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A driver for Apache Cassandra 1.2+ that works exclusively with the Cassandra Query Language version 3 (CQL3) and Cassandra's binary protocol.

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/*
 * Copyright DataStax, Inc.
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
package com.datastax.driver.core;

import static com.datastax.driver.core.HostDistance.LOCAL;
import static com.datastax.driver.core.HostDistance.REMOTE;

import com.google.common.base.Preconditions;
import com.google.common.collect.ImmutableMap;
import java.util.Map;
import java.util.concurrent.Executor;

/**
 * Options related to connection pooling.
 *
 * 

The driver uses connections in an asynchronous manner, meaning that multiple requests can be * submitted on the same connection at the same time. Therefore only a relatively small number of * connections is needed. For each host, the driver uses a connection pool that may have a variable * size (it will automatically adjust to the current load). * *

With {@code ProtocolVersion#V2} or below, there are at most 128 simultaneous requests per * connection, so the pool defaults to a variable size. You will typically raise the maximum * capacity by adding more connections with {@link #setMaxConnectionsPerHost(HostDistance, int)}. * *

With {@code ProtocolVersion#V3} or above, there are up to 32768 requests per connection, and * the pool defaults to a fixed size of 1. You will typically raise the maximum capacity by allowing * more simultaneous requests per connection ({@link #setMaxRequestsPerConnection(HostDistance, * int)}). * *

All parameters can be separately set for {@code LOCAL} and {@code REMOTE} hosts ({@link * HostDistance}). For {@code IGNORED} hosts, no connections are created so these settings cannot be * changed. */ public class PoolingOptions { /** * The value returned for connection options when they have not been set by the client, and the * protocol version is not known yet. * *

Once a {@code PoolingOptions} object is associated to a {@link Cluster} and that cluster * initializes, the protocol version will be detected, and connection options will take their * default values for that protocol version. * *

The methods that may return this value are: {@link * #getCoreConnectionsPerHost(HostDistance)}, {@link #getMaxConnectionsPerHost(HostDistance)}, * {@link #getNewConnectionThreshold(HostDistance)}, {@link * #getMaxRequestsPerConnection(HostDistance)}. */ public static final int UNSET = Integer.MIN_VALUE; public static final String CORE_POOL_LOCAL_KEY = "corePoolLocal"; public static final String MAX_POOL_LOCAL_KEY = "maxPoolLocal"; public static final String CORE_POOL_REMOTE_KEY = "corePoolRemote"; public static final String MAX_POOL_REMOTE_KEY = "maxPoolRemote"; public static final String NEW_CONNECTION_THRESHOLD_LOCAL_KEY = "newConnectionThresholdLocal"; public static final String NEW_CONNECTION_THRESHOLD_REMOTE_KEY = "newConnectionThresholdRemote"; public static final String MAX_REQUESTS_PER_CONNECTION_LOCAL_KEY = "maxRequestsPerConnectionLocal"; public static final String MAX_REQUESTS_PER_CONNECTION_REMOTE_KEY = "maxRequestsPerConnectionRemote"; /** * The default values for connection options, that depend on the native protocol version. * *

The map stores protocol versions in ascending order, and only the versions that introduced a * change are present. To find the defaults for a particular version, look for the highest key * that is less than or equal to that version, in other words: * *

{@code
   * ProtocolVersion referenceVersion = null;
   * for (ProtocolVersion key : DEFAULTS.keySet()) {
   *     if (key.compareTo(actualVersion) > 0)
   *         break;
   *     else
   *         referenceVersion = key;
   * }
   * Map defaults = DEFAULTS.get(referenceVersion);
   * }
* * Once you've extracted the underlying map, use the keys {@code CORE_POOL_LOCAL_KEY}, {@code * MAX_POOL_LOCAL_KEY}, {@code CORE_POOL_REMOTE_KEY}, {@code MAX_POOL_REMOTE_KEY}, {@code * NEW_CONNECTION_THRESHOLD_LOCAL_KEY}, {@code NEW_CONNECTION_THRESHOLD_REMOTE_KEY}, {@code * MAX_REQUESTS_PER_CONNECTION_LOCAL_KEY} and {@code MAX_REQUESTS_PER_CONNECTION_REMOTE_KEY}. * * @see #UNSET */ public static final Map> DEFAULTS = ImmutableMap.>of( ProtocolVersion.V1, ImmutableMap.builder() .put(CORE_POOL_LOCAL_KEY, 2) .put(MAX_POOL_LOCAL_KEY, 8) .put(CORE_POOL_REMOTE_KEY, 1) .put(MAX_POOL_REMOTE_KEY, 2) .put(NEW_CONNECTION_THRESHOLD_LOCAL_KEY, 100) .put(NEW_CONNECTION_THRESHOLD_REMOTE_KEY, 100) .put(MAX_REQUESTS_PER_CONNECTION_LOCAL_KEY, 128) .put(MAX_REQUESTS_PER_CONNECTION_REMOTE_KEY, 128) .build(), ProtocolVersion.V3, ImmutableMap.builder() .put(CORE_POOL_LOCAL_KEY, 1) .put(MAX_POOL_LOCAL_KEY, 1) .put(CORE_POOL_REMOTE_KEY, 1) .put(MAX_POOL_REMOTE_KEY, 1) .put(NEW_CONNECTION_THRESHOLD_LOCAL_KEY, 800) .put(NEW_CONNECTION_THRESHOLD_REMOTE_KEY, 200) .put(MAX_REQUESTS_PER_CONNECTION_LOCAL_KEY, 1024) .put(MAX_REQUESTS_PER_CONNECTION_REMOTE_KEY, 256) .build()); /** The default value for {@link #getIdleTimeoutSeconds()} ({@value}). */ public static final int DEFAULT_IDLE_TIMEOUT_SECONDS = 120; /** The default value for {@link #getPoolTimeoutMillis()} ({@value}). */ public static final int DEFAULT_POOL_TIMEOUT_MILLIS = 5000; /** The default value for {@link #getMaxQueueSize()} ({@value}). */ public static final int DEFAULT_MAX_QUEUE_SIZE = 256; /** The default value for {@link #getHeartbeatIntervalSeconds()} ({@value}). */ public static final int DEFAULT_HEARTBEAT_INTERVAL_SECONDS = 30; private static final Executor DEFAULT_INITIALIZATION_EXECUTOR = GuavaCompatibility.INSTANCE.sameThreadExecutor(); private volatile Cluster.Manager manager; private volatile ProtocolVersion protocolVersion; // The defaults for these fields depend on the protocol version, which is only known after control // connection initialization. // Yet if the user set them before initialization, we want to keep their values. So we use -1 to // mean "uninitialized". private final int[] coreConnections = new int[] {UNSET, UNSET, 0}; private final int[] maxConnections = new int[] {UNSET, UNSET, 0}; private final int[] newConnectionThreshold = new int[] {UNSET, UNSET, 0}; private volatile int maxRequestsPerConnectionLocal = UNSET; private volatile int maxRequestsPerConnectionRemote = UNSET; private volatile int idleTimeoutSeconds = DEFAULT_IDLE_TIMEOUT_SECONDS; private volatile int poolTimeoutMillis = DEFAULT_POOL_TIMEOUT_MILLIS; private volatile int maxQueueSize = DEFAULT_MAX_QUEUE_SIZE; private volatile int heartbeatIntervalSeconds = DEFAULT_HEARTBEAT_INTERVAL_SECONDS; private volatile Executor initializationExecutor = DEFAULT_INITIALIZATION_EXECUTOR; public PoolingOptions() {} void register(Cluster.Manager manager) { this.manager = manager; } /** * Returns the core number of connections per host. * * @param distance the {@code HostDistance} for which to return this threshold. * @return the core number of connections per host at distance {@code distance}. */ public int getCoreConnectionsPerHost(HostDistance distance) { return coreConnections[distance.ordinal()]; } /** * Sets the core number of connections per host. * *

For the provided {@code distance}, this corresponds to the number of connections initially * created and kept open to each host of that distance. * *

The default value is: * *

    *
  • with {@code ProtocolVersion#V2} or below: 2 for {@code LOCAL} hosts and 1 for {@code * REMOTE} hosts. *
  • with {@code ProtocolVersion#V3} or above: 1 for all hosts. *
* * @param distance the {@code HostDistance} for which to set this threshold. * @param newCoreConnections the value to set * @return this {@code PoolingOptions}. * @throws IllegalArgumentException if {@code distance == HostDistance.IGNORED}, or if {@code * newCoreConnections} is greater than the maximum value for this distance. * @see #setConnectionsPerHost(HostDistance, int, int) */ public synchronized PoolingOptions setCoreConnectionsPerHost( HostDistance distance, int newCoreConnections) { if (distance == HostDistance.IGNORED) throw new IllegalArgumentException( "Cannot set core connections per host for " + distance + " hosts"); Preconditions.checkArgument( newCoreConnections >= 0, "core number of connections must be positive"); if (maxConnections[distance.ordinal()] != UNSET) checkConnectionsPerHostOrder( newCoreConnections, maxConnections[distance.ordinal()], distance); int oldCore = coreConnections[distance.ordinal()]; coreConnections[distance.ordinal()] = newCoreConnections; if (oldCore < newCoreConnections && manager != null) manager.ensurePoolsSizing(); return this; } /** * Returns the maximum number of connections per host. * * @param distance the {@code HostDistance} for which to return this threshold. * @return the maximum number of connections per host at distance {@code distance}. */ public int getMaxConnectionsPerHost(HostDistance distance) { return maxConnections[distance.ordinal()]; } /** * Sets the maximum number of connections per host. * *

For the provided {@code distance}, this corresponds to the maximum number of connections * that can be created per host at that distance. * *

The default value is: * *

    *
  • with {@code ProtocolVersion#V2} or below: 8 for {@code LOCAL} hosts and 2 for {@code * REMOTE} hosts. *
  • with {@code ProtocolVersion#V3} or above: 1 for all hosts. *
* * @param distance the {@code HostDistance} for which to set this threshold. * @param newMaxConnections the value to set * @return this {@code PoolingOptions}. * @throws IllegalArgumentException if {@code distance == HostDistance.IGNORED}, or if {@code * newMaxConnections} is less than the core value for this distance. * @see #setConnectionsPerHost(HostDistance, int, int) */ public synchronized PoolingOptions setMaxConnectionsPerHost( HostDistance distance, int newMaxConnections) { if (distance == HostDistance.IGNORED) throw new IllegalArgumentException( "Cannot set max connections per host for " + distance + " hosts"); Preconditions.checkArgument( newMaxConnections >= 0, "max number of connections must be positive"); if (coreConnections[distance.ordinal()] != UNSET) checkConnectionsPerHostOrder( coreConnections[distance.ordinal()], newMaxConnections, distance); maxConnections[distance.ordinal()] = newMaxConnections; return this; } /** * Sets the core and maximum number of connections per host in one call. * *

This is a convenience method that is equivalent to calling {@link * #setCoreConnectionsPerHost(HostDistance, int)} and {@link * #setMaxConnectionsPerHost(HostDistance, int)}. * * @param distance the {@code HostDistance} for which to set these threshold. * @param core the core number of connections. * @param max the max number of connections. * @return this {@code PoolingOptions}. * @throws IllegalArgumentException if {@code distance == HostDistance.IGNORED}, or if {@code * core} > {@code max}. */ public synchronized PoolingOptions setConnectionsPerHost( HostDistance distance, int core, int max) { if (distance == HostDistance.IGNORED) throw new IllegalArgumentException( "Cannot set connections per host for " + distance + " hosts"); Preconditions.checkArgument(core >= 0, "core number of connections must be positive"); Preconditions.checkArgument(max >= 0, "max number of connections must be positive"); checkConnectionsPerHostOrder(core, max, distance); coreConnections[distance.ordinal()] = core; maxConnections[distance.ordinal()] = max; return this; } /** * Returns the threshold that triggers the creation of a new connection to a host. * * @param distance the {@code HostDistance} for which to return this threshold. * @return the configured threshold, or the default one if none have been set. * @see #setNewConnectionThreshold(HostDistance, int) */ public int getNewConnectionThreshold(HostDistance distance) { return newConnectionThreshold[distance.ordinal()]; } /** * Sets the threshold that triggers the creation of a new connection to a host. * *

A new connection gets created if: * *

    *
  • N connections are open *
  • N < {@link #getMaxConnectionsPerHost(HostDistance)} *
  • the number of active requests is more than (N - 1) * {@link * #getMaxRequestsPerConnection(HostDistance)} + {@link * #getNewConnectionThreshold(HostDistance)} *
* * In other words, if all but the last connection are full, and the last connection is above this * threshold. * *

The default value is: * *

    *
  • with {@code ProtocolVersion#V2} or below: 100 for all hosts. *
  • with {@code ProtocolVersion#V3} or above: 800 for {@code LOCAL} hosts and 200 for {@code * REMOTE} hosts. *
* * @param distance the {@code HostDistance} for which to configure this threshold. * @param newValue the value to set (between 0 and 128). * @return this {@code PoolingOptions}. * @throws IllegalArgumentException if {@code distance == HostDistance.IGNORED}, or if {@code * maxSimultaneousRequests} is not in range, or if {@code newValue} is less than the minimum * value for this distance. */ public synchronized PoolingOptions setNewConnectionThreshold( HostDistance distance, int newValue) { if (distance == HostDistance.IGNORED) throw new IllegalArgumentException( "Cannot set new connection threshold for " + distance + " hosts"); checkRequestsPerConnectionRange(newValue, "New connection threshold", distance); newConnectionThreshold[distance.ordinal()] = newValue; return this; } /** * Returns the maximum number of requests per connection. * * @param distance the {@code HostDistance} for which to return this threshold. * @return the maximum number of requests per connection at distance {@code distance}. * @see #setMaxRequestsPerConnection(HostDistance, int) */ public int getMaxRequestsPerConnection(HostDistance distance) { switch (distance) { case LOCAL: return maxRequestsPerConnectionLocal; case REMOTE: return maxRequestsPerConnectionRemote; default: return 0; } } /** * Sets the maximum number of requests per connection. * *

The default value is: * *

    *
  • with {@code ProtocolVersion#V2} or below: 128 for all hosts (there should not be any * reason to change this). *
  • with {@code ProtocolVersion#V3} or above: 1024 for {@code LOCAL} hosts and 256 for {@code * REMOTE} hosts. These values were chosen so that the default V2 and V3 configuration * generate the same load on a Cassandra cluster. Protocol V3 can go much higher (up to * 32768), so if your number of clients is low, don't hesitate to experiment with higher * values. If you have more than one connection per host, consider also adjusting {@link * #setNewConnectionThreshold(HostDistance, int)}. *
* * @param distance the {@code HostDistance} for which to set this threshold. * @param newMaxRequests the value to set. * @return this {@code PoolingOptions}. * @throws IllegalArgumentException if {@code distance == HostDistance.IGNORED}, or if {@code * newMaxConnections} is not within the allowed range. */ public PoolingOptions setMaxRequestsPerConnection(HostDistance distance, int newMaxRequests) { checkRequestsPerConnectionRange(newMaxRequests, "Max requests per connection", distance); switch (distance) { case LOCAL: maxRequestsPerConnectionLocal = newMaxRequests; break; case REMOTE: maxRequestsPerConnectionRemote = newMaxRequests; break; default: throw new IllegalArgumentException( "Cannot set max requests per host for " + distance + " hosts"); } return this; } /** * Returns the timeout before an idle connection is removed. * * @return the timeout. */ public int getIdleTimeoutSeconds() { return idleTimeoutSeconds; } /** * Sets the timeout before an idle connection is removed. * *

The order of magnitude should be a few minutes (the default is 120 seconds). The timeout * that triggers the removal has a granularity of 10 seconds. * * @param idleTimeoutSeconds the new timeout in seconds. * @return this {@code PoolingOptions}. * @throws IllegalArgumentException if the timeout is negative. */ public PoolingOptions setIdleTimeoutSeconds(int idleTimeoutSeconds) { if (idleTimeoutSeconds < 0) throw new IllegalArgumentException("Idle timeout must be positive"); this.idleTimeoutSeconds = idleTimeoutSeconds; return this; } /** * Returns the timeout when trying to acquire a connection from a host's pool. * * @return the timeout. */ public int getPoolTimeoutMillis() { return poolTimeoutMillis; } /** * Sets the timeout when trying to acquire a connection from a host's pool. * *

This option works in concert with {@link #setMaxQueueSize(int)} to determine what happens if * the driver tries to borrow a connection from the pool but none is available: * *

    *
  • if either option is set to zero, the attempt is rejected immediately; *
  • else if more than {@code maxQueueSize} requests are already waiting for a connection, the * attempt is also rejected; *
  • otherwise, the attempt is enqueued; if a connection becomes available before {@code * poolTimeoutMillis} has elapsed, then the attempt succeeds, otherwise it is rejected. *
* * If the attempt is rejected, the driver will move to the next host in the {@link * com.datastax.driver.core.policies.LoadBalancingPolicy#newQueryPlan(String, Statement)} query * plan}. * *

The default is 5 seconds. If this option is set to zero, the driver won't wait at all. * * @param poolTimeoutMillis the new value in milliseconds. * @return this {@code PoolingOptions} * @throws IllegalArgumentException if the timeout is negative. */ public PoolingOptions setPoolTimeoutMillis(int poolTimeoutMillis) { if (poolTimeoutMillis < 0) throw new IllegalArgumentException("Pool timeout must be positive"); this.poolTimeoutMillis = poolTimeoutMillis; return this; } /** * Returns the maximum number of requests that get enqueued if no connection is available. * * @return the maximum queue size. */ public int getMaxQueueSize() { return maxQueueSize; } /** * Sets the maximum number of requests that get enqueued if no connection is available. * *

This option works in concert with {@link #setPoolTimeoutMillis(int)} to determine what * happens if the driver tries to borrow a connection from the pool but none is available: * *

    *
  • if either options is set to zero, the attempt is rejected immediately; *
  • else if more than {@code maxQueueSize} requests are already waiting for a connection, the * attempt is also rejected; *
  • otherwise, the attempt is enqueued; if a connection becomes available before {@code * poolTimeoutMillis} has elapsed, then the attempt succeeds, otherwise it is rejected. *
* * If the attempt is rejected, the driver will move to the next host in the {@link * com.datastax.driver.core.policies.LoadBalancingPolicy#newQueryPlan(String, Statement)} query * plan}. * *

The default value is {@value DEFAULT_MAX_QUEUE_SIZE}. If this option is set to zero, the * driver will never enqueue requests. * * @param maxQueueSize the new value. * @return this {@code PoolingOptions} * @throws IllegalArgumentException if the value is negative. */ public PoolingOptions setMaxQueueSize(int maxQueueSize) { if (maxQueueSize < 0) throw new IllegalArgumentException("Max queue size must be positive"); this.maxQueueSize = maxQueueSize; return this; } /** * Returns the heart beat interval, after which a message is sent on an idle connection to make * sure it's still alive. * * @return the interval. */ public int getHeartbeatIntervalSeconds() { return heartbeatIntervalSeconds; } /** * Sets the heart beat interval, after which a message is sent on an idle connection to make sure * it's still alive. * *

This is an application-level keep-alive, provided for convenience since adjusting the TCP * keep-alive might not be practical in all environments. * *

This option should be set higher than {@link SocketOptions#getReadTimeoutMillis()}. * *

The default value for this option is 30 seconds. * * @param heartbeatIntervalSeconds the new value in seconds. If set to 0, it will disable the * feature. * @return this {@code PoolingOptions} * @throws IllegalArgumentException if the interval is negative. */ public PoolingOptions setHeartbeatIntervalSeconds(int heartbeatIntervalSeconds) { if (heartbeatIntervalSeconds < 0) throw new IllegalArgumentException("Heartbeat interval must be positive"); this.heartbeatIntervalSeconds = heartbeatIntervalSeconds; return this; } /** * Returns the executor to use for connection initialization. * * @return the executor. * @see #setInitializationExecutor(java.util.concurrent.Executor) */ public Executor getInitializationExecutor() { return initializationExecutor; } /** * Sets the executor to use for connection initialization. * *

Connections are open in a completely asynchronous manner. Since initializing the transport * requires separate CQL queries, the futures representing the completion of these queries are * transformed and chained. This executor is where these transformations happen. * *

This is an advanced option, which should be rarely needed in practice. It defaults to * Guava's {@code MoreExecutors.sameThreadExecutor()}, which results in running the * transformations on the network I/O threads; this is fine if the transformations are fast and * not I/O bound (which is the case by default). One reason why you might want to provide a custom * executor is if you use authentication with a custom {@link * com.datastax.driver.core.Authenticator} implementation that performs blocking calls. * * @param initializationExecutor the executor to use * @return this {@code PoolingOptions} * @throws java.lang.NullPointerException if the executor is null */ public PoolingOptions setInitializationExecutor(Executor initializationExecutor) { Preconditions.checkNotNull(initializationExecutor); this.initializationExecutor = initializationExecutor; return this; } synchronized void setProtocolVersion(ProtocolVersion actualVersion) { this.protocolVersion = actualVersion; ProtocolVersion referenceVersion = null; for (ProtocolVersion key : DEFAULTS.keySet()) { if (key.compareTo(actualVersion) > 0) break; else referenceVersion = key; } assert referenceVersion != null; // will not happen since V1 is a key Map defaults = DEFAULTS.get(referenceVersion); if (coreConnections[LOCAL.ordinal()] == UNSET) coreConnections[LOCAL.ordinal()] = defaults.get(CORE_POOL_LOCAL_KEY); if (maxConnections[LOCAL.ordinal()] == UNSET) maxConnections[LOCAL.ordinal()] = defaults.get(MAX_POOL_LOCAL_KEY); checkConnectionsPerHostOrder( coreConnections[LOCAL.ordinal()], maxConnections[LOCAL.ordinal()], LOCAL); if (coreConnections[REMOTE.ordinal()] == UNSET) coreConnections[REMOTE.ordinal()] = defaults.get(CORE_POOL_REMOTE_KEY); if (maxConnections[REMOTE.ordinal()] == UNSET) maxConnections[REMOTE.ordinal()] = defaults.get(MAX_POOL_REMOTE_KEY); checkConnectionsPerHostOrder( coreConnections[REMOTE.ordinal()], maxConnections[REMOTE.ordinal()], REMOTE); if (newConnectionThreshold[LOCAL.ordinal()] == UNSET) newConnectionThreshold[LOCAL.ordinal()] = defaults.get(NEW_CONNECTION_THRESHOLD_LOCAL_KEY); checkRequestsPerConnectionRange( newConnectionThreshold[LOCAL.ordinal()], "New connection threshold", LOCAL); if (newConnectionThreshold[REMOTE.ordinal()] == UNSET) newConnectionThreshold[REMOTE.ordinal()] = defaults.get(NEW_CONNECTION_THRESHOLD_REMOTE_KEY); checkRequestsPerConnectionRange( newConnectionThreshold[REMOTE.ordinal()], "New connection threshold", REMOTE); if (maxRequestsPerConnectionLocal == UNSET) maxRequestsPerConnectionLocal = defaults.get(MAX_REQUESTS_PER_CONNECTION_LOCAL_KEY); checkRequestsPerConnectionRange( maxRequestsPerConnectionLocal, "Max requests per connection", LOCAL); if (maxRequestsPerConnectionRemote == UNSET) maxRequestsPerConnectionRemote = defaults.get(MAX_REQUESTS_PER_CONNECTION_REMOTE_KEY); checkRequestsPerConnectionRange( maxRequestsPerConnectionRemote, "Max requests per connection", REMOTE); } /** * Requests the driver to re-evaluate the {@link HostDistance} (through the configured {@link * com.datastax.driver.core.policies.LoadBalancingPolicy#distance}) for every known hosts and to * drop/add connections to each hosts according to the computed distance. * *

Note that, due to backward compatibility issues, this method is not interruptible. If the * caller thread gets interrupted, the method will complete and only then re-interrupt the thread * (which you can check with {@code Thread.currentThread().isInterrupted()}). */ public void refreshConnectedHosts() { manager.refreshConnectedHosts(); } /** * Requests the driver to re-evaluate the {@link HostDistance} for a given node. * * @param host the host to refresh. * @see #refreshConnectedHosts() */ public void refreshConnectedHost(Host host) { manager.refreshConnectedHost(host); } private void checkRequestsPerConnectionRange( int value, String description, HostDistance distance) { // If we don't know the protocol version yet, use the highest possible upper bound, this will // get checked again when possible int max = (protocolVersion == null || protocolVersion.compareTo(ProtocolVersion.V3) >= 0) ? StreamIdGenerator.MAX_STREAM_PER_CONNECTION_V3 : StreamIdGenerator.MAX_STREAM_PER_CONNECTION_V2; if (value < 0 || value > max) throw new IllegalArgumentException( String.format( "%s for %s hosts must be in the range (0, %d)", description, distance, max)); } private static void checkConnectionsPerHostOrder(int core, int max, HostDistance distance) { if (core > max) throw new IllegalArgumentException( String.format( "Core connections for %s hosts must be less than max (%d > %d)", distance, core, max)); } }





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