modules/core/src/main/java/org/apache/ignite/internal/client/GridClientNodeMetrics.java - ignite - Git at Google

 /*
  * Licensed to the Apache Software Foundation (ASF) under one or more
  * contributor license agreements.  See the NOTICE file distributed with
  * this work for additional information regarding copyright ownership.
  * The ASF licenses this file to You 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 org.apache.ignite.internal.client;

 import java.io.Serializable;

 /**
  * Node metrics for remote grid node. Metrics can be retrieved via
  * {@link GridClientNode#metrics()} method.
  * <p>
  * Note that metrics are not available by default and have to be
  * fetched via any of the {@code refreshNode(...)} or {@code refreshTopology(...)}
  * methods on {@link GridClientCompute} API.
  * <p>
  * Also note that if {@link GridClientConfiguration#isEnableMetricsCache()} property
  * is set to {@code true}, then {@link GridClientNode} will cache the last fetched
  * instance of node metrics.
  */
 public interface GridClientNodeMetrics extends Serializable {
     /**
      * Gets last update time.
      *
      * @return Last update time.
      */
     public long getLastUpdateTime();

     /**
      * Gets max active jobs.
      *
      * @return Max active jobs.
      */
     public int getMaximumActiveJobs();

     /**
      * Gets current active jobs.
      *
      * @return Current active jobs.
      */
     public int getCurrentActiveJobs();

     /**
      * Gets average active jobs.
      *
      * @return Average active jobs.
      */
     public float getAverageActiveJobs();

     /**
      * Gets maximum waiting jobs.
      *
      * @return Maximum active jobs.
      */
     public int getMaximumWaitingJobs();

     /**
      * Gets current waiting jobs.
      *
      * @return Current waiting jobs.
      */
     public int getCurrentWaitingJobs();

     /**
      * Gets average waiting jobs.
      *
      * @return Average waiting jobs.
      */
     public float getAverageWaitingJobs();

     /**
      * Gets maximum number of jobs rejected during a single collision resolution event.
      *
      * @return Maximum number of jobs rejected during a single collision resolution event.
      */
     public int getMaximumRejectedJobs();

     /**
      * Gets number of jobs rejected during most recent collision resolution.
      *
      * @return Number of jobs rejected during most recent collision resolution.
      */
     public int getCurrentRejectedJobs();

     /**
      * Gets average number of jobs this node rejects.
      *
      * @return Average number of jobs this node rejects.
      */
     public float getAverageRejectedJobs();

     /**
      * Gets total number of jobs this node ever rejected.
      *
      * @return Total number of jobs this node ever rejected.
      */
     public int getTotalRejectedJobs();

     /**
      * Gets maximum cancelled jobs.
      *
      * @return Maximum cancelled jobs.
      */
     public int getMaximumCancelledJobs();

     /**
      * Gets current cancelled jobs.
      *
      * @return Current cancelled jobs.
      */
     public int getCurrentCancelledJobs();

     /**
      * Gets average cancelled jobs.
      *
      * @return Average cancelled jobs.
      */
     public float getAverageCancelledJobs();

     /**
      * Gets total active jobs.
      *
      * @return Total active jobs.
      */
     public int getTotalExecutedJobs();

     /**
      * Gets total cancelled jobs.
      *
      * @return Total cancelled jobs.
      */
     public int getTotalCancelledJobs();

     /**
      * Gets max job wait time.
      *
      * @return Max job wait time.
      */
     public long getMaximumJobWaitTime();

     /**
      * Gets current job wait time.
      *
      * @return Current job wait time.
      */
     public long getCurrentJobWaitTime();

     /**
      * Gets average job wait time.
      *
      * @return Average job wait time.
      */
     public double getAverageJobWaitTime();

     /**
      * Gets maximum job execution time.
      *
      * @return Maximum job execution time.
      */
     public long getMaximumJobExecuteTime();

     /**
      * Gets current job execute time.
      *
      * @return Current job execute time.
      */
     public long getCurrentJobExecuteTime();

     /**
      * Gets average job execution time.
      *
      * @return Average job execution time.
      */
     public double getAverageJobExecuteTime();

     /**
      * Gets total number of tasks handled by the node.
      *
      * @return Total number of jobs handled by the node.
      */
     public int getTotalExecutedTasks();

     /**
      * Gets total busy time.
      *
      * @return Total busy time.
      */
     public long getTotalBusyTime();

     /**
      * Gets total idle time.
      *
      * @return Total idle time.
      */
     public long getTotalIdleTime();

     /**
      * Gets current idle time.
      *
      * @return Current idle time.
      */
     public long getCurrentIdleTime();

     /**
      * Gets percentage of time this node is busy executing jobs vs. idling.
      *
      * @return Percentage of time this node is busy (value is less than
      *      or equal to {@code 1} and greater than or equal to {@code 0})
      */
     public float getBusyTimePercentage();

     /**
      * Gets percentage of time this node is idling vs. executing jobs.
      *
      * @return Percentage of time this node is idle (value is less than
      *      or equal to {@code 1} and greater than or equal to {@code 0})
      */
     public float getIdleTimePercentage();

     /**
      * Returns the number of CPUs available to the Java Virtual Machine.
      * This method is equivalent to the {@link Runtime#availableProcessors()}
      * method.
      * <p>
      * Note that this value may change during successive invocations of the
      * virtual machine.
      *
      * @return The number of processors available to the virtual
      *      machine, never smaller than one.
      */
     public int getTotalCpus();

     /**
      * Returns the system load average for the last minute.
      * The system load average is the sum of the number of runnable entities
      * queued to the {@linkplain #getTotalCpus available processors}
      * and the number of runnable entities running on the available processors
      * averaged over a period of time.
      * The way in which the load average is calculated is operating system
      * specific but is typically a damped time-dependent average.
      * <p>
      * If the load average is not available, a negative value is returned.
      * <p>
      * This method is designed to provide a hint about the system load
      * and may be queried frequently. The load average may be unavailable on
      * some platform where it is expensive to implement this method.
      *
      * @return The system load average in {@code [0, 1]} range.
      *      Negative value if not available.
      */
     public double getCurrentCpuLoad();

     /**
      * Gets average of CPU load values over all metrics kept in the history.
      *
      * @return Average of CPU load value in {@code [0, 1]} range over all metrics kept
      *      in the history.
      */
     public double getAverageCpuLoad();

     /**
      * Returns average CPU spent for GC since the last update.
      *
      * @return Average CPU spent for GC since the last update.
      */
     public double getCurrentGcCpuLoad();

     /**
      * Returns the amount of heap memory in bytes that the Java virtual machine
      * initially requests from the operating system for memory management.
      * This method returns {@code -1} if the initial memory size is undefined.
      *
      * @return The initial size of memory in bytes; {@code -1} if undefined.
      */
     public long getHeapMemoryInitialized();

     /**
      * Returns the current heap size that is used for object allocation.
      * The heap consists of one or more memory pools. This value is
      * the sum of {@code used} heap memory values of all heap memory pools.
      * <p>
      * The amount of used memory in the returned is the amount of memory
      * occupied by both live objects and garbage objects that have not
      * been collected, if any.
      * <p>
      * <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
      * from the time of the node's startup.
      *
      * @return Amount of heap memory used.
      */
     public long getHeapMemoryUsed();

     /**
      * Returns the amount of heap memory in bytes that is committed for
      * the Java virtual machine to use. This amount of memory is
      * guaranteed for the Java virtual machine to use.
      * The heap consists of one or more memory pools. This value is
      * the sum of {@code committed} heap memory values of all heap memory pools.
      * <p>
      * <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
      * from the time of the node's startup.
      *
      * @return The amount of committed memory in bytes.
      */
     public long getHeapMemoryCommitted();

     /**
      * Returns the maximum amount of heap memory in bytes that can be
      * used for memory management. This method returns {@code -1}
      * if the maximum memory size is undefined.
      * <p>
      * This amount of memory is not guaranteed to be available
      * for memory management if it is greater than the amount of
      * committed memory. The Java virtual machine may fail to allocate
      * memory even if the amount of used memory does not exceed this
      * maximum size.
      * <p>
      * This value represents a setting of the heap memory for Java VM and is
      * not a sum of all initial heap values for all memory pools.
      * <p>
      * <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
      * from the time of the node's startup.
      *
      * @return The maximum amount of memory in bytes; {@code -1} if undefined.
      */
     public long getHeapMemoryMaximum();

     /**
      * Returns the amount of non-heap memory in bytes that the Java virtual machine
      * initially requests from the operating system for memory management.
      * This method returns {@code -1} if the initial memory size is undefined.
      * <p>
      * This value represents a setting of non-heap memory for Java VM and is
      * not a sum of all initial heap values for all memory pools.
      * <p>
      * <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
      * from the time of the node's startup.
      *
      * @return The initial size of memory in bytes; {@code -1} if undefined.
      */
     public long getNonHeapMemoryInitialized();

     /**
      * Returns the current non-heap memory size that is used by Java VM.
      * The non-heap memory consists of one or more memory pools. This value is
      * the sum of {@code used} non-heap memory values of all non-heap memory pools.
      * <p>
      * <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
      * from the time of the node's startup.
      * <p>
      * <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
      * from the time of the node's startup.
      *
      * @return Amount of none-heap memory used.
      */
     public long getNonHeapMemoryUsed();

     /**
      * Returns the maximum amount of non-heap memory in bytes that can be
      * used for memory management. This method returns {@code -1}
      * if the maximum memory size is undefined.
      * <p>
      * This amount of memory is not guaranteed to be available
      * for memory management if it is greater than the amount of
      * committed memory.  The Java virtual machine may fail to allocate
      * memory even if the amount of used memory does not exceed this
      * maximum size.
      * <p>
      * This value represents a setting of the non-heap memory for Java VM and is
      * not a sum of all initial non-heap values for all memory pools.
      * <p>
      * <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
      * from the time of the node's startup.
      *
      * @return The maximum amount of memory in bytes; {@code -1} if undefined.
      */
     public long getNonHeapMemoryMaximum();

     /**
      * Returns the uptime of the Java virtual machine in milliseconds.
      *
      * @return Uptime of the Java virtual machine in milliseconds.
      */
     public long getUpTime();

     /**
      * Returns the start time of the Java virtual machine in milliseconds.
      * This method returns the approximate time when the Java virtual
      * machine started.
      *
      * @return Start time of the Java virtual machine in milliseconds.
      */
     public long getStartTime();

     /**
      * Returns the start time of grid node in milliseconds.
      * There can be several grid nodes started in one JVM, so JVM start time will be
      * the same for all of them, but node start time will be different.
      *
      * @return Start time of the grid node in milliseconds.
      */
     public long getNodeStartTime();

     /**
      * Returns the current number of live threads including both
      * daemon and non-daemon threads.
      *
      * @return Current number of live threads.
      */
     public int getCurrentThreadCount();

     /**
      * Returns the maximum live thread count since the Java virtual machine
      * started or peak was reset.
      * <p>
      * <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
      * from the time of the node's startup.
      *
      * @return The peak live thread count.
      */
     public int getMaximumThreadCount();

     /**
      * Returns the total number of threads created and also started
      * since the Java virtual machine started.
      * <p>
      * <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
      * from the time of the node's startup.
      *
      * @return The total number of threads started.
      */
     public long getTotalStartedThreadCount();

     /**
      * Returns the current number of live daemon threads.
      *
      * @return Current number of live daemon threads.
      */
     public int getCurrentDaemonThreadCount();

     /**
      * Returns the number of unallocated bytes in the partition.
      *
      * @return Number of unallocated bytes in the partition.
      */
     public long getFileSystemFreeSpace();

     /**
      * Returns the size of the partition.
      *
      * @return Size of the partition.
      */
     public long getFileSystemTotalSpace();

     /**
      * Returns the number of bytes available to this virtual machine on the partition.
      *
      * @return Number of bytes available to this virtual machine on the partition.
      */
     public long getFileSystemUsableSpace();

     /**
      * In-memory data grid assigns incremental versions to all cache operations. This method provides
      * the latest data version on the node.
      *
      * @return Last data version.
      */
     public long getLastDataVersion();

     /**
      * Gets sent messages count.
      *
      * @return Sent messages count.
      */
     public int getSentMessagesCount();

     /**
      * Gets sent bytes count.
      *
      * @return Sent bytes count.
      */
     public long getSentBytesCount();

     /**
      * Gets received messages count.
      *
      * @return Received messages count.
      */
     public int getReceivedMessagesCount();

     /**
      * Gets received bytes count.
      *
      * @return Received bytes count.
      */
     public long getReceivedBytesCount();
 }
	/*
	* Licensed to the Apache Software Foundation (ASF) under one or more
	* contributor license agreements. See the NOTICE file distributed with
	* this work for additional information regarding copyright ownership.
	* The ASF licenses this file to You 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 org.apache.ignite.internal.client;

	import java.io.Serializable;

	/**
	* Node metrics for remote grid node. Metrics can be retrieved via
	* {@link GridClientNode#metrics()} method.
	* <p>
	* Note that metrics are not available by default and have to be
	* fetched via any of the {@code refreshNode(...)} or {@code refreshTopology(...)}
	* methods on {@link GridClientCompute} API.
	* <p>
	* Also note that if {@link GridClientConfiguration#isEnableMetricsCache()} property
	* is set to {@code true}, then {@link GridClientNode} will cache the last fetched
	* instance of node metrics.
	*/
	public interface GridClientNodeMetrics extends Serializable {
	/**
	* Gets last update time.
	*
	* @return Last update time.
	*/
	public long getLastUpdateTime();

	/**
	* Gets max active jobs.
	*
	* @return Max active jobs.
	*/
	public int getMaximumActiveJobs();

	/**
	* Gets current active jobs.
	*
	* @return Current active jobs.
	*/
	public int getCurrentActiveJobs();

	/**
	* Gets average active jobs.
	*
	* @return Average active jobs.
	*/
	public float getAverageActiveJobs();

	/**
	* Gets maximum waiting jobs.
	*
	* @return Maximum active jobs.
	*/
	public int getMaximumWaitingJobs();

	/**
	* Gets current waiting jobs.
	*
	* @return Current waiting jobs.
	*/
	public int getCurrentWaitingJobs();

	/**
	* Gets average waiting jobs.
	*
	* @return Average waiting jobs.
	*/
	public float getAverageWaitingJobs();

	/**
	* Gets maximum number of jobs rejected during a single collision resolution event.
	*
	* @return Maximum number of jobs rejected during a single collision resolution event.
	*/
	public int getMaximumRejectedJobs();

	/**
	* Gets number of jobs rejected during most recent collision resolution.
	*
	* @return Number of jobs rejected during most recent collision resolution.
	*/
	public int getCurrentRejectedJobs();

	/**
	* Gets average number of jobs this node rejects.
	*
	* @return Average number of jobs this node rejects.
	*/
	public float getAverageRejectedJobs();

	/**
	* Gets total number of jobs this node ever rejected.
	*
	* @return Total number of jobs this node ever rejected.
	*/
	public int getTotalRejectedJobs();

	/**
	* Gets maximum cancelled jobs.
	*
	* @return Maximum cancelled jobs.
	*/
	public int getMaximumCancelledJobs();

	/**
	* Gets current cancelled jobs.
	*
	* @return Current cancelled jobs.
	*/
	public int getCurrentCancelledJobs();

	/**
	* Gets average cancelled jobs.
	*
	* @return Average cancelled jobs.
	*/
	public float getAverageCancelledJobs();

	/**
	* Gets total active jobs.
	*
	* @return Total active jobs.
	*/
	public int getTotalExecutedJobs();

	/**
	* Gets total cancelled jobs.
	*
	* @return Total cancelled jobs.
	*/
	public int getTotalCancelledJobs();

	/**
	* Gets max job wait time.
	*
	* @return Max job wait time.
	*/
	public long getMaximumJobWaitTime();

	/**
	* Gets current job wait time.
	*
	* @return Current job wait time.
	*/
	public long getCurrentJobWaitTime();

	/**
	* Gets average job wait time.
	*
	* @return Average job wait time.
	*/
	public double getAverageJobWaitTime();

	/**
	* Gets maximum job execution time.
	*
	* @return Maximum job execution time.
	*/
	public long getMaximumJobExecuteTime();

	/**
	* Gets current job execute time.
	*
	* @return Current job execute time.
	*/
	public long getCurrentJobExecuteTime();

	/**
	* Gets average job execution time.
	*
	* @return Average job execution time.
	*/
	public double getAverageJobExecuteTime();

	/**
	* Gets total number of tasks handled by the node.
	*
	* @return Total number of jobs handled by the node.
	*/
	public int getTotalExecutedTasks();

	/**
	* Gets total busy time.
	*
	* @return Total busy time.
	*/
	public long getTotalBusyTime();

	/**
	* Gets total idle time.
	*
	* @return Total idle time.
	*/
	public long getTotalIdleTime();

	/**
	* Gets current idle time.
	*
	* @return Current idle time.
	*/
	public long getCurrentIdleTime();

	/**
	* Gets percentage of time this node is busy executing jobs vs. idling.
	*
	* @return Percentage of time this node is busy (value is less than
	* or equal to {@code 1} and greater than or equal to {@code 0})
	*/
	public float getBusyTimePercentage();

	/**
	* Gets percentage of time this node is idling vs. executing jobs.
	*
	* @return Percentage of time this node is idle (value is less than
	* or equal to {@code 1} and greater than or equal to {@code 0})
	*/
	public float getIdleTimePercentage();

	/**
	* Returns the number of CPUs available to the Java Virtual Machine.
	* This method is equivalent to the {@link Runtime#availableProcessors()}
	* method.
	* <p>
	* Note that this value may change during successive invocations of the
	* virtual machine.
	*
	* @return The number of processors available to the virtual
	* machine, never smaller than one.
	*/
	public int getTotalCpus();

	/**
	* Returns the system load average for the last minute.
	* The system load average is the sum of the number of runnable entities
	* queued to the {@linkplain #getTotalCpus available processors}
	* and the number of runnable entities running on the available processors
	* averaged over a period of time.
	* The way in which the load average is calculated is operating system
	* specific but is typically a damped time-dependent average.
	* <p>
	* If the load average is not available, a negative value is returned.
	* <p>
	* This method is designed to provide a hint about the system load
	* and may be queried frequently. The load average may be unavailable on
	* some platform where it is expensive to implement this method.
	*
	* @return The system load average in {@code [0, 1]} range.
	* Negative value if not available.
	*/
	public double getCurrentCpuLoad();

	/**
	* Gets average of CPU load values over all metrics kept in the history.
	*
	* @return Average of CPU load value in {@code [0, 1]} range over all metrics kept
	* in the history.
	*/
	public double getAverageCpuLoad();

	/**
	* Returns average CPU spent for GC since the last update.
	*
	* @return Average CPU spent for GC since the last update.
	*/
	public double getCurrentGcCpuLoad();

	/**
	* Returns the amount of heap memory in bytes that the Java virtual machine
	* initially requests from the operating system for memory management.
	* This method returns {@code -1} if the initial memory size is undefined.
	*
	* @return The initial size of memory in bytes; {@code -1} if undefined.
	*/
	public long getHeapMemoryInitialized();

	/**
	* Returns the current heap size that is used for object allocation.
	* The heap consists of one or more memory pools. This value is
	* the sum of {@code used} heap memory values of all heap memory pools.
	* <p>
	* The amount of used memory in the returned is the amount of memory
	* occupied by both live objects and garbage objects that have not
	* been collected, if any.
	* <p>
	* <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
	* from the time of the node's startup.
	*
	* @return Amount of heap memory used.
	*/
	public long getHeapMemoryUsed();

	/**
	* Returns the amount of heap memory in bytes that is committed for
	* the Java virtual machine to use. This amount of memory is
	* guaranteed for the Java virtual machine to use.
	* The heap consists of one or more memory pools. This value is
	* the sum of {@code committed} heap memory values of all heap memory pools.
	* <p>
	* <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
	* from the time of the node's startup.
	*
	* @return The amount of committed memory in bytes.
	*/
	public long getHeapMemoryCommitted();

	/**
	* Returns the maximum amount of heap memory in bytes that can be
	* used for memory management. This method returns {@code -1}
	* if the maximum memory size is undefined.
	* <p>
	* This amount of memory is not guaranteed to be available
	* for memory management if it is greater than the amount of
	* committed memory. The Java virtual machine may fail to allocate
	* memory even if the amount of used memory does not exceed this
	* maximum size.
	* <p>
	* This value represents a setting of the heap memory for Java VM and is
	* not a sum of all initial heap values for all memory pools.
	* <p>
	* <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
	* from the time of the node's startup.
	*
	* @return The maximum amount of memory in bytes; {@code -1} if undefined.
	*/
	public long getHeapMemoryMaximum();

	/**
	* Returns the amount of non-heap memory in bytes that the Java virtual machine
	* initially requests from the operating system for memory management.
	* This method returns {@code -1} if the initial memory size is undefined.
	* <p>
	* This value represents a setting of non-heap memory for Java VM and is
	* not a sum of all initial heap values for all memory pools.
	* <p>
	* <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
	* from the time of the node's startup.
	*
	* @return The initial size of memory in bytes; {@code -1} if undefined.
	*/
	public long getNonHeapMemoryInitialized();

	/**
	* Returns the current non-heap memory size that is used by Java VM.
	* The non-heap memory consists of one or more memory pools. This value is
	* the sum of {@code used} non-heap memory values of all non-heap memory pools.
	* <p>
	* <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
	* from the time of the node's startup.
	* <p>
	* <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
	* from the time of the node's startup.
	*
	* @return Amount of none-heap memory used.
	*/
	public long getNonHeapMemoryUsed();

	/**
	* Returns the maximum amount of non-heap memory in bytes that can be
	* used for memory management. This method returns {@code -1}
	* if the maximum memory size is undefined.
	* <p>
	* This amount of memory is not guaranteed to be available
	* for memory management if it is greater than the amount of
	* committed memory. The Java virtual machine may fail to allocate
	* memory even if the amount of used memory does not exceed this
	* maximum size.
	* <p>
	* This value represents a setting of the non-heap memory for Java VM and is
	* not a sum of all initial non-heap values for all memory pools.
	* <p>
	* <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
	* from the time of the node's startup.
	*
	* @return The maximum amount of memory in bytes; {@code -1} if undefined.
	*/
	public long getNonHeapMemoryMaximum();

	/**
	* Returns the uptime of the Java virtual machine in milliseconds.
	*
	* @return Uptime of the Java virtual machine in milliseconds.
	*/
	public long getUpTime();

	/**
	* Returns the start time of the Java virtual machine in milliseconds.
	* This method returns the approximate time when the Java virtual
	* machine started.
	*
	* @return Start time of the Java virtual machine in milliseconds.
	*/
	public long getStartTime();

	/**
	* Returns the start time of grid node in milliseconds.
	* There can be several grid nodes started in one JVM, so JVM start time will be
	* the same for all of them, but node start time will be different.
	*
	* @return Start time of the grid node in milliseconds.
	*/
	public long getNodeStartTime();

	/**
	* Returns the current number of live threads including both
	* daemon and non-daemon threads.
	*
	* @return Current number of live threads.
	*/
	public int getCurrentThreadCount();

	/**
	* Returns the maximum live thread count since the Java virtual machine
	* started or peak was reset.
	* <p>
	* <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
	* from the time of the node's startup.
	*
	* @return The peak live thread count.
	*/
	public int getMaximumThreadCount();

	/**
	* Returns the total number of threads created and also started
	* since the Java virtual machine started.
	* <p>
	* <b>Note:</b> this is <b>not</b> an aggregated metric and it's calculated
	* from the time of the node's startup.
	*
	* @return The total number of threads started.
	*/
	public long getTotalStartedThreadCount();

	/**
	* Returns the current number of live daemon threads.
	*
	* @return Current number of live daemon threads.
	*/
	public int getCurrentDaemonThreadCount();

	/**
	* Returns the number of unallocated bytes in the partition.
	*
	* @return Number of unallocated bytes in the partition.
	*/
	public long getFileSystemFreeSpace();

	/**
	* Returns the size of the partition.
	*
	* @return Size of the partition.
	*/
	public long getFileSystemTotalSpace();

	/**
	* Returns the number of bytes available to this virtual machine on the partition.
	*
	* @return Number of bytes available to this virtual machine on the partition.
	*/
	public long getFileSystemUsableSpace();

	/**
	* In-memory data grid assigns incremental versions to all cache operations. This method provides
	* the latest data version on the node.
	*
	* @return Last data version.
	*/
	public long getLastDataVersion();

	/**
	* Gets sent messages count.
	*
	* @return Sent messages count.
	*/
	public int getSentMessagesCount();

	/**
	* Gets sent bytes count.
	*
	* @return Sent bytes count.
	*/
	public long getSentBytesCount();

	/**
	* Gets received messages count.
	*
	* @return Received messages count.
	*/
	public int getReceivedMessagesCount();

	/**
	* Gets received bytes count.
	*
	* @return Received bytes count.
	*/
	public long getReceivedBytesCount();
	}