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Fix race condition in preparing a transaction for two-phase commit. 

To lock a prepared transaction's shared memory entry, we used to mark it
with the XID of the backend. When the XID was no longer active according
to the proc array, the entry was implicitly considered as not locked
anymore. However, when preparing a transaction, the backend's proc array
entry was cleared before transfering the locks (and some other state) to
the prepared transaction's dummy PGPROC entry, so there was a window where
another backend could finish the transaction before it was in fact fully
prepared.

To fix, rewrite the locking mechanism of global transaction entries. Instead
of an XID, just have simple locked-or-not flag in each entry (we store the
locking backend's backend id rather than a simple boolean, but that's just
for debugging purposes). The backend is responsible for explicitly unlocking
the entry, and to make sure that that happens, install a callback to unlock
it on abort or process exit.

Backpatch to all supported versions.
This commit is contained in:
Heikki Linnakangas 2014-05-15 16:37:50 +03:00
parent ff810b4928
commit bb38fb0d43
3 changed files with 144 additions and 47 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

169
src/backend/access/transam/twophase.c
View File

@ -58,6 +58,7 @@
#include "replication/walsender.h"
#include "replication/syncrep.h"
#include "storage/fd.h"
#include "storage/ipc.h"
#include "storage/predicate.h"
#include "storage/proc.h"
#include "storage/procarray.h"
@ -82,25 +83,25 @@ int max_prepared_xacts = 0;
*
* The lifecycle of a global transaction is:
*
* 1. After checking that the requested GID is not in use, set up an
* entry in the TwoPhaseState->prepXacts array with the correct XID and GID,
* with locking_xid = my own XID and valid = false.
* 1. After checking that the requested GID is not in use, set up an entry in
* the TwoPhaseState->prepXacts array with the correct GID and valid = false,
* and mark it as locked by my backend.
*
* 2. After successfully completing prepare, set valid = true and enter the
* referenced PGPROC into the global ProcArray.
*
* 3. To begin COMMIT PREPARED or ROLLBACK PREPARED, check that the entry
* is valid and its locking_xid is no longer active, then store my current
* XID into locking_xid. This prevents concurrent attempts to commit or
* rollback the same prepared xact.
* 3. To begin COMMIT PREPARED or ROLLBACK PREPARED, check that the entry is
* valid and not locked, then mark the entry as locked by storing my current
* backend ID into locking_backend. This prevents concurrent attempts to
* commit or rollback the same prepared xact.
*
* 4. On completion of COMMIT PREPARED or ROLLBACK PREPARED, remove the entry
* from the ProcArray and the TwoPhaseState->prepXacts array and return it to
* the freelist.
*
* Note that if the preparing transaction fails between steps 1 and 2, the
* entry will remain in prepXacts until recycled. We can detect recyclable
* entries by checking for valid = false and locking_xid no longer active.
* entry must be removed so that the GID and the GlobalTransaction struct
* can be reused. See AtAbort_Twophase().
*
* typedef struct GlobalTransactionData *GlobalTransaction appears in
* twophase.h
@ -115,8 +116,8 @@ typedef struct GlobalTransactionData
TimestampTz prepared_at; /* time of preparation */
XLogRecPtr prepare_lsn; /* XLOG offset of prepare record */
Oid owner; /* ID of user that executed the xact */
TransactionId locking_xid; /* top-level XID of backend working on xact */
bool valid; /* TRUE if fully prepared */
BackendId locking_backend; /* backend currently working on the xact */
bool valid; /* TRUE if PGPROC entry is in proc array */
char gid[GIDSIZE]; /* The GID assigned to the prepared xact */
} GlobalTransactionData;
@ -141,6 +142,12 @@ typedef struct TwoPhaseStateData
static TwoPhaseStateData *TwoPhaseState;
/*
* Global transaction entry currently locked by us, if any.
*/
static GlobalTransaction MyLockedGxact = NULL;
static bool twophaseExitRegistered = false;
static void RecordTransactionCommitPrepared(TransactionId xid,
int nchildren,
@ -157,6 +164,7 @@ static void RecordTransactionAbortPrepared(TransactionId xid,
RelFileNode *rels);
static void ProcessRecords(char *bufptr, TransactionId xid,
const TwoPhaseCallback callbacks[]);
static void RemoveGXact(GlobalTransaction gxact);
/*
@ -230,6 +238,74 @@ TwoPhaseShmemInit(void)
Assert(found);
}
/*
* Exit hook to unlock the global transaction entry we're working on.
*/
static void
AtProcExit_Twophase(int code, Datum arg)
{
/* same logic as abort */
AtAbort_Twophase();
}
/*
* Abort hook to unlock the global transaction entry we're working on.
*/
void
AtAbort_Twophase(void)
{
if (MyLockedGxact == NULL)
return;
/*
* What to do with the locked global transaction entry? If we were in
* the process of preparing the transaction, but haven't written the WAL
* record and state file yet, the transaction must not be considered as
* prepared. Likewise, if we are in the process of finishing an
* already-prepared transaction, and fail after having already written
* the 2nd phase commit or rollback record to the WAL, the transaction
* should not be considered as prepared anymore. In those cases, just
* remove the entry from shared memory.
*
* Otherwise, the entry must be left in place so that the transaction
* can be finished later, so just unlock it.
*
* If we abort during prepare, after having written the WAL record, we
* might not have transfered all locks and other state to the prepared
* transaction yet. Likewise, if we abort during commit or rollback,
* after having written the WAL record, we might not have released
* all the resources held by the transaction yet. In those cases, the
* in-memory state can be wrong, but it's too late to back out.
*/
if (!MyLockedGxact->valid)
{
RemoveGXact(MyLockedGxact);
}
else
{
LWLockAcquire(TwoPhaseStateLock, LW_EXCLUSIVE);
MyLockedGxact->locking_backend = InvalidBackendId;
LWLockRelease(TwoPhaseStateLock);
}
MyLockedGxact = NULL;
}
/*
* This is called after we have finished transfering state to the prepared
* PGXACT entry.
*/
void
PostPrepare_Twophase()
{
LWLockAcquire(TwoPhaseStateLock, LW_EXCLUSIVE);
MyLockedGxact->locking_backend = InvalidBackendId;
LWLockRelease(TwoPhaseStateLock);
MyLockedGxact = NULL;
}
/*
* MarkAsPreparing
@ -261,29 +337,15 @@ MarkAsPreparing(TransactionId xid, const char *gid,
errmsg("prepared transactions are disabled"),
errhint("Set max_prepared_transactions to a nonzero value.")));
LWLockAcquire(TwoPhaseStateLock, LW_EXCLUSIVE);
/*
* First, find and recycle any gxacts that failed during prepare. We do
* this partly to ensure we don't mistakenly say their GIDs are still
* reserved, and partly so we don't fail on out-of-slots unnecessarily.
*/
for (i = 0; i < TwoPhaseState->numPrepXacts; i++)
/* on first call, register the exit hook */
if (!twophaseExitRegistered)
{
gxact = TwoPhaseState->prepXacts[i];
if (!gxact->valid && !TransactionIdIsActive(gxact->locking_xid))
{
/* It's dead Jim ... remove from the active array */
TwoPhaseState->numPrepXacts--;
TwoPhaseState->prepXacts[i] = TwoPhaseState->prepXacts[TwoPhaseState->numPrepXacts];
/* and put it back in the freelist */
gxact->next = TwoPhaseState->freeGXacts;
TwoPhaseState->freeGXacts = gxact;
/* Back up index count too, so we don't miss scanning one */
i--;
}
before_shmem_exit(AtProcExit_Twophase, 0);
twophaseExitRegistered = true;
}
LWLockAcquire(TwoPhaseStateLock, LW_EXCLUSIVE);
/* Check for conflicting GID */
for (i = 0; i < TwoPhaseState->numPrepXacts; i++)
{
@ -340,7 +402,7 @@ MarkAsPreparing(TransactionId xid, const char *gid,
/* initialize LSN to 0 (start of WAL) */
gxact->prepare_lsn = 0;
gxact->owner = owner;
gxact->locking_xid = xid;
gxact->locking_backend = MyBackendId;
gxact->valid = false;
strcpy(gxact->gid, gid);
@ -348,6 +410,12 @@ MarkAsPreparing(TransactionId xid, const char *gid,
Assert(TwoPhaseState->numPrepXacts < max_prepared_xacts);
TwoPhaseState->prepXacts[TwoPhaseState->numPrepXacts++] = gxact;
/*
* Remember that we have this GlobalTransaction entry locked for us.
* If we abort after this, we must release it.
*/
MyLockedGxact = gxact;
LWLockRelease(TwoPhaseStateLock);
return gxact;
@ -410,6 +478,13 @@ LockGXact(const char *gid, Oid user)
{
int i;
/* on first call, register the exit hook */
if (!twophaseExitRegistered)
{
before_shmem_exit(AtProcExit_Twophase, 0);
twophaseExitRegistered = true;
}
LWLockAcquire(TwoPhaseStateLock, LW_EXCLUSIVE);
for (i = 0; i < TwoPhaseState->numPrepXacts; i++)
@ -424,15 +499,11 @@ LockGXact(const char *gid, Oid user)
continue;
/* Found it, but has someone else got it locked? */
if (TransactionIdIsValid(gxact->locking_xid))
{
if (TransactionIdIsActive(gxact->locking_xid))
ereport(ERROR,
(errcode(ERRCODE_OBJECT_NOT_IN_PREREQUISITE_STATE),
errmsg("prepared transaction with identifier \"%s\" is busy",
gid)));
gxact->locking_xid = InvalidTransactionId;
}
if (gxact->locking_backend != InvalidBackendId)
ereport(ERROR,
(errcode(ERRCODE_OBJECT_NOT_IN_PREREQUISITE_STATE),
errmsg("prepared transaction with identifier \"%s\" is busy",
gid)));
if (user != gxact->owner && !superuser_arg(user))
ereport(ERROR,
@ -453,7 +524,8 @@ LockGXact(const char *gid, Oid user)
errhint("Connect to the database where the transaction was prepared to finish it.")));
/* OK for me to lock it */
gxact->locking_xid = GetTopTransactionId();
gxact->locking_backend = MyBackendId;
MyLockedGxact = gxact;
LWLockRelease(TwoPhaseStateLock);
@ -1089,6 +1161,13 @@ EndPrepare(GlobalTransaction gxact)
*/
MyPgXact->delayChkpt = false;
/*
* Remember that we have this GlobalTransaction entry locked for us. If
* we crash after this point, it's too late to abort, but we must unlock
* it so that the prepared transaction can be committed or rolled back.
*/
MyLockedGxact = gxact;
END_CRIT_SECTION();
/*
@ -1335,8 +1414,9 @@ FinishPreparedTransaction(const char *gid, bool isCommit)
/*
* In case we fail while running the callbacks, mark the gxact invalid so
* no one else will try to commit/rollback, and so it can be recycled
* properly later. It is still locked by our XID so it won't go away yet.
* no one else will try to commit/rollback, and so it will be recycled
* if we fail after this point. It is still locked by our backend so it
* won't go away yet.
*
* (We assume it's safe to do this without taking TwoPhaseStateLock.)
*/
@ -1396,6 +1476,7 @@ FinishPreparedTransaction(const char *gid, bool isCommit)
RemoveTwoPhaseFile(xid, true);
RemoveGXact(gxact);
MyLockedGxact = NULL;
pfree(buf);
}

19
src/backend/access/transam/xact.c
View File

@ -2231,9 +2231,13 @@ PrepareTransaction(void)
ProcArrayClearTransaction(MyProc);
/*
* This is all post-transaction cleanup. Note that if an error is raised
* here, it's too late to abort the transaction. This should be just
* noncritical resource releasing. See notes in CommitTransaction.
* In normal commit-processing, this is all non-critical post-transaction
* cleanup. When the transaction is prepared, however, it's important that
* the locks and other per-backend resources are transfered to the
* prepared transaction's PGPROC entry. Note that if an error is raised
* here, it's too late to abort the transaction. XXX: This probably should
* be in a critical section, to force a PANIC if any of this fails, but
* that cure could be worse than the disease.
*/
CallXactCallbacks(XACT_EVENT_PREPARE);
@ -2268,6 +2272,14 @@ PrepareTransaction(void)
RESOURCE_RELEASE_AFTER_LOCKS,
true, true);
/*
* Allow another backend to finish the transaction. After
* PostPrepare_Twophase(), the transaction is completely detached from
* our backend. The rest is just non-critical cleanup of backend-local
* state.
*/
PostPrepare_Twophase();
/* Check we've released all catcache entries */
AtEOXact_CatCache(true);
@ -2394,6 +2406,7 @@ AbortTransaction(void)
AtEOXact_LargeObject(false);
AtAbort_Notify();
AtEOXact_RelationMap(false);
AtAbort_Twophase();
/*
* Advertise the fact that we aborted in pg_clog (assuming that we got as

3
src/include/access/twophase.h
View File

@ -30,6 +30,9 @@ extern int max_prepared_xacts;
extern Size TwoPhaseShmemSize(void);
extern void TwoPhaseShmemInit(void);
extern void AtAbort_Twophase(void);
extern void PostPrepare_Twophase(void);
extern PGPROC *TwoPhaseGetDummyProc(TransactionId xid);
extern BackendId TwoPhaseGetDummyBackendId(TransactionId xid);