/**************************************************************************** * apps/examples/ipforward/ipforward.c * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. The * ASF licenses this file to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance with the * License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the * License for the specific language governing permissions and limitations * under the License. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "netutils/netlib.h" /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ #define MAX_DEVNAME 8 #define IPFWD_BUFSIZE CONFIG_NET_TUN_PKTSIZE #define NBYTES_PER_LINE 32 #define IPFWD_NPACKETS 3 #ifdef CONFIG_NET_IPv6 # define IPADDR_TYPE FAR const uint16_t * # define IP_HDRLEN IPv6_HDRLEN #else # define IPADDR_TYPE uint32_t # define IP_HDRLEN IPv4_HDRLEN #endif #if defined(CONFIG_NET_ETHERNET) # define MAC_ADDRLEN 6 /* IFHWADDRLEN */ #elif defined(CONFIG_NET_6LOWPAN) # ifdef CONFIG_NET_6LOWPAN_EXTENDEDADDR # define MAC_ADDRLEN 10 /* NET_6LOWPAN_EADDRSIZE */ # else # define MAC_ADDRLEN 2 /* NET_6LOWPAN_SADDRSIZE */ # endif #else # define MAC_ADDRLEN 0 /* No link layer address */ #endif /**************************************************************************** * Name: Private Types ****************************************************************************/ struct ipfwd_tun_s { int it_fd; char it_devname[MAX_DEVNAME]; }; struct ipfwd_state_s { struct ipfwd_tun_s if_tun0; struct ipfwd_tun_s if_tun1; pthread_t if_receiver; pthread_t if_sender; }; struct ipfwd_arg_s { int ia_fd; IPADDR_TYPE ia_srcipaddr; IPADDR_TYPE ia_destipaddr; uint8_t ia_buffer[IPFWD_BUFSIZE]; }; /**************************************************************************** * Private Data ****************************************************************************/ /* Network addresses: * * g_tun0_laddr is the address assigned to the tun0 device. g_tun1_laddr * is the address assigned to tun1 device. Both are loal addresses can the * target can received addresses on. * * g_netmask is the network mask that defines the networks: tun0 is on * network 0; tun1 is on network 1. * * g_tun0_raddr and g_tun1_raddr are addresses that are not local to the * target, but should instead be forwarded via the correct network device. * g_tun0_raddr lies on network 0 and g_tun1_raddr lies on network 1 and so * should be forwarded from network 0 to network1 by the NuttX IP forwarding * logic. */ #ifdef CONFIG_NET_IPv6 static const uint16_t g_tun0_laddr[8] = { HTONS(0x7c00), HTONS(0), HTONS(0), HTONS(0), HTONS(0), HTONS(0), HTONS(0), /* Netork 0 */ HTONS(0x0097), }; static const uint16_t g_tun1_laddr[8] = { HTONS(0x7c00), HTONS(0), HTONS(0), HTONS(0), HTONS(0), HTONS(0), HTONS(0x0001), /* Netork 1 */ HTONS(0x0139), }; static const uint16_t g_tun0_raddr[8] = { HTONS(0x7c00), HTONS(0), HTONS(0), HTONS(0), HTONS(0), HTONS(0), HTONS(0), /* Netork 0 */ HTONS(0x0062), }; static const uint16_t g_tun1_raddr[8] = { HTONS(0x7c00), HTONS(0), HTONS(0), HTONS(0), HTONS(0), HTONS(0), HTONS(0x0001), /* Netork 1 */ HTONS(0x0147), }; static const uint16_t g_netmask[8] = { HTONS(0xffff), HTONS(0xffff), HTONS(0xffff), HTONS(0xffff), HTONS(0xffff), HTONS(0xffff), HTONS(0xffff), HTONS(0), }; #else static const uint32_t g_tun0_laddr = HTONL(0x0a000097); /* Netork 0 */ static const uint32_t g_tun1_laddr = HTONL(0x0a000139); /* Netork 1 */ static const uint32_t g_tun0_raddr = HTONL(0x0a000062); /* Netork 0 */ static const uint32_t g_tun1_raddr = HTONL(0x0a000147); /* Netork 1 */ static const uint32_t g_netmask = HTONL(0xffffff00); #endif #ifdef CONFIG_EXAMPLES_IPFORWARD_TCP static const char g_payload[] = "Hi there TUN receiver!"; #endif #ifdef CONFIG_NET_IPv4 static uint16_t g_ipid; #endif /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Name: ipfwd_tun_configure ****************************************************************************/ static int ipfwd_tun_configure(FAR struct ipfwd_tun_s *tun) { struct ifreq ifr; int errcode; int ret; tun->it_fd = open("/dev/tun", O_RDWR); if (tun->it_fd < 0) { errcode = errno; fprintf(stderr, "ERROR: Failed to open /dev/tun: %d\n", errcode); return -errcode; } memset(&ifr, 0, sizeof(ifr)); ifr.ifr_flags = IFF_TUN; ret = ioctl(tun->it_fd, TUNSETIFF, (unsigned long)&ifr); if (ret < 0) { errcode = errno; fprintf(stderr, "ERROR: ioctl TUNSETIFF failed: %d\n", errcode); close(tun->it_fd); return -errcode; } strncpy(tun->it_devname, ifr.ifr_name, MAX_DEVNAME); printf("Created TUN device: %s\n", tun->it_devname); return 0; } /**************************************************************************** * Name: ipfwd_netconfig ****************************************************************************/ static int ipfwd_netconfig(FAR struct ipfwd_tun_s *tun, IPADDR_TYPE ipaddr, IPADDR_TYPE netmask) { int ret; #ifdef CONFIG_NET_IPv6 struct in6_addr addr; memcpy(addr.s6_addr16, ipaddr, 8 * sizeof(uint16_t)); ret = netlib_set_ipv6addr(tun->it_devname, &addr); if (ret < 0) { fprintf(stderr, "ERROR: netlib_set_ipv6addr() failed with %d\n", ret); return ret; } memcpy(addr.s6_addr16, netmask, 8 * sizeof(uint16_t)); ret = netlib_set_ipv6netmask(tun->it_devname, &addr); if (ret < 0) { fprintf(stderr, "ERROR: netlib_set_ipv6netmask() failed with %d\n", ret); return ret; } #else /* CONFIG_NET_IPv4 */ struct in_addr addr; addr.s_addr = ipaddr; ret = netlib_set_ipv4addr(tun->it_devname, &addr); if (ret < 0) { fprintf(stderr, "ERROR: netlib_set_ipv4addr() failed\n", ret); return ret; } addr.s_addr = netmask; ret = netlib_set_ipv4netmask(tun->it_devname, &addr); if (ret < 0) { fprintf(stderr, "ERROR: netlib_set_ipv4netmask() failed\n", ret); return ret; } #endif netlib_ifup(tun->it_devname); return 0; } /**************************************************************************** * Name: Checksums ****************************************************************************/ static uint16_t chksum(uint16_t sum, FAR const uint8_t *data, uint16_t len) { FAR const uint8_t *dataptr; FAR const uint8_t *last_byte; uint16_t t; dataptr = data; last_byte = data + len - 1; while (dataptr < last_byte) { /* At least two more bytes */ t = ((uint16_t)dataptr[0] << 8) + dataptr[1]; sum += t; if (sum < t) { sum++; /* carry */ } dataptr += 2; } if (dataptr == last_byte) { t = (dataptr[0] << 8) + 0; sum += t; if (sum < t) { sum++; /* carry */ } } /* Return sum in host byte order. */ return sum; } #ifdef CONFIG_NET_IPv4 static uint16_t ipv4_chksum(FAR const uint8_t *buffer) { uint16_t sum; sum = chksum(0, buffer, IPv4_HDRLEN); return (sum == 0) ? 0xffff : htons(sum); } #endif static uint16_t common_chksum(FAR uint8_t *buffer, uint8_t proto) { #ifdef CONFIG_NET_IPv6 FAR struct ipv6_hdr_s *ipv6 = (FAR struct ipv6_hdr_s *)buffer; uint16_t upperlen; uint16_t sum; /* The length reported in the IPv6 header is the length of the payload * that follows the header. */ upperlen = ((uint16_t)ipv6->len[0] << 8) + ipv6->len[1]; /* The checksum is calculated starting with a pseudo-header of IPv6 header * fields according to the IPv6 standard, which consists of the source * and destination addresses, the packet length and the next header field. */ sum = upperlen + proto; /* Sum IP source and destination addresses. */ sum = chksum(sum, (FAR uint8_t *)&ipv6->srcipaddr, 2 * sizeof(net_ipv6addr_t)); /* Sum IP payload data. */ sum = chksum(sum, &buffer[IPv6_HDRLEN], upperlen); return (sum == 0) ? 0xffff : htons(sum); #else FAR struct ipv4_hdr_s *ipv4 = (FAR struct ipv4_hdr_s *)buffer; uint16_t upperlen; uint16_t sum; /* The length reported in the IPv4 header is the length of both the IPv4 * header and the payload that follows the header. We need to subtract * the size of the IPv4 header to get the size of the payload. */ upperlen = (((uint16_t)(ipv4->len[0]) << 8) + ipv4->len[1]) - IPv4_HDRLEN; /* First sum pseudo-header. */ /* IP protocol and length fields. This addition cannot carry. */ sum = upperlen + proto; /* Sum IP source and destination addresses. */ sum = chksum(sum, (FAR uint8_t *)&ipv4->srcipaddr, 2 * sizeof(in_addr_t)); /* Sum IP payload data. */ sum = chksum(sum, &buffer[IPv4_HDRLEN], upperlen); return (sum == 0) ? 0xffff : htons(sum); #endif } #ifdef CONFIG_EXAMPLES_IPFORWARD_TCP static uint16_t tcp_chksum(FAR uint8_t *buffer) { return common_chksum(buffer, IP_PROTO_TCP); } #endif /* CONFIG_NET_IPv6 */ #ifdef CONFIG_EXAMPLES_IPFORWARD_ICMPv6 static uint16_t icmpv6_chksum(FAR uint8_t *buffer) { return common_chksum(buffer, IP_PROTO_ICMP6); } #endif /**************************************************************************** * Name: ipfwd_dumppkt (and friends) ****************************************************************************/ static char lib_nibble(unsigned char nibble) { if (nibble < 10) { return '0' + nibble; } else { return 'a' + nibble - 10; } } static void ipfwd_dumpbuffer(FAR uint8_t *buffer, size_t buflen) { unsigned int i; unsigned int j; unsigned int k; for (i = 0; i < buflen; i += NBYTES_PER_LINE) { putchar(' '); putchar(' '); /* Generate hex values: 2 * NBYTES_PER_LINE + 1 bytes */ for (j = 0; j < NBYTES_PER_LINE; j++) { k = i + j; if (j == (NBYTES_PER_LINE / 2)) { putchar(' '); } if (k < buflen) { putchar(lib_nibble((buffer[k] >> 4) & 0xf)); putchar(lib_nibble(buffer[k] & 0xf)); } else { putchar(' '); putchar(' '); } } putchar('\n'); } } static void ipfwd_dumppkt(FAR uint8_t *buffer, size_t buflen) { size_t dumpsize; if (buflen <= 0) { return; } dumpsize = IP_HDRLEN; if (dumpsize > buflen) { printf("Truncated "); dumpsize = buflen; } printf("IP Header:\n"); ipfwd_dumpbuffer(buffer, dumpsize); buffer += dumpsize; buflen -= dumpsize; if (buflen <= 0) { printf("Packet truncated\n"); return; } #ifdef CONFIG_EXAMPLES_IPFORWARD_TCP dumpsize = TCP_HDRLEN; if (dumpsize > buflen) { printf("Truncated "); dumpsize = buflen; } printf("TCP Header:\n"); ipfwd_dumpbuffer(buffer, dumpsize); buffer += dumpsize; buflen -= dumpsize; if (buflen <= 0) { printf("Packet truncated\n"); return; } printf("Payload:\n"); ipfwd_dumpbuffer(buffer, buflen); #else dumpsize = SIZEOF_ICMPV6_NEIGHBOR_SOLICIT_S(MAC_ADDRLEN); if (dumpsize > buflen) { printf("Truncated "); dumpsize = buflen; } printf("ICMPv6 Neighbor Solicitation:\n"); ipfwd_dumpbuffer(buffer, dumpsize); #endif } /**************************************************************************** * Name: ipfwd_receiver ****************************************************************************/ static FAR void *ipfwd_receiver(FAR void *arg) { FAR struct ipfwd_arg_s *fwd = (FAR struct ipfwd_arg_s *)arg; ssize_t nread; int errcode; int i; for (i = 0; i < IPFWD_NPACKETS; i++) { nread = read(fwd->ia_fd, fwd->ia_buffer, IPFWD_BUFSIZE); if (nread < 0) { errcode = errno; fprintf(stderr, "ERROR: read() failed: %d\n", errcode); break; } printf("Received packet %d: size=%lu\n", i + 1, (unsigned long)nread); ipfwd_dumppkt(fwd->ia_buffer, nread); } return NULL; } /**************************************************************************** * Name: ipfwd_sender ****************************************************************************/ static FAR void *ipfwd_sender(FAR void *arg) { FAR struct ipfwd_arg_s *fwd = (FAR struct ipfwd_arg_s *)arg; #ifdef CONFIG_NET_IPv6 FAR struct ipv6_hdr_s *ipv6; #else FAR struct ipv4_hdr_s *ipv4; #endif #ifdef CONFIG_EXAMPLES_IPFORWARD_TCP FAR struct tcp_hdr_s *tcp; FAR char *payload; #endif #ifdef CONFIG_EXAMPLES_IPFORWARD_ICMPv6 FAR struct icmpv6_neighbor_solicit_s *sol; #endif size_t paysize; size_t pktlen; ssize_t nwritten; uint16_t l3hdrlen; uint8_t proto; int errcode; int i; #ifdef CONFIG_EXAMPLES_IPFORWARD_TCP l3hdrlen = TCP_HDRLEN; paysize = sizeof(g_payload); proto = IP_PROTO_TCP; #else l3hdrlen = SIZEOF_ICMPV6_NEIGHBOR_SOLICIT_S(MAC_ADDRLEN); paysize = 0; proto = IP_PROTO_ICMP6; #endif for (i = 0; i < IPFWD_NPACKETS; i++) { #ifdef CONFIG_NET_IPv6 ipv6 = (FAR struct ipv6_hdr_s *)fwd->ia_buffer; /* Set up the IPv6 header */ ipv6->vtc = 0x60; /* Version/traffic class (MS) */ ipv6->tcf = 0; /* Traffic class (LS)/Flow label (MS) */ ipv6->flow = 0; /* Flow label (LS) */ /* Length excludes the IPv6 header */ pktlen = l3hdrlen + paysize; ipv6->len[0] = (pktlen >> 8); ipv6->len[1] = (pktlen & 0xff); ipv6->proto = proto; /* Next header */ ipv6->ttl = 255; /* Hop limit */ #ifdef CONFIG_EXAMPLES_IPFORWARD_TCP /* Set the uniicast destination IP address */ net_ipv6addr_copy(ipv6->destipaddr, fwd->ia_destipaddr); #else /* Set the multicast destination IP address */ ipv6->destipaddr[0] = HTONS(0xff02); ipv6->destipaddr[1] = HTONS(0x0000); ipv6->destipaddr[2] = HTONS(0x0000); ipv6->destipaddr[3] = HTONS(0x0000); ipv6->destipaddr[4] = HTONS(0x0000); ipv6->destipaddr[5] = HTONS(0x0001); ipv6->destipaddr[6] = fwd->ia_destipaddr[6] | HTONS(0xff00); ipv6->destipaddr[7] = fwd->ia_destipaddr[7]; #endif /* Set source IP address. */ net_ipv6addr_copy(ipv6->srcipaddr, fwd->ia_srcipaddr); pktlen = IPv6_HDRLEN + l3hdrlen + paysize; #ifdef CONFIG_EXAMPLES_IPFORWARD_TCP tcp = (FAR struct tcp_hdr_s *) &fwd->ia_buffer[IPv6_HDRLEN]; #else sol = (FAR struct icmpv6_neighbor_solicit_s *) &fwd->ia_buffer[IPv6_HDRLEN]; #endif #else ipv4 = (FAR struct ipv4_hdr_s *)fwd->ia_buffer; /* Set up the IPv4 header */ ipv4->vhl = 0x45; ipv4->tos = 0; pktlen = IPv4_HDRLEN + l3hdrlen + paysize; ipv4->len[0] = (pktlen >> 8); ipv4->len[1] = (pktlen & 0xff); ++g_ipid; ipv4->ipid[0] = g_ipid >> 8; ipv4->ipid[1] = g_ipid & 0xff; ipv4->ipoffset[0] = IP_FLAG_DONTFRAG >> 8; ipv4->ipoffset[1] = IP_FLAG_DONTFRAG & 0xff; ipv4->ttl = IP_TTL; ipv4->proto = proto; net_ipv4addr_hdrcopy(ipv4->srcipaddr, &fwd->ia_srcipaddr); net_ipv4addr_hdrcopy(ipv4->destipaddr, &fwd->ia_destipaddr); /* Calculate IP checksum. */ ipv4->ipchksum = 0; ipv4->ipchksum = ~(ipv4_chksum(fwd->ia_buffer)); #ifdef CONFIG_EXAMPLES_IPFORWARD_TCP tcp = (FAR struct tcp_hdr_s *) &fwd->ia_buffer[IPv4_HDRLEN]; #else sol = (FAR struct icmpv6_neighbor_solicit_s *) &fwd->ia_buffer[IPv4_HDRLEN]; #endif #endif #ifdef CONFIG_EXAMPLES_IPFORWARD_TCP /* Set up the TCP header. NOTE: Most of the elements are irrelevant * in this test. The forwarding is L2 layer only and the L3 header * content is not used in the forwarding. */ memset(tcp, 0, sizeof(struct tcp_hdr_s)); tcp->srcport = HTONS((0x1234 + i) & 0xffff); tcp->destport = HTONS(0xabcd); tcp->tcpoffset = (TCP_HDRLEN / 4) << 4; payload = (FAR char *)tcp + TCP_HDRLEN; memcpy(payload, g_payload, paysize); tcp->tcpchksum = ~tcp_chksum(fwd->ia_buffer); #else /* Set up the ICMPv6 Neighbor Solicitation message */ sol->type = ICMPv6_NEIGHBOR_SOLICIT; /* Message type */ sol->code = 0; /* Message qualifier */ sol->flags[0] = 0; /* flags */ sol->flags[1] = 0; sol->flags[2] = 0; sol->flags[3] = 0; /* Copy the target address into the Neighbor Solicitation message */ net_ipv6addr_copy(sol->tgtaddr, fwd->ia_destipaddr); /* Set up the options */ sol->opttype = ICMPv6_OPT_SRCLLADDR; /* Option type */ sol->optlen = ICMPv6_OPT_OCTECTS(MAC_ADDRLEN); /* Option length in octets */ /* Copy our link layer address into the message */ memset(sol->srclladdr, 0x88, MAC_ADDRLEN); /* Calculate the checksum over both the ICMP header and payload */ sol->chksum = 0; sol->chksum = ~icmpv6_chksum(fwd->ia_buffer); #endif printf("Sending packet %d: size=%lu\n", i + 1, (unsigned long)pktlen); ipfwd_dumppkt(fwd->ia_buffer, pktlen); nwritten = write(fwd->ia_fd, fwd->ia_buffer, pktlen); if (nwritten < 0) { errcode = errno; fprintf(stderr, "ERROR: write() failed: %d\n", errcode); break; } printf(" %lu bytes sent\n", (unsigned long)nwritten); } return NULL; } /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: fstest_main ****************************************************************************/ int main(int argc, FAR char *argv[]) { struct ipfwd_state_s fwd; struct ipfwd_arg_s tun0arg; struct ipfwd_arg_s tun1arg; FAR void *value; int errcode = EXIT_SUCCESS; int ret; /* Initialize the first TUN device */ ret = ipfwd_tun_configure(&fwd.if_tun0); if (ret < 0) { fprintf(stderr, "ERROR: Failed to create tun0: %d\n", ret); goto errout; } ret = ipfwd_netconfig(&fwd.if_tun0, g_tun0_laddr, g_netmask); if (ret < 0) { fprintf(stderr, "ERROR: ipfwd_netconfig for tun0 failed: %d\n", ret); goto errout_with_tun0; } /* Initialize the second TUN device */ ret = ipfwd_tun_configure(&fwd.if_tun1); if (ret < 0) { fprintf(stderr, "ERROR: Failed to create tun1: %d\n", ret); goto errout_with_tun0; } ret = ipfwd_netconfig(&fwd.if_tun1, g_tun1_laddr, g_netmask); if (ret < 0) { fprintf(stderr, "ERROR: ipfwd_netconfig tun1 failed: %d\n", ret); errcode = EXIT_FAILURE; goto errout_with_tun1; } /* Start receiver thread on tun1 */ tun1arg.ia_fd = fwd.if_tun1.it_fd; tun1arg.ia_srcipaddr = g_tun1_raddr; tun1arg.ia_destipaddr = g_tun0_raddr; ret = pthread_create(&fwd.if_receiver, NULL, ipfwd_receiver, &tun1arg); if (ret != 0) { fprintf(stderr, "ERROR: pthread_create() failed for receiver: %d\n", ret); errcode = EXIT_FAILURE; goto errout_with_tun1; } /* Start sender thread on tun0 */ tun0arg.ia_fd = fwd.if_tun0.it_fd; tun0arg.ia_srcipaddr = g_tun0_raddr; tun0arg.ia_destipaddr = g_tun1_raddr; ret = pthread_create(&fwd.if_sender, NULL, ipfwd_sender, &tun0arg); if (ret != 0) { fprintf(stderr, "ERROR: pthread_create() failed for sender: %d\n", ret); errcode = EXIT_FAILURE; goto errout_with_receiver; } /* Wait for sender thread to terminate */ ret = pthread_join(fwd.if_sender, &value); if (ret != OK) { fprintf(stderr, "ERROR: pthread_join() failed for sender: %d\n", ret); } errout_with_receiver: /* Wait for receiver thread to terminate */ pthread_kill(fwd.if_receiver, 9); ret = pthread_join(fwd.if_receiver, &value); if (ret != OK) { fprintf(stderr, "ERROR: pthread_join() failed for receiver: %d\n", ret); } errout_with_tun1: close(fwd.if_tun1.it_fd); errout_with_tun0: close(fwd.if_tun0.it_fd); errout: return errcode; }