- 本月热门
-
2015年创业者调查报告(State of Startups) by FirstRound -
JavaScript闭包你也懂 -
MongoDB Best Practices(最佳实践) by Jay Runkel -
Scaling & securing node.js apps(扩展和加强NodeJS应用的安全性) by Maciej Lasyk -
ASP.NET5快速入門[繁] by 小朱 -
Lua 在 Nginx 中的应用 by 章亦春@淘宝 -
基于Node.JS的全栈开发 by 张雪峰@携程 -
去哪儿SPA(面向服务)分享 by 蔡欢@Qunar -
指数级增长业务下的服务架构改造 by 梁宇鹏@环信 -
How Change Happens(如何拥抱变化,鼓励创新) by Openlab
加收藏
MySQL Parallel Replication inventory, use-cases and limitations(MySQL并行复制:存储、用例和限制) by Jean-François Gagné
第1页
MySQL Parallel Replication: inventory, use-cases and limitations
Jean-François Gagné (System Engineer) jeanfrancois DOT gagne AT booking.com
Presented at FOSDEM 2016
Jean-François Gagné (System Engineer) jeanfrancois DOT gagne AT booking.com
Presented at FOSDEM 2016
第2页
2
第3页
Booking.com
● Based in Amsterdam since 1996 ● Online Hotel and Accommodation Agent:
● +855.000 properties in 221 countries ● 42 languages (website and customer service) ● +21.000.000 bookable rooms
● Part of the Priceline Group
● And we use MySQL:
● Thousands (1000s) of servers, ~85% replicating ● >130 masters: ~25 >50 slaves & ~8 >100 slaves
● Based in Amsterdam since 1996 ● Online Hotel and Accommodation Agent:
● +855.000 properties in 221 countries ● 42 languages (website and customer service) ● +21.000.000 bookable rooms
● Part of the Priceline Group
● And we use MySQL:
● Thousands (1000s) of servers, ~85% replicating ● >130 masters: ~25 >50 slaves & ~8 >100 slaves
第4页
Session Summary
1. Replication Reminders 2. Introducing Parallel Replication 3. MySQL 5.6: schema based
MariaDB 10.0: out-of-order and in-order MariaDB 10.1: +optimistic MySQL 5.7: +logical clock 4. Benchmark Results from Booking.com
1. Replication Reminders 2. Introducing Parallel Replication 3. MySQL 5.6: schema based
MariaDB 10.0: out-of-order and in-order MariaDB 10.1: +optimistic MySQL 5.7: +logical clock 4. Benchmark Results from Booking.com
第5页
Replication: Reminders
● Replication: one master / one or more slaves
● The master records all writes in a journal: the binary logs ● Each slave:
● Downloads the journal and saves it locally (IO thread): relay logs ● Executes the relay logs on the local database: SQL thread(s) ● Could produce binary logs to be itself a master (log-slave-updates)
● Replication is:
● Asynchronous lag ● Was single-threaded slower than the master
(before MySQL 5.6 and MariaDB 10.0) ● Was single-master (before MySQL 5.7 and MariaDB 10.0)
● Replication: one master / one or more slaves
● The master records all writes in a journal: the binary logs ● Each slave:
● Downloads the journal and saves it locally (IO thread): relay logs ● Executes the relay logs on the local database: SQL thread(s) ● Could produce binary logs to be itself a master (log-slave-updates)
● Replication is:
● Asynchronous lag ● Was single-threaded slower than the master
(before MySQL 5.6 and MariaDB 10.0) ● Was single-master (before MySQL 5.7 and MariaDB 10.0)
第6页
// Replication
● Relatively new, because it is hard
● Why is it hard ?
● Data consistency
● Why is it important ?
● Computers have many Cores, using a single one for writes is a waste ● Some computer resources can give more throughput when used in
parallel (example: RAID1 has 2 disks we can do 2 IOs in parallel)
● Relatively new, because it is hard
● Why is it hard ?
● Data consistency
● Why is it important ?
● Computers have many Cores, using a single one for writes is a waste ● Some computer resources can give more throughput when used in
parallel (example: RAID1 has 2 disks we can do 2 IOs in parallel)
第7页
// Replication: History
● Before MySQL 5.6 and MariaDB 10.0, replication is single-threaded (Tungsten had support for parallel replication earlier)
● MySQL 5.6 has support for schema based parallel replication ● MariaDB 10.0 has support for domain id based parallel replication
and also has support for group commit based parallel replication ● MariaDB 10.1 adds support for optimistic parallel replication ● MySQL 5.7 adds support for logical clock parallel replication
● In early version, the logical clock is group commit based ● In current version, the logical clock is interval based
● Before MySQL 5.6 and MariaDB 10.0, replication is single-threaded (Tungsten had support for parallel replication earlier)
● MySQL 5.6 has support for schema based parallel replication ● MariaDB 10.0 has support for domain id based parallel replication
and also has support for group commit based parallel replication ● MariaDB 10.1 adds support for optimistic parallel replication ● MySQL 5.7 adds support for logical clock parallel replication
● In early version, the logical clock is group commit based ● In current version, the logical clock is interval based
第8页
// Replication: MySQL 5.6
● Concept: if transactions are “schema-local”, two transactions in different schema can be run in parallel on slaves
● Implementation:
● the master tags transactions with their schema in the binary logs ● the SQL thread dispatches work to worker threads
● Deployment:
● On the master: nothing to do (except having multiple independent schemas) ● On the slave: “SET GLOBAL slave_parallel_workers > 0;”
● MySQL 5.7 has the same feature:
● (default for slave-parallel-type = DATABASE)
● MySQL 5.8 defaults might be different:
● Need to “SET GLOBAL slave-parallel-type = DATABASE;” http://mysqlhighavailability.com/mysql-replication-defaults-after-5-7/
● Concept: if transactions are “schema-local”, two transactions in different schema can be run in parallel on slaves
● Implementation:
● the master tags transactions with their schema in the binary logs ● the SQL thread dispatches work to worker threads
● Deployment:
● On the master: nothing to do (except having multiple independent schemas) ● On the slave: “SET GLOBAL slave_parallel_workers > 0;”
● MySQL 5.7 has the same feature:
● (default for slave-parallel-type = DATABASE)
● MySQL 5.8 defaults might be different:
● Need to “SET GLOBAL slave-parallel-type = DATABASE;” http://mysqlhighavailability.com/mysql-replication-defaults-after-5-7/
第9页
// Replication: MySQL 5.6’
● Implication: transactions on slaves can be committed in a different order than the one they appear in the master binary logs
● On the master, some transactions in schema A and B:
● Order in the binary logs of the master: A1, A2, B1, B2, A3, B3
● On the slave, transactions in different schema are run in parallel:
● “A1, A2, A3” run in parallel with “B1, B2, B3” ● One possible commit order: A1, B1, A2, B2, A3, B3 ● Another if B1 is long to execute : A1, A2, A3, B1, B2, B3 ● Many other possible orders…
● Out-of-order commit on slave has many impacts…
● Implication: transactions on slaves can be committed in a different order than the one they appear in the master binary logs
● On the master, some transactions in schema A and B:
● Order in the binary logs of the master: A1, A2, B1, B2, A3, B3
● On the slave, transactions in different schema are run in parallel:
● “A1, A2, A3” run in parallel with “B1, B2, B3” ● One possible commit order: A1, B1, A2, B2, A3, B3 ● Another if B1 is long to execute : A1, A2, A3, B1, B2, B3 ● Many other possible orders…
● Out-of-order commit on slave has many impacts…
第10页
// Replication: MySQL 5.6’’
● Impacts on the binary log content on slaves:
● 2 slaves can have different binlogs (also different from the master binlogs)
● Impacts on “SHOW SLAVE STATUS”:
● All transactions before the reported SQL thread position are committed ● This “all committed before” position is called a checkpoint ● Some transactions might be committed after the SQL thread position ● But some transactions might still be executing (or queued for execution) gaps
● Impacts on crash recovery (because gaps):
● Not as simple as resetting the IO thread position at the SQL thread position
● Impacts on GTIDs:
● Temporary holes in @@global.gtid_executed (because of gaps)
● And more…
● Skipping transactions, backups, heartbeat, …
● Impacts on the binary log content on slaves:
● 2 slaves can have different binlogs (also different from the master binlogs)
● Impacts on “SHOW SLAVE STATUS”:
● All transactions before the reported SQL thread position are committed ● This “all committed before” position is called a checkpoint ● Some transactions might be committed after the SQL thread position ● But some transactions might still be executing (or queued for execution) gaps
● Impacts on crash recovery (because gaps):
● Not as simple as resetting the IO thread position at the SQL thread position
● Impacts on GTIDs:
● Temporary holes in @@global.gtid_executed (because of gaps)
● And more…
● Skipping transactions, backups, heartbeat, …
第11页
// Replication: MySQL 5.6’’’
● Removing gaps in transaction execution:
● “STOP SLAVE; START SLAVE UNTIL SQL_AFTER_MTS_GAPS;”
● MySQL 5.6 is not parallel replication crash safe without GTIDs (yet…):
● http://jfg-mysql.blogspot.co.uk/2016/01/replication-crash-safety-with-mts.html
● For skipping transactions, first remove gaps ● For backups, make sure your tool is parallel replication aware
● Worker states stored in mysql.slave_worker_info:
● https://dev.mysql.com/worklog/task/?id=5599 (not an easy read)
● Tuning parameters:
● slave-pending-jobs-size-max: RAM for unprocessed events (default 16M) ● slave_checkpoint_group: see next slide (default 512) ● slave_checkpoint_period: see next slide (default 300 ms)
● Removing gaps in transaction execution:
● “STOP SLAVE; START SLAVE UNTIL SQL_AFTER_MTS_GAPS;”
● MySQL 5.6 is not parallel replication crash safe without GTIDs (yet…):
● http://jfg-mysql.blogspot.co.uk/2016/01/replication-crash-safety-with-mts.html
● For skipping transactions, first remove gaps ● For backups, make sure your tool is parallel replication aware
● Worker states stored in mysql.slave_worker_info:
● https://dev.mysql.com/worklog/task/?id=5599 (not an easy read)
● Tuning parameters:
● slave-pending-jobs-size-max: RAM for unprocessed events (default 16M) ● slave_checkpoint_group: see next slide (default 512) ● slave_checkpoint_period: see next slide (default 300 ms)
第12页
// Replication: MySQL 5.6’’’ ’
● What is a MTS checkpoint ?
● After making sure gaps are filled, a checkpointing advances the position reported by “SHOW SLAVE STATUS”
● Checkpointing is tried every slave_checkpoint_period (300 ms by default)
● A checkpoint attempt might fail if a worker is still working on the next needed transaction long transaction might block checkpointing:
● Binlog content: A1,A2,B1,B2,B3,B4,B5…B500,B501,…B600 ● If A2 is very long (ALTER TABLE), it will block checkpointing ● This will block the slave execution at ~B511
● If this happens, workers will not be able to go beyond the group size
● Solution: increase slave_checkpoint_group (512 by default)
● Similar problems happen if transactions are big (in the binlogs)
● Solution: increase slave-pending-jobs-size-max (16M by default) ● But try keeping your transactions small (avoid LOAD DATA INFILE and others…)
● What is a MTS checkpoint ?
● After making sure gaps are filled, a checkpointing advances the position reported by “SHOW SLAVE STATUS”
● Checkpointing is tried every slave_checkpoint_period (300 ms by default)
● A checkpoint attempt might fail if a worker is still working on the next needed transaction long transaction might block checkpointing:
● Binlog content: A1,A2,B1,B2,B3,B4,B5…B500,B501,…B600 ● If A2 is very long (ALTER TABLE), it will block checkpointing ● This will block the slave execution at ~B511
● If this happens, workers will not be able to go beyond the group size
● Solution: increase slave_checkpoint_group (512 by default)
● Similar problems happen if transactions are big (in the binlogs)
● Solution: increase slave-pending-jobs-size-max (16M by default) ● But try keeping your transactions small (avoid LOAD DATA INFILE and others…)
第13页
// Replication: MariaDB 10.0 (out-of-order)
● Concept: manually tags independent transactions in “write domains” ● Implementation:
● MariaDB GTIDs: <domain ID>-<server ID>-<Sequence Number> (0-1-10) ● the SQL thread becomes a coordinator that dispatches work
● Deployment:
● On the master and for each trx: “SET SESSION gtid_domain_id = D;” ● On the slave: “SET GLOBAL slave_parallel_threads = N;” (SPT)
● Also available in MariaDB 10.1
● Do not mess-up advertising the write domain !
● MySQL 5.6 will protect you from multi-schema transactions, MariaDB cannot
● Also out-of-order commit of transactions on slaves:
● There will be gaps, those gaps are managed by MariaDB GTIDs,
● Impact on binary logs content, SHOW SLAVE STATUS, skipping transactions,
backups, heartbeat, …
● Concept: manually tags independent transactions in “write domains” ● Implementation:
● MariaDB GTIDs: <domain ID>-<server ID>-<Sequence Number> (0-1-10) ● the SQL thread becomes a coordinator that dispatches work
● Deployment:
● On the master and for each trx: “SET SESSION gtid_domain_id = D;” ● On the slave: “SET GLOBAL slave_parallel_threads = N;” (SPT)
● Also available in MariaDB 10.1
● Do not mess-up advertising the write domain !
● MySQL 5.6 will protect you from multi-schema transactions, MariaDB cannot
● Also out-of-order commit of transactions on slaves:
● There will be gaps, those gaps are managed by MariaDB GTIDs,
● Impact on binary logs content, SHOW SLAVE STATUS, skipping transactions,
backups, heartbeat, …
第14页
// Replication: MariaDB 10.0 (out-of-order)’
● Difference with MySQL 5.6:
● “SHOW SLAVE STATUS” is the position of the latest committed transactions, there might be gaps before…
● If the SQL thread stops (or is stopped), its position will “rewind” to a “safe” position https://mariadb.atlassian.net/browse/MDEV-6589 https://mariadb.atlassian.net/browse/MDEV-9138
● Removing gaps:
● STOP SLAVE; SET GLOBAL slave_parallel_threads = 0; START SLAVE;
● Not re-downloading relay logs, but see two MDEVs above:
STOP SLAVE SQL_THREAD; SET GLOBAL slave_parallel_threads=0; START SLAVE;
http://jfg-mysql.blogspot.com/2015/10/bad-commands-with-mariadb-gtids-2.html
● Skipping transactions:
● Go back to single threaded replication, START SLAVE break again, then skip ● Like above, restart the IO thread if you want to avoid problems
● Dispatching algorithm, its impact, and tuning parameters:
● Long transactions, big transactions, … we will come back to that after in-order
● Difference with MySQL 5.6:
● “SHOW SLAVE STATUS” is the position of the latest committed transactions, there might be gaps before…
● If the SQL thread stops (or is stopped), its position will “rewind” to a “safe” position https://mariadb.atlassian.net/browse/MDEV-6589 https://mariadb.atlassian.net/browse/MDEV-9138
● Removing gaps:
● STOP SLAVE; SET GLOBAL slave_parallel_threads = 0; START SLAVE;
● Not re-downloading relay logs, but see two MDEVs above:
STOP SLAVE SQL_THREAD; SET GLOBAL slave_parallel_threads=0; START SLAVE;
http://jfg-mysql.blogspot.com/2015/10/bad-commands-with-mariadb-gtids-2.html
● Skipping transactions:
● Go back to single threaded replication, START SLAVE break again, then skip ● Like above, restart the IO thread if you want to avoid problems
● Dispatching algorithm, its impact, and tuning parameters:
● Long transactions, big transactions, … we will come back to that after in-order
第15页
// Replication: MariaDB 10.0 (in-order)
● Concept: transactions committing together on the master can be executed in parallel on slaves
● Implementation:
● Build on top of the binary log Group Commit optimisation: the master tags transactions in the binary logs with their Commit ID (cid)
● Deployment:
● Needs a MariaDB 10.0 master ● On slaves: “SET GLOBAL slave_parallel_thread > 0;”
● Concept: transactions committing together on the master can be executed in parallel on slaves
● Implementation:
● Build on top of the binary log Group Commit optimisation: the master tags transactions in the binary logs with their Commit ID (cid)
● Deployment:
● Needs a MariaDB 10.0 master ● On slaves: “SET GLOBAL slave_parallel_thread > 0;”
第16页
// Replication: MariaDB 10.0 (in-order)’
● Binlog example:
... #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-184 cid=2324 #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-185 cid=2335 ... #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-189 cid=2335 #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-190 #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-191 cid=2346 ... #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-197 cid=2346 #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-198 cid=2361 ...
● Binlog example:
... #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-184 cid=2324 #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-185 cid=2335 ... #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-189 cid=2335 #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-190 #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-191 cid=2346 ... #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-197 cid=2346 #150316 11:33:46 server id 1 end_log_pos x GTID 0-1-198 cid=2361 ...
第17页
// Replication: MariaDB 10.0 (in-order)’’
● Good or bad grouping of transactions on the master:
● When sync_binlog = 1, instead of syncing the binlog after each transaction, MariaDB buffers transactions and sync the binlogs a single time for a group
● Setting sync_binlog = 0 or > 1 might lead to bad grouping ● When not enough parallelism, or sync very fast, grouping might be suboptimal
● Global Statuses can be used to monitor grouping on the master:
● BINLOG_COMMITS: number of commits in the binary logs ● BINLOG_GROUP_COMMITS: number of group commits in the binary logs ● The 1st divided by the 2nd gives the group size
● Grouping optimisation (slowing down the master to speed-up slaves):
● BINLOG_COMMIT_WAIT_USEC (BCWU): timeout, in microseconds, for waiting more transactions to join the group
● BINLOG_COMMIT_WAIT_COUNT (BCWC): number of transactions when waiting stops
● Good or bad grouping of transactions on the master:
● When sync_binlog = 1, instead of syncing the binlog after each transaction, MariaDB buffers transactions and sync the binlogs a single time for a group
● Setting sync_binlog = 0 or > 1 might lead to bad grouping ● When not enough parallelism, or sync very fast, grouping might be suboptimal
● Global Statuses can be used to monitor grouping on the master:
● BINLOG_COMMITS: number of commits in the binary logs ● BINLOG_GROUP_COMMITS: number of group commits in the binary logs ● The 1st divided by the 2nd gives the group size
● Grouping optimisation (slowing down the master to speed-up slaves):
● BINLOG_COMMIT_WAIT_USEC (BCWU): timeout, in microseconds, for waiting more transactions to join the group
● BINLOG_COMMIT_WAIT_COUNT (BCWC): number of transactions when waiting stops
第18页
// Replication: MariaDB 10.0 (in-order)’’’
● Long transactions can block the parallel execution pipeline ● On the master:
------------ Time -----------> T1: B-------------------------C T2: B--C T3: B--C ● On the slaves: T1: B-------------------------C T2: B-- . . . . . . . . . . . C T3: B-- . . . . . . . . . . . C Try reducing as much as possible the number of big transactions:
• Easier said than done: 10 ms is big compared to 1 ms
Avoid monster transactions !
● Long transactions can block the parallel execution pipeline ● On the master:
------------ Time -----------> T1: B-------------------------C T2: B--C T3: B--C ● On the slaves: T1: B-------------------------C T2: B-- . . . . . . . . . . . C T3: B-- . . . . . . . . . . . C Try reducing as much as possible the number of big transactions:
• Easier said than done: 10 ms is big compared to 1 ms
Avoid monster transactions !
第19页
// Replication: MariaDB 10.0 (in-order)’’’ ’
● Replicating through intermediate master losses grouping ● Four transactions on X, Y and Z:
+---+ |X| +---+
| V +---+ |Y| +---+ | V +---+ |Z| +---+
On X:
----Time----> T1 B---C T2 B---C T3 B-------C T4 B-------C
On Y:
----Time----> B---C B---C B-------C B-------C
On Z:
----Time---------> B---C B---C B-------C B-------C
● To get maximum replication speed on 2nd level slaves, replace intermediate masters by Binlog Servers
● Replicating through intermediate master losses grouping ● Four transactions on X, Y and Z:
+---+ |X| +---+
| V +---+ |Y| +---+ | V +---+ |Z| +---+
On X:
----Time----> T1 B---C T2 B---C T3 B-------C T4 B-------C
On Y:
----Time----> B---C B---C B-------C B-------C
On Z:
----Time---------> B---C B---C B-------C B-------C
● To get maximum replication speed on 2nd level slaves, replace intermediate masters by Binlog Servers
第20页
// Replication: MariaDB 10.0 (in-order)’’’ ’’
More graphs and details at:
http://blog.booking.com/better_parallel_replication_for_mysql.html
More graphs and details at:
http://blog.booking.com/better_parallel_replication_for_mysql.html
第21页
// Replication: MariaDB 10.0
● Work dispatching algorithm to threads:
● Work queue, per thread, which contains transactions to execute by this thread ● The coordinator is dispatching work round-robin to threads until a queue is full If a queue is full, dispatching work pauses (big transactions block scheduling) ● Once a thread is scheduled work in a domain, it is only queued work for this domain If all threads are scheduled work, a new domain will starve until a thread has
processed all its queue
● Solutions: tuning parameters:
● slave-parallel-max-queued (default 128KB): buffer, per thread, to queue transactions ● slave_domain_parallel_threads (default 0): max number of threads a domain can use
● Again: avoid big transactions (size in the binlogs)
● Work dispatching algorithm to threads:
● Work queue, per thread, which contains transactions to execute by this thread ● The coordinator is dispatching work round-robin to threads until a queue is full If a queue is full, dispatching work pauses (big transactions block scheduling) ● Once a thread is scheduled work in a domain, it is only queued work for this domain If all threads are scheduled work, a new domain will starve until a thread has
processed all its queue
● Solutions: tuning parameters:
● slave-parallel-max-queued (default 128KB): buffer, per thread, to queue transactions ● slave_domain_parallel_threads (default 0): max number of threads a domain can use
● Again: avoid big transactions (size in the binlogs)
第22页
// Replication: Slave Group Commit
● On a single-threaded slave, transactions are run sequentially: ----- Time ---->
T1: B----C T2: B----C
● If T1 and T2 are in different cid, they cannot be run in parallel
● But if they do not conflict, delaying committing of T1 might allow to completely run T2 in another thread, achieving group commit: T1: B---- . . C T2: B----C
● On a single-threaded slave, transactions are run sequentially: ----- Time ---->
T1: B----C T2: B----C
● If T1 and T2 are in different cid, they cannot be run in parallel
● But if they do not conflict, delaying committing of T1 might allow to completely run T2 in another thread, achieving group commit: T1: B---- . . C T2: B----C
第23页
// Replication: Slave Group Commit’
● MariaDB 10.0 implements Slave Group Commit when the master is running MariaDB 10.0, SPT > 0, BCWC > 0 and BCWU > 0
● Waiting is short-circuited when a transaction Tn blocks on Tn-I so this should not happen: T1: B---- . . . . C T2: B--- . . . --C
No penalty for using big value of BCWU
● Except for DDL where short-circuit is not implemented
● MariaDB 10.0 implements Slave Group Commit when the master is running MariaDB 10.0, SPT > 0, BCWC > 0 and BCWU > 0
● Waiting is short-circuited when a transaction Tn blocks on Tn-I so this should not happen: T1: B---- . . . . C T2: B--- . . . --C
No penalty for using big value of BCWU
● Except for DDL where short-circuit is not implemented
第24页
// Replication: MariaDB 10.1 (in-order)
● MariaDB 10.1 has different slave parallel modes:
● none: classic single-threaded slave (same as slave_parallel_threads = 0) ● minimal: in different threads, serialised execution of transaction
slave group commit (needs BCWC and BCWU > 0) (and out-of-order parallel replication disabled in this mode) ● conservative: parallel execution based on group commit (as in MariaD 10.0) ● optimistic: a new type of parallel execution ● aggressive: a more aggressive optimistic mode
● MariaDB 10.1 has different slave parallel modes:
● none: classic single-threaded slave (same as slave_parallel_threads = 0) ● minimal: in different threads, serialised execution of transaction
slave group commit (needs BCWC and BCWU > 0) (and out-of-order parallel replication disabled in this mode) ● conservative: parallel execution based on group commit (as in MariaD 10.0) ● optimistic: a new type of parallel execution ● aggressive: a more aggressive optimistic mode
第25页
// Replication: MariaDB 10.1 (in-order)’
● With MariaDB 10.0 (and with MariaDB 10.1 in conservative mode), running in parallel, transactions that group committed on the master, and committing them in-order, can lead to deadlocks
● On the master, T1 and T2 commit together: ----Time--->
T1: B-------C T2: B--C ● On the slaves, T2 blocks T1 (because index update, …), but T1 must commit before T2 deadlock ! T1: B---- . . . . . . . . . . . . . T2: B-- . . . . . . . . . . . . . . ● To solve this deadlock, MariaDB kills T2, which unblocks T1 ● Corresponding global status: slave_retried_transactions
● With MariaDB 10.0 (and with MariaDB 10.1 in conservative mode), running in parallel, transactions that group committed on the master, and committing them in-order, can lead to deadlocks
● On the master, T1 and T2 commit together: ----Time--->
T1: B-------C T2: B--C ● On the slaves, T2 blocks T1 (because index update, …), but T1 must commit before T2 deadlock ! T1: B---- . . . . . . . . . . . . . T2: B-- . . . . . . . . . . . . . . ● To solve this deadlock, MariaDB kills T2, which unblocks T1 ● Corresponding global status: slave_retried_transactions
第26页
// Replication: MariaDB 10.1 (in-order)’’
● Number of retried transactions catching up many hours of replication delay (~2.5K transactions per second):
Retried transactions happen 3 times in 4 minutes not often at all
● Number of retried transactions catching up many hours of replication delay (~2.5K transactions per second):
Retried transactions happen 3 times in 4 minutes not often at all
第27页
// Replication: MariaDB 10.1 (optimistic)
● Concept: run all transactions in parallel, if they conflict (replication blocked because in-order commit), deadlock detection unblocks the slave
● Implementation:
● Natural evolution from MariaDB 10.0
● Deployment:
● Needs a MariaDB 10.1 master ● SET GLOBAL slave_parallel_thread > 0; ● SET GLOBAL slave_parallel_mode = {optimistic | aggressive};
Optimistic will try to reduce the number of deadlocks (and rollbacks) using information put in the binary logs from the master, aggressive will run as many transactions in parallel as possible (bounded by the number of threads)
● DDLs cannot be rollbacks they cannot be run optimistically:
DDL blocks the parallel replication pipeline Same for other non-transactional operations
● Concept: run all transactions in parallel, if they conflict (replication blocked because in-order commit), deadlock detection unblocks the slave
● Implementation:
● Natural evolution from MariaDB 10.0
● Deployment:
● Needs a MariaDB 10.1 master ● SET GLOBAL slave_parallel_thread > 0; ● SET GLOBAL slave_parallel_mode = {optimistic | aggressive};
Optimistic will try to reduce the number of deadlocks (and rollbacks) using information put in the binary logs from the master, aggressive will run as many transactions in parallel as possible (bounded by the number of threads)
● DDLs cannot be rollbacks they cannot be run optimistically:
DDL blocks the parallel replication pipeline Same for other non-transactional operations
第28页
// Replication: MySQL 5.7
● MySQL 5.7 has different slave parallel type:
● DATABASE: the schema based parallel replication from MySQL 5.6 ● LOGICAL_CLOCK: “Transactions that are part of the same binary log group
commit on a master are applied in parallel on a slave.” (from the documentation) (the logical clock is implemented using intervals)
● Slowing down the master to speedup the slave:
● binlog_group_commit_sync_delay ● binlog_group_commit_sync_no_delay_count
● We can expect the same problems as with MariaDB 10.0:
● Problems with long/big transactions ● Problems with intermediate masters
● MySQL 5.7 has different slave parallel type:
● DATABASE: the schema based parallel replication from MySQL 5.6 ● LOGICAL_CLOCK: “Transactions that are part of the same binary log group
commit on a master are applied in parallel on a slave.” (from the documentation) (the logical clock is implemented using intervals)
● Slowing down the master to speedup the slave:
● binlog_group_commit_sync_delay ● binlog_group_commit_sync_no_delay_count
● We can expect the same problems as with MariaDB 10.0:
● Problems with long/big transactions ● Problems with intermediate masters
第29页
// Replication: MySQL 5.7’
● Binlog example:
#160121 15:45:51 ... last_committed=0 sequence_number=9 #160121 15:45:51 ... last_committed=0 sequence_number=10 #160121 15:45:51 ... last_committed=10 sequence_number=11 #160121 15:45:51 ... last_committed=10 sequence_number=12 ... #160121 15:45:51 ... last_committed=10 sequence_number=19 #160121 15:45:51 ... last_committed=10 sequence_number=20 #160121 15:45:52 ... last_committed=20 sequence_number=21 #160121 15:45:52 ... last_committed=20 sequence_number=22
● Binlog example:
#160121 15:45:51 ... last_committed=0 sequence_number=9 #160121 15:45:51 ... last_committed=0 sequence_number=10 #160121 15:45:51 ... last_committed=10 sequence_number=11 #160121 15:45:51 ... last_committed=10 sequence_number=12 ... #160121 15:45:51 ... last_committed=10 sequence_number=19 #160121 15:45:51 ... last_committed=10 sequence_number=20 #160121 15:45:52 ... last_committed=20 sequence_number=21 #160121 15:45:52 ... last_committed=20 sequence_number=22
第30页
// Replication: MySQL 5.7’’
● By default, MySQL 5.7 in logical clock does out-of-order commit:
There will be gaps (“START SLAVE UNTIL SQL_AFTER_MTS_GAPS;”) ● Not replication crash safe without GTIDs
http://jfg-mysql.blogspot.co.uk/2016/01/replication-crash-safety-with-mts.html ● And also everything else: binary logs content, SHOW SLAVE STATUS, skipping
transactions, backups, …
● Using slave_preserve_commit_order = 1 does what you expect
● This configuration does not generate gap ● But it needs log-slave-updates, there is a feature request to remove this limitation:
https://bugs.mysql.com/bug.php?id=75396 ● And it is still not replication crash safe (surprising because no gap):
https://bugs.mysql.com/bug.php?id=80103
● By default, MySQL 5.7 in logical clock does out-of-order commit:
There will be gaps (“START SLAVE UNTIL SQL_AFTER_MTS_GAPS;”) ● Not replication crash safe without GTIDs
http://jfg-mysql.blogspot.co.uk/2016/01/replication-crash-safety-with-mts.html ● And also everything else: binary logs content, SHOW SLAVE STATUS, skipping
transactions, backups, …
● Using slave_preserve_commit_order = 1 does what you expect
● This configuration does not generate gap ● But it needs log-slave-updates, there is a feature request to remove this limitation:
https://bugs.mysql.com/bug.php?id=75396 ● And it is still not replication crash safe (surprising because no gap):
https://bugs.mysql.com/bug.php?id=80103
第31页
// Replication: results from B.com
● MariaDB 10.0 tests:
● On four environments, from MySQL 5.6 masters, thanks to Slave Group Commit
● MariaDB 10.1 tests: conservative vs aggressive
● Four same environments
● MySQL 5.6 real deployment ● MariaDB 10.0 real deployment ● No results from MySQL 5.7:
● I guess we can expect similar results to MariaDB 10.0
● MariaDB 10.0 tests:
● On four environments, from MySQL 5.6 masters, thanks to Slave Group Commit
● MariaDB 10.1 tests: conservative vs aggressive
● Four same environments
● MySQL 5.6 real deployment ● MariaDB 10.0 real deployment ● No results from MySQL 5.7:
● I guess we can expect similar results to MariaDB 10.0
第32页
// Replication: MariaDB 10.0
● Four environments (E1, E2, E3 and E4):
● A is a MySQL 5.6 master ● B is a MariaDB 10.0 intermediate master ● C is a MariaDB 10.0 intermediate master doing slave group commit ● D is using the group commit information from C to run transaction in parallel
+---+
+---+
+---+
+---+
| A | --> | B | --> | C | --> | D |
+---+
+---+
+---+
+---+
● Note that a group committing master generates bigger groups than slave group commit, more information in:
● http://blog.booking.com/evaluating_mysql_parallel_replication_3under_the_hood.html#group_commit_slave_vs_master
● Four environments (E1, E2, E3 and E4):
● A is a MySQL 5.6 master ● B is a MariaDB 10.0 intermediate master ● C is a MariaDB 10.0 intermediate master doing slave group commit ● D is using the group commit information from C to run transaction in parallel
+---+
+---+
+---+
+---+
| A | --> | B | --> | C | --> | D |
+---+
+---+
+---+
+---+
● Note that a group committing master generates bigger groups than slave group commit, more information in:
● http://blog.booking.com/evaluating_mysql_parallel_replication_3under_the_hood.html#group_commit_slave_vs_master
第33页
// Replication: MariaDB 10.0 g-commit
● Upside of group commit: when a sync is expensive on a slave, syncing could become the bottleneck of replication
● In this case, doing less sync is a win ● Slave group commit allows that with “sync_binlog =1” and “trx_commit = 1”
● With B and C having RAID controller write cache (syncs are very fast):
1. Run B and C without slave group commit (before 17:05) 2. At 17:05, enable slave group commit on C 3. At 17:10, disable the write cache on C syncs become expensive 4. At 17:15: disable slave group commit on C
● During the test, we monitor commits and group commits
More details at:
http://blog.booking.com/evaluating_mysql_parallel_replication_2-slave_group_commit.html
● Upside of group commit: when a sync is expensive on a slave, syncing could become the bottleneck of replication
● In this case, doing less sync is a win ● Slave group commit allows that with “sync_binlog =1” and “trx_commit = 1”
● With B and C having RAID controller write cache (syncs are very fast):
1. Run B and C without slave group commit (before 17:05) 2. At 17:05, enable slave group commit on C 3. At 17:10, disable the write cache on C syncs become expensive 4. At 17:15: disable slave group commit on C
● During the test, we monitor commits and group commits
More details at:
http://blog.booking.com/evaluating_mysql_parallel_replication_2-slave_group_commit.html
第34页
// Replication: MariaDB 10.0 g-commit’
第35页
// Replication: MariaDB 10.0 g-commit’’
第36页
// Replication: MariaDB 10.0 p-tests
● Parallel replication with MariaDB 10.0 (or with 10.1 conservative):
● Catching up 24 hours of replication delay with 0, 5, 10, 20 and 40 threads
● Parallel replication with MariaDB 10.0 (or with 10.1 conservative):
● Catching up 24 hours of replication delay with 0, 5, 10, 20 and 40 threads
第37页
// Replication: MariaDB 10.0 p-tests’
More details at:
http://blog.booking.com/evaluating_mysql_parallel_replication_3benchmarks_in_production.html
More details at:
http://blog.booking.com/evaluating_mysql_parallel_replication_3benchmarks_in_production.html
第38页
// Replication: MariaDB 10.0 p-tests’’
Slave with binlogs (SB) but without log-slave-updates High Durability (HD): “sync_binlog = 1” + “trx_commit = 1” No Durability (ND): “sync_binlog = 0” + “trx_commit = 2”
2 1,9 1,8 1,7 1,6 1,5 1,4 1,3 1,2 1,1
1 5
E1 SB-HD&ND
10 20 HD ND
HD Single-Threaded: 3h09.34 ND Single-Threaded: 1h24.09
Slave with binlogs (SB) but without log-slave-updates High Durability (HD): “sync_binlog = 1” + “trx_commit = 1” No Durability (ND): “sync_binlog = 0” + “trx_commit = 2”
2 1,9 1,8 1,7 1,6 1,5 1,4 1,3 1,2 1,1
1 5
E1 SB-HD&ND
10 20 HD ND
HD Single-Threaded: 3h09.34 ND Single-Threaded: 1h24.09
第39页
// Replication: MariaDB 10.0 p-tests’’’
E1 SB-HD&ND
2,4 2,2
2 1,8 1,6 1,4 1,2
1 5
10 20 40
HD ND ND vs HD Single-Threaded ND vs HD
E2 SB-HD&ND
2,8 2,6 2,4 2,2
2 1,8 1,6 1,4 1,2
1 5
10 20 40
HD ND ND vs HD Single-Threaded ND vs HD
E1 SB-HD&ND
2,4 2,2
2 1,8 1,6 1,4 1,2
1 5
10 20 40
HD ND ND vs HD Single-Threaded ND vs HD
E2 SB-HD&ND
2,8 2,6 2,4 2,2
2 1,8 1,6 1,4 1,2
1 5
10 20 40
HD ND ND vs HD Single-Threaded ND vs HD
第40页
// Replication: MariaDB 10.0 p-tests’’’ ’
E3 SB-HD&ND
1,35 1,3
1,25 1,2
1,15 1,1
1,05 1 5
10 20 40
HD ND ND vs HD Single-Threaded ND vs HD
E4 SB-HD&ND
1,6
1,5
1,4
1,3
1,2
1,1
1 5
10 20 40
HD ND ND vs HD Single-Threaded ND vs HD
E3 SB-HD&ND
1,35 1,3
1,25 1,2
1,15 1,1
1,05 1 5
10 20 40
HD ND ND vs HD Single-Threaded ND vs HD
E4 SB-HD&ND
1,6
1,5
1,4
1,3
1,2
1,1
1 5
10 20 40
HD ND ND vs HD Single-Threaded ND vs HD
第41页
// Replication: MariaDB 10.1 tests
● Four same environments, D now runs MariaDB 10.1, and to take
advantage of optimistic parallel replication, we need a 10.1 master add E
+---+
+---+
+---+
+---+
| A | --> | B | --> | C | --> | D |
+---+
+---+
+---+
+---+
|
|
+---+
+---+
+-----> | E | --> | D2|
+---+
+---+
● D and D2 are the same hardware
● D runs with SPT = conservative
● D2 runs with SPT = aggressive
● Four same environments, D now runs MariaDB 10.1, and to take
advantage of optimistic parallel replication, we need a 10.1 master add E
+---+
+---+
+---+
+---+
| A | --> | B | --> | C | --> | D |
+---+
+---+
+---+
+---+
|
|
+---+
+---+
+-----> | E | --> | D2|
+---+
+---+
● D and D2 are the same hardware
● D runs with SPT = conservative
● D2 runs with SPT = aggressive
第42页
// Replication: MariaDB 10.1 tests’
2,5
1,5
1 5
E1 SB-HD
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
E1 SB-ND
2,2
1,8
1,6
1,4
1,2
1 5
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
2,5
1,5
1 5
E1 SB-HD
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
E1 SB-ND
2,2
1,8
1,6
1,4
1,2
1 5
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
第43页
// Replication: MariaDB 10.1 tests’’
3,5 3
2,5 2
1,5 1
0,5 5
E2 SB-HD
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
2,5
E2 SB-ND
1,5
0,5
0 5
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
3,5 3
2,5 2
1,5 1
0,5 5
E2 SB-HD
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
2,5
E2 SB-ND
1,5
0,5
0 5
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
第44页
// Replication: MariaDB 10.1 tests’’’
2,4 2,2
2 1,8 1,6 1,4 1,2
1 5
E3 SB-HD
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
E3 SB-ND
2,2
1,8
1,6
1,4
1,2
1 5
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
2,4 2,2
2 1,8 1,6 1,4 1,2
1 5
E3 SB-HD
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
E3 SB-ND
2,2
1,8
1,6
1,4
1,2
1 5
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
第45页
// Replication: MariaDB 10.1 tests’’’ ’
4 3,5
3 2,5
2 1,5
1 5
E4 SB-HD
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
E4 SB-ND
3,5
2,5
1,5
1 5
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
4 3,5
3 2,5
2 1,5
1 5
E4 SB-HD
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
E4 SB-ND
3,5
2,5
1,5
1 5
10 20 40 80 160 320 640 1280 2560 5120
Conservative
Aggressive
第46页
// Replication: MariaDB 10.1 tests’’’ ’’
E1 SB-HD&ND
4,5 4
3,5 3
2,5 2
1,5 1 5
10 20 40 80 160 320 640 1280 2560 5120
HD ND ND vs HD Single-Threaded ND vs HD
E2 SB-HD&ND
5 4,5
4 3,5
3 2,5
2 1,5
1 0,5
10 20 40 80 160 320 640 1280 2560 5120
HD ND ND vs HD Single-Threaded ND vs HD
E1 SB-HD&ND
4,5 4
3,5 3
2,5 2
1,5 1 5
10 20 40 80 160 320 640 1280 2560 5120
HD ND ND vs HD Single-Threaded ND vs HD
E2 SB-HD&ND
5 4,5
4 3,5
3 2,5
2 1,5
1 0,5
10 20 40 80 160 320 640 1280 2560 5120
HD ND ND vs HD Single-Threaded ND vs HD
第47页
// Replication: MariaDB 10.1 tests’’’ ’’’
E3 SB-HD&ND
2,4 2,2
2 1,8 1,6 1,4 1,2
1 5
10 20 40 80 160 320 640 1280 2560 5120
HD ND ND vs HD Single-Threaded ND Normalized
E4 SB-HD&ND
4,5 4
3,5 3
2,5 2
1,5 1 5
10 20 40 80 160 320 640 1280 2560 5120
HD ND ND vs HD Single-Threaded ND vs HD
E3 SB-HD&ND
2,4 2,2
2 1,8 1,6 1,4 1,2
1 5
10 20 40 80 160 320 640 1280 2560 5120
HD ND ND vs HD Single-Threaded ND Normalized
E4 SB-HD&ND
4,5 4
3,5 3
2,5 2
1,5 1 5
10 20 40 80 160 320 640 1280 2560 5120
HD ND ND vs HD Single-Threaded ND vs HD
第48页
// Replication: MySQL 5.6 real
● Booking.com session store is sharded with many schema per database:
● Running MySQL 5.6, >1 TB per node, 20 schema per node, magnetic disks ● PLAMS 2015: Combining Redis and MySQL to store HTTP cookie data
https://www.percona.com/live/europe-amsterdam-2015/sessions/combining-redis-andmysql-store-http-cookie-data
4 3,5
3 2,5
2 1,5
1 2
Sess SB-HD&ND
4 HD
ND
8 16 ND vs HD Single-Threaded
32 ND vs HD
● Booking.com session store is sharded with many schema per database:
● Running MySQL 5.6, >1 TB per node, 20 schema per node, magnetic disks ● PLAMS 2015: Combining Redis and MySQL to store HTTP cookie data
https://www.percona.com/live/europe-amsterdam-2015/sessions/combining-redis-andmysql-store-http-cookie-data
4 3,5
3 2,5
2 1,5
1 2
Sess SB-HD&ND
4 HD
ND
8 16 ND vs HD Single-Threaded
32 ND vs HD
第49页
// Replication: MariaDB 10.0 real
● Booking.com is also running MariaDB 10.0. ● One of those system has very high replication load:
● we optimised group commit on the master and enabled parallel replication on some slaves (blue and orange line below with 30 threads, and yellow with 0)
● The Y axis is the replication delay (in seconds)
● Booking.com is also running MariaDB 10.0. ● One of those system has very high replication load:
● we optimised group commit on the master and enabled parallel replication on some slaves (blue and orange line below with 30 threads, and yellow with 0)
● The Y axis is the replication delay (in seconds)
第50页
// Replication: MariaDB 10.0 real’
● Swapping parallel replication settings on blue and yellow:
● Swapping parallel replication settings on blue and yellow:
第51页
// Replication: Summary
● Parallel replication is not simple ● MariaDB 10.0 in-order (and probably MySQL 5.7 logical clock) has limitations:
● Long transactions block the parallel replication pipeline ● Intermediate master looses parallelism and reduce replication speed on slaves
● MySQL 5.6 and 5.7 are not fully MTS crash-safe (without GTIDs) ● MariaDB out-of-order solution needs careful developer involvement
● MySQL schema-based solution looks safer and simpler to use than MariaDB out-of-order which is more flexible but more complex
● MariaDB 10.1 aggressive mode much better than conservative
● In all cases, avoid big transactions in the binary logs
● Parallel replication is not simple ● MariaDB 10.0 in-order (and probably MySQL 5.7 logical clock) has limitations:
● Long transactions block the parallel replication pipeline ● Intermediate master looses parallelism and reduce replication speed on slaves
● MySQL 5.6 and 5.7 are not fully MTS crash-safe (without GTIDs) ● MariaDB out-of-order solution needs careful developer involvement
● MySQL schema-based solution looks safer and simpler to use than MariaDB out-of-order which is more flexible but more complex
● MariaDB 10.1 aggressive mode much better than conservative
● In all cases, avoid big transactions in the binary logs
第52页
// Replication: Links
● Better Parallel Replication for MySQL: http://blog.booking.com/better_parallel_replication_for_mysql.html
● Evaluating MySQL Parallel Replication Part 2: Slave Group Commit: http://blog.booking.com/evaluating_mysql_parallel_replication_2-slave_group_commit.html
● Evaluating MySQL Parallel Replication Part 2: Slave Group Commit: http://blog.booking.com/evaluating_mysql_parallel_replication_2-slave_group_commit.html
● Evaluating MySQL Parallel Replication Part 3: Benchmarks in Production: http://blog.booking.com/evaluating_mysql_parallel_replication_3benchmarks_in_production.html
● Evaluating MySQL Parallel Replication Part 4: More Benchmarks in Production: about optimistic // replication, to be published eventually on http://blog.booking.com
● Evaluating MySQL Parallel Replication Part 5: Event more Benchmarks in Production: about MySQL 5.6 and maybe more, to be published on http://blog.booking.com
● Replication crash safety with MTS in MySQL 5.6 and 5.7: reality or illusion? http://jfg-mysql.blogspot.co.uk/2016/01/replication-crash-safety-with-mts.html
● Do not run those commands with MariaDB GTIDs http://jfg-mysql.blogspot.fr/2015/10/bad-commands-with-mariadb-gtids-2.html
● Better Parallel Replication for MySQL: http://blog.booking.com/better_parallel_replication_for_mysql.html
● Evaluating MySQL Parallel Replication Part 2: Slave Group Commit: http://blog.booking.com/evaluating_mysql_parallel_replication_2-slave_group_commit.html
● Evaluating MySQL Parallel Replication Part 2: Slave Group Commit: http://blog.booking.com/evaluating_mysql_parallel_replication_2-slave_group_commit.html
● Evaluating MySQL Parallel Replication Part 3: Benchmarks in Production: http://blog.booking.com/evaluating_mysql_parallel_replication_3benchmarks_in_production.html
● Evaluating MySQL Parallel Replication Part 4: More Benchmarks in Production: about optimistic // replication, to be published eventually on http://blog.booking.com
● Evaluating MySQL Parallel Replication Part 5: Event more Benchmarks in Production: about MySQL 5.6 and maybe more, to be published on http://blog.booking.com
● Replication crash safety with MTS in MySQL 5.6 and 5.7: reality or illusion? http://jfg-mysql.blogspot.co.uk/2016/01/replication-crash-safety-with-mts.html
● Do not run those commands with MariaDB GTIDs http://jfg-mysql.blogspot.fr/2015/10/bad-commands-with-mariadb-gtids-2.html
第53页
// Replication: Links’
● Binlog Servers:
● http://blog.booking.com/mysql_slave_scaling_and_more.html
● http://blog.booking.com/better_parallel_replication_for_mysql.html
● http://blog.booking.com/abstracting_binlog_servers_and_mysql_master_promotion_w
o_reconfiguring_slaves.html
● Bugs/feature requests:
● Message after MTS crash misleading: https://bugs.mysql.com/bug.php?id=80102
(and https://bugs.mysql.com/bug.php?id=77496)
● MTS LOGICAL_CLOCK with slave_preserve_commit_order=1 not repl. crash safe:
http://bugs.mysql.com/bug.php?id=80103
● Relay log pos. corrupted with p-replication after interrupt. LOAD DATA on master
https://mariadb.atlassian.net/browse/MDEV-9138
(related to https://mariadb.atlassian.net/browse/MDEV-6589)
● Others
● https://mariadb.com/blog/how-get-mysql-56-parallel-replication-and-percona-
xtrabackup-play-nice-together
● https://www.percona.com/blog/2015/01/29/multi-threaded-replication-with-mysql-5-6-
use-gtids/
● Binlog Servers:
● http://blog.booking.com/mysql_slave_scaling_and_more.html
● http://blog.booking.com/better_parallel_replication_for_mysql.html
● http://blog.booking.com/abstracting_binlog_servers_and_mysql_master_promotion_w
o_reconfiguring_slaves.html
● Bugs/feature requests:
● Message after MTS crash misleading: https://bugs.mysql.com/bug.php?id=80102
(and https://bugs.mysql.com/bug.php?id=77496)
● MTS LOGICAL_CLOCK with slave_preserve_commit_order=1 not repl. crash safe:
http://bugs.mysql.com/bug.php?id=80103
● Relay log pos. corrupted with p-replication after interrupt. LOAD DATA on master
https://mariadb.atlassian.net/browse/MDEV-9138
(related to https://mariadb.atlassian.net/browse/MDEV-6589)
● Others
● https://mariadb.com/blog/how-get-mysql-56-parallel-replication-and-percona-
xtrabackup-play-nice-together
● https://www.percona.com/blog/2015/01/29/multi-threaded-replication-with-mysql-5-6-
use-gtids/
第54页
Thanks
Jean-François Gagné jeanfrancois DOT gagne AT booking.com
Jean-François Gagné jeanfrancois DOT gagne AT booking.com