* Add a new exec_simple_query method
This adds a new `exec_simple_query` method so we can make 'out of band'
queries to servers that don't interfere with pools at all.
In order to reuse startup code for making these simple queries,
we need to set the stats (`Reporter`) optional, so using these
simple queries wont interfere with stats.
* Add auth passthough (auth_query)
Adds a feature that allows setting auth passthrough for md5 auth.
It adds 3 new (general and pool) config parameters:
- `auth_query`: An string containing a query that will be executed on boot
to obtain the hash of a given user. This query have to use a placeholder `$1`,
so pgcat can replace it with the user its trying to fetch the hash from.
- `auth_query_user`: The user to use for connecting to the server and executing the
auth_query.
- `auth_query_password`: The password to use for connecting to the server and executing the
auth_query.
The configuration can be done either on the general config (so pools share them) or in a per-pool basis.
The behavior is, at boot time, when validating server connections, a hash is fetched per server
and stored in the pool. When new server connections are created, and no cleartext password is specified,
the obtained hash is used for creating them, if the hash could not be obtained for whatever reason, it retries
it.
When client authentication is tried, it uses cleartext passwords if specified, it not, it checks whether
we have query_auth set up, if so, it tries to use the obtained hash for making client auth. If there is no
hash (we could not obtain one when validating the connection), a new fetch is tried.
Once we have a hash, we authenticate using it against whathever the client has sent us, if there is a failure
we refetch the hash and retry auth (so password changes can be done).
The idea with this 'retrial' mechanism is to make it fault tolerant, so if for whatever reason hash could not be
obtained during connection validation, or the password has change, we can still connect later.
* Add documentation for Auth passthrough
* Prepared stmt sharding
s
tests
* len check
* remove python test
* latest rust
* move that to debug for sure
* Add the actual tests
* latest image
* Update tests/ruby/sharding_spec.rb
This is an implementation of Query mirroring in PgCat (outlined here #302)
In configs, we match mirror hosts with the servers handling the traffic. A mirror host will receive the same protocol messages as the main server it was matched with.
This is done by creating an async task for each mirror server, it communicates with the main server through two channels, one for the protocol messages and one for the exit signal. The mirror server sends the protocol packets to the underlying PostgreSQL server. We receive from the underlying PostgreSQL server as soon as the data is available and we immediately discard it. We use bb8 to manage the life cycle of the connection, not for pooling since each mirror server handler is more or less single-threaded.
We don't have any connection pooling in the mirrors. Matching each mirror connection to an actual server connection guarantees that we will not have more connections to any of the mirrors than the parent pool would allow.
What
Allows shard selection by the client to come in via comments like /* shard_id: 1 */ select * from foo;
Why
We're using a setup in Ruby that makes it tough or impossible to inject commands on the connection to set the shard before it gets to the "real" SQL being run. Instead we have an updated PG adapter that allows injection of comments before each executed SQL statement. We need this support in pgcat in order to keep some complex shard picking logic in Ruby code while using pgcat for connection management.
Local Testing
Run postgres and pgcat with the default options. Run psql < tests/sharding/query_routing_setup.sql to setup the database for the tests and run ./tests/pgbench/external_shard_test.sh as often as needed to exercise the shard setting comment test.
Least outstanding connections load balancing can improve the load distribution between instances but for Pgcat it may also improve handling slow replicas that don't go completely down. With LoC, traffic will quickly move away from the slow replica without waiting for the replica to be banned.
If all replicas slow down equally (due to a bad query that is hitting all replicas), the algorithm will degenerate to Random Load Balancing (which is what we had in Pgcat until today).
This may also allow Pgcat to accommodate pools with differently-sized replicas.
* Changes shard struct to use vector of ServerConfig
* Adds to query router
* Change client disconnect with error message to warn instead of debug
* Add warning logs for clean up actions
* Add support for multi-database / multi-user pools
* Nothing
* cargo fmt
* CI
* remove test users
* rename pool
* Update tests to use admin user/pass
* more fixes
* Revert bad change
* Use PGDATABASE env var
* send server info in case of admin
* Support reloading the entire config (including sharding logic) without restart.
* Fix bug incorrectly handing error reporting when the shard is set incorrectly via SET SHARD TO command.
selected wrong shard and the connection keep reporting fatal #80.
* Fix total_received and avg_recv admin database statistics.
* Enabling the query parser by default.
* More tests.
* Allow to set shard and set sharding key without quotes
* cover it
* dont look for these in the middle of another query
* friendly regex
* its own response to set shard key
* Refactor query routing into its own module
* commments; tests; dead code
* error message
* safer startup
* hm
* dont have to be public
* wow
* fix ci
* ok
* nl
* no more silent errors
