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/*
* Copyright (c) 2007, 2023, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*/
package nsk.share.runner;
import nsk.share.log.Log;
import nsk.share.test.StressOptions;
import java.io.PrintStream;
import jdk.test.lib.Utils;
public class RunParams {
private StressOptions stressOptions;
private long sleepTime = 500;
private long iterations = 0;
private int numberOfThreads;
private boolean runGCThread = false;
private boolean runFinThread = false;
private boolean runMemDiagThread = false;
private boolean runFinDiagThread = false;
private boolean runAllDiagThread = false;
private boolean runForever = false;
private long threadBlockSize = 64 * 1024 * 1024;
private boolean interruptThreads = false;
private boolean useVirtualThreads = false;
public RunParams() {
this(new StressOptions());
}
public RunParams(StressOptions stressOptions) {
this.stressOptions = stressOptions;
numberOfThreads = getMediumLoadThreadsCount();
}
public RunParams(String[] args) {
this();
parseCommandLine(args);
}
/**
* Get an approximate memory which test should fill.
*
* This can be used to adjust the parameters of allocated objects
* to test run environment. Currently it is 3/5 of
* Runtime.getRuntime().maxMemory().
*/
public long getTestMemory() {
return 3 * Runtime.getRuntime().maxMemory() / 5;
}
/**
* Return memory to use for allocation of threads.
*
* This is currently 3/4 of getTestMemory();
*/
public long getThreadsMemory() {
return 3 * getTestMemory() / 4;
}
public final long getSleepTime() {
return sleepTime;
}
public final void setSleepTime(long sleepTime) {
this.sleepTime = sleepTime;
}
public final long getIterations() {
return iterations;
}
public final void setIterations(long iterations) {
if (this.iterations != iterations) {
this.iterations = iterations;
System.out.println("Iterations: " + iterations);
}
}
public int getBasicLoadThreadsCount() {
int cnt = (int) Math.min(
Integer.MAX_VALUE,
Math.min(
Runtime.getRuntime().availableProcessors(),
Math.round((double) Runtime.getRuntime().maxMemory() / threadBlockSize)
)
);
// cnt could be equal to 0 in case maxMemory is less than threadBlockSize then
// so, need to check this
return (cnt > 0 ? cnt : 1);
}
public int getMediumLoadThreadsCount() {
return 2 * getBasicLoadThreadsCount();
}
public int getHighLoadThreadsCount() {
return 100 * getBasicLoadThreadsCount();
}
public final int getNumberOfThreads() {
return numberOfThreads * stressOptions.getThreadsFactor();
}
public final void setNumberOfThreads(int numberOfThreads) {
this.numberOfThreads = numberOfThreads;
}
public final long getSeed() {
// ensure that seed got printed out
Utils.getRandomInstance();
return Utils.SEED;
}
public final boolean isRunGCThread() {
return runGCThread;
}
public final void setRunGCThread(boolean runGCThread) {
this.runGCThread = runGCThread;
}
public final boolean isRunFinThread() {
return runFinThread;
}
public final void setRunFinThread(boolean runFinThread) {
this.runFinThread = runFinThread;
}
public final boolean isRunMemDiagThread() {
return runMemDiagThread;
}
public final void setRunMemDiagThread(boolean runMemDiagThread) {
this.runMemDiagThread = runMemDiagThread;
}
public final boolean isRunFinDiagThread() {
return runFinDiagThread;
}
public final void setRunFinDiagThread(boolean runFinDiagThread) {
this.runFinDiagThread = runFinDiagThread;
}
public final boolean isRunAllDiagThread() {
return runAllDiagThread;
}
public final void setRunAllDiagThread(boolean runAllDiagThread) {
this.runAllDiagThread = runAllDiagThread;
}
public final boolean isRunForever() {
return runForever;
}
public final void setRunForever(boolean runForever) {
this.runForever = runForever;
}
public final boolean isInterruptThreads() {
return interruptThreads;
}
public final void setInterruptThreads(boolean interruptThreads) {
this.interruptThreads = interruptThreads;
}
public final StressOptions getStressOptions() {
return stressOptions;
}
public final boolean useVirtualThreads() {
return this.useVirtualThreads;
}
public void parseCommandLine(String[] args) {
if (args == null)
return;
stressOptions.parseCommandLine(args);
for (int i = 0; i < args.length; ++i) {
if (args[i].equals("-f"))
runForever = true;
else if (args[i].equals("-tg"))
runGCThread = true;
else if (args[i].equals("-tf"))
runFinThread = true;
else if (args[i].equals("-Dm"))
runMemDiagThread = true;
else if (args[i].equals("-Dm-"))
runMemDiagThread = false;
else if (args[i].equals("-Df1"))
runFinDiagThread = true;
else if (args[i].equals("-Df"))
runFinDiagThread = true;
else if (args[i].equals("-v"))
useVirtualThreads = true;
else if (args[i].equals("-t"))
numberOfThreads = Integer.parseInt(args[++i]);
else if (args[i].equals("-it"))
interruptThreads = true;
else if (args[i].equals("-iterations"))
iterations = Integer.parseInt(args[++i]);
}
// Allow to force using vthreads using wrapper property
if ("Virtual".equals(System.getProperty("test.thread.factory"))) {
useVirtualThreads = true;
}
printConfig(System.out);
}
public void prinUsage() {
}
public void printConfig(PrintStream out) {
stressOptions.printInfo(out);
out.println("Max memory: " + Runtime.getRuntime().maxMemory());
out.println("Sleep time: " + sleepTime);
out.println("Iterations: " + iterations);
out.println("Number of threads: " + numberOfThreads);
out.println("Run GC thread: " + runGCThread);
out.println("Run mem diag thread: " + runMemDiagThread);
out.println("Run forever: " + runForever);
}
public void logConfig(Log log) {
log.debug("Max memory: " + Runtime.getRuntime().maxMemory());
log.debug("Sleep time: " + sleepTime);
log.debug("Iterations: " + iterations);
log.debug("Number of threads: " + numberOfThreads);
log.debug("Run GC thread: " + runGCThread);
log.debug("Run mem diag thread: " + runMemDiagThread);
log.debug("Run forever: " + runForever);
}
private static RunParams instance;
public static RunParams getInstance() {
synchronized (RunParams.class) {
if (instance == null)
instance = new RunParams();
return instance;
}
}
public static void setInstance(RunParams runParams) {
synchronized (RunParams.class) {
instance = runParams;
}
}
}
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