Small Datum

Wednesday, January 14, 2026

Debugging regressions with Postgres in IO-bound sysbench

I explained in this post that there is a possible performance regression for Postgres with IO-bound sysbench. It arrived in Postgres 16 and remains in Postgres 18. I normally run sysbench with a cached database, but I had a spare server so I repeated tests with an IO-bound workload.

The bad news for me is that I need to spend more time explaining the problem. The good news for me is that I learn more about Postgres by doing this. And to be clear, I have yet to explain the regression but this post documents my debugging efforts.

sysbench

This post explains how I use sysbench. Note that modern sysbench is a framework for running benchmarks and it comes with many built-in tests. By framework I mean that it includes much plumbing for several DBMS and you can write tests in Lua with support for the Lua JIT so the client side of the tests use less CPU.

The sysbench framework has been widely used in the MySQL community for a long time. Originally it hard-coded one (or perhaps a few tests) and in too many cases by sysbench people mean the classic (original) sysbench transaction that is a mix of point queries, range queries and writes. The classic transaction is now implemented by oltp_read_write.lua with help from oltp_common.lua.

The oltp_read_write.lua test is usually not good at detecting regressions but in this case (the problem motivating me to write this blog post) it has detected the regression.

How to find regressions

I have opinions about how to run DBMS benchmarks. For example, be careful about running read-only benchmarks for an LSM because the state (shape) of the LSM tree can have a large impact on CPU overhead and the LSM state (shape) might be in the same (bad or good) state for the duration of the test. With read-write tests the LSM state should cycle between better and worse states.

But traditional b-tree storage engines also have states. One aspect of that is MVCC debt -- write-heavy tests increase the debt and the engine doesn't always do a great job of limiting that debt. So I run sysbench tests in a certain order to both create and manage MVCC debt while trying to minimize noise.

The order of the tests is listed here and the general sequence is:

Load and index the tables
Run a few read-only tests to let MVCC debt get reduced if it exists
Optionally run more read-only tests (I usually skip these)
Run write-heavy tests
Do things to reduce MVCC debt (see here for Postgres and MySQL)
Run read-only tests (after the tables+indexes have been subject to random writes)
Run delete-only and then insert-only tests

Results

The possible regressions are:

update-zipf in Postgres 16, 17 and 18
write-only in Postgres 16, 17 and 18
read-write in Postgres 16, 17 and 18
insert in Postgres 18 - this reproduces in 18.0 and 18.1

Legend:

* relative QPS for Postgres 16.11, 17.7 and 18.1

* relative QPS is (QPS for my version / QPS for Postgres 15.15)

16.11 17.7 18.1

1.01 1.00 1.01 update-inlist

1.06 1.03 1.04 update-index

1.04 1.04 1.04 update-nonindex

1.00 1.08 1.07 update-one

0.85 0.72 0.71 update-zipf

0.88 0.86 0.84 write-only_range=10000

0.71 0.82 0.81 read-write_range=100

0.74 0.78 0.82 read-write_range=10

1.06 1.03 1.00 delete

1.02 1.00 0.80 insert

Note that when the insert test has a relative QPS of 0.80 for Postgres 18.1, then 18.1 gets 80% of the throughput vs Postgres 15.5. So this is a problem to figure out.

Explaining the insert test for Postgres 18.1

I wrote useful but messy Bash scripts to make it easier to run and explain sysbench results. One of the things I do is collect results from vmstat and iostat per test and then summarize average and normalized values from them where normalized values are: (avg from iostat or vmstat / QPS).

And then I compute relative values for them which is the following and the base case here is Postgres 15.15: (value from my version / value from the base case)

From the results below I see that from Postgres 17.7 to 18.1

throughput decreases by ~20% in 18.1
cpu/o increased by ~17% in 18.1
cs/o increased by ~2.6% in 18.1
r/o increased by ~14% in 18.1
rKB/o increased by ~22% in 18.1
wKB/o increased by ~27% in 18.1

So Postgres 18.1 does a lot more IO during the insert test. Possible reasons are that either insert processing changed to be less efficient or there is more MVCC debt at the start of the insert test from the write-heavy tests that precede it and thus there is more IO from write-back and vacuum during the insert test which reduces throughput. At this point I don't know. A next step for me is to repeat the benchmark with the delete test removed as that immediately precedes the insert test (see here).

Legend:
* cpu/o - CPU per operation. This includes us and sy from vmstat but

it isn't CPU microseconds.

* cs/o - context switches per operation

* r/o - reads from storage per operation

* rKB/o - KB read from storage per operation

* wKB/o - KB written to storage per operation

* o/s - operations/s, QPS, throughput

* dbms - Postgres version

--- absolute

cpu/o cs/o r/o rKB/o wKB/o o/s dbms

0.000780 5.017 0.407 8.937 24.2 34164 15.15

0.000755 5.090 0.409 9.002 24.648 34833 16.11

0.000800 5.114 0.418 9.146 24.626 34195 17.7

0.000939 5.251 0.477 11.186 31.197 27304 18.1

--- relative to first result

0.97 1.01 1.00 1.01 1.02 1.02 16.11

1.03 1.02 1.03 1.02 1.02 1.00 17.7

1.20 1.05 1.17 1.25 1.29 0.80 18.1

I also have results from pg_stat_all_tables collected at the end of the delete and insert tests for Postgres 17.7 and 18.1. Then I computed the difference as (results after insert test - results before insert test). From the results below I don't see a problem. Note that the difference for n_dead_tup is zero. While my analysis was limited to one of the 8 tables used for the benchmark, the values for the other 7 tables are similar.

The columns with a non-zero difference for Postgres 17.7 are:

3996146 n_tup_ins

3996146 n_live_tup

3996146 n_mod_since_analyze

3996146 n_ins_since_vacuum

The columns with a non-zero difference for Postgres 18.1 are:

3191278 n_tup_ins

3191278 n_live_tup

3191278 n_mod_since_analyze

3191278 n_ins_since_vacuum

Explaining the other tests for Postgres 16, 17 and 18

Above I listed the order in which the write-heavy tests are run. The regressions occur on the update-zipf, write-only and read-write tests. All of these follow the update-one test.

There is no regression for write-only and read-write when I change the test order so these run prior to update-one and update-zipf
There is a regression if either or both of update-one and update-zip are run prior to write-only and read-write

I assume that either the amount of MVCC debt created by update-one and update-zipf is larger starting with Postgres 16 or that starting in Postgres 16 something changed so that Postgres is less effective at dealing with that MVCC debt.

Note that the update-one and update-zipf tests are a bit awkward. But this workload hasn't been a problem for InnoDB so I assume this is specific to Postgres (and vacuum). For the update-one test all updates are limited to one row per table (the first row in the table). And for the update-zipf test a zipfian distribution is used to select the rows to update. So in both cases a small number of rows receive most of the updates.

Results from pg_stat_all_tables collected immediately prior to update-one and then after update-zipf are here for Postgres 15.15 and 16.11. Then I computed the difference as (results after update-zip - results before update-one).

The columns with a non-zero difference for Postgres 15.15 are:

23747485 idx_scan

23747485 idx_tup_fetch

23747485 n_tup_upd

22225868 n_tup_hot_upd

-69576 n_live_tup

3273433 n_dead_tup

-1428177 n_mod_since_analyze

The columns with a non-zero difference for Postgres 16.11 are:

23102012 idx_scan

23102012 idx_tup_fetch

23102012 n_tup_upd

21698107 n_tup_hot_upd

1403905 n_tup_newpage_upd

-3568 n_live_tup

2983730 n_dead_tup

-2064095 n_mod_since_analyze

I also have the vmstat and iostat data for each of the tests. In all cases, after update-one, the amount of CPU and IO per operation increases after Postgres 15.15.

For update-one results don't change much across versions

--- absolute

cpu/o cs/o r/o rKB/o wKB/o o/s dbms

0.000281 12.492 0.001 0.011 0.741 162046 15.15

0.000278 12.554 0.001 0.012 0.746 162415 16.11

0.000253 11.028 0.002 0.029 0.764 174715 17.7

0.000254 10.960 0.001 0.011 0.707 172790 18.1

--- relative to first result

0.99 1.00 1.00 1.09 1.01 1.00 16.11

0.90 0.88 2.00 2.64 1.03 1.08 17.7

0.90 0.88 1.00 1.00 0.95 1.07 18.1

For update-zipf the amount of CPU and IO per operation increases after Postgres 15.15

--- absolute

cpu/o cs/o r/o rKB/o wKB/o o/s dbms

0.000721 6.517 0.716 6.583 18.811 41531 15.15

0.000813 7.354 0.746 7.838 22.746 35497 16.11

0.000971 5.679 0.796 10.492 27.858 29700 17.7

0.000966 5.718 0.838 10.354 28.965 29289 18.1

--- relative to first result

1.13 1.13 1.04 1.19 1.21 0.85 16.11

1.35 0.87 1.11 1.59 1.48 0.72 17.7

1.34 0.88 1.17 1.57 1.54 0.71 18.1

For write-only_range=10000 the amount of CPU and IO per operation increases after Postgres 15.15

--- absolute

cpu/o cs/o r/o rKB/o wKB/o o/s dbms

0.000784 5.881 0.799 7.611 26.835 30174 15.15

0.000920 6.315 0.85 10.033 32 26444 16.11

0.001003 5.883 0.871 11.147 33.142 25889 17.7

0.000999 5.905 0.891 10.988 34.443 25232 18.1

--- relative to first result

1.17 1.07 1.06 1.32 1.19 0.88 16.11

1.28 1.00 1.09 1.46 1.24 0.86 17.7

1.27 1.00 1.12 1.44 1.28 0.84 18.1

For read-write_range=100 the amount of CPU and IO per operation increases after Postgres 15.15

--- absolute

cpu/o cs/o r/o rKB/o wKB/o o/s dbms

0.001358 7.756 1.758 25.654 22.615 31574 15.15

0.001649 8.111 1.86 30.99 35.413 22264 16.11

0.001629 7.609 1.856 29.901 28.681 25906 17.7

0.001646 7.484 1.978 29.456 29.138 25573 18.1

--- relative to first result

1.21 1.05 1.06 1.21 1.57 0.71 16.11

1.20 0.98 1.06 1.17 1.27 0.82 17.7

1.21 0.96 1.13 1.15 1.29 0.81 18.1

For read-write_range=10 the amount of CPU and IO per operation increases after Postgres 15.15

--- absolute

cpu/o cs/o r/o rKB/o wKB/o o/s dbms

0.000871 6.441 1.096 10.238 21.426 37141 15.15

0.001064 6.926 1.162 13.761 29.738 27540 16.11

0.001074 6.461 1.181 14.759 29.338 28839 17.7

0.001045 6.497 1.222 14.726 28.632 30431 18.1

--- relative to first result

1.22 1.08 1.06 1.34 1.39 0.74 16.11

1.23 1.00 1.08 1.44 1.37 0.78 17.7

1.20 1.01 1.11 1.44 1.34 0.82 18.1

Thursday, January 8, 2026

Postgres vs tproc-c on a small server

This is my first post with results from tproc-c using HammerDB. This post has results for Postgres.

tl;dr - across 8 workloads (low and medium concurrency, cached database to IO-bound)

there might be a regression for Postgres 14.20 and 15.15 in one workload
there are improvements, some big, for Postgres 17 and 18 in most workloads

Builds, configuration and hardware

I compiled Postgres from source using -O2 -fno-omit-frame-pointer for versions 12.22, 13.23, 14.20, 15.15, 16.11, 17.7 and 18.1.

The server is an ASUS ExpertCenter PN53 with an AMD Ryzen 7 7735HS CPU, 8 cores, SMT disabled, and 32G of RAM. Storage is one NVMe device for the database using ext-4 with discard enabled. The OS is Ubuntu 24.04. More details on it are here.

For versions prior to 18, the config file is named conf.diff.cx10a_c8r32 and they are as similar as possible and here for versions 12, 13, 14, 15, 16 and 17.

For Postgres 18 the config file is named conf.diff.cx10b_c8r32 and adds io_mod='sync' which matches behavior in earlier Postgres versions.

Benchmark

The benchmark is tproc-c from HammerDB. The tproc-c benchmark is derived from TPC-C.

The benchmark was run for several workloads:

vu=1, w=100 - 1 virtual user, 100 warehouses
vu=6, w=100 - 6 virtual users, 100 warehouses
vu=1, w=1000 - 1 virtual user, 1000 warehouses
vu=6, w=1000 - 6 virtual users, 1000 warehouses
vu=1, w=2000 - 1 virtual user, 2000 warehouses
vu=6, w=2000 - 6 virtual users, 2000 warehouses
vu=1, w=4000 - 1 virtual user, 4000 warehouses
vu=6, w=4000 - 6 virtual users, 4000 warehouses

The benchmark is run by this script which depends on scripts here.

stored procedures are enabled
partitioning is used for when the warehouse count is >= 1000
a 5 minute rampup is used
then performance is measured for 120 minutes

Results

All artifacts from the tests are here. A spreadsheet with the charts and numbers is here.

My analysis at this point is simple -- I only consider average throughput. Eventually I will examine throughput over time and efficiency (CPU and IO).

On the charts that follow y-axis starts at 0.9 to improve readability. The y-axis shows relative throughput. There might be a regression when the relative throughput is less than 1.0. There might be an improvement when it is > 1.0. The relative throughput is:

(NOPM for a given version / NOPM for Postgres 12.22)

Results: vu=1, w=100

Summary:

no regressions, no improvements

Results: vu=6, w=100

Summary:

no regressions, no improvements

Results: vu=1, w=1000

Summary:

no regressions, improvements in Postgres 17 and 18

Results: vu=6, w=1000

Summary:

no regressions, improvements in Postgres 16, 17 and 18

Results: vu=1, w=2000

Summary:

possible regressions in Postgres 14 and 15, improvements in 13, 16, 17\ and 18

Results: vu=6, w=2000

Summary:

no regressions, improvements in Postgres 13 through 18

Results: vu=1, w=4000

Summary:

no regressions, improvements in Postgres 13 through 18

Results: vu=6, w=4000

Summary:

no regressions, improvements in Postgres 16 through 18

Wednesday, January 7, 2026

SSDs, power loss protection and fsync latency

This has results to measure the impact of calling fsync (or fdatasync) per-write for files opened with O_DIRECT. My goal is to document the impact of the innodb_flush_method option.

The primary point of this post is to document the claim:

For an SSD without power loss protection, writes are fast but fsync is slow.

The secondary point of this post is to provide yet another example where context matters when reporting performance problems. This post is motivated by results that look bad when run on a server with slow fsync but look OK otherwise.

tl;dr

for my mini PCs I will switch from the Samsung 990 Pro to the Crucial T500 to get lower fsync latency. Both are nice devices but the T500 is better for my use case.
with a consumer SSD writes are fast but fsync is often slow
use an enterprise SSD if possible, if not run tests to understand fsync and fdatasync latency

Updates:

I am not surprised that Tanel Poder has a great blog post on this topic

InnoDB, O_DIRECT and O_DIRECT_NO_FSYNC

When innodb_flush_method is set to O_DIRECT there are calls to fsync after each batch of writes. While I don't know the source like I used to, I did browse it for this blog post and then I looked at SHOW GLOBAL STATUS counters. I think that InnoDB does the following with it set to O_DIRECT:

Do one large write to the doublewrite buffer, call fsync on that file
Do the batch of in-place (16kb) page writes
Call fsync once per database file that was written by step 2

When set to O_DIRECT_NO_FSYNC then the frequency of calls to fsync are greatly reduced and are only done in cases where important filesystem metadata needs to be updated, such as after extending a file. The reference manual is misleading WRT the following sentence. I don't think that InnoDB ever does an fsync after each write. It can do an fsync after each batch of writes:

O_DIRECT_NO_FSYNC: InnoDB uses O_DIRECT during flushing I/O, but skips the fsync() system call after each write operation.

Many years ago it was risky to use O_DIRECT_NO_FSYNC on some filesystems because the feature as implemented (either upstream or in forks) didn't do fsync for cases where it was needed (see comment about metadata above). I experienced problems from this and I only have myself to blame. But the feature has been enhanced to do the right thing. And if the #whynotpostgres crowd wants to snark about MySQL not caring about data, lets not forget that InnoDB had per-page checksums long before Postgres -- those checksums made web-scale life much easier when using less than stellar hardware.

The following table uses results while running the Insert Benchmark for InnoDB to compute the ratio of fsyncs per write using the SHOW GLOBAL STATUS counters:

Innodb_data_fsyncs / Innodb_data_writes

And from this table a few things are clear. First, there isn't an fsync per write with O_DIRECT but there might be an fsync per batch of writes as explained above. Second, the rate of fsyncs is greatly reduced by using O_DIRECT_NO_FSYNC.

5.7.44 8.0.44

.01046 .00729 O_DIRECT
.00172 .00053 O_DIRECT_NO_FSYNC

Power loss protection

I am far from an expert on this topic, but most SSDs have a write-buffer that makes small writes fast. And one way to achieve speed is to buffer those writes in RAM on the SSD while waiting for enough data to be written to an extent. But that speed means there is a risk of data loss if a server loses power. Some SSDs, especially those marketed as enterprise SSDs, have a feature called power loss protection that make data loss unlikely. Other SSDs, lets call them consumer SSDs, don't have that feature while some of the consumer SSDs claim to make a best effort to flush writes from the write buffer on power loss.

One solution to avoiding risk is to only buy enterprise SSDs. But they are more expensive, less common, and many are larger (22120 rather than 2280) because more room is needed for the capacitor or other HW that provides the power loss protection. Note that power loss protection is often abbreviated as PLP.

For devices without power loss protection it is often true that writes are fast but fsync is slow. When fsync is slow then calling fsync more frequently in InnoDB will hurt performance.

Results from fio

I used this fio script to measure performance for writes for files opened with O_DIRECT. The test was run twice configuration for 5 minutes per run followed by a 5 minute sleep. This was repeated for 1, 2, 4, 8, 16 and 32 fio jobs but I only share results here for 1 job. The configurations tested were:

O_DIRECT without fsync, 16kb writes
O_DIRECT with an fsync per write, 16kb writes
O_DIRECT with an fdatasync per write, 16kb writes
O_DIRECT without fsync, 2M writes
O_DIRECT with an fsync per write, 2M writes
O_DIRECT with an fdatasync per write, 2M writes

Results from all tests are here. I did the test on several servers:

dell32

a large server I have at home. The SSD is a Crucial T500 2TB using ext-4 with discard enabled and Ubuntu 24.04. This is a consumer SSD. While the web claims it has PLP via capacitors the fsync latency for it was almost 1 millisecond.

a c3d-standard-30-lssd from the Google cloud with 2 local NVMe devices using SW RAID 0 and 1TB of Hyperdisk Balanced storage configured for 50,000 IOPs and 800MB/s of throughput. The OS is Ubuntu 24.04 and I repeated tests for both ext-4 and xfs, both with discard enabled. I was not able to determine the brand of the local NVMe devices.

hetz

an ax162-s from Hetzner with 2 local NVME devices using SW RAID 1. Via udiskctl status I learned the devices are Intel D7-P5520 (now Solidigm). These are datacenter SSDs and the web claims they have power loss protection. The OS is Ubuntu 24.04 and the drives use ext-4 without discard enabled.

ser7

a mini-PC I have at home. The SSD is a Samsung 990 Pro using ext-4 with discard enabled and Ubuntu 24.04. This is a consumer SSD, the web claims it does not have PLP and fsync latency is several milliseconds.

socket2

a 2-socket server I have at home. The SSD is a Samsung PM-9a3. This is an enterprise SSD with power loss protection. The OS is Ubuntu 24.04 and the drives use ext-4 with discard enabled.

Results: overview

All of the results are here.

This table lists fsync and fdatasync latency per server:

for servers with consumer SSDs (dell, ser7) the latency is much larger on the ser7 that uses a Samsung 990 Pro than on the dell that uses a Crucial T500. This is to be expected given that the T500 has PLP while the 990 Pro does not.
sync latency is much lower on servers with enterprise SSDs
sync latency after 2M writes is sometimes much larger than after 16kb writes
for the Google server with Hyperdisk Balanced storage the fdatasync latency was good but fsync latency was high. While with the local NVMe devices the latencies were larger than for enterprise SSDs but much smaller than for consumer SSDs.

--- Sync latency in microseconds for sync after 16kb writes

dell hetz ser7 socket2

891.1 12.4 2974.2 1.6 fsync

447.4 9.8 2783.2 0.7 fdatasync

gcp

local devices hyperdisk

ext-4 xfs ext-4 xfs

56.2 39.5 738.1 635.0 fsync

28.1 29.0 46.8 46.0 fdatasync

--- Sync latency in microseconds for sync after 2M writes

dell hetz ser7 socket2

980.1 58.2 5396.8 139.1 fsync

449.7 10.8 3508.2 2.2 fdatasync

gcp

local devices hyperdisk

ext-4 xfs ext-4 xfs

1020.4 916.8 821.2 778.9 fsync

832.4 809.7 63.6 51.2 fdatasync

Results: dell

Summary:

Write throughput drops dramatically when there is an fsync or fdatasync per write because sync latency is large.
This servers uses a consumer SSD so high sync latency is expected

Legend:

w/s - writes/s
MB/s - MB written/s
sync - latency per sync (fsync or fdatasync)

16 KB writes

w/s MB/s sync test

43400 646.6 0.0 no-sync

43500 648.5 0.0 no-sync

1083 16.1 891.1 fsync

1085 16.2 889.2 fsync

2100 31.3 447.4 fdatasync

2095 31.2 448.6 fdatasync

2 MB writes

w/s MB/s sync test

2617 4992.5 0.0 no-sync

2360 4502.3 0.0 no-sync

727 1388.5 980.1 fsync

753 1436.2 942.5 fsync

1204 2297.4 449.7 fdatasync

1208 2306.0 446.9 fdatasync

Results: gcp

Summary

Local NVMe devices have lower sync latency and more throughput with and without a sync per write at low concurrency (1 fio job).
At higher concurrency (32 fio jobs), the Hyperdisk Balanced setup provides similar throughput to local NVMe and would do even better had I paid more to get more IOPs and throughput. Results don't have nice formatting but are here for xfs on the local and Hyperdisk Balanced devices.
fsync latency is ~2X larger than fdatasync on the local devices and closer to 15X larger on the Hyperdisk Balanced setup. That difference is interesting. I wonder what the results are for Hyperdisk Extreme.

Legend:

w/s - writes/s
MB/s - MB written/s
sync - latency per sync (fsync or fdatasync)

--- ext-4 and local devices

16 KB writes

w/s MB/s sync test

10100 150.7 0.0 no-sync

10300 153.5 0.0 no-sync

6555 97.3 56.2 fsync

6607 98.2 55.1 fsync

8189 122.1 28.1 fdatasync

8157 121.1 28.2 fdatasync

2 MB writes

w/s MB/s sync test

390 744.8 0.0 no-sync

388 741.0 1020.4 fsync

388 741.0 1012.7 fsync

390 744.8 832.4 fdatasync

390 744.8 869.6 fdatasync

--- xfs and local devices

16 KB writes

w/s MB/s sync test

9866 146.9 0.0 no-sync

9730 145.0 0.0 no-sync

7421 110.6 39.5 fsync

7537 112.5 38.3 fsync

8100 121.1 29.0 fdatasync

8117 121.1 28.8 fdatasync

2 MB writes

w/s MB/s sync test

390 744.8 0.0 no-sync

389 743.9 916.8 fsync

389 743.9 919.1 fsync

390 744.8 809.7 fdatasync

390 744.8 806.5 fdatasync

--- ext-4 and Hyperdisk Balanced

16 KB writes

w/s MB/s sync test

2093 31.2 0.0 no-sync

2068 30.8 0.0 no-sync

804 12.0 738.1 fsync

798 11.9 740.6 fsync

1963 29.3 46.8 fdatasync

1922 28.6 49.0 fdatasync

2 MB writes

w/s MB/s sync test

348 663.8 0.0 no-sync

367 701.0 0.0 no-sync

278 531.2 821.2 fsync

271 517.8 814.1 fsync

358 683.8 63.6 fdatasync

345 659.0 64.5 fdatasync

--- xfs and Hyperdisk Balanced

16 KB writes

w/s MB/s sync test

2033 30.3 0.0 no-sync

2004 29.9 0.0 no-sync

870 13.0 635.0 fsync

858 12.8 645.0 fsync

1787 26.6 46.0 fdatasync

1727 25.7 49.6 fdatasync

2 MB writes

w/s MB/s sync test

343 655.2 0.0 no-sync

267 511.2 778.9 fsync

268 511.2 774.7 fsync

347 661.8 51.2 fdatasync

336 642.8 54.4 fdatasync

Results: hetz

Summary

this has an enterprise SSD with excellent (low) sync latency

Legend:

w/s - writes/s
MB/s - MB written/s
sync - latency per sync (fsync or fdatasync)

16 KB writes

w/s MB/s sync test

37700 561.7 0.0 no-sync

37500 558.9 0.0 no-sync

25200 374.8 12.4 fsync

25100 374.8 12.4 fsync

27600 411.0 0.0 fdatasync

27200 404.4 9.8 fdatasync

2 MB writes

w/s MB/s sync test

1833 3497.1 0.0 no-sync

1922 3667.8 0.0 no-sync

1393 2656.9 58.2 fsync

1355 2585.4 59.6 fsync

1892 3610.6 10.8 fdatasync

1922 3665.9 10.8 fdatasync

Results: ser7

Summary:

this has a consumer SSD with high sync latency
results had much variance (see the 2MB results below) and results at higher concurrency. This is a great SSD, but not for my use case.

Legend:

w/s - writes/s
MB/s - MB written/s
sync - latency per sync (fsync or fdatasync)

16 KB writes

w/s MB/s sync test

34000 506.4 0.0 no-sync

40200 598.9 0.0 no-sync

325 5.0 2974.2 fsync

333 5.1 2867.3 fsync

331 5.1 2783.2 fdatasync

330 5.0 2796.1 fdatasync

2 MB writes

w/s MB/s sync test

362 691.4 0.0 no-sync

364 695.2 0.0 no-sync

67 128.7 10828.3 fsync

114 218.4 5396.8 fsync

141 268.9 3864.0 fdatasync

192 368.1 3508.2 fdatasync

Results: socket2

Summary:

this has an enterprise SSD with excellent (low) sync latency after small writes, but fsync latency after 2MB writes is much larger

Legend:

w/s - writes/s
MB/s - MB written/s
sync - latency per sync (fsync or fdatasync)

16 KB writes

w/s MB/s sync test

49500 737.2 0.0 no-sync

49300 734.3 0.0 no-sync

44500 662.8 1.6 fsync

45400 676.2 1.5 fsync

46700 696.2 0.7 fdatasync

45200 674.2 0.7 fdatasync

2 MB writes

w/s MB/s sync test

707 1350.4 0.0 no-sync

708 1350.4 0.0 no-sync

703 1342.8 139.1 fsync

703 1342.8 122.5 fsync

707 1350.4 2.2 fdatasync

707 1350.4 2.1 fdatasync

Friday, January 2, 2026

Common prefix skipping, adaptive sort

The patent expired for US7680791B2. I invented this while at Oracle and it landed in 10gR2 with claims of ~5X better performance vs the previous sort algorithm used by Oracle. I hope for an open-source implementation one day. The patent has a good description of the algorithm, it is much easier to read than your typical patent. Thankfully the IP lawyer made good use of the functional and design docs that I wrote.

The patent is for a new in-memory sort algorithm that needs a name. Features include:

common prefix skipping

skips comparing the prefix of of key bytes when possible

adaptive

switches between quicksort and most-significant digit radix sort

key substring caching

reduces CPU cache misses by caching the next few bytes of the key

produces results before sort is done

sorted output can be produced (to the rest of the query, or spilled to disk for an external sort) before the sort is finished.

Update:

the sort algorithm needs a name and common prefix skipping adaptive quicksort is much too long. So I suggest Orasort.

How it came to be

From 2000 to 2005 I worked on query processing for Oracle. I am not sure why I started on this effort and it wasn't suggested by my bosses or peers. But the Sort Benchmark contest was active and I had more time to read technical papers. Perhaps I was inspired by the Alphasort paper.

While the Sort Benchmark advanced the state of the art in sort algorithms, it also encouraged algorithms that were great for benchmarks (focus on short keys with uniform distribution). But keys sorted by a DBMS are often much larger than 8 bytes and adjacent rows often have long common prefixes in their keys.

So I thought about this while falling to sleep and after many nights realized that with a divide and conquer sort, as the algorithm descends into subpartitions of the data, that the common prefixes of the keys in each subpartition were likely to grow:

were the algorithm able to remember the length of the common prefix as it descends then it can skip the common prefix during comparisons to save on CPU overhead
were the algorithm able to learn when the length of the common prefix grows then it can switch from quicksort to most-significant digit (MSD) radix sort using the next byte beyond the common prefix and then switch back to quicksort after doing that
the algorithm can cache bytes from the key in an array, like Alphasort. But unlike Alphasort as it descends it can cache the next few bytes it will need to compare rather than only caching the first few bytes of the key. This provides much better memory system behavior (fewer cache misses).

Early implementation

This might have been in 2003 before we were able to access work computers from home. I needed to get results that would convince management this was worth doing. I started my proof-of-concept on an old PowerPC based Mac I had at home that found a second life after I installed Yellow Dog Linux on it.

After some iteration I had good results on the PowerPC. So I brought my source code into work and repeated the test on other CPUs that I could find. On my desk I had a Sun workstation and a Windows PC with a 6 year old Pentium 3 CPU (600MHz, 128kb L2 cache). Elsewhere I had access to a new Sun server with a 900MHz UltraSPARC IV (or IV+) CPU and an HP server with a PA RISC CPU.

I also implemented other state of the art algorithms including Alphasort along with the old sort algorithm used by Oracle. From testing I learned:

my new sort was much faster than other algorithms when keys were larger than 8 bytes
my new sort was faster on my old Pentium 3 CPU than on the Sun UltraSPARC IV

The first was great news for me, the second was less than great news for Sun shareholders. I never learned why that UltraSPARC IV performance was lousy. It might have been latency to the caches.

Real implementation

Once I had great results, it was time for the functional and design specification reviews. I remember two issues:

the old sort was stable, the new sort was not

I don't remember how this concern was addressed

the new sort has a bad, but unlikely, worst-case

The problem here is the worst-case when quicksort picks the worst pivot every time it selects a pivot. The new sort wasn't naive, it used the median from a sample of keys each time to select a pivot (the sample size might have been 5). So I did the math to estimate the risk. Given that the numbers are big and probabilities are small I needed a library or tool that supported arbitrary-precision arithmetic and ended up using a Scheme implementation. The speedup in most cases justified the risk in a few cases.

And once I had this implemented within the Oracle DBMS I was able to compare it with the old sort. The new sort was often about 5 times faster than the old sort. I then compared it with SyncSort. I don't remember whether they had a DeWitt Clause so I won't share the results but I will say that the new sort in Oracle looked great in comparison.

The End

The new sorted landed in 10gR2 and was featured in a white-paper. I also got a short email from Larry Ellison thanking me for the work. A promotion or bonus would have to wait as you had to play the long-game in your career at Oracle. And that was all the motivation I needed to leave Oracle -- first for a startup, and then to Google and Facebook.

After leaving Oracle, much of my time was spent on making MySQL better. Great open-source DBMS, like MySQL and PostgreSQL, were not good for Oracle's new license revenue. Oracle is a better DBMS, but not everyone needs it or can afford it.

Tuesday, December 30, 2025

Performance for RocksDB 9.8 through 10.10 on 8-core and 48-core servers

This post has results for RocksDB performance using db_bench on 8-core and 48-core servers. I previously shared results for RocksDB performance using gcc and clang and then for RocksDB on a small Arm server.

tl;dr

RocksDB is boring, there are few performance regressions.
There was a regression in write-heavy workloads with RocksDB 10.6.2. See bug 13996 for details. That has been fixed.
I will repeat tests in a few weeks

Software

I used RocksDB versions 9.8 through 10.0.

I compiled each version clang version 18.3.1 with link-time optimization enabled (LTO). The build command line was:

flags=( DISABLE_WARNING_AS_ERROR=1 DEBUG_LEVEL=0 V=1 VERBOSE=1 )

# for clang+LTO
AR=llvm-ar-18 RANLIB=llvm-ranlib-18 CC=clang CXX=clang++ \
make "${flags[@]}" static_lib db_bench

Hardware

I used servers with 8 and 48 cores, both run Ubuntu 22.04:

8-core

Ryzen 7 (AMD) CPU with 8 cores and 32G of RAM.
storage is one NVMe SSD with discard enabled and ext-4
benchmarks are run with 1 client, 20M KV pairs for byrx and 400M KV pairs for iobuf and iodir

48-core

an ax162s from Hetzner with an AMD EPYC 9454P 48-Core Processor with SMT disabled, 128G of RAM
storage is 2 SSDs with RAID 1 (3.8T each) and ext-4.
benchmarks are run with 36 clients, 200M KV pairs for byrx and 2B KV pairs for iobuf and iodir

Benchmark

Overviews on how I use db_bench are here and here.

Most benchmark steps were run for 1800 seconds and all used the LRU block cache. I try to use Hyperclock on large servers but forgot that this time.

Tests were run for three workloads:

byrx - database cached by RocksDB
iobuf - database is larger than RAM and RocksDB used buffered IO
iodir - database is larger than RAM and RocksDB used O_DIRECT

The benchmark steps that I focus on are:

fillseq

load RocksDB in key order with 1 thread

revrangeww, fwdrangeww

do reverse or forward range queries with a rate-limited writer. Report performance for the range queries

readww

do point queries with a rate-limited writer. Report performance for the point queries.

overwrite

overwrite (via Put) random keys and wait for compaction to stop at test end

Relative QPS

Many of the tables below (inlined and via URL) show the relative QPS which is:
(QPS for my version / QPS for RocksDB 9.8)

The base version varies and is listed below. When the relative QPS is > 1.0 then my version is faster than RocksDB 9.8. When it is < 1.0 then there might be a performance regression or there might just be noise.

The spreadsheet with numbers and charts is here. Performance summaries are here.

Results: cached database (byrx)

From 1 client on the 8-core server

Results are stable except for the overwrite test where there might be a regression, but I think that is noise after repeating this test 2 more times and the cause is that the base case (result from 9.8) was an outlier. I will revisit this.

From 36 clients on the 48-core server

Results are stable

Results: IO-bound with buffered IO (iobuf)

From 1 client on the 8-core server

Results are stable except for the overwrite test where there might be a large improvement. But I wonder if this is from noise in the result for the base case from RocksDB 9.8, just as there might be noice in the cached (byrx) results.
The regression in fillseq with 10.6.2 is from bug 13996

From 36 clients on the 48-core server

Results are stable except for the overwrite test where there might be a large improvement. But I wonder if this is from noise in the result for the base case from RocksDB 9.8, just as there might be noice in the cached (byrx) results.
The regression in fillseq with 10.6.2 is from bug 13996

Results: IO-bound with O_DIRECT (iodir)

From 1 client on the 8-core server

Results are stable
The regression in fillseq with 10.6.2 is from bug 13996

From 36 clients on the 48-core server

Results are stable
The regression in fillseq with 10.6.2 is from bug 13996

Monday, December 29, 2025

IO-bound sysbench vs Postgres on a 48-core server

This has results for an IO-bound sysbench benchmark on a 48-core server for Postgres versions 12 through 18. Results from a CPU-bound sysbench benchmark on the 48-core server are here.

tl;dr - for Postgres 18.1 relative to 12.22

QPS for IO-bound point-query tests is similar while there is a large improvement for the one CPU-bound test (hot-points)
QPS for range queries without aggregation is similar
QPS for range queries with aggregation is between 1.05X and 1.25X larger in 18.1
QPS for writes show there might be a few large regressions in 18.1

tl;dr - for Postgres 18.1 using different values for the io_method option

for tests that do long range queries without aggregation

the best QPS is from io_method=io_uring
the second best QPS is from io_method=worker with a large value for io_workers

for tests that do long range queries with aggregation

when using io_method=worker a larger value for io_workers hurt QPS in contrast to the result for range queries without aggregation
for most tests the best QPS is from io_method=io_uring

Builds, configuration and hardware

I compiled Postgres from source for versions 12.22, 13.23, 14.20, 15.15, 16.10, 16.11, 17.6, 17.7, 18.0 and 18.1.

I used a 48-core server from Hetzner

an ax162s with an AMD EPYC 9454P 48-Core Processor with SMT disabled
2 Intel D7-P5520 NVMe storage devices with RAID 1 (3.8T each) using ext4
128G RAM
Ubuntu 22.04 running the non-HWE kernel (5.5.0-118-generic)

Configuration files for the big server

the config file is named conf.diff.cx10a_c32r128 (x10a_c32r128) and is here for versions 12, 13, 14, 15, 16 and 17.
for Postgres 18 I used

conf.diff.cx10b_c32r128 (x10b_c32r128)

uses io_method=sync and is similar to the config used for versions 12 through 17.

conf.diff.cx10c_c32r128 (x10c_c32r128)

uses io_method=worker and io_workers is not set

conf.diff.cx10cw8_c32r128 (x10cw8_c32r128)

uses io_method=worker and io_workers=8

conf.diff.cx10cw16_c32r128 (x10cw8_c32r128)

uses io_method=worker and io_workers=16

conf.diff.cx10cw32_c32r128 (x10cw8_c32r128)

uses io_method=worker and io_workers=32

conf.diff.cx10d_c32r128 (x10d_c32r128)

uses io_method=io_uring

Benchmark

I used sysbench and my usage is explained here. I now run 32 of the 42 microbenchmarks listed in that blog post. Most test only one type of SQL statement. Benchmarks are run with the database cached by Postgres.

The read-heavy microbenchmarks are run for 600 seconds and the write-heavy for 900 seconds. The benchmark is run with 40 clients and 8 tables with 250M rows per table. With 250M rows per table this is IO-bound. I normally use 10M rows per table for CPU-bound workloads.

The purpose is to search for regressions from new CPU overhead and mutex contention. I use the small server with low concurrency to find regressions from new CPU overheads and then larger servers with high concurrency to find regressions from new CPU overheads and mutex contention.

Results

The microbenchmarks are split into 4 groups -- 1 for point queries, 2 for range queries, 1 for writes. For the range query microbenchmarks, part 1 has queries without aggregation while part 2 has queries with aggregation.

I provide charts below with relative QPS. The relative QPS is the following:

(QPS for some version) / (QPS for base version)

When the relative QPS is > 1 then some version is faster than base version. When it is < 1 then there might be a regression. When the relative QPS is 1.2 then some version is about 20% faster than base version.

I provide two comparisons and each uses a different base version. They are:

base version is Postgres 12.22

compare 12.22, 13.23, 14.20, 15.15, 16.11, 17.7 and 18.1
the goal for this is to see how performance changes over time
per-test results from vmstat and iostat are here

base version is Postgres 18.1

compare 18.1 using the x10b_c32r128, x10c_c32r128, x10cw8_c32r128, x10cw16_c32r128, x10cw32_c32r128 and x10d_c32r128 configs
the goal for this is to understand the impact of the io_method option
per-test results from vmstat and iostat are here

The per-test results from vmstat and iostat can help to explain why something is faster or slower because it shows how much HW is used per request, including CPU overhead per operation (cpu/o) and context switches per operation (cs/o) which are often a proxy for mutex contention.

The spreadsheet and charts are here and in some cases are easier to read than the charts below. Converting the Google Sheets charts to PNG files does the wrong thing for some of the test names listed at the bottom of the charts below.

Results: Postgres 12.22 through 18.1

All charts except the first have the y-axis start at 0.7 rather than 0.0 to improve readability.

There are two charts for point queries. The second truncates the y-axis to improve readability.

a large improvement for the hot-points test arrives in 17.x. While most tests are IO-bound, this test is CPU-bound because all queries fetch the same N rows.
for other tests there are small changes, both improvements and regressions, and the regressions are too small to investigate

For range queries without aggregation:

QPS for Postgres 18.1 is within 5% of 12.22, sometimes better and sometimes worse
for Postgres 17.7 there might be a large regression on the scan test and that also occurs with 17.6 (not shown). But the scan test can be prone to variance, especially with Postgres and I don't expect to spend time debugging this. Note that the config I use for 18.1 here uses io_method=sync which is similar to what Postgres uses in releases prior to 18.x. From the vmstat and iostat metrics what I see is:

a small reduction in CPU overhead (cpu/o) in 18.1
a large reduction in the context switch rate (cs/o) in 18.1
small reductions in read IO (r/o and rKB/o) in 18.1

For range queries with aggregation:

QPS for 18.1 is between 1.05X and 1.25X better than for 12.22

For write-heavy tests

there might be large regressions for several tests: read-write, update-zipf and write-only, The read-write tests do all of the writes done by write-only and then add read-only statements.
from the vmstat and iostat results for the read-write tests I see

CPU (cpu/o) is up by ~1.2X in PG 16.x through 18.x
storage reads per query (r/o) have been increasing from PG 16.x through 18.x and are up by ~1.1X in PG 18.1
storage KB read per query (rKB/o) increased started in PG 16.1 and are 1.44X and 1.16X larger in PG 18.x

from the vmstat and iostat results for the update-zipf test

results are similar to the read-write tests above

from the vmstat and iostat results for the write-only test

results are similar to the read-write tests above

Results: Postgres 18.1 and io_method

For point queries

results are similar for all configurations and this is expected

For range queries without aggregation

there are two charts, the y-axis is truncated in the second to improve readability
all configs get similar QPS for all tests except scan
for the scan test

the x10c_c32r128 config has the worst result. This is expected given there are 40 concurrent connections and it used the default for io_workers (=3)
QPS improves for io_method=worker with larger values for io_workers
io_method=io_uring has the best QPS (the x10d_c32r128 config)

For range queries with aggregation

when using io_method=worker a larger value for io_workers hurt QPS in contrast to the result for range queries without aggregation
io_method=io_uring gets the best QPS on all tests except for the read-only tests with range=10 and 10,000. There isn't an obvious problem based on the vmstat and iostat results. From the r_await column in iostat output (not shown) the differences are mostly explained by a change in IO latency. Perhaps variance in storage latency is the issue.

For writes

the best QPS occurs with the x10b_c32r128 config (io_method=sync). I am not sure if that option matters here and perhaps there is too much noise in the results.