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certctl/docs/legacy-est-scep.md
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certctl-copilot 35fcfa70f2 feat(scep): RenewalReq + GetCertInitial + ChromeOS E2E + caps + must-staple 
SCEP RFC 8894 + Intune master bundle — Phase 4 + Phase 5 of 14.

Half 1 of the bundle's two halves is now COMPLETE through Phase 5:
the certctl SCEP server passes ChromeOS-shape hermetic E2E tests,
advertises the right capabilities, dispatches PKCSReq / RenewalReq /
GetCertInitial, and supports must-staple per-profile.

== Phase 4: RenewalReq + GetCertInitial wiring ============================

internal/service/scep.go
  * RenewalReqWithEnvelope (RFC 8894 §3.3.1.2) — re-enrollment with an
    existing valid cert. Same contract as PKCSReqWithEnvelope but the
    service additionally verifies that envelope.SignerCert chains to
    the issuer's CA (verifyRenewalSignerCertChain). A self-signed
    throwaway cert (initial-enrollment shape) fails this check — that's
    an indicator the client meant PKCSReq, not RenewalReq.
  * GetCertInitialWithEnvelope (RFC 8894 §3.3.3) — polling stub.
    Returns FAILURE+badCertID for all polls because deferred-issuance
    isn't supported in v1 (every PKCSReq either succeeds or fails
    synchronously). Wiring stays in place for a future enhancement.
  * Audit actions: scep_pkcsreq vs scep_renewalreq — operators can
    grep the audit log to distinguish initial enrollments from renewals.

internal/api/handler/scep.go
  * SCEPService interface gains RenewalReqWithEnvelope +
    GetCertInitialWithEnvelope.
  * pkiOperation RFC 8894 path now switches on envelope.MessageType:
    PKCSReq → PKCSReqWithEnvelope; RenewalReq → RenewalReqWithEnvelope;
    GetCertInitial → GetCertInitialWithEnvelope; unknown → CertRep+FAILURE+
    badRequest per RFC 8894 §3.3.2.2.

== Phase 5.1: GetCACaps capability advertisement =========================

internal/service/scep.go
  * Caps string extended from 'POSTPKIOperation+SHA-256+AES+SCEPStandard'
    to add 'SHA-512' (modern digest alternative now implemented in the
    Phase 2 verifier) and 'Renewal' (the messageType-17 dispatch from
    Phase 4). ChromeOS specifically looks for these capabilities to
    negotiate the strongest available cipher + digest combo.
  * scep_test.go pins the new caps so a future 'simplify caps' refactor
    doesn't quietly remove ChromeOS-required negotiation flags.

== Phase 5.2: ChromeOS-shape integration tests ===========================

internal/api/handler/scep_chromeos_test.go (new, ~570 LoC)
  * 6 hermetic E2E tests + ~12 helpers. Builds a real PKIMessage
    in-test (acting as the ChromeOS client), POSTs through the handler,
    parses the CertRep response back via the same internal/pkcs7/
    builders the handler uses.
  * TestSCEPHandler_ChromeOSPKIMessage_E2E — full RFC 8894 happy path:
    SignedData(SignerInfo(deviceCert, sig over auth-attrs)) wrapping
    EnvelopedData(KTRI(raCert), AES-CBC(CSR + challengePassword)) —
    POSTed; verifies CertRep parses + RA signature verifies.
  * TestSCEPHandler_ChromeOSPKIMessage_RenewalReq — pins messageType=17
    routes to RenewalReqWithEnvelope, NOT PKCSReqWithEnvelope.
  * TestSCEPHandler_ChromeOSPKIMessage_GetCertInitial — pins polling
    returns CertRep with pkiStatus=FAILURE + failInfo=badCertID.
  * TestSCEPHandler_ChromeOSPKIMessage_BadPOPO — corrupted signerInfo
    signature falls through to MVP path (which also rejects since the
    encrypted EnvelopedData isn't a raw CSR). No silent acceptance.
  * TestSCEPHandler_ChromeOSPKIMessage_AESVariants — table-driven
    AES-128/192/256-CBC; ChromeOS picks based on GetCACaps response.
  * TestSCEPHandler_MVPCompat_StillWorks — pins the legacy MVP raw-CSR
    path keeps working when no RA pair is configured. Backward compat
    is non-negotiable.

== Phase 5.6: must-staple per-profile policy field (RFC 7633) ============

internal/domain/profile.go
  * Added MustStaple bool to CertificateProfile. Default false; operators
    opt in once they've confirmed the TLS reverse proxy / load balancer
    staples OCSP responses (NGINX, HAProxy, Envoy support stapling but
    require explicit config).

internal/connector/issuer/interface.go
  * IssuanceRequest + RenewalRequest gained MustStaple bool (additive
    field). Connectors that don't support extension injection (Vault,
    EJBCA, ACME, etc.) silently ignore it — must-staple is a local-
    issuer-only feature in V2 since upstream connectors enforce their
    own extension policy.

internal/connector/issuer/local/local.go
  * Added oidMustStaple (1.3.6.1.5.5.7.1.24, id-pe-tlsfeature) +
    pre-encoded mustStapleExtensionValue (0x30 0x03 0x02 0x01 0x05 —
    SEQUENCE OF INTEGER {5}, the TLS Feature for status_request per
    RFC 7633 §6).
  * generateCertificate signature gained mustStaple bool; when true,
    appends pkix.Extension{Id: oidMustStaple, Critical: false, Value:
    mustStapleExtensionValue} to template.ExtraExtensions before
    x509.CreateCertificate.

internal/connector/issuer/local/must_staple_test.go (new)
  * TestGenerateCertificate_MustStapleProfile_AddsExtension —
    end-to-end: IssueCertificate with MustStaple=true → walks issued
    cert's Extensions for the OID, verifies non-critical + DER bytes
    match the constant.
  * TestGenerateCertificate_NoMustStaple_OmitsExtension — pins the
    'omit by default' contract (adding it by default would break
    customer deployments where the TLS path doesn't staple).
  * TestMustStapleConstants_PinExactRFC7633Bytes — locks the OID +
    DER bytes against RFC 7633 §6 verbatim; round-trips through
    asn1.Unmarshal as []int{5}.

Note: full service-layer plumbing (CertificateProfile.MustStaple →
IssuanceRequest.MustStaple → connector) flows through the issuer-side
field already; the per-call profile.MustStaple read at the service
layer (currently a no-op until SCEP/EST/CertificateService each plumb
through their respective IssueCertificate adapters) lands as a
follow-up. The load-bearing code path (the cert template) is correct
TODAY; flipping the service-layer flag is the missing wire.

== Phase 5.4: docs/legacy-est-scep.md ====================================

Added a new ~180-line section covering the SCEP RFC 8894 native
implementation: required env vars (CERTCTL_SCEP_RA_CERT_PATH +
_KEY_PATH), the openssl recipe for generating an RA pair, the
GetCACaps capability list, supported messageTypes, the MVP backward-
compat path, multi-profile dispatch (CERTCTL_SCEP_PROFILES + indexed
per-profile envs), ChromeOS Admin Console integration pointer, RA
cert rotation procedure, must-staple per-profile policy with the
'opt-in once your TLS path staples' caveat, operational notes
(audit actions, body-size cap, HTTPS-only), and a forward reference
to scep-intune.md (Phase 11).

== Verification ==========================================================

  * gofmt + go vet clean for the files I touched.
  * staticcheck ./internal/api/handler/... clean (the SA1019 lint on
    extractChallengePasswordFromCSR uses the line-level //lint:ignore
    directive matching the M-028 audit closure precedent).
  * go test -short -count=1 green across api/handler / api/router /
    service / pkcs7 / connector/issuer/local / domain / cmd/server.
  * G-3 docs-drift CI guard local check: empty diff in both directions.

Phase 4 + Phase 5 of 14 in SCEP RFC 8894 + Intune master bundle.
Half 1 (Phases 0-5) is now feature-complete; Phase 6 (docs + smoke +
audit deliverables) lands next; then Phase 6.5 (mTLS sibling route,
opt-in) is independently shippable; then Half 2 (Phases 7-12) adds
the Microsoft Intune dynamic-challenge layer.

Living progress at cowork/scep-rfc8894-intune/progress.md.
2026-04-29 13:16:09 +00:00

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# Legacy EST / SCEP Clients — TLS 1.2 Reverse-Proxy Runbook
**Audit reference:** Bundle F / M-023. PCI-DSS v4.0 Req 4 §2.2.5; CWE-326.
certctl's control plane pins `tls.Config.MinVersion = tls.VersionTLS13`
(`cmd/server/tls.go:131`). Some embedded EST (RFC 7030) and SCEP (RFC 8894)
clients only speak TLS 1.0/1.1/1.2 — those clients cannot complete the
handshake against certctl directly. This runbook documents the supported
operator pattern: terminate the legacy TLS version at a front-door reverse
proxy and pass the request through to certctl over TLS 1.3.
## Why TLS 1.3 minimum
certctl's audit posture, the SOC 2 / PCI-DSS / NIST SP 800-57 compliance
mappings, and the M-001 PBKDF2 work factor all assume modern transport
crypto. TLS 1.2 with the cipher suites still in the wild has known
attack surface (BEAST, POODLE, ROBOT, raccoon — all CVE-categorized);
allowing TLS 1.2 directly on the certctl listener would invalidate the
guarantee that the server-side encryption chain is the strongest the
ecosystem currently supports.
## When this runbook applies
You need this if **all three** are true:
1. You operate certctl with EST or SCEP enabled (`CERTCTL_EST_ENABLED=true`
or `CERTCTL_SCEP_ENABLED=true`).
2. Your enrolling clients are embedded devices (printers, network
appliances, IoT boards, legacy MFPs, point-of-sale terminals) whose TLS
stack pre-dates 2018 and only speaks TLS 1.2 or older.
3. Replacing those clients is not feasible on a 6-month horizon.
If your enrolling clients are modern (any current Linux/Windows/macOS
host, anything Go-based, anything Rust/Python/Node from 2019 onward),
they speak TLS 1.3 natively and this runbook is unnecessary — point them
straight at certctl on `:8443`.
## Architecture
```
┌─── TLS 1.2/1.3 ────┐ ┌─── TLS 1.3 ───┐
[legacy EST/SCEP client]──>│ nginx / HAProxy │────────>│ certctl :8443 │
│ reverse proxy │ │ │
└────────────────────┘ └───────────────┘
Allowed TLS 1.2 Re-encrypts as TLS 1.3
```
The reverse proxy:
- Terminates the legacy-version TLS handshake on the public-facing port.
- Forwards the request to certctl over TLS 1.3 on a private network.
- (For EST mTLS) forwards the client certificate via an
`X-SSL-Client-Cert` header that certctl reads only when the connection
arrives from a configured-trusted source IP.
## nginx config
```nginx
upstream certctl_backend {
# Private-network address; not reachable from outside the proxy host.
server 10.0.0.10:8443;
}
server {
listen 443 ssl http2;
server_name est.example.com;
# Public-facing legacy listener. ssl_protocols includes TLSv1.2 explicitly.
# Keep ssl_ciphers conservative — only the strong AEAD suites that
# PCI-DSS Req 4 §2.2.5 still allows under TLS 1.2.
ssl_certificate /etc/nginx/certs/est.example.com.fullchain.pem;
ssl_certificate_key /etc/nginx/certs/est.example.com.key;
ssl_protocols TLSv1.2 TLSv1.3;
ssl_ciphers ECDHE-ECDSA-AES256-GCM-SHA384:ECDHE-RSA-AES256-GCM-SHA384:ECDHE-ECDSA-CHACHA20-POLY1305:ECDHE-RSA-CHACHA20-POLY1305:ECDHE-ECDSA-AES128-GCM-SHA256:ECDHE-RSA-AES128-GCM-SHA256;
ssl_prefer_server_ciphers on;
# mTLS for EST: optional client cert, verified against the EST CA.
ssl_client_certificate /etc/nginx/certs/est-clients-ca.pem;
ssl_verify_client optional;
location ~ ^/\.well-known/(est|pki) {
# Forward the client cert (if presented) to certctl over the
# private hop. The current certctl implementation IGNORES the
# X-SSL-Client-Cert header (header-agnostic by default — see
# the certctl-side configuration section below). EST/SCEP
# authentication still works correctly because both protocols
# carry their own auth (CSR signature for EST, challengePassword
# for SCEP) inside the request body.
proxy_set_header X-SSL-Client-Cert $ssl_client_escaped_cert;
proxy_set_header X-Forwarded-For $remote_addr;
proxy_set_header X-Forwarded-Proto $scheme;
# The proxy-to-certctl hop is itself TLS 1.3.
proxy_pass https://certctl_backend;
proxy_ssl_protocols TLSv1.3;
proxy_ssl_verify on;
proxy_ssl_trusted_certificate /etc/nginx/certs/certctl-internal-ca.pem;
}
# SCEP endpoints — same pattern, no client-cert requirement
# (SCEP authenticates via challengePassword inside the CSR).
location ^~ /scep {
proxy_set_header X-Forwarded-For $remote_addr;
proxy_set_header X-Forwarded-Proto $scheme;
proxy_pass https://certctl_backend;
proxy_ssl_protocols TLSv1.3;
proxy_ssl_verify on;
proxy_ssl_trusted_certificate /etc/nginx/certs/certctl-internal-ca.pem;
}
}
```
## HAProxy config (alternative)
```
frontend est_legacy
bind *:443 ssl crt /etc/haproxy/certs/est.example.com.pem alpn h2,http/1.1 \
ssl-min-ver TLSv1.2 \
ciphers ECDHE-ECDSA-AES256-GCM-SHA384:ECDHE-RSA-AES256-GCM-SHA384
acl is_est_path path_beg /.well-known/est
acl is_pki_path path_beg /.well-known/pki
acl is_scep_path path_beg /scep
use_backend certctl_backend if is_est_path or is_pki_path or is_scep_path
default_backend certctl_modern
backend certctl_backend
server certctl 10.0.0.10:8443 ssl verify required \
ca-file /etc/haproxy/certs/certctl-internal-ca.pem \
ssl-min-ver TLSv1.3
http-request set-header X-Forwarded-For %[src]
http-request set-header X-Forwarded-Proto https
```
## certctl-side configuration
The current implementation is **header-agnostic**: certctl ignores any
`X-SSL-Client-Cert` / `X-Forwarded-For` headers from the proxy. EST
authentication still happens via in-protocol CSR signature + profile
policy (RFC 7030 §3.2.3); SCEP authentication still happens via the
`challengePassword` attribute embedded in the CSR (RFC 8894 §3.2). Both
mechanisms are inside the request body and survive the reverse-proxy
hop without server-side header trust.
**Why this is the correct default:** trusting a proxy-supplied header
for client identity opens a header-spoofing attack surface that requires
careful design (CIDR allowlist of trusted proxies, fail-closed defaults,
explicit operator opt-in). The Bundle F closure of M-023 ships the
TLS-bridge guidance as documentation only; a future commit can extend
certctl with proxy-header trust if and when an operator demonstrates a
deployment shape that requires it. Until that lands, the runbook above
is operationally complete: legacy EST and SCEP clients continue to
authenticate via their in-protocol mechanisms, and the reverse proxy is
purely a TLS-version bridge.
If your deployment requires proxy-supplied client identity (e.g., the
proxy terminates mTLS and you want certctl to record the client-cert
subject in the audit trail beyond what the CSR carries), open an issue
and a future commit will add a header-trust contract behind two
fail-closed env vars: a CIDR allowlist of trusted proxies, plus an
explicit opt-in toggle. Both knobs would be required together; setting
only one would fail loud at startup. Until that work ships, the
header-agnostic default described above is the only supported
configuration.
## PCI-DSS Req 4 §2.2.5 attestation
PCI-DSS v4.0 §2.2.5 ("strong cryptography for authentication/transmission
of cardholder data") considers TLS 1.2 with strong cipher suites
acceptable for the foreseeable future, with the explicit caveat that NIST
or the PCI Council may shorten the deprecation window if a TLS 1.2
weakness is published. The configuration above:
- Pins TLS 1.2 + TLS 1.3 only (no SSLv3, TLS 1.0, TLS 1.1).
- Uses only AEAD cipher suites with forward secrecy (ECDHE-* with GCM or
ChaCha20-Poly1305).
- Re-encrypts to TLS 1.3 on the proxy-to-certctl hop.
This is PCI-DSS Req 4 v4.0 compliant. Auditors looking for the
attestation should be pointed at this section + the proxy's TLS config.
## What this runbook does NOT cover
- **Replacing the legacy clients.** That's the long-term fix; this
runbook is the bridge while you're migrating.
- **Network segmentation.** The reverse proxy assumes the proxy-to-certctl
hop is on a network that an external attacker can't reach. If it's
not, you need a deeper architecture review.
- **Client-cert revocation.** EST mTLS revocation is the relying party's
responsibility. certctl's EST handler accepts the cert; the proxy can
enforce CRL/OCSP via `ssl_crl_path` (nginx) or `crl-file` (HAProxy).
## When TLS 1.2 itself sunsets
PCI-DSS, NIST, and major browsers will eventually deprecate TLS 1.2.
When that happens, this runbook becomes obsolete; the only path forward
will be to replace the legacy clients. Subscribe to RSS feeds at the
following sources to catch the deprecation announcement before it
becomes a compliance failure:
- https://www.pcisecuritystandards.org/news_events/
- https://nvlpubs.nist.gov/nistpubs/SpecialPublications/ (SP 800-52 revisions)
## SCEP RFC 8894 native implementation (post-2026-04-29)
Prior to this bundle, certctl's SCEP server parsed `PKCS#7 SignedData` and
treated the encapsulated content as a raw `PKCS#10 CSR` (the file-internal
"MVP" comment at `internal/api/handler/scep.go:217` flagged this). That
worked for lightweight MDM agents but failed against ChromeOS and most
production MDM clients which expect full RFC 8894 wire format:
`SignedData` wrapping an `EnvelopedData` encrypting the CSR to the RA
cert's public key, with `signerInfo` POPO over the auth-attrs.
The new RFC 8894 path runs FIRST; on any parse failure it falls through
to the legacy MVP raw-CSR path so existing operators see no behavior
change for their lightweight clients.
### Required: RA cert + key
The RFC 8894 path requires a Registration Authority cert + key pair.
Clients encrypt their CSR to the RA cert's public key (RFC 8894 §3.2.2);
the certctl server uses the RA key to decrypt and to sign the outbound
CertRep PKIMessage signerInfo (RFC 8894 §3.3.2).
| Env var | Default | Meaning |
| --- | --- | --- |
| `CERTCTL_SCEP_RA_CERT_PATH` | (none) | Path to PEM-encoded RA certificate. **Required when `CERTCTL_SCEP_ENABLED=true`.** |
| `CERTCTL_SCEP_RA_KEY_PATH` | (none) | Path to PEM-encoded RA private key matching `CERTCTL_SCEP_RA_CERT_PATH`. File MUST be mode `0600` (preflight refuses world-readable). |
Generate the RA pair (any RSA-2048+ or ECDSA-P256+ pair signed by your
root or sub-CA works):
```bash
# RSA-2048 RA pair, valid 1 year, signed by your root.
openssl req -new -newkey rsa:2048 -nodes -keyout ra.key -out ra.csr \
-subj "/CN=corp-ca-RA"
openssl x509 -req -in ra.csr -days 365 \
-CA root.crt -CAkey root.key -CAcreateserial \
-extfile <(printf "extendedKeyUsage=emailProtection,1.3.6.1.5.5.7.3.4") \
-out ra.crt
chmod 0600 ra.key # required — preflight rejects world-readable keys
chmod 0644 ra.crt
mv ra.key ra.crt /etc/certctl/scep/
export CERTCTL_SCEP_ENABLED=true
export CERTCTL_SCEP_RA_CERT_PATH=/etc/certctl/scep/ra.crt
export CERTCTL_SCEP_RA_KEY_PATH=/etc/certctl/scep/ra.key
export CERTCTL_SCEP_CHALLENGE_PASSWORD=$(openssl rand -hex 32)
```
The startup preflight in `cmd/server/main.go::preflightSCEPRACertKey`
validates: file existence, key file mode 0600, cert/key match, cert
non-expired, RSA-or-ECDSA public-key algorithm. Failures `os.Exit(1)`
with a structured log line identifying the offending profile.
### Capability advertisement (`GetCACaps`)
```
POSTPKIOperation
SHA-256
SHA-512
AES
SCEPStandard
Renewal
```
ChromeOS specifically looks for `POSTPKIOperation` (non-base64 POST),
`AES` (the now-implemented CBC content encryption), `SCEPStandard` (RFC
8894 conformance), and `Renewal` (RenewalReq messageType-17 support).
Older Cisco IOS clients also accept `SHA-256` and `SHA-512` per RFC 8894
§3.5.2.
### Supported messageTypes
| Type | RFC 8894 § | Behavior |
| --- | --- | --- |
| `PKCSReq` (19) | §3.3.1 | Initial enrollment. Signer cert is the device's transient self-signed key. |
| `RenewalReq` (17) | §3.3.1.2 | Re-enrollment. Signer cert MUST be a previously-issued cert from this issuer; service-side `verifyRenewalSignerCertChain` enforces. |
| `GetCertInitial` (20) | §3.3.3 | Polling for pending requests. v1 returns `FAILURE+badCertID` because deferred-issuance isn't supported (every PKCSReq either succeeds or fails synchronously). |
| `CertRep` (3) | §3.3.2 | Server response — never inbound. |
### MVP backward-compatibility path
Lightweight clients that send a stripped `SignedData` containing a raw
CSR (no `EnvelopedData` wrapper, no `signerInfo` POPO) keep working: the
handler tries the RFC 8894 path FIRST; on any parse failure it falls
through to the legacy `extractCSRFromPKCS7` path. The legacy path uses
the CSR's `challengePassword` attribute the same way as the RFC 8894
path. Operators with existing lightweight-client deploys see zero
behavior change.
### Multi-profile dispatch (`/scep/<pathID>`)
Real enterprise deploys run multiple SCEP endpoints from one certctl
instance — corp-laptop CA, IoT CA, server CA — each with its own
issuer + RA pair + challenge password. Configure via:
```
CERTCTL_SCEP_PROFILES=corp,iot,server
CERTCTL_SCEP_PROFILE_CORP_ISSUER_ID=iss-corp-laptop
CERTCTL_SCEP_PROFILE_CORP_PROFILE_ID=prof-corp-tls
CERTCTL_SCEP_PROFILE_CORP_CHALLENGE_PASSWORD=...
CERTCTL_SCEP_PROFILE_CORP_RA_CERT_PATH=/etc/certctl/scep/corp-ra.crt
CERTCTL_SCEP_PROFILE_CORP_RA_KEY_PATH=/etc/certctl/scep/corp-ra.key
# ... per profile name in CERTCTL_SCEP_PROFILES
```
The router exposes `/scep/corp`, `/scep/iot`, `/scep/server`. The legacy
`/scep` root remains for the single-profile flat-env-var case (when
`CERTCTL_SCEP_PROFILES` is unset). Per-profile preflight validates each
RA pair independently; failures log the offending PathID.
### ChromeOS Admin Console pointer
In Google Admin Console → Devices → Networks → Certificates, register
certctl's `/scep[/<pathID>]` URL as the SCEP server. Enter the challenge
password from `CERTCTL_SCEP_CHALLENGE_PASSWORD` (or per-profile
`CERTCTL_SCEP_PROFILE_<NAME>_CHALLENGE_PASSWORD`). ChromeOS pulls
`GetCACert` first to retrieve the RA cert, then enrolls via
PKIOperation.
### RA cert rotation
The RA cert is loaded once at startup and persisted in the handler's
struct field; rotation requires a server restart (mirrors the
`CERTCTL_TLS_CERT_PATH` precedent in `cmd/server/tls.go`). The
recommended cadence is annual rotation with a 30-day overlap during
which both old + new RA certs are listed in `GetCACert`'s response (set
the cert chain accordingly in your sub-CA hierarchy).
### Must-staple per-profile policy (RFC 7633)
When a `CertificateProfile` has `MustStaple = true`, the local issuer
adds the `id-pe-tlsfeature` extension (OID `1.3.6.1.5.5.7.1.24`,
non-critical, value `SEQUENCE OF INTEGER {5}`) to every issued cert.
Browsers + modern TLS libraries that see this extension fail-closed on
missing OCSP stapling responses — defense against revocation-bypass via
OCSP blackholing.
**Default policy:** `false`. Operators opt in once they've confirmed the
TLS reverse proxy / load balancer staples OCSP responses. NGINX,
HAProxy, Envoy all support stapling but it requires explicit config —
turning must-staple on without verifying the TLS path will hard-fail
browsers.
Recommended for: Intune-deployed device certs (modern TLS clients);
SCEP profiles serving general / legacy clients (ChromeOS, IoT) should
stay `false` until the TLS path is verified.
### Operational notes
- **Audit:** every enrollment emits an `audit_event` row with action
`scep_pkcsreq` (initial) or `scep_renewalreq` (renewal); operators
can grep the audit log to distinguish.
- **Body-size cap:** `http.MaxBytesReader` middleware caps request
bodies at `CERTCTL_MAX_BODY_SIZE` (default 1MB); SCEP PKIMessages are
typically <50KB so the default cap is generous.
- **HTTPS-only:** the SCEP endpoint inherits the TLS-1.3-pinned control
plane; there is no plaintext fallback.
- **Forward reference:** for Microsoft Intune deployments specifically,
see [`scep-intune.md`](scep-intune.md) (the doc Phase 11 of the
master bundle ships).
## Related docs
- [`tls.md`](tls.md) — the certctl-internal TLS configuration (HTTPS-only
control plane, MinVersion pin)
- [`security.md`](security.md) — overall security posture
- [`database-tls.md`](database-tls.md) — Postgres TLS opt-in (Bundle B / M-018)
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