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tinysvcmdns.c
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tinysvcmdns.c
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// This file is the concatenation of mdnsd.c and mdns.c
// from tinysvcmdns with minor modifications
// The code was taken from https://bitbucket.org/geekman/tinysvcmdns at revision e34b562
/*
* tinysvcmdns - a tiny MDNS implementation for publishing services
* Copyright (C) 2011 Darell Tan
* All rights reserved.
* Updated many times by Mike Brady (c) 2014 -- 2019
* Includes fixes for CVE-12087 and CVE-2017-12130
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "tinysvcmdns.h"
#include "common.h"
#define DEBUG_PRINTF(...) debug(3, __VA_ARGS__)
#define log_message(level, ...) \
do { \
switch (level) { \
case LOG_ERR: \
warn(__VA_ARGS__); \
break; \
default: \
debug(3, __VA_ARGS__); \
} \
} while (0)
//******************************************************//
// mdns.c //
//******************************************************//
#include <assert.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#ifdef _WIN32
#include <in6addr.h>
#include <winsock.h>
#else
#include <netinet/in.h>
#endif
// See RFC 6762 Section 10 for an account of two TTLs -- 120 seconds for rrs with a host name as the
// record's name
// or a host name in the record's rdata
// 75 minutes for everything else.
// https://tools.ietf.org/html/rfc6762
#define DEFAULT_TTL_FOR_RECORD_WITH_HOSTNAME 120
#define DEFAULT_TTL 4500
struct name_comp {
uint8_t *label; // label
size_t pos; // position in msg
struct name_comp *next;
};
// ----- label functions -----
// duplicates a name
inline uint8_t *dup_nlabel(const uint8_t *n) {
if (n == NULL)
return NULL;
assert(n[0] <= 63); // prevent mis-use
return (uint8_t *)strdup((char *)n);
}
// duplicates a label
uint8_t *dup_label(const uint8_t *label) {
int len = *label + 1;
if (len > 63)
return NULL;
uint8_t *newlabel = malloc(len + 1);
if (newlabel)
strncpy((char *)newlabel, (char *)label, len);
else
die("could not allocate memory for \"newlabel\" in tinysvcmdns");
newlabel[len] = '\0';
return newlabel;
}
uint8_t *join_nlabel(const uint8_t *n1, const uint8_t *n2) {
int len1, len2;
uint8_t *s;
assert(n1[0] <= 63 && n2[0] <= 63); // detect misuse
len1 = strlen((char *)n1);
len2 = strlen((char *)n2);
s = malloc(len1 + len2 + 1);
if (s) {
memcpy((char *)s, (char *)n1, len1);
memcpy((char *)s + len1, (char *)n2, len2);
s[len1 + len2] = '\0';
} else {
die("can not allocate memory for \"s\" in tinysvcmdns");
}
return s;
}
// returns a human-readable name label in dotted form
char *nlabel_to_str(const uint8_t *name) {
char *label, *labelp;
const uint8_t *p;
size_t buf_len = 256;
if (name == NULL)
return NULL;
label = labelp = malloc(buf_len);
if (label) {
for (p = name; *p; p++) {
uint8_t label_len = *p;
if (buf_len <= label_len)
break;
strncpy(labelp, (char *)p + 1, label_len);
labelp += label_len;
*labelp = '.';
labelp++;
buf_len -= label_len + 1;
p += label_len;
}
// avoid writing NULL past end of buffer
if (buf_len == 0)
labelp--;
*labelp = '\0';
} else {
die("could not allocate memory for \"label\" in tinysvcmdns.c.");
}
return label;
}
// returns the length of a label field
// does NOT uncompress the field, so it could be as small as 2 bytes
// or 1 for the root
static size_t label_len(uint8_t *pkt_buf, size_t pkt_len, size_t off) {
uint8_t *p;
uint8_t *e = pkt_buf + pkt_len;
size_t len = 0;
for (p = pkt_buf + off; p < e; p++) {
if (*p == 0) {
return len + 1;
} else if ((*p & 0xC0) == 0xC0) {
return len + 2;
} else {
len += *p + 1;
p += *p;
}
}
return len;
}
// creates a label
// free() after use
uint8_t *create_label(const char *txt) {
int len;
uint8_t *s;
// assert(txt != NULL);
if (txt == NULL)
return NULL;
len = strlen(txt);
if (len > 63)
return NULL;
s = malloc(len + 2);
if (s) {
s[0] = len;
memcpy((char *)s + 1, txt, len);
s[len + 1] = '\0';
} else {
die("can not allocate memory for \"s\" 2 in tinysvcmdns.");
}
return s;
}
// creates a uncompressed name label given a DNS name like "apple.b.com"
// free() after use
uint8_t *create_nlabel(const char *name) {
char *label;
char *p, *e, *lenpos;
int len = 0;
assert(name != NULL);
len = strlen(name);
label = malloc(len + 1 + 1);
if (label == NULL)
return NULL;
memcpy((char *)label + 1, name, len);
label[len + 1] = '\0';
p = label;
e = p + len;
lenpos = p;
while (p < e) {
*lenpos = 0;
char *dot = memchr(p + 1, '.', e - p - 1);
if (dot == NULL)
dot = e + 1;
*lenpos = dot - p - 1;
p = dot;
lenpos = dot;
}
return (uint8_t *)label;
}
// copies a label from the buffer into a newly-allocated string
// free() after use
static uint8_t *copy_label(uint8_t *pkt_buf, size_t pkt_len, size_t off) {
int len;
if (off > pkt_len)
return NULL;
len = pkt_buf[off] + 1;
if (off + len > pkt_len) {
DEBUG_PRINTF("label length exceeds packet buffer\n");
return NULL;
}
return dup_label(pkt_buf + off);
}
// uncompresses a name
// free() after use
static uint8_t *uncompress_nlabel(uint8_t *pkt_buf, size_t pkt_len, size_t off) {
uint8_t *p;
uint8_t *e = pkt_buf + pkt_len;
size_t len = 0;
char *str, *sp;
if (off >= pkt_len)
return NULL;
// calculate length of uncompressed label
for (p = pkt_buf + off; *p && p < e; p++) {
size_t llen = 0;
if ((*p & 0xC0) == 0xC0) {
uint8_t *p2 = pkt_buf + (((p[0] & ~0xC0) << 8) | p[1]);
llen = *p2 + 1;
p = p2 + llen - 1;
} else {
llen = *p + 1;
p += llen - 1;
}
len += llen;
}
str = sp = malloc(len + 1);
if (str == NULL)
return NULL;
// FIXME: must merge this with above code
for (p = pkt_buf + off; *p && p < e; p++) {
size_t llen = 0;
if ((*p & 0xC0) == 0xC0) {
uint8_t *p2 = pkt_buf + (((p[0] & ~0xC0) << 8) | p[1]);
llen = *p2 + 1;
strncpy(sp, (char *)p2, llen);
p = p2 + llen - 1;
} else {
llen = *p + 1;
strncpy(sp, (char *)p, llen);
p += llen - 1;
}
sp += llen;
}
*sp = '\0';
return (uint8_t *)str;
}
// ----- RR list & group functions -----
const char *rr_get_type_name(enum rr_type type) {
switch (type) {
case RR_A:
return "A";
case RR_PTR:
return "PTR";
case RR_TXT:
return "TXT";
case RR_AAAA:
return "AAAA";
case RR_SRV:
return "SRV";
case RR_NSEC:
return "NSEC";
case RR_ANY:
return "ANY";
}
return NULL;
}
void rr_entry_destroy(struct rr_entry *rr) {
struct rr_data_txt *txt_rec;
assert(rr);
// check rr_type and free data elements
switch (rr->type) {
case RR_PTR:
if (rr->data.PTR.name)
free(rr->data.PTR.name);
// don't free entry
break;
case RR_TXT:
txt_rec = &rr->data.TXT;
while (txt_rec) {
struct rr_data_txt *next = txt_rec->next;
if (txt_rec->txt)
free(txt_rec->txt);
// only free() if it wasn't part of the struct
if (txt_rec != &rr->data.TXT)
free(txt_rec);
txt_rec = next;
}
break;
case RR_SRV:
if (rr->data.SRV.target)
free(rr->data.SRV.target);
break;
default:
// nothing to free
break;
}
free(rr->name);
free(rr);
}
// destroys an RR list (and optionally, items)
void rr_list_destroy(struct rr_list *rr, char destroy_items) {
struct rr_list *rr_next;
for (; rr; rr = rr_next) {
rr_next = rr->next;
if (destroy_items)
rr_entry_destroy(rr->e);
free(rr);
}
}
int rr_list_count(struct rr_list *rr) {
int i = 0;
for (; rr; i++, rr = rr->next)
;
return i;
}
struct rr_entry *rr_list_remove(struct rr_list **rr_head, struct rr_entry *rr) {
struct rr_list *le = *rr_head, *pe = NULL;
for (; le; le = le->next) {
if (le->e == rr) {
if (pe == NULL) {
*rr_head = le->next;
free(le);
return rr;
} else {
pe->next = le->next;
free(le);
return rr;
}
}
pe = le;
}
return NULL;
}
// appends an rr_entry to an RR list
// if the RR is already in the list, it will not be added
// RRs are compared by memory location - not its contents
// return value of 0 means item not added
int rr_list_append(struct rr_list **rr_head, struct rr_entry *rr) {
struct rr_list *node = malloc(sizeof(struct rr_list));
if (node) {
node->e = rr;
node->next = NULL;
if (*rr_head == NULL) {
*rr_head = node;
} else {
struct rr_list *e = *rr_head, *taile = NULL;
for (; e; e = e->next) {
// already in list - don't add
if (e->e == rr) {
free(node);
return 0;
}
if (e->next == NULL)
taile = e;
}
if (taile)
taile->next = node;
else
DEBUG_PRINTF("taile not given a value.\n");
}
} else {
die("can not allocate memory for \"node\" in tinysvcmdns.");
}
return 1;
}
#define FILL_RR_ENTRY(rr, _name, _type) \
rr->name = _name; \
rr->type = _type; \
rr->ttl = DEFAULT_TTL; \
rr->cache_flush = 1; \
rr->rr_class = 1;
struct rr_entry *rr_create_a(uint8_t *name, uint32_t addr) {
DECL_MALLOC_ZERO_STRUCT(rr, rr_entry);
if (rr) {
FILL_RR_ENTRY(rr, name, RR_A);
rr->data.A.addr = addr;
rr->ttl = DEFAULT_TTL_FOR_RECORD_WITH_HOSTNAME; // 120 seconds -- see RFC 6762 Section 10
} else {
die("could not allocate an RR data structure in tinysvcmdns.c.");
}
return rr;
}
struct rr_entry *rr_create_aaaa(uint8_t *name, struct in6_addr *addr) {
DECL_MALLOC_ZERO_STRUCT(rr, rr_entry);
if (rr) {
FILL_RR_ENTRY(rr, name, RR_AAAA);
rr->data.AAAA.addr = addr;
rr->ttl = DEFAULT_TTL_FOR_RECORD_WITH_HOSTNAME; // 120 seconds -- see RFC 6762 Section 10
} else {
die("could not allocate an RR 2 data structure in tinysvcmdns.c.");
}
return rr;
}
struct rr_entry *rr_create_srv(uint8_t *name, uint16_t port, uint8_t *target) {
DECL_MALLOC_ZERO_STRUCT(rr, rr_entry);
if (rr) {
FILL_RR_ENTRY(rr, name, RR_SRV);
rr->data.SRV.port = port;
rr->data.SRV.target = target;
} else {
die("could not allocate an RR 3 data structure in tinysvcmdns.c.");
}
return rr;
}
struct rr_entry *rr_create_ptr(uint8_t *name, struct rr_entry *d_rr) {
DECL_MALLOC_ZERO_STRUCT(rr, rr_entry);
if (rr) {
FILL_RR_ENTRY(rr, name, RR_PTR);
rr->cache_flush = 0; // PTRs shouldn't have their cache flush bit set
rr->data.PTR.entry = d_rr;
} else {
die("could not allocate an RR 4 data structure in tinysvcmdns.c.");
}
return rr;
}
struct rr_entry *rr_create(uint8_t *name, enum rr_type type) {
DECL_MALLOC_ZERO_STRUCT(rr, rr_entry);
if (rr) {
FILL_RR_ENTRY(rr, name, type);
} else {
die("could not allocate an RR 4 data structure in tinysvcmdns.c.");
}
return rr;
}
void rr_set_nsec(struct rr_entry *rr_nsec, enum rr_type type) {
assert((rr_nsec->type = RR_NSEC));
assert((type / 8) < sizeof(rr_nsec->data.NSEC.bitmap));
rr_nsec->data.NSEC.bitmap[type / 8] = 1 << (7 - (type % 8));
}
void rr_add_txt(struct rr_entry *rr_txt, const char *txt) {
struct rr_data_txt *txt_rec;
assert(rr_txt->type == RR_TXT);
txt_rec = &rr_txt->data.TXT;
// is current data filled?
if (txt_rec->txt == NULL) {
txt_rec->txt = create_label(txt);
return;
}
// find the last node
for (; txt_rec->next; txt_rec = txt_rec->next)
;
// create a new empty node
txt_rec->next = malloc(sizeof(struct rr_data_txt));
txt_rec = txt_rec->next;
txt_rec->txt = create_label(txt);
txt_rec->next = NULL;
}
// adds a record to an rr_group
void rr_group_add(struct rr_group **group, struct rr_entry *rr) {
struct rr_group *g;
assert(rr != NULL);
if (*group) {
g = rr_group_find(*group, rr->name);
if (g) {
rr_list_append(&g->rr, rr);
return;
}
}
MALLOC_ZERO_STRUCT(g, rr_group);
if (g) {
g->name = dup_nlabel(rr->name);
rr_list_append(&g->rr, rr);
// prepend to list
g->next = *group;
*group = g;
} else {
die("can not allocate memory for \"g\" in tinysvcmdns");
}
}
// finds a rr_group matching the given name
struct rr_group *rr_group_find(struct rr_group *g, uint8_t *name) {
for (; g; g = g->next) {
if (cmp_nlabel(g->name, name) == 0)
return g;
}
return NULL;
}
struct rr_entry *rr_entry_find(struct rr_list *rr_list, uint8_t *name, uint16_t type) {
struct rr_list *rr = rr_list;
for (; rr; rr = rr->next) {
if (rr->e->type == type && cmp_nlabel(rr->e->name, name) == 0)
return rr->e;
}
return NULL;
}
// looks for a matching entry in rr_list
// if entry is a PTR, we need to check if the PTR target also matches
struct rr_entry *rr_entry_match(struct rr_list *rr_list, struct rr_entry *entry) {
struct rr_list *rr = rr_list;
for (; rr; rr = rr->next) {
if (rr->e->type == entry->type && cmp_nlabel(rr->e->name, entry->name) == 0) {
if (entry->type != RR_PTR) {
return rr->e;
} else if (cmp_nlabel(MDNS_RR_GET_PTR_NAME(entry), MDNS_RR_GET_PTR_NAME(rr->e)) == 0) {
// if it's a PTR, we need to make sure PTR target also matches
return rr->e;
}
}
}
return NULL;
}
void rr_group_destroy(struct rr_group *group) {
struct rr_group *g = group;
while (g) {
struct rr_group *nextg = g->next;
free(g->name);
rr_list_destroy(g->rr, 1);
free(g);
g = nextg;
}
}
uint8_t *mdns_write_u16(uint8_t *ptr, const uint16_t v) {
*ptr++ = (uint8_t)(v >> 8) & 0xFF;
*ptr++ = (uint8_t)(v >> 0) & 0xFF;
return ptr;
}
uint8_t *mdns_write_u32(uint8_t *ptr, const uint32_t v) {
*ptr++ = (uint8_t)(v >> 24) & 0xFF;
*ptr++ = (uint8_t)(v >> 16) & 0xFF;
*ptr++ = (uint8_t)(v >> 8) & 0xFF;
*ptr++ = (uint8_t)(v >> 0) & 0xFF;
return ptr;
}
uint16_t mdns_read_u16(const uint8_t *ptr) {
return ((ptr[0] & 0xFF) << 8) | ((ptr[1] & 0xFF) << 0);
}
uint32_t mdns_read_u32(const uint8_t *ptr) {
return ((ptr[0] & 0xFF) << 24) | ((ptr[1] & 0xFF) << 16) | ((ptr[2] & 0xFF) << 8) |
((ptr[3] & 0xFF) << 0);
}
// initialize the packet for reply
// clears the packet of list structures but not its list items
void mdns_init_reply(struct mdns_pkt *pkt, uint16_t id) {
// copy transaction ID
pkt->id = id;
// response flags
pkt->flags = MDNS_FLAG_RESP | MDNS_FLAG_AA;
rr_list_destroy(pkt->rr_qn, 0);
rr_list_destroy(pkt->rr_ans, 0);
rr_list_destroy(pkt->rr_auth, 0);
rr_list_destroy(pkt->rr_add, 0);
pkt->rr_qn = NULL;
pkt->rr_ans = NULL;
pkt->rr_auth = NULL;
pkt->rr_add = NULL;
pkt->num_qn = 0;
pkt->num_ans_rr = 0;
pkt->num_auth_rr = 0;
pkt->num_add_rr = 0;
}
// destroys an mdns_pkt struct, including its contents
void mdns_pkt_destroy(struct mdns_pkt *p) {
rr_list_destroy(p->rr_qn, 1);
rr_list_destroy(p->rr_ans, 1);
rr_list_destroy(p->rr_auth, 1);
rr_list_destroy(p->rr_add, 1);
free(p);
}
// parse the MDNS questions section
// stores the parsed data in the given mdns_pkt struct
static size_t mdns_parse_qn(uint8_t *pkt_buf, size_t pkt_len, size_t off, struct mdns_pkt *pkt) {
const uint8_t *p = pkt_buf + off;
struct rr_entry *rr;
uint8_t *name;
assert(pkt != NULL);
rr = malloc(sizeof(struct rr_entry));
if (rr)
memset(rr, 0, sizeof(struct rr_entry));
else
goto err;
name = uncompress_nlabel(pkt_buf, pkt_len, off);
if (name == NULL)
goto err;
p += label_len(pkt_buf, pkt_len, off);
rr->name = name;
rr->type = mdns_read_u16(p);
p += sizeof(uint16_t);
rr->unicast_query = (*p & 0x80) == 0x80;
rr->rr_class = mdns_read_u16(p) & ~0x80;
p += sizeof(uint16_t);
rr_list_append(&pkt->rr_qn, rr);
return p - (pkt_buf + off);
err:
free(rr);
return 0;
}
// parse the MDNS RR section
// stores the parsed data in the given mdns_pkt struct
static size_t mdns_parse_rr(uint8_t *pkt_buf, size_t pkt_len, size_t off, struct mdns_pkt *pkt) {
const uint8_t *p = pkt_buf + off;
const uint8_t *e = pkt_buf + pkt_len;
struct rr_entry *rr;
uint8_t *name;
size_t rr_data_len = 0;
struct rr_data_txt *txt_rec;
int parse_error = 0;
assert(pkt != NULL);
if (off > pkt_len)
return 0;
rr = malloc(sizeof(struct rr_entry));
if (rr)
memset(rr, 0, sizeof(struct rr_entry));
else
goto err;
name = uncompress_nlabel(pkt_buf, pkt_len, off);
if (name == NULL)
goto err;
// parse the MDNS RR section
p += label_len(pkt_buf, pkt_len, off);
rr->name = name;
rr->type = mdns_read_u16(p);
p += sizeof(uint16_t);
rr->cache_flush = (*p & 0x80) == 0x80;
rr->rr_class = mdns_read_u16(p) & ~0x80;
p += sizeof(uint16_t);
rr->ttl = mdns_read_u32(p);
p += sizeof(uint32_t);
// RR data
rr_data_len = mdns_read_u16(p);
p += sizeof(uint16_t);
if (p + rr_data_len > e) {
DEBUG_PRINTF("rr_data_len goes beyond packet buffer: %lu > %lu\n", rr_data_len, e - p);
rr_entry_destroy(rr);
return 0;
}
e = p + rr_data_len;
// see if we can parse the RR data
switch (rr->type) {
case RR_A:
if (rr_data_len < sizeof(uint32_t)) {
DEBUG_PRINTF("invalid rr_data_len=%lu for A record\n", rr_data_len);
parse_error = 1;
break;
}
rr->data.A.addr = ntohl(mdns_read_u32(p)); /* addr already in net order */
p += sizeof(uint32_t);
break;
case RR_AAAA:
if (rr_data_len < sizeof(struct in6_addr)) {
DEBUG_PRINTF("invalid rr_data_len=%lu for AAAA record\n", rr_data_len);
parse_error = 1;
break;
}
rr->data.AAAA.addr = malloc(sizeof(struct in6_addr));
unsigned int i;
for (i = 0; i < sizeof(struct in6_addr); i++)
rr->data.AAAA.addr->s6_addr[i] = p[i];
p += sizeof(struct in6_addr);
break;
case RR_PTR:
rr->data.PTR.name = uncompress_nlabel(pkt_buf, pkt_len, p - pkt_buf);
if (rr->data.PTR.name == NULL) {
DEBUG_PRINTF("unable to parse/uncompress label for PTR name\n");
parse_error = 1;
break;
}
p += rr_data_len;
break;
case RR_TXT:
txt_rec = &rr->data.TXT;
// not supposed to happen, but we should handle it
if (rr_data_len == 0) {
DEBUG_PRINTF("WARN: rr_data_len for TXT is 0\n");
txt_rec->txt = create_label("");
break;
}
while (1) {
txt_rec->txt = copy_label(pkt_buf, pkt_len, p - pkt_buf);
if (txt_rec->txt == NULL) {
DEBUG_PRINTF("unable to copy label for TXT record\n");
parse_error = 1;
break;
}
p += txt_rec->txt[0] + 1;
if (p >= e)
break;
// allocate another record
txt_rec->next = malloc(sizeof(struct rr_data_txt));
txt_rec = txt_rec->next;
txt_rec->next = NULL;
}
break;
default:
// skip to end of RR data
p = e;
}
// if there was a parse error, destroy partial rr_entry
if (parse_error) {
rr_entry_destroy(rr);
return 0;
}
rr_list_append(&pkt->rr_ans, rr);
return p - (pkt_buf + off);
err:
free(rr);
return 0;
}
// parse a MDNS packet into an mdns_pkt struct
struct mdns_pkt *mdns_parse_pkt(uint8_t *pkt_buf, size_t pkt_len) {
uint8_t *p = pkt_buf;
size_t off;
struct mdns_pkt *pkt;
int i;
if (pkt_len < 12)
return NULL;
MALLOC_ZERO_STRUCT(pkt, mdns_pkt);
if (pkt == NULL)
die("cannot allocate memory for \"pkt\" in tinysvcmdns.c.");
// parse header
pkt->id = mdns_read_u16(p);
p += sizeof(uint16_t);
pkt->flags = mdns_read_u16(p);
p += sizeof(uint16_t);
pkt->num_qn = mdns_read_u16(p);
p += sizeof(uint16_t);
pkt->num_ans_rr = mdns_read_u16(p);
p += sizeof(uint16_t);
pkt->num_auth_rr = mdns_read_u16(p);
p += sizeof(uint16_t);
pkt->num_add_rr = mdns_read_u16(p);
p += sizeof(uint16_t);
off = p - pkt_buf;
// parse questions
for (i = 0; i < pkt->num_qn; i++) {
size_t l = mdns_parse_qn(pkt_buf, pkt_len, off, pkt);
if (!l) {
DEBUG_PRINTF("error parsing question #%d\n", i);
mdns_pkt_destroy(pkt);
return NULL;
}
off += l;
}
// parse answer RRs
for (i = 0; i < pkt->num_ans_rr; i++) {
size_t l = mdns_parse_rr(pkt_buf, pkt_len, off, pkt);
if (!l) {
DEBUG_PRINTF("error parsing answer #%d\n", i);
mdns_pkt_destroy(pkt);
return NULL;
}
off += l;
}
// TODO: parse the authority and additional RR sections
return pkt;
}
// encodes a name (label) into a packet using the name compression scheme
// encoded names will be added to the compression list for subsequent use
static size_t mdns_encode_name(uint8_t *pkt_buf, __attribute__((unused)) size_t pkt_len, size_t off,
const uint8_t *name, struct name_comp *comp) {
struct name_comp *c, *c_tail = NULL;
uint8_t *p = pkt_buf + off;
size_t len = 0;
if (name) {
while (*name) {
// find match for compression
for (c = comp; c; c = c->next) {
if (cmp_nlabel(name, c->label) == 0) {
mdns_write_u16(p, 0xC000 | (c->pos & ~0xC000));
return len + sizeof(uint16_t);
}
if (c->next == NULL)
c_tail = c;
}
// copy this segment
int segment_len = *name + 1;
strncpy((char *)p, (char *)name, segment_len);
// cache the name for subsequent compression
DECL_MALLOC_ZERO_STRUCT(new_c, name_comp);
new_c->label = (uint8_t *)name;
new_c->pos = p - pkt_buf;
c_tail->next = new_c;
// advance to next name segment
p += segment_len;
len += segment_len;
name += segment_len;
}
}
*p = '\0'; // root "label"
len += 1;
return len;
}
// encodes an RR entry at the given offset
// returns the size of the entire RR entry
static size_t mdns_encode_rr(uint8_t *pkt_buf, size_t pkt_len, size_t off, struct rr_entry *rr,
struct name_comp *comp) {
uint8_t *p = pkt_buf + off, *p_data;
size_t l;
struct rr_data_txt *txt_rec;
uint8_t *label;
unsigned int i;
assert(off < pkt_len);
// name
l = mdns_encode_name(pkt_buf, pkt_len, off, rr->name, comp);
assert(l != 0);
p += l;
// type
p = mdns_write_u16(p, rr->type);
// class & cache flush
p = mdns_write_u16(p, (rr->rr_class & ~0x8000) | (rr->cache_flush << 15));
// TTL
p = mdns_write_u32(p, rr->ttl);
// data length (filled in later)
p += sizeof(uint16_t);
// start of data marker
p_data = p;
switch (rr->type) {
case RR_A:
/* htonl() needed coz addr already in net order */
p = mdns_write_u32(p, htonl(rr->data.A.addr));
break;
case RR_AAAA:
for (i = 0; i < sizeof(struct in6_addr); i++)
*p++ = rr->data.AAAA.addr->s6_addr[i];
break;
case RR_PTR:
label = rr->data.PTR.name ? rr->data.PTR.name : rr->data.PTR.entry->name;
p += mdns_encode_name(pkt_buf, pkt_len, p - pkt_buf, label, comp);
break;