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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "AppTrustDomain.h"
#include "MainThreadUtils.h"
#include "cert_storage/src/cert_storage.h"
// FIXME: these two must be included before certdb.h {
#include "seccomon.h"
#include "certt.h"
// }
#include "certdb.h"
#include "mozilla/ArrayUtils.h"
#include "mozilla/Casting.h"
#include "mozilla/Logging.h"
#include "mozilla/Preferences.h"
#include "mozpkix/pkixnss.h"
#include "NSSCertDBTrustDomain.h"
#include "nsComponentManagerUtils.h"
#include "nsDirectoryServiceUtils.h"
#include "nsIContentSignatureVerifier.h"
#include "nsIX509CertDB.h"
#include "nsNSSCertificate.h"
#include "nsNetUtil.h"
#include "prerror.h"
// Generated by gen_cert_header.py, which gets called by the build system.
#include "xpcshell.inc"
// Add-on signing Certificates
#include "addons-public.inc"
#include "addons-public-intermediate.inc"
#include "addons-stage.inc"
#include "addons-stage-intermediate.inc"
// Content signature root certificates
#include "content-signature-dev.inc"
#include "content-signature-local.inc"
#include "content-signature-prod.inc"
#include "content-signature-stage.inc"
using namespace mozilla::pkix;
extern mozilla::LazyLogModule gPIPNSSLog;
namespace mozilla {
namespace psm {
AppTrustDomain::AppTrustDomain(nsTArray<Span<const uint8_t>>&& collectedCerts)
: mIntermediates(std::move(collectedCerts)),
mCertBlocklist(do_GetService(NS_CERT_STORAGE_CID)) {}
nsresult AppTrustDomain::SetTrustedRoot(AppTrustedRoot trustedRoot) {
switch (trustedRoot) {
case nsIX509CertDB::AppXPCShellRoot:
mTrustedRoot = {xpcshellRoot};
break;
case nsIX509CertDB::AddonsPublicRoot:
mTrustedRoot = {addonsPublicRoot};
break;
case nsIX509CertDB::AddonsStageRoot:
mTrustedRoot = {addonsStageRoot};
break;
case nsIContentSignatureVerifier::ContentSignatureLocalRoot:
mTrustedRoot = {contentSignatureLocalRoot};
break;
case nsIContentSignatureVerifier::ContentSignatureProdRoot:
mTrustedRoot = {contentSignatureProdRoot};
break;
case nsIContentSignatureVerifier::ContentSignatureStageRoot:
mTrustedRoot = {contentSignatureStageRoot};
break;
case nsIContentSignatureVerifier::ContentSignatureDevRoot:
mTrustedRoot = {contentSignatureDevRoot};
break;
default:
return NS_ERROR_INVALID_ARG;
}
// If we're verifying add-ons signed by our production root, we want to make
// sure a valid intermediate certificate is available for path building.
// The intermediate bundled with signed XPI files may have expired and be
// considered invalid, which can result in bug 1548973.
if (trustedRoot == nsIX509CertDB::AddonsPublicRoot) {
mAddonsIntermediate = {addonsPublicIntermediate};
}
// Similarly to the above logic for production, we hardcode the intermediate
// stage certificate here, so that stage is equivalent to production.
if (trustedRoot == nsIX509CertDB::AddonsStageRoot) {
mAddonsIntermediate = {addonsStageIntermediate};
}
return NS_OK;
}
pkix::Result AppTrustDomain::FindIssuer(Input encodedIssuerName,
IssuerChecker& checker, Time) {
MOZ_ASSERT(!mTrustedRoot.IsEmpty());
if (mTrustedRoot.IsEmpty()) {
return pkix::Result::FATAL_ERROR_INVALID_STATE;
}
nsTArray<Input> candidates;
Input rootInput;
pkix::Result rv =
rootInput.Init(mTrustedRoot.Elements(), mTrustedRoot.Length());
// This should never fail, since the possible roots are all hard-coded and
// they should never be too long.
if (rv != Success) {
return rv;
}
candidates.AppendElement(std::move(rootInput));
if (!mAddonsIntermediate.IsEmpty()) {
Input intermediateInput;
rv = intermediateInput.Init(mAddonsIntermediate.Elements(),
mAddonsIntermediate.Length());
// Again, this should never fail for the same reason as above.
if (rv != Success) {
return rv;
}
candidates.AppendElement(std::move(intermediateInput));
}
for (const auto& intermediate : mIntermediates) {
Input intermediateInput;
rv = intermediateInput.Init(intermediate.Elements(), intermediate.Length());
// This is untrusted input, so skip any intermediates that are too large.
if (rv != Success) {
continue;
}
candidates.AppendElement(std::move(intermediateInput));
}
for (const auto& candidate : candidates) {
bool keepGoing;
rv = checker.Check(candidate, nullptr /*additionalNameConstraints*/,
keepGoing);
if (rv != Success) {
return rv;
}
if (!keepGoing) {
return Success;
}
}
// If the above did not succeed in building a verified certificate chain,
// fall back to searching for candidates in NSS. This is important in case an
// intermediate involved in add-on signing expires before it is replaced. See
// bug 1548973.
SECItem encodedIssuerNameSECItem = UnsafeMapInputToSECItem(encodedIssuerName);
UniqueCERTCertList nssCandidates(CERT_CreateSubjectCertList(
nullptr, CERT_GetDefaultCertDB(), &encodedIssuerNameSECItem, 0, false));
if (nssCandidates) {
for (CERTCertListNode* n = CERT_LIST_HEAD(nssCandidates);
!CERT_LIST_END(n, nssCandidates); n = CERT_LIST_NEXT(n)) {
Input certDER;
pkix::Result rv =
certDER.Init(n->cert->derCert.data, n->cert->derCert.len);
if (rv != Success) {
continue; // probably too big
}
bool keepGoing;
rv = checker.Check(certDER, nullptr /*additionalNameConstraints*/,
keepGoing);
if (rv != Success) {
return rv;
}
if (!keepGoing) {
break;
}
}
}
return Success;
}
pkix::Result AppTrustDomain::GetCertTrust(EndEntityOrCA endEntityOrCA,
const CertPolicyId& policy,
Input candidateCertDER,
/*out*/ TrustLevel& trustLevel) {
MOZ_ASSERT(policy.IsAnyPolicy());
MOZ_ASSERT(!mTrustedRoot.IsEmpty());
if (!policy.IsAnyPolicy()) {
return pkix::Result::FATAL_ERROR_INVALID_ARGS;
}
if (mTrustedRoot.IsEmpty()) {
return pkix::Result::FATAL_ERROR_INVALID_STATE;
}
nsTArray<uint8_t> issuerBytes;
nsTArray<uint8_t> serialBytes;
nsTArray<uint8_t> subjectBytes;
nsTArray<uint8_t> pubKeyBytes;
pkix::Result result =
BuildRevocationCheckArrays(candidateCertDER, endEntityOrCA, issuerBytes,
serialBytes, subjectBytes, pubKeyBytes);
if (result != Success) {
return result;
}
int16_t revocationState;
nsresult nsrv = mCertBlocklist->GetRevocationState(
issuerBytes, serialBytes, subjectBytes, pubKeyBytes, &revocationState);
if (NS_FAILED(nsrv)) {
return pkix::Result::FATAL_ERROR_LIBRARY_FAILURE;
}
if (revocationState == nsICertStorage::STATE_ENFORCE) {
return pkix::Result::ERROR_REVOKED_CERTIFICATE;
}
// mTrustedRoot is the only trust anchor for this validation.
Span<const uint8_t> candidateCertDERSpan = {candidateCertDER.UnsafeGetData(),
candidateCertDER.GetLength()};
if (mTrustedRoot == candidateCertDERSpan) {
trustLevel = TrustLevel::TrustAnchor;
return Success;
}
trustLevel = TrustLevel::InheritsTrust;
return Success;
}
pkix::Result AppTrustDomain::DigestBuf(Input item, DigestAlgorithm digestAlg,
/*out*/ uint8_t* digestBuf,
size_t digestBufLen) {
return DigestBufNSS(item, digestAlg, digestBuf, digestBufLen);
}
pkix::Result AppTrustDomain::CheckRevocation(EndEntityOrCA, const CertID&, Time,
Duration,
/*optional*/ const Input*,
/*optional*/ const Input*,
/*optional*/ const Input*) {
// We don't currently do revocation checking. If we need to distrust an Apps
// certificate, we will use the active distrust mechanism.
return Success;
}
pkix::Result AppTrustDomain::IsChainValid(const DERArray& certChain, Time time,
const CertPolicyId& requiredPolicy) {
MOZ_ASSERT(requiredPolicy.IsAnyPolicy());
return Success;
}
pkix::Result AppTrustDomain::CheckSignatureDigestAlgorithm(
DigestAlgorithm digestAlg, EndEntityOrCA, Time) {
switch (digestAlg) {
case DigestAlgorithm::sha256: // fall through
case DigestAlgorithm::sha384: // fall through
case DigestAlgorithm::sha512:
return Success;
case DigestAlgorithm::sha1:
return pkix::Result::ERROR_CERT_SIGNATURE_ALGORITHM_DISABLED;
}
return pkix::Result::FATAL_ERROR_LIBRARY_FAILURE;
}
pkix::Result AppTrustDomain::CheckRSAPublicKeyModulusSizeInBits(
EndEntityOrCA /*endEntityOrCA*/, unsigned int modulusSizeInBits) {
if (modulusSizeInBits < 2048u) {
return pkix::Result::ERROR_INADEQUATE_KEY_SIZE;
}
return Success;
}
pkix::Result AppTrustDomain::VerifyRSAPKCS1SignedData(
Input data, DigestAlgorithm digestAlgorithm, Input signature,
Input subjectPublicKeyInfo) {
// TODO: We should restrict signatures to SHA-256 or better.
return VerifyRSAPKCS1SignedDataNSS(data, digestAlgorithm, signature,
subjectPublicKeyInfo, nullptr);
}
pkix::Result AppTrustDomain::VerifyRSAPSSSignedData(
Input data, DigestAlgorithm digestAlgorithm, Input signature,
Input subjectPublicKeyInfo) {
return VerifyRSAPSSSignedDataNSS(data, digestAlgorithm, signature,
subjectPublicKeyInfo, nullptr);
}
pkix::Result AppTrustDomain::CheckECDSACurveIsAcceptable(
EndEntityOrCA /*endEntityOrCA*/, NamedCurve curve) {
switch (curve) {
case NamedCurve::secp256r1: // fall through
case NamedCurve::secp384r1: // fall through
case NamedCurve::secp521r1:
return Success;
}
return pkix::Result::ERROR_UNSUPPORTED_ELLIPTIC_CURVE;
}
pkix::Result AppTrustDomain::VerifyECDSASignedData(
Input data, DigestAlgorithm digestAlgorithm, Input signature,
Input subjectPublicKeyInfo) {
return VerifyECDSASignedDataNSS(data, digestAlgorithm, signature,
subjectPublicKeyInfo, nullptr);
}
pkix::Result AppTrustDomain::CheckValidityIsAcceptable(
Time /*notBefore*/, Time /*notAfter*/, EndEntityOrCA /*endEntityOrCA*/,
KeyPurposeId /*keyPurpose*/) {
return Success;
}
pkix::Result AppTrustDomain::NetscapeStepUpMatchesServerAuth(
Time /*notBefore*/,
/*out*/ bool& matches) {
matches = false;
return Success;
}
void AppTrustDomain::NoteAuxiliaryExtension(AuxiliaryExtension /*extension*/,
Input /*extensionData*/) {}
} // namespace psm
} // namespace mozilla
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