/* $NetBSD: dhcpv6.c,v 1.3 2019/01/10 17:41:47 christos Exp $ */
/*
* Copyright (C) 2006-2017 by Internet Systems Consortium, Inc. ("ISC")
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND ISC DISCLAIMS ALL WARRANTIES WITH
* REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY
* AND FITNESS. IN NO EVENT SHALL ISC BE LIABLE FOR ANY SPECIAL, DIRECT,
* INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM
* LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE
* OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR
* PERFORMANCE OF THIS SOFTWARE.
*/
#include <sys/cdefs.h>
__RCSID("$NetBSD: dhcpv6.c,v 1.3 2019/01/10 17:41:47 christos Exp $");
/*! \file server/dhcpv6.c */
#include "dhcpd.h"
#ifdef DHCPv6
#ifdef DHCP4o6
static void forw_dhcpv4_query(struct packet *packet);
static void send_dhcpv4_response(struct data_string *raw);
static void recv_dhcpv4_query(struct data_string *raw);
static void dhcp4o6_dhcpv4_query(struct data_string *reply_ret,
struct packet *packet);
struct udp_data4o6 {
u_int16_t src_port;
u_int8_t rsp_opt_exist;
u_int8_t reserved;
};
static int offset_data4o6 = 36; /* 16+16+4 */
#endif
/*
* We use print_hex_1() to output DUID values. We could actually output
* the DUID with more information... MAC address if using type 1 or 3,
* and so on. However, RFC 3315 contains Grave Warnings against actually
* attempting to understand a DUID.
*/
/*
* TODO: gettext() or other method of localization for the messages
* for status codes (and probably for log formats eventually)
* TODO: refactoring (simplify, simplify, simplify)
* TODO: support multiple shared_networks on each interface (this
* will allow the server to issue multiple IPv6 addresses to
* a single interface)
*/
/*
* DHCPv6 Reply workflow assist. A Reply packet is built by various
* different functions; this gives us one location where we keep state
* regarding a reply.
*/
struct reply_state {
/* root level persistent state */
struct shared_network *shared;
struct host_decl *host;
struct subnet *subnet; /* Used to match fixed-addrs to subnet scopes. */
struct option_state *opt_state;
struct packet *packet;
struct data_string client_id;
/* IA level persistent state */
unsigned ia_count;
unsigned pd_count;
unsigned client_resources;
isc_boolean_t resources_included;
isc_boolean_t static_lease;
unsigned static_prefixes;
struct ia_xx *ia;
struct ia_xx *old_ia;
struct option_state *reply_ia;
struct data_string fixed;
struct iaddrcidrnet fixed_pref; /* static prefix for logging */
/* IAADDR/PREFIX level persistent state */
struct iasubopt *lease;
/*
* "t1", "t2", preferred, and valid lifetimes records for calculating
* t1 and t2 (min/max).
*/
u_int32_t renew, rebind, min_prefer, min_valid;
/* Client-requested valid and preferred lifetimes. */
u_int32_t client_valid, client_prefer;
/* Chosen values to transmit for valid and preferred lifetimes. */
u_int32_t send_valid, send_prefer;
/* Preferred prefix length (-1 is any). */
int preflen;
/* Index into the data field that has been consumed. */
unsigned cursor;
/* Space for the on commit statements for a fixed host */
struct on_star on_star;
union reply_buffer {
unsigned char data[65536];
struct dhcpv6_packet reply;
} buf;
};
/*
* Prototypes local to this file.
*/
static int get_encapsulated_IA_state(struct option_state **enc_opt_state,
struct data_string *enc_opt_data,
struct packet *packet,
struct option_cache *oc,
int offset);
static void build_dhcpv6_reply(struct data_string *, struct packet *);
static isc_result_t shared_network_from_packet6(struct shared_network **shared,
struct packet *packet);
static void seek_shared_host(struct host_decl **hp,
struct shared_network *shared);
static isc_boolean_t fixed_matches_shared(struct host_decl *host,
struct shared_network *shared);
static isc_result_t reply_process_ia_na(struct reply_state *reply,
struct option_cache *ia);
static isc_result_t reply_process_ia_ta(struct reply_state *reply,
struct option_cache *ia);
static isc_result_t reply_process_addr(struct reply_state *reply,
struct option_cache *addr);
static isc_boolean_t address_is_owned(struct reply_state *reply,
struct iaddr *addr);
static isc_boolean_t temporary_is_available(struct reply_state *reply,
struct iaddr *addr);
static isc_result_t find_client_temporaries(struct reply_state *reply);
static isc_result_t reply_process_try_addr(struct reply_state *reply,
struct iaddr *addr);
static isc_result_t find_client_address(struct reply_state *reply);
static isc_result_t reply_process_is_addressed(struct reply_state *reply,
struct binding_scope **scope,
struct group *group);
static isc_result_t reply_process_send_addr(struct reply_state *reply,
struct iaddr *addr);
static struct iasubopt *lease_compare(struct iasubopt *alpha,
struct iasubopt *beta);
static isc_result_t reply_process_ia_pd(struct reply_state *reply,
struct option_cache *ia_pd);
static struct group *find_group_by_prefix(struct reply_state *reply);
static isc_result_t reply_process_prefix(struct reply_state *reply,
struct option_cache *pref);
static isc_boolean_t prefix_is_owned(struct reply_state *reply,
struct iaddrcidrnet *pref);
static isc_result_t find_client_prefix(struct reply_state *reply);
static isc_result_t reply_process_try_prefix(struct reply_state *reply,
struct iaddrcidrnet *pref);
static isc_result_t reply_process_is_prefixed(struct reply_state *reply,
struct binding_scope **scope,
struct group *group);
static isc_result_t reply_process_send_prefix(struct reply_state *reply,
struct iaddrcidrnet *pref);
static struct iasubopt *prefix_compare(struct reply_state *reply,
struct iasubopt *alpha,
struct iasubopt *beta);
static void schedule_lease_timeout_reply(struct reply_state *reply);
static int eval_prefix_mode(int thislen, int preflen, int prefix_mode);
static isc_result_t pick_v6_prefix_helper(struct reply_state *reply,
int prefix_mode);
static void unicast_reject(struct data_string *reply_ret, struct packet *packet,
const struct data_string *client_id,
const struct data_string *server_id);
static isc_boolean_t is_unicast_option_defined(struct packet *packet);
static isc_result_t shared_network_from_requested_addr (struct shared_network
**shared,
struct packet* packet);
static isc_result_t get_first_ia_addr_val (struct packet* packet, int addr_type,
struct iaddr* iaddr);
static void
set_reply_tee_times(struct reply_state* reply, unsigned ia_cursor);
static const char *iasubopt_plen_str(struct iasubopt *lease);
static int release_on_roam(struct reply_state *reply);
static int reuse_lease6(struct reply_state *reply, struct iasubopt *lease);
static void shorten_lifetimes(struct reply_state *reply, struct iasubopt *lease,
time_t age, int threshold);
static void write_to_packet(struct reply_state *reply, unsigned ia_cursor);
static const char *iasubopt_plen_str(struct iasubopt *lease);
#ifdef NSUPDATE
static void ddns_update_static6(struct reply_state* reply);
#endif
#ifdef DHCP4o6
/*
* \brief Omapi I/O handler
*
* The inter-process communication receive handler.
* Get the message, put it into the raw data_string
* and call \ref send_dhcpv4_response() (DHCPv6 side) or
* \ref recv_dhcpv4_query() (DHCPv4 side)
*
* \param h the OMAPI object
* \return a result for I/O success or error (used by the I/O subsystem)
*/
isc_result_t dhcpv4o6_handler(omapi_object_t *h) {
char buf[65536];
struct data_string raw;
int cc;
if (h->type != dhcp4o6_type)
return DHCP_R_INVALIDARG;
cc = recv(dhcp4o6_fd, buf, sizeof(buf), 0);
if (cc < DHCP_FIXED_NON_UDP + offset_data4o6)
return ISC_R_UNEXPECTED;
memset(&raw, 0, sizeof(raw));
if (!buffer_allocate(&raw.buffer, cc, MDL)) {
log_error("dhcpv4o6_handler: no memory buffer.");
return ISC_R_NOMEMORY;
}
raw.data = raw.buffer->data;
raw.len = cc;
memcpy(raw.buffer->data, buf, cc);
if (local_family == AF_INET6) {
send_dhcpv4_response(&raw);
} else {
recv_dhcpv4_query(&raw);
}
data_string_forget(&raw, MDL);
return ISC_R_SUCCESS;
}
/*
* \brief Send the DHCPv4-response back to the DHCPv6 side
* (DHCPv6 server function)
*
* Format: interface:16 + address:16 + udp:4 + DHCPv6 DHCPv4-response message
*
* \param raw the IPC message content
*/
static void send_dhcpv4_response(struct data_string *raw) {
struct interface_info *ip;
char name[16 + 1];
struct sockaddr_in6 to_addr;
char pbuf[sizeof("ffff:ffff:ffff:ffff:ffff:ffff:255.255.255.255")];
struct udp_data4o6 udp_data;
int send_ret;
memset(name, 0, sizeof(name));
memcpy(name, raw->data, 16);
for (ip = interfaces; ip != NULL; ip = ip->next) {
if (!strcmp(name, ip->name))
break;
}
if (ip == NULL) {
log_error("send_dhcpv4_response: can't find interface %s.",
name);
return;
}
memset(&to_addr, 0, sizeof(to_addr));
to_addr.sin6_family = AF_INET6;
memcpy(&to_addr.sin6_addr, raw->data + 16, 16);
memset(&udp_data, 0, sizeof(udp_data));
memcpy(&udp_data, raw->data + 32, 4);
if ((raw->data[36] == DHCPV6_RELAY_FORW) ||
(raw->data[36] == DHCPV6_RELAY_REPL)) {
if (udp_data.rsp_opt_exist) {
to_addr.sin6_port = udp_data.src_port;
} else {
to_addr.sin6_port = local_port;
}
} else {
to_addr.sin6_port = remote_port;
}
log_info("send_dhcpv4_response(): sending %s on %s to %s port %d",
dhcpv6_type_names[raw->data[36]],
name,
inet_ntop(AF_INET6, raw->data + 16, pbuf, sizeof(pbuf)),
ntohs(to_addr.sin6_port));
send_ret = send_packet6(ip, raw->data + 36, raw->len - 36, &to_addr);
if (send_ret < 0) {
log_error("send_dhcpv4_response: send_packet6(): %m");
} else if (send_ret != raw->len - 36) {
log_error("send_dhcpv4_response: send_packet6() "
"sent %d of %d bytes",
send_ret, raw->len - 36);
}
}
#endif /* DHCP4o6 */
/*
* Schedule lease timeouts for all of the iasubopts in the reply.
* This is currently used to schedule timeouts for soft leases.
*/
static void
schedule_lease_timeout_reply(struct reply_state *reply) {
struct iasubopt *tmp;
int i;
/* sanity check the reply */
if ((reply == NULL) || (reply->ia == NULL) || (reply->ia->iasubopt == NULL))
return;
/* walk through the list, scheduling as we go */
for (i = 0 ; i < reply->ia->num_iasubopt ; i++) {
tmp = reply->ia->iasubopt[i];
schedule_lease_timeout(tmp->ipv6_pool);
}
}
/*
* This function returns the time since DUID time start for the
* given time_t value.
*/
static u_int32_t
duid_time(time_t when) {
/*
* This time is modulo 2^32.
*/
while ((when - DUID_TIME_EPOCH) > 4294967295u) {
/* use 2^31 to avoid spurious compiler warnings */
when -= 2147483648u;
when -= 2147483648u;
}
return when - DUID_TIME_EPOCH;
}
/*
* Server DUID.
*
* This must remain the same for the lifetime of this server, because
* clients return the server DUID that we sent them in Request packets.
*
* We pick the server DUID like this:
*
* 1. Check dhcpd.conf - any value the administrator has configured
* overrides any possible values.
* 2. Check the leases.txt - we want to use the previous value if
* possible.
* 3. Check if dhcpd.conf specifies a type of server DUID to use,
* and generate that type.
* 4. Generate a type 1 (time + hardware address) DUID.
*/
static struct data_string server_duid;
/*
* Check if the server_duid has been set.
*/
isc_boolean_t
server_duid_isset(void) {
return (server_duid.data != NULL);
}
/*
* Return the server_duid.
*/
void
copy_server_duid(struct data_string *ds, const char *file, int line) {
data_string_copy(ds, &server_duid, file, line);
}
/*
* Set the server DUID to a specified value. This is used when
* the server DUID is stored in persistent memory (basically the
* leases.txt file).
*/
void
set_server_duid(struct data_string *new_duid) {
/* INSIST(new_duid != NULL); */
/* INSIST(new_duid->data != NULL); */
if (server_duid_isset()) {
data_string_forget(&server_duid, MDL);
}
data_string_copy(&server_duid, new_duid, MDL);
}
/*
* Set the server DUID based on the D6O_SERVERID option. This handles
* the case where the administrator explicitly put it in the dhcpd.conf
* file.
*/
isc_result_t
set_server_duid_from_option(void) {
struct option_state *opt_state;
struct option_cache *oc;
struct data_string option_duid;
isc_result_t ret_val;
opt_state = NULL;
if (!option_state_allocate(&opt_state, MDL)) {
log_fatal("No memory for server DUID.");
}
execute_statements_in_scope(NULL, NULL, NULL, NULL, NULL,
opt_state, &global_scope, root_group,
NULL, NULL);
oc = lookup_option(&dhcpv6_universe, opt_state, D6O_SERVERID);
if (oc == NULL) {
ret_val = ISC_R_NOTFOUND;
} else {
memset(&option_duid, 0, sizeof(option_duid));
if (!evaluate_option_cache(&option_duid, NULL, NULL, NULL,
opt_state, NULL, &global_scope,
oc, MDL)) {
ret_val = ISC_R_UNEXPECTED;
} else {
set_server_duid(&option_duid);
data_string_forget(&option_duid, MDL);
ret_val = ISC_R_SUCCESS;
}
}
option_state_dereference(&opt_state, MDL);
return ret_val;
}
/*
* DUID layout, as defined in RFC 3315, section 9.
*
* We support type 1 (hardware address plus time) and type 3 (hardware
* address).
*
* We can support type 2 for specific vendors in the future, if they
* publish the specification. And of course there may be additional
* types later.
*/
static int server_duid_type = DUID_LLT;
/*
* Set the DUID type.
*/
void
set_server_duid_type(int type) {
server_duid_type = type;
}
/*
* Generate a new server DUID. This is done if there was no DUID in
* the leases.txt or in the dhcpd.conf file.
*/
isc_result_t
generate_new_server_duid(void) {
struct interface_info *p;
u_int32_t time_val;
struct data_string generated_duid;
/*
* Verify we have a type that we support.
*/
if ((server_duid_type != DUID_LL) && (server_duid_type != DUID_LLT)) {
log_error("Invalid DUID type %d specified, "
"only LL and LLT types supported", server_duid_type);
return DHCP_R_INVALIDARG;
}
/*
* Find an interface with a hardware address.
* Any will do. :)
*/
for (p = interfaces; p != NULL; p = p->next) {
if (p->hw_address.hlen > 0) {
break;
}
}
if (p == NULL) {
return ISC_R_UNEXPECTED;
}
/*
* Build our DUID.
*/
memset(&generated_duid, 0, sizeof(generated_duid));
if (server_duid_type == DUID_LLT) {
time_val = duid_time(time(NULL));
generated_duid.len = 8 + p->hw_address.hlen - 1;
if (!buffer_allocate(&generated_duid.buffer,
generated_duid.len, MDL)) {
log_fatal("No memory for server DUID.");
}
generated_duid.data = generated_duid.buffer->data;
putUShort(generated_duid.buffer->data, DUID_LLT);
putUShort(generated_duid.buffer->data + 2,
p->hw_address.hbuf[0]);
putULong(generated_duid.buffer->data + 4, time_val);
memcpy(generated_duid.buffer->data + 8,
p->hw_address.hbuf+1, p->hw_address.hlen-1);
} else if (server_duid_type == DUID_LL) {
generated_duid.len = 4 + p->hw_address.hlen - 1;
if (!buffer_allocate(&generated_duid.buffer,
generated_duid.len, MDL)) {
log_fatal("No memory for server DUID.");
}
generated_duid.data = generated_duid.buffer->data;
putUShort(generated_duid.buffer->data, DUID_LL);
putUShort(generated_duid.buffer->data + 2,
p->hw_address.hbuf[0]);
memcpy(generated_duid.buffer->data + 4,
p->hw_address.hbuf+1, p->hw_address.hlen-1);
} else {
log_fatal("Unsupported server DUID type %d.", server_duid_type);
}
set_server_duid(&generated_duid);
data_string_forget(&generated_duid, MDL);
return ISC_R_SUCCESS;
}
/*
* Get the client identifier from the packet.
*/
isc_result_t
get_client_id(struct packet *packet, struct data_string *client_id) {
struct option_cache *oc;
/*
* Verify our client_id structure is empty.
*/
if ((client_id->data != NULL) || (client_id->len != 0)) {
return DHCP_R_INVALIDARG;
}
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_CLIENTID);
if (oc == NULL) {
return ISC_R_NOTFOUND;
}
if (!evaluate_option_cache(client_id, packet, NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
return ISC_R_FAILURE;
}
return ISC_R_SUCCESS;
}
/*
* Message validation, defined in RFC 3315, sections 15.2, 15.5, 15.7:
*
* Servers MUST discard any Solicit messages that do not include a
* Client Identifier option or that do include a Server Identifier
* option.
*/
static int
valid_client_msg(struct packet *packet, struct data_string *client_id) {
int ret_val;
struct option_cache *oc;
struct data_string data;
ret_val = 0;
memset(client_id, 0, sizeof(*client_id));
memset(&data, 0, sizeof(data));
switch (get_client_id(packet, client_id)) {
case ISC_R_SUCCESS:
break;
case ISC_R_NOTFOUND:
log_debug("Discarding %s from %s; "
"client identifier missing",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr));
goto exit;
default:
log_error("Error processing %s from %s; "
"unable to evaluate Client Identifier",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr));
goto exit;
}
/*
* Required by RFC 3315, section 15.
*/
if (packet->unicast) {
log_debug("Discarding %s from %s; packet sent unicast "
"(CLIENTID %s)",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr),
print_hex_1(client_id->len, client_id->data, 60));
goto exit;
}
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_SERVERID);
if (oc != NULL) {
if (evaluate_option_cache(&data, packet, NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_debug("Discarding %s from %s; "
"server identifier found "
"(CLIENTID %s, SERVERID %s)",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr),
print_hex_1(client_id->len,
client_id->data, 60),
print_hex_2(data.len,
data.data, 60));
} else {
log_debug("Discarding %s from %s; "
"server identifier found "
"(CLIENTID %s)",
dhcpv6_type_names[packet->dhcpv6_msg_type],
print_hex_1(client_id->len,
client_id->data, 60),
piaddr(packet->client_addr));
}
goto exit;
}
/* looks good */
ret_val = 1;
exit:
if (data.len > 0) {
data_string_forget(&data, MDL);
}
if (!ret_val) {
if (client_id->len > 0) {
data_string_forget(client_id, MDL);
}
}
return ret_val;
}
/*
* Response validation, defined in RFC 3315, sections 15.4, 15.6, 15.8,
* 15.9 (slightly different wording, but same meaning):
*
* Servers MUST discard any received Request message that meet any of
* the following conditions:
*
* - the message does not include a Server Identifier option.
* - the contents of the Server Identifier option do not match the
* server's DUID.
* - the message does not include a Client Identifier option.
*/
static int
valid_client_resp(struct packet *packet,
struct data_string *client_id,
struct data_string *server_id)
{
int ret_val;
struct option_cache *oc;
/* INSIST((duid.data != NULL) && (duid.len > 0)); */
ret_val = 0;
memset(client_id, 0, sizeof(*client_id));
memset(server_id, 0, sizeof(*server_id));
switch (get_client_id(packet, client_id)) {
case ISC_R_SUCCESS:
break;
case ISC_R_NOTFOUND:
log_debug("Discarding %s from %s; "
"client identifier missing",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr));
goto exit;
default:
log_error("Error processing %s from %s; "
"unable to evaluate Client Identifier",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr));
goto exit;
}
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_SERVERID);
if (oc == NULL) {
log_debug("Discarding %s from %s: "
"server identifier missing (CLIENTID %s)",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr),
print_hex_1(client_id->len, client_id->data, 60));
goto exit;
}
if (!evaluate_option_cache(server_id, packet, NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("Error processing %s from %s; "
"unable to evaluate Server Identifier (CLIENTID %s)",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr),
print_hex_1(client_id->len, client_id->data, 60));
goto exit;
}
if ((server_duid.len != server_id->len) ||
(memcmp(server_duid.data, server_id->data, server_duid.len) != 0)) {
log_debug("Discarding %s from %s; "
"not our server identifier "
"(CLIENTID %s, SERVERID %s, server DUID %s)",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr),
print_hex_1(client_id->len, client_id->data, 60),
print_hex_2(server_id->len, server_id->data, 60),
print_hex_3(server_duid.len, server_duid.data, 60));
goto exit;
}
/* looks good */
ret_val = 1;
exit:
if (!ret_val) {
if (server_id->len > 0) {
data_string_forget(server_id, MDL);
}
if (client_id->len > 0) {
data_string_forget(client_id, MDL);
}
}
return ret_val;
}
/*
* Information request validation, defined in RFC 3315, section 15.12:
*
* Servers MUST discard any received Information-request message that
* meets any of the following conditions:
*
* - The message includes a Server Identifier option and the DUID in
* the option does not match the server's DUID.
*
* - The message includes an IA option.
*/
static int
valid_client_info_req(struct packet *packet, struct data_string *server_id) {
int ret_val;
struct option_cache *oc;
struct data_string client_id;
char client_id_str[80]; /* print_hex_1() uses maximum 60 characters,
plus a few more for extra information */
ret_val = 0;
memset(server_id, 0, sizeof(*server_id));
memset(&client_id, 0, sizeof(client_id));
/*
* Make a string that we can print out to give more
* information about the client if we need to.
*
* By RFC 3315, Section 18.1.5 clients SHOULD have a
* client-id on an Information-request packet, but it
* is not strictly necessary.
*/
if (get_client_id(packet, &client_id) == ISC_R_SUCCESS) {
snprintf(client_id_str, sizeof(client_id_str), " (CLIENTID %s)",
print_hex_1(client_id.len, client_id.data, 60));
data_string_forget(&client_id, MDL);
} else {
client_id_str[0] = '\0';
}
/*
* Required by RFC 3315, section 15.
*/
if (packet->unicast) {
log_debug("Discarding %s from %s; packet sent unicast%s",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr), client_id_str);
goto exit;
}
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_IA_NA);
if (oc != NULL) {
log_debug("Discarding %s from %s; "
"IA_NA option present%s",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr), client_id_str);
goto exit;
}
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_IA_TA);
if (oc != NULL) {
log_debug("Discarding %s from %s; "
"IA_TA option present%s",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr), client_id_str);
goto exit;
}
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_IA_PD);
if (oc != NULL) {
log_debug("Discarding %s from %s; "
"IA_PD option present%s",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr), client_id_str);
goto exit;
}
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_SERVERID);
if (oc != NULL) {
if (!evaluate_option_cache(server_id, packet, NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("Error processing %s from %s; "
"unable to evaluate Server Identifier%s",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr), client_id_str);
goto exit;
}
if ((server_duid.len != server_id->len) ||
(memcmp(server_duid.data, server_id->data,
server_duid.len) != 0)) {
log_debug("Discarding %s from %s; "
"not our server identifier "
"(SERVERID %s, server DUID %s)%s",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr),
print_hex_1(server_id->len,
server_id->data, 60),
print_hex_2(server_duid.len,
server_duid.data, 60),
client_id_str);
goto exit;
}
}
/* looks good */
ret_val = 1;
exit:
if (!ret_val) {
if (server_id->len > 0) {
data_string_forget(server_id, MDL);
}
}
return ret_val;
}
/*
* Options that we want to send, in addition to what was requested
* via the ORO.
*/
static const int required_opts[] = {
D6O_CLIENTID,
D6O_SERVERID,
D6O_STATUS_CODE,
D6O_PREFERENCE,
0
};
static const int required_opts_solicit[] = {
D6O_CLIENTID,
D6O_SERVERID,
D6O_IA_NA,
D6O_IA_TA,
D6O_IA_PD,
D6O_RAPID_COMMIT,
D6O_STATUS_CODE,
D6O_RECONF_ACCEPT,
D6O_PREFERENCE,
0
};
static const int required_opts_agent[] = {
D6O_INTERFACE_ID,
#if defined(RELAY_PORT)
D6O_RELAY_SOURCE_PORT,
#endif
D6O_RELAY_MSG,
0
};
static const int required_opts_IA[] = {
D6O_IAADDR,
D6O_STATUS_CODE,
0
};
static const int required_opts_IA_PD[] = {
D6O_IAPREFIX,
D6O_STATUS_CODE,
0
};
static const int required_opts_STATUS_CODE[] = {
D6O_STATUS_CODE,
0
};
#ifdef DHCP4o6
static const int required_opts_4o6[] = {
D6O_DHCPV4_MSG,
0
};
#endif
static const int unicast_reject_opts[] = {
D6O_CLIENTID,
D6O_SERVERID,
D6O_STATUS_CODE,
0
};
/*
* Extracts from packet contents an IA_* option, storing the IA structure
* in its entirety in enc_opt_data, and storing any decoded DHCPv6 options
* in enc_opt_state for later lookup and evaluation. The 'offset' indicates
* where in the IA_* the DHCPv6 options commence.
*/
static int
get_encapsulated_IA_state(struct option_state **enc_opt_state,
struct data_string *enc_opt_data,
struct packet *packet,
struct option_cache *oc,
int offset)
{
/*
* Get the raw data for the encapsulated options.
*/
memset(enc_opt_data, 0, sizeof(*enc_opt_data));
if (!evaluate_option_cache(enc_opt_data, packet,
NULL, NULL, packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("get_encapsulated_IA_state: "
"error evaluating raw option.");
return 0;
}
if (enc_opt_data->len < offset) {
log_error("get_encapsulated_IA_state: raw option too small.");
data_string_forget(enc_opt_data, MDL);
return 0;
}
/*
* Now create the option state structure, and pass it to the
* function that parses options.
*/
*enc_opt_state = NULL;
if (!option_state_allocate(enc_opt_state, MDL)) {
log_error("get_encapsulated_IA_state: no memory for options.");
data_string_forget(enc_opt_data, MDL);
return 0;
}
if (!parse_option_buffer(*enc_opt_state,
enc_opt_data->data + offset,
enc_opt_data->len - offset,
&dhcpv6_universe)) {
log_error("get_encapsulated_IA_state: error parsing options.");
option_state_dereference(enc_opt_state, MDL);
data_string_forget(enc_opt_data, MDL);
return 0;
}
return 1;
}
static int
set_status_code(u_int16_t status_code, const char *status_message,
struct option_state *opt_state)
{
struct data_string d;
int ret_val;
memset(&d, 0, sizeof(d));
d.len = sizeof(status_code) + strlen(status_message);
if (!buffer_allocate(&d.buffer, d.len, MDL)) {
log_fatal("set_status_code: no memory for status code.");
}
d.data = d.buffer->data;
putUShort(d.buffer->data, status_code);
memcpy(d.buffer->data + sizeof(status_code),
status_message, d.len - sizeof(status_code));
if (!save_option_buffer(&dhcpv6_universe, opt_state,
d.buffer, (unsigned char *)d.data, d.len,
D6O_STATUS_CODE, 0)) {
log_error("set_status_code: error saving status code.");
ret_val = 0;
} else {
ret_val = 1;
}
data_string_forget(&d, MDL);
return ret_val;
}
static void check_pool6_threshold(struct reply_state *reply,
struct iasubopt *lease)
{
struct ipv6_pond *pond;
isc_uint64_t used, count, high_threshold;
int poolhigh = 0, poollow = 0;
char *shared_name = "no name";
char tmp_addr[INET6_ADDRSTRLEN];
if ((lease->ipv6_pool == NULL) || (lease->ipv6_pool->ipv6_pond == NULL))
return;
pond = lease->ipv6_pool->ipv6_pond;
/* If the address range is too large to track, just skip all this. */
if (pond->jumbo_range == 1) {
return;
}
count = pond->num_total;
used = pond->num_active;
/* get network name for logging */
if ((pond->shared_network != NULL) &&
(pond->shared_network->name != NULL)) {
shared_name = pond->shared_network->name;
}
/* The logged flag indicates if we have already crossed the high
* threshold and emitted a log message. If it is set we check to
* see if we have re-crossed the low threshold and need to reset
* things. When we cross the high threshold we determine what
* the low threshold is and save it into the low_threshold value.
* When we cross that threshold we reset the logged flag and
* the low_threshold to 0 which allows the high threshold message
* to be emitted once again.
* if we haven't recrossed the boundry we don't need to do anything.
*/
if (pond->logged !=0) {
if (used <= pond->low_threshold) {
pond->low_threshold = 0;
pond->logged = 0;
log_error("Pool threshold reset - shared subnet: %s; "
"address: %s; low threshold %" PRIu64 "/%" PRIu64 ".",
shared_name,
inet_ntop(AF_INET6, &lease->addr,
tmp_addr, sizeof(tmp_addr)),
used, count);
}
return;
}
/* find the high threshold */
if (get_option_int(&poolhigh, &server_universe, reply->packet, NULL,
NULL, reply->packet->options, reply->opt_state,
reply->opt_state, &lease->scope,
SV_LOG_THRESHOLD_HIGH, MDL) == 0) {
/* no threshold bail out */
return;
}
/* We do have a threshold for this pool, see if its valid */
if ((poolhigh <= 0) || (poolhigh > 100)) {
/* not valid */
return;
}
/* we have a valid value, have we exceeded it */
high_threshold = FIND_POND6_PERCENT(count, poolhigh);
if (used < high_threshold) {
/* nope, no more to do */
return;
}
/* we've exceeded it, output a message */
log_error("Pool threshold exceeded - shared subnet: %s; "
"address: %s; high threshold %d%% %" PRIu64 "/%" PRIu64 ".",
shared_name,
inet_ntop(AF_INET6, &lease->addr, tmp_addr, sizeof(tmp_addr)),
poolhigh, used, count);
/* handle the low threshold now, if we don't
* have one we default to 0. */
if ((get_option_int(&poollow, &server_universe, reply->packet, NULL,
NULL, reply->packet->options, reply->opt_state,
reply->opt_state, &lease->scope,
SV_LOG_THRESHOLD_LOW, MDL) == 0) ||
(poollow > 100)) {
poollow = 0;
}
/*
* If the low theshold is higher than the high threshold we continue to log
* If it isn't then we set the flag saying we already logged and determine
* what the reset threshold is.
*/
if (poollow < poolhigh) {
pond->logged = 1;
pond->low_threshold = FIND_POND6_PERCENT(count, poollow);
}
}
/*
* We have a set of operations we do to set up the reply packet, which
* is the same for many message types.
*/
static int
start_reply(struct packet *packet,
const struct data_string *client_id,
const struct data_string *server_id,
struct option_state **opt_state,
struct dhcpv6_packet *reply)
{
struct option_cache *oc;
const unsigned char *server_id_data;
int server_id_len;
/*
* Build our option state for reply.
*/
*opt_state = NULL;
if (!option_state_allocate(opt_state, MDL)) {
log_error("start_reply: no memory for option_state.");
return 0;
}
execute_statements_in_scope(NULL, packet, NULL, NULL,
packet->options, *opt_state,
&global_scope, root_group, NULL, NULL);
/*
* A small bit of special handling for Solicit messages.
*
* We could move the logic into a flag, but for now just check
* explicitly.
*/
if (packet->dhcpv6_msg_type == DHCPV6_SOLICIT) {
reply->msg_type = DHCPV6_ADVERTISE;
/*
* If:
* - this message type supports rapid commit (Solicit), and
* - the server is configured to supply a rapid commit, and
* - the client requests a rapid commit,
* Then we add a rapid commit option, and send Reply (instead
* of an Advertise).
*/
oc = lookup_option(&dhcpv6_universe,
*opt_state, D6O_RAPID_COMMIT);
if (oc != NULL) {
oc = lookup_option(&dhcpv6_universe,
packet->options, D6O_RAPID_COMMIT);
if (oc != NULL) {
/* Rapid-commit in action. */
reply->msg_type = DHCPV6_REPLY;
} else {
/* Don't want a rapid-commit in advertise. */
delete_option(&dhcpv6_universe,
*opt_state, D6O_RAPID_COMMIT);
}
}
} else {
reply->msg_type = DHCPV6_REPLY;
/* Delete the rapid-commit from the sent options. */
oc = lookup_option(&dhcpv6_universe,
*opt_state, D6O_RAPID_COMMIT);
if (oc != NULL) {
delete_option(&dhcpv6_universe,
*opt_state, D6O_RAPID_COMMIT);
}
}
/*
* Use the client's transaction identifier for the reply.
*/
memcpy(reply->transaction_id, packet->dhcpv6_transaction_id,
sizeof(reply->transaction_id));
/*
* RFC 3315, section 18.2 says we need server identifier and
* client identifier.
*
* If the server ID is defined via the configuration file, then
* it will already be present in the option state at this point,
* so we don't need to set it.
*
* If we have a server ID passed in from the caller,
* use that, otherwise use the global DUID.
*/
oc = lookup_option(&dhcpv6_universe, *opt_state, D6O_SERVERID);
if (oc == NULL) {
if (server_id == NULL) {
server_id_data = server_duid.data;
server_id_len = server_duid.len;
} else {
server_id_data = server_id->data;
server_id_len = server_id->len;
}
if (!save_option_buffer(&dhcpv6_universe, *opt_state,
NULL, (unsigned char *)server_id_data,
server_id_len, D6O_SERVERID, 0)) {
log_error("start_reply: "
"error saving server identifier.");
return 0;
}
}
if (client_id->buffer != NULL) {
if (!save_option_buffer(&dhcpv6_universe, *opt_state,
client_id->buffer,
(unsigned char *)client_id->data,
client_id->len,
D6O_CLIENTID, 0)) {
log_error("start_reply: error saving "
"client identifier.");
return 0;
}
}
/*
* If the client accepts reconfiguration, let it know that we
* will send them.
*
* Note: we don't actually do this yet, but DOCSIS requires we
* claim to.
*/
oc = lookup_option(&dhcpv6_universe, packet->options,
D6O_RECONF_ACCEPT);
if (oc != NULL) {
if (!save_option_buffer(&dhcpv6_universe, *opt_state,
NULL, (unsigned char *)"", 0,
D6O_RECONF_ACCEPT, 0)) {
log_error("start_reply: "
"error saving RECONF_ACCEPT option.");
option_state_dereference(opt_state, MDL);
return 0;
}
}
return 1;
}
/*
* Try to get the IPv6 address the client asked for from the
* pool.
*
* addr is the result (should be a pointer to NULL on entry)
* pool is the pool to search in
* requested_addr is the address the client wants
*/
static isc_result_t
try_client_v6_address(struct iasubopt **addr,
struct ipv6_pool *pool,
const struct data_string *requested_addr)
{
struct in6_addr tmp_addr;
isc_result_t result;
if (requested_addr->len < sizeof(tmp_addr)) {
return DHCP_R_INVALIDARG;
}
memcpy(&tmp_addr, requested_addr->data, sizeof(tmp_addr));
if (IN6_IS_ADDR_UNSPECIFIED(&tmp_addr)) {
return ISC_R_FAILURE;
}
/*
* The address is not covered by this (or possibly any) dynamic
* range.
*/
if (!ipv6_in_pool(&tmp_addr, pool)) {
return ISC_R_ADDRNOTAVAIL;
}
if (lease6_exists(pool, &tmp_addr)) {
return ISC_R_ADDRINUSE;
}
result = iasubopt_allocate(addr, MDL);
if (result != ISC_R_SUCCESS) {
return result;
}
(*addr)->addr = tmp_addr;
(*addr)->plen = 0;
/* Default is soft binding for 2 minutes. */
result = add_lease6(pool, *addr, cur_time + 120);
if (result != ISC_R_SUCCESS) {
iasubopt_dereference(addr, MDL);
}
return result;
}
/*!
*
* \brief Get an IPv6 address for the client.
*
* Attempt to find a usable address for the client. We walk through
* the ponds checking for permit and deny then through the pools
* seeing if they have an available address.
*
* \param reply = the state structure for the current work on this request
* if we create a lease we return it using reply->lease
*
* \return
* ISC_R_SUCCESS = we were able to find an address and are returning a
* pointer to the lease
* ISC_R_NORESOURCES = there don't appear to be any free addresses. This
* is probabalistic. We don't exhaustively try the
* address range, instead we hash the duid and if
* the address derived from the hash is in use we
* hash the address. After a number of failures we
* conclude the pool is basically full.
*/
static isc_result_t
pick_v6_address(struct reply_state *reply)
{
struct ipv6_pool *p = NULL;
struct ipv6_pond *pond;
int i;
int start_pool;
unsigned int attempts;
char tmp_buf[INET6_ADDRSTRLEN];
struct iasubopt **addr = &reply->lease;
isc_uint64_t total = 0;
isc_uint64_t active = 0;
isc_uint64_t abandoned = 0;
int jumbo_range = 0;
char *shared_name = (reply->shared->name ?
reply->shared->name : "(no name)");
/*
* Do a quick walk through of the ponds and pools
* to see if we have any NA address pools
*/
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
if (pond->ipv6_pools == NULL)
continue;
for (i = 0; (p = pond->ipv6_pools[i]) != NULL; i++) {
if (p->pool_type == D6O_IA_NA)
break;
}
if (p != NULL)
break;
}
/* If we get here and p is NULL we have no useful pools */
if (p == NULL) {
log_debug("Unable to pick client address: "
"no IPv6 pools on this shared network");
return ISC_R_NORESOURCES;
}
/*
* We have at least one pool that could provide an address
* Now we walk through the ponds and pools again and check
* to see if the client is permitted and if an address is
* available
*
* Within a given pond we start looking at the last pool we
* allocated from, unless it had a collision trying to allocate
* an address. This will tend to move us into less-filled pools.
*/
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
isc_result_t result = ISC_R_FAILURE;
if (((pond->prohibit_list != NULL) &&
(permitted(reply->packet, pond->prohibit_list))) ||
((pond->permit_list != NULL) &&
(!permitted(reply->packet, pond->permit_list))))
continue;
#ifdef EUI_64
/* If pond is EUI-64 but client duid isn't a valid EUI-64
* id, then skip this pond */
if (pond->use_eui_64 &&
!valid_eui_64_duid(&reply->ia->iaid_duid, IAID_LEN)) {
continue;
}
#endif
start_pool = pond->last_ipv6_pool;
i = start_pool;
do {
p = pond->ipv6_pools[i];
if (p->pool_type == D6O_IA_NA) {
#ifdef EUI_64
if (pond->use_eui_64) {
result =
create_lease6_eui_64(p, addr,
&reply->ia->iaid_duid,
cur_time + 120);
}
else
#endif
{
result =
create_lease6(p, addr, &attempts,
&reply->ia->iaid_duid,
cur_time + 120);
}
if (result == ISC_R_SUCCESS) {
/*
* Record the pool used (or next one if
* there was a collision).
*/
if (attempts > 1) {
i++;
if (pond->ipv6_pools[i]
== NULL) {
i = 0;
}
}
pond->last_ipv6_pool = i;
log_debug("Picking pool address %s",
inet_ntop(AF_INET6,
&((*addr)->addr),
tmp_buf, sizeof(tmp_buf)));
return (ISC_R_SUCCESS);
}
}
i++;
if (pond->ipv6_pools[i] == NULL) {
i = 0;
}
} while (i != start_pool);
if (result == ISC_R_NORESOURCES) {
jumbo_range += pond->jumbo_range;
total += pond->num_total;
active += pond->num_active;
abandoned += pond->num_abandoned;
}
}
/*
* If we failed to pick an IPv6 address from any of the subnets.
* Presumably that means we have no addresses for the client.
*/
if (jumbo_range != 0) {
log_debug("Unable to pick client address: "
"no addresses available - shared network %s: "
" 2^64-1 < total, %" PRIu64 " active, %" PRIu64 " abandoned",
shared_name, active - abandoned, abandoned);
} else {
log_debug("Unable to pick client address: "
"no addresses available - shared network %s: "
"%" PRIu64 " total, %" PRIu64 " active, %" PRIu64 " abandoned",
shared_name, total, active - abandoned, abandoned);
}
return ISC_R_NORESOURCES;
}
/*
* Try to get the IPv6 prefix the client asked for from the
* prefix pool.
*
* pref is the result (should be a pointer to NULL on entry)
* pool is the prefix pool to search in
* requested_pref is the address the client wants
*/
static isc_result_t
try_client_v6_prefix(struct iasubopt **pref,
struct ipv6_pool *pool,
const struct data_string *requested_pref)
{
u_int8_t tmp_plen;
struct in6_addr tmp_pref;
struct iaddr ia;
isc_result_t result;
if (requested_pref->len < sizeof(tmp_plen) + sizeof(tmp_pref)) {
return DHCP_R_INVALIDARG;
}
tmp_plen = (int) requested_pref->data[0];
if ((tmp_plen < 3) || (tmp_plen > 128)) {
return ISC_R_FAILURE;
}
memcpy(&tmp_pref, requested_pref->data + 1, sizeof(tmp_pref));
if (IN6_IS_ADDR_UNSPECIFIED(&tmp_pref)) {
return ISC_R_FAILURE;
}
ia.len = 16;
memcpy(&ia.iabuf, &tmp_pref, 16);
if (!is_cidr_mask_valid(&ia, (int) tmp_plen)) {
return ISC_R_FAILURE;
}
if (!ipv6_in_pool(&tmp_pref, pool) ||
((int)tmp_plen != pool->units)) {
return ISC_R_ADDRNOTAVAIL;
}
if (prefix6_exists(pool, &tmp_pref, tmp_plen)) {
return ISC_R_ADDRINUSE;
}
result = iasubopt_allocate(pref, MDL);
if (result != ISC_R_SUCCESS) {
return result;
}
(*pref)->addr = tmp_pref;
(*pref)->plen = tmp_plen;
/* Default is soft binding for 2 minutes. */
result = add_lease6(pool, *pref, cur_time + 120);
if (result != ISC_R_SUCCESS) {
iasubopt_dereference(pref, MDL);
}
return result;
}
/*!
*
* \brief Get an IPv6 prefix for the client.
*
* Attempt to find a usable prefix for the client. Based upon the prefix
* length mode and the plen supplied by the client (if one), we make one
* or more calls to pick_v6_prefix_helper() to find a prefix as follows:
*
* PLM_IGNORE or client specifies a plen of zero, use the first available
* prefix regardless of it's length.
*
* PLM_PREFER – look for an exact match to client's plen first, if none
* found, use the first available prefix of any length
*
* PLM_EXACT – look for an exact match first, if none found then fail. This
* is the default behavior.
*
* PLM_MAXIMUM - look for an exact match first, then the first available whose
* prefix length is less than client's plen, otherwise fail.
*
* PLM_MINIMUM - look for an exact match first, then the first available whose
* prefix length is greater than client's plen, otherwise fail.
*
* Note that the selection mode is configurable at the global scope only via
* prefix-len-mode.
*
* \param reply = the state structure for the current work on this request
* if we create a lease we return it using reply->lease
*
* \return
* ISC_R_SUCCESS = we were able to find an prefix and are returning a
* pointer to the lease
* ISC_R_NORESOURCES = there don't appear to be any free addresses. This
* is probabalistic. We don't exhaustively try the
* address range, instead we hash the duid and if
* the address derived from the hash is in use we
* hash the address. After a number of failures we
* conclude the pool is basically full.
*/
static isc_result_t
pick_v6_prefix(struct reply_state *reply) {
struct ipv6_pool *p = NULL;
struct ipv6_pond *pond;
int i;
isc_result_t result;
/*
* Do a quick walk through of the ponds and pools
* to see if we have any prefix pools
*/
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
if (pond->ipv6_pools == NULL)
continue;
for (i = 0; (p = pond->ipv6_pools[i]) != NULL; i++) {
if (p->pool_type == D6O_IA_PD)
break;
}
if (p != NULL)
break;
}
/* If we get here and p is NULL we have no useful pools */
if (p == NULL) {
log_debug("Unable to pick client prefix: "
"no IPv6 pools on this shared network");
return ISC_R_NORESOURCES;
}
if (reply->preflen <= 0) {
/* If we didn't get a plen (-1) or client plen is 0, then just
* select first available (same as PLM_INGORE) */
result = pick_v6_prefix_helper(reply, PLM_IGNORE);
} else {
switch (prefix_length_mode) {
case PLM_PREFER:
/* First we look for an exact match, if not found
* then first available */
result = pick_v6_prefix_helper(reply, PLM_EXACT);
if (result != ISC_R_SUCCESS) {
result = pick_v6_prefix_helper(reply,
PLM_IGNORE);
}
break;
case PLM_EXACT:
/* Match exactly or fail */
result = pick_v6_prefix_helper(reply, PLM_EXACT);
break;
case PLM_MINIMUM:
case PLM_MAXIMUM:
/* First we look for an exact match, if not found
* then first available by mode */
result = pick_v6_prefix_helper(reply, PLM_EXACT);
if (result != ISC_R_SUCCESS) {
result = pick_v6_prefix_helper(reply,
prefix_length_mode);
}
break;
default:
/* First available */
result = pick_v6_prefix_helper(reply, PLM_IGNORE);
break;
}
}
if (result == ISC_R_SUCCESS) {
char tmp_buf[INET6_ADDRSTRLEN];
log_debug("Picking pool prefix %s/%u",
inet_ntop(AF_INET6, &(reply->lease->addr),
tmp_buf, sizeof(tmp_buf)),
(unsigned)(reply->lease->plen));
return (ISC_R_SUCCESS);
}
/*
* If we failed to pick an IPv6 prefix
* Presumably that means we have no prefixes for the client.
*/
log_debug("Unable to pick client prefix: no prefixes available");
return ISC_R_NORESOURCES;
}
/*!
*
* \brief Get an IPv6 prefix for the client based upon selection mode.
*
* We walk through the ponds checking for permit and deny. If a pond is
* permissable to use, loop through its PD pools checking prefix lengths
* against the client plen based on the prefix length mode, looking for
* available prefixes.
*
* \param reply = the state structure for the current work on this request
* if we create a lease we return it using reply->lease
* \prefix_mode = selection mode to use
*
* \return
* ISC_R_SUCCESS = we were able to find a prefix and are returning a
* pointer to the lease
* ISC_R_NORESOURCES = there don't appear to be any free addresses. This
* is probabalistic. We don't exhaustively try the
* address range, instead we hash the duid and if
* the address derived from the hash is in use we
* hash the address. After a number of failures we
* conclude the pool is basically full.
*/
isc_result_t
pick_v6_prefix_helper(struct reply_state *reply, int prefix_mode) {
struct ipv6_pool *p = NULL;
struct ipv6_pond *pond;
int i;
unsigned int attempts;
struct iasubopt **pref = &reply->lease;
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
if (((pond->prohibit_list != NULL) &&
(permitted(reply->packet, pond->prohibit_list))) ||
((pond->permit_list != NULL) &&
(!permitted(reply->packet, pond->permit_list))))
continue;
for (i = 0; (p = pond->ipv6_pools[i]) != NULL; i++) {
if ((p->pool_type == D6O_IA_PD) &&
(eval_prefix_mode(p->units, reply->preflen,
prefix_mode) == 1) &&
(create_prefix6(p, pref, &attempts,
&reply->ia->iaid_duid,
cur_time + 120) == ISC_R_SUCCESS)) {
return (ISC_R_SUCCESS);
}
}
}
return ISC_R_NORESOURCES;
}
/*!
*
* \brief Test a prefix length against another based on prefix length mode
*
* \param len - prefix length to test
* \param preflen - preferred prefix length against which to test
* \param prefix_mode - prefix selection mode with which to test
*
* Note that the case of preferred length of 0 is not short-cut here as it
* is assumed to be done at a higher level.
*
* \return 1 if the given length is usable based upon mode and a preferred
* length, 0 if not.
*/
int
eval_prefix_mode(int len, int preflen, int prefix_mode) {
int use_it = 1;
switch (prefix_mode) {
case PLM_EXACT:
use_it = (len == preflen);
break;
case PLM_MINIMUM:
/* they asked for a prefix length no "shorter" than preflen */
use_it = (len >= preflen);
break;
case PLM_MAXIMUM:
/* they asked for a prefix length no "longer" than preflen */
use_it = (len <= preflen);
break;
default:
/* otherwise use it */
break;
}
return (use_it);
}
/*
*! \file server/dhcpv6.c
*
* \brief construct a reply containing information about a client's lease
*
* lease_to_client() is called from several messages to construct a
* reply that contains all that we know about the client's correct lease
* (or projected lease).
*
* Solicit - "Soft" binding, ignore unknown addresses or bindings, just
* send what we "may" give them on a request.
*
* Request - "Hard" binding, but ignore supplied addresses (just provide what
* the client should really use).
*
* Renew - "Hard" binding, but client-supplied addresses are 'real'. Error
* Rebind out any "wrong" addresses the client sends. This means we send
* an empty IA_NA with a status code of NoBinding or NotOnLink or
* possibly send the address with zeroed lifetimes.
*
* Information-Request - No binding.
*
* The basic structure is to traverse the client-supplied data first, and
* validate and echo back any contents that can be. If the client-supplied
* data does not error out (on renew/rebind as above), but we did not send
* any addresses, attempt to allocate one.
*
* At the end of the this function we call commit_leases_timed() to
* fsync and rotate the file as necessary. commit_leases_timed() will
* check that we have written at least one lease to the file and that
* some time has passed before doing any fsync or file rewrite so we
* don't bother tracking if we did a write_ia during this function.
*/
/* TODO: look at client hints for lease times */
static void
lease_to_client(struct data_string *reply_ret,
struct packet *packet,
const struct data_string *client_id,
const struct data_string *server_id)
{
static struct reply_state reply;
struct option_cache *oc;
struct data_string packet_oro;
int i;
memset(&packet_oro, 0, sizeof(packet_oro));
/* Locate the client. */
if (shared_network_from_packet6(&reply.shared,
packet) != ISC_R_SUCCESS)
goto exit;
/*
* Initialize the reply.
*/
packet_reference(&reply.packet, packet, MDL);
data_string_copy(&reply.client_id, client_id, MDL);
if (!start_reply(packet, client_id, server_id, &reply.opt_state,
&reply.buf.reply))
goto exit;
/* Set the write cursor to just past the reply header. */
reply.cursor = REPLY_OPTIONS_INDEX;
/*
* Get the ORO from the packet, if any.
*/
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_ORO);
if (oc != NULL) {
if (!evaluate_option_cache(&packet_oro, packet,
NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("lease_to_client: error evaluating ORO.");
goto exit;
}
}
/*
* Find a host record that matches the packet, if any, and is
* valid for the shared network the client is on.
*/
if (find_hosts6(&reply.host, packet, client_id, MDL)) {
packet->known = 1;
seek_shared_host(&reply.host, reply.shared);
}
/* Process the client supplied IA's onto the reply buffer. */
reply.ia_count = 0;
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_IA_NA);
for (; oc != NULL ; oc = oc->next) {
isc_result_t status;
/* Start counting resources (addresses) offered. */
reply.client_resources = 0;
reply.resources_included = ISC_FALSE;
status = reply_process_ia_na(&reply, oc);
/*
* We continue to try other IA's whether we can address
* this one or not. Any other result is an immediate fail.
*/
if ((status != ISC_R_SUCCESS) &&
(status != ISC_R_NORESOURCES))
goto exit;
}
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_IA_TA);
for (; oc != NULL ; oc = oc->next) {
isc_result_t status;
/* Start counting resources (addresses) offered. */
reply.client_resources = 0;
reply.resources_included = ISC_FALSE;
status = reply_process_ia_ta(&reply, oc);
/*
* We continue to try other IA's whether we can address
* this one or not. Any other result is an immediate fail.
*/
if ((status != ISC_R_SUCCESS) &&
(status != ISC_R_NORESOURCES))
goto exit;
}
/* Same for IA_PD's. */
reply.pd_count = 0;
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_IA_PD);
for (; oc != NULL ; oc = oc->next) {
isc_result_t status;
/* Start counting resources (prefixes) offered. */
reply.client_resources = 0;
reply.resources_included = ISC_FALSE;
status = reply_process_ia_pd(&reply, oc);
/*
* We continue to try other IA_PD's whether we can address
* this one or not. Any other result is an immediate fail.
*/
if ((status != ISC_R_SUCCESS) &&
(status != ISC_R_NORESOURCES))
goto exit;
}
/*
* Make no reply if we gave no resources and is not
* for Information-Request.
*/
if ((reply.ia_count == 0) && (reply.pd_count == 0)) {
if (reply.packet->dhcpv6_msg_type !=
DHCPV6_INFORMATION_REQUEST)
goto exit;
/*
* Because we only execute statements on a per-IA basis,
* we need to execute statements in any non-IA reply to
* source configuration.
*/
execute_statements_in_scope(NULL, reply.packet, NULL, NULL,
reply.packet->options,
reply.opt_state, &global_scope,
reply.shared->group, root_group,
NULL);
/* Execute statements from class scopes. */
for (i = reply.packet->class_count; i > 0; i--) {
execute_statements_in_scope(NULL, reply.packet,
NULL, NULL,
reply.packet->options,
reply.opt_state,
&global_scope,
reply.packet->classes[i - 1]->group,
reply.shared->group, NULL);
}
/* Bring in any configuration from a host record. */
if (reply.host != NULL)
execute_statements_in_scope(NULL, reply.packet,
NULL, NULL,
reply.packet->options,
reply.opt_state,
&global_scope,
reply.host->group,
reply.shared->group, NULL);
}
/*
* RFC3315 section 17.2.2 (Solicit):
*
* If the server will not assign any addresses to any IAs in a
* subsequent Request from the client, the server MUST send an
* Advertise message to the client that includes only a Status
* Code option with code NoAddrsAvail and a status message for
* the user, a Server Identifier option with the server's DUID,
* and a Client Identifier option with the client's DUID.
*
* This has been updated by an errata such that the server
* can always send an IA.
*
* Section 18.2.1 (Request):
*
* If the server cannot assign any addresses to an IA in the
* message from the client, the server MUST include the IA in
* the Reply message with no addresses in the IA and a Status
* Code option in the IA containing status code NoAddrsAvail.
*
* Section 18.1.8 (Client Behavior):
*
* Leave unchanged any information about addresses the client has
* recorded in the IA but that were not included in the IA from
* the server.
* Sends a Renew/Rebind if the IA is not in the Reply message.
*/
/*
* Having stored the client's IA's, store any options that
* will fit in the remaining space.
*/
reply.cursor += store_options6((char *)reply.buf.data + reply.cursor,
sizeof(reply.buf) - reply.cursor,
reply.opt_state, reply.packet,
required_opts_solicit,
&packet_oro);
/* Return our reply to the caller. */
reply_ret->len = reply.cursor;
reply_ret->buffer = NULL;
if (!buffer_allocate(&reply_ret->buffer, reply.cursor, MDL)) {
log_fatal("No memory to store Reply.");
}
memcpy(reply_ret->buffer->data, reply.buf.data, reply.cursor);
reply_ret->data = reply_ret->buffer->data;
/* If appropriate commit and rotate the lease file */
(void) commit_leases_timed();
exit:
/* Cleanup. */
if (reply.shared != NULL)
shared_network_dereference(&reply.shared, MDL);
if (reply.host != NULL)
host_dereference(&reply.host, MDL);
if (reply.opt_state != NULL)
option_state_dereference(&reply.opt_state, MDL);
if (reply.packet != NULL)
packet_dereference(&reply.packet, MDL);
if (reply.client_id.data != NULL)
data_string_forget(&reply.client_id, MDL);
if (packet_oro.buffer != NULL)
data_string_forget(&packet_oro, MDL);
reply.renew = reply.rebind = reply.min_prefer = reply.min_valid = 0;
reply.cursor = 0;
}
/* Process a client-supplied IA_NA. This may append options to the tail of
* the reply packet being built in the reply_state structure.
*/
static isc_result_t
reply_process_ia_na(struct reply_state *reply, struct option_cache *ia) {
isc_result_t status = ISC_R_SUCCESS;
u_int32_t iaid;
unsigned ia_cursor;
struct option_state *packet_ia;
struct option_cache *oc;
struct data_string ia_data, data;
/* Initialize values that will get cleaned up on return. */
packet_ia = NULL;
memset(&ia_data, 0, sizeof(ia_data));
memset(&data, 0, sizeof(data));
/*
* Note that find_client_address() may set reply->lease.
*/
/* Make sure there is at least room for the header. */
if ((reply->cursor + IA_NA_OFFSET + 4) > sizeof(reply->buf)) {
log_error("reply_process_ia_na: Reply too long for IA.");
return ISC_R_NOSPACE;
}
/* Fetch the IA_NA contents. */
if (!get_encapsulated_IA_state(&packet_ia, &ia_data, reply->packet,
ia, IA_NA_OFFSET)) {
log_error("reply_process_ia_na: error evaluating ia");
status = ISC_R_FAILURE;
goto cleanup;
}
/* Extract IA_NA header contents. */
iaid = getULong(ia_data.data);
reply->renew = getULong(ia_data.data + 4);
reply->rebind = getULong(ia_data.data + 8);
/* Create an IA_NA structure. */
if (ia_allocate(&reply->ia, iaid, (char *)reply->client_id.data,
reply->client_id.len, MDL) != ISC_R_SUCCESS) {
log_error("reply_process_ia_na: no memory for ia.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
reply->ia->ia_type = D6O_IA_NA;
/* Cache pre-existing IA, if any. */
ia_hash_lookup(&reply->old_ia, ia_na_active,
(unsigned char *)reply->ia->iaid_duid.data,
reply->ia->iaid_duid.len, MDL);
/*
* Create an option cache to carry the IA_NA option contents, and
* execute any user-supplied values into it.
*/
if (!option_state_allocate(&reply->reply_ia, MDL)) {
status = ISC_R_NOMEMORY;
goto cleanup;
}
/* Check & cache the fixed host record. */
if ((reply->host != NULL) && (reply->host->fixed_addr != NULL)) {
struct iaddr tmp_addr;
if (!evaluate_option_cache(&reply->fixed, NULL, NULL, NULL,
NULL, NULL, &global_scope,
reply->host->fixed_addr, MDL)) {
log_error("reply_process_ia_na: unable to evaluate "
"fixed address.");
status = ISC_R_FAILURE;
goto cleanup;
}
if (reply->fixed.len < 16) {
log_error("reply_process_ia_na: invalid fixed address.");
status = DHCP_R_INVALIDARG;
goto cleanup;
}
/* Find the static lease's subnet. */
tmp_addr.len = 16;
memcpy(tmp_addr.iabuf, reply->fixed.data, 16);
if (find_grouped_subnet(&reply->subnet, reply->shared,
tmp_addr, MDL) == 0)
log_fatal("Impossible condition at %s:%d.", MDL);
reply->static_lease = ISC_TRUE;
} else
reply->static_lease = ISC_FALSE;
/*
* Save the cursor position at the start of the IA, so we can
* set length and adjust t1/t2 values later. We write a temporary
* header out now just in case we decide to adjust the packet
* within sub-process functions.
*/
ia_cursor = reply->cursor;
/* Initialize the IA_NA header. First the code. */
putUShort(reply->buf.data + reply->cursor, (unsigned)D6O_IA_NA);
reply->cursor += 2;
/* Then option length. */
putUShort(reply->buf.data + reply->cursor, 0x0Cu);
reply->cursor += 2;
/* Then IA_NA header contents; IAID. */
putULong(reply->buf.data + reply->cursor, iaid);
reply->cursor += 4;
/* We store the client's t1 for now, and may over-ride it later. */
putULong(reply->buf.data + reply->cursor, reply->renew);
reply->cursor += 4;
/* We store the client's t2 for now, and may over-ride it later. */
putULong(reply->buf.data + reply->cursor, reply->rebind);
reply->cursor += 4;
/*
* For each address in this IA_NA, decide what to do about it.
*
* Guidelines:
*
* The client leaves unchanged any information about addresses
* it has recorded but are not included ("cancel/break" below).
* A not included IA ("cleanup" below) could give a Renew/Rebind.
*/
oc = lookup_option(&dhcpv6_universe, packet_ia, D6O_IAADDR);
reply->min_valid = reply->min_prefer = INFINITE_TIME;
reply->client_valid = reply->client_prefer = 0;
for (; oc != NULL ; oc = oc->next) {
status = reply_process_addr(reply, oc);
/*
* Canceled means we did not allocate addresses to the
* client, but we're "done" with this IA - we set a status
* code. So transmit this reply, e.g., move on to the next
* IA.
*/
if (status == ISC_R_CANCELED)
break;
if ((status != ISC_R_SUCCESS) &&
(status != ISC_R_ADDRINUSE) &&
(status != ISC_R_ADDRNOTAVAIL))
goto cleanup;
}
reply->ia_count++;
/*
* If we fell through the above and never gave the client
* an address, give it one now.
*/
if ((status != ISC_R_CANCELED) && (reply->client_resources == 0)) {
status = find_client_address(reply);
if (status == ISC_R_NORESOURCES) {
switch (reply->packet->dhcpv6_msg_type) {
case DHCPV6_SOLICIT:
/*
* No address for any IA is handled
* by the caller.
*/
/* FALL THROUGH */
case DHCPV6_REQUEST:
/* Section 18.2.1 (Request):
*
* If the server cannot assign any addresses to
* an IA in the message from the client, the
* server MUST include the IA in the Reply
* message with no addresses in the IA and a
* Status Code option in the IA containing
* status code NoAddrsAvail.
*/
option_state_dereference(&reply->reply_ia, MDL);
if (!option_state_allocate(&reply->reply_ia,
MDL))
{
log_error("reply_process_ia_na: No "
"memory for option state "
"wipe.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
if (!set_status_code(STATUS_NoAddrsAvail,
"No addresses available "
"for this interface.",
reply->reply_ia)) {
log_error("reply_process_ia_na: Unable "
"to set NoAddrsAvail status "
"code.");
status = ISC_R_FAILURE;
goto cleanup;
}
status = ISC_R_SUCCESS;
break;
default:
/*
* RFC 3315 does not tell us to emit a status
* code in this condition, or anything else.
*
* If we included non-allocated addresses
* (zeroed lifetimes) in an IA, then the client
* will deconfigure them.
*
* So we want to include the IA even if we
* can't give it a new address if it includes
* zeroed lifetime addresses.
*
* We don't want to include the IA if we
* provide zero addresses including zeroed
* lifetimes.
*/
if (reply->resources_included)
status = ISC_R_SUCCESS;
else
goto cleanup;
break;
}
}
if (status != ISC_R_SUCCESS)
goto cleanup;
}
/*
* yes, goto's aren't the best but we also want to avoid extra
* indents
*/
if (status == ISC_R_CANCELED) {
/* We're replying with a status code so we still need to
* write it out in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
goto cleanup;
}
/*
* Handle static leases, we always log stuff and if it's
* a hard binding we run any commit statements that we have
*/
if (reply->static_lease) {
char tmp_addr[INET6_ADDRSTRLEN];
log_info("%s NA: address %s to client with duid %s iaid = %d "
"static",
dhcpv6_type_names[reply->buf.reply.msg_type],
inet_ntop(AF_INET6, reply->fixed.data, tmp_addr,
sizeof(tmp_addr)),
print_hex_1(reply->client_id.len,
reply->client_id.data, 60),
iaid);
/* Write the lease out in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
#ifdef NSUPDATE
/* Performs DDNS updates if we're configured to do them */
ddns_update_static6(reply);
#endif
if ((reply->buf.reply.msg_type == DHCPV6_REPLY) &&
(reply->on_star.on_commit != NULL)) {
execute_statements(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state, NULL,
reply->on_star.on_commit, NULL);
executable_statement_dereference
(&reply->on_star.on_commit, MDL);
}
goto cleanup;
}
/*
* If we have any addresses log what we are doing.
*/
if (reply->ia->num_iasubopt != 0) {
struct iasubopt *tmp;
int i;
char tmp_addr[INET6_ADDRSTRLEN];
for (i = 0 ; i < reply->ia->num_iasubopt ; i++) {
tmp = reply->ia->iasubopt[i];
log_info("%s NA: address %s to client with duid %s "
"iaid = %d valid for %u seconds",
dhcpv6_type_names[reply->buf.reply.msg_type],
inet_ntop(AF_INET6, &tmp->addr,
tmp_addr, sizeof(tmp_addr)),
print_hex_1(reply->client_id.len,
reply->client_id.data, 60),
iaid, tmp->valid);
}
}
/*
* If this is not a 'soft' binding, consume the new changes into
* the database (if any have been attached to the ia_na).
*
* Loop through the assigned dynamic addresses, referencing the
* leases onto this IA_NA rather than any old ones, and updating
* pool timers for each (if any).
*
* Note that we must do ddns_updates() before we test for lease
* reuse (so we'll know if DNS entries are different). To ensure
* we don't break any configs, we run on_commit statements before
* we do ddns_updates() just in case the former affects the later.
* This is symetrical with v4 logic. We always run on_commit and
* ddns_udpates() whether a lease is reused or renewed.
*/
if ((reply->ia->num_iasubopt != 0) &&
(reply->buf.reply.msg_type == DHCPV6_REPLY)) {
int must_commit = 0;
struct iasubopt *tmp;
struct data_string *ia_id;
int i;
for (i = 0 ; i < reply->ia->num_iasubopt ; i++) {
tmp = reply->ia->iasubopt[i];
if (tmp->ia != NULL) {
ia_dereference(&tmp->ia, MDL);
}
ia_reference(&tmp->ia, reply->ia, MDL);
/* If we have anything to do on commit do it now */
if (tmp->on_star.on_commit != NULL) {
execute_statements(NULL, reply->packet,
NULL, NULL,
reply->packet->options,
reply->opt_state,
&tmp->scope,
tmp->on_star.on_commit,
&tmp->on_star);
executable_statement_dereference
(&tmp->on_star.on_commit, MDL);
}
#if defined (NSUPDATE)
/* Perform ddns updates */
oc = lookup_option(&server_universe, reply->opt_state,
SV_DDNS_UPDATES);
if ((oc == NULL) ||
evaluate_boolean_option_cache(NULL, reply->packet,
NULL, NULL,
reply->packet->options,
reply->opt_state,
&tmp->scope,
oc, MDL)) {
ddns_updates(reply->packet, NULL, NULL,
tmp, NULL, reply->opt_state);
}
#endif
if (!reuse_lease6(reply, tmp)) {
/* Commit 'hard' bindings. */
must_commit = 1;
renew_lease6(tmp->ipv6_pool, tmp);
schedule_lease_timeout(tmp->ipv6_pool);
/* Do our threshold check. */
check_pool6_threshold(reply, tmp);
}
}
/* write the IA_NA in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
/* Remove any old ia from the hash. */
if (reply->old_ia != NULL) {
if (!release_on_roam(reply)) {
ia_id = &reply->old_ia->iaid_duid;
ia_hash_delete(ia_na_active,
(unsigned char *)ia_id->data,
ia_id->len, MDL);
}
ia_dereference(&reply->old_ia, MDL);
}
/* Put new ia into the hash. */
reply->ia->cltt = cur_time;
ia_id = &reply->ia->iaid_duid;
ia_hash_add(ia_na_active, (unsigned char *)ia_id->data,
ia_id->len, reply->ia, MDL);
/* If we couldn't reuse all of the iasubopts, we
* must update udpate the lease db */
if (must_commit) {
write_ia(reply->ia);
}
} else {
/* write the IA_NA in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
schedule_lease_timeout_reply(reply);
}
cleanup:
if (packet_ia != NULL)
option_state_dereference(&packet_ia, MDL);
if (reply->reply_ia != NULL)
option_state_dereference(&reply->reply_ia, MDL);
if (ia_data.data != NULL)
data_string_forget(&ia_data, MDL);
if (data.data != NULL)
data_string_forget(&data, MDL);
if (reply->ia != NULL)
ia_dereference(&reply->ia, MDL);
if (reply->old_ia != NULL)
ia_dereference(&reply->old_ia, MDL);
if (reply->lease != NULL)
iasubopt_dereference(&reply->lease, MDL);
if (reply->fixed.data != NULL)
data_string_forget(&reply->fixed, MDL);
if (reply->subnet != NULL)
subnet_dereference(&reply->subnet, MDL);
if (reply->on_star.on_expiry != NULL)
executable_statement_dereference
(&reply->on_star.on_expiry, MDL);
if (reply->on_star.on_release != NULL)
executable_statement_dereference
(&reply->on_star.on_release, MDL);
/*
* ISC_R_CANCELED is a status code used by the addr processing to
* indicate we're replying with a status code. This is still a
* success at higher layers.
*/
return((status == ISC_R_CANCELED) ? ISC_R_SUCCESS : status);
}
/*
* Writes the populated IA_xx in wire format to the reply buffer
*/
void
write_to_packet(struct reply_state *reply, unsigned ia_cursor) {
reply->cursor += store_options6((char *)reply->buf.data + reply->cursor,
sizeof(reply->buf) - reply->cursor,
reply->reply_ia, reply->packet,
(reply->ia->ia_type != D6O_IA_PD ?
required_opts_IA : required_opts_IA_PD),
NULL);
/* Reset the length of this IA to match what was just written. */
putUShort(reply->buf.data + ia_cursor + 2,
reply->cursor - (ia_cursor + 4));
if (reply->ia->ia_type != D6O_IA_TA) {
/* Calculate T1/T2 and stuff them in the reply */
set_reply_tee_times(reply, ia_cursor);
}
}
/*
* Process an IAADDR within a given IA_xA, storing any IAADDR reply contents
* into the reply's current ia-scoped option cache. Returns ISC_R_CANCELED
* in the event we are replying with a status code and do not wish to process
* more IAADDRs within this IA.
*/
static isc_result_t
reply_process_addr(struct reply_state *reply, struct option_cache *addr) {
u_int32_t pref_life, valid_life;
struct binding_scope **scope;
struct group *group;
struct subnet *subnet;
struct iaddr tmp_addr;
struct option_cache *oc;
struct data_string iaaddr, data;
isc_result_t status = ISC_R_SUCCESS;
#ifdef EUI_64
int invalid_for_eui_64 = 0;
#endif
/* Initializes values that will be cleaned up. */
memset(&iaaddr, 0, sizeof(iaaddr));
memset(&data, 0, sizeof(data));
/* Note that reply->lease may be set by address_is_owned() */
/*
* There is no point trying to process an incoming address if there
* is no room for an outgoing address.
*/
if ((reply->cursor + 28) > sizeof(reply->buf)) {
log_error("reply_process_addr: Out of room for address.");
return ISC_R_NOSPACE;
}
/* Extract this IAADDR option. */
if (!evaluate_option_cache(&iaaddr, reply->packet, NULL, NULL,
reply->packet->options, NULL, &global_scope,
addr, MDL) ||
(iaaddr.len < IAADDR_OFFSET)) {
log_error("reply_process_addr: error evaluating IAADDR.");
status = ISC_R_FAILURE;
goto cleanup;
}
/* The first 16 bytes are the IPv6 address. */
pref_life = getULong(iaaddr.data + 16);
valid_life = getULong(iaaddr.data + 20);
if ((reply->client_valid == 0) ||
(reply->client_valid > valid_life))
reply->client_valid = valid_life;
if ((reply->client_prefer == 0) ||
(reply->client_prefer > pref_life))
reply->client_prefer = pref_life;
/*
* Clients may choose to send :: as an address, with the idea to give
* hints about preferred-lifetime or valid-lifetime.
*/
tmp_addr.len = 16;
memset(tmp_addr.iabuf, 0, 16);
if (!memcmp(iaaddr.data, tmp_addr.iabuf, 16)) {
/* Status remains success; we just ignore this one. */
goto cleanup;
}
/* tmp_addr len remains 16 */
memcpy(tmp_addr.iabuf, iaaddr.data, 16);
/*
* Verify that this address is on the client's network.
*/
for (subnet = reply->shared->subnets ; subnet != NULL ;
subnet = subnet->next_sibling) {
if (addr_eq(subnet_number(tmp_addr, subnet->netmask),
subnet->net))
break;
}
#ifdef EUI_64
if (subnet) {
/* If the requested address falls into an EUI-64 pool, then
* we need to verify if it has EUI-64 duid AND the requested
* address is correct for that duid. If not we treat it just
* like an not-on-link request. */
struct ipv6_pool* pool = NULL;
struct in6_addr* addr = (struct in6_addr*)(iaaddr.data);
if ((find_ipv6_pool(&pool, D6O_IA_NA, addr) == ISC_R_SUCCESS)
&& (pool->ipv6_pond->use_eui_64) &&
(!valid_for_eui_64_pool(pool, &reply->client_id, 0, addr))) {
log_debug ("Requested address: %s,"
" not valid for EUI-64 pool",
pin6_addr(addr));
invalid_for_eui_64 = 1;
}
}
#endif
/* Address not found on shared network. */
#ifdef EUI_64
if ((subnet == NULL) || invalid_for_eui_64) {
#else
if (subnet == NULL) {
#endif
/* Ignore this address on 'soft' bindings. */
if (reply->packet->dhcpv6_msg_type == DHCPV6_SOLICIT) {
/* disable rapid commit */
reply->buf.reply.msg_type = DHCPV6_ADVERTISE;
delete_option(&dhcpv6_universe,
reply->opt_state,
D6O_RAPID_COMMIT);
/* status remains success */
goto cleanup;
}
/*
* RFC3315 section 18.2.1:
*
* If the server finds that the prefix on one or more IP
* addresses in any IA in the message from the client is not
* appropriate for the link to which the client is connected,
* the server MUST return the IA to the client with a Status
* Code option with the value NotOnLink.
*/
if (reply->packet->dhcpv6_msg_type == DHCPV6_REQUEST) {
/* Rewind the IA_NA to empty. */
option_state_dereference(&reply->reply_ia, MDL);
if (!option_state_allocate(&reply->reply_ia, MDL)) {
log_error("reply_process_addr: No memory for "
"option state wipe.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
/* Append a NotOnLink status code. */
if (!set_status_code(STATUS_NotOnLink,
"Address not for use on this "
"link.", reply->reply_ia)) {
log_error("reply_process_addr: Failure "
"setting status code.");
status = ISC_R_FAILURE;
goto cleanup;
}
/* Fin (no more IAADDRs). */
status = ISC_R_CANCELED;
goto cleanup;
}
/*
* RFC3315 sections 18.2.3 and 18.2.4 have identical language:
*
* If the server finds that any of the addresses are not
* appropriate for the link to which the client is attached,
* the server returns the address to the client with lifetimes
* of 0.
*/
if ((reply->packet->dhcpv6_msg_type != DHCPV6_RENEW) &&
(reply->packet->dhcpv6_msg_type != DHCPV6_REBIND)) {
log_error("It is impossible to lease a client that is "
"not sending a solicit, request, renew, or "
"rebind.");
status = ISC_R_FAILURE;
goto cleanup;
}
reply->send_prefer = reply->send_valid = 0;
goto send_addr;
}
/* Verify the address belongs to the client. */
if (!address_is_owned(reply, &tmp_addr)) {
/*
* For solicit and request, any addresses included are
* 'requested' addresses. For rebind, we actually have
* no direction on what to do from 3315 section 18.2.4!
* So I think the best bet is to try and give it out, and if
* we can't, zero lifetimes.
*/
if ((reply->packet->dhcpv6_msg_type == DHCPV6_SOLICIT) ||
(reply->packet->dhcpv6_msg_type == DHCPV6_REQUEST) ||
(reply->packet->dhcpv6_msg_type == DHCPV6_REBIND)) {
status = reply_process_try_addr(reply, &tmp_addr);
/*
* If the address is in use, or isn't in any dynamic
* range, continue as normal. If any other error was
* found, error out.
*/
if ((status != ISC_R_SUCCESS) &&
(status != ISC_R_ADDRINUSE) &&
(status != ISC_R_ADDRNOTAVAIL))
goto cleanup;
/*
* If we didn't honor this lease, for solicit and
* request we simply omit it from our answer. For
* rebind, we send it with zeroed lifetimes.
*/
if (reply->lease == NULL) {
if (reply->packet->dhcpv6_msg_type ==
DHCPV6_REBIND) {
reply->send_prefer = 0;
reply->send_valid = 0;
goto send_addr;
}
/* status remains success - ignore */
goto cleanup;
}
/*
* RFC3315 section 18.2.3:
*
* If the server cannot find a client entry for the IA the
* server returns the IA containing no addresses with a Status
* Code option set to NoBinding in the Reply message.
*
* On mismatch we (ab)use this pretending we have not the IA
* as soon as we have not an address.
*/
} else if (reply->packet->dhcpv6_msg_type == DHCPV6_RENEW) {
/* Rewind the IA_NA to empty. */
option_state_dereference(&reply->reply_ia, MDL);
if (!option_state_allocate(&reply->reply_ia, MDL)) {
log_error("reply_process_addr: No memory for "
"option state wipe.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
/* Append a NoBinding status code. */
if (!set_status_code(STATUS_NoBinding,
"Address not bound to this "
"interface.", reply->reply_ia)) {
log_error("reply_process_addr: Unable to "
"attach status code.");
status = ISC_R_FAILURE;
goto cleanup;
}
/* Fin (no more IAADDRs). */
status = ISC_R_CANCELED;
goto cleanup;
} else {
log_error("It is impossible to lease a client that is "
"not sending a solicit, request, renew, or "
"rebind message.");
status = ISC_R_FAILURE;
goto cleanup;
}
}
if (reply->static_lease) {
if (reply->host == NULL)
log_fatal("Impossible condition at %s:%d.", MDL);
scope = &global_scope;
group = reply->subnet->group;
} else {
if (reply->lease == NULL)
log_fatal("Impossible condition at %s:%d.", MDL);
scope = &reply->lease->scope;
group = reply->lease->ipv6_pool->ipv6_pond->group;
}
/*
* If client_resources is nonzero, then the reply_process_is_addressed
* function has executed configuration state into the reply option
* cache. We will use that valid cache to derive configuration for
* whether or not to engage in additional addresses, and similar.
*/
if (reply->client_resources != 0) {
unsigned limit = 1;
/*
* Does this client have "enough" addresses already? Default
* to one. Everybody gets one, and one should be enough for
* anybody.
*/
oc = lookup_option(&server_universe, reply->opt_state,
SV_LIMIT_ADDRS_PER_IA);
if (oc != NULL) {
if (!evaluate_option_cache(&data, reply->packet,
NULL, NULL,
reply->packet->options,
reply->opt_state,
scope, oc, MDL) ||
(data.len != 4)) {
log_error("reply_process_addr: unable to "
"evaluate addrs-per-ia value.");
status = ISC_R_FAILURE;
goto cleanup;
}
limit = getULong(data.data);
data_string_forget(&data, MDL);
}
/*
* If we wish to limit the client to a certain number of
* addresses, then omit the address from the reply.
*/
if (reply->client_resources >= limit)
goto cleanup;
}
status = reply_process_is_addressed(reply, scope, group);
if (status != ISC_R_SUCCESS)
goto cleanup;
send_addr:
status = reply_process_send_addr(reply, &tmp_addr);
cleanup:
if (iaaddr.data != NULL)
data_string_forget(&iaaddr, MDL);
if (data.data != NULL)
data_string_forget(&data, MDL);
if (reply->lease != NULL)
iasubopt_dereference(&reply->lease, MDL);
return status;
}
/*
* Verify the address belongs to the client. If we've got a host
* record with a fixed address, it has to be the assigned address
* (fault out all else). Otherwise it's a dynamic address, so lookup
* that address and make sure it belongs to this DUID:IAID pair.
*/
static isc_boolean_t
address_is_owned(struct reply_state *reply, struct iaddr *addr) {
int i;
struct ipv6_pond *pond;
/*
* This faults out addresses that don't match fixed addresses.
*/
if (reply->static_lease) {
if (reply->fixed.data == NULL)
log_fatal("Impossible condition at %s:%d.", MDL);
if (memcmp(addr->iabuf, reply->fixed.data, 16) == 0)
return (ISC_TRUE);
return (ISC_FALSE);
}
if ((reply->old_ia == NULL) || (reply->old_ia->num_iasubopt == 0))
return (ISC_FALSE);
for (i = 0 ; i < reply->old_ia->num_iasubopt ; i++) {
struct iasubopt *tmp;
tmp = reply->old_ia->iasubopt[i];
if (memcmp(addr->iabuf, &tmp->addr, 16) == 0) {
if (lease6_usable(tmp) == ISC_FALSE) {
return (ISC_FALSE);
}
pond = tmp->ipv6_pool->ipv6_pond;
if (((pond->prohibit_list != NULL) &&
(permitted(reply->packet, pond->prohibit_list))) ||
((pond->permit_list != NULL) &&
(!permitted(reply->packet, pond->permit_list))))
return (ISC_FALSE);
iasubopt_reference(&reply->lease, tmp, MDL);
return (ISC_TRUE);
}
}
return (ISC_FALSE);
}
/* Process a client-supplied IA_TA. This may append options to the tail of
* the reply packet being built in the reply_state structure.
*/
static isc_result_t
reply_process_ia_ta(struct reply_state *reply, struct option_cache *ia) {
isc_result_t status = ISC_R_SUCCESS;
u_int32_t iaid;
unsigned ia_cursor;
struct option_state *packet_ia;
struct option_cache *oc;
struct data_string ia_data, data;
struct data_string iaaddr;
u_int32_t pref_life, valid_life;
struct iaddr tmp_addr;
/* Initialize values that will get cleaned up on return. */
packet_ia = NULL;
memset(&ia_data, 0, sizeof(ia_data));
memset(&data, 0, sizeof(data));
memset(&iaaddr, 0, sizeof(iaaddr));
/* Make sure there is at least room for the header. */
if ((reply->cursor + IA_TA_OFFSET + 4) > sizeof(reply->buf)) {
log_error("reply_process_ia_ta: Reply too long for IA.");
return ISC_R_NOSPACE;
}
/* Fetch the IA_TA contents. */
if (!get_encapsulated_IA_state(&packet_ia, &ia_data, reply->packet,
ia, IA_TA_OFFSET)) {
log_error("reply_process_ia_ta: error evaluating ia");
status = ISC_R_FAILURE;
goto cleanup;
}
/* Extract IA_TA header contents. */
iaid = getULong(ia_data.data);
/* Create an IA_TA structure. */
if (ia_allocate(&reply->ia, iaid, (char *)reply->client_id.data,
reply->client_id.len, MDL) != ISC_R_SUCCESS) {
log_error("reply_process_ia_ta: no memory for ia.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
reply->ia->ia_type = D6O_IA_TA;
/* Cache pre-existing IA, if any. */
ia_hash_lookup(&reply->old_ia, ia_ta_active,
(unsigned char *)reply->ia->iaid_duid.data,
reply->ia->iaid_duid.len, MDL);
/*
* Create an option cache to carry the IA_TA option contents, and
* execute any user-supplied values into it.
*/
if (!option_state_allocate(&reply->reply_ia, MDL)) {
status = ISC_R_NOMEMORY;
goto cleanup;
}
/*
* Temporary leases are dynamic by definition.
*/
reply->static_lease = ISC_FALSE;
/*
* Save the cursor position at the start of the IA, so we can
* set length later. We write a temporary
* header out now just in case we decide to adjust the packet
* within sub-process functions.
*/
ia_cursor = reply->cursor;
/* Initialize the IA_TA header. First the code. */
putUShort(reply->buf.data + reply->cursor, (unsigned)D6O_IA_TA);
reply->cursor += 2;
/* Then option length. */
putUShort(reply->buf.data + reply->cursor, 0x04u);
reply->cursor += 2;
/* Then IA_TA header contents; IAID. */
putULong(reply->buf.data + reply->cursor, iaid);
reply->cursor += 4;
/*
* Deal with an IAADDR for lifetimes.
* For all or none, process IAADDRs as hints.
*/
reply->min_valid = reply->min_prefer = INFINITE_TIME;
reply->client_valid = reply->client_prefer = 0;
oc = lookup_option(&dhcpv6_universe, packet_ia, D6O_IAADDR);
for (; oc != NULL; oc = oc->next) {
memset(&iaaddr, 0, sizeof(iaaddr));
if (!evaluate_option_cache(&iaaddr, reply->packet,
NULL, NULL,
reply->packet->options, NULL,
&global_scope, oc, MDL) ||
(iaaddr.len < IAADDR_OFFSET)) {
log_error("reply_process_ia_ta: error "
"evaluating IAADDR.");
status = ISC_R_FAILURE;
goto cleanup;
}
/* The first 16 bytes are the IPv6 address. */
pref_life = getULong(iaaddr.data + 16);
valid_life = getULong(iaaddr.data + 20);
if ((reply->client_valid == 0) ||
(reply->client_valid > valid_life))
reply->client_valid = valid_life;
if ((reply->client_prefer == 0) ||
(reply->client_prefer > pref_life))
reply->client_prefer = pref_life;
/* Nothing more if something has failed. */
if (status == ISC_R_CANCELED)
continue;
tmp_addr.len = 16;
memcpy(tmp_addr.iabuf, iaaddr.data, 16);
if (!temporary_is_available(reply, &tmp_addr))
goto bad_temp;
status = reply_process_is_addressed(reply,
&reply->lease->scope,
reply->lease->ipv6_pool->ipv6_pond->group);
if (status != ISC_R_SUCCESS)
goto bad_temp;
status = reply_process_send_addr(reply, &tmp_addr);
if (status != ISC_R_SUCCESS)
goto bad_temp;
if (reply->lease != NULL)
iasubopt_dereference(&reply->lease, MDL);
continue;
bad_temp:
/* Rewind the IA_TA to empty. */
option_state_dereference(&reply->reply_ia, MDL);
if (!option_state_allocate(&reply->reply_ia, MDL)) {
status = ISC_R_NOMEMORY;
goto cleanup;
}
status = ISC_R_CANCELED;
reply->client_resources = 0;
reply->resources_included = ISC_FALSE;
if (reply->lease != NULL)
iasubopt_dereference(&reply->lease, MDL);
}
reply->ia_count++;
/*
* Give the client temporary addresses.
*/
if (reply->client_resources != 0)
goto store;
status = find_client_temporaries(reply);
if (status == ISC_R_NORESOURCES) {
switch (reply->packet->dhcpv6_msg_type) {
case DHCPV6_SOLICIT:
/*
* No address for any IA is handled
* by the caller.
*/
/* FALL THROUGH */
case DHCPV6_REQUEST:
/* Section 18.2.1 (Request):
*
* If the server cannot assign any addresses to
* an IA in the message from the client, the
* server MUST include the IA in the Reply
* message with no addresses in the IA and a
* Status Code option in the IA containing
* status code NoAddrsAvail.
*/
option_state_dereference(&reply->reply_ia, MDL);
if (!option_state_allocate(&reply->reply_ia, MDL)) {
log_error("reply_process_ia_ta: No "
"memory for option state wipe.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
if (!set_status_code(STATUS_NoAddrsAvail,
"No addresses available "
"for this interface.",
reply->reply_ia)) {
log_error("reply_process_ia_ta: Unable "
"to set NoAddrsAvail status code.");
status = ISC_R_FAILURE;
goto cleanup;
}
status = ISC_R_SUCCESS;
break;
default:
/*
* We don't want to include the IA if we
* provide zero addresses including zeroed
* lifetimes.
*/
if (reply->resources_included)
status = ISC_R_SUCCESS;
else
goto cleanup;
break;
}
} else if (status != ISC_R_SUCCESS)
goto cleanup;
store:
/*
* yes, goto's aren't the best but we also want to avoid extra
* indents
*/
if (status == ISC_R_CANCELED) {
/* We're replying with a status code so we still need to
* write it out in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
goto cleanup;
}
/*
* If we have any addresses log what we are doing.
*/
if (reply->ia->num_iasubopt != 0) {
struct iasubopt *tmp;
int i;
char tmp_addr[INET6_ADDRSTRLEN];
for (i = 0 ; i < reply->ia->num_iasubopt ; i++) {
tmp = reply->ia->iasubopt[i];
log_info("%s TA: address %s to client with duid %s "
"iaid = %d valid for %u seconds",
dhcpv6_type_names[reply->buf.reply.msg_type],
inet_ntop(AF_INET6, &tmp->addr,
tmp_addr, sizeof(tmp_addr)),
print_hex_1(reply->client_id.len,
reply->client_id.data, 60),
iaid,
tmp->valid);
}
}
/*
* For hard bindings we consume the new changes into
* the database (if any have been attached to the ia_ta).
*
* Loop through the assigned dynamic addresses, referencing the
* leases onto this IA_TA rather than any old ones, and updating
* pool timers for each (if any).
*/
if ((reply->ia->num_iasubopt != 0) &&
(reply->buf.reply.msg_type == DHCPV6_REPLY)) {
int must_commit = 0;
struct iasubopt *tmp;
struct data_string *ia_id;
int i;
for (i = 0 ; i < reply->ia->num_iasubopt ; i++) {
tmp = reply->ia->iasubopt[i];
if (tmp->ia != NULL)
ia_dereference(&tmp->ia, MDL);
ia_reference(&tmp->ia, reply->ia, MDL);
/* If we have anything to do on commit do it now */
if (tmp->on_star.on_commit != NULL) {
execute_statements(NULL, reply->packet,
NULL, NULL,
reply->packet->options,
reply->opt_state,
&tmp->scope,
tmp->on_star.on_commit,
&tmp->on_star);
executable_statement_dereference
(&tmp->on_star.on_commit, MDL);
}
#if defined (NSUPDATE)
/*
* Perform ddns updates.
*/
oc = lookup_option(&server_universe, reply->opt_state,
SV_DDNS_UPDATES);
if ((oc == NULL) ||
evaluate_boolean_option_cache(NULL, reply->packet,
NULL, NULL,
reply->packet->options,
reply->opt_state,
&tmp->scope,
oc, MDL)) {
ddns_updates(reply->packet, NULL, NULL,
tmp, NULL, reply->opt_state);
}
#endif
if (!reuse_lease6(reply, tmp)) {
/* Commit 'hard' bindings. */
must_commit = 1;
renew_lease6(tmp->ipv6_pool, tmp);
schedule_lease_timeout(tmp->ipv6_pool);
/* Do our threshold check. */
check_pool6_threshold(reply, tmp);
}
}
/* write the IA_TA in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
/* Remove any old ia from the hash. */
if (reply->old_ia != NULL) {
if (!release_on_roam(reply)) {
ia_id = &reply->old_ia->iaid_duid;
ia_hash_delete(ia_ta_active,
(unsigned char *)ia_id->data,
ia_id->len, MDL);
}
ia_dereference(&reply->old_ia, MDL);
}
/* Put new ia into the hash. */
reply->ia->cltt = cur_time;
ia_id = &reply->ia->iaid_duid;
ia_hash_add(ia_ta_active, (unsigned char *)ia_id->data,
ia_id->len, reply->ia, MDL);
/* If we couldn't reuse all of the iasubopts, we
* must update udpate the lease db */
if (must_commit) {
write_ia(reply->ia);
}
} else {
/* write the IA_TA in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
schedule_lease_timeout_reply(reply);
}
cleanup:
if (packet_ia != NULL)
option_state_dereference(&packet_ia, MDL);
if (iaaddr.data != NULL)
data_string_forget(&iaaddr, MDL);
if (reply->reply_ia != NULL)
option_state_dereference(&reply->reply_ia, MDL);
if (ia_data.data != NULL)
data_string_forget(&ia_data, MDL);
if (data.data != NULL)
data_string_forget(&data, MDL);
if (reply->ia != NULL)
ia_dereference(&reply->ia, MDL);
if (reply->old_ia != NULL)
ia_dereference(&reply->old_ia, MDL);
if (reply->lease != NULL)
iasubopt_dereference(&reply->lease, MDL);
/*
* ISC_R_CANCELED is a status code used by the addr processing to
* indicate we're replying with other addresses. This is still a
* success at higher layers.
*/
return((status == ISC_R_CANCELED) ? ISC_R_SUCCESS : status);
}
/*
* Determines if a lease (iasubopt) can be reused without extending it.
* If dhcp-cache-threshold is greater than zero (i.e enabled) then
* a lease may be reused without going through a full renewal if
* it meets all the requirements. In short it must be active, younger
* than the threshold, and not have DNS changes.
*
* If it is determined that it can be reused, that a call to
* shorten_lifetimes() is made to reduce the valid and preferred lifetimes
* sent to the client by the age of the lease.
*
* Returns 1 if lease can be reused, 0 otherwise
*/
int
reuse_lease6(struct reply_state *reply, struct iasubopt *lease) {
int threshold = DEFAULT_CACHE_THRESHOLD;
struct option_cache* oc = NULL;
struct data_string d1;
time_t age;
time_t limit;
int reuse_it = 0;
/* In order to even qualify for reuse consideration:
* 1. Lease must be active
* 2. It must have been accepted at least once
* 3. DNS info must not have changed */
if ((lease->state != FTS_ACTIVE) ||
(lease->hard_lifetime_end_time == 0) ||
(lease->ddns_cb != NULL)) {
return (0);
}
/* Look up threshold value */
memset(&d1, 0, sizeof(struct data_string));
oc = lookup_option(&server_universe, reply->opt_state,
SV_CACHE_THRESHOLD);
if (oc &&
evaluate_option_cache(&d1, reply->packet, NULL, NULL,
reply->packet->options, reply->opt_state,
&lease->scope, oc, MDL)) {
if (d1.len == 1 && (d1.data[0] < 100)) {
threshold = d1.data[0];
}
data_string_forget(&d1, MDL);
}
if (threshold <= 0) {
return (0);
}
if (lease->valid >= MAX_TIME) {
/* Infinite leases are always reused. We have to make
* a choice because we cannot determine when they actually
* began, so we either always reuse them or we never do. */
log_debug ("reusing infinite lease for: %s%s",
pin6_addr(&lease->addr), iasubopt_plen_str(lease));
return (1);
}
age = cur_tv.tv_sec - (lease->hard_lifetime_end_time - lease->valid);
if (lease->valid <= (INT_MAX / threshold))
limit = lease->valid * threshold / 100;
else
limit = lease->valid / 100 * threshold;
if (age < limit) {
/* Reduce valid/preferred going to the client by age */
shorten_lifetimes(reply, lease, age, threshold);
reuse_it = 1;
}
return (reuse_it);
}
/*
* Reduces the valid and preferred lifetimes for a given lease (iasubopt)
*
* We cannot determine until after a iasubopt has been added to
* the reply if the lease can be reused. Therefore, when we do reuse a
* lease we need a way to alter the lifetimes that will be sent to the client.
* That's where this function comes in handy:
*
* Locate the iasubopt by it's address within the reply the reduce both
* the preferred and valid lifetimes by the given number of seconds.
*
* Note that this function, by necessity, works directly with the
* option_cache data. Sort of a no-no but I don't have any better ideas.
*/
void shorten_lifetimes(struct reply_state *reply, struct iasubopt *lease,
time_t age, int threshold) {
struct option_cache* oc = NULL;
int subopt_type;
int addr_offset;
int pref_offset;
int val_offset;
int exp_length;
if (reply->ia->ia_type != D6O_IA_PD) {
subopt_type = D6O_IAADDR;
addr_offset = IASUBOPT_NA_ADDR_OFFSET;
pref_offset = IASUBOPT_NA_PREF_OFFSET;
val_offset = IASUBOPT_NA_VALID_OFFSET;
exp_length = IASUBOPT_NA_LEN;
}
else {
subopt_type = D6O_IAPREFIX;
addr_offset = IASUBOPT_PD_PREFIX_OFFSET;
pref_offset = IASUBOPT_PD_PREF_OFFSET;
val_offset = IASUBOPT_PD_VALID_OFFSET;
exp_length = IASUBOPT_PD_LEN;
}
// loop through the iasubopts for the one that matches this lease
oc = lookup_option(&dhcpv6_universe, reply->reply_ia, subopt_type);
for (; oc != NULL ; oc = oc->next) {
if (oc->data.data == NULL || oc->data.len != exp_length) {
/* shouldn't happen */
continue;
}
/* If address matches (and for PDs the prefix len matches)
* we assume this is our subopt, so update the lifetimes */
if (!memcmp(oc->data.data + addr_offset, &lease->addr, 16) &&
(subopt_type != D6O_IAPREFIX ||
(oc->data.data[IASUBOPT_PD_PREFLEN_OFFSET] ==
lease->plen))) {
u_int32_t pref_life = getULong(oc->data.data +
pref_offset);
u_int32_t valid_life = getULong(oc->data.data +
val_offset);
if (pref_life < MAX_TIME && pref_life > age) {
pref_life -= age;
putULong((unsigned char*)(oc->data.data) +
pref_offset, pref_life);
if (reply->min_prefer > pref_life) {
reply->min_prefer = pref_life;
}
}
if (valid_life < MAX_TIME && valid_life > age) {
valid_life -= age;
putULong((unsigned char*)(oc->data.data) +
val_offset, valid_life);
if (reply->min_valid > reply->send_valid) {
reply->min_valid = valid_life;
}
}
log_debug ("Reusing lease for: %s%s, "
"age %ld secs < %d%%,"
" sending shortened lifetimes -"
" preferred: %u, valid %u",
pin6_addr(&lease->addr),
iasubopt_plen_str(lease),
(long)age, threshold,
pref_life, valid_life);
break;
}
}
}
/*
* Verify the temporary address is available.
*/
static isc_boolean_t
temporary_is_available(struct reply_state *reply, struct iaddr *addr) {
struct in6_addr tmp_addr;
struct subnet *subnet;
struct ipv6_pool *pool = NULL;
struct ipv6_pond *pond = NULL;
int i;
memcpy(&tmp_addr, addr->iabuf, sizeof(tmp_addr));
/*
* Clients may choose to send :: as an address, with the idea to give
* hints about preferred-lifetime or valid-lifetime.
* So this is not a request for this address.
*/
if (IN6_IS_ADDR_UNSPECIFIED(&tmp_addr))
return ISC_FALSE;
/*
* Verify that this address is on the client's network.
*/
for (subnet = reply->shared->subnets ; subnet != NULL ;
subnet = subnet->next_sibling) {
if (addr_eq(subnet_number(*addr, subnet->netmask),
subnet->net))
break;
}
/* Address not found on shared network. */
if (subnet == NULL)
return ISC_FALSE;
/*
* Check if this address is owned (must be before next step).
*/
if (address_is_owned(reply, addr))
return ISC_TRUE;
/*
* Verify that this address is in a temporary pool and try to get it.
*/
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
if (((pond->prohibit_list != NULL) &&
(permitted(reply->packet, pond->prohibit_list))) ||
((pond->permit_list != NULL) &&
(!permitted(reply->packet, pond->permit_list))))
continue;
for (i = 0 ; (pool = pond->ipv6_pools[i]) != NULL ; i++) {
if (pool->pool_type != D6O_IA_TA)
continue;
if (ipv6_in_pool(&tmp_addr, pool))
break;
}
if (pool != NULL)
break;
}
if (pool == NULL)
return ISC_FALSE;
if (lease6_exists(pool, &tmp_addr))
return ISC_FALSE;
if (iasubopt_allocate(&reply->lease, MDL) != ISC_R_SUCCESS)
return ISC_FALSE;
reply->lease->addr = tmp_addr;
reply->lease->plen = 0;
/* Default is soft binding for 2 minutes. */
if (add_lease6(pool, reply->lease, cur_time + 120) != ISC_R_SUCCESS)
return ISC_FALSE;
return ISC_TRUE;
}
/*
* Get a temporary address per prefix.
*/
static isc_result_t
find_client_temporaries(struct reply_state *reply) {
int i;
struct ipv6_pool *p = NULL;
struct ipv6_pond *pond;
isc_result_t status = ISC_R_NORESOURCES;;
unsigned int attempts;
struct iaddr send_addr;
/*
* Do a quick walk through of the ponds and pools
* to see if we have any prefix pools
*/
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
if (pond->ipv6_pools == NULL)
continue;
for (i = 0; (p = pond->ipv6_pools[i]) != NULL; i++) {
if (p->pool_type == D6O_IA_TA)
break;
}
if (p != NULL)
break;
}
/* If we get here and p is NULL we have no useful pools */
if (p == NULL) {
log_debug("Unable to get client addresses: "
"no IPv6 pools on this shared network");
return ISC_R_NORESOURCES;
}
/*
* We have at least one pool that could provide an address
* Now we walk through the ponds and pools again and check
* to see if the client is permitted and if an address is
* available
*/
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
if (((pond->prohibit_list != NULL) &&
(permitted(reply->packet, pond->prohibit_list))) ||
((pond->permit_list != NULL) &&
(!permitted(reply->packet, pond->permit_list))))
continue;
for (i = 0; (p = pond->ipv6_pools[i]) != NULL; i++) {
if (p->pool_type != D6O_IA_TA) {
continue;
}
/*
* Get an address in this temporary pool.
*/
status = create_lease6(p, &reply->lease, &attempts,
&reply->client_id,
cur_time + 120);
if (status != ISC_R_SUCCESS) {
log_debug("Unable to get a temporary address.");
goto cleanup;
}
status = reply_process_is_addressed(reply,
&reply->lease->scope,
pond->group);
if (status != ISC_R_SUCCESS) {
goto cleanup;
}
send_addr.len = 16;
memcpy(send_addr.iabuf, &reply->lease->addr, 16);
status = reply_process_send_addr(reply, &send_addr);
if (status != ISC_R_SUCCESS) {
goto cleanup;
}
/*
* reply->lease can't be null as we use it above
* add check if that changes
*/
iasubopt_dereference(&reply->lease, MDL);
}
}
cleanup:
if (reply->lease != NULL) {
iasubopt_dereference(&reply->lease, MDL);
}
return status;
}
/*
* This function only returns failure on 'hard' failures. If it succeeds,
* it will leave a lease structure behind.
*/
static isc_result_t
reply_process_try_addr(struct reply_state *reply, struct iaddr *addr) {
isc_result_t status = ISC_R_ADDRNOTAVAIL;
struct ipv6_pool *pool = NULL;
struct ipv6_pond *pond = NULL;
int i;
struct data_string data_addr;
if ((reply == NULL) || (reply->shared == NULL) ||
(addr == NULL) || (reply->lease != NULL))
return (DHCP_R_INVALIDARG);
/*
* Do a quick walk through of the ponds and pools
* to see if we have any NA address pools
*/
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
if (pond->ipv6_pools == NULL)
continue;
for (i = 0; ; i++) {
pool = pond->ipv6_pools[i];
if ((pool == NULL) ||
(pool->pool_type == D6O_IA_NA))
break;
}
if (pool != NULL)
break;
}
/* If we get here and p is NULL we have no useful pools */
if (pool == NULL) {
return (ISC_R_ADDRNOTAVAIL);
}
memset(&data_addr, 0, sizeof(data_addr));
data_addr.len = addr->len;
data_addr.data = addr->iabuf;
/*
* We have at least one pool that could provide an address
* Now we walk through the ponds and pools again and check
* to see if the client is permitted and if an address is
* available
*
* Within a given pond we start looking at the last pool we
* allocated from, unless it had a collision trying to allocate
* an address. This will tend to move us into less-filled pools.
*/
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
if (((pond->prohibit_list != NULL) &&
(permitted(reply->packet, pond->prohibit_list))) ||
((pond->permit_list != NULL) &&
(!permitted(reply->packet, pond->permit_list))))
continue;
for (i = 0 ; (pool = pond->ipv6_pools[i]) != NULL ; i++) {
if (pool->pool_type != D6O_IA_NA)
continue;
status = try_client_v6_address(&reply->lease, pool,
&data_addr);
if (status == ISC_R_SUCCESS)
break;
}
if (status == ISC_R_SUCCESS)
break;
}
/* Note that this is just pedantry. There is no allocation to free. */
data_string_forget(&data_addr, MDL);
/* Return just the most recent status... */
return (status);
}
/* Look around for an address to give the client. First, look through the
* old IA for addresses we can extend. Second, try to allocate a new address.
* Finally, actually add that address into the current reply IA.
*/
static isc_result_t
find_client_address(struct reply_state *reply) {
struct iaddr send_addr;
isc_result_t status = ISC_R_NORESOURCES;
struct iasubopt *lease, *best_lease = NULL;
struct binding_scope **scope;
struct group *group;
int i;
if (reply->static_lease) {
if (reply->host == NULL)
return DHCP_R_INVALIDARG;
send_addr.len = 16;
memcpy(send_addr.iabuf, reply->fixed.data, 16);
scope = &global_scope;
group = reply->subnet->group;
goto send_addr;
}
if (reply->old_ia != NULL) {
for (i = 0 ; i < reply->old_ia->num_iasubopt ; i++) {
struct shared_network *candidate_shared;
struct ipv6_pond *pond;
lease = reply->old_ia->iasubopt[i];
candidate_shared = lease->ipv6_pool->shared_network;
pond = lease->ipv6_pool->ipv6_pond;
/*
* Look for the best lease on the client's shared
* network, that is still permitted
*/
if ((candidate_shared != reply->shared) ||
(lease6_usable(lease) != ISC_TRUE))
continue;
if (((pond->prohibit_list != NULL) &&
(permitted(reply->packet, pond->prohibit_list))) ||
((pond->permit_list != NULL) &&
(!permitted(reply->packet, pond->permit_list))))
continue;
best_lease = lease_compare(lease, best_lease);
}
}
/* Try to pick a new address if we didn't find one, or if we found an
* abandoned lease.
*/
if ((best_lease == NULL) || (best_lease->state == FTS_ABANDONED)) {
status = pick_v6_address(reply);
} else if (best_lease != NULL) {
iasubopt_reference(&reply->lease, best_lease, MDL);
status = ISC_R_SUCCESS;
}
/* Pick the abandoned lease as a last resort. */
if ((status == ISC_R_NORESOURCES) && (best_lease != NULL)) {
/* I don't see how this is supposed to be done right now. */
log_error("Best match for DUID %s is an abandoned address,"
" This may be a result of multiple clients attempting"
" to use this DUID",
print_hex_1(reply->client_id.len,
reply->client_id.data, 60));
/* iasubopt_reference(&reply->lease, best_lease, MDL); */
}
/* Give up now if we didn't find a lease. */
if (status != ISC_R_SUCCESS)
return status;
if (reply->lease == NULL)
log_fatal("Impossible condition at %s:%d.", MDL);
/* Draw binding scopes from the lease's binding scope, and config
* from the lease's containing subnet and higher. Note that it may
* be desirable to place the group attachment directly in the pool.
*/
scope = &reply->lease->scope;
group = reply->lease->ipv6_pool->ipv6_pond->group;
send_addr.len = 16;
memcpy(send_addr.iabuf, &reply->lease->addr, 16);
send_addr:
status = reply_process_is_addressed(reply, scope, group);
if (status != ISC_R_SUCCESS)
return status;
status = reply_process_send_addr(reply, &send_addr);
return status;
}
/* Once an address is found for a client, perform several common functions;
* Calculate and store valid and preferred lease times, draw client options
* into the option state.
*/
static isc_result_t
reply_process_is_addressed(struct reply_state *reply,
struct binding_scope **scope, struct group *group)
{
isc_result_t status = ISC_R_SUCCESS;
struct data_string data;
struct option_cache *oc;
struct option_state *tmp_options = NULL;
struct on_star *on_star;
int i;
/* Initialize values we will cleanup. */
memset(&data, 0, sizeof(data));
/*
* Find the proper on_star block to use. We use the
* one in the lease if we have a lease or the one in
* the reply if we don't have a lease because this is
* a static instance
*/
if (reply->lease) {
on_star = &reply->lease->on_star;
} else {
on_star = &reply->on_star;
}
/*
* Bring in the root configuration. We only do this to bring
* in the on * statements, as we didn't have the lease available
* we did it the first time.
*/
option_state_allocate(&tmp_options, MDL);
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options, tmp_options,
&global_scope, root_group, NULL,
on_star);
if (tmp_options != NULL) {
option_state_dereference(&tmp_options, MDL);
}
/*
* Bring configured options into the root packet level cache - start
* with the lease's closest enclosing group (passed in by the caller
* as 'group').
*/
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options, reply->opt_state,
scope, group, root_group, on_star);
/* Execute statements from class scopes. */
for (i = reply->packet->class_count; i > 0; i--) {
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state, scope,
reply->packet->classes[i - 1]->group,
group, on_star);
}
/*
* If there is a host record, over-ride with values configured there,
* without re-evaluating configuration from the previously executed
* group or its common enclosers.
*/
if (reply->host != NULL)
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state, scope,
reply->host->group, group,
on_star);
/* Determine valid lifetime. */
if (reply->client_valid == 0)
reply->send_valid = DEFAULT_DEFAULT_LEASE_TIME;
else
reply->send_valid = reply->client_valid;
oc = lookup_option(&server_universe, reply->opt_state,
SV_DEFAULT_LEASE_TIME);
if (oc != NULL) {
if (!evaluate_option_cache(&data, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state,
scope, oc, MDL) ||
(data.len != 4)) {
log_error("reply_process_is_addressed: unable to "
"evaluate default lease time");
status = ISC_R_FAILURE;
goto cleanup;
}
reply->send_valid = getULong(data.data);
data_string_forget(&data, MDL);
}
/* Check to see if the lease time would cause us to wrap
* in which case we make it infinite.
* The following doesn't work on at least some systems:
* (cur_time + reply->send_valid < cur_time)
*/
if (reply->send_valid != INFINITE_TIME) {
time_t test_time = cur_time + reply->send_valid;
if (test_time < cur_time)
reply->send_valid = INFINITE_TIME;
}
if (reply->client_prefer == 0)
reply->send_prefer = reply->send_valid;
else
reply->send_prefer = reply->client_prefer;
if ((reply->send_prefer >= reply->send_valid) &&
(reply->send_valid != INFINITE_TIME))
reply->send_prefer = (reply->send_valid / 2) +
(reply->send_valid / 8);
oc = lookup_option(&server_universe, reply->opt_state,
SV_PREFER_LIFETIME);
if (oc != NULL) {
if (!evaluate_option_cache(&data, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state,
scope, oc, MDL) ||
(data.len != 4)) {
log_error("reply_process_is_addressed: unable to "
"evaluate preferred lease time");
status = ISC_R_FAILURE;
goto cleanup;
}
reply->send_prefer = getULong(data.data);
data_string_forget(&data, MDL);
}
/* Note lowest values for later calculation of renew/rebind times. */
if (reply->min_prefer > reply->send_prefer)
reply->min_prefer = reply->send_prefer;
if (reply->min_valid > reply->send_valid)
reply->min_valid = reply->send_valid;
#if 0
/*
* XXX: Old 4.0.0 alpha code would change the host {} record
* XXX: uid upon lease assignment. This was intended to cover the
* XXX: case where a client first identifies itself using vendor
* XXX: options in a solicit, or request, but later neglects to include
* XXX: these options in a Renew or Rebind. It is not clear that this
* XXX: is required, and has some startling ramifications (such as
* XXX: how to recover this dynamic host {} state across restarts).
*/
if (reply->host != NULL)
change_host_uid(host, reply->client_id->data,
reply->client_id->len);
#endif /* 0 */
/* Perform dynamic lease related update work. */
if (reply->lease != NULL) {
/* Cached lifetimes */
reply->lease->prefer = reply->send_prefer;
reply->lease->valid = reply->send_valid;
/* Advance (or rewind) the valid lifetime.
* In the protocol 0xFFFFFFFF is infinite
* when connecting to the lease file MAX_TIME is
*/
if (reply->buf.reply.msg_type == DHCPV6_REPLY) {
if (reply->send_valid == INFINITE_TIME) {
reply->lease->soft_lifetime_end_time = MAX_TIME;
} else {
reply->lease->soft_lifetime_end_time =
cur_time + reply->send_valid;
}
/* Wait before renew! */
}
status = ia_add_iasubopt(reply->ia, reply->lease, MDL);
if (status != ISC_R_SUCCESS) {
log_fatal("reply_process_is_addressed: Unable to "
"attach lease to new IA: %s",
isc_result_totext(status));
}
/*
* If this is a new lease, make sure it is attached somewhere.
*/
if (reply->lease->ia == NULL) {
ia_reference(&reply->lease->ia, reply->ia, MDL);
}
}
/* Bring a copy of the relevant options into the IA scope. */
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options, reply->reply_ia,
scope, group, root_group, NULL);
/* Execute statements from class scopes. */
for (i = reply->packet->class_count; i > 0; i--) {
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->reply_ia, scope,
reply->packet->classes[i - 1]->group,
group, NULL);
}
/*
* And bring in host record configuration, if any, but not to overlap
* the previous group or its common enclosers.
*/
if (reply->host != NULL)
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->reply_ia, scope,
reply->host->group, group, NULL);
cleanup:
if (data.data != NULL)
data_string_forget(&data, MDL);
if (status == ISC_R_SUCCESS)
reply->client_resources++;
return status;
}
/* Simply send an IAADDR within the IA scope as described. */
static isc_result_t
reply_process_send_addr(struct reply_state *reply, struct iaddr *addr) {
isc_result_t status = ISC_R_SUCCESS;
struct data_string data;
memset(&data, 0, sizeof(data));
/* Now append the lease. */
data.len = IAADDR_OFFSET;
if (!buffer_allocate(&data.buffer, data.len, MDL)) {
log_error("reply_process_send_addr: out of memory"
"allocating new IAADDR buffer.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
data.data = data.buffer->data;
memcpy(data.buffer->data, addr->iabuf, 16);
putULong(data.buffer->data + 16, reply->send_prefer);
putULong(data.buffer->data + 20, reply->send_valid);
if (!append_option_buffer(&dhcpv6_universe, reply->reply_ia,
data.buffer, data.buffer->data,
data.len, D6O_IAADDR, 0)) {
log_error("reply_process_send_addr: unable "
"to save IAADDR option");
status = ISC_R_FAILURE;
goto cleanup;
}
reply->resources_included = ISC_TRUE;
cleanup:
if (data.data != NULL)
data_string_forget(&data, MDL);
return status;
}
/* Choose the better of two leases. */
static struct iasubopt *
lease_compare(struct iasubopt *alpha, struct iasubopt *beta) {
if (alpha == NULL)
return beta;
if (beta == NULL)
return alpha;
switch(alpha->state) {
case FTS_ACTIVE:
switch(beta->state) {
case FTS_ACTIVE:
/* Choose the lease with the longest lifetime (most
* likely the most recently allocated).
*/
if (alpha->hard_lifetime_end_time <
beta->hard_lifetime_end_time)
return beta;
else
return alpha;
case FTS_EXPIRED:
case FTS_ABANDONED:
return alpha;
default:
log_fatal("Impossible condition at %s:%d.", MDL);
}
break;
case FTS_EXPIRED:
switch (beta->state) {
case FTS_ACTIVE:
return beta;
case FTS_EXPIRED:
/* Choose the most recently expired lease. */
if (alpha->hard_lifetime_end_time <
beta->hard_lifetime_end_time)
return beta;
else if ((alpha->hard_lifetime_end_time ==
beta->hard_lifetime_end_time) &&
(alpha->soft_lifetime_end_time <
beta->soft_lifetime_end_time))
return beta;
else
return alpha;
case FTS_ABANDONED:
return alpha;
default:
log_fatal("Impossible condition at %s:%d.", MDL);
}
break;
case FTS_ABANDONED:
switch (beta->state) {
case FTS_ACTIVE:
case FTS_EXPIRED:
return alpha;
case FTS_ABANDONED:
/* Choose the lease that was abandoned longest ago. */
if (alpha->hard_lifetime_end_time <
beta->hard_lifetime_end_time)
return alpha;
else
return beta;
default:
log_fatal("Impossible condition at %s:%d.", MDL);
}
break;
default:
log_fatal("Impossible condition at %s:%d.", MDL);
}
log_fatal("Triple impossible condition at %s:%d.", MDL);
return NULL;
}
/* Process a client-supplied IA_PD. This may append options to the tail of
* the reply packet being built in the reply_state structure.
*/
static isc_result_t
reply_process_ia_pd(struct reply_state *reply, struct option_cache *ia) {
isc_result_t status = ISC_R_SUCCESS;
u_int32_t iaid;
unsigned ia_cursor;
struct option_state *packet_ia;
struct option_cache *oc;
struct data_string ia_data, data;
/* Initialize values that will get cleaned up on return. */
packet_ia = NULL;
memset(&ia_data, 0, sizeof(ia_data));
memset(&data, 0, sizeof(data));
/*
* Note that find_client_prefix() may set reply->lease.
*/
/* Make sure there is at least room for the header. */
if ((reply->cursor + IA_PD_OFFSET + 4) > sizeof(reply->buf)) {
log_error("reply_process_ia_pd: Reply too long for IA.");
return ISC_R_NOSPACE;
}
/* Fetch the IA_PD contents. */
if (!get_encapsulated_IA_state(&packet_ia, &ia_data, reply->packet,
ia, IA_PD_OFFSET)) {
log_error("reply_process_ia_pd: error evaluating ia");
status = ISC_R_FAILURE;
goto cleanup;
}
/* Extract IA_PD header contents. */
iaid = getULong(ia_data.data);
reply->renew = getULong(ia_data.data + 4);
reply->rebind = getULong(ia_data.data + 8);
/* Create an IA_PD structure. */
if (ia_allocate(&reply->ia, iaid, (char *)reply->client_id.data,
reply->client_id.len, MDL) != ISC_R_SUCCESS) {
log_error("reply_process_ia_pd: no memory for ia.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
reply->ia->ia_type = D6O_IA_PD;
/* Cache pre-existing IA_PD, if any. */
ia_hash_lookup(&reply->old_ia, ia_pd_active,
(unsigned char *)reply->ia->iaid_duid.data,
reply->ia->iaid_duid.len, MDL);
/*
* Create an option cache to carry the IA_PD option contents, and
* execute any user-supplied values into it.
*/
if (!option_state_allocate(&reply->reply_ia, MDL)) {
status = ISC_R_NOMEMORY;
goto cleanup;
}
/* Check & count the fixed prefix host records. */
reply->static_prefixes = 0;
if ((reply->host != NULL) && (reply->host->fixed_prefix != NULL)) {
struct iaddrcidrnetlist *fp;
for (fp = reply->host->fixed_prefix; fp != NULL;
fp = fp->next) {
reply->static_prefixes += 1;
}
}
/*
* Save the cursor position at the start of the IA_PD, so we can
* set length and adjust t1/t2 values later. We write a temporary
* header out now just in case we decide to adjust the packet
* within sub-process functions.
*/
ia_cursor = reply->cursor;
/* Initialize the IA_PD header. First the code. */
putUShort(reply->buf.data + reply->cursor, (unsigned)D6O_IA_PD);
reply->cursor += 2;
/* Then option length. */
putUShort(reply->buf.data + reply->cursor, 0x0Cu);
reply->cursor += 2;
/* Then IA_PD header contents; IAID. */
putULong(reply->buf.data + reply->cursor, iaid);
reply->cursor += 4;
/* We store the client's t1 for now, and may over-ride it later. */
putULong(reply->buf.data + reply->cursor, reply->renew);
reply->cursor += 4;
/* We store the client's t2 for now, and may over-ride it later. */
putULong(reply->buf.data + reply->cursor, reply->rebind);
reply->cursor += 4;
/*
* For each prefix in this IA_PD, decide what to do about it.
*/
oc = lookup_option(&dhcpv6_universe, packet_ia, D6O_IAPREFIX);
reply->min_valid = reply->min_prefer = INFINITE_TIME;
reply->client_valid = reply->client_prefer = 0;
reply->preflen = -1;
for (; oc != NULL ; oc = oc->next) {
status = reply_process_prefix(reply, oc);
/*
* Canceled means we did not allocate prefixes to the
* client, but we're "done" with this IA - we set a status
* code. So transmit this reply, e.g., move on to the next
* IA.
*/
if (status == ISC_R_CANCELED)
break;
if ((status != ISC_R_SUCCESS) &&
(status != ISC_R_ADDRINUSE) &&
(status != ISC_R_ADDRNOTAVAIL))
goto cleanup;
}
reply->pd_count++;
/*
* If we fell through the above and never gave the client
* a prefix, give it one now.
*/
if ((status != ISC_R_CANCELED) && (reply->client_resources == 0)) {
status = find_client_prefix(reply);
if (status == ISC_R_NORESOURCES) {
switch (reply->packet->dhcpv6_msg_type) {
case DHCPV6_SOLICIT:
/*
* No prefix for any IA is handled
* by the caller.
*/
/* FALL THROUGH */
case DHCPV6_REQUEST:
/* Same than for addresses. */
option_state_dereference(&reply->reply_ia, MDL);
if (!option_state_allocate(&reply->reply_ia,
MDL))
{
log_error("reply_process_ia_pd: No "
"memory for option state "
"wipe.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
if (!set_status_code(STATUS_NoPrefixAvail,
"No prefixes available "
"for this interface.",
reply->reply_ia)) {
log_error("reply_process_ia_pd: "
"Unable to set "
"NoPrefixAvail status "
"code.");
status = ISC_R_FAILURE;
goto cleanup;
}
status = ISC_R_SUCCESS;
break;
default:
if (reply->resources_included)
status = ISC_R_SUCCESS;
else
goto cleanup;
break;
}
}
if (status != ISC_R_SUCCESS)
goto cleanup;
}
/*
* yes, goto's aren't the best but we also want to avoid extra
* indents
*/
if (status == ISC_R_CANCELED) {
/* We're replying with a status code so we still need to
* write it out in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
goto cleanup;
}
/*
* Handle static prefixes, we always log stuff and if it's
* a hard binding we run any commit statements that we have
*/
if (reply->static_prefixes != 0) {
char tmp_addr[INET6_ADDRSTRLEN];
log_info("%s PD: address %s/%d to client with duid %s "
"iaid = %d static",
dhcpv6_type_names[reply->buf.reply.msg_type],
inet_ntop(AF_INET6, reply->fixed_pref.lo_addr.iabuf,
tmp_addr, sizeof(tmp_addr)),
reply->fixed_pref.bits,
print_hex_1(reply->client_id.len,
reply->client_id.data, 60),
iaid);
/* Write the lease out in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
if ((reply->buf.reply.msg_type == DHCPV6_REPLY) &&
(reply->on_star.on_commit != NULL)) {
execute_statements(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state,
NULL, reply->on_star.on_commit,
NULL);
executable_statement_dereference
(&reply->on_star.on_commit, MDL);
}
goto cleanup;
}
/*
* If we have any addresses log what we are doing.
*/
if (reply->ia->num_iasubopt != 0) {
struct iasubopt *tmp;
int i;
char tmp_addr[INET6_ADDRSTRLEN];
for (i = 0 ; i < reply->ia->num_iasubopt ; i++) {
tmp = reply->ia->iasubopt[i];
log_info("%s PD: address %s/%d to client with duid %s"
" iaid = %d valid for %u seconds",
dhcpv6_type_names[reply->buf.reply.msg_type],
inet_ntop(AF_INET6, &tmp->addr,
tmp_addr, sizeof(tmp_addr)),
(int)tmp->plen,
print_hex_1(reply->client_id.len,
reply->client_id.data, 60),
iaid, tmp->valid);
}
}
/*
* If this is not a 'soft' binding, consume the new changes into
* the database (if any have been attached to the ia_pd).
*
* Loop through the assigned dynamic prefixes, referencing the
* prefixes onto this IA_PD rather than any old ones, and updating
* prefix pool timers for each (if any).
*
* If a lease can be reused we skip renewing it or checking the
* pool threshold. If it can't we flag that the IA must be commited
* to the db and do the renewal and pool check.
*/
if ((reply->buf.reply.msg_type == DHCPV6_REPLY) &&
(reply->ia->num_iasubopt != 0)) {
int must_commit = 0;
struct iasubopt *tmp;
struct data_string *ia_id;
int i;
for (i = 0 ; i < reply->ia->num_iasubopt ; i++) {
tmp = reply->ia->iasubopt[i];
if (tmp->ia != NULL)
ia_dereference(&tmp->ia, MDL);
ia_reference(&tmp->ia, reply->ia, MDL);
/* If we have anything to do on commit do it now */
if (tmp->on_star.on_commit != NULL) {
execute_statements(NULL, reply->packet,
NULL, NULL,
reply->packet->options,
reply->opt_state,
&tmp->scope,
tmp->on_star.on_commit,
&tmp->on_star);
executable_statement_dereference
(&tmp->on_star.on_commit, MDL);
}
if (!reuse_lease6(reply, tmp)) {
/* Commit 'hard' bindings. */
must_commit = 1;
renew_lease6(tmp->ipv6_pool, tmp);
schedule_lease_timeout(tmp->ipv6_pool);
/* Do our threshold check. */
check_pool6_threshold(reply, tmp);
}
}
/* write the IA_PD in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
/* Remove any old ia from the hash. */
if (reply->old_ia != NULL) {
if (!release_on_roam(reply)) {
ia_id = &reply->old_ia->iaid_duid;
ia_hash_delete(ia_pd_active,
(unsigned char *)ia_id->data,
ia_id->len, MDL);
}
ia_dereference(&reply->old_ia, MDL);
}
/* Put new ia into the hash. */
reply->ia->cltt = cur_time;
ia_id = &reply->ia->iaid_duid;
ia_hash_add(ia_pd_active, (unsigned char *)ia_id->data,
ia_id->len, reply->ia, MDL);
/* If we couldn't reuse all of the iasubopts, we
* must udpate the lease db */
if (must_commit) {
write_ia(reply->ia);
}
} else {
/* write the IA_PD in wire-format to the outbound buffer */
write_to_packet(reply, ia_cursor);
schedule_lease_timeout_reply(reply);
}
cleanup:
if (packet_ia != NULL)
option_state_dereference(&packet_ia, MDL);
if (reply->reply_ia != NULL)
option_state_dereference(&reply->reply_ia, MDL);
if (ia_data.data != NULL)
data_string_forget(&ia_data, MDL);
if (data.data != NULL)
data_string_forget(&data, MDL);
if (reply->ia != NULL)
ia_dereference(&reply->ia, MDL);
if (reply->old_ia != NULL)
ia_dereference(&reply->old_ia, MDL);
if (reply->lease != NULL)
iasubopt_dereference(&reply->lease, MDL);
if (reply->on_star.on_expiry != NULL)
executable_statement_dereference
(&reply->on_star.on_expiry, MDL);
if (reply->on_star.on_release != NULL)
executable_statement_dereference
(&reply->on_star.on_release, MDL);
/*
* ISC_R_CANCELED is a status code used by the prefix processing to
* indicate we're replying with a status code. This is still a
* success at higher layers.
*/
return((status == ISC_R_CANCELED) ? ISC_R_SUCCESS : status);
}
/*!
*
* \brief Find the proper scoping group for use with a v6 static prefix.
*
* We start by trying to find a subnet based on the given prefix and
* the shared network. If we don't find one then the prefix has been
* declared outside of any subnets. If there is a static address
* associated with the host we use it to try and find a subnet (this
* should succeed). If there isn't a static address we fall back
* to the shared subnet itself.
* Once we have a subnet we extract the group from it and return it.
*
* \param reply - the reply structure we use to collect information
* we will use the fields shared, fixed_pref and host
* from the structure
*
* \return a pointer to the group structure to use for scoping
*/
static struct group *
find_group_by_prefix(struct reply_state *reply) {
/* default group if we don't find anything better */
struct group *group = reply->shared->group;
struct subnet *subnet = NULL;
struct iaddr tmp_addr;
struct data_string fixed_addr;
/* Try with the prefix first */
if (find_grouped_subnet(&subnet, reply->shared,
reply->fixed_pref.lo_addr, MDL) != 0) {
group = subnet->group;
subnet_dereference(&subnet, MDL);
return (group);
}
/* Didn't find a subnet via prefix, what about fixed address */
/* The caller has already tested reply->host != NULL */
memset(&fixed_addr, 0, sizeof(fixed_addr));
if ((reply->host->fixed_addr != NULL) &&
(evaluate_option_cache(&fixed_addr, NULL, NULL, NULL,
NULL, NULL, &global_scope,
reply->host->fixed_addr, MDL))) {
if (fixed_addr.len >= 16) {
tmp_addr.len = 16;
memcpy(tmp_addr.iabuf, fixed_addr.data, 16);
if (find_grouped_subnet(&subnet, reply->shared,
tmp_addr, MDL) != 0) {
group = subnet->group;
subnet_dereference(&subnet, MDL);
}
}
data_string_forget(&fixed_addr, MDL);
}
/* return whatever we got */
return (group);
}
/*
* Process an IAPREFIX within a given IA_PD, storing any IAPREFIX reply
* contents into the reply's current ia_pd-scoped option cache. Returns
* ISC_R_CANCELED in the event we are replying with a status code and do
* not wish to process more IAPREFIXes within this IA_PD.
*/
static isc_result_t
reply_process_prefix(struct reply_state *reply, struct option_cache *pref) {
u_int32_t pref_life, valid_life;
struct binding_scope **scope;
struct iaddrcidrnet tmp_pref;
struct option_cache *oc;
struct data_string iapref, data;
isc_result_t status = ISC_R_SUCCESS;
struct group *group;
/* Initializes values that will be cleaned up. */
memset(&iapref, 0, sizeof(iapref));
memset(&data, 0, sizeof(data));
/* Note that reply->lease may be set by prefix_is_owned() */
/*
* There is no point trying to process an incoming prefix if there
* is no room for an outgoing prefix.
*/
if ((reply->cursor + 29) > sizeof(reply->buf)) {
log_error("reply_process_prefix: Out of room for prefix.");
return ISC_R_NOSPACE;
}
/* Extract this IAPREFIX option. */
if (!evaluate_option_cache(&iapref, reply->packet, NULL, NULL,
reply->packet->options, NULL, &global_scope,
pref, MDL) ||
(iapref.len < IAPREFIX_OFFSET)) {
log_error("reply_process_prefix: error evaluating IAPREFIX.");
status = ISC_R_FAILURE;
goto cleanup;
}
/*
* Layout: preferred and valid lifetimes followed by the prefix
* length and the IPv6 address.
*/
pref_life = getULong(iapref.data);
valid_life = getULong(iapref.data + 4);
if ((reply->client_valid == 0) ||
(reply->client_valid > valid_life))
reply->client_valid = valid_life;
if ((reply->client_prefer == 0) ||
(reply->client_prefer > pref_life))
reply->client_prefer = pref_life;
/*
* Clients may choose to send ::/0 as a prefix, with the idea to give
* hints about preferred-lifetime or valid-lifetime.
*/
tmp_pref.lo_addr.len = 16;
memset(tmp_pref.lo_addr.iabuf, 0, 16);
if ((iapref.data[8] == 0) &&
(memcmp(iapref.data + 9, tmp_pref.lo_addr.iabuf, 16) == 0)) {
/* Status remains success; we just ignore this one. */
goto cleanup;
}
/*
* Clients may choose to send ::/X as a prefix to specify a
* preferred/requested prefix length. Note X is never zero here.
*/
tmp_pref.bits = (int) iapref.data[8];
if (reply->preflen < 0) {
/* Cache the first preferred prefix length. */
reply->preflen = tmp_pref.bits;
}
if (memcmp(iapref.data + 9, tmp_pref.lo_addr.iabuf, 16) == 0) {
goto cleanup;
}
memcpy(tmp_pref.lo_addr.iabuf, iapref.data + 9, 16);
/* Verify the prefix belongs to the client. */
if (!prefix_is_owned(reply, &tmp_pref)) {
/* Same than for addresses. */
if ((reply->packet->dhcpv6_msg_type == DHCPV6_SOLICIT) ||
(reply->packet->dhcpv6_msg_type == DHCPV6_REQUEST) ||
(reply->packet->dhcpv6_msg_type == DHCPV6_REBIND)) {
status = reply_process_try_prefix(reply, &tmp_pref);
/* Either error out or skip this prefix. */
if ((status != ISC_R_SUCCESS) &&
(status != ISC_R_ADDRINUSE) &&
(status != ISC_R_ADDRNOTAVAIL))
goto cleanup;
if (reply->lease == NULL) {
if (reply->packet->dhcpv6_msg_type ==
DHCPV6_REBIND) {
reply->send_prefer = 0;
reply->send_valid = 0;
goto send_pref;
}
/* status remains success - ignore */
goto cleanup;
}
/*
* RFC3633 section 18.2.3:
*
* If the delegating router cannot find a binding
* for the requesting router's IA_PD the delegating
* router returns the IA_PD containing no prefixes
* with a Status Code option set to NoBinding in the
* Reply message.
*
* On mismatch we (ab)use this pretending we have not the IA
* as soon as we have not a prefix.
*/
} else if (reply->packet->dhcpv6_msg_type == DHCPV6_RENEW) {
/* Rewind the IA_PD to empty. */
option_state_dereference(&reply->reply_ia, MDL);
if (!option_state_allocate(&reply->reply_ia, MDL)) {
log_error("reply_process_prefix: No memory "
"for option state wipe.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
/* Append a NoBinding status code. */
if (!set_status_code(STATUS_NoBinding,
"Prefix not bound to this "
"interface.", reply->reply_ia)) {
log_error("reply_process_prefix: Unable to "
"attach status code.");
status = ISC_R_FAILURE;
goto cleanup;
}
/* Fin (no more IAPREFIXes). */
status = ISC_R_CANCELED;
goto cleanup;
} else {
log_error("It is impossible to lease a client that is "
"not sending a solicit, request, renew, or "
"rebind message.");
status = ISC_R_FAILURE;
goto cleanup;
}
}
if (reply->static_prefixes > 0) {
if (reply->host == NULL)
log_fatal("Impossible condition at %s:%d.", MDL);
scope = &global_scope;
/* Copy the static prefix for logging and finding the group */
memcpy(&reply->fixed_pref, &tmp_pref, sizeof(tmp_pref));
/* Try to find a group for the static prefix */
group = find_group_by_prefix(reply);
} else {
if (reply->lease == NULL)
log_fatal("Impossible condition at %s:%d.", MDL);
scope = &reply->lease->scope;
group = reply->lease->ipv6_pool->ipv6_pond->group;
}
/*
* If client_resources is nonzero, then the reply_process_is_prefixed
* function has executed configuration state into the reply option
* cache. We will use that valid cache to derive configuration for
* whether or not to engage in additional prefixes, and similar.
*/
if (reply->client_resources != 0) {
unsigned limit = 1;
/*
* Does this client have "enough" prefixes already? Default
* to one. Everybody gets one, and one should be enough for
* anybody.
*/
oc = lookup_option(&server_universe, reply->opt_state,
SV_LIMIT_PREFS_PER_IA);
if (oc != NULL) {
if (!evaluate_option_cache(&data, reply->packet,
NULL, NULL,
reply->packet->options,
reply->opt_state,
scope, oc, MDL) ||
(data.len != 4)) {
log_error("reply_process_prefix: unable to "
"evaluate prefs-per-ia value.");
status = ISC_R_FAILURE;
goto cleanup;
}
limit = getULong(data.data);
data_string_forget(&data, MDL);
}
/*
* If we wish to limit the client to a certain number of
* prefixes, then omit the prefix from the reply.
*/
if (reply->client_resources >= limit)
goto cleanup;
}
status = reply_process_is_prefixed(reply, scope, group);
if (status != ISC_R_SUCCESS)
goto cleanup;
send_pref:
status = reply_process_send_prefix(reply, &tmp_pref);
cleanup:
if (iapref.data != NULL)
data_string_forget(&iapref, MDL);
if (data.data != NULL)
data_string_forget(&data, MDL);
if (reply->lease != NULL)
iasubopt_dereference(&reply->lease, MDL);
return status;
}
/*
* Verify the prefix belongs to the client. If we've got a host
* record with fixed prefixes, it has to be an assigned prefix
* (fault out all else). Otherwise it's a dynamic prefix, so lookup
* that prefix and make sure it belongs to this DUID:IAID pair.
*/
static isc_boolean_t
prefix_is_owned(struct reply_state *reply, struct iaddrcidrnet *pref) {
struct iaddrcidrnetlist *l;
int i;
struct ipv6_pond *pond;
/*
* This faults out prefixes that don't match fixed prefixes.
*/
if (reply->static_prefixes > 0) {
for (l = reply->host->fixed_prefix; l != NULL; l = l->next) {
if ((pref->bits == l->cidrnet.bits) &&
(memcmp(pref->lo_addr.iabuf,
l->cidrnet.lo_addr.iabuf, 16) == 0))
return (ISC_TRUE);
}
return (ISC_FALSE);
}
if ((reply->old_ia == NULL) ||
(reply->old_ia->num_iasubopt == 0))
return (ISC_FALSE);
for (i = 0 ; i < reply->old_ia->num_iasubopt ; i++) {
struct iasubopt *tmp;
tmp = reply->old_ia->iasubopt[i];
if ((pref->bits == (int) tmp->plen) &&
(memcmp(pref->lo_addr.iabuf, &tmp->addr, 16) == 0)) {
if (lease6_usable(tmp) == ISC_FALSE) {
return (ISC_FALSE);
}
pond = tmp->ipv6_pool->ipv6_pond;
if (((pond->prohibit_list != NULL) &&
(permitted(reply->packet, pond->prohibit_list))) ||
((pond->permit_list != NULL) &&
(!permitted(reply->packet, pond->permit_list))))
return (ISC_FALSE);
iasubopt_reference(&reply->lease, tmp, MDL);
return (ISC_TRUE);
}
}
return (ISC_FALSE);
}
/*
* This function only returns failure on 'hard' failures. If it succeeds,
* it will leave a prefix structure behind.
*/
static isc_result_t
reply_process_try_prefix(struct reply_state *reply,
struct iaddrcidrnet *pref) {
isc_result_t status = ISC_R_ADDRNOTAVAIL;
struct ipv6_pool *pool = NULL;
struct ipv6_pond *pond = NULL;
int i;
struct data_string data_pref;
if ((reply == NULL) || (reply->shared == NULL) ||
(pref == NULL) || (reply->lease != NULL))
return (DHCP_R_INVALIDARG);
/*
* Do a quick walk through of the ponds and pools
* to see if we have any prefix pools
*/
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
if (pond->ipv6_pools == NULL)
continue;
for (i = 0; (pool = pond->ipv6_pools[i]) != NULL; i++) {
if (pool->pool_type == D6O_IA_PD)
break;
}
if (pool != NULL)
break;
}
/* If we get here and p is NULL we have no useful pools */
if (pool == NULL) {
return (ISC_R_ADDRNOTAVAIL);
}
memset(&data_pref, 0, sizeof(data_pref));
data_pref.len = 17;
if (!buffer_allocate(&data_pref.buffer, data_pref.len, MDL)) {
log_error("reply_process_try_prefix: out of memory.");
return (ISC_R_NOMEMORY);
}
data_pref.data = data_pref.buffer->data;
data_pref.buffer->data[0] = (u_int8_t) pref->bits;
memcpy(data_pref.buffer->data + 1, pref->lo_addr.iabuf, 16);
/*
* We have at least one pool that could provide a prefix
* Now we walk through the ponds and pools again and check
* to see if the client is permitted and if an prefix is
* available
*
*/
for (pond = reply->shared->ipv6_pond; pond != NULL; pond = pond->next) {
if (((pond->prohibit_list != NULL) &&
(permitted(reply->packet, pond->prohibit_list))) ||
((pond->permit_list != NULL) &&
(!permitted(reply->packet, pond->permit_list))))
continue;
for (i = 0; (pool = pond->ipv6_pools[i]) != NULL; i++) {
if (pool->pool_type != D6O_IA_PD) {
continue;
}
status = try_client_v6_prefix(&reply->lease, pool,
&data_pref);
/* If we found it in this pool (either in use or available),
there is no need to look further. */
if ( (status == ISC_R_SUCCESS) || (status == ISC_R_ADDRINUSE) )
break;
}
if ( (status == ISC_R_SUCCESS) || (status == ISC_R_ADDRINUSE) )
break;
}
data_string_forget(&data_pref, MDL);
/* Return just the most recent status... */
return (status);
}
/* Look around for a prefix to give the client. First, look through the old
* IA_PD for prefixes we can extend. Second, try to allocate a new prefix.
* Finally, actually add that prefix into the current reply IA_PD.
*/
static isc_result_t
find_client_prefix(struct reply_state *reply) {
struct iaddrcidrnet send_pref;
isc_result_t status = ISC_R_NORESOURCES;
struct iasubopt *prefix, *best_prefix = NULL;
struct binding_scope **scope;
int i;
struct group *group;
if (reply->static_prefixes > 0) {
struct iaddrcidrnetlist *l;
if (reply->host == NULL)
return DHCP_R_INVALIDARG;
for (l = reply->host->fixed_prefix; l != NULL; l = l->next) {
if (l->cidrnet.bits == reply->preflen)
break;
}
if (l == NULL) {
/*
* If no fixed prefix has the preferred length,
* get the first one.
*/
l = reply->host->fixed_prefix;
}
memcpy(&send_pref, &l->cidrnet, sizeof(send_pref));
scope = &global_scope;
/* Copy the prefix for logging purposes */
memcpy(&reply->fixed_pref, &l->cidrnet, sizeof(send_pref));
/* Try to find a group for the static prefix */
group = find_group_by_prefix(reply);
goto send_pref;
}
if (reply->old_ia != NULL) {
for (i = 0 ; i < reply->old_ia->num_iasubopt ; i++) {
struct shared_network *candidate_shared;
struct ipv6_pond *pond;
prefix = reply->old_ia->iasubopt[i];
candidate_shared = prefix->ipv6_pool->shared_network;
pond = prefix->ipv6_pool->ipv6_pond;
/*
* Consider this prefix if it is in a global pool or
* if it is scoped in a pool under the client's shared
* network.
*/
if (((candidate_shared != NULL) &&
(candidate_shared != reply->shared)) ||
(lease6_usable(prefix) != ISC_TRUE))
continue;
/*
* And check if the prefix is still permitted
*/
if (((pond->prohibit_list != NULL) &&
(permitted(reply->packet, pond->prohibit_list))) ||
((pond->permit_list != NULL) &&
(!permitted(reply->packet, pond->permit_list))))
continue;
best_prefix = prefix_compare(reply, prefix,
best_prefix);
}
/*
* If we have prefix length hint and we're not igoring them,
* then toss the best match if it doesn't match the hint,
* unless this is in response to a rebind. In the latter
* case we're supposed to return it with zero lifetimes.
* (See rt45780) */
if (best_prefix && (reply->preflen > 0)
&& (prefix_length_mode != PLM_IGNORE)
&& (reply->preflen != best_prefix->plen)
&& (reply->packet->dhcpv6_msg_type != DHCPV6_REBIND)) {
best_prefix = NULL;
}
}
/* Try to pick a new prefix if we didn't find one, or if we found an
* abandoned prefix.
*/
if ((best_prefix == NULL) || (best_prefix->state == FTS_ABANDONED)) {
status = pick_v6_prefix(reply);
} else if (best_prefix != NULL) {
iasubopt_reference(&reply->lease, best_prefix, MDL);
status = ISC_R_SUCCESS;
}
/* Pick the abandoned prefix as a last resort. */
if ((status == ISC_R_NORESOURCES) && (best_prefix != NULL)) {
/* I don't see how this is supposed to be done right now. */
log_error("Reclaiming abandoned prefixes is not yet "
"supported. Treating this as an out of space "
"condition.");
/* iasubopt_reference(&reply->lease, best_prefix, MDL); */
}
/* Give up now if we didn't find a prefix. */
if (status != ISC_R_SUCCESS)
return status;
if (reply->lease == NULL)
log_fatal("Impossible condition at %s:%d.", MDL);
scope = &reply->lease->scope;
group = reply->lease->ipv6_pool->ipv6_pond->group;
send_pref.lo_addr.len = 16;
memcpy(send_pref.lo_addr.iabuf, &reply->lease->addr, 16);
send_pref.bits = (int) reply->lease->plen;
send_pref:
status = reply_process_is_prefixed(reply, scope, group);
if (status != ISC_R_SUCCESS)
return status;
status = reply_process_send_prefix(reply, &send_pref);
return status;
}
/* Once a prefix is found for a client, perform several common functions;
* Calculate and store valid and preferred prefix times, draw client options
* into the option state.
*/
static isc_result_t
reply_process_is_prefixed(struct reply_state *reply,
struct binding_scope **scope, struct group *group)
{
isc_result_t status = ISC_R_SUCCESS;
struct data_string data;
struct option_cache *oc;
struct option_state *tmp_options = NULL;
struct on_star *on_star;
int i;
/* Initialize values we will cleanup. */
memset(&data, 0, sizeof(data));
/*
* Find the proper on_star block to use. We use the
* one in the lease if we have a lease or the one in
* the reply if we don't have a lease because this is
* a static instance
*/
if (reply->lease) {
on_star = &reply->lease->on_star;
} else {
on_star = &reply->on_star;
}
/*
* Bring in the root configuration. We only do this to bring
* in the on * statements, as we didn't have the lease available
* we we did it the first time.
*/
option_state_allocate(&tmp_options, MDL);
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options, tmp_options,
&global_scope, root_group, NULL,
on_star);
if (tmp_options != NULL) {
option_state_dereference(&tmp_options, MDL);
}
/*
* Bring configured options into the root packet level cache - start
* with the lease's closest enclosing group (passed in by the caller
* as 'group').
*/
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options, reply->opt_state,
scope, group, root_group, on_star);
/* Execute statements from class scopes. */
for (i = reply->packet->class_count; i > 0; i--) {
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state, scope,
reply->packet->classes[i - 1]->group,
group, on_star);
}
/*
* If there is a host record, over-ride with values configured there,
* without re-evaluating configuration from the previously executed
* group or its common enclosers.
*/
if (reply->host != NULL)
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state, scope,
reply->host->group, group,
on_star);
/* Determine valid lifetime. */
if (reply->client_valid == 0)
reply->send_valid = DEFAULT_DEFAULT_LEASE_TIME;
else
reply->send_valid = reply->client_valid;
oc = lookup_option(&server_universe, reply->opt_state,
SV_DEFAULT_LEASE_TIME);
if (oc != NULL) {
if (!evaluate_option_cache(&data, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state,
scope, oc, MDL) ||
(data.len != 4)) {
log_error("reply_process_is_prefixed: unable to "
"evaluate default prefix time");
status = ISC_R_FAILURE;
goto cleanup;
}
reply->send_valid = getULong(data.data);
data_string_forget(&data, MDL);
}
/* Check to see if the lease time would cause us to wrap
* in which case we make it infinite.
* The following doesn't work on at least some systems:
* (cur_time + reply->send_valid < cur_time)
*/
if (reply->send_valid != INFINITE_TIME) {
time_t test_time = cur_time + reply->send_valid;
if (test_time < cur_time)
reply->send_valid = INFINITE_TIME;
}
if (reply->client_prefer == 0)
reply->send_prefer = reply->send_valid;
else
reply->send_prefer = reply->client_prefer;
if ((reply->send_prefer >= reply->send_valid) &&
(reply->send_valid != INFINITE_TIME))
reply->send_prefer = (reply->send_valid / 2) +
(reply->send_valid / 8);
oc = lookup_option(&server_universe, reply->opt_state,
SV_PREFER_LIFETIME);
if (oc != NULL) {
if (!evaluate_option_cache(&data, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state,
scope, oc, MDL) ||
(data.len != 4)) {
log_error("reply_process_is_prefixed: unable to "
"evaluate preferred prefix time");
status = ISC_R_FAILURE;
goto cleanup;
}
reply->send_prefer = getULong(data.data);
data_string_forget(&data, MDL);
}
/* Note lowest values for later calculation of renew/rebind times. */
if (reply->min_prefer > reply->send_prefer)
reply->min_prefer = reply->send_prefer;
if (reply->min_valid > reply->send_valid)
reply->min_valid = reply->send_valid;
/* Perform dynamic prefix related update work. */
if (reply->lease != NULL) {
/* Cached lifetimes */
reply->lease->prefer = reply->send_prefer;
reply->lease->valid = reply->send_valid;
/* Advance (or rewind) the valid lifetime.
* In the protocol 0xFFFFFFFF is infinite
* when connecting to the lease file MAX_TIME is
*/
if (reply->buf.reply.msg_type == DHCPV6_REPLY) {
if (reply->send_valid == INFINITE_TIME) {
reply->lease->soft_lifetime_end_time = MAX_TIME;
} else {
reply->lease->soft_lifetime_end_time =
cur_time + reply->send_valid;
}
/* Wait before renew! */
}
status = ia_add_iasubopt(reply->ia, reply->lease, MDL);
if (status != ISC_R_SUCCESS) {
log_fatal("reply_process_is_prefixed: Unable to "
"attach prefix to new IA_PD: %s",
isc_result_totext(status));
}
/*
* If this is a new prefix, make sure it is attached somewhere.
*/
if (reply->lease->ia == NULL) {
ia_reference(&reply->lease->ia, reply->ia, MDL);
}
}
/* Bring a copy of the relevant options into the IA_PD scope. */
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options, reply->reply_ia,
scope, group, root_group, NULL);
/* Execute statements from class scopes. */
for (i = reply->packet->class_count; i > 0; i--) {
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->reply_ia, scope,
reply->packet->classes[i - 1]->group,
group, NULL);
}
/*
* And bring in host record configuration, if any, but not to overlap
* the previous group or its common enclosers.
*/
if (reply->host != NULL)
execute_statements_in_scope(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->reply_ia, scope,
reply->host->group, group, NULL);
cleanup:
if (data.data != NULL)
data_string_forget(&data, MDL);
if (status == ISC_R_SUCCESS)
reply->client_resources++;
return status;
}
/* Simply send an IAPREFIX within the IA_PD scope as described. */
static isc_result_t
reply_process_send_prefix(struct reply_state *reply,
struct iaddrcidrnet *pref) {
isc_result_t status = ISC_R_SUCCESS;
struct data_string data;
memset(&data, 0, sizeof(data));
/* Now append the prefix. */
data.len = IAPREFIX_OFFSET;
if (!buffer_allocate(&data.buffer, data.len, MDL)) {
log_error("reply_process_send_prefix: out of memory"
"allocating new IAPREFIX buffer.");
status = ISC_R_NOMEMORY;
goto cleanup;
}
data.data = data.buffer->data;
putULong(data.buffer->data, reply->send_prefer);
putULong(data.buffer->data + 4, reply->send_valid);
data.buffer->data[8] = pref->bits;
memcpy(data.buffer->data + 9, pref->lo_addr.iabuf, 16);
if (!append_option_buffer(&dhcpv6_universe, reply->reply_ia,
data.buffer, data.buffer->data,
data.len, D6O_IAPREFIX, 0)) {
log_error("reply_process_send_prefix: unable "
"to save IAPREFIX option");
status = ISC_R_FAILURE;
goto cleanup;
}
reply->resources_included = ISC_TRUE;
cleanup:
if (data.data != NULL)
data_string_forget(&data, MDL);
return status;
}
/* Choose the better of two prefixes. */
static struct iasubopt *
prefix_compare(struct reply_state *reply,
struct iasubopt *alpha, struct iasubopt *beta) {
if (alpha == NULL)
return beta;
if (beta == NULL)
return alpha;
if (reply->preflen >= 0) {
if ((alpha->plen == reply->preflen) &&
(beta->plen != reply->preflen))
return alpha;
if ((beta->plen == reply->preflen) &&
(alpha->plen != reply->preflen))
return beta;
}
switch(alpha->state) {
case FTS_ACTIVE:
switch(beta->state) {
case FTS_ACTIVE:
/* Choose the prefix with the longest lifetime (most
* likely the most recently allocated).
*/
if (alpha->hard_lifetime_end_time <
beta->hard_lifetime_end_time)
return beta;
else
return alpha;
case FTS_EXPIRED:
case FTS_ABANDONED:
return alpha;
default:
log_fatal("Impossible condition at %s:%d.", MDL);
}
break;
case FTS_EXPIRED:
switch (beta->state) {
case FTS_ACTIVE:
return beta;
case FTS_EXPIRED:
/* Choose the most recently expired prefix. */
if (alpha->hard_lifetime_end_time <
beta->hard_lifetime_end_time)
return beta;
else if ((alpha->hard_lifetime_end_time ==
beta->hard_lifetime_end_time) &&
(alpha->soft_lifetime_end_time <
beta->soft_lifetime_end_time))
return beta;
else
return alpha;
case FTS_ABANDONED:
return alpha;
default:
log_fatal("Impossible condition at %s:%d.", MDL);
}
break;
case FTS_ABANDONED:
switch (beta->state) {
case FTS_ACTIVE:
case FTS_EXPIRED:
return alpha;
case FTS_ABANDONED:
/* Choose the prefix that was abandoned longest ago. */
if (alpha->hard_lifetime_end_time <
beta->hard_lifetime_end_time)
return alpha;
else
return beta;
default:
log_fatal("Impossible condition at %s:%d.", MDL);
}
break;
default:
log_fatal("Impossible condition at %s:%d.", MDL);
}
log_fatal("Triple impossible condition at %s:%d.", MDL);
return NULL;
}
/*
* Solicit is how a client starts requesting addresses.
*
* If the client asks for rapid commit, and we support it, we will
* allocate the addresses and reply.
*
* Otherwise we will send an advertise message.
*/
static void
dhcpv6_solicit(struct data_string *reply_ret, struct packet *packet) {
struct data_string client_id;
/*
* Validate our input.
*/
if (!valid_client_msg(packet, &client_id)) {
return;
}
lease_to_client(reply_ret, packet, &client_id, NULL);
/*
* Clean up.
*/
data_string_forget(&client_id, MDL);
}
/*
* Request is how a client actually requests addresses.
*
* Very similar to Solicit handling, except the server DUID is required.
*/
static void
dhcpv6_request(struct data_string *reply_ret, struct packet *packet) {
struct data_string client_id;
struct data_string server_id;
/*
* Validate our input.
*/
if (!valid_client_resp(packet, &client_id, &server_id)) {
return;
}
/* If the REQUEST arrived via unicast and unicast option isn't set,
* reject it per RFC 3315, Sec 18.2.1 */
if (packet->unicast == ISC_TRUE &&
is_unicast_option_defined(packet) == ISC_FALSE) {
unicast_reject(reply_ret, packet, &client_id, &server_id);
} else {
/*
* Issue our lease.
*/
lease_to_client(reply_ret, packet, &client_id, &server_id);
}
/*
* Cleanup.
*/
data_string_forget(&client_id, MDL);
data_string_forget(&server_id, MDL);
}
/* Find a DHCPv6 packet's shared network from hints in the packet.
*/
static isc_result_t
shared_network_from_packet6(struct shared_network **shared,
struct packet *packet)
{
const struct packet *chk_packet;
const struct in6_addr *link_addr, *first_link_addr;
struct iaddr tmp_addr;
struct subnet *subnet;
isc_result_t status;
if ((shared == NULL) || (*shared != NULL) || (packet == NULL))
return DHCP_R_INVALIDARG;
/*
* First, find the link address where the packet from the client
* first appeared (if this packet was relayed).
*/
first_link_addr = NULL;
chk_packet = packet->dhcpv6_container_packet;
while (chk_packet != NULL) {
link_addr = &chk_packet->dhcpv6_link_address;
if (!IN6_IS_ADDR_UNSPECIFIED(link_addr) &&
!IN6_IS_ADDR_LINKLOCAL(link_addr)) {
first_link_addr = link_addr;
break;
}
chk_packet = chk_packet->dhcpv6_container_packet;
}
/*
* If there is a relayed link address, find the subnet associated
* with that, and use that to get the appropriate
* shared_network.
*/
if (first_link_addr != NULL) {
tmp_addr.len = sizeof(*first_link_addr);
memcpy(tmp_addr.iabuf,
first_link_addr, sizeof(*first_link_addr));
subnet = NULL;
if (!find_subnet(&subnet, tmp_addr, MDL)) {
log_debug("No subnet found for link-address %s.",
piaddr(tmp_addr));
return ISC_R_NOTFOUND;
}
status = shared_network_reference(shared,
subnet->shared_network, MDL);
subnet_dereference(&subnet, MDL);
/*
* If there is no link address, we will use the interface
* that this packet came in on to pick the shared_network.
*/
} else if (packet->interface != NULL) {
status = shared_network_reference(shared,
packet->interface->shared_network,
MDL);
if (packet->dhcpv6_container_packet != NULL) {
log_info("[L2 Relay] No link address in relay packet "
"assuming L2 relay and using receiving "
"interface");
}
} else {
/*
* We shouldn't be able to get here but if there is no link
* address and no interface we don't know where to get the
* pool from log an error and return an error.
*/
log_error("No interface and no link address "
"can't determine pool");
status = DHCP_R_INVALIDARG;
}
return status;
}
/*
* When a client thinks it might be on a new link, it sends a
* Confirm message.
*
* From RFC3315 section 18.2.2:
*
* When the server receives a Confirm message, the server determines
* whether the addresses in the Confirm message are appropriate for the
* link to which the client is attached. If all of the addresses in the
* Confirm message pass this test, the server returns a status of
* Success. If any of the addresses do not pass this test, the server
* returns a status of NotOnLink. If the server is unable to perform
* this test (for example, the server does not have information about
* prefixes on the link to which the client is connected), or there were
* no addresses in any of the IAs sent by the client, the server MUST
* NOT send a reply to the client.
*/
static void
dhcpv6_confirm(struct data_string *reply_ret, struct packet *packet) {
struct shared_network *shared;
struct subnet *subnet;
struct option_cache *ia, *ta, *oc;
struct data_string cli_enc_opt_data, iaaddr, client_id, packet_oro;
struct option_state *cli_enc_opt_state, *opt_state;
struct iaddr cli_addr;
int pass;
isc_boolean_t inappropriate, has_addrs;
char reply_data[65536];
struct dhcpv6_packet *reply = (struct dhcpv6_packet *)reply_data;
int reply_ofs = (int)(offsetof(struct dhcpv6_packet, options));
/*
* Basic client message validation.
*/
memset(&client_id, 0, sizeof(client_id));
if (!valid_client_msg(packet, &client_id)) {
return;
}
/*
* Do not process Confirms that do not have IA's we do not recognize.
*/
ia = lookup_option(&dhcpv6_universe, packet->options, D6O_IA_NA);
ta = lookup_option(&dhcpv6_universe, packet->options, D6O_IA_TA);
if ((ia == NULL) && (ta == NULL))
return;
/*
* IA_PD's are simply ignored.
*/
delete_option(&dhcpv6_universe, packet->options, D6O_IA_PD);
/*
* Bit of variable initialization.
*/
opt_state = cli_enc_opt_state = NULL;
memset(&cli_enc_opt_data, 0, sizeof(cli_enc_opt_data));
memset(&iaaddr, 0, sizeof(iaaddr));
memset(&packet_oro, 0, sizeof(packet_oro));
/* Determine what shared network the client is connected to. We
* must not respond if we don't have any information about the
* network the client is on.
*/
shared = NULL;
if ((shared_network_from_packet6(&shared, packet) != ISC_R_SUCCESS) ||
(shared == NULL))
goto exit;
/* If there are no recorded subnets, then we have no
* information about this subnet - ignore Confirms.
*/
subnet = shared->subnets;
if (subnet == NULL)
goto exit;
/* Are the addresses in all the IA's appropriate for that link? */
has_addrs = inappropriate = ISC_FALSE;
pass = D6O_IA_NA;
while(!inappropriate) {
/* If we've reached the end of the IA_NA pass, move to the
* IA_TA pass.
*/
if ((pass == D6O_IA_NA) && (ia == NULL)) {
pass = D6O_IA_TA;
ia = ta;
}
/* If we've reached the end of all passes, we're done. */
if (ia == NULL)
break;
if (((pass == D6O_IA_NA) &&
!get_encapsulated_IA_state(&cli_enc_opt_state,
&cli_enc_opt_data,
packet, ia, IA_NA_OFFSET)) ||
((pass == D6O_IA_TA) &&
!get_encapsulated_IA_state(&cli_enc_opt_state,
&cli_enc_opt_data,
packet, ia, IA_TA_OFFSET))) {
goto exit;
}
oc = lookup_option(&dhcpv6_universe, cli_enc_opt_state,
D6O_IAADDR);
for ( ; oc != NULL ; oc = oc->next) {
if (!evaluate_option_cache(&iaaddr, packet, NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL) ||
(iaaddr.len < IAADDR_OFFSET)) {
log_error("dhcpv6_confirm: "
"error evaluating IAADDR.");
goto exit;
}
/* Copy out the IPv6 address for processing. */
cli_addr.len = 16;
memcpy(cli_addr.iabuf, iaaddr.data, 16);
data_string_forget(&iaaddr, MDL);
/* Record that we've processed at least one address. */
has_addrs = ISC_TRUE;
/* Find out if any subnets cover this address. */
for (subnet = shared->subnets ; subnet != NULL ;
subnet = subnet->next_sibling) {
if (addr_eq(subnet_number(cli_addr,
subnet->netmask),
subnet->net))
break;
}
/* If we reach the end of the subnet list, and no
* subnet matches the client address, then it must
* be inappropriate to the link (so far as our
* configuration says). Once we've found one
* inappropriate address, there is no reason to
* continue searching.
*/
if (subnet == NULL) {
inappropriate = ISC_TRUE;
break;
}
}
option_state_dereference(&cli_enc_opt_state, MDL);
data_string_forget(&cli_enc_opt_data, MDL);
/* Advance to the next IA_*. */
ia = ia->next;
}
/* If the client supplied no addresses, do not reply. */
if (!has_addrs)
goto exit;
/*
* Set up reply.
*/
if (!start_reply(packet, &client_id, NULL, &opt_state, reply)) {
goto exit;
}
/*
* Set our status.
*/
if (inappropriate) {
if (!set_status_code(STATUS_NotOnLink,
"Some of the addresses are not on link.",
opt_state)) {
goto exit;
}
} else {
if (!set_status_code(STATUS_Success,
"All addresses still on link.",
opt_state)) {
goto exit;
}
}
/*
* Only one option: add it.
*/
reply_ofs += store_options6(reply_data+reply_ofs,
sizeof(reply_data)-reply_ofs,
opt_state, packet,
required_opts, &packet_oro);
/*
* Return our reply to the caller.
*/
reply_ret->len = reply_ofs;
reply_ret->buffer = NULL;
if (!buffer_allocate(&reply_ret->buffer, reply_ofs, MDL)) {
log_fatal("No memory to store reply.");
}
reply_ret->data = reply_ret->buffer->data;
memcpy(reply_ret->buffer->data, reply, reply_ofs);
exit:
/* Cleanup any stale data strings. */
if (cli_enc_opt_data.buffer != NULL)
data_string_forget(&cli_enc_opt_data, MDL);
if (iaaddr.buffer != NULL)
data_string_forget(&iaaddr, MDL);
if (client_id.buffer != NULL)
data_string_forget(&client_id, MDL);
if (packet_oro.buffer != NULL)
data_string_forget(&packet_oro, MDL);
/* Release any stale option states. */
if (cli_enc_opt_state != NULL)
option_state_dereference(&cli_enc_opt_state, MDL);
if (opt_state != NULL)
option_state_dereference(&opt_state, MDL);
}
/*
* Renew is when a client wants to extend its lease/prefix, at time T1.
*
* We handle this the same as if the client wants a new lease/prefix,
* except for the error code of when addresses don't match.
*/
static void
dhcpv6_renew(struct data_string *reply, struct packet *packet) {
struct data_string client_id;
struct data_string server_id;
/*
* Validate the request.
*/
if (!valid_client_resp(packet, &client_id, &server_id)) {
return;
}
/* If the RENEW arrived via unicast and unicast option isn't set,
* reject it per RFC 3315, Sec 18.2.3 */
if (packet->unicast == ISC_TRUE &&
is_unicast_option_defined(packet) == ISC_FALSE) {
unicast_reject(reply, packet, &client_id, &server_id);
} else {
/*
* Renew our lease.
*/
lease_to_client(reply, packet, &client_id, &server_id);
}
/*
* Cleanup.
*/
data_string_forget(&server_id, MDL);
data_string_forget(&client_id, MDL);
}
/*
* Rebind is when a client wants to extend its lease, at time T2.
*
* We handle this the same as if the client wants a new lease, except
* for the error code of when addresses don't match.
*/
static void
dhcpv6_rebind(struct data_string *reply, struct packet *packet) {
struct data_string client_id;
if (!valid_client_msg(packet, &client_id)) {
return;
}
lease_to_client(reply, packet, &client_id, NULL);
data_string_forget(&client_id, MDL);
}
static void
ia_na_match_decline(const struct data_string *client_id,
const struct data_string *iaaddr,
struct iasubopt *lease)
{
char tmp_addr[INET6_ADDRSTRLEN];
log_error("Client %s reports address %s is "
"already in use by another host!",
print_hex_1(client_id->len, client_id->data, 60),
inet_ntop(AF_INET6, iaaddr->data,
tmp_addr, sizeof(tmp_addr)));
if (lease != NULL) {
decline_lease6(lease->ipv6_pool, lease);
lease->ia->cltt = cur_time;
write_ia(lease->ia);
}
}
static void
ia_na_nomatch_decline(const struct data_string *client_id,
const struct data_string *iaaddr,
u_int32_t *ia_na_id,
struct packet *packet,
char *reply_data,
int *reply_ofs,
int reply_len)
{
char tmp_addr[INET6_ADDRSTRLEN];
struct option_state *host_opt_state;
int len;
log_info("Client %s declines address %s, which is not offered to it.",
print_hex_1(client_id->len, client_id->data, 60),
inet_ntop(AF_INET6, iaaddr->data, tmp_addr, sizeof(tmp_addr)));
/*
* Create state for this IA_NA.
*/
host_opt_state = NULL;
if (!option_state_allocate(&host_opt_state, MDL)) {
log_error("ia_na_nomatch_decline: out of memory "
"allocating option_state.");
goto exit;
}
if (!set_status_code(STATUS_NoBinding, "Decline for unknown address.",
host_opt_state)) {
goto exit;
}
/*
* Insure we have enough space
*/
if (reply_len < (*reply_ofs + 16)) {
log_error("ia_na_nomatch_decline: "
"out of space for reply packet.");
goto exit;
}
/*
* Put our status code into the reply packet.
*/
len = store_options6(reply_data+(*reply_ofs)+16,
reply_len-(*reply_ofs)-16,
host_opt_state, packet,
required_opts_STATUS_CODE, NULL);
/*
* Store the non-encapsulated option data for this
* IA_NA into our reply packet. Defined in RFC 3315,
* section 22.4.
*/
/* option number */
putUShort((unsigned char *)reply_data+(*reply_ofs), D6O_IA_NA);
/* option length */
putUShort((unsigned char *)reply_data+(*reply_ofs)+2, len + 12);
/* IA_NA, copied from the client */
memcpy(reply_data+(*reply_ofs)+4, ia_na_id, 4);
/* t1 and t2, odd that we need them, but here it is */
putULong((unsigned char *)reply_data+(*reply_ofs)+8, 0);
putULong((unsigned char *)reply_data+(*reply_ofs)+12, 0);
/*
* Get ready for next IA_NA.
*/
*reply_ofs += (len + 16);
exit:
option_state_dereference(&host_opt_state, MDL);
}
static void
iterate_over_ia_na(struct data_string *reply_ret,
struct packet *packet,
const struct data_string *client_id,
const struct data_string *server_id,
const char *packet_type,
void (*ia_na_match)(const struct data_string *,
const struct data_string *,
struct iasubopt *),
void (*ia_na_nomatch)(const struct data_string *,
const struct data_string *,
u_int32_t *, struct packet *, char *,
int *, int))
{
struct option_state *opt_state;
struct host_decl *packet_host;
struct option_cache *ia;
struct option_cache *oc;
/* cli_enc_... variables come from the IA_NA/IA_TA options */
struct data_string cli_enc_opt_data;
struct option_state *cli_enc_opt_state;
struct host_decl *host;
struct data_string iaaddr;
struct data_string fixed_addr;
char reply_data[65536];
struct dhcpv6_packet *reply = (struct dhcpv6_packet *)reply_data;
int reply_ofs = (int)(offsetof(struct dhcpv6_packet, options));
char status_msg[32];
struct iasubopt *lease;
struct ia_xx *existing_ia_na;
int i;
struct data_string key;
u_int32_t iaid;
/*
* Initialize to empty values, in case we have to exit early.
*/
opt_state = NULL;
memset(&cli_enc_opt_data, 0, sizeof(cli_enc_opt_data));
cli_enc_opt_state = NULL;
memset(&iaaddr, 0, sizeof(iaaddr));
memset(&fixed_addr, 0, sizeof(fixed_addr));
lease = NULL;
/*
* Find the host record that matches from the packet, if any.
*/
packet_host = NULL;
find_hosts6(&packet_host, packet, client_id, MDL);
/*
* Set our reply information.
*/
reply->msg_type = DHCPV6_REPLY;
memcpy(reply->transaction_id, packet->dhcpv6_transaction_id,
sizeof(reply->transaction_id));
/*
* Build our option state for reply.
*/
opt_state = NULL;
if (!option_state_allocate(&opt_state, MDL)) {
log_error("iterate_over_ia_na: no memory for option_state.");
goto exit;
}
execute_statements_in_scope(NULL, packet, NULL, NULL,
packet->options, opt_state,
&global_scope, root_group, NULL, NULL);
/*
* RFC 3315, section 18.2.7 tells us which options to include.
*/
oc = lookup_option(&dhcpv6_universe, opt_state, D6O_SERVERID);
if (oc == NULL) {
if (!save_option_buffer(&dhcpv6_universe, opt_state, NULL,
(unsigned char *)server_duid.data,
server_duid.len, D6O_SERVERID, 0)) {
log_error("iterate_over_ia_na: "
"error saving server identifier.");
goto exit;
}
}
if (!save_option_buffer(&dhcpv6_universe, opt_state,
client_id->buffer,
(unsigned char *)client_id->data,
client_id->len,
D6O_CLIENTID, 0)) {
log_error("iterate_over_ia_na: "
"error saving client identifier.");
goto exit;
}
snprintf(status_msg, sizeof(status_msg), "%s received.", packet_type);
if (!set_status_code(STATUS_Success, status_msg, opt_state)) {
goto exit;
}
/*
* Add our options that are not associated with any IA_NA or IA_TA.
*/
reply_ofs += store_options6(reply_data+reply_ofs,
sizeof(reply_data)-reply_ofs,
opt_state, packet,
required_opts, NULL);
/*
* Loop through the IA_NA reported by the client, and deal with
* addresses reported as already in use.
*/
for (ia = lookup_option(&dhcpv6_universe, packet->options, D6O_IA_NA);
ia != NULL; ia = ia->next) {
if (!get_encapsulated_IA_state(&cli_enc_opt_state,
&cli_enc_opt_data,
packet, ia, IA_NA_OFFSET)) {
goto exit;
}
iaid = getULong(cli_enc_opt_data.data);
/*
* XXX: It is possible that we can get multiple addresses
* sent by the client. We don't send multiple
* addresses, so this indicates a client error.
* We should check for multiple IAADDR options, log
* if found, and set as an error.
*/
oc = lookup_option(&dhcpv6_universe, cli_enc_opt_state,
D6O_IAADDR);
if (oc == NULL) {
/* no address given for this IA, ignore */
option_state_dereference(&cli_enc_opt_state, MDL);
data_string_forget(&cli_enc_opt_data, MDL);
continue;
}
memset(&iaaddr, 0, sizeof(iaaddr));
if (!evaluate_option_cache(&iaaddr, packet, NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("iterate_over_ia_na: "
"error evaluating IAADDR.");
goto exit;
}
/*
* Now we need to figure out which host record matches
* this IA_NA and IAADDR (encapsulated option contents
* matching a host record by option).
*
* XXX: We don't currently track IA_NA separately, but
* we will need to do this!
*/
host = NULL;
if (!find_hosts_by_option(&host, packet,
cli_enc_opt_state, MDL)) {
if (packet_host != NULL) {
host = packet_host;
} else {
host = NULL;
}
}
while (host != NULL) {
if (host->fixed_addr != NULL) {
if (!evaluate_option_cache(&fixed_addr, NULL,
NULL, NULL, NULL,
NULL, &global_scope,
host->fixed_addr,
MDL)) {
log_error("iterate_over_ia_na: error "
"evaluating host address.");
goto exit;
}
if ((iaaddr.len >= 16) &&
!memcmp(fixed_addr.data, iaaddr.data, 16)) {
data_string_forget(&fixed_addr, MDL);
break;
}
data_string_forget(&fixed_addr, MDL);
}
host = host->n_ipaddr;
}
if ((host == NULL) && (iaaddr.len >= IAADDR_OFFSET)) {
/*
* Find existing IA_NA.
*/
if (ia_make_key(&key, iaid,
(char *)client_id->data,
client_id->len,
MDL) != ISC_R_SUCCESS) {
log_fatal("iterate_over_ia_na: no memory for "
"key.");
}
existing_ia_na = NULL;
if (ia_hash_lookup(&existing_ia_na, ia_na_active,
(unsigned char *)key.data,
key.len, MDL)) {
/*
* Make sure this address is in the IA_NA.
*/
for (i=0; i<existing_ia_na->num_iasubopt; i++) {
struct iasubopt *tmp;
struct in6_addr *in6_addr;
tmp = existing_ia_na->iasubopt[i];
in6_addr = &tmp->addr;
if (memcmp(in6_addr,
iaaddr.data, 16) == 0) {
iasubopt_reference(&lease,
tmp, MDL);
break;
}
}
}
data_string_forget(&key, MDL);
}
if ((host != NULL) || (lease != NULL)) {
ia_na_match(client_id, &iaaddr, lease);
} else {
ia_na_nomatch(client_id, &iaaddr,
(u_int32_t *)cli_enc_opt_data.data,
packet, reply_data, &reply_ofs,
sizeof(reply_data));
}
if (lease != NULL) {
iasubopt_dereference(&lease, MDL);
}
data_string_forget(&iaaddr, MDL);
option_state_dereference(&cli_enc_opt_state, MDL);
data_string_forget(&cli_enc_opt_data, MDL);
}
/*
* Return our reply to the caller.
*/
reply_ret->len = reply_ofs;
reply_ret->buffer = NULL;
if (!buffer_allocate(&reply_ret->buffer, reply_ofs, MDL)) {
log_fatal("No memory to store reply.");
}
reply_ret->data = reply_ret->buffer->data;
memcpy(reply_ret->buffer->data, reply, reply_ofs);
exit:
if (lease != NULL) {
iasubopt_dereference(&lease, MDL);
}
if (fixed_addr.buffer != NULL) {
data_string_forget(&fixed_addr, MDL);
}
if (iaaddr.buffer != NULL) {
data_string_forget(&iaaddr, MDL);
}
if (cli_enc_opt_state != NULL) {
option_state_dereference(&cli_enc_opt_state, MDL);
}
if (cli_enc_opt_data.buffer != NULL) {
data_string_forget(&cli_enc_opt_data, MDL);
}
if (opt_state != NULL) {
option_state_dereference(&opt_state, MDL);
}
}
/*
* Decline means a client has detected that something else is using an
* address we gave it.
*
* Since we're only dealing with fixed leases for now, there's not
* much we can do, other that log the occurrence.
*
* When we start issuing addresses from pools, then we will have to
* record our declined addresses and issue another. In general with
* IPv6 there is no worry about DoS by clients exhausting space, but
* we still need to be aware of this possibility.
*/
/* TODO: IA_TA */
static void
dhcpv6_decline(struct data_string *reply, struct packet *packet) {
struct data_string client_id;
struct data_string server_id;
/*
* Validate our input.
*/
if (!valid_client_resp(packet, &client_id, &server_id)) {
return;
}
/* If the DECLINE arrived via unicast and unicast option isn't set,
* reject it per RFC 3315, Sec 18.2.7 */
if (packet->unicast == ISC_TRUE &&
is_unicast_option_defined(packet) == ISC_FALSE) {
unicast_reject(reply, packet, &client_id, &server_id);
} else {
/*
* Undefined for IA_PD.
*/
delete_option(&dhcpv6_universe, packet->options, D6O_IA_PD);
/*
* And operate on each IA_NA in this packet.
*/
iterate_over_ia_na(reply, packet, &client_id, &server_id,
"Decline", ia_na_match_decline,
ia_na_nomatch_decline);
}
data_string_forget(&server_id, MDL);
data_string_forget(&client_id, MDL);
}
static void
ia_na_match_release(const struct data_string *client_id,
const struct data_string *iaaddr,
struct iasubopt *lease)
{
char tmp_addr[INET6_ADDRSTRLEN];
log_info("Client %s releases address %s",
print_hex_1(client_id->len, client_id->data, 60),
inet_ntop(AF_INET6, iaaddr->data, tmp_addr, sizeof(tmp_addr)));
if (lease != NULL) {
release_lease6(lease->ipv6_pool, lease);
lease->ia->cltt = cur_time;
write_ia(lease->ia);
}
}
static void
ia_na_nomatch_release(const struct data_string *client_id,
const struct data_string *iaaddr,
u_int32_t *ia_na_id,
struct packet *packet,
char *reply_data,
int *reply_ofs,
int reply_len)
{
char tmp_addr[INET6_ADDRSTRLEN];
struct option_state *host_opt_state;
int len;
log_info("Client %s releases address %s, which is not leased to it.",
print_hex_1(client_id->len, client_id->data, 60),
inet_ntop(AF_INET6, iaaddr->data, tmp_addr, sizeof(tmp_addr)));
/*
* Create state for this IA_NA.
*/
host_opt_state = NULL;
if (!option_state_allocate(&host_opt_state, MDL)) {
log_error("ia_na_nomatch_release: out of memory "
"allocating option_state.");
goto exit;
}
if (!set_status_code(STATUS_NoBinding,
"Release for non-leased address.",
host_opt_state)) {
goto exit;
}
/*
* Insure we have enough space
*/
if (reply_len < (*reply_ofs + 16)) {
log_error("ia_na_nomatch_release: "
"out of space for reply packet.");
goto exit;
}
/*
* Put our status code into the reply packet.
*/
len = store_options6(reply_data+(*reply_ofs)+16,
reply_len-(*reply_ofs)-16,
host_opt_state, packet,
required_opts_STATUS_CODE, NULL);
/*
* Store the non-encapsulated option data for this
* IA_NA into our reply packet. Defined in RFC 3315,
* section 22.4.
*/
/* option number */
putUShort((unsigned char *)reply_data+(*reply_ofs), D6O_IA_NA);
/* option length */
putUShort((unsigned char *)reply_data+(*reply_ofs)+2, len + 12);
/* IA_NA, copied from the client */
memcpy(reply_data+(*reply_ofs)+4, ia_na_id, 4);
/* t1 and t2, odd that we need them, but here it is */
putULong((unsigned char *)reply_data+(*reply_ofs)+8, 0);
putULong((unsigned char *)reply_data+(*reply_ofs)+12, 0);
/*
* Get ready for next IA_NA.
*/
*reply_ofs += (len + 16);
exit:
option_state_dereference(&host_opt_state, MDL);
}
static void
ia_pd_match_release(const struct data_string *client_id,
const struct data_string *iapref,
struct iasubopt *prefix)
{
char tmp_addr[INET6_ADDRSTRLEN];
log_info("Client %s releases prefix %s/%u",
print_hex_1(client_id->len, client_id->data, 60),
inet_ntop(AF_INET6, iapref->data + 9,
tmp_addr, sizeof(tmp_addr)),
(unsigned) getUChar(iapref->data + 8));
if (prefix != NULL) {
release_lease6(prefix->ipv6_pool, prefix);
prefix->ia->cltt = cur_time;
write_ia(prefix->ia);
}
}
static void
ia_pd_nomatch_release(const struct data_string *client_id,
const struct data_string *iapref,
u_int32_t *ia_pd_id,
struct packet *packet,
char *reply_data,
int *reply_ofs,
int reply_len)
{
char tmp_addr[INET6_ADDRSTRLEN];
struct option_state *host_opt_state;
int len;
log_info("Client %s releases prefix %s/%u, which is not leased to it.",
print_hex_1(client_id->len, client_id->data, 60),
inet_ntop(AF_INET6, iapref->data + 9,
tmp_addr, sizeof(tmp_addr)),
(unsigned) getUChar(iapref->data + 8));
/*
* Create state for this IA_PD.
*/
host_opt_state = NULL;
if (!option_state_allocate(&host_opt_state, MDL)) {
log_error("ia_pd_nomatch_release: out of memory "
"allocating option_state.");
goto exit;
}
if (!set_status_code(STATUS_NoBinding,
"Release for non-leased prefix.",
host_opt_state)) {
goto exit;
}
/*
* Insure we have enough space
*/
if (reply_len < (*reply_ofs + 16)) {
log_error("ia_pd_nomatch_release: "
"out of space for reply packet.");
goto exit;
}
/*
* Put our status code into the reply packet.
*/
len = store_options6(reply_data+(*reply_ofs)+16,
reply_len-(*reply_ofs)-16,
host_opt_state, packet,
required_opts_STATUS_CODE, NULL);
/*
* Store the non-encapsulated option data for this
* IA_PD into our reply packet. Defined in RFC 3315,
* section 22.4.
*/
/* option number */
putUShort((unsigned char *)reply_data+(*reply_ofs), D6O_IA_PD);
/* option length */
putUShort((unsigned char *)reply_data+(*reply_ofs)+2, len + 12);
/* IA_PD, copied from the client */
memcpy(reply_data+(*reply_ofs)+4, ia_pd_id, 4);
/* t1 and t2, odd that we need them, but here it is */
putULong((unsigned char *)reply_data+(*reply_ofs)+8, 0);
putULong((unsigned char *)reply_data+(*reply_ofs)+12, 0);
/*
* Get ready for next IA_PD.
*/
*reply_ofs += (len + 16);
exit:
option_state_dereference(&host_opt_state, MDL);
}
static void
iterate_over_ia_pd(struct data_string *reply_ret,
struct packet *packet,
const struct data_string *client_id,
const struct data_string *server_id,
const char *packet_type,
void (*ia_pd_match)(const struct data_string *,
const struct data_string *,
struct iasubopt *),
void (*ia_pd_nomatch)(const struct data_string *,
const struct data_string *,
u_int32_t *, struct packet *, char *,
int *, int))
{
struct data_string reply_new;
int reply_len;
struct option_state *opt_state;
struct host_decl *packet_host;
struct option_cache *ia;
struct option_cache *oc;
/* cli_enc_... variables come from the IA_PD options */
struct data_string cli_enc_opt_data;
struct option_state *cli_enc_opt_state;
struct host_decl *host;
struct data_string iaprefix;
char reply_data[65536];
int reply_ofs;
struct iasubopt *prefix;
struct ia_xx *existing_ia_pd;
int i;
struct data_string key;
u_int32_t iaid;
/*
* Initialize to empty values, in case we have to exit early.
*/
memset(&reply_new, 0, sizeof(reply_new));
opt_state = NULL;
memset(&cli_enc_opt_data, 0, sizeof(cli_enc_opt_data));
cli_enc_opt_state = NULL;
memset(&iaprefix, 0, sizeof(iaprefix));
prefix = NULL;
/*
* Compute the available length for the reply.
*/
reply_len = sizeof(reply_data) - reply_ret->len;
reply_ofs = 0;
/*
* Find the host record that matches from the packet, if any.
*/
packet_host = NULL;
find_hosts6(&packet_host, packet, client_id, MDL);
/*
* Build our option state for reply.
*/
opt_state = NULL;
if (!option_state_allocate(&opt_state, MDL)) {
log_error("iterate_over_ia_pd: no memory for option_state.");
goto exit;
}
execute_statements_in_scope(NULL, packet, NULL, NULL,
packet->options, opt_state,
&global_scope, root_group, NULL, NULL);
/*
* Loop through the IA_PD reported by the client, and deal with
* prefixes reported as already in use.
*/
for (ia = lookup_option(&dhcpv6_universe, packet->options, D6O_IA_PD);
ia != NULL; ia = ia->next) {
if (!get_encapsulated_IA_state(&cli_enc_opt_state,
&cli_enc_opt_data,
packet, ia, IA_PD_OFFSET)) {
goto exit;
}
iaid = getULong(cli_enc_opt_data.data);
oc = lookup_option(&dhcpv6_universe, cli_enc_opt_state,
D6O_IAPREFIX);
if (oc == NULL) {
/* no prefix given for this IA_PD, ignore */
option_state_dereference(&cli_enc_opt_state, MDL);
data_string_forget(&cli_enc_opt_data, MDL);
continue;
}
for (; oc != NULL; oc = oc->next) {
memset(&iaprefix, 0, sizeof(iaprefix));
if (!evaluate_option_cache(&iaprefix, packet, NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("iterate_over_ia_pd: "
"error evaluating IAPREFIX.");
goto exit;
}
/*
* Now we need to figure out which host record matches
* this IA_PD and IAPREFIX (encapsulated option contents
* matching a host record by option).
*
* XXX: We don't currently track IA_PD separately, but
* we will need to do this!
*/
host = NULL;
if (!find_hosts_by_option(&host, packet,
cli_enc_opt_state, MDL)) {
if (packet_host != NULL) {
host = packet_host;
} else {
host = NULL;
}
}
while (host != NULL) {
if (host->fixed_prefix != NULL) {
struct iaddrcidrnetlist *l;
int plen = (int) getUChar(iaprefix.data + 8);
for (l = host->fixed_prefix; l != NULL;
l = l->next) {
if (plen != l->cidrnet.bits)
continue;
if (memcmp(iaprefix.data + 9,
l->cidrnet.lo_addr.iabuf,
16) == 0)
break;
}
if ((l != NULL) && (iaprefix.len >= 17))
break;
}
host = host->n_ipaddr;
}
if ((host == NULL) && (iaprefix.len >= IAPREFIX_OFFSET)) {
/*
* Find existing IA_PD.
*/
if (ia_make_key(&key, iaid,
(char *)client_id->data,
client_id->len,
MDL) != ISC_R_SUCCESS) {
log_fatal("iterate_over_ia_pd: no memory for "
"key.");
}
existing_ia_pd = NULL;
if (ia_hash_lookup(&existing_ia_pd, ia_pd_active,
(unsigned char *)key.data,
key.len, MDL)) {
/*
* Make sure this prefix is in the IA_PD.
*/
for (i = 0;
i < existing_ia_pd->num_iasubopt;
i++) {
struct iasubopt *tmp;
u_int8_t plen;
plen = getUChar(iaprefix.data + 8);
tmp = existing_ia_pd->iasubopt[i];
if ((tmp->plen == plen) &&
(memcmp(&tmp->addr,
iaprefix.data + 9,
16) == 0)) {
iasubopt_reference(&prefix,
tmp, MDL);
break;
}
}
}
data_string_forget(&key, MDL);
}
if ((host != NULL) || (prefix != NULL)) {
ia_pd_match(client_id, &iaprefix, prefix);
} else {
ia_pd_nomatch(client_id, &iaprefix,
(u_int32_t *)cli_enc_opt_data.data,
packet, reply_data, &reply_ofs,
reply_len - reply_ofs);
}
if (prefix != NULL) {
iasubopt_dereference(&prefix, MDL);
}
data_string_forget(&iaprefix, MDL);
}
option_state_dereference(&cli_enc_opt_state, MDL);
data_string_forget(&cli_enc_opt_data, MDL);
}
/*
* Return our reply to the caller.
* The IA_NA routine has already filled at least the header.
*/
reply_new.len = reply_ret->len + reply_ofs;
if (!buffer_allocate(&reply_new.buffer, reply_new.len, MDL)) {
log_fatal("No memory to store reply.");
}
reply_new.data = reply_new.buffer->data;
memcpy(reply_new.buffer->data,
reply_ret->buffer->data, reply_ret->len);
memcpy(reply_new.buffer->data + reply_ret->len,
reply_data, reply_ofs);
data_string_forget(reply_ret, MDL);
data_string_copy(reply_ret, &reply_new, MDL);
data_string_forget(&reply_new, MDL);
exit:
if (prefix != NULL) {
iasubopt_dereference(&prefix, MDL);
}
if (iaprefix.buffer != NULL) {
data_string_forget(&iaprefix, MDL);
}
if (cli_enc_opt_state != NULL) {
option_state_dereference(&cli_enc_opt_state, MDL);
}
if (cli_enc_opt_data.buffer != NULL) {
data_string_forget(&cli_enc_opt_data, MDL);
}
if (opt_state != NULL) {
option_state_dereference(&opt_state, MDL);
}
}
/*
* Release means a client is done with the leases.
*/
static void
dhcpv6_release(struct data_string *reply, struct packet *packet) {
struct data_string client_id;
struct data_string server_id;
/*
* Validate our input.
*/
if (!valid_client_resp(packet, &client_id, &server_id)) {
return;
}
/* If the RELEASE arrived via unicast and unicast option isn't set,
* reject it per RFC 3315, Sec 18.2.6 */
if (packet->unicast == ISC_TRUE &&
is_unicast_option_defined(packet) == ISC_FALSE) {
unicast_reject(reply, packet, &client_id, &server_id);
} else {
/*
* And operate on each IA_NA in this packet.
*/
iterate_over_ia_na(reply, packet, &client_id, &server_id,
"Release", ia_na_match_release,
ia_na_nomatch_release);
/*
* And operate on each IA_PD in this packet.
*/
iterate_over_ia_pd(reply, packet, &client_id, &server_id,
"Release", ia_pd_match_release,
ia_pd_nomatch_release);
}
data_string_forget(&server_id, MDL);
data_string_forget(&client_id, MDL);
}
/*
* Information-Request is used by clients who have obtained an address
* from other means, but want configuration information from the server.
*/
static void
dhcpv6_information_request(struct data_string *reply, struct packet *packet) {
struct data_string client_id;
struct data_string server_id;
/*
* Validate our input.
*/
if (!valid_client_info_req(packet, &server_id)) {
return;
}
/*
* Get our client ID, if there is one.
*/
memset(&client_id, 0, sizeof(client_id));
if (get_client_id(packet, &client_id) != ISC_R_SUCCESS) {
data_string_forget(&client_id, MDL);
}
/*
* Use the lease_to_client() function. This will work fine,
* because the valid_client_info_req() insures that we
* don't have any IA that would cause us to allocate
* resources to the client.
*/
lease_to_client(reply, packet, &client_id,
server_id.data != NULL ? &server_id : NULL);
/*
* Cleanup.
*/
if (client_id.data != NULL) {
data_string_forget(&client_id, MDL);
}
data_string_forget(&server_id, MDL);
}
/*
* The Relay-forw message is sent by relays. It typically contains a
* single option, which encapsulates an entire packet.
*
* We need to build an encapsulated reply.
*/
/* XXX: this is very, very similar to do_packet6(), and should probably
be combined in a clever way */
/* DHCPv6 server side */
static void
dhcpv6_relay_forw(struct data_string *reply_ret, struct packet *packet) {
struct option_cache *oc;
struct data_string enc_opt_data;
struct packet *enc_packet;
unsigned char msg_type;
const struct dhcpv6_packet *msg;
const struct dhcpv6_relay_packet *relay;
struct data_string enc_reply;
char link_addr[sizeof("ffff:ffff:ffff:ffff:ffff:ffff:255.255.255.255")];
char peer_addr[sizeof("ffff:ffff:ffff:ffff:ffff:ffff:255.255.255.255")];
struct data_string a_opt, packet_ero;
struct option_state *opt_state;
static char reply_data[65536];
struct dhcpv6_relay_packet *reply;
int reply_ofs;
/*
* Initialize variables for early exit.
*/
opt_state = NULL;
memset(&a_opt, 0, sizeof(a_opt));
memset(&packet_ero, 0, sizeof(packet_ero));
memset(&enc_reply, 0, sizeof(enc_reply));
memset(&enc_opt_data, 0, sizeof(enc_opt_data));
enc_packet = NULL;
/*
* Get our encapsulated relay message.
*/
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_RELAY_MSG);
if (oc == NULL) {
inet_ntop(AF_INET6, &packet->dhcpv6_link_address,
link_addr, sizeof(link_addr));
inet_ntop(AF_INET6, &packet->dhcpv6_peer_address,
peer_addr, sizeof(peer_addr));
log_info("Relay-forward from %s with link address=%s and "
"peer address=%s missing Relay Message option.",
piaddr(packet->client_addr), link_addr, peer_addr);
goto exit;
}
if (!evaluate_option_cache(&enc_opt_data, NULL, NULL, NULL,
NULL, NULL, &global_scope, oc, MDL)) {
/* should be dhcpv6_relay_forw */
log_error("dhcpv6_forw_relay: error evaluating "
"relayed message.");
goto exit;
}
if (!packet6_len_okay((char *)enc_opt_data.data, enc_opt_data.len)) {
/* should be dhcpv6_relay_forw */
log_error("dhcpv6_forw_relay: encapsulated packet too short.");
goto exit;
}
/*
* Build a packet structure from this encapsulated packet.
*/
enc_packet = NULL;
if (!packet_allocate(&enc_packet, MDL)) {
/* should be dhcpv6_relay_forw */
log_error("dhcpv6_forw_relay: "
"no memory for encapsulated packet.");
goto exit;
}
if (!option_state_allocate(&enc_packet->options, MDL)) {
/* should be dhcpv6_relay_forw */
log_error("dhcpv6_forw_relay: "
"no memory for encapsulated packet's options.");
goto exit;
}
enc_packet->client_port = packet->client_port;
enc_packet->client_addr = packet->client_addr;
interface_reference(&enc_packet->interface, packet->interface, MDL);
enc_packet->dhcpv6_container_packet = packet;
msg_type = enc_opt_data.data[0];
if ((msg_type == DHCPV6_RELAY_FORW) ||
(msg_type == DHCPV6_RELAY_REPL)) {
int relaylen = (int)(offsetof(struct dhcpv6_relay_packet, options));
relay = (struct dhcpv6_relay_packet *)enc_opt_data.data;
enc_packet->dhcpv6_msg_type = relay->msg_type;
/* relay-specific data */
enc_packet->dhcpv6_hop_count = relay->hop_count;
memcpy(&enc_packet->dhcpv6_link_address,
relay->link_address, sizeof(relay->link_address));
memcpy(&enc_packet->dhcpv6_peer_address,
relay->peer_address, sizeof(relay->peer_address));
if (!parse_option_buffer(enc_packet->options,
relay->options,
enc_opt_data.len - relaylen,
&dhcpv6_universe)) {
/* no logging here, as parse_option_buffer() logs all
cases where it fails */
goto exit;
}
} else if ((msg_type == DHCPV6_DHCPV4_QUERY) ||
(msg_type == DHCPV6_DHCPV4_RESPONSE)) {
#ifdef DHCP4o6
if (!dhcpv4_over_dhcpv6 ||
(msg_type == DHCPV6_DHCPV4_RESPONSE)) {
log_error("dhcpv6_relay_forw: "
"unsupported %s message type.",
dhcpv6_type_names[msg_type]);
goto exit;
}
forw_dhcpv4_query(packet);
goto exit;
#else /* DHCP4o6 */
log_error("dhcpv6_relay_forw: unsupported %s message type.",
dhcpv6_type_names[msg_type]);
goto exit;
#endif /* DHCP4o6 */
} else {
int msglen = (int)(offsetof(struct dhcpv6_packet, options));
msg = (struct dhcpv6_packet *)enc_opt_data.data;
enc_packet->dhcpv6_msg_type = msg->msg_type;
/* message-specific data */
memcpy(enc_packet->dhcpv6_transaction_id,
msg->transaction_id,
sizeof(enc_packet->dhcpv6_transaction_id));
if (!parse_option_buffer(enc_packet->options,
msg->options,
enc_opt_data.len - msglen,
&dhcpv6_universe)) {
/* no logging here, as parse_option_buffer() logs all
cases where it fails */
goto exit;
}
}
/*
* This is recursive. It is possible to exceed maximum packet size.
* XXX: This will cause the packet send to fail.
*/
build_dhcpv6_reply(&enc_reply, enc_packet);
/*
* If we got no encapsulated data, then it is discarded, and
* our reply-forw is also discarded.
*/
if (enc_reply.data == NULL) {
goto exit;
}
/*
* Now we can use the reply_data buffer.
* Packet header stuff all comes from the forward message.
*/
reply = (struct dhcpv6_relay_packet *)reply_data;
reply->msg_type = DHCPV6_RELAY_REPL;
reply->hop_count = packet->dhcpv6_hop_count;
memcpy(reply->link_address, &packet->dhcpv6_link_address,
sizeof(reply->link_address));
memcpy(reply->peer_address, &packet->dhcpv6_peer_address,
sizeof(reply->peer_address));
reply_ofs = (int)(offsetof(struct dhcpv6_relay_packet, options));
/*
* Get the reply option state.
*/
opt_state = NULL;
if (!option_state_allocate(&opt_state, MDL)) {
log_error("dhcpv6_relay_forw: no memory for option state.");
goto exit;
}
/*
* Append the interface-id if present.
*/
oc = lookup_option(&dhcpv6_universe, packet->options,
D6O_INTERFACE_ID);
if (oc != NULL) {
if (!evaluate_option_cache(&a_opt, packet,
NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("dhcpv6_relay_forw: error evaluating "
"Interface ID.");
goto exit;
}
if (!save_option_buffer(&dhcpv6_universe, opt_state, NULL,
(unsigned char *)a_opt.data,
a_opt.len,
D6O_INTERFACE_ID, 0)) {
log_error("dhcpv6_relay_forw: error saving "
"Interface ID.");
goto exit;
}
data_string_forget(&a_opt, MDL);
}
#if defined(RELAY_PORT)
/*
* Append the relay_source_port option if present.
*/
oc = lookup_option(&dhcpv6_universe, packet->options,
D6O_RELAY_SOURCE_PORT);
if (oc != NULL) {
if (!evaluate_option_cache(&a_opt, packet,
NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("dhcpv6_relay_forw: error evaluating "
"Relay Source Port.");
goto exit;
}
if (!save_option_buffer(&dhcpv6_universe, opt_state, NULL,
(unsigned char *)a_opt.data,
a_opt.len,
D6O_RELAY_SOURCE_PORT, 0)) {
log_error("dhcpv6_relay_forw: error saving "
"Relay Source Port.");
goto exit;
}
data_string_forget(&a_opt, MDL);
packet->relay_source_port = ISC_TRUE;
}
#endif
/*
* Append our encapsulated stuff for caller.
*/
if (!save_option_buffer(&dhcpv6_universe, opt_state, NULL,
(unsigned char *)enc_reply.data,
enc_reply.len,
D6O_RELAY_MSG, 0)) {
log_error("dhcpv6_relay_forw: error saving Relay MSG.");
goto exit;
}
/*
* Get the ERO if any.
*/
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_ERO);
if (oc != NULL) {
unsigned req;
int i;
if (!evaluate_option_cache(&packet_ero, packet,
NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL) ||
(packet_ero.len & 1)) {
log_error("dhcpv6_relay_forw: error evaluating ERO.");
goto exit;
}
/* Decode and apply the ERO. */
for (i = 0; i < packet_ero.len; i += 2) {
req = getUShort(packet_ero.data + i);
/* Already in the reply? */
oc = lookup_option(&dhcpv6_universe, opt_state, req);
if (oc != NULL)
continue;
/* Get it from the packet if present. */
oc = lookup_option(&dhcpv6_universe,
packet->options,
req);
if (oc == NULL)
continue;
if (!evaluate_option_cache(&a_opt, packet,
NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("dhcpv6_relay_forw: error "
"evaluating option %u.", req);
goto exit;
}
if (!save_option_buffer(&dhcpv6_universe,
opt_state,
NULL,
(unsigned char *)a_opt.data,
a_opt.len,
req,
0)) {
log_error("dhcpv6_relay_forw: error saving "
"option %u.", req);
goto exit;
}
data_string_forget(&a_opt, MDL);
}
}
reply_ofs += store_options6(reply_data + reply_ofs,
sizeof(reply_data) - reply_ofs,
opt_state, packet,
required_opts_agent, &packet_ero);
/*
* Return our reply to the caller.
*/
reply_ret->len = reply_ofs;
reply_ret->buffer = NULL;
if (!buffer_allocate(&reply_ret->buffer, reply_ret->len, MDL)) {
log_fatal("No memory to store reply.");
}
reply_ret->data = reply_ret->buffer->data;
memcpy(reply_ret->buffer->data, reply_data, reply_ofs);
exit:
if (opt_state != NULL)
option_state_dereference(&opt_state, MDL);
if (a_opt.data != NULL) {
data_string_forget(&a_opt, MDL);
}
if (packet_ero.data != NULL) {
data_string_forget(&packet_ero, MDL);
}
if (enc_reply.data != NULL) {
data_string_forget(&enc_reply, MDL);
}
if (enc_opt_data.data != NULL) {
data_string_forget(&enc_opt_data, MDL);
}
if (enc_packet != NULL) {
packet_dereference(&enc_packet, MDL);
}
}
#ifdef DHCP4o6
/* \brief Internal processing of a relayed DHCPv4-query
* (DHCPv4 server side)
*
* Code copied from \ref dhcpv6_relay_forw() which itself is
* from \ref do_packet6().
*
* \param reply_ret pointer to the response
* \param packet the query
*/
static void
dhcp4o6_relay_forw(struct data_string *reply_ret, struct packet *packet) {
struct option_cache *oc;
struct data_string enc_opt_data;
struct packet *enc_packet;
unsigned char msg_type;
const struct dhcpv6_relay_packet *relay;
const struct dhcpv4_over_dhcpv6_packet *msg;
struct data_string enc_reply;
char link_addr[sizeof("ffff:ffff:ffff:ffff:ffff:ffff:255.255.255.255")];
char peer_addr[sizeof("ffff:ffff:ffff:ffff:ffff:ffff:255.255.255.255")];
struct data_string a_opt, packet_ero;
struct option_state *opt_state;
static char reply_data[65536];
struct dhcpv6_relay_packet *reply;
int reply_ofs;
/*
* Initialize variables for early exit.
*/
opt_state = NULL;
memset(&a_opt, 0, sizeof(a_opt));
memset(&packet_ero, 0, sizeof(packet_ero));
memset(&enc_reply, 0, sizeof(enc_reply));
memset(&enc_opt_data, 0, sizeof(enc_opt_data));
enc_packet = NULL;
/*
* Get our encapsulated relay message.
*/
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_RELAY_MSG);
if (oc == NULL) {
inet_ntop(AF_INET6, &packet->dhcpv6_link_address,
link_addr, sizeof(link_addr));
inet_ntop(AF_INET6, &packet->dhcpv6_peer_address,
peer_addr, sizeof(peer_addr));
log_info("Relay-forward from %s with link address=%s and "
"peer address=%s missing Relay Message option.",
piaddr(packet->client_addr), link_addr, peer_addr);
goto exit;
}
if (!evaluate_option_cache(&enc_opt_data, NULL, NULL, NULL,
NULL, NULL, &global_scope, oc, MDL)) {
log_error("dhcp4o6_relay_forw: error evaluating "
"relayed message.");
goto exit;
}
if (!packet6_len_okay((char *)enc_opt_data.data, enc_opt_data.len)) {
log_error("dhcp4o6_relay_forw: "
"encapsulated packet too short.");
goto exit;
}
/*
* Build a packet structure from this encapsulated packet.
*/
if (!packet_allocate(&enc_packet, MDL)) {
log_error("dhcp4o6_relay_forw: "
"no memory for encapsulated packet.");
goto exit;
}
if (!option_state_allocate(&enc_packet->options, MDL)) {
log_error("dhcp4o6_relay_forw: "
"no memory for encapsulated packet's options.");
goto exit;
}
enc_packet->client_port = packet->client_port;
enc_packet->client_addr = packet->client_addr;
interface_reference(&enc_packet->interface, packet->interface, MDL);
enc_packet->dhcpv6_container_packet = packet;
msg_type = enc_opt_data.data[0];
if ((msg_type == DHCPV6_RELAY_FORW) ||
(msg_type == DHCPV6_RELAY_REPL)) {
int relaylen = (int)(offsetof(struct dhcpv6_relay_packet, options));
relay = (struct dhcpv6_relay_packet *)enc_opt_data.data;
enc_packet->dhcpv6_msg_type = relay->msg_type;
/* relay-specific data */
enc_packet->dhcpv6_hop_count = relay->hop_count;
memcpy(&enc_packet->dhcpv6_link_address,
relay->link_address, sizeof(relay->link_address));
memcpy(&enc_packet->dhcpv6_peer_address,
relay->peer_address, sizeof(relay->peer_address));
if (!parse_option_buffer(enc_packet->options,
relay->options,
enc_opt_data.len - relaylen,
&dhcpv6_universe)) {
/* no logging here, as parse_option_buffer() logs all
cases where it fails */
goto exit;
}
} else if ((msg_type == DHCPV6_DHCPV4_QUERY) ||
(msg_type == DHCPV6_DHCPV4_RESPONSE)) {
int msglen =
(int)(offsetof(struct dhcpv4_over_dhcpv6_packet, options));
msg = (struct dhcpv4_over_dhcpv6_packet *)enc_opt_data.data;
enc_packet->dhcpv6_msg_type = msg->msg_type;
/* message-specific data */
memcpy(enc_packet->dhcp4o6_flags,
msg->flags,
sizeof(enc_packet->dhcp4o6_flags));
if (!parse_option_buffer(enc_packet->options,
msg->options,
enc_opt_data.len - msglen,
&dhcpv6_universe)) {
/* no logging here, as parse_option_buffer() logs all
cases where it fails */
goto exit;
}
} else {
log_error("dhcp4o6_relay_forw: unexpected message of type %d.",
(int)msg_type);
goto exit;
}
/*
* This is recursive. It is possible to exceed maximum packet size.
* XXX: This will cause the packet send to fail.
*/
build_dhcpv6_reply(&enc_reply, enc_packet);
/*
* If we got no encapsulated data, then it is discarded, and
* our reply-forw is also discarded.
*/
if (enc_reply.data == NULL) {
goto exit;
}
/*
* Now we can use the reply_data buffer.
* Packet header stuff all comes from the forward message.
*/
reply = (struct dhcpv6_relay_packet *)reply_data;
reply->msg_type = DHCPV6_RELAY_REPL;
reply->hop_count = packet->dhcpv6_hop_count;
memcpy(reply->link_address, &packet->dhcpv6_link_address,
sizeof(reply->link_address));
memcpy(reply->peer_address, &packet->dhcpv6_peer_address,
sizeof(reply->peer_address));
reply_ofs = (int)(offsetof(struct dhcpv6_relay_packet, options));
/*
* Get the reply option state.
*/
if (!option_state_allocate(&opt_state, MDL)) {
log_error("dhcp4o6_relay_forw: no memory for option state.");
goto exit;
}
/*
* Append the interface-id if present.
*/
oc = lookup_option(&dhcpv6_universe, packet->options,
D6O_INTERFACE_ID);
if (oc != NULL) {
if (!evaluate_option_cache(&a_opt, packet,
NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("dhcp4o6_relay_forw: error evaluating "
"Interface ID.");
goto exit;
}
if (!save_option_buffer(&dhcpv6_universe, opt_state, NULL,
(unsigned char *)a_opt.data,
a_opt.len,
D6O_INTERFACE_ID, 0)) {
log_error("dhcp4o6_relay_forw: error saving "
"Interface ID.");
goto exit;
}
data_string_forget(&a_opt, MDL);
}
#if defined(RELAY_PORT)
/*
* Append the relay_source_port option if present.
*/
oc = lookup_option(&dhcpv6_universe, packet->options,
D6O_RELAY_SOURCE_PORT);
if (oc != NULL) {
if (!evaluate_option_cache(&a_opt, packet,
NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("dhcpv4o6_relay_forw: error evaluating "
"Relay Source Port.");
goto exit;
}
if (!save_option_buffer(&dhcpv6_universe, opt_state, NULL,
(unsigned char *)a_opt.data,
a_opt.len,
D6O_RELAY_SOURCE_PORT, 0)) {
log_error("dhcpv4o6_relay_forw: error saving "
"Relay Source Port.");
goto exit;
}
data_string_forget(&a_opt, MDL);
packet->relay_source_port = ISC_TRUE;
}
#endif
/*
* Append our encapsulated stuff for caller.
*/
if (!save_option_buffer(&dhcpv6_universe, opt_state, NULL,
(unsigned char *)enc_reply.data,
enc_reply.len,
D6O_RELAY_MSG, 0)) {
log_error("dhcp4o6_relay_forw: error saving Relay MSG.");
goto exit;
}
/*
* Get the ERO if any.
*/
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_ERO);
if (oc != NULL) {
unsigned req;
int i;
if (!evaluate_option_cache(&packet_ero, packet,
NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL) ||
(packet_ero.len & 1)) {
log_error("dhcp4o6_relay_forw: error evaluating ERO.");
goto exit;
}
/* Decode and apply the ERO. */
for (i = 0; i < packet_ero.len; i += 2) {
req = getUShort(packet_ero.data + i);
/* Already in the reply? */
oc = lookup_option(&dhcpv6_universe, opt_state, req);
if (oc != NULL)
continue;
/* Get it from the packet if present. */
oc = lookup_option(&dhcpv6_universe,
packet->options,
req);
if (oc == NULL)
continue;
if (!evaluate_option_cache(&a_opt, packet,
NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("dhcp4o6_relay_forw: error "
"evaluating option %u.", req);
goto exit;
}
if (!save_option_buffer(&dhcpv6_universe,
opt_state,
NULL,
(unsigned char *)a_opt.data,
a_opt.len,
req,
0)) {
log_error("dhcp4o6_relay_forw: error saving "
"option %u.", req);
goto exit;
}
data_string_forget(&a_opt, MDL);
}
}
reply_ofs += store_options6(reply_data + reply_ofs,
sizeof(reply_data) - reply_ofs,
opt_state, packet,
required_opts_agent, &packet_ero);
/*
* Return our reply to the caller.
*/
reply_ret->len = reply_ofs;
reply_ret->buffer = NULL;
if (!buffer_allocate(&reply_ret->buffer, reply_ret->len, MDL)) {
log_fatal("No memory to store reply.");
}
reply_ret->data = reply_ret->buffer->data;
memcpy(reply_ret->buffer->data, reply_data, reply_ofs);
exit:
if (opt_state != NULL)
option_state_dereference(&opt_state, MDL);
if (a_opt.data != NULL) {
data_string_forget(&a_opt, MDL);
}
if (packet_ero.data != NULL) {
data_string_forget(&packet_ero, MDL);
}
if (enc_reply.data != NULL) {
data_string_forget(&enc_reply, MDL);
}
if (enc_opt_data.data != NULL) {
data_string_forget(&enc_opt_data, MDL);
}
if (enc_packet != NULL) {
packet_dereference(&enc_packet, MDL);
}
}
/*
* \brief Internal processing of a DHCPv4-query
* (DHCPv4 server function)
*
* Code copied from \ref do_packet().
*
* \param reply_ret pointer to the response
* \param packet the query
*/
static void
dhcp4o6_dhcpv4_query(struct data_string *reply_ret, struct packet *packet) {
struct option_cache *oc;
struct data_string enc_opt_data;
struct packet *enc_packet;
struct data_string enc_response;
struct option_state *opt_state;
static char response_data[65536];
struct dhcpv4_over_dhcpv6_packet *response;
int response_ofs;
/*
* Initialize variables for early exit.
*/
opt_state = NULL;
memset(&enc_response, 0, sizeof(enc_response));
memset(&enc_opt_data, 0, sizeof(enc_opt_data));
enc_packet = NULL;
/*
* Get our encapsulated relay message.
*/
oc = lookup_option(&dhcpv6_universe, packet->options, D6O_DHCPV4_MSG);
if (oc == NULL) {
log_info("DHCPv4-query from %s missing DHCPv4 Message option.",
piaddr(packet->client_addr));
goto exit;
}
if (!evaluate_option_cache(&enc_opt_data, NULL, NULL, NULL,
NULL, NULL, &global_scope, oc, MDL)) {
log_error("dhcp4o6_dhcpv4_query: error evaluating "
"DHCPv4 message.");
goto exit;
}
if (enc_opt_data.len < DHCP_FIXED_NON_UDP) {
log_error("dhcp4o6_dhcpv4_query: DHCPv4 packet too short.");
goto exit;
}
/*
* Build a packet structure from this encapsulated packet.
*/
if (!packet_allocate(&enc_packet, MDL)) {
log_error("dhcp4o6_dhcpv4_query: "
"no memory for encapsulated packet.");
goto exit;
}
enc_packet->raw = (struct dhcp_packet *)enc_opt_data.data;
enc_packet->packet_length = enc_opt_data.len;
enc_packet->dhcp4o6_response = &enc_response;
enc_packet->client_port = packet->client_port;
enc_packet->client_addr = packet->client_addr;
interface_reference(&enc_packet->interface, packet->interface, MDL);
enc_packet->dhcpv6_container_packet = packet;
if (packet->dhcp4o6_flags[0] & DHCP4O6_QUERY_UNICAST)
enc_packet->unicast = 1;
if (enc_packet->raw->hlen > sizeof(enc_packet->raw->chaddr)) {
log_info("dhcp4o6_dhcpv4_query: "
"discarding packet with bogus hlen.");
goto exit;
}
/* Allocate packet->options now so it is non-null for all packets */
if (!option_state_allocate (&enc_packet->options, MDL)) {
log_error("dhcp4o6_dhcpv4_query: no memory for options.");
goto exit;
}
/* If there's an option buffer, try to parse it. */
if (enc_packet->packet_length >= DHCP_FIXED_NON_UDP + 4) {
struct option_cache *op;
if (!parse_options(enc_packet)) {
if (enc_packet->options)
option_state_dereference
(&enc_packet->options, MDL);
packet_dereference (&enc_packet, MDL);
goto exit;
}
if (enc_packet->options_valid &&
(op = lookup_option(&dhcp_universe,
enc_packet->options,
DHO_DHCP_MESSAGE_TYPE))) {
struct data_string dp;
memset(&dp, 0, sizeof dp);
evaluate_option_cache(&dp, enc_packet, NULL, NULL,
enc_packet->options, NULL,
NULL, op, MDL);
if (dp.len > 0)
enc_packet->packet_type = dp.data[0];
else
enc_packet->packet_type = 0;
data_string_forget(&dp, MDL);
}
}
if (validate_packet(enc_packet) != 0) {
if (enc_packet->packet_type)
dhcp(enc_packet);
else
bootp(enc_packet);
}
/* If the caller kept the packet, they'll have upped the refcnt. */
packet_dereference(&enc_packet, MDL);
/*
* If we got no response data, then it is discarded, and
* our DHCPv4-response is also discarded.
*/
if (enc_response.data == NULL) {
goto exit;
}
/*
* Now we can use the response_data buffer.
*/
response = (struct dhcpv4_over_dhcpv6_packet *)response_data;
response->msg_type = DHCPV6_DHCPV4_RESPONSE;
response->flags[0] = response->flags[1] = response->flags[2] = 0;
response_ofs =
(int)(offsetof(struct dhcpv4_over_dhcpv6_packet, options));
/*
* Get the response option state.
*/
if (!option_state_allocate(&opt_state, MDL)) {
log_error("dhcp4o6_dhcpv4_query: no memory for option state.");
goto exit;
}
/*
* Append our encapsulated stuff for caller.
*/
if (!save_option_buffer(&dhcpv6_universe, opt_state, NULL,
(unsigned char *)enc_response.data,
enc_response.len,
D6O_DHCPV4_MSG, 0)) {
log_error("dhcp4o6_dhcpv4_query: error saving DHCPv4 MSG.");
goto exit;
}
response_ofs += store_options6(response_data + response_ofs,
sizeof(response_data) - response_ofs,
opt_state, packet,
required_opts_4o6, NULL);
/*
* Return our response to the caller.
*/
reply_ret->len = response_ofs;
reply_ret->buffer = NULL;
if (!buffer_allocate(&reply_ret->buffer, reply_ret->len, MDL)) {
log_fatal("dhcp4o6_dhcpv4_query: no memory to store reply.");
}
reply_ret->data = reply_ret->buffer->data;
memcpy(reply_ret->buffer->data, response_data, response_ofs);
exit:
if (opt_state != NULL)
option_state_dereference(&opt_state, MDL);
if (enc_response.data != NULL) {
data_string_forget(&enc_response, MDL);
}
if (enc_opt_data.data != NULL) {
data_string_forget(&enc_opt_data, MDL);
}
if (enc_packet != NULL) {
packet_dereference(&enc_packet, MDL);
}
}
/*
* \brief Forward a DHCPv4-query message to the DHCPv4 side
* (DHCPv6 server function)
*
* Format: interface:16 + address:16 + udp:4 + DHCPv6 DHCPv4-query message
*
* \brief packet the DHCPv6 DHCPv4-query message
*/
static void forw_dhcpv4_query(struct packet *packet) {
struct data_string ds;
struct udp_data4o6 udp_data;
unsigned len;
int cc;
/* Get the initial message. */
while (packet->dhcpv6_container_packet != NULL)
packet = packet->dhcpv6_container_packet;
/* Check the initial message. */
if ((packet->raw == NULL) ||
(packet->client_addr.len != 16) ||
(packet->interface == NULL)) {
log_error("forw_dhcpv4_query: can't find initial message.");
return;
}
/* Get a buffer. */
len = packet->packet_length + 36;
memset(&ds, 0, sizeof(ds));
if (!buffer_allocate(&ds.buffer, len, MDL)) {
log_error("forw_dhcpv4_query: "
"no memory for encapsulating packet.");
return;
}
ds.data = ds.buffer->data;
ds.len = len;
/* Fill the buffer. */
strncpy((char *)ds.buffer->data, packet->interface->name, 16);
memcpy(ds.buffer->data + 16,
packet->client_addr.iabuf, 16);
memset(&udp_data, 0, sizeof(udp_data));
udp_data.src_port = packet->client_port;
memcpy(ds.buffer->data + 32, &udp_data, 4);
memcpy(ds.buffer->data + 36,
(unsigned char *)packet->raw,
packet->packet_length);
/* Forward to the DHCPv4 server. */
cc = send(dhcp4o6_fd, ds.data, ds.len, 0);
if (cc < 0)
log_error("forw_dhcpv4_query: send(): %m");
data_string_forget(&ds, MDL);
}
#endif
static void
dhcpv6_discard(struct packet *packet) {
/* INSIST(packet->msg_type > 0); */
/* INSIST(packet->msg_type < dhcpv6_type_name_max); */
log_debug("Discarding %s from %s; message type not handled by server",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr));
}
static void
build_dhcpv6_reply(struct data_string *reply, struct packet *packet) {
memset(reply, 0, sizeof(*reply));
/* I would like to classify the client once here, but
* as I don't want to classify all of the incoming packets
* I need to do it before handling specific types.
* We don't need to classify if we are tossing the packet
* or if it is a relay - the classification step will get
* done when we process the inner client packet.
*/
switch (packet->dhcpv6_msg_type) {
case DHCPV6_SOLICIT:
classify_client(packet);
dhcpv6_solicit(reply, packet);
break;
case DHCPV6_ADVERTISE:
dhcpv6_discard(packet);
break;
case DHCPV6_REQUEST:
classify_client(packet);
dhcpv6_request(reply, packet);
break;
case DHCPV6_CONFIRM:
classify_client(packet);
dhcpv6_confirm(reply, packet);
break;
case DHCPV6_RENEW:
classify_client(packet);
dhcpv6_renew(reply, packet);
break;
case DHCPV6_REBIND:
classify_client(packet);
dhcpv6_rebind(reply, packet);
break;
case DHCPV6_REPLY:
dhcpv6_discard(packet);
break;
case DHCPV6_RELEASE:
classify_client(packet);
dhcpv6_release(reply, packet);
break;
case DHCPV6_DECLINE:
classify_client(packet);
dhcpv6_decline(reply, packet);
break;
case DHCPV6_RECONFIGURE:
dhcpv6_discard(packet);
break;
case DHCPV6_INFORMATION_REQUEST:
classify_client(packet);
dhcpv6_information_request(reply, packet);
break;
case DHCPV6_RELAY_FORW:
#ifdef DHCP4o6
if (dhcpv4_over_dhcpv6 && (local_family == AF_INET))
dhcp4o6_relay_forw(reply, packet);
else
#endif /* DHCP4o6 */
dhcpv6_relay_forw(reply, packet);
break;
case DHCPV6_RELAY_REPL:
dhcpv6_discard(packet);
break;
case DHCPV6_LEASEQUERY:
classify_client(packet);
dhcpv6_leasequery(reply, packet);
break;
case DHCPV6_LEASEQUERY_REPLY:
dhcpv6_discard(packet);
break;
case DHCPV6_DHCPV4_QUERY:
#ifdef DHCP4o6
if (dhcpv4_over_dhcpv6) {
if (local_family == AF_INET6) {
forw_dhcpv4_query(packet);
} else {
dhcp4o6_dhcpv4_query(reply, packet);
}
} else
#endif /* DHCP4o6 */
dhcpv6_discard(packet);
break;
case DHCPV6_DHCPV4_RESPONSE:
dhcpv6_discard(packet);
break;
default:
/* XXX: would be nice if we had "notice" level,
as syslog, for this */
log_info("Discarding unknown DHCPv6 message type %d "
"from %s", packet->dhcpv6_msg_type,
piaddr(packet->client_addr));
}
}
static void
log_packet_in(const struct packet *packet) {
struct data_string s;
u_int32_t tid;
char tmp_addr[INET6_ADDRSTRLEN];
const void *addr;
memset(&s, 0, sizeof(s));
if (packet->dhcpv6_msg_type < dhcpv6_type_name_max) {
data_string_sprintfa(&s, "%s message from %s port %d",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr),
ntohs(packet->client_port));
} else {
data_string_sprintfa(&s,
"Unknown message type %d from %s port %d",
packet->dhcpv6_msg_type,
piaddr(packet->client_addr),
ntohs(packet->client_port));
}
if ((packet->dhcpv6_msg_type == DHCPV6_RELAY_FORW) ||
(packet->dhcpv6_msg_type == DHCPV6_RELAY_REPL)) {
addr = &packet->dhcpv6_link_address;
data_string_sprintfa(&s, ", link address %s",
inet_ntop(AF_INET6, addr,
tmp_addr, sizeof(tmp_addr)));
addr = &packet->dhcpv6_peer_address;
data_string_sprintfa(&s, ", peer address %s",
inet_ntop(AF_INET6, addr,
tmp_addr, sizeof(tmp_addr)));
} else if ((packet->dhcpv6_msg_type != DHCPV6_DHCPV4_QUERY) &&
(packet->dhcpv6_msg_type != DHCPV6_DHCPV4_RESPONSE)) {
tid = 0;
memcpy(((char *)&tid)+1, packet->dhcpv6_transaction_id, 3);
data_string_sprintfa(&s, ", transaction ID 0x%06X", tid);
/*
oc = lookup_option(&dhcpv6_universe, packet->options,
D6O_CLIENTID);
if (oc != NULL) {
memset(&tmp_ds, 0, sizeof(tmp_ds_));
if (!evaluate_option_cache(&tmp_ds, packet, NULL, NULL,
packet->options, NULL,
&global_scope, oc, MDL)) {
log_error("Error evaluating Client Identifier");
} else {
data_strint_sprintf(&s, ", client ID %s",
data_string_forget(&tmp_ds, MDL);
}
}
*/
}
log_info("%s", s.data);
data_string_forget(&s, MDL);
}
void
dhcpv6(struct packet *packet) {
struct data_string reply;
struct sockaddr_in6 to_addr;
int send_ret;
/*
* Log a message that we received this packet.
*/
log_packet_in(packet);
/*
* Build our reply packet.
*/
build_dhcpv6_reply(&reply, packet);
if (reply.data != NULL) {
/*
* Send our reply, if we have one.
*/
memset(&to_addr, 0, sizeof(to_addr));
to_addr.sin6_family = AF_INET6;
if ((packet->dhcpv6_msg_type == DHCPV6_RELAY_FORW) ||
(packet->dhcpv6_msg_type == DHCPV6_RELAY_REPL)) {
to_addr.sin6_port = local_port;
} else {
to_addr.sin6_port = remote_port;
}
#if defined (REPLY_TO_SOURCE_PORT)
/*
* This appears to have been included for testing so we would
* not need a root client, but was accidently left in the
* final code. We continue to include it in case
* some users have come to rely upon it, but leave
* it off by default as it's a bad idea.
*/
to_addr.sin6_port = packet->client_port;
#endif
#if defined(RELAY_PORT)
/*
* Check relay source port.
*/
if (packet->relay_source_port) {
to_addr.sin6_port = packet->client_port;
}
#endif
memcpy(&to_addr.sin6_addr, packet->client_addr.iabuf,
sizeof(to_addr.sin6_addr));
log_info("Sending %s to %s port %d",
dhcpv6_type_names[reply.data[0]],
piaddr(packet->client_addr),
ntohs(to_addr.sin6_port));
send_ret = send_packet6(packet->interface,
reply.data, reply.len, &to_addr);
if (send_ret != reply.len) {
log_error("dhcpv6: send_packet6() sent %d of %d bytes",
send_ret, reply.len);
}
data_string_forget(&reply, MDL);
}
}
#ifdef DHCP4o6
/*
* \brief Receive a DHCPv4-query message from the DHCPv6 side
* (DHCPv4 server function)
*
* Receive a message with a DHCPv4-query inside from the DHCPv6 server.
* (code copied from \ref do_packet6() \ref and dhcpv6())
*
* Format: interface:16 + address:16 + udp:4 + DHCPv6 DHCPv4-query message
*
* \param raw the DHCPv6 DHCPv4-query message raw content
*/
static void recv_dhcpv4_query(struct data_string *raw) {
struct interface_info *ip;
char name[16 + 1];
struct iaddr iaddr;
struct packet *packet;
unsigned char msg_type;
const struct dhcpv6_relay_packet *relay;
const struct dhcpv4_over_dhcpv6_packet *msg;
struct data_string reply;
struct data_string ds;
struct udp_data4o6 udp_data;
unsigned len;
int cc;
memset(name, 0, sizeof(name));
memcpy(name, raw->data, 16);
for (ip = interfaces; ip != NULL; ip = ip->next) {
if (!strcmp(name, ip->name))
break;
}
if (ip == NULL) {
log_error("recv_dhcpv4_query: can't find interface %s.",
name);
return;
}
iaddr.len = 16;
memcpy(iaddr.iabuf, raw->data + 16, 16);
memset(&udp_data, 0, sizeof(udp_data));
memcpy(&udp_data, raw->data + 32, 4);
/*
* From do_packet6().
*/
if (!packet6_len_okay((char *)raw->data + 36, raw->len - 36)) {
log_error("recv_dhcpv4_query: "
"short packet from %s, len %d, dropped",
piaddr(iaddr), raw->len - 36);
return;
}
/*
* Build a packet structure.
*/
packet = NULL;
if (!packet_allocate(&packet, MDL)) {
log_error("recv_dhcpv4_query: no memory for packet.");
return;
}
if (!option_state_allocate(&packet->options, MDL)) {
log_error("recv_dhcpv4_query: no memory for options.");
packet_dereference(&packet, MDL);
return;
}
packet->raw = (struct dhcp_packet *)(raw->data + 36);
packet->packet_length = raw->len - 36;
packet->client_port = udp_data.src_port;
packet->client_addr = iaddr;
interface_reference(&packet->interface, ip, MDL);
msg_type = raw->data[36];
if ((msg_type == DHCPV6_RELAY_FORW) ||
(msg_type == DHCPV6_RELAY_REPL)) {
int relaylen =
(int)(offsetof(struct dhcpv6_relay_packet, options));
relay = (const struct dhcpv6_relay_packet *)(raw->data + 36);
packet->dhcpv6_msg_type = relay->msg_type;
/* relay-specific data */
packet->dhcpv6_hop_count = relay->hop_count;
memcpy(&packet->dhcpv6_link_address,
relay->link_address, sizeof(relay->link_address));
memcpy(&packet->dhcpv6_peer_address,
relay->peer_address, sizeof(relay->peer_address));
if (!parse_option_buffer(packet->options,
relay->options,
raw->len - 36 - relaylen,
&dhcpv6_universe)) {
/* no logging here, as parse_option_buffer() logs all
cases where it fails */
packet_dereference(&packet, MDL);
return;
}
} else if ((msg_type == DHCPV6_DHCPV4_QUERY) ||
(msg_type == DHCPV6_DHCPV4_RESPONSE)) {
int msglen =
(int)(offsetof(struct dhcpv4_over_dhcpv6_packet, options));
msg = (struct dhcpv4_over_dhcpv6_packet *)(raw->data + 36);
packet->dhcpv6_msg_type = msg->msg_type;
/* message-specific data */
memcpy(packet->dhcp4o6_flags, msg->flags,
sizeof(packet->dhcp4o6_flags));
if (!parse_option_buffer(packet->options,
msg->options,
raw->len - 36 - msglen,
&dhcpv6_universe)) {
/* no logging here, as parse_option_buffer() logs all
cases where it fails */
packet_dereference(&packet, MDL);
return;
}
} else {
log_error("recv_dhcpv4_query: unexpected message of type %d.",
(int)msg_type);
packet_dereference(&packet, MDL);
return;
}
/*
* From dhcpv6().
*/
/*
* Log a message that we received this packet.
*/
/* log_packet_in(packet); */
memset(&ds, 0, sizeof(ds));
if (packet->dhcpv6_msg_type < dhcpv6_type_name_max) {
data_string_sprintfa(&ds, "%s message from %s",
dhcpv6_type_names[packet->dhcpv6_msg_type],
piaddr(packet->client_addr));
} else {
data_string_sprintfa(&ds,
"Unknown message type %d from %s",
packet->dhcpv6_msg_type,
piaddr(packet->client_addr));
}
if ((packet->dhcpv6_msg_type == DHCPV6_RELAY_FORW) ||
(packet->dhcpv6_msg_type == DHCPV6_RELAY_REPL)) {
char tmp_addr[INET6_ADDRSTRLEN];
const void *addr;
addr = &packet->dhcpv6_link_address;
data_string_sprintfa(&ds, ", link address %s",
inet_ntop(AF_INET6, addr,
tmp_addr, sizeof(tmp_addr)));
addr = &packet->dhcpv6_peer_address;
data_string_sprintfa(&ds, ", peer address %s",
inet_ntop(AF_INET6, addr,
tmp_addr, sizeof(tmp_addr)));
} else if ((packet->dhcpv6_msg_type != DHCPV6_DHCPV4_QUERY) &&
(packet->dhcpv6_msg_type != DHCPV6_DHCPV4_RESPONSE)) {
u_int32_t tid = 0;
memcpy(((char *)&tid)+1, packet->dhcpv6_transaction_id, 3);
data_string_sprintfa(&ds, ", transaction ID 0x%06X", tid);
}
log_info("%s", ds.data);
data_string_forget(&ds, MDL);
/*
* Build our reply packet.
*/
build_dhcpv6_reply(&reply, packet);
if (reply.data == NULL) {
packet_dereference(&packet, MDL);
return;
}
/*
* Forward the response.
*/
len = reply.len + 36;
memset(&ds, 0, sizeof(ds));
if (!buffer_allocate(&ds.buffer, len, MDL)) {
log_error("recv_dhcpv4_query: no memory.");
packet_dereference(&packet, MDL);
return;
}
ds.data = ds.buffer->data;
ds.len = len;
memcpy(ds.buffer->data, name, 16);
memcpy(ds.buffer->data + 16, iaddr.iabuf, 16);
udp_data.rsp_opt_exist = packet->relay_source_port ? 1 : 0;
memcpy(ds.buffer->data + 32, &udp_data, 4);
memcpy(ds.buffer->data + 36, reply.data, reply.len);
/*
* Now we can release the packet.
*/
packet_dereference(&packet, MDL);
cc = send(dhcp4o6_fd, ds.data, ds.len, 0);
if (cc < 0)
log_error("recv_dhcpv4_query: send(): %m");
data_string_forget(&ds, MDL);
}
#endif /* DHCP4o6 */
static void
seek_shared_host(struct host_decl **hp, struct shared_network *shared) {
struct host_decl *nofixed = NULL;
struct host_decl *seek, *hold = NULL;
/*
* Seek forward through fixed addresses for the right link.
*
* Note: how to do this for fixed prefixes???
*/
host_reference(&hold, *hp, MDL);
host_dereference(hp, MDL);
seek = hold;
while (seek != NULL) {
if (seek->fixed_addr == NULL)
nofixed = seek;
else if (fixed_matches_shared(seek, shared))
break;
seek = seek->n_ipaddr;
}
if ((seek == NULL) && (nofixed != NULL))
seek = nofixed;
if (seek != NULL)
host_reference(hp, seek, MDL);
}
static isc_boolean_t
fixed_matches_shared(struct host_decl *host, struct shared_network *shared) {
struct subnet *subnet;
struct data_string addr;
isc_boolean_t matched;
struct iaddr fixed;
if (host->fixed_addr == NULL)
return ISC_FALSE;
memset(&addr, 0, sizeof(addr));
if (!evaluate_option_cache(&addr, NULL, NULL, NULL, NULL, NULL,
&global_scope, host->fixed_addr, MDL))
return ISC_FALSE;
if (addr.len < 16) {
data_string_forget(&addr, MDL);
return ISC_FALSE;
}
fixed.len = 16;
memcpy(fixed.iabuf, addr.data, 16);
matched = ISC_FALSE;
for (subnet = shared->subnets ; subnet != NULL ;
subnet = subnet->next_sibling) {
if (addr_eq(subnet_number(fixed, subnet->netmask),
subnet->net)) {
matched = ISC_TRUE;
break;
}
}
data_string_forget(&addr, MDL);
return matched;
}
/*!
*
* \brief Constructs a REPLY with status of UseMulticast to a given packet
*
* Per RFC 3315 Secs 18.2.1,3,6 & 7, when a server rejects a client's
* unicast-sent packet, the response must only contain the client id,
* server id, and a status code option of 5 (UseMulticast). This function
* constructs such a packet and returns it as a data_string.
*
* \param reply_ret = data_string which will receive the newly constructed
* reply
* \param packet = client request which is being rejected
* \param client_id = data_string which contains the client id
* \param server_id = data_string which which contains the server id
*
*/
void
unicast_reject(struct data_string *reply_ret,
struct packet *packet,
const struct data_string *client_id,
const struct data_string *server_id)
{
struct reply_state reply;
memset(&reply, 0x0, sizeof(struct reply_state));
/* Locate the client. */
if (shared_network_from_packet6(&reply.shared, packet)
!= ISC_R_SUCCESS) {
log_error("unicast_reject: could not locate client.");
return;
}
/* Initialize the reply. */
packet_reference(&reply.packet, packet, MDL);
data_string_copy(&reply.client_id, client_id, MDL);
if (start_reply(packet, client_id, server_id, &reply.opt_state,
&reply.buf.reply)) {
/* Set the UseMulticast status code. */
if (!set_status_code(STATUS_UseMulticast,
"Unicast not allowed by server.",
reply.opt_state)) {
log_error("unicast_reject: Unable to set status code.");
} else {
/* Set write cursor to just past the reply header. */
reply.cursor = REPLY_OPTIONS_INDEX;
reply.cursor += store_options6(((char *)reply.buf.data
+ reply.cursor),
(sizeof(reply.buf)
- reply.cursor),
reply.opt_state,
reply.packet,
unicast_reject_opts,
NULL);
/* Return our reply to the caller. */
reply_ret->len = reply.cursor;
reply_ret->buffer = NULL;
if (!buffer_allocate(&reply_ret->buffer,
reply.cursor, MDL)) {
log_fatal("unicast_reject:"
"No memory to store Reply.");
}
memcpy(reply_ret->buffer->data, reply.buf.data,
reply.cursor);
reply_ret->data = reply_ret->buffer->data;
}
}
/* Cleanup. */
if (reply.shared != NULL)
shared_network_dereference(&reply.shared, MDL);
if (reply.opt_state != NULL)
option_state_dereference(&reply.opt_state, MDL);
if (reply.packet != NULL)
packet_dereference(&reply.packet, MDL);
if (reply.client_id.data != NULL)
data_string_forget(&reply.client_id, MDL);
}
/*!
*
* \brief Checks if the dhcp6.unicast option has been defined
*
* Scans the option space for the presence of the dhcp6.unicast option. The
* function attempts to map the inbound packet to a shared network first
* by an ip address specified via an D6O_IA_XX option and if that fails then
* by the packet's source information (e.g. relay link, link, or interace).
* Once the packet is mapped to a shared network, the function executes all
* statements from the network's group outward into a local option cache.
* The option cache is then scanned for the presence of unicast option. If
* the packet cannot be mapped to a shared network, the function returns
* ISC_FALSE.
* \param packet inbound packet from the client
*
* \return ISC_TRUE if the dhcp6.unicast option is defined, false otherwise.
*
*/
isc_boolean_t
is_unicast_option_defined(struct packet *packet) {
isc_boolean_t is_defined = ISC_FALSE;
struct option_state *opt_state = NULL;
struct option_cache *oc = NULL;
struct shared_network *shared = NULL;
if (!option_state_allocate(&opt_state, MDL)) {
log_fatal("is_unicast_option_defined:"
"No memory for option state.");
}
/* We try to map the packet to a network first by an IA_XX value.
* If that fails, we try by packet source. */
if (((shared_network_from_requested_addr(&shared, packet)
!= ISC_R_SUCCESS) &&
(shared_network_from_packet6(&shared, packet) != ISC_R_SUCCESS))
|| (shared == NULL)) {
/* @todo what would this really mean? I think wrong network
* logic will catch it */
log_error("is_unicast_option_defined:"
"cannot attribute packet to a network.");
return (ISC_FALSE);
}
/* Now that we've mapped it to a network, execute statments to that
* scope, looking for the unicast option. We don't care about the
* value of the option, only whether or not it is defined. */
execute_statements_in_scope(NULL, NULL, NULL, NULL, NULL, opt_state,
&global_scope, shared->group, NULL, NULL);
oc = lookup_option(&dhcpv6_universe, opt_state, D6O_UNICAST);
is_defined = (oc != NULL ? ISC_TRUE : ISC_FALSE);
log_debug("is_unicast_option_defined: option found : %d", is_defined);
if (shared != NULL) {
shared_network_dereference(&shared, MDL);
}
if (opt_state != NULL) {
option_state_dereference(&opt_state, MDL);
}
return (is_defined);
}
/*!
*
* \brief Maps a packet to a shared network based on the requested IP address
*
* The function attempts to find a subnet that matches the first requested IP
* address contained within the given packet. Note that it looks first for
* D6O_IA_NAs, then D6O_IA_PDs and lastly D6O_IA_TAs. If a matching network is
* found, a reference to it is returned in the parameter, shared.
*
* \param shared shared_network pointer which will receive the matching network
* \param packet inbound packet from the client
*
* \return ISC_R_SUCCESS if the packet can be mapped to a shared_network.
*
*/
static isc_result_t
shared_network_from_requested_addr (struct shared_network **shared,
struct packet* packet) {
struct iaddr iaddr;
struct subnet* subnet = NULL;
isc_result_t status = ISC_R_FAILURE;
/* Try to match first IA_ address or prefix we find to a subnet. In
* theory all IA_ values in a given request are supposed to be in the
* same subnet so we only need to try one right? */
if ((get_first_ia_addr_val(packet, D6O_IA_NA, &iaddr) != ISC_R_SUCCESS)
&& (get_first_ia_addr_val(packet, D6O_IA_PD, &iaddr)
!= ISC_R_SUCCESS)
&& (get_first_ia_addr_val(packet, D6O_IA_TA, &iaddr)
!= ISC_R_SUCCESS)) {
/* we found nothing to match against */
log_debug("share_network_from_request_addr: nothing to match");
return (ISC_R_FAILURE);
}
if (!find_subnet(&subnet, iaddr, MDL)) {
log_debug("shared_network_from_requested_addr:"
"No subnet found for addr %s.", piaddr(iaddr));
} else {
status = shared_network_reference(shared,
subnet->shared_network, MDL);
subnet_dereference(&subnet, MDL);
log_debug("shared_network_from_requested_addr:"
" found shared network %s for address %s.",
((*shared)->name ? (*shared)->name : "unnamed"),
piaddr(iaddr));
return (status);
}
return (ISC_R_FAILURE);
}
/*!
*
* \brief Retrieves the first IP address from a given packet of a given type
*
* Search a packet for options of a given type (D6O_IA_AN, D6O_IA_PD, or
* D6O_IA_TA) for the first non-blank IA_XX value and return its IP address
* component.
*
* \param packet packet received from the client
* \param addr_type the address option type (D6O_IA_NA , D6O_IA_PD, or
* D6O_IP_TA) to look for within the packet.
* \param iaddr pointer to the iaddr structure which will receive the extracted
* address.
*
* \return ISC_R_SUCCESS if an address was succesfully extracted, ISC_R_FALURE
* otherwise.
*
*/
static isc_result_t
get_first_ia_addr_val (struct packet* packet, int addr_type,
struct iaddr* iaddr) {
struct option_cache *ia;
struct option_cache *oc = NULL;
struct data_string cli_enc_opt_data;
struct option_state *cli_enc_opt_state;
int addr_opt_offset;
int addr_opt;
int addr_opt_data_len;
int ip_addr_offset;
isc_result_t status = ISC_R_FAILURE;
memset(iaddr, 0, sizeof(struct iaddr));
/* Set up address type specifics */
switch (addr_type) {
case D6O_IA_NA:
addr_opt_offset = IA_NA_OFFSET;
addr_opt = D6O_IAADDR;
addr_opt_data_len = 24;
ip_addr_offset = 0;
break;
case D6O_IA_TA:
addr_opt_offset = IA_TA_OFFSET;
addr_opt = D6O_IAADDR;
addr_opt_data_len = 24;
ip_addr_offset = 0;
break;
case D6O_IA_PD:
addr_opt_offset = IA_PD_OFFSET;
addr_opt = D6O_IAPREFIX;
addr_opt_data_len = 25;
ip_addr_offset = 9;
break;
default:
/* shouldn't be here */
log_error ("get_first_ia_addr_val: invalid opt type %d",
addr_type);
return (ISC_R_FAILURE);
}
/* Find the first, non-blank IA_XX value within an D6O_IA_XX option. */
for (ia = lookup_option(&dhcpv6_universe, packet->options, addr_type);
ia != NULL && oc == NULL; ia = ia->next) {
if (!get_encapsulated_IA_state(&cli_enc_opt_state,
&cli_enc_opt_data,
packet, ia, addr_opt_offset)) {
log_debug ("get_first_ia_addr_val:"
" couldn't unroll enclosing option");
return (ISC_R_FAILURE);
}
oc = lookup_option(&dhcpv6_universe, cli_enc_opt_state,
addr_opt);
if (oc == NULL) {
/* no address given for this IA, ignore */
option_state_dereference(&cli_enc_opt_state, MDL);
data_string_forget(&cli_enc_opt_data, MDL);
}
}
/* If we found a non-blank IA_XX then extract its ip address. */
if (oc != NULL) {
struct data_string iaddr_str;
memset(&iaddr_str, 0, sizeof(iaddr_str));
if (!evaluate_option_cache(&iaddr_str, packet, NULL, NULL,
packet->options, NULL, &global_scope,
oc, MDL)) {
log_error("get_first_ia_addr_val: "
"error evaluating IA_XX option.");
} else {
if (iaddr_str.len != addr_opt_data_len) {
log_error("shared_network_from_requested_addr:"
" invalid length %d, expected %d",
iaddr_str.len, addr_opt_data_len);
} else {
iaddr->len = 16;
memcpy (iaddr->iabuf,
iaddr_str.data + ip_addr_offset, 16);
status = ISC_R_SUCCESS;
}
data_string_forget(&iaddr_str, MDL);
}
option_state_dereference(&cli_enc_opt_state, MDL);
data_string_forget(&cli_enc_opt_data, MDL);
}
return (status);
}
/*
* \brief Calculates the reply T1/T2 times and stuffs them in outbound buffer
*
* T1/T2 time selection is kind of weird. We actually use DHCP * (v4) scoped
* options, dhcp-renewal-time and dhcp-rebinding-time, as handy existing places
* where these can be configured by an administrator. A value of zero tells the
* client it may choose its own value.
*
* When those options are not defined, the values will be set to zero unless
* the global option, dhcpv6-set-tee-times is enabled. When this option is
* enabled the values are calculated as recommended by RFC 3315, Section 22.4:
*
* T1 will be set to 0.5 times the shortest preferred lifetime
* in the IA_XX option. If the "shortest" preferred lifetime is
* 0xFFFFFFFF, T1 will set to 0xFFFFFFFF.
*
* T2 will be set to 0.8 times the shortest preferred lifetime
* in the IA_XX option. If the "shortest" preferred lifetime is
* 0xFFFFFFFF, T2 will set to 0xFFFFFFFF.
*
* Note that dhcpv6-set-tee-times is intended to be transitional and will
* likely be removed in 4.4.0, leaving the behavior as getting the values
* either from the configured parameters (if you want zeros, define them as
* zeros) or by calculating them per the RFC.
*
* \param reply - pointer to the reply_state structure
* \param ia_cursor - offset of the beginning of the IA_XX option within the
* reply's outbound data buffer
*/
static void
set_reply_tee_times(struct reply_state* reply, unsigned ia_cursor)
{
struct option_cache *oc;
int set_tee_times;
/* Found out if calculated values are enabled. */
oc = lookup_option(&server_universe, reply->opt_state,
SV_DHCPV6_SET_TEE_TIMES);
set_tee_times = (oc &&
evaluate_boolean_option_cache(NULL, reply->packet,
NULL, NULL,
reply->packet->options,
reply->opt_state,
&global_scope, oc, MDL));
oc = lookup_option(&dhcp_universe, reply->opt_state,
DHO_DHCP_RENEWAL_TIME);
if (oc != NULL) {
/* dhcp-renewal-time is defined, use it */
struct data_string data;
memset(&data, 0x00, sizeof(data));
if (!evaluate_option_cache(&data, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state, &global_scope,
oc, MDL) ||
(data.len != 4)) {
log_error("Invalid renewal time.");
reply->renew = 0;
} else {
reply->renew = getULong(data.data);
}
if (data.data != NULL)
data_string_forget(&data, MDL);
} else if (set_tee_times) {
/* Setting them is enabled so T1 is either infinite or
* 0.5 * the shortest preferred lifetime in the IA_XX */
if (reply->min_prefer == INFINITE_TIME)
reply->renew = INFINITE_TIME;
else
reply->renew = reply->min_prefer / 2;
} else {
/* Default is to let the client choose */
reply->renew = 0;
}
putULong(reply->buf.data + ia_cursor + 8, reply->renew);
/* Now T2. */
oc = lookup_option(&dhcp_universe, reply->opt_state,
DHO_DHCP_REBINDING_TIME);
if (oc != NULL) {
/* dhcp-rebinding-time is defined, use it */
struct data_string data;
memset(&data, 0x00, sizeof(data));
if (!evaluate_option_cache(&data, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state, &global_scope,
oc, MDL) ||
(data.len != 4)) {
log_error("Invalid rebinding time.");
reply->rebind = 0;
} else {
reply->rebind = getULong(data.data);
}
if (data.data != NULL)
data_string_forget(&data, MDL);
} else if (set_tee_times) {
/* Setting them is enabled so T2 is either infinite or
* 0.8 * the shortest preferred lifetime in the reply */
if (reply->min_prefer == INFINITE_TIME)
reply->rebind = INFINITE_TIME;
else
reply->rebind = (reply->min_prefer / 5) * 4;
} else {
/* Default is to let the client choose */
reply->rebind = 0;
}
putULong(reply->buf.data + ia_cursor + 12, reply->rebind);
}
/*
* Releases the iasubopts in the pre-existing IA, if they are not in
* the same shared-network as the new IA.
*
* returns 1 if the release was done, 0 otherwise
*/
int
release_on_roam(struct reply_state* reply) {
struct ia_xx* old_ia = reply->old_ia;
struct iasubopt *lease = NULL;
int i;
if ((!do_release_on_roam) || old_ia == NULL
|| old_ia->num_iasubopt <= 0) {
return(0);
}
/* If the old shared-network and new are the same, client hasn't
* roamed, nothing to do. We only check the first one because you
* cannot have iasubopts on different shared-networks within a
* single ia. */
lease = old_ia->iasubopt[0];
if (lease->ipv6_pool->shared_network == reply->shared) {
return (0);
}
/* Old and new are on different shared networks so the client must
* roamed. Release the old leases. */
for (i = 0; i < old_ia->num_iasubopt; i++) {
lease = old_ia->iasubopt[i];
log_info("Client: %s roamed to new network,"
" releasing lease: %s%s",
print_hex_1(reply->client_id.len,
reply->client_id.data, 60),
pin6_addr(&lease->addr), iasubopt_plen_str(lease));
release_lease6(lease->ipv6_pool, lease);
lease->ia->cltt = cur_time;
write_ia(lease->ia);
}
return (1);
}
/*
* Convenience function which returns a string (static buffer)
* containing either a "/" followed by the prefix length or an
* empty string depending on the lease type
*/
const char *iasubopt_plen_str(struct iasubopt *lease) {
static char prefix_buf[16];
*prefix_buf = 0;
if ((lease->ia) && (lease->ia->ia_type == D6O_IA_PD)) {
sprintf(prefix_buf, "/%-d", lease->plen);
}
return (prefix_buf);
}
#ifdef NSUPDATE
/*
* Initiates DDNS updates for static v6 leases if configured to do so.
*
* The function, which must be called after the IA has been written to the
* packet, adds an iasubopt to the IA for static lease. This is done so we
* have an iasubopt to pass into ddns_updates(). A reference to the IA is
* added to the DDNS control block to ensure it and it's iasubopt remain in
* scope until the update is complete.
*
*/
void ddns_update_static6(struct reply_state* reply) {
struct iasubopt *iasub = NULL;
struct binding_scope *scope = NULL;
struct option_cache *oc = NULL;
oc = lookup_option(&server_universe, reply->opt_state, SV_DDNS_UPDATES);
if ((oc != NULL) &&
(evaluate_boolean_option_cache(NULL, reply->packet, NULL, NULL,
reply->packet->options,
reply->opt_state, NULL,
oc, MDL) == 0)) {
return;
}
oc = lookup_option(&server_universe, reply->opt_state,
SV_UPDATE_STATIC_LEASES);
if ((oc == NULL) ||
(evaluate_boolean_option_cache(NULL, reply->packet,
NULL, NULL,
reply->packet->options,
reply->opt_state, NULL,
oc, MDL) == 0)) {
return;
}
if (iasubopt_allocate(&iasub, MDL) != ISC_R_SUCCESS) {
log_fatal("No memory for iasubopt.");
}
if (ia_add_iasubopt(reply->ia, iasub, MDL) != ISC_R_SUCCESS) {
log_fatal("Could not add iasubopt.");
}
ia_reference(&iasub->ia, reply->ia, MDL);
memcpy(iasub->addr.s6_addr, reply->fixed.data, 16);
iasub->plen = 0;
iasub->prefer = MAX_TIME;
iasub->valid = MAX_TIME;
iasub->static_lease = 1;
if (!binding_scope_allocate(&scope, MDL)) {
log_fatal("Out of memory for binding scope.");
}
binding_scope_reference(&iasub->scope, scope, MDL);
ddns_updates(reply->packet, NULL, NULL, iasub, NULL, reply->opt_state);
}
#endif /* NSUPDATE */
#endif /* DHCPv6 */