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rbldnsd_ip4trie.c
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rbldnsd_ip4trie.c
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/* ip4trie dataset type: IP4 CIDR ranges with A and TXT values.
* Only one value per range allowed.
*/
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include "rbldnsd.h"
#include "btrie.h"
struct dsdata {
struct btrie *btrie;
const char *def_rr; /* default RR */
};
definedstype_update(ip4trie, DSTF_IP4REV, "set of (ip4cidr or ip6cidr, value) pairs");
static void ds_ip4trie_reset(struct dsdata *dsd, int UNUSED unused_freeall) {
memset(dsd, 0, sizeof(*dsd));
}
static void ds_ip4trie_start(struct dataset *ds) {
struct dsdata *dsd = ds->ds_dsd;
dsd->def_rr = def_rr;
if (!dsd->btrie)
dsd->btrie = btrie_init(ds->ds_mp);
}
static int
ds_ip4trie_line(struct dataset *ds, char *s, struct dsctx *dsc)
{
struct dsdata *dsd = ds->ds_dsd;
ip4addr_t a;
ip6oct_t ipv6_addr[IP6ADDR_FULL];
const char *orig;
int bits;
const char *rr;
unsigned rrl;
int not, ipv6 = 0;
if (*s == ':') {
if (!(rrl = parse_a_txt(s, &rr, def_rr, dsc)))
return 1;
if (!(dsd->def_rr = mp_dmemdup(ds->ds_mp, rr, rrl)))
return 0;
return 1;
}
if (*s == '!') {
not = 1;
++s;
SKIPSPACE(s);
}
else {
not = 0;
}
orig = s;
/* First try ip4 */
if ((bits = ip4cidr(orig, &a, &s)) < 0) {
/* Probably v6 address */
bits = ip6cidr(orig, ipv6_addr, &s);
if (bits >= 0) {
ipv6 = 1;
}
}
if (bits < 0 || (*s && !ISSPACE(*s) && !ISCOMMENT(*s) && *s != ':')) {
dswarn(dsc, "invalid address: %s", s);
return 0;
}
if (!ipv6) {
if (accept_in_cidr)
a &= ip4mask(bits);
else if (a & ~ip4mask(bits)) {
dswarn(dsc, "invalid range (non-zero host part): %s", s);
return 0;
}
if (dsc->dsc_ip4maxrange && dsc->dsc_ip4maxrange <= ~ip4mask(bits)) {
dswarn(dsc, "too large range (%u) ignored (%u max)",
~ip4mask(bits) + 1, dsc->dsc_ip4maxrange);
return 1;
}
}
else {
int non_zero_host = ip6mask(ipv6_addr, ipv6_addr, IP6ADDR_FULL, bits);
if (non_zero_host && !accept_in_cidr) {
dswarn(dsc, "invalid range (non-zero host part)");
return 1;
}
}
if (not)
rr = NULL;
else {
SKIPSPACE(s);
if (!*s || ISCOMMENT(*s))
rr = dsd->def_rr;
else if (!(rrl = parse_a_txt(s, &rr, dsd->def_rr, dsc)))
return 1;
else if (!(rr = mp_dmemdup(ds->ds_mp, rr, rrl)))
return 0;
}
int ret = -1;
if (ipv6) {
ret = btrie_add_prefix(dsd->btrie, ipv6_addr, bits, rr);
}
else {
memset(ipv6_addr, 0, 10);
ipv6_addr[10] = 0xffu;
ipv6_addr[11] = 0xffu;
ip4unpack(ipv6_addr + 12, a);
ret = btrie_add_prefix(dsd->btrie, ipv6_addr, 96 + bits, rr);
}
switch(ret) {
case BTRIE_OKAY:
return 1;
case BTRIE_DUPLICATE_PREFIX:
if (!ipv6) {
dswarn(dsc, "duplicated entry for ipv4 %s/%d", ip4atos(a), bits);
}
else {
dswarn(dsc, "duplicated entry for ipv6 %s/%d", ip6atos(ipv6_addr, IP6ADDR_FULL), bits);
}
return 1;
case BTRIE_ALLOC_FAILED:
default:
return 0; /* oom */
}
}
static int
ds_ip4trie_update(struct dataset *ds, char *s, struct dsctx *dsc)
{
/* Exactly the same for updates */
return ds_ip4trie_line(ds, s, dsc);
}
static void ds_ip4trie_finish(struct dataset *ds, struct dsctx *dsc) {
dsloaded(dsc, "%s", btrie_stats(ds->ds_dsd->btrie));
}
static int
ds_ip4trie_query(const struct dataset *ds, const struct dnsqinfo *qi,
struct dnspacket *pkt) {
const char *rr;
btrie_oct_t addr_bytes[IP6ADDR_FULL];
if (qi->qi_ip4valid) {
check_query_overwrites(qi);
// Convert to ipv4mapped
memset(addr_bytes, 0, 10);
addr_bytes[10] = 0xffu;
addr_bytes[11] = 0xffu;
ip4unpack(addr_bytes + 12, qi->qi_ip4);
rr = btrie_lookup(ds->ds_dsd->btrie, addr_bytes, 8 * IP6ADDR_FULL);
}
else if (qi->qi_ip6valid) {
check_query_overwrites(qi);
rr = btrie_lookup(ds->ds_dsd->btrie, qi->qi_ip6, 8 * IP6ADDR_FULL);
}
else {
return 0;
}
if (!rr)
return 0;
const char *subst = NULL;
if (qi->qi_tflag & NSQUERY_TXT) {
if (qi->qi_ip4valid) {
subst = ip4atos(qi->qi_ip4);
}
else {
subst = ip6atos(qi->qi_ip6, IP6ADDR_FULL);
}
}
addrr_a_txt(pkt, qi->qi_tflag, rr, subst, ds);
return NSQUERY_FOUND;
}
#ifndef NO_MASTER_DUMP
static inline int
increment_bit(ip4addr_t *addr, int bit)
{
ip4addr_t mask = (ip4addr_t)1 << (31 - bit);
if (*addr & mask) {
*addr &= ~mask;
return 1;
} else {
*addr |= mask;
return 0;
}
}
struct dump_context {
const struct dataset *ds;
FILE *f;
ip4addr_t prev_addr;
const char *prev_rr;
/* Keep stack of data inherited from parent prefixes */
const void *parent_data[33];
unsigned depth;
};
static void
dump_cb(const btrie_oct_t *prefix, unsigned len, const void *data, int post,
void *user_data)
{
struct dump_context *ctx = user_data;
ip4addr_t addr;
if (len > 32)
return; /* paranoia (or ipv6 for now, gah) */
addr = (prefix[0] << 24) + (prefix[1] << 16) + (prefix[2] << 8) + prefix[3];
addr &= len ? -((ip4addr_t)1 << (32 - len)) : 0;
if (post == 0) {
/* pre order visit (before child nodes are visited) */
/* push the inherited data stack down to our level */
for (; ctx->depth < len; ctx->depth++)
ctx->parent_data[ctx->depth + 1] = ctx->parent_data[ctx->depth];
ctx->parent_data[len] = data;
}
else {
/* post order - restore RR at end of prefix */
unsigned carry_bits;
/* increment address to one past the end of the current prefix */
for (carry_bits = 0; carry_bits < len; carry_bits++)
if (increment_bit(&addr, len - 1 - carry_bits) == 0)
break; /* no carry */
if (carry_bits == len)
return; /* wrapped - all done */
/* look up the stack one level for each bit of carry to get
* the inherited data value at the incremented address */
ctx->depth = len - 1 - carry_bits;
data = ctx->parent_data[ctx->depth];
}
if (data != ctx->prev_rr) {
if (addr != ctx->prev_addr) {
if (ctx->prev_rr)
dump_ip4range(ctx->prev_addr, addr - 1, ctx->prev_rr, ctx->ds, ctx->f);
ctx->prev_addr = addr;
}
/* else addr unchanged => zero-length range, ignore */
ctx->prev_rr = data;
}
/* else rr unchanged => merge current range with previous */
}
static void
ds_ip4trie_dump(const struct dataset *ds,
const unsigned char UNUSED *unused_odn,
FILE *f)
{
struct dump_context ctx;
memset(&ctx, 0, sizeof(ctx));
ctx.ds = ds;
ctx.f = f;
btrie_walk(ds->ds_dsd->btrie, dump_cb, &ctx);
/* flush final range */
if (ctx.prev_rr)
dump_ip4range(ctx.prev_addr, ip4mask(32), ctx.prev_rr, ds, f);
}
#endif