示例#1
0
/*
 * Perform the MPPE rekey algorithm, from RFC 3078, sec. 7.3.
 * Well, not what's written there, but rather what they meant.
 */
static void mppe_rekey(struct ppp_mppe_state * state, int initial_key)
{
	struct scatterlist sg_in[1], sg_out[1];

	get_new_key_from_sha(state);
	if (!initial_key) {
		crypto_cipher_setkey(state->arc4, state->sha1_digest,
				     state->keylen);
		setup_sg(sg_in, state->sha1_digest, state->keylen);
		setup_sg(sg_out, state->session_key, state->keylen);
		if (crypto_cipher_encrypt(state->arc4, sg_out, sg_in,
				      state->keylen) != 0) {
    		    printk(KERN_WARNING "mppe_rekey: cipher_encrypt failed\n");
		}
	} else {
		memcpy(state->session_key, state->sha1_digest, state->keylen);
	}
	if (state->keylen == 8) {
		/* See RFC 3078 */
		state->session_key[0] = 0xd1;
		state->session_key[1] = 0x26;
		state->session_key[2] = 0x9e;
	}
	crypto_cipher_setkey(state->arc4, state->session_key, state->keylen);
}
示例#2
0
/*
 * Key Derivation, from RFC 3078, RFC 3079.
 * Equivalent to Get_Key() for MS-CHAP as described in RFC 3079.
 */
static void get_new_key_from_sha(struct ppp_mppe_state * state)
{
	struct scatterlist sg[4];

	setup_sg(&sg[0], state->master_key, state->keylen);
	setup_sg(&sg[1], sha_pad->sha_pad1, sizeof(sha_pad->sha_pad1));
	setup_sg(&sg[2], state->session_key, state->keylen);
	setup_sg(&sg[3], sha_pad->sha_pad2, sizeof(sha_pad->sha_pad2));

	crypto_digest_digest (state->sha1, sg, 4, state->sha1_digest);
}
示例#3
0
/*
 * Key Derivation, from RFC 3078, RFC 3079.
 * Equivalent to Get_Key() for MS-CHAP as described in RFC 3079.
 */
static void get_new_key_from_sha(struct ppp_mppe_state * state)
{
	struct hash_desc desc;
	struct scatterlist sg[4];
	unsigned int nbytes;

	sg_init_table(sg, 4);

	nbytes = setup_sg(&sg[0], state->master_key, state->keylen);
	nbytes += setup_sg(&sg[1], sha_pad->sha_pad1,
			   sizeof(sha_pad->sha_pad1));
	nbytes += setup_sg(&sg[2], state->session_key, state->keylen);
	nbytes += setup_sg(&sg[3], sha_pad->sha_pad2,
			   sizeof(sha_pad->sha_pad2));

	desc.tfm = state->sha1;
	desc.flags = 0;

	crypto_hash_digest(&desc, sg, nbytes, state->sha1_digest);
}
示例#4
0
/*
 * Perform the MPPE rekey algorithm, from RFC 3078, sec. 7.3.
 * Well, not what's written there, but rather what they meant.
 */
static void mppe_rekey(struct ppp_mppe_state * state, int initial_key)
{
	struct scatterlist sg_in[1], sg_out[1];
	struct blkcipher_desc desc = { .tfm = state->arc4 };

	get_new_key_from_sha(state);
	if (!initial_key) {
		crypto_blkcipher_setkey(state->arc4, state->sha1_digest,
					state->keylen);
		sg_init_table(sg_in, 1);
		sg_init_table(sg_out, 1);
		setup_sg(sg_in, state->sha1_digest, state->keylen);
		setup_sg(sg_out, state->session_key, state->keylen);
		if (crypto_blkcipher_encrypt(&desc, sg_out, sg_in,
					     state->keylen) != 0) {
    		    printk(KERN_WARNING "mppe_rekey: cipher_encrypt failed\n");
		}
	} else {
		memcpy(state->session_key, state->sha1_digest, state->keylen);
	}
	if (state->keylen == 8) {
		/* See RFC 3078 */
		state->session_key[0] = 0xd1;
		state->session_key[1] = 0x26;
		state->session_key[2] = 0x9e;
	}
	crypto_blkcipher_setkey(state->arc4, state->session_key, state->keylen);
}

/*
 * Allocate space for a (de)compressor.
 */
static void *mppe_alloc(unsigned char *options, int optlen)
{
	struct ppp_mppe_state *state;
	unsigned int digestsize;

	if (optlen != CILEN_MPPE + sizeof(state->master_key)
	    || options[0] != CI_MPPE || options[1] != CILEN_MPPE)
		goto out;

	state = kzalloc(sizeof(*state), GFP_KERNEL);
	if (state == NULL)
		goto out;


	state->arc4 = crypto_alloc_blkcipher("ecb(arc4)", 0, CRYPTO_ALG_ASYNC);
	if (IS_ERR(state->arc4)) {
		state->arc4 = NULL;
		goto out_free;
	}

	state->sha1 = crypto_alloc_hash("sha1", 0, CRYPTO_ALG_ASYNC);
	if (IS_ERR(state->sha1)) {
		state->sha1 = NULL;
		goto out_free;
	}

	digestsize = crypto_hash_digestsize(state->sha1);
	if (digestsize < MPPE_MAX_KEY_LEN)
		goto out_free;

	state->sha1_digest = kmalloc(digestsize, GFP_KERNEL);
	if (!state->sha1_digest)
		goto out_free;

	/* Save keys. */
	memcpy(state->master_key, &options[CILEN_MPPE],
	       sizeof(state->master_key));
	memcpy(state->session_key, state->master_key,
	       sizeof(state->master_key));

	/*
	 * We defer initial key generation until mppe_init(), as mppe_alloc()
	 * is called frequently during negotiation.
	 */

	return (void *)state;

	out_free:
	    if (state->sha1_digest)
		kfree(state->sha1_digest);
	    if (state->sha1)
		crypto_free_hash(state->sha1);
	    if (state->arc4)
		crypto_free_blkcipher(state->arc4);
	    kfree(state);
	out:
	return NULL;
}

/*
 * Deallocate space for a (de)compressor.
 */
static void mppe_free(void *arg)
{
	struct ppp_mppe_state *state = (struct ppp_mppe_state *) arg;
	if (state) {
	    if (state->sha1_digest)
		kfree(state->sha1_digest);
	    if (state->sha1)
		crypto_free_hash(state->sha1);
	    if (state->arc4)
		crypto_free_blkcipher(state->arc4);
	    kfree(state);
	}
}

/*
 * Initialize (de)compressor state.
 */
static int
mppe_init(void *arg, unsigned char *options, int optlen, int unit, int debug,
	  const char *debugstr)
{
	struct ppp_mppe_state *state = (struct ppp_mppe_state *) arg;
	unsigned char mppe_opts;

	if (optlen != CILEN_MPPE
	    || options[0] != CI_MPPE || options[1] != CILEN_MPPE)
		return 0;

	MPPE_CI_TO_OPTS(&options[2], mppe_opts);
	if (mppe_opts & MPPE_OPT_128)
		state->keylen = 16;
	else if (mppe_opts & MPPE_OPT_40)
		state->keylen = 8;
	else {
		printk(KERN_WARNING "%s[%d]: unknown key length\n", debugstr,
		       unit);
		return 0;
	}
	if (mppe_opts & MPPE_OPT_STATEFUL)
		state->stateful = 1;

	/* Generate the initial session key. */
	mppe_rekey(state, 1);

	if (debug) {
		int i;
		char mkey[sizeof(state->master_key) * 2 + 1];
		char skey[sizeof(state->session_key) * 2 + 1];

		printk(KERN_DEBUG "%s[%d]: initialized with %d-bit %s mode\n",
		       debugstr, unit, (state->keylen == 16) ? 128 : 40,
		       (state->stateful) ? "stateful" : "stateless");

		for (i = 0; i < sizeof(state->master_key); i++)
			sprintf(mkey + i * 2, "%02x", state->master_key[i]);
		for (i = 0; i < sizeof(state->session_key); i++)
			sprintf(skey + i * 2, "%02x", state->session_key[i]);
		printk(KERN_DEBUG
		       "%s[%d]: keys: master: %s initial session: %s\n",
		       debugstr, unit, mkey, skey);
	}

	/*
	 * Initialize the coherency count.  The initial value is not specified
	 * in RFC 3078, but we can make a reasonable assumption that it will
	 * start at 0.  Setting it to the max here makes the comp/decomp code
	 * do the right thing (determined through experiment).
	 */
	state->ccount = MPPE_CCOUNT_SPACE - 1;

	/*
	 * Note that even though we have initialized the key table, we don't
	 * set the FLUSHED bit.  This is contrary to RFC 3078, sec. 3.1.
	 */
	state->bits = MPPE_BIT_ENCRYPTED;

	state->unit = unit;
	state->debug = debug;

	return 1;
}

static int
mppe_comp_init(void *arg, unsigned char *options, int optlen, int unit,
	       int hdrlen, int debug)
{
	/* ARGSUSED */
	return mppe_init(arg, options, optlen, unit, debug, "mppe_comp_init");
}

/*
 * We received a CCP Reset-Request (actually, we are sending a Reset-Ack),
 * tell the compressor to rekey.  Note that we MUST NOT rekey for
 * every CCP Reset-Request; we only rekey on the next xmit packet.
 * We might get multiple CCP Reset-Requests if our CCP Reset-Ack is lost.
 * So, rekeying for every CCP Reset-Request is broken as the peer will not
 * know how many times we've rekeyed.  (If we rekey and THEN get another
 * CCP Reset-Request, we must rekey again.)
 */
static void mppe_comp_reset(void *arg)
{
	struct ppp_mppe_state *state = (struct ppp_mppe_state *) arg;

	state->bits |= MPPE_BIT_FLUSHED;
}

/*
 * Compress (encrypt) a packet.
 * It's strange to call this a compressor, since the output is always
 * MPPE_OVHD + 2 bytes larger than the input.
 */
static int
mppe_compress(void *arg, unsigned char *ibuf, unsigned char *obuf,
	      int isize, int osize)
{
	struct ppp_mppe_state *state = (struct ppp_mppe_state *) arg;
	struct blkcipher_desc desc = { .tfm = state->arc4 };
	int proto;
	struct scatterlist sg_in[1], sg_out[1];

	/*
	 * Check that the protocol is in the range we handle.
	 */
	proto = PPP_PROTOCOL(ibuf);
	if (proto < 0x0021 || proto > 0x00fa)
		return 0;

	/* Make sure we have enough room to generate an encrypted packet. */
	if (osize < isize + MPPE_OVHD + 2) {
		/* Drop the packet if we should encrypt it, but can't. */
		printk(KERN_DEBUG "mppe_compress[%d]: osize too small! "
		       "(have: %d need: %d)\n", state->unit,
		       osize, osize + MPPE_OVHD + 2);
		return -1;
	}

	osize = isize + MPPE_OVHD + 2;

	/*
	 * Copy over the PPP header and set control bits.
	 */
	obuf[0] = PPP_ADDRESS(ibuf);
	obuf[1] = PPP_CONTROL(ibuf);
	obuf[2] = PPP_COMP >> 8;	/* isize + MPPE_OVHD + 1 */
	obuf[3] = PPP_COMP;	/* isize + MPPE_OVHD + 2 */
	obuf += PPP_HDRLEN;

	state->ccount = (state->ccount + 1) % MPPE_CCOUNT_SPACE;
	if (state->debug >= 7)
		printk(KERN_DEBUG "mppe_compress[%d]: ccount %d\n", state->unit,
		       state->ccount);
	obuf[0] = state->ccount >> 8;
	obuf[1] = state->ccount & 0xff;

	if (!state->stateful ||	/* stateless mode     */
	    ((state->ccount & 0xff) == 0xff) ||	/* "flag" packet      */
	    (state->bits & MPPE_BIT_FLUSHED)) {	/* CCP Reset-Request  */
		/* We must rekey */
		if (state->debug && state->stateful)
			printk(KERN_DEBUG "mppe_compress[%d]: rekeying\n",
			       state->unit);
		mppe_rekey(state, 0);
		state->bits |= MPPE_BIT_FLUSHED;
	}
	obuf[0] |= state->bits;
	state->bits &= ~MPPE_BIT_FLUSHED;	/* reset for next xmit */

	obuf += MPPE_OVHD;
	ibuf += 2;		/* skip to proto field */
	isize -= 2;

	/* Encrypt packet */
	sg_init_table(sg_in, 1);
	sg_init_table(sg_out, 1);
	setup_sg(sg_in, ibuf, isize);
	setup_sg(sg_out, obuf, osize);
	if (crypto_blkcipher_encrypt(&desc, sg_out, sg_in, isize) != 0) {
		printk(KERN_DEBUG "crypto_cypher_encrypt failed\n");
		return -1;
	}

	state->stats.unc_bytes += isize;
	state->stats.unc_packets++;
	state->stats.comp_bytes += osize;
	state->stats.comp_packets++;

	return osize;
}

/*
 * Since every frame grows by MPPE_OVHD + 2 bytes, this is always going
 * to look bad ... and the longer the link is up the worse it will get.
 */
static void mppe_comp_stats(void *arg, struct compstat *stats)
{
	struct ppp_mppe_state *state = (struct ppp_mppe_state *) arg;

	*stats = state->stats;
}

static int
mppe_decomp_init(void *arg, unsigned char *options, int optlen, int unit,
		 int hdrlen, int mru, int debug)
{
	/* ARGSUSED */
	return mppe_init(arg, options, optlen, unit, debug, "mppe_decomp_init");
}

/*
 * We received a CCP Reset-Ack.  Just ignore it.
 */
static void mppe_decomp_reset(void *arg)
{
	/* ARGSUSED */
	return;
}

/*
 * Decompress (decrypt) an MPPE packet.
 */
static int
mppe_decompress(void *arg, unsigned char *ibuf, int isize, unsigned char *obuf,
		int osize)
{
	struct ppp_mppe_state *state = (struct ppp_mppe_state *) arg;
	struct blkcipher_desc desc = { .tfm = state->arc4 };
	unsigned ccount;
	int flushed = MPPE_BITS(ibuf) & MPPE_BIT_FLUSHED;
	int sanity = 0;
	struct scatterlist sg_in[1], sg_out[1];

	if (isize <= PPP_HDRLEN + MPPE_OVHD) {
		if (state->debug)
			printk(KERN_DEBUG
			       "mppe_decompress[%d]: short pkt (%d)\n",
			       state->unit, isize);
		return DECOMP_ERROR;
	}

	/*
	 * Make sure we have enough room to decrypt the packet.
	 * Note that for our test we only subtract 1 byte whereas in
	 * mppe_compress() we added 2 bytes (+MPPE_OVHD);
	 * this is to account for possible PFC.
	 */
	if (osize < isize - MPPE_OVHD - 1) {
		printk(KERN_DEBUG "mppe_decompress[%d]: osize too small! "
		       "(have: %d need: %d)\n", state->unit,
		       osize, isize - MPPE_OVHD - 1);
		return DECOMP_ERROR;
	}
	osize = isize - MPPE_OVHD - 2;	/* assume no PFC */

	ccount = MPPE_CCOUNT(ibuf);
	if (state->debug >= 7)
		printk(KERN_DEBUG "mppe_decompress[%d]: ccount %d\n",
		       state->unit, ccount);

	/* sanity checks -- terminate with extreme prejudice */
	if (!(MPPE_BITS(ibuf) & MPPE_BIT_ENCRYPTED)) {
		printk(KERN_DEBUG
		       "mppe_decompress[%d]: ENCRYPTED bit not set!\n",
		       state->unit);
		state->sanity_errors += 100;
		sanity = 1;
	}
	if (!state->stateful && !flushed) {
		printk(KERN_DEBUG "mppe_decompress[%d]: FLUSHED bit not set in "
		       "stateless mode!\n", state->unit);
		state->sanity_errors += 100;
		sanity = 1;
	}
	if (state->stateful && ((ccount & 0xff) == 0xff) && !flushed) {
		printk(KERN_DEBUG "mppe_decompress[%d]: FLUSHED bit not set on "
		       "flag packet!\n", state->unit);
		state->sanity_errors += 100;
		sanity = 1;
	}

	if (sanity) {
		if (state->sanity_errors < SANITY_MAX)
			return DECOMP_ERROR;
		else
			/*
			 * Take LCP down if the peer is sending too many bogons.
			 * We don't want to do this for a single or just a few
			 * instances since it could just be due to packet corruption.
			 */
			return DECOMP_FATALERROR;
	}

	/*
	 * Check the coherency count.
	 */

	if (!state->stateful) {
		/* RFC 3078, sec 8.1.  Rekey for every packet. */
		while (state->ccount != ccount) {
			mppe_rekey(state, 0);
			state->ccount = (state->ccount + 1) % MPPE_CCOUNT_SPACE;
		}
	} else {
		/* RFC 3078, sec 8.2. */
		if (!state->discard) {
			/* normal state */
			state->ccount = (state->ccount + 1) % MPPE_CCOUNT_SPACE;
			if (ccount != state->ccount) {
				/*
				 * (ccount > state->ccount)
				 * Packet loss detected, enter the discard state.
				 * Signal the peer to rekey (by sending a CCP Reset-Request).
				 */
				state->discard = 1;
				return DECOMP_ERROR;
			}
		} else {
			/* discard state */
			if (!flushed) {
				/* ccp.c will be silent (no additional CCP Reset-Requests). */
				return DECOMP_ERROR;
			} else {
				/* Rekey for every missed "flag" packet. */
				while ((ccount & ~0xff) !=
				       (state->ccount & ~0xff)) {
					mppe_rekey(state, 0);
					state->ccount =
					    (state->ccount +
					     256) % MPPE_CCOUNT_SPACE;
				}

				/* reset */
				state->discard = 0;
				state->ccount = ccount;
				/*
				 * Another problem with RFC 3078 here.  It implies that the
				 * peer need not send a Reset-Ack packet.  But RFC 1962
				 * requires it.  Hopefully, M$ does send a Reset-Ack; even
				 * though it isn't required for MPPE synchronization, it is
				 * required to reset CCP state.
				 */
			}
		}
		if (flushed)
			mppe_rekey(state, 0);
	}

	/*
	 * Fill in the first part of the PPP header.  The protocol field
	 * comes from the decrypted data.
	 */
	obuf[0] = PPP_ADDRESS(ibuf);	/* +1 */
	obuf[1] = PPP_CONTROL(ibuf);	/* +1 */
	obuf += 2;
	ibuf += PPP_HDRLEN + MPPE_OVHD;
	isize -= PPP_HDRLEN + MPPE_OVHD;	/* -6 */
	/* net osize: isize-4 */

	/*
	 * Decrypt the first byte in order to check if it is
	 * a compressed or uncompressed protocol field.
	 */
	sg_init_table(sg_in, 1);
	sg_init_table(sg_out, 1);
	setup_sg(sg_in, ibuf, 1);
	setup_sg(sg_out, obuf, 1);
	if (crypto_blkcipher_decrypt(&desc, sg_out, sg_in, 1) != 0) {
		printk(KERN_DEBUG "crypto_cypher_decrypt failed\n");
		return DECOMP_ERROR;
	}

	/*
	 * Do PFC decompression.
	 * This would be nicer if we were given the actual sk_buff
	 * instead of a char *.
	 */
	if ((obuf[0] & 0x01) != 0) {
		obuf[1] = obuf[0];
		obuf[0] = 0;
		obuf++;
		osize++;
	}

	/* And finally, decrypt the rest of the packet. */
	setup_sg(sg_in, ibuf + 1, isize - 1);
	setup_sg(sg_out, obuf + 1, osize - 1);
	if (crypto_blkcipher_decrypt(&desc, sg_out, sg_in, isize - 1)) {
		printk(KERN_DEBUG "crypto_cypher_decrypt failed\n");
		return DECOMP_ERROR;
	}

	state->stats.unc_bytes += osize;
	state->stats.unc_packets++;
	state->stats.comp_bytes += isize;
	state->stats.comp_packets++;

	/* good packet credit */
	state->sanity_errors >>= 1;

	return osize;
}

/*
 * Incompressible data has arrived (this should never happen!).
 * We should probably drop the link if the protocol is in the range
 * of what should be encrypted.  At the least, we should drop this
 * packet.  (How to do this?)
 */
static void mppe_incomp(void *arg, unsigned char *ibuf, int icnt)
{
	struct ppp_mppe_state *state = (struct ppp_mppe_state *) arg;

	if (state->debug &&
	    (PPP_PROTOCOL(ibuf) >= 0x0021 && PPP_PROTOCOL(ibuf) <= 0x00fa))
		printk(KERN_DEBUG
		       "mppe_incomp[%d]: incompressible (unencrypted) data! "
		       "(proto %04x)\n", state->unit, PPP_PROTOCOL(ibuf));

	state->stats.inc_bytes += icnt;
	state->stats.inc_packets++;
	state->stats.unc_bytes += icnt;
	state->stats.unc_packets++;
}

/*************************************************************
 * Module interface table
 *************************************************************/

/*
 * Procedures exported to if_ppp.c.
 */
static struct compressor ppp_mppe = {
	.compress_proto = CI_MPPE,
	.comp_alloc     = mppe_alloc,
	.comp_free      = mppe_free,
	.comp_init      = mppe_comp_init,
	.comp_reset     = mppe_comp_reset,
	.compress       = mppe_compress,
	.comp_stat      = mppe_comp_stats,
	.decomp_alloc   = mppe_alloc,
	.decomp_free    = mppe_free,
	.decomp_init    = mppe_decomp_init,
	.decomp_reset   = mppe_decomp_reset,
	.decompress     = mppe_decompress,
	.incomp         = mppe_incomp,
	.decomp_stat    = mppe_comp_stats,
	.owner          = THIS_MODULE,
	.comp_extra     = MPPE_PAD,
};

/*
 * ppp_mppe_init()
 *
 * Prior to allowing load, try to load the arc4 and sha1 crypto
 * libraries.  The actual use will be allocated later, but
 * this way the module will fail to insmod if they aren't available.
 */

static int __init ppp_mppe_init(void)
{
	int answer;
	if (!(crypto_has_blkcipher("ecb(arc4)", 0, CRYPTO_ALG_ASYNC) &&
	      crypto_has_hash("sha1", 0, CRYPTO_ALG_ASYNC)))
		return -ENODEV;

	sha_pad = kmalloc(sizeof(struct sha_pad), GFP_KERNEL);
	if (!sha_pad)
		return -ENOMEM;
	sha_pad_init(sha_pad);

	answer = ppp_register_compressor(&ppp_mppe);

	if (answer == 0)
		printk(KERN_INFO "PPP MPPE Compression module registered\n");
	else
		kfree(sha_pad);

	return answer;
}

static void __exit ppp_mppe_cleanup(void)
{
	ppp_unregister_compressor(&ppp_mppe);
	kfree(sha_pad);
}

module_init(ppp_mppe_init);
module_exit(ppp_mppe_cleanup);
示例#5
0
/*
 * Decompress (decrypt) an MPPE packet.
 */
static int
mppe_decompress(void *arg, unsigned char *ibuf, int isize, unsigned char *obuf,
		int osize)
{
	struct ppp_mppe_state *state = (struct ppp_mppe_state *) arg;
	unsigned ccount;
	int flushed = MPPE_BITS(ibuf) & MPPE_BIT_FLUSHED;
	int sanity = 0;
	struct scatterlist sg_in[1], sg_out[1];

	if (isize <= PPP_HDRLEN + MPPE_OVHD) {
		if (state->debug)
			printk(KERN_DEBUG
			       "mppe_decompress[%d]: short pkt (%d)\n",
			       state->unit, isize);
		return DECOMP_ERROR;
	}

	/*
	 * Make sure we have enough room to decrypt the packet.
	 * Note that for our test we only subtract 1 byte whereas in
	 * mppe_compress() we added 2 bytes (+MPPE_OVHD);
	 * this is to account for possible PFC.
	 */
	if (osize < isize - MPPE_OVHD - 1) {
		printk(KERN_DEBUG "mppe_decompress[%d]: osize too small! "
		       "(have: %d need: %d)\n", state->unit,
		       osize, isize - MPPE_OVHD - 1);
		return DECOMP_ERROR;
	}
	osize = isize - MPPE_OVHD - 2;	/* assume no PFC */

	ccount = MPPE_CCOUNT(ibuf);
	if (state->debug >= 7)
		printk(KERN_DEBUG "mppe_decompress[%d]: ccount %d\n",
		       state->unit, ccount);

	/* sanity checks -- terminate with extreme prejudice */
	if (!(MPPE_BITS(ibuf) & MPPE_BIT_ENCRYPTED)) {
		printk(KERN_DEBUG
		       "mppe_decompress[%d]: ENCRYPTED bit not set!\n",
		       state->unit);
		state->sanity_errors += 100;
		sanity = 1;
	}
	if (!state->stateful && !flushed) {
		printk(KERN_DEBUG "mppe_decompress[%d]: FLUSHED bit not set in "
		       "stateless mode!\n", state->unit);
		state->sanity_errors += 100;
		sanity = 1;
	}
	if (state->stateful && ((ccount & 0xff) == 0xff) && !flushed) {
		printk(KERN_DEBUG "mppe_decompress[%d]: FLUSHED bit not set on "
		       "flag packet!\n", state->unit);
		state->sanity_errors += 100;
		sanity = 1;
	}

	if (sanity) {
		if (state->sanity_errors < SANITY_MAX)
			return DECOMP_ERROR;
		else
			/*
			 * Take LCP down if the peer is sending too many bogons.
			 * We don't want to do this for a single or just a few
			 * instances since it could just be due to packet corruption.
			 */
			return DECOMP_FATALERROR;
	}

	/*
	 * Check the coherency count.
	 */

	if (!state->stateful) {
		/* RFC 3078, sec 8.1.  Rekey for every packet. */
		while (state->ccount != ccount) {
			mppe_rekey(state, 0);
			state->ccount = (state->ccount + 1) % MPPE_CCOUNT_SPACE;
		}
	} else {
		/* RFC 3078, sec 8.2. */
		if (!state->discard) {
			/* normal state */
			state->ccount = (state->ccount + 1) % MPPE_CCOUNT_SPACE;
			if (ccount != state->ccount) {
				/*
				 * (ccount > state->ccount)
				 * Packet loss detected, enter the discard state.
				 * Signal the peer to rekey (by sending a CCP Reset-Request).
				 */
				state->discard = 1;
				return DECOMP_ERROR;
			}
		} else {
			/* discard state */
			if (!flushed) {
				/* ccp.c will be silent (no additional CCP Reset-Requests). */
				return DECOMP_ERROR;
			} else {
				/* Rekey for every missed "flag" packet. */
				while ((ccount & ~0xff) !=
				       (state->ccount & ~0xff)) {
					mppe_rekey(state, 0);
					state->ccount =
					    (state->ccount +
					     256) % MPPE_CCOUNT_SPACE;
				}

				/* reset */
				state->discard = 0;
				state->ccount = ccount;
				/*
				 * Another problem with RFC 3078 here.  It implies that the
				 * peer need not send a Reset-Ack packet.  But RFC 1962
				 * requires it.  Hopefully, M$ does send a Reset-Ack; even
				 * though it isn't required for MPPE synchronization, it is
				 * required to reset CCP state.
				 */
			}
		}
		if (flushed)
			mppe_rekey(state, 0);
	}

	/*
	 * Fill in the first part of the PPP header.  The protocol field
	 * comes from the decrypted data.
	 */
	obuf[0] = PPP_ADDRESS(ibuf);	/* +1 */
	obuf[1] = PPP_CONTROL(ibuf);	/* +1 */
	obuf += 2;
	ibuf += PPP_HDRLEN + MPPE_OVHD;
	isize -= PPP_HDRLEN + MPPE_OVHD;	/* -6 */
	/* net osize: isize-4 */

	/*
	 * Decrypt the first byte in order to check if it is
	 * a compressed or uncompressed protocol field.
	 */
	setup_sg(sg_in, ibuf, 1);
	setup_sg(sg_out, obuf, 1);
	if (crypto_cipher_decrypt(state->arc4, sg_out, sg_in, 1) != 0) {
		printk(KERN_DEBUG "crypto_cypher_decrypt failed\n");
		return DECOMP_ERROR;
	}

	/*
	 * Do PFC decompression.
	 * This would be nicer if we were given the actual sk_buff
	 * instead of a char *.
	 */
	if ((obuf[0] & 0x01) != 0) {
		obuf[1] = obuf[0];
		obuf[0] = 0;
		obuf++;
		osize++;
	}

	/* And finally, decrypt the rest of the packet. */
	setup_sg(sg_in, ibuf + 1, isize - 1);
	setup_sg(sg_out, obuf + 1, osize - 1);
	if (crypto_cipher_decrypt(state->arc4, sg_out, sg_in, isize - 1) != 0) {
		printk(KERN_DEBUG "crypto_cypher_decrypt failed\n");
		return DECOMP_ERROR;
	}

	state->stats.unc_bytes += osize;
	state->stats.unc_packets++;
	state->stats.comp_bytes += isize;
	state->stats.comp_packets++;

	/* good packet credit */
	state->sanity_errors >>= 1;

	return osize;
}
示例#6
0
/*
 * Compress (encrypt) a packet.
 * It's strange to call this a compressor, since the output is always
 * MPPE_OVHD + 2 bytes larger than the input.
 */
static int
mppe_compress(void *arg, unsigned char *ibuf, unsigned char *obuf,
	      int isize, int osize)
{
	struct ppp_mppe_state *state = (struct ppp_mppe_state *) arg;
	int proto;
	struct scatterlist sg_in[1], sg_out[1];

	/*
	 * Check that the protocol is in the range we handle.
	 */
	proto = PPP_PROTOCOL(ibuf);
	if (proto < 0x0021 || proto > 0x00fa)
		return 0;

	/* Make sure we have enough room to generate an encrypted packet. */
	if (osize < isize + MPPE_OVHD + 2) {
		/* Drop the packet if we should encrypt it, but can't. */
		printk(KERN_DEBUG "mppe_compress[%d]: osize too small! "
		       "(have: %d need: %d)\n", state->unit,
		       osize, osize + MPPE_OVHD + 2);
		return -1;
	}

	osize = isize + MPPE_OVHD + 2;

	/*
	 * Copy over the PPP header and set control bits.
	 */
	obuf[0] = PPP_ADDRESS(ibuf);
	obuf[1] = PPP_CONTROL(ibuf);
	obuf[2] = PPP_COMP >> 8;	/* isize + MPPE_OVHD + 1 */
	obuf[3] = PPP_COMP;	/* isize + MPPE_OVHD + 2 */
	obuf += PPP_HDRLEN;

	state->ccount = (state->ccount + 1) % MPPE_CCOUNT_SPACE;
	if (state->debug >= 7)
		printk(KERN_DEBUG "mppe_compress[%d]: ccount %d\n", state->unit,
		       state->ccount);
	obuf[0] = state->ccount >> 8;
	obuf[1] = state->ccount & 0xff;

	if (!state->stateful ||	/* stateless mode     */
	    ((state->ccount & 0xff) == 0xff) ||	/* "flag" packet      */
	    (state->bits & MPPE_BIT_FLUSHED)) {	/* CCP Reset-Request  */
		/* We must rekey */
		if (state->debug && state->stateful)
			printk(KERN_DEBUG "mppe_compress[%d]: rekeying\n",
			       state->unit);
		mppe_rekey(state, 0);
		state->bits |= MPPE_BIT_FLUSHED;
	}
	obuf[0] |= state->bits;
	state->bits &= ~MPPE_BIT_FLUSHED;	/* reset for next xmit */

	obuf += MPPE_OVHD;
	ibuf += 2;		/* skip to proto field */
	isize -= 2;

	/* Encrypt packet */
	setup_sg(sg_in, ibuf, isize);
	setup_sg(sg_out, obuf, osize);
	if (crypto_cipher_encrypt(state->arc4, sg_out, sg_in, isize) != 0) {
		printk(KERN_DEBUG "crypto_cypher_encrypt failed\n");
		return -1;
	}

	state->stats.unc_bytes += isize;
	state->stats.unc_packets++;
	state->stats.comp_bytes += osize;
	state->stats.comp_packets++;

	return osize;
}