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authorNeels Hofmeyr <nhofmeyr@sysmocom.de>2017-03-13 17:27:17 +0100
committerHarald Welte <laforge@gnumonks.org>2017-03-15 12:46:08 +0000
commitbb6f7b7becb138da78c0f677d6340065f91d0067 (patch)
tree4b225228eaa90bbd9400e4d24dd045be4887f86e /src
parent82c9a0ec198d83452a4232f288e230b59fa1eaf8 (diff)
osmo_auth_gen_vec: UMTS auth: fix SQN as SEQ || IND
So far we incremented SQN by 1, which doesn't match the procedures described in 3GPP TS 33.102. An IND (index) denotes a non-significant part of SQN, and the significant SEQ part needs to be incremented. In OsmoHLR we furthermore want to use the "exception" suggested in annex C.3.4, so that each HLR's client has a fixed IND index. In other words, we will not assign IND cyclically, but keep IND unchanged per auth vector consumer. Add 'ind_bitlen' and 'ind' to the osmo_sub_auth_data.u.umts structure and increment SQN accordingly. Add a comment explaining the details. Because 'ind_bitlen' is still passed as zero, the milenage_test does not change its behavior, which is a feature I want to clearly show in this patch. The test will be expanded for the newly implemented SQN scheme in a subsequent patch. Adjust osmo-auc-gen.c to still show the right SQN and SQN.MS -- because it is passing ind_bitlen == 0, osmo-auc-gen can rely on single increments and know SQN.MS is sqn - 1. Note that osmo-auc-gen_test output remains unchanged. Related: OS#1968 Change-Id: Ibc97e1736a797ffcbf8c1f7d41c5c4518f4e41bf
Diffstat (limited to 'src')
-rw-r--r--src/gsm/auth_milenage.c67
1 files changed, 66 insertions, 1 deletions
diff --git a/src/gsm/auth_milenage.c b/src/gsm/auth_milenage.c
index e1807621..f151c5e8 100644
--- a/src/gsm/auth_milenage.c
+++ b/src/gsm/auth_milenage.c
@@ -32,10 +32,73 @@ static int milenage_gen_vec(struct osmo_auth_vector *vec,
size_t res_len = sizeof(vec->res);
uint64_t next_sqn;
uint8_t sqn[6];
+ uint64_t ind_mask;
+ uint64_t seq_1;
int rc;
+ /* Determine next SQN, according to 3GPP TS 33.102:
+ * SQN consists of SEQ and a lower significant part of IND bits:
+ *
+ * |----------SEQ------------|
+ * |------------------------SQN-----------|
+ * |-----IND----|
+ *
+ * The IND part is used as "slots": e.g. a given HLR client will always
+ * get the same IND part, called ind here, with incrementing SEQ. In
+ * the USIM, each IND slot enforces that its SEQ are used in ascending
+ * order -- as long as that constraint is satisfied, the SQN may jump
+ * forwards and backwards. For example, for ind_bitlen == 5, asking the
+ * USIM for SQN = 32, 64, 33 is allowed, because 32 and 64 are
+ * SEQ || (ind == 0), and though 33 is below 64, it is ind == 1 and
+ * allowed. Not allowed would be 32, 96, 64, because 64 would go
+ * backwards after 96, both being ind == 0.
+ *
+ * From the last used SQN, we want to increment SEQ + 1, and then pick
+ * the matching IND part.
+ *
+ * IND size is suggested in TS 33.102 as 5 bits. SQN is 48 bits long.
+ * If ind_bitlen is passed too large here, the algorithms will break
+ * down. But at which point should we return an error? A sane limit
+ * seems to be ind_bitlen == 10, but to protect against failure,
+ * limiting ind_bitlen to 28 is enough, 28 being the number of bits
+ * suggested for the delta in 33.102, which is discussed to still
+ * require 2^15 > 32000 authentications to wrap the SQN back to the
+ * start.
+ *
+ * Note that if a caller with ind == 1 generates N vectors, the SQN
+ * stored after this will reflect SEQ + N. If then another caller with
+ * ind == 2 generates another N vectors, this will then use SEQ + N
+ * onwards and end up with SEQ + N + N. In other words, most of each
+ * SEQ's IND slots will remain unused. When looking at SQN being 48
+ * bits wide, after dropping ind_bitlen (say 5) from it, we will still
+ * have a sequence range of 2^43 = 8.8e12, eight trillion sequences,
+ * which is large enough to not bother further. With the maximum
+ * ind_bitlen of 28 enforced below, we still get more than 1 million
+ * sequences, which is also sufficiently large.
+ *
+ * An ind_bitlen of zero may be passed from legacy callers that are not
+ * aware of the IND extension. For these, below algorithm works out as
+ * before, simply incrementing SQN by 1.
+ *
+ * This is also a mechanism for tools like the osmo-auc-gen to directly
+ * request a given SQN to be used. With ind_bitlen == 0 the caller can
+ * be sure that this code will increment SQN by exactly one before
+ * generating a tuple, thus a caller would simply pass
+ * { .ind_bitlen = 0, .ind = 0, .sqn = (desired_sqn - 1) }
+ */
+
+ if (aud->u.umts.ind_bitlen > 28)
+ return -2;
+
+ seq_1 = 1LL << aud->u.umts.ind_bitlen;
+ ind_mask = ~(seq_1 - 1);
+
+ /* the ind index must not affect the SEQ part */
+ if (aud->u.umts.ind > seq_1)
+ return -3;
+
/* keep the incremented SQN local until gsm_milenage() succeeded. */
- next_sqn = aud->u.umts.sqn + 1;
+ next_sqn = ((aud->u.umts.sqn + seq_1) & ind_mask) + aud->u.umts.ind;
osmo_store64be_ext(next_sqn, sqn, 6);
milenage_generate(aud->u.umts.opc, aud->u.umts.amf, aud->u.umts.k,
@@ -78,6 +141,8 @@ static int milenage_gen_vec_auts(struct osmo_auth_vector *vec,
if (rc < 0)
return rc;
+ /* Update our "largest used SQN" from the USIM -- milenage_gen_vec()
+ * below will increment SQN. */
aud->u.umts.sqn = osmo_load64be_ext(sqn_out, 6) >> 16;
return milenage_gen_vec(vec, aud, _rand);