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shankar0123 3a665ae6ba loadtest: add k6 harness for certctl API throughput

Closes the #8 acquisition-readiness blocker from the 2026-05-01 issuer
coverage audit. Pre-fix, certctl had zero benchmarks or load tests for
any API path. An acquirer evaluating "can certctl handle our 50k-cert
fleet at 47-day rotation" had nothing to point at; CA/B Forum SC-081v3
lands 47-day TLS in 2029, and operators need real numbers, not hand-
waved capacity claims.

What landed:

- deploy/test/loadtest/docker-compose.yml — minimal stack (postgres +
  tls-init bootstrap + certctl-server with CERTCTL_DEMO_SEED=true so
  the FK rows the script needs exist + grafana/k6:0.54.0 driver).
  Pinned k6 version so threshold expressions stay stable across runs.
  k6 command runs the script once and exits with the threshold-driven
  exit code so `--exit-code-from k6` propagates non-zero on any
  regression.

- deploy/test/loadtest/k6.js — two scenarios at 50 req/s × 5 min,
  staggered 5s. Scenario 1: POST /api/v1/certificates (issuance-
  acceptance hot path: auth + JSON decode + validation + service
  CreateCertificate + DB insert). Scenario 2: GET /api/v1/certificates
  (most-trafficked read endpoint, exercises pagination). Hard
  thresholds: p99 < 5s + p95 < 2s for issuance-acceptance, p99 < 2s +
  p95 < 800ms for list, error rate < 1% globally. constant-arrival-
  rate executor (NOT constant-vus) so VU-bound load doesn't backpressure
  the offered rate and mask capacity ceilings. __ENV.CERTCTL_BASE
  lets the same script run on the operator's workstation
  (https://localhost:8443) and inside the compose stack
  (https://certctl-server:8443).

- deploy/test/loadtest/README.md — documents what's measured (API
  tier: auth → DB) vs what's NOT (issuer connector latency: pinned
  separately by certctl_issuance_duration_seconds from audit fix #4;
  full ACME enrollment flow: deferred — sustained 100/s through
  multi-RTT pebble takes pebble tuning + crypto helpers k6 doesn't
  ship with). Threshold contract pinned. Baseline numbers row reads
  TBD until the operator captures on a representative workstation;
  methodology pinned so future tuning commits land alongside refreshed
  baselines that are diffable.

- deploy/test/loadtest/.gitignore — results/{summary.json,summary.txt}
  + certs/ (per-run TLS bootstrap output). Both regenerate on every
  run; committing them would create huge per-run diffs.

- deploy/test/loadtest/results/.gitkeep — placeholder so the
  directory exists in fresh checkouts (the k6 container mounts it).

- Makefile: new `loadtest` target spinning up the compose stack with
  --abort-on-container-exit --exit-code-from k6 and printing the
  summary. Added to .PHONY + help. Explicitly NOT in `make verify` —
  load tests are minutes long and don't gate per-PR signal.

- .github/workflows/loadtest.yml — workflow_dispatch (manual) +
  weekly cron at Mon 06:00 UTC. NOT per-push. 15-minute hard cap.
  Always uploads results/ as an artifact (90d retention) so a
  regression has a diffable artifact even when k6 exited non-zero.
  Read-only repo permissions.

- docs/architecture.md: new "Performance Characteristics" section
  citing the harness location, scenarios, thresholds, scope (what's
  measured vs not), and where the captured baseline lives. Inserted
  before the existing "What's Next" section.

Scope decisions documented in the README + this commit message:

- The audit prompt's k6 example targeted POST /api/v1/certificates +
  ACME-via-pebble. CreateCertificate exercises auth + DB but the
  downstream issuer-connector call is async (renewal scheduler);
  that's the right surface for "request-acceptance" throughput.
  Driving the connectors directly would load-test someone else's
  API.
- Pebble was excluded from the harness stack. Sustained 100/s
  through ACME's order/challenge/finalize flow needs pebble tuning
  + k6 crypto helpers that don't exist out of the box. README flags
  this as a deferred follow-up.

Acquirer impact: the diligence question "what's your throughput?"
now has a number with a reproducible methodology and a regression
guard, not a claim. The first operator run captures the baseline
into README.md so subsequent tuning commits are diffable.

Verified locally:
- gofmt -l . clean
- go vet ./... clean
- staticcheck ./... clean
- go build ./... clean
- bash scripts/ci-guards/H-1-encryption-key-min-length.sh — clean
  (the 38-byte loadtest key is above the 32-byte floor)
- bash scripts/ci-guards/openapi-handler-parity.sh — clean
- bash scripts/ci-guards/test-compose-scep-coherence.sh — clean
- make -n loadtest produces the expected command sequence
- The first `make loadtest` run from the operator's workstation
  populates the README baseline numbers (committed in a follow-up).

Audit reference: cowork/issuer-coverage-audit-2026-05-01/RESULTS.md
Top-10 fix #8.

2026-05-02 14:00:10 +00:00

results

loadtest: add k6 harness for certctl API throughput

2026-05-02 14:00:10 +00:00

.gitignore

loadtest: add k6 harness for certctl API throughput

2026-05-02 14:00:10 +00:00

docker-compose.yml

loadtest: add k6 harness for certctl API throughput

2026-05-02 14:00:10 +00:00

k6.js

loadtest: add k6 harness for certctl API throughput

2026-05-02 14:00:10 +00:00

README.md

loadtest: add k6 harness for certctl API throughput

2026-05-02 14:00:10 +00:00

README.md

certctl Load-Test Harness

Closes the #8 acquisition-readiness blocker from the 2026-05-01 issuer coverage audit (cowork/issuer-coverage-audit-2026-05-01/RESULTS.md). Pre-fix, certctl had zero benchmarks or load tests for any API path; an acquirer evaluating "can certctl handle our 50k-cert fleet at 47-day rotation" had nothing to point at. This harness is the substantiation.

What it measures

A k6 driver hits two scenarios in parallel for 5 minutes at a fixed 50 req/s:

POST /api/v1/certificates — the issuance-acceptance hot path. Exercises auth, JSON decode, validation, service.CreateCertificate, and the managed_certificates insert. This is the operator-facing request-acceptance throughput an automation client (Terraform, Crossplane, GitOps controller) would generate.
GET /api/v1/certificates?per_page=50 — the most-trafficked read endpoint. Exercises pagination + filtering on the cert list query.

Latency is reported as avg / min / med / p95 / p99 / max. The error floor is < 1% (any 4xx/5xx counts as failed).

What it explicitly does NOT measure

Issuer connector latency. Connector calls (DigiCert, ACME, Vault, AWS ACM PCA, etc.) happen asynchronously via the renewal scheduler. Their latency is pinned by the certctl_issuance_duration_seconds{issuer_type=...} Prometheus histogram (audit fix #4). Driving them through k6 would load-test someone else's API, which is wrong.
Full ACME enrollment flow. The audit prompt mentioned ACME-via- pebble; sustained 100/s through a multi-RTT order/challenge/finalize flow requires pebble tuning + crypto helpers k6 doesn't ship out of the box. Deferred to a follow-up.
Bulk-revoke / bulk-renew. Those are admin endpoints with their own throughput characteristics and warrant a separate scenario.
Scheduler concurrency under bulk renewal. That's audit fix #9's scope; the harness here measures the API tier, not the scheduler.

Threshold contract

Any future change that breaches one of these fails the test:

Scenario	p95	p99	Error rate
`issuance_acceptance`	< 2 s	< 5 s	n/a
`list_certificates`	< 800 ms	< 2 s	n/a
All requests	n/a	n/a	< 1%

These are the regression guards, not the SLO. The SLO is whatever the operator chooses based on the baseline below.

How to run

From the repo root:

make loadtest

This:

Builds the certctl image from the repo root Dockerfile.
Spins up postgres, the tls-init bootstrap, certctl-server (with CERTCTL_DEMO_SEED=true so the FK rows the script needs exist), and the k6 driver.
Runs the k6 script for ~5 minutes 5 seconds (5s stagger between scenarios + 5m duration).
Prints the summary text to stdout.
Exits non-zero if any threshold was breached.

The full machine-readable summary lands at deploy/test/loadtest/results/summary.json (gitignored). The human-readable summary lands at results/summary.txt.

To run against a server already booted on the host (skip the compose spin-up):

docker run --rm \
  -e CERTCTL_BASE=https://localhost:8443 \
  -e CERTCTL_TOKEN=load-test-token \
  -e K6_INSECURE_SKIP_TLS_VERIFY=true \
  -v "$(pwd)/deploy/test/loadtest/k6.js:/scripts/k6.js:ro" \
  -v "$(pwd)/deploy/test/loadtest/results:/results" \
  --network host \
  grafana/k6:0.54.0 run /scripts/k6.js

Current baseline

The first operator run captures real numbers and commits them into this section. Pre-baseline this section reads "TBD — operator captures on first make loadtest run." The numbers below are the agreed minimum-acceptable thresholds, not the captured baseline; once captured, the baseline goes here as a separate row so future regressions have a diff target.

Scenario	p50	p95	p99	Error rate
issuance_acceptance (threshold)	—	< 2 s	< 5 s	< 1%
issuance_acceptance (baseline)	TBD	TBD	TBD	TBD
list_certificates (threshold)	—	< 800 ms	< 2 s	< 1%
list_certificates (baseline)	TBD	TBD	TBD	TBD

Methodology pinned at baseline capture:

Hardware: TBD (operator's workstation specs at capture time).
Postgres: 16-alpine, default config.
certctl: image built from this repo at the commit referenced below.
Concurrency: 50 req/s sustained per scenario (100 req/s total).
Duration: 5 minutes per scenario, 5s stagger.
Auth: api-key (Bearer token, single key).
Encryption: CERTCTL_CONFIG_ENCRYPTION_KEY set (32+ bytes).

To recapture the baseline after a tuning commit:

make loadtest
# Inspect deploy/test/loadtest/results/summary.txt for the new numbers.
# Update the table above + the methodology line, commit alongside the
# tuning commit.

Interpreting a regression

If a future PR's make loadtest run pushes p99 above the threshold, the make target exits non-zero and CI fails. The summary.txt prints which threshold breached. Triage:

Look at the per-scenario http_req_duration p95 + p99 in summary.json. If only one scenario regressed, the change is localized to that endpoint's hot path.
Look at the iteration_duration per scenario — if total iteration time grew but http_req_duration is flat, the latency is in k6 client setup (rare; suggests something changed in the script).
Compare against the committed baseline. If p99 was 800 ms at baseline and is now 1.5 s but still under the 5 s threshold, the change is below the regression guard but still meaningful — flag in the PR description.

The harness deliberately does NOT auto-tune. Tuning is informed by the data; tuning commits land separately, each with their own captured baseline update.

CI cadence

Defined in .github/workflows/loadtest.yml:

workflow_dispatch — manual trigger from the Actions tab. Used before tagging a release or after a meaningful tuning commit.
Weekly cron — Mondays at 06:00 UTC. Catches gradual regressions from cumulative changes that no single PR triggered.

The workflow does not run per-push. Load tests are minutes long and would not provide useful per-PR signal; per-push pressure goes through make verify (which is fast) and the deploy-vendor-e2e job.

Files in this directory

deploy/test/loadtest/
├── README.md         (this file)
├── docker-compose.yml
├── k6.js             (the load script)
├── certs/            (gitignored — tls-init writes here)
└── results/          (gitignored — k6 writes summary.{json,txt} here)

Audit reference

cowork/issuer-coverage-audit-2026-05-01/RESULTS.md Top-10 fix #8.