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|
/* Copyright (C) CZ.NIC, z.s.p.o. <knot-resolver@labs.nic.cz>
* SPDX-License-Identifier: GPL-3.0-or-later
*/
#include <string.h>
#include <libdnssec/binary.h>
#include <libdnssec/error.h>
#include <libdnssec/nsec.h>
#include <libknot/descriptor.h>
#include <contrib/base32hex.h>
#include <libknot/rrset.h>
#include <libknot/rrtype/nsec3.h>
#include "lib/defines.h"
#include "lib/dnssec/nsec.h"
#include "lib/dnssec/nsec3.h"
#include "lib/utils.h"
#define OPT_OUT_BIT 0x01
//#define FLG_CLOSEST_ENCLOSER (1 << 0)
#define FLG_CLOSEST_PROVABLE_ENCLOSER (1 << 1)
#define FLG_NAME_COVERED (1 << 2)
#define FLG_NAME_MATCHED (1 << 3)
#define FLG_TYPE_BIT_MISSING (1 << 4)
#define FLG_CNAME_BIT_MISSING (1 << 5)
/**
* Obtains NSEC3 parameters from RR.
* @param params NSEC3 parameters structure to be set.
* @param nsec3 NSEC3 RR containing the parameters.
* @return 0 or error code.
*/
static int nsec3_parameters(dnssec_nsec3_params_t *params, const knot_rrset_t *nsec3)
{
if (kr_fails_assert(params && nsec3))
return kr_error(EINVAL);
const knot_rdata_t *rr = knot_rdataset_at(&nsec3->rrs, 0);
if (kr_fails_assert(rr))
return kr_error(EINVAL);
/* Every NSEC3 RR contains data from NSEC3PARAMS. */
const size_t SALT_OFFSET = 5; /* First 5 octets contain { Alg, Flags, Iterations, Salt length } */
dnssec_binary_t rdata = {
.size = SALT_OFFSET + (size_t)knot_nsec3_salt_len(nsec3->rrs.rdata),
.data = /*const-cast*/(uint8_t *)rr->data,
};
if (rdata.size > rr->len)
return kr_error(EMSGSIZE);
int ret = dnssec_nsec3_params_from_rdata(params, &rdata);
if (ret != DNSSEC_EOK)
return kr_error(EINVAL);
return kr_ok();
}
/**
* Computes a hash of a given domain name.
* @param hash Resulting hash, must be freed.
* @param params NSEC3 parameters.
* @param name Domain name to be hashed.
* @return 0 or error code.
*/
static int hash_name(dnssec_binary_t *hash, const dnssec_nsec3_params_t *params,
const knot_dname_t *name)
{
if (kr_fails_assert(hash && params))
return kr_error(EINVAL);
if (!name)
return kr_error(EINVAL);
if (kr_fails_assert(params->iterations <= KR_NSEC3_MAX_ITERATIONS)) {
/* This if is mainly defensive; it shouldn't happen. */
return kr_error(EINVAL);
}
dnssec_binary_t dname = {
.size = knot_dname_size(name),
.data = (uint8_t *) name,
};
int ret = dnssec_nsec3_hash(&dname, params, hash);
if (ret != DNSSEC_EOK) {
return kr_error(EINVAL);
}
return kr_ok();
}
/**
* Read hash from NSEC3 owner name and store its binary form.
* @param hash Buffer to be written.
* @param max_hash_size Maximal has size.
* @param nsec3 NSEC3 RR.
* @return 0 or error code.
*/
static int read_owner_hash(dnssec_binary_t *hash, size_t max_hash_size, const knot_rrset_t *nsec3)
{
if (kr_fails_assert(hash && nsec3 && hash->data))
return kr_error(EINVAL);
int32_t ret = base32hex_decode(nsec3->owner + 1, nsec3->owner[0], hash->data, max_hash_size);
if (ret < 0)
return kr_error(EILSEQ);
hash->size = ret;
return kr_ok();
}
#define MAX_HASH_BYTES 64
/**
* Closest (provable) encloser match (RFC5155 7.2.1, bullet 1).
* @param flags Flags to be set according to check outcome.
* @param nsec3 NSEC3 RR.
* @param name Name to be checked.
* @param skipped Number of skipped labels to find closest (provable) match.
* @return 0 or error code.
*/
static int closest_encloser_match(int *flags, const knot_rrset_t *nsec3,
const knot_dname_t *name, unsigned *skipped)
{
if (kr_fails_assert(flags && nsec3 && name && skipped))
return kr_error(EINVAL);
uint8_t hash_data[MAX_HASH_BYTES] = {0, };
dnssec_binary_t owner_hash = { 0, hash_data };
dnssec_nsec3_params_t params = { 0, };
dnssec_binary_t name_hash = { 0, };
int ret = read_owner_hash(&owner_hash, MAX_HASH_BYTES, nsec3);
if (ret != 0)
goto fail;
ret = nsec3_parameters(¶ms, nsec3);
if (ret != 0)
goto fail;
/* Root label has no encloser */
if (!name[0]) {
ret = kr_error(ENOENT);
goto fail;
}
const knot_dname_t *encloser = knot_wire_next_label(name, NULL);
*skipped = 1;
while(encloser) {
ret = hash_name(&name_hash, ¶ms, encloser);
if (ret != 0)
goto fail;
if ((owner_hash.size == name_hash.size) &&
(memcmp(owner_hash.data, name_hash.data, owner_hash.size) == 0)) {
dnssec_binary_free(&name_hash);
*flags |= FLG_CLOSEST_PROVABLE_ENCLOSER;
break;
}
dnssec_binary_free(&name_hash);
if (!encloser[0])
break;
encloser = knot_wire_next_label(encloser, NULL);
++(*skipped);
}
ret = kr_ok();
fail:
if (params.salt.data)
dnssec_nsec3_params_free(¶ms);
if (name_hash.data)
dnssec_binary_free(&name_hash);
return ret;
}
/**
* Checks whether NSEC3 RR covers the supplied name (RFC5155 7.2.1, bullet 2).
* @param flags Flags to be set according to check outcome.
* @param nsec3 NSEC3 RR.
* @param name Name to be checked.
* @return 0 or error code.
*/
static int covers_name(int *flags, const knot_rrset_t *nsec3, const knot_dname_t *name)
{
if (kr_fails_assert(flags && nsec3 && name))
return kr_error(EINVAL);
uint8_t hash_data[MAX_HASH_BYTES] = { 0, };
dnssec_binary_t owner_hash = { 0, hash_data };
dnssec_nsec3_params_t params = { 0, };
dnssec_binary_t name_hash = { 0, };
int ret = read_owner_hash(&owner_hash, MAX_HASH_BYTES, nsec3);
if (ret != 0)
goto fail;
ret = nsec3_parameters(¶ms, nsec3);
if (ret != 0)
goto fail;
ret = hash_name(&name_hash, ¶ms, name);
if (ret != 0)
goto fail;
uint8_t next_size = knot_nsec3_next_len(nsec3->rrs.rdata);
const uint8_t *next_hash = knot_nsec3_next(nsec3->rrs.rdata);
if ((next_size > 0) && (owner_hash.size == next_size) && (name_hash.size == next_size)) {
/* All hash lengths must be same. */
const uint8_t *ownerd = owner_hash.data;
const uint8_t *nextd = next_hash;
int covered = 0;
int greater_then_owner = (memcmp(ownerd, name_hash.data, next_size) < 0);
int less_then_next = (memcmp(name_hash.data, nextd, next_size) < 0);
if (memcmp(ownerd, nextd, next_size) < 0) {
/*
* 0 (...) owner ... next (...) MAX
* ^
* name
* ==>
* (owner < name) && (name < next)
*/
covered = ((greater_then_owner) && (less_then_next));
} else {
/*
* owner ... MAX, 0 ... next
* ^ ^ ^
* name name name
* =>
* (owner < name) || (name < next)
*/
covered = ((greater_then_owner) || (less_then_next));
}
if (covered) {
*flags |= FLG_NAME_COVERED;
uint8_t nsec3_flags = knot_nsec3_flags(nsec3->rrs.rdata);
if (nsec3_flags & ~OPT_OUT_BIT) {
/* RFC5155 3.1.2 */
ret = kr_error(EINVAL);
} else {
ret = kr_ok();
}
}
}
fail:
if (params.salt.data)
dnssec_nsec3_params_free(¶ms);
if (name_hash.data)
dnssec_binary_free(&name_hash);
return ret;
}
/**
* Checks whether NSEC3 RR has the opt-out bit set.
* @param flags Flags to be set according to check outcome.
* @param nsec3 NSEC3 RR.
* @param name Name to be checked.
* @return 0 or error code.
*/
static bool has_optout(const knot_rrset_t *nsec3)
{
if (!nsec3)
return false;
uint8_t nsec3_flags = knot_nsec3_flags(nsec3->rrs.rdata);
if (nsec3_flags & ~OPT_OUT_BIT) {
/* RFC5155 3.1.2 */
return false;
}
return nsec3_flags & OPT_OUT_BIT;
}
/**
* Checks whether NSEC3 RR matches the supplied name.
* @param flags Flags to be set according to check outcome.
* @param nsec3 NSEC3 RR.
* @param name Name to be checked.
* @return 0 if matching, >0 if not (abs(ENOENT)), or error code (<0).
*/
static int matches_name(const knot_rrset_t *nsec3, const knot_dname_t *name)
{
if (kr_fails_assert(nsec3 && name))
return kr_error(EINVAL);
uint8_t hash_data[MAX_HASH_BYTES] = { 0, };
dnssec_binary_t owner_hash = { 0, hash_data };
dnssec_nsec3_params_t params = { 0, };
dnssec_binary_t name_hash = { 0, };
int ret = read_owner_hash(&owner_hash, MAX_HASH_BYTES, nsec3);
if (ret != 0)
goto fail;
ret = nsec3_parameters(¶ms, nsec3);
if (ret != 0)
goto fail;
ret = hash_name(&name_hash, ¶ms, name);
if (ret != 0)
goto fail;
if ((owner_hash.size == name_hash.size) &&
(memcmp(owner_hash.data, name_hash.data, owner_hash.size) == 0)) {
ret = kr_ok();
} else {
ret = abs(ENOENT);
}
fail:
if (params.salt.data)
dnssec_nsec3_params_free(¶ms);
if (name_hash.data)
dnssec_binary_free(&name_hash);
return ret;
}
#undef MAX_HASH_BYTES
/**
* Prepends an asterisk label to given name.
*
* @param tgt Target buffer to write domain name into.
* @param name Name to be added to the asterisk.
* @return Size of the resulting name or error code.
*/
static int prepend_asterisk(uint8_t *tgt, size_t maxlen, const knot_dname_t *name)
{
if (kr_fails_assert(maxlen >= 3))
return kr_error(EINVAL);
memcpy(tgt, "\1*", 3);
return knot_dname_to_wire(tgt + 2, name, maxlen - 2);
}
/**
* Closest encloser proof (RFC5155 7.2.1).
* @note No RRSIGs are validated.
* @param pkt Packet structure to be processed.
* @param section_id Packet section to be processed.
* @param sname Name to be checked.
* @param encloser_name Returned matching encloser name, if found.
* @param matching_encloser_nsec3 Pointer to matching encloser NSEC RRSet.
* @param covering_next_nsec3 Pointer to covering next closer NSEC3 RRSet.
* @return 0 or error code.
*/
static int closest_encloser_proof(const knot_pkt_t *pkt,
knot_section_t section_id,
const knot_dname_t *sname,
const knot_dname_t **encloser_name,
const knot_rrset_t **matching_encloser_nsec3,
const knot_rrset_t **covering_next_nsec3)
{
const knot_pktsection_t *sec = knot_pkt_section(pkt, section_id);
if (!sec || !sname)
return kr_error(EINVAL);
const knot_rrset_t *matching = NULL;
const knot_rrset_t *covering = NULL;
int flags = 0;
const knot_dname_t *next_closer = NULL;
for (unsigned i = 0; i < sec->count; ++i) {
const knot_rrset_t *rrset = knot_pkt_rr(sec, i);
if (rrset->type != KNOT_RRTYPE_NSEC3)
continue;
/* Also skip the NSEC3-to-match an ancestor of sname if it's
* a parent-side delegation, as that would mean the owner
* does not really exist (authoritatively in this zone,
* even in case of opt-out).
*/
const uint8_t *bm = knot_nsec3_bitmap(rrset->rrs.rdata);
uint16_t bm_size = knot_nsec3_bitmap_len(rrset->rrs.rdata);
if (kr_nsec_children_in_zone_check(bm, bm_size) != 0)
continue; /* no fatal errors from bad RRs */
/* Match the NSEC3 to sname or one of its ancestors. */
unsigned skipped = 0;
flags = 0;
int ret = closest_encloser_match(&flags, rrset, sname, &skipped);
if (ret != 0)
return ret;
if (!(flags & FLG_CLOSEST_PROVABLE_ENCLOSER))
continue;
matching = rrset;
/* Construct the next closer name and try to cover it. */
--skipped;
next_closer = sname;
for (unsigned j = 0; j < skipped; ++j) {
if (kr_fails_assert(next_closer[0]))
return kr_error(EINVAL);
next_closer = knot_wire_next_label(next_closer, NULL);
}
for (unsigned j = 0; j < sec->count; ++j) {
const knot_rrset_t *rrset_j = knot_pkt_rr(sec, j);
if (rrset_j->type != KNOT_RRTYPE_NSEC3)
continue;
ret = covers_name(&flags, rrset_j, next_closer);
if (ret != 0)
return ret;
if (flags & FLG_NAME_COVERED) {
covering = rrset_j;
break;
}
}
if (flags & FLG_NAME_COVERED)
break;
flags = 0; //
}
if ((flags & FLG_CLOSEST_PROVABLE_ENCLOSER) && (flags & FLG_NAME_COVERED) && next_closer) {
if (encloser_name && next_closer[0])
*encloser_name = knot_wire_next_label(next_closer, NULL);
if (matching_encloser_nsec3)
*matching_encloser_nsec3 = matching;
if (covering_next_nsec3)
*covering_next_nsec3 = covering;
return kr_ok();
}
return kr_error(ENOENT);
}
/**
* Check whether any NSEC3 RR covers a wildcard RR at the closer encloser.
* @param pkt Packet structure to be processed.
* @param section_id Packet section to be processed.
* @param encloser Closest (provable) encloser domain name.
* @return 0 or error code:
* KNOT_ERANGE - NSEC3 RR (that covers a wildcard)
* has been found, but has opt-out flag set;
* otherwise - error.
*/
static int covers_closest_encloser_wildcard(const knot_pkt_t *pkt, knot_section_t section_id,
const knot_dname_t *encloser)
{
const knot_pktsection_t *sec = knot_pkt_section(pkt, section_id);
if (!sec || !encloser)
return kr_error(EINVAL);
uint8_t wildcard[KNOT_DNAME_MAXLEN];
wildcard[0] = 1;
wildcard[1] = '*';
int encloser_len = knot_dname_size(encloser);
if (encloser_len < 0)
return encloser_len;
memcpy(wildcard + 2, encloser, encloser_len);
int flags = 0;
for (unsigned i = 0; i < sec->count; ++i) {
const knot_rrset_t *rrset = knot_pkt_rr(sec, i);
if (rrset->type != KNOT_RRTYPE_NSEC3)
continue;
int ret = covers_name(&flags, rrset, wildcard);
if (ret != 0)
return ret;
if (flags & FLG_NAME_COVERED) {
return has_optout(rrset) ?
kr_error(KNOT_ERANGE) : kr_ok();
}
}
return kr_error(ENOENT);
}
int kr_nsec3_name_error_response_check(const knot_pkt_t *pkt, knot_section_t section_id,
const knot_dname_t *sname)
{
const knot_dname_t *encloser = NULL;
const knot_rrset_t *covering_next_nsec3 = NULL;
int ret = closest_encloser_proof(pkt, section_id, sname,
&encloser, NULL, &covering_next_nsec3);
if (ret != 0)
return ret;
ret = covers_closest_encloser_wildcard(pkt, section_id, encloser);
if (ret != 0) {
/* OK, but NSEC3 for wildcard at encloser has opt-out;
* or error */
return ret;
}
/* Closest encloser proof is OK and
* NSEC3 for wildcard has been found and optout flag is not set.
* Now check if NSEC3 that covers next closer name has opt-out. */
return has_optout(covering_next_nsec3) ?
kr_error(KNOT_ERANGE) : kr_ok();
}
/**
* Search the packet section for a matching NSEC3 with nodata-proving bitmap.
* @param pkt Packet structure to be processed.
* @param section_id Packet section to be processed.
* @param sname Name to be checked.
* @param stype Type to be checked.
* @return 0 or error code.
* @note This does NOT check the opt-out case if type is DS;
* see RFC 5155 8.6.
*/
static int nodata_find(const knot_pkt_t *pkt, knot_section_t section_id,
const knot_dname_t *name, const uint16_t type)
{
const knot_pktsection_t *sec = knot_pkt_section(pkt, section_id);
if (!sec || !name)
return kr_error(EINVAL);
for (unsigned i = 0; i < sec->count; ++i) {
const knot_rrset_t *nsec3 = knot_pkt_rr(sec, i);
/* Records causing any errors are simply skipped. */
if (nsec3->type != KNOT_RRTYPE_NSEC3
|| matches_name(nsec3, name) != kr_ok()) {
continue;
/* LATER(optim.): we repeatedly recompute the hash of `name` */
}
const uint8_t *bm = knot_nsec3_bitmap(nsec3->rrs.rdata);
uint16_t bm_size = knot_nsec3_bitmap_len(nsec3->rrs.rdata);
if (kr_nsec_bitmap_nodata_check(bm, bm_size, type, nsec3->owner) == kr_ok())
return kr_ok();
}
return kr_error(ENOENT);
}
/**
* Check whether NSEC3 RR matches a wildcard at the closest encloser and has given type bit missing.
* @param pkt Packet structure to be processed.
* @param section_id Packet section to be processed.
* @param encloser Closest (provable) encloser domain name.
* @param stype Type to be checked.
* @return 0 or error code.
*/
static int matches_closest_encloser_wildcard(const knot_pkt_t *pkt, knot_section_t section_id,
const knot_dname_t *encloser, uint16_t stype)
{
const knot_pktsection_t *sec = knot_pkt_section(pkt, section_id);
if (!sec || !encloser)
return kr_error(EINVAL);
uint8_t wildcard[KNOT_DNAME_MAXLEN]; /**< the source of synthesis */
int ret = prepend_asterisk(wildcard, sizeof(wildcard), encloser);
if (ret < 0)
return ret;
kr_require(ret >= 3);
return nodata_find(pkt, section_id, wildcard, stype);
}
int kr_nsec3_wildcard_answer_response_check(const knot_pkt_t *pkt, knot_section_t section_id,
const knot_dname_t *sname, int trim_to_next)
{
const knot_pktsection_t *sec = knot_pkt_section(pkt, section_id);
if (!sec || !sname)
return kr_error(EINVAL);
/* Compute the next closer name. */
for (int i = 0; i < trim_to_next; ++i) {
if (kr_fails_assert(sname[0]))
return kr_error(EINVAL);
sname = knot_wire_next_label(sname, NULL);
}
int flags = 0;
for (unsigned i = 0; i < sec->count; ++i) {
const knot_rrset_t *rrset = knot_pkt_rr(sec, i);
if (rrset->type != KNOT_RRTYPE_NSEC3)
continue;
if (knot_nsec3_iters(rrset->rrs.rdata) > KR_NSEC3_MAX_ITERATIONS) {
/* Avoid hashing with too many iterations.
* If we get here, the `sname` wildcard probably ends up bogus,
* but it gets downgraded to KR_RANK_INSECURE when validator
* gets to verifying one of these over-limit NSEC3 RRs. */
continue;
}
int ret = covers_name(&flags, rrset, sname);
if (ret != 0)
return ret;
if (flags & FLG_NAME_COVERED) {
return has_optout(rrset) ?
kr_error(KNOT_ERANGE) : kr_ok();
}
}
return kr_error(ENOENT);
}
int kr_nsec3_no_data(const knot_pkt_t *pkt, knot_section_t section_id,
const knot_dname_t *sname, uint16_t stype)
{
/* DS record may be also matched by an existing NSEC3 RR. */
int ret = nodata_find(pkt, section_id, sname, stype);
if (ret == 0) {
/* Satisfies RFC5155 8.5 and 8.6, both first paragraph. */
return ret;
}
/* Find closest provable encloser. */
const knot_dname_t *encloser_name = NULL;
const knot_rrset_t *covering_next_nsec3 = NULL;
ret = closest_encloser_proof(pkt, section_id, sname, &encloser_name,
NULL, &covering_next_nsec3);
if (ret != 0)
return ret;
if (kr_fails_assert(encloser_name && covering_next_nsec3))
return kr_error(EFAULT);
ret = matches_closest_encloser_wildcard(pkt, section_id,
encloser_name, stype);
if (ret == 0) {
/* Satisfies RFC5155 8.7 */
if (has_optout(covering_next_nsec3)) {
/* Opt-out is detected.
* Despite the fact that all records
* in the packet can be properly signed,
* AD bit must not be set due to rfc5155 9.2.
* Return appropriate code to the caller */
ret = kr_error(KNOT_ERANGE);
}
return ret;
}
if (!has_optout(covering_next_nsec3)) {
/* Bogus */
ret = kr_error(ENOENT);
} else {
/*
* Satisfies RFC5155 8.6 (QTYPE == DS), 2nd paragraph.
* Also satisfies ERRATA 3441 8.5 (QTYPE != DS), 3rd paragraph.
* - (wildcard) empty nonterminal
* derived from insecure delegation.
* Denial of existence can not be proven.
* Set error code to proceed insecure.
*/
ret = kr_error(KNOT_ERANGE);
}
return ret;
}
int kr_nsec3_ref_to_unsigned(const knot_pkt_t *pkt)
{
const knot_pktsection_t *sec = knot_pkt_section(pkt, KNOT_AUTHORITY);
if (!sec)
return kr_error(EINVAL);
for (unsigned i = 0; i < sec->count; ++i) {
const knot_rrset_t *ns = knot_pkt_rr(sec, i);
if (ns->type == KNOT_RRTYPE_DS)
return kr_error(EEXIST);
if (ns->type != KNOT_RRTYPE_NS)
continue;
bool nsec3_found = false;
for (unsigned j = 0; j < sec->count; ++j) {
const knot_rrset_t *nsec3 = knot_pkt_rr(sec, j);
if (nsec3->type == KNOT_RRTYPE_DS)
return kr_error(EEXIST);
if (nsec3->type != KNOT_RRTYPE_NSEC3)
continue;
nsec3_found = true;
/* nsec3 found, check if owner name matches the delegation name.
* Just skip in case of *any* errors. */
if (matches_name(nsec3, ns->owner) != kr_ok())
continue;
const uint8_t *bm = knot_nsec3_bitmap(nsec3->rrs.rdata);
uint16_t bm_size = knot_nsec3_bitmap_len(nsec3->rrs.rdata);
if (!bm)
return kr_error(EINVAL);
if (dnssec_nsec_bitmap_contains(bm, bm_size,
KNOT_RRTYPE_NS) &&
!dnssec_nsec_bitmap_contains(bm, bm_size,
KNOT_RRTYPE_DS) &&
!dnssec_nsec_bitmap_contains(bm, bm_size,
KNOT_RRTYPE_SOA)) {
/* Satisfies rfc5155, 8.9. paragraph 2 */
return kr_ok();
}
}
if (!nsec3_found)
return kr_error(DNSSEC_NOT_FOUND);
/* nsec3 that matches the delegation was not found.
* Check rfc5155, 8.9. paragraph 4.
* Find closest provable encloser.
*/
const knot_dname_t *encloser_name = NULL;
const knot_rrset_t *covering_next_nsec3 = NULL;
int ret = closest_encloser_proof(pkt, KNOT_AUTHORITY, ns->owner,
&encloser_name, NULL, &covering_next_nsec3);
if (ret != 0)
return kr_error(EINVAL);
if (has_optout(covering_next_nsec3)) {
return kr_error(KNOT_ERANGE);
} else {
return kr_error(EINVAL);
}
}
return kr_error(EINVAL);
}
int kr_nsec3_matches_name_and_type(const knot_rrset_t *nsec3,
const knot_dname_t *name, uint16_t type)
{
/* It's not secure enough to just check a single bit for (some) other types,
* but we don't (currently) only use this API for NS. See RFC 6840 sec. 4.
*/
if (kr_fails_assert(type == KNOT_RRTYPE_NS))
return kr_error(EINVAL);
int ret = matches_name(nsec3, name);
if (ret)
return kr_error(ret);
const uint8_t *bm = knot_nsec3_bitmap(nsec3->rrs.rdata);
uint16_t bm_size = knot_nsec3_bitmap_len(nsec3->rrs.rdata);
if (!bm)
return kr_error(EINVAL);
if (dnssec_nsec_bitmap_contains(bm, bm_size, type)) {
return kr_ok();
} else {
return kr_error(ENOENT);
}
}
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