// seckey.h - written and placed in the public domain by Wei Dai
// This file contains helper classes/functions for implementing secret key algorithms.
#ifndef CRYPTOPP_SECKEY_H
#define CRYPTOPP_SECKEY_H
#include "cryptlib.h"
#include "misc.h"
#include "simple.h"
NAMESPACE_BEGIN(CryptoPP)
inline CipherDir ReverseCipherDir(CipherDir dir)
{
return (dir == ENCRYPTION) ? DECRYPTION : ENCRYPTION;
}
//! to be inherited by block ciphers with fixed block size
template <unsigned int N>
class FixedBlockSize
{
public:
CRYPTOPP_CONSTANT(BLOCKSIZE = N)
};
// ************** rounds ***************
//! to be inherited by ciphers with fixed number of rounds
template <unsigned int R>
class FixedRounds
{
public:
CRYPTOPP_CONSTANT(ROUNDS = R)
};
//! to be inherited by ciphers with variable number of rounds
template <unsigned int D, unsigned int N=1, unsigned int M=INT_MAX> // use INT_MAX here because enums are treated as signed ints
class VariableRounds
{
public:
CRYPTOPP_CONSTANT(DEFAULT_ROUNDS = D)
CRYPTOPP_CONSTANT(MIN_ROUNDS = N)
CRYPTOPP_CONSTANT(MAX_ROUNDS = M)
static unsigned int StaticGetDefaultRounds(size_t keylength) {return DEFAULT_ROUNDS;}
protected:
inline void ThrowIfInvalidRounds(int rounds, const Algorithm *alg)
{
if (rounds < MIN_ROUNDS || rounds > MAX_ROUNDS)
throw InvalidRounds(alg->AlgorithmName(), rounds);
}
inline unsigned int GetRoundsAndThrowIfInvalid(const NameValuePairs ¶m, const Algorithm *alg)
{
int rounds = param.GetIntValueWithDefault("Rounds", DEFAULT_ROUNDS);
ThrowIfInvalidRounds(rounds, alg);
return (unsigned int)rounds;
}
};
// ************** key length ***************
//! to be inherited by keyed algorithms with fixed key length
template <unsigned int N, unsigned int IV_REQ = SimpleKeyingInterface::NOT_RESYNCHRONIZABLE, unsigned int IV_L = 0>
class FixedKeyLength
{
public:
CRYPTOPP_CONSTANT(KEYLENGTH=N)
CRYPTOPP_CONSTANT(MIN_KEYLENGTH=N)
CRYPTOPP_CONSTANT(MAX_KEYLENGTH=N)
CRYPTOPP_CONSTANT(DEFAULT_KEYLENGTH=N)
CRYPTOPP_CONSTANT(IV_REQUIREMENT = IV_REQ)
CRYPTOPP_CONSTANT(IV_LENGTH = IV_L)
static size_t CRYPTOPP_API StaticGetValidKeyLength(size_t) {return KEYLENGTH;}
};
/// support query of variable key length, template parameters are default, min, max, multiple (default multiple 1)
template <unsigned int D, unsigned int N, unsigned int M, unsigned int Q = 1, unsigned int IV_REQ = SimpleKeyingInterface::NOT_RESYNCHRONIZABLE, unsigned int IV_L = 0>
class VariableKeyLength
{
// make these private to avoid Doxygen documenting them in all derived classes
CRYPTOPP_COMPILE_ASSERT(Q > 0);
CRYPTOPP_COMPILE_ASSERT(N % Q == 0);
CRYPTOPP_COMPILE_ASSERT(M % Q == 0);
CRYPTOPP_COMPILE_ASSERT(N < M);
CRYPTOPP_COMPILE_ASSERT(D >= N);
CRYPTOPP_COMPILE_ASSERT(M >= D);
public:
CRYPTOPP_CONSTANT(MIN_KEYLENGTH=N)
CRYPTOPP_CONSTANT(MAX_KEYLENGTH=M)
CRYPTOPP_CONSTANT(DEFAULT_KEYLENGTH=D)
CRYPTOPP_CONSTANT(KEYLENGTH_MULTIPLE=Q)
CRYPTOPP_CONSTANT(IV_REQUIREMENT=IV_REQ)
CRYPTOPP_CONSTANT(IV_LENGTH=IV_L)
static size_t CRYPTOPP_API StaticGetValidKeyLength(size_t n)
{
if (n < (size_t)MIN_KEYLENGTH)
return MIN_KEYLENGTH;
else if (n > (size_t)MAX_KEYLENGTH)
return (size_t)MAX_KEYLENGTH;
else
{
n += KEYLENGTH_MULTIPLE-1;
return n - n%KEYLENGTH_MULTIPLE;
}
}
};
/// support query of key length that's the same as another class
template <class T>
class SameKeyLengthAs
{
public:
CRYPTOPP_CONSTANT(MIN_KEYLENGTH=T::MIN_KEYLENGTH)
CRYPTOPP_CONSTANT(MAX_KEYLENGTH=T::MAX_KEYLENGTH)
CRYPTOPP_CONSTANT(DEFAULT_KEYLENGTH=T::DEFAULT_KEYLENGTH)
CRYPTOPP_CONSTANT(IV_REQUIREMENT = T::IV_REQUIREMENT)
CRYPTOPP_CONSTANT(IV_LENGTH = T::IV_LENGTH)
static size_t CRYPTOPP_API StaticGetValidKeyLength(size_t keylength)
{return T::StaticGetValidKeyLength(keylength);}
};
// ************** implementation helper for SimpleKeyed ***************
//! _
template <class BASE, class INFO = BASE>
class CRYPTOPP_NO_VTABLE SimpleKeyingInterfaceImpl : public BASE
{
public:
size_t MinKeyLength() const {return INFO::MIN_KEYLENGTH;}
size_t MaxKeyLength() const {return (size_t)INFO::MAX_KEYLENGTH;}
size_t DefaultKeyLength() const {return INFO::DEFAULT_KEYLENGTH;}
size_t GetValidKeyLength(size_t n) const {return INFO::StaticGetValidKeyLength(n);}
typename BASE::IV_Requirement IVRequirement() const {return (typename BASE::IV_Requirement)INFO::IV_REQUIREMENT;}
unsigned int IVSize() const {return INFO::IV_LENGTH;}
};
template <class INFO, class BASE = BlockCipher>
class CRYPTOPP_NO_VTABLE BlockCipherImpl : public AlgorithmImpl<SimpleKeyingInterfaceImpl<TwoBases<BASE, INFO> > >
{
public:
unsigned int BlockSize() const {return this->BLOCKSIZE;}
};
//! _
template <CipherDir DIR, class BASE>
class BlockCipherFinal : public ClonableImpl<BlockCipherFinal<DIR, BASE>, BASE>
{
public:
BlockCipherFinal() {}
BlockCipherFinal(const byte *key)
{this->SetKey(key, this->DEFAULT_KEYLENGTH);}
BlockCipherFinal(const byte *key, size_t length)
{this->SetKey(key, length);}
BlockCipherFinal(const byte *key, size_t length, unsigned int rounds)
{this->SetKeyWithRounds(key, length, rounds);}
bool IsForwardTransformation() const {return DIR == ENCRYPTION;}
};
//! _
template <class BASE, class INFO = BASE>
class MessageAuthenticationCodeImpl : public AlgorithmImpl<SimpleKeyingInterfaceImpl<BASE, INFO>, INFO>
{
};
//! _
template <class BASE>
class MessageAuthenticationCodeFinal : public ClonableImpl<MessageAuthenticationCodeFinal<BASE>, MessageAuthenticationCodeImpl<BASE> >
{
public:
MessageAuthenticationCodeFinal() {}
MessageAuthenticationCodeFinal(const byte *key)
{this->SetKey(key, this->DEFAULT_KEYLENGTH);}
MessageAuthenticationCodeFinal(const byte *key, size_t length)
{this->SetKey(key, length);}
};
// ************** documentation ***************
//! These objects usually should not be used directly. See CipherModeDocumentation instead.
/*! Each class derived from this one defines two types, Encryption and Decryption,
both of which implement the BlockCipher interface. */
struct BlockCipherDocumentation
{
//! implements the BlockCipher interface
typedef BlockCipher Encryption;
//! implements the BlockCipher interface
typedef BlockCipher Decryption;
};
/*! \brief Each class derived from this one defines two types, Encryption and Decryption,
both of which implement the SymmetricCipher interface. Two types of classes derive
from this class: stream ciphers and block cipher modes. Stream ciphers can be used
alone, cipher mode classes need to be used with a block cipher. See CipherModeDocumentation
for more for information about using cipher modes and block ciphers. */
struct SymmetricCipherDocumentation
{
//! implements the SymmetricCipher interface
typedef SymmetricCipher Encryption;
//! implements the SymmetricCipher interface
typedef SymmetricCipher Decryption;
};
NAMESPACE_END
#endif
Submit an article or tip