/* Print an IPv6 header by using LWIP_DEBUGF
* @param p an IPv6 packet, p->payload pointing to the IPv6 header
*/
void
ip6_debug_print(struct pbuf *p)
{
struct ip6_hdr *ip6hdr = (struct ip6_hdr *)p->payload;
LWIP_UNUSED_ARG(ip6hdr);
LWIP_DEBUGF(IP6_DEBUG, ("IPv6 header:\n"));
LWIP_DEBUGF(IP6_DEBUG, ("+-------------------------------+\n"));
LWIP_DEBUGF(IP6_DEBUG, ("| %2"U16_F" | %3"U16_F" | %7"U32_F" | (ver, class, flow)\n",
IP6H_V(ip6hdr),
IP6H_TC(ip6hdr),
IP6H_FL(ip6hdr)));
LWIP_DEBUGF(IP6_DEBUG, ("+-------------------------------+\n"));
LWIP_DEBUGF(IP6_DEBUG, ("| %5"U16_F" | %3"U16_F" | %3"U16_F" | (plen, nexth, hopl)\n",
IP6H_PLEN(ip6hdr),
IP6H_NEXTH(ip6hdr),
IP6H_HOPLIM(ip6hdr)));
LWIP_DEBUGF(IP6_DEBUG, ("+-------------------------------+\n"));
LWIP_DEBUGF(IP6_DEBUG, ("| %4"X32_F" | %4"X32_F" | %4"X32_F" | %4"X32_F" | (src)\n",
IP6_ADDR_BLOCK1(&(ip6hdr->src)),
IP6_ADDR_BLOCK2(&(ip6hdr->src)),
IP6_ADDR_BLOCK3(&(ip6hdr->src)),
IP6_ADDR_BLOCK4(&(ip6hdr->src))));
LWIP_DEBUGF(IP6_DEBUG, ("| %4"X32_F" | %4"X32_F" | %4"X32_F" | %4"X32_F" |\n",
IP6_ADDR_BLOCK5(&(ip6hdr->src)),
IP6_ADDR_BLOCK6(&(ip6hdr->src)),
IP6_ADDR_BLOCK7(&(ip6hdr->src)),
IP6_ADDR_BLOCK8(&(ip6hdr->src))));
LWIP_DEBUGF(IP6_DEBUG, ("+-------------------------------+\n"));
LWIP_DEBUGF(IP6_DEBUG, ("| %4"X32_F" | %4"X32_F" | %4"X32_F" | %4"X32_F" | (dest)\n",
IP6_ADDR_BLOCK1(&(ip6hdr->dest)),
IP6_ADDR_BLOCK2(&(ip6hdr->dest)),
IP6_ADDR_BLOCK3(&(ip6hdr->dest)),
IP6_ADDR_BLOCK4(&(ip6hdr->dest))));
LWIP_DEBUGF(IP6_DEBUG, ("| %4"X32_F" | %4"X32_F" | %4"X32_F" | %4"X32_F" |\n",
IP6_ADDR_BLOCK5(&(ip6hdr->dest)),
IP6_ADDR_BLOCK6(&(ip6hdr->dest)),
IP6_ADDR_BLOCK7(&(ip6hdr->dest)),
IP6_ADDR_BLOCK8(&(ip6hdr->dest))));
LWIP_DEBUGF(IP6_DEBUG, ("+-------------------------------+\n"));
}
/**
* This function is called by the network interface device driver when
* an IPv6 packet is received. The function does the basic checks of the
* IP header such as packet size being at least larger than the header
* size etc. If the packet was not destined for us, the packet is
* forwarded (using ip6_forward).
*
* Finally, the packet is sent to the upper layer protocol input function.
*
* @param p the received IPv6 packet (p->payload points to IPv6 header)
* @param inp the netif on which this packet was received
* @return ERR_OK if the packet was processed (could return ERR_* if it wasn't
* processed, but currently always returns ERR_OK)
*/
err_t
ip6_input(struct pbuf *p, struct netif *inp)
{
struct ip6_hdr *ip6hdr;
struct netif *netif;
u8_t nexth;
u16_t hlen; /* the current header length */
u8_t i;
#if 0 /*IP_ACCEPT_LINK_LAYER_ADDRESSING*/
@todo
int check_ip_src=1;
#endif /* IP_ACCEPT_LINK_LAYER_ADDRESSING */
IP6_STATS_INC(ip6.recv);
/* identify the IP header */
ip6hdr = (struct ip6_hdr *)p->payload;
if (IP6H_V(ip6hdr) != 6) {
LWIP_DEBUGF(IP6_DEBUG | LWIP_DBG_LEVEL_WARNING, ("IPv6 packet dropped due to bad version number %"U32_F"\n",
IP6H_V(ip6hdr)));
pbuf_free(p);
IP6_STATS_INC(ip6.err);
IP6_STATS_INC(ip6.drop);
return ERR_OK;
}
#ifdef LWIP_HOOK_IP6_INPUT
if (LWIP_HOOK_IP6_INPUT(p, inp)) {
/* the packet has been eaten */
return ERR_OK;
}
#endif
/* header length exceeds first pbuf length, or ip length exceeds total pbuf length? */
if ((IP6_HLEN > p->len) || ((IP6H_PLEN(ip6hdr) + IP6_HLEN) > p->tot_len)) {
if (IP6_HLEN > p->len) {
LWIP_DEBUGF(IP6_DEBUG | LWIP_DBG_LEVEL_SERIOUS,
("IPv6 header (len %"U16_F") does not fit in first pbuf (len %"U16_F"), IP packet dropped.\n",
IP6_HLEN, p->len));
}
if ((IP6H_PLEN(ip6hdr) + IP6_HLEN) > p->tot_len) {
LWIP_DEBUGF(IP6_DEBUG | LWIP_DBG_LEVEL_SERIOUS,
("IPv6 (plen %"U16_F") is longer than pbuf (len %"U16_F"), IP packet dropped.\n",
IP6H_PLEN(ip6hdr) + IP6_HLEN, p->tot_len));
}
/* free (drop) packet pbufs */
pbuf_free(p);
IP6_STATS_INC(ip6.lenerr);
IP6_STATS_INC(ip6.drop);
return ERR_OK;
}
/* Trim pbuf. This should have been done at the netif layer,
* but we'll do it anyway just to be sure that its done. */
pbuf_realloc(p, IP6_HLEN + IP6H_PLEN(ip6hdr));
/* copy IP addresses to aligned ip6_addr_t */
ip_addr_copy_from_ip6(ip_data.current_iphdr_dest, ip6hdr->dest);
ip_addr_copy_from_ip6(ip_data.current_iphdr_src, ip6hdr->src);
/* current header pointer. */
ip_data.current_ip6_header = ip6hdr;
/* In netif, used in case we need to send ICMPv6 packets back. */
ip_data.current_netif = inp;
ip_data.current_input_netif = inp;
/* match packet against an interface, i.e. is this packet for us? */
if (ip6_addr_ismulticast(ip6_current_dest_addr())) {
/* Always joined to multicast if-local and link-local all-nodes group. */
if (ip6_addr_isallnodes_iflocal(ip6_current_dest_addr()) ||
ip6_addr_isallnodes_linklocal(ip6_current_dest_addr())) {
netif = inp;
}
#if LWIP_IPV6_MLD
else if (mld6_lookfor_group(inp, ip6_current_dest_addr())) {
netif = inp;
}
#else /* LWIP_IPV6_MLD */
else if (ip6_addr_issolicitednode(ip6_current_dest_addr())) {
/* Filter solicited node packets when MLD is not enabled
* (for Neighbor discovery). */
netif = NULL;
for (i = 0; i < LWIP_IPV6_NUM_ADDRESSES; i++) {
if (ip6_addr_isvalid(netif_ip6_addr_state(inp, i)) &&
ip6_addr_cmp_solicitednode(ip6_current_dest_addr(), netif_ip6_addr(inp, i))) {
netif = inp;
LWIP_DEBUGF(IP6_DEBUG, ("ip6_input: solicited node packet accepted on interface %c%c\n",
netif->name[0], netif->name[1]));
break;
}
}
}
#endif /* LWIP_IPV6_MLD */
else {
netif = NULL;
}
} else {
/* start trying with inp. if that's not acceptable, start walking the
list of configured netifs.
'first' is used as a boolean to mark whether we started walking the list */
int first = 1;
netif = inp;
do {
/* interface is up? */
if (netif_is_up(netif)) {
/* unicast to this interface address? address configured? */
for (i = 0; i < LWIP_IPV6_NUM_ADDRESSES; i++) {
if (ip6_addr_isvalid(netif_ip6_addr_state(netif, i)) &&
ip6_addr_cmp(ip6_current_dest_addr(), netif_ip6_addr(netif, i))) {
/* exit outer loop */
goto netif_found;
}
}
}
if (ip6_addr_islinklocal(ip6_current_dest_addr())) {
/* Do not match link-local addresses to other netifs. */
netif = NULL;
break;
}
if (first) {
first = 0;
netif = netif_list;
} else {
netif = netif->next;
}
if (netif == inp) {
netif = netif->next;
}
} while (netif != NULL);
netif_found:
LWIP_DEBUGF(IP6_DEBUG, ("ip6_input: packet accepted on interface %c%c\n",
netif ? netif->name[0] : 'X', netif? netif->name[1] : 'X'));
}
/* "::" packet source address? (used in duplicate address detection) */
if (ip6_addr_isany(ip6_current_src_addr()) &&
(!ip6_addr_issolicitednode(ip6_current_dest_addr()))) {
/* packet source is not valid */
/* free (drop) packet pbufs */
LWIP_DEBUGF(IP6_DEBUG, ("ip6_input: packet with src ANY_ADDRESS dropped\n"));
pbuf_free(p);
IP6_STATS_INC(ip6.drop);
goto ip6_input_cleanup;
}
/* packet not for us? */
if (netif == NULL) {
/* packet not for us, route or discard */
LWIP_DEBUGF(IP6_DEBUG | LWIP_DBG_TRACE, ("ip6_input: packet not for us.\n"));
#if LWIP_IPV6_FORWARD
/* non-multicast packet? */
if (!ip6_addr_ismulticast(ip6_current_dest_addr())) {
/* try to forward IP packet on (other) interfaces */
ip6_forward(p, ip6hdr, inp);
}
#endif /* LWIP_IPV6_FORWARD */
pbuf_free(p);
goto ip6_input_cleanup;
}
/* current netif pointer. */
ip_data.current_netif = netif;
/* Save next header type. */
nexth = IP6H_NEXTH(ip6hdr);
/* Init header length. */
hlen = ip_data.current_ip_header_tot_len = IP6_HLEN;
/* Move to payload. */
pbuf_header(p, -IP6_HLEN);
/* Process known option extension headers, if present. */
while (nexth != IP6_NEXTH_NONE)
{
switch (nexth) {
case IP6_NEXTH_HOPBYHOP:
LWIP_DEBUGF(IP6_DEBUG, ("ip6_input: packet with Hop-by-Hop options header\n"));
/* Get next header type. */
nexth = *((u8_t *)p->payload);
/* Get the header length. */
hlen = 8 * (1 + *((u8_t *)p->payload + 1));
ip_data.current_ip_header_tot_len += hlen;
/* Skip over this header. */
if (hlen > p->len) {
LWIP_DEBUGF(IP6_DEBUG | LWIP_DBG_LEVEL_SERIOUS,
("IPv6 options header (hlen %"U16_F") does not fit in first pbuf (len %"U16_F"), IPv6 packet dropped.\n",
hlen, p->len));
/* free (drop) packet pbufs */
pbuf_free(p);
IP6_STATS_INC(ip6.lenerr);
IP6_STATS_INC(ip6.drop);
goto ip6_input_cleanup;
}
pbuf_header(p, -(s16_t)hlen);
break;
case IP6_NEXTH_DESTOPTS:
LWIP_DEBUGF(IP6_DEBUG, ("ip6_input: packet with Destination options header\n"));
/* Get next header type. */
nexth = *((u8_t *)p->payload);
/* Get the header length. */
hlen = 8 * (1 + *((u8_t *)p->payload + 1));
ip_data.current_ip_header_tot_len += hlen;
/* Skip over this header. */
if (hlen > p->len) {
LWIP_DEBUGF(IP6_DEBUG | LWIP_DBG_LEVEL_SERIOUS,
("IPv6 options header (hlen %"U16_F") does not fit in first pbuf (len %"U16_F"), IPv6 packet dropped.\n",
hlen, p->len));
/* free (drop) packet pbufs */
pbuf_free(p);
IP6_STATS_INC(ip6.lenerr);
IP6_STATS_INC(ip6.drop);
goto ip6_input_cleanup;
}
pbuf_header(p, -(s16_t)hlen);
break;
case IP6_NEXTH_ROUTING:
LWIP_DEBUGF(IP6_DEBUG, ("ip6_input: packet with Routing header\n"));
/* Get next header type. */
nexth = *((u8_t *)p->payload);
/* Get the header length. */
hlen = 8 * (1 + *((u8_t *)p->payload + 1));
ip_data.current_ip_header_tot_len += hlen;
/* Skip over this header. */
if (hlen > p->len) {
LWIP_DEBUGF(IP6_DEBUG | LWIP_DBG_LEVEL_SERIOUS,
("IPv6 options header (hlen %"U16_F") does not fit in first pbuf (len %"U16_F"), IPv6 packet dropped.\n",
hlen, p->len));
/* free (drop) packet pbufs */
pbuf_free(p);
IP6_STATS_INC(ip6.lenerr);
IP6_STATS_INC(ip6.drop);
goto ip6_input_cleanup;
}
pbuf_header(p, -(s16_t)hlen);
break;
case IP6_NEXTH_FRAGMENT:
{
struct ip6_frag_hdr * frag_hdr;
LWIP_DEBUGF(IP6_DEBUG, ("ip6_input: packet with Fragment header\n"));
frag_hdr = (struct ip6_frag_hdr *)p->payload;
/* Get next header type. */
nexth = frag_hdr->_nexth;
/* Fragment Header length. */
hlen = 8;
ip_data.current_ip_header_tot_len += hlen;
/* Make sure this header fits in current pbuf. */
if (hlen > p->len) {
LWIP_DEBUGF(IP6_DEBUG | LWIP_DBG_LEVEL_SERIOUS,
("IPv6 options header (hlen %"U16_F") does not fit in first pbuf (len %"U16_F"), IPv6 packet dropped.\n",
hlen, p->len));
/* free (drop) packet pbufs */
pbuf_free(p);
IP6_FRAG_STATS_INC(ip6_frag.lenerr);
IP6_FRAG_STATS_INC(ip6_frag.drop);
goto ip6_input_cleanup;
}
/* Offset == 0 and more_fragments == 0? */
if ((frag_hdr->_fragment_offset &
PP_HTONS(IP6_FRAG_OFFSET_MASK | IP6_FRAG_MORE_FLAG)) == 0) {
/* This is a 1-fragment packet, usually a packet that we have
* already reassembled. Skip this header anc continue. */
pbuf_header(p, -(s16_t)hlen);
} else {
#if LWIP_IPV6_REASS
/* reassemble the packet */
p = ip6_reass(p);
/* packet not fully reassembled yet? */
if (p == NULL) {
goto ip6_input_cleanup;
}
/* Returned p point to IPv6 header.
* Update all our variables and pointers and continue. */
ip6hdr = (struct ip6_hdr *)p->payload;
nexth = IP6H_NEXTH(ip6hdr);
hlen = ip_data.current_ip_header_tot_len = IP6_HLEN;
pbuf_header(p, -IP6_HLEN);
#else /* LWIP_IPV6_REASS */
/* free (drop) packet pbufs */
LWIP_DEBUGF(IP6_DEBUG, ("ip6_input: packet with Fragment header dropped (with LWIP_IPV6_REASS==0)\n"));
pbuf_free(p);
IP6_STATS_INC(ip6.opterr);
IP6_STATS_INC(ip6.drop);
goto ip6_input_cleanup;
#endif /* LWIP_IPV6_REASS */
}
break;
}
default:
goto options_done;
break;
}
}
options_done:
/* p points to IPv6 header again. */
pbuf_header_force(p, ip_data.current_ip_header_tot_len);
/* send to upper layers */
LWIP_DEBUGF(IP6_DEBUG, ("ip6_input: \n"));
ip6_debug_print(p);
LWIP_DEBUGF(IP6_DEBUG, ("ip6_input: p->len %"U16_F" p->tot_len %"U16_F"\n", p->len, p->tot_len));
#if LWIP_RAW
/* raw input did not eat the packet? */
if (raw_input(p, inp) == 0)
#endif /* LWIP_RAW */
{
switch (nexth) {
case IP6_NEXTH_NONE:
pbuf_free(p);
break;
#if LWIP_UDP
case IP6_NEXTH_UDP:
#if LWIP_UDPLITE
case IP6_NEXTH_UDPLITE:
#endif /* LWIP_UDPLITE */
/* Point to payload. */
pbuf_header(p, -(s16_t)ip_data.current_ip_header_tot_len);
udp_input(p, inp);
break;
#endif /* LWIP_UDP */
#if LWIP_TCP
case IP6_NEXTH_TCP:
/* Point to payload. */
pbuf_header(p, -(s16_t)ip_data.current_ip_header_tot_len);
tcp_input(p, inp);
break;
#endif /* LWIP_TCP */
#if LWIP_ICMP6
case IP6_NEXTH_ICMP6:
/* Point to payload. */
pbuf_header(p, -(s16_t)ip_data.current_ip_header_tot_len);
icmp6_input(p, inp);
break;
#endif /* LWIP_ICMP */
default:
#if LWIP_ICMP6
/* send ICMP parameter problem unless it was a multicast or ICMPv6 */
if ((!ip6_addr_ismulticast(ip6_current_dest_addr())) &&
(IP6H_NEXTH(ip6hdr) != IP6_NEXTH_ICMP6)) {
icmp6_param_problem(p, ICMP6_PP_HEADER, ip_data.current_ip_header_tot_len - hlen);
}
#endif /* LWIP_ICMP */
LWIP_DEBUGF(IP6_DEBUG | LWIP_DBG_LEVEL_SERIOUS, ("ip6_input: Unsupported transport protocol %"U16_F"\n", IP6H_NEXTH(ip6hdr)));
pbuf_free(p);
IP6_STATS_INC(ip6.proterr);
IP6_STATS_INC(ip6.drop);
break;
}
}
ip6_input_cleanup:
ip_data.current_netif = NULL;
ip_data.current_input_netif = NULL;
ip_data.current_ip6_header = NULL;
ip_data.current_ip_header_tot_len = 0;
ip6_addr_set_zero(ip6_current_src_addr());
ip6_addr_set_zero(ip6_current_dest_addr());
return ERR_OK;
}
/**
* Forwards an IPv6 packet. It finds an appropriate route for the
* packet, decrements the HL value of the packet, and outputs
* the packet on the appropriate interface.
*
* @param p the packet to forward (p->payload points to IP header)
* @param iphdr the IPv6 header of the input packet
* @param inp the netif on which this packet was received
*/
static void
ip6_forward(struct pbuf *p, struct ip6_hdr *iphdr, struct netif *inp)
{
struct netif *netif;
/* do not forward link-local addresses */
if (ip6_addr_islinklocal(ip6_current_dest_addr())) {
LWIP_DEBUGF(IP6_DEBUG, ("ip6_forward: not forwarding link-local address.\n"));
IP6_STATS_INC(ip6.rterr);
IP6_STATS_INC(ip6.drop);
return;
}
/* Find network interface where to forward this IP packet to. */
netif = ip6_route(IP6_ADDR_ANY6, ip6_current_dest_addr());
if (netif == NULL) {
LWIP_DEBUGF(IP6_DEBUG, ("ip6_forward: no route for %"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F"\n",
IP6_ADDR_BLOCK1(ip6_current_dest_addr()),
IP6_ADDR_BLOCK2(ip6_current_dest_addr()),
IP6_ADDR_BLOCK3(ip6_current_dest_addr()),
IP6_ADDR_BLOCK4(ip6_current_dest_addr()),
IP6_ADDR_BLOCK5(ip6_current_dest_addr()),
IP6_ADDR_BLOCK6(ip6_current_dest_addr()),
IP6_ADDR_BLOCK7(ip6_current_dest_addr()),
IP6_ADDR_BLOCK8(ip6_current_dest_addr())));
#if LWIP_ICMP6
/* Don't send ICMP messages in response to ICMP messages */
if (IP6H_NEXTH(iphdr) != IP6_NEXTH_ICMP6) {
icmp6_dest_unreach(p, ICMP6_DUR_NO_ROUTE);
}
#endif /* LWIP_ICMP6 */
IP6_STATS_INC(ip6.rterr);
IP6_STATS_INC(ip6.drop);
return;
}
/* Do not forward packets onto the same network interface on which
* they arrived. */
if (netif == inp) {
LWIP_DEBUGF(IP6_DEBUG, ("ip6_forward: not bouncing packets back on incoming interface.\n"));
IP6_STATS_INC(ip6.rterr);
IP6_STATS_INC(ip6.drop);
return;
}
/* decrement HL */
IP6H_HOPLIM_SET(iphdr, IP6H_HOPLIM(iphdr) - 1);
/* send ICMP6 if HL == 0 */
if (IP6H_HOPLIM(iphdr) == 0) {
#if LWIP_ICMP6
/* Don't send ICMP messages in response to ICMP messages */
if (IP6H_NEXTH(iphdr) != IP6_NEXTH_ICMP6) {
icmp6_time_exceeded(p, ICMP6_TE_HL);
}
#endif /* LWIP_ICMP6 */
IP6_STATS_INC(ip6.drop);
return;
}
if (netif->mtu && (p->tot_len > netif->mtu)) {
#if LWIP_ICMP6
/* Don't send ICMP messages in response to ICMP messages */
if (IP6H_NEXTH(iphdr) != IP6_NEXTH_ICMP6) {
icmp6_packet_too_big(p, netif->mtu);
}
#endif /* LWIP_ICMP6 */
IP6_STATS_INC(ip6.drop);
return;
}
LWIP_DEBUGF(IP6_DEBUG, ("ip6_forward: forwarding packet to %"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F"\n",
IP6_ADDR_BLOCK1(ip6_current_dest_addr()),
IP6_ADDR_BLOCK2(ip6_current_dest_addr()),
IP6_ADDR_BLOCK3(ip6_current_dest_addr()),
IP6_ADDR_BLOCK4(ip6_current_dest_addr()),
IP6_ADDR_BLOCK5(ip6_current_dest_addr()),
IP6_ADDR_BLOCK6(ip6_current_dest_addr()),
IP6_ADDR_BLOCK7(ip6_current_dest_addr()),
IP6_ADDR_BLOCK8(ip6_current_dest_addr())));
/* transmit pbuf on chosen interface */
netif->output_ip6(netif, p, ip6_current_dest_addr());
IP6_STATS_INC(ip6.fw);
IP6_STATS_INC(ip6.xmit);
return;
}
/**
* Determine if in incoming IP packet is covered by a RAW PCB
* and if so, pass it to a user-provided receive callback function.
*
* Given an incoming IP datagram (as a chain of pbufs) this function
* finds a corresponding RAW PCB and calls the corresponding receive
* callback function.
*
* @param p pbuf to be demultiplexed to a RAW PCB.
* @param inp network interface on which the datagram was received.
* @return - 1 if the packet has been eaten by a RAW PCB receive
* callback function. The caller MAY NOT not reference the
* packet any longer, and MAY NOT call pbuf_free().
* @return - 0 if packet is not eaten (pbuf is still referenced by the
* caller).
*
*/
u8_t ICACHE_FLASH_ATTR
raw_input(struct pbuf *p, struct netif *inp)
{
struct raw_pcb *pcb, *prev;
struct ip_hdr *iphdr;
s16_t proto;
u8_t eaten = 0;
#if LWIP_IPV6
struct ip6_hdr *ip6hdr;
#endif /* LWIP_IPV6 */
LWIP_UNUSED_ARG(inp);
iphdr = (struct ip_hdr *)p->payload;
#if LWIP_IPV6
if (IPH_V(iphdr) == 6) {
ip6hdr = (struct ip6_hdr *)p->payload;
proto = IP6H_NEXTH(ip6hdr);
}
else
#endif /* LWIP_IPV6 */
{
proto = IPH_PROTO(iphdr);
}
prev = NULL;
pcb = raw_pcbs;
/* loop through all raw pcbs until the packet is eaten by one */
/* this allows multiple pcbs to match against the packet by design */
while ((eaten == 0) && (pcb != NULL)) {
if ((pcb->protocol == proto) && IP_PCB_IPVER_INPUT_MATCH(pcb) &&
(ipX_addr_isany(PCB_ISIPV6(pcb), &pcb->local_ip) ||
ipX_addr_cmp(PCB_ISIPV6(pcb), &(pcb->local_ip), ipX_current_dest_addr()))) {
#if IP_SOF_BROADCAST_RECV
/* broadcast filter? */
if ((ip_get_option(pcb, SOF_BROADCAST) || !ip_addr_isbroadcast(ip_current_dest_addr(), inp))
#if LWIP_IPV6
&& !PCB_ISIPV6(pcb)
#endif /* LWIP_IPV6 */
)
#endif /* IP_SOF_BROADCAST_RECV */
{
/* receive callback function available? */
if (pcb->recv.ip4 != NULL) {
#ifndef LWIP_NOASSERT
void* old_payload = p->payload;
#endif
/* the receive callback function did not eat the packet? */
eaten = pcb->recv.ip4(pcb->recv_arg, pcb, p, ip_current_src_addr());
if (eaten != 0) {
/* receive function ate the packet */
p = NULL;
eaten = 1;
if (prev != NULL) {
/* move the pcb to the front of raw_pcbs so that is
found faster next time */
prev->next = pcb->next;
pcb->next = raw_pcbs;
raw_pcbs = pcb;
}
} else {
/* sanity-check that the receive callback did not alter the pbuf */
LWIP_ASSERT("raw pcb recv callback altered pbuf payload pointer without eating packet",
p->payload == old_payload);
}
}
/* no receive callback function was set for this raw PCB */
}
/* drop the packet */
}
prev = pcb;
pcb = pcb->next;
}
return eaten;
}
/**
* Determine if in incoming IP packet is covered by a RAW PCB
* and if so, pass it to a user-provided receive callback function.
*
* Given an incoming IP datagram (as a chain of pbufs) this function
* finds a corresponding RAW PCB and calls the corresponding receive
* callback function.
*
* @param p pbuf to be demultiplexed to a RAW PCB.
* @param inp network interface on which the datagram was received.
* @return - 1 if the packet has been eaten by a RAW PCB receive
* callback function. The caller MAY NOT not reference the
* packet any longer, and MAY NOT call pbuf_free().
* @return - 0 if packet is not eaten (pbuf is still referenced by the
* caller).
*
*/
u8_t
raw_input(struct pbuf *p, struct netif *inp)
{
struct raw_pcb *pcb, *prev;
s16_t proto;
u8_t eaten = 0;
u8_t broadcast = ip_addr_isbroadcast(ip_current_dest_addr(), ip_current_netif());
LWIP_UNUSED_ARG(inp);
#if LWIP_IPV6
#if LWIP_IPV4
if (IP_HDR_GET_VERSION(p->payload) == 6)
#endif /* LWIP_IPV4 */
{
struct ip6_hdr *ip6hdr = (struct ip6_hdr *)p->payload;
proto = IP6H_NEXTH(ip6hdr);
}
#if LWIP_IPV4
else
#endif /* LWIP_IPV4 */
#endif /* LWIP_IPV6 */
#if LWIP_IPV4
{
proto = IPH_PROTO((struct ip_hdr *)p->payload);
}
#endif /* LWIP_IPV4 */
prev = NULL;
pcb = raw_pcbs;
/* loop through all raw pcbs until the packet is eaten by one */
/* this allows multiple pcbs to match against the packet by design */
while ((eaten == 0) && (pcb != NULL)) {
if ((pcb->protocol == proto) && raw_input_match(pcb, broadcast)) {
/* receive callback function available? */
if (pcb->recv != NULL) {
#ifndef LWIP_NOASSERT
void* old_payload = p->payload;
#endif
/* the receive callback function did not eat the packet? */
eaten = pcb->recv(pcb->recv_arg, pcb, p, ip_current_src_addr());
if (eaten != 0) {
/* receive function ate the packet */
p = NULL;
eaten = 1;
if (prev != NULL) {
/* move the pcb to the front of raw_pcbs so that is
found faster next time */
prev->next = pcb->next;
pcb->next = raw_pcbs;
raw_pcbs = pcb;
}
} else {
/* sanity-check that the receive callback did not alter the pbuf */
LWIP_ASSERT("raw pcb recv callback altered pbuf payload pointer without eating packet",
p->payload == old_payload);
}
}
/* no receive callback function was set for this raw PCB */
}
/* drop the packet */
prev = pcb;
pcb = pcb->next;
}
return eaten;
}
/**
* This function does the actual transmission of a packet. The packet is
* contained in the pbuf that is passed to the function. This pbuf
* can be chained.
*
* @param netif
* the lwip network interface structure for this netfrontif
* @param p
* the packet to send (e.g. IP packet including MAC addresses and type)
* @return
* ERR_OK when the packet could be enqueued for sending; an err_t value otherwise
*/
static inline err_t netfrontif_transmit(struct netif *netif, struct pbuf *p)
{
struct netfrontif *nfi = netif->state;
#if LWIP_CHECKSUM_PARTIAL || defined CONFIG_LWIP_BATCHTX
s16_t ip_hdr_offset;
const struct eth_hdr *ethhdr;
const struct ip_hdr *iphdr;
#endif /* LWIP_CHECKSUM_PARTIAL || defined CONFIG_LWIP_BATCHTX */
#ifdef CONFIG_LWIP_BATCHTX
const struct tcp_hdr *tcphdr;
#endif /* CONFIG_LWIP_BATCHTX */
int tso = 0;
int push = 1;
err_t err;
LWIP_DEBUGF(NETIF_DEBUG, ("netfrontif_transmit: %c%c: "
"Transmitting %u bytes\n",
netif->name[0], netif->name[1],
p->tot_len));
#if LWIP_CHECKSUM_PARTIAL || defined CONFIG_LWIP_BATCHTX
/* detect if payload contains a TCP packet */
/* NOTE: We assume here that all protocol headers are in the first pbuf of a pbuf chain! */
ip_hdr_offset = SIZEOF_ETH_HDR;
ethhdr = (struct eth_hdr *) p->payload;
#if ETHARP_SUPPORT_VLAN
if (type == PP_HTONS(ETHTYPE_VLAN)) {
type = ((struct eth_vlan_hdr*)(((uintptr_t)ethhdr) + SIZEOF_ETH_HDR))->tpid;
ip_hdr_offset = SIZEOF_ETH_HDR + SIZEOF_VLAN_HDR;
}
#endif /* ETHARP_SUPPORT_VLAN */
/* TODO: PPP support? */
switch (ethhdr->type) {
case PP_HTONS(ETHTYPE_IP):
iphdr = (struct ip_hdr *)((uintptr_t) p->payload + ip_hdr_offset);
if (IPH_PROTO(iphdr) != IP_PROTO_TCP) {
goto xmit; /* IPv4 but not TCP */
}
#if LWIP_CHECKSUM_PARTIAL
tso = XEN_NETIF_GSO_TYPE_TCPV4; /* TCPv4 segmentation and checksum offloading */
#endif /* LWIP_CHECKSUM_PARTIAL */
#ifdef CONFIG_LWIP_BATCHTX
/* push only when FIN, RST, PSH, or URG flag is set */
tcphdr = (struct tcp_hdr *)((uintptr_t) p->payload + ip_hdr_offset + (IPH_HL(iphdr) * 4));
push = (TCPH_FLAGS(tcphdr) & (TCP_FIN | TCP_RST | TCP_PSH | TCP_URG));
#endif /* CONFIG_LWIP_BATCHTX */
break;
#if IPV6_SUPPORT
case PP_HTONS(ETHTYPE_IPV6):
if (IP6H_NEXTH((struct ip6_hdr *)((uintptr_t) p->payload + ip_hdr_offset)) != IP6_NEXTH_TCP)
goto xmit; /* IPv6 but not TCP */
#if LWIP_CHECKSUM_PARTIAL
tso = XEN_NETIF_GSO_TYPE_TCPV6; /* TCPv6 segmentation and checksum offloading */
#endif /* LWIP_CHECKSUM_PARTIAL */
#ifdef CONFIG_LWIP_BATCHTX
/* push only when FIN, RST, PSH, or URG flag is set */
#error "TSOv6 is not yet supported. Please add it"
tcphdr = NULL;
push = (TCPH_FLAGS(tcphdr) & (TCP_FIN | TCP_RST | TCP_PSH | TCP_URG));
#endif /* CONFIG_LWIP_BATCHTX */
break;
#endif /* IPV6_SUPPORT */
default:
break; /* non-IP packet */
}
#endif /* LWIP_CHECKSUM_PARTIAL || defined CONFIG_LWIP_BATCHTX */
xmit:
#if ETH_PAD_SIZE
pbuf_header(p, -ETH_PAD_SIZE); /* drop the padding word */
#endif
err = netfront_xmit_pbuf(nfi->dev, p, tso, push);
if (likely(err == ERR_OK)) {
LINK_STATS_INC(link.xmit);
} else {
LWIP_DEBUGF(NETIF_DEBUG, ("netfrontif_transmit: transmission failed, dropping packet: %d\n", err));
LINK_STATS_INC(link.drop);
}
#if ETH_PAD_SIZE
pbuf_header(p, ETH_PAD_SIZE); /* reclaim the padding word */
#endif
return err;
}
/**
* Reassembles incoming IPv6 fragments into an IPv6 datagram.
*
* @param p points to the IPv6 Fragment Header
* @return NULL if reassembly is incomplete, pbuf pointing to
* IPv6 Header if reassembly is complete
*/
struct pbuf *
ip6_reass(struct pbuf *p)
{
struct ip6_reassdata *ipr, *ipr_prev;
struct ip6_reass_helper *iprh, *iprh_tmp, *iprh_prev=NULL;
struct ip6_frag_hdr *frag_hdr;
u16_t offset, len, start, end;
ptrdiff_t hdrdiff;
u16_t clen;
u8_t valid = 1;
struct pbuf *q, *next_pbuf;
IP6_FRAG_STATS_INC(ip6_frag.recv);
/* ip6_frag_hdr must be in the first pbuf, not chained. Checked by caller. */
LWIP_ASSERT("IPv6 fragment header does not fit in first pbuf",
p->len >= sizeof(struct ip6_frag_hdr));
frag_hdr = (struct ip6_frag_hdr *) p->payload;
clen = pbuf_clen(p);
offset = lwip_ntohs(frag_hdr->_fragment_offset);
/* Calculate fragment length from IPv6 payload length.
* Adjust for headers before Fragment Header.
* And finally adjust by Fragment Header length. */
len = lwip_ntohs(ip6_current_header()->_plen);
hdrdiff = (u8_t*)p->payload - (const u8_t*)ip6_current_header();
LWIP_ASSERT("not a valid pbuf (ip6_input check missing?)", hdrdiff <= 0xFFFF);
LWIP_ASSERT("not a valid pbuf (ip6_input check missing?)", hdrdiff >= IP6_HLEN);
hdrdiff -= IP6_HLEN;
hdrdiff += IP6_FRAG_HLEN;
if (hdrdiff > len) {
IP6_FRAG_STATS_INC(ip6_frag.proterr);
goto nullreturn;
}
len = (u16_t)(len - hdrdiff);
start = (offset & IP6_FRAG_OFFSET_MASK);
if (start > (0xFFFF - len)) {
/* u16_t overflow, cannot handle this */
IP6_FRAG_STATS_INC(ip6_frag.proterr);
goto nullreturn;
}
/* Look for the datagram the fragment belongs to in the current datagram queue,
* remembering the previous in the queue for later dequeueing. */
for (ipr = reassdatagrams, ipr_prev = NULL; ipr != NULL; ipr = ipr->next) {
/* Check if the incoming fragment matches the one currently present
in the reassembly buffer. If so, we proceed with copying the
fragment into the buffer. */
if ((frag_hdr->_identification == ipr->identification) &&
ip6_addr_cmp_packed(ip6_current_src_addr(), &(IPV6_FRAG_SRC(ipr)), ipr->src_zone) &&
ip6_addr_cmp_packed(ip6_current_dest_addr(), &(IPV6_FRAG_DEST(ipr)), ipr->dest_zone)) {
IP6_FRAG_STATS_INC(ip6_frag.cachehit);
break;
}
ipr_prev = ipr;
}
if (ipr == NULL) {
/* Enqueue a new datagram into the datagram queue */
ipr = (struct ip6_reassdata *)memp_malloc(MEMP_IP6_REASSDATA);
if (ipr == NULL) {
#if IP_REASS_FREE_OLDEST
/* Make room and try again. */
ip6_reass_remove_oldest_datagram(ipr, clen);
ipr = (struct ip6_reassdata *)memp_malloc(MEMP_IP6_REASSDATA);
if (ipr != NULL) {
/* re-search ipr_prev since it might have been removed */
for (ipr_prev = reassdatagrams; ipr_prev != NULL; ipr_prev = ipr_prev->next) {
if (ipr_prev->next == ipr) {
break;
}
}
} else
#endif /* IP_REASS_FREE_OLDEST */
{
IP6_FRAG_STATS_INC(ip6_frag.memerr);
goto nullreturn;
}
}
memset(ipr, 0, sizeof(struct ip6_reassdata));
ipr->timer = IPV6_REASS_MAXAGE;
/* enqueue the new structure to the front of the list */
ipr->next = reassdatagrams;
reassdatagrams = ipr;
/* Use the current IPv6 header for src/dest address reference.
* Eventually, we will replace it when we get the first fragment
* (it might be this one, in any case, it is done later). */
/* need to use the none-const pointer here: */
ipr->iphdr = ip_data.current_ip6_header;
#if IPV6_FRAG_COPYHEADER
MEMCPY(&ipr->src, &ip6_current_header()->src, sizeof(ipr->src));
MEMCPY(&ipr->dest, &ip6_current_header()->dest, sizeof(ipr->dest));
#endif /* IPV6_FRAG_COPYHEADER */
#if LWIP_IPV6_SCOPES
/* Also store the address zone information.
* @todo It is possible that due to netif destruction and recreation, the
* stored zones end up resolving to a different interface. In that case, we
* risk sending a "time exceeded" ICMP response over the wrong link.
* Ideally, netif destruction would clean up matching pending reassembly
* structures, but custom zone mappings would make that non-trivial. */
ipr->src_zone = ip6_addr_zone(ip6_current_src_addr());
ipr->dest_zone = ip6_addr_zone(ip6_current_dest_addr());
#endif /* LWIP_IPV6_SCOPES */
/* copy the fragmented packet id. */
ipr->identification = frag_hdr->_identification;
/* copy the nexth field */
ipr->nexth = frag_hdr->_nexth;
}
/* Check if we are allowed to enqueue more datagrams. */
if ((ip6_reass_pbufcount + clen) > IP_REASS_MAX_PBUFS) {
#if IP_REASS_FREE_OLDEST
ip6_reass_remove_oldest_datagram(ipr, clen);
if ((ip6_reass_pbufcount + clen) <= IP_REASS_MAX_PBUFS) {
/* re-search ipr_prev since it might have been removed */
for (ipr_prev = reassdatagrams; ipr_prev != NULL; ipr_prev = ipr_prev->next) {
if (ipr_prev->next == ipr) {
break;
}
}
} else
#endif /* IP_REASS_FREE_OLDEST */
{
/* @todo: send ICMPv6 time exceeded here? */
/* drop this pbuf */
IP6_FRAG_STATS_INC(ip6_frag.memerr);
goto nullreturn;
}
}
/* Overwrite Fragment Header with our own helper struct. */
#if IPV6_FRAG_COPYHEADER
if (IPV6_FRAG_REQROOM > 0) {
/* Make room for struct ip6_reass_helper (only required if sizeof(void*) > 4).
This cannot fail since we already checked when receiving this fragment. */
u8_t hdrerr = pbuf_header_force(p, IPV6_FRAG_REQROOM);
LWIP_UNUSED_ARG(hdrerr); /* in case of LWIP_NOASSERT */
LWIP_ASSERT("no room for struct ip6_reass_helper", hdrerr == 0);
}
#else /* IPV6_FRAG_COPYHEADER */
LWIP_ASSERT("sizeof(struct ip6_reass_helper) <= IP6_FRAG_HLEN, set IPV6_FRAG_COPYHEADER to 1",
sizeof(struct ip6_reass_helper) <= IP6_FRAG_HLEN);
#endif /* IPV6_FRAG_COPYHEADER */
/* Prepare the pointer to the helper structure, and its initial values.
* Do not yet write to the structure itself, as we still have to make a
* backup of the original data, and we should not do that until we know for
* sure that we are going to add this packet to the list. */
iprh = (struct ip6_reass_helper *)p->payload;
next_pbuf = NULL;
end = (u16_t)(start + len);
/* find the right place to insert this pbuf */
/* Iterate through until we either get to the end of the list (append),
* or we find on with a larger offset (insert). */
for (q = ipr->p; q != NULL;) {
iprh_tmp = (struct ip6_reass_helper*)q->payload;
if (start < iprh_tmp->start) {
#if IP_REASS_CHECK_OVERLAP
if (end > iprh_tmp->start) {
/* fragment overlaps with following, throw away */
IP6_FRAG_STATS_INC(ip6_frag.proterr);
goto nullreturn;
}
if (iprh_prev != NULL) {
if (start < iprh_prev->end) {
/* fragment overlaps with previous, throw away */
IP6_FRAG_STATS_INC(ip6_frag.proterr);
goto nullreturn;
}
}
#endif /* IP_REASS_CHECK_OVERLAP */
/* the new pbuf should be inserted before this */
next_pbuf = q;
if (iprh_prev != NULL) {
/* not the fragment with the lowest offset */
iprh_prev->next_pbuf = p;
} else {
/* fragment with the lowest offset */
ipr->p = p;
}
break;
} else if (start == iprh_tmp->start) {
/* received the same datagram twice: no need to keep the datagram */
goto nullreturn;
#if IP_REASS_CHECK_OVERLAP
} else if (start < iprh_tmp->end) {
/* overlap: no need to keep the new datagram */
IP6_FRAG_STATS_INC(ip6_frag.proterr);
goto nullreturn;
#endif /* IP_REASS_CHECK_OVERLAP */
} else {
/* Check if the fragments received so far have no gaps. */
if (iprh_prev != NULL) {
if (iprh_prev->end != iprh_tmp->start) {
/* There is a fragment missing between the current
* and the previous fragment */
valid = 0;
}
}
}
q = iprh_tmp->next_pbuf;
iprh_prev = iprh_tmp;
}
/* If q is NULL, then we made it to the end of the list. Determine what to do now */
if (q == NULL) {
if (iprh_prev != NULL) {
/* this is (for now), the fragment with the highest offset:
* chain it to the last fragment */
#if IP_REASS_CHECK_OVERLAP
LWIP_ASSERT("check fragments don't overlap", iprh_prev->end <= start);
#endif /* IP_REASS_CHECK_OVERLAP */
iprh_prev->next_pbuf = p;
if (iprh_prev->end != start) {
valid = 0;
}
} else {
#if IP_REASS_CHECK_OVERLAP
LWIP_ASSERT("no previous fragment, this must be the first fragment!",
ipr->p == NULL);
#endif /* IP_REASS_CHECK_OVERLAP */
/* this is the first fragment we ever received for this ip datagram */
ipr->p = p;
}
}
/* Track the current number of pbufs current 'in-flight', in order to limit
the number of fragments that may be enqueued at any one time */
ip6_reass_pbufcount = (u16_t)(ip6_reass_pbufcount + clen);
/* Remember IPv6 header if this is the first fragment. */
if (start == 0) {
/* need to use the none-const pointer here: */
ipr->iphdr = ip_data.current_ip6_header;
/* Make a backup of the part of the packet data that we are about to
* overwrite, so that we can restore the original later. */
MEMCPY(ipr->orig_hdr, p->payload, sizeof(*iprh));
/* For IPV6_FRAG_COPYHEADER there is no need to copy src/dst again, as they
* will be the same as they were. With LWIP_IPV6_SCOPES, the same applies
* to the source/destination zones. */
}
/* Only after the backup do we get to fill in the actual helper structure. */
iprh->next_pbuf = next_pbuf;
iprh->start = start;
iprh->end = end;
/* If this is the last fragment, calculate total packet length. */
if ((offset & IP6_FRAG_MORE_FLAG) == 0) {
ipr->datagram_len = iprh->end;
}
/* Additional validity tests: we have received first and last fragment. */
iprh_tmp = (struct ip6_reass_helper*)ipr->p->payload;
if (iprh_tmp->start != 0) {
valid = 0;
}
if (ipr->datagram_len == 0) {
valid = 0;
}
/* Final validity test: no gaps between current and last fragment. */
iprh_prev = iprh;
q = iprh->next_pbuf;
while ((q != NULL) && valid) {
iprh = (struct ip6_reass_helper*)q->payload;
if (iprh_prev->end != iprh->start) {
valid = 0;
break;
}
iprh_prev = iprh;
q = iprh->next_pbuf;
}
if (valid) {
/* All fragments have been received */
struct ip6_hdr* iphdr_ptr;
/* chain together the pbufs contained within the ip6_reassdata list. */
iprh = (struct ip6_reass_helper*) ipr->p->payload;
while (iprh != NULL) {
next_pbuf = iprh->next_pbuf;
if (next_pbuf != NULL) {
/* Save next helper struct (will be hidden in next step). */
iprh_tmp = (struct ip6_reass_helper*)next_pbuf->payload;
/* hide the fragment header for every succeeding fragment */
pbuf_remove_header(next_pbuf, IP6_FRAG_HLEN);
#if IPV6_FRAG_COPYHEADER
if (IPV6_FRAG_REQROOM > 0) {
/* hide the extra bytes borrowed from ip6_hdr for struct ip6_reass_helper */
u8_t hdrerr = pbuf_remove_header(next_pbuf, IPV6_FRAG_REQROOM);
LWIP_UNUSED_ARG(hdrerr); /* in case of LWIP_NOASSERT */
LWIP_ASSERT("no room for struct ip6_reass_helper", hdrerr == 0);
}
#endif
pbuf_cat(ipr->p, next_pbuf);
}
else {
iprh_tmp = NULL;
}
iprh = iprh_tmp;
}
/* Get the first pbuf. */
p = ipr->p;
#if IPV6_FRAG_COPYHEADER
if (IPV6_FRAG_REQROOM > 0) {
u8_t hdrerr;
/* Restore (only) the bytes that we overwrote beyond the fragment header.
* Those bytes may belong to either the IPv6 header or an extension
* header placed before the fragment header. */
MEMCPY(p->payload, ipr->orig_hdr, IPV6_FRAG_REQROOM);
/* get back room for struct ip6_reass_helper (only required if sizeof(void*) > 4) */
hdrerr = pbuf_remove_header(p, IPV6_FRAG_REQROOM);
LWIP_UNUSED_ARG(hdrerr); /* in case of LWIP_NOASSERT */
LWIP_ASSERT("no room for struct ip6_reass_helper", hdrerr == 0);
}
#endif
/* We need to get rid of the fragment header itself, which is somewhere in
* the middle of the packet (but still in the first pbuf of the chain).
* Getting rid of the header is required by RFC 2460 Sec. 4.5 and necessary
* in order to be able to reassemble packets that are close to full size
* (i.e., around 65535 bytes). We simply move up all the headers before the
* fragment header, including the IPv6 header, and adjust the payload start
* accordingly. This works because all these headers are in the first pbuf
* of the chain, and because the caller adjusts all its pointers on
* successful reassembly. */
MEMMOVE((u8_t*)ipr->iphdr + sizeof(struct ip6_frag_hdr), ipr->iphdr,
(size_t)((u8_t*)p->payload - (u8_t*)ipr->iphdr));
/* This is where the IPv6 header is now. */
iphdr_ptr = (struct ip6_hdr*)((u8_t*)ipr->iphdr +
sizeof(struct ip6_frag_hdr));
/* Adjust datagram length by adding header lengths. */
ipr->datagram_len = (u16_t)(ipr->datagram_len + ((u8_t*)p->payload - (u8_t*)iphdr_ptr)
- IP6_HLEN);
/* Set payload length in ip header. */
iphdr_ptr->_plen = lwip_htons(ipr->datagram_len);
/* With the fragment header gone, we now need to adjust the next-header
* field of whatever header was originally before it. Since the packet made
* it through the original header processing routines at least up to the
* fragment header, we do not need any further sanity checks here. */
if (IP6H_NEXTH(iphdr_ptr) == IP6_NEXTH_FRAGMENT) {
iphdr_ptr->_nexth = ipr->nexth;
} else {
u8_t *ptr = (u8_t *)iphdr_ptr + IP6_HLEN;
while (*ptr != IP6_NEXTH_FRAGMENT) {
ptr += 8 * (1 + ptr[1]);
}
*ptr = ipr->nexth;
}
/* release the resources allocated for the fragment queue entry */
if (reassdatagrams == ipr) {
/* it was the first in the list */
reassdatagrams = ipr->next;
} else {
/* it wasn't the first, so it must have a valid 'prev' */
LWIP_ASSERT("sanity check linked list", ipr_prev != NULL);
ipr_prev->next = ipr->next;
}
memp_free(MEMP_IP6_REASSDATA, ipr);
/* adjust the number of pbufs currently queued for reassembly. */
clen = pbuf_clen(p);
LWIP_ASSERT("ip6_reass_pbufcount >= clen", ip6_reass_pbufcount >= clen);
ip6_reass_pbufcount = (u16_t)(ip6_reass_pbufcount - clen);
/* Move pbuf back to IPv6 header. This should never fail. */
if (pbuf_header_force(p, (s16_t)((u8_t*)p->payload - (u8_t*)iphdr_ptr))) {
LWIP_ASSERT("ip6_reass: moving p->payload to ip6 header failed\n", 0);
pbuf_free(p);
return NULL;
}
/* Return the pbuf chain */
return p;
}
/* the datagram is not (yet?) reassembled completely */
return NULL;
nullreturn:
IP6_FRAG_STATS_INC(ip6_frag.drop);
pbuf_free(p);
return NULL;
}
/*********************************************************************************************************
** 函数名称: __inetPingRecv
** 功能描述: 接收 ping 包
** 输 入 : iSock socket
** usSeqRecv 需要判断的 seq
** piHL 接收的 hop limit
** 输 出 : ERROR
** 全局变量:
** 调用模块:
*********************************************************************************************************/
static INT __inetPing6Recv (INT iSock, UINT16 usSeqRecv, INT *piHL)
{
CHAR cBuffer[512];
INT iCnt = 20; /* 默认最多接收的数据包数 */
REGISTER ssize_t sstLen;
INT iAddLen = sizeof(struct sockaddr_in6);
struct sockaddr_in6 sockaddrin6From;
struct ip6_hdr *ip6hdrFrom;
struct icmp6_echo_hdr *icmp6hdrFrom;
u8_t nexth;
INT hlen;
INT totalhlen = 0;
u8_t *pucData;
*piHL = 0;
while ((sstLen = recvfrom(iSock, cBuffer, sizeof(cBuffer), 0,
(struct sockaddr *)&sockaddrin6From, (socklen_t *)&iAddLen)) > 0) {
if (sstLen >= (sizeof(struct ip6_hdr) + sizeof(struct icmp6_echo_hdr))) {
ip6hdrFrom = (struct ip6_hdr *)cBuffer;
hlen = IP6_HLEN;
totalhlen = IP6_HLEN;
nexth = IP6H_NEXTH(ip6hdrFrom);
*piHL = IP6H_HOPLIM(ip6hdrFrom);
pucData = (u8_t *)cBuffer;
pucData += IP6_HLEN;
while (nexth != IP6_NEXTH_NONE) {
switch (nexth) {
case IP6_NEXTH_HOPBYHOP:
case IP6_NEXTH_DESTOPTS:
case IP6_NEXTH_ROUTING:
nexth = *pucData;
hlen = 8 * (1 + *(pucData + 1));
totalhlen += hlen;
pucData += hlen;
break;
case IP6_NEXTH_FRAGMENT:
nexth = *pucData;
hlen = 8;
totalhlen += hlen;
pucData += hlen;
break;
default:
goto __hdrlen_cal_ok;
break;
}
}
__hdrlen_cal_ok:
icmp6hdrFrom = (struct icmp6_echo_hdr *)(cBuffer + totalhlen);
if ((icmp6hdrFrom->id == 0xAFAF) && (icmp6hdrFrom->seqno == htons(usSeqRecv))) {
return (ERROR_NONE);
}
}
iCnt--; /* 接收到错误的数据包太多 */
if (iCnt < 0) {
break; /* 退出 */
}
}
return (PX_ERROR);
}
/**
* Forwards an IPv6 packet. It finds an appropriate route for the
* packet, decrements the HL value of the packet, and outputs
* the packet on the appropriate interface.
*
* @param p the packet to forward (p->payload points to IP header)
* @param iphdr the IPv6 header of the input packet
* @param inp the netif on which this packet was received
* @return -1 if packet is to be dropped, 0 if there's no route, 1 if forwarded
*/
static int
ip6_forward(struct pbuf *p, struct ip6_hdr *iphdr, struct netif *inp)
{
enum { FWD_DROP = -1, FWD_PROXY = 0, FWD_FORWARDED = 1 };
struct netif *netif;
/* do not forward link-local addresses */
if (ip6_addr_islinklocal(ip6_current_dest_addr())) {
LWIP_DEBUGF(IP6_DEBUG, ("ip6_forward: not forwarding link-local address.\n"));
IP6_STATS_INC(ip6.rterr);
IP6_STATS_INC(ip6.drop);
return FWD_DROP;
}
/* Find network interface where to forward this IP packet to. */
netif = ip6_route_fwd(ip6_current_dest_addr());
if (netif == NULL) {
LWIP_DEBUGF(IP6_DEBUG, ("ip6_forward: no route for %"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F"\n",
IP6_ADDR_BLOCK1(ip6_current_dest_addr()),
IP6_ADDR_BLOCK2(ip6_current_dest_addr()),
IP6_ADDR_BLOCK3(ip6_current_dest_addr()),
IP6_ADDR_BLOCK4(ip6_current_dest_addr()),
IP6_ADDR_BLOCK5(ip6_current_dest_addr()),
IP6_ADDR_BLOCK6(ip6_current_dest_addr()),
IP6_ADDR_BLOCK7(ip6_current_dest_addr()),
IP6_ADDR_BLOCK8(ip6_current_dest_addr())));
#if LWIP_CONNECTION_PROXY
return FWD_PROXY;
#else /* !LWIP_CONNECTION_PROXY */
#if LWIP_ICMP6
/* Don't send ICMP messages in response to ICMP messages */
if (IP6H_NEXTH(iphdr) != IP6_NEXTH_ICMP6) {
icmp6_dest_unreach(p, ICMP6_DUR_NO_ROUTE);
}
#endif /* LWIP_ICMP6 */
IP6_STATS_INC(ip6.rterr);
IP6_STATS_INC(ip6.drop);
return FWD_DROP;
#endif /* !LWIP_CONNECTION_PROXY */
}
#if LWIP_CONNECTION_PROXY
/* The packet is for a destination on a directly connected network.
* Check for addresses in that address space that proxy wants to
* remap (e.g. to host loopback address/es) and hand it off to
* proxy */
if (netif != netif_default
&& proxy_ip6_divert_hook != NULL
&& (*proxy_ip6_divert_hook)(netif, ip6_current_dest_addr()))
{
return FWD_PROXY;
}
#endif /* LWIP_CONNECTION_PROXY */
/* Do not forward packets onto the same network interface on which
* they arrived. */
if (netif == inp) {
LWIP_DEBUGF(IP6_DEBUG, ("ip6_forward: not bouncing packets back on incoming interface.\n"));
IP6_STATS_INC(ip6.rterr);
IP6_STATS_INC(ip6.drop);
return FWD_DROP;
}
/* decrement HL */
IP6H_HOPLIM_SET(iphdr, IP6H_HOPLIM(iphdr) - 1);
/* send ICMP6 if HL == 0 */
if (IP6H_HOPLIM(iphdr) == 0) {
#if LWIP_ICMP6
/* Don't send ICMP messages in response to ICMP messages */
if (IP6H_NEXTH(iphdr) != IP6_NEXTH_ICMP6) {
icmp6_time_exceeded(p, ICMP6_TE_HL);
}
#endif /* LWIP_ICMP6 */
IP6_STATS_INC(ip6.drop);
return FWD_DROP;
}
if (netif->mtu && (p->tot_len > netif->mtu)) {
#if LWIP_ICMP6
/* Don't send ICMP messages in response to ICMP messages */
if (IP6H_NEXTH(iphdr) != IP6_NEXTH_ICMP6) {
icmp6_packet_too_big(p, netif->mtu);
}
#endif /* LWIP_ICMP6 */
IP6_STATS_INC(ip6.drop);
return FWD_DROP;
}
LWIP_DEBUGF(IP6_DEBUG, ("ip6_forward: forwarding packet to %"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F":%"X16_F"\n",
IP6_ADDR_BLOCK1(ip6_current_dest_addr()),
IP6_ADDR_BLOCK2(ip6_current_dest_addr()),
IP6_ADDR_BLOCK3(ip6_current_dest_addr()),
IP6_ADDR_BLOCK4(ip6_current_dest_addr()),
IP6_ADDR_BLOCK5(ip6_current_dest_addr()),
IP6_ADDR_BLOCK6(ip6_current_dest_addr()),
IP6_ADDR_BLOCK7(ip6_current_dest_addr()),
IP6_ADDR_BLOCK8(ip6_current_dest_addr())));
/* transmit pbuf on chosen interface */
netif->output_ip6(netif, p, ip6_current_dest_addr());
IP6_STATS_INC(ip6.fw);
IP6_STATS_INC(ip6.xmit);
return FWD_FORWARDED;
}
