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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 "CertVerifier.h"
#include <stdint.h>
#include "CTKnownLogs.h"
#include "ExtendedValidation.h"
#include "MultiLogCTVerifier.h"
#include "NSSCertDBTrustDomain.h"
#include "NSSErrorsService.h"
#include "cert.h"
#include "mozilla/Assertions.h"
#include "mozilla/Casting.h"
#include "nsNSSComponent.h"
#include "nsServiceManagerUtils.h"
#include "pk11pub.h"
#include "pkix/pkix.h"
#include "pkix/pkixnss.h"
#include "prerror.h"
#include "secerr.h"
#include "secmod.h"
#include "sslerr.h"
using namespace mozilla::ct;
using namespace mozilla::pkix;
using namespace mozilla::psm;
mozilla::LazyLogModule gCertVerifierLog("certverifier");
namespace mozilla { namespace psm {
const CertVerifier::Flags CertVerifier::FLAG_LOCAL_ONLY = 1;
const CertVerifier::Flags CertVerifier::FLAG_MUST_BE_EV = 2;
const CertVerifier::Flags CertVerifier::FLAG_TLS_IGNORE_STATUS_REQUEST = 4;
CertVerifier::CertVerifier(OcspDownloadConfig odc,
OcspStrictConfig osc,
OcspGetConfig ogc,
uint32_t certShortLifetimeInDays,
PinningMode pinningMode,
SHA1Mode sha1Mode,
BRNameMatchingPolicy::Mode nameMatchingMode,
NetscapeStepUpPolicy netscapeStepUpPolicy,
CertificateTransparencyMode ctMode)
: mOCSPDownloadConfig(odc)
, mOCSPStrict(osc == ocspStrict)
, mOCSPGETEnabled(ogc == ocspGetEnabled)
, mCertShortLifetimeInDays(certShortLifetimeInDays)
, mPinningMode(pinningMode)
, mSHA1Mode(sha1Mode)
, mNameMatchingMode(nameMatchingMode)
, mNetscapeStepUpPolicy(netscapeStepUpPolicy)
, mCTMode(ctMode)
{
LoadKnownCTLogs();
}
CertVerifier::~CertVerifier()
{
}
Result
IsCertChainRootBuiltInRoot(const UniqueCERTCertList& chain, bool& result)
{
if (!chain || CERT_LIST_EMPTY(chain)) {
return Result::FATAL_ERROR_LIBRARY_FAILURE;
}
CERTCertListNode* rootNode = CERT_LIST_TAIL(chain);
if (!rootNode) {
return Result::FATAL_ERROR_LIBRARY_FAILURE;
}
CERTCertificate* root = rootNode->cert;
if (!root) {
return Result::FATAL_ERROR_LIBRARY_FAILURE;
}
return IsCertBuiltInRoot(root, result);
}
Result
IsCertBuiltInRoot(CERTCertificate* cert, bool& result)
{
result = false;
#ifdef DEBUG
nsCOMPtr<nsINSSComponent> component(do_GetService(PSM_COMPONENT_CONTRACTID));
if (!component) {
return Result::FATAL_ERROR_LIBRARY_FAILURE;
}
nsresult rv = component->IsCertTestBuiltInRoot(cert, result);
if (NS_FAILED(rv)) {
return Result::FATAL_ERROR_LIBRARY_FAILURE;
}
if (result) {
return Success;
}
#endif // DEBUG
AutoSECMODListReadLock lock;
for (SECMODModuleList* list = SECMOD_GetDefaultModuleList(); list;
list = list->next) {
for (int i = 0; i < list->module->slotCount; i++) {
PK11SlotInfo* slot = list->module->slots[i];
// PK11_HasRootCerts should return true if and only if the given slot has
// an object with a CKA_CLASS of CKO_NETSCAPE_BUILTIN_ROOT_LIST, which
// should be true only of the builtin root list.
// If we can find a copy of the given certificate on the slot with the
// builtin root list, that certificate must be a builtin.
if (PK11_IsPresent(slot) && PK11_HasRootCerts(slot) &&
PK11_FindCertInSlot(slot, cert, nullptr) != CK_INVALID_HANDLE) {
result = true;
return Success;
}
}
}
return Success;
}
static Result
BuildCertChainForOneKeyUsage(NSSCertDBTrustDomain& trustDomain, Input certDER,
Time time, KeyUsage ku1, KeyUsage ku2,
KeyUsage ku3, KeyPurposeId eku,
const CertPolicyId& requiredPolicy,
const Input* stapledOCSPResponse,
/*optional out*/ CertVerifier::OCSPStaplingStatus*
ocspStaplingStatus)
{
trustDomain.ResetAccumulatedState();
Result rv = BuildCertChain(trustDomain, certDER, time,
EndEntityOrCA::MustBeEndEntity, ku1,
eku, requiredPolicy, stapledOCSPResponse);
if (rv == Result::ERROR_INADEQUATE_KEY_USAGE) {
trustDomain.ResetAccumulatedState();
rv = BuildCertChain(trustDomain, certDER, time,
EndEntityOrCA::MustBeEndEntity, ku2,
eku, requiredPolicy, stapledOCSPResponse);
if (rv == Result::ERROR_INADEQUATE_KEY_USAGE) {
trustDomain.ResetAccumulatedState();
rv = BuildCertChain(trustDomain, certDER, time,
EndEntityOrCA::MustBeEndEntity, ku3,
eku, requiredPolicy, stapledOCSPResponse);
if (rv != Success) {
rv = Result::ERROR_INADEQUATE_KEY_USAGE;
}
}
}
if (ocspStaplingStatus) {
*ocspStaplingStatus = trustDomain.GetOCSPStaplingStatus();
}
return rv;
}
void
CertVerifier::LoadKnownCTLogs()
{
mCTVerifier = MakeUnique<MultiLogCTVerifier>();
for (const CTLogInfo& log : kCTLogList) {
Input publicKey;
Result rv = publicKey.Init(
BitwiseCast<const uint8_t*, const char*>(log.logKey), log.logKeyLength);
if (rv != Success) {
MOZ_ASSERT_UNREACHABLE("Failed reading a log key for a known CT Log");
continue;
}
rv = mCTVerifier->AddLog(publicKey);
if (rv != Success) {
MOZ_ASSERT_UNREACHABLE("Failed initializing a known CT Log");
continue;
}
}
}
Result
CertVerifier::VerifySignedCertificateTimestamps(
NSSCertDBTrustDomain& trustDomain, const UniqueCERTCertList& builtChain,
Input sctsFromTLS, Time time,
/*optional out*/ CertificateTransparencyInfo* ctInfo)
{
if (ctInfo) {
ctInfo->Reset();
}
if (mCTMode == CertificateTransparencyMode::Disabled) {
return Success;
}
if (ctInfo) {
ctInfo->enabled = true;
}
if (!builtChain || CERT_LIST_EMPTY(builtChain)) {
return Result::FATAL_ERROR_INVALID_ARGS;
}
bool gotScts = false;
Input embeddedSCTs = trustDomain.GetSCTListFromCertificate();
if (embeddedSCTs.GetLength() > 0) {
gotScts = true;
MOZ_LOG(gCertVerifierLog, LogLevel::Debug,
("Got embedded SCT data of length %zu\n",
static_cast<size_t>(embeddedSCTs.GetLength())));
}
Input sctsFromOCSP = trustDomain.GetSCTListFromOCSPStapling();
if (sctsFromOCSP.GetLength() > 0) {
gotScts = true;
MOZ_LOG(gCertVerifierLog, LogLevel::Debug,
("Got OCSP SCT data of length %zu\n",
static_cast<size_t>(sctsFromOCSP.GetLength())));
}
if (sctsFromTLS.GetLength() > 0) {
gotScts = true;
MOZ_LOG(gCertVerifierLog, LogLevel::Debug,
("Got TLS SCT data of length %zu\n",
static_cast<size_t>(sctsFromTLS.GetLength())));
}
if (!gotScts) {
return Success;
}
CERTCertListNode* endEntityNode = CERT_LIST_HEAD(builtChain);
if (!endEntityNode || CERT_LIST_END(endEntityNode, builtChain)) {
return Result::FATAL_ERROR_INVALID_ARGS;
}
CERTCertListNode* issuerNode = CERT_LIST_NEXT(endEntityNode);
if (!issuerNode || CERT_LIST_END(issuerNode, builtChain)) {
// Issuer certificate is required for SCT verification.
// TODO(bug 1294580): change this to Result::FATAL_ERROR_INVALID_ARGS
return Success;
}
CERTCertificate* endEntity = endEntityNode->cert;
CERTCertificate* issuer = issuerNode->cert;
if (!endEntity || !issuer) {
return Result::FATAL_ERROR_INVALID_ARGS;
}
Input endEntityDER;
Result rv = endEntityDER.Init(endEntity->derCert.data,
endEntity->derCert.len);
if (rv != Success) {
return rv;
}
Input issuerPublicKeyDER;
rv = issuerPublicKeyDER.Init(issuer->derPublicKey.data,
issuer->derPublicKey.len);
if (rv != Success) {
return rv;
}
CTVerifyResult result;
rv = mCTVerifier->Verify(endEntityDER, issuerPublicKeyDER,
embeddedSCTs, sctsFromOCSP, sctsFromTLS, time,
result);
if (rv != Success) {
MOZ_LOG(gCertVerifierLog, LogLevel::Debug,
("SCT verification failed with fatal error %i\n", rv));
return rv;
}
if (MOZ_LOG_TEST(gCertVerifierLog, LogLevel::Debug)) {
size_t verifiedCount = 0;
size_t unknownLogCount = 0;
size_t invalidSignatureCount = 0;
size_t invalidTimestampCount = 0;
for (const SignedCertificateTimestamp& sct : result.scts) {
switch (sct.verificationStatus) {
case SignedCertificateTimestamp::VerificationStatus::OK:
verifiedCount++;
break;
case SignedCertificateTimestamp::VerificationStatus::UnknownLog:
unknownLogCount++;
break;
case SignedCertificateTimestamp::VerificationStatus::InvalidSignature:
invalidSignatureCount++;
break;
case SignedCertificateTimestamp::VerificationStatus::InvalidTimestamp:
invalidTimestampCount++;
break;
case SignedCertificateTimestamp::VerificationStatus::None:
default:
MOZ_ASSERT_UNREACHABLE("Unexpected SCT verificationStatus");
}
}
MOZ_LOG(gCertVerifierLog, LogLevel::Debug,
("SCT verification result: "
"verified=%zu unknownLog=%zu "
"invalidSignature=%zu invalidTimestamp=%zu "
"decodingErrors=%zu\n",
verifiedCount, unknownLogCount,
invalidSignatureCount, invalidTimestampCount,
result.decodingErrors));
}
if (ctInfo) {
ctInfo->processedSCTs = true;
ctInfo->verifyResult = Move(result);
}
return Success;
}
bool
CertVerifier::SHA1ModeMoreRestrictiveThanGivenMode(SHA1Mode mode)
{
switch (mSHA1Mode) {
case SHA1Mode::Forbidden:
return mode != SHA1Mode::Forbidden;
case SHA1Mode::ImportedRoot:
return mode != SHA1Mode::Forbidden && mode != SHA1Mode::ImportedRoot;
case SHA1Mode::ImportedRootOrBefore2016:
return mode == SHA1Mode::Allowed;
case SHA1Mode::Allowed:
return false;
// MSVC warns unless we explicitly handle this now-unused option.
case SHA1Mode::UsedToBeBefore2016ButNowIsForbidden:
default:
MOZ_ASSERT(false, "unexpected SHA1Mode type");
return true;
}
}
static const unsigned int MIN_RSA_BITS = 2048;
static const unsigned int MIN_RSA_BITS_WEAK = 1024;
Result
CertVerifier::VerifyCert(CERTCertificate* cert, SECCertificateUsage usage,
Time time, void* pinArg, const char* hostname,
/*out*/ UniqueCERTCertList& builtChain,
/*optional*/ const Flags flags,
/*optional*/ const SECItem* stapledOCSPResponseSECItem,
/*optional*/ const SECItem* sctsFromTLSSECItem,
/*optional*/ const NeckoOriginAttributes& originAttributes,
/*optional out*/ SECOidTag* evOidPolicy,
/*optional out*/ OCSPStaplingStatus* ocspStaplingStatus,
/*optional out*/ KeySizeStatus* keySizeStatus,
/*optional out*/ SHA1ModeResult* sha1ModeResult,
/*optional out*/ PinningTelemetryInfo* pinningTelemetryInfo,
/*optional out*/ CertificateTransparencyInfo* ctInfo)
{
MOZ_LOG(gCertVerifierLog, LogLevel::Debug, ("Top of VerifyCert\n"));
PR_ASSERT(cert);
PR_ASSERT(usage == certificateUsageSSLServer || !(flags & FLAG_MUST_BE_EV));
PR_ASSERT(usage == certificateUsageSSLServer || !keySizeStatus);
PR_ASSERT(usage == certificateUsageSSLServer || !sha1ModeResult);
if (evOidPolicy) {
*evOidPolicy = SEC_OID_UNKNOWN;
}
if (ocspStaplingStatus) {
if (usage != certificateUsageSSLServer) {
return Result::FATAL_ERROR_INVALID_ARGS;
}
*ocspStaplingStatus = OCSP_STAPLING_NEVER_CHECKED;
}
if (keySizeStatus) {
if (usage != certificateUsageSSLServer) {
return Result::FATAL_ERROR_INVALID_ARGS;
}
*keySizeStatus = KeySizeStatus::NeverChecked;
}
if (sha1ModeResult) {
if (usage != certificateUsageSSLServer) {
return Result::FATAL_ERROR_INVALID_ARGS;
}
*sha1ModeResult = SHA1ModeResult::NeverChecked;
}
if (!cert ||
(usage != certificateUsageSSLServer && (flags & FLAG_MUST_BE_EV))) {
return Result::FATAL_ERROR_INVALID_ARGS;
}
Input certDER;
Result rv = certDER.Init(cert->derCert.data, cert->derCert.len);
if (rv != Success) {
return rv;
}
// We configure the OCSP fetching modes separately for EV and non-EV
// verifications.
NSSCertDBTrustDomain::OCSPFetching defaultOCSPFetching
= (mOCSPDownloadConfig == ocspOff) ||
(mOCSPDownloadConfig == ocspEVOnly) ||
(flags & FLAG_LOCAL_ONLY) ? NSSCertDBTrustDomain::NeverFetchOCSP
: !mOCSPStrict ? NSSCertDBTrustDomain::FetchOCSPForDVSoftFail
: NSSCertDBTrustDomain::FetchOCSPForDVHardFail;
OcspGetConfig ocspGETConfig = mOCSPGETEnabled ? ocspGetEnabled
: ocspGetDisabled;
Input stapledOCSPResponseInput;
const Input* stapledOCSPResponse = nullptr;
if (stapledOCSPResponseSECItem) {
rv = stapledOCSPResponseInput.Init(stapledOCSPResponseSECItem->data,
stapledOCSPResponseSECItem->len);
if (rv != Success) {
// The stapled OCSP response was too big.
return Result::ERROR_OCSP_MALFORMED_RESPONSE;
}
stapledOCSPResponse = &stapledOCSPResponseInput;
}
Input sctsFromTLSInput;
if (sctsFromTLSSECItem) {
rv = sctsFromTLSInput.Init(sctsFromTLSSECItem->data,
sctsFromTLSSECItem->len);
// Silently discard the error of the extension being too big,
// do not fail the verification.
MOZ_ASSERT(rv == Success);
}
switch (usage) {
case certificateUsageSSLClient: {
// XXX: We don't really have a trust bit for SSL client authentication so
// just use trustEmail as it is the closest alternative.
NSSCertDBTrustDomain trustDomain(trustEmail, defaultOCSPFetching,
mOCSPCache, pinArg, ocspGETConfig,
mCertShortLifetimeInDays,
pinningDisabled, MIN_RSA_BITS_WEAK,
ValidityCheckingMode::CheckingOff,
SHA1Mode::Allowed,
NetscapeStepUpPolicy::NeverMatch,
originAttributes,
builtChain, nullptr, nullptr);
rv = BuildCertChain(trustDomain, certDER, time,
EndEntityOrCA::MustBeEndEntity,
KeyUsage::digitalSignature,
KeyPurposeId::id_kp_clientAuth,
CertPolicyId::anyPolicy, stapledOCSPResponse);
break;
}
case certificateUsageSSLServer: {
// TODO: When verifying a certificate in an SSL handshake, we should
// restrict the acceptable key usage based on the key exchange method
// chosen by the server.
// These configurations are in order of most restrictive to least
// restrictive. This enables us to gather telemetry on the expected
// results of setting the default policy to a particular configuration.
SHA1Mode sha1ModeConfigurations[] = {
SHA1Mode::Forbidden,
SHA1Mode::ImportedRoot,
SHA1Mode::ImportedRootOrBefore2016,
SHA1Mode::Allowed,
};
SHA1ModeResult sha1ModeResults[] = {
SHA1ModeResult::SucceededWithoutSHA1,
SHA1ModeResult::SucceededWithImportedRoot,
SHA1ModeResult::SucceededWithImportedRootOrSHA1Before2016,
SHA1ModeResult::SucceededWithSHA1,
};
size_t sha1ModeConfigurationsCount = MOZ_ARRAY_LENGTH(sha1ModeConfigurations);
static_assert(MOZ_ARRAY_LENGTH(sha1ModeConfigurations) ==
MOZ_ARRAY_LENGTH(sha1ModeResults),
"digestAlgorithm array lengths differ");
rv = Result::ERROR_UNKNOWN_ERROR;
// Try to validate for EV first.
NSSCertDBTrustDomain::OCSPFetching evOCSPFetching
= (mOCSPDownloadConfig == ocspOff) ||
(flags & FLAG_LOCAL_ONLY) ? NSSCertDBTrustDomain::LocalOnlyOCSPForEV
: NSSCertDBTrustDomain::FetchOCSPForEV;
CertPolicyId evPolicy;
SECOidTag evPolicyOidTag;
SECStatus srv = GetFirstEVPolicy(cert, evPolicy, evPolicyOidTag);
for (size_t i = 0;
i < sha1ModeConfigurationsCount && rv != Success && srv == SECSuccess;
i++) {
// Don't attempt verification if the SHA1 mode set by preferences
// (mSHA1Mode) is more restrictive than the SHA1 mode option we're on.
// (To put it another way, only attempt verification if the SHA1 mode
// option we're on is as restrictive or more restrictive than
// mSHA1Mode.) This allows us to gather telemetry information while
// still enforcing the mode set by preferences.
if (SHA1ModeMoreRestrictiveThanGivenMode(sha1ModeConfigurations[i])) {
continue;
}
// Because of the try-strict and fallback approach, we have to clear any
// previously noted telemetry information
if (pinningTelemetryInfo) {
pinningTelemetryInfo->Reset();
}
NSSCertDBTrustDomain
trustDomain(trustSSL, evOCSPFetching,
mOCSPCache, pinArg, ocspGETConfig,
mCertShortLifetimeInDays, mPinningMode, MIN_RSA_BITS,
ValidityCheckingMode::CheckForEV,
sha1ModeConfigurations[i], mNetscapeStepUpPolicy,
originAttributes, builtChain, pinningTelemetryInfo,
hostname);
rv = BuildCertChainForOneKeyUsage(trustDomain, certDER, time,
KeyUsage::digitalSignature,// (EC)DHE
KeyUsage::keyEncipherment, // RSA
KeyUsage::keyAgreement, // (EC)DH
KeyPurposeId::id_kp_serverAuth,
evPolicy, stapledOCSPResponse,
ocspStaplingStatus);
if (rv == Success &&
sha1ModeConfigurations[i] == SHA1Mode::ImportedRoot) {
bool isBuiltInRoot = false;
rv = IsCertChainRootBuiltInRoot(builtChain, isBuiltInRoot);
if (rv != Success) {
break;
}
if (isBuiltInRoot) {
rv = Result::ERROR_CERT_SIGNATURE_ALGORITHM_DISABLED;
}
}
if (rv == Success) {
MOZ_LOG(gCertVerifierLog, LogLevel::Debug,
("cert is EV with status %i\n", sha1ModeResults[i]));
if (evOidPolicy) {
*evOidPolicy = evPolicyOidTag;
}
if (sha1ModeResult) {
*sha1ModeResult = sha1ModeResults[i];
}
rv = VerifySignedCertificateTimestamps(trustDomain, builtChain,
sctsFromTLSInput, time,
ctInfo);
if (rv != Success) {
break;
}
}
}
if (rv == Success) {
break;
}
if (flags & FLAG_MUST_BE_EV) {
rv = Result::ERROR_POLICY_VALIDATION_FAILED;
break;
}
// Now try non-EV.
unsigned int keySizeOptions[] = {
MIN_RSA_BITS,
MIN_RSA_BITS_WEAK
};
KeySizeStatus keySizeStatuses[] = {
KeySizeStatus::LargeMinimumSucceeded,
KeySizeStatus::CompatibilityRisk
};
static_assert(MOZ_ARRAY_LENGTH(keySizeOptions) ==
MOZ_ARRAY_LENGTH(keySizeStatuses),
"keySize array lengths differ");
size_t keySizeOptionsCount = MOZ_ARRAY_LENGTH(keySizeStatuses);
for (size_t i = 0; i < keySizeOptionsCount && rv != Success; i++) {
for (size_t j = 0; j < sha1ModeConfigurationsCount && rv != Success;
j++) {
// Don't attempt verification if the SHA1 mode set by preferences
// (mSHA1Mode) is more restrictive than the SHA1 mode option we're on.
// (To put it another way, only attempt verification if the SHA1 mode
// option we're on is as restrictive or more restrictive than
// mSHA1Mode.) This allows us to gather telemetry information while
// still enforcing the mode set by preferences.
if (SHA1ModeMoreRestrictiveThanGivenMode(sha1ModeConfigurations[j])) {
continue;
}
// invalidate any telemetry info relating to failed chains
if (pinningTelemetryInfo) {
pinningTelemetryInfo->Reset();
}
NSSCertDBTrustDomain trustDomain(trustSSL, defaultOCSPFetching,
mOCSPCache, pinArg, ocspGETConfig,
mCertShortLifetimeInDays,
mPinningMode, keySizeOptions[i],
ValidityCheckingMode::CheckingOff,
sha1ModeConfigurations[j],
mNetscapeStepUpPolicy,
originAttributes, builtChain,
pinningTelemetryInfo, hostname);
rv = BuildCertChainForOneKeyUsage(trustDomain, certDER, time,
KeyUsage::digitalSignature,//(EC)DHE
KeyUsage::keyEncipherment,//RSA
KeyUsage::keyAgreement,//(EC)DH
KeyPurposeId::id_kp_serverAuth,
CertPolicyId::anyPolicy,
stapledOCSPResponse,
ocspStaplingStatus);
if (rv == Success &&
sha1ModeConfigurations[j] == SHA1Mode::ImportedRoot) {
bool isBuiltInRoot = false;
rv = IsCertChainRootBuiltInRoot(builtChain, isBuiltInRoot);
if (rv != Success) {
break;
}
if (isBuiltInRoot) {
rv = Result::ERROR_CERT_SIGNATURE_ALGORITHM_DISABLED;
}
}
if (rv == Success) {
if (keySizeStatus) {
*keySizeStatus = keySizeStatuses[i];
}
if (sha1ModeResult) {
*sha1ModeResult = sha1ModeResults[j];
}
rv = VerifySignedCertificateTimestamps(trustDomain, builtChain,
sctsFromTLSInput, time,
ctInfo);
if (rv != Success) {
break;
}
}
}
}
if (rv == Success) {
break;
}
if (keySizeStatus) {
*keySizeStatus = KeySizeStatus::AlreadyBad;
}
// The telemetry probe CERT_CHAIN_SHA1_POLICY_STATUS gives us feedback on
// the result of setting a specific policy. However, we don't want noise
// from users who have manually set the policy to something other than the
// default, so we only collect for ImportedRoot (which is the default).
if (sha1ModeResult && mSHA1Mode == SHA1Mode::ImportedRoot) {
*sha1ModeResult = SHA1ModeResult::Failed;
}
break;
}
case certificateUsageSSLCA: {
NSSCertDBTrustDomain trustDomain(trustSSL, defaultOCSPFetching,
mOCSPCache, pinArg, ocspGETConfig,
mCertShortLifetimeInDays,
pinningDisabled, MIN_RSA_BITS_WEAK,
ValidityCheckingMode::CheckingOff,
SHA1Mode::Allowed, mNetscapeStepUpPolicy,
originAttributes, builtChain, nullptr,
nullptr);
rv = BuildCertChain(trustDomain, certDER, time,
EndEntityOrCA::MustBeCA, KeyUsage::keyCertSign,
KeyPurposeId::id_kp_serverAuth,
CertPolicyId::anyPolicy, stapledOCSPResponse);
break;
}
case certificateUsageEmailSigner: {
NSSCertDBTrustDomain trustDomain(trustEmail, defaultOCSPFetching,
mOCSPCache, pinArg, ocspGETConfig,
mCertShortLifetimeInDays,
pinningDisabled, MIN_RSA_BITS_WEAK,
ValidityCheckingMode::CheckingOff,
SHA1Mode::Allowed,
NetscapeStepUpPolicy::NeverMatch,
originAttributes, builtChain, nullptr,
nullptr);
rv = BuildCertChain(trustDomain, certDER, time,
EndEntityOrCA::MustBeEndEntity,
KeyUsage::digitalSignature,
KeyPurposeId::id_kp_emailProtection,
CertPolicyId::anyPolicy, stapledOCSPResponse);
if (rv == Result::ERROR_INADEQUATE_KEY_USAGE) {
rv = BuildCertChain(trustDomain, certDER, time,
EndEntityOrCA::MustBeEndEntity,
KeyUsage::nonRepudiation,
KeyPurposeId::id_kp_emailProtection,
CertPolicyId::anyPolicy, stapledOCSPResponse);
}
break;
}
case certificateUsageEmailRecipient: {
// TODO: The higher level S/MIME processing should pass in which key
// usage it is trying to verify for, and base its algorithm choices
// based on the result of the verification(s).
NSSCertDBTrustDomain trustDomain(trustEmail, defaultOCSPFetching,
mOCSPCache, pinArg, ocspGETConfig,
mCertShortLifetimeInDays,
pinningDisabled, MIN_RSA_BITS_WEAK,
ValidityCheckingMode::CheckingOff,
SHA1Mode::Allowed,
NetscapeStepUpPolicy::NeverMatch,
originAttributes, builtChain, nullptr,
nullptr);
rv = BuildCertChain(trustDomain, certDER, time,
EndEntityOrCA::MustBeEndEntity,
KeyUsage::keyEncipherment, // RSA
KeyPurposeId::id_kp_emailProtection,
CertPolicyId::anyPolicy, stapledOCSPResponse);
if (rv == Result::ERROR_INADEQUATE_KEY_USAGE) {
rv = BuildCertChain(trustDomain, certDER, time,
EndEntityOrCA::MustBeEndEntity,
KeyUsage::keyAgreement, // ECDH/DH
KeyPurposeId::id_kp_emailProtection,
CertPolicyId::anyPolicy, stapledOCSPResponse);
}
break;
}
case certificateUsageObjectSigner: {
NSSCertDBTrustDomain trustDomain(trustObjectSigning, defaultOCSPFetching,
mOCSPCache, pinArg, ocspGETConfig,
mCertShortLifetimeInDays,
pinningDisabled, MIN_RSA_BITS_WEAK,
ValidityCheckingMode::CheckingOff,
SHA1Mode::Allowed,
NetscapeStepUpPolicy::NeverMatch,
originAttributes, builtChain, nullptr,
nullptr);
rv = BuildCertChain(trustDomain, certDER, time,
EndEntityOrCA::MustBeEndEntity,
KeyUsage::digitalSignature,
KeyPurposeId::id_kp_codeSigning,
CertPolicyId::anyPolicy, stapledOCSPResponse);
break;
}
case certificateUsageVerifyCA:
case certificateUsageStatusResponder: {
// XXX This is a pretty useless way to verify a certificate. It is used
// by the certificate viewer UI. Because we don't know what trust bit is
// interesting, we just try them all.
mozilla::pkix::EndEntityOrCA endEntityOrCA;
mozilla::pkix::KeyUsage keyUsage;
KeyPurposeId eku;
if (usage == certificateUsageVerifyCA) {
endEntityOrCA = EndEntityOrCA::MustBeCA;
keyUsage = KeyUsage::keyCertSign;
eku = KeyPurposeId::anyExtendedKeyUsage;
} else {
endEntityOrCA = EndEntityOrCA::MustBeEndEntity;
keyUsage = KeyUsage::digitalSignature;
eku = KeyPurposeId::id_kp_OCSPSigning;
}
NSSCertDBTrustDomain sslTrust(trustSSL, defaultOCSPFetching, mOCSPCache,
pinArg, ocspGETConfig, mCertShortLifetimeInDays,
pinningDisabled, MIN_RSA_BITS_WEAK,
ValidityCheckingMode::CheckingOff,
SHA1Mode::Allowed,
NetscapeStepUpPolicy::NeverMatch,
originAttributes, builtChain, nullptr,
nullptr);
rv = BuildCertChain(sslTrust, certDER, time, endEntityOrCA,
keyUsage, eku, CertPolicyId::anyPolicy,
stapledOCSPResponse);
if (rv == Result::ERROR_UNKNOWN_ISSUER) {
NSSCertDBTrustDomain emailTrust(trustEmail, defaultOCSPFetching,
mOCSPCache, pinArg, ocspGETConfig,
mCertShortLifetimeInDays,
pinningDisabled, MIN_RSA_BITS_WEAK,
ValidityCheckingMode::CheckingOff,
SHA1Mode::Allowed,
NetscapeStepUpPolicy::NeverMatch,
originAttributes, builtChain, nullptr,
nullptr);
rv = BuildCertChain(emailTrust, certDER, time, endEntityOrCA,
keyUsage, eku, CertPolicyId::anyPolicy,
stapledOCSPResponse);
if (rv == Result::ERROR_UNKNOWN_ISSUER) {
NSSCertDBTrustDomain objectSigningTrust(trustObjectSigning,
defaultOCSPFetching, mOCSPCache,
pinArg, ocspGETConfig,
mCertShortLifetimeInDays,
pinningDisabled,
MIN_RSA_BITS_WEAK,
ValidityCheckingMode::CheckingOff,
SHA1Mode::Allowed,
NetscapeStepUpPolicy::NeverMatch,
originAttributes, builtChain,
nullptr, nullptr);
rv = BuildCertChain(objectSigningTrust, certDER, time,
endEntityOrCA, keyUsage, eku,
CertPolicyId::anyPolicy, stapledOCSPResponse);
}
}
break;
}
default:
rv = Result::FATAL_ERROR_INVALID_ARGS;
}
if (rv != Success) {
return rv;
}
return Success;
}
Result
CertVerifier::VerifySSLServerCert(const UniqueCERTCertificate& peerCert,
/*optional*/ const SECItem* stapledOCSPResponse,
/*optional*/ const SECItem* sctsFromTLS,
Time time,
/*optional*/ void* pinarg,
const char* hostname,
/*out*/ UniqueCERTCertList& builtChain,
/*optional*/ bool saveIntermediatesInPermanentDatabase,
/*optional*/ Flags flags,
/*optional*/ const NeckoOriginAttributes& originAttributes,
/*optional out*/ SECOidTag* evOidPolicy,
/*optional out*/ OCSPStaplingStatus* ocspStaplingStatus,
/*optional out*/ KeySizeStatus* keySizeStatus,
/*optional out*/ SHA1ModeResult* sha1ModeResult,
/*optional out*/ PinningTelemetryInfo* pinningTelemetryInfo,
/*optional out*/ CertificateTransparencyInfo* ctInfo)
{
PR_ASSERT(peerCert);
// XXX: PR_ASSERT(pinarg)
PR_ASSERT(hostname);
PR_ASSERT(hostname[0]);
if (evOidPolicy) {
*evOidPolicy = SEC_OID_UNKNOWN;
}
if (!hostname || !hostname[0]) {
return Result::ERROR_BAD_CERT_DOMAIN;
}
// CreateCertErrorRunnable assumes that CheckCertHostname is only called
// if VerifyCert succeeded.
Result rv = VerifyCert(peerCert.get(), certificateUsageSSLServer, time,
pinarg, hostname, builtChain, flags,
stapledOCSPResponse, sctsFromTLS, originAttributes,
evOidPolicy, ocspStaplingStatus, keySizeStatus,
sha1ModeResult, pinningTelemetryInfo, ctInfo);
if (rv != Success) {
return rv;
}
Input peerCertInput;
rv = peerCertInput.Init(peerCert->derCert.data, peerCert->derCert.len);
if (rv != Success) {
return rv;
}
Input stapledOCSPResponseInput;
Input* responseInputPtr = nullptr;
if (stapledOCSPResponse) {
rv = stapledOCSPResponseInput.Init(stapledOCSPResponse->data,
stapledOCSPResponse->len);
if (rv != Success) {
// The stapled OCSP response was too big.
return Result::ERROR_OCSP_MALFORMED_RESPONSE;
}
responseInputPtr = &stapledOCSPResponseInput;
}
if (!(flags & FLAG_TLS_IGNORE_STATUS_REQUEST)) {
rv = CheckTLSFeaturesAreSatisfied(peerCertInput, responseInputPtr);
if (rv != Success) {
return rv;
}
}
Input hostnameInput;
rv = hostnameInput.Init(BitwiseCast<const uint8_t*, const char*>(hostname),
strlen(hostname));
if (rv != Success) {
return Result::FATAL_ERROR_INVALID_ARGS;
}
bool isBuiltInRoot;
rv = IsCertChainRootBuiltInRoot(builtChain, isBuiltInRoot);
if (rv != Success) {
return rv;
}
BRNameMatchingPolicy nameMatchingPolicy(
isBuiltInRoot ? mNameMatchingMode
: BRNameMatchingPolicy::Mode::DoNotEnforce);
rv = CheckCertHostname(peerCertInput, hostnameInput, nameMatchingPolicy);
if (rv != Success) {
// Treat malformed name information as a domain mismatch.
if (rv == Result::ERROR_BAD_DER) {
return Result::ERROR_BAD_CERT_DOMAIN;
}
return rv;
}
if (saveIntermediatesInPermanentDatabase) {
SaveIntermediateCerts(builtChain);
}
return Success;
}
} } // namespace mozilla::psm
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