(cherry picked from commit 90928cfd74)
Fix function signature generation
Fix comment typo
Add test for worker_create_or_replace_object
Add test for recreating distributed functions with OUT/TABLE params
Add test for recreating distributed function that returns setof int
Fix test output
Fix comment
Simply applies
```SQL
SELECT textlike(command, citus.grep_remote_commands)
```
And, if returns true, the command is logged. Else, the log is ignored.
When citus.grep_remote_commands is empty string, all commands are
logged.
This UDF coordinates connectivity checks accross the whole cluster.
This UDF gets the list of active readable nodes in the cluster, and
coordinates all connectivity checks in sequential order.
The algorithm is:
for sourceNode in activeReadableWorkerList:
c = connectToNode(sourceNode)
for targetNode in activeReadableWorkerList:
result = c.execute(
"SELECT citus_check_connection_to_node(targetNode.name,
targetNode.port")
emit sourceNode.name,
sourceNode.port,
targetNode.name,
targetNode.port,
result
- result -> true -> connection attempt from source to target succeeded
- result -> false -> connection attempt from source to target failed
- result -> NULL -> connection attempt from the current node to source node failed
I suggest you use the following query to get an overview on the connectivity:
SELECT bool_and(COALESCE(result, false))
FROM citus_check_cluster_node_health();
Whenever this query returns false, there is a connectivity issue, check in detail.
PostgreSQL does not need calling this function since 7.4 release, and it
is a NOOP.
For more details, check PostgreSQL commit below :
commit dd04e958c8b03c0f0512497651678c7816af3198
Author: Tom Lane <tgl@sss.pgh.pa.us>
Date: Sun Mar 9 03:34:10 2003 +0000
tuplestore_donestoring() isn't needed anymore, but provide a no-op
macro definition so as not to create compatibility problems.
diff --git a/src/include/utils/tuplestore.h b/src/include/utils/tuplestore.h
index b46babacd1..76fe9fb428 100644
--- a/src/include/utils/tuplestore.h
+++ b/src/include/utils/tuplestore.h
@@ -17,7 +17,7 @@
* Portions Copyright (c) 1996-2002, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
- * $Id: tuplestore.h,v 1.8 2003/03/09 02:19:13 tgl Exp $
+ * $Id: tuplestore.h,v 1.9 2003/03/09 03:34:10 tgl Exp $
*
*-------------------------------------------------------------------------
*/
@@ -41,6 +41,9 @@ extern Tuplestorestate *tuplestore_begin_heap(bool randomAccess,
extern void tuplestore_puttuple(Tuplestorestate *state, void *tuple);
+/* tuplestore_donestoring() used to be required, but is no longer used */
+#define tuplestore_donestoring(state) ((void) 0)
+
/* backwards scan is only allowed if randomAccess was specified 'true' */
extern void *tuplestore_gettuple(Tuplestorestate *state, bool forward,
bool *should_free);
Since sequences are not marked as distributed while creating table if no
metadata worker node exists, we are marking all sequences distributed
while syncing metadata explicitly.
We've both allowed delegating functions and procedures from worker nodes
and also prevented delegation if a function/procedure has already been
propagated from another node.
Before that PR we were updating citus.pg_dist_object metadata, which keeps
the metadata related to objects on Citus, only on the coordinator node. In
order to allow using those object from worker nodes (or erroring out with
proper error message) we've started to propagate that metedata to worker
nodes as well.
citus_check_connection_to_node runs a simple query on a remote node and
reports whether this attempt was successful.
This UDF will be used to make sure each worker node can connect to all
the worker nodes in the cluster.
parameters:
nodename: required
nodeport: optional (default: 5432)
return value:
boolean success
As of master branch, Citus does all the modifications to replicated tables
(e.g., reference tables and distributed tables with replication factor > 1),
via 2PC and avoids any shardstate=3. As a side-effect of those changes,
handling node failures for replicated tables change.
With this PR, when one (or multiple) node failures happen, the users would
see query errors on modifications. If the problem is intermitant, that's OK,
once the node failure(s) recover by themselves, the modification queries would
succeed. If the node failure(s) are permenant, the users should call
`SELECT citus_disable_node(...)` to disable the node. As soon as the node is
disabled, modification would start to succeed. However, now the old node gets
behind. It means that, when the node is up again, the placements should be
re-created on the node. First, use `SELECT citus_activate_node()`. Then, use
`SELECT replicate_table_shards(...)` to replicate the missing placements on
the re-activated node.
With this commit, we make sure to use a dedicated connection per
node for all the metadata operations within the same transaction.
This is needed because the same metadata (e.g., metadata includes
the distributed table on the workers) can be modified accross
multiple connections.
With this connection we guarantee that there is a single metadata connection.
But note that this connection can be used for any other operation.
In other words, this connection is not only reserved for metadata
operations.
The checks for preventing to remove a node are very much reference
table centric. We are soon going to add the same checks for replicated
tables. So, make the checks generic such that:
(a) replicated tables fit naturally
(b) we can the same checks in `citus_disable_node`.
We re-define the meaning of active shard placement. It used
to only be defined via shardstate == SHARD_STATE_ACTIVE.
Now, we also add one more check. The worker node that the
placement is on should be active as well.
This is a preparation for supporting citus_disable_node()
for MX with multiple failures at the same time.
With this change, the maintanince daemon only needs to
sync the "node metadata" (e.g., pg_dist_node), not the
shard metadata.
Before this commit, we acquire the metadata locks on the reference
tables while removing/disabling a node on all the MX nodes.
Although it has some marginal benefits, such as a concurrent
modification during remove/disable node blocks, instead of erroring
out, the drawbacks seems worse. Both citus_remove_node and citus_disable_node
are not tolerant to multiple node failures.
With this commit, we relax the locks. The implication is that while
a node is removed/disabled, users might see query errors. On the
other hand, this change becomes removing/disabling nodes more
tolerant to multiple node failures.
When refactoring storage layer in #4907, we deleted the code that allows
overwriting a disk page previously written but not known by metadata.
Readers can see the change that introduced the code allows doing so in
commit a8da9acc63.
The reasoning was that; as of 10.2, we started aligning page
reservations (`AlignReservation`) for subsequent writes right after
allocating pages from disk. That means, even if writer transaction
fails, subsequent writes are guaranteed to allocate a new page and write
to there. For this reason, attempting to write to a page allocated
before is not possible for a columnar table that user created when using
v10.2.x.
However, since the older versions of columnar doesn't do that, following
example scenario can still result in writing to such disk page, even if
user now upgraded to v10.2.x. This is because, when upgrading storage to
2.0 (`ColumnarStorageUpdateIfNeeded`), we calculate `reservedOffset` of
the metapage based on the highest used address known by stripe
metadata (`GetHighestUsedAddressAndId`). However, stripe metadata
doesn't have entries for aborted writes. As a result, highest used
address would be computed by ignoring pages that are allocated but not
used.
- User attempts writing to columnar table on Citus v10.0x/v10.1x.
- Write operation fails for some reason.
- User upgrades Citus to v10.2.x.
- When attempting to write to same columnar table, they hit to "attempt
to write columnar data .." error since write operation done in the
older version of columnar already allocated that page, and now we are
overwriting it.
For this reason, with this commit, we re-do the change done in
a8da9acc63.
And for the reasons given above, it wasn't possible to add a test for
this commit via usual code-paths. For this reason, added a UDF only for
testing purposes so that we can reproduce the exact scenario in our
regression test suite.
During pg upgrades, we have seen that it is not guaranteed that a
columnar table will be created after metadata objects got created.
Prior to changes done in this commit, we had such a dependency
relationship in `pg_depend`:
```
columnar_table ----> columnarAM ----> citus extension
^ ^
| |
columnar.storage_id_seq -------------------- |
|
columnar.stripe -------------------------------
```
Since `pg_upgrade` just knows to follow topological sort of the objects
when creating database dump, above dependency graph doesn't imply that
`columnar_table` should be created before metadata objects such as
`columnar.storage_id_seq` and `columnar.stripe` are created.
For this reason, with this commit we add new records to `pg_depend` to
make columnarAM depending on all rel objects living in `columnar`
schema. That way, `pg_upgrade` will know it needs to create those before
creating `columnarAM`, and similarly, before creating any tables using
`columnarAM`.
Note that in addition to inserting those records via installation script,
we also do the same in `citus_finish_pg_upgrade()`. This is because,
`pg_upgrade` rebuilds catalog tables in the new cluster and that means,
we must insert them in the new cluster too.
- [x] Add some more regression test coverage
- [x] Make sure returning works fine in case of
local execution + remote execution
(task->partiallyLocalOrRemote works as expected, already added tests)
- [x] Implement locking properly (and add isolation tests)
- [x] We do #shardcount round-trips on `SerializeNonCommutativeWrites`.
We made it a single round-trip.
- [x] Acquire locks for subselects on the workers & add isolation tests
- [x] Add a GUC to prevent modification from the workers, hence increase the
coordinator-only throughput
- The performance slightly drops (~%15), unless
`citus.allow_modifications_from_workers_to_replicated_tables`
is set to false
Drop extension might cascade to columnar.options before dropping a
columnar table. In that case, we were getting below error when opening
columnar.options to delete records for the columnar table that we are
about to drop.: "ERROR: could not open relation with OID 0".
I somehow reproduced this bug easily when upgrading pg, that is why
adding added the test to after_pg_upgrade_schedule.
We recently introduced a set of patches to 10.2, and introduced 10.2-4
migration version. This migration version only resides on `release-10.2`
branch, and is missing on our default branch. This creates a problem
because we do not have a valid migration path from 10.2 to latest 11.0.
To remedy this issue, I copied the relevant migration files from
`release-10.2` branch, and renamed some of our migration files on
default branch to make sure we have a linear upgrade path.
Before this commit, we required the user to be owner of the shard/table
in order to call lock_shard_resources.
However, that is too restrictive. We can have users with GRANTS
to the table who are not owners of the tables/shards.
With this commit, we allow such patterns.
This change creates a slightly higher abstraction of the `PartitionedResultDestReceiver` where it decouples the partitioning from writing it to a file. This allows for easier reuse for other `DestReceiver`'s that would like to route different tuples to different `DestReceiver`'s.
Originally there was a lot of state kept in `PartitionedResultDestReceiver` to be able to lazily create `FileDestReceivers` when the first tuple arrived for that target. This convoluted the implementation of the processing of tuples with where they should go.
This refactor changes that where it makes the `PartitionedResultDestReceiver` completely agnostic of what kind of Receivers it is writing to. When constructed you pass it a list of `DestReceiver` compatible pointers with the length of `partitionCount`. Internally the `PartitionedResultDestReceiver` keeps track of which `DestReceiver`'s have been started or not, and start them when they first receive a tuple.
Alternatively, if the instantiating code of the `PartitionedResultDestReceiver` wants, the startup can be turned from lazily to eagerly. When the startup is eager (not lazy) all `rStartup` functions on the list of `DestReceiver`'s are called during the startup of the `PartitionedResultDestReceiver` and marked as such.
A downside of this approach is the following. On highly partitioned destinations we now need to allocate a `FileDestReceiver` for every target, _always_. When the data passed into the `PartitionedResultDestReceiver` is highly skewed to a small set of `FileDestReceiver`'s this will waste some memory. Given the small size of a `FileDestReceiver`, and the fact that actual file handles are only created during the processing of the startup of the `FileDestReceiver` I think this memory waste is not a problem. If this would become a problem we could refactor the source list into some kind of generator object which can generate the `DestReceiver`'s on the fly.
* Refactor some checks in citus local tables
* all existing citus local tables are auto converted after upgrade
* Update warning messages in CreateCitusLocalTable
* Hide notice msg for auto converting local tables
* Hide hint msg
Co-authored-by: Ahmet Gedemenli <afgedemenli@gmail.com>
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