Statement-Based Replication (SBR) will replicate SQL Statements. It is easier to read using mysqlbinlog dump program.
Row based replication (RBR) will replicate actual data changes. Binary logs and relay logs will grow much faster than SBR. You also cannot identify the SQL that generated the changes.
(Please read updated information for MySQL 5.6.2. below)
Here is a more comprehensive pros-and-cons list : http://www.databasejournal.com/features/mysql/article.php/3922266/Comparing-MySQL-Statement-Based-and-Row-Based-Replication.htm
MySQL will allow both types of statement/row formats in its binary logs. I recommend STATEMENT based. Default binary log format is MIXED which is OK.
Since you are using replicate-ignore-db
and replicate-do-db
, I would trust Statement-Based Replication.
Update for MySQL 5.6.2:
Introduced in MySQL 5.6.2 the binlog_rows_query_log_events
system variable causes a MySQL 5.6.2 or later server to write informational log events such as row query log events into its binary log. So we can identify the SQL that generated the changes.
Reference: 17.1.4.4 Binary Log Options and Variables
All of these approaches show that you gave these things a lot of thought.
You are worried about any pending changes when running FLUSH TABLES WITH READ LOCK;
.
Think about this: When you issue FLUSH TABLES WITH READ LOCK;
, how is replication affected? Recall that replication has two threads
The IO Thread is responsible for communication between Master and Slave. It downloads binary log entries from the Master and stores them in the Slave's relay logs.
The SQL Thread is responsible for
- reading the next SQL statement from the Slave's relay logs and processing them
- maintain are temp tables created within the session of the SQL Thread
When you run FLUSH TABLES WITH READ LOCK;
, only the SQL Thread gets affected because it needs to connect to tables. The IO Thread can still collect binary log entries from the Master and store them in the Slave's relay logs. Any replication lag will simply be caught off guard as is. In light of this, STOP SLAVE;
should be faster than FLUSH TABLES WITH READ LOCK;
. If you are concerned about pending changes, then use STOP SLAVE SQL_THREAD;
instead of STOP SLAVE;
. That way, whatever is last executed on each Master should be checked.
When you do SHOW SLAVE STATUS\G
look for two lines
- Relay_Master_Log_File (line 10)
- Exec_Master_Log_Pos (line 22)
This tells you what was the SQL statement downloaded to the Slave that was last executed.
Knowing this, you could try the following
- Step 01 : On M1 and M2,
STOP SLAVE SQL_THREAD;
- Step 02 : Run
SHOW MASTER STATUS;
on M1 and M2
- Step 03 : Run
SHOW SLAVE STATUS\G
on M1 and M2
- Step 04 : Evaluate this condition
- Does M1's File = M2's Relay_Master_Log_File ?
- Does M2's File = M1's Relay_Master_Log_File ?
- Does M1's Position = M2's Exec_Master_Log_Pos ?
- Does M2's Position = M1's Exec_Master_Log_Pos ?
- Step 05 : If any one of the four conditions in Step 04 is not met
- On M1 and M2,
START SLAVE SQL_THREAD;
- SELECT SLEEP(30);
- Go Back to Step 01
If you get past Step 05 with all four conditions in Step 04, M1 and M2 are in sync.
Once M1 and M2 are frozen simultaneously
- S1 should match M1
- Wait until S1's Seconds_Behind_Master = 0
- M1's File = S1's Relay_Master_Log_File
- M1's Position = S1's Exec_Master_Log_Pos
- S2 should match M2
- Wait until S2's Seconds_Behind_Master = 0
- M2's File = S2's Relay_Master_Log_File
- M2's Position = S2's Exec_Master_Log_Pos
- No need to run
STOP SLAVE;
on S1 or S2
I hope this helps
UPDATE 2012-05-11 17:30 EDT
Once S1 and S2 match up with their respective Master, you could STOP SLAVE;
if you want to. Since M1 and M2 are frozen, no other changes can reach S1 or S2. Thus, STOP SLAVE;
is not a requirement but you do so anyway.
UPDATE 2012-05-11 21:29 EDT
Your Comment
M1/M2 are frozen from receiving updates from one another but not from receiving a legit update from an external client/application, no?
Are you still accepting incoming feeds? You did say in the original question
As I try thinking this out I keep running into gotchas that won't quite work out.
That would certainly be one gotcha. Therefore, discontinue incoming feeds.
Since you want to do FLUSH TABLES WITH READ LOCK;
to M1 and M2, I have one recommendation. Please set this one hour before syncing everything:
SET GLOBAL innodb_max_dirty_pages_pct = 0;
This will clear all dirty pages from the InnoDB Buffer Pool. That way, the time for FLUSH TABLES WITH READ LOCK;
is as fast as possible. When all syncing is done, set it back to 90 (if running MySQL 5.5) or 75 (otherwise).
Your Comment
I could see how M1/M2 were locked if they flushed w/ read lock but it seemed your steps were not including such a step
I was not including such a step because I was under the impression you would disable outside feeds.
Best Answer
Parallel replication allows concurrent transactions out of order, but does not allow concurrent non-transactional updates. Certain SQL statements — including DDL statements — cannot be rolled back, so they cause a "barrier" such that they wait until all parallel workers catch up, and workers are blocked from executing changes after the non-transactional change.
This means there's no race condition. DDL effectively forces a kind of "synchronization".