kernel-fxtec-pro1x/net/xfrm/xfrm_algo.c
Lorenzo Colitti db8b08fe26 ANDROID: net: xfrm: make PF_KEY SHA256 use RFC-compliant truncation.
When using the PF_KEY interface, SHA-256 hashes are hardcoded to
use 96-bit truncation. This is a violation of RFC4868, which
specifies 128-bit truncation, but will not be fixed upstream due
to backwards compatibility concerns and because the PF_KEY
interface is deprecated in favour of netlink XFRM (which allows
the app to specify an arbitrary truncation length).

Change the hardcoded truncation length from 96 to 128 so that
PF_KEY apps such as racoon will work with standards-compliant VPN
servers.

Bug: 34114242
Change-Id: Ie46bff4b6358f18117d0be241171d677d31d33f7
Signed-off-by: Lorenzo Colitti <lorenzo@google.com>
2018-08-28 17:10:42 +05:30

829 lines
14 KiB
C

/*
* xfrm algorithm interface
*
* Copyright (c) 2002 James Morris <jmorris@intercode.com.au>
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the Free
* Software Foundation; either version 2 of the License, or (at your option)
* any later version.
*/
#include <crypto/hash.h>
#include <crypto/skcipher.h>
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/pfkeyv2.h>
#include <linux/crypto.h>
#include <linux/scatterlist.h>
#include <net/xfrm.h>
#if IS_ENABLED(CONFIG_INET_ESP) || IS_ENABLED(CONFIG_INET6_ESP)
#include <net/esp.h>
#endif
/*
* Algorithms supported by IPsec. These entries contain properties which
* are used in key negotiation and xfrm processing, and are used to verify
* that instantiated crypto transforms have correct parameters for IPsec
* purposes.
*/
static struct xfrm_algo_desc aead_list[] = {
{
.name = "rfc4106(gcm(aes))",
.uinfo = {
.aead = {
.geniv = "seqiv",
.icv_truncbits = 64,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_AES_GCM_ICV8,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256
}
},
{
.name = "rfc4106(gcm(aes))",
.uinfo = {
.aead = {
.geniv = "seqiv",
.icv_truncbits = 96,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_AES_GCM_ICV12,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256
}
},
{
.name = "rfc4106(gcm(aes))",
.uinfo = {
.aead = {
.geniv = "seqiv",
.icv_truncbits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_AES_GCM_ICV16,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256
}
},
{
.name = "rfc4309(ccm(aes))",
.uinfo = {
.aead = {
.geniv = "seqiv",
.icv_truncbits = 64,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_AES_CCM_ICV8,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256
}
},
{
.name = "rfc4309(ccm(aes))",
.uinfo = {
.aead = {
.geniv = "seqiv",
.icv_truncbits = 96,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_AES_CCM_ICV12,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256
}
},
{
.name = "rfc4309(ccm(aes))",
.uinfo = {
.aead = {
.geniv = "seqiv",
.icv_truncbits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_AES_CCM_ICV16,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256
}
},
{
.name = "rfc4543(gcm(aes))",
.uinfo = {
.aead = {
.geniv = "seqiv",
.icv_truncbits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_NULL_AES_GMAC,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256
}
},
{
.name = "rfc7539esp(chacha20,poly1305)",
.uinfo = {
.aead = {
.geniv = "seqiv",
.icv_truncbits = 128,
}
},
.pfkey_supported = 0,
},
};
static struct xfrm_algo_desc aalg_list[] = {
{
.name = "digest_null",
.uinfo = {
.auth = {
.icv_truncbits = 0,
.icv_fullbits = 0,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_AALG_NULL,
.sadb_alg_ivlen = 0,
.sadb_alg_minbits = 0,
.sadb_alg_maxbits = 0
}
},
{
.name = "hmac(md5)",
.compat = "md5",
.uinfo = {
.auth = {
.icv_truncbits = 96,
.icv_fullbits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_AALG_MD5HMAC,
.sadb_alg_ivlen = 0,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 128
}
},
{
.name = "hmac(sha1)",
.compat = "sha1",
.uinfo = {
.auth = {
.icv_truncbits = 96,
.icv_fullbits = 160,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_AALG_SHA1HMAC,
.sadb_alg_ivlen = 0,
.sadb_alg_minbits = 160,
.sadb_alg_maxbits = 160
}
},
{
.name = "hmac(sha256)",
.compat = "sha256",
.uinfo = {
.auth = {
.icv_truncbits = 128,
.icv_fullbits = 256,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_AALG_SHA2_256HMAC,
.sadb_alg_ivlen = 0,
.sadb_alg_minbits = 256,
.sadb_alg_maxbits = 256
}
},
{
.name = "hmac(sha384)",
.uinfo = {
.auth = {
.icv_truncbits = 192,
.icv_fullbits = 384,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_AALG_SHA2_384HMAC,
.sadb_alg_ivlen = 0,
.sadb_alg_minbits = 384,
.sadb_alg_maxbits = 384
}
},
{
.name = "hmac(sha512)",
.uinfo = {
.auth = {
.icv_truncbits = 256,
.icv_fullbits = 512,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_AALG_SHA2_512HMAC,
.sadb_alg_ivlen = 0,
.sadb_alg_minbits = 512,
.sadb_alg_maxbits = 512
}
},
{
.name = "hmac(rmd160)",
.compat = "rmd160",
.uinfo = {
.auth = {
.icv_truncbits = 96,
.icv_fullbits = 160,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_AALG_RIPEMD160HMAC,
.sadb_alg_ivlen = 0,
.sadb_alg_minbits = 160,
.sadb_alg_maxbits = 160
}
},
{
.name = "xcbc(aes)",
.uinfo = {
.auth = {
.icv_truncbits = 96,
.icv_fullbits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_AALG_AES_XCBC_MAC,
.sadb_alg_ivlen = 0,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 128
}
},
{
/* rfc4494 */
.name = "cmac(aes)",
.uinfo = {
.auth = {
.icv_truncbits = 96,
.icv_fullbits = 128,
}
},
.pfkey_supported = 0,
},
};
static struct xfrm_algo_desc ealg_list[] = {
{
.name = "ecb(cipher_null)",
.compat = "cipher_null",
.uinfo = {
.encr = {
.blockbits = 8,
.defkeybits = 0,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_EALG_NULL,
.sadb_alg_ivlen = 0,
.sadb_alg_minbits = 0,
.sadb_alg_maxbits = 0
}
},
{
.name = "cbc(des)",
.compat = "des",
.uinfo = {
.encr = {
.geniv = "echainiv",
.blockbits = 64,
.defkeybits = 64,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_EALG_DESCBC,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 64,
.sadb_alg_maxbits = 64
}
},
{
.name = "cbc(des3_ede)",
.compat = "des3_ede",
.uinfo = {
.encr = {
.geniv = "echainiv",
.blockbits = 64,
.defkeybits = 192,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_EALG_3DESCBC,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 192,
.sadb_alg_maxbits = 192
}
},
{
.name = "cbc(cast5)",
.compat = "cast5",
.uinfo = {
.encr = {
.geniv = "echainiv",
.blockbits = 64,
.defkeybits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_CASTCBC,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 40,
.sadb_alg_maxbits = 128
}
},
{
.name = "cbc(blowfish)",
.compat = "blowfish",
.uinfo = {
.encr = {
.geniv = "echainiv",
.blockbits = 64,
.defkeybits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_BLOWFISHCBC,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 40,
.sadb_alg_maxbits = 448
}
},
{
.name = "cbc(aes)",
.compat = "aes",
.uinfo = {
.encr = {
.geniv = "echainiv",
.blockbits = 128,
.defkeybits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_AESCBC,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256
}
},
{
.name = "cbc(serpent)",
.compat = "serpent",
.uinfo = {
.encr = {
.geniv = "echainiv",
.blockbits = 128,
.defkeybits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_SERPENTCBC,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256,
}
},
{
.name = "cbc(camellia)",
.compat = "camellia",
.uinfo = {
.encr = {
.geniv = "echainiv",
.blockbits = 128,
.defkeybits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_CAMELLIACBC,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256
}
},
{
.name = "cbc(twofish)",
.compat = "twofish",
.uinfo = {
.encr = {
.geniv = "echainiv",
.blockbits = 128,
.defkeybits = 128,
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_TWOFISHCBC,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 128,
.sadb_alg_maxbits = 256
}
},
{
.name = "rfc3686(ctr(aes))",
.uinfo = {
.encr = {
.geniv = "seqiv",
.blockbits = 128,
.defkeybits = 160, /* 128-bit key + 32-bit nonce */
}
},
.pfkey_supported = 1,
.desc = {
.sadb_alg_id = SADB_X_EALG_AESCTR,
.sadb_alg_ivlen = 8,
.sadb_alg_minbits = 160,
.sadb_alg_maxbits = 288
}
},
};
static struct xfrm_algo_desc calg_list[] = {
{
.name = "deflate",
.uinfo = {
.comp = {
.threshold = 90,
}
},
.pfkey_supported = 1,
.desc = { .sadb_alg_id = SADB_X_CALG_DEFLATE }
},
{
.name = "lzs",
.uinfo = {
.comp = {
.threshold = 90,
}
},
.pfkey_supported = 1,
.desc = { .sadb_alg_id = SADB_X_CALG_LZS }
},
{
.name = "lzjh",
.uinfo = {
.comp = {
.threshold = 50,
}
},
.pfkey_supported = 1,
.desc = { .sadb_alg_id = SADB_X_CALG_LZJH }
},
};
static inline int aalg_entries(void)
{
return ARRAY_SIZE(aalg_list);
}
static inline int ealg_entries(void)
{
return ARRAY_SIZE(ealg_list);
}
static inline int calg_entries(void)
{
return ARRAY_SIZE(calg_list);
}
struct xfrm_algo_list {
struct xfrm_algo_desc *algs;
int entries;
u32 type;
u32 mask;
};
static const struct xfrm_algo_list xfrm_aead_list = {
.algs = aead_list,
.entries = ARRAY_SIZE(aead_list),
.type = CRYPTO_ALG_TYPE_AEAD,
.mask = CRYPTO_ALG_TYPE_MASK,
};
static const struct xfrm_algo_list xfrm_aalg_list = {
.algs = aalg_list,
.entries = ARRAY_SIZE(aalg_list),
.type = CRYPTO_ALG_TYPE_HASH,
.mask = CRYPTO_ALG_TYPE_HASH_MASK,
};
static const struct xfrm_algo_list xfrm_ealg_list = {
.algs = ealg_list,
.entries = ARRAY_SIZE(ealg_list),
.type = CRYPTO_ALG_TYPE_BLKCIPHER,
.mask = CRYPTO_ALG_TYPE_BLKCIPHER_MASK,
};
static const struct xfrm_algo_list xfrm_calg_list = {
.algs = calg_list,
.entries = ARRAY_SIZE(calg_list),
.type = CRYPTO_ALG_TYPE_COMPRESS,
.mask = CRYPTO_ALG_TYPE_MASK,
};
static struct xfrm_algo_desc *xfrm_find_algo(
const struct xfrm_algo_list *algo_list,
int match(const struct xfrm_algo_desc *entry, const void *data),
const void *data, int probe)
{
struct xfrm_algo_desc *list = algo_list->algs;
int i, status;
for (i = 0; i < algo_list->entries; i++) {
if (!match(list + i, data))
continue;
if (list[i].available)
return &list[i];
if (!probe)
break;
status = crypto_has_alg(list[i].name, algo_list->type,
algo_list->mask);
if (!status)
break;
list[i].available = status;
return &list[i];
}
return NULL;
}
static int xfrm_alg_id_match(const struct xfrm_algo_desc *entry,
const void *data)
{
return entry->desc.sadb_alg_id == (unsigned long)data;
}
struct xfrm_algo_desc *xfrm_aalg_get_byid(int alg_id)
{
return xfrm_find_algo(&xfrm_aalg_list, xfrm_alg_id_match,
(void *)(unsigned long)alg_id, 1);
}
EXPORT_SYMBOL_GPL(xfrm_aalg_get_byid);
struct xfrm_algo_desc *xfrm_ealg_get_byid(int alg_id)
{
return xfrm_find_algo(&xfrm_ealg_list, xfrm_alg_id_match,
(void *)(unsigned long)alg_id, 1);
}
EXPORT_SYMBOL_GPL(xfrm_ealg_get_byid);
struct xfrm_algo_desc *xfrm_calg_get_byid(int alg_id)
{
return xfrm_find_algo(&xfrm_calg_list, xfrm_alg_id_match,
(void *)(unsigned long)alg_id, 1);
}
EXPORT_SYMBOL_GPL(xfrm_calg_get_byid);
static int xfrm_alg_name_match(const struct xfrm_algo_desc *entry,
const void *data)
{
const char *name = data;
return name && (!strcmp(name, entry->name) ||
(entry->compat && !strcmp(name, entry->compat)));
}
struct xfrm_algo_desc *xfrm_aalg_get_byname(const char *name, int probe)
{
return xfrm_find_algo(&xfrm_aalg_list, xfrm_alg_name_match, name,
probe);
}
EXPORT_SYMBOL_GPL(xfrm_aalg_get_byname);
struct xfrm_algo_desc *xfrm_ealg_get_byname(const char *name, int probe)
{
return xfrm_find_algo(&xfrm_ealg_list, xfrm_alg_name_match, name,
probe);
}
EXPORT_SYMBOL_GPL(xfrm_ealg_get_byname);
struct xfrm_algo_desc *xfrm_calg_get_byname(const char *name, int probe)
{
return xfrm_find_algo(&xfrm_calg_list, xfrm_alg_name_match, name,
probe);
}
EXPORT_SYMBOL_GPL(xfrm_calg_get_byname);
struct xfrm_aead_name {
const char *name;
int icvbits;
};
static int xfrm_aead_name_match(const struct xfrm_algo_desc *entry,
const void *data)
{
const struct xfrm_aead_name *aead = data;
const char *name = aead->name;
return aead->icvbits == entry->uinfo.aead.icv_truncbits && name &&
!strcmp(name, entry->name);
}
struct xfrm_algo_desc *xfrm_aead_get_byname(const char *name, int icv_len, int probe)
{
struct xfrm_aead_name data = {
.name = name,
.icvbits = icv_len,
};
return xfrm_find_algo(&xfrm_aead_list, xfrm_aead_name_match, &data,
probe);
}
EXPORT_SYMBOL_GPL(xfrm_aead_get_byname);
struct xfrm_algo_desc *xfrm_aalg_get_byidx(unsigned int idx)
{
if (idx >= aalg_entries())
return NULL;
return &aalg_list[idx];
}
EXPORT_SYMBOL_GPL(xfrm_aalg_get_byidx);
struct xfrm_algo_desc *xfrm_ealg_get_byidx(unsigned int idx)
{
if (idx >= ealg_entries())
return NULL;
return &ealg_list[idx];
}
EXPORT_SYMBOL_GPL(xfrm_ealg_get_byidx);
/*
* Probe for the availability of crypto algorithms, and set the available
* flag for any algorithms found on the system. This is typically called by
* pfkey during userspace SA add, update or register.
*/
void xfrm_probe_algs(void)
{
int i, status;
BUG_ON(in_softirq());
for (i = 0; i < aalg_entries(); i++) {
status = crypto_has_ahash(aalg_list[i].name, 0, 0);
if (aalg_list[i].available != status)
aalg_list[i].available = status;
}
for (i = 0; i < ealg_entries(); i++) {
status = crypto_has_skcipher(ealg_list[i].name, 0, 0);
if (ealg_list[i].available != status)
ealg_list[i].available = status;
}
for (i = 0; i < calg_entries(); i++) {
status = crypto_has_comp(calg_list[i].name, 0,
CRYPTO_ALG_ASYNC);
if (calg_list[i].available != status)
calg_list[i].available = status;
}
}
EXPORT_SYMBOL_GPL(xfrm_probe_algs);
int xfrm_count_pfkey_auth_supported(void)
{
int i, n;
for (i = 0, n = 0; i < aalg_entries(); i++)
if (aalg_list[i].available && aalg_list[i].pfkey_supported)
n++;
return n;
}
EXPORT_SYMBOL_GPL(xfrm_count_pfkey_auth_supported);
int xfrm_count_pfkey_enc_supported(void)
{
int i, n;
for (i = 0, n = 0; i < ealg_entries(); i++)
if (ealg_list[i].available && ealg_list[i].pfkey_supported)
n++;
return n;
}
EXPORT_SYMBOL_GPL(xfrm_count_pfkey_enc_supported);
MODULE_LICENSE("GPL");