Personal blog of Yzmir Ramirez

In this blog, I will provide answers to the Q & A for the MySQL 8.0 Architecture and Enhancement webinar.

First, I want to thank everybody for attending my April 9, 2019, webinar. The recording and slides are available here. Below is the list of your questions that I was unable to answer fully during the webinar.

Q: What kind of Encryption levels are provided into MySQL 8.0?

The MySQL data-at-rest encryption feature supports the Advanced Encryption Standard (AES) block-based encryption algorithm.

In MySQL block_encryption_mode variable controls the block encryption mode. The default setting is aes-128-ecb. Set this option to aes-256-cbc, for example, under the [mysqld] option group in the MySQL configuration file (/etc/my.cnf):

[mysqld]
block_encryption_mode=aes-256-cbc

Q: At what frequency does the redo log buffer flush the changes to disk? When is the commit variable set to zero?

Here’s an overview:

• innodb_flush_log_at_trx_commit variable can be configured to set flush frequency in MySQL 5.7 and 8.0 it’s set to 1 by default.
• innodb_flush_log_at_trx_commit =0  logs are written and flushed to disk once per second. Transactions for which logs have not been flushed can be lost in a crash.
• innodb_flush_log_at_trx_commit =1 is required for full ACID compliance. Logs are written and flushed to disk at each transaction commit. Default Setting.
• innodb_flush_log_at_trx_commit =2 logs are written after each transaction commit and flushed to disk once per second. Transactions for which logs have not been flushed can be lost in a crash.

Q: How are persistent variables reset?

Using the RESET PERSIST command we can remove persisted global system variable settings from the mysqld-auto.cnf.

Example:

mysql > SET PERSIST binlog_encryption=ON;
Query OK, 0 rows affected (0.00 sec)
$ cat data/mysqld-auto.cnf
{ "Version" : 1 , "mysql_server" : { "mysql_server_static_options" : { "binlog_encryption" : { "Value" : "ON" , "Metadata" : { "Timestamp" : 1554896858076255 , "User" : "msandbox" , "Host" : "localhost" } } } } }
MySQL > RESET PERSIST binlog_encryption;
Query OK, 0 rows affected (0.00 sec)
$ cat data/mysqld-auto.cnf
{ "Version" : 1 , "mysql_server" : { } }

To reset all persistent variables use following command.

mysql > RESET PERSIST;
Query OK, 0 rows affected (0.00 sec)

Q: Does pt-config-diff work with these persistent vs. my.cnf variable settings?

No, it will not work. Due to config format differences in these files.

$ pt-config-diff ./my.sandbox.cnf data/mysqld-auto.cnf
Cannot auto-detect the MySQL config format at /home/lalit/perl5/bin/pt-config-diff line 3010.

Q: Regarding the UNDO Tablespace, do we have any specific retention to follow?

This is not required because in MySQL 8.0, the innodb_undo_log_truncate variable is enabled by default. It will perform an automatic truncate operation on the UNDO tablespace. When undo tablespaces exceed the threshold value defined by innodb_max_undo_log_size (default value is 1024 MiB) they are marked for truncation.

Truncating the undo tablespace performs the following action:

1. Performs deactivation of undo tablespace
2. Truncation of undo tablespace
3. Reactivation of undo tablespaces

NOTE:  Truncating undo logs that reside in the system tablespace is not supported. 

Q: Corrupted data on disk where the secondary indexes don’t match to the primary?

I’ll be happy to respond to this, but I’ll need a little bit more information… feel free to add more detail to the comments section and I’ll see if I can provide some insight.

Thanks for attending this webinar on MySQL 8.0 Architecture and Enhancement Webinar . You can find the slides and a recording here.

 

Please join Percona’s Product Manager, Michael Coburn, as he presents his talk Extending and Customizing Percona Monitoring and Management on April 10th, 2019 at 10:00 AM PDT (UTC-7) / 1:00 PM EDT (UTC-4).

Register Now

Do you already run stock PMM in your environment and want to learn how you extend the PMM platform? If so, come learn about:

1. Dashboard Customizations
* How to create a custom dashboard from existing graphs, or build Cross Server Dashboards
2. External Exporters – Monitor any service, anywhere!
* Adding an exporter, view the data in data exploration, to deploying a working Dashboard
3. Working with custom queries (MySQL and PostgreSQL)
* Execute SELECT statements against your database and store in Prometheus
* Build Dashboards relevant to your environment
4. Customizing Exporter Options
* Enable deactivated functionality that applies to your environment
5. Using Grafana Alerting
* Moreover, how to set up channels (SMTP, Slack, etc)
* What’s more, how to configure thresholds and alerts
6. Using MySQL/PostgreSQL Data Source
* Also, execute SELECT statements against your database and plot your application metrics

In order to learn more, register for Extending and Customizing Percona Monitoring and Management.

Please join Percona’s Bug Analyst, Lalit Choudhary as he presents his talk MySQL 8.0 Architecture and Enhancement on Tuesday, April 9th, 2019 at 6:00 AM PDT (UTC-7) / 9:00 AM EDT (UTC-4).

Register Now

The release of MySQL 8.0 offers much more to users compared to previous releases. There are major changes in architecture as well as adding differentiating features, and improvements to manage the database more efficiently.

In our talk we will go through, MySQL 8.0 architecture:
* On Disk
* In-memory

Examples and use cases will be shared showing the new features introduced in MySQL 8.0.

Register for MySQL 8.0 Architecture and Enhancement to learn more.

Please join Percona’s Product Manager, Michael Coburn, as he presents his talk Monitoring PostgreSQL with Percona Monitoring and Management (PMM) on March 27th, 2019 at 11:00 AM PDT (UTC-7) / 2:00 PM EDT (UTC-4).

Register Now

In this webinar, learn how to monitor PostgreSQL using Percona Monitoring and Management (PMM) so that you can:

Gain greater visibility of performance and bottlenecks for PostgreSQL
Consolidate your PostgreSQL servers into the same monitoring platform you already use for MySQL and MongoDB
Respond more quickly and efficiently in Severity 1 issues

We’ll also show how using PMM’s External Exporters can help you integrate PostgreSQL in only minutes!

In order to learn more, register for this webinar on how to monitor PostgreSQL with PMM.

Please join Percona’s Principal Support Engineer, Sveta Smirnova, as she presents MySQL Performance Schema in 1 hour on Thursday, March 21st, 2019, at 10:00 am PDT (UTC-7) / 1:00 pm EDT (UTC-4).

Register Now

MySQL 8.0 Performance Schema is a mature tool, used by humans and monitoring products. It was born in 2010 as “a feature for monitoring server execution at a low level.” The tool has grown over the years with performance fixes and DBA-faced features. In this webinar, I will give an overview of Performance Schema, focusing on its tuning, performance, and usability.

Performance Schema helps to troubleshoot query performance, complicated locking issues and memory leaks. It can also troubleshoot resource usage, problematic behavior caused by inappropriate settings and much more. Additionally, it comes with hundreds of options which allow for greater precision tuning.

Performance Schema is a potent and very complicated tool. What’s more, it does not affect performance in most cases. However, it collects a lot of data and sometimes this data is hard to read.

In this webinar, I will guide you through the main Performance Schema features, design, and configuration. You will learn how to get the best of it. I will cover its companion sys schema and graphical monitoring tools.

In order to learn more, register for MySQL Performance Schema in 1 hour today.

Join Percona Support Engineer, Vinicius Grippa, as he presents his talk Enhancing MySQL Security on Thursday, March 7th, 2019 at 7:00 AM PST (UTC-8) / 10:00 AM EST (UTC-5).

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Security is always a challenge when it comes to data. What’s more, regulations like GDPR add a whole new layer on top of it, with rules more and more restrictive to access and manipulate data. Join us in this presentation to check security best practices, as well as traditional and new features available for MySQL including features coming with the new MySQL 8.

In this talk, DBA’s and sysadmins will walk through the security features available on the OS and MySQL. For instance, these features include:

– SO security
– SSL
– ACL
– TDE
– Audit Plugin
– MySQL 8 features (undo, redo and binlog encryption)
– New caching_sha2_password
– Roles
– Password Management
– FIPS mode

In order to learn more register for this webinar on Enhancing MySQL Security.

Join Percona CEO Peter Zaitsev as he presents MySQL High Availability and Disaster Recovery on Wednesday, March 6th, 2019, at 11:00 AM PST (UTC-8) / 2:00 PM EST (UTC-5).

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In this hour-long webinar, Peter describes the differences between high availability (HA) and disaster recovery (DR). Afterward, Peter will go through scenarios detailing how each is handled manually and in Amazon RDS.

He will review the pros and cons of managing HA and DR in the traditional database environment as well in the cloud. Having full control of these areas is daunting. However, Amazon RDS makes meeting these needs easier and more efficient.

Regardless of which path you choose, monitoring your environment is vital. Peter’s talk will make that message clear. A discussion of metrics you should regularly review to keep your environment working correctly and performing optimally concludes the webinar.

In order to learn more register for Peter’s webinar on MySQL High Availability and Disaster Recovery.

Modern CPU models have a huge number of cores. For many years, applications have been sending queries in parallel to databases. Where there are reporting queries that deal with many table rows, the ability for a query to use multiple CPUs helps us with a faster execution. Parallel queries in PostgreSQL allow us to utilize many CPUs to finish report queries faster. The parallel queries feature was implemented in 9.6 and helps. Starting from PostgreSQL 9.6 a report query is able to use many CPUs and finish faster.

The initial implementation of the parallel queries execution took three years. Parallel support requires code changes in many query execution stages. PostgreSQL 9.6 created an infrastructure for further code improvements. Later versions extended parallel execution support for other query types.

Limitations

• Do not enable parallel executions if all CPU cores are already saturated. Parallel execution steals CPU time from other queries, and increases response time.
• Most importantly, parallel processing significantly increases memory usage with high WORK_MEM values, as each hash join or sort operation takes a work_mem amount of memory.
• Next, low latency OLTP queries can’t be made any faster with parallel execution. In particular, queries that returns a single row can perform badly when parallel execution is enabled.
• The Pierian spring for developers is a TPC-H benchmark. Check if you have similar queries for the best parallel execution.
• Parallel execution supports only SELECT queries without lock predicates.
• Proper indexing might be a better alternative to a parallel sequential table scan.
• There is no support for cursors or suspended queries.
• Windowed functions and ordered-set aggregate functions are non-parallel.
• There is no benefit for an IO-bound workload.
• There are no parallel sort algorithms. However, queries with sorts still can be parallel in some aspects.
• Replace CTE (WITH …) with a sub-select to support parallel execution.
• Foreign data wrappers do not currently support parallel execution (but they could!)
• There is no support for FULL OUTER JOIN.
• Clients setting max_rows disable parallel execution.
• If a query uses a function that is not marked as PARALLEL SAFE, it will be single-threaded.
• SERIALIZABLE transaction isolation level disables parallel execution.

Test environment

The PostgreSQL development team have tried to improve TPC-H benchmark queries’ response time. You can download the benchmark and adapt it to PostgreSQL by using these instructions. It’s not an official way to use the TPC-H benchmark, so you shouldn’t use it to compare different databases or hardware.

1. Download TPC-H_Tools_v2.17.3.zip (or newer version) from official TPC site.
2. Rename makefile.suite to Makefile and modify it as requested at https://github.com/tvondra/pg_tpch . Compile the code with make command
3. Generate data: ./dbgen -s 10 generates 23GB database which is enough to see the difference in performance for parallel and non-parallel queries.
4. Convert tbl files to csv with for + sed
5. Clone pg_tpch repository and copy csv files to pg_tpch/dss/data
6. Generate queries with qgen command
7. Load data to the database with ./tpch.sh command.

Parallel sequential scan

This might be faster not because of parallel reads, but due to scattering of data across many CPU cores. Modern OS provides good caching for PostgreSQL data files. Read-ahead allows getting a block from storage more than just the block requested by PG daemon. As a result, query performance is not limited due to disk IO. It consumes CPU cycles for:

• reading rows one by one from table data pages
• comparing row values and WHERE conditions

Let’s try to execute simple select query:

tpch=# explain analyze select l_quantity as sum_qty from lineitem where l_shipdate <= date '1998-12-01' - interval '105' day;
QUERY PLAN
--------------------------------------------------------------------------------------------------------------------------
Seq Scan on lineitem (cost=0.00..1964772.00 rows=58856235 width=5) (actual time=0.014..16951.669 rows=58839715 loops=1)
Filter: (l_shipdate <= '1998-08-18 00:00:00'::timestamp without time zone)
Rows Removed by Filter: 1146337
Planning Time: 0.203 ms
Execution Time: 19035.100 ms

A sequential scan produces too many rows without aggregation. So, the query is executed by a single CPU core.

After adding SUM(), it’s clear to see that two workers will help us to make the query faster:

explain analyze select sum(l_quantity) as sum_qty from lineitem where l_shipdate <= date '1998-12-01' - interval '105' day;
QUERY PLAN
----------------------------------------------------------------------------------------------------------------------------------------------------
Finalize Aggregate (cost=1589702.14..1589702.15 rows=1 width=32) (actual time=8553.365..8553.365 rows=1 loops=1)
-> Gather (cost=1589701.91..1589702.12 rows=2 width=32) (actual time=8553.241..8555.067 rows=3 loops=1)
Workers Planned: 2
Workers Launched: 2
-> Partial Aggregate (cost=1588701.91..1588701.92 rows=1 width=32) (actual time=8547.546..8547.546 rows=1 loops=3)
-> Parallel Seq Scan on lineitem (cost=0.00..1527393.33 rows=24523431 width=5) (actual time=0.038..5998.417 rows=19613238 loops=3)
Filter: (l_shipdate <= '1998-08-18 00:00:00'::timestamp without time zone)
Rows Removed by Filter: 382112
Planning Time: 0.241 ms
Execution Time: 8555.131 ms

The more complex query is 2.2X faster compared to the plain, single-threaded select.

Parallel Aggregation

A “Parallel Seq Scan” node produces rows for partial aggregation. A “Partial Aggregate” node reduces these rows with SUM(). At the end, the SUM counter from each worker collected by “Gather” node.

The final result is calculated by the “Finalize Aggregate” node. If you have your own aggregation functions, do not forget to mark them as “parallel safe”.

Number of workers

We can increase the number of workers without server restart:

alter system set max_parallel_workers_per_gather=4;
select * from pg_reload_conf();
Now, there are 4 workers in explain output:
tpch=# explain analyze select sum(l_quantity) as sum_qty from lineitem where l_shipdate <= date '1998-12-01' - interval '105' day;
QUERY PLAN
----------------------------------------------------------------------------------------------------------------------------------------------------
Finalize Aggregate (cost=1440213.58..1440213.59 rows=1 width=32) (actual time=5152.072..5152.072 rows=1 loops=1)
-> Gather (cost=1440213.15..1440213.56 rows=4 width=32) (actual time=5151.807..5153.900 rows=5 loops=1)
Workers Planned: 4
Workers Launched: 4
-> Partial Aggregate (cost=1439213.15..1439213.16 rows=1 width=32) (actual time=5147.238..5147.239 rows=1 loops=5)
-> Parallel Seq Scan on lineitem (cost=0.00..1402428.00 rows=14714059 width=5) (actual time=0.037..3601.882 rows=11767943 loops=5)
Filter: (l_shipdate <= '1998-08-18 00:00:00'::timestamp without time zone)
Rows Removed by Filter: 229267
Planning Time: 0.218 ms
Execution Time: 5153.967 ms

What’s happening here? We have changed the number of workers from 2 to 4, but the query became only 1.6599 times faster. Actually, scaling is amazing. We had two workers plus one leader. After a configuration change, it becomes 4+1.

The biggest improvement from parallel execution that we can achieve is: 5/3 = 1.66(6)X faster.

How does it work?

Processes

Query execution always starts in the “leader” process. A leader executes all non-parallel activity and its own contribution to parallel processing. Other processes executing the same queries are called “worker” processes. Parallel execution utilizes the Dynamic Background Workers infrastructure (added in 9.4). As other parts of PostgreSQL uses processes, but not threads, the query creating three worker processes could be 4X faster than the traditional execution.

Communication

Workers communicate with the leader using a message queue (based on shared memory). Each process has two queues: one for errors and the second one for tuples.

How many workers to use?

Firstly, the max_parallel_workers_per_gather parameter is the smallest limit on the number of workers. Secondly, the query executor takes workers from the pool limited by max_parallel_workers size. Finally, the top-level limit is max_worker_processes: the total number of background processes.

Failed worker allocation leads to single-process execution.

The query planner could consider decreasing the number of workers based on a table or index size. min_parallel_table_scan_size and min_parallel_index_scan_size control this behavior.

set min_parallel_table_scan_size='8MB'
8MB table => 1 worker
24MB table => 2 workers
72MB table => 3 workers
x => log(x / min_parallel_table_scan_size) / log(3) + 1 worker

Each time the table is 3X bigger than min_parallel_(index|table)_scan_size, postgres adds a worker. The number of workers is not cost-based! A circular dependency makes a complex implementation hard. Instead, the planner uses simple rules.

In practice, these rules are not always acceptable in production and you can override the number of workers for the specific table with ALTER TABLE … SET (parallel_workers = N).

Why parallel execution is not used?

Besides to the long list of parallel execution limitations, PostgreSQL checks costs:

parallel_setup_cost to avoid parallel execution for short queries. It models the time spent for memory setup, process start, and initial communication

parallel_tuple_cost : The communication between leader and workers could take a long time. The time is proportional to the number of tuples sent by workers. The parameter models the communication cost.

Nested loop joins

PostgreSQL 9.6+ could execute a “Nested loop” in parallel due to the simplicity of the operation.

explain (costs off) select c_custkey, count(o_orderkey)
                from    customer left outer join orders on
                                c_custkey = o_custkey and o_comment not like '%special%deposits%'
                group by c_custkey;
                                      QUERY PLAN
--------------------------------------------------------------------------------------
 Finalize GroupAggregate
   Group Key: customer.c_custkey
   ->  Gather Merge
         Workers Planned: 4
         ->  Partial GroupAggregate
               Group Key: customer.c_custkey
               ->  Nested Loop Left Join
                     ->  Parallel Index Only Scan using customer_pkey on customer
                     ->  Index Scan using idx_orders_custkey on orders
                           Index Cond: (customer.c_custkey = o_custkey)
                           Filter: ((o_comment)::text !~~ '%special%deposits%'::text)

Gather happens in the last stage, so “Nested Loop Left Join” is a parallel operation. “Parallel Index Only Scan” is available from version 10. It acts in a similar way to a parallel sequential scan. The

c_custkey = o_custkey

condition reads a single order for each customer row. Thus it’s not parallel.

Hash Join

Each worker builds its own hash table until PostgreSQL 11. As a result, 4+ workers weren’t able to improve performance. The new implementation uses a shared hash table. Each worker can utilize WORK_MEM to build the hash table.

select
        l_shipmode,
        sum(case
                when o_orderpriority = '1-URGENT'
                        or o_orderpriority = '2-HIGH'
                        then 1
                else 0
        end) as high_line_count,
        sum(case
                when o_orderpriority <> '1-URGENT'
                        and o_orderpriority <> '2-HIGH'
                        then 1
                else 0
        end) as low_line_count
from
        orders,
        lineitem
where
        o_orderkey = l_orderkey
        and l_shipmode in ('MAIL', 'AIR')
        and l_commitdate < l_receiptdate
        and l_shipdate < l_commitdate
        and l_receiptdate >= date '1996-01-01'
        and l_receiptdate < date '1996-01-01' + interval '1' year
group by
        l_shipmode
order by
        l_shipmode
LIMIT 1;
                                                                                                                                    QUERY PLAN
-----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
 Limit  (cost=1964755.66..1964961.44 rows=1 width=27) (actual time=7579.592..7922.997 rows=1 loops=1)
   ->  Finalize GroupAggregate  (cost=1964755.66..1966196.11 rows=7 width=27) (actual time=7579.590..7579.591 rows=1 loops=1)
         Group Key: lineitem.l_shipmode
         ->  Gather Merge  (cost=1964755.66..1966195.83 rows=28 width=27) (actual time=7559.593..7922.319 rows=6 loops=1)
               Workers Planned: 4
               Workers Launched: 4
               ->  Partial GroupAggregate  (cost=1963755.61..1965192.44 rows=7 width=27) (actual time=7548.103..7564.592 rows=2 loops=5)
                     Group Key: lineitem.l_shipmode
                     ->  Sort  (cost=1963755.61..1963935.20 rows=71838 width=27) (actual time=7530.280..7539.688 rows=62519 loops=5)
                           Sort Key: lineitem.l_shipmode
                           Sort Method: external merge  Disk: 2304kB
                           Worker 0:  Sort Method: external merge  Disk: 2064kB
                           Worker 1:  Sort Method: external merge  Disk: 2384kB
                           Worker 2:  Sort Method: external merge  Disk: 2264kB
                           Worker 3:  Sort Method: external merge  Disk: 2336kB
                           ->  Parallel Hash Join  (cost=382571.01..1957960.99 rows=71838 width=27) (actual time=7036.917..7499.692 rows=62519 loops=5)
                                 Hash Cond: (lineitem.l_orderkey = orders.o_orderkey)
                                 ->  Parallel Seq Scan on lineitem  (cost=0.00..1552386.40 rows=71838 width=19) (actual time=0.583..4901.063 rows=62519 loops=5)
                                       Filter: ((l_shipmode = ANY ('{MAIL,AIR}'::bpchar[])) AND (l_commitdate < l_receiptdate) AND (l_shipdate < l_commitdate) AND (l_receiptdate >= '1996-01-01'::date) AND (l_receiptdate < '1997-01-01 00:00:00'::timestamp without time zone))
                                       Rows Removed by Filter: 11934691
                                 ->  Parallel Hash  (cost=313722.45..313722.45 rows=3750045 width=20) (actual time=2011.518..2011.518 rows=3000000 loops=5)
                                       Buckets: 65536  Batches: 256  Memory Usage: 3840kB
                                       ->  Parallel Seq Scan on orders  (cost=0.00..313722.45 rows=3750045 width=20) (actual time=0.029..995.948 rows=3000000 loops=5)
 Planning Time: 0.977 ms
 Execution Time: 7923.770 ms

Query 12 from TPC-H is a good illustration for a parallel hash join. Each worker helps to build a shared hash table.

Merge Join

Due to the nature of merge join it’s not possible to make it parallel. Don’t worry if it’s the last stage of the query execution—you can still can see parallel execution for queries with a merge join.

-- Query 2 from TPC-H
explain (costs off) select s_acctbal, s_name, n_name, p_partkey, p_mfgr, s_address, s_phone, s_comment
from    part, supplier, partsupp, nation, region
where
        p_partkey = ps_partkey
        and s_suppkey = ps_suppkey
        and p_size = 36
        and p_type like '%BRASS'
        and s_nationkey = n_nationkey
        and n_regionkey = r_regionkey
        and r_name = 'AMERICA'
        and ps_supplycost = (
                select
                        min(ps_supplycost)
                from    partsupp, supplier, nation, region
                where
                        p_partkey = ps_partkey
                        and s_suppkey = ps_suppkey
                        and s_nationkey = n_nationkey
                        and n_regionkey = r_regionkey
                        and r_name = 'AMERICA'
        )
order by s_acctbal desc, n_name, s_name, p_partkey
LIMIT 100;
                                                QUERY PLAN
----------------------------------------------------------------------------------------------------------
 Limit
   ->  Sort
         Sort Key: supplier.s_acctbal DESC, nation.n_name, supplier.s_name, part.p_partkey
         ->  Merge Join
               Merge Cond: (part.p_partkey = partsupp.ps_partkey)
               Join Filter: (partsupp.ps_supplycost = (SubPlan 1))
               ->  Gather Merge
                     Workers Planned: 4
                     ->  Parallel Index Scan using part_pkey on part
                           Filter: (((p_type)::text ~~ '%BRASS'::text) AND (p_size = 36))
               ->  Materialize
                     ->  Sort
                           Sort Key: partsupp.ps_partkey
                           ->  Nested Loop
                                 ->  Nested Loop
                                       Join Filter: (nation.n_regionkey = region.r_regionkey)
                                       ->  Seq Scan on region
                                             Filter: (r_name = 'AMERICA'::bpchar)
                                       ->  Hash Join
                                             Hash Cond: (supplier.s_nationkey = nation.n_nationkey)
                                             ->  Seq Scan on supplier
                                             ->  Hash
                                                   ->  Seq Scan on nation
                                 ->  Index Scan using idx_partsupp_suppkey on partsupp
                                       Index Cond: (ps_suppkey = supplier.s_suppkey)
               SubPlan 1
                 ->  Aggregate
                       ->  Nested Loop
                             Join Filter: (nation_1.n_regionkey = region_1.r_regionkey)
                             ->  Seq Scan on region region_1
                                   Filter: (r_name = 'AMERICA'::bpchar)
                             ->  Nested Loop
                                   ->  Nested Loop
                                         ->  Index Scan using idx_partsupp_partkey on partsupp partsupp_1
                                               Index Cond: (part.p_partkey = ps_partkey)
                                         ->  Index Scan using supplier_pkey on supplier supplier_1
                                               Index Cond: (s_suppkey = partsupp_1.ps_suppkey)
                                   ->  Index Scan using nation_pkey on nation nation_1
                                         Index Cond: (n_nationkey = supplier_1.s_nationkey)

The “Merge Join” node is above “Gather Merge”. Thus merge is not using parallel execution. But the “Parallel Index Scan” node still helps with the part_pkey segment.

Partition-wise join

PostgreSQL 11 disables the partition-wise join feature by default. Partition-wise join has a high planning cost. Joins for similarly partitioned tables could be done partition-by-partition. This allows postgres to use smaller hash tables. Each per-partition join operation could be executed in parallel.

tpch=# set enable_partitionwise_join=t;
tpch=# explain (costs off) select * from prt1 t1, prt2 t2
where t1.a = t2.b and t1.b = 0 and t2.b between 0 and 10000;
                    QUERY PLAN
---------------------------------------------------
 Append
   ->  Hash Join
         Hash Cond: (t2.b = t1.a)
         ->  Seq Scan on prt2_p1 t2
               Filter: ((b >= 0) AND (b <= 10000))
         ->  Hash
               ->  Seq Scan on prt1_p1 t1
                     Filter: (b = 0)
   ->  Hash Join
         Hash Cond: (t2_1.b = t1_1.a)
         ->  Seq Scan on prt2_p2 t2_1
               Filter: ((b >= 0) AND (b <= 10000))
         ->  Hash
               ->  Seq Scan on prt1_p2 t1_1
                     Filter: (b = 0)
tpch=# set parallel_setup_cost = 1;
tpch=# set parallel_tuple_cost = 0.01;
tpch=# explain (costs off) select * from prt1 t1, prt2 t2
where t1.a = t2.b and t1.b = 0 and t2.b between 0 and 10000;
                        QUERY PLAN
-----------------------------------------------------------
 Gather
   Workers Planned: 4
   ->  Parallel Append
         ->  Parallel Hash Join
               Hash Cond: (t2_1.b = t1_1.a)
               ->  Parallel Seq Scan on prt2_p2 t2_1
                     Filter: ((b >= 0) AND (b <= 10000))
               ->  Parallel Hash
                     ->  Parallel Seq Scan on prt1_p2 t1_1
                           Filter: (b = 0)
         ->  Parallel Hash Join
               Hash Cond: (t2.b = t1.a)
               ->  Parallel Seq Scan on prt2_p1 t2
                     Filter: ((b >= 0) AND (b <= 10000))
               ->  Parallel Hash
                     ->  Parallel Seq Scan on prt1_p1 t1
                           Filter: (b = 0)

Above all, a partition-wise join can use parallel execution only if partitions are big enough.

Parallel Append

Parallel Append partitions work instead of using different blocks in different workers. Usually, you can see this with UNION ALL queries. The drawback – less parallelism, because every worker could ultimately work for a single query.

There are just two workers launched even with four workers enabled.

tpch=# explain (costs off) select sum(l_quantity) as sum_qty from lineitem where l_shipdate <= date '1998-12-01' - interval '105' day union all select sum(l_quantity) as sum_qty from lineitem where l_shipdate <= date '2000-12-01' - interval '105' day;
                                           QUERY PLAN
------------------------------------------------------------------------------------------------
 Gather
   Workers Planned: 2
   ->  Parallel Append
         ->  Aggregate
               ->  Seq Scan on lineitem
                     Filter: (l_shipdate <= '2000-08-18 00:00:00'::timestamp without time zone)
         ->  Aggregate
               ->  Seq Scan on lineitem lineitem_1
                     Filter: (l_shipdate <= '1998-08-18 00:00:00'::timestamp without time zone)

Most important variables

• WORK_MEM limits the memory usage of each process! Not just for queries: work_mem * processes * joins => could lead to significant memory usage.
• max_parallel_workers_per_gather  – how many workers an executor will use for the parallel execution of a planner node
• max_worker_processes – adapt the total number of workers to the number of CPU cores installed on a server
• max_parallel_workers – same for the number of parallel workers

Summary

Starting from 9.6 parallel queries execution could significantly improve performance for complex queries scanning many rows or index records. In PostgreSQL 10, parallel execution was enabled by default. Do not forget to disable parallel execution on servers with a heavy OLTP workload. Sequential scans or index scans still consume a significant amount of resources. If you are not running a report against the whole dataset, you may improve query performance just by adding missing indexes or by using proper partitioning.

References

• https://www.postgresql.org/docs/11/how-parallel-query-works.html
• https://www.postgresql.org/docs/11/parallel-plans.html
• http://ashutoshpg.blogspot.com/2017/12/partition-wise-joins-divide-and-conquer.html
• http://rhaas.blogspot.com/2016/04/postgresql-96-with-parallel-query-vs.html
  
• http://amitkapila16.blogspot.com/2015/11/parallel-sequential-scans-in-play.html
• https://write-skew.blogspot.com/2018/01/parallel-hash-for-postgresql.html
• http://rhaas.blogspot.com/2017/03/parallel-query-v2.html
• https://blog.2ndquadrant.com/parallel-monster-benchmark/
• https://blog.2ndquadrant.com/parallel-aggregate/
• https://www.depesz.com/2018/02/12/waiting-for-postgresql-11-support-parallel-btree-index-builds/
• Parallelism in PostgreSQL 11

—
Image compiled from photos by Nathan Gonthier and Pavel Nekoranec on Unsplash

While implementing ClickHouse for query executions statistics storage in Percona Monitoring and Management (PMM),  we were faced with a question of choosing the data type for metrics we store. It came down to this question: what is the difference in performance and space usage between Uint32, Uint64, Float32, and Float64 column types?

To test this, I created a test table with an abbreviated and simplified version of the main table in our ClickHouse Schema.

The “number of queries” is stored four times in four different columns to be able to benchmark queries referencing different columns.  We can do this with ClickHouse because it is a column store and it works only with columns referenced by the query. This method would not be appropriate for testing on MySQL, for example.

CREATE TABLE test
(
    digest String,
    db_server String,
    db_schema String,
    db_username String,
    client_host String,
    period_start DateTime,
    nq_UInt32 UInt32,
    nq_UInt64 UInt64,
    nq_Float32 Float32,
    nq_Float64 Float64
)
ENGINE = MergeTree
PARTITION BY toYYYYMM(period_start)
ORDER BY (digest, db_server, db_username, db_schema, client_host, period_start)
SETTINGS index_granularity = 8192

When testing ClickHouse performance you need to consider compression. Highly compressible data (for example just a bunch of zeroes) will compress very well and may be processed a lot faster than incompressible data. To take this into account we will do a test with three different data sets:

• Very Compressible when “number of queries” is mostly 1
• Somewhat Compressible when we use a range from 1 to 1000 and
• Poorly Compressible when we use range from 1 to 1000000.

Since it’s unlikely that an application will use the full 32 bit range, we haven’t used it for this test.

Another factor which can impact ClickHouse performance is the number of “parts” the table has. After loading the data we ran OPTIMIZE TABLE FINAL to ensure only one part is there on the disk. Note: ClickHouse will gradually delete old files after the optimize command has completed. To avoid these operations interfering with benchmarks, I waited for about 15 minutes to ensure all unused data was removed from the disk.

The amount of memory on the system was enough to cache whole columns in all tests, so this is an in-memory test.

Here is how the table with only one part looks on disk:

root@d01e692c291f:/var/lib/clickhouse/data/pmm/test_lc# ls -la
total 28
drwxr-xr-x 4 clickhouse clickhouse 12288 Feb 10 20:39 .
drwxr-xr-x 8 clickhouse clickhouse 4096 Feb 10 22:38 ..
drwxr-xr-x 2 clickhouse clickhouse 4096 Feb 10 20:30 201902_1_372_4
drwxr-xr-x 2 clickhouse clickhouse 4096 Feb 10 19:38 detached
-rw-r--r-- 1 clickhouse clickhouse 1 Feb 10 19:38 format_version.txt

When you have only one part it makes it very easy to see the space different columns take:

root@d01e692c291f:/var/lib/clickhouse/data/pmm/test_lc/201902_1_372_4# ls -la
total 7950468
drwxr-xr-x 2 clickhouse clickhouse 4096 Feb 10 20:30 .
drwxr-xr-x 4 clickhouse clickhouse 12288 Feb 10 20:39 ..
-rw-r--r-- 1 clickhouse clickhouse 971 Feb 10 20:30 checksums.txt
-rw-r--r-- 1 clickhouse clickhouse 663703499 Feb 10 20:30 client_host.bin
-rw-r--r-- 1 clickhouse clickhouse 754848 Feb 10 20:30 client_host.mrk
-rw-r--r-- 1 clickhouse clickhouse 238 Feb 10 20:30 columns.txt
-rw-r--r-- 1 clickhouse clickhouse 9 Feb 10 20:30 count.txt
-rw-r--r-- 1 clickhouse clickhouse 228415690 Feb 10 20:30 db_schema.bin
-rw-r--r-- 1 clickhouse clickhouse 754848 Feb 10 20:30 db_schema.mrk
-rw-r--r-- 1 clickhouse clickhouse 6985801 Feb 10 20:30 db_server.bin
-rw-r--r-- 1 clickhouse clickhouse 754848 Feb 10 20:30 db_server.mrk
-rw-r--r-- 1 clickhouse clickhouse 19020651 Feb 10 20:30 db_username.bin
-rw-r--r-- 1 clickhouse clickhouse 754848 Feb 10 20:30 db_username.mrk
-rw-r--r-- 1 clickhouse clickhouse 28227119 Feb 10 20:30 digest.bin
-rw-r--r-- 1 clickhouse clickhouse 754848 Feb 10 20:30 digest.mrk
-rw-r--r-- 1 clickhouse clickhouse 8 Feb 10 20:30 minmax_period_start.idx
-rw-r--r-- 1 clickhouse clickhouse 1552547644 Feb 10 20:30 nq_Float32.bin
-rw-r--r-- 1 clickhouse clickhouse 754848 Feb 10 20:30 nq_Float32.mrk
-rw-r--r-- 1 clickhouse clickhouse 1893758221 Feb 10 20:30 nq_Float64.bin
-rw-r--r-- 1 clickhouse clickhouse 754848 Feb 10 20:30 nq_Float64.mrk
-rw-r--r-- 1 clickhouse clickhouse 1552524811 Feb 10 20:30 nq_UInt32.bin
-rw-r--r-- 1 clickhouse clickhouse 754848 Feb 10 20:30 nq_UInt32.mrk
-rw-r--r-- 1 clickhouse clickhouse 1784991726 Feb 10 20:30 nq_UInt64.bin
-rw-r--r-- 1 clickhouse clickhouse 754848 Feb 10 20:30 nq_UInt64.mrk
-rw-r--r-- 1 clickhouse clickhouse 4 Feb 10 20:30 partition.dat
-rw-r--r-- 1 clickhouse clickhouse 400961033 Feb 10 20:30 period_start.bin
-rw-r--r-- 1 clickhouse clickhouse 754848 Feb 10 20:30 period_start.mrk
-rw-r--r-- 1 clickhouse clickhouse 2486243 Feb 10 20:30 primary.idx

We can see there are two files for every column (plus some extras), and so, for example, the Float32 based “number of queries” metric store takes around 1.5GB.

You can also use the SQL queries to get this data from the ClickHouse system tables instead:

SELECT *
FROM system.columns
WHERE (database = 'pmm') AND (table = 'test') AND (name = 'nq_UInt32')
Row 1:
??????
database: pmm
table: test
name: nq_UInt32
type: UInt32
default_kind:
default_expression:
data_compressed_bytes: 7250570
data_uncompressed_bytes: 1545913232
marks_bytes: 754848
comment:
is_in_partition_key: 0
is_in_sorting_key: 0
is_in_primary_key: 0
is_in_sampling_key: 0
compression_codec:
1 rows in set. Elapsed: 0.002 sec.
SELECT *
FROM system.parts
WHERE (database = 'pmm') AND (table = 'test')
Row 1:
??????
partition: 201902
name: 201902_1_372_4
active: 1
marks: 47178
rows: 386478308
bytes_on_disk: 1401028031
data_compressed_bytes: 1390993287
data_uncompressed_bytes: 29642900064
marks_bytes: 7548480
modification_time: 2019-02-10 23:26:20
remove_time: 0000-00-00 00:00:00
refcount: 1
min_date: 0000-00-00
max_date: 0000-00-00
min_time: 2019-02-08 14:50:32
max_time: 2019-02-08 15:58:30
partition_id: 201902
min_block_number: 1
max_block_number: 372
level: 4
data_version: 1
primary_key_bytes_in_memory: 4373363
primary_key_bytes_in_memory_allocated: 6291456
database: pmm
table: test
engine: MergeTree
path: /var/lib/clickhouse/data/pmm/test/201902_1_372_4/
1 rows in set. Elapsed: 0.003 sec.

Now let’s look at the queries

We tested with two queries.  One of them – we’ll call it Q1 – is a very trivial query, simply taking the sum across all column values. This query needs only to access one column to return results so it is likely to be the most impacted by a change of data type:

SELECT sum(nq_UInt32)
FROM test

The second query – which we’ll call Q2 – is a typical ranking query which computes the number of queries per period and then shows periods with the highest amount of queries in them:

SELECT
    sum(nq_UInt32) AS cnt,
    period_start
FROM test
GROUP BY period_start
ORDER BY cnt DESC
LIMIT 10

This query needs to access two columns and do more complicated processing so we expect it to be less impacted by the change of data type.

Before we get to results I think it is worth drawing attention to the raw performance we’re getting.  I did these tests on DigitalOcean Droplet with just six virtual CPU cores, yet still I see numbers like these:

SELECT sum(nq_UInt32)
FROM test
??sum(nq_UInt32) ???
?     386638984    ?
????????????????????
1 rows in set. Elapsed: 0.205 sec. Processed 386.48 million rows, 1.55 GB (1.88 billion rows/s., 7.52 GB/s.)

Processing more than 300M rows/sec per core and more than 1GB/sec per core is very cool!

Query Performance

Results between different compression levels show similar differences between column types, so let’s focus on those with the least compression:

As you can see, the width of the data type (32 bit vs 64 bit) matters a lot more than the type (float vs integer). In some cases float may even perform faster than integer. This was the most unexpected result for me.

Another metric ClickHouse reports is the processing speed in GB/sec. We see a different picture here:

64 bit data types have a higher processing speed than their 32 bit counter parts, but queries run slower as there is more raw data to process.

Compression

Let’s now take a closer look at compression.  For this test we use default LZ4 compression. ClickHouse has powerful support for Per Column Compression Codecs but testing them is outside of scope for this post.

So let’s look at size on disk for UInt32 Column:

What you can see from these results is that when data is very compressible ClickHouse can compress it to almost nothing.  The compression ratio for our very compressible data set is about 200x (or 99.5% size reduction if you prefer this metric).

Somewhat compressible data compression rate is 1.4x.  That’s not bad but considering we are only storing 1-1000 range in this column – which requires 10 bits out of 32 – I would hope for better compression. I guess LZ4 is not compressing such data very well.

Now let’s look at compression for a 64 bit integer column:

We can see that while the size almost doubled for very compressible data, increases for our somewhat compressible data and poorly compressible data are not that large.  Somewhat compressible data now compresses 2.5x.

Now let’s take a look at Performance depending on data compressibility:

Poorly compressible data which takes a larger space on disk is processed faster than somewhat compressible data? This did not make sense. I repeated the run a few times to make sure that the results were correct. When I looked at the compression ratio, though, it suddenly made sense to me.

Poorly compressible data for the UInt32 data type was not compressible by LZ4 so it seems the original data was stored, significantly speeding up “decompression” process.   With somewhat compressible data, compression worked and so real decompression needed to take place too. This makes things slower.

This is why we can only observe these results with UInt32 and Float32 data types.  UInt64 and Float64 show the more expected results:

Summary

Here are my conclusions:

• Even with “slower” data types, ClickHouse is very fast
• Data type choice matters – but less than I expected
• Width (32bit vs 64bit) impacts performance more than integer vs float data types
• Storing a small range of values in a wider column type is likely to yield better compression, though with default compression it is not as good as theoretically possible
• Compression is interesting. We get the best performance when data can be well compressed. Second best is when we do not have to spend a lot of time decompressing it, as long as it is fits in memory.