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#ifndef __AES_H__
#define __AES_H__
#include <cstring>
#include "inspircd_config.h"
#include "base.h"
using namespace std;
/** The AES class is a utility class for use in modules and the core for encryption of data.
*/
class AES : public classbase
{
public:
enum { ECB=0, CBC=1, CFB=2 };
private:
enum { DEFAULT_BLOCK_SIZE=16 };
enum { MAX_BLOCK_SIZE=32, MAX_ROUNDS=14, MAX_KC=8, MAX_BC=8 };
static int Mul(int a, int b)
{
return (a != 0 && b != 0) ? sm_alog[(sm_log[a & 0xFF] + sm_log[b & 0xFF]) % 255] : 0;
}
/** Convenience method used in generating Transposition Boxes
*/
static int Mul4(int a, char b[])
{
if(a == 0)
return 0;
a = sm_log[a & 0xFF];
int a0 = (b[0] != 0) ? sm_alog[(a + sm_log[b[0] & 0xFF]) % 255] & 0xFF : 0;
int a1 = (b[1] != 0) ? sm_alog[(a + sm_log[b[1] & 0xFF]) % 255] & 0xFF : 0;
int a2 = (b[2] != 0) ? sm_alog[(a + sm_log[b[2] & 0xFF]) % 255] & 0xFF : 0;
int a3 = (b[3] != 0) ? sm_alog[(a + sm_log[b[3] & 0xFF]) % 255] & 0xFF : 0;
return a0 << 24 | a1 << 16 | a2 << 8 | a3;
}
public:
AES();
virtual ~AES();
/** Expand a user-supplied key material into a session key.
*
* @param key The 128/192/256-bit user-key to use.
* @param chain Initial chain block for CBC and CFB modes.
* @param keylength 16, 24 or 32 bytes
* @param blockSize The block size in bytes of this Rijndael (16, 24 or 32 bytes).
*/
void MakeKey(char const* key, char const* chain, int keylength=DEFAULT_BLOCK_SIZE, int blockSize=DEFAULT_BLOCK_SIZE);
private:
/** Auxiliary Function
*/
void Xor(char* buff, char const* chain)
{
if(false==m_bKeyInit)
return;
for(int i=0; i<m_blockSize; i++)
*(buff++) ^= *(chain++);
}
/** Convenience method to encrypt exactly one block of plaintext, assuming Rijndael's default block size (128-bit).
* @param in The plaintext
* @param result The ciphertext generated from a plaintext using the key
*/
void DefEncryptBlock(char const* in, char* result);
/** Convenience method to decrypt exactly one block of plaintext, assuming Rijndael's default block size (128-bit).
* @param in The ciphertext.
* @param result The plaintext generated from a ciphertext using the session key.
*/
void DefDecryptBlock(char const* in, char* result);
public:
/** Encrypt exactly one block of plaintext.
* @param in The plaintext.
* @param result The ciphertext generated from a plaintext using the key.
*/
void EncryptBlock(char const* in, char* result);
/** Decrypt exactly one block of ciphertext.
* @param in The ciphertext.
* @param result The plaintext generated from a ciphertext using the session key.
*/
void DecryptBlock(char const* in, char* result);
/** Encrypt multiple blocks of plaintext.
* @param n Number of bytes to encrypt, must be a multiple of the keysize
* @param in The plaintext to encrypt
* @param result The output ciphertext
* @param iMode Mode to use
*/
void Encrypt(char const* in, char* result, size_t n, int iMode=ECB);
/** Decrypt multiple blocks of ciphertext.
* @param n Number of bytes to decrypt, must be a multiple of the keysize
* @param in The ciphertext to decrypt
* @param result The output plaintext
* @param iMode Mode to use
*/
void Decrypt(char const* in, char* result, size_t n, int iMode=ECB);
/** Get Key Length
*/
int GetKeyLength()
{
if(false==m_bKeyInit)
return 0;
return m_keylength;
}
/** Get Block Size
*/
int GetBlockSize()
{
if(false==m_bKeyInit)
return 0;
return m_blockSize;
}
/** Get Number of Rounds
*/
int GetRounds()
{
if(false==m_bKeyInit)
return 0;
return m_iROUNDS;
}
/** Reset the chain
*/
void ResetChain()
{
memcpy(m_chain, m_chain0, m_blockSize);
}
public:
/** Null chain
*/
static char const* sm_chain0;
private:
static const int sm_alog[256];
static const int sm_log[256];
static const char sm_S[256];
static const char sm_Si[256];
static const int sm_T1[256];
static const int sm_T2[256];
static const int sm_T3[256];
static const int sm_T4[256];
static const int sm_T5[256];
static const int sm_T6[256];
static const int sm_T7[256];
static const int sm_T8[256];
static const int sm_U1[256];
static const int sm_U2[256];
static const int sm_U3[256];
static const int sm_U4[256];
static const char sm_rcon[30];
static const int sm_shifts[3][4][2];
/** Key Initialization Flag
*/
bool m_bKeyInit;
/** Encryption (m_Ke) round key
*/
int m_Ke[MAX_ROUNDS+1][MAX_BC];
/** Decryption (m_Kd) round key
*/
int m_Kd[MAX_ROUNDS+1][MAX_BC];
/** Key Length
*/
int m_keylength;
/** Block Size
*/
int m_blockSize;
/** Number of Rounds
*/
int m_iROUNDS;
/**Chain Block
*/
char m_chain0[MAX_BLOCK_SIZE];
char m_chain[MAX_BLOCK_SIZE];
/** Auxiliary private use buffers
*/
int tk[MAX_KC];
int a[MAX_BC];
int t[MAX_BC];
};
#endif
/** Convert from binary to base64
* @param out Output
* @param in Input
* @param inlen Number of bytes in input buffer
*/
void to64frombits(unsigned char *out, const unsigned char *in, int inlen);
/** Convert from base64 to binary
* @out Output
* @in Input
* @maxlen Size of output buffer
* @return Number of bytes actually converted
*/
int from64tobits(char *out, const char *in, int maxlen);
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