4 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
6 * This program is free software; you can redistribute it and/or modify
7 * it under the terms of the GNU General Public License version 2 only,
8 * as published by the Free Software Foundation.
10 * This program is distributed in the hope that it will be useful, but
11 * WITHOUT ANY WARRANTY; without even the implied warranty of
12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
13 * General Public License version 2 for more details (a copy is included
14 * in the LICENSE file that accompanied this code).
16 * You should have received a copy of the GNU General Public License
17 * version 2 along with this program; If not, see
18 * http://www.gnu.org/licenses/gpl-2.0.html
23 * Copyright (C) 2013, 2015, Trustees of Indiana University
25 * Copyright (c) 2014, 2016, Intel Corporation.
27 * Author: Jeremy Filizetti <jfilizet@iu.edu>
28 * Author: Andrew Korty <ajk@iu.edu>
31 #define DEBUG_SUBSYSTEM S_SEC
32 #include <linux/init.h>
33 #include <linux/module.h>
34 #include <linux/slab.h>
35 #include <linux/crypto.h>
36 #include <linux/mutex.h>
37 #include <crypto/ctr.h>
40 #include <obd_class.h>
41 #include <obd_support.h>
44 #include "gss_crypto.h"
45 #include "gss_internal.h"
49 #define SK_INTERFACE_VERSION 1
50 #define SK_MSG_VERSION 1
54 /* Starting number for reverse contexts. It is critical to security
55 * that reverse contexts use a different range of numbers than regular
56 * contexts because they are using the same key. Therefore the IV/nonce
57 * combination must be unique for them. To accomplish this reverse contexts
58 * use the the negative range of a 64-bit number and regular contexts use the
59 * postive range. If the same IV/nonce combination were reused it would leak
60 * information about the plaintext. */
61 #define SK_IV_REV_START (1ULL << 63)
64 enum cfs_crypto_crypt_alg sc_crypt;
65 enum cfs_crypto_hash_alg sc_hmac;
71 struct gss_keyblock sc_session_kb;
77 } __attribute__((packed));
79 /* The format of SK wire data is similar to that of RFC3686 ESP Payload
80 * (section 3) except instead of just an IV there is a struct sk_hdr.
81 * ---------------------------------------------------------------------
82 * | struct sk_hdr | ciphertext (variable size) | HMAC (variable size) |
83 * --------------------------------------------------------------------- */
90 static inline unsigned long sk_block_mask(unsigned long len, int blocksize)
92 return (len + blocksize - 1) & (~(blocksize - 1));
95 static int sk_fill_header(struct sk_ctx *skc, struct sk_hdr *skh)
98 skh->skh_version = be64_to_cpu(SK_MSG_VERSION);
100 /* Always using inc_return so we don't use our initial numbers which
101 * could be the reuse detecting numbers */
102 tmp_iv = atomic64_inc_return(&skc->sc_iv);
103 skh->skh_iv = be64_to_cpu(tmp_iv);
104 if (tmp_iv == 0 || tmp_iv == SK_IV_REV_START) {
105 CERROR("Counter looped, connection must be reset to avoid "
106 "plaintext information\n");
107 return GSS_S_FAILURE;
110 return GSS_S_COMPLETE;
113 static int sk_verify_header(struct sk_hdr *skh)
115 if (cpu_to_be64(skh->skh_version) != SK_MSG_VERSION)
116 return GSS_S_DEFECTIVE_TOKEN;
118 return GSS_S_COMPLETE;
121 void sk_construct_rfc3686_iv(__u8 *iv, __u32 nonce, __u64 partial_iv)
123 __u32 ctr = cpu_to_be32(1);
125 memcpy(iv, &nonce, CTR_RFC3686_NONCE_SIZE);
126 iv += CTR_RFC3686_NONCE_SIZE;
127 memcpy(iv, &partial_iv, CTR_RFC3686_IV_SIZE);
128 iv += CTR_RFC3686_IV_SIZE;
129 memcpy(iv, &ctr, sizeof(ctr));
132 static int sk_fill_context(rawobj_t *inbuf, struct sk_ctx *skc)
134 char *ptr = inbuf->data;
135 char *end = inbuf->data + inbuf->len;
136 char sk_hmac[CRYPTO_MAX_ALG_NAME];
137 char sk_crypt[CRYPTO_MAX_ALG_NAME];
140 /* see sk_serialize_kctx() for format from userspace side */
142 if (gss_get_bytes(&ptr, end, &tmp, sizeof(tmp))) {
143 CERROR("Failed to read shared key interface version\n");
146 if (tmp != SK_INTERFACE_VERSION) {
147 CERROR("Invalid shared key interface version: %d\n", tmp);
152 if (gss_get_bytes(&ptr, end, &sk_hmac, sizeof(sk_hmac))) {
153 CERROR("Failed to read HMAC algorithm type\n");
157 skc->sc_hmac = cfs_crypto_hash_alg(sk_hmac);
158 if (skc->sc_hmac != CFS_HASH_ALG_NULL &&
159 skc->sc_hmac != CFS_HASH_ALG_SHA256 &&
160 skc->sc_hmac != CFS_HASH_ALG_SHA512) {
161 CERROR("Invalid hmac type: %s\n", sk_hmac);
166 if (gss_get_bytes(&ptr, end, &sk_crypt, sizeof(sk_crypt))) {
167 CERROR("Failed to read crypt algorithm type\n");
171 skc->sc_crypt = cfs_crypto_crypt_alg(sk_crypt);
172 if (skc->sc_crypt == CFS_CRYPT_ALG_UNKNOWN) {
173 CERROR("Invalid crypt type: %s\n", sk_crypt);
177 /* 4. expiration time */
178 if (gss_get_bytes(&ptr, end, &tmp, sizeof(tmp))) {
179 CERROR("Failed to read context expiration time\n");
182 skc->sc_expire = tmp + ktime_get_real_seconds();
184 /* 5. host random is used as nonce for encryption */
185 if (gss_get_bytes(&ptr, end, &skc->sc_host_random,
186 sizeof(skc->sc_host_random))) {
187 CERROR("Failed to read host random\n");
191 /* 6. peer random is used as nonce for decryption */
192 if (gss_get_bytes(&ptr, end, &skc->sc_peer_random,
193 sizeof(skc->sc_peer_random))) {
194 CERROR("Failed to read peer random\n");
199 if (gss_get_rawobj(&ptr, end, &skc->sc_hmac_key)) {
200 CERROR("Failed to read HMAC key\n");
203 if (skc->sc_hmac_key.len <= SK_MIN_SIZE) {
204 CERROR("HMAC key must key must be larger than %d bytes\n",
209 /* 8. Session key, can be empty if not using privacy mode */
210 if (gss_get_rawobj(&ptr, end, &skc->sc_session_kb.kb_key)) {
211 CERROR("Failed to read session key\n");
218 static void sk_delete_context(struct sk_ctx *skc)
223 rawobj_free(&skc->sc_hmac_key);
224 gss_keyblock_free(&skc->sc_session_kb);
229 __u32 gss_import_sec_context_sk(rawobj_t *inbuf, struct gss_ctx *gss_context)
232 bool privacy = false;
234 if (inbuf == NULL || inbuf->data == NULL)
235 return GSS_S_FAILURE;
239 return GSS_S_FAILURE;
241 atomic64_set(&skc->sc_iv, 0);
243 if (sk_fill_context(inbuf, skc))
246 /* Only privacy mode needs to initialize keys */
247 if (skc->sc_session_kb.kb_key.len > 0) {
249 if (gss_keyblock_init(&skc->sc_session_kb,
250 cfs_crypto_crypt_name(skc->sc_crypt), 0))
254 gss_context->internal_ctx_id = skc;
255 CDEBUG(D_SEC, "successfully imported sk%s context\n",
256 privacy ? " (with privacy)" : "");
258 return GSS_S_COMPLETE;
261 sk_delete_context(skc);
262 return GSS_S_FAILURE;
266 __u32 gss_copy_reverse_context_sk(struct gss_ctx *gss_context_old,
267 struct gss_ctx *gss_context_new)
269 struct sk_ctx *skc_old = gss_context_old->internal_ctx_id;
270 struct sk_ctx *skc_new;
272 OBD_ALLOC_PTR(skc_new);
274 return GSS_S_FAILURE;
276 skc_new->sc_hmac = skc_old->sc_hmac;
277 skc_new->sc_crypt = skc_old->sc_crypt;
278 skc_new->sc_expire = skc_old->sc_expire;
279 skc_new->sc_host_random = skc_old->sc_host_random;
280 skc_new->sc_peer_random = skc_old->sc_peer_random;
282 atomic64_set(&skc_new->sc_iv, SK_IV_REV_START);
284 if (rawobj_dup(&skc_new->sc_hmac_key, &skc_old->sc_hmac_key))
286 if (gss_keyblock_dup(&skc_new->sc_session_kb, &skc_old->sc_session_kb))
289 /* Only privacy mode needs to initialize keys */
290 if (skc_new->sc_session_kb.kb_key.len > 0)
291 if (gss_keyblock_init(&skc_new->sc_session_kb,
292 cfs_crypto_crypt_name(skc_new->sc_crypt),
296 gss_context_new->internal_ctx_id = skc_new;
297 CDEBUG(D_SEC, "successfully copied reverse sk context\n");
299 return GSS_S_COMPLETE;
302 sk_delete_context(skc_new);
303 return GSS_S_FAILURE;
307 __u32 gss_inquire_context_sk(struct gss_ctx *gss_context,
310 struct sk_ctx *skc = gss_context->internal_ctx_id;
312 *endtime = skc->sc_expire;
313 return GSS_S_COMPLETE;
317 u32 sk_make_hmac(enum cfs_crypto_hash_alg algo, rawobj_t *key, int msg_count,
318 rawobj_t *msgs, int iov_count, lnet_kiov_t *iovs,
321 struct ahash_request *req;
324 req = cfs_crypto_hash_init(algo, key->data, key->len);
327 goto out_init_failed;
330 rc2 = gss_digest_hash(req, NULL, msg_count, msgs, iov_count, iovs,
332 rc = cfs_crypto_hash_final(req, key->data, &key->len);
336 return rc ? GSS_S_FAILURE : GSS_S_COMPLETE;
340 __u32 gss_get_mic_sk(struct gss_ctx *gss_context,
347 struct sk_ctx *skc = gss_context->internal_ctx_id;
349 return sk_make_hmac(skc->sc_hmac,
350 &skc->sc_hmac_key, message_count, messages,
351 iov_count, iovs, token);
355 u32 sk_verify_hmac(enum cfs_crypto_hash_alg algo, rawobj_t *key,
356 int message_count, rawobj_t *messages,
357 int iov_count, lnet_kiov_t *iovs,
360 rawobj_t checksum = RAWOBJ_EMPTY;
361 __u32 rc = GSS_S_FAILURE;
363 checksum.len = cfs_crypto_hash_digestsize(algo);
364 if (token->len < checksum.len) {
365 CDEBUG(D_SEC, "Token received too short, expected %d "
366 "received %d\n", token->len, checksum.len);
367 return GSS_S_DEFECTIVE_TOKEN;
370 OBD_ALLOC_LARGE(checksum.data, checksum.len);
374 if (sk_make_hmac(algo, key, message_count,
375 messages, iov_count, iovs, &checksum)) {
376 CDEBUG(D_SEC, "Failed to create checksum to validate\n");
380 if (memcmp(token->data, checksum.data, checksum.len)) {
381 CERROR("checksum mismatch\n");
389 OBD_FREE(checksum.data, checksum.len);
393 /* sk_verify_bulk_hmac() differs slightly from sk_verify_hmac() because all
394 * encrypted pages in the bulk descriptor are populated although we only need
395 * to decrypt up to the number of bytes actually specified from the sender
396 * (bd_nob) otherwise the calulated HMAC will be incorrect. */
398 u32 sk_verify_bulk_hmac(enum cfs_crypto_hash_alg sc_hmac, rawobj_t *key,
399 int msgcnt, rawobj_t *msgs, int iovcnt,
400 lnet_kiov_t *iovs, int iov_bytes, rawobj_t *token)
402 rawobj_t checksum = RAWOBJ_EMPTY;
403 struct ahash_request *req;
404 struct scatterlist sg[1];
405 int rc = GSS_S_FAILURE;
410 checksum.len = cfs_crypto_hash_digestsize(sc_hmac);
411 if (token->len < checksum.len) {
412 CDEBUG(D_SEC, "Token received too short, expected %d "
413 "received %d\n", token->len, checksum.len);
414 return GSS_S_DEFECTIVE_TOKEN;
417 OBD_ALLOC_LARGE(checksum.data, checksum.len);
421 req = cfs_crypto_hash_init(sc_hmac, key->data, key->len);
425 for (i = 0; i < msgcnt; i++) {
429 rc = gss_setup_sgtable(&sgt, sg, msgs[i].data, msgs[i].len);
433 ahash_request_set_crypt(req, sg, NULL, msgs[i].len);
434 rc = crypto_ahash_update(req);
436 gss_teardown_sgtable(&sgt);
440 gss_teardown_sgtable(&sgt);
443 for (i = 0; i < iovcnt && iov_bytes > 0; i++) {
444 if (iovs[i].kiov_len == 0)
447 bytes = min_t(int, iov_bytes, iovs[i].kiov_len);
450 sg_init_table(sg, 1);
451 sg_set_page(&sg[0], iovs[i].kiov_page, bytes,
452 iovs[i].kiov_offset);
453 ahash_request_set_crypt(req, sg, NULL, bytes);
454 rc = crypto_ahash_update(req);
459 if (memcmp(token->data, checksum.data, checksum.len)) {
467 cfs_crypto_hash_final(req, checksum.data, &checksum.len);
470 OBD_FREE_LARGE(checksum.data, checksum.len);
476 __u32 gss_verify_mic_sk(struct gss_ctx *gss_context,
483 struct sk_ctx *skc = gss_context->internal_ctx_id;
485 return sk_verify_hmac(skc->sc_hmac, &skc->sc_hmac_key,
486 message_count, messages, iov_count, iovs, token);
490 __u32 gss_wrap_sk(struct gss_ctx *gss_context, rawobj_t *gss_header,
491 rawobj_t *message, int message_buffer_length,
494 struct sk_ctx *skc = gss_context->internal_ctx_id;
495 size_t sht_bytes = cfs_crypto_hash_digestsize(skc->sc_hmac);
499 __u8 local_iv[SK_IV_SIZE];
500 unsigned int blocksize;
502 LASSERT(skc->sc_session_kb.kb_tfm);
504 blocksize = crypto_blkcipher_blocksize(skc->sc_session_kb.kb_tfm);
505 if (gss_add_padding(message, message_buffer_length, blocksize))
506 return GSS_S_FAILURE;
508 memset(token->data, 0, token->len);
510 if (sk_fill_header(skc, &skh) != GSS_S_COMPLETE)
511 return GSS_S_FAILURE;
513 skw.skw_header.data = token->data;
514 skw.skw_header.len = sizeof(skh);
515 memcpy(skw.skw_header.data, &skh, sizeof(skh));
517 sk_construct_rfc3686_iv(local_iv, skc->sc_host_random, skh.skh_iv);
518 skw.skw_cipher.data = skw.skw_header.data + skw.skw_header.len;
519 skw.skw_cipher.len = token->len - skw.skw_header.len - sht_bytes;
520 if (gss_crypt_rawobjs(skc->sc_session_kb.kb_tfm, local_iv, 1, message,
522 return GSS_S_FAILURE;
524 /* HMAC covers the SK header, GSS header, and ciphertext */
525 msgbufs[0] = skw.skw_header;
526 msgbufs[1] = *gss_header;
527 msgbufs[2] = skw.skw_cipher;
529 skw.skw_hmac.data = skw.skw_cipher.data + skw.skw_cipher.len;
530 skw.skw_hmac.len = sht_bytes;
531 if (sk_make_hmac(skc->sc_hmac, &skc->sc_hmac_key,
532 3, msgbufs, 0, NULL, &skw.skw_hmac))
533 return GSS_S_FAILURE;
535 token->len = skw.skw_header.len + skw.skw_cipher.len + skw.skw_hmac.len;
537 return GSS_S_COMPLETE;
541 __u32 gss_unwrap_sk(struct gss_ctx *gss_context, rawobj_t *gss_header,
542 rawobj_t *token, rawobj_t *message)
544 struct sk_ctx *skc = gss_context->internal_ctx_id;
545 size_t sht_bytes = cfs_crypto_hash_digestsize(skc->sc_hmac);
549 __u8 local_iv[SK_IV_SIZE];
550 unsigned int blocksize;
553 LASSERT(skc->sc_session_kb.kb_tfm);
555 if (token->len < sizeof(skh) + sht_bytes)
556 return GSS_S_DEFECTIVE_TOKEN;
558 skw.skw_header.data = token->data;
559 skw.skw_header.len = sizeof(struct sk_hdr);
560 skw.skw_cipher.data = skw.skw_header.data + skw.skw_header.len;
561 skw.skw_cipher.len = token->len - skw.skw_header.len - sht_bytes;
562 skw.skw_hmac.data = skw.skw_cipher.data + skw.skw_cipher.len;
563 skw.skw_hmac.len = sht_bytes;
565 blocksize = crypto_blkcipher_blocksize(skc->sc_session_kb.kb_tfm);
566 if (skw.skw_cipher.len % blocksize != 0)
567 return GSS_S_DEFECTIVE_TOKEN;
569 skh = (struct sk_hdr *)skw.skw_header.data;
570 rc = sk_verify_header(skh);
571 if (rc != GSS_S_COMPLETE)
574 /* HMAC covers the SK header, GSS header, and ciphertext */
575 msgbufs[0] = skw.skw_header;
576 msgbufs[1] = *gss_header;
577 msgbufs[2] = skw.skw_cipher;
578 rc = sk_verify_hmac(skc->sc_hmac, &skc->sc_hmac_key, 3, msgbufs,
579 0, NULL, &skw.skw_hmac);
583 sk_construct_rfc3686_iv(local_iv, skc->sc_peer_random, skh->skh_iv);
584 message->len = skw.skw_cipher.len;
585 if (gss_crypt_rawobjs(skc->sc_session_kb.kb_tfm, local_iv,
586 1, &skw.skw_cipher, message, 0))
587 return GSS_S_FAILURE;
589 return GSS_S_COMPLETE;
593 __u32 gss_prep_bulk_sk(struct gss_ctx *gss_context,
594 struct ptlrpc_bulk_desc *desc)
596 struct sk_ctx *skc = gss_context->internal_ctx_id;
600 LASSERT(skc->sc_session_kb.kb_tfm);
601 blocksize = crypto_blkcipher_blocksize(skc->sc_session_kb.kb_tfm);
603 for (i = 0; i < desc->bd_iov_count; i++) {
604 if (BD_GET_KIOV(desc, i).kiov_offset & blocksize) {
605 CERROR("offset %d not blocksize aligned\n",
606 BD_GET_KIOV(desc, i).kiov_offset);
607 return GSS_S_FAILURE;
610 BD_GET_ENC_KIOV(desc, i).kiov_offset =
611 BD_GET_KIOV(desc, i).kiov_offset;
612 BD_GET_ENC_KIOV(desc, i).kiov_len =
613 sk_block_mask(BD_GET_KIOV(desc, i).kiov_len, blocksize);
616 return GSS_S_COMPLETE;
619 static __u32 sk_encrypt_bulk(struct crypto_blkcipher *tfm, __u8 *iv,
620 struct ptlrpc_bulk_desc *desc, rawobj_t *cipher,
623 struct blkcipher_desc cdesc = {
628 struct scatterlist ptxt;
629 struct scatterlist ctxt;
635 blocksize = crypto_blkcipher_blocksize(tfm);
637 sg_init_table(&ptxt, 1);
638 sg_init_table(&ctxt, 1);
640 for (i = 0; i < desc->bd_iov_count; i++) {
641 sg_set_page(&ptxt, BD_GET_KIOV(desc, i).kiov_page,
642 sk_block_mask(BD_GET_KIOV(desc, i).kiov_len,
644 BD_GET_KIOV(desc, i).kiov_offset);
647 sg_set_page(&ctxt, BD_GET_ENC_KIOV(desc, i).kiov_page,
648 ptxt.length, ptxt.offset);
650 BD_GET_ENC_KIOV(desc, i).kiov_offset = ctxt.offset;
651 BD_GET_ENC_KIOV(desc, i).kiov_len = ctxt.length;
653 rc = crypto_blkcipher_encrypt_iv(&cdesc, &ctxt, &ptxt,
656 CERROR("failed to encrypt page: %d\n", rc);
667 static __u32 sk_decrypt_bulk(struct crypto_blkcipher *tfm, __u8 *iv,
668 struct ptlrpc_bulk_desc *desc, rawobj_t *cipher,
671 struct blkcipher_desc cdesc = {
676 struct scatterlist ptxt;
677 struct scatterlist ctxt;
684 sg_init_table(&ptxt, 1);
685 sg_init_table(&ctxt, 1);
687 blocksize = crypto_blkcipher_blocksize(tfm);
688 if (desc->bd_nob_transferred % blocksize != 0) {
689 CERROR("Transfer not a multiple of block size: %d\n",
690 desc->bd_nob_transferred);
691 return GSS_S_DEFECTIVE_TOKEN;
694 for (i = 0; i < desc->bd_iov_count && cnob < desc->bd_nob_transferred;
696 lnet_kiov_t *piov = &BD_GET_KIOV(desc, i);
697 lnet_kiov_t *ciov = &BD_GET_ENC_KIOV(desc, i);
699 if (ciov->kiov_offset % blocksize != 0 ||
700 ciov->kiov_len % blocksize != 0) {
701 CERROR("Invalid bulk descriptor vector\n");
702 return GSS_S_DEFECTIVE_TOKEN;
705 /* Must adjust bytes here because we know the actual sizes after
706 * decryption. Similar to what gss_cli_ctx_unwrap_bulk does for
707 * integrity only mode */
709 /* cipher text must not exceed transferred size */
710 if (ciov->kiov_len + cnob > desc->bd_nob_transferred)
712 desc->bd_nob_transferred - cnob;
714 piov->kiov_len = ciov->kiov_len;
716 /* plain text must not exceed bulk's size */
717 if (ciov->kiov_len + pnob > desc->bd_nob)
718 piov->kiov_len = desc->bd_nob - pnob;
720 /* Taken from krb5_decrypt since it was not verified
721 * whether or not LNET guarantees these */
722 if (ciov->kiov_len + cnob > desc->bd_nob_transferred ||
723 piov->kiov_len > ciov->kiov_len) {
724 CERROR("Invalid decrypted length\n");
725 return GSS_S_FAILURE;
729 if (ciov->kiov_len == 0)
732 sg_init_table(&ctxt, 1);
733 sg_set_page(&ctxt, ciov->kiov_page, ciov->kiov_len,
737 /* In the event the plain text size is not a multiple
738 * of blocksize we decrypt in place and copy the result
739 * after the decryption */
740 if (piov->kiov_len % blocksize == 0)
741 sg_assign_page(&ptxt, piov->kiov_page);
743 rc = crypto_blkcipher_decrypt_iv(&cdesc, &ptxt, &ctxt,
746 CERROR("Decryption failed for page: %d\n", rc);
747 return GSS_S_FAILURE;
750 if (piov->kiov_len % blocksize != 0) {
751 memcpy(page_address(piov->kiov_page) +
753 page_address(ciov->kiov_page) +
758 cnob += ciov->kiov_len;
759 pnob += piov->kiov_len;
762 /* if needed, clear up the rest unused iovs */
764 while (i < desc->bd_iov_count)
765 BD_GET_KIOV(desc, i++).kiov_len = 0;
767 if (unlikely(cnob != desc->bd_nob_transferred)) {
768 CERROR("%d cipher text transferred but only %d decrypted\n",
769 desc->bd_nob_transferred, cnob);
770 return GSS_S_FAILURE;
773 if (unlikely(!adj_nob && pnob != desc->bd_nob)) {
774 CERROR("%d plain text expected but only %d received\n",
776 return GSS_S_FAILURE;
783 __u32 gss_wrap_bulk_sk(struct gss_ctx *gss_context,
784 struct ptlrpc_bulk_desc *desc, rawobj_t *token,
787 struct sk_ctx *skc = gss_context->internal_ctx_id;
788 size_t sht_bytes = cfs_crypto_hash_digestsize(skc->sc_hmac);
791 __u8 local_iv[SK_IV_SIZE];
793 LASSERT(skc->sc_session_kb.kb_tfm);
795 memset(token->data, 0, token->len);
796 if (sk_fill_header(skc, &skh) != GSS_S_COMPLETE)
797 return GSS_S_FAILURE;
799 skw.skw_header.data = token->data;
800 skw.skw_header.len = sizeof(skh);
801 memcpy(skw.skw_header.data, &skh, sizeof(skh));
803 sk_construct_rfc3686_iv(local_iv, skc->sc_host_random, skh.skh_iv);
804 skw.skw_cipher.data = skw.skw_header.data + skw.skw_header.len;
805 skw.skw_cipher.len = token->len - skw.skw_header.len - sht_bytes;
806 if (sk_encrypt_bulk(skc->sc_session_kb.kb_tfm, local_iv,
807 desc, &skw.skw_cipher, adj_nob))
808 return GSS_S_FAILURE;
810 skw.skw_hmac.data = skw.skw_cipher.data + skw.skw_cipher.len;
811 skw.skw_hmac.len = sht_bytes;
812 if (sk_make_hmac(skc->sc_hmac, &skc->sc_hmac_key, 1, &skw.skw_cipher,
813 desc->bd_iov_count, GET_ENC_KIOV(desc), &skw.skw_hmac))
814 return GSS_S_FAILURE;
816 return GSS_S_COMPLETE;
820 __u32 gss_unwrap_bulk_sk(struct gss_ctx *gss_context,
821 struct ptlrpc_bulk_desc *desc,
822 rawobj_t *token, int adj_nob)
824 struct sk_ctx *skc = gss_context->internal_ctx_id;
825 size_t sht_bytes = cfs_crypto_hash_digestsize(skc->sc_hmac);
828 __u8 local_iv[SK_IV_SIZE];
831 LASSERT(skc->sc_session_kb.kb_tfm);
833 if (token->len < sizeof(skh) + sht_bytes)
834 return GSS_S_DEFECTIVE_TOKEN;
836 skw.skw_header.data = token->data;
837 skw.skw_header.len = sizeof(struct sk_hdr);
838 skw.skw_cipher.data = skw.skw_header.data + skw.skw_header.len;
839 skw.skw_cipher.len = token->len - skw.skw_header.len - sht_bytes;
840 skw.skw_hmac.data = skw.skw_cipher.data + skw.skw_cipher.len;
841 skw.skw_hmac.len = sht_bytes;
843 skh = (struct sk_hdr *)skw.skw_header.data;
844 rc = sk_verify_header(skh);
845 if (rc != GSS_S_COMPLETE)
848 rc = sk_verify_bulk_hmac(skc->sc_hmac, &skc->sc_hmac_key, 1,
849 &skw.skw_cipher, desc->bd_iov_count,
850 GET_ENC_KIOV(desc), desc->bd_nob,
855 sk_construct_rfc3686_iv(local_iv, skc->sc_peer_random, skh->skh_iv);
856 rc = sk_decrypt_bulk(skc->sc_session_kb.kb_tfm, local_iv,
857 desc, &skw.skw_cipher, adj_nob);
861 return GSS_S_COMPLETE;
865 void gss_delete_sec_context_sk(void *internal_context)
867 struct sk_ctx *sk_context = internal_context;
868 sk_delete_context(sk_context);
871 int gss_display_sk(struct gss_ctx *gss_context, char *buf, int bufsize)
873 return snprintf(buf, bufsize, "sk");
876 static struct gss_api_ops gss_sk_ops = {
877 .gss_import_sec_context = gss_import_sec_context_sk,
878 .gss_copy_reverse_context = gss_copy_reverse_context_sk,
879 .gss_inquire_context = gss_inquire_context_sk,
880 .gss_get_mic = gss_get_mic_sk,
881 .gss_verify_mic = gss_verify_mic_sk,
882 .gss_wrap = gss_wrap_sk,
883 .gss_unwrap = gss_unwrap_sk,
884 .gss_prep_bulk = gss_prep_bulk_sk,
885 .gss_wrap_bulk = gss_wrap_bulk_sk,
886 .gss_unwrap_bulk = gss_unwrap_bulk_sk,
887 .gss_delete_sec_context = gss_delete_sec_context_sk,
888 .gss_display = gss_display_sk,
891 static struct subflavor_desc gss_sk_sfs[] = {
893 .sf_subflavor = SPTLRPC_SUBFLVR_SKN,
895 .sf_service = SPTLRPC_SVC_NULL,
899 .sf_subflavor = SPTLRPC_SUBFLVR_SKA,
901 .sf_service = SPTLRPC_SVC_AUTH,
905 .sf_subflavor = SPTLRPC_SUBFLVR_SKI,
907 .sf_service = SPTLRPC_SVC_INTG,
911 .sf_subflavor = SPTLRPC_SUBFLVR_SKPI,
913 .sf_service = SPTLRPC_SVC_PRIV,
918 static struct gss_api_mech gss_sk_mech = {
919 /* .gm_owner uses default NULL value for THIS_MODULE */
921 .gm_oid = (rawobj_t) {
923 .data = "\053\006\001\004\001\311\146\215\126\001\000\001",
925 .gm_ops = &gss_sk_ops,
927 .gm_sfs = gss_sk_sfs,
930 int __init init_sk_module(void)
934 status = lgss_mech_register(&gss_sk_mech);
936 CERROR("Failed to register sk gss mechanism!\n");
941 void cleanup_sk_module(void)
943 lgss_mech_unregister(&gss_sk_mech);