abort();
}
-#define IN6_ADDR_EQUALP(a, b) \
- (!memcmp((a).s6_addr, (b).s6_addr, sizeof((a).s6_addr)))
-
-int adns__genaddr_equal_p(int af, const union gen_addr *a,
- int bf, const void *b) {
- const union gen_addr *bb= b;
- if (af != bf) return 0;
- switch (af) {
+int adns__addrs_equal_raw(const struct sockaddr *a,
+ int bf, const void *b) {
+ if (a->sa_family != bf) return 0;
+ switch (a->sa_family) {
AF_CASES(af);
- af_inet: return a->v4.s_addr == bb->v4.s_addr;
- af_inet6: return IN6_ADDR_EQUALP(a->v6, bb->v6);
- default: unknown_af(af); return -1;
+ af_inet:
+ return ((const struct sockaddr_in*)a)->sin_addr.s_addr ==
+ ((const struct in_addr*)b)->s_addr;
+ af_inet6:
+ return !memcmp(&((const struct sockaddr_in6*)a)->sin6_addr,
+ b, sizeof(struct in6_addr));
+ default: unknown_af(a->sa_family); return -1;
}
}
-int adns__sockaddr_equal_p(const struct sockaddr *sa,
- const struct sockaddr *sb) {
- if (sa->sa_family != sb->sa_family) return 0;
+int adns__addrs_equal(const adns_sockaddr *a, const adns_sockaddr *b) {
+ return adns__addrs_equal_raw(&a->sa, b->sa.sa_family,
+ adns__sockaddr_addr(&b->sa));
+}
+
+int adns__sockaddrs_equal(const struct sockaddr *sa,
+ const struct sockaddr *sb) {
+ if (!adns__addrs_equal_raw(sa, sb->sa_family, adns__sockaddr_addr(sb)))
+ return 0;
switch (sa->sa_family) {
AF_CASES(af);
af_inet: {
const struct sockaddr_in *sina= CSIN(sa), *sinb= CSIN(sb);
- return (sina->sin_addr.s_addr == sinb->sin_addr.s_addr &&
- sina->sin_port == sinb->sin_port);
+ return sina->sin_port == sinb->sin_port;
}
af_inet6: {
/* Don't check the flowlabel. That's apparently useful for routing
* performance, but doesn't affect the address in any important
* respect. */
const struct sockaddr_in6 *sin6a= CSIN6(sa), *sin6b= CSIN6(sb);
- return (IN6_ADDR_EQUALP(sin6a->sin6_addr, sin6b->sin6_addr) &&
- sin6a->sin6_port == sin6b->sin6_port &&
- sin6a->sin6_scope_id == sin6b->sin6_scope_id);
+ return sin6a->sin6_port == sin6b->sin6_port &&
+ sin6a->sin6_scope_id == sin6b->sin6_scope_id;
}
default:
unknown_af(sa->sa_family);
}
}
-void adns__prefix_mask(int af, int len, union gen_addr *mask_r) {
+void adns__prefix_mask(adns_sockaddr *sa, int len) {
+ int af= sa->sa.sa_family;
switch (af) {
AF_CASES(af);
af_inet:
assert(len <= 32);
- mask_r->v4.s_addr= htonl(!len ? 0 : 0xffffffff << (32-len));
+ sa->inet.sin_addr.s_addr= htonl(!len ? 0 : 0xffffffff << (32-len));
break;
af_inet6: {
int i= len/8, j= len%8;
- unsigned char *m= mask_r->v6.s6_addr;
+ unsigned char *m= sa->inet6.sin6_addr.s6_addr;
assert(len <= 128);
memset(m, 0xff, i);
if (j) m[i++]= (0xff << (8-j)) & 0xff;
}
}
-int adns__guess_prefix_length(int af, const union gen_addr *addr) {
+int adns__guess_prefix_length(const adns_sockaddr *sa) {
+ int af= sa->sa.sa_family;
switch (af) {
AF_CASES(af);
af_inet: {
- unsigned a= (ntohl(addr->v4.s_addr) >> 24) & 0xff;
+ unsigned a= (ntohl(sa->inet.sin_addr.s_addr) >> 24) & 0xff;
if (a < 128) return 8;
else if (a < 192) return 16;
else if (a < 224) return 24;
}
}
-int adns__addr_match_p(int addraf, const union gen_addr *addr,
- int netaf, const union gen_addr *base,
- const union gen_addr *mask)
+int adns__addr_matches(int af, const void *addr,
+ const adns_sockaddr *base, const adns_sockaddr *mask)
{
- if (addraf != netaf) return 0;
- switch (addraf) {
+ assert(base->sa.sa_family == mask->sa.sa_family);
+ if (af != base->sa.sa_family) return 0;
+ switch (af) {
AF_CASES(af);
- af_inet:
- return (addr->v4.s_addr & mask->v4.s_addr) == base->v4.s_addr;
+ af_inet: {
+ const struct in_addr *v4 = addr;
+ return (v4->s_addr & mask->inet.sin_addr.s_addr)
+ == base->inet.sin_addr.s_addr;
+ }
af_inet6: {
int i;
- const char *a= addr->v6.s6_addr;
- const char *b= base->v6.s6_addr;
- const char *m= mask->v6.s6_addr;
+ const char *a= addr;
+ const char *b= base->inet6.sin6_addr.s6_addr;
+ const char *m= mask->inet6.sin6_addr.s6_addr;
for (i = 0; i < 16; i++)
if ((a[i] & m[i]) != b[i]) return 0;
return 1;
} break;
default:
- unknown_af(addraf);
+ unknown_af(af);
return -1;
}
}
-void adns__sockaddr_extract(const struct sockaddr *sa,
- union gen_addr *a_r, int *port_r) {
+const void *adns__sockaddr_addr(const struct sockaddr *sa) {
switch (sa->sa_family) {
AF_CASES(af);
af_inet: {
const struct sockaddr_in *sin = CSIN(sa);
- if (port_r) *port_r= ntohs(sin->sin_port);
- if (a_r) a_r->v4= sin->sin_addr;
- break;
+ return &sin->sin_addr;
}
af_inet6: {
const struct sockaddr_in6 *sin6 = CSIN6(sa);
- if (port_r) *port_r= ntohs(sin6->sin6_port);
- if (a_r) a_r->v6= sin6->sin6_addr;
- break;
+ return &sin6->sin6_addr;
}
default:
unknown_af(sa->sa_family);
}
}
-void adns__sockaddr_inject(const union gen_addr *a, int port,
- struct sockaddr *sa) {
- switch (sa->sa_family) {
+void adns__addr_inject(const void *a, adns_sockaddr *sa) {
+ switch (sa->sa.sa_family) {
AF_CASES(af);
af_inet: {
- struct sockaddr_in *sin = SIN(sa);
- if (port != -1) sin->sin_port= htons(port);
- if (a) sin->sin_addr= a->v4;
+ struct sockaddr_in *sin = &sa->inet;
+ memcpy(&sin->sin_addr, a, sizeof(sin->sin_addr));
break;
}
af_inet6: {
- struct sockaddr_in6 *sin6 = SIN6(sa);
- if (port != -1) sin6->sin6_port= htons(port);
- if (a) sin6->sin6_addr= a->v6;
+ struct sockaddr_in6 *sin6 = &sa->inet6;
+ memcpy(&sin6->sin6_addr, a, sizeof(sin6->sin6_addr));
break;
}
default:
- unknown_af(sa->sa_family);
+ unknown_af(sa->sa.sa_family);
}
}
return i;
}
-static void inet_rev_mkaddr(union gen_addr *addr, const byte *ipv) {
- addr->v4.s_addr= htonl((ipv[3]<<24) | (ipv[2]<<16) |
- (ipv[1]<<8) | (ipv[0]));
+static void inet_rev_mkaddr(adns_sockaddr *addr, const byte *ipv) {
+ struct in_addr *v4 = &addr->inet.sin_addr;
+ v4->s_addr= htonl((ipv[3]<<24) | (ipv[2]<<16) |
+ (ipv[1]<<8) | (ipv[0]));
}
static int inet6_rev_parsecomp(const char *p, size_t n) {
else return -1;
}
-static void inet6_rev_mkaddr(union gen_addr *addr, const byte *ipv) {
- unsigned char *a= addr->v6.s6_addr;
+static void inet6_rev_mkaddr(adns_sockaddr *addr, const byte *ipv) {
+ struct in6_addr *v6 = &addr->inet6.sin6_addr;
+ unsigned char *a= v6->s6_addr;
int i;
for (i=0; i<16; i++)
* if it was unintelligible.
*/
- void (*rev_mkaddr)(union gen_addr *addr, const byte *ipv);
- /* write out the parsed address from a vector of parsed components */
+ void (*rev_mkaddr)(adns_sockaddr *addr, const byte *ipv);
+ /* write out the parsed protocol address from a vector of parsed components */
const char *const tail[3]; /* tail label names */
} revparse_domains[NREVDOMAINS] = {
}
int adns__revparse_done(struct revparse_state *rps, int nlabels,
- adns_rrtype *rrtype_r, struct af_addr *addr_r) {
+ adns_rrtype *rrtype_r, adns_sockaddr *addr_r) {
unsigned f= REVDOMAIN_MAP(rps, nlabels);
const struct revparse_domain *rpd;
unsigned d;
rpd= &revparse_domains[found];
*rrtype_r= rpd->rrtype;
- addr_r->af= rpd->af;
- rpd->rev_mkaddr(&addr_r->addr, rps->ipv[found]);
+ addr_r->sa.sa_family= rpd->af;
+ rpd->rev_mkaddr(addr_r, rps->ipv[found]);
return 0;
}