public void NestedCollectorTest()
{
using (PerformanceCollector collector = new PerformanceCollector(TimeSpan.FromMilliseconds(10)))
{
using (var aggregator = collector.CreateAggregator())
{
// Sleep until we get a sample
Stopwatch sw = Stopwatch.StartNew();
while (sw.Elapsed.TotalSeconds < 60 && GetMaxAggregatorCount(aggregator) < 2)
{
Thread.Sleep(10);
}
XAssert.IsTrue(GetMaxAggregatorCount(aggregator) > 0, "No samples were collected");
using (var aggregator2 = collector.CreateAggregator())
{
Stopwatch sw2 = Stopwatch.StartNew();
while (sw2.Elapsed.TotalSeconds < 1 && GetMaxAggregatorCount(aggregator2) < 2)
{
Thread.Sleep(10);
}
XAssert.IsTrue(GetMaxAggregatorCount(aggregator) > GetMaxAggregatorCount(aggregator2), "The nested aggregator should have fewer samples than the earlier created aggregator");
}
}
}
}
private static IFrontEndController TryCreateFrontEndController(
FrontEndFactory frontEndFactory,
IDecorator <EvaluationResult> decorator,
ICommandLineConfiguration configuration,
SymbolTable symbolTable,
LoggingContext loggingContext,
PerformanceCollector collector,
bool collectMemoryAsSoonAsPossible,
IFrontEndStatistics statistics)
{
Contract.Requires(frontEndFactory != null && !frontEndFactory.IsSealed);
// Statistic should be global for all front-ends, not per an instance.
var frontEndStatistics = statistics ?? new FrontEndStatistics();
var sharedModuleRegistry = new ModuleRegistry(symbolTable);
// Note, that the following code is absolutely critical for detecting that front-end related objects
// are freed successfully after evaluation.
// ModuleRegistry was picked intentionally because it holds vast amount of front-end data.
FrontEndControllerMemoryObserver.CaptureFrontEndReference(sharedModuleRegistry);
frontEndFactory.SetConfigurationProcessor(
new ConfigurationProcessor(
new FrontEndStatistics(), // Configuration processing is so lightweight that it won't affect overall perf statistics
logger: null));
frontEndFactory.AddFrontEnd(new DScriptFrontEnd(
frontEndStatistics,
evaluationDecorator: decorator));
frontEndFactory.AddFrontEnd(new NugetFrontEnd(
frontEndStatistics,
evaluationDecorator: decorator));
frontEndFactory.AddFrontEnd(new DownloadFrontEnd());
#if PLATFORM_WIN
frontEndFactory.AddFrontEnd(new MsBuildFrontEnd());
frontEndFactory.AddFrontEnd(new NinjaFrontEnd());
frontEndFactory.AddFrontEnd(new CMakeFrontEnd());
frontEndFactory.AddFrontEnd(new RushFrontEnd());
frontEndFactory.AddFrontEnd(new YarnFrontEnd());
frontEndFactory.AddFrontEnd(new LageFrontEnd());
#endif
if (!frontEndFactory.TrySeal(loggingContext))
{
return(null);
}
return(new FrontEndHostController(
frontEndFactory,
evaluationScheduler: EvaluationScheduler.Default,
moduleRegistry: sharedModuleRegistry,
frontEndStatistics: frontEndStatistics,
logger: BuildXL.FrontEnd.Core.Tracing.Logger.CreateLogger(),
collector: collector,
collectMemoryAsSoonAsPossible: collectMemoryAsSoonAsPossible));
}
public void PerformanceCollectorBadStateTest()
{
var counters = new PerformanceCounter[]
{
new PerformanceCounter("Processor", "% Processor Time", "_Total123blabla"),
new PerformanceCounter("Processor", "% Processor Time", "_Total")
};
IPerformanceCollector collector = new PerformanceCollector();
foreach (var pc in counters)
{
try
{
collector.RegisterPerformanceCounter(
PerformanceCounterUtility.FormatPerformanceCounter(pc),
null,
pc.CategoryName,
pc.CounterName,
pc.InstanceName,
false,
true);
}
catch (Exception)
{
}
}
Assert.IsTrue(collector.PerformanceCounters.First().IsInBadState);
Assert.IsFalse(collector.PerformanceCounters.Last().IsInBadState);
}
/// <nodoc/>
public Aggregator(PerformanceCollector collector)
{
m_parent = collector;
ProcessCpu = new Aggregation();
ProcessPrivateMB = new Aggregation();
ProcessWorkingSetMB = new Aggregation();
ProcessThreadCount = new Aggregation();
ProcessHeldMB = new Aggregation();
MachineCpu = new Aggregation();
MachineAvailablePhysicalMB = new Aggregation();
MachineTotalPhysicalMB = new Aggregation();
CommitLimitMB = new Aggregation();
CommitUsedMB = new Aggregation();
MachineBandwidth = new Aggregation();
MachineKbitsPerSecSent = new Aggregation();
MachineKbitsPerSecReceived = new Aggregation();
ModifiedPagelistMB = new Aggregation();
StandbyPagelistMB = new Aggregation();
FreePagelistMB = new Aggregation();
List <Tuple <string, Aggregation> > aggs = new List <Tuple <string, Aggregation> >();
List <DiskStatistics> diskStats = new List <DiskStatistics>();
foreach (var drive in collector.GetDrives())
{
aggs.Add(new Tuple <string, Aggregation>(drive, new Aggregation()));
diskStats.Add(new DiskStatistics()
{
Drive = drive
});
}
m_diskStats = diskStats.ToArray();
}
public void PerformanceCollectorRefreshTest()
{
var counters = new PerformanceCounter[]
{
new PerformanceCounter("Processor", "% Processor Time", "_Total"),
new PerformanceCounter("Processor", "% Processor Time", "_Total")
};
var newCounter = new PerformanceCounter("Memory", "Available Bytes", string.Empty);
IPerformanceCollector collector = new PerformanceCollector();
foreach (var pc in counters)
{
collector.RegisterPerformanceCounter(
PerformanceCounterUtility.FormatPerformanceCounter(pc),
null,
pc.CategoryName,
pc.CounterName,
pc.InstanceName,
false,
true);
}
collector.RefreshPerformanceCounter(collector.PerformanceCounters.Last(), newCounter);
Assert.IsTrue(collector.PerformanceCounters.Last().PerformanceCounter.CategoryName == newCounter.CategoryName);
Assert.IsTrue(collector.PerformanceCounters.Last().PerformanceCounter.CounterName == newCounter.CounterName);
Assert.IsTrue(collector.PerformanceCounters.Last().PerformanceCounter.InstanceName == newCounter.InstanceName);
}
public static TimedBlock <TStartObject, TEndObject> Start(
LoggingContext parentLoggingContext,
PerformanceCollector collector,
string phaseFriendlyName,
Action <LoggingContext, TStartObject> startAction,
TStartObject startObject,
Action <LoggingContext, TEndObject> endAction,
Func <TEndObject> endObjGetter)
{
// There's no point is using this structure if the end action and struct aren't set
Contract.Requires(parentLoggingContext != null);
Contract.Requires(endAction != null);
Contract.Requires(endObjGetter != null);
Contract.Requires(startAction != null);
Contract.Requires(collector == null || !string.IsNullOrWhiteSpace(phaseFriendlyName));
startAction(parentLoggingContext, startObject);
return(new TimedBlock <TStartObject, TEndObject>(
parentLoggingContext,
collector?.CreateAggregator(),
phaseFriendlyName,
endAction,
endObjGetter));
}
public static PerformanceMeasurement Start(
LoggingContext parentLoggingContext,
PerformanceCollector collector,
string phaseFriendlyName,
Action <Guid> startAction,
Action endAction)
{
Contract.Requires(parentLoggingContext != null);
Contract.Requires(collector == null || !string.IsNullOrWhiteSpace(phaseFriendlyName));
Contract.Requires(startAction != null);
Contract.Requires(endAction != null);
return(Start(
parentLoggingContext,
collector,
phaseFriendlyName,
(context) =>
{
EventSource.SetCurrentThreadActivityId(context.ActivityId);
startAction(context.ParentActivityId);
},
(context) =>
{
EventSource.SetCurrentThreadActivityId(context.ActivityId);
endAction();
}));
}
private static AnalyzerTaskResult InternalAnalyzeAsync(ProcedureContext procedureContext, AdomdClient.AdomdConnection connection)
{
var queryResult = default(DataTable);
var profilerResult = default(ProfilerResult);
var performanceResult = default(PerformanceResult);
using (var collectorsSynchronizer = CollectorsSynchronizer.Create(procedureContext.CancellationToken))
using (var performanceTask = PerformanceCollector.StartAsync(procedureContext, collectorsSynchronizer))
{
try
{
if (!performanceTask.IsFaulted && !procedureContext.IsCancellationRequested)
{
#region profiler collector
using (var profilerCancellation = CancellationTokenSource.CreateLinkedTokenSource(procedureContext.CancellationToken))
using (var profilerTask = ProfilerCollector.StartAsync(procedureContext, collectorsSynchronizer, profilerCancellation.Token))
{
try
{
if (!profilerTask.IsFaulted && !profilerCancellation.IsCancellationRequested)
{
try
{
queryResult = AdomdClientHelper.ExecuteDataTable(
connection,
procedureContext.CancellationToken,
procedureContext.Statement,
activityID: procedureContext.ClientActivityID,
rowsLimit: procedureContext.QueryResultRowLimit,
beforeStart: () => EventsNotifier.Instance.Notify(ProcedureEvents.ProcedureAnalyzeStepExecuteStatement),
beforeWait: () => EventsNotifier.Instance.Notify(ProcedureEvents.ProcedureAnalyzeStepPendingOutcome)
);
}
finally
{
profilerCancellation.Cancel();
}
}
}
finally
{
profilerResult = profilerTask.Result;
}
}
#endregion
}
}
finally
{
performanceResult = performanceTask.Result;
}
}
return(AnalyzerTaskResult.Create(queryResult, profilerResult, performanceResult));
}
static MainWindow()
{
var counterCreationDatas = new[]
{
new CounterCreationData(COUNTER_NAME, "Help", PerformanceCounterType.NumberOfItems64),
new CounterCreationData(COUNTER2_NAME, "Help", PerformanceCounterType.RateOfCountsPerSecond64)
};
_performanceCollector = PerformanceCollector.Create("_Temp1", "test", counterCreationDatas);
}
public TestScheduler(
PipGraph graph,
TestPipQueue pipQueue,
PipExecutionContext context,
FileContentTable fileContentTable,
EngineCache cache,
IConfiguration configuration,
FileAccessWhitelist fileAccessWhitelist,
DirectoryMembershipFingerprinterRuleSet directoryMembershipFingerprinterRules = null,
ITempCleaner tempCleaner = null,
PipRuntimeTimeTable runningTimeTable = null,
JournalState journalState = null,
PerformanceCollector performanceCollector = null,
string fingerprintSalt = null,
PreserveOutputsInfo?previousInputsSalt = null,
IEnumerable <Pip> successfulPips = null,
IEnumerable <Pip> failedPips = null,
LoggingContext loggingContext = null,
IIpcProvider ipcProvider = null,
DirectoryTranslator directoryTranslator = null,
VmInitializer vmInitializer = null,
SchedulerTestHooks testHooks = null) : base(graph, pipQueue, context, fileContentTable, cache,
configuration, fileAccessWhitelist, loggingContext, null, directoryMembershipFingerprinterRules,
tempCleaner, AsyncLazy <PipRuntimeTimeTable> .FromResult(runningTimeTable), performanceCollector, fingerprintSalt, previousInputsSalt,
ipcProvider: ipcProvider,
directoryTranslator: directoryTranslator,
journalState: journalState,
vmInitializer: vmInitializer,
testHooks: testHooks)
{
m_testPipQueue = pipQueue;
if (successfulPips != null)
{
foreach (var pip in successfulPips)
{
Contract.Assume(pip.PipId.IsValid, "Override results must be added after the pip has been added to the scheduler");
m_overridePipResults.Add(pip.PipId, PipResultStatus.Succeeded);
}
}
if (failedPips != null)
{
foreach (var pip in failedPips)
{
Contract.Assume(pip.PipId.IsValid, "Override results must be added after the pip has been added to the scheduler");
m_overridePipResults.Add(pip.PipId, PipResultStatus.Failed);
}
}
m_loggingContext = loggingContext;
}
/// <summary>
/// Calls the specified observable call.
/// </summary>
/// <param name="statementMetricHandle">The statement metric handle.</param>
/// <param name="perfCollector">The perf collector.</param>
/// <param name="observableCall">The observable call.</param>
/// <param name="numInput">The num input.</param>
public static void Call(this StatementMetricHandle statementMetricHandle, PerformanceCollector perfCollector, Action observableCall, int numInput = 1)
{
if ((MetricReportingPath.IsMetricsEnabled) && statementMetricHandle.IsEnabled)
{
#if MONO
long lCreationTime, lExitTime;
long lUserTimeA, lKernelTimeA;
long lUserTimeB, lKernelTimeB;
//IntPtr thread = GetCurrentThread();
long lWallTimeA = PerformanceObserverMono.NanoTime;
//GetThreadTimes(out lUserTimeA, out lKernelTimeA);
observableCall.Invoke();
//GetThreadTimes(out lUserTimeB, out lKernelTimeB);
long lWallTimeB = PerformanceObserverMono.NanoTime;
long lTimeA = 0; // lKernelTimeA + lUserTimeA
long lTimeB = 0; // lKernelTimeB + lUserTimeB
perfCollector.Invoke(
metricValue,
100 * (lTimeB - lTimeA),
lWallTimeB - lWallTimeA);
#else
long lCreationTime, lExitTime;
long lUserTimeA, lKernelTimeA;
long lUserTimeB, lKernelTimeB;
IntPtr thread = GetCurrentThread();
long lWallTimeA = PerformanceObserverMono.NanoTime;
GetThreadTimes(thread, out lCreationTime, out lExitTime, out lUserTimeA, out lKernelTimeA);
observableCall.Invoke();
GetThreadTimes(thread, out lCreationTime, out lExitTime, out lUserTimeB, out lKernelTimeB);
long lWallTimeB = PerformanceObserverMono.NanoTime;
long lTimeA = (lKernelTimeA + lUserTimeA);
long lTimeB = (lKernelTimeB + lUserTimeB);
perfCollector.Invoke(
statementMetricHandle,
100 * (lTimeB - lTimeA),
lWallTimeB - lWallTimeA,
numInput);
#endif
}
else
{
observableCall.Invoke();
}
}
/// <summary>
/// Makes a new instance of <see cref="GameLoop"/> class.
/// </summary>
/// <param name="actionToDo">Delegate that will be executed on each frame.</param>
/// <param name="threadName">Name of the associated thread.</param>
public GameLoop(TimedAction actionToDo, string threadName)
{
loopAction = actionToDo;
ExitRequest = false;
this.threadName = threadName;
// - Initialize performance collector
Performance = new PerformanceCollector(threadName);
// - Initialize scheduler
Scheduler = new Scheduler();
// - Initialize clock
Clock = new ThrottledFramedClock();
}
/// <nodoc />
private FrontEndControllerFactory(
FrontEndMode mode,
LoggingContext loggingContext,
ICommandLineConfiguration configuration,
PerformanceCollector collector,
bool collectMemoryAsSoonAsPossible,
IFrontEndStatistics statistics)
{
m_mode = mode;
CollectMemoryAsSoonAsPossible = collectMemoryAsSoonAsPossible;
Configuration = configuration;
LoggingContext = loggingContext;
Collector = collector;
m_statistics = statistics;
}
/// <summary>
/// Makes a new instance of <see cref="GameLoop"/> class.
/// </summary>
/// <param name="action">Delegate that will be executed on each frame.</param>
/// <param name="threadName">Name of the associated thread.</param>
public GameLoop(Action <IFrameBasedClock> action, string threadName)
{
pLoopAction = action;
ExitRequest = false;
ThreadName = threadName;
// - Initialize performance collector
Performance = new PerformanceCollector(threadName);
// - Initialize scheduler
Scheduler = new Scheduler();
// - Initialize clock
Clock = new ThrottledFramedClock();
}
/// <nodoc />
public static FrontEndControllerFactory Create(
FrontEndMode mode,
LoggingContext loggingContext,
ICommandLineConfiguration configuration,
PerformanceCollector collector,
bool collectMemoryAsSoonAsPossible = true,
IFrontEndStatistics statistics = null)
{
return(new FrontEndControllerFactory(
mode,
loggingContext,
configuration,
collector,
collectMemoryAsSoonAsPossible,
statistics));
}
public static DataTable GetConfigurationFor(ConfigurationType configurationType)
{
switch (configurationType)
{
case ConfigurationType.Engine:
return(ProcedureContext.GetConfiguration());
case ConfigurationType.TraceEvents:
return(ProfilerCollector.GetConfiguration());
case ConfigurationType.PerformanceCounters:
return(PerformanceCollector.GetConfiguration());
default:
throw new ApplicationException("Unknown ConfigurationType [{0}]".FormatWith(configurationType));
}
}
public static List <TestResult> CallBatch(Func <IRpcService, TestRequest> requestFactory, int batchSize, PerformanceCollectorOptions options, TestResultCollector testResultCollector = null)
{
string requestMethodName = null;
var testResults = new List <TestResult>();
foreach (var service in TestExecutor.Services)
{
var request = requestFactory(service);
if (requestMethodName == null)
{
requestMethodName = request.MethodName;
}
if (options.Enabled)
{
options?.Writer?
.WriteLine()
.WriteLine($"Calling batch of {batchSize} {requestMethodName}".Center(80, '~'))
.WriteLine(request.ToString())
.DrawLine('~');
}
using (PerformanceCollector performanceCollector = new PerformanceCollector(service.GetServiceDescription(), options))
{
PerformanceEntry performance = performanceCollector.Measure(() => service.CallBatch(Enumerable.Range(0, batchSize).Select(n => request).ToList()));
testResults.Add(new TestResult(service, batchSize, performance));
AddBatchCallResult(service, requestMethodName, batchSize, performance.Elapsed);
}
}
if (testResultCollector != null)
{
testResultCollector.Collect(batchSize.ToString(), testResults);
}
else
{
using (testResultCollector = new TestResultCollector($"{requestMethodName} BATCH calls"))
{
testResultCollector.Collect(batchSize.ToString(), testResults);
}
}
return(testResults);
}
public static PerformanceMeasurement Start(
LoggingContext parentLoggingContext,
PerformanceCollector collector,
string phaseFriendlyName,
Action <LoggingContext> startAction,
Action <LoggingContext> endAction)
{
Contract.Requires(parentLoggingContext != null);
Contract.Requires(collector == null || !string.IsNullOrWhiteSpace(phaseFriendlyName));
Contract.Requires(startAction != null);
Contract.Requires(endAction != null);
var pm = new PerformanceMeasurement(
parentLoggingContext,
collector != null ? collector.CreateAggregator() : null,
phaseFriendlyName,
endAction);
startAction(pm.LoggingContext);
return(pm);
}
public void PerformanceCollectorSanityTest()
{
const int CounterCount = 3;
const string CategoryName = "Processor";
const string CounterName = "% Processor Time";
const string InstanceName = "_Total";
IPerformanceCollector collector = new PerformanceCollector();
for (int i = 0; i < CounterCount; i++)
{
collector.RegisterPerformanceCounter(
@"\Processor(_Total)\% Processor Time",
null,
CategoryName,
CounterName,
InstanceName,
false,
true);
}
var results = collector.Collect().ToList();
Assert.AreEqual(CounterCount, results.Count);
foreach (var result in results)
{
var pc = result.Item1.PerformanceCounter;
var value = result.Item2;
Assert.AreEqual(CategoryName, pc.CategoryName);
Assert.AreEqual(CounterName, pc.CounterName);
Assert.AreEqual(InstanceName, pc.InstanceName);
Assert.IsTrue(value >= 0 && value <= 100);
}
}
/// <summary>
/// Run the test
/// </summary>
public bool Run(string testFolder, string specFile, string fullIdentifier, string shortName, string lkgFile, params string[] sdksToResolve)
{
Contract.Requires(!string.IsNullOrEmpty(testFolder));
Contract.Requires(!string.IsNullOrEmpty(specFile));
Contract.Requires(sdksToResolve != null);
// Sadly the frontend doesn't use the engine abstractions file api's so we have to materialize stuff on disk for now...
// TODO: Fix this code once the frontend supports a proper virtual FileSystem.
// TODO: Change the package semantics to implicit when we expose a way to evaluate a single value
var testFileName = Path.GetFileName(specFile);
var mainFileName = "testMain.bp";
var testMainFile = Path.Combine(testFolder, mainFileName);
Directory.CreateDirectory(testFolder);
File.WriteAllText(Path.Combine(testFolder, Names.ModuleConfigBm), I($@"module(
{{
name: 'TestPackage',
nameResolutionSemantics: NameResolutionSemantics.implicitProjectReferences,
projects: [
f`{mainFileName}`,
f`{testFileName}`,
],
}});"));
File.WriteAllText(testMainFile, I($@"
export const testFolder = d`{Path.GetDirectoryName(specFile).Replace('\\', '/')}`;
@@public
export const main = {fullIdentifier}();"));
File.Copy(specFile, Path.Combine(testFolder, testFileName));
// Create a fake package for Sdk.TestRunner so that you can safely test packages that have the tests embedded in them.
var testRunnerFolder = Path.Combine(testFolder, "Sdk.TestRunner");
Directory.CreateDirectory(testRunnerFolder);
File.WriteAllText(Path.Combine(testRunnerFolder, Names.ModuleConfigBm), I($"module({{\n\tname: 'Sdk.TestRunner',\n}});"));
File.WriteAllText(Path.Combine(testRunnerFolder, "package" + Names.DotDscExtension), I($@"
export interface TestArguments {{
testFiles: File[];
sdkFolders?: (Directory|StaticDirectory)[];
autoFixLkgs?: boolean;
}}
export interface TestResult {{
xmlResults: File;
}}
export function test(args: TestArguments): TestResult {{
Contract.fail(""Can't run a DScript UnitTest inside of a DScript UnitTest"");
}}"));
// Setup Context and configuration
var frontEndContext = FrontEndContext.CreateInstanceForTesting();
var pipContext = new SchedulerContext(CancellationToken.None, frontEndContext.StringTable, frontEndContext.PathTable, frontEndContext.SymbolTable, frontEndContext.QualifierTable);
var pathTable = frontEndContext.PathTable;
var testFolderPath = AbsolutePath.Create(pathTable, testFolder);
var configuration = CreateConfiguration(sdksToResolve.Union(new[] { testRunnerFolder }), pathTable, testFolderPath);
var engineAbstraction = new TestEngineAbstraction(pathTable, frontEndContext.StringTable, testFolderPath, new PassThroughFileSystem(pathTable));
var frontEndStatistics = new FrontEndStatistics();
if (!CreateFactories(
frontEndContext,
engineAbstraction,
frontEndStatistics,
configuration,
out var ambientTesting,
out var moduleRegistry,
out var frontEndFactory))
{
return(false);
}
// Set the timeout to a large number to avoid useless performance collections in tests.
using (var performanceCollector = new PerformanceCollector(TimeSpan.FromHours(1)))
using (var frontEndHostController = new FrontEndHostController(
frontEndFactory,
new EvaluationScheduler(1),
moduleRegistry,
frontEndStatistics,
m_tracingLogger,
performanceCollector,
collectMemoryAsSoonAsPossible: true))
{
var frontEndController = (IFrontEndController)frontEndHostController;
frontEndController.InitializeHost(frontEndContext, configuration);
frontEndController.ParseConfig(configuration);
// Populate the graph
using (var pipTable = new PipTable(
pipContext.PathTable,
pipContext.SymbolTable,
initialBufferSize: 16384,
maxDegreeOfParallelism: 1,
debug: true))
{
var mountPathExpander = new MountPathExpander(pathTable);
mountPathExpander.Add(pathTable, new SemanticPathInfo(PathAtom.Create(frontEndContext.StringTable, "testFolder"), testFolderPath, allowHashing: true, readable: true, writable: false));
mountPathExpander.Add(pathTable, new SemanticPathInfo(PathAtom.Create(frontEndContext.StringTable, "src"), testFolderPath.Combine(pathTable, "src"), allowHashing: true, readable: true, writable: true));
mountPathExpander.Add(pathTable, new SemanticPathInfo(PathAtom.Create(frontEndContext.StringTable, "out"), testFolderPath.Combine(pathTable, "out"), allowHashing: true, readable: true, writable: true));
mountPathExpander.Add(pathTable, new SemanticPathInfo(PathAtom.Create(frontEndContext.StringTable, "noRead"), testFolderPath.Combine(pathTable, "noRead"), allowHashing: true, readable: false, writable: true));
mountPathExpander.Add(pathTable, new SemanticPathInfo(PathAtom.Create(frontEndContext.StringTable, "temp"), engineAbstraction.Layout.TempDirectory, allowHashing: true, readable: true, writable: true));
mountPathExpander.Add(pathTable, new SemanticPathInfo(PathAtom.Create(frontEndContext.StringTable, "obj"), engineAbstraction.Layout.ObjectDirectory, allowHashing: true, readable: true, writable: true));
var graph = new PipGraph.Builder(
pipTable,
pipContext,
m_pipLogger,
frontEndContext.LoggingContext,
configuration,
mountPathExpander);
using (var cacheLayer = new EngineCache(
new InMemoryArtifactContentCache(),
new InMemoryTwoPhaseFingerprintStore()))
{
var cache = Task.FromResult(Possible.Create(cacheLayer));
try
{
var evaluationFilter = new EvaluationFilter(
pipContext.SymbolTable,
pipContext.PathTable,
new FullSymbol[0],
new[]
{
AbsolutePath.Create(frontEndContext.PathTable, testMainFile),
},
CollectionUtilities.EmptyArray <StringId>());
if (!frontEndController.PopulateGraph(cache, graph, engineAbstraction, evaluationFilter, configuration, configuration.Startup))
{
HandleDiagnostics();
return(false);
}
}
catch (AggregateException e)
{
var baseException = e.GetBaseException();
if (baseException is XunitException)
{
// If it is an XUnit assert, then unwrap the exception and throw that because XUnit other doesn't display the error nicely.
ExceptionDispatchInfo.Capture(baseException).Throw();
}
throw;
}
}
if (!ValidatePips(frontEndContext, graph, testFolderPath, specFile, shortName, lkgFile, ambientTesting.DontValidatePipsEnabled))
{
return(false);
}
}
}
HandleDiagnostics();
return(true);
}
public static void CallNTimes(Func <IRpcService, TestRequest> requestFactory, int count, PerformanceCollectorOptions options, TestResultCollector testResultCollector = null)
{
string requestMethodName = null;
List <TestResult>[] testResults = Enumerable.Range(0, count).Select((i) => new List <TestResult>()).ToArray();
foreach (var service in TestExecutor.Services)
{
var request = requestFactory(service);
if (requestMethodName == null)
{
requestMethodName = request.MethodName;
}
if (options.Enabled)
{
options?.Writer?
.WriteLine()
.WriteLine($"Calling {requestMethodName} {count} times".Center(80, '~'))
.WriteLine(request.ToString())
.DrawLine('~');
}
using (PerformanceCollector performanceCollector = new PerformanceCollector(service.GetServiceDescription(), options))
{
for (int i = 0; i < count; i++)
{
int retries = 0;
while (retries < MAX_RETRY)
{
try
{
PerformanceEntry performance = performanceCollector.Measure(() => service.CallSingle(request));
testResults[i].Add(new TestResult(service, count, performance));
AddSingleCallResult(service, requestMethodName, performance.Elapsed);
break;
}
catch (System.Exception ex)
{
Thread.Sleep(200); //introduces a wait between calls because of intermittent problem with "The server returned an invalid or unrecognized response" error
retries++;
}
}
}
}
}
if (testResultCollector != null)
{
for (int i = 0; i < testResults.Length; i++)
{
testResultCollector.Collect($"t-{i + 1}", testResults[i]);
}
}
else
{
using (testResultCollector = new TestResultCollector($"{requestMethodName} repeated calls ({count})."))
{
for (int i = 0; i < testResults.Length; i++)
{
testResultCollector.Collect($"t-{i + 1}", testResults[i]);
}
}
}
}
/// <summary>
/// Calls the specified observable call.
/// </summary>
/// <param name="statementMetricHandle">The statement metric handle.</param>
/// <param name="perfCollector">The perf collector.</param>
/// <param name="observableCall">The observable call.</param>
/// <param name="numInput">The num input.</param>
public static void Call(this StatementMetricHandle statementMetricHandle, PerformanceCollector perfCollector, Action observableCall, int numInput = 1)
{
if ((MetricReportingPath.IsMetricsEnabled) && statementMetricHandle.IsEnabled)
{
#if MONO
long lCreationTime, lExitTime;
long lUserTimeA, lKernelTimeA;
long lUserTimeB, lKernelTimeB;
//IntPtr thread = GetCurrentThread();
long lWallTimeA = PerformanceObserverMono.NanoTime;
//GetThreadTimes(out lUserTimeA, out lKernelTimeA);
observableCall.Invoke();
//GetThreadTimes(out lUserTimeB, out lKernelTimeB);
long lWallTimeB = PerformanceObserverMono.NanoTime;
long lTimeA = 0; // lKernelTimeA + lUserTimeA
long lTimeB = 0; // lKernelTimeB + lUserTimeB
perfCollector.Invoke(
metricValue,
100 * (lTimeB - lTimeA),
lWallTimeB - lWallTimeA);
#else
FILETIME lCreationTime;
FILETIME lExitTime;
FILETIME lUserTimeA;
FILETIME lKernelTimeA;
FILETIME lUserTimeB;
FILETIME lKernelTimeB;
IntPtr thread = GetCurrentThread();
long lWallTimeA = PerformanceObserverMono.NanoTime;
GetThreadTimes(thread, out lCreationTime, out lExitTime, out lUserTimeA, out lKernelTimeA);
observableCall.Invoke();
GetThreadTimes(thread, out lCreationTime, out lExitTime, out lUserTimeB, out lKernelTimeB);
long lWallTimeB = PerformanceObserverMono.NanoTime;
// Calculate the time, not that the numbers represent 100-nanosecond intervals since
// January 1, 601 (UTC).
// https://msdn.microsoft.com/en-us/library/windows/desktop/ms724284(v=vs.85).aspx
var kernelTimeA = (((long)lKernelTimeA.dwHighDateTime) << 32) | ((long)lKernelTimeA.dwLowDateTime);
var kernelTimeB = (((long)lKernelTimeB.dwHighDateTime) << 32) | ((long)lKernelTimeB.dwLowDateTime);
var userTimeA = (((long)lUserTimeA.dwHighDateTime) << 32) | ((long)lUserTimeA.dwLowDateTime);
var userTimeB = (((long)lUserTimeB.dwHighDateTime) << 32) | ((long)lUserTimeB.dwLowDateTime);
var execTimeNano = 100 * (userTimeB - userTimeA + kernelTimeB - kernelTimeA);
perfCollector.Invoke(
statementMetricHandle,
execTimeNano,
lWallTimeB - lWallTimeA,
numInput);
#endif
}
else
{
observableCall.Invoke();
}
}
private static IFrontEndController TryCreateFrontEndController(
FrontEndFactory frontEndFactory,
IDecorator <EvaluationResult> decorator,
ICommandLineConfiguration configuration,
SymbolTable symbolTable,
LoggingContext loggingContext,
PerformanceCollector collector,
bool collectMemoryAsSoonAsPossible,
IFrontEndStatistics statistics)
{
var workspaceResolverFactory = new DScriptWorkspaceResolverFactory();
Contract.Requires(frontEndFactory != null && !frontEndFactory.IsSealed);
// Statistic should be global for all front-ends, not per an instance.
var frontEndStatistics = statistics ?? new FrontEndStatistics();
var globalConstants = new GlobalConstants(symbolTable);
var sharedModuleRegistry = new ModuleRegistry();
// Note, that the following code is absolutely critical for detecting that front-end related objects
// are freed successfully after evaluation.
// ModuleRegistry was picked intentionally because it holds vast amount of front-end data.
FrontEndControllerMemoryObserver.CaptureFrontEndReference(sharedModuleRegistry);
frontEndFactory.SetConfigurationProcessor(
new ConfigurationProcessor(globalConstants, sharedModuleRegistry, logger: null));
var msBuildFrontEnd = new MsBuildFrontEnd(
globalConstants,
sharedModuleRegistry,
frontEndStatistics);
var ninjaFrontEnd = new NinjaFrontEnd(
globalConstants,
sharedModuleRegistry,
frontEndStatistics);
var cmakeFrontEnd = new CMakeFrontEnd(
globalConstants,
sharedModuleRegistry,
frontEndStatistics);
// TODO: Workspace resolvers and frontends are registered in separate factories. Consider
// adding a main coordinator/registry
RegisterKnownWorkspaceResolvers(
workspaceResolverFactory,
globalConstants,
sharedModuleRegistry,
frontEndStatistics,
msBuildFrontEnd,
ninjaFrontEnd,
cmakeFrontEnd);
frontEndFactory.AddFrontEnd(new DScriptFrontEnd(
globalConstants,
sharedModuleRegistry,
frontEndStatistics,
evaluationDecorator: decorator));
frontEndFactory.AddFrontEnd(new NugetFrontEnd(
globalConstants,
sharedModuleRegistry,
frontEndStatistics,
evaluationDecorator: decorator));
frontEndFactory.AddFrontEnd(new DownloadFrontEnd(
globalConstants,
sharedModuleRegistry));
frontEndFactory.AddFrontEnd(msBuildFrontEnd);
frontEndFactory.AddFrontEnd(ninjaFrontEnd);
frontEndFactory.AddFrontEnd(cmakeFrontEnd);
if (!frontEndFactory.TrySeal(loggingContext))
{
return(null);
}
return(new FrontEndHostController(frontEndFactory, workspaceResolverFactory,
frontEndStatistics: frontEndStatistics, collector: collector, collectMemoryAsSoonAsPossible: collectMemoryAsSoonAsPossible));
}
