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/*
* ECIES
* (C) 2016 Philipp Weber
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#ifndef BOTAN_ECIES_H_
#define BOTAN_ECIES_H_
#include <botan/ecdh.h>
#include <botan/ec_group.h>
#include <botan/cipher_mode.h>
#include <botan/point_gfp.h>
#include <botan/pubkey.h>
#include <botan/secmem.h>
#include <botan/symkey.h>
#include <botan/mac.h>
#include <memory>
#include <string>
#include <vector>
namespace Botan {
class RandomNumberGenerator;
enum class ECIES_Flags : uint32_t
{
NONE = 0,
/// if set: prefix the input of the (ecdh) key agreement with the encoded (ephemeral) public key
SINGLE_HASH_MODE = 1,
/// (decryption only) if set: use cofactor multiplication during (ecdh) key agreement
COFACTOR_MODE = 2,
/// if set: use ecdhc instead of ecdh
OLD_COFACTOR_MODE = 4,
/// (decryption only) if set: test if the (ephemeral) public key is on the curve
CHECK_MODE = 8
};
inline ECIES_Flags operator |(ECIES_Flags a, ECIES_Flags b)
{
return static_cast<ECIES_Flags>(static_cast<uint32_t>(a) | static_cast<uint32_t>(b));
}
inline ECIES_Flags operator &(ECIES_Flags a, ECIES_Flags b)
{
return static_cast<ECIES_Flags>(static_cast<uint32_t>(a) & static_cast<uint32_t>(b));
}
/**
* Parameters for ECIES secret derivation
*/
class BOTAN_PUBLIC_API(2,0) ECIES_KA_Params
{
public:
/**
* @param domain ec domain parameters of the involved ec keys
* @param kdf_spec name of the key derivation function
* @param length length of the secret to be derived
* @param compression_type format of encoded keys (affects the secret derivation if single_hash_mode is used)
* @param flags options, see documentation of ECIES_Flags
*/
ECIES_KA_Params(const EC_Group& domain, const std::string& kdf_spec, size_t length,
PointGFp::Compression_Type compression_type, ECIES_Flags flags);
ECIES_KA_Params(const ECIES_KA_Params&) = default;
ECIES_KA_Params& operator=(const ECIES_KA_Params&) = delete;
virtual ~ECIES_KA_Params() = default;
inline const EC_Group& domain() const
{
return m_domain;
}
inline size_t secret_length() const
{
return m_length;
}
inline bool single_hash_mode() const
{
return (m_flags & ECIES_Flags::SINGLE_HASH_MODE) == ECIES_Flags::SINGLE_HASH_MODE;
}
inline bool cofactor_mode() const
{
return (m_flags & ECIES_Flags::COFACTOR_MODE) == ECIES_Flags::COFACTOR_MODE;
}
inline bool old_cofactor_mode() const
{
return (m_flags & ECIES_Flags::OLD_COFACTOR_MODE) == ECIES_Flags::OLD_COFACTOR_MODE;
}
inline bool check_mode() const
{
return (m_flags & ECIES_Flags::CHECK_MODE) == ECIES_Flags::CHECK_MODE;
}
inline PointGFp::Compression_Type compression_type() const
{
return m_compression_mode;
}
const std::string& kdf_spec() const
{
return m_kdf_spec;
}
private:
const EC_Group m_domain;
const std::string m_kdf_spec;
const size_t m_length;
const PointGFp::Compression_Type m_compression_mode;
const ECIES_Flags m_flags;
};
class BOTAN_PUBLIC_API(2,0) ECIES_System_Params final : public ECIES_KA_Params
{
public:
/**
* @param domain ec domain parameters of the involved ec keys
* @param kdf_spec name of the key derivation function
* @param dem_algo_spec name of the data encryption method
* @param dem_key_len length of the key used for the data encryption method
* @param mac_spec name of the message authentication code
* @param mac_key_len length of the key used for the message authentication code
*/
ECIES_System_Params(const EC_Group& domain, const std::string& kdf_spec, const std::string& dem_algo_spec,
size_t dem_key_len, const std::string& mac_spec, size_t mac_key_len);
/**
* @param domain ec domain parameters of the involved ec keys
* @param kdf_spec name of the key derivation function
* @param dem_algo_spec name of the data encryption method
* @param dem_key_len length of the key used for the data encryption method
* @param mac_spec name of the message authentication code
* @param mac_key_len length of the key used for the message authentication code
* @param compression_type format of encoded keys (affects the secret derivation if single_hash_mode is used)
* @param flags options, see documentation of ECIES_Flags
*/
ECIES_System_Params(const EC_Group& domain, const std::string& kdf_spec, const std::string& dem_algo_spec,
size_t dem_key_len, const std::string& mac_spec, size_t mac_key_len,
PointGFp::Compression_Type compression_type, ECIES_Flags flags);
ECIES_System_Params(const ECIES_System_Params&) = default;
ECIES_System_Params& operator=(const ECIES_System_Params&) = delete;
virtual ~ECIES_System_Params() = default;
/// creates an instance of the message authentication code
std::unique_ptr<MessageAuthenticationCode> create_mac() const;
/// creates an instance of the data encryption method
std::unique_ptr<Cipher_Mode> create_cipher(Botan::Cipher_Dir direction) const;
/// returns the length of the key used by the data encryption method
inline size_t dem_keylen() const
{
return m_dem_keylen;
}
/// returns the length of the key used by the message authentication code
inline size_t mac_keylen() const
{
return m_mac_keylen;
}
private:
const std::string m_dem_spec;
const size_t m_dem_keylen;
const std::string m_mac_spec;
const size_t m_mac_keylen;
};
/**
* ECIES secret derivation according to ISO 18033-2
*/
class BOTAN_PUBLIC_API(2,0) ECIES_KA_Operation
{
public:
/**
* @param private_key the (ephemeral) private key which is used to derive the secret
* @param ecies_params settings for ecies
* @param for_encryption disable cofactor mode if the secret will be used for encryption
* (according to ISO 18033 cofactor mode is only used during decryption)
* @param rng the RNG to use
*/
ECIES_KA_Operation(const PK_Key_Agreement_Key& private_key,
const ECIES_KA_Params& ecies_params,
bool for_encryption,
RandomNumberGenerator& rng);
/**
* Performs a key agreement with the provided keys and derives the secret from the result
* @param eph_public_key_bin the encoded (ephemeral) public key which belongs to the used (ephemeral) private key
* @param other_public_key_point public key point of the other party
*/
SymmetricKey derive_secret(const std::vector<uint8_t>& eph_public_key_bin,
const PointGFp& other_public_key_point) const;
private:
const PK_Key_Agreement m_ka;
const ECIES_KA_Params m_params;
};
/**
* ECIES Encryption according to ISO 18033-2
*/
class BOTAN_PUBLIC_API(2,0) ECIES_Encryptor final : public PK_Encryptor
{
public:
/**
* @param private_key the (ephemeral) private key which is used for the key agreement
* @param ecies_params settings for ecies
* @param rng random generator to use
*/
ECIES_Encryptor(const PK_Key_Agreement_Key& private_key,
const ECIES_System_Params& ecies_params,
RandomNumberGenerator& rng);
/**
* Creates an ephemeral private key which is used for the key agreement
* @param rng random generator used during private key generation
* @param ecies_params settings for ecies
*/
ECIES_Encryptor(RandomNumberGenerator& rng, const ECIES_System_Params& ecies_params);
/// Set the public key of the other party
inline void set_other_key(const Botan::PointGFp& public_point)
{
m_other_point = public_point;
}
/// Set the initialization vector for the data encryption method
inline void set_initialization_vector(const InitializationVector& iv)
{
m_iv = iv;
}
/// Set the label which is appended to the input for the message authentication code
inline void set_label(const std::string& label)
{
m_label = std::vector<uint8_t>(label.begin(), label.end());
}
private:
std::vector<uint8_t> enc(const uint8_t data[], size_t length, RandomNumberGenerator&) const override;
size_t maximum_input_size() const override;
size_t ciphertext_length(size_t ptext_len) const override;
const ECIES_KA_Operation m_ka;
const ECIES_System_Params m_params;
std::unique_ptr<MessageAuthenticationCode> m_mac;
std::unique_ptr<Cipher_Mode> m_cipher;
std::vector<uint8_t> m_eph_public_key_bin;
InitializationVector m_iv;
PointGFp m_other_point;
std::vector<uint8_t> m_label;
};
/**
* ECIES Decryption according to ISO 18033-2
*/
class BOTAN_PUBLIC_API(2,0) ECIES_Decryptor final : public PK_Decryptor
{
public:
/**
* @param private_key the private key which is used for the key agreement
* @param ecies_params settings for ecies
* @param rng the random generator to use
*/
ECIES_Decryptor(const PK_Key_Agreement_Key& private_key,
const ECIES_System_Params& ecies_params,
RandomNumberGenerator& rng);
/// Set the initialization vector for the data encryption method
inline void set_initialization_vector(const InitializationVector& iv)
{
m_iv = iv;
}
/// Set the label which is appended to the input for the message authentication code
inline void set_label(const std::string& label)
{
m_label = std::vector<uint8_t>(label.begin(), label.end());
}
private:
secure_vector<uint8_t> do_decrypt(uint8_t& valid_mask, const uint8_t in[], size_t in_len) const override;
size_t plaintext_length(size_t ctext_len) const override;
const ECIES_KA_Operation m_ka;
const ECIES_System_Params m_params;
std::unique_ptr<MessageAuthenticationCode> m_mac;
std::unique_ptr<Cipher_Mode> m_cipher;
InitializationVector m_iv;
std::vector<uint8_t> m_label;
};
}
#endif
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