freebsd-skq/contrib/unbound/validator/val_nsec3.c
Dag-Erling Smørgrav ff8258499c Upgrade to Unbound 1.5.1. Almost all our local changes to date have been
adopted upstream, greatly reducing the diff.
2015-01-03 02:40:51 +00:00

1489 lines
46 KiB
C

/*
* validator/val_nsec3.c - validator NSEC3 denial of existance functions.
*
* Copyright (c) 2007, NLnet Labs. All rights reserved.
*
* This software is open source.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* Neither the name of the NLNET LABS nor the names of its contributors may
* be used to endorse or promote products derived from this software without
* specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
* TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/**
* \file
*
* This file contains helper functions for the validator module.
* The functions help with NSEC3 checking, the different NSEC3 proofs
* for denial of existance, and proofs for presence of types.
*/
#include "config.h"
#include <ctype.h>
#ifdef HAVE_OPENSSL_SSL_H
#include "openssl/ssl.h"
#endif
#ifdef HAVE_NSS
/* nss3 */
#include "sechash.h"
#endif
#include "validator/val_nsec3.h"
#include "validator/validator.h"
#include "validator/val_kentry.h"
#include "services/cache/rrset.h"
#include "util/regional.h"
#include "util/rbtree.h"
#include "util/module.h"
#include "util/net_help.h"
#include "util/data/packed_rrset.h"
#include "util/data/dname.h"
#include "util/data/msgreply.h"
/* we include nsec.h for the bitmap_has_type function */
#include "validator/val_nsec.h"
#include "ldns/sbuffer.h"
/**
* This function we get from ldns-compat or from base system
* it returns the number of data bytes stored at the target, or <0 on error.
*/
int sldns_b32_ntop_extended_hex(uint8_t const *src, size_t srclength,
char *target, size_t targsize);
/**
* This function we get from ldns-compat or from base system
* it returns the number of data bytes stored at the target, or <0 on error.
*/
int sldns_b32_pton_extended_hex(char const *src, size_t hashed_owner_str_len,
uint8_t *target, size_t targsize);
/**
* Closest encloser (ce) proof results
* Contains the ce and the next-closer (nc) proof.
*/
struct ce_response {
/** the closest encloser name */
uint8_t* ce;
/** length of ce */
size_t ce_len;
/** NSEC3 record that proved ce. rrset */
struct ub_packed_rrset_key* ce_rrset;
/** NSEC3 record that proved ce. rr number */
int ce_rr;
/** NSEC3 record that proved nc. rrset */
struct ub_packed_rrset_key* nc_rrset;
/** NSEC3 record that proved nc. rr*/
int nc_rr;
};
/**
* Filter conditions for NSEC3 proof
* Used to iterate over the applicable NSEC3 RRs.
*/
struct nsec3_filter {
/** Zone name, only NSEC3 records for this zone are considered */
uint8_t* zone;
/** length of the zonename */
size_t zone_len;
/** the list of NSEC3s to filter; array */
struct ub_packed_rrset_key** list;
/** number of rrsets in list */
size_t num;
/** class of records for the NSEC3, only this class applies */
uint16_t fclass;
};
/** return number of rrs in an rrset */
static size_t
rrset_get_count(struct ub_packed_rrset_key* rrset)
{
struct packed_rrset_data* d = (struct packed_rrset_data*)
rrset->entry.data;
if(!d) return 0;
return d->count;
}
/** return if nsec3 RR has unknown flags */
static int
nsec3_unknown_flags(struct ub_packed_rrset_key* rrset, int r)
{
struct packed_rrset_data* d = (struct packed_rrset_data*)
rrset->entry.data;
log_assert(d && r < (int)d->count);
if(d->rr_len[r] < 2+2)
return 0; /* malformed */
return (int)(d->rr_data[r][2+1] & NSEC3_UNKNOWN_FLAGS);
}
int
nsec3_has_optout(struct ub_packed_rrset_key* rrset, int r)
{
struct packed_rrset_data* d = (struct packed_rrset_data*)
rrset->entry.data;
log_assert(d && r < (int)d->count);
if(d->rr_len[r] < 2+2)
return 0; /* malformed */
return (int)(d->rr_data[r][2+1] & NSEC3_OPTOUT);
}
/** return nsec3 RR algorithm */
static int
nsec3_get_algo(struct ub_packed_rrset_key* rrset, int r)
{
struct packed_rrset_data* d = (struct packed_rrset_data*)
rrset->entry.data;
log_assert(d && r < (int)d->count);
if(d->rr_len[r] < 2+1)
return 0; /* malformed */
return (int)(d->rr_data[r][2+0]);
}
/** return if nsec3 RR has known algorithm */
static int
nsec3_known_algo(struct ub_packed_rrset_key* rrset, int r)
{
struct packed_rrset_data* d = (struct packed_rrset_data*)
rrset->entry.data;
log_assert(d && r < (int)d->count);
if(d->rr_len[r] < 2+1)
return 0; /* malformed */
switch(d->rr_data[r][2+0]) {
case NSEC3_HASH_SHA1:
return 1;
}
return 0;
}
/** return nsec3 RR iteration count */
static size_t
nsec3_get_iter(struct ub_packed_rrset_key* rrset, int r)
{
uint16_t i;
struct packed_rrset_data* d = (struct packed_rrset_data*)
rrset->entry.data;
log_assert(d && r < (int)d->count);
if(d->rr_len[r] < 2+4)
return 0; /* malformed */
memmove(&i, d->rr_data[r]+2+2, sizeof(i));
i = ntohs(i);
return (size_t)i;
}
/** return nsec3 RR salt */
static int
nsec3_get_salt(struct ub_packed_rrset_key* rrset, int r,
uint8_t** salt, size_t* saltlen)
{
struct packed_rrset_data* d = (struct packed_rrset_data*)
rrset->entry.data;
log_assert(d && r < (int)d->count);
if(d->rr_len[r] < 2+5) {
*salt = 0;
*saltlen = 0;
return 0; /* malformed */
}
*saltlen = (size_t)d->rr_data[r][2+4];
if(d->rr_len[r] < 2+5+(size_t)*saltlen) {
*salt = 0;
*saltlen = 0;
return 0; /* malformed */
}
*salt = d->rr_data[r]+2+5;
return 1;
}
int nsec3_get_params(struct ub_packed_rrset_key* rrset, int r,
int* algo, size_t* iter, uint8_t** salt, size_t* saltlen)
{
if(!nsec3_known_algo(rrset, r) || nsec3_unknown_flags(rrset, r))
return 0;
if(!nsec3_get_salt(rrset, r, salt, saltlen))
return 0;
*algo = nsec3_get_algo(rrset, r);
*iter = nsec3_get_iter(rrset, r);
return 1;
}
int
nsec3_get_nextowner(struct ub_packed_rrset_key* rrset, int r,
uint8_t** next, size_t* nextlen)
{
size_t saltlen;
struct packed_rrset_data* d = (struct packed_rrset_data*)
rrset->entry.data;
log_assert(d && r < (int)d->count);
if(d->rr_len[r] < 2+5) {
*next = 0;
*nextlen = 0;
return 0; /* malformed */
}
saltlen = (size_t)d->rr_data[r][2+4];
if(d->rr_len[r] < 2+5+saltlen+1) {
*next = 0;
*nextlen = 0;
return 0; /* malformed */
}
*nextlen = (size_t)d->rr_data[r][2+5+saltlen];
if(d->rr_len[r] < 2+5+saltlen+1+*nextlen) {
*next = 0;
*nextlen = 0;
return 0; /* malformed */
}
*next = d->rr_data[r]+2+5+saltlen+1;
return 1;
}
size_t nsec3_hash_to_b32(uint8_t* hash, size_t hashlen, uint8_t* zone,
size_t zonelen, uint8_t* buf, size_t max)
{
/* write b32 of name, leave one for length */
int ret;
if(max < hashlen*2+1) /* quick approx of b32, as if hexb16 */
return 0;
ret = sldns_b32_ntop_extended_hex(hash, hashlen, (char*)buf+1, max-1);
if(ret < 1)
return 0;
buf[0] = (uint8_t)ret; /* length of b32 label */
ret++;
if(max - ret < zonelen)
return 0;
memmove(buf+ret, zone, zonelen);
return zonelen+(size_t)ret;
}
size_t nsec3_get_nextowner_b32(struct ub_packed_rrset_key* rrset, int r,
uint8_t* buf, size_t max)
{
uint8_t* nm, *zone;
size_t nmlen, zonelen;
if(!nsec3_get_nextowner(rrset, r, &nm, &nmlen))
return 0;
/* append zone name; the owner name must be <b32>.zone */
zone = rrset->rk.dname;
zonelen = rrset->rk.dname_len;
dname_remove_label(&zone, &zonelen);
return nsec3_hash_to_b32(nm, nmlen, zone, zonelen, buf, max);
}
int
nsec3_has_type(struct ub_packed_rrset_key* rrset, int r, uint16_t type)
{
uint8_t* bitmap;
size_t bitlen, skiplen;
struct packed_rrset_data* d = (struct packed_rrset_data*)
rrset->entry.data;
log_assert(d && r < (int)d->count);
skiplen = 2+4;
/* skip salt */
if(d->rr_len[r] < skiplen+1)
return 0; /* malformed, too short */
skiplen += 1+(size_t)d->rr_data[r][skiplen];
/* skip next hashed owner */
if(d->rr_len[r] < skiplen+1)
return 0; /* malformed, too short */
skiplen += 1+(size_t)d->rr_data[r][skiplen];
if(d->rr_len[r] < skiplen)
return 0; /* malformed, too short */
bitlen = d->rr_len[r] - skiplen;
bitmap = d->rr_data[r]+skiplen;
return nsecbitmap_has_type_rdata(bitmap, bitlen, type);
}
/**
* Iterate through NSEC3 list, per RR
* This routine gives the next RR in the list (or sets rrset null).
* Usage:
*
* size_t rrsetnum;
* int rrnum;
* struct ub_packed_rrset_key* rrset;
* for(rrset=filter_first(filter, &rrsetnum, &rrnum); rrset;
* rrset=filter_next(filter, &rrsetnum, &rrnum))
* do_stuff;
*
* Also filters out
* o unknown flag NSEC3s
* o unknown algorithm NSEC3s.
* @param filter: nsec3 filter structure.
* @param rrsetnum: in/out rrset number to look at.
* @param rrnum: in/out rr number in rrset to look at.
* @returns ptr to the next rrset (or NULL at end).
*/
static struct ub_packed_rrset_key*
filter_next(struct nsec3_filter* filter, size_t* rrsetnum, int* rrnum)
{
size_t i;
int r;
uint8_t* nm;
size_t nmlen;
if(!filter->zone) /* empty list */
return NULL;
for(i=*rrsetnum; i<filter->num; i++) {
/* see if RRset qualifies */
if(ntohs(filter->list[i]->rk.type) != LDNS_RR_TYPE_NSEC3 ||
ntohs(filter->list[i]->rk.rrset_class) !=
filter->fclass)
continue;
/* check RRset zone */
nm = filter->list[i]->rk.dname;
nmlen = filter->list[i]->rk.dname_len;
dname_remove_label(&nm, &nmlen);
if(query_dname_compare(nm, filter->zone) != 0)
continue;
if(i == *rrsetnum)
r = (*rrnum) + 1; /* continue at next RR */
else r = 0; /* new RRset start at first RR */
for(; r < (int)rrset_get_count(filter->list[i]); r++) {
/* skip unknown flags, algo */
if(nsec3_unknown_flags(filter->list[i], r) ||
!nsec3_known_algo(filter->list[i], r))
continue;
/* this one is a good target */
*rrsetnum = i;
*rrnum = r;
return filter->list[i];
}
}
return NULL;
}
/**
* Start iterating over NSEC3 records.
* @param filter: the filter structure, must have been filter_init-ed.
* @param rrsetnum: can be undefined on call, inited.
* @param rrnum: can be undefined on call, inited.
* @return first rrset of an NSEC3, together with rrnum this points to
* the first RR to examine. Is NULL on empty list.
*/
static struct ub_packed_rrset_key*
filter_first(struct nsec3_filter* filter, size_t* rrsetnum, int* rrnum)
{
*rrsetnum = 0;
*rrnum = -1;
return filter_next(filter, rrsetnum, rrnum);
}
/** see if at least one RR is known (flags, algo) */
static int
nsec3_rrset_has_known(struct ub_packed_rrset_key* s)
{
int r;
for(r=0; r < (int)rrset_get_count(s); r++) {
if(!nsec3_unknown_flags(s, r) && nsec3_known_algo(s, r))
return 1;
}
return 0;
}
/**
* Initialize the filter structure.
* Finds the zone by looking at available NSEC3 records and best match.
* (skips the unknown flag and unknown algo NSEC3s).
*
* @param filter: nsec3 filter structure.
* @param list: list of rrsets, an array of them.
* @param num: number of rrsets in list.
* @param qinfo:
* query name to match a zone for.
* query type (if DS a higher zone must be chosen)
* qclass, to filter NSEC3s with.
*/
static void
filter_init(struct nsec3_filter* filter, struct ub_packed_rrset_key** list,
size_t num, struct query_info* qinfo)
{
size_t i;
uint8_t* nm;
size_t nmlen;
filter->zone = NULL;
filter->zone_len = 0;
filter->list = list;
filter->num = num;
filter->fclass = qinfo->qclass;
for(i=0; i<num; i++) {
/* ignore other stuff in the list */
if(ntohs(list[i]->rk.type) != LDNS_RR_TYPE_NSEC3 ||
ntohs(list[i]->rk.rrset_class) != qinfo->qclass)
continue;
/* skip unknown flags, algo */
if(!nsec3_rrset_has_known(list[i]))
continue;
/* since NSEC3s are base32.zonename, we can find the zone
* name by stripping off the first label of the record */
nm = list[i]->rk.dname;
nmlen = list[i]->rk.dname_len;
dname_remove_label(&nm, &nmlen);
/* if we find a domain that can prove about the qname,
* and if this domain is closer to the qname */
if(dname_subdomain_c(qinfo->qname, nm) && (!filter->zone ||
dname_subdomain_c(nm, filter->zone))) {
/* for a type DS do not accept a zone equal to qname*/
if(qinfo->qtype == LDNS_RR_TYPE_DS &&
query_dname_compare(qinfo->qname, nm) == 0 &&
!dname_is_root(qinfo->qname))
continue;
filter->zone = nm;
filter->zone_len = nmlen;
}
}
}
/**
* Find max iteration count using config settings and key size
* @param ve: validator environment with iteration count config settings.
* @param bits: key size
* @return max iteration count
*/
static size_t
get_max_iter(struct val_env* ve, size_t bits)
{
int i;
log_assert(ve->nsec3_keyiter_count > 0);
/* round up to nearest config keysize, linear search, keep it small */
for(i=0; i<ve->nsec3_keyiter_count; i++) {
if(bits <= ve->nsec3_keysize[i])
return ve->nsec3_maxiter[i];
}
/* else, use value for biggest key */
return ve->nsec3_maxiter[ve->nsec3_keyiter_count-1];
}
/**
* Determine if any of the NSEC3 rrs iteration count is too high, from key.
* @param ve: validator environment with iteration count config settings.
* @param filter: what NSEC3s to loop over.
* @param kkey: key entry used for verification; used for iteration counts.
* @return 1 if some nsec3s are above the max iteration count.
*/
static int
nsec3_iteration_count_high(struct val_env* ve, struct nsec3_filter* filter,
struct key_entry_key* kkey)
{
size_t rrsetnum;
int rrnum;
struct ub_packed_rrset_key* rrset;
/* first determine the max number of iterations */
size_t bits = key_entry_keysize(kkey);
size_t max_iter = get_max_iter(ve, bits);
verbose(VERB_ALGO, "nsec3: keysize %d bits, max iterations %d",
(int)bits, (int)max_iter);
for(rrset=filter_first(filter, &rrsetnum, &rrnum); rrset;
rrset=filter_next(filter, &rrsetnum, &rrnum)) {
if(nsec3_get_iter(rrset, rrnum) > max_iter)
return 1;
}
return 0;
}
/* nsec3_cache_compare for rbtree */
int
nsec3_hash_cmp(const void* c1, const void* c2)
{
struct nsec3_cached_hash* h1 = (struct nsec3_cached_hash*)c1;
struct nsec3_cached_hash* h2 = (struct nsec3_cached_hash*)c2;
uint8_t* s1, *s2;
size_t s1len, s2len;
int c = query_dname_compare(h1->dname, h2->dname);
if(c != 0)
return c;
/* compare parameters */
/* if both malformed, its equal, robustness */
if(nsec3_get_algo(h1->nsec3, h1->rr) !=
nsec3_get_algo(h2->nsec3, h2->rr)) {
if(nsec3_get_algo(h1->nsec3, h1->rr) <
nsec3_get_algo(h2->nsec3, h2->rr))
return -1;
return 1;
}
if(nsec3_get_iter(h1->nsec3, h1->rr) !=
nsec3_get_iter(h2->nsec3, h2->rr)) {
if(nsec3_get_iter(h1->nsec3, h1->rr) <
nsec3_get_iter(h2->nsec3, h2->rr))
return -1;
return 1;
}
(void)nsec3_get_salt(h1->nsec3, h1->rr, &s1, &s1len);
(void)nsec3_get_salt(h2->nsec3, h2->rr, &s2, &s2len);
if(s1len != s2len) {
if(s1len < s2len)
return -1;
return 1;
}
return memcmp(s1, s2, s1len);
}
size_t
nsec3_get_hashed(sldns_buffer* buf, uint8_t* nm, size_t nmlen, int algo,
size_t iter, uint8_t* salt, size_t saltlen, uint8_t* res, size_t max)
{
size_t i, hash_len;
/* prepare buffer for first iteration */
sldns_buffer_clear(buf);
sldns_buffer_write(buf, nm, nmlen);
query_dname_tolower(sldns_buffer_begin(buf));
sldns_buffer_write(buf, salt, saltlen);
sldns_buffer_flip(buf);
switch(algo) {
#if defined(HAVE_EVP_SHA1) || defined(HAVE_NSS)
case NSEC3_HASH_SHA1:
#ifdef HAVE_SSL
hash_len = SHA_DIGEST_LENGTH;
#else
hash_len = SHA1_LENGTH;
#endif
if(hash_len > max)
return 0;
# ifdef HAVE_SSL
(void)SHA1((unsigned char*)sldns_buffer_begin(buf),
(unsigned long)sldns_buffer_limit(buf),
(unsigned char*)res);
# else
(void)HASH_HashBuf(HASH_AlgSHA1, (unsigned char*)res,
(unsigned char*)sldns_buffer_begin(buf),
(unsigned long)sldns_buffer_limit(buf));
# endif
for(i=0; i<iter; i++) {
sldns_buffer_clear(buf);
sldns_buffer_write(buf, res, hash_len);
sldns_buffer_write(buf, salt, saltlen);
sldns_buffer_flip(buf);
# ifdef HAVE_SSL
(void)SHA1(
(unsigned char*)sldns_buffer_begin(buf),
(unsigned long)sldns_buffer_limit(buf),
(unsigned char*)res);
# else
(void)HASH_HashBuf(HASH_AlgSHA1,
(unsigned char*)res,
(unsigned char*)sldns_buffer_begin(buf),
(unsigned long)sldns_buffer_limit(buf));
# endif
}
break;
#endif /* HAVE_EVP_SHA1 or NSS */
default:
log_err("nsec3 hash of unknown algo %d", algo);
return 0;
}
return hash_len;
}
/** perform hash of name */
static int
nsec3_calc_hash(struct regional* region, sldns_buffer* buf,
struct nsec3_cached_hash* c)
{
int algo = nsec3_get_algo(c->nsec3, c->rr);
size_t iter = nsec3_get_iter(c->nsec3, c->rr);
uint8_t* salt;
size_t saltlen, i;
if(!nsec3_get_salt(c->nsec3, c->rr, &salt, &saltlen))
return -1;
/* prepare buffer for first iteration */
sldns_buffer_clear(buf);
sldns_buffer_write(buf, c->dname, c->dname_len);
query_dname_tolower(sldns_buffer_begin(buf));
sldns_buffer_write(buf, salt, saltlen);
sldns_buffer_flip(buf);
switch(algo) {
#if defined(HAVE_EVP_SHA1) || defined(HAVE_NSS)
case NSEC3_HASH_SHA1:
#ifdef HAVE_SSL
c->hash_len = SHA_DIGEST_LENGTH;
#else
c->hash_len = SHA1_LENGTH;
#endif
c->hash = (uint8_t*)regional_alloc(region,
c->hash_len);
if(!c->hash)
return 0;
# ifdef HAVE_SSL
(void)SHA1((unsigned char*)sldns_buffer_begin(buf),
(unsigned long)sldns_buffer_limit(buf),
(unsigned char*)c->hash);
# else
(void)HASH_HashBuf(HASH_AlgSHA1,
(unsigned char*)c->hash,
(unsigned char*)sldns_buffer_begin(buf),
(unsigned long)sldns_buffer_limit(buf));
# endif
for(i=0; i<iter; i++) {
sldns_buffer_clear(buf);
sldns_buffer_write(buf, c->hash, c->hash_len);
sldns_buffer_write(buf, salt, saltlen);
sldns_buffer_flip(buf);
# ifdef HAVE_SSL
(void)SHA1(
(unsigned char*)sldns_buffer_begin(buf),
(unsigned long)sldns_buffer_limit(buf),
(unsigned char*)c->hash);
# else
(void)HASH_HashBuf(HASH_AlgSHA1,
(unsigned char*)c->hash,
(unsigned char*)sldns_buffer_begin(buf),
(unsigned long)sldns_buffer_limit(buf));
# endif
}
break;
#endif /* HAVE_EVP_SHA1 or NSS */
default:
log_err("nsec3 hash of unknown algo %d", algo);
return -1;
}
return 1;
}
/** perform b32 encoding of hash */
static int
nsec3_calc_b32(struct regional* region, sldns_buffer* buf,
struct nsec3_cached_hash* c)
{
int r;
sldns_buffer_clear(buf);
r = sldns_b32_ntop_extended_hex(c->hash, c->hash_len,
(char*)sldns_buffer_begin(buf), sldns_buffer_limit(buf));
if(r < 1) {
log_err("b32_ntop_extended_hex: error in encoding: %d", r);
return 0;
}
c->b32_len = (size_t)r;
c->b32 = regional_alloc_init(region, sldns_buffer_begin(buf),
c->b32_len);
if(!c->b32)
return 0;
return 1;
}
int
nsec3_hash_name(rbtree_t* table, struct regional* region, sldns_buffer* buf,
struct ub_packed_rrset_key* nsec3, int rr, uint8_t* dname,
size_t dname_len, struct nsec3_cached_hash** hash)
{
struct nsec3_cached_hash* c;
struct nsec3_cached_hash looki;
#ifdef UNBOUND_DEBUG
rbnode_t* n;
#endif
int r;
looki.node.key = &looki;
looki.nsec3 = nsec3;
looki.rr = rr;
looki.dname = dname;
looki.dname_len = dname_len;
/* lookup first in cache */
c = (struct nsec3_cached_hash*)rbtree_search(table, &looki);
if(c) {
*hash = c;
return 1;
}
/* create a new entry */
c = (struct nsec3_cached_hash*)regional_alloc(region, sizeof(*c));
if(!c) return 0;
c->node.key = c;
c->nsec3 = nsec3;
c->rr = rr;
c->dname = dname;
c->dname_len = dname_len;
r = nsec3_calc_hash(region, buf, c);
if(r != 1)
return r;
r = nsec3_calc_b32(region, buf, c);
if(r != 1)
return r;
#ifdef UNBOUND_DEBUG
n =
#else
(void)
#endif
rbtree_insert(table, &c->node);
log_assert(n); /* cannot be duplicate, just did lookup */
*hash = c;
return 1;
}
/**
* compare a label lowercased
*/
static int
label_compare_lower(uint8_t* lab1, uint8_t* lab2, size_t lablen)
{
size_t i;
for(i=0; i<lablen; i++) {
if(tolower((unsigned char)*lab1) != tolower((unsigned char)*lab2)) {
if(tolower((unsigned char)*lab1) < tolower((unsigned char)*lab2))
return -1;
return 1;
}
lab1++;
lab2++;
}
return 0;
}
/**
* Compare a hashed name with the owner name of an NSEC3 RRset.
* @param flt: filter with zone name.
* @param hash: the hashed name.
* @param s: rrset with owner name.
* @return true if matches exactly, false if not.
*/
static int
nsec3_hash_matches_owner(struct nsec3_filter* flt,
struct nsec3_cached_hash* hash, struct ub_packed_rrset_key* s)
{
uint8_t* nm = s->rk.dname;
/* compare, does hash of name based on params in this NSEC3
* match the owner name of this NSEC3?
* name must be: <hashlength>base32 . zone name
* so; first label must not be root label (not zero length),
* and match the b32 encoded hash length,
* and the label content match the b32 encoded hash
* and the rest must be the zone name.
*/
if(hash->b32_len != 0 && (size_t)nm[0] == hash->b32_len &&
label_compare_lower(nm+1, hash->b32, hash->b32_len) == 0 &&
query_dname_compare(nm+(size_t)nm[0]+1, flt->zone) == 0) {
return 1;
}
return 0;
}
/**
* Find matching NSEC3
* Find the NSEC3Record that matches a hash of a name.
* @param env: module environment with temporary region and buffer.
* @param flt: the NSEC3 RR filter, contains zone name and RRs.
* @param ct: cached hashes table.
* @param nm: name to look for.
* @param nmlen: length of name.
* @param rrset: nsec3 that matches is returned here.
* @param rr: rr number in nsec3 rrset that matches.
* @return true if a matching NSEC3 is found, false if not.
*/
static int
find_matching_nsec3(struct module_env* env, struct nsec3_filter* flt,
rbtree_t* ct, uint8_t* nm, size_t nmlen,
struct ub_packed_rrset_key** rrset, int* rr)
{
size_t i_rs;
int i_rr;
struct ub_packed_rrset_key* s;
struct nsec3_cached_hash* hash;
int r;
/* this loop skips other-zone and unknown NSEC3s, also non-NSEC3 RRs */
for(s=filter_first(flt, &i_rs, &i_rr); s;
s=filter_next(flt, &i_rs, &i_rr)) {
/* get name hashed for this NSEC3 RR */
r = nsec3_hash_name(ct, env->scratch, env->scratch_buffer,
s, i_rr, nm, nmlen, &hash);
if(r == 0) {
log_err("nsec3: malloc failure");
break; /* alloc failure */
} else if(r < 0)
continue; /* malformed NSEC3 */
else if(nsec3_hash_matches_owner(flt, hash, s)) {
*rrset = s; /* rrset with this name */
*rr = i_rr; /* matches hash with these parameters */
return 1;
}
}
*rrset = NULL;
*rr = 0;
return 0;
}
int
nsec3_covers(uint8_t* zone, struct nsec3_cached_hash* hash,
struct ub_packed_rrset_key* rrset, int rr, sldns_buffer* buf)
{
uint8_t* next, *owner;
size_t nextlen;
int len;
if(!nsec3_get_nextowner(rrset, rr, &next, &nextlen))
return 0; /* malformed RR proves nothing */
/* check the owner name is a hashed value . apex
* base32 encoded values must have equal length.
* hash_value and next hash value must have equal length. */
if(nextlen != hash->hash_len || hash->hash_len==0||hash->b32_len==0||
(size_t)*rrset->rk.dname != hash->b32_len ||
query_dname_compare(rrset->rk.dname+1+
(size_t)*rrset->rk.dname, zone) != 0)
return 0; /* bad lengths or owner name */
/* This is the "normal case: owner < next and owner < hash < next */
if(label_compare_lower(rrset->rk.dname+1, hash->b32,
hash->b32_len) < 0 &&
memcmp(hash->hash, next, nextlen) < 0)
return 1;
/* convert owner name from text to binary */
sldns_buffer_clear(buf);
owner = sldns_buffer_begin(buf);
len = sldns_b32_pton_extended_hex((char*)rrset->rk.dname+1,
hash->b32_len, owner, sldns_buffer_limit(buf));
if(len<1)
return 0; /* bad owner name in some way */
if((size_t)len != hash->hash_len || (size_t)len != nextlen)
return 0; /* wrong length */
/* this is the end of zone case: next <= owner &&
* (hash > owner || hash < next)
* this also covers the only-apex case of next==owner.
*/
if(memcmp(next, owner, nextlen) <= 0 &&
( memcmp(hash->hash, owner, nextlen) > 0 ||
memcmp(hash->hash, next, nextlen) < 0)) {
return 1;
}
return 0;
}
/**
* findCoveringNSEC3
* Given a name, find a covering NSEC3 from among a list of NSEC3s.
*
* @param env: module environment with temporary region and buffer.
* @param flt: the NSEC3 RR filter, contains zone name and RRs.
* @param ct: cached hashes table.
* @param nm: name to check if covered.
* @param nmlen: length of name.
* @param rrset: covering NSEC3 rrset is returned here.
* @param rr: rr of cover is returned here.
* @return true if a covering NSEC3 is found, false if not.
*/
static int
find_covering_nsec3(struct module_env* env, struct nsec3_filter* flt,
rbtree_t* ct, uint8_t* nm, size_t nmlen,
struct ub_packed_rrset_key** rrset, int* rr)
{
size_t i_rs;
int i_rr;
struct ub_packed_rrset_key* s;
struct nsec3_cached_hash* hash;
int r;
/* this loop skips other-zone and unknown NSEC3s, also non-NSEC3 RRs */
for(s=filter_first(flt, &i_rs, &i_rr); s;
s=filter_next(flt, &i_rs, &i_rr)) {
/* get name hashed for this NSEC3 RR */
r = nsec3_hash_name(ct, env->scratch, env->scratch_buffer,
s, i_rr, nm, nmlen, &hash);
if(r == 0) {
log_err("nsec3: malloc failure");
break; /* alloc failure */
} else if(r < 0)
continue; /* malformed NSEC3 */
else if(nsec3_covers(flt->zone, hash, s, i_rr,
env->scratch_buffer)) {
*rrset = s; /* rrset with this name */
*rr = i_rr; /* covers hash with these parameters */
return 1;
}
}
*rrset = NULL;
*rr = 0;
return 0;
}
/**
* findClosestEncloser
* Given a name and a list of NSEC3s, find the candidate closest encloser.
* This will be the first ancestor of 'name' (including itself) to have a
* matching NSEC3 RR.
* @param env: module environment with temporary region and buffer.
* @param flt: the NSEC3 RR filter, contains zone name and RRs.
* @param ct: cached hashes table.
* @param qinfo: query that is verified for.
* @param ce: closest encloser information is returned in here.
* @return true if a closest encloser candidate is found, false if not.
*/
static int
nsec3_find_closest_encloser(struct module_env* env, struct nsec3_filter* flt,
rbtree_t* ct, struct query_info* qinfo, struct ce_response* ce)
{
uint8_t* nm = qinfo->qname;
size_t nmlen = qinfo->qname_len;
/* This scans from longest name to shortest, so the first match
* we find is the only viable candidate. */
/* (David:) FIXME: modify so that the NSEC3 matching the zone apex need
* not be present. (Mark Andrews idea).
* (Wouter:) But make sure you check for DNAME bit in zone apex,
* if the NSEC3 you find is the only NSEC3 in the zone, then this
* may be the case. */
while(dname_subdomain_c(nm, flt->zone)) {
if(find_matching_nsec3(env, flt, ct, nm, nmlen,
&ce->ce_rrset, &ce->ce_rr)) {
ce->ce = nm;
ce->ce_len = nmlen;
return 1;
}
dname_remove_label(&nm, &nmlen);
}
return 0;
}
/**
* Given a qname and its proven closest encloser, calculate the "next
* closest" name. Basically, this is the name that is one label longer than
* the closest encloser that is still a subdomain of qname.
*
* @param qname: query name.
* @param qnamelen: length of qname.
* @param ce: closest encloser
* @param nm: result name.
* @param nmlen: length of nm.
*/
static void
next_closer(uint8_t* qname, size_t qnamelen, uint8_t* ce,
uint8_t** nm, size_t* nmlen)
{
int strip = dname_count_labels(qname) - dname_count_labels(ce) -1;
*nm = qname;
*nmlen = qnamelen;
if(strip>0)
dname_remove_labels(nm, nmlen, strip);
}
/**
* proveClosestEncloser
* Given a List of nsec3 RRs, find and prove the closest encloser to qname.
* @param env: module environment with temporary region and buffer.
* @param flt: the NSEC3 RR filter, contains zone name and RRs.
* @param ct: cached hashes table.
* @param qinfo: query that is verified for.
* @param prove_does_not_exist: If true, then if the closest encloser
* turns out to be qname, then null is returned.
* If set true, and the return value is true, then you can be
* certain that the ce.nc_rrset and ce.nc_rr are set properly.
* @param ce: closest encloser information is returned in here.
* @return bogus if no closest encloser could be proven.
* secure if a closest encloser could be proven, ce is set.
* insecure if the closest-encloser candidate turns out to prove
* that an insecure delegation exists above the qname.
*/
static enum sec_status
nsec3_prove_closest_encloser(struct module_env* env, struct nsec3_filter* flt,
rbtree_t* ct, struct query_info* qinfo, int prove_does_not_exist,
struct ce_response* ce)
{
uint8_t* nc;
size_t nc_len;
/* robust: clean out ce, in case it gets abused later */
memset(ce, 0, sizeof(*ce));
if(!nsec3_find_closest_encloser(env, flt, ct, qinfo, ce)) {
verbose(VERB_ALGO, "nsec3 proveClosestEncloser: could "
"not find a candidate for the closest encloser.");
return sec_status_bogus;
}
log_nametypeclass(VERB_ALGO, "ce candidate", ce->ce, 0, 0);
if(query_dname_compare(ce->ce, qinfo->qname) == 0) {
if(prove_does_not_exist) {
verbose(VERB_ALGO, "nsec3 proveClosestEncloser: "
"proved that qname existed, bad");
return sec_status_bogus;
}
/* otherwise, we need to nothing else to prove that qname
* is its own closest encloser. */
return sec_status_secure;
}
/* If the closest encloser is actually a delegation, then the
* response should have been a referral. If it is a DNAME, then
* it should have been a DNAME response. */
if(nsec3_has_type(ce->ce_rrset, ce->ce_rr, LDNS_RR_TYPE_NS) &&
!nsec3_has_type(ce->ce_rrset, ce->ce_rr, LDNS_RR_TYPE_SOA)) {
if(!nsec3_has_type(ce->ce_rrset, ce->ce_rr, LDNS_RR_TYPE_DS)) {
verbose(VERB_ALGO, "nsec3 proveClosestEncloser: "
"closest encloser is insecure delegation");
return sec_status_insecure;
}
verbose(VERB_ALGO, "nsec3 proveClosestEncloser: closest "
"encloser was a delegation, bad");
return sec_status_bogus;
}
if(nsec3_has_type(ce->ce_rrset, ce->ce_rr, LDNS_RR_TYPE_DNAME)) {
verbose(VERB_ALGO, "nsec3 proveClosestEncloser: closest "
"encloser was a DNAME, bad");
return sec_status_bogus;
}
/* Otherwise, we need to show that the next closer name is covered. */
next_closer(qinfo->qname, qinfo->qname_len, ce->ce, &nc, &nc_len);
if(!find_covering_nsec3(env, flt, ct, nc, nc_len,
&ce->nc_rrset, &ce->nc_rr)) {
verbose(VERB_ALGO, "nsec3: Could not find proof that the "
"candidate encloser was the closest encloser");
return sec_status_bogus;
}
return sec_status_secure;
}
/** allocate a wildcard for the closest encloser */
static uint8_t*
nsec3_ce_wildcard(struct regional* region, uint8_t* ce, size_t celen,
size_t* len)
{
uint8_t* nm;
if(celen > LDNS_MAX_DOMAINLEN - 2)
return 0; /* too long */
nm = (uint8_t*)regional_alloc(region, celen+2);
if(!nm) {
log_err("nsec3 wildcard: out of memory");
return 0; /* alloc failure */
}
nm[0] = 1;
nm[1] = (uint8_t)'*'; /* wildcard label */
memmove(nm+2, ce, celen);
*len = celen+2;
return nm;
}
/** Do the name error proof */
static enum sec_status
nsec3_do_prove_nameerror(struct module_env* env, struct nsec3_filter* flt,
rbtree_t* ct, struct query_info* qinfo)
{
struct ce_response ce;
uint8_t* wc;
size_t wclen;
struct ub_packed_rrset_key* wc_rrset;
int wc_rr;
enum sec_status sec;
/* First locate and prove the closest encloser to qname. We will
* use the variant that fails if the closest encloser turns out
* to be qname. */
sec = nsec3_prove_closest_encloser(env, flt, ct, qinfo, 1, &ce);
if(sec != sec_status_secure) {
if(sec == sec_status_bogus)
verbose(VERB_ALGO, "nsec3 nameerror proof: failed "
"to prove a closest encloser");
else verbose(VERB_ALGO, "nsec3 nameerror proof: closest "
"nsec3 is an insecure delegation");
return sec;
}
log_nametypeclass(VERB_ALGO, "nsec3 namerror: proven ce=", ce.ce,0,0);
/* At this point, we know that qname does not exist. Now we need
* to prove that the wildcard does not exist. */
log_assert(ce.ce);
wc = nsec3_ce_wildcard(env->scratch, ce.ce, ce.ce_len, &wclen);
if(!wc || !find_covering_nsec3(env, flt, ct, wc, wclen,
&wc_rrset, &wc_rr)) {
verbose(VERB_ALGO, "nsec3 nameerror proof: could not prove "
"that the applicable wildcard did not exist.");
return sec_status_bogus;
}
if(ce.nc_rrset && nsec3_has_optout(ce.nc_rrset, ce.nc_rr)) {
verbose(VERB_ALGO, "nsec3 nameerror proof: nc has optout");
return sec_status_insecure;
}
return sec_status_secure;
}
enum sec_status
nsec3_prove_nameerror(struct module_env* env, struct val_env* ve,
struct ub_packed_rrset_key** list, size_t num,
struct query_info* qinfo, struct key_entry_key* kkey)
{
rbtree_t ct;
struct nsec3_filter flt;
if(!list || num == 0 || !kkey || !key_entry_isgood(kkey))
return sec_status_bogus; /* no valid NSEC3s, bogus */
rbtree_init(&ct, &nsec3_hash_cmp); /* init names-to-hash cache */
filter_init(&flt, list, num, qinfo); /* init RR iterator */
if(!flt.zone)
return sec_status_bogus; /* no RRs */
if(nsec3_iteration_count_high(ve, &flt, kkey))
return sec_status_insecure; /* iteration count too high */
log_nametypeclass(VERB_ALGO, "start nsec3 nameerror proof, zone",
flt.zone, 0, 0);
return nsec3_do_prove_nameerror(env, &flt, &ct, qinfo);
}
/*
* No code to handle qtype=NSEC3 specially.
* This existed in early drafts, but was later (-05) removed.
*/
/** Do the nodata proof */
static enum sec_status
nsec3_do_prove_nodata(struct module_env* env, struct nsec3_filter* flt,
rbtree_t* ct, struct query_info* qinfo)
{
struct ce_response ce;
uint8_t* wc;
size_t wclen;
struct ub_packed_rrset_key* rrset;
int rr;
enum sec_status sec;
if(find_matching_nsec3(env, flt, ct, qinfo->qname, qinfo->qname_len,
&rrset, &rr)) {
/* cases 1 and 2 */
if(nsec3_has_type(rrset, rr, qinfo->qtype)) {
verbose(VERB_ALGO, "proveNodata: Matching NSEC3 "
"proved that type existed, bogus");
return sec_status_bogus;
} else if(nsec3_has_type(rrset, rr, LDNS_RR_TYPE_CNAME)) {
verbose(VERB_ALGO, "proveNodata: Matching NSEC3 "
"proved that a CNAME existed, bogus");
return sec_status_bogus;
}
/*
* If type DS: filter_init zone find already found a parent
* zone, so this nsec3 is from a parent zone.
* o can be not a delegation (unusual query for normal name,
* no DS anyway, but we can verify that).
* o can be a delegation (which is the usual DS check).
* o may not have the SOA bit set (only the top of the
* zone, which must have been above the name, has that).
* Except for the root; which is checked by itself.
*
* If not type DS: matching nsec3 must not be a delegation.
*/
if(qinfo->qtype == LDNS_RR_TYPE_DS && qinfo->qname_len != 1
&& nsec3_has_type(rrset, rr, LDNS_RR_TYPE_SOA) &&
!dname_is_root(qinfo->qname)) {
verbose(VERB_ALGO, "proveNodata: apex NSEC3 "
"abused for no DS proof, bogus");
return sec_status_bogus;
} else if(qinfo->qtype != LDNS_RR_TYPE_DS &&
nsec3_has_type(rrset, rr, LDNS_RR_TYPE_NS) &&
!nsec3_has_type(rrset, rr, LDNS_RR_TYPE_SOA)) {
if(!nsec3_has_type(rrset, rr, LDNS_RR_TYPE_DS)) {
verbose(VERB_ALGO, "proveNodata: matching "
"NSEC3 is insecure delegation");
return sec_status_insecure;
}
verbose(VERB_ALGO, "proveNodata: matching "
"NSEC3 is a delegation, bogus");
return sec_status_bogus;
}
return sec_status_secure;
}
/* For cases 3 - 5, we need the proven closest encloser, and it
* can't match qname. Although, at this point, we know that it
* won't since we just checked that. */
sec = nsec3_prove_closest_encloser(env, flt, ct, qinfo, 1, &ce);
if(sec == sec_status_bogus) {
verbose(VERB_ALGO, "proveNodata: did not match qname, "
"nor found a proven closest encloser.");
return sec_status_bogus;
} else if(sec==sec_status_insecure && qinfo->qtype!=LDNS_RR_TYPE_DS){
verbose(VERB_ALGO, "proveNodata: closest nsec3 is insecure "
"delegation.");
return sec_status_insecure;
}
/* Case 3: removed */
/* Case 4: */
log_assert(ce.ce);
wc = nsec3_ce_wildcard(env->scratch, ce.ce, ce.ce_len, &wclen);
if(wc && find_matching_nsec3(env, flt, ct, wc, wclen, &rrset, &rr)) {
/* found wildcard */
if(nsec3_has_type(rrset, rr, qinfo->qtype)) {
verbose(VERB_ALGO, "nsec3 nodata proof: matching "
"wildcard had qtype, bogus");
return sec_status_bogus;
} else if(nsec3_has_type(rrset, rr, LDNS_RR_TYPE_CNAME)) {
verbose(VERB_ALGO, "nsec3 nodata proof: matching "
"wildcard had a CNAME, bogus");
return sec_status_bogus;
}
if(qinfo->qtype == LDNS_RR_TYPE_DS && qinfo->qname_len != 1
&& nsec3_has_type(rrset, rr, LDNS_RR_TYPE_SOA)) {
verbose(VERB_ALGO, "nsec3 nodata proof: matching "
"wildcard for no DS proof has a SOA, bogus");
return sec_status_bogus;
} else if(qinfo->qtype != LDNS_RR_TYPE_DS &&
nsec3_has_type(rrset, rr, LDNS_RR_TYPE_NS) &&
!nsec3_has_type(rrset, rr, LDNS_RR_TYPE_SOA)) {
verbose(VERB_ALGO, "nsec3 nodata proof: matching "
"wilcard is a delegation, bogus");
return sec_status_bogus;
}
/* everything is peachy keen, except for optout spans */
if(ce.nc_rrset && nsec3_has_optout(ce.nc_rrset, ce.nc_rr)) {
verbose(VERB_ALGO, "nsec3 nodata proof: matching "
"wildcard is in optout range, insecure");
return sec_status_insecure;
}
return sec_status_secure;
}
/* Case 5: */
/* Due to forwarders, cnames, and other collating effects, we
* can see the ordinary unsigned data from a zone beneath an
* insecure delegation under an optout here */
if(!ce.nc_rrset) {
verbose(VERB_ALGO, "nsec3 nodata proof: no next closer nsec3");
return sec_status_bogus;
}
/* We need to make sure that the covering NSEC3 is opt-out. */
log_assert(ce.nc_rrset);
if(!nsec3_has_optout(ce.nc_rrset, ce.nc_rr)) {
if(qinfo->qtype == LDNS_RR_TYPE_DS)
verbose(VERB_ALGO, "proveNodata: covering NSEC3 was not "
"opt-out in an opt-out DS NOERROR/NODATA case.");
else verbose(VERB_ALGO, "proveNodata: could not find matching "
"NSEC3, nor matching wildcard, nor optout NSEC3 "
"-- no more options, bogus.");
return sec_status_bogus;
}
/* RFC5155 section 9.2: if nc has optout then no AD flag set */
return sec_status_insecure;
}
enum sec_status
nsec3_prove_nodata(struct module_env* env, struct val_env* ve,
struct ub_packed_rrset_key** list, size_t num,
struct query_info* qinfo, struct key_entry_key* kkey)
{
rbtree_t ct;
struct nsec3_filter flt;
if(!list || num == 0 || !kkey || !key_entry_isgood(kkey))
return sec_status_bogus; /* no valid NSEC3s, bogus */
rbtree_init(&ct, &nsec3_hash_cmp); /* init names-to-hash cache */
filter_init(&flt, list, num, qinfo); /* init RR iterator */
if(!flt.zone)
return sec_status_bogus; /* no RRs */
if(nsec3_iteration_count_high(ve, &flt, kkey))
return sec_status_insecure; /* iteration count too high */
return nsec3_do_prove_nodata(env, &flt, &ct, qinfo);
}
enum sec_status
nsec3_prove_wildcard(struct module_env* env, struct val_env* ve,
struct ub_packed_rrset_key** list, size_t num,
struct query_info* qinfo, struct key_entry_key* kkey, uint8_t* wc)
{
rbtree_t ct;
struct nsec3_filter flt;
struct ce_response ce;
uint8_t* nc;
size_t nc_len;
size_t wclen;
(void)dname_count_size_labels(wc, &wclen);
if(!list || num == 0 || !kkey || !key_entry_isgood(kkey))
return sec_status_bogus; /* no valid NSEC3s, bogus */
rbtree_init(&ct, &nsec3_hash_cmp); /* init names-to-hash cache */
filter_init(&flt, list, num, qinfo); /* init RR iterator */
if(!flt.zone)
return sec_status_bogus; /* no RRs */
if(nsec3_iteration_count_high(ve, &flt, kkey))
return sec_status_insecure; /* iteration count too high */
/* We know what the (purported) closest encloser is by just
* looking at the supposed generating wildcard.
* The *. has already been removed from the wc name.
*/
memset(&ce, 0, sizeof(ce));
ce.ce = wc;
ce.ce_len = wclen;
/* Now we still need to prove that the original data did not exist.
* Otherwise, we need to show that the next closer name is covered. */
next_closer(qinfo->qname, qinfo->qname_len, ce.ce, &nc, &nc_len);
if(!find_covering_nsec3(env, &flt, &ct, nc, nc_len,
&ce.nc_rrset, &ce.nc_rr)) {
verbose(VERB_ALGO, "proveWildcard: did not find a covering "
"NSEC3 that covered the next closer name.");
return sec_status_bogus;
}
if(ce.nc_rrset && nsec3_has_optout(ce.nc_rrset, ce.nc_rr)) {
verbose(VERB_ALGO, "proveWildcard: NSEC3 optout");
return sec_status_insecure;
}
return sec_status_secure;
}
/** test if list is all secure */
static int
list_is_secure(struct module_env* env, struct val_env* ve,
struct ub_packed_rrset_key** list, size_t num,
struct key_entry_key* kkey, char** reason)
{
struct packed_rrset_data* d;
size_t i;
for(i=0; i<num; i++) {
d = (struct packed_rrset_data*)list[i]->entry.data;
if(list[i]->rk.type != htons(LDNS_RR_TYPE_NSEC3))
continue;
if(d->security == sec_status_secure)
continue;
rrset_check_sec_status(env->rrset_cache, list[i], *env->now);
if(d->security == sec_status_secure)
continue;
d->security = val_verify_rrset_entry(env, ve, list[i], kkey,
reason);
if(d->security != sec_status_secure) {
verbose(VERB_ALGO, "NSEC3 did not verify");
return 0;
}
rrset_update_sec_status(env->rrset_cache, list[i], *env->now);
}
return 1;
}
enum sec_status
nsec3_prove_nods(struct module_env* env, struct val_env* ve,
struct ub_packed_rrset_key** list, size_t num,
struct query_info* qinfo, struct key_entry_key* kkey, char** reason)
{
rbtree_t ct;
struct nsec3_filter flt;
struct ce_response ce;
struct ub_packed_rrset_key* rrset;
int rr;
log_assert(qinfo->qtype == LDNS_RR_TYPE_DS);
if(!list || num == 0 || !kkey || !key_entry_isgood(kkey)) {
*reason = "no valid NSEC3s";
return sec_status_bogus; /* no valid NSEC3s, bogus */
}
if(!list_is_secure(env, ve, list, num, kkey, reason))
return sec_status_bogus; /* not all NSEC3 records secure */
rbtree_init(&ct, &nsec3_hash_cmp); /* init names-to-hash cache */
filter_init(&flt, list, num, qinfo); /* init RR iterator */
if(!flt.zone) {
*reason = "no NSEC3 records";
return sec_status_bogus; /* no RRs */
}
if(nsec3_iteration_count_high(ve, &flt, kkey))
return sec_status_insecure; /* iteration count too high */
/* Look for a matching NSEC3 to qname -- this is the normal
* NODATA case. */
if(find_matching_nsec3(env, &flt, &ct, qinfo->qname, qinfo->qname_len,
&rrset, &rr)) {
/* If the matching NSEC3 has the SOA bit set, it is from
* the wrong zone (the child instead of the parent). If
* it has the DS bit set, then we were lied to. */
if(nsec3_has_type(rrset, rr, LDNS_RR_TYPE_SOA) &&
qinfo->qname_len != 1) {
verbose(VERB_ALGO, "nsec3 provenods: NSEC3 is from"
" child zone, bogus");
*reason = "NSEC3 from child zone";
return sec_status_bogus;
} else if(nsec3_has_type(rrset, rr, LDNS_RR_TYPE_DS)) {
verbose(VERB_ALGO, "nsec3 provenods: NSEC3 has qtype"
" DS, bogus");
*reason = "NSEC3 has DS in bitmap";
return sec_status_bogus;
}
/* If the NSEC3 RR doesn't have the NS bit set, then
* this wasn't a delegation point. */
if(!nsec3_has_type(rrset, rr, LDNS_RR_TYPE_NS))
return sec_status_indeterminate;
/* Otherwise, this proves no DS. */
return sec_status_secure;
}
/* Otherwise, we are probably in the opt-out case. */
if(nsec3_prove_closest_encloser(env, &flt, &ct, qinfo, 1, &ce)
!= sec_status_secure) {
/* an insecure delegation *above* the qname does not prove
* anything about this qname exactly, and bogus is bogus */
verbose(VERB_ALGO, "nsec3 provenods: did not match qname, "
"nor found a proven closest encloser.");
*reason = "no NSEC3 closest encloser";
return sec_status_bogus;
}
/* robust extra check */
if(!ce.nc_rrset) {
verbose(VERB_ALGO, "nsec3 nods proof: no next closer nsec3");
*reason = "no NSEC3 next closer";
return sec_status_bogus;
}
/* we had the closest encloser proof, then we need to check that the
* covering NSEC3 was opt-out -- the proveClosestEncloser step already
* checked to see if the closest encloser was a delegation or DNAME.
*/
log_assert(ce.nc_rrset);
if(!nsec3_has_optout(ce.nc_rrset, ce.nc_rr)) {
verbose(VERB_ALGO, "nsec3 provenods: covering NSEC3 was not "
"opt-out in an opt-out DS NOERROR/NODATA case.");
*reason = "covering NSEC3 was not opt-out in an opt-out "
"DS NOERROR/NODATA case";
return sec_status_bogus;
}
/* RFC5155 section 9.2: if nc has optout then no AD flag set */
return sec_status_insecure;
}
enum sec_status
nsec3_prove_nxornodata(struct module_env* env, struct val_env* ve,
struct ub_packed_rrset_key** list, size_t num,
struct query_info* qinfo, struct key_entry_key* kkey, int* nodata)
{
enum sec_status sec, secnx;
rbtree_t ct;
struct nsec3_filter flt;
*nodata = 0;
if(!list || num == 0 || !kkey || !key_entry_isgood(kkey))
return sec_status_bogus; /* no valid NSEC3s, bogus */
rbtree_init(&ct, &nsec3_hash_cmp); /* init names-to-hash cache */
filter_init(&flt, list, num, qinfo); /* init RR iterator */
if(!flt.zone)
return sec_status_bogus; /* no RRs */
if(nsec3_iteration_count_high(ve, &flt, kkey))
return sec_status_insecure; /* iteration count too high */
/* try nxdomain and nodata after another, while keeping the
* hash cache intact */
secnx = nsec3_do_prove_nameerror(env, &flt, &ct, qinfo);
if(secnx==sec_status_secure)
return sec_status_secure;
sec = nsec3_do_prove_nodata(env, &flt, &ct, qinfo);
if(sec==sec_status_secure) {
*nodata = 1;
} else if(sec == sec_status_insecure) {
*nodata = 1;
} else if(secnx == sec_status_insecure) {
sec = sec_status_insecure;
}
return sec;
}