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ScyllaDB extends the CQL language to provide a few extra features. This document lists those extensions.
The BYPASS CACHE clause on SELECT statements informs the database that the data
being read is unlikely to be read again in the near future, and also
was unlikely to have been read in the near past; therefore no attempt
should be made to read it from the cache or to populate the cache with
the data. This is mostly useful for range scans; these typically
process large amounts of data with no temporal locality and do not
benefit from the cache.
The clause is placed immediately after the optional ALLOW FILTERING
clause:
SELECT ... FROM ...
WHERE ...
ALLOW FILTERING -- optional
BYPASS CACHE
The paxos_grace_seconds option is used to set the amount of seconds which
are used to TTL data in paxos tables when using LWT queries against the base
table.
This value is intentionally decoupled from gc_grace_seconds since,
in general, the base table could use completely different strategy to garbage
collect entries, e.g. can set gc_grace_seconds to 0 if it doesn’t use
deletions and hence doesn’t need to repair.
However, paxos tables still rely on repair to achieve consistency, and
the user is required to execute repair within paxos_grace_seconds.
Default value is equal to DEFAULT_GC_GRACE_SECONDS, which is 10 days.
The option can be specified at CREATE TABLE or ALTER TABLE queries in the same
way as other options by using WITH clause:
CREATE TABLE tbl ...
WITH paxos_grace_seconds=1234
TIMEOUT extension allows specifying per-query timeouts. This parameter accepts a single
duration and applies it as a timeout specific to a single particular query.
The parameter is supported for prepared statements as well.
The parameter acts as part of the USING clause, and thus can be combined with other
parameters - like timestamps and time-to-live.
For example, one can use USING TIMEOUT ... and TTL ... to specify both a non-default timeout and a ttl.
Examples:
SELECT * FROM t USING TIMEOUT 200ms;
INSERT INTO t(a,b,c) VALUES (1,2,3) USING TIMESTAMP 42 AND TIMEOUT 50ms;
TRUNCATE TABLE t USING TIMEOUT 5m;
Working with prepared statements works as usual - the timeout parameter can be explicitly defined or provided as a marker:
SELECT * FROM t USING TIMEOUT ?;
INSERT INTO t(a,b,c) VALUES (?,?,?) USING TIMESTAMP 42 AND TIMEOUT 50ms;
The timeout parameter can be applied to the following data modification queries: INSERT, UPDATE, DELETE, PRUNE MATERIALIZED VIEW, BATCH, and to the TRUNCATE data definition query.
In addition, the timeout parameter can be applied to SELECT queries as well.
By default, SStables of a keyspace are stored in a local directory. As an alternative, you can configure your keyspace to be stored on Amazon S3 or another S3-compatible object store.
Support for object storage is experimental and must be explicitly
enabled in the scylla.yaml configuration file by specifying
the keyspace-storage-options option:
experimental_features:
- keyspace-storage-options
With support for object storage enabled, add your endpoint configuration
to scylla.yaml:
Create an object-storage-config-file.yaml file with a description of
allowed endpoints, for example:
endpoints:
- name: $endpoint_address_or_domain_name
port: $port_number
https: optional True or False
aws_region: optional region name, e.g. us-east-1
aws_access_key_id: optional AWS access key ID
aws_secret_access_key: optional AWS secret access key
aws_session_token: optional AWS session token
Specify the object-storage-config-file option in your scylla.yaml,
providing object-storage-config-file.yaml as the value:
object-storage-config-file: object-storage-config-file.yaml
Now you can configure your object storage when creating a keyspace:
CREATE KEYSPACE with STORAGE = { 'type': 'S3', 'endpoint': '$endpoint_name', 'bucket': '$bucket' }
Example
CREATE KEYSPACE ks
WITH REPLICATION = { 'class' : 'NetworkTopologyStrategy', 'replication_factor' : 3 }
AND STORAGE = { 'type' : 'S3', 'bucket' : '/tmp/b1', 'endpoint' : 'localhost' } ;
Storage options can be inspected by checking the new system schema table: system_schema.scylla_keyspaces:
cassandra@cqlsh> select * from system_schema.scylla_keyspaces;
keyspace_name | storage_options | storage_type
---------------+------------------------------------------------+--------------
ksx | {'bucket': '/tmp/xx', 'endpoint': 'localhost'} | S3
A special statement is dedicated for pruning ghost rows from materialized views. Ghost row is an inconsistency issue which manifests itself by having rows in a materialized view which do not correspond to any base table rows. Such inconsistencies should be prevented altogether and ScyllaDB is striving to avoid them, but if they happen, this statement can be used to restore a materialized view to a fully consistent state without rebuilding it from scratch.
Example usages:
PRUNE MATERIALIZED VIEW my_view;
PRUNE MATERIALIZED VIEW my_view WHERE token(v) > 7 AND token(v) < 1535250;
PRUNE MATERIALIZED VIEW my_view WHERE v = 19;
The statement works by fetching requested rows from a materialized view and then trying to fetch their corresponding rows from the base table. If it turns out that the base row does not exist, the row is considered a ghost row and is thus deleted. The statement implicitly works with consistency level ALL when fetching from the base table to avoid false positives. As the example shows, a materialized view can be pruned in one go, but one can also specify specific primary keys or token ranges, which is recommended in order to make the operation less heavyweight and allow for running multiple parallel pruning statements for non-overlapping token ranges.
Usually, when a table with materialized views is updated, the update to the views happens asynchronously, i.e., in the background. This means that the user cannot know when the view updates have all finished - or even be sure that they succeeded.
ScyllaDB allows marking a view as synchronous. When a view is marked synchronous, base-table updates will wait for that view to be updated before returning. A base table may have multiple views marked synchronous, and will wait for all of them. The consistency level of a write applies to synchronous views as well as to the base table: For example, writing with QUORUM consistency level returns only after a quorum of the base-table replicas were updated and also a quorum of each synchronous view table was also updated.
Synchronous views tend to reduce the observed availability of the base table, because a base-table write would only succeed if enough synchronous view updates also succeed. On the other hand, failed view updates would be detected immediately, and appropriate action can be taken, such as retrying the write or pruning the materialized view (as mentioned in the previous section). This can improve the consistency of the base table with its views.
To create a new materialized view with synchronous updates, use:
CREATE MATERIALIZED VIEW main.mv
AS SELECT * FROM main.t
WHERE v IS NOT NULL
PRIMARY KEY (v, id)
WITH synchronous_updates = true;
To make an existing materialized view synchronous, use:
ALTER MATERIALIZED VIEW main.mv WITH synchronous_updates = true;
To return a materialized view to the default behavior (which, as explained above, usually means asynchronous updates), use:
ALTER MATERIALIZED VIEW main.mv WITH synchronous_updates = false;
Even in an asynchronous view, some view updates may be done synchronously.
This happens when the materialized-view replica is on the same node as the
base-table replica. This happens, for example, in tables using vnodes where
the base table and the view have the same partition key; But is not the case
if the table uses tablets: With tablets, the base and view tablets may migrate
to different nodes. In general, users should not, and cannot, rely on these
serendipitous synchronous view updates; If synchronous view updates are
important, mark the view explicitly with synchronous_updates = true.
Synchronous updates can also be turned on for global secondary indexes.
At the time of writing this paragraph there is no direct syntax to do that,
but it’s possible to mark the underlying materialized view of an index
as synchronous. ScyllaDB’s implementation of secondary indexes is based
on materialized views and the generated view’s name can be extracted
from schema tables, and is generally constructed by appending _index
suffix to the index name:
create table main.t(id int primary key, v int);
create index on main.t(v);
select * from system_schema.indexes ;
keyspace_name | table_name | index_name | kind | options
---------------+------------+------------+------------+-----------------
main | t | t_v_idx | COMPOSITES | {'target': 'v'}
(1 rows)
select keyspace_name, view_name from system_schema.views ;
keyspace_name | view_name
---------------+---------------
main | t_v_idx_index
(1 rows)
alter materialized view t_v_idx_index with synchronous_updates = true;
Local secondary indexes already have synchronous updates, so there’s no need to explicitly mark them as such.
Scylla aims for a uniform handling of NULL values in expressions, inspired
by SQL: The overarching principle is that a NULL signifies an unknown value,
so most expressions calculated based on a NULL also results in a NULL.
For example, the results of x + NULL, x = NULL or x < NULL are all NULL,
no matter what x is. Even the expression NULL = NULL evaluates to NULL,
not TRUE.
But not all expressions of NULL evaluate to NULL. An interesting example
is boolean conjunction:FALSE AND NULL returns FALSE - not NULL. This is
because no matter which unknown value the NULL represents, ANDing it with
FALSE will always result in FALSE. So the return value is not unknown - it
is a FALSE. In contrast, TRUE AND NULL does return NULL, because if we AND
a TRUE with an unknown value the result is also unknown: TRUE AND TRUE is
TRUE but TRUE AND FALSE is FALSE.
Because x = NULL always evaluates to NULL, a SELECT filter WHERE x = NULL
matches no row (matching means evaluating to TRUE). It does not match
rows where x is missing. If you really want to match rows with missing x,
SQL offers a different syntax x IS NULL (and similarly, also x IS NOT NULL), Scylla does not yet implement this syntax.
In contrast, Cassandra is less consistent in its handling of nulls.
The example x = NULL is considered an error, not a valid expression
whose result is NULL.
The rules explained above apply to most expressions, in particular to WHERE
filters in SELECT. However, the evaluation rules for LWT IF clauses
(conditional updates) are different: a IF x = NULL condition succeeds
if x is unset. This non-standard behavior of NULLs in IF expressions may
be made configurable in a future version.
NULL is valid input for LWT IF clause element access¶The LWT IF clauses
IF some_map[:var] = 3
or
IF some_map[:var] != 3
is an error if :var is NULL on Cassandra, but is accepted by
Scylla. The result of the comparison, for both = and !=, is FALSE.
NULL is valid input for LWT IF clause LIKE patterns¶The LWT IF clauses
IF some_column LIKE :pattern
is an error if :pattern is NULL on Cassandra, but is accepted by
Scylla. The result of the pattern match is FALSE.
REDUCEFUNC extension adds optional reduction function to user-defined aggregate. This allows to speed up aggregation query execution by distributing the calculations to other nodes and reducing partial results into final one. Specification of this function is it has to be scalar function with two arguments, both of the same type as UDA’s state, also returning the state type.
CREATE FUNCTION row_fct(acc tuple<bigint, int>, val int)
RETURNS NULL ON NULL INPUT
RETURNS tuple<bigint, int>
LANGUAGE lua
AS $$
return { acc[1]+val, acc[2]+1 }
$$;
CREATE FUNCTION reduce_fct(acc tuple<bigint, int>, acc2 tuple<bigint, int>)
RETURNS NULL ON NULL INPUT
RETURNS tuple<bigint, int>
LANGUAGE lua
AS $$
return { acc[1]+acc2[1], acc[2]+acc2[2] }
$$;
CREATE FUNCTION final_fct(acc tuple<bigint, int>)
RETURNS NULL ON NULL INPUT
RETURNS double
LANGUAGE lua
AS $$
return acc[1]/acc[2]
$$;
CREATE AGGREGATE custom_avg(int)
SFUNC row_fct
STYPE tuple<bigint, int>
REDUCEFUNC reduce_fct
FINALFUNC final_fct
INITCOND (0, 0);
If a bind variable is referred to twice (example: WHERE aa = :var AND bb = :var; :var
is referenced twice), ScyllaDB and Cassandra treat it differently:
Cassandra ignores the double reference and treats the two as two separate variables. They can have different types, and occupy two slots in the bind variable metadata (used by drivers when the user provides a bind variable tuple rather than a map)
ScyllaDB treats the two references as referring to the same variable. The two references must have the same type, and occupy one slot in the bind variable metadata.
ScyllaDB can revert to the Cassandra treatment by setting the configuration item
cql_duplicate_bind_variable_names_refer_to_same_variable to false.
Subscripting a list in a WHERE clause is supported as are maps.
WHERE some_list[:index] = :value
The per_partition_rate_limit option can be used to limit the allowed
rate of requests to each partition in a given table. When the cluster detects
that the rate of requests exceeds configured limit, the cluster will start
rejecting some of them in order to bring the throughput back to the configured
limit. Rejected requests are less costly which can help reduce overload.
NOTE: Due to ScyllaDB’s distributed nature, tracking per-partition request rates
is not perfect and the actual rate of accepted requests may be higher up to
a factor of keyspace’s RF. This feature should not be used to enforce precise
limits but rather serve as an overload protection feature.
NOTE: This feature works best when shard-aware drivers are used (rejected requests have the least cost).
Limits are configured separately for reads and writes. Some examples:
ALTER TABLE t WITH per_partition_rate_limit = {
'max_reads_per_second': 100,
'max_writes_per_second': 200
};
Limit reads only, no limit for writes:
ALTER TABLE t WITH per_partition_rate_limit = {
'max_reads_per_second': 200
};
Rejected requests receive the scylla-specific “Rate limit exceeded” error.
If the driver doesn’t support it, Config_error will be sent instead.
For more details, see:
Detailed design notes
Description of the rate limit exceeded error
Actual values of service level’s options may come from different service levels, not only from the one user is assigned with.
To facilitate insight into which values come from which service level, there is LIST EFFECTIVE SERVICE LEVEL OF <role_name> command.
> LIST EFFECTIVE SERVICE LEVEL OF role2;
service_level_option | effective_service_level | value
----------------------+-------------------------+-------------
workload_type | sl2 | batch
timeout | sl1 | 2s
For more details, check Service Levels docs
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