Mercurial > dropbear
view libtomcrypt/src/stream/sober128/sober128_stream.c @ 1857:6022df862942
Use DSCP for IP QoS traffic classes
The previous TOS values are deprecated and not used by modern traffic
classifiers. This sets AF21 for "interactive" traffic (with a tty).
Non-tty traffic sets AF11 - that indicates high throughput but is not
lowest priority (which would be CS1 or LE).
This differs from the CS1 used by OpenSSH, it lets interactive git over SSH
have higher priority than background least effort traffic. Dropbear's settings
here should be suitable with the diffservs used by CAKE qdisc.
author | Matt Johnston <matt@ucc.asn.au> |
---|---|
date | Tue, 25 Jan 2022 17:32:20 +0800 |
parents | 6dba84798cd5 |
children |
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/* 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 sober128_stream.c Implementation of SOBER-128 by Tom St Denis. Based on s128fast.c reference code supplied by Greg Rose of QUALCOMM. */ #ifdef LTC_SOBER128 #define __LTC_SOBER128TAB_C__ #include "sober128tab.c" /* don't change these... */ #define N 17 #define FOLD N /* how many iterations of folding to do */ #define INITKONST 0x6996c53a /* value of KONST to use during key loading */ #define KEYP 15 /* where to insert key words */ #define FOLDP 4 /* where to insert non-linear feedback */ #define B(x,i) ((unsigned char)(((x) >> (8*i)) & 0xFF)) static ulong32 BYTE2WORD(unsigned char *b) { ulong32 t; LOAD32L(t, b); return t; } static void XORWORD(ulong32 w, const unsigned char *in, unsigned char *out) { ulong32 t; LOAD32L(t, in); t ^= w; STORE32L(t, out); } /* give correct offset for the current position of the register, * where logically R[0] is at position "zero". */ #define OFF(zero, i) (((zero)+(i)) % N) /* step the LFSR */ /* After stepping, "zero" moves right one place */ #define STEP(R,z) \ R[OFF(z,0)] = R[OFF(z,15)] ^ R[OFF(z,4)] ^ (R[OFF(z,0)] << 8) ^ Multab[(R[OFF(z,0)] >> 24) & 0xFF]; static void cycle(ulong32 *R) { ulong32 t; int i; STEP(R,0); t = R[0]; for (i = 1; i < N; ++i) { R[i-1] = R[i]; } R[N-1] = t; } /* Return a non-linear function of some parts of the register. */ #define NLFUNC(c,z) \ { \ t = c->R[OFF(z,0)] + c->R[OFF(z,16)]; \ t ^= Sbox[(t >> 24) & 0xFF]; \ t = RORc(t, 8); \ t = ((t + c->R[OFF(z,1)]) ^ c->konst) + c->R[OFF(z,6)]; \ t ^= Sbox[(t >> 24) & 0xFF]; \ t = t + c->R[OFF(z,13)]; \ } static ulong32 nltap(sober128_state *c) { ulong32 t; NLFUNC(c, 0); return t; } /* Save the current register state */ static void s128_savestate(sober128_state *c) { int i; for (i = 0; i < N; ++i) { c->initR[i] = c->R[i]; } } /* initialise to previously saved register state */ static void s128_reloadstate(sober128_state *c) { int i; for (i = 0; i < N; ++i) { c->R[i] = c->initR[i]; } } /* Initialise "konst" */ static void s128_genkonst(sober128_state *c) { ulong32 newkonst; do { cycle(c->R); newkonst = nltap(c); } while ((newkonst & 0xFF000000) == 0); c->konst = newkonst; } /* Load key material into the register */ #define ADDKEY(k) \ c->R[KEYP] += (k); #define XORNL(nl) \ c->R[FOLDP] ^= (nl); /* nonlinear diffusion of register for key */ #define DROUND(z) STEP(c->R,z); NLFUNC(c,(z+1)); c->R[OFF((z+1),FOLDP)] ^= t; static void s128_diffuse(sober128_state *c) { ulong32 t; /* relies on FOLD == N == 17! */ DROUND(0); DROUND(1); DROUND(2); DROUND(3); DROUND(4); DROUND(5); DROUND(6); DROUND(7); DROUND(8); DROUND(9); DROUND(10); DROUND(11); DROUND(12); DROUND(13); DROUND(14); DROUND(15); DROUND(16); } /** Initialize an Sober128 context (only the key) @param c [out] The destination of the Sober128 state @param key The secret key @param keylen The length of the secret key (octets) @return CRYPT_OK if successful */ int sober128_stream_setup(sober128_state *c, const unsigned char *key, unsigned long keylen) { ulong32 i, k; LTC_ARGCHK(c != NULL); LTC_ARGCHK(key != NULL); LTC_ARGCHK(keylen > 0); /* keylen must be multiple of 4 bytes */ if ((keylen & 3) != 0) { return CRYPT_INVALID_KEYSIZE; } /* Register initialised to Fibonacci numbers */ c->R[0] = 1; c->R[1] = 1; for (i = 2; i < N; ++i) { c->R[i] = c->R[i-1] + c->R[i-2]; } c->konst = INITKONST; for (i = 0; i < keylen; i += 4) { k = BYTE2WORD((unsigned char *)&key[i]); ADDKEY(k); cycle(c->R); XORNL(nltap(c)); } /* also fold in the length of the key */ ADDKEY(keylen); /* now diffuse */ s128_diffuse(c); s128_genkonst(c); s128_savestate(c); c->nbuf = 0; return CRYPT_OK; } /** Set IV to the Sober128 state @param c The Sober12820 state @param iv The IV data to add @param ivlen The length of the IV (must be 12) @return CRYPT_OK on success */ int sober128_stream_setiv(sober128_state *c, const unsigned char *iv, unsigned long ivlen) { ulong32 i, k; LTC_ARGCHK(c != NULL); LTC_ARGCHK(iv != NULL); LTC_ARGCHK(ivlen > 0); /* ok we are adding an IV then... */ s128_reloadstate(c); /* ivlen must be multiple of 4 bytes */ if ((ivlen & 3) != 0) { return CRYPT_INVALID_KEYSIZE; } for (i = 0; i < ivlen; i += 4) { k = BYTE2WORD((unsigned char *)&iv[i]); ADDKEY(k); cycle(c->R); XORNL(nltap(c)); } /* also fold in the length of the key */ ADDKEY(ivlen); /* now diffuse */ s128_diffuse(c); c->nbuf = 0; return CRYPT_OK; } /* XOR pseudo-random bytes into buffer */ #define SROUND(z) STEP(c->R,z); NLFUNC(c,(z+1)); XORWORD(t, in+(z*4), out+(z*4)); /** Encrypt (or decrypt) bytes of ciphertext (or plaintext) with Sober128 @param c The Sober128 state @param in The plaintext (or ciphertext) @param inlen The length of the input (octets) @param out [out] The ciphertext (or plaintext), length inlen @return CRYPT_OK if successful */ int sober128_stream_crypt(sober128_state *c, const unsigned char *in, unsigned long inlen, unsigned char *out) { ulong32 t; if (inlen == 0) return CRYPT_OK; /* nothing to do */ LTC_ARGCHK(out != NULL); LTC_ARGCHK(c != NULL); /* handle any previously buffered bytes */ while (c->nbuf != 0 && inlen != 0) { *out++ = *in++ ^ (unsigned char)(c->sbuf & 0xFF); c->sbuf >>= 8; c->nbuf -= 8; --inlen; } #ifndef LTC_SMALL_CODE /* do lots at a time, if there's enough to do */ while (inlen >= N*4) { SROUND(0); SROUND(1); SROUND(2); SROUND(3); SROUND(4); SROUND(5); SROUND(6); SROUND(7); SROUND(8); SROUND(9); SROUND(10); SROUND(11); SROUND(12); SROUND(13); SROUND(14); SROUND(15); SROUND(16); out += 4*N; in += 4*N; inlen -= 4*N; } #endif /* do small or odd size buffers the slow way */ while (4 <= inlen) { cycle(c->R); t = nltap(c); XORWORD(t, in, out); out += 4; in += 4; inlen -= 4; } /* handle any trailing bytes */ if (inlen != 0) { cycle(c->R); c->sbuf = nltap(c); c->nbuf = 32; while (c->nbuf != 0 && inlen != 0) { *out++ = *in++ ^ (unsigned char)(c->sbuf & 0xFF); c->sbuf >>= 8; c->nbuf -= 8; --inlen; } } return CRYPT_OK; } int sober128_stream_keystream(sober128_state *c, unsigned char *out, unsigned long outlen) { if (outlen == 0) return CRYPT_OK; /* nothing to do */ LTC_ARGCHK(out != NULL); XMEMSET(out, 0, outlen); return sober128_stream_crypt(c, out, outlen, out); } /** Terminate and clear Sober128 state @param c The Sober128 state @return CRYPT_OK on success */ int sober128_stream_done(sober128_state *c) { LTC_ARGCHK(c != NULL); XMEMSET(c, 0, sizeof(sober128_state)); return CRYPT_OK; } #endif /* ref: $Format:%D$ */ /* git commit: $Format:%H$ */ /* commit time: $Format:%ai$ */