/*- * Copyright (c) 1991, 1993 * The Regents of the University of California. 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. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University 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 REGENTS 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 REGENTS 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. * * $FreeBSD: src/crypto/telnet/libtelnet/enc_des.c,v 1.3.2.2 2003/02/14 22:38:13 nectar Exp $ * $DragonFly: src/crypto/telnet/libtelnet/enc_des.c,v 1.2 2003/06/17 04:24:37 dillon Exp $ * * @(#)enc_des.c 8.3 (Berkeley) 5/30/95 * $FreeBSD: src/crypto/telnet/libtelnet/enc_des.c,v 1.3.2.2 2003/02/14 22:38:13 nectar Exp $ */ #ifdef ENCRYPTION # ifdef AUTHENTICATION #include #include #include #include #include #include "encrypt.h" #include "key-proto.h" #include "misc-proto.h" extern int encrypt_debug_mode; #define CFB 0 #define OFB 1 #define NO_SEND_IV 1 #define NO_RECV_IV 2 #define NO_KEYID 4 #define IN_PROGRESS (NO_SEND_IV|NO_RECV_IV|NO_KEYID) #define SUCCESS 0 #define FAILED -1 struct fb { Block krbdes_key; Schedule krbdes_sched; Block temp_feed; unsigned char fb_feed[64]; int need_start; int state[2]; int keyid[2]; struct stinfo { Block str_output; Block str_feed; Block str_iv; Block str_ikey; Schedule str_sched; int str_index; int str_flagshift; } streams[2]; }; static struct fb fb[2]; struct keyidlist { const char *keyid; int keyidlen; char *key; int keylen; int flags; } keyidlist [] = { { "\0", 1, 0, 0, 0 }, /* default key of zero */ { 0, 0, 0, 0, 0 } }; #define KEYFLAG_MASK 03 #define KEYFLAG_NOINIT 00 #define KEYFLAG_INIT 01 #define KEYFLAG_OK 02 #define KEYFLAG_BAD 03 #define KEYFLAG_SHIFT 2 #define SHIFT_VAL(a,b) (KEYFLAG_SHIFT*((a)+((b)*2))) #define FB64_IV 1 #define FB64_IV_OK 2 #define FB64_IV_BAD 3 void fb64_stream_iv(Block, struct stinfo *); void fb64_init(struct fb *); static int fb64_start(struct fb *, int, int); int fb64_is(unsigned char *, int, struct fb *); int fb64_reply(unsigned char *, int, struct fb *); static void fb64_session(Session_Key *, int, struct fb *); void fb64_stream_key(Block, struct stinfo *); int fb64_keyid(int, unsigned char *, int *, struct fb *); void cfb64_init(int server __unused) { fb64_init(&fb[CFB]); fb[CFB].fb_feed[4] = ENCTYPE_DES_CFB64; fb[CFB].streams[0].str_flagshift = SHIFT_VAL(0, CFB); fb[CFB].streams[1].str_flagshift = SHIFT_VAL(1, CFB); } void ofb64_init(int server __unused) { fb64_init(&fb[OFB]); fb[OFB].fb_feed[4] = ENCTYPE_DES_OFB64; fb[CFB].streams[0].str_flagshift = SHIFT_VAL(0, OFB); fb[CFB].streams[1].str_flagshift = SHIFT_VAL(1, OFB); } void fb64_init(struct fb *fbp) { memset((void *)fbp, 0, sizeof(*fbp)); fbp->state[0] = fbp->state[1] = FAILED; fbp->fb_feed[0] = IAC; fbp->fb_feed[1] = SB; fbp->fb_feed[2] = TELOPT_ENCRYPT; fbp->fb_feed[3] = ENCRYPT_IS; } /* * Returns: * -1: some error. Negotiation is done, encryption not ready. * 0: Successful, initial negotiation all done. * 1: successful, negotiation not done yet. * 2: Not yet. Other things (like getting the key from * Kerberos) have to happen before we can continue. */ int cfb64_start(int dir, int server) { return(fb64_start(&fb[CFB], dir, server)); } int ofb64_start(int dir, int server) { return(fb64_start(&fb[OFB], dir, server)); } static int fb64_start(struct fb *fbp, int dir, int server __unused) { size_t x; unsigned char *p; int state; switch (dir) { case DIR_DECRYPT: /* * This is simply a request to have the other side * start output (our input). He will negotiate an * IV so we need not look for it. */ state = fbp->state[dir-1]; if (state == FAILED) state = IN_PROGRESS; break; case DIR_ENCRYPT: state = fbp->state[dir-1]; if (state == FAILED) state = IN_PROGRESS; else if ((state & NO_SEND_IV) == 0) break; if (!VALIDKEY(fbp->krbdes_key)) { fbp->need_start = 1; break; } state &= ~NO_SEND_IV; state |= NO_RECV_IV; if (encrypt_debug_mode) printf("Creating new feed\r\n"); /* * Create a random feed and send it over. */ des_random_key((Block *)fbp->temp_feed); des_ecb_encrypt((Block *)fbp->temp_feed, (Block *)fbp->temp_feed, fbp->krbdes_sched, 1); p = fbp->fb_feed + 3; *p++ = ENCRYPT_IS; p++; *p++ = FB64_IV; for (x = 0; x < sizeof(Block); ++x) { if ((*p++ = fbp->temp_feed[x]) == IAC) *p++ = IAC; } *p++ = IAC; *p++ = SE; printsub('>', &fbp->fb_feed[2], p - &fbp->fb_feed[2]); net_write(fbp->fb_feed, p - fbp->fb_feed); break; default: return(FAILED); } return(fbp->state[dir-1] = state); } /* * Returns: * -1: some error. Negotiation is done, encryption not ready. * 0: Successful, initial negotiation all done. * 1: successful, negotiation not done yet. */ int cfb64_is(unsigned char *data, int cnt) { return(fb64_is(data, cnt, &fb[CFB])); } int ofb64_is(unsigned char *data, int cnt) { return(fb64_is(data, cnt, &fb[OFB])); } int fb64_is(unsigned char *data, int cnt, struct fb *fbp) { unsigned char *p; int state = fbp->state[DIR_DECRYPT-1]; if (cnt-- < 1) goto failure; switch (*data++) { case FB64_IV: if (cnt != sizeof(Block)) { if (encrypt_debug_mode) printf("CFB64: initial vector failed on size\r\n"); state = FAILED; goto failure; } if (encrypt_debug_mode) printf("CFB64: initial vector received\r\n"); if (encrypt_debug_mode) printf("Initializing Decrypt stream\r\n"); fb64_stream_iv((void *)data, &fbp->streams[DIR_DECRYPT-1]); p = fbp->fb_feed + 3; *p++ = ENCRYPT_REPLY; p++; *p++ = FB64_IV_OK; *p++ = IAC; *p++ = SE; printsub('>', &fbp->fb_feed[2], p - &fbp->fb_feed[2]); net_write(fbp->fb_feed, p - fbp->fb_feed); state = fbp->state[DIR_DECRYPT-1] = IN_PROGRESS; break; default: if (encrypt_debug_mode) { printf("Unknown option type: %d\r\n", *(data-1)); printd(data, cnt); printf("\r\n"); } /* FALL THROUGH */ failure: /* * We failed. Send an FB64_IV_BAD option * to the other side so it will know that * things failed. */ p = fbp->fb_feed + 3; *p++ = ENCRYPT_REPLY; p++; *p++ = FB64_IV_BAD; *p++ = IAC; *p++ = SE; printsub('>', &fbp->fb_feed[2], p - &fbp->fb_feed[2]); net_write(fbp->fb_feed, p - fbp->fb_feed); break; } return(fbp->state[DIR_DECRYPT-1] = state); } /* * Returns: * -1: some error. Negotiation is done, encryption not ready. * 0: Successful, initial negotiation all done. * 1: successful, negotiation not done yet. */ int cfb64_reply(unsigned char *data, int cnt) { return(fb64_reply(data, cnt, &fb[CFB])); } int ofb64_reply(unsigned char *data, int cnt) { return(fb64_reply(data, cnt, &fb[OFB])); } int fb64_reply(unsigned char *data, int cnt, struct fb *fbp) { int state = fbp->state[DIR_ENCRYPT-1]; if (cnt-- < 1) goto failure; switch (*data++) { case FB64_IV_OK: fb64_stream_iv(fbp->temp_feed, &fbp->streams[DIR_ENCRYPT-1]); if (state == FAILED) state = IN_PROGRESS; state &= ~NO_RECV_IV; encrypt_send_keyid(DIR_ENCRYPT, "\0", 1, 1); break; case FB64_IV_BAD: memset(fbp->temp_feed, 0, sizeof(Block)); fb64_stream_iv(fbp->temp_feed, &fbp->streams[DIR_ENCRYPT-1]); state = FAILED; break; default: if (encrypt_debug_mode) { printf("Unknown option type: %d\r\n", data[-1]); printd(data, cnt); printf("\r\n"); } /* FALL THROUGH */ failure: state = FAILED; break; } return(fbp->state[DIR_ENCRYPT-1] = state); } void cfb64_session(Session_Key *key, int server) { fb64_session(key, server, &fb[CFB]); } void ofb64_session(Session_Key *key, int server) { fb64_session(key, server, &fb[OFB]); } static void fb64_session(Session_Key *key, int server, struct fb *fbp) { if (!key || key->type != SK_DES) { if (encrypt_debug_mode) printf("Can't set krbdes's session key (%d != %d)\r\n", key ? key->type : -1, SK_DES); return; } memmove((void *)fbp->krbdes_key, (void *)key->data, sizeof(Block)); fb64_stream_key(fbp->krbdes_key, &fbp->streams[DIR_ENCRYPT-1]); fb64_stream_key(fbp->krbdes_key, &fbp->streams[DIR_DECRYPT-1]); des_key_sched((Block *)fbp->krbdes_key, fbp->krbdes_sched); /* * Now look to see if krbdes_start() was was waiting for * the key to show up. If so, go ahead an call it now * that we have the key. */ if (fbp->need_start) { fbp->need_start = 0; fb64_start(fbp, DIR_ENCRYPT, server); } } /* * We only accept a keyid of 0. If we get a keyid of * 0, then mark the state as SUCCESS. */ int cfb64_keyid(int dir, unsigned char *kp, int *lenp) { return(fb64_keyid(dir, kp, lenp, &fb[CFB])); } int ofb64_keyid(int dir, unsigned char *kp, int *lenp) { return(fb64_keyid(dir, kp, lenp, &fb[OFB])); } int fb64_keyid(int dir, unsigned char *kp, int *lenp, struct fb *fbp) { int state = fbp->state[dir-1]; if (*lenp != 1 || (*kp != '\0')) { *lenp = 0; return(state); } if (state == FAILED) state = IN_PROGRESS; state &= ~NO_KEYID; return(fbp->state[dir-1] = state); } void fb64_printsub(unsigned char *data, int cnt, unsigned char *buf, int buflen, const char *type) { char lbuf[32]; int i; char *cp; buf[buflen-1] = '\0'; /* make sure it's NULL terminated */ buflen -= 1; switch(data[2]) { case FB64_IV: sprintf(lbuf, "%s_IV", type); cp = lbuf; goto common; case FB64_IV_OK: sprintf(lbuf, "%s_IV_OK", type); cp = lbuf; goto common; case FB64_IV_BAD: sprintf(lbuf, "%s_IV_BAD", type); cp = lbuf; goto common; default: sprintf(lbuf, " %d (unknown)", data[2]); cp = lbuf; common: for (; (buflen > 0) && (*buf = *cp++); buf++) buflen--; for (i = 3; i < cnt; i++) { sprintf(lbuf, " %d", data[i]); for (cp = lbuf; (buflen > 0) && (*buf = *cp++); buf++) buflen--; } break; } } void cfb64_printsub(unsigned char *data, int cnt, unsigned char *buf, int buflen) { fb64_printsub(data, cnt, buf, buflen, "CFB64"); } void ofb64_printsub(unsigned char *data, int cnt, unsigned char *buf, int buflen) { fb64_printsub(data, cnt, buf, buflen, "OFB64"); } void fb64_stream_iv(Block seed, struct stinfo *stp) { memmove((void *)stp->str_iv, (void *)seed, sizeof(Block)); memmove((void *)stp->str_output, (void *)seed, sizeof(Block)); des_key_sched((Block *)stp->str_ikey, stp->str_sched); stp->str_index = sizeof(Block); } void fb64_stream_key(Block key, struct stinfo *stp) { memmove((void *)stp->str_ikey, (void *)key, sizeof(Block)); des_key_sched((Block *)key, stp->str_sched); memmove((void *)stp->str_output, (void *)stp->str_iv, sizeof(Block)); stp->str_index = sizeof(Block); } /* * DES 64 bit Cipher Feedback * * key --->+-----+ * +->| DES |--+ * | +-----+ | * | v * INPUT --(--------->(+)+---> DATA * | | * +-------------+ * * * Given: * iV: Initial vector, 64 bits (8 bytes) long. * Dn: the nth chunk of 64 bits (8 bytes) of data to encrypt (decrypt). * On: the nth chunk of 64 bits (8 bytes) of encrypted (decrypted) output. * * V0 = DES(iV, key) * On = Dn ^ Vn * V(n+1) = DES(On, key) */ void cfb64_encrypt(unsigned char *s, int c) { struct stinfo *stp = &fb[CFB].streams[DIR_ENCRYPT-1]; int idx; idx = stp->str_index; while (c-- > 0) { if (idx == sizeof(Block)) { Block b; des_ecb_encrypt((Block *)stp->str_output, (Block *)b, stp->str_sched, 1); memmove((void *)stp->str_feed, (void *)b, sizeof(Block)); idx = 0; } /* On encryption, we store (feed ^ data) which is cypher */ *s = stp->str_output[idx] = (stp->str_feed[idx] ^ *s); s++; idx++; } stp->str_index = idx; } int cfb64_decrypt(int data) { struct stinfo *stp = &fb[CFB].streams[DIR_DECRYPT-1]; int idx; if (data == -1) { /* * Back up one byte. It is assumed that we will * never back up more than one byte. If we do, this * may or may not work. */ if (stp->str_index) --stp->str_index; return(0); } idx = stp->str_index++; if (idx == sizeof(Block)) { Block b; des_ecb_encrypt((Block *)stp->str_output, (Block *)b, stp->str_sched, 1); memmove((void *)stp->str_feed, (void *)b, sizeof(Block)); stp->str_index = 1; /* Next time will be 1 */ idx = 0; /* But now use 0 */ } /* On decryption we store (data) which is cypher. */ stp->str_output[idx] = data; return(data ^ stp->str_feed[idx]); } /* * DES 64 bit Output Feedback * * key --->+-----+ * +->| DES |--+ * | +-----+ | * +-----------+ * v * INPUT -------->(+) ----> DATA * * Given: * iV: Initial vector, 64 bits (8 bytes) long. * Dn: the nth chunk of 64 bits (8 bytes) of data to encrypt (decrypt). * On: the nth chunk of 64 bits (8 bytes) of encrypted (decrypted) output. * * V0 = DES(iV, key) * V(n+1) = DES(Vn, key) * On = Dn ^ Vn */ void ofb64_encrypt(unsigned char *s, int c) { struct stinfo *stp = &fb[OFB].streams[DIR_ENCRYPT-1]; int idx; idx = stp->str_index; while (c-- > 0) { if (idx == sizeof(Block)) { Block b; des_ecb_encrypt((Block *)stp->str_feed, (Block *)b, stp->str_sched, 1); memmove((void *)stp->str_feed, (void *)b, sizeof(Block)); idx = 0; } *s++ ^= stp->str_feed[idx]; idx++; } stp->str_index = idx; } int ofb64_decrypt(int data) { struct stinfo *stp = &fb[OFB].streams[DIR_DECRYPT-1]; int idx; if (data == -1) { /* * Back up one byte. It is assumed that we will * never back up more than one byte. If we do, this * may or may not work. */ if (stp->str_index) --stp->str_index; return(0); } idx = stp->str_index++; if (idx == sizeof(Block)) { Block b; des_ecb_encrypt((Block *)stp->str_feed, (Block *)b, stp->str_sched, 1); memmove((void *)stp->str_feed, (void *)b, sizeof(Block)); stp->str_index = 1; /* Next time will be 1 */ idx = 0; /* But now use 0 */ } return(data ^ stp->str_feed[idx]); } # endif /* AUTHENTICATION */ #endif /* ENCRYPTION */