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zephyr/subsys/net/ip/dhcpv4.c
Flavio Ceolin c4f7faea10 random: Include header where it is used 
Unit tests were failing to build because random header was included by
kernel_includes.h. The problem is that rand32.h includes a generated
file that is either not generated or not included when building unit
tests. Also, it is better to limit the scope of this file to where it is
used.

Signed-off-by: Flavio Ceolin <flavio.ceolin@intel.com>
2020-07-08 21:05:36 -04:00

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/** @file
* @brief DHCPv4 client related functions
*/
/*
* Copyright (c) 2017 ARM Ltd.
* Copyright (c) 2016 Intel Corporation
* Copyright (c) 2018 Vincent van der Locht
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <logging/log.h>
LOG_MODULE_REGISTER(net_dhcpv4, CONFIG_NET_DHCPV4_LOG_LEVEL);
#include <errno.h>
#include <inttypes.h>
#include <random/rand32.h>
#include <net/net_core.h>
#include <net/net_pkt.h>
#include <net/net_if.h>
#include <net/net_mgmt.h>
#include "net_private.h"
#include <net/udp.h>
#include "udp_internal.h"
#include <net/dhcpv4.h>
#include <net/dns_resolve.h>
#include "dhcpv4.h"
#include "ipv4.h"
#define PKT_WAIT_TIME K_SECONDS(1)
static sys_slist_t dhcpv4_ifaces;
static struct k_delayed_work timeout_work;
static struct net_mgmt_event_callback mgmt4_cb;
/* RFC 1497 [17] */
static const uint8_t magic_cookie[4] = { 0x63, 0x82, 0x53, 0x63 };
static const char *dhcpv4_msg_type_name(enum dhcpv4_msg_type msg_type)
__attribute__((unused));
static const char *dhcpv4_msg_type_name(enum dhcpv4_msg_type msg_type)
{
static const char * const name[] = {
"discover",
"offer",
"request",
"decline",
"ack",
"nak",
"release",
"inform"
};
__ASSERT_NO_MSG(msg_type >= 1 && msg_type <= sizeof(name));
return name[msg_type - 1];
}
/* Add magic cookie to DCHPv4 messages */
static inline bool dhcpv4_add_cookie(struct net_pkt *pkt)
{
if (net_pkt_write(pkt, (void *)magic_cookie,
ARRAY_SIZE(magic_cookie))) {
return false;
}
return true;
}
/* Add a an option with the form OPTION LENGTH VALUE. */
static bool dhcpv4_add_option_length_value(struct net_pkt *pkt, uint8_t option,
uint8_t size, const void *value)
{
if (net_pkt_write_u8(pkt, option) ||
net_pkt_write_u8(pkt, size) ||
net_pkt_write(pkt, value, size)) {
return false;
}
return true;
}
/* Add DHCPv4 message type */
static bool dhcpv4_add_msg_type(struct net_pkt *pkt, uint8_t type)
{
return dhcpv4_add_option_length_value(pkt, DHCPV4_OPTIONS_MSG_TYPE,
1, &type);
}
/* Add DHCPv4 minimum required options for server to reply.
* Can be added more if needed.
*/
static bool dhcpv4_add_req_options(struct net_pkt *pkt)
{
static uint8_t data[3] = { DHCPV4_OPTIONS_SUBNET_MASK,
DHCPV4_OPTIONS_ROUTER,
DHCPV4_OPTIONS_DNS_SERVER };
return dhcpv4_add_option_length_value(pkt, DHCPV4_OPTIONS_REQ_LIST,
ARRAY_SIZE(data), data);
}
static bool dhcpv4_add_server_id(struct net_pkt *pkt,
const struct in_addr *addr)
{
return dhcpv4_add_option_length_value(pkt, DHCPV4_OPTIONS_SERVER_ID,
4, addr->s4_addr);
}
static bool dhcpv4_add_req_ipaddr(struct net_pkt *pkt,
const struct in_addr *addr)
{
return dhcpv4_add_option_length_value(pkt, DHCPV4_OPTIONS_REQ_IPADDR,
4, addr->s4_addr);
}
#if defined(CONFIG_NET_HOSTNAME_ENABLE)
static bool dhcpv4_add_hostname(struct net_pkt *pkt,
const char *hostname, const size_t size)
{
return dhcpv4_add_option_length_value(pkt, DHCPV4_OPTIONS_HOST_NAME,
size, hostname);
}
#endif
/* Add DHCPv4 Options end, rest of the message can be padded wit zeros */
static inline bool dhcpv4_add_end(struct net_pkt *pkt)
{
if (net_pkt_write_u8(pkt, DHCPV4_OPTIONS_END)) {
return false;
}
return true;
}
/* File is empty ATM */
static inline bool dhcpv4_add_file(struct net_pkt *pkt)
{
if (net_pkt_memset(pkt, 0, SIZE_OF_FILE)) {
return false;
}
return true;
}
/* SNAME is empty ATM */
static inline bool dhcpv4_add_sname(struct net_pkt *pkt)
{
if (net_pkt_memset(pkt, 0, SIZE_OF_SNAME)) {
return false;
}
return true;
}
/* Create DHCPv4 message and add options as per message type */
static struct net_pkt *dhcpv4_create_message(struct net_if *iface, uint8_t type,
const struct in_addr *ciaddr,
const struct in_addr *src_addr,
const struct in_addr *server_addr,
bool server_id, bool requested_ip)
{
NET_PKT_DATA_ACCESS_DEFINE(dhcp_access, struct dhcp_msg);
const struct in_addr *addr;
size_t size = DHCPV4_MESSAGE_SIZE;
struct net_pkt *pkt;
struct dhcp_msg *msg;
#if defined(CONFIG_NET_HOSTNAME_ENABLE)
const char *hostname = net_hostname_get();
const size_t hostname_size = strlen(hostname);
#endif
if (src_addr == NULL) {
addr = net_ipv4_unspecified_address();
} else {
addr = src_addr;
}
if (server_id) {
size += DHCPV4_OLV_MSG_SERVER_ID;
}
if (requested_ip) {
size += DHCPV4_OLV_MSG_REQ_IPADDR;
}
if (type == DHCPV4_MSG_TYPE_DISCOVER) {
size += DHCPV4_OLV_MSG_REQ_LIST;
}
#if defined(CONFIG_NET_HOSTNAME_ENABLE)
if (hostname_size > 0) {
size += DHCPV4_OLV_MSG_HOST_NAME + hostname_size;
}
#endif
pkt = net_pkt_alloc_with_buffer(iface, size, AF_INET,
IPPROTO_UDP, K_FOREVER);
net_pkt_set_ipv4_ttl(pkt, 0xFF);
if (net_ipv4_create(pkt, addr, server_addr) ||
net_udp_create(pkt, htons(DHCPV4_CLIENT_PORT),
htons(DHCPV4_SERVER_PORT))) {
goto fail;
}
msg = (struct dhcp_msg *)net_pkt_get_data(pkt, &dhcp_access);
(void)memset(msg, 0, sizeof(struct dhcp_msg));
msg->op = DHCPV4_MSG_BOOT_REQUEST;
msg->htype = HARDWARE_ETHERNET_TYPE;
msg->hlen = HARDWARE_ETHERNET_LEN;
msg->xid = htonl(iface->config.dhcpv4.xid);
msg->flags = htons(DHCPV4_MSG_BROADCAST);
if (ciaddr) {
/* The ciaddr field was zero'd out above, if we are
* asked to send a ciaddr then fill it in now
* otherwise leave it as all zeros.
*/
memcpy(msg->ciaddr, ciaddr, 4);
}
memcpy(msg->chaddr, net_if_get_link_addr(iface)->addr,
net_if_get_link_addr(iface)->len);
if (net_pkt_set_data(pkt, &dhcp_access)) {
goto fail;
}
if (!dhcpv4_add_sname(pkt) ||
!dhcpv4_add_file(pkt) ||
!dhcpv4_add_cookie(pkt) ||
!dhcpv4_add_msg_type(pkt, type)) {
goto fail;
}
if ((server_id &&
!dhcpv4_add_server_id(pkt, &iface->config.dhcpv4.server_id)) ||
(requested_ip &&
!dhcpv4_add_req_ipaddr(pkt, &iface->config.dhcpv4.requested_ip))) {
goto fail;
}
if (type == DHCPV4_MSG_TYPE_DISCOVER && !dhcpv4_add_req_options(pkt)) {
goto fail;
}
#if defined(CONFIG_NET_HOSTNAME_ENABLE)
if (hostname_size > 0 &&
!dhcpv4_add_hostname(pkt, hostname, hostname_size)) {
goto fail;
}
#endif
if (!dhcpv4_add_end(pkt)) {
goto fail;
}
net_pkt_cursor_init(pkt);
net_ipv4_finalize(pkt, IPPROTO_UDP);
return pkt;
fail:
NET_DBG("Message creation failed");
net_pkt_unref(pkt);
return NULL;
}
/* Prepare DHCPv4 Message request and send it to peer */
static uint32_t dhcpv4_send_request(struct net_if *iface)
{
const struct in_addr *server_addr = net_ipv4_broadcast_address();
const struct in_addr *ciaddr = NULL;
const struct in_addr *src_addr = NULL;
bool with_server_id = false;
bool with_requested_ip = false;
struct net_pkt *pkt;
uint32_t timeout;
iface->config.dhcpv4.xid++;
switch (iface->config.dhcpv4.state) {
case NET_DHCPV4_DISABLED:
case NET_DHCPV4_INIT:
case NET_DHCPV4_SELECTING:
case NET_DHCPV4_BOUND:
/* Not possible */
NET_ASSERT(0, "Invalid state %s",
net_dhcpv4_state_name(iface->config.dhcpv4.state));
break;
case NET_DHCPV4_REQUESTING:
with_server_id = true;
with_requested_ip = true;
break;
case NET_DHCPV4_RENEWING:
/* Since we have an address populate the ciaddr field.
*/
ciaddr = &iface->config.dhcpv4.requested_ip;
/* UNICAST the DHCPREQUEST */
src_addr = ciaddr;
server_addr = &iface->config.dhcpv4.server_id;
/* RFC2131 4.4.5 Client MUST NOT include server
* identifier in the DHCPREQUEST.
*/
break;
case NET_DHCPV4_REBINDING:
/* Since we have an address populate the ciaddr field.
*/
ciaddr = &iface->config.dhcpv4.requested_ip;
src_addr = ciaddr;
break;
}
pkt = dhcpv4_create_message(iface, DHCPV4_MSG_TYPE_REQUEST,
ciaddr, src_addr, server_addr,
with_server_id, with_requested_ip);
if (!pkt) {
goto fail;
}
if (net_send_data(pkt) < 0) {
goto fail;
}
timeout = DHCPV4_INITIAL_RETRY_TIMEOUT << iface->config.dhcpv4.attempts;
iface->config.dhcpv4.attempts++;
NET_DBG("send request dst=%s xid=0x%x ciaddr=%s%s%s timeout=%us",
log_strdup(net_sprint_ipv4_addr(server_addr)),
iface->config.dhcpv4.xid,
ciaddr ?
log_strdup(net_sprint_ipv4_addr(ciaddr)) : "<unknown>",
with_server_id ? " +server-id" : "",
with_requested_ip ? " +requested-ip" : "",
timeout);
iface->config.dhcpv4.timer_start = k_uptime_get();
iface->config.dhcpv4.request_time = timeout;
return timeout;
fail:
if (pkt) {
net_pkt_unref(pkt);
}
return UINT32_MAX;
}
/* Prepare DHCPv4 Discover message and broadcast it */
static uint32_t dhcpv4_send_discover(struct net_if *iface)
{
struct net_pkt *pkt;
uint32_t timeout;
iface->config.dhcpv4.xid++;
pkt = dhcpv4_create_message(iface, DHCPV4_MSG_TYPE_DISCOVER,
NULL, NULL, net_ipv4_broadcast_address(),
false, false);
if (!pkt) {
goto fail;
}
if (net_send_data(pkt) < 0) {
goto fail;
}
timeout = DHCPV4_INITIAL_RETRY_TIMEOUT << iface->config.dhcpv4.attempts;
iface->config.dhcpv4.attempts++;
NET_DBG("send discover xid=0x%x timeout=%us",
iface->config.dhcpv4.xid, timeout);
iface->config.dhcpv4.timer_start = k_uptime_get();
iface->config.dhcpv4.request_time = timeout;
return timeout;
fail:
if (pkt) {
net_pkt_unref(pkt);
}
return iface->config.dhcpv4.xid %
(CONFIG_NET_DHCPV4_INITIAL_DELAY_MAX -
DHCPV4_INITIAL_DELAY_MIN) +
DHCPV4_INITIAL_DELAY_MIN;
}
static void dhcpv4_update_timeout_work(uint32_t timeout)
{
if (!k_delayed_work_remaining_get(&timeout_work) ||
(MSEC_PER_SEC * timeout) <
k_delayed_work_remaining_get(&timeout_work)) {
k_delayed_work_cancel(&timeout_work);
k_delayed_work_submit(&timeout_work, K_SECONDS(timeout));
}
}
static void dhcpv4_enter_selecting(struct net_if *iface)
{
iface->config.dhcpv4.attempts = 0U;
iface->config.dhcpv4.lease_time = 0U;
iface->config.dhcpv4.renewal_time = 0U;
iface->config.dhcpv4.rebinding_time = 0U;
iface->config.dhcpv4.state = NET_DHCPV4_SELECTING;
NET_DBG("enter state=%s",
net_dhcpv4_state_name(iface->config.dhcpv4.state));
}
static bool dhcpv4_check_timeout(int64_t start, uint32_t time, int64_t timeout)
{
start += MSEC_PER_SEC * time;
if (start < 0) {
start = -start;
}
if (start > timeout) {
return false;
}
return true;
}
static bool dhcpv4_request_timedout(struct net_if *iface, int64_t timeout)
{
return dhcpv4_check_timeout(iface->config.dhcpv4.timer_start,
iface->config.dhcpv4.request_time,
timeout);
}
static bool dhcpv4_renewal_timedout(struct net_if *iface, int64_t timeout)
{
if (!dhcpv4_check_timeout(iface->config.dhcpv4.timer_start,
iface->config.dhcpv4.renewal_time,
timeout)) {
return false;
}
iface->config.dhcpv4.state = NET_DHCPV4_RENEWING;
NET_DBG("enter state=%s",
net_dhcpv4_state_name(iface->config.dhcpv4.state));
iface->config.dhcpv4.attempts = 0U;
return true;
}
static bool dhcpv4_rebinding_timedout(struct net_if *iface, int64_t timeout)
{
if (!dhcpv4_check_timeout(iface->config.dhcpv4.timer_start,
iface->config.dhcpv4.rebinding_time,
timeout)) {
return false;
}
iface->config.dhcpv4.state = NET_DHCPV4_REBINDING;
NET_DBG("enter state=%s",
net_dhcpv4_state_name(iface->config.dhcpv4.state));
iface->config.dhcpv4.attempts = 0U;
return true;
}
static void dhcpv4_enter_requesting(struct net_if *iface)
{
iface->config.dhcpv4.attempts = 0U;
iface->config.dhcpv4.state = NET_DHCPV4_REQUESTING;
NET_DBG("enter state=%s",
net_dhcpv4_state_name(iface->config.dhcpv4.state));
dhcpv4_update_timeout_work(dhcpv4_send_request(iface));
}
static void dhcpv4_enter_bound(struct net_if *iface)
{
uint32_t renewal_time;
uint32_t rebinding_time;
renewal_time = iface->config.dhcpv4.renewal_time;
if (!renewal_time) {
/* The default renewal time rfc2131 4.4.5 */
renewal_time = iface->config.dhcpv4.lease_time / 2U;
iface->config.dhcpv4.renewal_time = renewal_time;
}
rebinding_time = iface->config.dhcpv4.rebinding_time;
if (!rebinding_time) {
/* The default rebinding time rfc2131 4.4.5 */
rebinding_time = iface->config.dhcpv4.lease_time * 875U / 1000;
iface->config.dhcpv4.rebinding_time = rebinding_time;
}
iface->config.dhcpv4.state = NET_DHCPV4_BOUND;
NET_DBG("enter state=%s renewal=%us rebinding=%us",
net_dhcpv4_state_name(iface->config.dhcpv4.state),
renewal_time, rebinding_time);
iface->config.dhcpv4.timer_start = k_uptime_get();
iface->config.dhcpv4.request_time = MIN(renewal_time, rebinding_time);
dhcpv4_update_timeout_work(iface->config.dhcpv4.request_time);
}
static uint32_t dhcph4_manage_timers(struct net_if *iface, int64_t timeout)
{
NET_DBG("iface %p state=%s", iface,
net_dhcpv4_state_name(iface->config.dhcpv4.state));
if (!dhcpv4_request_timedout(iface, timeout)) {
return iface->config.dhcpv4.request_time;
}
switch (iface->config.dhcpv4.state) {
case NET_DHCPV4_DISABLED:
break;
case NET_DHCPV4_INIT:
dhcpv4_enter_selecting(iface);
/* Fall through, as discover msg needs to be sent */
case NET_DHCPV4_SELECTING:
/* Failed to get OFFER message, send DISCOVER again */
return dhcpv4_send_discover(iface);
case NET_DHCPV4_REQUESTING:
/* Maximum number of renewal attempts failed, so start
* from the beginning.
*/
if (iface->config.dhcpv4.attempts >=
DHCPV4_MAX_NUMBER_OF_ATTEMPTS) {
NET_DBG("too many attempts, restart");
dhcpv4_enter_selecting(iface);
return dhcpv4_send_discover(iface);
}
return dhcpv4_send_request(iface);
case NET_DHCPV4_BOUND:
if (dhcpv4_renewal_timedout(iface, timeout) ||
dhcpv4_rebinding_timedout(iface, timeout)) {
return dhcpv4_send_request(iface);
}
return MIN(iface->config.dhcpv4.renewal_time,
iface->config.dhcpv4.rebinding_time);
case NET_DHCPV4_RENEWING:
case NET_DHCPV4_REBINDING:
if (iface->config.dhcpv4.attempts >=
DHCPV4_MAX_NUMBER_OF_ATTEMPTS) {
NET_DBG("too many attempts, restart");
if (!net_if_ipv4_addr_rm(iface,
&iface->config.dhcpv4.requested_ip)) {
NET_DBG("Failed to remove addr from iface");
}
/* Maximum number of renewal attempts failed, so start
* from the beginning.
*/
dhcpv4_enter_selecting(iface);
return dhcpv4_send_discover(iface);
} else {
return dhcpv4_send_request(iface);
}
}
return UINT32_MAX;
}
static void dhcpv4_timeout(struct k_work *work)
{
uint32_t timeout_update = UINT32_MAX - 1;
int64_t timeout = k_uptime_get();
struct net_if_dhcpv4 *current, *next;
ARG_UNUSED(work);
SYS_SLIST_FOR_EACH_CONTAINER_SAFE(&dhcpv4_ifaces, current, next, node) {
struct net_if *iface = CONTAINER_OF(
CONTAINER_OF(current, struct net_if_config, dhcpv4),
struct net_if, config);
uint32_t next_timeout;
next_timeout = dhcph4_manage_timers(iface, timeout);
if (next_timeout < timeout_update) {
timeout_update = next_timeout;
}
}
if (timeout_update != UINT32_MAX) {
NET_DBG("Waiting for %us", timeout_update);
k_delayed_work_submit(&timeout_work,
K_SECONDS(timeout_update));
}
}
/* Parse DHCPv4 options and retrieve relavant information
* as per RFC 2132.
*/
static bool dhcpv4_parse_options(struct net_pkt *pkt,
struct net_if *iface,
enum dhcpv4_msg_type *msg_type)
{
uint8_t cookie[4];
uint8_t length;
uint8_t type;
if (net_pkt_read(pkt, cookie, sizeof(cookie)) ||
memcmp(magic_cookie, cookie, sizeof(magic_cookie))) {
NET_DBG("Incorrect magic cookie");
return false;
}
while (!net_pkt_read_u8(pkt, &type)) {
if (type == DHCPV4_OPTIONS_END) {
NET_DBG("options_end");
return true;
}
if (net_pkt_read_u8(pkt, &length)) {
NET_ERR("option parsing, bad length");
return false;
}
switch (type) {
case DHCPV4_OPTIONS_SUBNET_MASK: {
struct in_addr netmask;
if (length != 4U) {
NET_ERR("options_subnet_mask, bad length");
return false;
}
if (net_pkt_read(pkt, netmask.s4_addr, length)) {
NET_ERR("options_subnet_mask, short packet");
return false;
}
net_if_ipv4_set_netmask(iface, &netmask);
NET_DBG("options_subnet_mask %s",
log_strdup(net_sprint_ipv4_addr(&netmask)));
break;
}
case DHCPV4_OPTIONS_ROUTER: {
struct in_addr router;
/* Router option may present 1 or more
* addresses for routers on the clients
* subnet. Routers should be listed in order
* of preference. Hence we choose the first
* and skip the rest.
*/
if (length % 4 != 0U || length < 4) {
NET_ERR("options_router, bad length");
return false;
}
if (net_pkt_read(pkt, router.s4_addr, 4) ||
net_pkt_skip(pkt, length - 4U)) {
NET_ERR("options_router, short packet");
return false;
}
NET_DBG("options_router: %s",
log_strdup(net_sprint_ipv4_addr(&router)));
net_if_ipv4_set_gw(iface, &router);
break;
}
#if defined(CONFIG_DNS_RESOLVER)
case DHCPV4_OPTIONS_DNS_SERVER: {
int i;
struct dns_resolve_context *ctx;
struct sockaddr_in dns;
const struct sockaddr *dns_servers[] = {
(struct sockaddr *)&dns, NULL
};
int status;
/* DNS server option may present 1 or more
* addresses. Each 4 bytes in length. DNS
* servers should be listed in order
* of preference. Hence we choose the first
* and skip the rest.
*/
if (length % 4 != 0U) {
NET_ERR("options_dns, bad length");
return false;
}
(void)memset(&dns, 0, sizeof(dns));
if (net_pkt_read(pkt, dns.sin_addr.s4_addr, 4) ||
net_pkt_skip(pkt, length - 4U)) {
NET_ERR("options_dns, short packet");
return false;
}
ctx = dns_resolve_get_default();
for (i = 0; i < CONFIG_DNS_NUM_CONCUR_QUERIES; i++) {
if (!ctx->queries[i].cb) {
continue;
}
dns_resolve_cancel(ctx, ctx->queries[i].id);
}
dns_resolve_close(ctx);
dns.sin_family = AF_INET;
status = dns_resolve_init(ctx, NULL, dns_servers);
if (status < 0) {
NET_DBG("options_dns, failed to set "
"resolve address: %d", status);
return false;
}
break;
}
#endif
case DHCPV4_OPTIONS_LEASE_TIME:
if (length != 4U) {
NET_ERR("options_lease_time, bad length");
return false;
}
if (net_pkt_read_be32(
pkt, &iface->config.dhcpv4.lease_time) ||
!iface->config.dhcpv4.lease_time) {
NET_ERR("options_lease_time, wrong value");
return false;
}
NET_DBG("options_lease_time: %u",
iface->config.dhcpv4.lease_time);
break;
case DHCPV4_OPTIONS_RENEWAL:
if (length != 4U) {
NET_DBG("options_renewal, bad length");
return false;
}
if (net_pkt_read_be32(
pkt, &iface->config.dhcpv4.renewal_time) ||
!iface->config.dhcpv4.renewal_time) {
NET_DBG("options_renewal, wrong value");
return false;
}
NET_DBG("options_renewal: %u",
iface->config.dhcpv4.renewal_time);
break;
case DHCPV4_OPTIONS_REBINDING:
if (length != 4U) {
NET_DBG("options_rebinding, bad length");
return false;
}
if (net_pkt_read_be32(
pkt,
&iface->config.dhcpv4.rebinding_time) ||
!iface->config.dhcpv4.rebinding_time) {
NET_DBG("options_rebinding, wrong value");
return false;
}
NET_DBG("options_rebinding: %u",
iface->config.dhcpv4.rebinding_time);
break;
case DHCPV4_OPTIONS_SERVER_ID:
if (length != 4U) {
NET_DBG("options_server_id, bad length");
return false;
}
if (net_pkt_read(
pkt,
iface->config.dhcpv4.server_id.s4_addr,
length)) {
NET_DBG("options_server_id, read err");
return false;
}
NET_DBG("options_server_id: %s",
log_strdup(net_sprint_ipv4_addr(
&iface->config.dhcpv4.server_id)));
break;
case DHCPV4_OPTIONS_MSG_TYPE: {
if (length != 1U) {
NET_DBG("options_msg_type, bad length");
return false;
}
if (net_pkt_read_u8(pkt, (uint8_t *)msg_type)) {
NET_DBG("options_msg_type, read err");
return false;
}
break;
}
default:
NET_DBG("option unknown: %d", type);
if (net_pkt_skip(pkt, length)) {
NET_DBG("option unknown, skip err");
return false;
}
break;
}
}
/* Invalid case: Options without DHCPV4_OPTIONS_END. */
return false;
}
static inline void dhcpv4_handle_msg_offer(struct net_if *iface)
{
switch (iface->config.dhcpv4.state) {
case NET_DHCPV4_DISABLED:
case NET_DHCPV4_INIT:
case NET_DHCPV4_REQUESTING:
case NET_DHCPV4_RENEWING:
case NET_DHCPV4_REBINDING:
case NET_DHCPV4_BOUND:
break;
case NET_DHCPV4_SELECTING:
dhcpv4_enter_requesting(iface);
break;
}
}
static void dhcpv4_handle_msg_ack(struct net_if *iface)
{
switch (iface->config.dhcpv4.state) {
case NET_DHCPV4_DISABLED:
case NET_DHCPV4_INIT:
case NET_DHCPV4_SELECTING:
case NET_DHCPV4_BOUND:
break;
case NET_DHCPV4_REQUESTING:
NET_INFO("Received: %s",
log_strdup(net_sprint_ipv4_addr(
&iface->config.dhcpv4.requested_ip)));
if (!net_if_ipv4_addr_add(iface,
&iface->config.dhcpv4.requested_ip,
NET_ADDR_DHCP,
iface->config.dhcpv4.lease_time)) {
NET_DBG("Failed to add IPv4 addr to iface %p", iface);
return;
}
dhcpv4_enter_bound(iface);
break;
case NET_DHCPV4_RENEWING:
case NET_DHCPV4_REBINDING:
/* TODO: If the renewal is success, update only
* vlifetime on iface.
*/
dhcpv4_enter_bound(iface);
break;
}
}
static void dhcpv4_handle_msg_nak(struct net_if *iface)
{
switch (iface->config.dhcpv4.state) {
case NET_DHCPV4_DISABLED:
case NET_DHCPV4_INIT:
case NET_DHCPV4_SELECTING:
case NET_DHCPV4_RENEWING:
case NET_DHCPV4_BOUND:
break;
case NET_DHCPV4_REQUESTING:
case NET_DHCPV4_REBINDING:
/* Restart the configuration process. */
dhcpv4_enter_selecting(iface);
break;
}
}
static void dhcpv4_handle_reply(struct net_if *iface,
enum dhcpv4_msg_type msg_type)
{
NET_DBG("state=%s msg=%s",
net_dhcpv4_state_name(iface->config.dhcpv4.state),
dhcpv4_msg_type_name(msg_type));
switch (msg_type) {
case DHCPV4_MSG_TYPE_OFFER:
dhcpv4_handle_msg_offer(iface);
break;
case DHCPV4_MSG_TYPE_ACK:
dhcpv4_handle_msg_ack(iface);
break;
case DHCPV4_MSG_TYPE_NAK:
dhcpv4_handle_msg_nak(iface);
break;
default:
NET_DBG("ignore message");
break;
}
}
static enum net_verdict net_dhcpv4_input(struct net_conn *conn,
struct net_pkt *pkt,
union net_ip_header *ip_hdr,
union net_proto_header *proto_hdr,
void *user_data)
{
NET_PKT_DATA_ACCESS_DEFINE(dhcp_access, struct dhcp_msg);
enum dhcpv4_msg_type msg_type = 0;
struct dhcp_msg *msg;
struct net_if *iface;
if (!conn) {
NET_DBG("Invalid connection");
return NET_DROP;
}
if (!pkt) {
NET_DBG("Invalid packet");
return NET_DROP;
}
iface = net_pkt_iface(pkt);
if (!iface) {
NET_DBG("no iface");
return NET_DROP;
}
/* If the message is not DHCP then continue passing to
* related handlers.
*/
if (net_pkt_get_len(pkt) < NET_IPV4UDPH_LEN + sizeof(struct dhcp_msg)) {
NET_DBG("Input msg is not related to DHCPv4");
return NET_CONTINUE;
}
net_pkt_cursor_init(pkt);
if (net_pkt_skip(pkt, NET_IPV4UDPH_LEN)) {
return NET_DROP;
}
msg = (struct dhcp_msg *)net_pkt_get_data(pkt, &dhcp_access);
if (!msg) {
return NET_DROP;
}
NET_DBG("Received dhcp msg [op=0x%x htype=0x%x hlen=%u xid=0x%x "
"secs=%u flags=0x%x chaddr=%s",
msg->op, msg->htype, msg->hlen, ntohl(msg->xid),
msg->secs, msg->flags,
log_strdup(net_sprint_ll_addr(msg->chaddr, 6)));
NET_DBG(" ciaddr=%d.%d.%d.%d",
msg->ciaddr[0], msg->ciaddr[1], msg->ciaddr[2], msg->ciaddr[3]);
NET_DBG(" yiaddr=%d.%d.%d.%d",
msg->yiaddr[0], msg->yiaddr[1], msg->yiaddr[2], msg->yiaddr[3]);
NET_DBG(" siaddr=%d.%d.%d.%d",
msg->siaddr[0], msg->siaddr[1], msg->siaddr[2], msg->siaddr[3]);
NET_DBG(" giaddr=%d.%d.%d.%d]",
msg->giaddr[0], msg->giaddr[1], msg->giaddr[2], msg->giaddr[3]);
if (!(msg->op == DHCPV4_MSG_BOOT_REPLY &&
iface->config.dhcpv4.xid == ntohl(msg->xid) &&
!memcmp(msg->chaddr, net_if_get_link_addr(iface)->addr,
net_if_get_link_addr(iface)->len))) {
NET_DBG("Unexpected op (%d), xid (%x vs %x) or chaddr",
msg->op, iface->config.dhcpv4.xid, ntohl(msg->xid));
return NET_DROP;
}
memcpy(iface->config.dhcpv4.requested_ip.s4_addr,
msg->yiaddr, sizeof(msg->yiaddr));
net_pkt_acknowledge_data(pkt, &dhcp_access);
/* SNAME, FILE are not used at the moment, skip it */
if (net_pkt_skip(pkt, SIZE_OF_SNAME + SIZE_OF_FILE)) {
NET_DBG("short packet while skipping sname");
return NET_DROP;
}
if (!dhcpv4_parse_options(pkt, iface, &msg_type)) {
return NET_DROP;
}
net_pkt_unref(pkt);
dhcpv4_handle_reply(iface, msg_type);
return NET_OK;
}
static void dhcpv4_iface_event_handler(struct net_mgmt_event_callback *cb,
uint32_t mgmt_event, struct net_if *iface)
{
sys_snode_t *node = NULL;
SYS_SLIST_FOR_EACH_NODE(&dhcpv4_ifaces, node) {
if (node == &iface->config.dhcpv4.node) {
break;
}
}
if (node == NULL) {
return;
}
if (mgmt_event == NET_EVENT_IF_DOWN) {
NET_DBG("Interface %p going down", iface);
if (iface->config.dhcpv4.state == NET_DHCPV4_BOUND) {
iface->config.dhcpv4.attempts = 0U;
iface->config.dhcpv4.state = NET_DHCPV4_RENEWING;
NET_DBG("enter state=%s", net_dhcpv4_state_name(
iface->config.dhcpv4.state));
}
} else if (mgmt_event == NET_EVENT_IF_UP) {
NET_DBG("Interface %p coming up", iface);
/* We should not call dhcpv4_send_request() directly here as
* the CONFIG_NET_MGMT_EVENT_STACK_SIZE is not large
* enough. Instead we can force a request timeout
* which will then call dhcpv4_send_request() automatically.
*/
iface->config.dhcpv4.timer_start = k_uptime_get() - 1;
iface->config.dhcpv4.request_time = 0U;
k_delayed_work_cancel(&timeout_work);
k_delayed_work_submit(&timeout_work, K_NO_WAIT);
}
}
const char *net_dhcpv4_state_name(enum net_dhcpv4_state state)
{
static const char * const name[] = {
"disabled",
"init",
"selecting",
"requesting",
"renewing",
"rebinding",
"bound",
};
__ASSERT_NO_MSG(state >= 0 && state < sizeof(name));
return name[state];
}
void net_dhcpv4_start(struct net_if *iface)
{
uint32_t timeout;
uint32_t entropy;
switch (iface->config.dhcpv4.state) {
case NET_DHCPV4_DISABLED:
iface->config.dhcpv4.state = NET_DHCPV4_INIT;
NET_DBG("iface %p state=%s", iface,
net_dhcpv4_state_name(iface->config.dhcpv4.state));
iface->config.dhcpv4.attempts = 0U;
iface->config.dhcpv4.lease_time = 0U;
iface->config.dhcpv4.renewal_time = 0U;
iface->config.dhcpv4.server_id.s_addr = 0U;
iface->config.dhcpv4.requested_ip.s_addr = 0U;
/* We need entropy for both an XID and a random delay
* before sending the initial discover message.
*/
entropy = sys_rand32_get();
/* A DHCP client MUST choose xid's in such a way as to
* minimize the change of using and xid identical to
* one used by another client. Choose a random xid st
* startup and increment it on each new request.
*/
iface->config.dhcpv4.xid = entropy;
/* RFC2131 4.1.1 requires we wait a random period
* between 1 and 10 seconds before sending the initial
* discover.
*/
timeout = entropy %
(CONFIG_NET_DHCPV4_INITIAL_DELAY_MAX -
DHCPV4_INITIAL_DELAY_MIN) +
DHCPV4_INITIAL_DELAY_MIN;
NET_DBG("wait timeout=%us", timeout);
if (sys_slist_is_empty(&dhcpv4_ifaces)) {
net_mgmt_add_event_callback(&mgmt4_cb);
}
sys_slist_append(&dhcpv4_ifaces,
&iface->config.dhcpv4.node);
iface->config.dhcpv4.timer_start = k_uptime_get();
iface->config.dhcpv4.request_time = timeout;
dhcpv4_update_timeout_work(timeout);
break;
case NET_DHCPV4_INIT:
case NET_DHCPV4_SELECTING:
case NET_DHCPV4_REQUESTING:
case NET_DHCPV4_RENEWING:
case NET_DHCPV4_REBINDING:
case NET_DHCPV4_BOUND:
break;
}
}
void net_dhcpv4_stop(struct net_if *iface)
{
switch (iface->config.dhcpv4.state) {
case NET_DHCPV4_DISABLED:
break;
case NET_DHCPV4_RENEWING:
case NET_DHCPV4_BOUND:
if (!net_if_ipv4_addr_rm(iface,
&iface->config.dhcpv4.requested_ip)) {
NET_DBG("Failed to remove addr from iface");
}
/* Fall through */
case NET_DHCPV4_INIT:
case NET_DHCPV4_SELECTING:
case NET_DHCPV4_REQUESTING:
case NET_DHCPV4_REBINDING:
iface->config.dhcpv4.state = NET_DHCPV4_DISABLED;
NET_DBG("state=%s",
net_dhcpv4_state_name(iface->config.dhcpv4.state));
sys_slist_find_and_remove(&dhcpv4_ifaces,
&iface->config.dhcpv4.node);
if (sys_slist_is_empty(&dhcpv4_ifaces)) {
k_delayed_work_cancel(&timeout_work);
net_mgmt_del_event_callback(&mgmt4_cb);
}
break;
}
}
int net_dhcpv4_init(void)
{
struct sockaddr local_addr;
int ret;
NET_DBG("");
net_ipaddr_copy(&net_sin(&local_addr)->sin_addr,
net_ipv4_unspecified_address());
local_addr.sa_family = AF_INET;
/* Register UDP input callback on
* DHCPV4_SERVER_PORT(67) and DHCPV4_CLIENT_PORT(68) for
* all dhcpv4 related incoming packets.
*/
ret = net_udp_register(AF_INET, NULL, &local_addr,
DHCPV4_SERVER_PORT,
DHCPV4_CLIENT_PORT,
net_dhcpv4_input, NULL, NULL);
if (ret < 0) {
NET_DBG("UDP callback registration failed");
return ret;
}
k_delayed_work_init(&timeout_work, dhcpv4_timeout);
/* Catch network interface UP or DOWN events and renew the address
* if interface is coming back up again.
*/
net_mgmt_init_event_callback(&mgmt4_cb, dhcpv4_iface_event_handler,
NET_EVENT_IF_DOWN | NET_EVENT_IF_UP);
return 0;
}
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