Reference configuration
The following is a copy of the reference.conf file matching the version of this documentation. It is packaged in the java-driver-core JAR artifact, and used at runtime to provide the default values for all configuration options (in the sources, it can be found under core/src/main/resources).
See the configuration page for more explanations.
# Reference configuration for the DataStax Java driver for Apache Cassandra®. # # Unless you use a custom mechanism to load your configuration (see # SessionBuilder.withConfigLoader), all the values declared here will be used as defaults. You can # place your own `application.conf` in the classpath to override them. # # Options are classified into two categories: # - basic: what is most likely to be customized first when kickstarting a new application. # - advanced: more elaborate tuning options, or "expert"-level customizations. # # This file is in HOCON format, see https://github.com/typesafehub/config/blob/master/HOCON.md. datastax-java-driver { # BASIC OPTIONS ---------------------------------------------------------------------------------- # The contact points to use for the initial connection to the cluster. # # These are addresses of Cassandra nodes that the driver uses to discover the cluster topology. # Only one contact point is required (the driver will retrieve the address of the other nodes # automatically), but it is usually a good idea to provide more than one contact point, because if # that single contact point is unavailable, the driver cannot initialize itself correctly. # # This must be a list of strings with each contact point specified as "host:port". If the host is # a DNS name that resolves to multiple A-records, all the corresponding addresses will be used. Do # not use "localhost" as the host name (since it resolves to both IPv4 and IPv6 addresses on some # platforms). # # Note that Cassandra 3 and below requires all nodes in a cluster to share the same port (see # CASSANDRA-7544). # # Contact points can also be provided programmatically when you build a cluster instance. If both # are specified, they will be merged. If both are absent, the driver will default to # 127.0.0.1:9042. # # Required: no # Modifiable at runtime: no # Overridable in a profile: no // basic.contact-points = [ "127.0.0.1:9042", "127.0.0.2:9042" ] # A name that uniquely identifies the driver instance created from this configuration. This is # used as a prefix for log messages and metrics. # # If this option is absent, the driver will generate an identifier composed of the letter 's' # followed by an incrementing counter. If you provide a different value, try to keep it short to # keep the logs readable. Also, make sure it is unique: reusing the same value will not break the # driver, but it will mix up the logs and metrics. # # Required: no # Modifiable at runtime: no # Overridable in a profile: no // basic.session-name = my_session # The name of the keyspace that the session should initially be connected to. # # This expects the same format as in a CQL query: case-sensitive names must be quoted (note that # the quotes must be escaped in HOCON format). For example: # session-keyspace = case_insensitive_name # session-keyspace = \"CaseSensitiveName\" # # If this option is absent, the session won't be connected to any keyspace, and you'll have to # either qualify table names in your queries, or use the per-query keyspace feature available in # Cassandra 4 and above (see Request.getKeyspace()). # # This can also be provided programatically in CqlSessionBuilder. # # Required: no # Modifiable at runtime: no # Overridable in a profile: no // basic.session-keyspace = my_keyspace # How often the driver tries to reload the configuration. # # To disable periodic reloading, set this to 0. # # Required: yes (unless you pass a different ConfigLoader to the session builder). # Modifiable at runtime: yes, the new value will be used after the next time the configuration # gets reloaded. # Overridable in a profile: no basic.config-reload-interval = 5 minutes basic.request { # How long the driver waits for a request to complete. This is a global limit on the duration of # a session.execute() call, including any internal retries the driver might do. # # By default, this value is set pretty high to ensure that DDL queries don't time out, in order # to provide the best experience for new users trying the driver with the out-of-the-box # configuration. # For any serious deployment, we recommend that you use separate configuration profiles for DDL # and DML; you can then set the DML timeout much lower (down to a few milliseconds if needed). # # Note that, because timeouts are scheduled on the driver's timer thread, the duration specified # here must be greater than the timer tick duration defined by the # advanced.netty.timer.tick-duration setting (see below). If that is not the case, timeouts will # not be triggered as timely as desired. # # Required: yes # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes timeout = 2 seconds # The consistency level. # # Required: yes # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes consistency = LOCAL_ONE # The page size. This controls how many rows will be retrieved simultaneously in a single # network roundtrip (the goal being to avoid loading too many results in memory at the same # time). If there are more results, additional requests will be used to retrieve them (either # automatically if you iterate with the sync API, or explicitly with the async API's # fetchNextPage method). # If the value is 0 or negative, it will be ignored and the request will not be paged. # # Required: yes # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes page-size = 5000 # The serial consistency level. # The allowed values are SERIAL and LOCAL_SERIAL. # # Required: yes # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes serial-consistency = SERIAL # The default idempotence of a request, that will be used for all `Request` instances where # `isIdempotent()` returns null. # # Required: yes # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes default-idempotence = false } # The policy that decides the "query plan" for each query; that is, which nodes to try as # coordinators, and in which order. # # Required: yes # Modifiable at runtime: no (but custom implementations may elect to watch configuration changes # and allow child options to be changed at runtime). # Overridable in a profile: yes. Note that the driver creates as few instances as possible: if a # named profile inherits from the default profile, or if two sibling profiles have the exact # same configuration, they will share a single policy instance at runtime. # If there are multiple load balancing policies in a single driver instance, they work together # in the following way: # - each request gets a query plan from its profile's policy (or the default policy if the # request has no profile, or the profile does not override the policy). # - when the policies assign distances to nodes, the driver uses the closest assigned distance # for any given node. basic.load-balancing-policy { # The class of the policy. If it is not qualified, the driver assumes that it resides in one of # the following packages: # - com.datastax.oss.driver.internal.core.loadbalancing. # - com.datastax.dse.driver.internal.core.loadbalancing. # # The driver provides three implementations out of the box: # # - `DefaultLoadBalancingPolicy`: should almost always be used; it requires a local datacenter # to be specified either programmatically when creating the session, or via the configuration # option: datastax-java-driver.basic.load-balancing-policy.local-datacenter. It can also # use a highly efficient slow replica avoidance mechanism, which is by default enabled – see # the option: datastax-java-driver.basic.load-balancing-policy.slow-replica-avoidance. # - `DcInferringLoadBalancingPolicy`: similar to `DefaultLoadBalancingPolicy`, but does not # require a local datacenter to be defined, in which case it will attempt to infer the local # datacenter from the provided contact points, if possible; if that fails, it will throw an # error during session initialization. This policy is intended mostly for ETL tools and # should not be used by normal applications. # - `BasicLoadBalancingPolicy`: similar to `DefaultLoadBalancingPolicy`, but does not have # the slow replica avoidance mechanism. More importantly, it is the only policy capable of # operating without local datacenter defined, in which case it will consider nodes in the # cluster in a datacenter-agnostic way. Beware that this could cause spikes in # cross-datacenter traffic! This policy is provided mostly as a starting point for users # wishing to implement their own load balancing policy; it should not be used as is in normal # applications. # # You can also specify a custom class that implements LoadBalancingPolicy and has a public # constructor with two arguments: the DriverContext and a String representing the profile name. class = DefaultLoadBalancingPolicy # The datacenter that is considered "local": the default policy will only include nodes from # this datacenter in its query plans. # # When using the default policy, this option can only be absent if you specified no contact # points: in that case, the driver defaults to 127.0.0.1:9042, and that node's datacenter is # used as the local datacenter. As soon as you provide contact points (either through the # configuration or through the session builder), you must define the local datacenter # explicitly, and initialization will fail if this property is absent. In addition, all contact # points should be from this datacenter; warnings will be logged for nodes that are from a # different one. # # This can also be specified programmatically with SessionBuilder.withLocalDatacenter. If both # are specified, the programmatic value takes precedence. // local-datacenter = datacenter1 # The class of a custom node distance evaluator. # # This option is not required; if present, it must be the fully-qualified name of a class that # implements `com.datastax.oss.driver.api.core.loadbalancing.NodeDistanceEvaluator`, and has a # public constructor taking two arguments: the DriverContext and a String representing the # profile name. # # Alternatively, you can pass an instance of your distance evaluator to # CqlSession.builder().withNodeDistanceEvaluator(). In that case, this option will be ignored. # # The evaluator will be invoked each time the policy processes a topology or state change. The # evaluator's `evaluateDistance` method will be called with the node affected by the change, and # the local datacenter name (or null if none is defined). If it returns a non-null distance, the # policy will suggest that distance for the node; if the function returns null, the policy will # will assign a default distance instead, based on its internal algorithm for computing node # distances. // evaluator.class= # DEPRECATED. Use evaluator.class instead (see above). If both evaluator.class and filter.class # are defined, the former wins. # # A custom filter to include/exclude nodes. # # This option is not required; if present, it must be the fully-qualified name of a class that # implements `java.util.function.Predicate<Node>`, and has a public constructor taking two # arguments: the DriverContext and a String representing the profile name. # # Alternatively, you can pass an instance of your filter to # CqlSession.builder().withNodeFilter(). In that case, this option will be ignored. # # The predicate's `test(Node)` method will be invoked each time the policy processes a # topology or state change: if it returns false, the node will be set at distance IGNORED # (meaning the driver won't ever connect to it), and never included in any query plan. // filter.class= # Whether to enable the slow replica avoidance mechanism in DefaultLoadBalancingPolicy. # # The default policy always moves replicas first in the query plan (if routing information can # be determined for the current request). However: # - if this option is true, it also applies a custom algorithm that takes the responsiveness and # uptime of each replica into account to order them among each other; # - if this option is false, replicas are simply shuffled. # # If this option is not defined, the driver defaults to true. slow-replica-avoidance = true } basic.cloud { # The location of the cloud secure bundle used to connect to Datastax Apache Cassandra as a # service. # This setting must be a valid URL. # If the protocol is not specified, it is implicitly assumed to be the `file://` protocol, # in which case the value is expected to be a valid path on the local filesystem. # For example, `/a/path/to/bundle` will be interpreted as `file:/a/path/to/bunde`. # If the protocol is provided explicitly, then the value will be used as is. # # Required: no # Modifiable at runtime: no # Overridable in a profile: no // secure-connect-bundle = /location/of/secure/connect/bundle } # DataStax Insights monitoring. basic.application { # The name of the application using the session. # # It will be sent in the STARTUP protocol message for each new connection established by the # driver. # # This can also be defined programmatically with DseSessionBuilder.withApplicationName(). If you # specify both, the programmatic value takes precedence and this option is ignored. # # Required: no # Modifiable at runtime: no # Overridable in a profile: no // name = # The version of the application using the session. # # It will be sent in the STARTUP protocol message for each new connection established by the # driver. # # This can also be defined programmatically with DseSessionBuilder.withApplicationVersion(). If # you specify both, the programmatic value takes precedence and this option is ignored. # # Required: no # Modifiable at runtime: no # Overridable in a profile: no // version = } # Graph (DataStax Enterprise only) basic.graph { # The name of the graph targeted by graph statements. # # This can also be overridden programmatically with GraphStatement.setGraphName(). If both are # specified, the programmatic value takes precedence, and this option is ignored. # # Required: no. In particular, system queries -- such as creating or dropping a graph -- must be # executed without a graph name (see also basic.graph.is-system-query). # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes // name = your-graph-name # The traversal source to use for graph statements. # # This setting doesn't usually need to change, unless executing OLAP queries, which require the # traversal source "a". # # This can also be overridden programmatically with GraphStatement.setTraversalSource(). If both # are specified, the programmatic value takes precedence, and this option is ignored. # # Required: no # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes traversal-source = "g" # Whether a script statement represents a system query. # # Script statements that access the `system` variable *must not* specify a graph name (otherwise # `system` is not available). However, if your application executes a lot of non-system # statements, it is convenient to configure basic.graph.name to avoid repeating it every time. # This option allows you to ignore that global graph name, for example in a specific profile. # # This can also be overridden programmatically with ScriptGraphStatement.setSystemQuery(). If # both are specified, the programmatic value takes precedence, and this option is ignored. # # Required: no (defaults to false) # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes // is-system-query = false # The read consistency level to use for graph statements. # # DSE Graph is able to distinguish between read and write timeouts for the internal storage # queries that will be produced by a traversal. Hence the consistency level for reads and writes # can be set separately. # # This can also be overridden programmatically with GraphStatement.setReadConsistencyLevel(). If # both are specified, the programmatic value takes precedence, and this option is ignored. # # Required: no (defaults to request.basic.consistency) # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes // read-consistency-level = LOCAL_QUORUM # The write consistency level to use for graph statements. # # DSE Graph is able to distinguish between read and write timeouts for the internal storage # queries that will be produced by a traversal. Hence the consistency level for reads and writes # can be set separately. # # This can also be overridden programmatically with GraphStatement.setReadConsistencyLevel(). If # both are specified, the programmatic value takes precedence, and this option is ignored. # # Required: no (defaults to request.basic.consistency) # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes // write-consistency-level = LOCAL_ONE # How long the driver waits for a graph request to complete. This is a global limit on the # duration of a session.execute() call, including any internal retries the driver might do. # # Graph statements behave a bit differently than regular CQL requests (hence this dedicated # option instead of reusing basic.request.timeout): by default, the client timeout is not set, # and the driver will just wait as long as needed until the server replies (which is itself # governed by server-side timeout configuration). # If you specify a client timeout with this option, then the driver will fail the request after # the given time; note that the value is also sent along with the request, so that the server # can also time out early and avoid wasting resources on a response that the client has already # given up on. # # This can also be overridden programmatically with GraphStatement.setTimeout(). If both are # specified, the programmatic value takes precedence, and this option is ignored. # # If this value is left unset (default) or is explicitly set to zero, no timeout will be # applied. # # Required: no (defaults to zero - no timeout) # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes // timeout = 10 seconds } # ADVANCED OPTIONS ------------------------------------------------------------------------------- # The maximum number of live sessions that are allowed to coexist in a given VM. # # This is intended to help detect resource leaks in client applications that create too many # sessions and/or do not close them correctly. The driver keeps track of the number of live # sessions in a static variable; if it gets over this threshold, a warning will be logged for # every new session. # # If the value is less than or equal to 0, the feature is disabled: no warning will be issued. # # Required: yes # Modifiable at runtime: yes, the new value will be used for sessions created after the change. # Overridable in a profile: no advanced.session-leak.threshold = 4 advanced.connection { # The timeout to use when establishing driver connections. # # This timeout is for controlling how long the driver will wait for the underlying channel # to actually connect to the server. This is not the time limit for completing protocol # negotiations, only the time limit for establishing a channel connection. # # Required: yes # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no connect-timeout = 5 seconds # The timeout to use for internal queries that run as part of the initialization process, just # after we open a connection. If this timeout fires, the initialization of the connection will # fail. If this is the first connection ever, the driver will fail to initialize as well, # otherwise it will retry the connection later. # # Required: yes # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no init-query-timeout = 5 seconds # The timeout to use when the driver changes the keyspace on a connection at runtime (this # happens when the client issues a `USE ...` query, and all connections belonging to the current # session need to be updated). # # Required: yes # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no set-keyspace-timeout = ${datastax-java-driver.advanced.connection.init-query-timeout} # The driver maintains a connection pool to each node, according to the distance assigned to it # by the load balancing policy. # If the distance is LOCAL, then local.size connections are opened; if the distance is REMOTE, # then remote.size connections are opened. If the distance is IGNORED, no connections at all # are maintained. pool { # The number of connections in the pool for a node whose distance is LOCAL, that is, a node # that belongs to the local datacenter, as inferred by the load balancing or defined by the # option: datastax-java-driver.basic.load-balancing-policy.local-datacenter. # # Each connection can handle many concurrent requests, so 1 is generally a good place to # start. You should only need higher values in very high performance scenarios, where # connections might start maxing out their I/O thread (see the driver's online manual for # more tuning instructions). # # Required: yes # Modifiable at runtime: yes; when the change is detected, all active pools will be notified # and will adjust their size. # Overridable in a profile: no local.size = 1 # The number of connections in the pool for a node whose distance is REMOTE, that is, a node # that does not belong to the local datacenter. # # Note: by default, the built-in load-balancing policies will never assign the REMOTE distance # to any node, to avoid cross-datacenter network traffic. If you want to change this behavior # and understand the consequences, configure your policy to accept nodes in remote # datacenters by adjusting the following advanced options: # # - datastax-java-driver.advanced.load-balancing-policy.dc-failover.max-nodes-per-remote-dc # - datastax-java-driver.advanced.load-balancing-policy.dc-failover.allow-for-local-consistency-levels # # Required: yes # Modifiable at runtime: yes; when the change is detected, all active pools will be notified # and will adjust their size. # Overridable in a profile: no remote.size = 1 } # The maximum number of requests that can be executed concurrently on a connection. This must be # strictly positive, and less than 32768. # # We recommend against changing this value: the default of 1024 is fine for most situations, # it's a good balance between sufficient concurrency on the client and reasonable pressure on # the server. If you're looking for a way to limit the global throughput of the session, this is # not the right way to do it: use a request throttler instead (see the `advanced.throttler` # section in this configuration). # # Required: yes # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no max-requests-per-connection = 1024 # The maximum number of "orphaned" requests before a connection gets closed automatically. # # Sometimes the driver writes to a node but stops listening for a response (for example if the # request timed out, or was completed by another node). But we can't safely reuse the stream id # on this connection until we know for sure that the server is done with it. Therefore the id is # marked as "orphaned" until we get a response from the node. # # If the response never comes (or is lost because of a network issue), orphaned ids can # accumulate over time, eventually affecting the connection's throughput. So we monitor them # and close the connection above a given threshold (the pool will replace it). # # The value must be lower than `max-requests-per-connection`. # # Required: yes # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no max-orphan-requests = 256 # Whether to log non-fatal errors when the driver tries to open a new connection. # # This error as recoverable, as the driver will try to reconnect according to the reconnection # policy. Therefore some users see them as unnecessary clutter in the logs. On the other hand, # those logs can be handy to debug a misbehaving node. # # Note that some type of errors are always logged, regardless of this option: # - protocol version mismatches (the node gets forced down) # - when the cluster name in system.local doesn't match the other nodes (the node gets forced # down) # - authentication errors (will be retried) # # Required: yes # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no warn-on-init-error = true } # Advanced options for the built-in load-balancing policies. advanced.load-balancing-policy { # Cross-datacenter failover configuration: configure the load-balancing policies to use nodes # in remote datacenters. dc-failover { # The maximum number of nodes to contact in each remote datacenter. # # By default, this number is zero, to avoid cross-datacenter network traffic. When this # number is greater than zero: # # - The load policies will assign the REMOTE distance to that many nodes in each remote # datacenter. # - The driver will then attempt to open connections to those nodes. The actual number of # connections to open to each one of those nodes is configurable via the option: # datastax-java-driver.advanced.connection.pool.remote.size. # - The load-balancing policies will include those remote nodes (and only those) in query # plans, effectively enabling cross-datacenter failover. # # Beware that enabling such failover can result in cross-datacenter network traffic spikes, # if the local datacenter is down or experiencing high latencies! # # Required: yes # Modifiable at runtime: no # Overridable in a profile: yes max-nodes-per-remote-dc = 0 # Whether cross-datacenter failover should be allowed for requests executed with local # consistency levels (LOCAL_ONE, LOCAL_QUORUM and LOCAL_SERIAL). # # This is disabled by default. Enabling this feature may have unexpected results, since a # local consistency level may have different semantics depending on the replication factor in # use in each datacenter. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: yes allow-for-local-consistency-levels = false } } # Whether to schedule reconnection attempts if all contact points are unreachable on the first # initialization attempt. # # If this is true, the driver will retry according to the reconnection policy. The # `SessionBuilder.build()` call -- or the future returned by `SessionBuilder.buildAsync()` -- # won't complete until a contact point has been reached. # # If this is false and no contact points are available, the driver will fail with an # AllNodesFailedException. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no advanced.reconnect-on-init = false # The policy that controls how often the driver tries to re-establish connections to down nodes. # # Required: yes # Modifiable at runtime: no (but custom implementations may elect to watch configuration changes # and allow child options to be changed at runtime). # Overridable in a profile: no advanced.reconnection-policy { # The class of the policy. If it is not qualified, the driver assumes that it resides in the # package com.datastax.oss.driver.internal.core.connection. # # The driver provides two implementations out of the box: ExponentialReconnectionPolicy and # ConstantReconnectionPolicy. # # You can also specify a custom class that implements ReconnectionPolicy and has a public # constructor with a DriverContext argument. class = ExponentialReconnectionPolicy # ExponentialReconnectionPolicy starts with the base delay, and doubles it after each failed # reconnection attempt, up to the maximum delay (after that it stays constant). # # ConstantReconnectionPolicy only uses the base-delay value, the interval never changes. base-delay = 1 second max-delay = 60 seconds } # The policy that controls if the driver retries requests that have failed on one node. # # Required: yes # Modifiable at runtime: no (but custom implementations may elect to watch configuration changes # and allow child options to be changed at runtime). # Overridable in a profile: yes. Note that the driver creates as few instances as possible: if a # named profile inherits from the default profile, or if two sibling profiles have the exact # same configuration, they will share a single policy instance at runtime. advanced.retry-policy { # The class of the policy. If it is not qualified, the driver assumes that it resides in the # package com.datastax.oss.driver.internal.core.retry. # # The driver provides two implementations out of the box: # # - DefaultRetryPolicy: the default policy, should almost always be the right choice. # - ConsistencyDowngradingRetryPolicy: an alternative policy that weakens consistency guarantees # as a trade-off to maximize the chance of success when retrying. Use with caution. # # Refer to the manual to understand how these policies work. # # You can also specify a custom class that implements RetryPolicy and has a public constructor # with two arguments: the DriverContext and a String representing the profile name. class = DefaultRetryPolicy } # The policy that controls if the driver pre-emptively tries other nodes if a node takes too long # to respond. # # Required: yes # Modifiable at runtime: no (but custom implementations may elect to watch configuration changes # and allow child options to be changed at runtime). # Overridable in a profile: yes. Note that the driver creates as few instances as possible: if a # named profile inherits from the default profile, or if two sibling profiles have the exact # same configuration, they will share a single policy instance at runtime. advanced.speculative-execution-policy { # The class of the policy. If it is not qualified, the driver assumes that it resides in the # package com.datastax.oss.driver.internal.core.specex. # # The following implementations are available out of the box: # - NoSpeculativeExecutionPolicy: never schedule any speculative execution # - ConstantSpeculativeExecutionPolicy: schedule executions based on constant delays. This # requires the `max-executions` and `delay` options below. # # You can also specify a custom class that implements SpeculativeExecutionPolicy and has a # public constructor with two arguments: the DriverContext and a String representing the # profile name. class = NoSpeculativeExecutionPolicy # The maximum number of executions (including the initial, non-speculative execution). # This must be at least one. // max-executions = 3 # The delay between each execution. 0 is allowed, and will result in all executions being sent # simultaneously when the request starts. # # Note that sub-millisecond precision is not supported, any excess precision information will be # dropped; in particular, delays of less than 1 millisecond are equivalent to 0. # # Also note that, because speculative executions are scheduled on the driver's timer thread, # the duration specified here must be greater than the timer tick duration defined by the # advanced.netty.timer.tick-duration setting (see below). If that is not the case, speculative # executions will not be triggered as timely as desired. # # This must be positive or 0. // delay = 100 milliseconds } # The component that handles authentication on each new connection. # # Required: no. If the 'class' child option is absent, no authentication will occur. # Modifiable at runtime: no # Overridable in a profile: no # # Note that the contents of this section can be overridden programmatically with # SessionBuilder.withAuthProvider or SessionBuilder.withAuthCredentials. advanced.auth-provider { # The class of the provider. If it is not qualified, the driver assumes that it resides in one # of the following packages: # - com.datastax.oss.driver.internal.core.auth # - com.datastax.dse.driver.internal.core.auth # # The driver provides two implementations: # - PlainTextAuthProvider: uses plain-text credentials. It requires the `username` and # `password` options below. When connecting to Datastax Enterprise, an optional # `authorization-id` can also be specified. # For backward compatibility with previous driver versions, you can also use the class name # "DsePlainTextAuthProvider" for this provider. # - DseGssApiAuthProvider: provides GSSAPI authentication for DSE clusters secured with # DseAuthenticator. See the example below and refer to the manual for detailed instructions. # # You can also specify a custom class that implements AuthProvider and has a public constructor # with a DriverContext argument (to simplify this, the driver provides two abstract classes that # can be extended: PlainTextAuthProviderBase and DseGssApiAuthProviderBase). # # Finally, you can configure a provider instance programmatically with # DseSessionBuilder#withAuthProvider. In that case, it will take precedence over the # configuration. // class = PlainTextAuthProvider # # Sample configuration for plain-text authentication providers: // username = cassandra // password = cassandra # # Proxy authentication: allows to login as another user or role (valid for both # PlainTextAuthProvider and DseGssApiAuthProvider): // authorization-id = userOrRole # # The settings below are only applicable to DseGssApiAuthProvider: # # Service name. For example, if in your dse.yaml configuration file the # "kerberos_options/service_principal" setting is "cassandra/my.host.com@MY.REALM.COM", then set # this option to "cassandra". If this value is not explicitly set via configuration (in an # application.conf or programmatically), the driver will attempt to set it via a System # property. The property should be "dse.sasl.service". For backwards compatibility with 1.x # versions of the driver, if "dse.sasl.service" is not set as a System property, the driver will # attempt to use "dse.sasl.protocol" as a fallback (which is the property for the 1.x driver). //service = "cassandra" # # Login configuration. It is also possible to provide login configuration through a standard # JAAS configuration file. The below configuration is just an example, see all possible options # here: # https://docs.oracle.com/javase/6/docs/jre/api/security/jaas/spec/com/sun/security/auth/module/Krb5LoginModule.html // login-configuration { // principal = "cassandra@DATASTAX.COM" // useKeyTab = "true" // refreshKrb5Config = "true" // keyTab = "/path/to/keytab/file" // } # # Internal SASL properties, if any, such as QOP. // sasl-properties { // javax.security.sasl.qop = "auth-conf" // } } # The SSL engine factory that will initialize an SSL engine for each new connection to a server. # # Required: no. If the 'class' child option is absent, SSL won't be activated. # Modifiable at runtime: no # Overridable in a profile: no # # Note that the contents of this section can be overridden programmatically with # SessionBuilder.withSslEngineFactory or SessionBuilder#withSslContext. advanced.ssl-engine-factory { # The class of the factory. If it is not qualified, the driver assumes that it resides in the # package com.datastax.oss.driver.internal.core.ssl. # # The driver provides a single implementation out of the box: DefaultSslEngineFactory, that uses # the JDK's built-in SSL implementation. # # You can also specify a custom class that implements SslEngineFactory and has a public # constructor with a DriverContext argument. // class = DefaultSslEngineFactory # Sample configuration for the default SSL factory: # The cipher suites to enable when creating an SSLEngine for a connection. # This property is optional. If it is not present, the driver won't explicitly enable cipher # suites on the engine, which according to the JDK documentations results in "a minimum quality # of service". // cipher-suites = [ "TLS_RSA_WITH_AES_128_CBC_SHA", "TLS_RSA_WITH_AES_256_CBC_SHA" ] # Whether or not to require validation that the hostname of the server certificate's common # name matches the hostname of the server being connected to. If not set, defaults to true. // hostname-validation = true # The locations and passwords used to access truststore and keystore contents. # These properties are optional. If either truststore-path or keystore-path are specified, # the driver builds an SSLContext from these files. If neither option is specified, the # default SSLContext is used, which is based on system property configuration. // truststore-path = /path/to/client.truststore // truststore-password = password123 // keystore-path = /path/to/client.keystore // keystore-password = password123 } # The generator that assigns a microsecond timestamp to each request. # # Required: yes # Modifiable at runtime: no (but custom implementations may elect to watch configuration changes # and allow child options to be changed at runtime). # Overridable in a profile: yes. Note that the driver creates as few instances as possible: if a # named profile inherits from the default profile, or if two sibling profiles have the exact # same configuration, they will share a single generator instance at runtime. advanced.timestamp-generator { # The class of the generator. If it is not qualified, the driver assumes that it resides in the # package com.datastax.oss.driver.internal.core.time. # # The driver provides the following implementations out of the box: # - AtomicTimestampGenerator: timestamps are guaranteed to be unique across all client threads. # - ThreadLocalTimestampGenerator: timestamps that are guaranteed to be unique within each # thread only. # - ServerSideTimestampGenerator: do not generate timestamps, let the server assign them. # # You can also specify a custom class that implements TimestampGenerator and has a public # constructor with two arguments: the DriverContext and a String representing the profile name. class = AtomicTimestampGenerator # To guarantee that queries are applied on the server in the same order as the client issued # them, timestamps must be strictly increasing. But this means that, if the driver sends more # than one query per microsecond, timestamps will drift in the future. While this could happen # occasionally under high load, it should not be a regular occurrence. Therefore the built-in # implementations log a warning to detect potential issues. drift-warning { # How far in the future timestamps are allowed to drift before the warning is logged. # If it is undefined or set to 0, warnings are disabled. threshold = 1 second # How often the warning will be logged if timestamps keep drifting above the threshold. interval = 10 seconds } # Whether to force the driver to use Java's millisecond-precision system clock. # If this is false, the driver will try to access the microsecond-precision OS clock via native # calls (and fallback to the Java one if the native calls fail). # Unless you explicitly want to avoid native calls, there's no reason to change this. force-java-clock = false } # Request trackers are session-wide components that get notified of the outcome of requests. advanced.request-tracker { # The list of trackers to register. # # This must be a list of class names, either fully-qualified or non-qualified; if the latter, # the driver assumes that the class resides in the package # com.datastax.oss.driver.internal.core.tracker. # # All classes specified here must implement # com.datastax.oss.driver.api.core.tracker.RequestTracker and have a public constructor with a # DriverContext argument. # # The driver provides the following implementation out of the box: # - RequestLogger: logs requests (see the parameters below). # # You can also pass instances of your trackers programmatically with # CqlSession.builder().addRequestTracker(). # # Required: no # Modifiable at runtime: no (but custom implementations may elect to watch configuration changes # and allow child options to be changed at runtime). # Overridable in a profile: no #classes = [RequestLogger,com.example.app.MyTracker] # Parameters for RequestLogger. All of them can be overridden in a profile, and changed at # runtime (the new values will be taken into account for requests logged after the change). logs { # Whether to log successful requests. // success.enabled = true slow { # The threshold to classify a successful request as "slow". If this is unset, all successful # requests will be considered as normal. // threshold = 1 second # Whether to log slow requests. // enabled = true } # Whether to log failed requests. // error.enabled = true # The maximum length of the query string in the log message. If it is longer than that, it # will be truncated. // max-query-length = 500 # Whether to log bound values in addition to the query string. // show-values = true # The maximum length for bound values in the log message. If the formatted representation of a # value is longer than that, it will be truncated. // max-value-length = 50 # The maximum number of bound values to log. If a request has more values, the list of values # will be truncated. // max-values = 50 # Whether to log stack traces for failed queries. If this is disabled, the log will just # include the exception's string representation (generally the class name and message). // show-stack-traces = true } } # A session-wide component that controls the rate at which requests are executed. # # Implementations vary, but throttlers generally track a metric that represents the level of # utilization of the session, and prevent new requests from starting when that metric exceeds a # threshold. Pending requests may be enqueued and retried later. # # From the public API's point of view, this process is mostly transparent: any time that the # request is throttled is included in the session.execute() or session.executeAsync() call. # Similarly, the request timeout encompasses throttling: the timeout starts ticking before the # throttler has started processing the request; a request may time out while it is still in the # throttler's queue, before the driver has even tried to send it to a node. # # The only visible effect is that a request may fail with a RequestThrottlingException, if the # throttler has determined that it can neither allow the request to proceed now, nor enqueue it; # this indicates that your session is overloaded. # # Required: yes # Modifiable at runtime: no (but custom implementations may elect to watch configuration changes # and allow child options to be changed at runtime). # Overridable in a profile: no advanced.throttler { # The class of the throttler. If it is not qualified, the driver assumes that it resides in # the package com.datastax.oss.driver.internal.core.session.throttling. # # The driver provides the following implementations out of the box: # # - PassThroughRequestThrottler: does not perform any kind of throttling, all requests are # allowed to proceed immediately. Required options: none. # # - ConcurrencyLimitingRequestThrottler: limits the number of requests that can be executed in # parallel. Required options: max-concurrent-requests, max-queue-size. # # - RateLimitingRequestThrottler: limits the request rate per second. Required options: # max-requests-per-second, max-queue-size, drain-interval. # # You can also specify a custom class that implements RequestThrottler and has a public # constructor with a DriverContext argument. class = PassThroughRequestThrottler # The maximum number of requests that can be enqueued when the throttling threshold is exceeded. # Beyond that size, requests will fail with a RequestThrottlingException. // max-queue-size = 10000 # The maximum number of requests that are allowed to execute in parallel. # Only used by ConcurrencyLimitingRequestThrottler. // max-concurrent-requests = 10000 # The maximum allowed request rate. # Only used by RateLimitingRequestThrottler. // max-requests-per-second = 10000 # How often the throttler attempts to dequeue requests. This is the only way for rate-based # throttling, because the completion of an active request does not necessarily free a "slot" for # a queued one (the rate might still be too high). # # You want to set this high enough that each attempt will process multiple entries in the queue, # but not delay requests too much. A few milliseconds is probably a happy medium. # # Only used by RateLimitingRequestThrottler. // drain-interval = 10 milliseconds } # The list of node state listeners to register. Node state listeners are session-wide # components that listen for node state changes (e.g., when nodes go down or back up). # # This must be a list of fully-qualified class names; classes specified here must implement # com.datastax.oss.driver.api.core.metadata.NodeStateListener and have a public # constructor with a DriverContext argument. # # You can also pass instances of your listeners programmatically with # CqlSession.builder().addNodeStateListener(). # # Required: no # Modifiable at runtime: no (but custom implementations may elect to watch configuration changes # and allow child options to be changed at runtime). # Overridable in a profile: no #advanced.node-state-listener.classes = [com.example.app.MyListener1,com.example.app.MyListener2] # The list of schema change listeners to register. Schema change listeners are session-wide # components that listen for schema changes (e.g., when tables are created or dropped). # # This must be a list of fully-qualified class names; classes specified here must implement # com.datastax.oss.driver.api.core.metadata.schema.SchemaChangeListener and have a public # constructor with a DriverContext argument. # # You can also pass instances of your listeners programmatically with # CqlSession.builder().addSchemaChangeListener(). # # Required: no # Modifiable at runtime: no (but custom implementations may elect to watch configuration changes # and allow child options to be changed at runtime). # Overridable in a profile: no #advanced.schema-change-listener.classes = [com.example.app.MyListener1,com.example.app.MyListener2] # The address translator to use to convert the addresses sent by Cassandra nodes into ones that # the driver uses to connect. # This is only needed if the nodes are not directly reachable from the driver (for example, the # driver is in a different network region and needs to use a public IP, or it connects through a # proxy). # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no advanced.address-translator { # The class of the translator. If it is not qualified, the driver assumes that it resides in # the package com.datastax.oss.driver.internal.core.addresstranslation. # # The driver provides the following implementations out of the box: # - PassThroughAddressTranslator: returns all addresses unchanged # - FixedHostNameAddressTranslator: translates all addresses to a specific hostname. # - Ec2MultiRegionAddressTranslator: suitable for an Amazon multi-region EC2 deployment where # clients are also deployed in EC2. It optimizes network costs by favoring private IPs over # public ones whenever possible. # # You can also specify a custom class that implements AddressTranslator and has a public # constructor with a DriverContext argument. class = PassThroughAddressTranslator # This property has to be set only in case you use FixedHostNameAddressTranslator. # advertised-hostname = mycustomhostname } # Whether to resolve the addresses passed to `basic.contact-points`. # # If this is true, addresses are created with `InetSocketAddress(String, int)`: the host name will # be resolved the first time, and the driver will use the resolved IP address for all subsequent # connection attempts. # # If this is false, addresses are created with `InetSocketAddress.createUnresolved()`: the host # name will be resolved again every time the driver opens a new connection. This is useful for # containerized environments where DNS records are more likely to change over time (note that the # JVM and OS have their own DNS caching mechanisms, so you might need additional configuration # beyond the driver). # # This option only applies to the contact points specified in the configuration. It has no effect # on: # - programmatic contact points passed to SessionBuilder.addContactPoints: these addresses are # built outside of the driver, so it is your responsibility to provide unresolved instances. # - dynamically discovered peers: the driver relies on Cassandra system tables, which expose raw # IP addresses. Use a custom address translator to convert them to unresolved addresses (if # you're in a containerized environment, you probably already need address translation anyway). # # Required: no (defaults to true) # Modifiable at runtime: no # Overridable in a profile: no advanced.resolve-contact-points = true advanced.protocol { # The native protocol version to use. # # If this option is absent, the driver looks up the versions of the nodes at startup (by default # in system.peers.release_version), and chooses the highest common protocol version. # For example, if you have a mixed cluster with Apache Cassandra 2.1 nodes (protocol v3) and # Apache Cassandra 3.0 nodes (protocol v3 and v4), then protocol v3 is chosen. If the nodes # don't have a common protocol version, initialization fails. # # If this option is set, then the given version will be used for all connections, without any # negotiation or downgrading. If any of the contact points doesn't support it, that contact # point will be skipped. # # Once the protocol version is set, it can't change for the rest of the driver's lifetime; if # an incompatible node joins the cluster later, connection will fail and the driver will force # it down (i.e. never try to connect to it again). # # You can check the actual version at runtime with Session.getContext().getProtocolVersion(). # # Required: no # Modifiable at runtime: no # Overridable in a profile: no // version = V4 # The name of the algorithm used to compress protocol frames. # # The possible values are: # - lz4: requires net.jpountz.lz4:lz4 in the classpath. # - snappy: requires org.xerial.snappy:snappy-java in the classpath. # - the string "none" to indicate no compression (this is functionally equivalent to omitting # the option). # # The driver depends on the compression libraries, but they are optional. Make sure you # redeclare an explicit dependency in your project. Refer to the driver's POM or manual for the # exact version. # # Required: no. If the option is absent, protocol frames are not compressed. # Modifiable at runtime: no # Overridable in a profile: no // compression = lz4 # The maximum length of the frames supported by the driver. Beyond that limit, requests will # fail with an exception # # Required: yes # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no max-frame-length = 256 MiB } advanced.request { # Whether a warning is logged when a request (such as a CQL `USE ...`) changes the active # keyspace. # Switching keyspace at runtime is highly discouraged, because it is inherently unsafe (other # requests expecting the old keyspace might be running concurrently), and may cause statements # prepared before the change to fail. # It should only be done in very specific use cases where there is only a single client thread # executing synchronous queries (such as a cqlsh-like interpreter). In other cases, clients # should prefix table names in their queries instead. # # Note that CASSANDRA-10145 (scheduled for C* 4.0) will introduce a per-request keyspace option # as a workaround to this issue. # # Required: yes # Modifiable at runtime: yes, the new value will be used for keyspace switches occurring after # the change. # Overridable in a profile: no warn-if-set-keyspace = true # If tracing is enabled for a query, this controls how the trace is fetched. trace { # How many times the driver will attempt to fetch the query if it is not ready yet. # # Required: yes # Modifiable at runtime: yes, the new value will be used for traces fetched after the change. # Overridable in a profile: yes attempts = 5 # The interval between each attempt. # # Required: yes # Modifiable at runtime: yes, the new value will be used for traces fetched after the change. # Overridable in a profile: yes interval = 3 milliseconds # The consistency level to use for trace queries. # Note that the default replication strategy for the system_traces keyspace is SimpleStrategy # with RF=2, therefore LOCAL_ONE might not work if the local DC has no replicas for a given # trace id. # # Required: yes # Modifiable at runtime: yes, the new value will be used for traces fetched after the change. # Overridable in a profile: yes consistency = ONE } # Whether logging of server warnings generated during query execution should be disabled by the # driver. All server generated warnings will be available programmatically via the ExecutionInfo # object on the executed statement's ResultSet. If set to "false", this will prevent the driver # from logging these warnings. # # NOTE: The log formatting for these warning messages will reuse the options defined for # advanced.request-tracker. # # Required: yes # Modifiable at runtime: yes, the new value will be used for query warnings received after the change. # Overridable in a profile: yes log-warnings = true } # Graph (DataStax Enterprise only) advanced.graph { # The sub-protocol the driver will use to communicate with DSE Graph, on top of the Cassandra # native protocol. # # You should almost never have to change this: the driver sets it automatically, based on the # information it has about the server. One exception is if you use the script API against a # legacy DSE version (5.0.3 or older). In that case, you need to force the sub-protocol to # "graphson-1.0". # # This can also be overridden programmatically with GraphStatement.setSubProtocol(). If both are # specified, the programmatic value takes precedence, and this option is ignored. # # Possible values with built-in support in the driver are: # [ "graphson-1.0", "graphson-2.0", "graph-binary-1.0"] # # IMPORTANT: The default value for the Graph sub-protocol is based only on the DSE # version. If the version is DSE 6.7 and lower, "graphson-2.0" will be the default. For DSE 6.8 # and higher, the default value is "graphson-binary-1.0". # # Required: no # Modifiable at runtime: yes, the new value will be used for requests issued after the change. # Overridable in a profile: yes // sub-protocol = "graphson-2.0" # # Whether or not Graph paging should be enabled or disabled for all queries. # # <p>If AUTO is set, the driver will decide whether or not to enable Graph paging # based on the protocol version in use and the DSE version of all hosts. For this reason it is # usually not necessary to change this setting. # # <p><b>IMPORTANT</b>: Paging for DSE Graph is only available in DSE 6.8 and higher, and # requires protocol version DSE_V1 or higher and graphs created with the Native engine; enabling # paging for clusters and graphs that do not meet this requirement may result in query failures. # # Supported values are: ENABLED, DISABLED, AUTO paging-enabled = "AUTO" paging-options { # The page size. # # The value specified here can be interpreted in number of rows. # Interpetation in number of bytes is not supported for graph continuous paging queries. # # It controls how many rows will be retrieved simultaneously in a single # network roundtrip (the goal being to avoid loading too many results in memory at the same # time). If there are more results, additional requests will be used to retrieve them (either # automatically if you iterate with the sync API, or explicitly with the async API's # fetchNextPage method). # # The default is the same as the driver's normal request page size, # i.e., 5000 (rows). # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes page-size = ${datastax-java-driver.advanced.continuous-paging.page-size} # The maximum number of pages to return. # # The default is zero, which means retrieve all pages. # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes max-pages = ${datastax-java-driver.advanced.continuous-paging.max-pages} # Returns the maximum number of pages per second. # # The default is zero, which means no limit. # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes max-pages-per-second = ${datastax-java-driver.advanced.continuous-paging.max-pages-per-second} # Returns the maximum number of pages per second. # # The default is zero, which means no limit. # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes max-enqueued-pages = ${datastax-java-driver.advanced.continuous-paging.max-enqueued-pages} } } # Continuous paging (DataStax Enterprise only) advanced.continuous-paging { # The page size. # # The value specified here can be interpreted in number of rows # or in number of bytes, depending on the unit defined with page-unit (see below). # # It controls how many rows (or how much data) will be retrieved simultaneously in a single # network roundtrip (the goal being to avoid loading too many results in memory at the same # time). If there are more results, additional requests will be used to retrieve them (either # automatically if you iterate with the sync API, or explicitly with the async API's # fetchNextPage method). # # The default is the same as the driver's normal request page size, # i.e., 5000 (rows). # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes page-size = ${datastax-java-driver.basic.request.page-size} # Whether the page-size option should be interpreted in number of rows or bytes. # # The default is false, i.e., the page size will be interpreted in number of rows. # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes page-size-in-bytes = false # The maximum number of pages to return. # # The default is zero, which means retrieve all pages. # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes max-pages = 0 # Returns the maximum number of pages per second. # # The default is zero, which means no limit. # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes max-pages-per-second = 0 # The maximum number of pages that can be stored in the local queue. # # This value must be positive. The default is 4. # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes max-enqueued-pages = 4 # Timeouts for continuous paging. # # Note that there is no global timeout for continuous paging as there is # for regular queries, because continuous paging queries can take an arbitrarily # long time to complete. # # Instead, timeouts are applied to each exchange between the driver and the coordinator. In # other words, if the driver decides to retry, all timeouts are reset. timeout { # How long to wait for the coordinator to send the first page. # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes first-page = 2 seconds # How long to wait for the coordinator to send subsequent pages. # # Required: yes # Modifiable at runtime: yes, the new value will be used for continuous requests issued after # the change # Overridable in a profile: yes other-pages = 1 second } } # DataStax Insights advanced.monitor-reporting { # Whether to send monitoring events. # # The default is true. # # Required: no (defaults to true) # Modifiable at runtime: no # Overridable in a profile: no enabled = true } advanced.metrics { # Metrics Factory configuration. factory { # The class for the metrics factory. # # The driver provides out-of-the-box support for three metrics libraries: Dropwizard, # Micrometer and MicroProfile Metrics. # # Dropwizard is the default metrics library in the driver; to use Dropwizard, this value # should be left to its default, "DefaultMetricsFactory", or set to # "DropwizardMetricsFactory". The only difference between the two is that the former will work # even if Dropwizard is not present on the classpath (in which case it will silently disable # metrics), while the latter requires its presence. # # To select Micrometer, set the value to "MicrometerMetricsFactory", and to select # MicroProfile Metrics, set the value to "MicroProfileMetricsFactory". For these libraries to # be used, you will also need to add an additional dependency: # - Micrometer: com.datastax.oss:java-driver-metrics-micrometer # - MicroProfile: com.datastax.oss:java-driver-metrics-microprofile # # If you would like to use another metrics library, set this value to the fully-qualified name # of a class that implements com.datastax.oss.driver.internal.core.metrics.MetricsFactory. # # It is also possible to use "NoopMetricsFactory", which forcibly disables metrics completely. # In fact, "DefaultMetricsFactory" delegates to "DropwizardMetricsFactory" if Dropwizard is # present on the classpath, or to "NoopMetricsFactory" if it isn't. # # Note: specifying a metrics factory is not enough to enable metrics; for the driver to # actually start collecting metrics, you also need to specify which metrics to collect. See # the following options for more information: # - advanced.metrics.session.enabled # - advanced.metrics.node.enabled # # See also the driver online manual for extensive instructions about how to configure metrics. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no class = DefaultMetricsFactory } # This section configures how metric ids are generated. A metric id is a unique combination of # a metric name and metric tags. id-generator { # The class name of a component implementing # com.datastax.oss.driver.internal.core.metrics.MetricIdGenerator. If it is not qualified, the # driver assumes that it resides in the package com.datastax.oss.driver.internal.core.metrics. # # The driver ships with two built-in implementations: # # - DefaultMetricIdGenerator: generates identifiers composed solely of (unique) metric names; # it does not generate tags. It is mostly suitable for use with metrics libraries that do # not support tags, like Dropwizard. # - TaggingMetricIdGenerator: generates identifiers composed of name and tags. It is mostly # suitable for use with metrics libraries that support tags, like Micrometer or MicroProfile # Metrics. # # For example, here is how each one of them generates identifiers for the session metric # "bytes-sent", assuming that the session is named "s0": # - DefaultMetricIdGenerator: name "s0.bytes-sent", tags: {}. # - TaggingMetricIdGenerator: name "session.bytes-sent", tags: {"session":"s0"} # # Here is how each one of them generates identifiers for the node metric "bytes-sent", # assuming that the session is named "s0", and the node's broadcast address is 10.1.2.3:9042: # - DefaultMetricIdGenerator: name "s0.nodes.10_1_2_3:9042.bytes-sent", tags: {}. # - TaggingMetricIdGenerator: name "nodes.bytes-sent", tags: { "session" : "s0", # "node" : "\10.1.2.3:9042" } # # As shown above, both built-in implementations generate names that are path-like structures # separated by dots. This is indeed the most common expected format by reporting tools. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no class = DefaultMetricIdGenerator # An optional prefix to prepend to each generated metric name. # # The prefix should not start nor end with a dot or any other path separator; the following # are two valid examples: "cassandra" or "myapp.prod.cassandra". # # For example, if this prefix is set to "cassandra", here is how the session metric # "bytes-sent" would be named, assuming that the session is named "s0": # - with DefaultMetricIdGenerator: "cassandra.s0.bytes-sent" # - with TaggingMetricIdGenerator: "cassandra.session.bytes-sent" # # Here is how the node metric "bytes-sent" would be named, assuming that the session is named # "s0", and the node's broadcast address is 10.1.2.3:9042: # - with DefaultMetricIdGenerator: "cassandra.s0.nodes.10_1_2_3:9042.bytes-sent" # - with TaggingMetricIdGenerator: "cassandra.nodes.bytes-sent" # # Required: no # Modifiable at runtime: no # Overridable in a profile: no // prefix = "cassandra" } # The session-level metrics (all disabled by default). # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no session { enabled = [ # The number and rate of bytes sent for the entire session (exposed as a Meter if available, # otherwise as a Counter). // bytes-sent, # The number and rate of bytes received for the entire session (exposed as a Meter if # available, otherwise as a Counter). // bytes-received # The number of nodes to which the driver has at least one active connection (exposed as a # Gauge<Integer>). // connected-nodes, # The throughput and latency percentiles of CQL requests (exposed as a Timer). # # This corresponds to the overall duration of the session.execute() call, including any # retry. // cql-requests, # The number of CQL requests that timed out -- that is, the session.execute() call failed # with a DriverTimeoutException (exposed as a Counter). // cql-client-timeouts, # The size of the driver-side cache of CQL prepared statements (exposed as a Gauge<Long>). # # The cache uses weak values eviction, so this represents the number of PreparedStatement # instances that your application has created, and is still holding a reference to. Note # that the returned value is approximate. // cql-prepared-cache-size, # How long requests are being throttled (exposed as a Timer). # # This is the time between the start of the session.execute() call, and the moment when # the throttler allows the request to proceed. // throttling.delay, # The size of the throttling queue (exposed as a Gauge<Integer>). # # This is the number of requests that the throttler is currently delaying in order to # preserve its SLA. This metric only works with the built-in concurrency- and rate-based # throttlers; in other cases, it will always be 0. // throttling.queue-size, # The number of times a request was rejected with a RequestThrottlingException (exposed as # a Counter) // throttling.errors, # The throughput and latency percentiles of DSE continuous CQL requests (exposed as a # Timer). # # This metric is a session-level metric and corresponds to the overall duration of the # session.executeContinuously() call, including any retry. # # Note that this metric is analogous to the OSS driver's 'cql-requests' metrics, but for # continuous paging requests only. Continuous paging requests do not update the # 'cql-requests' metric, because they are usually much longer. Only the following metrics # are updated during a continuous paging request: # # - At node level: all the usual metrics available for normal CQL requests, such as # 'cql-messages' and error-related metrics (but these are only updated for the first # page of results); # - At session level: only 'continuous-cql-requests' is updated (this metric). // continuous-cql-requests, # The throughput and latency percentiles of Graph requests (exposed as a Timer). # # This metric is a session-level metric and corresponds to the overall duration of the # session.execute(GraphStatement) call, including any retry. // graph-requests, # The number of graph requests that timed out -- that is, the # session.execute(GraphStatement) call failed with a DriverTimeoutException (exposed as a # Counter). # # Note that this metric is analogous to the OSS driver's 'cql-client-timeouts' metrics, but # for Graph requests only. // graph-client-timeouts ] # Extra configuration (for the metrics that need it) # Required: if the 'cql-requests' metric is enabled, and Dropwizard or Micrometer is used. # Modifiable at runtime: no # Overridable in a profile: no cql-requests { # The largest latency that we expect to record. # # This should be slightly higher than request.timeout (in theory, readings can't be higher # than the timeout, but there might be a small overhead due to internal scheduling). # # This is used to scale internal data structures. If a higher recording is encountered at # runtime, it is discarded and a warning is logged. # Valid for: Dropwizard, Micrometer. highest-latency = 3 seconds # The shortest latency that we expect to record. This is used to scale internal data # structures. # Valid for: Micrometer. lowest-latency = 1 millisecond # The number of significant decimal digits to which internal structures will maintain # value resolution and separation (for example, 3 means that recordings up to 1 second # will be recorded with a resolution of 1 millisecond or better). # # For Dropwizard, this must be between 0 and 5. If the value is out of range, it defaults to # 3 and a warning is logged. # Valid for: Dropwizard, Micrometer. significant-digits = 3 # The interval at which percentile data is refreshed. # # The driver records latency data in a "live" histogram, and serves results from a cached # snapshot. Each time the snapshot gets older than the interval, the two are switched. # Note that this switch happens upon fetching the metrics, so if you never fetch the # recording interval might grow higher (that shouldn't be an issue in a production # environment because you would typically have a metrics reporter that exports to a # monitoring tool at a regular interval). # # In practice, this means that if you set this to 5 minutes, you're looking at data from a # 5-minute interval in the past, that is at most 5 minutes old. If you fetch the metrics # at a faster pace, you will observe the same data for 5 minutes until the interval # expires. # # Note that this does not apply to the total count and rates (those are updated in real # time). # Valid for: Dropwizard. refresh-interval = 5 minutes # An optional list of latencies to track as part of the application's service-level # objectives (SLOs). # # If defined, the histogram is guaranteed to contain these boundaries alongside other # buckets used to generate aggregable percentile approximations. # Valid for: Micrometer. // slo = [ 100 milliseconds, 500 milliseconds, 1 second ] } # Required: if the 'throttling.delay' metric is enabled, and Dropwizard or Micrometer is used. # Modifiable at runtime: no # Overridable in a profile: no throttling.delay { highest-latency = 3 seconds lowest-latency = 1 millisecond significant-digits = 3 refresh-interval = 5 minutes // slo = [ 100 milliseconds, 500 milliseconds, 1 second ] } # Required: if the 'continuous-cql-requests' metric is enabled, and Dropwizard or Micrometer # is used. # Modifiable at runtime: no # Overridable in a profile: no continuous-cql-requests { highest-latency = 120 seconds lowest-latency = 10 milliseconds significant-digits = 3 refresh-interval = 5 minutes // slo = [ 100 milliseconds, 500 milliseconds, 1 second ] } # Required: if the 'graph-requests' metric is enabled, and Dropwizard or Micrometer is used. # Modifiable at runtime: no # Overridable in a profile: no graph-requests { highest-latency = 12 seconds lowest-latency = 1 millisecond significant-digits = 3 refresh-interval = 5 minutes // slo = [ 100 milliseconds, 500 milliseconds, 1 second ] } } # The node-level metrics (all disabled by default). # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no node { enabled = [ # The number of connections open to this node for regular requests (exposed as a # Gauge<Integer>). # # This includes the control connection (which uses at most one extra connection to a # random node in the cluster). // pool.open-connections, # The number of stream ids available on the connections to this node (exposed as a # Gauge<Integer>). # # Stream ids are used to multiplex requests on each connection, so this is an indication # of how many more requests the node could handle concurrently before becoming saturated # (note that this is a driver-side only consideration, there might be other limitations on # the server that prevent reaching that theoretical limit). // pool.available-streams, # The number of requests currently executing on the connections to this node (exposed as a # Gauge<Integer>). This includes orphaned streams. // pool.in-flight, # The number of "orphaned" stream ids on the connections to this node (exposed as a # Gauge<Integer>). # # See the description of the connection.max-orphan-requests option for more details. // pool.orphaned-streams, # The number and rate of bytes sent to this node (exposed as a Meter if available, otherwise # as a Counter). // bytes-sent, # The number and rate of bytes received from this node (exposed as a Meter if available, # otherwise as a Counter). // bytes-received, # The throughput and latency percentiles of individual CQL messages sent to this node as # part of an overall request (exposed as a Timer). # # Note that this does not necessarily correspond to the overall duration of the # session.execute() call, since the driver might query multiple nodes because of retries # and speculative executions. Therefore a single "request" (as seen from a client of the # driver) can be composed of more than one of the "messages" measured by this metric. # # Therefore this metric is intended as an insight into the performance of this particular # node. For statistics on overall request completion, use the session-level cql-requests. // cql-messages, # The number of times the driver failed to send a request to this node (exposed as a # Counter). # # In those case we know the request didn't even reach the coordinator, so they are retried # on the next node automatically (without going through the retry policy). // errors.request.unsent, # The number of times a request was aborted before the driver even received a response # from this node (exposed as a Counter). # # This can happen in two cases: if the connection was closed due to an external event # (such as a network error or heartbeat failure); or if there was an unexpected error # while decoding the response (this can only be a driver bug). // errors.request.aborted, # The number of times this node replied with a WRITE_TIMEOUT error (exposed as a Counter). # # Whether this error is rethrown directly to the client, rethrown or ignored is determined # by the RetryPolicy. // errors.request.write-timeouts, # The number of times this node replied with a READ_TIMEOUT error (exposed as a Counter). # # Whether this error is rethrown directly to the client, rethrown or ignored is determined # by the RetryPolicy. // errors.request.read-timeouts, # The number of times this node replied with an UNAVAILABLE error (exposed as a Counter). # # Whether this error is rethrown directly to the client, rethrown or ignored is determined # by the RetryPolicy. // errors.request.unavailables, # The number of times this node replied with an error that doesn't fall under other # 'errors.*' metrics (exposed as a Counter). // errors.request.others, # The total number of errors on this node that caused the RetryPolicy to trigger a retry # (exposed as a Counter). # # This is a sum of all the other retries.* metrics. // retries.total, # The number of errors on this node that caused the RetryPolicy to trigger a retry, broken # down by error type (exposed as Counters). // retries.aborted, // retries.read-timeout, // retries.write-timeout, // retries.unavailable, // retries.other, # The total number of errors on this node that were ignored by the RetryPolicy (exposed as # a Counter). # # This is a sum of all the other ignores.* metrics. // ignores.total, # The number of errors on this node that were ignored by the RetryPolicy, broken down by # error type (exposed as Counters). // ignores.aborted, // ignores.read-timeout, // ignores.write-timeout, // ignores.unavailable, // ignores.other, # The number of speculative executions triggered by a slow response from this node # (exposed as a Counter). // speculative-executions, # The number of errors encountered while trying to establish a connection to this node # (exposed as a Counter). # # Connection errors are not a fatal issue for the driver, failed connections will be # retried periodically according to the reconnection policy. You can choose whether or not # to log those errors at WARN level with the connection.warn-on-init-error option. # # Authentication errors are not included in this counter, they are tracked separately in # errors.connection.auth. // errors.connection.init, # The number of authentication errors encountered while trying to establish a connection # to this node (exposed as a Counter). # Authentication errors are also logged at WARN level. // errors.connection.auth, # The throughput and latency percentiles of individual graph messages sent to this node as # part of an overall request (exposed as a Timer). # # Note that this does not necessarily correspond to the overall duration of the # session.execute() call, since the driver might query multiple nodes because of retries # and speculative executions. Therefore a single "request" (as seen from a client of the # driver) can be composed of more than one of the "messages" measured by this metric. # # Therefore this metric is intended as an insight into the performance of this particular # node. For statistics on overall request completion, use the session-level graph-requests. // graph-messages, ] # See cql-requests in the `session` section # # Required: if the 'cql-messages' metric is enabled, and Dropwizard or Micrometer is used. # Modifiable at runtime: no # Overridable in a profile: no cql-messages { highest-latency = 3 seconds lowest-latency = 1 millisecond significant-digits = 3 refresh-interval = 5 minutes // slo = [ 100 milliseconds, 500 milliseconds, 1 second ] } # See graph-requests in the `session` section # # Required: if the 'graph-messages' metric is enabled, and Dropwizard or Micrometer is used. # Modifiable at runtime: no # Overridable in a profile: no graph-messages { highest-latency = 3 seconds lowest-latency = 1 millisecond significant-digits = 3 refresh-interval = 5 minutes // slo = [ 100 milliseconds, 500 milliseconds, 1 second ] } # The time after which the node level metrics will be evicted. # # This is used to unregister stale metrics if a node leaves the cluster or gets a new address. # If the node does not come back up when this interval elapses, all its metrics are removed # from the registry. # # The lowest allowed value is 5 minutes. If you try to set it lower, the driver will log a # warning and use 5 minutes. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no expire-after = 1 hour } } advanced.socket { # Whether or not to disable the Nagle algorithm. # # By default, this option is set to true (Nagle disabled), because the driver has its own # internal message coalescing algorithm. # # See java.net.StandardSocketOptions.TCP_NODELAY. # # Required: yes # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no tcp-no-delay = true # All other socket options are unset by default. The actual value depends on the underlying # Netty transport: # - NIO uses the defaults from java.net.Socket (refer to the javadocs of # java.net.StandardSocketOptions for each option). # - Epoll delegates to the underlying file descriptor, which uses the O/S defaults. # Whether or not to enable TCP keep-alive probes. # # See java.net.StandardSocketOptions.SO_KEEPALIVE. # # Required: no # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no //keep-alive = false # Whether or not to allow address reuse. # # See java.net.StandardSocketOptions.SO_REUSEADDR. # # Required: no # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no //reuse-address = true # Sets the linger interval. # # If the value is zero or greater, then it represents a timeout value, in seconds; # if the value is negative, it means that this option is disabled. # # See java.net.StandardSocketOptions.SO_LINGER. # # Required: no # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no //linger-interval = 0 # Sets a hint to the size of the underlying buffers for incoming network I/O. # # See java.net.StandardSocketOptions.SO_RCVBUF. # # Required: no # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no //receive-buffer-size = 65535 # Sets a hint to the size of the underlying buffers for outgoing network I/O. # # See java.net.StandardSocketOptions.SO_SNDBUF. # # Required: no # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no //send-buffer-size = 65535 } advanced.heartbeat { # The heartbeat interval. If a connection stays idle for that duration (no reads), the driver # sends a dummy message on it to make sure it's still alive. If not, the connection is trashed # and replaced. # # Required: yes # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no interval = 30 seconds # How long the driver waits for the response to a heartbeat. If this timeout fires, the # heartbeat is considered failed. # # Required: yes # Modifiable at runtime: yes, the new value will be used for connections created after the # change. # Overridable in a profile: no timeout = ${datastax-java-driver.advanced.connection.init-query-timeout} } advanced.metadata { # Topology events are external signals that inform the driver of the state of Cassandra nodes # (by default, they correspond to gossip events received on the control connection). # The debouncer helps smoothen out oscillations if conflicting events are sent out in short # bursts. # Debouncing may be disabled by setting the window to 0 or max-events to 1 (this is not # recommended). topology-event-debouncer { # How long the driver waits to propagate an event. If another event is received within that # time, the window is reset and a batch of accumulated events will be delivered. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no window = 1 second # The maximum number of events that can accumulate. If this count is reached, the events are # delivered immediately and the time window is reset. This avoids holding events indefinitely # if the window keeps getting reset. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no max-events = 20 } # Options relating to schema metadata (Session.getMetadata.getKeyspaces). # This metadata is exposed by the driver for informational purposes, and is also necessary for # token-aware routing. schema { # Whether schema metadata is enabled. # If this is false, the schema will remain empty, or to the last known value. # # Required: yes # Modifiable at runtime: yes, the new value will be used for refreshes issued after the # change. It can also be overridden programmatically via Session.setSchemaMetadataEnabled. # Overridable in a profile: no enabled = true # The keyspaces for which schema and token metadata should be maintained. # # Each element can be one of the following: # 1. An exact name inclusion, for example "Ks1". If the name is case-sensitive, it must appear # in its exact case. # 2. An exact name exclusion, for example "!Ks1". # 3. A regex inclusion, enclosed in slashes, for example "/^Ks.*/". The part between the # slashes must follow the syntax rules of java.util.regex.Pattern. # 4. A regex exclusion, for example "!/^Ks.*/". # # If the list is empty, or the option is unset, all keyspaces will match. Otherwise: # # If a keyspace matches an exact name inclusion, it is always included, regardless of what any # other rule says. # Otherwise, if it matches an exact name exclusion, it is always excluded, regardless of what # any regex rule says. # Otherwise, if there are regex rules: # - if they're only inclusions, the keyspace must match at least one of them. # - if they're only exclusions, the keyspace must match none of them. # - if they're both, the keyspace must match at least one inclusion and none of the # exclusions. # # If an element is malformed, or if its regex has a syntax error, a warning is logged and that # single element is ignored. # # Try to use only exact name inclusions if possible. This allows the driver to filter on the # server side with a WHERE IN clause. If you use any other rule, it has to fetch all system # rows and filter on the client side. # # Required: no. The default value excludes all Cassandra and DSE system keyspaces. If the # option is unset, this is interpreted as "include all keyspaces". # Modifiable at runtime: yes, the new value will be used for refreshes issued after the # change. # Overridable in a profile: no refreshed-keyspaces = [ "!system", "!/^system_.*/", "!/^dse_.*/", "!solr_admin", "!OpsCenter" ] # The timeout for the requests to the schema tables. # # Required: yes # Modifiable at runtime: yes, the new value will be used for refreshes issued after the # change. # Overridable in a profile: no request-timeout = ${datastax-java-driver.basic.request.timeout} # The page size for the requests to the schema tables. # # Required: yes # Modifiable at runtime: yes, the new value will be used for refreshes issued after the # change. # Overridable in a profile: no request-page-size = ${datastax-java-driver.basic.request.page-size} # Protects against bursts of schema updates (for example when a client issues a sequence of # DDL queries), by coalescing them into a single update. # Debouncing may be disabled by setting the window to 0 or max-events to 1 (this is highly # discouraged for schema refreshes). debouncer { # How long the driver waits to apply a refresh. If another refresh is requested within that # time, the window is reset and a single refresh will be triggered when it ends. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no window = 1 second # The maximum number of refreshes that can accumulate. If this count is reached, a refresh # is done immediately and the window is reset. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no max-events = 20 } } # Whether token metadata (Session.getMetadata.getTokenMap) is enabled. # This metadata is exposed by the driver for informational purposes, and is also necessary for # token-aware routing. # If this is false, it will remain empty, or to the last known value. Note that its computation # requires information about the schema; therefore if schema metadata is disabled or filtered to # a subset of keyspaces, the token map will be incomplete, regardless of the value of this # property. # # Required: yes # Modifiable at runtime: yes, the new value will be used for refreshes issued after the change. # Overridable in a profile: no token-map.enabled = true } advanced.control-connection { # How long the driver waits for responses to control queries (e.g. fetching the list of nodes, # refreshing the schema). # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no timeout = ${datastax-java-driver.advanced.connection.init-query-timeout} # Due to the distributed nature of Cassandra, schema changes made on one node might not be # immediately visible to others. Under certain circumstances, the driver waits until all nodes # agree on a common schema version (namely: before a schema refresh, before repreparing all # queries on a newly up node, and before completing a successful schema-altering query). To do # so, it queries system tables to find out the schema version of all nodes that are currently # UP. If all the versions match, the check succeeds, otherwise it is retried periodically, until # a given timeout. # # A schema agreement failure is not fatal, but it might produce unexpected results (for example, # getting an "unconfigured table" error for a table that you created right before, just because # the two queries went to different coordinators). # # Note that schema agreement never succeeds in a mixed-version cluster (it would be challenging # because the way the schema version is computed varies across server versions); the assumption # is that schema updates are unlikely to happen during a rolling upgrade anyway. schema-agreement { # The interval between each attempt. # Required: yes # Modifiable at runtime: yes, the new value will be used for checks issued after the change. # Overridable in a profile: no interval = 200 milliseconds # The timeout after which schema agreement fails. # If this is set to 0, schema agreement is skipped and will always fail. # # Required: yes # Modifiable at runtime: yes, the new value will be used for checks issued after the change. # Overridable in a profile: no timeout = 10 seconds # Whether to log a warning if schema agreement fails. # You might want to change this if you've set the timeout to 0. # # Required: yes # Modifiable at runtime: yes, the new value will be used for checks issued after the change. # Overridable in a profile: no warn-on-failure = true } } advanced.prepared-statements { # Whether `Session.prepare` calls should be sent to all nodes in the cluster. # # A request to prepare is handled in two steps: # 1) send to a single node first (to rule out simple errors like malformed queries). # 2) if step 1 succeeds, re-send to all other active nodes (i.e. not ignored by the load # balancing policy). # This option controls whether step 2 is executed. # # The reason why you might want to disable it is to optimize network usage if you have a large # number of clients preparing the same set of statements at startup. If your load balancing # policy distributes queries randomly, each client will pick a different host to prepare its # statements, and on the whole each host has a good chance of having been hit by at least one # client for each statement. # On the other hand, if that assumption turns out to be wrong and one host hasn't prepared a # given statement, it needs to be re-prepared on the fly the first time it gets executed; this # causes a performance penalty (one extra roundtrip to resend the query to prepare, and another # to retry the execution). # # Required: yes # Modifiable at runtime: yes, the new value will be used for prepares issued after the change. # Overridable in a profile: yes prepare-on-all-nodes = true # How the driver replicates prepared statements on a node that just came back up or joined the # cluster. reprepare-on-up { # Whether the driver tries to prepare on new nodes at all. # # The reason why you might want to disable it is to optimize reconnection time when you # believe nodes often get marked down because of temporary network issues, rather than the # node really crashing. In that case, the node still has prepared statements in its cache when # the driver reconnects, so re-preparing is redundant. # # On the other hand, if that assumption turns out to be wrong and the node had really # restarted, its prepared statement cache is empty (before CASSANDRA-8831), and statements # need to be re-prepared on the fly the first time they get executed; this causes a # performance penalty (one extra roundtrip to resend the query to prepare, and another to # retry the execution). # # Required: yes # Modifiable at runtime: yes, the new value will be used for nodes that come back up after the # change. # Overridable in a profile: no enabled = true # Whether to check `system.prepared_statements` on the target node before repreparing. # # This table exists since CASSANDRA-8831 (merged in 3.10). It stores the statements already # prepared on the node, and preserves them across restarts. # # Checking the table first avoids repreparing unnecessarily, but the cost of the query is not # always worth the improvement, especially if the number of statements is low. # # If the table does not exist, or the query fails for any other reason, the error is ignored # and the driver proceeds to reprepare statements according to the other parameters. # # Required: yes # Modifiable at runtime: yes, the new value will be used for nodes that come back up after the # change. # Overridable in a profile: no check-system-table = false # The maximum number of statements that should be reprepared. 0 or a negative value means no # limit. # # Required: yes # Modifiable at runtime: yes, the new value will be used for nodes that come back up after the # change. # Overridable in a profile: no max-statements = 0 # The maximum number of concurrent requests when repreparing. # # Required: yes # Modifiable at runtime: yes, the new value will be used for nodes that come back up after the # change. # Overridable in a profile: no max-parallelism = 100 # The request timeout. This applies both to querying the system.prepared_statements table (if # relevant), and the prepare requests themselves. # # Required: yes # Modifiable at runtime: yes, the new value will be used for nodes that come back up after the # change. # Overridable in a profile: no timeout = ${datastax-java-driver.advanced.connection.init-query-timeout} } # How to build the cache of prepared statements. prepared-cache { # Whether to use weak references for the prepared statements cache values. # # If this option is absent, weak references will be used. # # Required: no # Modifiable at runtime: no # Overridable in a profile: no // weak-values = true } } # Options related to the Netty event loop groups used internally by the driver. advanced.netty { # Whether the threads created by the driver should be daemon threads. # This will apply to the threads in io-group, admin-group, and the timer thread. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no daemon = false # The event loop group used for I/O operations (reading and writing to Cassandra nodes). # By default, threads in this group are named after the session name, "-io-" and an incrementing # counter, for example "s0-io-0". io-group { # The number of threads. # If this is set to 0, the driver will use `Runtime.getRuntime().availableProcessors() * 2`. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no size = 0 # The options to shut down the event loop group gracefully when the driver closes. If a task # gets submitted during the quiet period, it is accepted and the quiet period starts over. # The timeout limits the overall shutdown time. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no shutdown {quiet-period = 2, timeout = 15, unit = SECONDS} } # The event loop group used for admin tasks not related to request I/O (handle cluster events, # refresh metadata, schedule reconnections, etc.) # By default, threads in this group are named after the session name, "-admin-" and an # incrementing counter, for example "s0-admin-0". admin-group { size = 2 shutdown {quiet-period = 2, timeout = 15, unit = SECONDS} } # The timer used for scheduling request timeouts and speculative executions # By default, this thread is named after the session name and "-timer-0", for example # "s0-timer-0". timer { # The timer tick duration. # This is how frequent the timer should wake up to check for timed-out tasks or speculative # executions. Lower resolution (i.e. longer durations) will leave more CPU cycles for running # I/O operations at the cost of precision of exactly when a request timeout will expire or a # speculative execution will run. Higher resolution (i.e. shorter durations) will result in # more precise request timeouts and speculative execution scheduling, but at the cost of CPU # cycles taken from I/O operations, which could lead to lower overall I/O throughput. # # The default value is 100 milliseconds, which is a comfortable value for most use cases. # However if you are using more agressive timeouts or speculative execution delays, then you # should lower the timer tick duration as well, so that its value is always equal to or lesser # than the timeout duration and/or speculative execution delay you intend to use. # # Note for Windows users: avoid setting this to aggressive values, that is, anything under 100 # milliseconds; doing so is known to cause extreme CPU usage. Also, the tick duration must be # a multiple of 10 under Windows; if that is not the case, it will be automatically rounded # down to the nearest multiple of 10 (e.g. 99 milliseconds will be rounded down to 90 # milliseconds). # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no tick-duration = 100 milliseconds # Number of ticks in a Timer wheel. The underlying implementation uses Netty's # HashedWheelTimer, which uses hashes to arrange the timeouts. This effectively controls the # size of the timer wheel. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no ticks-per-wheel = 2048 } } # The component that coalesces writes on the connections. # This is exposed mainly to facilitate tuning during development. You shouldn't have to adjust # this. advanced.coalescer { # The reschedule interval. # # Required: yes # Modifiable at runtime: no # Overridable in a profile: no reschedule-interval = 10 microseconds } profiles { # This is where your custom profiles go, for example: # olap { # basic.request.timeout = 5 seconds # } # An example configuration profile for graph requests. // my-graph-profile-example { // graph { // read-consistency-level = LOCAL_QUORUM // write-consistency-level = LOCAL_ONE // } // } # An example pre-defined configuration profile for OLAP graph queries. // graph-olap { // graph { // traversal-source = "a" // traversal source needs to be set to "a" for OLAP queries. // } // } } }