Golang Observability
by @samber
Golang everyday observability — the always-on signals in production. Covers structured logging with slog, Prometheus metrics, OpenTelemetry distributed traci...
clawhub install golang-observability📖 About This Skill
name: golang-observability description: "Golang everyday observability — the always-on signals in production. Covers structured logging with slog, Prometheus metrics, OpenTelemetry distributed tracing, continuous profiling with pprof/Pyroscope, server-side RUM event tracking, alerting, and Grafana dashboards. Apply when instrumenting Go services for production monitoring, setting up metrics or alerting, adding OpenTelemetry tracing, correlating logs with traces, migrating legacy loggers (zap/logrus/zerolog) to slog, adding observability to new features, or implementing GDPR/CCPA-compliant tracking with Customer Data Platforms (CDP). Not for temporary deep-dive performance investigation (→ See golang-benchmark and golang-performance skills)." user-invocable: true license: MIT compatibility: Designed for Claude Code or similar AI coding agents, and for projects using Golang. metadata: author: samber version: "1.1.3" openclaw: emoji: "📡" homepage: https://github.com/samber/cc-skills-golang requires: bins: - go install: [] allowed-tools: Read Edit Write Glob Grep Bash(go:*) Bash(golangci-lint:*) Bash(git:*) Agent WebFetch WebSearch AskUserQuestion
Persona: You are a Go observability engineer. You treat every unobserved production system as a liability — instrument proactively, correlate signals to diagnose, and never consider a feature done until it is observable.
Modes:
> Community default. A company skill that explicitly supersedes samber/cc-skills-golang@golang-observability skill takes precedence.
Go Observability Best Practices
Observability is the ability to understand a system's internal state from its external outputs. In Go services, this means five complementary signals: logs, metrics, traces, profiles, and RUM. Each answers different questions, and together they give you full visibility into both system behavior and user experience.
When using observability libraries (Prometheus client, OpenTelemetry SDK, vendor integrations), refer to the library's official documentation and code examples for current API signatures.
Best Practices Summary
1. Use structured logging with log/slog — production services MUST emit structured logs (JSON), not freeform strings
2. Choose the right log level — Debug for development, Info for normal operations, Warn for degraded states, Error for failures requiring attention
3. Log with context — use slog.InfoContext(ctx, ...) to correlate logs with traces
4. Prefer Histogram over Summary for latency metrics — Histograms support server-side aggregation and percentile queries. Every HTTP endpoint MUST have latency and error rate metrics.
5. Keep label cardinality low in Prometheus — NEVER use unbounded values (user IDs, full URLs) as label values
6. Track percentiles (P50, P90, P99, P99.9) using Histograms + histogram_quantile() in PromQL
7. Set up OpenTelemetry tracing on new projects — configure the TracerProvider early, then add spans everywhere
8. Add spans to every meaningful operation — service methods, DB queries, external API calls, message queue operations
9. Propagate context everywhere — context is the vehicle that carries trace_id, span_id, and deadlines across service boundaries
10. Enable profiling via environment variables — toggle pprof and continuous profiling on/off without redeploying
11. Correlate signals — inject trace_id into logs, use exemplars to link metrics to traces
12. A feature is not done until it is observable — declare metrics, add proper logging, create spans
13. Use awesome-prometheus-alerts as a starting point for infrastructure and dependency alerting — browse by technology, copy rules, customize thresholds
Cross-References
See samber/cc-skills-golang@golang-error-handling skill for the single handling rule. See samber/cc-skills-golang@golang-troubleshooting skill for using observability signals to diagnose production issues. See samber/cc-skills-golang@golang-security skill for protecting pprof endpoints and avoiding PII in logs. See samber/cc-skills-golang@golang-context skill for propagating trace context across service boundaries. See samber/cc-skills@promql-cli skill for querying and exploring PromQL expressions against Prometheus from the CLI.
The Five Signals
| Signal | Question it answers | Tool | When to use |
| --- | --- | --- | --- |
| Logs | What happened? | log/slog | Discrete events, errors, audit trails |
| Metrics | How much / how fast? | Prometheus client | Aggregated measurements, alerting, SLOs |
| Traces | Where did time go? | OpenTelemetry | Request flow across services, latency breakdown |
| Profiles | Why is it slow / using memory? | pprof, Pyroscope | CPU hotspots, memory leaks, lock contention |
| RUM | How do users experience it? | PostHog, Segment | Product analytics, funnels, session replay |
Detailed Guides
Each signal has a dedicated guide with full code examples, configuration patterns, and cost analysis:
log/slog setup, log levels (Debug/Info/Warn/Error) and when to use each, request correlation with trace IDs, context propagation with slog.InfoContext, request-scoped attributes, the slog ecosystem (handlers, formatters, middleware), and migration strategies from zap/logrus/zerolog.histogram_quantile PromQL), naming conventions, the PromQL-as-comments convention (write queries above metric declarations for discoverability), production-grade PromQL examples, multi-window SLO burn rate alerting, and the high-cardinality label problem (why unbounded values like user IDs destroy performance).otelhttp middleware for HTTP instrumentation, error recording with span.RecordError(), trace sampling (why you can't collect everything at scale), propagating trace context across service boundaries, and cost optimization.irate instead of rate, missing for: duration to avoid flapping).Correlating Signals
Signals are most powerful when connected. A trace_id in your logs lets you jump from a log line to the full request trace. An exemplar on a metric links a latency spike to the exact trace that caused it.
Logs + Traces: otelslog bridge
import "go.opentelemetry.io/contrib/bridges/otelslog"// Create a logger that automatically injects trace_id and span_id
logger := otelslog.NewHandler("my-service")
slog.SetDefault(slog.New(logger))
// Now every slog call with context includes trace correlation
slog.InfoContext(ctx, "order created", "order_id", orderID)
// Output includes: {"trace_id":"abc123", "span_id":"def456", "msg":"order created", ...}
Metrics + Traces: Exemplars
// When recording a histogram observation, attach the trace_id as an exemplar
// so you can jump from a P99 spike directly to the offending trace
histogram.WithLabelValues("POST", "/orders").
Exemplar(prometheus.Labels{"trace_id": traceID}, duration)
Migrating Legacy Loggers
If the project currently uses zap, logrus, or zerolog, migrate to log/slog. It is the standard library logger since Go 1.21, has a stable API, and the ecosystem has consolidated around it. Continuing with third-party loggers means maintaining an extra dependency for no benefit.
Migration strategy:
1. Add slog as the new logger with slog.SetDefault()
2. Use bridge handlers during migration to route slog output through the existing logger: samber/slog-zap, samber/slog-logrus, samber/slog-zerolog
3. Gradually replace all zap.L().Info(...) / logrus.Info(...) / log.Info().Msg(...) calls with slog.Info(...)
4. Once fully migrated, remove the bridge handler and the old logger dependency
Definition of Done for Observability
A feature is not production-ready until it is observable. Before marking a feature as done, verify:
slog, context variants used (slog.InfoContext), no PII in logs, errors MUST be either logged OR returned (NEVER both).span.RecordError().user_id (not email), consent checked before tracking.Common Mistakes
// ✗ Bad — log AND return (error gets logged multiple times up the chain)
if err != nil {
slog.Error("query failed", "error", err)
return fmt.Errorf("query: %w", err)
}// ✓ Good — return with context, log once at the top level
if err != nil {
return fmt.Errorf("querying users: %w", err)
}
// ✗ Bad — high-cardinality label (unbounded user IDs)
httpRequests.WithLabelValues(r.Method, r.URL.Path, userID).Inc()// ✓ Good — bounded label values only
httpRequests.WithLabelValues(r.Method, routePattern).Inc()
// ✗ Bad — not passing context (breaks trace propagation)
result, err := db.Query("SELECT ...")// ✓ Good — context flows through, trace continues
result, err := db.QueryContext(ctx, "SELECT ...")
// ✗ Bad — using Summary for latency (can't aggregate across instances)
prometheus.NewSummary(prometheus.SummaryOpts{
Name: "http_request_duration_seconds",
Objectives: map[float64]float64{0.99: 0.001},
})// ✓ Good — use Histogram (aggregatable, supports histogram_quantile)
prometheus.NewHistogram(prometheus.HistogramOpts{
Name: "http_request_duration_seconds",
Buckets: prometheus.DefBuckets,
})