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Lets say I open a transaction and run update queries.

UPDATE x SET y = z WHERE w = v

The query returns successfully and the transaction stays open deliberately for a period of time before I decide to commit.

While I'm sitting on the transaction is it ever possible the MSSQL deadlock machinary would be able to preempt my open transaction that is not actually executing anything to either clear a deadlock or free resources as system memory/resource limits are reached?

I know about SET DEADLOCK_PRIORITY and have read the MSDN articles on the topic of deadlocks. Logically since I'm not actively seeking to stake claim on any additional resources I can't imagine a scenario that would trigger a sane deadlock avoidance algorithm.

Does anyone know for sure if its possible that simply holding any locks can make me a valid target? Similarly could any low resource condition trigger the killing of my SPID?

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I don't know for sure (that is why this is a comment), but I would think that if you are just hanging around with locks open you would be more likely to be selected as a deadlock victim (not less likely). Deadlocks happen when two processes need the same resource and neither is going to give up. If you are holding locks then you are making a deadlock with your process more likely, not less. As to which spid is the victim, I have never heard that the selection process it is deterministic at at the user level. Either way, your odds get worse the longer you hold the locks. – Vaccano Jan 13 '10 at 7:32
up vote 3 down vote accepted


For a deadlock to occur all the participants in the deadlock chain must be waiting for a resource (a lock). If your connection is idle it means it doesn't execute a request, which implies it cannot be waiting.

As for other conditions that can kill your session I can think of at least three:

  • administrative operations that use WITH ROLLBACK_IMMEDIATE
  • a mirroring failover
  • intentional KILL <yourspid>, perhaps as a joke by your friendly DBA
share|improve this answer
Gotta love those friendly DBAs... – Rory Jan 13 '10 at 7:55
Are you sure he has to be waiting? What if he's blocking another thread, and sitting on a WAITFOR? – John Saunders Jan 13 '10 at 11:48
@John: Yes, it must be waiting for a resource. If T1 waits for resource A owned by T2 and T2 sits in WAITFOR then there will be progress when T2 resumes. For the deadlock chain to close T2 has to be waiting a resource, otherwise the deadlock detection will not see a complete circle and will not intervene. Also the full circle must be inside SQL, if T2 waits on a application semaphore owned by T1 then the circle completes outside of SQL and will again not be detected. – Remus Rusanu Jan 13 '10 at 16:30
Thank you for your input. The sad thing is the reason I bring this up seems likely to be the result of a friendly DBA :( – Einstein Jan 14 '10 at 8:13
@Remus: do you have a reference for this? I want to make sure it's not enough for the deadlock algorithm to see no progress if T2 is in the WAITFOR too long. – John Saunders Jan 14 '10 at 15:29

To answer your question: you can be a deadlock victim if you're not executing a query in a transaction.

It's counter-intuitive, but you can be a deadlock victim by running a SELECT statement.

It can happen if you're running a query that uses an index:

  • you scan indexes looking for matching rows

  • other process starts updating data pages

  • you now want to fetch data from data pages from matching rows

    other process holding locks on data pages

    you wait for data page locks to release

  • other process finished updating data pages, wants to update indexes

    you are holding read locks on indexes

    other process waits for index locks to release


So, strictly speaking, you can be a deadlock victim, when you're not executing a query in a transaction. The other guy wasn't executing his UPDATE statement in a transaction either.

Nobody's explicitly using a transaction, yet there's a deadlock.

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A select is a query in a transaction anyway... since autocommit is 1. – Pacerier Dec 19 '14 at 3:37

Possible problems:

  1. SQL Server only has a finite number of locks. It is possible to run out of locks.

  2. Other resources are finite (e.g. memory, tempdb). Holding on to these resources could cause those resources to run out.

  3. Transaction logs - the logical transaction logs cannot be freed for re-use if a transaction is open. The result could be a log that fills up. This problem could stop your process because it would halt the entire instance.

To consider:

  1. CASCADE: DELETE may only have one table in the command, but the a CASCADE relationship may touch other tables.

  2. Triggers: Triggers on the modified table may affect other tables.

  3. DELETE and UPDATE commands may use the FROM clause which touch other tables. I've never seen this, but I would not rule it out.

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Transactions may time out, is that what is happening.

As you have at least 1 (or more) update locks taken out and make be some read and table scan locks, you may be killed to help free up deadlocks created by other transactions. The deadlock recovery code in SQL Server is unlikely to be totally bug free and it is not normal to keep a transaction open for a long time on SQL Server. However I would not expect that to happen often.

Some system when they detach deadlock type problem, just start killing “long lived” transactions that have not done match work so as to free up locks. Just because you are not part of the deadlock loop, does not stop the system picking on you.

To understand what is going on in your case, you will have to use the Sql Server Profiler to collect all the locking and deadlock related events, as well as event about aborted connection and transactions etc. Good lack this will time some time and a good level of understanding of the profiler events you are looking at...

The detail of this sort of things are different between database vendors and versions of their database. However as it is considered bad design by most database vendors to have a transaction open for a long time, doing so tends to lead to problems and hit code paths that have not had the most testing effort.

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This is the type of thing I'm looking for.. Can I ask what lead you to say processes not directly involved in a deadlock can be killed to resolve one? Is there offhand a reference or specific experience? – Einstein Jan 14 '10 at 9:00

Just because you're not in a transaction doesn't mean you're not holding locks.

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I can see why you posted this, the title is poorly worded. However, he means that while in a transaction, he is not actually running a query. (He is in a transaction, but is not doing SQL stuff.) At least that is how I read it. – Vaccano Jan 13 '10 at 7:39
As I said, what matters is not that he's in a transaction or not - what matters is the locks he holds, and the locks he may be waiting for. Depending on the details of the deadlock detection algorithm, it seems to me he could be considered part of the deadlock if he's holding a lock and "not doing anything" for too long. – John Saunders Jan 13 '10 at 11:46
In terms of detection algorithm itself I tried to find anything that states lock hold time is part of the detection algorithms decision process. Is there any first hand experience or reference for this I can follow? Most of my information comes from: It states the deadlock detection process runs at 5 seconds intervals but thats about all I was able to find. – Einstein Jan 14 '10 at 9:38
It's not a question of "lock hold time". If one thread is holding a lock for a period of time, then another thread may be blocked waiting for that lock. That second thread may be holding a lock that a third thread is waiting for. Again, it depends on the details of the deadlock detcection code, which I do not know. Some such algorithms will consider "C waits on B waits on A" to be a chain worth breaking. Others will require an actual cycle: C->B->C. – John Saunders Jan 14 '10 at 15:27

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