A .NET client library for Zipkin.
Linux | Windows |
---|---|
It provides you with:
- Zipkin primitives (spans, annotations, binary annotations, ...)
- Asynchronous trace sending
- Trace transport abstraction
The easiest way to use the library is the following
var logger = CreateLogger(); //It should implement ILogger
var sender = CreateYourTransport(); // It should implement IZipkinSender
TraceManager.SamplingRate = 1.0f; //full tracing
var tracer = new ZipkinTracer(sender);
TraceManager.RegisterTracer(tracer);
TraceManager.Start(logger);
//Run your application
//On shutdown
TraceManager.Stop();
Your zipkin client is now ready!
To create a new trace, simply call
var trace = Trace.Create();
Then, you can record annotations
trace.Record(Annotations.ServerRecv());
trace.Record(Annotations.ServiceName(serviceName));
trace.Record(Annotations.Rpc("GET"));
trace.Record(Annotations.ServerSend());
trace.Record(Annotations.Tag("http.url", "<url>")); //adds binary annotation
The transport is responsible to send traces to a zipkin collector.
We provide you with an HTTP transport. Just create it with the zipkin collector url (i.e. if you test locally, you'll probably end up with something like 'http://localhost:9411') and pass it to the creation of the ZipkinTracer and you're set.
The implementation is really easy to do. All you have to do is to implement a Send(byte[]) method. For example, if you want to send traces through Kafka and assuming you have a kafka producer, you should write
class KafkaZipkinSender : IZipkinSender
{
private readonly IKafkaProducer _producer;
private const string Topic = "zipkin";
public KafkaZipkinSender(IKafkaProducer producer)
{
_producer = producer;
}
public void Send(byte[] data)
{
_producer.produce(Topic, data);
}
}
We internally use Kafka-sharp.
Zipkin is designed to handle complete spans. However, an incorrect usage of the library can lead to incomplete span creation. To create a complete span, you need a pair of matching annotations in the following list:
- ServerRecv and ServerSend annotations
- ClientSend and ClientRecv annotations
- LocalOperationStart and LocalOperationStop annotations
A span is sent asynchronously to the zipkin collector when one of the following annotation is recorded:
- ServerSend
- ClientRecv
- LocalOperationStop
with the matching opening annotation specified above (matching means same (traceId, spanId, parentSpanId)).
A flushing mechanism regurlarly checks for incomplete spans waiting in the memory to be sent.
The library comes with few handy tricks to help you monitor tracers
ZipkinTracer can be created with an implementation of IStatistics interface. This is useful if you want to send various metrics to graphite. We update four metrics:
Metric | Description |
---|---|
RecordProcessed | The number of annotation, binaryAnnotations, ... recorded by the tracer |
SpanSent | The number of span successfully sent |
SpanSentBytes | What went on the network |
SpanFlushed | The number of span flushed |
Since the library is meant to have almost no dependency, you'll have to write the implementation that sends these metrics to graphite for example.
When integrating this kind of library, it can be useful to know that we called it correctly.
ConsoleTracer writes every record it gets on the console (annotations, service names, ...).
- InMemoryTracer keeps every record in a queue. It is useful when a mock tracer is not enough.
- VoidTracer drops records. It is useful when you don't need tracing in tests.
Please also note that the default sampling is 0 meaning that by default, tracing is disabled. You should either set the sampling to 1.0 (to be deterministic) or force the trace to be sampled.
If your services communicate through HTTP, we provide you with headers injection and extraction (ZipkinHttpTraceInjector and ZipkinHttpTraceExtractor). It will allow you to add headers in HTTP requests between your services. The headers are zipkin standard headers but you can also implement yours with interfaces ITraceInjector and ITraceExtractor.
We implemented a safety mechanism in the library in order to avoid any memory footprint explosion. Spans can remain in memory if the user doesn't record the matching annotation to complete the span, leading to a memory leak. To avoid it, we added a safety that removes these spans after 60 seconds.
You can force a trace to bypass sampling. It is useful for tests but can also be useful if you want to trace specific requests depending on the context.
Trace.ForceSampled();
If you want to do that in production, we highly recommend too wrap your IZipkinSender implementation with the RateLimiterZipkinSender. It will throttle traces based on a time-window pattern.
Passing the trace context accross every API can be very cumbersome and doesn't bring any real added value. It's also a bit painful to implement a working solution if you have async code. That's why we implemented TraceContext which relies on .Net CallContext to carry traces over the execution path.
By setting
Trace.Current = myTrace;
You will be able to retrieve it, even if you have async code in between. It means that it will follow the sync/async path of your request. Since it can be a bit tricky, please use it with caution and if you know what you're doing.