Archive for andrew

FOSDEM 2015 – SQL & NoSQL Presentation

Last weekend I got to present to the MySQL Developers Room at FOSDEM in Brussels.
FOSDEM-2015
The subject of my presentation was NoSQL and SQL the best of both worlds

There’s a lot of excitement around NoSQL Data Stores with the promise of simple access patterns, flexible schemas, scalability and High Availability. The downside comes in the form of losing ACID transactions, consistency, flexible queries and data integrity checks. What if you could have the best of both worlds? This session shows how MySQL Cluster provides simultaneous SQL and native NoSQL access to your data – whether a simple key-value API (Memcached), REST, JavaScript, Java or C++. You will hear how the MySQL Cluster architecture delivers in-memory real-time performance, 99.999% availability, on-line maintenance and linear, horizontal scalability through transparent auto-sharding.





MySQL Cluster 7.2.19 Released

MySQL Cluster Logo

The binary and source versions of MySQL Cluster 7.2.19 have now been made available at http://dev.mysql.com/downloads/cluster/7.2.html.

MySQL Cluster NDB 7.2.19 is a maintenance release of MySQL Cluster, incorporating fixes for bugs found in previous MySQL Cluster NDB 7.2 development releases.

MySQL Cluster NDB 7.2.19 source code and binaries can be obtained from here.

Review the MySQL Cluster 7.2.19 Release Notes for a description of the bug fixes included.





MySQL Cluster 7.4.3 RELEASE CANDIDATE now available

MySQL Cluster Logo

Oracle have just made availble the Release Candidate for MySQL Cluster 7.4 (MySQL Cluster 7.4.3) – it can be downloaded from the development release tab here. Note that this is not a GA release and so we wouldn’t recommend using it in production.

The delta between this RC and the 7.4.2 DMR can be viewed in the MySQL Cluster 7.4.3 Release Notes

There are three main focus areas for this RC and the purpose of this post is to briefly introduce them:

  • Active-Active (Multi-Master) Replication
  • Performance
  • Operational improvements (speeding up of restarts; enhanced memory reporting)

Active-Active (Multi-Master) Replication

MySQL Cluster allows bi-directional replication between two (or more) clusters. Replication within each cluster is synchronous but between clusters it is asynchronous which means the following scenario is possible:

Conflict with asynchronous replication
Site A Replication Site B
x == 10 x == 10
x = 11 x = 20
— x=11 –> x == 11
x==20 <– x=20 —

 

In this example a value (column for a row in a table) is set to 11 on site A and the change is queued for replication to site B. In the mean time, an application sets the value to 20 on site B and that change is queued for replication to site A. Once both sites have received and applied the replicated change from the other cluster site A contains the value 20 while site B contains 11 – in other words the databases are now inconsistent.

How MySQL Cluster implements eventual consistency

There are two phases to establishing consistency between both clusters after an inconsistency has been introduced:

  1. Detect that a conflict has happened
  2. Resolve the inconsistency

The following animation illustrates how MySQL Cluster 7.2 detects that an inconsistency has been introduced by the asynchronous, active-active replication:

Detecting conflicts

While we typically consider the 2 clusters in an active-active replication configuration to be peers, in this case we designate one to be the primary and the other the secondary. Reads and writes can still be sent to either cluster but it is the responsibility of the primary to identify that a conflict has arisen and then remove the inconsistency.

A logical clock is used to identify (in relative terms) when a change is made on the primary – for those who know something of the MySQL Cluster internals, we use the index of the Global Checkpoint that the update is contained in. For all tables that have this feature turned on, an extra, hidden column is automatically added on the primary – this represents the value of the logical clock when the change was made.

Once the change has been applied on the primary, there is a “window of conflict” for the effected row(s) during which if a different change is made to the same row(s) on the secondary then there will be an inconsistency. Once the slave on the secondary has applied the change from the primary, it will send a replication event back to the slave on the primary, containing the primary’s clock value associated with the changes that have just been applied on the secondary. (Remember that the clock is actually the Global Checkpoint Index and so this feature is sometimes referred to as Reflected GCI). Once the slave on the primary has received this event, it knows that all changes tagged with a clock value no later than the reflected GCI are now safe – the window of conflict has closed.

If an application modifies this same row on the secondary before the replication event from the primary was applied then it will send an associated replication event to the slave on the primary before it reflects the new GCI. The slave on the primary will process this replication event and compare the clock value recorded with the effected rows with the latest reflected GCI; as the clock value for the conflicting row is higher the primary recognises that a conflict has occured and will launch the algorithm to resolve the inconsistency.

Options for MySQL Cluster replication conflict detection/resolution

After a conflict has been detected, you have the option of having the database simply report the conflict to the application or have it roll back just the conflicting row or the entire transaction and all subsequent transactions that were dependent on it.

So – what’s new in 7.4?

  • Detects conflicts between inserts and updates
  • Option to roll back entire transaction (and dependent transactions) rather than just the conflicting row
  • All conflicts are handled before switching primary – avoiding potential race conditions

Performance

MySQL CLuster Read-Write Performance
Being a scaled-out, in-memory, real-time database, MySQL Cluster performance has always been great but we continue to work on making it faster each release. In particular, we want to keep pace with the trend of having more and more cores rather than faster ones. 7.4 continues along the path of better exploiting multiple cores – as can be seen from these benchmark results.
MySQL CLuster 7.4 Read Performance
Just make sure that you’re using the multi-threaded data node (ndbmtd rather than ndbd) and have configured how many threads it should use.

Faster Restarts

You can restart MySQL Cluster processes (nodes) without losing database service (for example if adding extra memory to a server) and so on the face of it, the speed of the restarts isn’t that important. Having said that, while the node is restarting you’ve lost some of your high-availability which for super-critical applications can make you nervous. Additionally, faster restarts mean that you can complete maintenance activities faster – for example, a software upgrade requires a rolling restart of all of the nodes – if you have 48 data nodes then you want each of the data nodes to restart as quickly as possible.

MySQL 7.4 includes a number of optimisations to the restart code and so if you’re already using MySQL Cluster, it might be interesting to see how much faster it gets for your application. We also have some extra optimisations in the works that you can expect to see in later 7.4 versions.

Extra Memory Reporting

MySQL Cluster presents a lot of monitoring information through the ndbinfo database and in 7.4 we’ve added some extra information on how memory is used for individual tables.

For example; to see how much memory is being used by each data node for a particular table…

mysql> CREATE DATABASE clusterdb;USE clusterdb;
mysql> CREATE TABLE simples (id INT NOT NULL AUTO_INCREMENT PRIMARY KEY) ENGINE=NDB;
mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |      131072 |       5504 |        172 |
|    1 |    2 |      131072 |       1280 |         40 |
|    2 |    0 |      131072 |       5504 |        172 |
|    2 |    2 |      131072 |       1280 |         40 |
|    3 |    1 |      131072 |       3104 |         97 |
|    3 |    3 |      131072 |       4256 |        133 |
|    4 |    1 |      131072 |       3104 |         97 |
|    4 |    3 |      131072 |       4256 |        133 |
+------+------+-------------+------------+------------+

When you delete rows from a MySQL Cluster table, the memory is not actually freed up and so if you check the existing memoryusage table you won’t see a change. This memory will be reused when you add new rows to that same table. In MySQL Cluster 7.4, it’s possible to see how much memory is in that state for a table…

mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |      131072 |       5504 |        172 |
|    1 |    2 |      131072 |       1280 |         40 |
|    2 |    0 |      131072 |       5504 |        172 |
|    2 |    2 |      131072 |       1280 |         40 |
|    3 |    1 |      131072 |       3104 |         97 |
|    3 |    3 |      131072 |       4256 |        133 |
|    4 |    1 |      131072 |       3104 |         97 |
|    4 |    3 |      131072 |       4256 |        133 |
+------+------+-------------+------------+------------+
mysql> DELETE FROM clusterdb.simples LIMIT 1;
mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |      131072 |       5504 |        172 |
|    1 |    2 |      131072 |       1312 |         41 |
|    2 |    0 |      131072 |       5504 |        172 |
|    2 |    2 |      131072 |       1312 |         41 |
|    3 |    1 |      131072 |       3104 |         97 |
|    3 |    3 |      131072 |       4288 |        134 |
|    4 |    1 |      131072 |       3104 |         97 |
|    4 |    3 |      131072 |       4288 |        134 |
+------+------+-------------+------------+------------+

As a final example, we can check whether a table is being evenly sharded accross the data nodes (in this case a realy bad sharding key was chosen)…

mysql> CREATE TABLE simples (id INT NOT NULL AUTO_INCREMENT, \
        species VARCHAR(20) DEFAULT "Human", 
        PRIMARY KEY(id, species)) engine=ndb PARTITION BY KEY(species);

// Add some data

mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |           0 |          0 |          0 |
|    1 |    2 |      196608 |      11732 |        419 |
|    2 |    0 |           0 |          0 |          0 |
|    2 |    2 |      196608 |      11732 |        419 |
|    3 |    1 |           0 |          0 |          0 |
|    3 |    3 |           0 |          0 |          0 |
|    4 |    1 |           0 |          0 |          0 |
|    4 |    3 |           0 |          0 |          0 |
+------+------+-------------+------------+------------+

If you get chance to try out this new release then please let us know how you get on – either through a comment on this blog, a MySQL bug report or a post to the MySQL Cluster Forum.





MySQL Cluster 7.3.8 Released

MySQL Cluster Logo

The binary and source versions of MySQL Cluster 7.3.8 have now been made available at http://www.mysql.com/downloads/cluster/.

Release notes

MySQL Cluster NDB 7.3.8 is a new release of MySQL Cluster, based on MySQL Server 5.6 and including features from version 7.3 of the NDB storage engine, as well as fixing a number of recently discovered bugs in previous MySQL Cluster releases. Obtaining MySQL Cluster NDB 7.3. MySQL Cluster NDB 7.3 source code and binaries can be obtained from
http://dev.mysql.com/downloads/cluster/.

For an overview of changes made in MySQL Cluster NDB 7.3, see MySQL Cluster Development in MySQL Cluster NDB 7.3 (
http://dev.mysql.com/doc/refman/5.6/en/mysql-cluster-development-5-6-ndb-7-3.html).

This release also incorporates all bugfixes and changes made in previous MySQL Cluster releases, as well as all bugfixes and feature changes which were added in mainline MySQL 5.6 through MySQL 5.6.22 (see Changes in MySQL 5.6.22). A full description of feature changes and bug fixes in can be found in the MySQL Cluster 7.3.8 release notes; for convenience, the feature changes (but not bug fixes) are listed here.

Functionality Added or Changed

 

  • Performance: Recent improvements made to the multithreaded scheduler were intended to optimize the cache behavior of its internal data structures, with members of these structures placed such that those local to a given thread do not overflow into a cache line which can be accessed by another thread. Where required, extra padding bytes are inserted to isolate cache lines owned (or shared) by other threads, thus avoiding invalidation of the entire cache line if another thread writes into a cache line not entirely owned by itself. This optimization improved MT Scheduler performance by several percent.It has since been found that the optimization just described depends on the global instance of struct thr_repository starting at a cache line aligned base address as well as the compiler not rearranging or adding extra padding to the scheduler struct; it was also found that these prerequisites were not guaranteed (or even checked). Thus this cache line optimization has previously worked only when g_thr_repository (that is, the global instance) ended up being cache line aligned only by accident. In addition, on 64-bit platforms, the compiler added extra padding words in struct thr_safe_pool such that attempts to pad it to a cache line aligned size failed.

    The current fix ensures that g_thr_repository is constructed on a cache line aligned address, and the constructors modified so as to verify cacheline aligned adresses where these are assumed by design.

    Results from internal testing show improvements in MT Scheduler read performance of up to 10% in some cases, following these changes. (Bug #18352514)

  • Cluster API: Two new example programs, demonstrating reads and writes of CHAR, VARCHAR, and VARBINARY column values, have been added to storage/ndb/ndbapi-examples in the MySQL Cluster source tree. For more information about these programs, including source code listings, see NDB API Simple Array Example, and NDB API Simple Array Example Using Adapter.




MySQL Replication: What’s New in MySQL 5.7 and Beyond – webinar replay

MySQL Replication LogoLuís Soares and I recently hosted a webinar which explained the latest developments in MySQL Replication.

The webinar replay is now available to download from here.

Details:

Continuing in the footsteps of its predecessor, MySQL 5.7 is set to be a groundbreaking release. In this webinar, the engineers behind the product provide insights into what’s new for MySQL replication in the latest 5.7 Development Milestone Release and review the early access features available via labs.mysql.com. The next generation of replication features cover several technical areas such as better semi-synchronous replication, an enhanced multithreaded slave (per-transaction parallelism), improved monitoring with performance schema tables, online configuration changes, options for fine-tuning replication performance, support for more-advanced topologies with multisource replication, and much more. This is also a great chance to learn about MySQL Group Replication – the next generation of active-active, update-anywhere replication for MySQL.

Seize the opportunity to learn how you will be able to leverage MySQL 5.7 replication to grow your business.





Upcoming Webinar – MySQL Replication: What’s New in MySQL 5.7 and Beyond

MySQL Replication LogoOn Tuesday 25th November, Luís Soares and I will be hosting a webinar which explains the latest developments in MySQL Replication. As always the webinar is free but please register here.

Details:

Continuing in the footsteps of its predecessor, MySQL 5.7 is set to be a groundbreaking release. In this webinar, the engineers behind the product provide insights into what’s new for MySQL replication in the latest 5.7 Development Milestone Release and review the early access features available via labs.mysql.com. The next generation of replication features cover several technical areas such as better semi-synchronous replication, an enhanced multithreaded slave (per-transaction parallelism), improved monitoring with performance schema tables, online configuration changes, options for fine-tuning replication performance, support for more-advanced topologies with multisource replication, and much more. This is also a great chance to learn about MySQL Group Replication – the next generation of active-active, update-anywhere replication for MySQL.

Seize the opportunity to learn how you will be able to leverage MySQL 5.7 replication to grow your business.

When:

  • Tue, Nov 25: 09:00 Pacific time (America)
  • Tue, Nov 25: 10:00 Mountain time (America)
  • Tue, Nov 25: 11:00 Central time (America)
  • Tue, Nov 25: 12:00 Eastern time (America)
  • Tue, Nov 25: 15:00 São Paulo time
  • Tue, Nov 25: 17:00 UTC
  • Tue, Nov 25: 17:00 Western European time
  • Tue, Nov 25: 18:00 Central European time
  • Tue, Nov 25: 19:00 Eastern European time
  • Tue, Nov 25: 22:30 India, Sri Lanka
  • Wed, Nov 26: 01:00 Singapore/Malaysia/Philippines time
  • Wed, Nov 26: 01:00 China time
  • Wed, Nov 26: 02:00 日本
  • Wed, Nov 26: 04:00 NSW, ACT, Victoria, Tasmania (Australia)

Even if you can’t join the live webinar, it’s worth registering as you’ll be emailed a link to the replay as soon as it’s available.





Active-Active Replication, Performance Improvements & Operational Enhancements – some of what’s available in the new MySQL Cluster 7.4.2 DMR

MySQL Cluster Logo

Oracle have just made availble the new MySQL Cluster 7.4.2 Development Milestone Release – it can be downloaded from the development release tab here. Note that this is not a GA release and so we wouldn’t recommend using it in production.

This is the second DMR for MySQL 7.4; the delta between this DMR and 7.4.1 can be viewed in the MySQL Cluster 7.4.2 Release Notes

There are three main focus areas for this DMR and the purpose of this post is to briefly introduce them:

  • Active-Active (Multi-Master) Replication
  • Performance
  • Operational improvements (speeding up of restarts; enhanced memory reporting)

Active-Active (Multi-Master) Replication

MySQL Cluster allows bi-directional replication between two (or more) clusters. Replication within each cluster is synchronous but between clusters it is asynchronous which means the following scenario is possible:

Conflict with asynchronous replication
Site A Replication Site B
x == 10 x == 10
x = 11 x = 20
— x=11 –> x == 11
x==20 <– x=20 —

 

In this example a value (column for a row in a table) is set to 11 on site A and the change is queued for replication to site B. In the mean time, an application sets the value to 20 on site B and that change is queued for replication to site A. Once both sites have received and applied the replicated change from the other cluster site A contains the value 20 while site B contains 11 – in other words the databases are now inconsistent.

How MySQL Cluster implements eventual consistency

There are two phases to establishing consistency between both clusters after an inconsistency has been introduced:

  1. Detect that a conflict has happened
  2. Resolve the inconsistency

The following animation illustrates how MySQL Cluster 7.2 detects that an inconsistency has been introduced by the asynchronous, active-active replication:

Detecting conflicts

While we typically consider the 2 clusters in an active-active replication configuration to be peers, in this case we designate one to be the primary and the other the secondary. Reads and writes can still be sent to either cluster but it is the responsibility of the primary to identify that a conflict has arisen and then remove the inconsistency.

A logical clock is used to identify (in relative terms) when a change is made on the primary – for those who know something of the MySQL Cluster internals, we use the index of the Global Checkpoint that the update is contained in. For all tables that have this feature turned on, an extra, hidden column is automatically added on the primary – this represents the value of the logical clock when the change was made.

Once the change has been applied on the primary, there is a “window of conflict” for the effected row(s) during which if a different change is made to the same row(s) on the secondary then there will be an inconsistency. Once the slave on the secondary has applied the change from the primary, it will send a replication event back to the slave on the primary, containing the primary’s clock value associated with the changes that have just been applied on the secondary. (Remember that the clock is actually the Global Checkpoint Index and so this feature is sometimes referred to as Reflected GCI). Once the slave on the primary has received this event, it knows that all changes tagged with a clock value no later than the reflected GCI are now safe – the window of conflict has closed.

If an application modifies this same row on the secondary before the replication event from the primary was applied then it will send an associated replication event to the slave on the primary before it reflects the new GCI. The slave on the primary will process this replication event and compare the clock value recorded with the effected rows with the latest reflected GCI; as the clock value for the conflicting row is higher the primary recognises that a conflict has occured and will launch the algorithm to resolve the inconsistency.

Options for MySQL Cluster replication conflict detection/resolution

After a conflict has been detected, you have the option of having the database simply report the conflict to the application or have it roll back just the conflicting row or the entire transaction and all subsequent transactions that were dependent on it.

So – what’s new in 7.4.1?

  • Detects conflicts between inserts and updates
  • Option to roll back entire transaction (and dependent transactions) rather than just the conflicting row
  • All conflicts are handled before switching primary – avoiding potential race conditions

As mentioned at the start of this post, this is pre-GA and there are some extra enhancements we plan on including in the final version:

  • Handle deletes which conflict with other operations
  • Roll back transactions that have read a row that had been rolled back due to a conflict

Performance

MySQL CLuster 7.4.1 Read-Write Performance
Being a scaled-out, in-memory, real-time database, MySQL Cluster performance has always been great but we continue to work on making it faster each release. In particular, we want to keep pace with the trend of having more and more cores rather than faster ones. 7.4 continues along the path of better exploiting multiple cores – as can be seen from these benchmark results.
MySQL CLuster 7.4.1 Read Performance
Just make sure that you’re using the multi-threaded data node (ndbmtd rather than ndbd) and have configured how many threads it should use.

Faster Restarts

You can restart MySQL Cluster processes (nodes) without losing database service (for example if adding extra memory to a server) and so on the face of it, the speed of the restarts isn’t that important. Having said that, while the node is restarting you’ve lost some of your high-availability which for super-critical applications can make you nervous. Additionally, faster restarts mean that you can complete maintenance activities faster – for example, a software upgrade requires a rolling restart of all of the nodes – if you have 48 data nodes then you want each of the data nodes to restart as quickly as possible.

MySQL 7.4.1 includes a number of optimisations to the restart code and so if you’re already using MySQL Cluster, it might be interesting to see how much faster it gets for your application. We also have some extra optimisations in the works that you can expect to see in later 7.4 versions.

Extra Memory Reporting

MySQL Cluster presents a lot of monitoring information through the ndbinfo database and in 7.4 we’ve added some extra information on how memory is used for individual tables.

For example; to see how much memory is being used by each data node for a particular table…

mysql> CREATE DATABASE clusterdb;USE clusterdb;
mysql> CREATE TABLE simples (id INT NOT NULL AUTO_INCREMENT PRIMARY KEY) ENGINE=NDB;
mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |      131072 |       5504 |        172 |
|    1 |    2 |      131072 |       1280 |         40 |
|    2 |    0 |      131072 |       5504 |        172 |
|    2 |    2 |      131072 |       1280 |         40 |
|    3 |    1 |      131072 |       3104 |         97 |
|    3 |    3 |      131072 |       4256 |        133 |
|    4 |    1 |      131072 |       3104 |         97 |
|    4 |    3 |      131072 |       4256 |        133 |
+------+------+-------------+------------+------------+

When you delete rows from a MySQL Cluster table, the memory is not actually freed up and so if you check the existing memoryusage table you won’t see a change. This memory will be reused when you add new rows to that same table. In MySQL Cluster 7.4, it’s possible to see how much memory is in that state for a table…

mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |      131072 |       5504 |        172 |
|    1 |    2 |      131072 |       1280 |         40 |
|    2 |    0 |      131072 |       5504 |        172 |
|    2 |    2 |      131072 |       1280 |         40 |
|    3 |    1 |      131072 |       3104 |         97 |
|    3 |    3 |      131072 |       4256 |        133 |
|    4 |    1 |      131072 |       3104 |         97 |
|    4 |    3 |      131072 |       4256 |        133 |
+------+------+-------------+------------+------------+
mysql> DELETE FROM clusterdb.simples LIMIT 1;
mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |      131072 |       5504 |        172 |
|    1 |    2 |      131072 |       1312 |         41 |
|    2 |    0 |      131072 |       5504 |        172 |
|    2 |    2 |      131072 |       1312 |         41 |
|    3 |    1 |      131072 |       3104 |         97 |
|    3 |    3 |      131072 |       4288 |        134 |
|    4 |    1 |      131072 |       3104 |         97 |
|    4 |    3 |      131072 |       4288 |        134 |
+------+------+-------------+------------+------------+

As a final example, we can check whether a table is being evenly sharded accross the data nodes (in this case a realy bad sharding key was chosen)…

mysql> CREATE TABLE simples (id INT NOT NULL AUTO_INCREMENT, \
        species VARCHAR(20) DEFAULT "Human", 
        PRIMARY KEY(id, species)) engine=ndb PARTITION BY KEY(species);

// Add some data

mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |           0 |          0 |          0 |
|    1 |    2 |      196608 |      11732 |        419 |
|    2 |    0 |           0 |          0 |          0 |
|    2 |    2 |      196608 |      11732 |        419 |
|    3 |    1 |           0 |          0 |          0 |
|    3 |    3 |           0 |          0 |          0 |
|    4 |    1 |           0 |          0 |          0 |
|    4 |    3 |           0 |          0 |          0 |
+------+------+-------------+------------+------------+

If you get chance to try out this new release then please let us know how you get on – either through a comment on this blog, a MySQL bug report or a post to the MySQL Cluster Forum.





SQL/NoSQL and MySQL Cluster 7.4 Presentations now available

My 2 sessions from 2014’s MySQL Central at Oracle OpenWorld are now available:

NoSQL and SQL: The Best of Both Worlds [CON2853]

There’s a lot of excitement about NoSQL data stores, with the promise of simple access patterns, flexible schemas, scalability, and high availability. The downside comes in the form of losing ACID transactions, consistency, flexible queries, and data integrity checks. What if you could have the best of both worlds? This session shows how MySQL Cluster provides simultaneous SQL and native NoSQL access to your data—whether it’s in a simple key-value API (memcached) or REST, JavaScript, Java, or C++. You will hear how the MySQL Cluster architecture delivers in-memory real-time performance; 99.999 percent availability; online maintenance; and linear, horizontal scalability through transparent autosharding.

MySQL Cluster: Dive into the Latest Developments [CON3815]

Wednesday, Oct 1, 3:30 PM – 4:15 PM – Moscone South – 250

I’ll be co-presenting this session with Bernd Ocklin – Director MySQL Cluster, Oracle

MySQL Cluster does more than scale beyond a billion transactions per minute. It’s also the in-memory database at the heart of mobile phone networks and online games. Scaling for the masses. A touch of your mobile phone’s green button likely has already gotten you in contact with MySQL Cluster. Driven by these extreme use cases, this session covers how to build business-critical scalable solutions with MySQL Cluster.





My NoSQL/SQL and MySQL Cluster sessions at Oracle OpenWorld

I have 2 sessions at Oracle OpenWorld in San Francisco this Thursday (2nd October 2014); please come along if your in town and feel free to grab me after the sessions for any extra questions:

NoSQL and SQL: The Best of Both Worlds [CON2853]

Thursday, Oct 2, 9:30 AM – 10:15 AM – Moscone South – 252

There’s a lot of excitement about NoSQL data stores, with the promise of simple access patterns, flexible schemas, scalability, and high availability. The downside comes in the form of losing ACID transactions, consistency, flexible queries, and data integrity checks. What if you could have the best of both worlds? This session shows how MySQL Cluster provides simultaneous SQL and native NoSQL access to your data—whether it’s in a simple key-value API (memcached) or REST, JavaScript, Java, or C++. You will hear how the MySQL Cluster architecture delivers in-memory real-time performance; 99.999 percent availability; online maintenance; and linear, horizontal scalability through transparent autosharding.

MySQL Cluster: Dive into the Latest Developments [CON3815]

Wednesday, Oct 1, 3:30 PM – 4:15 PM – Moscone South – 250

I’ll be co-presenting this session with Bernd Ocklin – Director MySQL Cluster, Oracle

MySQL Cluster does more than scale beyond a billion transactions per minute. It’s also the in-memory database at the heart of mobile phone networks and online games. Scaling for the masses. A touch of your mobile phone’s green button likely has already gotten you in contact with MySQL Cluster. Driven by these extreme use cases, this session covers how to build business-critical scalable solutions with MySQL Cluster.





Active-Active Replication, Performance Improvements & Operational Enhancements – some of what’s available in the new MySQL Cluster 7.4.1 DMR

MySQL Cluster Logo

Oracle have just made availble the new MySQL Cluster 7.4.1 Development Milestone Release – it can be downloaded from the development release tab here. Note that this is not a GA release and so we wouldn’t recommend using it in production.

There are three main focus areas for this DMR and the purpose of this post is to briefly introduce them:

  • Active-Active (Multi-Master) Replication
  • Performance
  • Operational improvements (speeding up of restarts; enhanced memory reporting)

Active-Active (Multi-Master) Replication

MySQL Cluster allows bi-directional replication between two (or more) clusters. Replication within each cluster is synchronous but between clusters it is asynchronous which means the following scenario is possible:

Conflict with asynchronous replication
Site A Replication Site B
x == 10 x == 10
x = 11 x = 20
— x=11 –> x == 11
x==20 <– x=20 —

 

In this example a value (column for a row in a table) is set to 11 on site A and the change is queued for replication to site B. In the mean time, an application sets the value to 20 on site B and that change is queued for replication to site A. Once both sites have received and applied the replicated change from the other cluster site A contains the value 20 while site B contains 11 – in other words the databases are now inconsistent.

How MySQL Cluster implements eventual consistency

There are two phases to establishing consistency between both clusters after an inconsistency has been introduced:

  1. Detect that a conflict has happened
  2. Resolve the inconsistency

The following animation illustrates how MySQL Cluster 7.2 detects that an inconsistency has been introduced by the asynchronous, active-active replication:

Detecting conflicts

While we typically consider the 2 clusters in an active-active replication configuration to be peers, in this case we designate one to be the primary and the other the secondary. Reads and writes can still be sent to either cluster but it is the responsibility of the primary to identify that a conflict has arisen and then remove the inconsistency.

A logical clock is used to identify (in relative terms) when a change is made on the primary – for those who know something of the MySQL Cluster internals, we use the index of the Global Checkpoint that the update is contained in. For all tables that have this feature turned on, an extra, hidden column is automatically added on the primary – this represents the value of the logical clock when the change was made.

Once the change has been applied on the primary, there is a “window of conflict” for the effected row(s) during which if a different change is made to the same row(s) on the secondary then there will be an inconsistency. Once the slave on the secondary has applied the change from the primary, it will send a replication event back to the slave on the primary, containing the primary’s clock value associated with the changes that have just been applied on the secondary. (Remember that the clock is actually the Global Checkpoint Index and so this feature is sometimes referred to as Reflected GCI). Once the slave on the primary has received this event, it knows that all changes tagged with a clock value no later than the reflected GCI are now safe – the window of conflict has closed.

If an application modifies this same row on the secondary before the replication event from the primary was applied then it will send an associated replication event to the slave on the primary before it reflects the new GCI. The slave on the primary will process this replication event and compare the clock value recorded with the effected rows with the latest reflected GCI; as the clock value for the conflicting row is higher the primary recognises that a conflict has occured and will launch the algorithm to resolve the inconsistency.

Options for MySQL Cluster replication conflict detection/resolution

After a conflict has been detected, you have the option of having the database simply report the conflict to the application or have it roll back just the conflicting row or the entire transaction and all subsequent transactions that were dependent on it.

So – what’s new in 7.4.1?

  • Detects conflicts between inserts and updates
  • Option to roll back entire transaction (and dependent transactions) rather than just the conflicting row
  • All conflicts are handled before switching primary – avoiding potential race conditions

As mentioned at the start of this post, this is pre-GA and there are some extra enhancements we plan on including in the final version:

  • Handle deletes which conflict with other operations
  • Roll back transactions that have read a row that had been rolled back due to a conflict

Performance

MySQL CLuster 7.4.1 Read-Write Performance
Being a scaled-out, in-memory, real-time database, MySQL Cluster performance has always been great but we continue to work on making it faster each release. In particular, we want to keep pace with the trend of having more and more cores rather than faster ones. 7.4 continues along the path of better exploiting multiple cores – as can be seen from these benchmark results.
MySQL CLuster 7.4.1 Read Performance
Just make sure that you’re using the multi-threaded data node (ndbmtd rather than ndbd) and have configured how many threads it should use.

Faster Restarts

You can restart MySQL Cluster processes (nodes) without losing database service (for example if adding extra memory to a server) and so on the face of it, the speed of the restarts isn’t that important. Having said that, while the node is restarting you’ve lost some of your high-availability which for super-critical applications can make you nervous. Additionally, faster restarts mean that you can complete maintenance activities faster – for example, a software upgrade requires a rolling restart of all of the nodes – if you have 48 data nodes then you want each of the data nodes to restart as quickly as possible.

MySQL 7.4.1 includes a number of optimisations to the restart code and so if you’re already using MySQL Cluster, it might be interesting to see how much faster it gets for your application. We also have some extra optimisations in the works that you can expect to see in later 7.4 versions.

Extra Memory Reporting

MySQL Cluster presents a lot of monitoring information through the ndbinfo database and in 7.4 we’ve added some extra information on how memory is used for individual tables.

For example; to see how much memory is being used by each data node for a particular table…

mysql> CREATE DATABASE clusterdb;USE clusterdb;
mysql> CREATE TABLE simples (id INT NOT NULL AUTO_INCREMENT PRIMARY KEY) ENGINE=NDB;
mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |      131072 |       5504 |        172 |
|    1 |    2 |      131072 |       1280 |         40 |
|    2 |    0 |      131072 |       5504 |        172 |
|    2 |    2 |      131072 |       1280 |         40 |
|    3 |    1 |      131072 |       3104 |         97 |
|    3 |    3 |      131072 |       4256 |        133 |
|    4 |    1 |      131072 |       3104 |         97 |
|    4 |    3 |      131072 |       4256 |        133 |
+------+------+-------------+------------+------------+

When you delete rows from a MySQL Cluster table, the memory is not actually freed up and so if you check the existing memoryusage table you won’t see a change. This memory will be reused when you add new rows to that same table. In MySQL Cluster 7.4, it’s possible to see how much memory is in that state for a table…

mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |      131072 |       5504 |        172 |
|    1 |    2 |      131072 |       1280 |         40 |
|    2 |    0 |      131072 |       5504 |        172 |
|    2 |    2 |      131072 |       1280 |         40 |
|    3 |    1 |      131072 |       3104 |         97 |
|    3 |    3 |      131072 |       4256 |        133 |
|    4 |    1 |      131072 |       3104 |         97 |
|    4 |    3 |      131072 |       4256 |        133 |
+------+------+-------------+------------+------------+
mysql> DELETE FROM clusterdb.simples LIMIT 1;
mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |      131072 |       5504 |        172 |
|    1 |    2 |      131072 |       1312 |         41 |
|    2 |    0 |      131072 |       5504 |        172 |
|    2 |    2 |      131072 |       1312 |         41 |
|    3 |    1 |      131072 |       3104 |         97 |
|    3 |    3 |      131072 |       4288 |        134 |
|    4 |    1 |      131072 |       3104 |         97 |
|    4 |    3 |      131072 |       4288 |        134 |
+------+------+-------------+------------+------------+

As a final example, we can check whether a table is being evenly sharded accross the data nodes (in this case a realy bad sharding key was chosen)…

mysql> CREATE TABLE simples (id INT NOT NULL AUTO_INCREMENT, \
        species VARCHAR(20) DEFAULT "Human", 
        PRIMARY KEY(id, species)) engine=ndb PARTITION BY KEY(species);

// Add some data

mysql> SELECT node_id AS node, fragment_num AS frag, \
        fixed_elem_alloc_bytes alloc_bytes, \
        fixed_elem_free_bytes AS free_bytes, \
        fixed_elem_free_rows AS spare_rows \
        FROM ndbinfo.memory_per_fragment \
        WHERE fq_name LIKE '%simples%';
+------+------+-------------+------------+------------+
| node | frag | alloc_bytes | free_bytes | spare_rows |
+------+------+-------------+------------+------------+
|    1 |    0 |           0 |          0 |          0 |
|    1 |    2 |      196608 |      11732 |        419 |
|    2 |    0 |           0 |          0 |          0 |
|    2 |    2 |      196608 |      11732 |        419 |
|    3 |    1 |           0 |          0 |          0 |
|    3 |    3 |           0 |          0 |          0 |
|    4 |    1 |           0 |          0 |          0 |
|    4 |    3 |           0 |          0 |          0 |
+------+------+-------------+------------+------------+

If you get chance to try out this new release then please let us know how you get on – either through a comment on this blog, a MySQL bug report or a post to the MySQL Cluster Forum.