It's now possible to have a rules file with an array of rule
objects, e.g.
[
{
store: [ ... ],
use: [ ... ]
},
{
store: [ ... ],
use: [ ... ]
}
]
This commit only contains the low-level modifications for
supporting that; the upper-level modifications are made in
another commit.
The resultset processing for MySQL requires some extra work as it lacks
the proper SERVER_MORE_RESULTS_EXIST flag in the last EOF packet. Instead,
the first EOF packet has the SERVER_PS_OUT_PARAMS flag which needs to be
interpreted as a SERVER_MORE_RESULTS_EXIST flag for the second EOF packet.
Also corrected the EOF packet handling to do the flag checks in the code
that deals with the EOF packets.
As the modutil_state parameter is now used for more than large packet
tracking, the correct solution is to store this state object in the
readwritesplit session instead of interpreting it to a boolean value.
Added the `transaction_replay_max_size` parameter that controls the
maximum size of a transaction that can be replayed. If the limit is
exceeded, the stored statements are released thus preventing the
transaction from being replayed.
This limitation prevents accidental misuse of the transaction replaying
system when autocommit is disabled. It also allows the user to control the
amount of memory that MaxScale will use.
The transaction retrying behavior is now configurable and documented. The
`transaction_replay` parameter implicitly enables the required
functionality in the router that it needs.
As the current query was added to the transaction log before it finished,
the m_current_query contained a duplicate of the latest transaction log
entry. To correctly log only successful transactions, the statement should
be added only after it has successfully completed. This change also
removed the unnecessary cloning that took place when the statement was
added to the log before it finished.
With the fixed transaction logging, the value of m_current_query can be
stashed for later retrying while the replay process is happening. If the
replay completes successfully and the checksums match, the interrupted
query is retried.
Also added a clarifying comment to can_retry_query to explain why a query
inside a transaction cannot be retried.
Added the initial implementation of transaction replay. Transactions are
only replayed if the master fails when no statement is being executed.
The validity of the replayed transaction is done by verifying that the
checksums of the returned results are equal.
Added a close function into the Trx class to make resetting its state
easier. Also changed the return type of the pop_stmt to GWBUF* as the
places where it is used expect a raw GWBUF pointer.
The queries that make up the transaction are now stored in the router
session while the transaction is in progress. For the time being, the
queries are only used to log extra information about the transaction
contents.
Readwritesplit now calculates checksums for all successful and failed
transactions. This checksum is not of any practical use until the
transaction replaying is implemented.
5.1 to 5.3 are officially not supported anymore, so support can be removed from
the monitor. This allows removing the config parameter "mysql51_replication".
In this case, the server was already a slave and is not being demoted. Also, the file may
contain queries which cannot be ran while a slave connection is running.
Fixed string truncation warnings by reducing max parameter lengths by one
where applicable. The binlogrouter filename lengths are slightly different
so using memcpy to work around the warnings is an adequate "solution"
until the root of the problem is solved.
Removed unnecessary CMake policy settings from qc_sqlite. Adding a
self-dependency on the source file of an external project has no effect
and only caused warnings to be logged.
The SESSION_TRACK_SCHEMA tracking capability handling assumed an encoding
integer in the data. This value does not exist for the data returned by
schema change or session state tracking.
The sql queries are given in two text files, defined by options promotion_sql_file
and demotion_sql_file. The files must exist when monitor starts. The files are read
line by line, ignoring empty lines and lines starting with '#'. All other lines
are sent to the server being promoted, demoted or rejoined. Any error in opening
a file, reading it or executing the contents will cause the entire operation to
fail.
The filed defined in demotion_sql_file is also ran when rejoining a server. This
is to ensure a previously failed master is "demoted" properly when it joins the
cluster.
Large session commands weren't properly handled which caused the router to
think that the trailing end of a multi-packet query was actually a new
query.
This cannot be confidently solved in 2.2 which is why the router session
is now closed the moment a large session command is noticed.
Only commands that can contain an SQL statements should be stored for
retrying (COM_QUERY and COM_EXECUTE). Other commands are either session
commands or do not work with query retrying.
Worker is now the base class of all workers. It has a message
queue and can be run in a thread of its own, or in the calling
thread. Worker can not be used as such, but a concrete worker
class must be derived from it. Currently there is only one
concrete class RoutingWorker.
There is some overlapping in functionality between Worker and
RoutingWorker, as there is e.g. a need for broadcasting a
message to all routing workers, but not to other workers.
Currently other workers can not be created as the array for
holding the pointers to the workers is exactly as large as
there will be RoutingWorkers. That will be changed so that
the maximum number of threads is hardwired to some ridiculous
value such as 128. That's the first step in the path towards
a situation where the number of worker threads can be changed
at runtime.
A new class mxs::Worker will be introduced and mxs::RoutingWorker
will be inherited from that. mxs::Worker will basically only be a
thread with a message-loop.
Once available, all current non-worker threads (but the one
implicitly created by microhttpd) can be creating by inheriting
from that; in practice that means the housekeeping thread, all
monitor threads and possibly the logging thread.
The benefit of this arrangement is that there then will be a general
mechanism for cross thread communication without having to use any
shared data structures.
