run-chaos-experiment
О программе
Этот навык позволяет разработчикам проектировать и проводить эксперименты по хаос-инжинирингу с использованием Litmus или Chaos Mesh. Он обеспечивает контролируемое внедрение сбоев для тестирования устойчивости системы, проверки гипотез и улучшения восстановления после отказов. Используйте его перед крупными запусками, после изменений в архитектуре или во время тренировок по отказоустойчивости для проактивного выявления слабых мест.
Быстрая установка
Claude Code
Рекомендуетсяnpx skills add pjt222/agent-almanac -a claude-code/plugin add https://github.com/pjt222/agent-almanacgit clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/run-chaos-experimentСкопируйте и вставьте эту команду в Claude Code для установки этого навыка
Документация
Run Chaos Experiment
Inject controlled failures. Test, improve resilience.
When Use
- Before major launches (load testing)
- After architecture changes (validate resilience)
- During GameDays or DR drills
- Validate assumptions about failure modes
- Part of SRE maturity program
Inputs
- Required: Kubernetes cluster (Litmus or Chaos Mesh)
- Required: Steady-state definition (what "normal" looks)
- Required: Hypothesis to test (e.g., "API stays up if one pod crashes")
- Optional: Observability stack (Prometheus, Grafana) to measure impact
- Optional: Rollback plan
Steps
Step 1: Define Steady State and Hypothesis
Document normal behavior.
## Steady State Definition
### Service: API Gateway
- **Availability**: 99.9% (< 0.1% error rate)
- **Latency**: p95 < 200ms
- **Throughput**: 1000 req/s
- **Dependencies**: Database (Postgres), Cache (Redis), Auth Service
### Metrics
- `rate(http_requests_total{job="api"}[5m])`
- `histogram_quantile(0.95, rate(http_request_duration_seconds_bucket[5m]))`
- `rate(http_requests_total{status=~"5.."}[5m])`
## Hypothesis
**"If one API pod is killed, the remaining pods will handle the load with <5s
disruption and no increase in error rate."**
### Validation Criteria
- Error rate remains <1%
- p95 latency stays <300ms (50ms grace)
- Service recovers within 5 seconds
- No cascading failures to downstream services
Got: Clear, measurable definition of normal + success criteria.
If fail: Cannot define steady state? Observability insufficient. Add metrics first.
Step 2: Set Blast Radius Limits
Scope experiment to minimize risk.
# chaos-config.yaml
apiVersion: v1
kind: Namespace
metadata:
name: chaos-testing
---
# Label pods participating in chaos experiments
apiVersion: v1
kind: Pod
metadata:
labels:
chaos-enabled: "true"
environment: staging # NEVER production for first run
Set safeguards.
## Blast Radius Controls
### Environment
- **Scope**: Staging only (first 5 runs)
- **Production**: Only after 5 successful staging runs
- **Timing**: Business hours (09:00-17:00 local), never weekends/holidays
### Target Selection
- **Limit**: Max 1 pod per service
- **Percentage**: Max 25% of replicas
- **Exclusions**: Database, payment service, auth service (critical path)
### Auto-Abort Conditions
- Error rate >10% for >30 seconds
- Customer-facing alerts fire
- Manual abort signal from on-call engineer
### Rollback Plan
- Kubernetes will auto-restart killed pods
- Manual rollback: `kubectl rollout undo deployment/api`
- Incident declared if recovery takes >5 minutes
Got: Experiment has clear bounds, will not take down whole system.
If fail: Blast radius too large? Narrow scope. Start with one non-critical service.
Step 3: Install Chaos Mesh
Deploy Chaos Mesh (Kubernetes-native).
# Add Chaos Mesh Helm repo
helm repo add chaos-mesh https://charts.chaos-mesh.org
helm repo update
# Install Chaos Mesh in isolated namespace
helm install chaos-mesh chaos-mesh/chaos-mesh \
--namespace chaos-mesh \
--create-namespace \
--set dashboard.create=true \
--set controllerManager.replicaCount=1
# Verify installation
kubectl get pods -n chaos-mesh
# Access dashboard
kubectl port-forward -n chaos-mesh svc/chaos-dashboard 2333:2333
# Open http://localhost:2333
Alt: Litmus (vendor-neutral).
# Install Litmus
kubectl apply -f https://litmuschaos.github.io/litmus/litmus-operator-v2.14.0.yaml
# Wait for Litmus pods
kubectl get pods -n litmus
# Install Litmus CRDs
kubectl apply -f https://hub.litmuschaos.io/api/chaos/master?file=charts/generic/experiments.yaml
Got: Chaos Mesh or Litmus running, dashboard accessible.
If fail: Check RBAC perms. Chaos tools need cluster-wide access.
Step 4: Create and Execute Experiment
Example: Pod Kill (Chaos Mesh).
# pod-kill-experiment.yaml
apiVersion: chaos-mesh.org/v1alpha1
kind: PodChaos
metadata:
name: api-pod-kill-test
namespace: chaos-testing
spec:
action: pod-kill
mode: one # Kill one pod only
selector:
namespaces:
- production
labelSelectors:
app: api-gateway
chaos-enabled: "true"
duration: "30s"
scheduler:
cron: "@every 5m" # Repeat every 5 minutes (for sustained testing)
Apply experiment.
# Apply experiment
kubectl apply -f pod-kill-experiment.yaml
# Watch experiment status
kubectl get podchaos -n chaos-testing -w
# View detailed status
kubectl describe podchaos api-pod-kill-test -n chaos-testing
# Check which pods were affected
kubectl get events -n production --sort-by=.metadata.creationTimestamp | grep api-gateway
Monitor impact in Grafana.
# Error rate during experiment
rate(http_requests_total{status=~"5..", job="api"}[1m])
# Latency spike
histogram_quantile(0.95, rate(http_request_duration_seconds_bucket{job="api"}[1m]))
# Pod restarts
rate(kube_pod_container_status_restarts_total{pod=~"api-.*"}[5m])
Got: Pod killed, Kubernetes restarts it, service continues with minor blip.
If fail: Error rate spikes or service degrades hard? Abort and investigate.
Step 5: Analyze Results and Iterate
Make experiment report.
# Chaos Experiment Report: API Pod Kill
**Date**: 2025-02-09
**Hypothesis**: API stays available if one pod crashes
**Tool**: Chaos Mesh
**Environment**: Staging
**Duration**: 30 seconds (pod kill + recovery)
## Results
### Metrics During Experiment
- **Error Rate**: Increased from 0.1% to 2.3% (spike lasted 8 seconds)
- **p95 Latency**: Increased from 180ms to 450ms (spike lasted 12 seconds)
- **Recovery Time**: 8 seconds (pod restart + load balancer update)
### Hypothesis Outcome
**FAILED**: Error rate exceeded 1% threshold, latency spike >300ms
## Root Cause Analysis
- Load balancer continued routing to killed pod for 8 seconds (stale endpoint)
- Readiness probe set to 10s interval (too slow)
- No pre-stop hook to drain connections gracefully
## Improvements Made
1. **Reduced readiness probe interval**: 10s → 2s
2. **Added pre-stop hook**: 5-second sleep for connection draining
3. **Tuned load balancer**: Enabled faster endpoint updates
## Follow-Up Experiment
- Re-run with same parameters in 1 week
- Expected: Error rate <1%, recovery <5s
Track experiments in log.
# chaos-experiment-log.csv
date,experiment,environment,status,error_rate_peak,recovery_time_s,outcome
2025-02-09,pod-kill-api,staging,complete,2.3%,8,failed
2025-02-16,pod-kill-api,staging,complete,0.8%,4,passed
2025-02-23,network-delay-db,staging,aborted,15%,N/A,failed
Got: Learnings captured, fixes done, follow-up scheduled.
If fail: No action taken post-experiment? Chaos = theater. Prioritize fixes.
Step 6: Graduate to Production (Carefully)
Once staging consistent.
# Production pod-kill experiment (more conservative)
apiVersion: chaos-mesh.org/v1alpha1
kind: PodChaos
metadata:
name: api-pod-kill-prod
namespace: chaos-testing
spec:
action: pod-kill
mode: one
selector:
namespaces:
- production
labelSelectors:
app: api-gateway
chaos-enabled: "true"
duration: "10s" # Shorter than staging
scheduler:
cron: "0 10 * * 2" # Tuesdays at 10 AM only (predictable, low-risk time)
Production safeguards.
# Create a kill switch for production chaos
kubectl create configmap chaos-killswitch \
-n chaos-testing \
--from-literal=enabled=true
# Update experiments to check kill switch
# (implementation depends on chaos tool)
Got: Prod experiments run during low-risk windows, kill switch ready.
If fail: Prod experiment causes incident? Disable immediately, post-mortem.
Checks
- Steady state, hypothesis clearly defined
- Blast radius limited (env, scope, timing)
- Chaos tool (Chaos Mesh or Litmus) installed, tested
- Experiment runs in staging
- Results documented with metrics + analysis
- Improvements done based on findings
- Follow-up validates fixes
- Prod experiments only after 5+ staging successes
Pitfalls
- No hypothesis: Run chaos "to see what happens" = waste. Always have hypothesis.
- Too broad scope: Kill all pods = tests DR not resilience. Start small.
- Production-first: Never first experiment in prod. Staging first, always.
- Ignore results: Chaos without action = theater. Fix what you learn.
- Alert fatigue: Chaos triggers alerts. Annotate Grafana or silence expected.
- No abort plan: If experiment goes wrong, need kill switch. Ready it.
See Also
setup-prometheus-monitoring- metrics to measure impactconfigure-alerting-rules- alerts that fire during chaos (expected)define-slo-sli-sla- steady state tied to SLOs
GitHub репозиторий
Frequently asked questions
What is the run-chaos-experiment skill?
run-chaos-experiment is a Claude Skill by pjt222. Skills package instructions and resources that Claude loads on demand, so Claude can perform run-chaos-experiment-related tasks without extra prompting.
How do I install run-chaos-experiment?
Use the install commands on this page: add run-chaos-experiment to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.
What category does run-chaos-experiment belong to?
run-chaos-experiment is in the Testing category, tagged ai, testing and design.
Is run-chaos-experiment free to use?
Yes. run-chaos-experiment is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.
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