcLocks[i])));
}
#endif
/*
* Acquire ownership of the PGPROC's latch, so that we can use WaitLatch
* on it. That allows us to repoint the process latch, which so far
* points to process local one, to the shared one.
*/
OwnLatch(&MyProc->procLatch);
SwitchToSharedLatch();
/* now that we have a proc, report wait events to shared memory */
pgstat_set_wait_event_storage(&MyProc->wait_event_info);
/* Check that group locking fields are in a proper initial state. */
Assert(MyProc->lockGroupLeader == NULL);
Assert(dlist_is_empty(&MyProc->lockGroupMembers));
/*
* We might be reusing a semaphore that belonged to a failed process. So
* be careful and reinitialize its value here. (This is not strictly
* necessary anymore, but seems like a good idea for cleanliness.)
*/
PGSemaphoreReset(MyProc->sem);
/*
* Arrange to clean up at process exit.
*/
on_shmem_exit(AuxiliaryProcKill, Int32GetDatum(proctype));
}
/*
* Used from bufmgr to share the value of the buffer that Startup waits on,
* or to reset the value to "not waiting" (-1). This allows processing
* of recovery conflicts for buffer pins. Set is made before backends look
* at this value, so locking not required, especially since the set is
* an atomic integer set operation.
*/
void
SetStartupBufferPinWaitBufId(int bufid)
{
/* use volatile pointer to prevent code rearrangement */
volatile PROC_HDR *procglobal = ProcGlobal;
procglobal->startupBufferPinWaitBufId = bufid;
}
/*
* Used by backends when they receive a request to check for buffer pin waits.
*/
int
GetStartupBufferPinWaitBufId(void)
{
/* use volatile pointer to prevent code rearrangement */
volatile PROC_HDR *procglobal = ProcGlobal;
return procglobal->startupBufferPinWaitBufId;
}
/*
* Check whether there are at least N free PGPROC objects.
*
* Note: this is designed on the assumption that N will generally be small.
*/
bool
HaveNFreeProcs(int n)
{
PGPROC *proc;
SpinLockAcquire(ProcStructLock);
proc = ProcGlobal->freeProcs;
while (n > 0 && proc != NULL)
{
proc = (PGPROC *) proc->links.next;
n--;
}
SpinLockRelease(ProcStructLock);
return (n <= 0);
}
/*
* Check if the current process is awaiting a lock.
*/
bool
IsWaitingForLock(void)
{
if (lockAwaited == NULL)
return false;
return true;
}
/*
* Cancel any pending wait for lock, when aborting a transaction, and revert
* any strong lock count acquisition for a lock being acquired.
*
* (Normally, this would only happen if we accept a cancel/die
* interrupt while waiting; but an ereport(ERROR) before or during the lock
* wait is within the realm of possibility, too.)
*/
void
LockErrorCleanup(void)
{
LWLock *partitionLock;
DisableTimeoutParams timeouts[2];
HOLD_INTERRUPTS();
AbortStrongLockAcquire();
/* Nothing to do if we weren't waiting for a lock */
if (lockAwaited == NULL)
{
RESUME_INTERRUPTS();
return;
}
/*
* Turn off the deadlock and lock timeout timers, if they are still
* running (see ProcSleep). Note we must preserve the LOCK_TIMEOUT
* indicator flag, since this function is executed before
* ProcessInterrupts when responding to SIGINT; else we'd lose the
* knowledge that the SIGINT came from a lock timeout and not an external
* source.
*/
timeouts[0].id = DEADLOCK_TIMEOUT;
timeouts[0].keep_indicator = false;
timeouts[1].id = LOCK_TIMEOUT;
timeouts[1].keep_indicator = true;
disable_timeouts(timeouts, 2);
/* Unlink myself from the wait queue, if on it (might not be anymore!) */
partitionLock = LockHashPartitionLock(lockAwaited->hashcode);
LWLockAcquire(partitionLock, LW_EXCLUSIVE);
if (MyProc->links.next != NULL)
{
/* We could not have been granted the lock yet */
RemoveFromWaitQueue(MyProc, lockAwaited->hashcode);
}
else
{
/*
* Somebody kicked us off the lock queue already. Perhaps they
* granted us the lock, or perhaps they detected a deadlock. If they
* did grant us the lock, we'd better remember it in our local lock
* table.
*/
if (MyProc->waitStatus == PROC_WAIT_STATUS_OK)
GrantAwaitedLock();
}
lockAwaited = NULL;
LWLockRelease(partitionLock);
RESUME_INTERRUPTS();
}
/*
* ProcReleaseLocks() -- release locks associated with current transaction
* at main transaction commit or abort
*
* At main transaction commit, we release standard locks except session locks.
* At main transaction abort, we release all locks including session locks.
*
* Advisory locks are released only if they are transaction-level;
* session-level holds remain, whether this is a commit or not.
*
* At subtransaction commit, we don't release any locks (so this func is not
* needed at all); we will defer the releasing to the parent transaction.
* At subtransaction abort, we release all locks held by the subtransaction;
* this is implemented by retail releasing of the locks under control of
* the ResourceOwner mechanism.
*/
void
ProcReleaseLocks(bool isCommit)
{
if (!MyProc)
return;
/* If waiting, get off wait queue (should only be needed after error) */
LockErrorCleanup();
/* Release standard locks, including session-level if aborting */
LockReleaseAll(DEFAULT_LOCKMETHOD, !isCommit);
/* Release transaction-level advisory locks */
LockReleaseAll(USER_LOCKMETHOD, false);
}
/*
* RemoveProcFromArray() -- Remove this process from the shared ProcArray.
*/
static void
RemoveProcFromArray(int code, Datum arg)
{
Assert(MyProc != NULL);
ProcArrayRemove(MyProc, InvalidTransactionId);
}
/*
* ProcKill() -- Destroy the per-proc data structure for
* this process. Release any of its held LW locks.
*/
static void
ProcKill(int code, Datum arg)
{
PGPROC *proc;
PGPROC *volatile *procgloballist;
Assert(MyProc != NULL);
/* not safe if forked by system(), etc. */
if (MyProc->pid != (int) getpid())
elog(PANIC, "ProcKill() called in child process");
/* Make sure we're out of the sync rep lists */
SyncRepCleanupAtProcExit();
#ifdef USE_ASSERT_CHECKING
{
int i;
/* Last process should have released all locks. */
for (i = 0; i < NUM_LOCK_PARTITIONS; i++)
Assert(SHMQueueEmpty(&(MyProc->myProcLocks[i])));
}
#endif
/*
* Release any LW locks I am holding. There really shouldn't be any, but
* it's cheap to check again before we cut the knees off the LWLock
* facility by releasing our PGPROC ...
*/
LWLockReleaseAll();
/* Cancel any pending condition variable sleep, too */
ConditionVariableCancelSleep();
/*
* Detach from any lock group of which we are a member. If the leader
* exist before all other group members, its PGPROC will remain allocated
* until the last group process exits; that process must return the
* leader's PGPROC to the appropriate list.
*/
if (MyProc->lockGroupLeader != NULL)
{
PGPROC *leader = MyProc->lockGroupLeader;
LWLock *leader_lwlock = LockHashPartitionLockByProc(leader);
LWLockAcquire(leader_lwlock, LW_EXCLUSIVE);
Assert(!dlist_is_empty(&leader->lockGroupMembers));
dlist_delete(&MyProc->lockGroupLink);
if (dlist_is_empty(&leader->lockGroupMembers))
{
leader->lockGroupLeader = NULL;
if (leader != MyProc)
{
procgloballist = leader->procgloballist;
/* Leader exited first; return its PGPROC. */
SpinLockAcquire(ProcStructLock);
leader->links.next = (SHM_QUEUE *) *procgloballist;
*procgloballist = leader;
SpinLockRelease(ProcStructLock);
}
}
else if (leader != MyProc)
MyProc->lockGroupLeader = NULL;
LWLockRelease(leader_lwlock);
}
/*
* Reset MyLatch to the process local one. This is so that signal
* handlers et al can continue using the latch after the shared latch
* isn't ours anymore.
*
* Similarly, stop reporting wait events to MyProc->wait_event_info.
*
* After that clear MyProc and disown the shared latch.
*/
SwitchBackToLocalLatch();
pgstat_reset_wait_event_storage();
proc = MyProc;
MyProc = NULL;
DisownLatch(&proc->procLatch);
procgloballist = proc->procgloballist;
SpinLockAcquire(ProcStructLock);
/*
* If we're still a member of a locking group, that means we're a leader
* which has somehow exited before its children. The last remaining child
* will release our PGPROC. Otherwise, release it now.
*/
if (proc->lockGroupLeader == NULL)
{
/* Since lockGroupLeader is NULL, lockGroupMembers should be empty. */
Assert(dlist_is_empty(&proc->lockGroupMembers));
/* Return PGPROC structure (and semaphore) to appropriate freelist */
proc->links.next = (SHM_QUEUE *) *procgloballist;
*procgloballist = proc;
}
/* Update shared estimate of spins_per_delay */
ProcGlobal->spins_per_delay = update_spins_per_delay(ProcGlobal->spins_per_delay);
SpinLockRelease(ProcStructLock);
/*
* This process is no longer present in shared memory in any meaningful
* way, so tell the postmaster we've cleaned up acceptably well. (XXX
* autovac launcher should be included here someday)
*/
if (IsUnderPostmaster && !IsAutoVacuumLauncherProcess())
MarkPostmasterChildInactive();
/* wake autovac launcher if needed -- see comments in FreeWorkerInfo */
if (AutovacuumLauncherPid != 0)
kill(AutovacuumLauncherPid, SIGUSR2);
}
/*
* AuxiliaryProcKill() -- Cut-down version of ProcKill for auxiliary
* processes (bgwriter, etc). The PGPROC and sema are not released, only
* marked as not-in-use.
*/
static void
AuxiliaryProcKill(int code, Datum arg)
{
int proctype = DatumGetInt32(arg);
PGPROC *auxproc PG_USED_FOR_ASSERTS_ONLY;
PGPROC *proc;
Assert(proctype >= 0 && proctype < NUM_AUXILIARY_PROCS);
/* not safe if forked by system(), etc. */
if (MyProc->pid != (int) getpid())
elog(PANIC, "AuxiliaryProcKill() called in child process");
auxproc = &AuxiliaryProcs[proctype];
Assert(MyProc == auxproc);
/* Release any LW locks I am holding (see notes above) */
LWLockReleaseAll();
/* Cancel any pending condition variable sleep, too */
ConditionVariableCancelSleep();
/* look at the equivalent ProcKill() code for comments */
SwitchBackToLocalLatch();
pgstat_reset_wait_event_storage();
proc = MyProc;
MyProc = NULL;
DisownLatch(&proc->procLatch);
SpinLockAcquire(ProcStructLock);
/* Mark auxiliary proc no longer in use */
proc->pid = 0;
/* Update shared estimate of spins_per_delay */
ProcGlobal->spins_per_delay = update_spins_per_delay(ProcGlobal->spins_per_delay);
SpinLockRelease(ProcStructLock);
}
/*
* AuxiliaryPidGetProc -- get PGPROC for an auxiliary process
* given its PID
*
* Returns NULL if not found.
*/
PGPROC *
AuxiliaryPidGetProc(int pid)
{
PGPROC *result = NULL;
int index;
if (pid == 0) /* never match dummy PGPROCs */
return NULL;
for (index = 0; index < NUM_AUXILIARY_PROCS; index++)
{
PGPROC *proc = &AuxiliaryProcs[index];
if (proc->pid == pid)
{
result = proc;
break;
}
}
return result;
}
/*
* ProcQueue package: routines for putting processes to sleep
* and waking them up
*/
/*
* ProcQueueAlloc -- alloc/attach to a shared memory process queue
*
* Returns: a pointer to the queue
* Side Effects: Initializes the queue if it wasn't there before
*/
#ifdef NOT_USED
PROC_QUEUE *
ProcQueueAlloc(const char *name)
{
PROC_QUEUE *queue;
bool found;
queue = (PROC_QUEUE *)
ShmemInitStruct(name, sizeof(PROC_QUEUE), &found);
if (!found)
ProcQueueInit(queue);
return queue;
}
#endif
/*
* ProcQueueInit -- initialize a shared memory process queue
*/
void
ProcQueueInit(PROC_QUEUE *queue)
{
SHMQueueInit(&(queue->links));
queue->size = 0;
}
/*
* ProcSleep -- put a process to sleep on the specified lock
*
* Caller must have set MyProc->heldLocks to reflect locks already held
* on the lockable object by this process (under all XIDs).
*
* The lock table's partition lock must be held at entry, and will be held
* at exit.
*
* Result: PROC_WAIT_STATUS_OK if we acquired the lock, PROC_WAIT_STATUS_ERROR if not (deadlock).
*
* ASSUME: that no one will fiddle with the queue until after
* we release the partition lock.
*
* NOTES: The process queue is now a priority queue for locking.
*/
ProcWaitStatus
ProcSleep(LOCALLOCK *locallock, LockMethod lockMethodTable)
{
LOCKMODE lockmode = locallock->tag.mode;
LOCK *lock = locallock->lock;
PROCLOCK *proclock = locallock->proclock;
uint32 hashcode = locallock->hashcode;
LWLock *partitionLock = LockHashPartitionLock(hashcode);
PROC_QUEUE *waitQueue = &(lock->waitProcs);
SHM_QUEUE *waitQueuePos;
LOCKMASK myHeldLocks = MyProc->heldLocks;
TimestampTz standbyWaitStart = 0;
bool early_deadlock = false;
bool allow_autovacuum_cancel = true;
bool logged_recovery_conflict = false;
ProcWaitStatus myWaitStatus;
PGPROC *leader = MyProc->lockGroupLeader;
int i;
/*
* If group locking is in use, locks held by members of my locking group
* need to be included in myHeldLocks. This is not required for relation
* extension lock which conflict among group members. However, including
* them in myHeldLocks will give group members the priority to get those
* locks as compared to other backends which are also trying to acquire
* those locks. OTOH, we can avoid giving priority to group members for
* that kind of locks, but there doesn't appear to be a clear advantage of
* the same.
*/
if (leader != NULL)
{
SHM_QUEUE *procLocks = &(lock->procLocks);
PROCLOCK *otherproclock;
otherproclock = (PROCLOCK *)
SHMQueueNext(procLocks, procLocks, offsetof(PROCLOCK, lockLink));
while (otherproclock != NULL)
{
if (otherproclock->groupLeader == leader)
myHeldLocks |= otherproclock->holdMask;
otherproclock = (PROCLOCK *)
SHMQueueNext(procLocks, &otherproclock->lockLink,
offsetof(PROCLOCK, lockLink));
}
}
/*
* Determine where to add myself in the wait queue.
*
* Normally I should go at the end of the queue. However, if I already
* hold locks that conflict with the request of any previous waiter, put
* myself in the queue just in front of the first such waiter. This is not
* a necessary step, since deadlock detection would move me to before that
* waiter anyway; but it's relatively cheap to detect such a conflict
* immediately, and avoid delaying till deadlock timeout.
*
* Special case: if I find I should go in front of some waiter, check to
* see if I conflict with already-held locks or the requests before that
* waiter. If not, then just grant myself the requested lock immediately.
* This is the same as the test for immediate grant in LockAcquire, except
* we are only considering the part of the wait queue before my insertion
* point.
*/
if (myHeldLocks != 0 && waitQueue->size > 0)
{
LOCKMASK aheadRequests = 0;
SHM_QUEUE *proc_node;
proc_node = waitQueue->links.next;
for (i = 0; i < waitQueue->size; i++)
{
PGPROC *proc = (PGPROC *) proc_node;
/*
* If we're part of the same locking group as this waiter, its
* locks neither conflict with ours nor contribute to
* aheadRequests.
*/
if (leader != NULL && leader == proc->lockGroupLeader)
{
proc_node = proc->links.next;
continue;
}
/* Must he wait for me? */
if (lockMethodTable->conflictTab[proc->waitLockMode] & myHeldLocks)
{
/* Must I wait for him ? */
if (lockMethodTable->conflictTab[lockmode] & proc->heldLocks)
{
/*
* Yes, so we have a deadlock. Easiest way to clean up
* correctly is to call RemoveFromWaitQueue(), but we
* can't do that until we are *on* the wait queue. So, set
* a flag to check below, and break out of loop. Also,
* record deadlock info for later message.
*/
RememberSimpleDeadLock(MyProc, lockmode, lock, proc);
early_deadlock = true;
break;
}
/* I must go before this waiter. Check special case. */
if ((lockMethodTable->conflictTab[lockmode] & aheadRequests) == 0 &&
!LockCheckConflicts(lockMethodTable, lockmode, lock,
proclock))
{
/* Skip the wait and just grant myself the lock. */
GrantLock(lock, proclock, lockmode);
GrantAwaitedLock();
return PROC_WAIT_STATUS_OK;
}
/* Break out of loop to put myself before him */
break;
}
/* Nope, so advance to next waiter */
aheadRequests |= LOCKBIT_ON(proc->waitLockMode);
proc_node = proc->links.next;
}
/*
* If we iterated through the whole queue, cur points to the waitQueue
* head, so we will insert at tail of queue as desired.
*/
waitQueuePos = proc_node;
}
else
{
/* I hold no locks, so I can't push in front of anyone. */
waitQueuePos = &waitQueue->links;
}
/*
* Insert self into queue, at the position determined above.
*/
SHMQueueInsertBefore(waitQueuePos, &MyProc->links);
waitQueue->size++;
lock->waitMask |= LOCKBIT_ON(lockmode);
/* Set up wait information in PGPROC object, too */
MyProc->waitLock = lock;
MyProc->waitProcLock = proclock;
MyProc->waitLockMode = lockmode;
MyProc->waitStatus = PROC_WAIT_STATUS_WAITING;
/*
* If we detected deadlock, give up without waiting. This must agree with
* CheckDeadLock's recovery code.
*/
if (early_deadlock)
{
RemoveFromWaitQueue(MyProc, hashcode);
return PROC_WAIT_STATUS_ERROR;
}
/* mark that we are waiting for a lock */
lockAwaited = locallock;
/*
* Release the lock table's partition lock.
*
* NOTE: this may also cause us to exit critical-section state, possibly
* allowing a cancel/die interrupt to be accepted. This is OK because we
* have recorded the fact that we are waiting for a lock, and so
* LockErrorCleanup will clean up if cancel/die happens.
*/
LWLockRelease(partitionLock);
/*
* Also, now that we will successfully clean up after an ereport, it's
* safe to check to see if there's a buffer pin deadlock against the
* Startup process. Of course, that's only necessary if we're doing Hot
* Standby and are not the Startup process ourselves.
*/
if (RecoveryInProgress() && !InRecovery)
CheckRecoveryConflictDeadlock();
/* Reset deadlock_state before enabling the timeout handler */
deadlock_state = DS_NOT_YET_CHECKED;
got_deadlock_timeout = false;
/*
* Set timer so we can wake up after awhile and check for a deadlock. If a
* deadlock is detected, the handler sets MyProc->waitStatus =
* PROC_WAIT_STATUS_ERROR, allowing us to know that we must report failure
* rather than success.
*
* By delaying the check until we've waited for a bit, we can avoid
* running the rather expensive deadlock-check code in most cases.
*
* If LockTimeout is set, also enable the timeout for that. We can save a
* few cycles by enabling both timeout sources in one call.
*
* If InHotStandby we set lock waits slightly later for clarity with other
* code.
*/
if (!InHotStandby)
{
if (LockTimeout > 0)
{
EnableTimeoutParams timeouts[2];
timeouts[0].id = DEADLOCK_TIMEOUT;
timeouts[0].type = TMPARAM_AFTER;
timeouts[0].delay_ms = DeadlockTimeout;
timeouts[1].id = LOCK_TIMEOUT;
timeouts[1].type = TMPARAM_AFTER;
timeouts[1].delay_ms = LockTimeout;
enable_timeouts(timeouts, 2);
}
else
enable_timeout_after(DEADLOCK_TIMEOUT, DeadlockTimeout);
/*
* Use the current time obtained for the deadlock timeout timer as
* waitStart (i.e., the time when this process started waiting for the
* lock). Since getting the current time newly can cause overhead, we
* reuse the already-obtained time to avoid that overhead.
*
* Note that waitStart is updated without holding the lock table's
* partition lock, to avoid the overhead by additional lock
* acquisition. This can cause "waitstart" in pg_locks to become NULL
* for a very short period of time after the wait started even though
* "granted" is false. This is OK in practice because we can assume
* that users are likely to look at "waitstart" when waiting for the
* lock for a long time.
*/
pg_atomic_write_u64(&MyProc->waitStart,
get_timeout_start_time(DEADLOCK_TIMEOUT));
}
else if (log_recovery_conflict_waits)
{
/*
* Set the wait start timestamp if logging is enabled and in hot
* standby.
*/
standbyWaitStart = GetCurrentTimestamp();
}
/*
* If somebody wakes us between LWLockRelease and WaitLatch, the latch
* will not wait. But a set latch does not necessarily mean that the lock
* is free now, as there are many other sources for latch sets than
* somebody releasing the lock.
*
* We process interrupts whenever the latch has been set, so cancel/die
* interrupts are processed quickly. This means we must not mind losing
* control to a cancel/die interrupt here. We don't, because we have no
* shared-state-change work to do after being granted the lock (the
* grantor did it all). We do have to worry about canceling the deadlock
* timeout and updating the locallock table, but if we lose control to an
* error, LockErrorCleanup will fix that up.
*/
do
{
if (InHotStandby)
{
bool maybe_log_conflict =
(standbyWaitStart != 0 && !logged_recovery_conflict);
/* Set a timer and wait for that or for the lock to be granted */
ResolveRecoveryConflictWithLock(locallock->tag.lock,
maybe_log_conflict);
/*
* Emit the log message if the startup process is waiting longer
* than deadlock_timeout for recovery conflict on lock.
*/
if (maybe_log_conflict)
{
TimestampTz now = GetCurrentTimestamp();
if (TimestampDifferenceExceeds(standbyWaitStart, now,
DeadlockTimeout))
{
VirtualTransactionId *vxids;
int cnt;
vxids = GetLockConflicts(&locallock->tag.lock,
AccessExclusiveLock, &cnt);
/*
* Log the recovery conflict and the list of PIDs of
* backends holding the conflicting lock. Note that we do
* logging even if there are no such backends right now
* because the startup process here has already waited
* longer than deadlock_timeout.
*/
LogRecoveryConflict(PROCSIG_RECOVERY_CONFLICT_LOCK,
standbyWaitStart, now,
cnt > 0 ? vxids : NULL, true);
logged_recovery_conflict = true;
}
}
}
else
{
(void) WaitLatch(MyLatch, WL_LATCH_SET | WL_EXIT_ON_PM_DEATH, 0,
PG_WAIT_LOCK | locallock->tag.lock.locktag_type);
ResetLatch(MyLatch);
/* check for deadlocks first, as that's probably log-worthy */
if (got_deadlock_timeout)
{
CheckDeadLock();
got_deadlock_timeout = false;
}
CHECK_FOR_INTERRUPTS();
}
/*
* waitStatus could change from PROC_WAIT_STATUS_WAITING to something
* else asynchronously. Read it just once per loop to prevent
* surprising behavior (such as missing log messages).
*/
myWaitStatus = *((volatile ProcWaitStatus *) &MyProc->waitStatus);
/*
* If we are not deadlocked, but are waiting on an autovacuum-induced
* task, send a signal to interrupt it.
*/
if (deadlock_state == DS_BLOCKED_BY_AUTOVACUUM && allow_autovacuum_cancel)
{
PGPROC *autovac = GetBlockingAutoVacuumPgproc();
uint8 statusFlags;
uint8 lockmethod_copy;
LOCKTAG locktag_copy;
/*
* Grab info we need, then release lock immediately. Note this
* coding means that there is a tiny chance that the process
* terminates its current transaction and starts a different one
* before we have a change to send the signal; the worst possible
* consequence is that a for-wraparound vacuum is cancelled. But
* that could happen in any case unless we were to do kill() with
* the lock held, which is much more undesirable.
*/
LWLockAcquire(ProcArrayLock, LW_EXCLUSIVE);
statusFlags = ProcGlobal->statusFlags[autovac->pgxactoff];
lockmethod_copy = lock->tag.locktag_lockmethodid;
locktag_copy = lock->tag;
LWLockRelease(ProcArrayLock);
/*
* Only do it if the worker is not working to protect against Xid
* wraparound.
*/
if ((statusFlags & PROC_IS_AUTOVACUUM) &&
!(statusFlags & PROC_VACUUM_FOR_WRAPAROUND))
{
int pid = autovac->pid;
/* report the case, if configured to do so */
if (message_level_is_interesting(DEBUG1))
{
StringInfoData locktagbuf;
StringInfoData logbuf; /* errdetail for server log */
initStringInfo(&locktagbuf);
initStringInfo(&logbuf);
DescribeLockTag(&locktagbuf, &locktag_copy);
appendStringInfo(&logbuf,
"Process %d waits for %s on %s.",
MyProcPid,
GetLockmodeName(lockmethod_copy, lockmode),
locktagbuf.data);
ereport(DEBUG1,
(errmsg_internal("sending cancel to blocking autovacuum PID %d",
pid),
errdetail_log("%s", logbuf.data)));
pfree(locktagbuf.data);
pfree(logbuf.data);
}
/* send the autovacuum worker Back to Old Kent Road */
if (kill(pid, SIGINT) < 0)
{
/*
* There's a race condition here: once we release the
* ProcArrayLock, it's possible for the autovac worker to
* close up shop and exit before we can do the kill().
* Therefore, we do not whinge about no-such-process.
* Other errors such as EPERM could conceivably happen if
* the kernel recycles the PID fast enough, but such cases
* seem improbable enough that it's probably best to issue
* a warning if we see some other errno.
*/
if (errno != ESRCH)
ereport(WARNING,
(errmsg("could not send signal to process %d: %m",
pid)));
}
}
/* prevent signal from being sent again more than once */
allow_autovacuum_cancel = false;
}
/*
* If awoken after the deadlock check interrupt has run, and
* log_lock_waits is on, then report about the wait.
*/
if (log_lock_waits && deadlock_state != DS_NOT_YET_CHECKED)
{
StringInfoData buf,
lock_waiters_sbuf,
lock_holders_sbuf;
const char *modename;
long secs;
int usecs;
long msecs;
SHM_QUEUE *procLocks;
PROCLOCK *proclock;
bool first_holder = true,
first_waiter = true;
int lockHoldersNum = 0;
initStringInfo(&buf);
initStringInfo(&lock_waiters_sbuf);
initStringInfo(&lock_holders_sbuf);
DescribeLockTag(&buf, &locallock->tag.lock);
modename = GetLockmodeName(locallock->tag.lock.locktag_lockmethodid,
lockmode);
TimestampDifference(get_timeout_start_time(DEADLOCK_TIMEOUT),
GetCurrentTimestamp(),
&secs, &usecs);
msecs = secs * 1000 + usecs / 1000;
usecs = usecs % 1000;
/*
* we loop over the lock's procLocks to gather a list of all
* holders and waiters. Thus we will be able to provide more
* detailed information for lock debugging purposes.
*
* lock->procLocks contains all processes which hold or wait for
* this lock.
*/
LWLockAcquire(partitionLock, LW_SHARED);
procLocks = &(lock->procLocks);
proclock = (PROCLOCK *) SHMQueueNext(procLocks, procLocks,
offsetof(PROCLOCK, lockLink));
while (proclock)
{
/*
* we are a waiter if myProc->waitProcLock == proclock; we are
* a holder if it is NULL or something different
*/
if (proclock->tag.myProc->waitProcLock == proclock)
{
if (first_waiter)
{
appendStringInfo(&lock_waiters_sbuf, "%d",
proclock->tag.myProc->pid);
first_waiter = false;
}
else
appendStringInfo(&lock_waiters_sbuf, ", %d",
proclock->tag.myProc->pid);
}
else
{
if (first_holder)
{
appendStringInfo(&lock_holders_sbuf, "%d",
proclock->tag.myProc->pid);
first_holder = false;
}
else
appendStringInfo(&lock_holders_sbuf, ", %d",
proclock->tag.myProc->pid);
lockHoldersNum++;
}
proclock = (PROCLOCK *) SHMQueueNext(procLocks, &proclock->lockLink,
offsetof(PROCLOCK, lockLink));
}
LWLockRelease(partitionLock);
if (deadlock_state == DS_SOFT_DEADLOCK)
ereport(LOG,
(errmsg("process %d avoided deadlock for %s on %s by rearranging queue order after %ld.%03d ms",
MyProcPid, modename, buf.data, msecs, usecs),
(errdetail_log_plural("Process holding the lock: %s. Wait queue: %s.",
"Processes holding the lock: %s. Wait queue: %s.",
lockHoldersNum, lock_holders_sbuf.data, lock_waiters_sbuf.data))));
else if (deadlock_state == DS_HARD_DEADLOCK)
{
/*
* This message is a bit redundant with the error that will be
* reported subsequently, but in some cases the error report
* might not make it to the log (eg, if it's caught by an
* exception handler), and we want to ensure all long-wait
* events get logged.
*/
ereport(LOG,
(errmsg("process %d detected deadlock while waiting for %s on %s after %ld.%03d ms",
MyProcPid, modename, buf.data, msecs, usecs),
(errdetail_log_plural("Process holding the lock: %s. Wait queue: %s.",
"Processes holding the lock: %s. Wait queue: %s.",
lockHoldersNum, lock_holders_sbuf.data, lock_waiters_sbuf.data))));
}
if (myWaitStatus == PROC_WAIT_STATUS_WAITING)
ereport(LOG,
(errmsg("process %d still waiting for %s on %s after %ld.%03d ms",
MyProcPid, modename, buf.data, msecs, usecs),
(errdetail_log_plural("Process holding the lock: %s. Wait queue: %s.",
"Processes holding the lock: %s. Wait queue: %s.",
lockHoldersNum, lock_holders_sbuf.data, lock_waiters_sbuf.data))));
else if (myWaitStatus == PROC_WAIT_STATUS_OK)
ereport(LOG,
(errmsg("process %d acquired %s on %s after %ld.%03d ms",
MyProcPid, modename, buf.data, msecs, usecs)));
else
{
Assert(myWaitStatus == PROC_WAIT_STATUS_ERROR);
/*
* Currently, the deadlock checker always kicks its own
* process, which means that we'll only see
* PROC_WAIT_STATUS_ERROR when deadlock_state ==
* DS_HARD_DEADLOCK, and there's no need to print redundant
* messages. But for completeness and future-proofing, print
* a message if it looks like someone else kicked us off the
* lock.
*/
if (deadlock_state != DS_HARD_DEADLOCK)
ereport(LOG,
(errmsg("process %d failed to acquire %s on %s after %ld.%03d ms",
MyProcPid, modename, buf.data, msecs, usecs),
(errdetail_log_plural("Process holding the lock: %s. Wait queue: %s.",
"Processes holding the lock: %s. Wait queue: %s.",
lockHoldersNum, lock_holders_sbuf.data, lock_waiters_sbuf.data))));
}
/*
* At this point we might still need to wait for the lock. Reset
* state so we don't print the above messages again.
*/
deadlock_state = DS_NO_DEADLOCK;
pfree(buf.data);
pfree(lock_holders_sbuf.data);
pfree(lock_waiters_sbuf.data);
}
} while (myWaitStatus == PROC_WAIT_STATUS_WAITING);
/*
* Disable the timers, if they are still running. As in LockErrorCleanup,
* we must preserve the LOCK_TIMEOUT indicator flag: if a lock timeout has
* already caused QueryCancelPending to become set, we want the cancel to
* be reported as a lock timeout, not a user cancel.
*/
if (!InHotStandby)
{
if (LockTimeout > 0)
{
DisableTimeoutParams timeouts[2];
timeouts[0].id = DEADLOCK_TIMEOUT;
timeouts[0].keep_indicator = false;
timeouts[1].id = LOCK_TIMEOUT;
timeouts[1].keep_indicator = true;
disable_timeouts(timeouts, 2);
}
else
disable_timeout(DEADLOCK_TIMEOUT, false);
}
/*
* Emit the log message if recovery conflict on lock was resolved but the
* startup process waited longer than deadlock_timeout for it.
*/
if (InHotStandby && logged_recovery_conflict)
LogRecoveryConflict(PROCSIG_RECOVERY_CONFLICT_LOCK,
standbyWaitStart, GetCurrentTimestamp(),
NULL, false);
/*
* Re-acquire the lock table's partition lock. We have to do this to hold
* off cancel/die interrupts before we can mess with lockAwaited (else we
* might have a missed or duplicated locallock update).
*/
LWLockAcquire(partitionLock, LW_EXCLUSIVE);
/*
* We no longer want LockErrorCleanup to do anything.
*/
lockAwaited = NULL;
/*
* If we got the lock, be sure to remember it in the locallock table.
*/
if (MyProc->waitStatus == PROC_WAIT_STATUS_OK)
GrantAwaitedLock();
/*
* We don't have to do anything else, because the awaker did all the
* necessary update of the lock table and MyProc.
*/
return MyProc->waitStatus;
}
/*
* ProcWakeup -- wake up a process by setting its latch.
*
* Also remove the process from the wait queue and set its links invalid.
* RETURN: the next process in the wait queue.
*
* The appropriate lock partition lock must be held by caller.
*
* XXX: presently, this code is only used for the "success" case, and only
* works correctly for that case. To clean up in failure case, would need
* to twiddle the lock's request counts too --- see RemoveFromWaitQueue.
* Hence, in practice the waitStatus parameter must be PROC_WAIT_STATUS_OK.
*/
PGPROC *
ProcWakeup(PGPROC *proc, ProcWaitStatus waitStatus)
{
PGPROC *retProc;
/* Proc should be sleeping ... */
if (proc->links.prev == NULL ||
proc->links.next == NULL)
return NULL;
Assert(proc->waitStatus == PROC_WAIT_STATUS_WAITING);
/* Save next process before we zap the list link */
retProc = (PGPROC *) proc->links.next;
/* Remove process from wait queue */
SHMQueueDelete(&(proc->links));
(proc->waitLock->waitProcs.size)--;
/* Clean up process' state and pass it the ok/fail signal */
proc->waitLock = NULL;
proc->waitProcLock = NULL;
proc->waitStatus = waitStatus;
pg_atomic_write_u64(&MyProc->waitStart, 0);
/* And awaken it */
SetLatch(&proc->procLatch);
return retProc;
}
/*
* ProcLockWakeup -- routine for waking up processes when a lock is
* released (or a prior waiter is aborted). Scan all waiters
* for lock, waken any that are no longer blocked.
*
* The appropriate lock partition lock must be held by caller.
*/
void
ProcLockWakeup(LockMethod lockMethodTable, LOCK *lock)
{
PROC_QUEUE *waitQueue = &(lock->waitProcs);
int queue_size = waitQueue->size;
PGPROC *proc;
LOCKMASK aheadRequests = 0;
Assert(queue_size >= 0);
if (queue_size == 0)
return;
proc = (PGPROC *) waitQueue->links.next;
while (queue_size-- > 0)
{
LOCKMODE lockmode = proc->waitLockMode;
/*
* Waken if (a) doesn't conflict with requests of earlier waiters, and
* (b) doesn't conflict with already-held locks.
*/
if ((lockMethodTable->conflictTab[lockmode] & aheadRequests) == 0 &&
!LockCheckConflicts(lockMethodTable, lockmode, lock,
proc->waitProcLock))
{
/* OK to waken */
GrantLock(lock, proc->waitProcLock, lockmode);
proc = ProcWakeup(proc, PROC_WAIT_STATUS_OK);
/*
* ProcWakeup removes proc from the lock's waiting process queue
* and returns the next proc in chain; don't use proc's next-link,
* because it's been cleared.
*/
}
else
{
/*
* Cannot wake this guy. Remember his request for later checks.
*/
aheadRequests |= LOCKBIT_ON(lockmode);
proc = (PGPROC *) proc->links.next;
}
}
Assert(waitQueue->size >= 0);
}
/*
* CheckDeadLock
*
* We only get to this routine, if DEADLOCK_TIMEOUT fired while waiting for a
* lock to be released by some other process. Check if there's a deadlock; if
* not, just return. (But signal ProcSleep to log a message, if
* log_lock_waits is true.) If we have a real deadlock, remove ourselves from
* the lock's wait queue and signal an error to ProcSleep.
*/
static void
CheckDeadLock(void)
{
int i;
/*
* Acquire exclusive lock on the entire shared lock data structures. Must
* grab LWLocks in partition-number order to avoid LWLock deadlock.
*
* Note that the deadlock check interrupt had better not be enabled
* anywhere that this process itself holds lock partition locks, else this
* will wait forever. Also note that LWLockAcquire creates a critical
* section, so that this routine cannot be interrupted by cancel/die
* interrupts.
*/
for (i = 0; i < NUM_LOCK_PARTITIONS; i++)
LWLockAcquire(LockHashPartitionLockByIndex(i), LW_EXCLUSIVE);
/*
* Check to see if we've been awoken by anyone in the interim.
*
* If we have, we can return and resume our transaction -- happy day.
* Before we are awoken the process releasing the lock grants it to us so
* we know that we don't have to wait anymore.
*
* We check by looking to see if we've been unlinked from the wait queue.
* This is safe because we hold the lock partition lock.
*/
if (MyProc->links.prev == NULL ||
MyProc->links.next == NULL)
goto check_done;
#ifdef LOCK_DEBUG
if (Debug_deadlocks)
DumpAllLocks();
#endif
/* Run the deadlock check, and set deadlock_state for use by ProcSleep */
deadlock_state = DeadLockCheck(MyProc);
if (deadlock_state == DS_HARD_DEADLOCK)
{
/*
* Oops. We have a deadlock.
*
* Get this process out of wait state. (Note: we could do this more
* efficiently by relying on lockAwaited, but use this coding to
* preserve the flexibility to kill some other transaction than the
* one detecting the deadlock.)
*
* RemoveFromWaitQueue sets MyProc->waitStatus to
* PROC_WAIT_STATUS_ERROR, so ProcSleep will report an error after we
* return from the signal handler.
*/
Assert(MyProc->waitLock != NULL);
RemoveFromWaitQueue(MyProc, LockTagHashCode(&(MyProc->waitLock->tag)));
/*
* We're done here. Transaction abort caused by the error that
* ProcSleep will raise will cause any other locks we hold to be
* released, thus allowing other processes to wake up; we don't need
* to do that here. NOTE: an exception is that releasing locks we
* hold doesn't consider the possibility of waiters that were blocked
* behind us on the lock we just failed to get, and might now be
* wakable because we're not in front of them anymore. However,
* RemoveFromWaitQueue took care of waking up any such processes.
*/
}
/*
* And release locks. We do this in reverse order for two reasons: (1)
* Anyone else who needs more than one of the locks will be trying to lock
* them in increasing order; we don't want to release the other process
* until it can get all the locks it needs. (2) This avoids O(N^2)
* behavior inside LWLockRelease.
*/
check_done:
for (i = NUM_LOCK_PARTITIONS; --i >= 0;)
LWLockRelease(LockHashPartitionLockByIndex(i));
}
/*
* CheckDeadLockAlert - Handle the expiry of deadlock_timeout.
*
* NB: Runs inside a signal handler, be careful.
*/
void
CheckDeadLockAlert(void)
{
int save_errno = errno;
got_deadlock_timeout = true;
/*
* Have to set the latch again, even if handle_sig_alarm already did. Back
* then got_deadlock_timeout wasn't yet set... It's unlikely that this
* ever would be a problem, but setting a set latch again is cheap.
*
* Note that, when this function runs inside procsignal_sigusr1_handler(),
* the handler function sets the latch again after the latch is set here.
*/
SetLatch(MyLatch);
errno = save_errno;
}
/*
* ProcWaitForSignal - wait for a signal from another backend.
*
* As this uses the generic process latch the caller has to be robust against
* unrelated wakeups: Always check that the desired state has occurred, and
* wait again if not.
*/
void
ProcWaitForSignal(uint32 wait_event_info)
{
(void) WaitLatch(MyLatch, WL_LATCH_SET | WL_EXIT_ON_PM_DEATH, 0,
wait_event_info);
ResetLatch(MyLatch);
CHECK_FOR_INTERRUPTS();
}
/*
* ProcSendSignal - set the latch of a backend identified by pgprocno
*/
void
ProcSendSignal(int pgprocno)
{
if (pgprocno < 0 || pgprocno >= ProcGlobal->allProcCount)
elog(ERROR, "pgprocno out of range");
SetLatch(&ProcGlobal->allProcs[pgprocno].procLatch);
}
/*
* BecomeLockGroupLeader - designate process as lock group leader
*
* Once this function has returned, other processes can join the lock group
* by calling BecomeLockGroupMember.
*/
void
BecomeLockGroupLeader(void)
{
LWLock *leader_lwlock;
/* If we already did it, we don't need to do it again. */
if (MyProc->lockGroupLeader == MyProc)
return;
/* We had better not be a follower. */
Assert(MyProc->lockGroupLeader == NULL);
/* Create single-member group, containing only ourselves. */
leader_lwlock = LockHashPartitionLockByProc(MyProc);
LWLockAcquire(leader_lwlock, LW_EXCLUSIVE);
MyProc->lockGroupLeader = MyProc;
dlist_push_head(&MyProc->lockGroupMembers, &MyProc->lockGroupLink);
LWLockRelease(leader_lwlock);
}
/*
* BecomeLockGroupMember - designate process as lock group member
*
* This is pretty straightforward except for the possibility that the leader
* whose group we're trying to join might exit before we manage to do so;
* and the PGPROC might get recycled for an unrelated process. To avoid
* that, we require the caller to pass the PID of the intended PGPROC as
* an interlock. Returns true if we successfully join the intended lock
* group, and false if not.
*/
bool
BecomeLockGroupMember(PGPROC *leader, int pid)
{
LWLock *leader_lwlock;
bool ok = false;
/* Group leader can't become member of group */
Assert(MyProc != leader);
/* Can't already be a member of a group */
Assert(MyProc->lockGroupLeader == NULL);
/* PID must be valid. */
Assert(pid != 0);
/*
* Get lock protecting the group fields. Note LockHashPartitionLockByProc
* accesses leader->pgprocno in a PGPROC that might be free. This is safe
* because all PGPROCs' pgprocno fields are set during shared memory
* initialization and never change thereafter; so we will acquire the
* correct lock even if the leader PGPROC is in process of being recycled.
*/
leader_lwlock = LockHashPartitionLockByProc(leader);
LWLockAcquire(leader_lwlock, LW_EXCLUSIVE);
/* Is this the leader we're looking for? */
if (leader->pid == pid && leader->lockGroupLeader == leader)
{
/* OK, join the group */
ok = true;
MyProc->lockGroupLeader = leader;
dlist_push_tail(&leader->lockGroupMembers, &MyProc->lockGroupLink);
}
LWLockRelease(leader_lwlock);
return ok;
}
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