Ejemplo n.º 1
0
        private static IReadOnlyList <string> GetServices(string tracePath)
        {
            using (ITraceProcessor trace = TraceProcessor.Create(tracePath))
            {
                IPendingResult <IServiceDataSource> pendingServices = trace.UseServices();

                trace.Process();

                IServiceDataSource serviceData = pendingServices.Result;

                return(serviceData.Services.Select(s => Cleanup(s.Name)).ToArray());
            }
        }
Ejemplo n.º 2
0
    // Scan through a trace and print a summary of the system activity, with
    // svchost.exe and powershell process purposes annotated, chrome and
    // some other processes grouped, and with sampled data summarized by the
    // module it hits in and which modules are on the stacks.
    static void ProcessTrace(ITraceProcessor trace, string[] moduleList)
    {
        // metadata is retrieved directly instead of being retrieved after
        // trace.Process().
        var metadata = trace.UseMetadata();

        // Needed for precise CPU usage calculations.
        var pendingSchedulingData = trace.UseCpuSchedulingData();
        // Needed for processor count and memory size.
        var pendingSystemMetadata = trace.UseSystemMetadata();
        // Needed for PID to service mapping.
        var pendingServices = trace.UseServices();
        // Needed for seeing what modules samples hit in.
        var pendingSamplingData = trace.UseCpuSamplingData();

        trace.Process();

        // Convert from pending to actual data.
        var schedulingData = pendingSchedulingData.Result;
        var systemMetadata = pendingSystemMetadata.Result;
        var services       = pendingServices.Result;
        var samplingData   = pendingSamplingData.Result;

        // Print some high-level data about the trace and system.
        var traceDuration = metadata.AnalyzerDisplayedDuration;

        Console.WriteLine("Trace length is {0:0.00} seconds, system has {1} logical processors, {2}.",
                          traceDuration.TotalSeconds, systemMetadata.ProcessorCount, systemMetadata.UsableMemorySize);
        Console.WriteLine();

        // Map from an IProcess to CPUUsageDetails.
        var execTimes = new Dictionary <IProcess, CPUUsageDetails>();

        // Scan through the context-switch data to build up how much time
        // was spent by each process.
        foreach (var slice in schedulingData.CpuTimeSlices)
        {
            // Yep, this happens.
            if (slice.Process == null)
            {
                continue;
            }
            execTimes.TryGetValue(slice.Process, out CPUUsageDetails last);
            last.ns += slice.Duration.Nanoseconds;
            last.contextSwitches    += 1;
            execTimes[slice.Process] = last;
        }

        // Report on CPU usage for theses processes by name instead of by
        // process. That is, add same-named processes together.
        string[] sumNames = { "chrome.exe", "WmiPrvSE.exe", };
        var      sumsNs   = new long[sumNames.Length];

        // Scan through the per-process CPU consumption data
        var report = new List <Tuple <double, string> >();

        foreach (var times in execTimes)
        {
            var             process = times.Key;
            CPUUsageDetails details = times.Value;

            // See if we want to sum this process name.
            int i = Array.IndexOf(sumNames, process.ImageName);
            if (i >= 0)
            {
                sumsNs[i] += times.Value.ns;
                continue;
            }

            // Find the script name or service name that is associated with this
            // process so that our report associates the CPU time with a script
            // or service.
            string context     = "";
            var    commandLine = process.CommandLine;
            if (process.ImageName == "svchost.exe")
            {
                // Look for this pid in the snapshots. This should handle it if
                // multiple services exist in one process but this has not been
                // tested.
                foreach (var service in services.Snapshots)
                {
                    if (service.ProcessId == process.Id)
                    {
                        if (context.Length > 0)
                        {
                            context += ' ';
                        }
                        context += service.Name;
                    }
                }
            }
            else if (process.ImageName == "powershell.exe")
            {
                // Look for .ps1 and then search backwards for a space or slash character.
                var scriptEnd = commandLine.IndexOf(".ps1");
                if (scriptEnd > 0)
                {
                    // Look for a slash or space character to mark the beginning of
                    // the file name of the script.
                    var slash = commandLine.LastIndexOf('\\', scriptEnd);
                    var space = commandLine.LastIndexOf(' ', scriptEnd);
                    var start = Math.Max(slash, space) + 1;
                    context = commandLine.Substring(start, scriptEnd + 4 - start);
                }

                // If no .ps1 filename was found then try something else.
                if (context.Length == 0)
                {
                    // Grab the last parameter. This really needs to handle quotes to
                    // be useful.
                    var parts = commandLine.Split(' ');
                    context = parts[parts.Length - 1];
                }
            }
            else if (process.ImageName == "ruby.exe")
            {
                // Grab the start of the command-line and hope that helps.
                context = commandLine.Substring(0, Math.Min(20, commandLine.Length));
            }

            double timeSeconds = details.ns / 1e9;
            report.Add(new Tuple <double, string>(timeSeconds, string.Format("{0,20} ({1,5}) - {2}", process.ImageName, process.Id, context)));
        }

        // Add in the processes that we sum by name instead of by processes.
        for (int i = 0; i < sumNames.Length; ++i)
        {
            double timeSeconds = sumsNs[i] / 1e9;
            report.Add(new Tuple <double, string>(timeSeconds, string.Format("{0,20}", sumNames[i])));
        }

        // Sort the data by CPU time consumed and print the busiest processes:
        report.Sort();
        report.Reverse();
        foreach (var r in report)
        {
            // Arbitrary threshold so that we ignore boring data.
            if (r.Item1 > 2.0)
            {
                double percentage = r.Item1 / (double)traceDuration.TotalSeconds;
                Console.WriteLine("{0,9:P} of a core, {1,8:0.00} s CPU, {2}", percentage, r.Item1, r.Item2);
            }
        }

        // Record two dictionaries that map from modules to sample counts.
        // One is for samples that hit in that module, the other is for samples
        // that hit when an "interesting" module is on the stack.
        // Track by module name rather than IImage because some DLLs (ntdll.dll)
        // show up as many different IImage objects, which makes for a confusing
        // report.
        var samplesByImage      = new Dictionary <string, ulong>();
        var stackSamplesByImage = new Dictionary <string, ulong>();

        foreach (var sample in samplingData.Samples)
        {
            {
                // Attribute samples to the module they hit in. This gives a
                // sense of where CPU time is being spent across all processes
                // on the system. In some cases this can give hints - perhaps a
                // lower bound - on the cost of modules which inject themselves
                // into all processes.
                if (sample.Image != null)
                {
                    samplesByImage.TryGetValue(sample.Image.FileName, out ulong count);
                    ++count;
                    samplesByImage[sample.Image.FileName] = count;
                }
            }

            if (moduleList != null && sample.Stack != null)
            {
                // Attributes samples to interesting modules that are on the stack.
                // In some cases an injected module may ask the OS or other modules
                // to do work on its behalf. If antivirus DLLs are on the
                // stack but not currently executing then the executing code *may*
                // be doing work on their behalf, or not. Thus, gives gives a
                // rough upper bound on the cost of these systems. Note that only the
                // first module hit is counted.
                foreach (var frame in sample.Stack.Frames)
                {
                    if (frame.Image != null && frame.Image.FileName != null)
                    {
                        string imageName = frame.Image.FileName;
                        if (moduleList.Contains(imageName))
                        {
                            stackSamplesByImage.TryGetValue(imageName, out ulong count);
                            ++count;
                            stackSamplesByImage[imageName] = count;
                            break;
                        }
                    }
                }
            }
        }

        Console.WriteLine();
        int totalSamples = samplingData.Samples.Count;

        Console.WriteLine("Exclusive samples by module (out of {0:#,#} samples total):", totalSamples);
        PrintSampleData(new List <KeyValuePair <string, ulong> >(samplesByImage),
                        totalSamples, "{0,9:#,#} samples {1,6:P} in {2}");

        if (moduleList != null)
        {
            Console.WriteLine("");
            Console.WriteLine("Inclusive (stacks containing them) samples (out of {0:#,#} samples total):", totalSamples);
            PrintSampleData(new List <KeyValuePair <string, ulong> >(stackSamplesByImage),
                            totalSamples, "{0,9:#,#} samples {1,6:P} with {2} on the call stack");
        }
    }