On Thu, Oct 24, 2019 at 4:33 PM Dilip Kumar <[email protected]> wrote: > > On Thu, Oct 24, 2019 at 4:21 PM Amit Kapila <[email protected]> wrote: > > > > On Thu, Oct 24, 2019 at 11:51 AM Dilip Kumar <[email protected]> wrote: > > > > > > On Fri, Oct 18, 2019 at 12:18 PM Dilip Kumar <[email protected]> > > > wrote: > > > > > > > > On Fri, Oct 18, 2019 at 11:25 AM Amit Kapila <[email protected]> > > > > wrote: > > > > > > > > > > I am thinking if we can write the patch for both the approaches (a. > > > > > compute shared costs and try to delay based on that, b. try to divide > > > > > the I/O cost among workers as described in the email above[1]) and do > > > > > some tests to see the behavior of throttling, that might help us in > > > > > deciding what is the best strategy to solve this problem, if any. > > > > > What do you think? > > > > > > > > I agree with this idea. I can come up with a POC patch for approach > > > > (b). Meanwhile, if someone is interested to quickly hack with the > > > > approach (a) then we can do some testing and compare. Sawada-san, > > > > by any chance will you be interested to write POC with approach (a)? > > > > Otherwise, I will try to write it after finishing the first one > > > > (approach b). > > > > > > > I have come up with the POC for approach (a).
> > Can we compute the overall throttling (sleep time) in the operation
> > separately for heap and index, then divide the index's sleep_time with
> > a number of workers and add it to heap's sleep time? Then, it will be
> > a bit easier to compare the data between parallel and non-parallel
> > case.
I have come up with a patch to compute the total delay during the
vacuum. So the idea of computing the total cost delay is
Total cost delay = Total dealy of heap scan + Total dealy of
index/worker; Patch is attached for the same.
I have prepared this patch on the latest patch of the parallel
vacuum[1]. I have also rebased the patch for the approach [b] for
dividing the vacuum cost limit and done some testing for computing the
I/O throttling. Attached patches 0001-POC-compute-total-cost-delay
and 0002-POC-divide-vacuum-cost-limit can be applied on top of
v31-0005-Add-paralell-P-option-to-vacuumdb-command.patch. I haven't
rebased on top of v31-0006, because v31-0006 is implementing the I/O
throttling with one approach and 0002-POC-divide-vacuum-cost-limit is
doing the same with another approach. But,
0001-POC-compute-total-cost-delay can be applied on top of v31-0006 as
well (just 1-2 lines conflict).
Testing: I have performed 2 tests, one with the same size indexes and
second with the different size indexes and measured total I/O delay
with the attached patch.
Setup:
VacuumCostDelay=10ms
VacuumCostLimit=2000
Test1 (Same size index):
create table test(a int, b varchar, c varchar);
create index idx1 on test(a);
create index idx2 on test(b);
create index idx3 on test(c);
insert into test select i, repeat('a',30)||i, repeat('a',20)||i from
generate_series(1,500000) as i;
delete from test where a < 200000;
Vacuum (Head) Parallel Vacuum
Vacuum Cost Divide Patch
Total Delay 1784 (ms) 1398(ms)
1938(ms)
Test2 (Variable size dead tuple in index)
create table test(a int, b varchar, c varchar);
create index idx1 on test(a);
create index idx2 on test(b) where a > 100000;
create index idx3 on test(c) where a > 150000;
insert into test select i, repeat('a',30)||i, repeat('a',20)||i from
generate_series(1,500000) as i;
delete from test where a < 200000;
Vacuum (Head) Parallel Vacuum
Vacuum Cost Divide Patch
Total Delay 1438 (ms) 1029(ms)
1529(ms)
Conclusion:
1. The tests prove that the total I/O delay is significantly less with
the parallel vacuum.
2. With the vacuum cost divide the problem is solved but the delay bit
more compared to the non-parallel version. The reason could be the
problem discussed at[2], but it needs further investigation.
Next, I will test with the v31-0006 (shared vacuum cost) patch. I
will also try to test different types of indexes.
[1]
https://www.postgresql.org/message-id/CAD21AoBMo9dr_QmhT%3DdKh7fmiq7tpx%2ByLHR8nw9i5NZ-SgtaVg%40mail.gmail.com
[2]
https://www.postgresql.org/message-id/CAA4eK1%2BPeiFLdTuwrE6CvbNdx80E-O%3DZxCuWB2maREKFD-RaCA%40mail.gmail.com
--
Regards,
Dilip Kumar
EnterpriseDB: http://www.enterprisedb.com
0001-POC-compute-total-cost-delay.patch
Description: Binary data
0002-POC-divide-vacuum-cost-limit.patch
Description: Binary data
