src/security/transform/private-key.cpp - ndn-cxx - Gitiles

 /* -*- 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 "private-key.hpp"
 #include "buffer-source.hpp"
 #include "stream-source.hpp"
 #include "base64-encode.hpp"
 #include "base64-decode.hpp"
 #include "stream-sink.hpp"
 #include "../../encoding/buffer-stream.hpp"
 #include "../detail/openssl-helper.hpp"
 #include "../key-params.hpp"

 #include <string.h>

 #define ENSURE_PRIVATE_KEY_LOADED(key) \
   do { \
     if (key == nullptr) \
       BOOST_THROW_EXCEPTION(Error("Private key has not been loaded yet")); \
   } while (false)

 namespace ndn {
 namespace security {
 namespace transform {

 class PrivateKey::Impl
 {
 public:
   Impl()
     : key(nullptr)
   {
   }

   ~Impl()
   {
     EVP_PKEY_free(key);
   }

 public:
   EVP_PKEY* key;
 };

 PrivateKey::PrivateKey()
   : m_impl(new Impl)
 {
 }

 PrivateKey::~PrivateKey() = default;

 void
 PrivateKey::loadPkcs1(const uint8_t* buf, size_t size)
 {
   detail::Bio mem(BIO_s_mem());
   BIO_write(mem.get(), buf, size);

   d2i_PrivateKey_bio(mem.get(), &m_impl->key);

   ENSURE_PRIVATE_KEY_LOADED(m_impl->key);
 }

 void
 PrivateKey::loadPkcs1(std::istream& is)
 {
   OBufferStream os;
   streamSource(is) >> streamSink(os);
   this->loadPkcs1(os.buf()->buf(), os.buf()->size());
 }

 void
 PrivateKey::loadPkcs1Base64(const uint8_t* buf, size_t size)
 {
   OBufferStream os;
   bufferSource(buf, size) >> base64Decode() >> streamSink(os);
   this->loadPkcs1(os.buf()->buf(), os.buf()->size());
 }

 void
 PrivateKey::loadPkcs1Base64(std::istream& is)
 {
   OBufferStream os;
   streamSource(is) >> base64Decode() >> streamSink(os);
   this->loadPkcs1(os.buf()->buf(), os.buf()->size());
 }

 void
 PrivateKey::loadPkcs8(const uint8_t* buf, size_t size, const char* pw, size_t pwLen)
 {
   BOOST_ASSERT(std::strlen(pw) == pwLen);

   detail::Bio mem(BIO_s_mem());
   BIO_write(mem.get(), buf, size);

   m_impl->key = d2i_PKCS8PrivateKey_bio(mem.get(), &m_impl->key, nullptr, const_cast<char*>(pw));

   ENSURE_PRIVATE_KEY_LOADED(m_impl->key);
 }

 static inline int
 passwordCallback(char* buf, int size, int rwflag, void* u)
 {
   auto cb = reinterpret_cast<PrivateKey::PasswordCallback*>(u);
   return (*cb)(buf, size, rwflag);
 }

 void
 PrivateKey::loadPkcs8(const uint8_t* buf, size_t size, PasswordCallback pwCallback)
 {
   OpenSSL_add_all_algorithms();
   detail::Bio mem(BIO_s_mem());
   BIO_write(mem.get(), buf, size);

   if (pwCallback)
     m_impl->key = d2i_PKCS8PrivateKey_bio(mem.get(), &m_impl->key, passwordCallback, &pwCallback);
   else
     m_impl->key = d2i_PKCS8PrivateKey_bio(mem.get(), &m_impl->key, nullptr, nullptr);

   ENSURE_PRIVATE_KEY_LOADED(m_impl->key);
 }

 void
 PrivateKey::loadPkcs8(std::istream& is, const char* pw, size_t pwLen)
 {
   OBufferStream os;
   streamSource(is) >> streamSink(os);
   this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pw, pwLen);
 }

 void
 PrivateKey::loadPkcs8(std::istream& is, PasswordCallback pwCallback)
 {
   OBufferStream os;
   streamSource(is) >> streamSink(os);
   this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pwCallback);
 }

 void
 PrivateKey::loadPkcs8Base64(const uint8_t* buf, size_t size, const char* pw, size_t pwLen)
 {
   OBufferStream os;
   bufferSource(buf, size) >> base64Decode() >> streamSink(os);
   this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pw, pwLen);
 }

 void
 PrivateKey::loadPkcs8Base64(const uint8_t* buf, size_t size, PasswordCallback pwCallback)
 {
   OBufferStream os;
   bufferSource(buf, size) >> base64Decode() >> streamSink(os);
   this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pwCallback);
 }

 void
 PrivateKey::loadPkcs8Base64(std::istream& is, const char* pw, size_t pwLen)
 {
   OBufferStream os;
   streamSource(is) >> base64Decode() >> streamSink(os);
   this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pw, pwLen);
 }

 void
 PrivateKey::loadPkcs8Base64(std::istream& is, PasswordCallback pwCallback)
 {
   OBufferStream os;
   streamSource(is) >> base64Decode() >> streamSink(os);
   this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pwCallback);
 }

 void
 PrivateKey::savePkcs1(std::ostream& os) const
 {
   bufferSource(*this->toPkcs1()) >> streamSink(os);
 }

 void
 PrivateKey::savePkcs1Base64(std::ostream& os) const
 {
   bufferSource(*this->toPkcs1()) >> base64Encode() >> streamSink(os);
 }

 void
 PrivateKey::savePkcs8(std::ostream& os, const char* pw, size_t pwLen) const
 {
   bufferSource(*this->toPkcs8(pw, pwLen)) >> streamSink(os);
 }

 void
 PrivateKey::savePkcs8(std::ostream& os, PasswordCallback pwCallback) const
 {
   bufferSource(*this->toPkcs8(pwCallback)) >> streamSink(os);
 }

 void
 PrivateKey::savePkcs8Base64(std::ostream& os, const char* pw, size_t pwLen) const
 {
   bufferSource(*this->toPkcs8(pw, pwLen)) >> base64Encode() >> streamSink(os);
 }

 void
 PrivateKey::savePkcs8Base64(std::ostream& os, PasswordCallback pwCallback) const
 {
   bufferSource(*this->toPkcs8(pwCallback)) >> base64Encode() >> streamSink(os);
 }

 ConstBufferPtr
 PrivateKey::derivePublicKey() const
 {
   ENSURE_PRIVATE_KEY_LOADED(m_impl->key);

   uint8_t* pkcs8 = nullptr;
   int len = i2d_PUBKEY(m_impl->key, &pkcs8);

   if (len <= 0)
     BOOST_THROW_EXCEPTION(Error("Failed to derive public key"));

   auto result = make_shared<Buffer>(pkcs8, len);
   OPENSSL_free(pkcs8);

   return result;
 }

 ConstBufferPtr
 PrivateKey::decrypt(const uint8_t* cipherText, size_t cipherLen) const
 {
   ENSURE_PRIVATE_KEY_LOADED(m_impl->key);

 #if OPENSSL_VERSION_NUMBER < 0x1010000fL
   switch (EVP_PKEY_type(m_impl->key->type)) {
 #else
   switch (EVP_PKEY_base_id(m_impl->key)) {
 #endif // OPENSSL_VERSION_NUMBER < 0x1010000fL
   case EVP_PKEY_RSA:
     return rsaDecrypt(cipherText, cipherLen);
   default:
     BOOST_THROW_EXCEPTION(Error("Decryption is not supported for this key type"));
   }
 }

 void*
 PrivateKey::getEvpPkey() const
 {
   return m_impl->key;
 }

 ConstBufferPtr
 PrivateKey::toPkcs1() const
 {
   ENSURE_PRIVATE_KEY_LOADED(m_impl->key);

   OpenSSL_add_all_algorithms();
   detail::Bio mem(BIO_s_mem());
   int ret = i2d_PrivateKey_bio(mem.get(), m_impl->key);
   if (ret != 1)
     BOOST_THROW_EXCEPTION(Error("Cannot convert key into PKCS1 format"));

   int len8 = BIO_pending(mem.get());
   auto buffer = make_shared<Buffer>(len8);
   BIO_read(mem.get(), buffer->buf(), len8);

   return buffer;
 }

 ConstBufferPtr
 PrivateKey::toPkcs8(const char* pw, size_t pwLen) const
 {
   ENSURE_PRIVATE_KEY_LOADED(m_impl->key);

   BOOST_ASSERT(std::strlen(pw) == pwLen);

   OpenSSL_add_all_algorithms();
   detail::Bio mem(BIO_s_mem());
   int ret = i2d_PKCS8PrivateKey_bio(mem.get(), m_impl->key, EVP_des_cbc(),
                                     const_cast<char*>(pw), pwLen, nullptr, nullptr);
   if (ret != 1)
     BOOST_THROW_EXCEPTION(Error("Cannot convert key into PKCS8 format"));

   int len8 = BIO_pending(mem.get());
   auto buffer = make_shared<Buffer>(len8);
   BIO_read(mem.get(), buffer->buf(), len8);

   return buffer;
 }

 ConstBufferPtr
 PrivateKey::toPkcs8(PasswordCallback pwCallback) const
 {
   ENSURE_PRIVATE_KEY_LOADED(m_impl->key);

   OpenSSL_add_all_algorithms();
   detail::Bio mem(BIO_s_mem());
   int ret = i2d_PKCS8PrivateKey_bio(mem.get(), m_impl->key, EVP_des_cbc(),
                                     nullptr, 0,
                                     passwordCallback, &pwCallback);
   if (ret != 1)
     BOOST_THROW_EXCEPTION(Error("Cannot convert key into PKCS8 format"));

   int len8 = BIO_pending(mem.get());
   auto buffer = make_shared<Buffer>(len8);
   BIO_read(mem.get(), buffer->buf(), len8);

   return buffer;
 }

 ConstBufferPtr
 PrivateKey::rsaDecrypt(const uint8_t* cipherText, size_t cipherLen) const
 {
   detail::EvpPkeyCtx ctx(m_impl->key);

   if (EVP_PKEY_decrypt_init(ctx.get()) <= 0)
     BOOST_THROW_EXCEPTION(Error("Failed to initialize decryption context"));

   if (EVP_PKEY_CTX_set_rsa_padding(ctx.get(), RSA_PKCS1_OAEP_PADDING) <= 0)
     BOOST_THROW_EXCEPTION(Error("Failed to set padding"));

   size_t outlen = 0;
   // Determine buffer length
   if (EVP_PKEY_decrypt(ctx.get(), nullptr, &outlen, cipherText, cipherLen) <= 0)
     BOOST_THROW_EXCEPTION(Error("Failed to estimate output length"));

   auto out = make_shared<Buffer>(outlen);

   if (EVP_PKEY_decrypt(ctx.get(), out->buf(), &outlen, cipherText, cipherLen) <= 0)
     BOOST_THROW_EXCEPTION(Error("Failed to decrypt cipher text"));

   out->resize(outlen);
   return out;
 }

 static unique_ptr<PrivateKey>
 generateRsaKey(uint32_t keySize)
 {
   detail::EvpPkeyCtx kctx(EVP_PKEY_RSA);

   int ret = EVP_PKEY_keygen_init(kctx.get());
   if (ret != 1)
     BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate RSA key"));

   ret = EVP_PKEY_CTX_set_rsa_keygen_bits(kctx.get(), keySize);
   if (ret != 1)
     BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate RSA key"));

   detail::EvpPkey key;
   ret = EVP_PKEY_keygen(kctx.get(), &key);
   if (ret != 1)
     BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate RSA key"));

   detail::Bio mem(BIO_s_mem());
   i2d_PrivateKey_bio(mem.get(), key.get());
   int len = BIO_pending(mem.get());
   Buffer buffer(len);
   BIO_read(mem.get(), buffer.buf(), len);

   auto privateKey = make_unique<PrivateKey>();
   privateKey->loadPkcs1(buffer.buf(), buffer.size());

   return privateKey;
 }

 static unique_ptr<PrivateKey>
 generateEcKey(uint32_t keySize)
 {
   detail::EvpPkeyCtx ctx(EVP_PKEY_EC);

   int ret = EVP_PKEY_paramgen_init(ctx.get());
   if (ret != 1)
     BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));

   switch (keySize) {
     case 256:
       ret = EVP_PKEY_CTX_set_ec_paramgen_curve_nid(ctx.get(), NID_X9_62_prime256v1);
       break;
     case 384:
       ret = EVP_PKEY_CTX_set_ec_paramgen_curve_nid(ctx.get(), NID_secp384r1);
       break;
     default:
       BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));
   }
   if (ret != 1)
     BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));

   detail::EvpPkey params;
   ret = EVP_PKEY_paramgen(ctx.get(), &params);
   if (ret != 1)
     BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));

   detail::EvpPkeyCtx kctx(params.get());
   ret = EVP_PKEY_keygen_init(kctx.get());
   if (ret != 1)
     BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));

   detail::EvpPkey key;
   ret = EVP_PKEY_keygen(kctx.get(), &key);
   if (ret != 1)
     BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));

   detail::Bio mem(BIO_s_mem());
   i2d_PrivateKey_bio(mem.get(), key.get());
   int len = BIO_pending(mem.get());
   Buffer buffer(len);
   BIO_read(mem.get(), buffer.buf(), len);

   auto privateKey = make_unique<PrivateKey>();
   privateKey->loadPkcs1(buffer.buf(), buffer.size());

   return privateKey;
 }

 unique_ptr<PrivateKey>
 generatePrivateKey(const KeyParams& keyParams)
 {
   switch (keyParams.getKeyType()) {
     case KeyType::RSA: {
       const RsaKeyParams& rsaParams = static_cast<const RsaKeyParams&>(keyParams);
       return generateRsaKey(rsaParams.getKeySize());
     }
     case KeyType::EC: {
       const EcKeyParams& ecParams = static_cast<const EcKeyParams&>(keyParams);
       return generateEcKey(ecParams.getKeySize());
     }
     default:
       BOOST_THROW_EXCEPTION(std::invalid_argument("Unsupported asymmetric key type"));
   }
 }

 } // namespace transform
 } // namespace security
 } // namespace ndn
	/* -- 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 "private-key.hpp"
	#include "buffer-source.hpp"
	#include "stream-source.hpp"
	#include "base64-encode.hpp"
	#include "base64-decode.hpp"
	#include "stream-sink.hpp"
	#include "../../encoding/buffer-stream.hpp"
	#include "../detail/openssl-helper.hpp"
	#include "../key-params.hpp"

	#include <string.h>

	#define ENSURE_PRIVATE_KEY_LOADED(key) \
	do { \
	if (key == nullptr) \
	BOOST_THROW_EXCEPTION(Error("Private key has not been loaded yet")); \
	} while (false)

	namespace ndn {
	namespace security {
	namespace transform {

	class PrivateKey::Impl
	{
	public:
	Impl()
	: key(nullptr)
	{
	}

	~Impl()
	{
	EVP_PKEY_free(key);
	}

	public:
	EVP_PKEY* key;
	};

	PrivateKey::PrivateKey()
	: m_impl(new Impl)
	{
	}

	PrivateKey::~PrivateKey() = default;

	void
	PrivateKey::loadPkcs1(const uint8_t* buf, size_t size)
	{
	detail::Bio mem(BIO_s_mem());
	BIO_write(mem.get(), buf, size);

	d2i_PrivateKey_bio(mem.get(), &m_impl->key);

	ENSURE_PRIVATE_KEY_LOADED(m_impl->key);
	}

	void
	PrivateKey::loadPkcs1(std::istream& is)
	{
	OBufferStream os;
	streamSource(is) >> streamSink(os);
	this->loadPkcs1(os.buf()->buf(), os.buf()->size());
	}

	void
	PrivateKey::loadPkcs1Base64(const uint8_t* buf, size_t size)
	{
	OBufferStream os;
	bufferSource(buf, size) >> base64Decode() >> streamSink(os);
	this->loadPkcs1(os.buf()->buf(), os.buf()->size());
	}

	void
	PrivateKey::loadPkcs1Base64(std::istream& is)
	{
	OBufferStream os;
	streamSource(is) >> base64Decode() >> streamSink(os);
	this->loadPkcs1(os.buf()->buf(), os.buf()->size());
	}

	void
	PrivateKey::loadPkcs8(const uint8_t* buf, size_t size, const char* pw, size_t pwLen)
	{
	BOOST_ASSERT(std::strlen(pw) == pwLen);

	detail::Bio mem(BIO_s_mem());
	BIO_write(mem.get(), buf, size);

	m_impl->key = d2i_PKCS8PrivateKey_bio(mem.get(), &m_impl->key, nullptr, const_cast<char*>(pw));

	ENSURE_PRIVATE_KEY_LOADED(m_impl->key);
	}

	static inline int
	passwordCallback(char* buf, int size, int rwflag, void* u)
	{
	auto cb = reinterpret_cast<PrivateKey::PasswordCallback*>(u);
	return (*cb)(buf, size, rwflag);
	}

	void
	PrivateKey::loadPkcs8(const uint8_t* buf, size_t size, PasswordCallback pwCallback)
	{
	OpenSSL_add_all_algorithms();
	detail::Bio mem(BIO_s_mem());
	BIO_write(mem.get(), buf, size);

	if (pwCallback)
	m_impl->key = d2i_PKCS8PrivateKey_bio(mem.get(), &m_impl->key, passwordCallback, &pwCallback);
	else
	m_impl->key = d2i_PKCS8PrivateKey_bio(mem.get(), &m_impl->key, nullptr, nullptr);

	ENSURE_PRIVATE_KEY_LOADED(m_impl->key);
	}

	void
	PrivateKey::loadPkcs8(std::istream& is, const char* pw, size_t pwLen)
	{
	OBufferStream os;
	streamSource(is) >> streamSink(os);
	this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pw, pwLen);
	}

	void
	PrivateKey::loadPkcs8(std::istream& is, PasswordCallback pwCallback)
	{
	OBufferStream os;
	streamSource(is) >> streamSink(os);
	this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pwCallback);
	}

	void
	PrivateKey::loadPkcs8Base64(const uint8_t* buf, size_t size, const char* pw, size_t pwLen)
	{
	OBufferStream os;
	bufferSource(buf, size) >> base64Decode() >> streamSink(os);
	this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pw, pwLen);
	}

	void
	PrivateKey::loadPkcs8Base64(const uint8_t* buf, size_t size, PasswordCallback pwCallback)
	{
	OBufferStream os;
	bufferSource(buf, size) >> base64Decode() >> streamSink(os);
	this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pwCallback);
	}

	void
	PrivateKey::loadPkcs8Base64(std::istream& is, const char* pw, size_t pwLen)
	{
	OBufferStream os;
	streamSource(is) >> base64Decode() >> streamSink(os);
	this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pw, pwLen);
	}

	void
	PrivateKey::loadPkcs8Base64(std::istream& is, PasswordCallback pwCallback)
	{
	OBufferStream os;
	streamSource(is) >> base64Decode() >> streamSink(os);
	this->loadPkcs8(os.buf()->buf(), os.buf()->size(), pwCallback);
	}

	void
	PrivateKey::savePkcs1(std::ostream& os) const
	{
	bufferSource(*this->toPkcs1()) >> streamSink(os);
	}

	void
	PrivateKey::savePkcs1Base64(std::ostream& os) const
	{
	bufferSource(*this->toPkcs1()) >> base64Encode() >> streamSink(os);
	}

	void
	PrivateKey::savePkcs8(std::ostream& os, const char* pw, size_t pwLen) const
	{
	bufferSource(*this->toPkcs8(pw, pwLen)) >> streamSink(os);
	}

	void
	PrivateKey::savePkcs8(std::ostream& os, PasswordCallback pwCallback) const
	{
	bufferSource(*this->toPkcs8(pwCallback)) >> streamSink(os);
	}

	void
	PrivateKey::savePkcs8Base64(std::ostream& os, const char* pw, size_t pwLen) const
	{
	bufferSource(*this->toPkcs8(pw, pwLen)) >> base64Encode() >> streamSink(os);
	}

	void
	PrivateKey::savePkcs8Base64(std::ostream& os, PasswordCallback pwCallback) const
	{
	bufferSource(*this->toPkcs8(pwCallback)) >> base64Encode() >> streamSink(os);
	}

	ConstBufferPtr
	PrivateKey::derivePublicKey() const
	{
	ENSURE_PRIVATE_KEY_LOADED(m_impl->key);

	uint8_t* pkcs8 = nullptr;
	int len = i2d_PUBKEY(m_impl->key, &pkcs8);

	if (len <= 0)
	BOOST_THROW_EXCEPTION(Error("Failed to derive public key"));

	auto result = make_shared<Buffer>(pkcs8, len);
	OPENSSL_free(pkcs8);

	return result;
	}

	ConstBufferPtr
	PrivateKey::decrypt(const uint8_t* cipherText, size_t cipherLen) const
	{
	ENSURE_PRIVATE_KEY_LOADED(m_impl->key);

	#if OPENSSL_VERSION_NUMBER < 0x1010000fL
	switch (EVP_PKEY_type(m_impl->key->type)) {
	#else
	switch (EVP_PKEY_base_id(m_impl->key)) {
	#endif // OPENSSL_VERSION_NUMBER < 0x1010000fL
	case EVP_PKEY_RSA:
	return rsaDecrypt(cipherText, cipherLen);
	default:
	BOOST_THROW_EXCEPTION(Error("Decryption is not supported for this key type"));
	}
	}

	void*
	PrivateKey::getEvpPkey() const
	{
	return m_impl->key;
	}

	ConstBufferPtr
	PrivateKey::toPkcs1() const
	{
	ENSURE_PRIVATE_KEY_LOADED(m_impl->key);

	OpenSSL_add_all_algorithms();
	detail::Bio mem(BIO_s_mem());
	int ret = i2d_PrivateKey_bio(mem.get(), m_impl->key);
	if (ret != 1)
	BOOST_THROW_EXCEPTION(Error("Cannot convert key into PKCS1 format"));

	int len8 = BIO_pending(mem.get());
	auto buffer = make_shared<Buffer>(len8);
	BIO_read(mem.get(), buffer->buf(), len8);

	return buffer;
	}

	ConstBufferPtr
	PrivateKey::toPkcs8(const char* pw, size_t pwLen) const
	{
	ENSURE_PRIVATE_KEY_LOADED(m_impl->key);

	BOOST_ASSERT(std::strlen(pw) == pwLen);

	OpenSSL_add_all_algorithms();
	detail::Bio mem(BIO_s_mem());
	int ret = i2d_PKCS8PrivateKey_bio(mem.get(), m_impl->key, EVP_des_cbc(),
	const_cast<char*>(pw), pwLen, nullptr, nullptr);
	if (ret != 1)
	BOOST_THROW_EXCEPTION(Error("Cannot convert key into PKCS8 format"));

	int len8 = BIO_pending(mem.get());
	auto buffer = make_shared<Buffer>(len8);
	BIO_read(mem.get(), buffer->buf(), len8);

	return buffer;
	}

	ConstBufferPtr
	PrivateKey::toPkcs8(PasswordCallback pwCallback) const
	{
	ENSURE_PRIVATE_KEY_LOADED(m_impl->key);

	OpenSSL_add_all_algorithms();
	detail::Bio mem(BIO_s_mem());
	int ret = i2d_PKCS8PrivateKey_bio(mem.get(), m_impl->key, EVP_des_cbc(),
	nullptr, 0,
	passwordCallback, &pwCallback);
	if (ret != 1)
	BOOST_THROW_EXCEPTION(Error("Cannot convert key into PKCS8 format"));

	int len8 = BIO_pending(mem.get());
	auto buffer = make_shared<Buffer>(len8);
	BIO_read(mem.get(), buffer->buf(), len8);

	return buffer;
	}

	ConstBufferPtr
	PrivateKey::rsaDecrypt(const uint8_t* cipherText, size_t cipherLen) const
	{
	detail::EvpPkeyCtx ctx(m_impl->key);

	if (EVP_PKEY_decrypt_init(ctx.get()) <= 0)
	BOOST_THROW_EXCEPTION(Error("Failed to initialize decryption context"));

	if (EVP_PKEY_CTX_set_rsa_padding(ctx.get(), RSA_PKCS1_OAEP_PADDING) <= 0)
	BOOST_THROW_EXCEPTION(Error("Failed to set padding"));

	size_t outlen = 0;
	// Determine buffer length
	if (EVP_PKEY_decrypt(ctx.get(), nullptr, &outlen, cipherText, cipherLen) <= 0)
	BOOST_THROW_EXCEPTION(Error("Failed to estimate output length"));

	auto out = make_shared<Buffer>(outlen);

	if (EVP_PKEY_decrypt(ctx.get(), out->buf(), &outlen, cipherText, cipherLen) <= 0)
	BOOST_THROW_EXCEPTION(Error("Failed to decrypt cipher text"));

	out->resize(outlen);
	return out;
	}

	static unique_ptr<PrivateKey>
	generateRsaKey(uint32_t keySize)
	{
	detail::EvpPkeyCtx kctx(EVP_PKEY_RSA);

	int ret = EVP_PKEY_keygen_init(kctx.get());
	if (ret != 1)
	BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate RSA key"));

	ret = EVP_PKEY_CTX_set_rsa_keygen_bits(kctx.get(), keySize);
	if (ret != 1)
	BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate RSA key"));

	detail::EvpPkey key;
	ret = EVP_PKEY_keygen(kctx.get(), &key);
	if (ret != 1)
	BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate RSA key"));

	detail::Bio mem(BIO_s_mem());
	i2d_PrivateKey_bio(mem.get(), key.get());
	int len = BIO_pending(mem.get());
	Buffer buffer(len);
	BIO_read(mem.get(), buffer.buf(), len);

	auto privateKey = make_unique<PrivateKey>();
	privateKey->loadPkcs1(buffer.buf(), buffer.size());

	return privateKey;
	}

	static unique_ptr<PrivateKey>
	generateEcKey(uint32_t keySize)
	{
	detail::EvpPkeyCtx ctx(EVP_PKEY_EC);

	int ret = EVP_PKEY_paramgen_init(ctx.get());
	if (ret != 1)
	BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));

	switch (keySize) {
	case 256:
	ret = EVP_PKEY_CTX_set_ec_paramgen_curve_nid(ctx.get(), NID_X9_62_prime256v1);
	break;
	case 384:
	ret = EVP_PKEY_CTX_set_ec_paramgen_curve_nid(ctx.get(), NID_secp384r1);
	break;
	default:
	BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));
	}
	if (ret != 1)
	BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));

	detail::EvpPkey params;
	ret = EVP_PKEY_paramgen(ctx.get(), &params);
	if (ret != 1)
	BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));

	detail::EvpPkeyCtx kctx(params.get());
	ret = EVP_PKEY_keygen_init(kctx.get());
	if (ret != 1)
	BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));

	detail::EvpPkey key;
	ret = EVP_PKEY_keygen(kctx.get(), &key);
	if (ret != 1)
	BOOST_THROW_EXCEPTION(PrivateKey::Error("Fail to generate EC key"));

	detail::Bio mem(BIO_s_mem());
	i2d_PrivateKey_bio(mem.get(), key.get());
	int len = BIO_pending(mem.get());
	Buffer buffer(len);
	BIO_read(mem.get(), buffer.buf(), len);

	auto privateKey = make_unique<PrivateKey>();
	privateKey->loadPkcs1(buffer.buf(), buffer.size());

	return privateKey;
	}

	unique_ptr<PrivateKey>
	generatePrivateKey(const KeyParams& keyParams)
	{
	switch (keyParams.getKeyType()) {
	case KeyType::RSA: {
	const RsaKeyParams& rsaParams = static_cast<const RsaKeyParams&>(keyParams);
	return generateRsaKey(rsaParams.getKeySize());
	}
	case KeyType::EC: {
	const EcKeyParams& ecParams = static_cast<const EcKeyParams&>(keyParams);
	return generateEcKey(ecParams.getKeySize());
	}
	default:
	BOOST_THROW_EXCEPTION(std::invalid_argument("Unsupported asymmetric key type"));
	}
	}

	} // namespace transform
	} // namespace security
	} // namespace ndn