/* * Author: Tatu Ylonen * Copyright (c) 1995 Tatu Ylonen , Espoo, Finland * All rights reserved * * As far as I am concerned, the code I have written for this software * can be used freely for any purpose. Any derived versions of this * software must be clearly marked as such, and if the derived work is * incompatible with the protocol description in the RFC file, it must be * called by a name other than "ssh" or "Secure Shell". * * * Copyright (c) 1999 Niels Provos. All rights reserved. * Copyright (c) 1999,2000 Markus Friedl. 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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 "includes.h" RCSID("$OpenBSD: cipher.c,v 1.44 2001/05/28 22:51:10 markus Exp $"); #include "xmalloc.h" #include "log.h" #include "cipher.h" #include /* no encryption */ void none_setkey(CipherContext *cc, const u_char *key, u_int keylen) { } void none_setiv(CipherContext *cc, const u_char *iv, u_int ivlen) { } void none_crypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { memcpy(dest, src, len); } /* DES */ void des_ssh1_setkey(CipherContext *cc, const u_char *key, u_int keylen) { static int dowarn = 1; if (dowarn) { error("Warning: use of DES is strongly discouraged " "due to cryptographic weaknesses"); dowarn = 0; } des_set_key((void *)key, cc->u.des.key); } void des_ssh1_setiv(CipherContext *cc, const u_char *iv, u_int ivlen) { memset(cc->u.des.iv, 0, sizeof(cc->u.des.iv)); } void des_ssh1_encrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { des_ncbc_encrypt(src, dest, len, cc->u.des.key, &cc->u.des.iv, DES_ENCRYPT); } void des_ssh1_decrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { des_ncbc_encrypt(src, dest, len, cc->u.des.key, &cc->u.des.iv, DES_DECRYPT); } /* 3DES */ void des3_setkey(CipherContext *cc, const u_char *key, u_int keylen) { des_set_key((void *) key, cc->u.des3.key1); des_set_key((void *) (key+8), cc->u.des3.key2); des_set_key((void *) (key+16), cc->u.des3.key3); } void des3_setiv(CipherContext *cc, const u_char *iv, u_int ivlen) { memset(cc->u.des3.iv1, 0, sizeof(cc->u.des3.iv1)); memset(cc->u.des3.iv2, 0, sizeof(cc->u.des3.iv2)); memset(cc->u.des3.iv3, 0, sizeof(cc->u.des3.iv3)); if (iv == NULL) return; memcpy(cc->u.des3.iv3, (char *)iv, 8); } void des3_cbc_encrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { des_ede3_cbc_encrypt(src, dest, len, cc->u.des3.key1, cc->u.des3.key2, cc->u.des3.key3, &cc->u.des3.iv3, DES_ENCRYPT); } void des3_cbc_decrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { des_ede3_cbc_encrypt(src, dest, len, cc->u.des3.key1, cc->u.des3.key2, cc->u.des3.key3, &cc->u.des3.iv3, DES_DECRYPT); } /* * This is used by SSH1: * * What kind of triple DES are these 2 routines? * * Why is there a redundant initialization vector? * * If only iv3 was used, then, this would till effect have been * outer-cbc. However, there is also a private iv1 == iv2 which * perhaps makes differential analysis easier. On the other hand, the * private iv1 probably makes the CRC-32 attack ineffective. This is a * result of that there is no longer any known iv1 to use when * choosing the X block. */ void des3_ssh1_setkey(CipherContext *cc, const u_char *key, u_int keylen) { des_set_key((void *) key, cc->u.des3.key1); des_set_key((void *) (key+8), cc->u.des3.key2); if (keylen <= 16) des_set_key((void *) key, cc->u.des3.key3); else des_set_key((void *) (key+16), cc->u.des3.key3); } void des3_ssh1_encrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { des_ncbc_encrypt(src, dest, len, cc->u.des3.key1, &cc->u.des3.iv1, DES_ENCRYPT); des_ncbc_encrypt(dest, dest, len, cc->u.des3.key2, &cc->u.des3.iv2, DES_DECRYPT); des_ncbc_encrypt(dest, dest, len, cc->u.des3.key3, &cc->u.des3.iv3, DES_ENCRYPT); } void des3_ssh1_decrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { des_ncbc_encrypt(src, dest, len, cc->u.des3.key3, &cc->u.des3.iv3, DES_DECRYPT); des_ncbc_encrypt(dest, dest, len, cc->u.des3.key2, &cc->u.des3.iv2, DES_ENCRYPT); des_ncbc_encrypt(dest, dest, len, cc->u.des3.key1, &cc->u.des3.iv1, DES_DECRYPT); } /* Blowfish */ void blowfish_setkey(CipherContext *cc, const u_char *key, u_int keylen) { BF_set_key(&cc->u.bf.key, keylen, (u_char *)key); } void blowfish_setiv(CipherContext *cc, const u_char *iv, u_int ivlen) { if (iv == NULL) memset(cc->u.bf.iv, 0, 8); else memcpy(cc->u.bf.iv, (char *)iv, 8); } void blowfish_cbc_encrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { BF_cbc_encrypt((void *)src, dest, len, &cc->u.bf.key, cc->u.bf.iv, BF_ENCRYPT); } void blowfish_cbc_decrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { BF_cbc_encrypt((void *)src, dest, len, &cc->u.bf.key, cc->u.bf.iv, BF_DECRYPT); } /* * SSH1 uses a variation on Blowfish, all bytes must be swapped before * and after encryption/decryption. Thus the swap_bytes stuff (yuk). */ static void swap_bytes(const u_char *src, u_char *dst, int n) { char c[4]; /* Process 4 bytes every lap. */ for (n = n / 4; n > 0; n--) { c[3] = *src++; c[2] = *src++; c[1] = *src++; c[0] = *src++; *dst++ = c[0]; *dst++ = c[1]; *dst++ = c[2]; *dst++ = c[3]; } } void blowfish_ssh1_encrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { swap_bytes(src, dest, len); BF_cbc_encrypt((void *)dest, dest, len, &cc->u.bf.key, cc->u.bf.iv, BF_ENCRYPT); swap_bytes(dest, dest, len); } void blowfish_ssh1_decrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { swap_bytes(src, dest, len); BF_cbc_encrypt((void *)dest, dest, len, &cc->u.bf.key, cc->u.bf.iv, BF_DECRYPT); swap_bytes(dest, dest, len); } /* alleged rc4 */ void arcfour_setkey(CipherContext *cc, const u_char *key, u_int keylen) { RC4_set_key(&cc->u.rc4, keylen, (u_char *)key); } void arcfour_crypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { RC4(&cc->u.rc4, len, (u_char *)src, dest); } /* CAST */ void cast_setkey(CipherContext *cc, const u_char *key, u_int keylen) { CAST_set_key(&cc->u.cast.key, keylen, (u_char *) key); } void cast_setiv(CipherContext *cc, const u_char *iv, u_int ivlen) { if (iv == NULL) fatal("no IV for %s.", cc->cipher->name); memcpy(cc->u.cast.iv, (char *)iv, 8); } void cast_cbc_encrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { CAST_cbc_encrypt(src, dest, len, &cc->u.cast.key, cc->u.cast.iv, CAST_ENCRYPT); } void cast_cbc_decrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { CAST_cbc_encrypt(src, dest, len, &cc->u.cast.key, cc->u.cast.iv, CAST_DECRYPT); } /* RIJNDAEL */ #define RIJNDAEL_BLOCKSIZE 16 void rijndael_setkey(CipherContext *cc, const u_char *key, u_int keylen) { rijndael_set_key(&cc->u.rijndael.enc, (u4byte *)key, 8*keylen, 1); rijndael_set_key(&cc->u.rijndael.dec, (u4byte *)key, 8*keylen, 0); } void rijndael_setiv(CipherContext *cc, const u_char *iv, u_int ivlen) { if (iv == NULL) fatal("no IV for %s.", cc->cipher->name); memcpy((u_char *)cc->u.rijndael.iv, iv, RIJNDAEL_BLOCKSIZE); } void rijndael_cbc_encrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { rijndael_ctx *ctx = &cc->u.rijndael.enc; u4byte *iv = cc->u.rijndael.iv; u4byte in[4]; u4byte *cprev, *cnow, *plain; int i, blocks = len / RIJNDAEL_BLOCKSIZE; if (len == 0) return; if (len % RIJNDAEL_BLOCKSIZE) fatal("rijndael_cbc_encrypt: bad len %d", len); cnow = (u4byte*) dest; plain = (u4byte*) src; cprev = iv; for(i = 0; i < blocks; i++, plain+=4, cnow+=4) { in[0] = plain[0] ^ cprev[0]; in[1] = plain[1] ^ cprev[1]; in[2] = plain[2] ^ cprev[2]; in[3] = plain[3] ^ cprev[3]; rijndael_encrypt(ctx, in, cnow); cprev = cnow; } memcpy(iv, cprev, RIJNDAEL_BLOCKSIZE); } void rijndael_cbc_decrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { rijndael_ctx *ctx = &cc->u.rijndael.dec; u4byte *iv = cc->u.rijndael.iv; u4byte ivsaved[4]; u4byte *cnow = (u4byte*) (src+len-RIJNDAEL_BLOCKSIZE); u4byte *plain = (u4byte*) (dest+len-RIJNDAEL_BLOCKSIZE); u4byte *ivp; int i, blocks = len / RIJNDAEL_BLOCKSIZE; if (len == 0) return; if (len % RIJNDAEL_BLOCKSIZE) fatal("rijndael_cbc_decrypt: bad len %d", len); memcpy(ivsaved, cnow, RIJNDAEL_BLOCKSIZE); for(i = blocks; i > 0; i--, cnow-=4, plain-=4) { rijndael_decrypt(ctx, cnow, plain); ivp = (i == 1) ? iv : cnow-4; plain[0] ^= ivp[0]; plain[1] ^= ivp[1]; plain[2] ^= ivp[2]; plain[3] ^= ivp[3]; } memcpy(iv, ivsaved, RIJNDAEL_BLOCKSIZE); } Cipher ciphers[] = { { "none", SSH_CIPHER_NONE, 8, 0, none_setkey, none_setiv, none_crypt, none_crypt }, { "des", SSH_CIPHER_DES, 8, 8, des_ssh1_setkey, des_ssh1_setiv, des_ssh1_encrypt, des_ssh1_decrypt }, { "3des", SSH_CIPHER_3DES, 8, 16, des3_ssh1_setkey, des3_setiv, des3_ssh1_encrypt, des3_ssh1_decrypt }, { "blowfish", SSH_CIPHER_BLOWFISH, 8, 16, blowfish_setkey, blowfish_setiv, blowfish_ssh1_encrypt, blowfish_ssh1_decrypt }, { "3des-cbc", SSH_CIPHER_SSH2, 8, 24, des3_setkey, des3_setiv, des3_cbc_encrypt, des3_cbc_decrypt }, { "blowfish-cbc", SSH_CIPHER_SSH2, 8, 16, blowfish_setkey, blowfish_setiv, blowfish_cbc_encrypt, blowfish_cbc_decrypt }, { "cast128-cbc", SSH_CIPHER_SSH2, 8, 16, cast_setkey, cast_setiv, cast_cbc_encrypt, cast_cbc_decrypt }, { "arcfour", SSH_CIPHER_SSH2, 8, 16, arcfour_setkey, none_setiv, arcfour_crypt, arcfour_crypt }, { "aes128-cbc", SSH_CIPHER_SSH2, 16, 16, rijndael_setkey, rijndael_setiv, rijndael_cbc_encrypt, rijndael_cbc_decrypt }, { "aes192-cbc", SSH_CIPHER_SSH2, 16, 24, rijndael_setkey, rijndael_setiv, rijndael_cbc_encrypt, rijndael_cbc_decrypt }, { "aes256-cbc", SSH_CIPHER_SSH2, 16, 32, rijndael_setkey, rijndael_setiv, rijndael_cbc_encrypt, rijndael_cbc_decrypt }, { "rijndael128-cbc", SSH_CIPHER_SSH2, 16, 16, rijndael_setkey, rijndael_setiv, rijndael_cbc_encrypt, rijndael_cbc_decrypt }, { "rijndael192-cbc", SSH_CIPHER_SSH2, 16, 24, rijndael_setkey, rijndael_setiv, rijndael_cbc_encrypt, rijndael_cbc_decrypt }, { "rijndael256-cbc", SSH_CIPHER_SSH2, 16, 32, rijndael_setkey, rijndael_setiv, rijndael_cbc_encrypt, rijndael_cbc_decrypt }, { "rijndael-cbc@lysator.liu.se", SSH_CIPHER_SSH2, 16, 32, rijndael_setkey, rijndael_setiv, rijndael_cbc_encrypt, rijndael_cbc_decrypt }, { NULL, SSH_CIPHER_ILLEGAL, 0, 0, NULL, NULL, NULL, NULL } }; /*--*/ u_int cipher_mask_ssh1(int client) { u_int mask = 0; mask |= 1 << SSH_CIPHER_3DES; /* Mandatory */ mask |= 1 << SSH_CIPHER_BLOWFISH; if (client) { mask |= 1 << SSH_CIPHER_DES; } return mask; } Cipher * cipher_by_name(const char *name) { Cipher *c; for (c = ciphers; c->name != NULL; c++) if (strcasecmp(c->name, name) == 0) return c; return NULL; } Cipher * cipher_by_number(int id) { Cipher *c; for (c = ciphers; c->name != NULL; c++) if (c->number == id) return c; return NULL; } #define CIPHER_SEP "," int ciphers_valid(const char *names) { Cipher *c; char *ciphers, *cp; char *p; if (names == NULL || strcmp(names, "") == 0) return 0; ciphers = cp = xstrdup(names); for ((p = strsep(&cp, CIPHER_SEP)); p && *p != '\0'; (p = strsep(&cp, CIPHER_SEP))) { c = cipher_by_name(p); if (c == NULL || c->number != SSH_CIPHER_SSH2) { debug("bad cipher %s [%s]", p, names); xfree(ciphers); return 0; } else { debug3("cipher ok: %s [%s]", p, names); } } debug3("ciphers ok: [%s]", names); xfree(ciphers); return 1; } /* * Parses the name of the cipher. Returns the number of the corresponding * cipher, or -1 on error. */ int cipher_number(const char *name) { Cipher *c; if (name == NULL) return -1; c = cipher_by_name(name); return (c==NULL) ? -1 : c->number; } char * cipher_name(int id) { Cipher *c = cipher_by_number(id); return (c==NULL) ? "" : c->name; } void cipher_init(CipherContext *cc, Cipher *cipher, const u_char *key, u_int keylen, const u_char *iv, u_int ivlen) { if (keylen < cipher->key_len) fatal("cipher_init: key length %d is insufficient for %s.", keylen, cipher->name); if (iv != NULL && ivlen < cipher->block_size) fatal("cipher_init: iv length %d is insufficient for %s.", ivlen, cipher->name); cc->cipher = cipher; cipher->setkey(cc, key, keylen); cipher->setiv(cc, iv, ivlen); } void cipher_encrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { if (len % cc->cipher->block_size) fatal("cipher_encrypt: bad plaintext length %d", len); cc->cipher->encrypt(cc, dest, src, len); } void cipher_decrypt(CipherContext *cc, u_char *dest, const u_char *src, u_int len) { if (len % cc->cipher->block_size) fatal("cipher_decrypt: bad ciphertext length %d", len); cc->cipher->decrypt(cc, dest, src, len); } /* * Selects the cipher, and keys if by computing the MD5 checksum of the * passphrase and using the resulting 16 bytes as the key. */ void cipher_set_key_string(CipherContext *cc, Cipher *cipher, const char *passphrase) { MD5_CTX md; u_char digest[16]; MD5_Init(&md); MD5_Update(&md, (const u_char *)passphrase, strlen(passphrase)); MD5_Final(digest, &md); cipher_init(cc, cipher, digest, 16, NULL, 0); memset(digest, 0, sizeof(digest)); memset(&md, 0, sizeof(md)); }