/* $NetBSD: esp_core.c,v 1.21 2002/02/27 01:32:17 itojun Exp $ */ /* $KAME: esp_core.c,v 1.53 2001/11/27 09:47:30 sakane Exp $ */ /* * Copyright (C) 1995, 1996, 1997, and 1998 WIDE Project. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the project nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE PROJECT AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE PROJECT OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include __KERNEL_RCSID(0, "$NetBSD: esp_core.c,v 1.21 2002/02/27 01:32:17 itojun Exp $"); #include "opt_inet.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef INET6 #include #include #include #endif #include #include #include #include #include #include #include #include #include #include #include static int esp_null_mature __P((struct secasvar *)); static int esp_null_decrypt __P((struct mbuf *, size_t, struct secasvar *, const struct esp_algorithm *, int)); static int esp_null_encrypt __P((struct mbuf *, size_t, size_t, struct secasvar *, const struct esp_algorithm *, int)); static int esp_descbc_mature __P((struct secasvar *)); static int esp_descbc_ivlen __P((const struct esp_algorithm *, struct secasvar *)); static int esp_des_schedule __P((const struct esp_algorithm *, struct secasvar *)); static int esp_des_schedlen __P((const struct esp_algorithm *)); static int esp_des_blockdecrypt __P((const struct esp_algorithm *, struct secasvar *, u_int8_t *, u_int8_t *)); static int esp_des_blockencrypt __P((const struct esp_algorithm *, struct secasvar *, u_int8_t *, u_int8_t *)); static int esp_cbc_mature __P((struct secasvar *)); static int esp_blowfish_schedule __P((const struct esp_algorithm *, struct secasvar *)); static int esp_blowfish_schedlen __P((const struct esp_algorithm *)); static int esp_blowfish_blockdecrypt __P((const struct esp_algorithm *, struct secasvar *, u_int8_t *, u_int8_t *)); static int esp_blowfish_blockencrypt __P((const struct esp_algorithm *, struct secasvar *, u_int8_t *, u_int8_t *)); static int esp_cast128_schedule __P((const struct esp_algorithm *, struct secasvar *)); static int esp_cast128_schedlen __P((const struct esp_algorithm *)); static int esp_cast128_blockdecrypt __P((const struct esp_algorithm *, struct secasvar *, u_int8_t *, u_int8_t *)); static int esp_cast128_blockencrypt __P((const struct esp_algorithm *, struct secasvar *, u_int8_t *, u_int8_t *)); static int esp_3des_schedule __P((const struct esp_algorithm *, struct secasvar *)); static int esp_3des_schedlen __P((const struct esp_algorithm *)); static int esp_3des_blockdecrypt __P((const struct esp_algorithm *, struct secasvar *, u_int8_t *, u_int8_t *)); static int esp_3des_blockencrypt __P((const struct esp_algorithm *, struct secasvar *, u_int8_t *, u_int8_t *)); static int esp_common_ivlen __P((const struct esp_algorithm *, struct secasvar *)); static int esp_cbc_decrypt __P((struct mbuf *, size_t, struct secasvar *, const struct esp_algorithm *, int)); static int esp_cbc_encrypt __P((struct mbuf *, size_t, size_t, struct secasvar *, const struct esp_algorithm *, int)); #define MAXIVLEN 16 static const struct esp_algorithm esp_algorithms[] = { { 8, -1, esp_descbc_mature, 64, 64, esp_des_schedlen, "des-cbc", esp_descbc_ivlen, esp_cbc_decrypt, esp_cbc_encrypt, esp_des_schedule, esp_des_blockdecrypt, esp_des_blockencrypt, }, { 8, 8, esp_cbc_mature, 192, 192, esp_3des_schedlen, "3des-cbc", esp_common_ivlen, esp_cbc_decrypt, esp_cbc_encrypt, esp_3des_schedule, esp_3des_blockdecrypt, esp_3des_blockencrypt, }, { 1, 0, esp_null_mature, 0, 2048, 0, "null", esp_common_ivlen, esp_null_decrypt, esp_null_encrypt, NULL, }, { 8, 8, esp_cbc_mature, 40, 448, esp_blowfish_schedlen, "blowfish-cbc", esp_common_ivlen, esp_cbc_decrypt, esp_cbc_encrypt, esp_blowfish_schedule, esp_blowfish_blockdecrypt, esp_blowfish_blockencrypt, }, { 8, 8, esp_cbc_mature, 40, 128, esp_cast128_schedlen, "cast128-cbc", esp_common_ivlen, esp_cbc_decrypt, esp_cbc_encrypt, esp_cast128_schedule, esp_cast128_blockdecrypt, esp_cast128_blockencrypt, }, { 16, 16, esp_cbc_mature, 128, 256, esp_rijndael_schedlen, "rijndael-cbc", esp_common_ivlen, esp_cbc_decrypt, esp_cbc_encrypt, esp_rijndael_schedule, esp_rijndael_blockdecrypt, esp_rijndael_blockencrypt }, }; const struct esp_algorithm * esp_algorithm_lookup(idx) int idx; { switch (idx) { case SADB_EALG_DESCBC: return &esp_algorithms[0]; case SADB_EALG_3DESCBC: return &esp_algorithms[1]; case SADB_EALG_NULL: return &esp_algorithms[2]; case SADB_X_EALG_BLOWFISHCBC: return &esp_algorithms[3]; case SADB_X_EALG_CAST128CBC: return &esp_algorithms[4]; case SADB_X_EALG_RIJNDAELCBC: return &esp_algorithms[5]; default: return NULL; } } int esp_max_ivlen() { int idx; int ivlen; ivlen = 0; for (idx = 0; idx < sizeof(esp_algorithms)/sizeof(esp_algorithms[0]); idx++) { if (esp_algorithms[idx].ivlenval > ivlen) ivlen = esp_algorithms[idx].ivlenval; } return ivlen; } int esp_schedule(algo, sav) const struct esp_algorithm *algo; struct secasvar *sav; { int error; /* check for key length */ if (_KEYBITS(sav->key_enc) < algo->keymin || _KEYBITS(sav->key_enc) > algo->keymax) { ipseclog((LOG_ERR, "esp_schedule %s: unsupported key length %d: " "needs %d to %d bits\n", algo->name, _KEYBITS(sav->key_enc), algo->keymin, algo->keymax)); return EINVAL; } /* already allocated */ if (sav->sched && sav->schedlen != 0) return 0; /* no schedule necessary */ if (!algo->schedule || !algo->schedlen) return 0; sav->schedlen = (*algo->schedlen)(algo); if (sav->schedlen < 0) return EINVAL; sav->sched = malloc(sav->schedlen, M_SECA, M_DONTWAIT); if (!sav->sched) { sav->schedlen = 0; return ENOBUFS; } error = (*algo->schedule)(algo, sav); if (error) { ipseclog((LOG_ERR, "esp_schedule %s: error %d\n", algo->name, error)); free(sav->sched, M_SECA); sav->sched = NULL; sav->schedlen = 0; } return error; } static int esp_null_mature(sav) struct secasvar *sav; { /* anything is okay */ return 0; } static int esp_null_decrypt(m, off, sav, algo, ivlen) struct mbuf *m; size_t off; /* offset to ESP header */ struct secasvar *sav; const struct esp_algorithm *algo; int ivlen; { return 0; /* do nothing */ } static int esp_null_encrypt(m, off, plen, sav, algo, ivlen) struct mbuf *m; size_t off; /* offset to ESP header */ size_t plen; /* payload length (to be encrypted) */ struct secasvar *sav; const struct esp_algorithm *algo; int ivlen; { return 0; /* do nothing */ } static int esp_descbc_mature(sav) struct secasvar *sav; { const struct esp_algorithm *algo; if (!(sav->flags & SADB_X_EXT_OLD) && (sav->flags & SADB_X_EXT_IV4B)) { ipseclog((LOG_ERR, "esp_cbc_mature: " "algorithm incompatible with 4 octets IV length\n")); return 1; } if (!sav->key_enc) { ipseclog((LOG_ERR, "esp_descbc_mature: no key is given.\n")); return 1; } algo = esp_algorithm_lookup(sav->alg_enc); if (!algo) { ipseclog((LOG_ERR, "esp_descbc_mature: unsupported algorithm.\n")); return 1; } if (_KEYBITS(sav->key_enc) < algo->keymin || _KEYBITS(sav->key_enc) > algo->keymax) { ipseclog((LOG_ERR, "esp_descbc_mature: invalid key length %d.\n", _KEYBITS(sav->key_enc))); return 1; } /* weak key check */ if (des_is_weak_key((des_cblock *)_KEYBUF(sav->key_enc))) { ipseclog((LOG_ERR, "esp_descbc_mature: weak key was passed.\n")); return 1; } return 0; } static int esp_descbc_ivlen(algo, sav) const struct esp_algorithm *algo; struct secasvar *sav; { if (!sav) return 8; if ((sav->flags & SADB_X_EXT_OLD) && (sav->flags & SADB_X_EXT_IV4B)) return 4; if (!(sav->flags & SADB_X_EXT_OLD) && (sav->flags & SADB_X_EXT_DERIV)) return 4; return 8; } static int esp_des_schedlen(algo) const struct esp_algorithm *algo; { return sizeof(des_key_schedule); } static int esp_des_schedule(algo, sav) const struct esp_algorithm *algo; struct secasvar *sav; { if (des_key_sched((des_cblock *)_KEYBUF(sav->key_enc), *(des_key_schedule *)sav->sched)) return EINVAL; else return 0; } static int esp_des_blockdecrypt(algo, sav, s, d) const struct esp_algorithm *algo; struct secasvar *sav; u_int8_t *s; u_int8_t *d; { /* assumption: d has a good alignment */ bcopy(s, d, sizeof(DES_LONG) * 2); des_ecb_encrypt((des_cblock *)d, (des_cblock *)d, *(des_key_schedule *)sav->sched, DES_DECRYPT); return 0; } static int esp_des_blockencrypt(algo, sav, s, d) const struct esp_algorithm *algo; struct secasvar *sav; u_int8_t *s; u_int8_t *d; { /* assumption: d has a good alignment */ bcopy(s, d, sizeof(DES_LONG) * 2); des_ecb_encrypt((des_cblock *)d, (des_cblock *)d, *(des_key_schedule *)sav->sched, DES_ENCRYPT); return 0; } static int esp_cbc_mature(sav) struct secasvar *sav; { int keylen; const struct esp_algorithm *algo; if (sav->flags & SADB_X_EXT_OLD) { ipseclog((LOG_ERR, "esp_cbc_mature: algorithm incompatible with esp-old\n")); return 1; } if (sav->flags & SADB_X_EXT_DERIV) { ipseclog((LOG_ERR, "esp_cbc_mature: algorithm incompatible with derived\n")); return 1; } if (!sav->key_enc) { ipseclog((LOG_ERR, "esp_cbc_mature: no key is given.\n")); return 1; } algo = esp_algorithm_lookup(sav->alg_enc); if (!algo) { ipseclog((LOG_ERR, "esp_cbc_mature %s: unsupported algorithm.\n", algo->name)); return 1; } keylen = sav->key_enc->sadb_key_bits; if (keylen < algo->keymin || algo->keymax < keylen) { ipseclog((LOG_ERR, "esp_cbc_mature %s: invalid key length %d.\n", algo->name, sav->key_enc->sadb_key_bits)); return 1; } switch (sav->alg_enc) { case SADB_EALG_3DESCBC: /* weak key check */ if (des_is_weak_key((des_cblock *)_KEYBUF(sav->key_enc)) || des_is_weak_key((des_cblock *)(_KEYBUF(sav->key_enc) + 8)) || des_is_weak_key((des_cblock *)(_KEYBUF(sav->key_enc) + 16))) { ipseclog((LOG_ERR, "esp_cbc_mature %s: weak key was passed.\n", algo->name)); return 1; } break; case SADB_X_EALG_BLOWFISHCBC: case SADB_X_EALG_CAST128CBC: break; case SADB_X_EALG_RIJNDAELCBC: /* allows specific key sizes only */ if (!(keylen == 128 || keylen == 192 || keylen == 256)) { ipseclog((LOG_ERR, "esp_cbc_mature %s: invalid key length %d.\n", algo->name, keylen)); return 1; } break; } return 0; } static int esp_blowfish_schedlen(algo) const struct esp_algorithm *algo; { return sizeof(BF_KEY); } static int esp_blowfish_schedule(algo, sav) const struct esp_algorithm *algo; struct secasvar *sav; { BF_set_key((BF_KEY *)sav->sched, _KEYLEN(sav->key_enc), _KEYBUF(sav->key_enc)); return 0; } static int esp_blowfish_blockdecrypt(algo, sav, s, d) const struct esp_algorithm *algo; struct secasvar *sav; u_int8_t *s; u_int8_t *d; { /* HOLY COW! BF_decrypt() takes values in host byteorder */ BF_LONG t[2]; bcopy(s, t, sizeof(t)); t[0] = ntohl(t[0]); t[1] = ntohl(t[1]); BF_decrypt(t, (BF_KEY *)sav->sched); t[0] = htonl(t[0]); t[1] = htonl(t[1]); bcopy(t, d, sizeof(t)); return 0; } static int esp_blowfish_blockencrypt(algo, sav, s, d) const struct esp_algorithm *algo; struct secasvar *sav; u_int8_t *s; u_int8_t *d; { /* HOLY COW! BF_encrypt() takes values in host byteorder */ BF_LONG t[2]; bcopy(s, t, sizeof(t)); t[0] = ntohl(t[0]); t[1] = ntohl(t[1]); BF_encrypt(t, (BF_KEY *)sav->sched); t[0] = htonl(t[0]); t[1] = htonl(t[1]); bcopy(t, d, sizeof(t)); return 0; } static int esp_cast128_schedlen(algo) const struct esp_algorithm *algo; { return sizeof(u_int32_t) * 32; } static int esp_cast128_schedule(algo, sav) const struct esp_algorithm *algo; struct secasvar *sav; { set_cast128_subkey((u_int32_t *)sav->sched, _KEYBUF(sav->key_enc), _KEYLEN(sav->key_enc)); return 0; } static int esp_cast128_blockdecrypt(algo, sav, s, d) const struct esp_algorithm *algo; struct secasvar *sav; u_int8_t *s; u_int8_t *d; { if (_KEYLEN(sav->key_enc) <= 80 / 8) cast128_decrypt_round12(d, s, (u_int32_t *)sav->sched); else cast128_decrypt_round16(d, s, (u_int32_t *)sav->sched); return 0; } static int esp_cast128_blockencrypt(algo, sav, s, d) const struct esp_algorithm *algo; struct secasvar *sav; u_int8_t *s; u_int8_t *d; { if (_KEYLEN(sav->key_enc) <= 80 / 8) cast128_encrypt_round12(d, s, (u_int32_t *)sav->sched); else cast128_encrypt_round16(d, s, (u_int32_t *)sav->sched); return 0; } static int esp_3des_schedlen(algo) const struct esp_algorithm *algo; { return sizeof(des_key_schedule) * 3; } static int esp_3des_schedule(algo, sav) const struct esp_algorithm *algo; struct secasvar *sav; { int error; des_key_schedule *p; int i; char *k; p = (des_key_schedule *)sav->sched; k = _KEYBUF(sav->key_enc); for (i = 0; i < 3; i++) { error = des_key_sched((des_cblock *)(k + 8 * i), p[i]); if (error) return EINVAL; } return 0; } static int esp_3des_blockdecrypt(algo, sav, s, d) const struct esp_algorithm *algo; struct secasvar *sav; u_int8_t *s; u_int8_t *d; { des_key_schedule *p; /* assumption: d has a good alignment */ p = (des_key_schedule *)sav->sched; bcopy(s, d, sizeof(DES_LONG) * 2); des_ecb3_encrypt((des_cblock *)d, (des_cblock *)d, p[0], p[1], p[2], DES_DECRYPT); return 0; } static int esp_3des_blockencrypt(algo, sav, s, d) const struct esp_algorithm *algo; struct secasvar *sav; u_int8_t *s; u_int8_t *d; { des_key_schedule *p; /* assumption: d has a good alignment */ p = (des_key_schedule *)sav->sched; bcopy(s, d, sizeof(DES_LONG) * 2); des_ecb3_encrypt((des_cblock *)d, (des_cblock *)d, p[0], p[1], p[2], DES_ENCRYPT); return 0; } static int esp_common_ivlen(algo, sav) const struct esp_algorithm *algo; struct secasvar *sav; { if (!algo) panic("esp_common_ivlen: unknown algorithm"); return algo->ivlenval; } static int esp_cbc_decrypt(m, off, sav, algo, ivlen) struct mbuf *m; size_t off; struct secasvar *sav; const struct esp_algorithm *algo; int ivlen; { struct mbuf *s; struct mbuf *d, *d0, *dp; int soff, doff; /* offset from the head of chain, to head of this mbuf */ int sn, dn; /* offset from the head of the mbuf, to meat */ size_t ivoff, bodyoff; u_int8_t iv[MAXIVLEN], *ivp; u_int8_t sbuf[MAXIVLEN], *sp; u_int8_t *p, *q; struct mbuf *scut; int scutoff; int i; int blocklen; int derived; if (ivlen != sav->ivlen || ivlen > sizeof(iv)) { ipseclog((LOG_ERR, "esp_cbc_decrypt %s: " "unsupported ivlen %d\n", algo->name, ivlen)); m_freem(m); return EINVAL; } /* assumes blocklen == padbound */ blocklen = algo->padbound; #ifdef DIAGNOSTIC if (blocklen > sizeof(iv)) { ipseclog((LOG_ERR, "esp_cbc_decrypt %s: " "unsupported blocklen %d\n", algo->name, blocklen)); m_freem(m); return EINVAL; } #endif if (sav->flags & SADB_X_EXT_OLD) { /* RFC 1827 */ ivoff = off + sizeof(struct esp); bodyoff = off + sizeof(struct esp) + ivlen; derived = 0; } else { /* RFC 2406 */ if (sav->flags & SADB_X_EXT_DERIV) { /* * draft-ietf-ipsec-ciph-des-derived-00.txt * uses sequence number field as IV field. */ ivoff = off + sizeof(struct esp); bodyoff = off + sizeof(struct esp) + sizeof(u_int32_t); ivlen = sizeof(u_int32_t); derived = 1; } else { ivoff = off + sizeof(struct newesp); bodyoff = off + sizeof(struct newesp) + ivlen; derived = 0; } } /* grab iv */ m_copydata(m, ivoff, ivlen, iv); /* extend iv */ if (ivlen == blocklen) ; else if (ivlen == 4 && blocklen == 8) { bcopy(&iv[0], &iv[4], 4); iv[4] ^= 0xff; iv[5] ^= 0xff; iv[6] ^= 0xff; iv[7] ^= 0xff; } else { ipseclog((LOG_ERR, "esp_cbc_encrypt %s: " "unsupported ivlen/blocklen: %d %d\n", algo->name, ivlen, blocklen)); m_freem(m); return EINVAL; } if (m->m_pkthdr.len < bodyoff) { ipseclog((LOG_ERR, "esp_cbc_decrypt %s: bad len %d/%lu\n", algo->name, m->m_pkthdr.len, (unsigned long)bodyoff)); m_freem(m); return EINVAL; } if ((m->m_pkthdr.len - bodyoff) % blocklen) { ipseclog((LOG_ERR, "esp_cbc_decrypt %s: " "payload length must be multiple of %d\n", algo->name, blocklen)); m_freem(m); return EINVAL; } s = m; d = d0 = dp = NULL; soff = doff = sn = dn = 0; ivp = sp = NULL; /* skip bodyoff */ while (soff < bodyoff) { if (soff + s->m_len > bodyoff) { sn = bodyoff - soff; break; } soff += s->m_len; s = s->m_next; } scut = s; scutoff = sn; /* skip over empty mbuf */ while (s && s->m_len == 0) s = s->m_next; while (soff < m->m_pkthdr.len) { /* source */ if (sn + blocklen <= s->m_len) { /* body is continuous */ sp = mtod(s, u_int8_t *) + sn; } else { /* body is non-continuous */ m_copydata(s, sn, blocklen, sbuf); sp = sbuf; } /* destination */ if (!d || dn + blocklen > d->m_len) { if (d) dp = d; MGET(d, M_DONTWAIT, MT_DATA); i = m->m_pkthdr.len - (soff + sn); if (d && i > MLEN) { MCLGET(d, M_DONTWAIT); if ((d->m_flags & M_EXT) == 0) { m_free(d); d = NULL; } } if (!d) { m_freem(m); if (d0) m_freem(d0); return ENOBUFS; } if (!d0) d0 = d; if (dp) dp->m_next = d; d->m_len = 0; d->m_len = (M_TRAILINGSPACE(d) / blocklen) * blocklen; if (d->m_len > i) d->m_len = i; dn = 0; } /* decrypt */ (*algo->blockdecrypt)(algo, sav, sp, mtod(d, u_int8_t *) + dn); /* xor */ p = ivp ? ivp : iv; q = mtod(d, u_int8_t *) + dn; for (i = 0; i < blocklen; i++) q[i] ^= p[i]; /* next iv */ if (sp == sbuf) { bcopy(sbuf, iv, blocklen); ivp = NULL; } else ivp = sp; sn += blocklen; dn += blocklen; /* find the next source block */ while (s && sn >= s->m_len) { sn -= s->m_len; soff += s->m_len; s = s->m_next; } /* skip over empty mbuf */ while (s && s->m_len == 0) s = s->m_next; } m_freem(scut->m_next); scut->m_len = scutoff; scut->m_next = d0; /* just in case */ bzero(iv, sizeof(iv)); bzero(sbuf, sizeof(sbuf)); return 0; } static int esp_cbc_encrypt(m, off, plen, sav, algo, ivlen) struct mbuf *m; size_t off; size_t plen; struct secasvar *sav; const struct esp_algorithm *algo; int ivlen; { struct mbuf *s; struct mbuf *d, *d0, *dp; int soff, doff; /* offset from the head of chain, to head of this mbuf */ int sn, dn; /* offset from the head of the mbuf, to meat */ size_t ivoff, bodyoff; u_int8_t iv[MAXIVLEN], *ivp; u_int8_t sbuf[MAXIVLEN], *sp; u_int8_t *p, *q; struct mbuf *scut; int scutoff; int i; int blocklen; int derived; if (ivlen != sav->ivlen || ivlen > sizeof(iv)) { ipseclog((LOG_ERR, "esp_cbc_encrypt %s: " "unsupported ivlen %d\n", algo->name, ivlen)); m_freem(m); return EINVAL; } /* assumes blocklen == padbound */ blocklen = algo->padbound; #ifdef DIAGNOSTIC if (blocklen > sizeof(iv)) { ipseclog((LOG_ERR, "esp_cbc_encrypt %s: " "unsupported blocklen %d\n", algo->name, blocklen)); m_freem(m); return EINVAL; } #endif if (sav->flags & SADB_X_EXT_OLD) { /* RFC 1827 */ ivoff = off + sizeof(struct esp); bodyoff = off + sizeof(struct esp) + ivlen; derived = 0; } else { /* RFC 2406 */ if (sav->flags & SADB_X_EXT_DERIV) { /* * draft-ietf-ipsec-ciph-des-derived-00.txt * uses sequence number field as IV field. */ ivoff = off + sizeof(struct esp); bodyoff = off + sizeof(struct esp) + sizeof(u_int32_t); ivlen = sizeof(u_int32_t); derived = 1; } else { ivoff = off + sizeof(struct newesp); bodyoff = off + sizeof(struct newesp) + ivlen; derived = 0; } } /* put iv into the packet. if we are in derived mode, use seqno. */ if (derived) m_copydata(m, ivoff, ivlen, iv); else { bcopy(sav->iv, iv, ivlen); /* maybe it is better to overwrite dest, not source */ m_copyback(m, ivoff, ivlen, iv); } /* extend iv */ if (ivlen == blocklen) ; else if (ivlen == 4 && blocklen == 8) { bcopy(&iv[0], &iv[4], 4); iv[4] ^= 0xff; iv[5] ^= 0xff; iv[6] ^= 0xff; iv[7] ^= 0xff; } else { ipseclog((LOG_ERR, "esp_cbc_encrypt %s: " "unsupported ivlen/blocklen: %d %d\n", algo->name, ivlen, blocklen)); m_freem(m); return EINVAL; } if (m->m_pkthdr.len < bodyoff) { ipseclog((LOG_ERR, "esp_cbc_encrypt %s: bad len %d/%lu\n", algo->name, m->m_pkthdr.len, (unsigned long)bodyoff)); m_freem(m); return EINVAL; } if ((m->m_pkthdr.len - bodyoff) % blocklen) { ipseclog((LOG_ERR, "esp_cbc_encrypt %s: " "payload length must be multiple of %lu\n", algo->name, (unsigned long)algo->padbound)); m_freem(m); return EINVAL; } s = m; d = d0 = dp = NULL; soff = doff = sn = dn = 0; ivp = sp = NULL; /* skip bodyoff */ while (soff < bodyoff) { if (soff + s->m_len > bodyoff) { sn = bodyoff - soff; break; } soff += s->m_len; s = s->m_next; } scut = s; scutoff = sn; /* skip over empty mbuf */ while (s && s->m_len == 0) s = s->m_next; while (soff < m->m_pkthdr.len) { /* source */ if (sn + blocklen <= s->m_len) { /* body is continuous */ sp = mtod(s, u_int8_t *) + sn; } else { /* body is non-continuous */ m_copydata(s, sn, blocklen, sbuf); sp = sbuf; } /* destination */ if (!d || dn + blocklen > d->m_len) { if (d) dp = d; MGET(d, M_DONTWAIT, MT_DATA); i = m->m_pkthdr.len - (soff + sn); if (d && i > MLEN) { MCLGET(d, M_DONTWAIT); if ((d->m_flags & M_EXT) == 0) { m_free(d); d = NULL; } } if (!d) { m_freem(m); if (d0) m_freem(d0); return ENOBUFS; } if (!d0) d0 = d; if (dp) dp->m_next = d; d->m_len = 0; d->m_len = (M_TRAILINGSPACE(d) / blocklen) * blocklen; if (d->m_len > i) d->m_len = i; dn = 0; } /* xor */ p = ivp ? ivp : iv; q = sp; for (i = 0; i < blocklen; i++) q[i] ^= p[i]; /* encrypt */ (*algo->blockencrypt)(algo, sav, sp, mtod(d, u_int8_t *) + dn); /* next iv */ ivp = mtod(d, u_int8_t *) + dn; sn += blocklen; dn += blocklen; /* find the next source block */ while (s && sn >= s->m_len) { sn -= s->m_len; soff += s->m_len; s = s->m_next; } /* skip over empty mbuf */ while (s && s->m_len == 0) s = s->m_next; } m_freem(scut->m_next); scut->m_len = scutoff; scut->m_next = d0; /* just in case */ bzero(iv, sizeof(iv)); bzero(sbuf, sizeof(sbuf)); key_sa_stir_iv(sav); return 0; } /*------------------------------------------------------------*/ /* does not free m0 on error */ int esp_auth(m0, skip, length, sav, sum) struct mbuf *m0; size_t skip; /* offset to ESP header */ size_t length; /* payload length */ struct secasvar *sav; u_char *sum; { struct mbuf *m; size_t off; struct ah_algorithm_state s; u_char sumbuf[AH_MAXSUMSIZE]; const struct ah_algorithm *algo; size_t siz; int error; /* sanity checks */ if (m0->m_pkthdr.len < skip) { ipseclog((LOG_DEBUG, "esp_auth: mbuf length < skip\n")); return EINVAL; } if (m0->m_pkthdr.len < skip + length) { ipseclog((LOG_DEBUG, "esp_auth: mbuf length < skip + length\n")); return EINVAL; } /* * length of esp part (excluding authentication data) must be 4n, * since nexthdr must be at offset 4n+3. */ if (length % 4) { ipseclog((LOG_ERR, "esp_auth: length is not multiple of 4\n")); return EINVAL; } if (!sav) { ipseclog((LOG_DEBUG, "esp_auth: NULL SA passed\n")); return EINVAL; } algo = ah_algorithm_lookup(sav->alg_auth); if (!algo) { ipseclog((LOG_ERR, "esp_auth: bad ESP auth algorithm passed: %d\n", sav->alg_auth)); return EINVAL; } m = m0; off = 0; siz = (((*algo->sumsiz)(sav) + 3) & ~(4 - 1)); if (sizeof(sumbuf) < siz) { ipseclog((LOG_DEBUG, "esp_auth: AH_MAXSUMSIZE is too small: siz=%lu\n", (u_long)siz)); return EINVAL; } /* skip the header */ while (skip) { if (!m) panic("mbuf chain?"); if (m->m_len <= skip) { skip -= m->m_len; m = m->m_next; off = 0; } else { off = skip; skip = 0; } } error = (*algo->init)(&s, sav); if (error) return error; while (0 < length) { if (!m) panic("mbuf chain?"); if (m->m_len - off < length) { (*algo->update)(&s, mtod(m, u_char *) + off, m->m_len - off); length -= m->m_len - off; m = m->m_next; off = 0; } else { (*algo->update)(&s, mtod(m, u_char *) + off, length); break; } } (*algo->result)(&s, sumbuf); bcopy(sumbuf, sum, siz); /* XXX */ return 0; }