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/**
 * Oshi (https://github.com/dblock/oshi)
 *
 * Copyright (c) 2010 - 2016 The Oshi Project Team
 *
 * All rights reserved. This program and the accompanying materials
 * are made available under the terms of the Eclipse Public License v1.0
 * which accompanies this distribution, and is available at
 * http://www.eclipse.org/legal/epl-v10.html
 *
 * Maintainers:
 * dblock[at]dblock[dot]org
 * widdis[at]gmail[dot]com
 * enrico.bianchi[at]gmail[dot]com
 *
 * Contributors:
 * https://github.com/dblock/oshi/graphs/contributors
 */
package oshi.hardware;

import java.io.Serializable;

/**
 * The Central Processing Unit (CPU) or the processor is the portion of a
 * computer system that carries out the instructions of a computer program, and
 * is the primary element carrying out the computer's functions.
 *
 * @author dblock[at]dblock[dot]org
 */
public interface CentralProcessor extends Serializable {

    /**
     * Index of CPU tick counters in the {@link #getSystemCpuLoadTicks()} and
     * {@link #getProcessorCpuLoadTicks()} arrays.
     */
    enum TickType {
        /**
         * CPU utilization that occurred while executing at the user level
         * (application).
         */
        USER(0),
        /**
         * CPU utilization that occurred while executing at the user level with
         * nice priority.
         */
        NICE(1),
        /**
         * CPU utilization that occurred while executing at the system level
         * (kernel). Also includes CPU time which the hypervisor dedicated for
         * other guests in the system (steal).
         */
        SYSTEM(2),
        /**
         * Time that the CPU or CPUs were idle and the system did not have an
         * outstanding disk I/O request.
         */
        IDLE(3),
        /**
         * Time that the CPU or CPUs were idle during which the system had an
         * outstanding disk I/O request.
         */
        IOWAIT(4),
        /**
         * Time that the CPU used to service hardware IRQs
         */
        IRQ(5),
        /**
         * Time that the CPU used to service soft IRQs
         */
        SOFTIRQ(6);

        private int index;

        TickType(int value) {
            this.index = value;
        }

        /**
         * @return The integer index of this ENUM in the processor tick arrays,
         *         which matches the output of Linux /proc/cpuinfo
         */
        public int getIndex() {
            return index;
        }
    }

    /**
     * Processor vendor.
     *
     * @return vendor string.
     */
    String getVendor();

    /**
     * Set processor vendor.
     *
     * @param vendor
     *            Vendor.
     */
    void setVendor(String vendor);

    /**
     * Name, eg. Intel(R) Core(TM)2 Duo CPU T7300 @ 2.00GHz
     *
     * @return Processor name.
     */
    String getName();

    /**
     * Set processor name.
     *
     * @param name
     *            Name.
     */
    void setName(String name);

    /**
     * Vendor frequency (in Hz), eg. for processor named Intel(R) Core(TM)2 Duo
     * CPU T7300 @ 2.00GHz the vendor frequency is 2000000000.
     *
     * @return Processor frequency or -1 if unknown.
     */
    long getVendorFreq();

    /**
     * Set processor vendor frequency (in Hz).
     *
     * @param freq
     *            Frequency.
     */
    void setVendorFreq(long freq);

    /**
     * Identifier, eg. x86 Family 6 Model 15 Stepping 10.
     *
     * @return Processor identifier.
     */
    String getIdentifier();

    /**
     * Set processor identifier.
     *
     * @param identifier
     *            Identifier.
     */
    void setIdentifier(String identifier);

    /**
     * Is CPU 64bit?
     *
     * @return True if cpu is 64bit.
     */
    boolean isCpu64bit();

    /**
     * Set flag is cpu is 64bit.
     *
     * @param cpu64
     *            True if cpu is 64.
     */
    void setCpu64(boolean cpu64);

    /**
     * @return the stepping
     */
    String getStepping();

    /**
     * @param stepping
     *            the stepping to set
     */
    void setStepping(String stepping);

    /**
     * @return the model
     */
    String getModel();

    /**
     * @param model
     *            the model to set
     */
    void setModel(String model);

    /**
     * @return the family
     */
    String getFamily();

    /**
     * @param family
     *            the family to set
     */
    void setFamily(String family);

    /**
     * Returns the "recent cpu usage" for the whole system by counting ticks
     * from {@link #getSystemCpuLoadTicks()} between successive calls of this
     * method, with a minimum interval slightly less than 1 second. If less than
     * one second has elapsed since the last call of this method, it will return
     * a calculation based on the tick counts and times of the previous two
     * calls. If at least a second has elapsed, it will return the average CPU
     * load for the interval and update the "last called" times. This method is
     * intended to be used for periodic polling at intervals of 1 second or
     * longer.
     *
     * @return CPU load between 0 and 1 (100%)
     */
    double getSystemCpuLoadBetweenTicks();

    /**
     * Get System-wide CPU Load tick counters. Returns an array with seven
     * elements representing either clock ticks or milliseconds (platform
     * dependent) spent in User (0), Nice (1), System (2), Idle (3), IOwait (4),
     * Hardware interrupts (IRQ) (5), or Software interrupts/DPC (SoftIRQ) (6)
     * states. Use {@link TickType#getIndex()} to retrieve the appropriate
     * index. By measuring the difference between ticks across a time interval,
     * CPU load over that interval may be calculated.
     *
     * Nice and IOWait information is not available on Windows, and IOwait and
     * IRQ information is not available on macOS, so these ticks will always be
     * zero.
     *
     * To calculate overall Idle time using this method, include both Idle and
     * IOWait ticks. Similarly, IRQ and SoftIRQ ticks should be added to the
     * System value to get the total. System ticks also include time executing
     * other virtual hosts (steal).
     *
     * @return An array of 7 long values representing time spent in User, Nice,
     *         System, Idle, IOwait, IRQ, and SoftIRQ states.
     */
    long[] getSystemCpuLoadTicks();

    /**
     * Returns the "recent cpu usage" for the whole system from
     * {@link com.sun.management.OperatingSystemMXBean#getSystemCpuLoad()} if a
     * user is running the Oracle JVM. This value is a double in the [0.0,1.0]
     * interval. A value of 0.0 means that all CPUs were idle during the recent
     * period of time observed, while a value of 1.0 means that all CPUs were
     * actively running 100% of the time during the recent period being
     * observed. All values between 0.0 and 1.0 are possible depending of the
     * activities going on in the system. If the system recent cpu usage is not
     * available, the method returns a negative value. Calling this method
     * immediately upon instantiating the {@link CentralProcessor} may give
     * unreliable results. If a user is not running the Oracle JVM, this method
     * will default to the behavior and return value of
     * {@link #getSystemCpuLoadBetweenTicks()}.
     *
     * @return the "recent cpu usage" for the whole system; a negative value if
     *         not available.
     */
    @SuppressWarnings("restriction")
    double getSystemCpuLoad();

    /**
     * Returns the system load average for the last minute. This is equivalent
     * to calling {@link CentralProcessor#getSystemLoadAverage(int)} with an
     * argument of 1 and returning the first value, and is retained for
     * compatibility.
     *
     * @return the system load average; or a negative value if not available.
     */
    double getSystemLoadAverage();

    /**
     * Returns the system load average for the number of elements specified, up
     * to 3, representing 1, 5, and 15 minutes. The system load average is the
     * sum of the number of runnable entities queued to the 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. If the load average is not available, a negative
     * value is returned. 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 platforms (e.g., Windows) where it is expensive to
     * implement this method.
     *
     * @param nelem
     *            Number of elements to return.
     * @return an array of the system load averages for 1, 5, and 15 minutes
     *         with the size of the array specified by nelem; or negative values
     *         if not available.
     */
    double[] getSystemLoadAverage(int nelem);

    /**
     * Returns the "recent cpu usage" for all logical processors by counting
     * ticks for the processors from {@link #getProcessorCpuLoadTicks()} between
     * successive calls of this method, with a minimum interval slightly less
     * than 1 second. If less than one second has elapsed since the last call of
     * this method, it will return a calculation based on the tick counts and
     * times of the previous two calls. If at least a second has elapsed, it
     * will return the average CPU load for the interval and update the
     * "last called" times. This method is intended to be used for periodic
     * polling (iterating over all processors) at intervals of 1 second or
     * longer.
     *
     * @return array of CPU load between 0 and 1 (100%) for each logical
     *         processor
     */
    double[] getProcessorCpuLoadBetweenTicks();

    /**
     * Get Processor CPU Load tick counters. Returns a two dimensional array,
     * with {@link #getLogicalProcessorCount()} arrays, each containing seven
     * elements representing either clock ticks or milliseconds (platform
     * dependent) spent in User (0), Nice (1), System (2), Idle (3), IOwait (4),
     * Hardware interrupts (IRQ) (5), or Software interrupts/DPC (SoftIRQ) (6)
     * states. Use {@link TickType#getIndex()} to retrieve the appropriate
     * index. By measuring the difference between ticks across a time interval,
     * CPU load over that interval may be calculated.
     *
     * Nice and IOwait per processor information is not available on Windows,
     * and IOwait and IRQ information is not available on macOS, so these ticks
     * will always be zero.
     *
     * To calculate overall Idle time using this method, include both Idle and
     * IOWait ticks. Similarly, IRQ and SoftIRQ ticks should be added to the
     * System value to get the total. System ticks also include time executing
     * other virtual hosts (steal).
     *
     * @return A 2D array of logicalProcessorCount x 7 long values representing
     *         time spent in User, Nice, System, Idle, IOwait, IRQ, and SoftIRQ
     *         states.
     */
    long[][] getProcessorCpuLoadTicks();

    /**
     * Get the System uptime (time since boot).
     *
     * @return Number of seconds since boot.
     */
    long getSystemUptime();

    /**
     * Get the System/CPU Serial Number, if available.
     *
     * On Linux and FreeBSD, this requires either root permissions, installation
     * of the (deprecated) HAL library (lshal command). Linux also attempts to
     * read the dmi/id serial number files in sysfs, which are read-only root by
     * default but may have permissions altered by the user.
     *
     * @return the System/CPU Serial Number, if available, otherwise returns
     *         "unknown"
     */
    String getSystemSerialNumber();

    /**
     * Get the number of logical CPUs available for processing.
     *
     * @return The number of logical CPUs available.
     */
    int getLogicalProcessorCount();

    /**
     * Get the number of physical CPUs/cores available for processing.
     *
     * @return The number of physical CPUs available.
     */
    int getPhysicalProcessorCount();
}




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