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/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/**
* Copyright (c) 2013-2017 Regents of the University of California.
*
* This file is part of ndn-cxx library (NDN C++ library with eXperimental eXtensions).
*
* ndn-cxx library is free software: you can redistribute it and/or modify it under the
* terms of the GNU Lesser General Public License as published by the Free Software
* Foundation, either version 3 of the License, or (at your option) any later version.
*
* ndn-cxx library is distributed in the hope that it will be useful, but WITHOUT ANY
* WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A
* PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details.
*
* You should have received copies of the GNU General Public License and GNU Lesser
* General Public License along with ndn-cxx, e.g., in COPYING.md file. If not, see
* <http://www.gnu.org/licenses/>.
*
* See AUTHORS.md for complete list of ndn-cxx authors and contributors.
*/
#include "key-chain.hpp"
#include "../../util/config-file.hpp"
#include "../pib/pib-sqlite3.hpp"
#include "../pib/pib-memory.hpp"
#ifdef NDN_CXX_HAVE_OSX_SECURITY
#include "../tpm/back-end-osx.hpp"
#endif // NDN_CXX_HAVE_OSX_SECURITY
#include "../tpm/back-end-file.hpp"
#include "../tpm/back-end-mem.hpp"
#include "../transform/bool-sink.hpp"
#include "../transform/buffer-source.hpp"
#include "../transform/private-key.hpp"
#include "../transform/verifier-filter.hpp"
#include "../../encoding/buffer-stream.hpp"
#include "../../util/crypto.hpp"
#include <boost/lexical_cast.hpp>
namespace ndn {
namespace security {
// When static library is used, not everything is compiled into the resulting binary.
// Therefore, the following standard PIB and TPMs need to be registered here.
// http://stackoverflow.com/q/9459980/2150331
/////////
// PIB //
/////////
namespace pib {
NDN_CXX_V2_KEYCHAIN_REGISTER_PIB_BACKEND(PibSqlite3);
NDN_CXX_V2_KEYCHAIN_REGISTER_PIB_BACKEND(PibMemory);
} // namespace pib
/////////
// TPM //
/////////
namespace tpm {
#if defined(NDN_CXX_HAVE_OSX_SECURITY) && defined(NDN_CXX_WITH_OSX_KEYCHAIN)
NDN_CXX_V2_KEYCHAIN_REGISTER_TPM_BACKEND(BackEndOsx);
#endif // defined(NDN_CXX_HAVE_OSX_SECURITY) && defined(NDN_CXX_WITH_OSX_KEYCHAIN)
NDN_CXX_V2_KEYCHAIN_REGISTER_TPM_BACKEND(BackEndFile);
NDN_CXX_V2_KEYCHAIN_REGISTER_TPM_BACKEND(BackEndMem);
} // namespace tpm
namespace v2 {
std::string KeyChain::s_defaultPibLocator;
std::string KeyChain::s_defaultTpmLocator;
KeyChain::PibFactories&
KeyChain::getPibFactories()
{
static PibFactories pibFactories;
return pibFactories;
}
KeyChain::TpmFactories&
KeyChain::getTpmFactories()
{
static TpmFactories tpmFactories;
return tpmFactories;
}
const std::string&
KeyChain::getDefaultPibScheme()
{
return pib::PibSqlite3::getScheme();;
}
const std::string&
KeyChain::getDefaultTpmScheme()
{
#if defined(NDN_CXX_HAVE_OSX_SECURITY) && defined(NDN_CXX_WITH_OSX_KEYCHAIN)
return tpm::BackEndOsx::getScheme();;
#else
return tpm::BackEndFile::getScheme();
#endif // defined(NDN_CXX_HAVE_OSX_SECURITY) && defined(NDN_CXX_WITH_OSX_KEYCHAIN)
}
const std::string&
KeyChain::getDefaultPibLocator()
{
if (!s_defaultPibLocator.empty())
return s_defaultPibLocator;
if (getenv("NDN_CLIENT_PIB") != nullptr) {
s_defaultPibLocator = getenv("NDN_CLIENT_PIB");
}
else {
ConfigFile config;
s_defaultPibLocator = config.getParsedConfiguration().get<std::string>("pib", getDefaultPibScheme() + ":");
}
return s_defaultPibLocator;
}
const std::string&
KeyChain::getDefaultTpmLocator()
{
if (!s_defaultTpmLocator.empty())
return s_defaultTpmLocator;
if (getenv("NDN_CLIENT_TPM") != nullptr) {
s_defaultTpmLocator = getenv("NDN_CLIENT_TPM");
}
else {
ConfigFile config;
s_defaultTpmLocator = config.getParsedConfiguration().get<std::string>("tpm", getDefaultTpmScheme() + ":");
}
return s_defaultTpmLocator;
}
// Other defaults
const SigningInfo&
KeyChain::getDefaultSigningInfo()
{
static SigningInfo signingInfo;
return signingInfo;
}
const KeyParams&
KeyChain::getDefaultKeyParams()
{
static EcdsaKeyParams keyParams;
return keyParams;
}
//
KeyChain::KeyChain()
: KeyChain(getDefaultPibLocator(), getDefaultTpmLocator(), true)
{
}
KeyChain::KeyChain(const std::string& pibLocator, const std::string& tpmLocator, bool allowReset)
{
// PIB Locator
std::string pibScheme, pibLocation;
std::tie(pibScheme, pibLocation) = parseAndCheckPibLocator(pibLocator);
std::string canonicalPibLocator = pibScheme + ":" + pibLocation;
// Create PIB
m_pib = createPib(canonicalPibLocator);
std::string oldTpmLocator;
try {
oldTpmLocator = m_pib->getTpmLocator();
}
catch (const Pib::Error&) {
// TPM locator is not set in PIB yet.
}
// TPM Locator
std::string tpmScheme, tpmLocation;
std::tie(tpmScheme, tpmLocation) = parseAndCheckTpmLocator(tpmLocator);
std::string canonicalTpmLocator = tpmScheme + ":" + tpmLocation;
if (canonicalPibLocator == getDefaultPibLocator()) {
// Default PIB must use default TPM
if (!oldTpmLocator.empty() && oldTpmLocator != getDefaultTpmLocator()) {
m_pib->reset();
canonicalTpmLocator = getDefaultTpmLocator();
}
}
else {
// non-default PIB check consistency
if (!oldTpmLocator.empty() && oldTpmLocator != canonicalTpmLocator) {
if (allowReset)
m_pib->reset();
else
BOOST_THROW_EXCEPTION(LocatorMismatchError("TPM locator supplied does not match TPM locator in PIB: " +
oldTpmLocator + " != " + canonicalTpmLocator));
}
}
// note that key mismatch may still happen if the TPM locator is initially set to a
// wrong one or if the PIB was shared by more than one TPMs before. This is due to the
// old PIB does not have TPM info, new pib should not have this problem.
m_tpm = createTpm(canonicalTpmLocator);
m_pib->setTpmLocator(canonicalTpmLocator);
}
KeyChain::~KeyChain() = default;
// public: management
Identity
KeyChain::createIdentity(const Name& identityName, const KeyParams& params)
{
Identity id = m_pib->addIdentity(identityName);
Key key;
try {
key = id.getDefaultKey();
}
catch (const Pib::Error&) {
key = createKey(id, params);
}
try {
key.getDefaultCertificate();
}
catch (const Pib::Error&) {
selfSign(key);
}
return id;
}
void
KeyChain::deleteIdentity(const Identity& identity)
{
BOOST_ASSERT(static_cast<bool>(identity));
Name identityName = identity.getName();
for (const auto& key : identity.getKeys()) {
m_tpm->deleteKey(key.getName());
}
m_pib->removeIdentity(identityName);
}
void
KeyChain::setDefaultIdentity(const Identity& identity)
{
BOOST_ASSERT(static_cast<bool>(identity));
m_pib->setDefaultIdentity(identity.getName());
}
Key
KeyChain::createKey(const Identity& identity, const KeyParams& params)
{
BOOST_ASSERT(static_cast<bool>(identity));
// create key in TPM
Name keyName = m_tpm->createKey(identity.getName(), params);
// set up key info in PIB
ConstBufferPtr pubKey = m_tpm->getPublicKey(keyName);
Key key = identity.addKey(pubKey->buf(), pubKey->size(), keyName);
selfSign(key);
return key;
}
void
KeyChain::deleteKey(const Identity& identity, const Key& key)
{
BOOST_ASSERT(static_cast<bool>(identity));
BOOST_ASSERT(static_cast<bool>(key));
Name keyName = key.getName();
if (identity.getName() != key.getIdentity()) {
BOOST_THROW_EXCEPTION(std::invalid_argument("Identity `" + identity.getName().toUri() + "` "
"does match key `" + keyName.toUri() + "`"));
}
identity.removeKey(keyName);
m_tpm->deleteKey(keyName);
}
void
KeyChain::setDefaultKey(const Identity& identity, const Key& key)
{
BOOST_ASSERT(static_cast<bool>(identity));
BOOST_ASSERT(static_cast<bool>(key));
if (identity.getName() != key.getIdentity())
BOOST_THROW_EXCEPTION(std::invalid_argument("Identity `" + identity.getName().toUri() + "` "
"does match key `" + key.getName().toUri() + "`"));
identity.setDefaultKey(key.getName());
}
void
KeyChain::addCertificate(const Key& key, const Certificate& certificate)
{
BOOST_ASSERT(static_cast<bool>(key));
if (key.getName() != certificate.getKeyName() ||
!std::equal(certificate.getContent().value_begin(), certificate.getContent().value_end(),
key.getPublicKey().begin()))
BOOST_THROW_EXCEPTION(std::invalid_argument("Key `" + key.getName().toUri() + "` "
"does match certificate `" + certificate.getName().toUri() + "`"));
key.addCertificate(certificate);
}
void
KeyChain::deleteCertificate(const Key& key, const Name& certificateName)
{
BOOST_ASSERT(static_cast<bool>(key));
if (!Certificate::isValidName(certificateName)) {
BOOST_THROW_EXCEPTION(std::invalid_argument("Wrong certificate name `" + certificateName.toUri() + "`"));
}
key.removeCertificate(certificateName);
}
void
KeyChain::setDefaultCertificate(const Key& key, const Certificate& cert)
{
BOOST_ASSERT(static_cast<bool>(key));
try {
addCertificate(key, cert);
}
catch (const Pib::Error&) { // force to overwrite the existing certificates
key.removeCertificate(cert.getName());
addCertificate(key, cert);
}
key.setDefaultCertificate(cert.getName());
}
shared_ptr<SafeBag>
KeyChain::exportSafeBag(const Certificate& certificate, const char* pw, size_t pwLen)
{
Name identity = certificate.getIdentity();
Name keyName = certificate.getKeyName();
ConstBufferPtr encryptedKey;
try {
encryptedKey = m_tpm->exportPrivateKey(keyName, pw, pwLen);
}
catch (const tpm::BackEnd::Error&) {
BOOST_THROW_EXCEPTION(Error("Private `" + keyName.toUri() + "` key does not exist"));
}
return make_shared<SafeBag>(certificate, *encryptedKey);
}
void
KeyChain::importSafeBag(const SafeBag& safeBag, const char* pw, size_t pwLen)
{
Data certData = safeBag.getCertificate();
Certificate cert(std::move(certData));
Name identity = cert.getIdentity();
Name keyName = cert.getKeyName();
const Buffer publicKeyBits = cert.getPublicKey();
if (m_tpm->hasKey(keyName)) {
BOOST_THROW_EXCEPTION(Error("Private key `" + keyName.toUri() + "` already exists"));
}
try {
Identity existingId = m_pib->getIdentity(identity);
existingId.getKey(keyName);
BOOST_THROW_EXCEPTION(Error("Public key `" + keyName.toUri() + "` already exists"));
}
catch (const Pib::Error&) {
// Either identity or key doesn't exist. OK to import.
}
try {
m_tpm->importPrivateKey(keyName,
safeBag.getEncryptedKeyBag().buf(), safeBag.getEncryptedKeyBag().size(),
pw, pwLen);
}
catch (const std::runtime_error&) {
BOOST_THROW_EXCEPTION(Error("Fail to import private key `" + keyName.toUri() + "`"));
}
// check the consistency of private key and certificate
const uint8_t content[] = {0x01, 0x02, 0x03, 0x04};
ConstBufferPtr sigBits;
try {
sigBits = m_tpm->sign(content, 4, keyName, DigestAlgorithm::SHA256);
}
catch (const std::runtime_error&) {
m_tpm->deleteKey(keyName);
BOOST_THROW_EXCEPTION(Error("Invalid private key `" + keyName.toUri() + "`"));
}
bool isVerified = false;
{
using namespace transform;
PublicKey publicKey;
publicKey.loadPkcs8(publicKeyBits.buf(), publicKeyBits.size());
bufferSource(content, sizeof(content)) >> verifierFilter(DigestAlgorithm::SHA256, publicKey,
sigBits->buf(), sigBits->size())
>> boolSink(isVerified);
}
if (!isVerified) {
m_tpm->deleteKey(keyName);
BOOST_THROW_EXCEPTION(Error("Certificate `" + cert.getName().toUri() + "` "
"and private key `" + keyName.toUri() + "` do not match"));
}
Identity id = m_pib->addIdentity(identity);
Key key = id.addKey(cert.getPublicKey().buf(), cert.getPublicKey().size(), keyName);
key.addCertificate(cert);
}
// public: signing
void
KeyChain::sign(Data& data, const SigningInfo& params)
{
Name keyName;
SignatureInfo sigInfo;
std::tie(keyName, sigInfo) = prepareSignatureInfo(params);
data.setSignature(Signature(sigInfo));
EncodingBuffer encoder;
data.wireEncode(encoder, true);
Block sigValue = sign(encoder.buf(), encoder.size(), keyName, params.getDigestAlgorithm());
data.wireEncode(encoder, sigValue);
}
void
KeyChain::sign(Interest& interest, const SigningInfo& params)
{
Name keyName;
SignatureInfo sigInfo;
std::tie(keyName, sigInfo) = prepareSignatureInfo(params);
Name signedName = interest.getName();
signedName.append(sigInfo.wireEncode()); // signatureInfo
Block sigValue = sign(signedName.wireEncode().value(), signedName.wireEncode().value_size(),
keyName, params.getDigestAlgorithm());
sigValue.encode();
signedName.append(sigValue); // signatureValue
interest.setName(signedName);
}
Block
KeyChain::sign(const uint8_t* buffer, size_t bufferLength, const SigningInfo& params)
{
Name keyName;
SignatureInfo sigInfo;
std::tie(keyName, sigInfo) = prepareSignatureInfo(params);
return sign(buffer, bufferLength, keyName, params.getDigestAlgorithm());
}
// public: PIB/TPM creation helpers
static inline std::tuple<std::string/*type*/, std::string/*location*/>
parseLocatorUri(const std::string& uri)
{
size_t pos = uri.find(':');
if (pos != std::string::npos) {
return std::make_tuple(uri.substr(0, pos), uri.substr(pos + 1));
}
else {
return std::make_tuple(uri, "");
}
}
std::tuple<std::string/*type*/, std::string/*location*/>
KeyChain::parseAndCheckPibLocator(const std::string& pibLocator)
{
std::string pibScheme, pibLocation;
std::tie(pibScheme, pibLocation) = parseLocatorUri(pibLocator);
if (pibScheme.empty()) {
pibScheme = getDefaultPibScheme();
}
auto pibFactory = getPibFactories().find(pibScheme);
if (pibFactory == getPibFactories().end()) {
BOOST_THROW_EXCEPTION(KeyChain::Error("PIB scheme `" + pibScheme + "` is not supported"));
}
return std::make_tuple(pibScheme, pibLocation);
}
unique_ptr<Pib>
KeyChain::createPib(const std::string& pibLocator)
{
std::string pibScheme, pibLocation;
std::tie(pibScheme, pibLocation) = parseAndCheckPibLocator(pibLocator);
auto pibFactory = getPibFactories().find(pibScheme);
BOOST_ASSERT(pibFactory != getPibFactories().end());
return unique_ptr<Pib>(new Pib(pibScheme, pibLocation, pibFactory->second(pibLocation)));
}
std::tuple<std::string/*type*/, std::string/*location*/>
KeyChain::parseAndCheckTpmLocator(const std::string& tpmLocator)
{
std::string tpmScheme, tpmLocation;
std::tie(tpmScheme, tpmLocation) = parseLocatorUri(tpmLocator);
if (tpmScheme.empty()) {
tpmScheme = getDefaultTpmScheme();
}
auto tpmFactory = getTpmFactories().find(tpmScheme);
if (tpmFactory == getTpmFactories().end()) {
BOOST_THROW_EXCEPTION(KeyChain::Error("TPM scheme `" + tpmScheme + "` is not supported"));
}
return std::make_tuple(tpmScheme, tpmLocation);
}
unique_ptr<Tpm>
KeyChain::createTpm(const std::string& tpmLocator)
{
std::string tpmScheme, tpmLocation;
std::tie(tpmScheme, tpmLocation) = parseAndCheckTpmLocator(tpmLocator);
auto tpmFactory = getTpmFactories().find(tpmScheme);
BOOST_ASSERT(tpmFactory != getTpmFactories().end());
return unique_ptr<Tpm>(new Tpm(tpmScheme, tpmLocation, tpmFactory->second(tpmLocation)));
}
// private: signing
Certificate
KeyChain::selfSign(Key& key)
{
Certificate certificate;
// set name
Name certificateName = key.getName();
certificateName
.append("self")
.appendVersion();
certificate.setName(certificateName);
// set metainfo
certificate.setContentType(tlv::ContentType_Key);
certificate.setFreshnessPeriod(time::hours(1));
// set content
certificate.setContent(key.getPublicKey().buf(), key.getPublicKey().size());
// set signature-info
SignatureInfo sigInfo;
sigInfo.setKeyLocator(key.getName());
sigInfo.setSignatureType(getSignatureType(key.getKeyType(), DigestAlgorithm::SHA256));
sigInfo.setValidityPeriod(ValidityPeriod(time::system_clock::now(),
time::system_clock::now() + time::days(1000 * 3365)));
certificate.setSignature(Signature(sigInfo));
EncodingBuffer encoder;
certificate.wireEncode(encoder, true);
Block sigValue = sign(encoder.buf(), encoder.size(), key.getName(), DigestAlgorithm::SHA256);
certificate.wireEncode(encoder, sigValue);
key.addCertificate(certificate);
return certificate;
}
std::tuple<Name, SignatureInfo>
KeyChain::prepareSignatureInfo(const SigningInfo& params)
{
SignatureInfo sigInfo = params.getSignatureInfo();
Name identityName;
name::Component keyId;
Name certificateName;
pib::Identity identity;
pib::Key key;
switch (params.getSignerType()) {
case SigningInfo::SIGNER_TYPE_NULL: {
try {
identity = m_pib->getDefaultIdentity();
}
catch (const Pib::Error&) { // no default identity, use sha256 for signing.
sigInfo.setSignatureType(tlv::DigestSha256);
return std::make_tuple(SigningInfo::getDigestSha256Identity(), sigInfo);
}
break;
}
case SigningInfo::SIGNER_TYPE_ID: {
try {
identity = m_pib->getIdentity(params.getSignerName());
}
catch (const Pib::Error&) {
BOOST_THROW_EXCEPTION(InvalidSigningInfoError("Signing identity `" +
params.getSignerName().toUri() + "` does not exist"));
}
break;
}
case SigningInfo::SIGNER_TYPE_KEY: {
Name identityName = extractIdentityFromKeyName(params.getSignerName());
try {
identity = m_pib->getIdentity(identityName);
key = identity.getKey(params.getSignerName());
identity = Identity(); // we will use the PIB key instance, so reset identity;
}
catch (const Pib::Error&) {
BOOST_THROW_EXCEPTION(InvalidSigningInfoError("Signing key `" +
params.getSignerName().toUri() + "` does not exist"));
}
break;
}
case SigningInfo::SIGNER_TYPE_CERT: {
Name identityName = extractIdentityFromCertName(params.getSignerName());
Name keyName = extractKeyNameFromCertName(params.getSignerName());
try {
identity = m_pib->getIdentity(identityName);
key = identity.getKey(keyName);
}
catch (const Pib::Error&) {
BOOST_THROW_EXCEPTION(InvalidSigningInfoError("Signing certificate `" +
params.getSignerName().toUri() + "` does not exist"));
}
break;
}
case SigningInfo::SIGNER_TYPE_SHA256: {
sigInfo.setSignatureType(tlv::DigestSha256);
return std::make_tuple(SigningInfo::getDigestSha256Identity(), sigInfo);
}
case SigningInfo::SIGNER_TYPE_PIB_ID: {
identity = params.getPibIdentity();
if (!identity)
BOOST_THROW_EXCEPTION(InvalidSigningInfoError("PIB Identity is invalid"));
break;
}
case SigningInfo::SIGNER_TYPE_PIB_KEY: {
key = params.getPibKey();
if (!key)
BOOST_THROW_EXCEPTION(InvalidSigningInfoError("PIB Key is invalid"));
break;
}
default: {
BOOST_THROW_EXCEPTION(InvalidSigningInfoError("Unrecognized signer type " +
boost::lexical_cast<std::string>(params.getSignerType())));
}
}
if (!identity && !key) {
BOOST_THROW_EXCEPTION(InvalidSigningInfoError("Cannot determine signing parameters"));
}
if (identity && !key) {
try {
key = identity.getDefaultKey();
}
catch (const Pib::Error&) {
BOOST_THROW_EXCEPTION(InvalidSigningInfoError("Signing identity `" + identity.getName().toUri() +
"` does not have default certificate"));
}
}
BOOST_ASSERT(key);
sigInfo.setSignatureType(getSignatureType(key.getKeyType(), params.getDigestAlgorithm()));
sigInfo.setKeyLocator(KeyLocator(key.getName()));
return std::make_tuple(key.getName(), sigInfo);
}
Block
KeyChain::sign(const uint8_t* buf, size_t size,
const Name& keyName, DigestAlgorithm digestAlgorithm) const
{
if (keyName == SigningInfo::getDigestSha256Identity())
return Block(tlv::SignatureValue, crypto::sha256(buf, size));
return Block(tlv::SignatureValue, m_tpm->sign(buf, size, keyName, digestAlgorithm));
}
tlv::SignatureTypeValue
KeyChain::getSignatureType(KeyType keyType, DigestAlgorithm digestAlgorithm)
{
switch (keyType) {
case KeyType::RSA:
return tlv::SignatureSha256WithRsa;
case KeyType::EC:
return tlv::SignatureSha256WithEcdsa;
default:
BOOST_THROW_EXCEPTION(Error("Unsupported key types"));
}
}
} // namespace v2
} // namespace security
} // namespace ndn