singrdk/base/Applications/Tests/MpStress/MpStress.cs

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2008-11-17 18:29:00 -05:00
///////////////////////////////////////////////////////////////////////////////
//
// Microsoft Research Singularity
//
// Copyright (c) Microsoft Corporation. All rights reserved.
//
// Note: Perform short (bvt) and long running stress of multiprocessor
// sensitive areas of the system. Used MonitorTest.cs as an
// application template
//
using System;
using System.Threading;
using Microsoft.Singularity.UnitTest;
using Microsoft.Singularity.Channels;
using Microsoft.Contracts;
using Microsoft.SingSharp.Reflection;
using Microsoft.Singularity.Applications;
using Microsoft.Singularity.Io;
using Microsoft.Singularity.Configuration;
[assembly: Transform(typeof(ApplicationResourceTransform))]
namespace Microsoft.Singularity.Applications
{
[ConsoleCategory(DefaultAction=true)]
internal class Parameters {
[InputEndpoint("data")]
public readonly TRef<UnicodePipeContract.Exp:READY> Stdin;
[OutputEndpoint("data")]
public readonly TRef<UnicodePipeContract.Imp:READY> Stdout;
[LongParameter("cpucount", Default=2, HelpMessage="CPU Count for test")]
internal long cpuCount;
[LongParameter("passcount", Default=10, HelpMessage="Pass Count for test")]
internal long passCount;
reflective internal Parameters();
internal int AppMain() {
return MpStress.AppMain(this);
}
}
public class MpStress
{
internal static int AppMain(Parameters! config)
{
int result;
Console.WriteLine("Running MpStress for CPU Count {0}", config.cpuCount);
ThreadTest tt = new ThreadTest();
result = tt.RunTest(config.cpuCount, config.passCount);
if (result != 0) {
return result;
}
return 0;
}
}
public class ThreadTest
{
public int RunTest(long cpuCount, long passCount) {
// Start the thread create/destroy test
//ThreadTestsThread threadTests = new ThreadTestsThread(cpuCount);
// Run pulse tests
PulseTestsThread pulseTests = new PulseTestsThread(cpuCount, passCount);
pulseTests.RunThread();
// Start the background threads
//threadTests.RunThread();
// Wait for pulse tests to complete
((!)pulseTests.Thread).Join();
return 0;
}
}
//
// Implementation classes represent different thread creation
// parameters, and actions
//
public class PrintThread : ThreadRunner
{
private long argValue;
public PrintThread(long arg) : base() {
argValue = arg;
}
public override void ThreadMain() {
//System.Console.WriteLine("PrintThread: Thread {0}, ThreadIndex {1}\n", Thread.CurrentThread.GetThreadId(), argValue);
// Call some additional "interesting" system calls here in order to disturb
// the system state, cause lock contention, flesh out races and unprotected code
// regions, etc.
//
// This exits the thread
//Console.Write("-");
return;
}
}
public class ThreadTestsThread : ThreadRunner
{
private long cpuCount;
public ThreadTestsThread(long cpuCount) : base() {
this.cpuCount = cpuCount;
}
public override void ThreadMain() {
const long Timeout = 1000 * 10; // 10 seconds
long threadCount = 0;
PrintThread[] threads;
threadCount = cpuCount * 2;
//
// Run forever, process will exit when the ApMain thread
// is done with the test sequence
//
for (;;) {
//Console.Write(".");
threads = new PrintThread[threadCount];
if (threads == null) {
System.Console.WriteLine("Error allocating Thread[]");
return;
}
for (int i = 0; i < threadCount; i++) {
threads[i] = new PrintThread(i);
if (threads[i] == null) {
System.Console.WriteLine("Error creating thread");
return;
}
}
// Start them running
for (int i = 0; i < threadCount; i++) {
((!)threads[i]).RunThread();
}
TimeSpan timeout = TimeSpan.FromMilliseconds(Timeout);
for (int i = 0; i < threadCount; i++) {
if (!((!)(((!)threads[i]).Thread)).Join(timeout)) {
Console.WriteLine("Timeout waiting for thread exit");
return;
}
//Console.Write("+");
}
}
}
}
public class PulseTestsThread : ThreadRunner
{
private long cpuCount;
private long passes;
private int threadCount;
private int maxThreadCount;
private const int threadsPerCpu = 64;
public PulseTestsThread(long cpuCount, long passes) : base() {
this.cpuCount = cpuCount;
this.passes = passes;
maxThreadCount = threadsPerCpu * (int)cpuCount;
// Limit max threads, otherwise we will overflow the kernel's thread table
if (maxThreadCount > 512) {
maxThreadCount = 512;
}
}
public override void ThreadMain() {
System.Console.WriteLine("Running PulseTests: Thread {0}\n", Thread.CurrentThread.GetThreadId());
Console.Write("passes={0}", passes);
Console.WriteLine(" cpuCount={0}", cpuCount);
for (int pass = 0; pass < passes; pass++) {
Console.WriteLine("pass={0}", pass);
UnitTest.Clear();
threadCount = 0;
for (int i = 0; i < cpuCount; i++) {
// 50 threads
if (!CheckMaxThreads(50)) {
UnitTest.Add("Many Threads PulseAll",
new UnitTest.TestDelegate(PulseAllTest.ManyThreadsTest));
}
// 8 threads
if (!CheckMaxThreads(8)) {
UnitTest.Add("Few Threads PulseAll",
new UnitTest.TestDelegate(PulseAllTest.FewThreadsTest));
}
// 17 threads
if (!CheckMaxThreads(17)) {
UnitTest.Add("Low-density Pulse",
new UnitTest.TestDelegate(PulseTest.LowDensityTest));
}
// 32 threads
if (!CheckMaxThreads(32)) {
UnitTest.Add("Medium-density Pulse",
new UnitTest.TestDelegate(PulseTest.MediumDensityTest));
}
// 128 threads
if (!CheckMaxThreads(128)) {
UnitTest.Add("High-density Pulse",
new UnitTest.TestDelegate(PulseTest.HighDensityTest));
}
}
Console.WriteLine("{0} PulseThreads", threadCount);
// Wait for the sub-threads to run
if (UnitTest.Run(true) != UnitTest.Result.Passed) {
Console.WriteLine("PulseTest failed!\n");
}
}
// This exits the thread
return;
}
// We must keep total thread count at a reasonable level
// otherwise we overflow the kernel thread table that is
// hardcoded at 1024. We will set 512 max threads for now.
private bool CheckMaxThreads(int count)
{
if ((count + threadCount) <= maxThreadCount) {
threadCount += count;
return false;
}
return true;
}
}
// Generic class that creates the thread
public class ThreadRunner
{
private Thread thread;
public ThreadRunner() {
}
public Thread Thread {
get {
return thread;
}
}
// Creates thread, returns with it running
public Thread RunThread() {
thread = new Thread(new ThreadStart(ThreadMain));
thread.Start();
return thread;
}
public virtual void ThreadMain() {
// This exits the thread
return;
}
}
}