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4 Commits
| Author | SHA1 | Message | Date | |
|---|---|---|---|---|
 shankar0123
|
8b75e0311b |
chore: rename Go module path to github.com/certctl-io/certctl
Mechanical sed across the main go.mod's module declaration, the f5-mock-icontrol
sub-module's go.mod, every Go file's import path (361 files), and a rebuild of
the checked-in f5-mock-icontrol binary so its embedded build-info reflects the
new module path. No behavior change.
Choice B from cowork/transfer-certctl-to-org.md, executed 2026-05-04. Choice A
(keep module path declared as github.com/shankar0123/certctl regardless of
repo URL) shipped on the day of the org transfer (2026-05-03) since we had no
external Go consumers; this commit closes that deferral.
Backward-compat: GitHub HTTP redirects continue to forward
github.com/shankar0123/certctl → github.com/certctl-io/certctl at the URL
level, but Go's module proxy uses the path declared in go.mod as the
canonical name. Pre-fix, anyone trying `go get github.com/certctl-io/certctl/...`
hit a "module path mismatch" error because go.mod said
github.com/shankar0123/certctl and the URL they fetched it from said
certctl-io/certctl. Post-fix, the canonical name and the URL agree, so
go get / go install / external Go consumers / Go-tooling integrations
work cleanly via either the new path (preferred) or the old path (which
redirects and Go follows the redirect for source fetch).
Anyone still importing the old path inside their own code keeps working
provided they update their go.mod's `require` line to match — the module
path declared in their consumer's go.sum / go.mod is the authoritative
import name, so a mass sed across their import statements is the migration
on the consumer side. No external consumers exist today.
Diff shape:
361 *.go files — import path replacement only
2 go.mod — module declaration replacement only
1 binary — deploy/test/f5-mock-icontrol/f5-mock-icontrol rebuilt
so embedded build-info reflects the new path (8618965 vs
8618933 bytes; 32-byte diff is the build-info change)
Total: 364 files, 730 insertions / 730 deletions, net-zero size, pure
mechanical substitution.
Verification:
gofmt: 17 files needed re-alignment after sed (the new path is one char
shorter than the old, so column-aligned import groups drifted). Applied
`gofmt -w` to fix.
go mod tidy: clean exit on both modules.
go vet ./...: clean exit.
go build ./...: clean exit.
go test -short -count=1 on representative packages: all green
(internal/domain, internal/validation, internal/crypto, internal/crypto/signer,
cmd/agent). Test output now reads `ok github.com/certctl-io/certctl/...`
confirming the module path resolves correctly.
binary: f5-mock-icontrol rebuilt; `strings | grep shankar0123` returns
nothing; `strings | grep certctl-io/certctl` shows the new module path
embedded in build-info.
Files intentionally NOT touched in this commit:
README.md / CHANGELOG.md / docs/ / etc. — already swept to certctl-io
URLs in commit
|
||
|
shankar0123
|
b33b843908 |
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.
|
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|
shankar0123
|
a546a1bbef |
feat(scep): EnvelopedData decrypt + signerInfo POPO verify (RFC 8894 §3.2)
SCEP RFC 8894 + Intune master bundle — Phase 2 of 14.
Implements the new RFC 8894 PKIMessage parse path: EnvelopedData parser
+ decryptor, signerInfo parser + signature verifier, handler dispatch
that tries the RFC 8894 path FIRST and falls through to the legacy MVP
raw-CSR path on any parse failure. Backward compat with lightweight SCEP
clients is preserved by design — no behavior change for any existing
deploy that doesn't set CERTCTL_SCEP_RA_*.
internal/pkcs7/envelopeddata.go (new, ~330 LoC)
* ParseEnvelopedData: parses CMS EnvelopedData per RFC 5652 §6.1, with
optional outer ContentInfo unwrapping. Handles SET OF RecipientInfo
+ IssuerAndSerial form rid (RFC 8894 §3.2.2).
* EnvelopedData.Decrypt: RSA PKCS#1 v1.5 key-trans + AES-CBC (128/192/
256) or DES-EDE3-CBC content decryption with **constant-time PKCS#7
padding strip** (no branch on padding-byte values; closes the
padding-oracle leak surface). Recipient mismatch is BadMessageCheck
per RFC 8894 §3.3.2.2 (NOT BadCertID); every failure mode returns
the same ErrEnvelopedDataDecrypt sentinel to close timing-leak legs
of Bleichenbacher attacks.
* Equivalent to micromdm/scep's cryptoutil/cryptoutil.go::DecryptPKCS-
Envelope (cited in code comments; not vendored — fuzz-target
ownership stays in this sub-package per the operating rule).
internal/pkcs7/signedinfo.go (new, ~370 LoC)
* ParseSignedData / ParseSignerInfos: parses CMS SignedData per RFC
5652 §5.3. Resolves each SignerInfo's SID (IssuerAndSerial v1 OR
[0] SubjectKeyId v3) against the SignedData certificates SET to
pluck the device's transient signing cert.
* SignerInfo.VerifySignature: re-serialises signedAttrs as the
canonical SET OF Attribute (the RFC 5652 §5.4 quirk every CMS
implementation hits — wire form is [0] IMPLICIT but the signature
is over EXPLICIT SET OF). Hashes with SHA-1/SHA-256/SHA-512 +
verifies via RSA PKCS1v15 or ECDSA per the cert's pubkey type.
* Auth-attr extractors: GetMessageType (PrintableString-decimal),
GetTransactionID, GetSenderNonce, GetMessageDigest. SCEP attr OIDs
pinned (RFC 8894 §3.2.1.4).
internal/pkcs7/{envelopeddata,signedinfo}_fuzz_test.go (new)
* FuzzParseEnvelopedData / FuzzParseSignedData / FuzzParseSignerInfos
/ FuzzVerifySignerInfoSignature — every parser certctl adds gets a
panic-safety fuzzer (the fuzz-target-ownership rule from
cowork/CLAUDE.md::Operating Rules). Local 5s runs hit ~270k
executions per parser without panic. Errors are expected for
arbitrary inputs; only panics are bugs.
internal/pkcs7/{envelopeddata,signedinfo}_test.go (new)
* Round-trip tests that materialise real RSA/ECDSA pairs, hand-build
the wire bytes, parse + decrypt + verify, and assert plaintext /
auth-attr equality. The build helpers use this package's ASN1Wrap
primitives directly (asn1.Marshal of structs containing nested
asn1.RawValue is finicky for mixed Class/Tag); gives byte-level
control matching what real SCEP clients emit.
* Negative tests: tampered ciphertext / tampered auth-attrs / wrong
RA / wrong key / mismatched recipients / random garbage all return
the appropriate sentinel error without panic.
internal/service/scep.go
* PKCSReqWithEnvelope: RFC 8894 envelope-aware variant. Returns
*SCEPResponseEnvelope (not error + *SCEPEnrollResult) because RFC
8894 §3.3 mandates a CertRep PKIMessage on every response, even
failures — the handler shouldn't translate Go errors into SCEP
failInfo codes. Returns nil to signal 'invalid challenge password'
so the caller can translate to HTTP 403 (matches MVP path's wire
shape; RFC 8894 §3.3.1 is silent on this case).
* mapServiceErrorToFailInfo: exact mapping table from the prompt
(CSR parse → BadRequest, CSR sig → BadMessageCheck, crypto policy
→ BadAlg, default → BadRequest).
internal/api/handler/scep.go
* SCEPService interface gains PKCSReqWithEnvelope.
* SCEPHandler now optionally carries an RA cert + key pair. SetRAPair
upgrades the handler to the RFC 8894 path; without that call the
handler stays MVP-only (the v2.0.x behavior).
* pkiOperation: tries the RFC 8894 path FIRST when the RA pair is
set. tryParseRFC8894 helper does the full pipeline (ParseSignedData
→ VerifySignature → extract auth-attrs → ParseEnvelopedData → Decrypt
→ x509.ParseCertificateRequest the recovered bytes). On any failure
it falls through to the legacy extractCSRFromPKCS7 MVP path —
backward compat is non-negotiable.
* Phase 2 emits the legacy certs-only response on RFC 8894 success;
Phase 3 (next commit) swaps in writeCertRepPKIMessage with the
proper status / failInfo / nonce-echo wire shape.
cmd/server/main.go
* Per-profile loop now calls loadSCEPRAPair after preflight to load
the cert + key + inject via SetRAPair. crypto + crypto/tls imports
added.
* loadSCEPRAPair helper: tls.X509KeyPair-based parse + leaf cert
extraction. Failures here indicate TOCTOU between preflight + load.
internal/api/handler/scep_handler_test.go +
internal/api/router/router_scep_profiles_test.go
* mockSCEPService / scepProfileMockService gain PKCSReqWithEnvelope
stubs to satisfy the extended interface. Existing test cases
unchanged (they exercise the MVP path; RA pair is unset).
Verification:
* gofmt + go vet clean for the files I touched.
* go test -short -count=1 green across pkcs7 / api/handler /
api/router / service / cmd/server.
* Coverage: pkcs7 78.4% (was 100% — drops because new code includes
paths the round-trip tests don't yet hit, like decryption alg
fall-through and v3 SubjectKeyId SID matching).
* Fuzz-target seed-corpus runs (5s each, ~270k execs/parser): no
panic. Pre-merge fuzz-time bumps to 30s per the prompt's
verification gate.
Phase 2 of 14 in SCEP RFC 8894 + Intune master bundle.
Living progress at cowork/scep-rfc8894-intune/progress.md.
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shankar0123
|
bcefb11e65 |
feat(M51): add SCEP server (RFC 8894) for MDM and network device enrollment
Implements Simple Certificate Enrollment Protocol with single-endpoint operation-based dispatch (GetCACaps, GetCACert, PKIOperation), PKCS#7 SignedData CSR extraction with fallback for raw/base64 CSR, challenge password authentication via CSR attributes, and shared internal/pkcs7 package extracted from EST handler to eliminate code duplication. 24 new tests (11 service + 13 handler) plus 5 shared pkcs7 package tests. Co-Authored-By: Claude Opus 4.6 <noreply@anthropic.com> |