385 lines
12 KiB
C#
385 lines
12 KiB
C#
///////////////////////////////////////////////////////////////////////////////
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//
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// Microsoft Research Singularity
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//
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// Copyright (c) Microsoft Corporation. All rights reserved.
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//
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// Note: Perform short (bvt) and long running stress of OutOfMemory
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// behavior of the system.
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//
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//
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// Tests to support:
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//
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// - Overcommit of heap memory within a SIP
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//
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// Create lots of managed array objects until the OS can no
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// longer satisfy the request and terminates the SIP.
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//
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//
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// - Overcommit of stack memory within a SIP
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//
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// Implement a recursive function that results in stack overflow
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// and termination of the SIP.
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//
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// - Overcommit of heap memory within the kernel
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//
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// Since we can't directly allocate kernel heap memory,
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// we do this by creating lots of kernel objects that occupy
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// the heap (such as new threads)
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//
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// - Overcommit kernel heap memory from within the kernel in multiple
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// threads to find races in any resource reservation strategies that
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// may be timing dependent.
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//
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using System;
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using System.Threading;
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using Microsoft.Contracts;
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using Microsoft.SingSharp.Reflection;
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using Microsoft.Singularity.UnitTest;
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using Microsoft.Singularity.V1.Services;
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using Microsoft.Singularity.Channels;
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using Microsoft.Singularity.Directory;
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using Microsoft.Singularity.Applications;
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using Microsoft.Singularity.Io;
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using Microsoft.Singularity.Configuration;
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[assembly: Transform(typeof(ApplicationResourceTransform))]
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namespace Microsoft.Singularity.Applications
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{
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[ConsoleCategory(DefaultAction=true)]
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internal class Parameters {
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[InputEndpoint("data")]
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public readonly TRef<UnicodePipeContract.Exp:READY> Stdin;
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[OutputEndpoint("data")]
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public readonly TRef<UnicodePipeContract.Imp:READY> Stdout;
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[Endpoint]
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public readonly TRef<DirectoryServiceContract.Imp:Start> nsRef;
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[BoolParameter( "sip_so", Default=false, HelpMessage="Create Stack Overflow in SIP")]
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internal bool sipSo;
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[BoolParameter( "sip_oom", Default=false, HelpMessage="Create Out Of Memory in SIP")]
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internal bool sipOom;
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[BoolParameter( "kernel_oom", Default=false, HelpMessage="Create Kernel Out Of Memory")]
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internal bool kernelOom;
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[BoolParameter( "kernel_oom_stress", Default=false, HelpMessage="Create Kernel Out Of Memory Stress")]
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internal bool kernelOomStress;
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//
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// The noProcess parameter runs the test without creating a sub-process.
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//
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// Since success for this test is running out of memory and having the SIP
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// die, there is no way to return a success status to a top level test script.
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// The script thinks that the SIP failure due to OOM is a failure of the test.
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//
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// So by default, the tests are run in a sub-process which we can then monitor
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// and return a proper result to the top level test script.
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//
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// This parameter allows the same executable to be used for both parts
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// of the test.
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//
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[BoolParameter( "noprocess", Default=false, HelpMessage="Run directly without a sub-process")]
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internal bool noProcess;
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reflective internal Parameters();
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internal int AppMain() {
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return MemStress.AppMain(this);
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}
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}
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public class MemStress
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{
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internal static int AppMain(Parameters! config)
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{
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#if PAGING
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if (true) {
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Console.WriteLine("MemStress does not work on PAGING builds");
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return -1;
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}
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#endif
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DumpMemInfo();
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SipMemoryStresser sipms = new SipMemoryStresser();
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if (!config.noProcess) {
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if (config.sipSo) {
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sipms.RunTestAsProcess(config, "-sip_so");
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}
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else if (config.sipOom) {
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sipms.RunTestAsProcess(config, "-sip_oom");
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}
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else if (config.kernelOom) {
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sipms.RunTestAsProcess(config, "-kernel_oom");
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}
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else if (config.kernelOomStress) {
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sipms.RunTestAsProcess(config, "-kernel_oom_stress");
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}
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else {
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Console.WriteLine("Usage: MemStress [-sip_oom] [-sip_so] [-kernel_oom] [-kernel_oom_stress]");
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Console.WriteLine("Must pick one option");
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}
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}
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else {
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if (config.sipSo) {
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sipms.RunSOTest();
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}
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else if (config.sipOom) {
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sipms.RunOOMTest();
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}
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else if (config.kernelOom) {
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sipms.KernelOOMTest();
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}
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else if (config.kernelOomStress) {
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sipms.KernelOOMStress();
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}
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else {
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Console.WriteLine("Usage: MemStress [-sip_oom] [-sip_so] [-kernel_oom] [-kernel_oom_stress]");
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Console.WriteLine("Must pick one option");
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}
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}
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return 0;
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}
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public static void DumpMemInfo()
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{
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int result;
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ulong totalMemoryFree = 0;
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ulong totalMemoryInUse = 0;
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ulong kernelHeapInUse = 0;
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ulong kernelStackInUse = 0;
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ulong totalSIPHeapInUse = 0;
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ulong totalSIPStackInUse = 0;
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ulong kernelStackReservation = 0;
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ulong kernelHeapReservation = 0;
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result = MemoryInfoService.MemoryUsageInfo(
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out totalMemoryFree,
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out totalMemoryInUse,
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out kernelHeapInUse,
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out kernelStackInUse,
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out totalSIPHeapInUse,
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out totalSIPStackInUse,
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out kernelStackReservation,
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out kernelHeapReservation
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);
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// TODO: Use standard ErrorCode's
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if (result != 0) {
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Console.WriteLine("Error {0} retrieving MemoryUsageInfo");
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}
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else {
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Console.WriteLine("TotalMemoryFree 0x{0:x8}, TotalMemoryInUse {1:x8}", totalMemoryFree, totalMemoryInUse);
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Console.WriteLine("KernelHeapInUse {0:x8}, KernelStackInUse {1:x8}", kernelHeapInUse, kernelStackInUse);
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Console.WriteLine("TotalSIPHeapInUse {0:x8}, TotalSIPStackInUse {1:x8}", totalSIPHeapInUse, totalSIPStackInUse);
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Console.WriteLine("KernelStackReservation {0:x8}, KernelHeapReservation {1:x8}", kernelStackReservation, kernelHeapReservation);
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Console.WriteLine("");
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}
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}
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}
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public class SipMemoryStresser
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{
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//
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// Run out of memory test, eventually terminates the SIP due
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// to fail fast.
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//
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internal void RunTestAsProcess(Parameters! config, string test) {
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Process p = null;
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//
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// Create a subprocess run of "memstress -testparameter"
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//
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string[] args = new string[3];
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args[0] = "memstress";
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args[1] = test;
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args[2] = "-noprocess";
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Console.WriteLine("Creating subprocess memstress {0} -noprocess", test);
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try {
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p = ProcessLauncher.CreateSubProcess(config, args);
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}
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catch (Exception e) {
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Console.WriteLine("Exception from CreateSubProcess: " + e.Message);
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return;
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}
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if (p == null) {
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Console.WriteLine("Error creating process");
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return;
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}
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Console.WriteLine("Process returned with ExitCode={0}", p.ExitCode);
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}
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public void RunOOMTest() {
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object[] TopLevel;
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object[] tmp;
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TopLevel = new Object[1];
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//
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// Currrently the test handles the OOM exception showing
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// that this works. Additional testing should create multiple
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// threads and have OOM failures at random places in the runtime
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// without try/except handlers so we can test the case when
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// the exception bubbles up to the top of the stack.
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//
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try {
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for (int count = 65535;; count *= 2) {
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tmp = new object[count];
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tmp[0] = TopLevel;
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TopLevel = tmp;
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for (int i = 1; i < count; i++) {
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TopLevel[i] = new object[count];
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}
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MemStress.DumpMemInfo();
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}
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}
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catch (OutOfMemoryException e) {
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e=e;
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//Thread.CurrentProcess.Stop(1);
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return;
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}
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}
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// Run stack overflow test, terminates the SIP
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public void RunSOTest() {
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// Test the fail fast path directly
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//Microsoft.Singularity.V1.Services.StackService.StackOverflow();
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RunSOTest();
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}
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//
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// Invoke a kernel heap out of memory condition by creating
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// lots of kernel objects
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//
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public void KernelOOMTest() {
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IdleThread[] threads;
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int threadCount = 1000;
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while (true) {
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System.Console.WriteLine("Creating {0} threads", threadCount);
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threads = new IdleThread[threadCount];
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if (threads == null) {
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System.Console.WriteLine("Error allocating Thread[]");
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return;
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}
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for (int i = 0; i < threadCount; i++) {
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threads[i] = new IdleThread(i);
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if (threads[i] == null) {
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System.Console.WriteLine("Error creating thread");
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return;
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}
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}
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// Start them running
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for (int i = 0; i < threadCount; i++) {
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((!)threads[i]).RunThread();
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}
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}
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}
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//
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// Use multiple threads to stress the system and induce
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// kernel heap OOM to test the ability for the system
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// to remain running.
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//
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public void KernelOOMStress() {
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Console.WriteLine("Not implemented yet");
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return;
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}
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}
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// Generic class that creates the thread
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public class ThreadRunner
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{
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private Thread thread;
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public ThreadRunner() {
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}
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public Thread Thread {
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get {
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return thread;
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}
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}
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// Creates thread, returns with it running
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public Thread RunThread() {
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thread = new Thread(new ThreadStart(ThreadMain));
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thread.Start();
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return thread;
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}
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public virtual void ThreadMain() {
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// This exits the thread
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return;
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}
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}
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//
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// Implementation classes represent different thread creation
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// parameters, and actions
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//
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//
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// This creates an idle thread that just waits.
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//
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// The goal is to create lots of kernel objects and use up
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// memory, not jam the system with many threads until
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// it stalls.
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//
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public class IdleThread : ThreadRunner
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{
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private long argValue;
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public IdleThread(long arg) : base() {
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argValue = arg;
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}
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public override void ThreadMain() {
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// Wait for ever
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while (true) {
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Thread.Sleep(60*60*1000);
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}
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// This exits the thread
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return;
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}
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}
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}
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