Service Mesh Fundamentals with Linkerd
Decoupling at Layer 5
layer5.io
cloud native and its management
Service Mesh Patterns
calcotestudios.com/talks
Our virtual lab assistant
Abishek Kumar
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Prereq
What is a Service Mesh?
a services-first network
Traffic Control
control over chaos
Resilency
content-based traffic steering
Observability
what gets people hooked on service metrics
Security
identity and policy
Service Mesh Functionality
Expect more from your infrastructure
Business Logic
in-network application logic
What is Linkerd?
an open platform to connect, manage, and secure microservices
-
Observability
-
Resiliency
-
Traffic Control
-
Security
-
Policy Enforcement
linkerd.io
@linkerd
Reviews v1
Reviews Pod
Reviews v2
Reviews v3
Product Pod
Details Container
Details Pod
Ratings Container
Ratings Pod
Product Container
Reviews Service
Ratings Service
Details Service
Product Service
BookInfo Sample App
BookInfo Sample App on Service Mesh
Reviews v1
Reviews Pod
Reviews v2
Reviews v3
Product Pod
Details Container
Details Pod
Ratings Container
Ratings Pod
Product Container
Proxy sidecar
Proxy sidecar
Proxy sidecar
Proxy sidecar
Proxy sidecar
Reviews Service
Proxy sidecar
Proxy ingress
Product Service
Ratings Service
Details Service
Observability
what gets people hooked on service metrics
Goals
-
Metrics without instrumenting apps
-
Consistent metrics across fleet
-
Trace flow of requests across services
-
Portable across metric back-end providers
You get a metric! You get a metric! Everyone gets a metric!
Traffic Control
control over chaos
- Traffic splitting
- L7 tag based routing?
- Traffic steering
- Look at the contents of a request and route it to a specific set of instances.
- Ingress and egress routing
Resilency
- Systematic fault injection
-
Timeouts and Retries with timeout budget
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Control connection pool size and request load
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Circuit breakers and Health checks
content-based traffic steering
Missing: application lifecycle management, but not by much
Missing: distributed debugging; provide nascent visibility (topology)
Confirm Prerequisites
-
Start Docker Desktop, Minikube or other.
(either single-node or multi-node clusters will work) -
Verify that you have a functional Docker environment by running :
$ docker run hello-world
Unable to find image 'hello-world:latest' locally
latest: Pulling from library/hello-world
1b930d010525: Pull complete
Digest: sha256:0e11c388b664df8a27a901dce21eb89f11d8292f7fca1b3e3c4321bf7897bffe
Status: Downloaded newer image for hello-world:latest
Hello from Docker!Docker and Kubernetes
Prereq
Prepare Docker Desktop
Ensure your Docker Desktop VM has 4GB of memory assigned.
Ensure Kubernetes is enabled.
Prereq
Deploy Kubernetes
- Confirm access to your Kubernetes cluster.
$ kubectl version --short
Client Version: v1.19.2
Server Version: v1.18.8$ kubectl get nodes
NAME STATUS ROLES AGE VERSION
docker-desktop Ready master 10m v1.18.8
Prereq
v1.9 or higher
meshery.io
Deploy Management Plane
Management
Plane
Provides expanded governance, backend system integration, multi-mesh, federation, expanded policy, and dynamic application and mesh configuration.
Control Plane
Data Plane
brew tap layer5io/tap
brew install mesheryctl
mesheryctl system startInstall Meshery
Prereq
Using brew
Using bash
curl -L https://git.io/meshery | sudo bash - kubectl config view --minify --flatten > config_minikube.yamlUsing minikube:
Relating to
Service Meshes
Which is why...
I have a container orchestrator.
Core
Capabilities
-
Cluster Management
-
Host Discovery
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Host Health Monitoring
-
-
Scheduling
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Orchestrator Updates and Host Maintenance
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Service Discovery
-
Networking and Load Balancing
-
Stateful Services
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Multi-Tenant, Multi-Region
Additional
Key Capabilities
-
Application Health and Performance Monitoring
-
Application Deployments
-
Application Secrets
minimal capabilities required to qualify as a container orchestrator
Service meshes generally rely on these underlying layers.
Which is why...
I have an API gateway.
Microservices API Gateways
-
Ambassador uses Envoy
-
Kong uses Nginx
-
OpenResty uses Nginx
north-south vs. east-west
Which is why...
I have client-side libraries.
Enforcing consistency is challenging.
Foo Container
Flow Control
Foo Pod
Go Library
A v1
Network Stack
Service Discovery
Circuit Breaking
Application / Business Logic
Bar Container
Flow Control
Bar Pod
Go Library
A v2
Network Stack
Service Discovery
Circuit Breaking
Application / Business Logic
Baz Container
Flow Control
Baz Pod
Java Library
B v1
Network Stack
Service Discovery
Circuit Breaking
Application / Business Logic
Retry Budgets
Rate Limiting
Help with Modernization
-
Can modernize your IT inventory without:
-
Rewriting your applications
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Adopting microservices, regular services are fine
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Adopting new frameworks
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Moving to the cloud
-
address the long-tail of IT services
Get there for free
Why use a Service Mesh?
-
Bloated service (application) code
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Duplicating work to make services production-ready
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Load balancing, auto scaling, rate limiting, traffic routing...
-
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Inconsistency across services
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Retry, tls, failover, deadlines, cancellation, etc., for each language, framework
-
Siloed implementations lead to fragmented, non-uniform policy application and difficult debugging
-
-
Diffusing responsibility of service management
to avoid...
DEVELOPER
OPERATOR
Decoupling at Layer 5
where Dev, Ops, Product meet
Empowered and independent teams can iterate faster
PRODUCT OWNER
DEVELOPER
OPERATOR
Decoupling at Layer 5
where Dev, Ops, Product meet
Empowered and independent teams can iterate faster
PRODUCT OWNER
Q&A
Service Mesh Architectures
Data Plane
Touches every packet/request in the system.
Responsible for service discovery, health checking, routing, load balancing, authentication, authorization, and observability.
Ingress Gateway
Egress Gateway
Service Mesh Architecture
No control plane? Not a service mesh.
Control Plane
Provides policy, configuration, and platform integration.
Takes a set of isolated stateless sidecar proxies and turns them into a service mesh.
Does not touch any packets/requests in the data path.
Data Plane
Touches every packet/request in the system.
Responsible for service discovery, health checking, routing, load balancing, authentication, authorization, and observability.
Ingress Gateway
Egress Gateway
Service Mesh Architecture
Control Plane
Data Plane
-
Touches every packet/request in the system.
-
Responsible for service discovery, health checking, routing, load balancing, authentication, authorization, and observability.
-
Provides policy, configuration, and platform integration.
-
Takes a set of isolated stateless sidecar proxies and turns them into a service mesh.
-
Does not touch any packets/requests in the data path.
You need a management plane.
Ingress Gateway
Management
Plane
-
Provides backend system integration, expanded policy and governance, continuous delivery integration, workflow, chaos engineering, configuration and performance management and multi-mesh federation.
Egress Gateway
Service Mesh Architecture
Pilot
Citadel
Mixer
Control Plane
Data Plane
istio-system namespace
policy check
Foo Pod
Proxy Sidecar
Service Foo
tls certs
discovery & config
Foo Container
Bar Pod
Proxy Sidecar
Service Bar
Bar Container
Out-of-band telemetry propagation
telemetry
reports
Control flow
application traffic
Application traffic
application namespace
telemetry reports
Istio Architecture
Galley
Ingress Gateway
Egress Gateway
Control Plane
Data Plane
octa-system namespace
policy check
Foo Pod
Proxy
Sidecar
Service Foo
discovery & config
Foo Container
Bar Pod
Service Bar
Bar Container
Out-of-band telemetry propagation
telemetry
reports
Control flow
application traffic
Application traffic
application namespace
telemetry reports
Policy
Engine
Security Engine
Visibility
Engine
+
Proxy
Sidecar
+
Octarine Architecture
Leader
Agent
Control Plane
Data Plane
intentions
Foo Pod
Proxy Sidecar
Service Foo
discovery, config,
tls certs
Foo Container
Bar Pod
Proxy Sidecar
Service Bar
Bar Container
Control flow
application traffic
Application traffic
application namespace
Follower
Consul Client
Consul Servers
Follower
policy
check
Consul Architecture
layer5.io/service-mesh-architectures
WASM Filter
node
Our service mesh of study: Linkerd
Deploy Linkerd
- Install Linkerd using Meshery
- Find control plane namespace
- Inspect control plane services
- Inspect control plane components
open http://localhost:9081kubectl get namespaceskubectl get svc -n linkerdkubectl get pod -n linkerdLab 1
github.com/layer5io/linkerd-service-mesh-workshop
Control Plane
Data Plane
linkerd namespace
Foo Pod
Proxy Sidecar
Service Foo
Foo Container
Bar Pod
Proxy Sidecar
Service Bar
Bar Container
Out-of-band telemetry propagation
telemetry
scarping
Control flow during request processing
application traffic
Application traffic
application namespace
telemetry scraping
Architecture
Prometheus
Grafana
web
CLI
public-api
Linkerd
linkerd-controller
sp-validator
Control Plane
destination
tap
web
CLI
proxy-injector
identity
Service Proxy Sidecar
- A Rust-based L4/L7 proxy
- Low memory footprint
- Designed for service mesh use cases
Capabilities:
-
Transparent, zero-config proxying for HTTP, HTTP/2, and arbitrary TCP protocols.
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Automatic Prometheus metrics export for HTTP and TCP traffic.
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Transparent, zero-config WebSocket proxying.
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Automatic, latency-aware, layer-7 load balancing.
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Automatic layer-4 load balancing for non-HTTP traffic.
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Automatic TLS.
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An on-demand diagnostic tap API.
The proxy supports service discovery via DNS and the destination gRPC API.
the included, non-swappable battery
Data Plane
Pod
Proxy sidecar
App Container
the workhorse
What's Identify for?
-
Verifiable identity
- Issues certs
- Certs distributed to service proxies
- Mounted as a Kubernetes secret
- Secure naming / addressing
- Traffic encryption
security at scale
security by default
Orchestrate Key & Certificate:
- Generation
- Deployment
- Rotation
- Revocation
linkerd namespace
Prometheus
Grafana
web
CLI
public-api
linkerd-controller
sp-validator
destination
tap
web
CLI
proxy-injector
identity
Q&A
Break
Deploy Sample App
- Multi-language, multi-service application
-
Automatic vs manual sidecar injection
- Verify install
Use Meshery or install manually
Lab 2
emoji Pod
web Pod
web
Container
emoji-svc Service
web Service
Emojivoto Sample App
emoji
Container
voting Pod
voting-svc Service
voting
Container
emoji Pod
web Pod
web
Container
emoji-svc Service
web Service
Emojivoto Sample App on the Service Mesh
emoji
Container
voting Pod
voting-svc Service
voting
Container
Linkerd sidecar
Linkerd sidecar
Linkerd sidecar
Sidecar Injection
Automatic sidecar injection leverages Kubernetes' Mutating Webhook Admission Controller.
- Verify whether your Kubernetes deployment supports these APIs by executing:
- Inspect the linkerd-proxy-injector-webhook-config webhook:
Lab 2
github.com/layer5io/linkerd-service-mesh-workshop
kubectl get mutatingwebhookconfigurations
kubectl get mutatingwebhookconfigurations linkerd-proxy-injector-webhook-config -o yamlkubectl api-versions | grep admissionregistrationSidecars proxy can be either manually or automatically injected into your pods.
Deploy Sample App with Automatic Sidecar Injection
- Verify presence of the sidecar injector
kubectl get deployment linkerd-proxy-injector -n linkerdLab 2
github.com/layer5io/linkerd-service-mesh-workshop
2. Confirm namespace annotation
kubectl describe namespace linkerdsidecar proxy
Deploy Sample App with Manual Sidecar Injection
In namespaces without the linkerd.io/inject annotation, you can use linkerd inject to manually inject Linkerd proxies into your application pods before deploying them:
kubectl kustomize kustomize/deployment | \
linkerd inject - | \
kubectl apply -f -Lab 2
github.com/layer5io/linkerd-service-mesh-workshop
sidecar proxy
Expose Emojivoto via NGINX Ingress Controller
Inspect the Linkerd proxy of the web pod
NGINX Ingress
application traffic
Lab 3
github.com/layer5io/linkerd-service-mesh-workshop
apiVersion: extensions/v1beta1
kind: Ingress
metadata:
name: web-ingress
namespace: emojivoto
annotations:
kubernetes.io/ingress.class: "nginx"
nginx.ingress.kubernetes.io/configuration-snippet: |
proxy_set_header l5d-dst-override $service_name.$namespace.svc.cluster.local:$service_port;
grpc_set_header l5d-dst-override $service_name.$namespace.svc.cluster.local:$service_port;
spec:
rules:
- host: example.com
http:
paths:
- backend:
serviceName: web-svc
servicePort: 80- Deploy the NGINX Ingress Controller
2. Configure NGINX Ingress for Emojivoto
Q&A
Break
layer5.io/landscape
It's meshy out there.
Strengths of Service Mesh Implementations
Different tools for different use cases
a sample
Service mesh abstractions
Meshery is interoperable with these abstractions.
Service Mesh Interface
(SMI)
Multi-Vendor Service Mesh Interoperation (Hamlet)
Service Mesh Performance (SMP)
A standard interface for service meshes on Kubernetes.
A set of API standards for enabling service mesh federation.
A format for describing and capturing service mesh performance.
to the rescue
-
benchmarking of service mesh performance
-
exchange of performance information from system-to-system / mesh-to-mesh
-
apples-to-apples performance comparisons of service mesh deployments.
-
MeshMark - a universal performance index to gauge a service mesh’s efficiency against deployments in other organizations’ environments
Service Mesh Performance
https://smp-spec.io
Directly provides:
Indirectly facilitates:
- a vendor neutral specification for capturing details of infrastructure capacity, service mesh configuration, and workload metadata.
Service Mesh Interface
Four API specifications
Service Mesh Interface aims to provide:
• Standard interface for service mesh on Kubernetes
• Basic feature set for most common mesh use cases
• Extensible to support new features
• Space for the ecosystem to innovate
Traffic Split
Traffic Specs
Traffic Metrics
Traffic Access Control
APIs:
Service Mesh Interface (SMI) Conformance
Operate and upgrade with confirmation of SMI compatibility
✔︎ Learn Layer5 sample application used for validating test assertions.
✔︎ Defines compliant behavior.
✔︎ Produces compatibility matrix.
✔︎ Ensures provenance of results.
✔︎ Runs a set of conformance tests.
✔︎ Built into participating service mesh’s release pipeline.
Telemetry
Service Mesh Interface (SMI)
Service Mesh Performance (SMP)
Configuration
Security
Telemetry
Control Plane
Data
Plane
service mesh ns
Foo Pod
Proxy Sidecar
Service Foo
Foo Container
Bar Pod
Proxy Sidecar
Service Bar
Bar Container
Out-of-band telemetry propagation
Control flow
application
traffic
Application traffic
application namespace
Meshery Architecture
Ingress Gateway
Egress Gateway
Management
Plane
meshery
adapters
gRPC
kube-api
kube-system
generated load
http / gRPC traffic
fortio
wrk2
nighthawk
UI
API
workloads
Meshery WASM Filter
CLI
perf analysis
patterns
@mesheryio
Metrics Dashboard
Lab 4
- Expose Grafana with `linkerd`
linkerd dashboard &Grafana
github.com/layer5io/linkerd-service-mesh-workshop
Lab 6
Distributed Tracing
Jaeger
github.com/layer5io/linkerd-service-mesh-workshop
Distributed Tracing
Jaeger
The istio-proxy collects and propagates the following headers from the incoming request to any outgoing requests:
- x-request-id
- x-b3-traceid
- x-b3-spanid
- x-b3-parentspanid
- x-b3-sampled
- x-b3-flags
- x-ot-span-context
Lab 6
cat >> config.yaml << EOF
tracing:
enabled: true
EOFgithub.com/layer5io/linkerd-service-mesh-workshop
linkerd upgrade --config config.yaml | kubectl apply -f -Q&A
Lee Calcote
cloud native and its management
layer5.io/subscribe
