Rivoreo Source Code Repositories
src.rivoreo.one / systemd-stable / v239-50 / . / src / resolve / resolved-dns-rr.h
blob: 2f08b6119e2c898dd3388ad6ed04081869fc6e11 [file] [log] [blame] [raw]
/* SPDX-License-Identifier: LGPL-2.1+ */
#pragma once
/***
***/
#include <netinet/in.h>
#include "bitmap.h"
#include "dns-type.h"
#include "hashmap.h"
#include "in-addr-util.h"
#include "list.h"
#include "string-util.h"
typedef struct DnsResourceKey DnsResourceKey;
typedef struct DnsResourceRecord DnsResourceRecord;
typedef struct DnsTxtItem DnsTxtItem;
/* DNSKEY RR flags */
#define DNSKEY_FLAG_SEP (UINT16_C(1) << 0)
#define DNSKEY_FLAG_REVOKE (UINT16_C(1) << 7)
#define DNSKEY_FLAG_ZONE_KEY (UINT16_C(1) << 8)
/* mDNS RR flags */
#define MDNS_RR_CACHE_FLUSH (UINT16_C(1) << 15)
/* DNSSEC algorithm identifiers, see
* http://tools.ietf.org/html/rfc4034#appendix-A.1 and
* https://www.iana.org/assignments/dns-sec-alg-numbers/dns-sec-alg-numbers.xhtml */
enum {
DNSSEC_ALGORITHM_RSAMD5 = 1,
DNSSEC_ALGORITHM_DH,
DNSSEC_ALGORITHM_DSA,
DNSSEC_ALGORITHM_ECC,
DNSSEC_ALGORITHM_RSASHA1,
DNSSEC_ALGORITHM_DSA_NSEC3_SHA1,
DNSSEC_ALGORITHM_RSASHA1_NSEC3_SHA1,
DNSSEC_ALGORITHM_RSASHA256 = 8, /* RFC 5702 */
DNSSEC_ALGORITHM_RSASHA512 = 10, /* RFC 5702 */
DNSSEC_ALGORITHM_ECC_GOST = 12, /* RFC 5933 */
DNSSEC_ALGORITHM_ECDSAP256SHA256 = 13, /* RFC 6605 */
DNSSEC_ALGORITHM_ECDSAP384SHA384 = 14, /* RFC 6605 */
DNSSEC_ALGORITHM_ED25519 = 15, /* RFC 8080 */
DNSSEC_ALGORITHM_ED448 = 16, /* RFC 8080 */
DNSSEC_ALGORITHM_INDIRECT = 252,
DNSSEC_ALGORITHM_PRIVATEDNS,
DNSSEC_ALGORITHM_PRIVATEOID,
_DNSSEC_ALGORITHM_MAX_DEFINED
};
/* DNSSEC digest identifiers, see
* https://www.iana.org/assignments/ds-rr-types/ds-rr-types.xhtml */
enum {
DNSSEC_DIGEST_SHA1 = 1,
DNSSEC_DIGEST_SHA256 = 2, /* RFC 4509 */
DNSSEC_DIGEST_GOST_R_34_11_94 = 3, /* RFC 5933 */
DNSSEC_DIGEST_SHA384 = 4, /* RFC 6605 */
_DNSSEC_DIGEST_MAX_DEFINED
};
/* DNSSEC NSEC3 hash algorithms, see
* https://www.iana.org/assignments/dnssec-nsec3-parameters/dnssec-nsec3-parameters.xhtml */
enum {
NSEC3_ALGORITHM_SHA1 = 1,
_NSEC3_ALGORITHM_MAX_DEFINED
};
struct DnsResourceKey {
unsigned n_ref; /* (unsigned -1) for const keys, see below */
uint16_t class, type;
char *_name; /* don't access directly, use dns_resource_key_name()! */
};
/* Creates a temporary resource key. This is only useful to quickly
* look up something, without allocating a full DnsResourceKey object
* for it. Note that it is not OK to take references to this kind of
* resource key object. */
#define DNS_RESOURCE_KEY_CONST(c, t, n) \
((DnsResourceKey) { \
.n_ref = (unsigned) -1, \
.class = c, \
.type = t, \
._name = (char*) n, \
})
struct DnsTxtItem {
size_t length;
LIST_FIELDS(DnsTxtItem, items);
uint8_t data[];
};
struct DnsResourceRecord {
unsigned n_ref;
DnsResourceKey *key;
char *to_string;
uint32_t ttl;
usec_t expiry; /* RRSIG signature expiry */
/* How many labels to strip to determine "signer" of the RRSIG (aka, the zone). -1 if not signed. */
unsigned n_skip_labels_signer;
/* How many labels to strip to determine "synthesizing source" of this RR, i.e. the wildcard's immediate parent. -1 if not signed. */
unsigned n_skip_labels_source;
bool unparseable:1;
bool wire_format_canonical:1;
void *wire_format;
size_t wire_format_size;
size_t wire_format_rdata_offset;
union {
struct {
void *data;
size_t data_size;
} generic, opt;
struct {
uint16_t priority;
uint16_t weight;
uint16_t port;
char *name;
} srv;
struct {
char *name;
} ptr, ns, cname, dname;
struct {
char *cpu;
char *os;
} hinfo;
struct {
DnsTxtItem *items;
} txt, spf;
struct {
struct in_addr in_addr;
} a;
struct {
struct in6_addr in6_addr;
} aaaa;
struct {
char *mname;
char *rname;
uint32_t serial;
uint32_t refresh;
uint32_t retry;
uint32_t expire;
uint32_t minimum;
} soa;
struct {
uint16_t priority;
char *exchange;
} mx;
/* https://tools.ietf.org/html/rfc1876 */
struct {
uint8_t version;
uint8_t size;
uint8_t horiz_pre;
uint8_t vert_pre;
uint32_t latitude;
uint32_t longitude;
uint32_t altitude;
} loc;
/* https://tools.ietf.org/html/rfc4255#section-3.1 */
struct {
uint8_t algorithm;
uint8_t fptype;
void *fingerprint;
size_t fingerprint_size;
} sshfp;
/* http://tools.ietf.org/html/rfc4034#section-2.1 */
struct {
uint16_t flags;
uint8_t protocol;
uint8_t algorithm;
void* key;
size_t key_size;
} dnskey;
/* http://tools.ietf.org/html/rfc4034#section-3.1 */
struct {
uint16_t type_covered;
uint8_t algorithm;
uint8_t labels;
uint32_t original_ttl;
uint32_t expiration;
uint32_t inception;
uint16_t key_tag;
char *signer;
void *signature;
size_t signature_size;
} rrsig;
/* https://tools.ietf.org/html/rfc4034#section-4.1 */
struct {
char *next_domain_name;
Bitmap *types;
} nsec;
/* https://tools.ietf.org/html/rfc4034#section-5.1 */
struct {
uint16_t key_tag;
uint8_t algorithm;
uint8_t digest_type;
void *digest;
size_t digest_size;
} ds;
struct {
uint8_t algorithm;
uint8_t flags;
uint16_t iterations;
void *salt;
size_t salt_size;
void *next_hashed_name;
size_t next_hashed_name_size;
Bitmap *types;
} nsec3;
/* https://tools.ietf.org/html/draft-ietf-dane-protocol-23 */
struct {
uint8_t cert_usage;
uint8_t selector;
uint8_t matching_type;
void *data;
size_t data_size;
} tlsa;
/* https://tools.ietf.org/html/rfc6844 */
struct {
uint8_t flags;
char *tag;
void *value;
size_t value_size;
} caa;
};
};
static inline const void* DNS_RESOURCE_RECORD_RDATA(DnsResourceRecord *rr) {
if (!rr)
return NULL;
if (!rr->wire_format)
return NULL;
assert(rr->wire_format_rdata_offset <= rr->wire_format_size);
return (uint8_t*) rr->wire_format + rr->wire_format_rdata_offset;
}
static inline size_t DNS_RESOURCE_RECORD_RDATA_SIZE(DnsResourceRecord *rr) {
if (!rr)
return 0;
if (!rr->wire_format)
return 0;
assert(rr->wire_format_rdata_offset <= rr->wire_format_size);
return rr->wire_format_size - rr->wire_format_rdata_offset;
}
static inline uint8_t DNS_RESOURCE_RECORD_OPT_VERSION_SUPPORTED(DnsResourceRecord *rr) {
assert(rr);
assert(rr->key->type == DNS_TYPE_OPT);
return ((rr->ttl >> 16) & 0xFF) == 0;
}
DnsResourceKey* dns_resource_key_new(uint16_t class, uint16_t type, const char *name);
DnsResourceKey* dns_resource_key_new_redirect(const DnsResourceKey *key, const DnsResourceRecord *cname);
int dns_resource_key_new_append_suffix(DnsResourceKey **ret, DnsResourceKey *key, char *name);
DnsResourceKey* dns_resource_key_new_consume(uint16_t class, uint16_t type, char *name);
DnsResourceKey* dns_resource_key_ref(DnsResourceKey *key);
DnsResourceKey* dns_resource_key_unref(DnsResourceKey *key);
const char* dns_resource_key_name(const DnsResourceKey *key);
bool dns_resource_key_is_address(const DnsResourceKey *key);
bool dns_resource_key_is_dnssd_ptr(const DnsResourceKey *key);
int dns_resource_key_equal(const DnsResourceKey *a, const DnsResourceKey *b);
int dns_resource_key_match_rr(const DnsResourceKey *key, DnsResourceRecord *rr, const char *search_domain);
int dns_resource_key_match_cname_or_dname(const DnsResourceKey *key, const DnsResourceKey *cname, const char *search_domain);
int dns_resource_key_match_soa(const DnsResourceKey *key, const DnsResourceKey *soa);
/* _DNS_{CLASS,TYPE}_STRING_MAX include one byte for NUL, which we use for space instead below.
* DNS_HOSTNAME_MAX does not include the NUL byte, so we need to add 1. */
#define DNS_RESOURCE_KEY_STRING_MAX (_DNS_CLASS_STRING_MAX + _DNS_TYPE_STRING_MAX + DNS_HOSTNAME_MAX + 1)
char* dns_resource_key_to_string(const DnsResourceKey *key, char *buf, size_t buf_size);
ssize_t dns_resource_record_payload(DnsResourceRecord *rr, void **out);
DEFINE_TRIVIAL_CLEANUP_FUNC(DnsResourceKey*, dns_resource_key_unref);
static inline bool dns_key_is_shared(const DnsResourceKey *key) {
return IN_SET(key->type, DNS_TYPE_PTR);
}
bool dns_resource_key_reduce(DnsResourceKey **a, DnsResourceKey **b);
DnsResourceRecord* dns_resource_record_new(DnsResourceKey *key);
DnsResourceRecord* dns_resource_record_new_full(uint16_t class, uint16_t type, const char *name);
DnsResourceRecord* dns_resource_record_ref(DnsResourceRecord *rr);
DnsResourceRecord* dns_resource_record_unref(DnsResourceRecord *rr);
int dns_resource_record_new_reverse(DnsResourceRecord **ret, int family, const union in_addr_union *address, const char *name);
int dns_resource_record_new_address(DnsResourceRecord **ret, int family, const union in_addr_union *address, const char *name);
int dns_resource_record_equal(const DnsResourceRecord *a, const DnsResourceRecord *b);
const char* dns_resource_record_to_string(DnsResourceRecord *rr);
DnsResourceRecord *dns_resource_record_copy(DnsResourceRecord *rr);
DEFINE_TRIVIAL_CLEANUP_FUNC(DnsResourceRecord*, dns_resource_record_unref);
int dns_resource_record_to_wire_format(DnsResourceRecord *rr, bool canonical);
int dns_resource_record_signer(DnsResourceRecord *rr, const char **ret);
int dns_resource_record_source(DnsResourceRecord *rr, const char **ret);
int dns_resource_record_is_signer(DnsResourceRecord *rr, const char *zone);
int dns_resource_record_is_synthetic(DnsResourceRecord *rr);
int dns_resource_record_clamp_ttl(DnsResourceRecord **rr, uint32_t max_ttl);
DnsTxtItem *dns_txt_item_free_all(DnsTxtItem *i);
bool dns_txt_item_equal(DnsTxtItem *a, DnsTxtItem *b);
DnsTxtItem *dns_txt_item_copy(DnsTxtItem *i);
int dns_txt_item_new_empty(DnsTxtItem **ret);
void dns_resource_record_hash_func(const void *i, struct siphash *state);
extern const struct hash_ops dns_resource_key_hash_ops;
extern const struct hash_ops dns_resource_record_hash_ops;
int dnssec_algorithm_to_string_alloc(int i, char **ret);
int dnssec_algorithm_from_string(const char *s) _pure_;
int dnssec_digest_to_string_alloc(int i, char **ret);
int dnssec_digest_from_string(const char *s) _pure_;