public bool Read(XmlReader reader)
{
if(reader.IsStartElement() && reader.Name == "Fixture") {
Fixture fixture = new Fixture();
//...Any attributes go here...
fixture.AllowFrameSkip = bool.Parse(reader.GetAttribute("allowFrameSkip"));
fixture.Name = reader.GetAttribute("name");
// This needs to hold off until after channels are loaded.
string fixtureDefinitionName = reader.GetAttribute("fixtureDefinitionName");
if(reader.ElementsExistWithin("Fixture")) { // Entity element
// Channels
if(reader.ElementsExistWithin("Channels")) { // Container element for child entity
ChannelReader<OutputChannel> channelReader = new ChannelReader<OutputChannel>();
while(channelReader.Read(reader)) {
fixture.InsertChannel(channelReader.Channel);
}
reader.ReadEndElement(); // Channels
}
// With channels loaded, the fixture template reference can be set.
fixture.FixtureDefinitionName = fixtureDefinitionName;
reader.ReadEndElement(); // Fixture
this.Fixture = fixture;
}
return true;
}
return false;
}
// The constructor taking the input info channel and the output acknowledge channel.
public Taxi(ChannelReader<Tuple<int, int, string>> info, ChannelWriter<string> ack)
{
customerInfoChannel = info;
ackChannel = ack;
timer = new Timer();
rand = new Random();
}
public Dispatch(ChannelReader<Tuple<int, int, string>> customer, int taxis)
{
customerChan = customer;
ackChannel = new Channel<string>();
taxiChan = new Channel<Tuple<int, int, string>>();
numTaxis = vacantTaxis = taxis;
}
protected override void ReadBody(XmlReader reader)
{
// Channels
if(reader.ElementsExistWithin("Channels")) { // Container element for child entity
ChannelReader<OutputChannel> channelReader = new ChannelReader<OutputChannel>();
while(channelReader.Read(reader)) {
InsertChannel(channelReader.Channel);
}
reader.ReadEndElement(); // Channels
}
}
public AsyncEnumerableImplChannelThrows(ChannelReader <T> inner)
{
_inner = inner;
}
public async Task StreamDontRead(ChannelReader <string> source)
{
while (await source.WaitToReadAsync())
{
}
}
/// <summary> /// Channel reader, executing the function once data is available in channel /// </summary> /// <param name="reader">The channel reader</param> /// <param name="cancellationToken">Cancellation token indicating the host is shutting down</param> /// <param name="logger">Logger</param> protected abstract Task ReaderAsync(ChannelReader <KafkaEventData[]> reader, CancellationToken cancellationToken, ILogger logger);
public Consumer(ChannelReader <string> reader, HardWorker worker)
{
_reader = reader;
_worker = worker;
}
// ConcurrentTransform
public static async Task ConcurrentTransform <TIn, TOut>(
this ChannelReader <TIn> reader,
ChannelWriter <TOut> writer,
Func <TIn, TOut> transformer,
int concurrencyLevel = -1,
ChannelCompletionMode channelCompletionMode = ChannelCompletionMode.CompleteAndPropagateError,
CancellationToken cancellationToken = default)
{
if (concurrencyLevel < 0)
{
concurrencyLevel = HardwareInfo.GetProcessorCountFactor();
}
var semaphore = new SemaphoreSlim(concurrencyLevel, concurrencyLevel);
Exception?error = null;
async Task Worker()
{
try {
for (;;)
{
await semaphore !.WaitAsync(cancellationToken).ConfigureAwait(false);
try {
if (!await reader.WaitToReadAsync(cancellationToken).ConfigureAwait(false))
{
break;
}
if (!reader.TryRead(out var item))
{
continue;
}
var newItem = transformer.Invoke(item);
await writer.WriteAsync(newItem, cancellationToken).ConfigureAwait(false);
}
finally {
semaphore.Release();
}
}
}
catch (OperationCanceledException) {
throw;
}
catch (Exception e) {
if (channelCompletionMode == ChannelCompletionMode.CompleteAndPropagateError)
{
error = e;
}
else
{
throw;
}
}
}
var workers = new Task[concurrencyLevel];
for (var i = 0; i < concurrencyLevel; i++)
{
workers[i] = Task.Run(Worker, cancellationToken);
}
await Task.WhenAll(workers).ConfigureAwait(false);
if ((channelCompletionMode & ChannelCompletionMode.Complete) != 0)
{
writer.TryComplete(error);
}
}
public Consumer(ChannelReader <string> reader, int identifier, int delay)
{
_reader = reader;
_identifier = identifier;
_delay = delay;
}
private async Task Run(ChannelReader <BlockGraph> reader)
{
while (await reader.WaitToReadAsync())
{
while (reader.TryRead(out var data))
{
var entries = new Entry[data.Deps.Count];
GraphMutex.WaitOne();
var max = data.Block.Round;
var round = Round;
for (var i = 0; i < data.Deps.Count; i++)
{
var dep = data.Deps[i];
Debug.WriteLine($"Dep: block.id={dep.Block}");
var depMax = dep.Block.Round;
var rcheck = false;
var e = new Entry(dep.Block, dep.Prev);
if (dep.Block.Round != 1)
{
e.Deps = new BlockID[dep.Deps.Count + 1];
e.Deps[0] = dep.Prev;
Array.Copy(dep.Deps.ToArray(), 0, e.Deps, 1, dep.Deps.Count);
var prevMax = (ulong)0;
if (Max.ContainsKey(dep.Prev))
{
prevMax = Max[dep.Prev];
rcheck = true;
}
else if (prevMax > depMax)
{
depMax = prevMax;
}
}
else
{
e.Deps = dep.Deps.ToArray();
}
entries[i] = e;
foreach (var link in dep.Deps)
{
if (!Max.ContainsKey(link))
{
rcheck = true;
}
else
{
var linkMax = Max[link];
if (linkMax > depMax)
{
depMax = linkMax;
}
}
}
if (rcheck && round > depMax)
{
depMax = round;
}
Max[dep.Block] = depMax;
if (depMax > max)
{
max = depMax;
}
}
var rcheck2 = false;
if (data.Block.Round != 1)
{
if (!Max.ContainsKey(data.Prev))
{
rcheck2 = true;
}
else
{
var pmax = Max[data.Prev];
if (pmax > max)
{
max = pmax;
}
}
}
if (rcheck2 && round > max)
{
max = round;
}
Max[data.Block] = max;
Blocks.Add(new BlockInfo(data, max));
GraphMutex.ReleaseMutex();
foreach (var e in entries)
{
Process(e);
}
var self = new Entry(data.Block, data.Prev)
{
Deps = new BlockID[data.Deps.Count + 1]
};
self.Deps[0] = data.Prev;
for (var i = 0; i < data.Deps.Count; i++)
{
var dep = data.Deps[i];
self.Deps[i + 1] = dep.Block;
}
Process(self);
}
}
}
public FilteringChannelReader(ChannelReader <T> source, Func <T, bool> predicate)
{
_source = source ?? throw new ArgumentNullException(nameof(source));
_predicate = predicate ?? throw new ArgumentNullException(nameof(predicate));
Contract.EndContractBlock();
}
public async ValueTask Init(ChannelReader <byte[]> outboundChan, ILocalAdapter localAdapter, CancellationToken cancellationToken = default)
{
if (localAdapter.Destination.TransportProtocol == TransportProtocol.Udp)
{
throw UdpNotSupportedException;
}
var dev = NetworkInformation.GetInternetConnectionProfile().NetworkAdapter;
var connectTask = socket.ConnectAsync(new HostName(server), port.ToString(), SocketProtectionLevel.PlainSocket, dev).AsTask(cancellationToken).ConfigureAwait(false);
var destination = localAdapter.Destination;
var dstPort = destination.Port;
var dstPortStrSize = CountDigit(dstPort);
var dstHostStrSize = destination.Host.Size;
int headerLen = HEADER1.Length + dstHostStrSize + 1 + dstPortStrSize + HEADER2.Length;
var firstSeg = sendArrayPool.Rent(headerLen);
try
{
HEADER1.CopyTo(firstSeg, 0);
destination.Host.CopyTo(firstSeg.AsSpan(HEADER1.Length));
firstSeg[HEADER1.Length + dstHostStrSize] = (byte)':';
while (dstPortStrSize-- > 0)
{
firstSeg[HEADER1.Length + dstHostStrSize + 1 + dstPortStrSize] = (byte)(dstPort % 10 + '0');
dstPort /= 10;
}
HEADER2.CopyTo(firstSeg, headerLen - HEADER2.Length);
// Connect and perform handshake
await connectTask;
inputStream = socket.InputStream;
outputStream = socket.OutputStream;
await outputStream.WriteAsync(firstSeg.AsBuffer(0, headerLen)).AsTask(cancellationToken).ConfigureAwait(false);
}
finally
{
sendArrayPool.Return(firstSeg);
}
var responseBuf = sendArrayPool.Rent(HEAD_BUFFER_LEN);
try
{
var resBuf = await inputStream.ReadAsync(responseBuf.AsBuffer(), HEAD_BUFFER_LEN, InputStreamOptions.Partial).AsTask(cancellationToken).ConfigureAwait(false);
uint responseLen = resBuf.Length;
if (responseLen < 14)
{
throw new InvalidOperationException("Remote response too short");
}
if ((responseBuf[9] == (byte)'2') && (responseBuf[10] == (byte)'0') && (responseBuf[11] == (byte)'0'))
{
// 200 objk
}
else
{
var code = 100 * (responseBuf[9] - '0') + 10 * (responseBuf[10] - '0') + responseBuf[11] - '0';
throw new InvalidOperationException("Remote status code: " + code.ToString());
}
bool foundHeader = false;
for (int headerStart = 12; headerStart < responseLen - 3; headerStart++)
{
if (responseBuf[headerStart] == '\r')
{
if (responseBuf[headerStart + 1] == '\n')
{
if (responseBuf[headerStart + 2] == '\r')
{
if (responseBuf[headerStart + 3] == '\n')
{
foundHeader = true;
break;
}
}
}
}
}
if (!foundHeader)
{
throw new InvalidOperationException("Unrecognized remote header: " + Encoding.UTF8.GetString(responseBuf, 0, (int)responseLen));
}
}
finally
{
sendArrayPool.Return(responseBuf);
}
// Initial data?
}
public Consumer(ChannelReader <T> reader)
{
_reader = reader;
}
public IConsumerManager Create(ChannelReader <string> reader)
{
return(new ConsumerManager(2, reader, EmbeddedFileUtils.GetExcludedWords()));
}
public static IAsyncEnumerator <object?> MakeAsyncEnumeratorFromChannel <T>(ChannelReader <T> channel, CancellationToken cancellationToken = default)
{
return(new ChannelAsyncEnumerator <T>(channel, cancellationToken));
}
public void ReadWriteVariations(
Func <ChannelOptions, Channel <int> > channelCreator,
ChannelOptions options,
Func <ChannelReader <int>, Task <bool> > readDelegate,
Func <ChannelWriter <int>, int, Task> writeDelegate)
{
Channel <int> channel = channelCreator(options);
ChannelReader <int> reader = channel.Reader;
ChannelWriter <int> writer = channel.Writer;
BoundedChannelOptions boundedOptions = options as BoundedChannelOptions;
bool shouldReadAllWrittenValues = boundedOptions == null || boundedOptions.FullMode == BoundedChannelFullMode.Wait;
List <Task> taskList = new List <Task>();
int readerTasksCount;
int writerTasksCount;
if (options.SingleReader)
{
readerTasksCount = 1;
writerTasksCount = options.SingleWriter ? 1 : MaxTaskCounts - 1;
}
else if (options.SingleWriter)
{
writerTasksCount = 1;
readerTasksCount = MaxTaskCounts - 1;
}
else
{
readerTasksCount = MaxTaskCounts / 2;
writerTasksCount = MaxTaskCounts - readerTasksCount;
}
int readCount = 0;
for (int i = 0; i < readerTasksCount; i++)
{
taskList.Add(Task.Run(async delegate
{
try
{
while (true)
{
if (!await readDelegate(reader))
{
break;
}
Interlocked.Increment(ref readCount);
}
}
catch (ChannelClosedException)
{
}
}));
}
int numberToWriteToQueue = -1;
int remainingWriters = writerTasksCount;
for (int i = 0; i < writerTasksCount; i++)
{
taskList.Add(Task.Run(async delegate
{
int num = Interlocked.Increment(ref numberToWriteToQueue);
while (num < MaxNumberToWriteToChannel)
{
await writeDelegate(writer, num);
num = Interlocked.Increment(ref numberToWriteToQueue);
}
if (Interlocked.Decrement(ref remainingWriters) == 0)
{
writer.Complete();
}
}));
}
Task.WaitAll(taskList.ToArray());
if (shouldReadAllWrittenValues)
{
Assert.Equal(MaxNumberToWriteToChannel, readCount);
}
else
{
Assert.InRange(readCount, 0, MaxNumberToWriteToChannel);
}
}
public static InvocationRequest Stream(CancellationToken cancellationToken, Type resultType, string invocationId,
ILoggerFactory loggerFactory, HubConnection hubConnection, out ChannelReader <object?> result)
{
var req = new Streaming(cancellationToken, resultType, invocationId, loggerFactory, hubConnection);
result = req.Result;
return(req);
}
public async Task <string> DoubleStreamUpload(ChannelReader <string> letters, ChannelReader <int> numbers)
{
var total = await Sum(numbers);
var word = await UploadWord(letters);
return(string.Format("You sent over <{0}> <{1}s>", total, word));
}
public static IAsyncEnumerable <object> MakeCancelableAsyncEnumerableFromChannel <T>(ChannelReader <T> channel, CancellationToken cancellationToken = default)
{
return(MakeCancelableAsyncEnumerable(channel.ReadAllAsync(), cancellationToken));
}
private static async Task <List <ReplaceOneModel <BsonDocument> > > ReadModelsFromChannelAsync(ChannelReader <ReplaceOneModel <BsonDocument> > reader)
{
var models = new List <ReplaceOneModel <BsonDocument> >();
await foreach (var model in reader.ReadAllAsync())
{
models.Add(model);
}
return(models);
}
public static T MustRead <T>(this ChannelReader <T> reader)
{
return(reader.TryRead(out T value) ?
value :
throw new InvalidOperationException("nothing to read"));
}
public ChannelReaderSource(ChannelReader <T> reader)
{
_reader = reader;
Outlet = new Outlet <T>("channelReader.out");
Shape = new SourceShape <T>(Outlet);
}
public WebSocketChannel(ChannelReader <WebSocketMessage> input, ChannelWriter <WebSocketMessage> output)
{
_input = input;
_output = output;
}
private async Task <bool> WriteResultsAsync(TContext rootContext)
{
int currentIndex = 0;
var itemsSeen = new HashSet <int>();
ChannelReader <int> reader = _resultsWritingChannel.Reader;
// Wait until there is work or the channel is closed.
while (await reader.WaitToReadAsync())
{
// Loop while there is work to do.
while (reader.TryRead(out int item))
{
Debug.Assert(!itemsSeen.Contains(item));
itemsSeen.Add(item);
// This condition can occur if currentIndex moves
// ahead in array processing due to operations
// against it by other threads. For this case,
// since the relevant file has already been
// processed, we just ignore this notification.
if (currentIndex > item)
{
break;
}
TContext context = default;
try
{
context = _fileContexts[currentIndex];
while (context?.AnalysisComplete == true)
{
CachingLogger cachingLogger = ((CachingLogger)context.Logger);
IDictionary <ReportingDescriptor, IList <Result> > results = cachingLogger.Results;
if (results?.Count > 0)
{
if (context.Hashes != null)
{
Debug.Assert(_run != null);
int index = _run.GetFileIndex(new ArtifactLocation()
{
Uri = context.TargetUri
});
_run.Artifacts[index].Hashes = new Dictionary <string, string>
{
{ "sha-256", context.Hashes.Sha256 },
};
}
foreach (KeyValuePair <ReportingDescriptor, IList <Result> > kv in results)
{
foreach (Result result in kv.Value)
{
rootContext.Logger.Log(kv.Key, result);
}
}
}
if (cachingLogger.ToolNotifications != null)
{
foreach (Notification notification in cachingLogger.ToolNotifications)
{
rootContext.Logger.LogToolNotification(notification);
}
}
if (cachingLogger.ConfigurationNotifications != null)
{
foreach (Notification notification in cachingLogger.ConfigurationNotifications)
{
rootContext.Logger.LogConfigurationNotification(notification);
}
}
RuntimeErrors |= context.RuntimeErrors;
_fileContexts[currentIndex] = default;
context = currentIndex < (_fileContexts.Count - 1)
? context = _fileContexts[currentIndex + 1]
: default;
currentIndex++;
}
}
catch (Exception e)
{
context = default;
RuntimeErrors |= Errors.LogUnhandledEngineException(rootContext, e);
ThrowExitApplicationException(context, ExitReason.ExceptionWritingToLogFile, e);
}
}
}
Debug.Assert(currentIndex == _fileContexts.Count);
Debug.Assert(itemsSeen.Count == _fileContexts.Count);
return(true);
}
private async Task <bool> MergeSarifLogsAsync()
{
if (_options.SplittingStrategy != SplittingStrategy.PerRule)
{
this._idToSarifLogMap[""] = new SarifLog()
{
Runs = new List <Run>()
};
}
ChannelReader <SarifLog> reader = _mergeLogsChannel.Reader;
// Wait until there is work or the channel is closed.
while (await reader.WaitToReadAsync())
{
// Loop while there is work to do.
while (reader.TryRead(out SarifLog sarifLog))
{
foreach (Run run in sarifLog.Runs)
{
if (_options.SplittingStrategy == SplittingStrategy.PerRule || !_options.MergeEmptyLogs)
{
if (run.Results == null || run.Results.Count == 0)
{
continue;
}
}
IList <Result> cachedResults = run.Results;
run.Results = null;
Run emptyRun = run.DeepClone();
run.Results = cachedResults;
if (run.Results != null)
{
foreach (Result result in run.Results)
{
string key = _options.SplittingStrategy == SplittingStrategy.PerRule
? result.RuleId
: string.Empty;
if (!_idToSarifLogMap.TryGetValue(key, out SarifLog splitLog))
{
splitLog = _idToSarifLogMap[key] = new SarifLog()
{
Runs = new List <Run>()
};
}
key = CreateRuleKey(result.RuleId, emptyRun);
if (!_ruleIdToRunsMap.TryGetValue(key, out Run splitRun))
{
emptyRun.Results = new List <Result>();
splitRun = _ruleIdToRunsMap[key] = emptyRun;
splitLog.Runs.Add(splitRun);
_ruleIdToResultsMap[key] = new HashSet <Result>(Result.ValueComparer);
}
if (!_ruleIdToResultsMap[key].Contains(result))
{
_ruleIdToResultsMap[key].Add(result);
splitRun.Results.Add(result);
}
}
}
}
}
}
return(true);
}
public JoiningChannelReader(ChannelReader <TList> source, bool singleReader) : base(source, singleReader)
{
}
public Task UploadIgnoreItems(ChannelReader <string> source)
{
// Wait for an item to appear first then return from the hub method to end the invocation
return(source.WaitToReadAsync().AsTask());
}
/// <summary> /// Joins collections of the same type into a single channel reader in the order provided. /// </summary> /// <typeparam name="T">The result type.</typeparam> /// <param name="source">The source reader.</param> /// <param name="singleReader">True will cause the resultant reader to optimize for the assumption that no concurrent read operations will occur.</param> /// <returns>A channel reader containing the joined results.</returns> public static ChannelReader <T> Join <T>(this ChannelReader <IEnumerable <T> > source, bool singleReader = false) => new JoiningChannelReader <IEnumerable <T>, T>(source, singleReader);
public ChannelAsyncEnumerator(ChannelReader <T> channel, CancellationToken cancellationToken)
{
_channel = channel;
_cancellationToken = cancellationToken;
}
/// <summary>
/// Enumerates the events as they become available in the associated channel.
/// </summary>
///
/// <typeparam name="T">The type of data contained in the channel.</typeparam>
///
/// <param name="reader">The <see cref="ChannelReader{T}" /> instance that this method was invoked on, and from which events are to be sourced.</param>
/// <param name="maximumWaitTime">The maximum amount of time to wait to for an event to be available before emitting an empty item; if <c>null</c>, empty items will not be emitted.</param>
/// <param name="cancellationToken">The <see cref="System.Threading.CancellationToken"/> instance to signal the request to cancel enumeration.</param>
///
/// <returns>An asynchronous enumerator that can be used to iterate over events as they are available.</returns>
///
public static async IAsyncEnumerable <T> EnumerateChannel <T>(this ChannelReader <T> reader,
TimeSpan?maximumWaitTime,
[EnumeratorCancellation] CancellationToken cancellationToken)
{
Argument.AssertNotNull(reader, nameof(reader));
if (maximumWaitTime.HasValue)
{
Argument.AssertNotNegative(maximumWaitTime.Value, nameof(maximumWaitTime));
}
CancellationToken waitToken = cancellationToken;
var waitSource = default(CancellationTokenSource);
try
{
while (!cancellationToken.IsCancellationRequested)
{
if (reader.TryRead(out T result))
{
waitSource?.CancelAfter(Timeout.Infinite);
yield return(result);
}
else if (reader.Completion.IsCompleted)
{
// If the channel was marked as final, then await the completion task to surface any exceptions.
await reader.Completion.ConfigureAwait(false);
break;
}
else
{
try
{
if (maximumWaitTime.HasValue)
{
if ((waitSource == null) || (waitSource.IsCancellationRequested))
{
waitSource?.Dispose();
waitSource = CancellationTokenSource.CreateLinkedTokenSource(cancellationToken);
}
waitSource.CancelAfter(maximumWaitTime.Value);
waitToken = waitSource.Token;
}
// Wait for an item to be available in the channel; if it becomes so, then
// reset the loop so that it can be read and emitted.
if (await reader.WaitToReadAsync(waitToken).ConfigureAwait(false))
{
waitSource?.CancelAfter(Timeout.Infinite);
continue;
}
}
catch (OperationCanceledException)
{
// This is thrown when the wait token expires. It may be caused by the maximum wait time
// being exceeded or the main cancellation token being set. Ignore this as an expected
// case; if the iteration was canceled, it will be detected in the body of the loop and
// appropriate action taken.
waitSource?.Dispose();
waitSource = null;
}
// If the wait token was set, but the main cancellation token was not, then the wait time was
// exceeded and a default item needs to be emitted.
if ((waitToken.IsCancellationRequested) && (!cancellationToken.IsCancellationRequested))
{
yield return(default);
public Barber(ChannelReader<Customer> customers)
{
this.customers = customers;
}
/// <summary> /// Joins collections of the same type into a single channel reader in the order provided. /// </summary> /// <typeparam name="T">The result type.</typeparam> /// <param name="source">The source reader.</param> /// <param name="singleReader">True will cause the resultant reader to optimize for the assumption that no concurrent read operations will occur.</param> /// <returns>A channel reader containing the joined results.</returns> public static ChannelReader <T> Join <T>(this ChannelReader <T[]> source, bool singleReader = false) => new JoiningChannelReader <T[], T>(source, singleReader);
/// <summary> /// Joins collections of the same type into a single channel reader in the order provided. /// </summary> /// <typeparam name="T">The result type.</typeparam> /// <param name="source">The source reader.</param> /// <param name="singleReader">True will cause the resultant reader to optimize for the assumption that no concurrent read operations will occur.</param> /// <returns>A channel reader containing the joined results.</returns> public static ChannelReader <T> Join <T>(this ChannelReader <ICollection <T> > source, bool singleReader = false) => new JoiningChannelReader <ICollection <T>, T>(source, singleReader);
public static IAsyncEnumerable <T> AsAsyncEnumerable <T>(this ChannelReader <T> reader, CancellationToken cancellationToken = default) => reader.ReadAllAsync(cancellationToken);
