I need to do a Postgres update on a collection of records & I'm trying to prevent a deadlock which appeared in the stress tests.

The typical resolution to this is to update records in a certain order, by ID for example - but it seems that Postgres doesn't allow ORDER BY for UPDATE.

Assuming I need to do an update, for example:


results in deadlocks when you run 200 queries concurrently. What to do?

I'm looking for a general solution, not case-specific workarounds like in UPDATE with ORDER BY

It feels that there must be a better solution than writing a cursor function. Also, if there's no better way, how would that cursor function optimally look like? Update record-by-record

  • Have you tried UPDATE... FROM... syntax? Commented Jun 20, 2017 at 21:06
  • Yes, i tried UPDATE....FROM....SELECT...FOR UPDATE but no change in the stack trace. It actually makes the issue more common.
    – bbozo
    Commented Jun 21, 2017 at 6:33

2 Answers 2


As far as I know, there's no way to accomplish this directly through the UPDATE statement; the only way to guarantee lock order is to explicitly acquire locks with a SELECT ... ORDER BY ID FOR UPDATE, e.g.:

UPDATE Balances
SET Balance = 0
  WHERE ID IN (SELECT ID FROM some_function())

This has the downside of repeating the ID index lookup on the Balances table. In your simple example, you can avoid this overhead by fetching the physical row address (represented by the ctid system column) during the locking query, and using that to drive the UPDATE:

UPDATE Balances
SET Balance = 0
  SELECT ctid FROM Balances
  WHERE ID IN (SELECT ID FROM some_function())

(Be careful when using ctids, as the values are transient. We're safe here, as the locks will block any changes.)

Unfortunately, the planner will only utilise the ctid in a narrow set of cases (you can tell if it's working by looking for a "Tid Scan" node in the EXPLAIN output). To handle more complicated queries within a single UPDATE statement, e.g. if your new balance was being returned by some_function() alongside the ID, you'll need to fall back to the ID-based lookup:

UPDATE Balances
SET Balance = Locks.NewBalance
  SELECT Balances.ID, some_function.NewBalance
  FROM Balances
  JOIN some_function() ON some_function.ID = Balances.ID
  ORDER BY Balances.ID
) Locks
WHERE Balances.ID = Locks.ID

If the performance overhead is an issue, you'd need to resort to using a cursor, which would look something like this:

DO $$
    SELECT Balances.ID, some_function.NewBalance
    FROM Balances
    JOIN some_function() ON some_function.ID = Balances.ID
    ORDER BY Balances.ID
  FOR row IN c LOOP
    UPDATE Balances
    SET Balance = row.NewBalance
  • 3
    What a fantastic answer - should be framed.
    – KateYoak
    Commented Feb 3, 2020 at 21:47
  • Thank you so much. I ended took the update...from..locks... solution as I my function was a counter increment which updated another table. Worked great once I added the locks and the function in the from. Thanks so much. Commented May 27, 2020 at 22:22
  • @NickBarnes Does CTID solution guarantee Update will happen in same sequence as the array is created in? I understand only locks were acquired in the same sequence, unless ANY guarantee its a POP data structure for update where clause... or am i missing something
    – Lau
    Commented Nov 17, 2020 at 14:30
  • 1
    @Laukik: No, I don't think there are ever any guarantees about the update order - if there were, we could just use that to control the lock order, and we wouldn't need the SELECT FOR UPDATE. If you really need this guarantee, I think you'll need to use the cursor. Commented Nov 17, 2020 at 15:55
  • 1
    beautiful! it is sometimes needed to return whatever you have just updated, and that can be achieved using ... returning ID
    – Eugene
    Commented Apr 11, 2022 at 11:01

In general, concurrency is difficult. Especially with 200 statements (i'm assuming you don't only query = SELECT) or even transactions (actually every single statement issued is wrapped into a transaction if it's not in a transaction already).

The general solution concepts are (a combination of) these:

  1. To be aware that deadlocks can happen, catch them in the application, check the Error Codes for class 40 or 40P01 and retry the transaction.

  2. Reserve locks. Use SELECT ... FOR UPDATE. Evade explicit locks as long as possible. Locks will force other transactions to wait for lock release, which harms concurrency, but can prevent transactions running into deadlocks. Check the example for deadlocks in chapter 13. Especially the one in which transaction A waits for B and B waits for A (the bank account thingy).

  3. Choose a different Isolation Level, for example a weaker one like READ COMMITED, if possible. Be aware of LOST UPDATEs in READ COMMITED mode. Prevent them with REPEATABLE READ.

Write your statements with locks in the same order in EVERY transaction, for example by table name alphabetically.

LOCK / USE A  -- Transaction 1 
LOCK / USE B  -- Transaction 1
LOCK / USE C  -- Transaction 1
-- D not used -- Transaction 1

-- A not used -- Transaction 2
LOCK / USE B  -- Transaction 2
-- C not used -- Transaction 2
LOCK / USE D  -- Transaction 2

with the general locking order A B C D. This way, the transactions can interleave in any relative order and still have a good chance not to deadlock (depending on your statements you may have other serialization issues though). The statements of the transactions will run in the order specified by them, but it can be that transaction 1 runs their first 2, then xact 2 runs the first one, then 1 finishes and finally xact 2 finishes.

Also, you should realise that a statement involving multiple rows is not executed atomically in a concurrent situation. In other words, if you have two statements A and B involving multiple rows, then they can be executed in this order:

a1 b1 a2 a3 a4 b2 b3     

but NOT as a block of a's followed by b's. The same applies to a statement with a sub-query. Have you looked at the query plans using EXPLAIN ?

In your case, you can try

 SELECT ID FROM some_function() FOR UPDATE  -- LOCK using FOR UPDATE 
 -- other transactions will WAIT / BLOCK temporarily on conc. write access

If possible by what you want to do, you can also use SELECT ... FOR UPDATE SKIP LOCK, which will skip already locked data to get back concurrency, which is lost by WAITing for another transaction to release a lock (FOR UPDATE). But this will not apply an UPDATE to locked rows, which your application logic might require. So run that later on (see point 1).

Also read LOST UPDATE about the LOST UPDATE and SKIP LOCKED about SKIP LOCKED. A queue might be an idea in your case, which is explained perfectly in the SKIP LOCKED reference, although relational DBMS are not meant to be queues.


  • Thank you, I'll play with this. Is there some locking being done under the hood for selects? I guess no but I'm getting crazy
    – bbozo
    Commented Jun 21, 2017 at 6:36
  • 3
    I don't think your FOR UPDATE is doing anything, since the SELECT doesn't reference any tables... Commented Jun 21, 2017 at 7:56

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.