static bool run_tests(void)
{
struct net_pkt *pkt, *pkt2;
struct net_buf *frag;
struct net_if *iface;
struct net_if_addr *ifaddr;
struct net_arp_hdr *arp_hdr;
struct net_ipv4_hdr *ipv4;
struct net_eth_hdr *eth_hdr;
int len;
struct in_addr dst = { { { 192, 168, 0, 2 } } };
struct in_addr dst_far = { { { 10, 11, 12, 13 } } };
struct in_addr dst_far2 = { { { 172, 16, 14, 186 } } };
struct in_addr src = { { { 192, 168, 0, 1 } } };
struct in_addr netmask = { { { 255, 255, 255, 0 } } };
struct in_addr gw = { { { 192, 168, 0, 42 } } };
net_arp_init();
iface = net_if_get_default();
net_if_ipv4_set_gw(iface, &gw);
net_if_ipv4_set_netmask(iface, &netmask);
/* Unicast test */
ifaddr = net_if_ipv4_addr_add(iface,
&src,
NET_ADDR_MANUAL,
0);
ifaddr->addr_state = NET_ADDR_PREFERRED;
/* Application data for testing */
pkt = net_pkt_get_reserve_tx(sizeof(struct net_eth_hdr), K_FOREVER);
if (!pkt) {
printk("Out of mem TX\n");
return false;
}
frag = net_pkt_get_frag(pkt, K_FOREVER);
if (!frag) {
printk("Out of mem DATA\n");
return false;
}
net_pkt_frag_add(pkt, frag);
net_pkt_set_iface(pkt, iface);
setup_eth_header(iface, pkt, &hwaddr, NET_ETH_PTYPE_IP);
len = strlen(app_data);
if (net_pkt_ll_reserve(pkt) != sizeof(struct net_eth_hdr)) {
printk("LL reserve invalid, should be %zd was %d\n",
sizeof(struct net_eth_hdr),
net_pkt_ll_reserve(pkt));
return false;
}
ipv4 = (struct net_ipv4_hdr *)net_buf_add(frag,
sizeof(struct net_ipv4_hdr));
net_ipaddr_copy(&ipv4->src, &src);
net_ipaddr_copy(&ipv4->dst, &dst);
memcpy(net_buf_add(frag, len), app_data, len);
pkt2 = net_arp_prepare(pkt);
/* pkt2 is the ARP packet and pkt is the IPv4 packet and it was
* stored in ARP table.
*/
if (pkt2 == pkt) {
/* The packets cannot be the same as the ARP cache has
* still room for the pkt.
*/
printk("ARP cache should still have free space\n");
return false;
}
if (!pkt2) {
printk("ARP pkt is empty\n");
return false;
}
/* The ARP cache should now have a link to pending net_pkt
* that is to be sent after we have got an ARP reply.
*/
if (!pkt->frags) {
printk("Pending pkt fragment is NULL\n");
return false;
}
pending_pkt = pkt;
/* pkt2 should contain the arp header, verify it */
if (memcmp(net_pkt_ll(pkt2), net_eth_broadcast_addr(),
sizeof(struct net_eth_addr))) {
printk("ARP ETH dest address invalid\n");
net_hexdump("ETH dest wrong ", net_pkt_ll(pkt2),
sizeof(struct net_eth_addr));
net_hexdump("ETH dest correct",
(u8_t *)net_eth_broadcast_addr(),
sizeof(struct net_eth_addr));
return false;
}
if (memcmp(net_pkt_ll(pkt2) + sizeof(struct net_eth_addr),
iface->link_addr.addr,
sizeof(struct net_eth_addr))) {
printk("ARP ETH source address invalid\n");
net_hexdump("ETH src correct",
iface->link_addr.addr,
sizeof(struct net_eth_addr));
net_hexdump("ETH src wrong ",
net_pkt_ll(pkt2) + sizeof(struct net_eth_addr),
sizeof(struct net_eth_addr));
return false;
}
arp_hdr = NET_ARP_HDR(pkt2);
eth_hdr = NET_ETH_HDR(pkt2);
if (eth_hdr->type != htons(NET_ETH_PTYPE_ARP)) {
printk("ETH type 0x%x, should be 0x%x\n",
eth_hdr->type, htons(NET_ETH_PTYPE_ARP));
return false;
}
if (arp_hdr->hwtype != htons(NET_ARP_HTYPE_ETH)) {
printk("ARP hwtype 0x%x, should be 0x%x\n",
arp_hdr->hwtype, htons(NET_ARP_HTYPE_ETH));
return false;
}
if (arp_hdr->protocol != htons(NET_ETH_PTYPE_IP)) {
printk("ARP protocol 0x%x, should be 0x%x\n",
arp_hdr->protocol, htons(NET_ETH_PTYPE_IP));
return false;
}
if (arp_hdr->hwlen != sizeof(struct net_eth_addr)) {
printk("ARP hwlen 0x%x, should be 0x%zx\n",
arp_hdr->hwlen, sizeof(struct net_eth_addr));
return false;
}
if (arp_hdr->protolen != sizeof(struct in_addr)) {
printk("ARP IP addr len 0x%x, should be 0x%zx\n",
arp_hdr->protolen, sizeof(struct in_addr));
return false;
}
if (arp_hdr->opcode != htons(NET_ARP_REQUEST)) {
printk("ARP opcode 0x%x, should be 0x%x\n",
arp_hdr->opcode, htons(NET_ARP_REQUEST));
return false;
}
if (!net_ipv4_addr_cmp(&arp_hdr->dst_ipaddr,
&NET_IPV4_HDR(pkt)->dst)) {
char out[sizeof("xxx.xxx.xxx.xxx")];
snprintk(out, sizeof(out), "%s",
net_sprint_ipv4_addr(&arp_hdr->dst_ipaddr));
printk("ARP IP dest invalid %s, should be %s", out,
net_sprint_ipv4_addr(&NET_IPV4_HDR(pkt)->dst));
return false;
}
if (!net_ipv4_addr_cmp(&arp_hdr->src_ipaddr,
&NET_IPV4_HDR(pkt)->src)) {
char out[sizeof("xxx.xxx.xxx.xxx")];
snprintk(out, sizeof(out), "%s",
net_sprint_ipv4_addr(&arp_hdr->src_ipaddr));
printk("ARP IP src invalid %s, should be %s", out,
net_sprint_ipv4_addr(&NET_IPV4_HDR(pkt)->src));
return false;
}
/* We could have send the new ARP request but for this test we
* just free it.
*/
net_pkt_unref(pkt2);
if (pkt->ref != 2) {
printk("ARP cache should own the original packet\n");
return false;
}
/* Then a case where target is not in the same subnet */
net_ipaddr_copy(&ipv4->dst, &dst_far);
pkt2 = net_arp_prepare(pkt);
if (pkt2 == pkt) {
printk("ARP cache should not find anything\n");
return false;
}
if (!pkt2) {
printk("ARP pkt2 is empty\n");
return false;
}
arp_hdr = NET_ARP_HDR(pkt2);
if (!net_ipv4_addr_cmp(&arp_hdr->dst_ipaddr, &iface->ipv4.gw)) {
char out[sizeof("xxx.xxx.xxx.xxx")];
snprintk(out, sizeof(out), "%s",
net_sprint_ipv4_addr(&arp_hdr->dst_ipaddr));
printk("ARP IP dst invalid %s, should be %s\n", out,
net_sprint_ipv4_addr(&iface->ipv4.gw));
return false;
}
net_pkt_unref(pkt2);
/* Try to find the same destination again, this should fail as there
* is a pending request in ARP cache.
*/
net_ipaddr_copy(&ipv4->dst, &dst_far);
/* Make sure prepare will not free the pkt because it will be
* needed in the later test case.
*/
net_pkt_ref(pkt);
pkt2 = net_arp_prepare(pkt);
if (!pkt2) {
printk("ARP cache is not sending the request again\n");
return false;
}
net_pkt_unref(pkt2);
/* Try to find the different destination, this should fail too
* as the cache table should be full.
*/
net_ipaddr_copy(&ipv4->dst, &dst_far2);
/* Make sure prepare will not free the pkt because it will be
* needed in the next test case.
*/
net_pkt_ref(pkt);
pkt2 = net_arp_prepare(pkt);
if (!pkt2) {
printk("ARP cache did not send a req\n");
return false;
}
/* Restore the original address so that following test case can
* work properly.
*/
net_ipaddr_copy(&ipv4->dst, &dst);
/* The arp request packet is now verified, create an arp reply.
* The previous value of pkt is stored in arp table and is not lost.
*/
pkt = net_pkt_get_reserve_rx(sizeof(struct net_eth_hdr), K_FOREVER);
if (!pkt) {
printk("Out of mem RX reply\n");
return false;
}
printk("%d pkt %p\n", __LINE__, pkt);
frag = net_pkt_get_frag(pkt, K_FOREVER);
if (!frag) {
printk("Out of mem DATA reply\n");
return false;
}
printk("%d frag %p\n", __LINE__, frag);
net_pkt_frag_add(pkt, frag);
net_pkt_set_iface(pkt, iface);
arp_hdr = NET_ARP_HDR(pkt);
net_buf_add(frag, sizeof(struct net_arp_hdr));
net_ipaddr_copy(&arp_hdr->dst_ipaddr, &dst);
net_ipaddr_copy(&arp_hdr->src_ipaddr, &src);
pkt2 = prepare_arp_reply(iface, pkt, &hwaddr);
if (!pkt2) {
printk("ARP reply generation failed.");
return false;
}
/* The pending packet should now be sent */
switch (net_arp_input(pkt2)) {
case NET_OK:
case NET_CONTINUE:
break;
case NET_DROP:
break;
}
/* Yielding so that network interface TX thread can proceed. */
k_yield();
if (send_status < 0) {
printk("ARP reply was not sent\n");
return false;
}
if (pkt->ref != 1) {
printk("ARP cache should no longer own the original packet\n");
return false;
}
net_pkt_unref(pkt);
/* Then feed in ARP request */
pkt = net_pkt_get_reserve_rx(sizeof(struct net_eth_hdr), K_FOREVER);
if (!pkt) {
printk("Out of mem RX request\n");
return false;
}
frag = net_pkt_get_frag(pkt, K_FOREVER);
if (!frag) {
printk("Out of mem DATA request\n");
return false;
}
net_pkt_frag_add(pkt, frag);
net_pkt_set_iface(pkt, iface);
send_status = -EINVAL;
arp_hdr = NET_ARP_HDR(pkt);
net_buf_add(frag, sizeof(struct net_arp_hdr));
net_ipaddr_copy(&arp_hdr->dst_ipaddr, &src);
net_ipaddr_copy(&arp_hdr->src_ipaddr, &dst);
setup_eth_header(iface, pkt, &hwaddr, NET_ETH_PTYPE_ARP);
pkt2 = prepare_arp_request(iface, pkt, &hwaddr);
if (!pkt2) {
printk("ARP request generation failed.");
return false;
}
req_test = true;
switch (net_arp_input(pkt2)) {
case NET_OK:
case NET_CONTINUE:
break;
case NET_DROP:
break;
}
/* Yielding so that network interface TX thread can proceed. */
k_yield();
if (send_status < 0) {
printk("ARP req was not sent\n");
return false;
}
net_pkt_unref(pkt);
printk("Network ARP checks passed\n");
return true;
}
/*
* Parse DHCPv4 options and retrieve relavant information
* as per RFC 2132.
*/
static enum net_verdict parse_options(struct net_if *iface, struct net_buf *buf,
uint16_t offset, uint8_t *msg_type)
{
struct net_buf *frag;
uint8_t cookie[4];
uint8_t length;
uint8_t type;
uint16_t pos;
bool end = false;
frag = net_nbuf_read(buf, offset, &pos, sizeof(magic_cookie),
(uint8_t *)cookie);
if (!frag || memcmp(magic_cookie, cookie, sizeof(magic_cookie))) {
NET_DBG("Incorrect magic cookie");
return NET_DROP;
}
while (frag) {
frag = net_nbuf_read_u8(frag, pos, &pos, &type);
if (type == DHCPV4_OPTIONS_END) {
NET_DBG("options_end");
end = true;
return NET_OK;
}
frag = net_nbuf_read_u8(frag, pos, &pos, &length);
if (!frag) {
NET_ERR("option parsing, bad length");
return NET_DROP;
}
switch (type) {
case DHCPV4_OPTIONS_SUBNET_MASK: {
struct in_addr netmask;
if (length != 4) {
NET_ERR("options_subnet_mask, bad length");
return NET_DROP;
}
frag = net_nbuf_read(frag, pos, &pos, length,
netmask.s4_addr);
if (!frag && pos) {
NET_ERR("options_subnet_mask, short packet");
return NET_DROP;
}
net_if_ipv4_set_netmask(iface, &netmask);
NET_DBG("options_subnet_mask %s",
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 != 0 || length < 4) {
NET_ERR("options_router, bad length");
return NET_DROP;
}
frag = net_nbuf_read(frag, pos, &pos, 4,
router.s4_addr);
frag = net_nbuf_skip(frag, pos, &pos, length - 4);
if (!frag && pos) {
NET_ERR("options_router, short packet");
return NET_DROP;
}
NET_DBG("options_router: %s",
net_sprint_ipv4_addr(&router));
net_if_ipv4_set_gw(iface, &router);
break;
}
case DHCPV4_OPTIONS_LEASE_TIME:
if (length != 4) {
NET_ERR("options_lease_time, bad length");
return NET_DROP;
}
frag = net_nbuf_read_be32(frag, pos, &pos,
&iface->dhcpv4.lease_time);
NET_DBG("options_lease_time: %u",
iface->dhcpv4.lease_time);
if (!iface->dhcpv4.lease_time) {
return NET_DROP;
}
break;
case DHCPV4_OPTIONS_RENEWAL:
if (length != 4) {
NET_DBG("options_renewal, bad length");
return NET_DROP;
}
frag = net_nbuf_read_be32(frag, pos, &pos,
&iface->dhcpv4.renewal_time);
NET_DBG("options_renewal: %u",
iface->dhcpv4.renewal_time);
if (!iface->dhcpv4.renewal_time) {
return NET_DROP;
}
break;
case DHCPV4_OPTIONS_SERVER_ID:
if (length != 4) {
NET_DBG("options_server_id, bad length");
return NET_DROP;
}
frag = net_nbuf_read(frag, pos, &pos, length,
iface->dhcpv4.server_id.s4_addr);
NET_DBG("options_server_id: %s",
net_sprint_ipv4_addr(&iface->dhcpv4.server_id));
break;
case DHCPV4_OPTIONS_MSG_TYPE:
if (length != 1) {
NET_DBG("options_msg_type, bad length");
return NET_DROP;
}
frag = net_nbuf_read_u8(frag, pos, &pos, msg_type);
break;
default:
NET_DBG("option unknown: %d", type);
frag = net_nbuf_skip(frag, pos, &pos, length);
break;
}
if (!frag && pos) {
return NET_DROP;
}
}
if (!end) {
return NET_DROP;
}
return NET_OK;
}
