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/*
* Public Key Interface
* (C) 1999-2010 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#ifndef BOTAN_PUBKEY_H__
#define BOTAN_PUBKEY_H__
#include <botan/pk_keys.h>
#include <botan/pk_ops.h>
#include <botan/symkey.h>
#include <botan/rng.h>
#include <botan/eme.h>
#include <botan/emsa.h>
#include <botan/kdf.h>
namespace Botan {
/**
* The two types of signature format supported by Botan.
*/
enum Signature_Format { IEEE_1363, DER_SEQUENCE };
/**
* Public Key Encryptor
*/
class BOTAN_DLL PK_Encryptor
{
public:
/**
* Encrypt a message.
* @param in the message as a byte array
* @param length the length of the above byte array
* @param rng the random number source to use
* @return encrypted message
*/
std::vector<byte> encrypt(const byte in[], size_t length,
RandomNumberGenerator& rng) const
{
return enc(in, length, rng);
}
/**
* Encrypt a message.
* @param in the message
* @param rng the random number source to use
* @return encrypted message
*/
template<typename Alloc>
std::vector<byte> encrypt(const std::vector<byte, Alloc>& in,
RandomNumberGenerator& rng) const
{
return enc(in.data(), in.size(), rng);
}
/**
* Return the maximum allowed message size in bytes.
* @return maximum message size in bytes
*/
virtual size_t maximum_input_size() const = 0;
PK_Encryptor() {}
virtual ~PK_Encryptor() {}
PK_Encryptor(const PK_Encryptor&) = delete;
PK_Encryptor& operator=(const PK_Encryptor&) = delete;
private:
virtual std::vector<byte> enc(const byte[], size_t,
RandomNumberGenerator&) const = 0;
};
/**
* Public Key Decryptor
*/
class BOTAN_DLL PK_Decryptor
{
public:
/**
* Decrypt a ciphertext.
* @param in the ciphertext as a byte array
* @param length the length of the above byte array
* @return decrypted message
*/
secure_vector<byte> decrypt(const byte in[], size_t length) const
{
return dec(in, length);
}
/**
* Decrypt a ciphertext.
* @param in the ciphertext
* @return decrypted message
*/
template<typename Alloc>
secure_vector<byte> decrypt(const std::vector<byte, Alloc>& in) const
{
return dec(in.data(), in.size());
}
PK_Decryptor() {}
virtual ~PK_Decryptor() {}
PK_Decryptor(const PK_Decryptor&) = delete;
PK_Decryptor& operator=(const PK_Decryptor&) = delete;
private:
virtual secure_vector<byte> dec(const byte[], size_t) const = 0;
};
/**
* Public Key Signer. Use the sign_message() functions for small
* messages. Use multiple calls update() to process large messages and
* generate the signature by finally calling signature().
*/
class BOTAN_DLL PK_Signer
{
public:
/**
* Construct a PK Signer.
* @param key the key to use inside this signer
* @param emsa the EMSA to use
* An example would be "EMSA1(SHA-224)".
* @param format the signature format to use
*/
PK_Signer(const Private_Key& key,
const std::string& emsa,
Signature_Format format = IEEE_1363,
const std::string& provider = "");
/**
* Sign a message all in one go
* @param in the message to sign as a byte array
* @param length the length of the above byte array
* @param rng the rng to use
* @return signature
*/
std::vector<byte> sign_message(const byte in[], size_t length,
RandomNumberGenerator& rng)
{
this->update(in, length);
return this->signature(rng);
}
/**
* Sign a message.
* @param in the message to sign
* @param rng the rng to use
* @return signature
*/
std::vector<byte> sign_message(const std::vector<byte>& in,
RandomNumberGenerator& rng)
{ return sign_message(in.data(), in.size(), rng); }
std::vector<byte> sign_message(const secure_vector<byte>& in,
RandomNumberGenerator& rng)
{ return sign_message(in.data(), in.size(), rng); }
/**
* Add a message part (single byte).
* @param in the byte to add
*/
void update(byte in) { update(&in, 1); }
/**
* Add a message part.
* @param in the message part to add as a byte array
* @param length the length of the above byte array
*/
void update(const byte in[], size_t length);
/**
* Add a message part.
* @param in the message part to add
*/
void update(const std::vector<byte>& in) { update(in.data(), in.size()); }
/**
* Add a message part.
* @param in the message part to add
*/
void update(const std::string& in)
{
update(reinterpret_cast<const byte*>(in.data()), in.size());
}
/**
* Get the signature of the so far processed message (provided by the
* calls to update()).
* @param rng the rng to use
* @return signature of the total message
*/
std::vector<byte> signature(RandomNumberGenerator& rng);
/**
* Set the output format of the signature.
* @param format the signature format to use
*/
void set_output_format(Signature_Format format) { m_sig_format = format; }
private:
std::unique_ptr<PK_Ops::Signature> m_op;
Signature_Format m_sig_format;
};
/**
* Public Key Verifier. Use the verify_message() functions for small
* messages. Use multiple calls update() to process large messages and
* verify the signature by finally calling check_signature().
*/
class BOTAN_DLL PK_Verifier
{
public:
/**
* Construct a PK Verifier.
* @param pub_key the public key to verify against
* @param emsa the EMSA to use (eg "EMSA3(SHA-1)")
* @param format the signature format to use
*/
PK_Verifier(const Public_Key& pub_key,
const std::string& emsa,
Signature_Format format = IEEE_1363,
const std::string& provider = "");
/**
* Verify a signature.
* @param msg the message that the signature belongs to, as a byte array
* @param msg_length the length of the above byte array msg
* @param sig the signature as a byte array
* @param sig_length the length of the above byte array sig
* @return true if the signature is valid
*/
bool verify_message(const byte msg[], size_t msg_length,
const byte sig[], size_t sig_length);
/**
* Verify a signature.
* @param msg the message that the signature belongs to
* @param sig the signature
* @return true if the signature is valid
*/
template<typename Alloc, typename Alloc2>
bool verify_message(const std::vector<byte, Alloc>& msg,
const std::vector<byte, Alloc2>& sig)
{
return verify_message(msg.data(), msg.size(),
sig.data(), sig.size());
}
/**
* Add a message part (single byte) of the message corresponding to the
* signature to be verified.
* @param in the byte to add
*/
void update(byte in) { update(&in, 1); }
/**
* Add a message part of the message corresponding to the
* signature to be verified.
* @param msg_part the new message part as a byte array
* @param length the length of the above byte array
*/
void update(const byte msg_part[], size_t length);
/**
* Add a message part of the message corresponding to the
* signature to be verified.
* @param in the new message part
*/
void update(const std::vector<byte>& in)
{ update(in.data(), in.size()); }
/**
* Add a message part of the message corresponding to the
* signature to be verified.
*/
void update(const std::string& in)
{
update(reinterpret_cast<const byte*>(in.data()), in.size());
}
/**
* Check the signature of the buffered message, i.e. the one build
* by successive calls to update.
* @param sig the signature to be verified as a byte array
* @param length the length of the above byte array
* @return true if the signature is valid, false otherwise
*/
bool check_signature(const byte sig[], size_t length);
/**
* Check the signature of the buffered message, i.e. the one build
* by successive calls to update.
* @param sig the signature to be verified
* @return true if the signature is valid, false otherwise
*/
template<typename Alloc>
bool check_signature(const std::vector<byte, Alloc>& sig)
{
return check_signature(sig.data(), sig.size());
}
/**
* Set the format of the signatures fed to this verifier.
* @param format the signature format to use
*/
void set_input_format(Signature_Format format);
private:
std::unique_ptr<PK_Ops::Verification> m_op;
Signature_Format m_sig_format;
};
/**
* Key used for key agreement
*/
class BOTAN_DLL PK_Key_Agreement
{
public:
/**
* Construct a PK Key Agreement.
* @param key the key to use
* @param kdf name of the KDF to use (or 'Raw' for no KDF)
* @param provider the algo provider to use (or empty for default)
*/
PK_Key_Agreement(const Private_Key& key,
const std::string& kdf,
const std::string& provider = "");
/*
* Perform Key Agreement Operation
* @param key_len the desired key output size
* @param in the other parties key
* @param in_len the length of in in bytes
* @param params extra derivation params
* @param params_len the length of params in bytes
*/
SymmetricKey derive_key(size_t key_len,
const byte in[],
size_t in_len,
const byte params[],
size_t params_len) const;
/*
* Perform Key Agreement Operation
* @param key_len the desired key output size
* @param in the other parties key
* @param in_len the length of in in bytes
* @param params extra derivation params
* @param params_len the length of params in bytes
*/
SymmetricKey derive_key(size_t key_len,
const std::vector<byte>& in,
const byte params[],
size_t params_len) const
{
return derive_key(key_len, in.data(), in.size(),
params, params_len);
}
/*
* Perform Key Agreement Operation
* @param key_len the desired key output size
* @param in the other parties key
* @param in_len the length of in in bytes
* @param params extra derivation params
*/
SymmetricKey derive_key(size_t key_len,
const byte in[], size_t in_len,
const std::string& params = "") const
{
return derive_key(key_len, in, in_len,
reinterpret_cast<const byte*>(params.data()),
params.length());
}
/*
* Perform Key Agreement Operation
* @param key_len the desired key output size
* @param in the other parties key
* @param params extra derivation params
*/
SymmetricKey derive_key(size_t key_len,
const std::vector<byte>& in,
const std::string& params = "") const
{
return derive_key(key_len, in.data(), in.size(),
reinterpret_cast<const byte*>(params.data()),
params.length());
}
private:
std::unique_ptr<PK_Ops::Key_Agreement> m_op;
};
/**
* Encryption using a standard message recovery algorithm like RSA or
* ElGamal, paired with an encoding scheme like OAEP.
*/
class BOTAN_DLL PK_Encryptor_EME : public PK_Encryptor
{
public:
size_t maximum_input_size() const override;
/**
* Construct an instance.
* @param key the key to use inside the decryptor
* @param padding the message encoding scheme to use (eg "OAEP(SHA-256)")
*/
PK_Encryptor_EME(const Public_Key& key,
const std::string& padding,
const std::string& provider = "");
private:
std::vector<byte> enc(const byte[], size_t,
RandomNumberGenerator& rng) const override;
std::unique_ptr<PK_Ops::Encryption> m_op;
};
/**
* Decryption with an MR algorithm and an EME.
*/
class BOTAN_DLL PK_Decryptor_EME : public PK_Decryptor
{
public:
/**
* Construct an instance.
* @param key the key to use inside the encryptor
* @param eme the EME to use
*/
PK_Decryptor_EME(const Private_Key& key,
const std::string& eme,
const std::string& provider = "");
private:
secure_vector<byte> dec(const byte[], size_t) const override;
std::unique_ptr<PK_Ops::Decryption> m_op;
};
class BOTAN_DLL PK_KEM_Encryptor
{
public:
PK_KEM_Encryptor(const Public_Key& key,
const std::string& kem_param = "",
const std::string& provider = "");
void encrypt(secure_vector<byte>& out_encapsulated_key,
secure_vector<byte>& out_shared_key,
size_t desired_shared_key_len,
Botan::RandomNumberGenerator& rng,
const uint8_t salt[],
size_t salt_len);
template<typename Alloc>
void encrypt(secure_vector<byte>& out_encapsulated_key,
secure_vector<byte>& out_shared_key,
size_t desired_shared_key_len,
Botan::RandomNumberGenerator& rng,
const std::vector<uint8_t, Alloc>& salt)
{
this->encrypt(out_encapsulated_key,
out_shared_key,
desired_shared_key_len,
rng,
salt.data(), salt.size());
}
void encrypt(secure_vector<byte>& out_encapsulated_key,
secure_vector<byte>& out_shared_key,
size_t desired_shared_key_len,
Botan::RandomNumberGenerator& rng)
{
this->encrypt(out_encapsulated_key,
out_shared_key,
desired_shared_key_len,
rng,
nullptr,
0);
}
private:
std::unique_ptr<PK_Ops::KEM_Encryption> m_op;
};
class BOTAN_DLL PK_KEM_Decryptor
{
public:
PK_KEM_Decryptor(const Private_Key& key,
const std::string& kem_param = "",
const std::string& provider = "");
secure_vector<byte> decrypt(const byte encap_key[],
size_t encap_key_len,
size_t desired_shared_key_len,
const uint8_t salt[],
size_t salt_len);
secure_vector<byte> decrypt(const byte encap_key[],
size_t encap_key_len,
size_t desired_shared_key_len)
{
return this->decrypt(encap_key, encap_key_len,
desired_shared_key_len,
nullptr, 0);
}
template<typename Alloc1, typename Alloc2>
secure_vector<byte> decrypt(const std::vector<byte, Alloc1>& encap_key,
size_t desired_shared_key_len,
const std::vector<byte, Alloc2>& salt)
{
return this->decrypt(encap_key.data(), encap_key.size(),
desired_shared_key_len,
salt.data(), salt.size());
}
private:
std::unique_ptr<PK_Ops::KEM_Decryption> m_op;
};
}
#endif
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