This quickstart explores the observability capabilities of Dapr. Observability includes metric collection, tracing, logging and health checks. In this quickstart you'll be enabling distributed tracing on an application without changing any application code or creating a dependency on any specific tracing system. Since Dapr uses OpenCensus, a variety of observability tools can be used to view and capture the traces.
In this quickstart you will:
- Deploy Zipkin and configure it as a tracing provider for Dapr in self hosted mode and in Kubernetes.
- Configure an application for tracing and then deploy it.
- Troubleshoot a performance issue.
For self hosted mode, first run dapr init
. When you run dapr init
:
- The following YAML file is created by default in
$HOME/.dapr/config.yaml
(on Linux/Mac) or%USERPROFILE%\.dapr\config.yaml
(on Windows) and it is referenced by default ondapr run
calls unless otherwise overridden:
- config.yaml
apiVersion: dapr.io/v1alpha1
kind: Configuration
metadata:
name: daprConfig
namespace: default
spec:
tracing:
samplingRate: "1"
zipkin:
endpointAddress: "http://localhost:9411/api/v2/spans"
-
The openzipkin/zipkin docker container is launched.
-
The applications launched with
dapr run
will by default reference the config file in$HOME/.dapr/config.yaml
or%USERPROFILE%\.dapr\config.yaml
and can be overridden with the Dapr CLI using the--config
param. For example, the following command will launch the hello-world quickstart app using the default config.yaml: -
Clone this repo using
git clone [-b <dapr_version_tag>] https://github.com/dapr/quickstarts.git
and go to the repo's directory viacd quickstarts/tutorials/observability
.
cd ../hello-world/node && npm install && dapr run --app-id hello-tracing --app-port 3000 node app.js && cd ../../observability
- Once the app is running, you can make a request, which will populate at least one trace:
dapr invoke --app-id hello-tracing --method neworder --data-file sample.json
Tracing is set up out of the box when running dapr init
. To
view traces, in your browser go to http://localhost:9411 and you will
see the Zipkin UI.
Zipkin also has an API available. See Zipkin API for more details.
To see traces collected through the API:
curl -s "http://localhost:9411/api/v2/traces?spanName=calllocal%2Fhello-tracing%2Fneworder" -H "accept:application/json" -o output.json && python3 -m json.tool output.json
You should see output like the following:
[
[
{
"traceId": "4c480d57b0e6d96b7150b46d027c5904",
"id": "90d58917274e180a",
"kind": "CLIENT",
"name": "calllocal/hello-tracing/neworder",
"timestamp": 1613170216016911,
"duration": 93671,
"localEndpoint": {
"serviceName": "hello-tracing",
"ipv4": "127.0.0.1"
},
"tags": {
"dapr.api": "POST /v1.0/invoke/hello-tracing/method/neworder",
"dapr.protocol": "http",
"dapr.status_code": "200",
"net.peer.name": "hello-tracing",
"opencensus.status_description": "OK",
"rpc.service": "ServiceInvocation"
}
}
]
]
dapr stop --app-id hello-tracing
This quickstart builds on the distributed calculator quickstart and requires Dapr to be installed on a Kubernetes cluster along with a state store. It is suggested to go through the distributed calculator quickstart before this one. If you have not done this then:
- Clone this repo using
git clone [-b <dapr_version_tag>] https://github.com/dapr/quickstarts.git
and go to the directory viacd quickstarts/tutorials/obervability
. - Install Dapr on Kubernetes.
- Configure Redis as a state store for Dapr.
- Review the host and password for Redis state store Component in
../distributed-calculator/deploy/redis.yaml
.
Note: See https://github.com/dapr/quickstarts#supported-dapr-runtime-version for supported tags. Use
git clone https://github.com/dapr/quickstarts.git
when using the edge version of dapr runtime.
Review the Dapr configuration file ./deploy/appconfig.yaml
below:
apiVersion: dapr.io/v1alpha1
kind: Configuration
metadata:
name: appconfig
spec:
tracing:
samplingRate: "1"
zipkin:
endpointAddress: "http://zipkin.default.svc.cluster.local:9411/api/v2/spans"
samplingRate
is used to enable or disable the tracing. To disable the sampling rate , setsamplingRate : "0"
in the configuration. The valid range of samplingRate is between 0 and 1 inclusive. The sampling rate determines whether a trace span should be sampled or not based on value.samplingRate : "1"
will always sample the traces. By default, the sampling rate is 1 in 10,000.zipkin.endpointAddress
is used to specify the trace backend to receive trace using the Zipkin format. Any backend that understands the Zipkin trace format, like Zipkin, Jaeger, New Relic, etc can be used. In this sample, we use the address of the Zipkin server that we will deploy in the next step.
This configuration file enables Dapr tracing. Deploy the configuration by running:
kubectl apply -f ./deploy/appconfig.yaml
You can see that now a new Dapr configuration which enables tracing has been added. Run the command:
dapr configurations --kubernetes
You should see output that looks like this:
NAME TRACING-ENABLED METRICS-ENABLED AGE CREATED
appconfig true true 1h 2020-12-10 22:01.59
You can see that appconfig
has TRACING-ENABLED
set to true
.
In this quickstart Zipkin is used for tracing. Examine ./deploy/zipkin.yaml and see how it includes three sections:
- A Deployment for Zipkin using the openzipkin/zipkin docker image.
- A Service which will expose Zipkin internally as a ClusterIP in Kubernetes.
Deploy Zipkin to your cluster by running:
kubectl apply -f ./deploy/zipkin.yaml
Now that Zipkin is deployed, you can access the Zipkin UI by creating a tunnel to the internal Zipkin service you just created by running (with port 19411 chosen to avoid conflicts with Dapr CLI running Zipkin in self-hosted mode):
kubectl port-forward svc/zipkin 19411:9411
On your browser go to http://localhost:19411. You should be able to see the Zipkin dashboard.
To instrument a service for tracing with Dapr, no code changes are required, Dapr handles all of the tracing using the Dapr side-car. All that is needed is to add the Dapr annotation for the configuration you deployed earlier (which enables tracing) in the application deployment yaml along with the other Dapr annotations. The configuration annotation looks like this:
...
annotations:
...
dapr.io/config: "appconfig"
...
For this quickstart, a configuration has already been enabled for every service in the distributed calculator app. You can find the annotation in each one of the calculator yaml files. For example review the yaml file for the calculator front end service here.
Note you did not introduce any dependency on Zipkin into the calculator app code or deployment yaml files. The Zipkin Dapr component is configured to read tracing events and write these to a tracing backend.
Now deploy the distributed calculator application to your cluster:
kubectl apply -f ../distributed-calculator/deploy
Kubernetes deployments are asyncronous. This means you'll need to wait for the deployment to complete before moving on to the next steps. You can do so with the following commands:
kubectl rollout status deploy/addapp
kubectl rollout status deploy/subtractapp
kubectl rollout status deploy/divideapp
kubectl rollout status deploy/multiplyapp
kubectl rollout status deploy/calculator-front-end
You can view the status of the running pods with:
kubectl get pods
Then, open the distributed calculator UI.
If this is the first time trying the distributed calculator, find more detailed instructions in the distributed-calculator tutorial.
Note: If the distributed calculator is already running on your cluster you will need to restart it for the tracing to take effect. You can do so by running:
kubectl rollout restart deployment addapp calculator-front-end divideapp multiplyapp subtractapp
Optional: if you don't have easy public browser access, you can always use port forwarding
kubectl port-forward service/calculator-front-end 8000:80
To show how observability can help discover and troubleshoot issues on a distributed application, you'll update one of the services in the calculator app. This updated version simulates a performance degradation in the multiply operation of the calculator that you can then investigate using the traces emitted by the Dapr sidecar. Run the following to apply a new version of the python-multiplier service:
kubectl apply -f ./deploy/python-multiplier.yaml
As above, you can wait for the asyncronous Kubernetes deployment with the following:
kubectl rollout status deploy/multiplyapp
Now go to the calculator UI and perform several calculations. Make sure to use all operands. For example, do the following:
9 + 3 * 2 / 4 - 1 =
Optional: You can also use the following curl commands to execute all operations:
curl -s http://localhost:8000/calculate/add -H Content-Type:application/json --data @operands.json
curl -s http://localhost:8000/calculate/subtract -H Content-Type:application/json --data @operands.json
curl -s http://localhost:8000/calculate/divide -H Content-Type:application/json --data @operands.json
curl -s http://localhost:8000/calculate/multiply -H Content-Type:application/json --data @operands.json
curl -s http://localhost:8000/persist -H Content-Type:application/json --data @persist.json
curl -s http://localhost:8000/state
Now go to the Zipkin dashboard by running. (Note: if you are running Dapr locally, be sure to use a different local port for Zipkin):
kubectl port-forward svc/zipkin 19411:9411
And browsing to http://localhost:19411. Click the search button to view tracing coming from the application:
Dapr adds a HTTP/gRPC middleware to the Dapr sidecar. The middleware intercepts all Dapr and application traffic and automatically injects correlation IDs to trace events. You can see a lot of transactions are being captured including the regular health checks done by Kubernetes:
Now look for any performance issues by filtering on any requests that have take too long. You can use minDuration
criteria to query for long requests only:
You can quickly see that the multiply method invocation is unusually slow (takes over 1 second). Since the problem may be either at the calculator-frontend service or the python-multiplier service you can dig further by clicking on the entry:
Now you can see which specific call was delayed via the data
field (here it's the 12 * 2 operation) and confirm that it is the multiplier service which you updated that is causing the slowdown (You can find the code for the slow multiplier under the python directory).
As before, you can also access traces through the Zipkin API. The following will give you the same traces as the UI search above:
curl -s http://localhost:19411/api/v2/traces?minDuration=250000 -H accept:application/json -o output.json && python3 -m json.tool output.json
You should get output like this:
[
[
{
"duration": 1009084,
"id": "ff0bf110ca88f770",
"kind": "SERVER",
"localEndpoint": {
"ipv4": "10.244.4.225",
"serviceName": "multiplyapp"
},
"name": "calllocal/multiplyapp/multiply",
"parentId": "733a1812e839dcfb",
"tags": {
"dapr.api": "/dapr.proto.internals.v1.ServiceInvocation/CallLocal",
"dapr.invoke_method": "multiply",
"dapr.protocol": "grpc",
"rpc.service": "ServiceInvocation"
},
"timestamp": 1613177766316506,
"traceId": "926f1a5a6c63ae6f5167c29b3ddf4271"
},
...
- To remove the distributed calculator application from your cluster run:
kubectl delete -f ../distributed-calculator/deploy
- To remove the Zipkin installation and tracing configuration run:
kubectl delete -f deploy/zipkin.yaml
- Learn more about observability.
- Learn more on how Dapr does distributed tracing.
- Explore additional quickstarts
If you see an error with the following message:
time="2021-02-13T00:39:00.48769561Z" level=fatal msg="process component zipkin error: incorrect type exporters.zipkin" app_id=addapp instance=addapp-59f447d8b6-w48jt scope=dapr.runtime type=log ver=1.0.0-rc.4
It means there is an old exporter Component in your Kubernetes cluster. First, list Components:
kubectl get components
NAME AGE
zipkin 71d
statestore 43m
Then, identify which Component is the exporter (usually named zipkin
) and delete it:
kubectl delete component zipkin