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Fix problems validating NSEC3 and wildcards.

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This commit is contained in:
Simon Kelley
2014-12-23 15:46:08 +00:00
parent cbc6524234
commit fbc5205702
1 changed files with 128 additions and 125 deletions
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253
src/dnssec.c
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@@ -615,6 +615,7 @@ static void sort_rrset(struct dns_header *header, size_t plen, u16 *rr_desc, int
Return code: Return code:
STAT_SECURE if it validates. STAT_SECURE if it validates.
STAT_SECURE_WILDCARD if it validates and is the result of wildcard expansion. STAT_SECURE_WILDCARD if it validates and is the result of wildcard expansion.
(In this case *wildcard_out points to the "body" of the wildcard within name.)
STAT_NO_SIG no RRsigs found. STAT_NO_SIG no RRsigs found.
STAT_INSECURE RRset empty. STAT_INSECURE RRset empty.
STAT_BOGUS signature is wrong, bad packet. STAT_BOGUS signature is wrong, bad packet.
@@ -625,8 +626,8 @@ static void sort_rrset(struct dns_header *header, size_t plen, u16 *rr_desc, int
name is unchanged on exit. keyname is used as workspace and trashed. name is unchanged on exit. keyname is used as workspace and trashed.
*/ */
static int validate_rrset(time_t now, struct dns_header *header, size_t plen, int class, static int validate_rrset(time_t now, struct dns_header *header, size_t plen, int class, int type,
int type, char *name, char *keyname, struct blockdata *key, int keylen, int algo_in, int keytag_in) char *name, char *keyname, char **wildcard_out, struct blockdata *key, int keylen, int algo_in, int keytag_in)
{ {
static unsigned char **rrset = NULL, **sigs = NULL; static unsigned char **rrset = NULL, **sigs = NULL;
static int rrset_sz = 0, sig_sz = 0; static int rrset_sz = 0, sig_sz = 0;
@@ -798,8 +799,16 @@ static int validate_rrset(time_t now, struct dns_header *header, size_t plen, in
{ {
int k; int k;
for (k = name_labels - labels; k != 0; k--) for (k = name_labels - labels; k != 0; k--)
while (*name_start != '.' && *name_start != 0) {
name_start++; while (*name_start != '.' && *name_start != 0)
name_start++;
if (k != 1)
name_start++;
}
if (wildcard_out)
*wildcard_out = name_start+1;
name_start--; name_start--;
*name_start = '*'; *name_start = '*';
} }
@@ -974,7 +983,7 @@ int dnssec_validate_by_ds(time_t now, struct dns_header *header, size_t plen, ch
if (recp1->addr.ds.keylen == (int)hash->digest_size && if (recp1->addr.ds.keylen == (int)hash->digest_size &&
(ds_digest = blockdata_retrieve(recp1->addr.key.keydata, recp1->addr.ds.keylen, NULL)) && (ds_digest = blockdata_retrieve(recp1->addr.key.keydata, recp1->addr.ds.keylen, NULL)) &&
memcmp(ds_digest, digest, recp1->addr.ds.keylen) == 0 && memcmp(ds_digest, digest, recp1->addr.ds.keylen) == 0 &&
validate_rrset(now, header, plen, class, T_DNSKEY, name, keyname, key, rdlen - 4, algo, keytag) == STAT_SECURE) validate_rrset(now, header, plen, class, T_DNSKEY, name, keyname, NULL, key, rdlen - 4, algo, keytag) == STAT_SECURE)
{ {
valid = 1; valid = 1;
break; break;
@@ -1443,11 +1452,88 @@ static int base32_decode(char *in, unsigned char *out)
return p - out; return p - out;
} }
static int check_nsec3_coverage(struct dns_header *header, size_t plen, int digest_len, unsigned char *digest, int type,
char *workspace1, char *workspace2, unsigned char **nsecs, int nsec_count)
{
int i, hash_len, salt_len, base32_len, rdlen;
unsigned char *p, *psave;
for (i = 0; i < nsec_count; i++)
if ((p = nsecs[i]))
{
if (!extract_name(header, plen, &p, workspace1, 1, 0) ||
!(base32_len = base32_decode(workspace1, (unsigned char *)workspace2)))
return 0;
p += 8; /* class, type, TTL */
GETSHORT(rdlen, p);
psave = p;
p += 4; /* algo, flags, iterations */
salt_len = *p++; /* salt_len */
p += salt_len; /* salt */
hash_len = *p++; /* p now points to next hashed name */
if (!CHECK_LEN(header, p, plen, hash_len))
return 0;
if (digest_len == base32_len && hash_len == base32_len)
{
int rc = memcmp(workspace2, digest, digest_len);
if (rc == 0)
{
/* We found an NSEC3 whose hashed name exactly matches the query, so
we just need to check the type map. p points to the RR data for the record. */
int offset = (type & 0xff) >> 3;
int mask = 0x80 >> (type & 0x07);
p += hash_len; /* skip next-domain hash */
rdlen -= p - psave;
if (!CHECK_LEN(header, p, plen, rdlen))
return 0;
while (rdlen >= 2)
{
if (p[0] == type >> 8)
{
/* Does the NSEC3 say our type exists? */
if (offset < p[1] && (p[offset+2] & mask) != 0)
return STAT_BOGUS;
break; /* finshed checking */
}
rdlen -= p[1];
p += p[1];
}
return 1;
}
else if (rc <= 0)
{
/* Normal case, hash falls between NSEC3 name-hash and next domain name-hash,
wrap around case, name-hash falls between NSEC3 name-hash and end */
if (memcmp(p, digest, digest_len) > 0 || memcmp(workspace2, p, digest_len) > 0)
return 1;
}
else
{
/* wrap around case, name falls between start and next domain name */
if (memcmp(workspace2, p, digest_len) > 0 && memcmp(p, digest, digest_len) > 0)
return 1;
}
}
}
return 0;
}
static int prove_non_existence_nsec3(struct dns_header *header, size_t plen, unsigned char **nsecs, int nsec_count, static int prove_non_existence_nsec3(struct dns_header *header, size_t plen, unsigned char **nsecs, int nsec_count,
char *workspace1, char *workspace2, char *name, int type) char *workspace1, char *workspace2, char *name, int type, char *wildname)
{ {
unsigned char *salt, *p, *digest; unsigned char *salt, *p, *digest;
int digest_len, i, iterations, salt_len, hash_len, base32_len, algo = 0; int digest_len, i, iterations, salt_len, base32_len, algo = 0;
struct nettle_hash const *hash; struct nettle_hash const *hash;
char *closest_encloser, *next_closest, *wildcard; char *closest_encloser, *next_closest, *wildcard;
@@ -1520,7 +1606,14 @@ static int prove_non_existence_nsec3(struct dns_header *header, size_t plen, uns
if (!(hash = hash_find("sha1"))) if (!(hash = hash_find("sha1")))
return STAT_BOGUS; return STAT_BOGUS;
/* Now, we need the "closest encloser NSEC3" */ if ((digest_len = hash_name(name, &digest, hash, salt, salt_len, iterations)) == 0)
return STAT_BOGUS;
if (check_nsec3_coverage(header, plen, digest_len, digest, type, workspace1, workspace2, nsecs, nsec_count))
return STAT_SECURE;
/* Can't find an NSEC3 which covers the name directly, we need the "closest encloser NSEC3"
or an answer inferred from a wildcard record. */
closest_encloser = name; closest_encloser = name;
next_closest = NULL; next_closest = NULL;
@@ -1529,6 +1622,9 @@ static int prove_non_existence_nsec3(struct dns_header *header, size_t plen, uns
if (*closest_encloser == '.') if (*closest_encloser == '.')
closest_encloser++; closest_encloser++;
if (wildname && hostname_isequal(closest_encloser, wildname))
break;
if ((digest_len = hash_name(closest_encloser, &digest, hash, salt, salt_len, iterations)) == 0) if ((digest_len = hash_name(closest_encloser, &digest, hash, salt, salt_len, iterations)) == 0)
return STAT_BOGUS; return STAT_BOGUS;
@@ -1551,127 +1647,33 @@ static int prove_non_existence_nsec3(struct dns_header *header, size_t plen, uns
} }
while ((closest_encloser = strchr(closest_encloser, '.'))); while ((closest_encloser = strchr(closest_encloser, '.')));
/* No usable NSEC3s */ if (!closest_encloser)
if (i == nsec_count)
return STAT_BOGUS; return STAT_BOGUS;
if (!next_closest)
{
/* We found an NSEC3 whose hashed name exactly matches the query, so
Now we just need to check the type map. p points to the RR data for the record. */
int rdlen;
unsigned char *psave;
int offset = (type & 0xff) >> 3;
int mask = 0x80 >> (type & 0x07);
p += 8; /* class, type, TTL */
GETSHORT(rdlen, p);
psave = p;
p += 5 + salt_len; /* algo, flags, iterations, salt_len, salt */
hash_len = *p++;
if (!CHECK_LEN(header, p, plen, hash_len))
return STAT_BOGUS; /* bad packet */
p += hash_len;
rdlen -= p - psave;
while (rdlen >= 2)
{
if (!CHECK_LEN(header, p, plen, rdlen))
return STAT_BOGUS;
if (p[0] == type >> 8)
{
/* Does the NSEC3 say our type exists? */
if (offset < p[1] && (p[offset+2] & mask) != 0)
return STAT_BOGUS;
break; /* finshed checking */
}
rdlen -= p[1];
p += p[1];
}
return STAT_SECURE;
}
/* Look for NSEC3 that proves the non-existence of the next-closest encloser */ /* Look for NSEC3 that proves the non-existence of the next-closest encloser */
if ((digest_len = hash_name(next_closest, &digest, hash, salt, salt_len, iterations)) == 0) if ((digest_len = hash_name(next_closest, &digest, hash, salt, salt_len, iterations)) == 0)
return STAT_BOGUS; return STAT_BOGUS;
for (i = 0; i < nsec_count; i++) if (!check_nsec3_coverage(header, plen, digest_len, digest, type, workspace1, workspace2, nsecs, nsec_count))
if ((p = nsecs[i])) return STAT_BOGUS;
{
if (!extract_name(header, plen, &p, workspace1, 1, 0) ||
!(base32_len = base32_decode(workspace1, (unsigned char *)workspace2)))
return STAT_BOGUS;
p += 15 + salt_len; /* class, type, TTL, rdlen, algo, flags, iterations, salt_len, salt */
hash_len = *p++; /* p now points to next hashed name */
if (!CHECK_LEN(header, p, plen, hash_len))
return STAT_BOGUS;
if (digest_len == base32_len && hash_len == base32_len)
{
if (memcmp(workspace2, digest, digest_len) <= 0)
{
/* Normal case, hash falls between NSEC3 name-hash and next domain name-hash,
wrap around case, name-hash falls between NSEC3 name-hash and end */
if (memcmp(p, digest, digest_len) > 0 || memcmp(workspace2, p, digest_len) > 0)
return STAT_SECURE;
}
else
{
/* wrap around case, name falls between start and next domain name */
if (memcmp(workspace2, p, digest_len) > 0 && memcmp(p, digest, digest_len) > 0)
return STAT_SECURE;
}
}
}
/* Finally, check that there's no seat of wildcard synthesis */ /* Finally, check that there's no seat of wildcard synthesis */
if (!(wildcard = strchr(next_closest, '.')) || wildcard == next_closest) if (!wildname)
return STAT_BOGUS; {
if (!(wildcard = strchr(next_closest, '.')) || wildcard == next_closest)
return STAT_BOGUS;
wildcard--;
*wildcard = '*';
if ((digest_len = hash_name(wildcard, &digest, hash, salt, salt_len, iterations)) == 0)
return STAT_BOGUS;
if (!check_nsec3_coverage(header, plen, digest_len, digest, type, workspace1, workspace2, nsecs, nsec_count))
return STAT_BOGUS;
}
wildcard--; return STAT_SECURE;
*wildcard = '*';
if ((digest_len = hash_name(wildcard, &digest, hash, salt, salt_len, iterations)) == 0)
return STAT_BOGUS;
for (i = 0; i < nsec_count; i++)
if ((p = nsecs[i]))
{
if (!extract_name(header, plen, &p, workspace1, 1, 0) ||
!(base32_len = base32_decode(workspace1, (unsigned char *)workspace2)))
return STAT_BOGUS;
p += 15 + salt_len; /* class, type, TTL, rdlen, algo, flags, iterations, salt_len, salt */
hash_len = *p++; /* p now points to next hashed name */
if (!CHECK_LEN(header, p, plen, hash_len))
return STAT_BOGUS;
if (digest_len == base32_len && hash_len == base32_len)
{
if (memcmp(workspace2, digest, digest_len) <= 0)
{
/* Normal case, hash falls between NSEC3 name-hash and next domain name-hash,
wrap around case, name-hash falls between NSEC3 name-hash and end */
if (memcmp(p, digest, digest_len) > 0 || memcmp(workspace2, p, digest_len) > 0)
return STAT_SECURE;
}
else
{
/* wrap around case, name falls between start and next domain name */
if (memcmp(workspace2, p, digest_len) > 0 && memcmp(p, digest, digest_len) > 0)
return STAT_SECURE;
}
}
}
return STAT_BOGUS;
} }
/* Validate all the RRsets in the answer and authority sections of the reply (4035:3.2.3) */ /* Validate all the RRsets in the answer and authority sections of the reply (4035:3.2.3) */
@@ -1792,8 +1794,9 @@ int dnssec_validate_reply(time_t now, struct dns_header *header, size_t plen, ch
struct all_addr a; struct all_addr a;
struct blockdata *key; struct blockdata *key;
struct crec *crecp; struct crec *crecp;
char *wildname;
rc = validate_rrset(now, header, plen, class1, type1, name, keyname, NULL, 0, 0, 0);
rc = validate_rrset(now, header, plen, class1, type1, name, keyname, &wildname, NULL, 0, 0, 0);
if (rc == STAT_SECURE_WILDCARD) if (rc == STAT_SECURE_WILDCARD)
{ {
@@ -1807,7 +1810,7 @@ int dnssec_validate_reply(time_t now, struct dns_header *header, size_t plen, ch
if (nsec_type == T_NSEC) if (nsec_type == T_NSEC)
rc = prove_non_existence_nsec(header, plen, nsecs, nsec_count, daemon->workspacename, keyname, name, type1); rc = prove_non_existence_nsec(header, plen, nsecs, nsec_count, daemon->workspacename, keyname, name, type1);
else else
rc = prove_non_existence_nsec3(header, plen, nsecs, nsec_count, daemon->workspacename, keyname, name, type1); rc = prove_non_existence_nsec3(header, plen, nsecs, nsec_count, daemon->workspacename, keyname, name, type1, wildname);
if (rc != STAT_SECURE) if (rc != STAT_SECURE)
return rc; return rc;
@@ -1933,7 +1936,7 @@ int dnssec_validate_reply(time_t now, struct dns_header *header, size_t plen, ch
if (nsec_type == T_NSEC) if (nsec_type == T_NSEC)
return prove_non_existence_nsec(header, plen, nsecs, nsec_count, daemon->workspacename, keyname, name, qtype); return prove_non_existence_nsec(header, plen, nsecs, nsec_count, daemon->workspacename, keyname, name, qtype);
else else
return prove_non_existence_nsec3(header, plen, nsecs, nsec_count, daemon->workspacename, keyname, name, qtype); return prove_non_existence_nsec3(header, plen, nsecs, nsec_count, daemon->workspacename, keyname, name, qtype, NULL);
} }
/* Chase the CNAME chain in the packet until the first record which _doesn't validate. /* Chase the CNAME chain in the packet until the first record which _doesn't validate.
@@ -1980,7 +1983,7 @@ int dnssec_chase_cname(time_t now, struct dns_header *header, size_t plen, char
return STAT_INSECURE; return STAT_INSECURE;
/* validate CNAME chain, return if insecure or need more data */ /* validate CNAME chain, return if insecure or need more data */
rc = validate_rrset(now, header, plen, class, type, name, keyname, NULL, 0, 0, 0); rc = validate_rrset(now, header, plen, class, type, name, keyname, NULL, NULL, 0, 0, 0);
if (rc != STAT_SECURE) if (rc != STAT_SECURE)
{ {
if (rc == STAT_NO_SIG) if (rc == STAT_NO_SIG)