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package com.sun.management.internal;
import jdk.internal.platform.Metrics;
import sun.management.BaseOperatingSystemImpl;
import sun.management.VMManagement;
import java.util.concurrent.TimeUnit;
Implementation class for the operating system.
Standard and committed hotspot-specific metrics if any.
ManagementFactory.getOperatingSystemMXBean() returns an instance
of this class.
/**
* Implementation class for the operating system.
* Standard and committed hotspot-specific metrics if any.
*
* ManagementFactory.getOperatingSystemMXBean() returns an instance
* of this class.
*/
class OperatingSystemImpl extends BaseOperatingSystemImpl
implements com.sun.management.UnixOperatingSystemMXBean {
private static final int MAX_ATTEMPTS_NUMBER = 10;
private final Metrics containerMetrics;
OperatingSystemImpl(VMManagement vm) {
super(vm);
this.containerMetrics = jdk.internal.platform.Container.metrics();
}
public long getCommittedVirtualMemorySize() {
return getCommittedVirtualMemorySize0();
}
public long getTotalSwapSpaceSize() {
if (containerMetrics != null) {
long limit = containerMetrics.getMemoryAndSwapLimit();
// The memory limit metrics is not available if JVM runs on Linux host (not in a docker container)
// or if a docker container was started without specifying a memory limit (without '--memory='
// Docker option). In latter case there is no limit on how much memory the container can use and
// it can use as much memory as the host's OS allows.
long memLimit = containerMetrics.getMemoryLimit();
if (limit >= 0 && memLimit >= 0) {
// we see a limit == 0 on some machines where "kernel does not support swap limit capabilities"
return (limit < memLimit) ? 0 : limit - memLimit;
}
}
return getTotalSwapSpaceSize0();
}
public long getFreeSwapSpaceSize() {
if (containerMetrics != null) {
long memSwapLimit = containerMetrics.getMemoryAndSwapLimit();
long memLimit = containerMetrics.getMemoryLimit();
if (memSwapLimit >= 0 && memLimit >= 0) {
for (int attempt = 0; attempt < MAX_ATTEMPTS_NUMBER; attempt++) {
long memSwapUsage = containerMetrics.getMemoryAndSwapUsage();
long memUsage = containerMetrics.getMemoryUsage();
if (memSwapUsage > 0 && memUsage > 0) {
// We read "memory usage" and "memory and swap usage" not atomically,
// and it's possible to get the negative value when subtracting these two.
// If this happens just retry the loop for a few iterations.
if ((memSwapUsage - memUsage) >= 0) {
return memSwapLimit - memLimit - (memSwapUsage - memUsage);
}
}
}
}
}
return getFreeSwapSpaceSize0();
}
public long getProcessCpuTime() {
return getProcessCpuTime0();
}
public long getFreePhysicalMemorySize() {
if (containerMetrics != null) {
long usage = containerMetrics.getMemoryUsage();
long limit = containerMetrics.getMemoryLimit();
if (usage > 0 && limit >= 0) {
return limit - usage;
}
}
return getFreePhysicalMemorySize0();
}
public long getTotalPhysicalMemorySize() {
if (containerMetrics != null) {
long limit = containerMetrics.getMemoryLimit();
if (limit >= 0) {
return limit;
}
}
return getTotalPhysicalMemorySize0();
}
public long getOpenFileDescriptorCount() {
return getOpenFileDescriptorCount0();
}
public long getMaxFileDescriptorCount() {
return getMaxFileDescriptorCount0();
}
public double getSystemCpuLoad() {
if (containerMetrics != null) {
long quota = containerMetrics.getCpuQuota();
if (quota > 0) {
long periodLength = containerMetrics.getCpuPeriod();
long numPeriods = containerMetrics.getCpuNumPeriods();
long usageNanos = containerMetrics.getCpuUsage();
if (periodLength > 0 && numPeriods > 0 && usageNanos > 0) {
long elapsedNanos = TimeUnit.MICROSECONDS.toNanos(periodLength * numPeriods);
double systemLoad = (double) usageNanos / elapsedNanos;
// Ensure the return value is in the range 0.0 -> 1.0
systemLoad = Math.max(0.0, systemLoad);
systemLoad = Math.min(1.0, systemLoad);
return systemLoad;
}
return -1;
} else {
// If CPU quotas are not active then find the average system load for
// all online CPUs that are allowed to run this container.
// If the cpuset is the same as the host's one there is no need to iterate over each CPU
if (isCpuSetSameAsHostCpuSet()) {
return getSystemCpuLoad0();
} else {
int[] cpuSet = containerMetrics.getEffectiveCpuSetCpus();
if (cpuSet != null && cpuSet.length > 0) {
double systemLoad = 0.0;
for (int cpu : cpuSet) {
double cpuLoad = getSingleCpuLoad0(cpu);
if (cpuLoad < 0) {
return -1;
}
systemLoad += cpuLoad;
}
return systemLoad / cpuSet.length;
}
return -1;
}
}
}
return getSystemCpuLoad0();
}
public double getProcessCpuLoad() {
return getProcessCpuLoad0();
}
private boolean isCpuSetSameAsHostCpuSet() {
if (containerMetrics != null) {
return containerMetrics.getCpuSetCpus().length == getHostConfiguredCpuCount0();
}
return false;
}
/* native methods */
private native long getCommittedVirtualMemorySize0();
private native long getFreePhysicalMemorySize0();
private native long getFreeSwapSpaceSize0();
private native long getMaxFileDescriptorCount0();
private native long getOpenFileDescriptorCount0();
private native long getProcessCpuTime0();
private native double getProcessCpuLoad0();
private native double getSystemCpuLoad0();
private native long getTotalPhysicalMemorySize0();
private native long getTotalSwapSpaceSize0();
private native double getSingleCpuLoad0(int cpuNum);
private native int getHostConfiguredCpuCount0();
static {
initialize0();
}
private static native void initialize0();
}