Eager conflict resolution v5.6
Eager conflict resolution (also known as Eager Replication) prevents conflicts by aborting transactions that conflict with each other with serializable errors during the COMMIT decision process.
You configure it using commit scopes as one of the conflict resolution options for Group Commit.
Usage
To enable Eager conflict resolution, the client needs to switch to a commit scope, which uses it at session level or for individual transactions as shown here:
The client can continue to issue a COMMIT
at the end of the transaction and let PGD manage the two phases:
In this case, the eager_scope
commit scope is defined something like this:
Upgrading?
The old global
commit scope doesn't exist anymore. The above command creates a scope that's the same as the old global
scope with bdr.global_commit_timeout
set to 60s
.
The commit scope group for the Eager conflict resolution rule can only be ALL
or MAJORITY
. Where ALL
is used, the commit_decision
setting must also be set to raft
.
Error handling
Given that PGD manages the transaction, the client needs to check only the result of the COMMIT
. This is advisable in any case, including single-node Postgres.
In case of an origin node failure, the remaining nodes eventually, after at least ABORT ON timeout
, decide to roll back the globally prepared transaction. Raft prevents inconsistent commit versus rollback decisions. However, this requires a majority of connected nodes. Disconnected nodes keep the transactions prepared to eventually commit them (or roll back) as needed to reconcile with the majority of nodes that might have decided and made further progress.
Effects of Eager Replication in general
Increased abort rate
With single-node Postgres, or even with PGD in its default asynchronous
replication mode, errors at COMMIT
time are rare. The added synchronization
step due to the use of a commit scope using eager
for conflict resolution also adds a source of errors. Applications need to be
prepared to properly handle such errors, usually by applying a retry loop.
The rate of aborts depends solely on the workload. Large transactions changing many rows are much more likely to conflict with other concurrent transactions.
Effects of MAJORITY and ALL node replication in general
Increased commit latency
Adding a synchronization step due to the use of a commit scope means more
communication between the nodes, resulting in more latency at commit time. When
ALL
is used in the commit scope, this also means that the availability of the
system is reduced, since any node going down causes transactions to fail.
If one or more nodes are lagging behind, the round-trip delay in getting confirmations can be large, causing high latencies. ALL or MAJORITY node replication adds roughly two network round trips (to the furthest peer node in the worst case). Logical standby nodes and nodes still in the process of joining or catching up aren't included but eventually receive changes.
Before a peer node can confirm its local preparation of the transaction, it also
needs to apply it locally. This further adds to the commit latency, depending on
the size of the transaction. This setting is independent of the
synchronous_commit
setting.