Scrub compaction can pick up input sstables from maintenance sstable set
but on compaction completion, it doesn't update the maintenance set
leaving the original sstable in set after it has been scrubbed. To fix
this, on compaction completion has to update the maintenance sstable if
the input originated from there. This PR solves the issue by updating the
correct sstable_sets on compaction completion.
Fixes#20030
This issue has existed since the introduction of main and maintenance sstable sets into scrub compaction. It would be good to have the fix backported to versions 6.1 and 6.2.
Closesscylladb/scylladb#21582
* github.com:scylladb/scylladb:
compaction: remove unused `update_sstable_lists_on_off_strategy_completion`
compaction_group: replace `update_sstable_lists_on_off_strategy_completion`
compaction_group: rename `update_main_sstable_list_on_compaction_completion`
compaction_group: update maintenance sstable set on scrub compaction completion
compaction_group: store table::sstable_list_builder::result in replacement_desc
table::sstable_list_builder: remove old sstables only from current list
table::sstable_list_builder: return removed sstables from build_new_list
(cherry picked from commit 58baeac0ad)
Closesscylladb/scylladb#21790
To fix a race between split and repair here c1de4859d8, a new sstable
generated during streaming can be split before being attached to the sstable
set. That's to prevent an unsplit sstable from reaching the set after the
tablet map is resized.
So we can think this split is an extension of the sstable writer. A failure
during split means the new sstable won't be added. Also, the duration of split
is also adding to the time erm is held. For example, repair writer will only
release its erm once the split sstable is added into the set.
This single-sstable split is going through run_custom_job(), which serializes
with other maintenance tasks. That was a terrible decision, since the split may
have to wait for ongoing maintenance task to finish, which means holding erm
for longer. Additionally, if split monitor decides to run split on the entire
compaction group, it can cause single-sstable split to be aborted since the
former wants to select all sstables, propagating a failure to the streaming
writer.
That results in new sstable being leaked and may cause problems on restart,
since the underlying tablet may have moved elsewhere or multiple splits may
have happened. We have some fragility today in cleaning up leaked sstables on
streaming failure, but this single-sstable split made it worse since the
failure can happen during normal operation, when there's e.g. no I/O error.
It makes sense to kill run_custom_job() usage, since the single-sstable split
is offline and an extension of sstable writing, therefore it makes no sense to
serialize with maintenance tasks. It must also inherit the sched group of the
process writing the new sstable. The inheritance happens today, but is fragile.
Fixes#20626.
Closesscylladb/scylladb#20737
* github.com:scylladb/scylladb:
tablet: Fix single-sstable split when attaching new unsplit sstables
replica: Fix tablet split execute after restart
(cherry picked from commit bca8258150)
Ref scylladb/scylladb#21415
During split prepare phase, there will be more than 1 compaction group with
overlapping token range for a given replica.
Assume tablet 1 has sstable A containing deleted data, and sstable B containing
a tombstone that shadows data in A.
Then split starts:
1) sstable B is split first, and moved from main (unsplit) group to a
split-ready group
2) now compaction runs in split-ready group before sstable A is split
tombstone GC logic today only looks at underlying group, so compaction is step
2 will discard the deleted data in A, since it belongs to another group (the
unsplit one), and so the tombstone can be purged incorrectly.
To fix it, compaction will now work with all uncompacting sstables that belong
to the same replica, since tombstone GC requires all sstables that possibly
contain shadowed data to be available for correct decision to be made.
Fixes#20044.
Signed-off-by: Raphael S. Carvalho <raphaelsc@scylladb.com>
(cherry picked from commit 93815e0649)
On the read path, the compacting reader is applied only to the sstable
reader. This can cause an expired tombstone from an sstable to be purged
from the request before it has a chance to merge with deleted data in
the memtable leading to data resurrection.
Fix this by checking the memtables before deciding to purge tombstones
from the request on the read path. A tombstone will not be purged if a
key exists in any of the table's memtables with a minimum live timestamp
that is lower than the maximum purgeable timestamp.
Fixes#20916
`perf-simple-query` stats before and after this fix :
`build/Dev/scylla perf-simple-query --smp=1 --flush` :
```
// Before this Fix
// ---------------
94941.79 tps ( 71.1 allocs/op, 0.0 logallocs/op, 14.1 tasks/op, 59393 insns/op, 24029 cycles/op, 0 errors)
97551.14 tps ( 71.1 allocs/op, 0.0 logallocs/op, 14.1 tasks/op, 59376 insns/op, 23966 cycles/op, 0 errors)
96599.92 tps ( 71.1 allocs/op, 0.0 logallocs/op, 14.1 tasks/op, 59367 insns/op, 23998 cycles/op, 0 errors)
97774.91 tps ( 71.1 allocs/op, 0.0 logallocs/op, 14.1 tasks/op, 59370 insns/op, 23968 cycles/op, 0 errors)
97796.13 tps ( 71.1 allocs/op, 0.0 logallocs/op, 14.1 tasks/op, 59368 insns/op, 23947 cycles/op, 0 errors)
throughput: mean=96932.78 standard-deviation=1215.71 median=97551.14 median-absolute-deviation=842.13 maximum=97796.13 minimum=94941.79
instructions_per_op: mean=59374.78 standard-deviation=10.78 median=59369.59 median-absolute-deviation=6.36 maximum=59393.12 minimum=59367.02
cpu_cycles_per_op: mean=23981.67 standard-deviation=32.29 median=23967.76 median-absolute-deviation=16.33 maximum=24029.38 minimum=23947.19
// After this Fix
// --------------
95313.53 tps ( 71.1 allocs/op, 0.0 logallocs/op, 14.1 tasks/op, 59392 insns/op, 24058 cycles/op, 0 errors)
97311.48 tps ( 71.1 allocs/op, 0.0 logallocs/op, 14.1 tasks/op, 59375 insns/op, 24005 cycles/op, 0 errors)
98043.10 tps ( 71.1 allocs/op, 0.0 logallocs/op, 14.1 tasks/op, 59381 insns/op, 23941 cycles/op, 0 errors)
96750.31 tps ( 71.1 allocs/op, 0.0 logallocs/op, 14.1 tasks/op, 59396 insns/op, 24025 cycles/op, 0 errors)
93381.21 tps ( 71.1 allocs/op, 0.0 logallocs/op, 14.1 tasks/op, 59390 insns/op, 24097 cycles/op, 0 errors)
throughput: mean=96159.93 standard-deviation=1847.88 median=96750.31 median-absolute-deviation=1151.55 maximum=98043.10 minimum=93381.21
instructions_per_op: mean=59386.60 standard-deviation=8.78 median=59389.55 median-absolute-deviation=6.02 maximum=59396.40 minimum=59374.73
cpu_cycles_per_op: mean=24025.13 standard-deviation=58.39 median=24025.17 median-absolute-deviation=32.67 maximum=24096.66 minimum=23941.22
```
This PR fixes a regression introduced in ce96b472d3 and should be backported to older versions.
Closesscylladb/scylladb#20985
* github.com:scylladb/scylladb:
topology-custom: add test to verify tombstone gc in read path
replica/table: check memtable before discarding tombstone during read
compaction_group: track maximum timestamp across all sstables
(cherry picked from commit 519e167611)
Backported from #20985 to 6.2.
Signed-off-by: Lakshmi Narayanan Sreethar <lakshmi.sreethar@scylladb.com>
Closesscylladb/scylladb#21251
This is a manual backport of #20788
When tablets are migrated with file-based streaming, we can have a situation where a tombstone is garbage collected before the data it shadows lands. For instance, if we have a tablet replica with 3 sstables:
1. sstable containing an expired tombstone
2. sstable with additional data
3. sstable containing data which is shadowed by the expired tombstone in sstable 1
If this tablet is migrated, and the sstables are streamed in the order listed above, the first two sstables can be compacted before the third sstable arrives. In that case, the expired tombstone will be garbage collected, and data in the third sstable will be resurrected after it arrives to the pending replica.
This change fixes this problem by disabling tombstone garbage collection for pending replicas.
This fixes a problem in Enterprise, but the change is in OSS in order to have as few differences between OSS and Enterprise and to have a common infrastructure for disabling tombstone GC on pending replicas.
Fixes#21090Closesscylladb/scylladb#21061
* github.com:scylladb/scylladb:
test: test tombstone GC disabled on pending replica
tablet_storage_group_manager: update tombstone_gc_enabled in compaction group
database::table: add tombstone_gc_enabled(locator::tablet_id)
In order to avoid cases during tablet migrations where we garbage
collect tombstones before the data it shadows arrives, we will
disable tombstone GC on pending replicas.
To achieve this we added a tombston_gc_enabled flag to compaction_group.
This flag is updated from updte_effective_repliction_map method of the
tablet_storage_group_manager class.
During migration cleanup, there's a small window in which the storage
group was stopped but not yet removed from the list. So concurrent
operations traversing the list could work with stopped groups.
During a test which emitted schema changes during migrations,
a failure happened when updating the compaction strategy of a table,
but since the group was stopped, the compaction manager was unable
to find the state for that group.
In order to fix it, we'll skip stopped groups when traversing the
list since they're unused at this stage of migration and going away
soon.
Fixes#20699.
Signed-off-by: Raphael S. Carvalho <raphaelsc@scylladb.com>
(cherry picked from commit cf58674029)
Closesscylladb/scylladb#20899
Cleanup of a deallocated tablet throws an exception.
Since failed cleanup is retried, we end up in an infinite loop.
Ignore cleanup of deallocated storage groups.
Fixes: #19752.
Needs to be backported to all branches with tablets (6.0 and later)
Closesscylladb/scylladb#20584
* github.com:scylladb/scylladb:
test: check if cleanup of deallocated sg is ignored
replica: ignore cleanup of deallocated storage group
Currently, attempt to cleanup deallocated storage group throws
an exception. Failed tablet cleanup is retried, stucking
in an endless loop.
Ignore cleanup of deallocated storage group.
When purging regular tombstone consult the min_live_timestamp, if available.
This is safe since we don't need to protect dead data from resurrection, as it is already dead.
For shadowable_tombstones, consult the min_memtable_live_row_marker_timestamp,
if available, otherwise fallback to the min_live_timestamp.
If we see in a view table a shadowable tombstone with time T, then in any row where the row marker's timestamp is higher than T the shadowable tombstone is completely ignored and it doesn't hide any data in any column, so the shadowable tombstone can be safely purged without any effect or risk resurrecting any deleted data.
In other words, rows which might cause problems for purging a shadowable tombstone with time T are rows with row markers older or equal T. So to know if a whole sstable can cause problems for shadowable tombstone of time T, we need to check if the sstable's oldest row marker (and not oldest column) is older or equal T. And the same check applies similarly to the memtable.
If both extended timestamp statistics are missing, fallback to the legacy (and inaccurate) min_timestamp.
Fixesscylladb/scylladb#20423Fixesscylladb/scylladb#20424
> [!NOTE]
> no backport needed at this time
> We may consider backport later on after given some soak time in master/enterprise
> since we do see tombstone accumulation in the field under some materialized views workloads
Closesscylladb/scylladb#20446
* github.com:scylladb/scylladb:
cql-pytest: add test_compaction_tombstone_gc
sstable_compaction_test: add mv_tombstone_purge_test
sstable_compaction_test: tombstone_purge_test: test that old deleted data do not inhibit tombstone garbage collection
sstable_compaction_test: tombstone_purge_test: add testlog debugging
sstable_compaction_test: tombstone_purge_test: make_expiring: use next_timestamp
sstable, compaction: add debug logging for extended min timestamp stats
compaction: get_max_purgeable_timestamp: use memtable and sstable extended timestamp stats
compaction: define max_purgeable_fn
tombstone: can_gc_fn: move declaration to compaction_garbage_collector.hh
sstables: scylla_metadata: add ext_timestamp_stats
compaction_group, storage_group, table_state: add extended timestamp stats getters
sstables, memtable: track live timestamps
memtable_encoding_stats_collector: update row_marker: do nothing if missing
Before we add a new, is_shadowable, parameter to it.
And define global `can_always_purge` and `can_never_purge`
functions, a-la `always_gc` and `never_gc`.
Signed-off-by: Benny Halevy <bhalevy@scylladb.com>
To return the minimum live timestamp and live row-marker
timestamp across a compaction_group, storage_group, or
table_state.
Signed-off-by: Benny Halevy <bhalevy@scylladb.com>
Added a new parameter `consider_only_existing_data` to major compaction
API endpoints. When enabled, major compaction will:
- Force-flush all tables.
- Force a new active segment in the commit log.
- Compact all existing SSTables and garbage-collect tombstones by only
checking the SSTables being compacted. Memtables, commit logs, and
other SSTables not part of the compaction will not be checked, as they
will only contain newer data that arrived after the compaction
started.
The `consider_only_existing_data` is passed down to the compaction
descriptor's `gc_check_only_compacting_sstables` option to ensure that
only the existing data is considered for garbage collection.
The option is also passed to the `maybe_flush_commitlog` method to make
sure all the tables are flushed and a new active segment is created in
the commit log.
Fixes#19728
Signed-off-by: Lakshmi Narayanan Sreethar <lakshmi.sreethar@scylladb.com>
Currently "table removal" is logged as a reason of compaction stop for table drop,
tablet cleanup and tablet split. Modify log to reflect the reason.
Closesscylladb/scylladb#20042
* github.com:scylladb/scylladb:
test: add test to check compaction stop log
compaction: fix compaction group stop reason
compaction_manager::remove passes "table removal" as a reason
of stopping ongoing compactions, but currently remove method
is also called when a tablet is migrated or split.
Pass the actual reason of compaction stop, so that logs aren't
misleading.
Now, when each shard storage_group_manager keeps
only the storage_groups for the tablet replica it owns,
we can simple return the storage_group map size
instead of counting the number of tablet replicas
mapped to this shard.
Add a unit test that sums the tablet count
on all shards and tests that the sum is equal
to the configured default `initial_tablets.
Fixes#18909
Signed-off-by: Benny Halevy <bhalevy@scylladb.com>
Closesscylladb/scylladb#20223
Consider the following:
```
T
0 split prepare starts
1 repair starts
2 split prepare finishes
3 repair adds unsplit sstables
4 repair ends
5 split executes
```
If repair produces sstable after split prepare phase, the replica will not split that sstable later, as prepare phase is considered completed already. That causes split execution to fail as replicas weren't really prepared. This also can be triggered with load-and-stream which shares the same write (consumer) path.
The approach to fix this is the same employed to prevent a race between split and migration. If migration happens during prepare phase, it can happen source misses the split request, but the tablet will still be split on the destination (if needed). Similarly, the repair writer becomes responsible for splitting the data if underlying table is in split mode. That's implemented in replica::table for correctness, so if node crashes, the new sstable missing split is still split before added to the set.
Fixes#19378.
Fixes#19416.
**Please replace this line with justification for the backport/\* labels added to this PR**
Closesscylladb/scylladb#19427
* github.com:scylladb/scylladb:
tablets: Fix race between repair and split
compaction: Allow "offline" sstable to be split
The reconcilable_result is built as it would be constructed for
forward read queries for tables with reversed order.
Mutations constructed for reversed queries are consumed forward.
Drop overloaded reversed functions that reverse read_command and
reconcilable_result directly and keep only those requiring smart
pointers. They are not used any more.
Remove schema reversing in query() and query_mutations() methods.
Instead, a reversed schema shall be passed for reversed queries.
Rename a schema variable from s into query_schema for readability.
Reverse reads have already been with us for a while, thus this back
door option to read entire paritions forward and reversing them after
can be retired.
Consider the following:
T
0 split prepare starts
1 repair starts
2 split prepare finishes
3 repair adds unsplit sstables
4 repair ends
5 split executes
If repair produces sstable after split prepare phase, the replica
will not split that sstable later, as prepare phase is considered
completed already. That causes split execution to fail as replicas
weren't really prepared. This also can be triggered with
load-and-stream which shares the same write (consumer) path.
The approach to fix this is the same employed to prevent a race
between split and migration. If migration happens during prepare
phase, it can happen source misses the split request, but the
tablet will still be split on the destination (if needed).
Similarly, the repair writer becomes responsible for splitting
the data if underlying table is in split mode. That's implemented
in replica::table for correctness, so if node crashes, the new
sstable missing split is still split before added to the set.
Fixes#19378.
Fixes#19416.
Signed-off-by: Raphael S. Carvalho <raphaelsc@scylladb.com>
Fixes#19960
Write path for sstables/commitlog need to handle the fact that IO extensions can
generate errors, some of which should be considered retry-able, and some that should,
similar to system IO errors, cause the node to go into isolate mode.
One option would of course be for extensions to simply generate std::system_errors,
with system_category and appropriate codes. But this is probably a bad idea, since
it makes it more muddy at which level an error happened, as well as limits the
expressibility of the error.
This adds three distinct types (sharing base) distinguishing permission, availabilty
and configuration errors. These are treated akin to EACCESS, ENOENT and EINVAL in
disk error handler and memtable write loop.
Tests updated to use and verify behaviour.
Closesscylladb/scylladb#19961
After removal of rwlock (53a6ec05ed), the race was introduced because the order that
compaction groups of a tablet are closed, is no longer deterministic.
Some background first:
Split compaction runs in main (unsplit) group, and adds sstable to left and right groups
on completion.
The race works as follow:
1) split compaction starts on main group of tablet X
2) tablet X reaches cleanup stage, so its compaction groups are closed in parallel
3) left or right group are closed before main (more likely when only main has flush work to do)
4) split compaction completes, and adds sstable to left and right
5) if e.g left is closed, adjusting backlog tracker will trigger an exception, and since that
happens in row cache update's execute(), node crashes.
The problem manifested as follow:
[shard 0: gms] raft_topology - Initiating tablet cleanup of 5739b9b0-49d4-11ef-828f-770894013415:15 on 102a904a-0b15-4661-ba3f-f9085a5ad03c:0
...
[shard 0:strm] compaction - [Split keyspace1.standard1 009e2f80-49e5-11ef-85e3-7161200fb137] Splitting [/var/lib/scylla/data/keyspace1/...]
...
[shard 0:strm] cache - Fatal error during cache update: std::out_of_range (Compaction state for table [0x600007772740] not found),
at: ...
--------
seastar::continuation<seastar::internal::promise_base_with_type<void>, row_cache::do_update(...
--------
seastar::internal::do_with_state<std::tuple<row_cache::external_updater, std::function<seastar::future<void> ()> >, seastar::future<void> >
--------
seastar::internal::coroutine_traits_base<void>::promise_type
--------
seastar::internal::coroutine_traits_base<void>::promise_type
--------
seastar::(anonymous namespace)::thread_wake_task
--------
seastar::continuation<seastar::internal::promise_base_with_type<sstables::compaction_result>, seastar::async<sstables::compaction::run(...
seastar::continuation<seastar::internal::promise_base_with_type<sstables::compaction_result>, seastar::future<sstables::compaction_resu...
From the log above, it can be seen cache update failure happens under streaming sched group and
during compaction completion, which was good evidence to the cause.
Problem was reproduced locally with the help of tablet shuffling.
Fixes: #19873.
Signed-off-by: Raphael S. Carvalho <raphaelsc@scylladb.com>
Closesscylladb/scylladb#19987
If parent_info argument of compaction_manager::perform_compaction
is std::nullopt, then created compaction executor isn't tracked by task
manager. Currently, all compaction operations should by visible in task
manager.
Modify split methods to keep split executor in task manager. Get rid of
the option to bypass task manager.
Closesscylladb/scylladb#19995
* github.com:scylladb/scylladb:
compaction: replace optional<task_info> with task_info param
compaction: keep split executor in task manager
assert() is traditionally disabled in release builds, but not in
scylladb. This hasn't caused problems so far, but the latest abseil
release includes a commit [1] that causes a 1000 insn/op regression when
NDEBUG is not defined.
Clearly, we must move towards a build system where NDEBUG is defined in
release builds. But we can't just define it blindly without vetting
all the assert() calls, as some were written with the expectation that
they are enabled in release mode.
To solve the conundrum, change all assert() calls to a new SCYLLA_ASSERT()
macro in utils/assert.hh. This macro is always defined and is not conditional
on NDEBUG, so we can later (after vetting Seastar) enable NDEBUG in release
mode.
[1] 66ef711d68Closesscylladb/scylladb#20006
compaction_manager::perform_compaction does not create task manager
task for compaction if parent_info is set to std::nullopt. Currently,
we always want to create task manager task for compaction.
Remove optional from task info parameters which start compaction.
Track all compactions with task manager.
If perform_compaction gets std::nullopt as a parent info then
the executor won't be tracked by task manager.
Modify storage_group::split call so that it passes empty task_info
instead of nullopt to track split.
rwlock was added to protect iterations against concurrent updates to the map.
the updates can happen when allocating a new tablet replica or removing an old one (tablet cleanup).
the rwlock is very problematic because it can result in topology changes blocked, as updating
token metadata takes the exclusive lock, which is serialized with table wide ops like
split / major / explicit flush (and those can take a long time).
to get rid of the lock, we can copy the storage group map and guard individual groups with a gate
(not a problem since map is expected to have a maximum of ~100 elements).
so cleanup can close that gate (carefully closed after stopping individual groups such that
migrations aren't blocked by long-running ops like major), and ongoing iterations (e.g. triggered
by nodetool flush) can skip a group that was closed, as such a group is being migrated out.
Check documentation added to compaction_group.hh to understand how
concurrent iterations and updates to the map work without the rwlock.
Yielding variants that iterate over groups are no longer returning group
id since id stability can no longer be guaranteed without serializing split
finalization and iteration.
Fixes#18821.
Signed-off-by: Raphael S. Carvalho <raphaelsc@scylladb.com>
It was added to make integration of storage groups easier, but it's
complicated since it's another source of truth and we could have
problems if it becomes inconsistent with the group map.
Fixes#18506.
Signed-off-by: Raphael S. Carvalho <raphaelsc@scylladb.com>
We currently disable tombstone GC for compaction done on the read path of streaming and repair, because those expired tombstones can still prevent data resurrection. With time-based tombstone GC, missing a repair for long enough can cause data resurrection because a tombstone is potentially GC'd before it could be spread to every node by repair. So repair disseminating these expired tombstones helps clusters which missed repair for long enough. It is not a guarantee because compaction could have done the GC itself, but it is better than nothing.
This last resort is getting less important with repair-based tombstone GC. Furthermore, we have seen this cause huge repair amplification in a cluster, where expired tombstones triggered repair replicating otherwise identical rows.
This series makes tombstone GC on the streaming/repair compaction path configurable with a config item. This new config item defaults to `false` (current behaviour), setting it to `true`, will enable tombstone GC.
Fixes: https://github.com/scylladb/scylladb/issues/19015
Not a regression, no backport needed
Closesscylladb/scylladb#19016
* github.com:scylladb/scylladb:
test/topology_custom/test_repair: add test for enable_tombstone_gc_for_streaming_and_repair
replica/table: maybe_compact_for_streaming(): toggle tombstone GC based on the control flag
replica: propagate enable_tombstone_gc_for_streaming_and_repair to maybe_compact_for_streaming()
db/config: introduce enable_tombstone_gc_for_streaming_and_repair
Currently, a pending replica that applies a write on a table that has
materialized views, will build all the view updates as a normal replica,
only to realize at a late point, in db::view::get_view_natural_endpoint(),
that it doesn't have a paired view replica to send the updates to. It will
then either drop the view updates, or send them to a pending view
replica, if such exists.
This work is unnecessary since it may be dropped, and even if there is a
pending view replica to send the updates to, the updates that are built
by the pending replica may be wrong since it may have incomplete
information.
This commit fixes the inefficiency by skipping the view update building
step when applying an update on a pending replica.
The metric total_view_updates_on_wrong_node is added to count the cases
that a view update is determined to be unnecessary.
The test reproduces the scenario of writing to a table and applying
the update on a pending replica, and verifies that the pending replica
doesn't try to build view updates.
Fixesscylladb/scylladb#19152Closesscylladb/scylladb#19488
C++23 made std::unique_ptr constexpr. A side effect of this (presumably)
is that the compiler compiles it more eagerly, requiring the full definition
of the class in std::make_unique, while it previously was content with
finding the definition later.
One victim of this change is compaction_group::table_state; define
it earlier to build with C++23.
Define compaction_group::~compaction_group() out-of-line to prevent
problems instantiating compaction_group::_table_state, which is an
std::unique_ptr. In C++23, std::unique_ptr is constexpr, which means
its methods (in this case the destructor) require seeing the definition
of the class at the point of instantiation.
Now enable_tombstone_gc_for_streaming_and_repair is wired in all the way
to maybe_compact_for_streaming(), so we can implement the toggling of
tombstone GC based on it.
flat_mutation_reader_v2 was introduced in a pair of commits in 2021:
e3309322c3 "Clone flat_mutation_reader related classes into v2 variants"
08b5773c12 "Adapt flat_mutation_reader_v2 to the new version of the API"
as a replacement for flat_mutation_reader, using range_tombstone_change
instead of range_tombstone to represent represent range tombstones. See
those commits for more information.
The transition was incremental; the last use of the original
flat_mutation_reader was removed in 2022 in commit
026f8cc1e7 "db: Use mutation_partition_v2 in mvcc"
In turn, flat_mutation_reader was introduced in 2017 in commit
748205ca75 "Introduce flat_mutation_reader"
To transition from a mutation_reader that nested rows within
a partition in a separate stream, to a flat reader that streamed
partitions and rows in the same stream.
Here, we reclaim the original name and rename the awkward
flat_mutation_reader_v2 to mutation_reader.
Note that mutation_fragment_v2 remains since we still use the original
for compatibilty, sometimes.
Some notes about the transition:
- files were also renamed. In one case (flat_mutation_reader_test.cc), the
rename target already existed, so we rename to
mutation_reader_another_test.cc.
- a namespace 'mutation_reader' with two definitions existed (in
mutation_reader_fwd.hh). Its contents was folded into the mutation_reader
class. As a result, a few #includes had to be adjusted.
Closesscylladb/scylladb#19356
backport not needed, these are just cleanups.
Closesscylladb/scylladb#19260
* github.com:scylladb/scylladb:
replica: simplify perform_cleanup_compaction()
replica: return storage_group by reference on storage_group_for*()
replica: devirtualize storage_group_of()
with tablets, we're expected to have a worst of ~100 tablets in a given
table and shard, so let's avoid linear search when looking for the
memtable_list in a range scan. we're bounded by ~100 elements, so
shouldn't be a big problem, but it's an inefficiency we can easily
get rid of.
Signed-off-by: Raphael S. Carvalho <raphaelsc@scylladb.com>
Closesscylladb/scylladb#19286
those functions cannot return nullptr, will throw when group is not
found, so better return ref instead.
Signed-off-by: Raphael S. Carvalho <raphaelsc@scylladb.com>
This config item is propagated to the table object via table::config. Although the field in `table::config`, used to propagate the value, was `utils::updateable_value<T>`, it was assigned a constant and so the live-update chain was broken.
This series fixes this and adds a test which fails before the patch and passes after. The test needed new test infrastructure, around the failure injection api, namely the ability to exfiltrate the value of internal variable. This infrastructure is also added in this series.
Fixes: https://github.com/scylladb/scylladb/issues/18674
- [x] This patch has to be backported because it fixes broken functionality
Closesscylladb/scylladb#18705
* github.com:scylladb/scylladb:
test/topology_custom: add test for enable_compacting_data_for_streaming_and_repair live-update
test/pylib: rest_client: add get_injection()
api/error_injection: add getter for error_injection
utils/error_injection: add set_parameter()
replica/database: fix live-update enable_compacting_data_for_streaming_and_repair
Consider the following:
1) table A has N tablets and views
2) migration starts for a tablet of A from node 1 to 2.
3) migration is at write_both_read_old stage
4) coordinator will push writes to both nodes (pending and leaving)
5) A has view, so writes to it will also result in reads (table::push_view_replica_updates())
6) tablet's update_effective_replication_map() is not refreshing tablet sstable set (for new tablet migrating in)
7) so read on step 5 is not being able to find sstable set for tablet migrating in
Causes the following error:
"tablets - SSTable set wasn't found for tablet 21 of table mview.users"
which means loss of write on pending replica.
The fix will refresh the table's sstable set (tablet_sstable_set) and cache's snapshot.
It's not a problem to refresh the cache snapshot as long as the logical
state of the data hasn't changed, which is true when allocating new
tablet replicas. That's also done in the context of compactions for example.
Fixes#19052.
Fixes#19033.
Signed-off-by: Raphael S. Carvalho <raphaelsc@scylladb.com>
Closesscylladb/scylladb#19099
tablet snapshot, used by migration, can race with compaction and
can find files deleted. That won't cause data loss because the
error is propagated back into the coordinator that decides to
retry streaming stage. So the consequence is delayed migration,
which might in turn reduce node operation throughput (e.g.
when decommissioning a node). It should be rare though, so
shouldn't have drastic consequences.
Fixes#18977.
Signed-off-by: Raphael S. Carvalho <raphaelsc@scylladb.com>
Closesscylladb/scylladb#18979
