// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "net/cert/x509_util.h" #include "net/cert/x509_util_nss.h" #include <cert.h> // Must be included before certdb.h #include <certdb.h> #include <cryptohi.h> #include <nss.h> #include <pk11pub.h> #include <prerror.h> #include <secder.h> #include <secmod.h> #include <secport.h> #include "base/debug/leak_annotations.h" #include "base/logging.h" #include "base/memory/scoped_ptr.h" #include "base/memory/singleton.h" #include "base/pickle.h" #include "base/strings/stringprintf.h" #include "crypto/ec_private_key.h" #include "crypto/nss_util.h" #include "crypto/nss_util_internal.h" #include "crypto/rsa_private_key.h" #include "crypto/scoped_nss_types.h" #include "crypto/third_party/nss/chromium-nss.h" #include "net/cert/x509_certificate.h" namespace net { namespace { class DomainBoundCertOIDWrapper { public: static DomainBoundCertOIDWrapper* GetInstance() { // Instantiated as a leaky singleton to allow the singleton to be // constructed on a worker thead that is not joined when a process // shuts down. return Singleton<DomainBoundCertOIDWrapper, LeakySingletonTraits<DomainBoundCertOIDWrapper> >::get(); } SECOidTag domain_bound_cert_oid_tag() const { return domain_bound_cert_oid_tag_; } private: friend struct DefaultSingletonTraits<DomainBoundCertOIDWrapper>; DomainBoundCertOIDWrapper(); SECOidTag domain_bound_cert_oid_tag_; DISALLOW_COPY_AND_ASSIGN(DomainBoundCertOIDWrapper); }; DomainBoundCertOIDWrapper::DomainBoundCertOIDWrapper() : domain_bound_cert_oid_tag_(SEC_OID_UNKNOWN) { // 1.3.6.1.4.1.11129.2.1.6 // (iso.org.dod.internet.private.enterprises.google.googleSecurity. // certificateExtensions.originBoundCertificate) static const uint8 kObCertOID[] = { 0x2b, 0x06, 0x01, 0x04, 0x01, 0xd6, 0x79, 0x02, 0x01, 0x06 }; SECOidData oid_data; memset(&oid_data, 0, sizeof(oid_data)); oid_data.oid.data = const_cast<uint8*>(kObCertOID); oid_data.oid.len = sizeof(kObCertOID); oid_data.offset = SEC_OID_UNKNOWN; oid_data.desc = "Origin Bound Certificate"; oid_data.mechanism = CKM_INVALID_MECHANISM; oid_data.supportedExtension = SUPPORTED_CERT_EXTENSION; domain_bound_cert_oid_tag_ = SECOID_AddEntry(&oid_data); if (domain_bound_cert_oid_tag_ == SEC_OID_UNKNOWN) LOG(ERROR) << "OB_CERT OID tag creation failed"; } // Creates a Certificate object that may be passed to the SignCertificate // method to generate an X509 certificate. // Returns NULL if an error is encountered in the certificate creation // process. // Caller responsible for freeing returned certificate object. CERTCertificate* CreateCertificate( SECKEYPublicKey* public_key, const std::string& subject, uint32 serial_number, base::Time not_valid_before, base::Time not_valid_after) { // Create info about public key. CERTSubjectPublicKeyInfo* spki = SECKEY_CreateSubjectPublicKeyInfo(public_key); if (!spki) return NULL; // Create the certificate request. CERTName* subject_name = CERT_AsciiToName(const_cast<char*>(subject.c_str())); CERTCertificateRequest* cert_request = CERT_CreateCertificateRequest(subject_name, spki, NULL); SECKEY_DestroySubjectPublicKeyInfo(spki); if (!cert_request) { PRErrorCode prerr = PR_GetError(); LOG(ERROR) << "Failed to create certificate request: " << prerr; CERT_DestroyName(subject_name); return NULL; } CERTValidity* validity = CERT_CreateValidity( crypto::BaseTimeToPRTime(not_valid_before), crypto::BaseTimeToPRTime(not_valid_after)); if (!validity) { PRErrorCode prerr = PR_GetError(); LOG(ERROR) << "Failed to create certificate validity object: " << prerr; CERT_DestroyName(subject_name); CERT_DestroyCertificateRequest(cert_request); return NULL; } CERTCertificate* cert = CERT_CreateCertificate(serial_number, subject_name, validity, cert_request); if (!cert) { PRErrorCode prerr = PR_GetError(); LOG(ERROR) << "Failed to create certificate: " << prerr; } // Cleanup for resources used to generate the cert. CERT_DestroyName(subject_name); CERT_DestroyValidity(validity); CERT_DestroyCertificateRequest(cert_request); return cert; } SECOidTag ToSECOid(x509_util::DigestAlgorithm alg) { switch (alg) { case x509_util::DIGEST_SHA1: return SEC_OID_SHA1; case x509_util::DIGEST_SHA256: return SEC_OID_SHA256; } return SEC_OID_UNKNOWN; } // Signs a certificate object, with |key| generating a new X509Certificate // and destroying the passed certificate object (even when NULL is returned). // The logic of this method references SignCert() in NSS utility certutil: // http://mxr.mozilla.org/security/ident?i=SignCert. // Returns true on success or false if an error is encountered in the // certificate signing process. bool SignCertificate( CERTCertificate* cert, SECKEYPrivateKey* key, SECOidTag hash_algorithm) { // |arena| is used to encode the cert. PLArenaPool* arena = cert->arena; SECOidTag algo_id = SEC_GetSignatureAlgorithmOidTag(key->keyType, hash_algorithm); if (algo_id == SEC_OID_UNKNOWN) return false; SECStatus rv = SECOID_SetAlgorithmID(arena, &cert->signature, algo_id, 0); if (rv != SECSuccess) return false; // Generate a cert of version 3. *(cert->version.data) = 2; cert->version.len = 1; SECItem der = { siBuffer, NULL, 0 }; // Use ASN1 DER to encode the cert. void* encode_result = SEC_ASN1EncodeItem( NULL, &der, cert, SEC_ASN1_GET(CERT_CertificateTemplate)); if (!encode_result) return false; // Allocate space to contain the signed cert. SECItem result = { siBuffer, NULL, 0 }; // Sign the ASN1 encoded cert and save it to |result|. rv = DerSignData(arena, &result, &der, key, algo_id); PORT_Free(der.data); if (rv != SECSuccess) { DLOG(ERROR) << "DerSignData: " << PORT_GetError(); return false; } // Save the signed result to the cert. cert->derCert = result; return true; } #if defined(USE_NSS) || defined(OS_IOS) // Callback for CERT_DecodeCertPackage(), used in // CreateOSCertHandlesFromBytes(). SECStatus PR_CALLBACK CollectCertsCallback(void* arg, SECItem** certs, int num_certs) { X509Certificate::OSCertHandles* results = reinterpret_cast<X509Certificate::OSCertHandles*>(arg); for (int i = 0; i < num_certs; ++i) { X509Certificate::OSCertHandle handle = X509Certificate::CreateOSCertHandleFromBytes( reinterpret_cast<char*>(certs[i]->data), certs[i]->len); if (handle) results->push_back(handle); } return SECSuccess; } typedef scoped_ptr_malloc< CERTName, crypto::NSSDestroyer<CERTName, CERT_DestroyName> > ScopedCERTName; // Create a new CERTName object from its encoded representation. // |arena| is the allocation pool to use. // |data| points to a DER-encoded X.509 DistinguishedName. // Return a new CERTName pointer on success, or NULL. CERTName* CreateCertNameFromEncoded(PLArenaPool* arena, const base::StringPiece& data) { if (!arena) return NULL; ScopedCERTName name(PORT_ArenaZNew(arena, CERTName)); if (!name.get()) return NULL; SECItem item; item.len = static_cast<unsigned int>(data.length()); item.data = reinterpret_cast<unsigned char*>( const_cast<char*>(data.data())); SECStatus rv = SEC_ASN1DecodeItem( arena, name.get(), SEC_ASN1_GET(CERT_NameTemplate), &item); if (rv != SECSuccess) return NULL; return name.release(); } #endif // defined(USE_NSS) || defined(OS_IOS) } // namespace namespace x509_util { bool CreateSelfSignedCert(crypto::RSAPrivateKey* key, DigestAlgorithm alg, const std::string& subject, uint32 serial_number, base::Time not_valid_before, base::Time not_valid_after, std::string* der_cert) { DCHECK(key); DCHECK(!strncmp(subject.c_str(), "CN=", 3U)); CERTCertificate* cert = CreateCertificate(key->public_key(), subject, serial_number, not_valid_before, not_valid_after); if (!cert) return false; if (!SignCertificate(cert, key->key(), ToSECOid(alg))) { CERT_DestroyCertificate(cert); return false; } der_cert->assign(reinterpret_cast<char*>(cert->derCert.data), cert->derCert.len); CERT_DestroyCertificate(cert); return true; } bool IsSupportedValidityRange(base::Time not_valid_before, base::Time not_valid_after) { CERTValidity* validity = CERT_CreateValidity( crypto::BaseTimeToPRTime(not_valid_before), crypto::BaseTimeToPRTime(not_valid_after)); if (!validity) return false; CERT_DestroyValidity(validity); return true; } bool CreateDomainBoundCertEC(crypto::ECPrivateKey* key, DigestAlgorithm alg, const std::string& domain, uint32 serial_number, base::Time not_valid_before, base::Time not_valid_after, std::string* der_cert) { DCHECK(key); CERTCertificate* cert = CreateCertificate(key->public_key(), "CN=anonymous.invalid", serial_number, not_valid_before, not_valid_after); if (!cert) return false; // Create opaque handle used to add extensions later. void* cert_handle; if ((cert_handle = CERT_StartCertExtensions(cert)) == NULL) { LOG(ERROR) << "Unable to get opaque handle for adding extensions"; CERT_DestroyCertificate(cert); return false; } // Create SECItem for IA5String encoding. SECItem domain_string_item = { siAsciiString, (unsigned char*)domain.data(), static_cast<unsigned>(domain.size()) }; // IA5Encode and arena allocate SECItem SECItem* asn1_domain_string = SEC_ASN1EncodeItem( cert->arena, NULL, &domain_string_item, SEC_ASN1_GET(SEC_IA5StringTemplate)); if (asn1_domain_string == NULL) { LOG(ERROR) << "Unable to get ASN1 encoding for domain in domain_bound_cert" " extension"; CERT_DestroyCertificate(cert); return false; } // Add the extension to the opaque handle if (CERT_AddExtension( cert_handle, DomainBoundCertOIDWrapper::GetInstance()->domain_bound_cert_oid_tag(), asn1_domain_string, PR_TRUE, PR_TRUE) != SECSuccess){ LOG(ERROR) << "Unable to add domain bound cert extension to opaque handle"; CERT_DestroyCertificate(cert); return false; } // Copy extension into x509 cert if (CERT_FinishExtensions(cert_handle) != SECSuccess){ LOG(ERROR) << "Unable to copy extension to X509 cert"; CERT_DestroyCertificate(cert); return false; } if (!SignCertificate(cert, key->key(), ToSECOid(alg))) { CERT_DestroyCertificate(cert); return false; } DCHECK(cert->derCert.len); // XXX copied from X509Certificate::GetDEREncoded der_cert->clear(); der_cert->append(reinterpret_cast<char*>(cert->derCert.data), cert->derCert.len); CERT_DestroyCertificate(cert); return true; } #if defined(USE_NSS) || defined(OS_IOS) void ParsePrincipal(CERTName* name, CertPrincipal* principal) { // Starting in NSS 3.15, CERTGetNameFunc takes a const CERTName* argument. #if NSS_VMINOR >= 15 typedef char* (*CERTGetNameFunc)(const CERTName* name); #else typedef char* (*CERTGetNameFunc)(CERTName* name); #endif // TODO(jcampan): add business_category and serial_number. // TODO(wtc): NSS has the CERT_GetOrgName, CERT_GetOrgUnitName, and // CERT_GetDomainComponentName functions, but they return only the most // general (the first) RDN. NSS doesn't have a function for the street // address. static const SECOidTag kOIDs[] = { SEC_OID_AVA_STREET_ADDRESS, SEC_OID_AVA_ORGANIZATION_NAME, SEC_OID_AVA_ORGANIZATIONAL_UNIT_NAME, SEC_OID_AVA_DC }; std::vector<std::string>* values[] = { &principal->street_addresses, &principal->organization_names, &principal->organization_unit_names, &principal->domain_components }; DCHECK_EQ(arraysize(kOIDs), arraysize(values)); CERTRDN** rdns = name->rdns; for (size_t rdn = 0; rdns[rdn]; ++rdn) { CERTAVA** avas = rdns[rdn]->avas; for (size_t pair = 0; avas[pair] != 0; ++pair) { SECOidTag tag = CERT_GetAVATag(avas[pair]); for (size_t oid = 0; oid < arraysize(kOIDs); ++oid) { if (kOIDs[oid] == tag) { SECItem* decode_item = CERT_DecodeAVAValue(&avas[pair]->value); if (!decode_item) break; // TODO(wtc): Pass decode_item to CERT_RFC1485_EscapeAndQuote. std::string value(reinterpret_cast<char*>(decode_item->data), decode_item->len); values[oid]->push_back(value); SECITEM_FreeItem(decode_item, PR_TRUE); break; } } } } // Get CN, L, S, and C. CERTGetNameFunc get_name_funcs[4] = { CERT_GetCommonName, CERT_GetLocalityName, CERT_GetStateName, CERT_GetCountryName }; std::string* single_values[4] = { &principal->common_name, &principal->locality_name, &principal->state_or_province_name, &principal->country_name }; for (size_t i = 0; i < arraysize(get_name_funcs); ++i) { char* value = get_name_funcs[i](name); if (value) { single_values[i]->assign(value); PORT_Free(value); } } } void ParseDate(const SECItem* der_date, base::Time* result) { PRTime prtime; SECStatus rv = DER_DecodeTimeChoice(&prtime, der_date); DCHECK_EQ(SECSuccess, rv); *result = crypto::PRTimeToBaseTime(prtime); } std::string ParseSerialNumber(const CERTCertificate* certificate) { return std::string(reinterpret_cast<char*>(certificate->serialNumber.data), certificate->serialNumber.len); } void GetSubjectAltName(CERTCertificate* cert_handle, std::vector<std::string>* dns_names, std::vector<std::string>* ip_addrs) { if (dns_names) dns_names->clear(); if (ip_addrs) ip_addrs->clear(); SECItem alt_name; SECStatus rv = CERT_FindCertExtension(cert_handle, SEC_OID_X509_SUBJECT_ALT_NAME, &alt_name); if (rv != SECSuccess) return; PLArenaPool* arena = PORT_NewArena(DER_DEFAULT_CHUNKSIZE); DCHECK(arena != NULL); CERTGeneralName* alt_name_list; alt_name_list = CERT_DecodeAltNameExtension(arena, &alt_name); SECITEM_FreeItem(&alt_name, PR_FALSE); CERTGeneralName* name = alt_name_list; while (name) { // DNSName and IPAddress are encoded as IA5String and OCTET STRINGs // respectively, both of which can be byte copied from // SECItemType::data into the appropriate output vector. if (dns_names && name->type == certDNSName) { dns_names->push_back(std::string( reinterpret_cast<char*>(name->name.other.data), name->name.other.len)); } else if (ip_addrs && name->type == certIPAddress) { ip_addrs->push_back(std::string( reinterpret_cast<char*>(name->name.other.data), name->name.other.len)); } name = CERT_GetNextGeneralName(name); if (name == alt_name_list) break; } PORT_FreeArena(arena, PR_FALSE); } X509Certificate::OSCertHandles CreateOSCertHandlesFromBytes( const char* data, int length, X509Certificate::Format format) { X509Certificate::OSCertHandles results; if (length < 0) return results; crypto::EnsureNSSInit(); if (!NSS_IsInitialized()) return results; switch (format) { case X509Certificate::FORMAT_SINGLE_CERTIFICATE: { X509Certificate::OSCertHandle handle = X509Certificate::CreateOSCertHandleFromBytes(data, length); if (handle) results.push_back(handle); break; } case X509Certificate::FORMAT_PKCS7: { // Make a copy since CERT_DecodeCertPackage may modify it std::vector<char> data_copy(data, data + length); SECStatus result = CERT_DecodeCertPackage(&data_copy[0], length, CollectCertsCallback, &results); if (result != SECSuccess) results.clear(); break; } default: NOTREACHED() << "Certificate format " << format << " unimplemented"; break; } return results; } X509Certificate::OSCertHandle ReadOSCertHandleFromPickle( PickleIterator* pickle_iter) { const char* data; int length; if (!pickle_iter->ReadData(&data, &length)) return NULL; return X509Certificate::CreateOSCertHandleFromBytes(data, length); } void GetPublicKeyInfo(CERTCertificate* handle, size_t* size_bits, X509Certificate::PublicKeyType* type) { // Since we might fail, set the output parameters to default values first. *type = X509Certificate::kPublicKeyTypeUnknown; *size_bits = 0; crypto::ScopedSECKEYPublicKey key(CERT_ExtractPublicKey(handle)); if (!key.get()) return; *size_bits = SECKEY_PublicKeyStrengthInBits(key.get()); switch (key->keyType) { case rsaKey: *type = X509Certificate::kPublicKeyTypeRSA; break; case dsaKey: *type = X509Certificate::kPublicKeyTypeDSA; break; case dhKey: *type = X509Certificate::kPublicKeyTypeDH; break; case ecKey: *type = X509Certificate::kPublicKeyTypeECDSA; break; default: *type = X509Certificate::kPublicKeyTypeUnknown; *size_bits = 0; break; } } bool GetIssuersFromEncodedList( const std::vector<std::string>& encoded_issuers, PLArenaPool* arena, std::vector<CERTName*>* out) { std::vector<CERTName*> result; for (size_t n = 0; n < encoded_issuers.size(); ++n) { CERTName* name = CreateCertNameFromEncoded(arena, encoded_issuers[n]); if (name != NULL) result.push_back(name); } if (result.size() == encoded_issuers.size()) { out->swap(result); return true; } for (size_t n = 0; n < result.size(); ++n) CERT_DestroyName(result[n]); return false; } bool IsCertificateIssuedBy(const std::vector<CERTCertificate*>& cert_chain, const std::vector<CERTName*>& valid_issuers) { for (size_t n = 0; n < cert_chain.size(); ++n) { CERTName* cert_issuer = &cert_chain[n]->issuer; for (size_t i = 0; i < valid_issuers.size(); ++i) { if (CERT_CompareName(valid_issuers[i], cert_issuer) == SECEqual) return true; } } return false; } std::string GetUniqueNicknameForSlot(const std::string& nickname, const SECItem* subject, PK11SlotInfo* slot) { int index = 2; std::string new_name = nickname; std::string temp_nickname = new_name; std::string token_name; if (!slot) return new_name; if (!PK11_IsInternalKeySlot(slot)) { token_name.assign(PK11_GetTokenName(slot)); token_name.append(":"); temp_nickname = token_name + new_name; } while (SEC_CertNicknameConflict(temp_nickname.c_str(), const_cast<SECItem*>(subject), CERT_GetDefaultCertDB())) { base::SStringPrintf(&new_name, "%s #%d", nickname.c_str(), index++); temp_nickname = token_name + new_name; } return new_name; } #endif // defined(USE_NSS) || defined(OS_IOS) } // namespace x509_util } // namespace net