Add Chacha20-Poly1305, AES128-GCM and AES256-GCM support (#93) * Add Chacha20-Poly1305 authenticated encryption * Add general AEAD approach. * Add [email protected] algo using LibTomCrypt chacha and poly1305 routines. Chacha20-Poly1305 is generally faster than AES256 on CPU w/o dedicated AES instructions, having the same key size. Compiling in will add ~5,5kB to binary size on x86-64. function old new delta chacha_crypt - 1397 +1397 _poly1305_block - 608 +608 poly1305_done - 595 +595 dropbear_chachapoly_crypt - 457 +457 .rodata 26976 27392 +416 poly1305_process - 290 +290 poly1305_init - 221 +221 chacha_setup - 218 +218 encrypt_packet 1068 1270 +202 dropbear_chachapoly_getlength - 147 +147 decrypt_packet 756 897 +141 chacha_ivctr64 - 137 +137 read_packet 543 637 +94 dropbear_chachapoly_start - 94 +94 read_kex_algos 792 880 +88 chacha_keystream - 69 +69 dropbear_mode_chachapoly - 48 +48 sshciphers 280 320 +40 dropbear_mode_none 24 48 +24 dropbear_mode_ctr 24 48 +24 dropbear_mode_cbc 24 48 +24 dropbear_chachapoly_mac - 24 +24 dropbear_chachapoly - 24 +24 gen_new_keys 848 854 +6 ------------------------------------------------------------------------------ (add/remove: 14/0 grow/shrink: 10/0 up/down: 5388/0) Total: 5388 bytes * Add AES128-GCM and AES256-GCM authenticated encryption * Add general AES-GCM mode. * Add [email protected] and [email protected] algo using LibTomCrypt gcm routines. AES-GCM is combination of AES CTR mode and GHASH, slower than AES-CTR on CPU w/o dedicated AES/GHASH instructions therefore disabled by default. Compiling in will add ~6kB to binary size on x86-64. function old new delta gcm_process - 1060 +1060 .rodata 26976 27808 +832 gcm_gf_mult - 820 +820 gcm_add_aad - 660 +660 gcm_shift_table - 512 +512 gcm_done - 471 +471 gcm_add_iv - 384 +384 gcm_init - 347 +347 dropbear_gcm_crypt - 309 +309 encrypt_packet 1068 1270 +202 decrypt_packet 756 897 +141 gcm_reset - 118 +118 read_packet 543 637 +94 read_kex_algos 792 880 +88 sshciphers 280 360 +80 gcm_mult_h - 80 +80 dropbear_gcm_start - 62 +62 dropbear_mode_gcm - 48 +48 dropbear_mode_none 24 48 +24 dropbear_mode_ctr 24 48 +24 dropbear_mode_cbc 24 48 +24 dropbear_ghash - 24 +24 dropbear_gcm_getlength - 24 +24 gen_new_keys 848 854 +6 ------------------------------------------------------------------------------ (add/remove: 14/0 grow/shrink: 10/0 up/down: 6434/0) Total: 6434 bytes

/* LibTomCrypt, modular cryptographic library -- Tom St Denis
 *
 * LibTomCrypt is a library that provides various cryptographic
 * algorithms in a highly modular and flexible manner.
 *
 * The library is free for all purposes without any express
 * guarantee it works.
 */
#include "tomcrypt.h"

/**
   @file f8_start.c
   F8 implementation, start chain, Tom St Denis
*/


#ifdef LTC_F8_MODE

/**
   Initialize an F8 context
   @param cipher      The index of the cipher desired
   @param IV          The initialization vector
   @param key         The secret key
   @param keylen      The length of the secret key (octets)
   @param salt_key    The salting key for the IV
   @param skeylen     The length of the salting key (octets)
   @param num_rounds  Number of rounds in the cipher desired (0 for default)
   @param f8          The F8 state to initialize
   @return CRYPT_OK if successful
*/
int f8_start(                int  cipher, const unsigned char *IV,
             const unsigned char *key,                    int  keylen,
             const unsigned char *salt_key,               int  skeylen,
                             int  num_rounds,   symmetric_F8  *f8)
{
   int           x, err;
   unsigned char tkey[MAXBLOCKSIZE];

   LTC_ARGCHK(IV       != NULL);
   LTC_ARGCHK(key      != NULL);
   LTC_ARGCHK(salt_key != NULL);
   LTC_ARGCHK(f8       != NULL);

   if ((err = cipher_is_valid(cipher)) != CRYPT_OK) {
      return err;
   }

#ifdef LTC_FAST
   if (cipher_descriptor[cipher].block_length % sizeof(LTC_FAST_TYPE)) {
      return CRYPT_INVALID_ARG;
   }
#endif

   /* copy details */
   f8->blockcnt = 0;
   f8->cipher   = cipher;
   f8->blocklen = cipher_descriptor[cipher].block_length;
   f8->padlen   = f8->blocklen;

   /* now get key ^ salt_key [extend salt_ket with 0x55 as required to match length] */
   zeromem(tkey, sizeof(tkey));
   for (x = 0; x < keylen && x < (int)sizeof(tkey); x++) {
       tkey[x] = key[x];
   }
   for (x = 0; x < skeylen && x < (int)sizeof(tkey); x++) {
       tkey[x] ^= salt_key[x];
   }
   for (; x < keylen && x < (int)sizeof(tkey); x++) {
       tkey[x] ^= 0x55;
   }

   /* now encrypt with tkey[0..keylen-1] the IV and use that as the IV */
   if ((err = cipher_descriptor[cipher].setup(tkey, keylen, num_rounds, &f8->key)) != CRYPT_OK) {
      return err;
   }

   /* encrypt IV */
   if ((err = cipher_descriptor[f8->cipher].ecb_encrypt(IV, f8->MIV, &f8->key)) != CRYPT_OK) {
      cipher_descriptor[f8->cipher].done(&f8->key);
      return err;
   }
   zeromem(tkey, sizeof(tkey));
   zeromem(f8->IV, sizeof(f8->IV));

   /* terminate this cipher */
   cipher_descriptor[f8->cipher].done(&f8->key);

   /* init the cipher */
   return cipher_descriptor[cipher].setup(key, keylen, num_rounds, &f8->key);
}

#endif

/* ref:         $Format:%D$ */
/* git commit:  $Format:%H$ */
/* commit time: $Format:%ai$ */