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/*
* namedb.h -- nsd(8) internal namespace database definitions
*
* Copyright (c) 2001-2006, NLnet Labs. All rights reserved.
*
* See LICENSE for the license.
*
*/
#ifndef _NAMEDB_H_
#define _NAMEDB_H_
#include <stdio.h>
#include "dname.h"
#include "dns.h"
#include "rbtree.h"
struct zone_options;
struct nsd_options;
#define NAMEDB_MAGIC "NSDdbV07"
#define NAMEDB_MAGIC_SIZE 8
typedef union rdata_atom rdata_atom_type;
typedef struct rrset rrset_type;
typedef struct rr rr_type;
/*
* A domain name table supporting fast insert and search operations.
*/
typedef struct domain_table domain_table_type;
typedef struct domain domain_type;
typedef struct zone zone_type;
struct domain_table
{
region_type *region;
rbtree_t *names_to_domains;
domain_type *root;
};
struct domain
{
rbnode_t node;
domain_type *parent;
domain_type *wildcard_child_closest_match;
rrset_type *rrsets;
#ifdef NSEC3
/* (if nsec3 chain complete) always the covering nsec3 record */
domain_type *nsec3_cover;
/* the nsec3 that covers the wildcard child of this domain. */
domain_type *nsec3_wcard_child_cover;
/* for the DS case we must answer on the parent side of zone cut */
domain_type *nsec3_ds_parent_cover;
/* the NSEC3 domain that has a hash-base32 <= than this dname. */
/* or NULL (no smaller one within this zone)
* this variable is used to look up the NSEC3 record that matches
* or covers a given b64-encoded-hash-string domain name.
* The result of the lookup is stored in the *_cover variables.
* The variable makes it possible to perform a rbtree lookup for
* a name, then take this 'jump' to the previous element that contains
* an NSEC3 record, with hopefully the correct parameters. */
domain_type *nsec3_lookup;
#endif
uint32_t number; /* Unique domain name number. */
/*
* This domain name exists (see wildcard clarification draft).
*/
unsigned is_existing : 1;
unsigned is_apex : 1;
#ifdef NSEC3
/* if the domain has an NSEC3 for it, use cover ptr to get it. */
unsigned nsec3_is_exact : 1;
/* same but on parent side */
unsigned nsec3_ds_parent_is_exact : 1;
#endif
};
struct zone
{
zone_type *next;
domain_type *apex;
rrset_type *soa_rrset;
rrset_type *soa_nx_rrset; /* see bug #103 */
rrset_type *ns_rrset;
#ifdef NSEC3
rr_type *nsec3_soa_rr; /* rrset with SOA bit set */
domain_type *nsec3_last; /* last domain with nsec3, wraps */
#endif
struct zone_options *opts;
uint32_t number;
uint8_t* dirty; /* array of dirty-flags, per child */
unsigned is_secure : 1; /* zone uses DNSSEC */
unsigned updated : 1; /* zone SOA was updated */
unsigned is_ok : 1; /* zone has not expired. */
};
/* a RR in DNS */
struct rr {
domain_type *owner;
rdata_atom_type *rdatas;
uint32_t ttl;
uint16_t type;
uint16_t klass;
uint16_t rdata_count;
};
/*
* An RRset consists of at least one RR. All RRs are from the same
* zone.
*/
struct rrset
{
rrset_type *next;
zone_type *zone;
rr_type *rrs;
uint16_t rr_count;
};
/*
* The field used is based on the wireformat the atom is stored in.
* The allowed wireformats are defined by the rdata_wireformat_type
* enumeration.
*/
union rdata_atom
{
/* RDATA_WF_COMPRESSED_DNAME, RDATA_WF_UNCOMPRESSED_DNAME */
domain_type *domain;
/* Default. */
uint16_t *data;
};
/*
* Create a new domain_table containing only the root domain.
*/
domain_table_type *domain_table_create(region_type *region);
/*
* Search the domain table for a match and the closest encloser.
*/
int domain_table_search(domain_table_type *table,
const dname_type *dname,
domain_type **closest_match,
domain_type **closest_encloser);
/*
* The number of domains stored in the table (minimum is one for the
* root domain).
*/
static inline uint32_t
domain_table_count(domain_table_type *table)
{
return table->names_to_domains->count;
}
/*
* Find the specified dname in the domain_table. NULL is returned if
* there is no exact match.
*/
domain_type *domain_table_find(domain_table_type *table,
const dname_type *dname);
/*
* Insert a domain name in the domain table. If the domain name is
* not yet present in the table it is copied and a new dname_info node
* is created (as well as for the missing parent domain names, if
* any). Otherwise the domain_type that is already in the
* domain_table is returned.
*/
domain_type *domain_table_insert(domain_table_type *table,
const dname_type *dname);
/*
* Iterate over all the domain names in the domain tree.
*/
typedef int (*domain_table_iterator_type)(domain_type *node,
void *user_data);
int domain_table_iterate(domain_table_type *table,
domain_table_iterator_type iterator,
void *user_data);
/*
* Add an RRset to the specified domain. Updates the is_existing flag
* as required.
*/
void domain_add_rrset(domain_type *domain, rrset_type *rrset);
rrset_type *domain_find_rrset(domain_type *domain, zone_type *zone, uint16_t type);
rrset_type *domain_find_any_rrset(domain_type *domain, zone_type *zone);
zone_type *domain_find_zone(domain_type *domain);
zone_type *domain_find_parent_zone(zone_type *zone);
domain_type *domain_find_ns_rrsets(domain_type *domain, zone_type *zone, rrset_type **ns);
int domain_is_glue(domain_type *domain, zone_type *zone);
rrset_type *domain_find_non_cname_rrset(domain_type *domain, zone_type *zone);
domain_type *domain_wildcard_child(domain_type *domain);
int zone_is_secure(zone_type *zone);
static inline const dname_type *
domain_dname(domain_type *domain)
{
return (const dname_type *) domain->node.key;
}
static inline domain_type *
domain_previous(domain_type *domain)
{
rbnode_t *prev = rbtree_previous((rbnode_t *) domain);
return prev == RBTREE_NULL ? NULL : (domain_type *) prev;
}
static inline domain_type *
domain_next(domain_type *domain)
{
rbnode_t *next = rbtree_next((rbnode_t *) domain);
return next == RBTREE_NULL ? NULL : (domain_type *) next;
}
/*
* The type covered by the signature in the specified RRSIG RR.
*/
uint16_t rr_rrsig_type_covered(rr_type *rr);
typedef struct namedb namedb_type;
struct namedb
{
region_type *region;
domain_table_type *domains;
zone_type *zones;
size_t zone_count;
char *filename;
FILE *fd;
/* the timestamp on the ixfr.db file */
struct timeval diff_timestamp;
/* the CRC on the nsd.db file and position of CRC in the db file */
uint32_t crc;
off_t crc_pos;
/* if diff_skip=1, diff_pos contains the nsd.diff place to continue */
uint8_t diff_skip;
off_t diff_pos;
};
static inline int rdata_atom_is_domain(uint16_t type, size_t index);
static inline domain_type *
rdata_atom_domain(rdata_atom_type atom)
{
return atom.domain;
}
static inline uint16_t
rdata_atom_size(rdata_atom_type atom)
{
return *atom.data;
}
static inline uint8_t *
rdata_atom_data(rdata_atom_type atom)
{
return (uint8_t *) (atom.data + 1);
}
/*
* Find the zone for the specified DOMAIN in DB.
*/
zone_type *namedb_find_zone(namedb_type *db, domain_type *domain);
/* dbcreate.c */
struct namedb *namedb_new(const char *filename);
int namedb_save(struct namedb *db);
void namedb_discard(struct namedb *db);
/* dbaccess.c */
int namedb_lookup (struct namedb *db,
const dname_type *dname,
domain_type **closest_match,
domain_type **closest_encloser);
/* pass number of children (to alloc in dirty array */
struct namedb *namedb_open(const char *filename, struct nsd_options* opt,
size_t num_children);
void namedb_fd_close(struct namedb *db);
void namedb_close(struct namedb *db);
static inline int
rdata_atom_is_domain(uint16_t type, size_t index)
{
const rrtype_descriptor_type *descriptor
= rrtype_descriptor_by_type(type);
return (index < descriptor->maximum
&& (descriptor->wireformat[index] == RDATA_WF_COMPRESSED_DNAME
|| descriptor->wireformat[index] == RDATA_WF_UNCOMPRESSED_DNAME));
}
static inline rdata_wireformat_type
rdata_atom_wireformat_type(uint16_t type, size_t index)
{
const rrtype_descriptor_type *descriptor
= rrtype_descriptor_by_type(type);
assert(index < descriptor->maximum);
return (rdata_wireformat_type) descriptor->wireformat[index];
}
static inline uint16_t
rrset_rrtype(rrset_type *rrset)
{
assert(rrset);
assert(rrset->rr_count > 0);
return rrset->rrs[0].type;
}
static inline uint16_t
rrset_rrclass(rrset_type *rrset)
{
assert(rrset);
assert(rrset->rr_count > 0);
return rrset->rrs[0].klass;
}
#endif
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