PG now allows foreign keys on partitioned tables.
Each foreign key constraint on partitioned table
is propagated down to partitions.
We used to create all constraints on shards when we are creating
a new shard, or when just simply moving a shard from one worker
to another. We also used the same logic when creating a copy of
coordinator table in mx node.
With this change we create the constraint on worker node only if
it is not an inherited constraint.
We used to set the execution mode in the truncate trigger. However,
when multiple tables are truncated with a single command, we could
set the execution mode very late. Instead, now set the execution mode
on the utility hook.
By setting the CPU tuple cost so high, we were triggering JIT. Instead,
we should use parallel_tuple_cost.
See: rhaas.blogspot.com/2018/06/using-forceparallelmode-correctly.html
This reverts commit a2fb5a84f1.
JIT wasn't actually interfering with the operation of Citus, a test was
just written in a way which caused JIT to run for a function on every
row in a 150k-row table.
With this commit, we all partitioned distributed tables with
replication factor > 1. However, we also have many restrictions.
In summary, we disallow all kinds of modifications (including DDLs)
on the partition tables. Instead, the user is allowed to run the
modifications over the parent table.
The necessity for such a restriction have two aspects:
- We need to acquire shard resource locks appropriately
- We need to handle marking partitions INVALID in case
of any failures. Note that, in theory, the parent table
should also become INVALID, which is too aggressive.
We acquire distributed lock on all mx nodes for truncated
tables before actually doing truncate operation.
This is needed for distributed serialization of the truncate
command without causing a deadlock.
Reason for the failure is that PG11 introduced a new relation kind
RELKIND_PARTITIONED_INDEX to be used for partitioned indices.
We expanded our check to cover that case.
This commit uses *_walker instead of *_mutator for performance reasons.
Given that we're only updating a functionId in the tree, the approach
seems fine.
In case a failure happens when a transaction is failed on PREPARE,
we used to hit an assertion for ensuring there is no pending
activity on the connection. However, that's not true after the
changes in #2031. Thus, we've replaced the assertion with a more
generic function call to consume any pending activity, if exists.
In the distributed deadlock detection design, we concluded that prepared transactions
cannot be part of a distributed deadlock. The idea is that (a) when the transaction
is prepared it already acquires all the locks, so cannot be part of a deadlock
(b) even if some other processes blocked on the prepared transaction, prepared transactions
would eventually be committed (or rollbacked) and the system will continue operating.
With the above in mind, we probably had a mistake in terms of memory allocations. For each
backend initialized, we keep a `BackendData` struct. The bug we've introduced is that, we
assumed there would only be `MaxBackend` number of backends. However, `MaxBackends` doesn't
include the prepared transactions and axuliary processes. When you check Postgres' InitProcGlobal`
you'd see that `TotalProcs = MaxBackends + NUM_AUXILIARY_PROCS + max_prepared_xacts;`
This commit aligns with total procs processed with that.
PG11 introduced PROCEDURE concept similar to FUNCTION
Procedure's allow committing/rolling back behavior.
This commmit adds regression tests for procedure calls.
Hadi Moshayedi
Marco Slot
Murat Tuncer
Murat Tuncer
Burak Velioglu
velioglu
Önder Kalacı
Marco Slot
Jason Petersen
Jason Petersen
Metin Döşlü
Brian Cloutier