uint8_t werr_to_dns_err(WERROR werr)
{
if (W_ERROR_EQUAL(WERR_OK, werr)) {
return DNS_RCODE_OK;
} else if (W_ERROR_EQUAL(DNS_ERR(FORMAT_ERROR), werr)) {
return DNS_RCODE_FORMERR;
} else if (W_ERROR_EQUAL(DNS_ERR(SERVER_FAILURE), werr)) {
return DNS_RCODE_SERVFAIL;
} else if (W_ERROR_EQUAL(DNS_ERR(NAME_ERROR), werr)) {
return DNS_RCODE_NXDOMAIN;
} else if (W_ERROR_EQUAL(DNS_ERR(NOT_IMPLEMENTED), werr)) {
return DNS_RCODE_NOTIMP;
} else if (W_ERROR_EQUAL(DNS_ERR(REFUSED), werr)) {
return DNS_RCODE_REFUSED;
} else if (W_ERROR_EQUAL(DNS_ERR(YXDOMAIN), werr)) {
return DNS_RCODE_YXDOMAIN;
} else if (W_ERROR_EQUAL(DNS_ERR(YXRRSET), werr)) {
return DNS_RCODE_YXRRSET;
} else if (W_ERROR_EQUAL(DNS_ERR(NXRRSET), werr)) {
return DNS_RCODE_NXRRSET;
} else if (W_ERROR_EQUAL(DNS_ERR(NOTAUTH), werr)) {
return DNS_RCODE_NOTAUTH;
} else if (W_ERROR_EQUAL(DNS_ERR(NOTZONE), werr)) {
return DNS_RCODE_NOTZONE;
}
DEBUG(5, ("No mapping exists for %%s\n"));
return DNS_RCODE_SERVFAIL;
}
WERROR dns_server_process_query(struct dns_server *dns,
struct dns_request_state *state,
TALLOC_CTX *mem_ctx,
struct dns_name_packet *in,
struct dns_res_rec **answers, uint16_t *ancount,
struct dns_res_rec **nsrecs, uint16_t *nscount,
struct dns_res_rec **additional, uint16_t *arcount)
{
uint16_t num_answers=0, num_nsrecs=0, num_additional=0;
struct dns_res_rec *ans=NULL, *ns=NULL, *adds=NULL;
WERROR werror;
if (in->qdcount != 1) {
return DNS_ERR(FORMAT_ERROR);
}
/* Windows returns NOT_IMPLEMENTED on this as well */
if (in->questions[0].question_class == DNS_QCLASS_NONE) {
return DNS_ERR(NOT_IMPLEMENTED);
}
if (dns_authorative_for_zone(dns, in->questions[0].name)) {
state->flags |= DNS_FLAG_AUTHORITATIVE;
werror = handle_question(dns, mem_ctx, &in->questions[0],
&ans, &num_answers);
} else {
if (state->flags & DNS_FLAG_RECURSION_DESIRED &&
state->flags & DNS_FLAG_RECURSION_AVAIL) {
DEBUG(2, ("Not authorative for '%s', forwarding\n",
in->questions[0].name));
werror = ask_forwarder(dns, mem_ctx, &in->questions[0],
&ans, &num_answers,
&ns, &num_nsrecs,
&adds, &num_additional);
} else {
werror = DNS_ERR(NAME_ERROR);
}
}
W_ERROR_NOT_OK_GOTO(werror, query_failed);
*answers = ans;
*ancount = num_answers;
/*FIXME: Do something for these */
*nsrecs = ns;
*nscount = num_nsrecs;
*additional = adds;
*arcount = num_additional;
return WERR_OK;
query_failed:
/*FIXME: add our SOA record to nsrecs */
return werror;
}
WERROR dns_name2dn(struct dns_server *dns,
TALLOC_CTX *mem_ctx,
const char *name,
struct ldb_dn **_dn)
{
struct ldb_dn *base;
struct ldb_dn *dn;
const struct dns_server_zone *z;
size_t host_part_len = 0;
if (name == NULL) {
return DNS_ERR(FORMAT_ERROR);
}
/*TODO: Check if 'name' is a valid DNS name */
if (strcmp(name, "") == 0) {
base = ldb_get_default_basedn(dns->samdb);
dn = ldb_dn_copy(mem_ctx, base);
ldb_dn_add_child_fmt(dn, "DC=@,DC=RootDNSServers,CN=MicrosoftDNS,CN=System");
*_dn = dn;
return WERR_OK;
}
for (z = dns->zones; z != NULL; z = z->next) {
bool match;
match = dns_name_match(z->name, name, &host_part_len);
if (match) {
break;
}
}
if (z == NULL) {
return DNS_ERR(NAME_ERROR);
}
if (host_part_len == 0) {
dn = ldb_dn_copy(mem_ctx, z->dn);
ldb_dn_add_child_fmt(dn, "DC=@");
*_dn = dn;
return WERR_OK;
}
dn = ldb_dn_copy(mem_ctx, z->dn);
ldb_dn_add_child_fmt(dn, "DC=%*.*s", (int)host_part_len, (int)host_part_len, name);
*_dn = dn;
return WERR_OK;
}
WERROR dns_lookup_records(struct dns_server *dns,
TALLOC_CTX *mem_ctx,
struct ldb_dn *dn,
struct dnsp_DnssrvRpcRecord **records,
uint16_t *rec_count)
{
static const char * const attrs[] = { "dnsRecord", NULL};
struct ldb_message_element *el;
uint16_t ri;
int ret;
struct ldb_message *msg = NULL;
struct dnsp_DnssrvRpcRecord *recs;
ret = dsdb_search_one(dns->samdb, mem_ctx, &msg, dn,
LDB_SCOPE_BASE, attrs, 0, "%s", "(objectClass=dnsNode)");
if (ret != LDB_SUCCESS) {
/* TODO: we need to check if there's a glue record we need to
* create a referral to */
return DNS_ERR(NAME_ERROR);
}
el = ldb_msg_find_element(msg, attrs[0]);
if (el == NULL) {
*records = NULL;
*rec_count = 0;
return WERR_OK;
}
recs = talloc_zero_array(mem_ctx, struct dnsp_DnssrvRpcRecord, el->num_values);
W_ERROR_HAVE_NO_MEMORY(recs);
for (ri = 0; ri < el->num_values; ri++) {
struct ldb_val *v = &el->values[ri];
enum ndr_err_code ndr_err;
ndr_err = ndr_pull_struct_blob(v, recs, &recs[ri],
(ndr_pull_flags_fn_t)ndr_pull_dnsp_DnssrvRpcRecord);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
DEBUG(0, ("Failed to grab dnsp_DnssrvRpcRecord\n"));
return DNS_ERR(SERVER_FAILURE);
}
}
*records = recs;
*rec_count = el->num_values;
return WERR_OK;
}
static WERROR create_response_rr(const struct dns_name_question *question,
const struct dnsp_DnssrvRpcRecord *rec,
struct dns_res_rec **answers, uint16_t *ancount)
{
struct dns_res_rec *ans = *answers;
uint16_t ai = *ancount;
ZERO_STRUCT(ans[ai]);
switch (rec->wType) {
case DNS_QTYPE_CNAME:
ans[ai].rdata.cname_record = talloc_strdup(ans, rec->data.cname);
break;
case DNS_QTYPE_A:
ans[ai].rdata.ipv4_record = talloc_strdup(ans, rec->data.ipv4);
break;
case DNS_QTYPE_AAAA:
ans[ai].rdata.ipv6_record = rec->data.ipv6;
break;
case DNS_TYPE_NS:
ans[ai].rdata.ns_record = rec->data.ns;
break;
case DNS_QTYPE_SRV:
ans[ai].rdata.srv_record.priority = rec->data.srv.wPriority;
ans[ai].rdata.srv_record.weight = rec->data.srv.wWeight;
ans[ai].rdata.srv_record.port = rec->data.srv.wPort;
ans[ai].rdata.srv_record.target = rec->data.srv.nameTarget;
break;
case DNS_QTYPE_SOA:
ans[ai].rdata.soa_record.mname = rec->data.soa.mname;
ans[ai].rdata.soa_record.rname = rec->data.soa.rname;
ans[ai].rdata.soa_record.serial = rec->data.soa.serial;
ans[ai].rdata.soa_record.refresh = rec->data.soa.refresh;
ans[ai].rdata.soa_record.retry = rec->data.soa.retry;
ans[ai].rdata.soa_record.expire = rec->data.soa.expire;
ans[ai].rdata.soa_record.minimum = rec->data.soa.minimum;
break;
default:
return DNS_ERR(NOT_IMPLEMENTED);
}
ans[ai].name = talloc_strdup(ans, question->name);
ans[ai].rr_type = rec->wType;
ans[ai].rr_class = DNS_QCLASS_IN;
ans[ai].ttl = rec->dwTtlSeconds;
ans[ai].length = UINT16_MAX;
ai++;
*answers = ans;
*ancount = ai;
return WERR_OK;
}
WERROR dns_server_process_query(struct dns_server *dns,
TALLOC_CTX *mem_ctx,
struct dns_name_packet *in,
struct dns_res_rec **answers, uint16_t *ancount,
struct dns_res_rec **nsrecs, uint16_t *nscount,
struct dns_res_rec **additional, uint16_t *arcount)
{
uint16_t num_answers=0;
struct dns_res_rec *ans=NULL;
WERROR werror;
if (in->qdcount != 1) {
return DNS_ERR(FORMAT_ERROR);
}
/* Windows returns NOT_IMPLEMENTED on this as well */
if (in->questions[0].question_class == DNS_QCLASS_NONE) {
return DNS_ERR(NOT_IMPLEMENTED);
}
werror = handle_question(dns, mem_ctx, &in->questions[0], &ans, &num_answers);
W_ERROR_NOT_OK_GOTO(werror, query_failed);
*answers = ans;
*ancount = num_answers;
/*FIXME: Do something for these */
*nsrecs = NULL;
*nscount = 0;
*additional = NULL;
*arcount = 0;
return WERR_OK;
query_failed:
/*FIXME: add our SOA record to nsrecs */
return werror;
}
static WERROR handle_question(struct dns_server *dns,
TALLOC_CTX *mem_ctx,
const struct dns_name_question *question,
struct dns_res_rec **answers, uint16_t *ancount)
{
struct dns_res_rec *ans;
WERROR werror;
unsigned int ri;
struct dnsp_DnssrvRpcRecord *recs;
uint16_t rec_count, ai = 0;
struct ldb_dn *dn = NULL;
werror = dns_name2dn(dns, mem_ctx, question->name, &dn);
W_ERROR_NOT_OK_RETURN(werror);
werror = dns_lookup_records(dns, mem_ctx, dn, &recs, &rec_count);
W_ERROR_NOT_OK_RETURN(werror);
ans = talloc_zero_array(mem_ctx, struct dns_res_rec, rec_count);
W_ERROR_HAVE_NO_MEMORY(ans);
for (ri = 0; ri < rec_count; ri++) {
if ((question->question_type != DNS_QTYPE_ALL) &&
(recs[ri].wType != question->question_type)) {
continue;
}
werror = create_response_rr(question, &recs[ri], &ans, &ai);
W_ERROR_NOT_OK_RETURN(werror);
}
if (ai == 0) {
return DNS_ERR(NAME_ERROR);
}
*ancount = ai;
*answers = ans;
return WERR_OK;
}
static WERROR create_response_rr(const struct dns_name_question *question,
const struct dnsp_DnssrvRpcRecord *rec,
struct dns_res_rec **answers, uint16_t *ancount)
{
struct dns_res_rec *ans = *answers;
uint16_t ai = *ancount;
char *tmp;
uint32_t i;
ZERO_STRUCT(ans[ai]);
switch (rec->wType) {
case DNS_QTYPE_CNAME:
ans[ai].rdata.cname_record = talloc_strdup(ans, rec->data.cname);
break;
case DNS_QTYPE_A:
ans[ai].rdata.ipv4_record = talloc_strdup(ans, rec->data.ipv4);
break;
case DNS_QTYPE_AAAA:
ans[ai].rdata.ipv6_record = rec->data.ipv6;
break;
case DNS_TYPE_NS:
ans[ai].rdata.ns_record = rec->data.ns;
break;
case DNS_QTYPE_SRV:
ans[ai].rdata.srv_record.priority = rec->data.srv.wPriority;
ans[ai].rdata.srv_record.weight = rec->data.srv.wWeight;
ans[ai].rdata.srv_record.port = rec->data.srv.wPort;
ans[ai].rdata.srv_record.target = rec->data.srv.nameTarget;
break;
case DNS_QTYPE_SOA:
ans[ai].rdata.soa_record.mname = rec->data.soa.mname;
ans[ai].rdata.soa_record.rname = rec->data.soa.rname;
ans[ai].rdata.soa_record.serial = rec->data.soa.serial;
ans[ai].rdata.soa_record.refresh = rec->data.soa.refresh;
ans[ai].rdata.soa_record.retry = rec->data.soa.retry;
ans[ai].rdata.soa_record.expire = rec->data.soa.expire;
ans[ai].rdata.soa_record.minimum = rec->data.soa.minimum;
break;
case DNS_QTYPE_PTR:
ans[ai].rdata.ptr_record = talloc_strdup(ans, rec->data.ptr);
break;
case DNS_QTYPE_TXT:
tmp = talloc_asprintf(ans, "\"%s\"", rec->data.txt.str[0]);
for (i=1; i<rec->data.txt.count; i++) {
tmp = talloc_asprintf_append(tmp, " \"%s\"",
rec->data.txt.str[i]);
}
ans[ai].rdata.txt_record.txt = tmp;
break;
default:
DEBUG(0, ("Got unhandled type %u query.\n", rec->wType));
return DNS_ERR(NOT_IMPLEMENTED);
}
ans[ai].name = talloc_strdup(ans, question->name);
ans[ai].rr_type = rec->wType;
ans[ai].rr_class = DNS_QCLASS_IN;
ans[ai].ttl = rec->dwTtlSeconds;
ans[ai].length = UINT16_MAX;
ai++;
*answers = ans;
*ancount = ai;
return WERR_OK;
}
static WERROR ask_forwarder(struct dns_server *dns,
TALLOC_CTX *mem_ctx,
struct dns_name_question *question,
struct dns_res_rec **answers, uint16_t *ancount,
struct dns_res_rec **nsrecs, uint16_t *nscount,
struct dns_res_rec **additional, uint16_t *arcount)
{
struct tevent_context *ev = tevent_context_init(mem_ctx);
struct dns_name_packet *out_packet, *in_packet;
uint16_t id = random();
DATA_BLOB out, in;
enum ndr_err_code ndr_err;
WERROR werr = WERR_OK;
struct tevent_req *req;
const char *forwarder = lpcfg_dns_forwarder(dns->task->lp_ctx);
if (!is_ipaddress(forwarder)) {
DEBUG(0, ("Invalid 'dns forwarder' setting '%s', needs to be "
"an IP address\n", forwarder));
return DNS_ERR(NAME_ERROR);
}
out_packet = talloc_zero(mem_ctx, struct dns_name_packet);
W_ERROR_HAVE_NO_MEMORY(out_packet);
out_packet->id = id;
out_packet->operation |= DNS_OPCODE_QUERY | DNS_FLAG_RECURSION_DESIRED;
out_packet->qdcount = 1;
out_packet->questions = question;
ndr_err = ndr_push_struct_blob(&out, mem_ctx, out_packet,
(ndr_push_flags_fn_t)ndr_push_dns_name_packet);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
return DNS_ERR(SERVER_FAILURE);
}
req = dns_udp_request_send(mem_ctx, ev, forwarder, out.data, out.length);
W_ERROR_HAVE_NO_MEMORY(req);
if(!tevent_req_poll(req, ev)) {
return DNS_ERR(SERVER_FAILURE);
}
werr = dns_udp_request_recv(req, mem_ctx, &in.data, &in.length);
W_ERROR_NOT_OK_RETURN(werr);
in_packet = talloc_zero(mem_ctx, struct dns_name_packet);
W_ERROR_HAVE_NO_MEMORY(in_packet);
ndr_err = ndr_pull_struct_blob(&in, in_packet, in_packet,
(ndr_pull_flags_fn_t)ndr_pull_dns_name_packet);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
return DNS_ERR(SERVER_FAILURE);
}
if (in_packet->id != id) {
DEBUG(0, ("DNS packet id mismatch: 0x%0x, expected 0x%0x\n",
in_packet->id, id));
return DNS_ERR(NAME_ERROR);
}
*ancount = in_packet->ancount;
*answers = talloc_move(mem_ctx, &in_packet->answers);
*nscount = in_packet->nscount;
*nsrecs = talloc_move(mem_ctx, &in_packet->nsrecs);
*arcount = in_packet->arcount;
*additional = talloc_move(mem_ctx, &in_packet->additional);
return werr;
}
WERROR dns_verify_tsig(struct dns_server *dns,
TALLOC_CTX *mem_ctx,
struct dns_request_state *state,
struct dns_name_packet *packet,
DATA_BLOB *in)
{
WERROR werror;
NTSTATUS status;
enum ndr_err_code ndr_err;
bool found_tsig = false;
uint16_t i, arcount = 0;
DATA_BLOB tsig_blob, fake_tsig_blob, sig;
uint8_t *buffer = NULL;
size_t buffer_len = 0, packet_len = 0;
struct dns_server_tkey *tkey = NULL;
struct dns_fake_tsig_rec *check_rec = talloc_zero(mem_ctx,
struct dns_fake_tsig_rec);
/* Find the first TSIG record in the additional records */
for (i=0; i < packet->arcount; i++) {
if (packet->additional[i].rr_type == DNS_QTYPE_TSIG) {
found_tsig = true;
break;
}
}
if (!found_tsig) {
return WERR_OK;
}
/* The TSIG record needs to be the last additional record */
if (found_tsig && i + 1 != packet->arcount) {
DEBUG(1, ("TSIG record not the last additional record!\n"));
return DNS_ERR(FORMAT_ERROR);
}
/* We got a TSIG, so we need to sign our reply */
state->sign = true;
state->tsig = talloc_zero(state->mem_ctx, struct dns_res_rec);
if (state->tsig == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
werror = dns_copy_tsig(state->tsig, &packet->additional[i],
state->tsig);
if (!W_ERROR_IS_OK(werror)) {
return werror;
}
packet->arcount--;
tkey = dns_find_tkey(dns->tkeys, state->tsig->name);
if (tkey == NULL) {
/*
* We must save the name for use in the TSIG error
* response and have no choice here but to save the
* keyname from the TSIG request.
*/
state->key_name = talloc_strdup(state->mem_ctx,
state->tsig->name);
if (state->key_name == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
state->tsig_error = DNS_RCODE_BADKEY;
return DNS_ERR(NOTAUTH);
}
/*
* Remember the keyname that found an existing tkey, used
* later to fetch the key with dns_find_tkey() when signing
* and adding a TSIG record with MAC.
*/
state->key_name = talloc_strdup(state->mem_ctx, tkey->name);
if (state->key_name == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
/* FIXME: check TSIG here */
if (check_rec == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
/* first build and verify check packet */
check_rec->name = talloc_strdup(check_rec, tkey->name);
if (check_rec->name == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
check_rec->rr_class = DNS_QCLASS_ANY;
check_rec->ttl = 0;
check_rec->algorithm_name = talloc_strdup(check_rec, tkey->algorithm);
if (check_rec->algorithm_name == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
check_rec->time_prefix = 0;
check_rec->time = state->tsig->rdata.tsig_record.time;
check_rec->fudge = state->tsig->rdata.tsig_record.fudge;
check_rec->error = 0;
check_rec->other_size = 0;
check_rec->other_data = NULL;
ndr_err = ndr_push_struct_blob(&tsig_blob, mem_ctx, state->tsig,
(ndr_push_flags_fn_t)ndr_push_dns_res_rec);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
DEBUG(1, ("Failed to push packet: %s!\n",
ndr_errstr(ndr_err)));
return DNS_ERR(SERVER_FAILURE);
}
ndr_err = ndr_push_struct_blob(&fake_tsig_blob, mem_ctx, check_rec,
(ndr_push_flags_fn_t)ndr_push_dns_fake_tsig_rec);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
DEBUG(1, ("Failed to push packet: %s!\n",
ndr_errstr(ndr_err)));
return DNS_ERR(SERVER_FAILURE);
}
/* we need to work some magic here. we need to keep the input packet
* exactly like we got it, but we need to cut off the tsig record */
packet_len = in->length - tsig_blob.length;
buffer_len = packet_len + fake_tsig_blob.length;
buffer = talloc_zero_array(mem_ctx, uint8_t, buffer_len);
if (buffer == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
memcpy(buffer, in->data, packet_len);
memcpy(buffer + packet_len, fake_tsig_blob.data, fake_tsig_blob.length);
sig.length = state->tsig->rdata.tsig_record.mac_size;
sig.data = talloc_memdup(mem_ctx, state->tsig->rdata.tsig_record.mac, sig.length);
if (sig.data == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
/* Now we also need to count down the additional record counter */
arcount = RSVAL(buffer, 10);
RSSVAL(buffer, 10, arcount-1);
status = gensec_check_packet(tkey->gensec, buffer, buffer_len,
buffer, buffer_len, &sig);
if (NT_STATUS_EQUAL(NT_STATUS_ACCESS_DENIED, status)) {
state->tsig_error = DNS_RCODE_BADSIG;
return DNS_ERR(NOTAUTH);
}
if (!NT_STATUS_IS_OK(status)) {
DEBUG(1, ("Verifying tsig failed: %s\n", nt_errstr(status)));
return ntstatus_to_werror(status);
}
state->authenticated = true;
return WERR_OK;
}
WERROR dns_sign_tsig(struct dns_server *dns,
TALLOC_CTX *mem_ctx,
struct dns_request_state *state,
struct dns_name_packet *packet,
uint16_t error)
{
WERROR werror;
time_t current_time = time(NULL);
struct dns_res_rec *tsig = NULL;
DATA_BLOB sig = (DATA_BLOB) {
.data = NULL,
.length = 0
};
tsig = talloc_zero(mem_ctx, struct dns_res_rec);
if (tsig == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
if (state->tsig_error == DNS_RCODE_OK) {
struct dns_server_tkey *tkey = dns_find_tkey(
dns->tkeys, state->key_name);
if (tkey == NULL) {
return DNS_ERR(SERVER_FAILURE);
}
werror = dns_tsig_compute_mac(mem_ctx, state, packet,
tkey, current_time, &sig);
if (!W_ERROR_IS_OK(werror)) {
return werror;
}
}
tsig->name = talloc_strdup(tsig, state->key_name);
if (tsig->name == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
tsig->rr_class = DNS_QCLASS_ANY;
tsig->rr_type = DNS_QTYPE_TSIG;
tsig->ttl = 0;
tsig->length = UINT16_MAX;
tsig->rdata.tsig_record.algorithm_name = talloc_strdup(tsig, "gss-tsig");
tsig->rdata.tsig_record.time_prefix = 0;
tsig->rdata.tsig_record.time = current_time;
tsig->rdata.tsig_record.fudge = 300;
tsig->rdata.tsig_record.error = state->tsig_error;
tsig->rdata.tsig_record.original_id = packet->id;
tsig->rdata.tsig_record.other_size = 0;
tsig->rdata.tsig_record.other_data = NULL;
if (sig.length > 0) {
tsig->rdata.tsig_record.mac_size = sig.length;
tsig->rdata.tsig_record.mac = talloc_memdup(tsig, sig.data, sig.length);
}
if (packet->arcount == 0) {
packet->additional = talloc_zero(mem_ctx, struct dns_res_rec);
if (packet->additional == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
}
packet->additional = talloc_realloc(mem_ctx, packet->additional,
struct dns_res_rec,
packet->arcount + 1);
if (packet->additional == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
werror = dns_copy_tsig(mem_ctx, tsig,
&packet->additional[packet->arcount]);
if (!W_ERROR_IS_OK(werror)) {
return werror;
}
packet->arcount++;
return WERR_OK;
}
static WERROR dns_tsig_compute_mac(TALLOC_CTX *mem_ctx,
struct dns_request_state *state,
struct dns_name_packet *packet,
struct dns_server_tkey *tkey,
time_t current_time,
DATA_BLOB *_psig)
{
NTSTATUS status;
enum ndr_err_code ndr_err;
DATA_BLOB packet_blob, tsig_blob, sig;
uint8_t *buffer = NULL;
uint8_t *p = NULL;
size_t buffer_len = 0;
struct dns_fake_tsig_rec *check_rec = talloc_zero(mem_ctx,
struct dns_fake_tsig_rec);
size_t mac_size = 0;
if (check_rec == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
/* first build and verify check packet */
check_rec->name = talloc_strdup(check_rec, tkey->name);
if (check_rec->name == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
check_rec->rr_class = DNS_QCLASS_ANY;
check_rec->ttl = 0;
check_rec->algorithm_name = talloc_strdup(check_rec, tkey->algorithm);
if (check_rec->algorithm_name == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
check_rec->time_prefix = 0;
check_rec->time = current_time;
check_rec->fudge = 300;
check_rec->error = state->tsig_error;
check_rec->other_size = 0;
check_rec->other_data = NULL;
ndr_err = ndr_push_struct_blob(&packet_blob, mem_ctx, packet,
(ndr_push_flags_fn_t)ndr_push_dns_name_packet);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
DEBUG(1, ("Failed to push packet: %s!\n",
ndr_errstr(ndr_err)));
return DNS_ERR(SERVER_FAILURE);
}
ndr_err = ndr_push_struct_blob(&tsig_blob, mem_ctx, check_rec,
(ndr_push_flags_fn_t)ndr_push_dns_fake_tsig_rec);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
DEBUG(1, ("Failed to push packet: %s!\n",
ndr_errstr(ndr_err)));
return DNS_ERR(SERVER_FAILURE);
}
if (state->tsig != NULL) {
mac_size = state->tsig->rdata.tsig_record.mac_size;
}
buffer_len = mac_size;
buffer_len += packet_blob.length;
if (buffer_len < packet_blob.length) {
return WERR_INVALID_PARAMETER;
}
buffer_len += tsig_blob.length;
if (buffer_len < tsig_blob.length) {
return WERR_INVALID_PARAMETER;
}
buffer = talloc_zero_array(mem_ctx, uint8_t, buffer_len);
if (buffer == NULL) {
return WERR_NOT_ENOUGH_MEMORY;
}
p = buffer;
/*
* RFC 2845 "4.2 TSIG on Answers", how to lay out the buffer
* that we're going to sign:
* 1. MAC of request (if present)
* 2. Outgoing packet
* 3. TSIG record
*/
if (mac_size > 0) {
memcpy(p, state->tsig->rdata.tsig_record.mac, mac_size);
p += mac_size;
}
memcpy(p, packet_blob.data, packet_blob.length);
p += packet_blob.length;
memcpy(p, tsig_blob.data, tsig_blob.length);
status = gensec_sign_packet(tkey->gensec, mem_ctx, buffer, buffer_len,
buffer, buffer_len, &sig);
if (!NT_STATUS_IS_OK(status)) {
return ntstatus_to_werror(status);
}
*_psig = sig;
return WERR_OK;
}
WERROR dns_replace_records(struct dns_server *dns,
TALLOC_CTX *mem_ctx,
struct ldb_dn *dn,
bool needs_add,
const struct dnsp_DnssrvRpcRecord *records,
uint16_t rec_count)
{
struct ldb_message_element *el;
uint16_t i;
int ret;
struct ldb_message *msg = NULL;
msg = ldb_msg_new(mem_ctx);
W_ERROR_HAVE_NO_MEMORY(msg);
msg->dn = dn;
ret = ldb_msg_add_empty(msg, "dnsRecord", LDB_FLAG_MOD_REPLACE, &el);
if (ret != LDB_SUCCESS) {
return DNS_ERR(SERVER_FAILURE);
}
el->values = talloc_zero_array(el, struct ldb_val, rec_count);
if (rec_count > 0) {
W_ERROR_HAVE_NO_MEMORY(el->values);
}
for (i = 0; i < rec_count; i++) {
static const struct dnsp_DnssrvRpcRecord zero;
struct ldb_val *v = &el->values[el->num_values];
enum ndr_err_code ndr_err;
if (memcmp(&records[i], &zero, sizeof(zero)) == 0) {
continue;
}
ndr_err = ndr_push_struct_blob(v, el->values, &records[i],
(ndr_push_flags_fn_t)ndr_push_dnsp_DnssrvRpcRecord);
if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) {
DEBUG(0, ("Failed to grab dnsp_DnssrvRpcRecord\n"));
return DNS_ERR(SERVER_FAILURE);
}
el->num_values++;
}
if (el->num_values == 0) {
if (needs_add) {
return WERR_OK;
}
/* TODO: Delete object? */
}
if (needs_add) {
ret = ldb_msg_add_string(msg, "objectClass", "dnsNode");
if (ret != LDB_SUCCESS) {
return DNS_ERR(SERVER_FAILURE);
}
ret = ldb_add(dns->samdb, msg);
if (ret != LDB_SUCCESS) {
return DNS_ERR(SERVER_FAILURE);
}
return WERR_OK;
}
ret = ldb_modify(dns->samdb, msg);
if (ret != LDB_SUCCESS) {
return DNS_ERR(SERVER_FAILURE);
}
return WERR_OK;
}
