/* * pcap-linux.c: Packet capture interface to the Linux kernel * * Copyright (c) 2000 Torsten Landschoff * Sebastian Krahmer * * License: BSD * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. The names of the authors may not be used to endorse or promote * products derived from this software without specific prior * written permission. * * THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. * * Modifications: Added PACKET_MMAP support * Paolo Abeni * * based on previous works of: * Simon Patarin * Phil Wood */ #ifndef lint static const char rcsid[] _U_ = "@(#) $Header: /tcpdump/master/libpcap/pcap-linux.c,v 1.129.2.29 2008-10-28 00:50:39 guy Exp $ (LBL)"; #endif /* * Known problems with 2.0[.x] kernels: * * - The loopback device gives every packet twice; on 2.2[.x] kernels, * if we use PF_PACKET, we can filter out the transmitted version * of the packet by using data in the "sockaddr_ll" returned by * "recvfrom()", but, on 2.0[.x] kernels, we have to use * PF_INET/SOCK_PACKET, which means "recvfrom()" supplies a * "sockaddr_pkt" which doesn't give us enough information to let * us do that. * * - We have to set the interface's IFF_PROMISC flag ourselves, if * we're to run in promiscuous mode, which means we have to turn * it off ourselves when we're done; the kernel doesn't keep track * of how many sockets are listening promiscuously, which means * it won't get turned off automatically when no sockets are * listening promiscuously. We catch "pcap_close()" and, for * interfaces we put into promiscuous mode, take them out of * promiscuous mode - which isn't necessarily the right thing to * do, if another socket also requested promiscuous mode between * the time when we opened the socket and the time when we close * the socket. * * - MSG_TRUNC isn't supported, so you can't specify that "recvfrom()" * return the amount of data that you could have read, rather than * the amount that was returned, so we can't just allocate a buffer * whose size is the snapshot length and pass the snapshot length * as the byte count, and also pass MSG_TRUNC, so that the return * value tells us how long the packet was on the wire. * * This means that, if we want to get the actual size of the packet, * so we can return it in the "len" field of the packet header, * we have to read the entire packet, not just the part that fits * within the snapshot length, and thus waste CPU time copying data * from the kernel that our caller won't see. * * We have to get the actual size, and supply it in "len", because * otherwise, the IP dissector in tcpdump, for example, will complain * about "truncated-ip", as the packet will appear to have been * shorter, on the wire, than the IP header said it should have been. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Got Wireless Extensions? */ #ifdef HAVE_LINUX_WIRELESS_H #include #endif #include "pcap-int.h" #include "pcap/sll.h" #include "pcap/vlan.h" #ifdef HAVE_DAG_API #include "pcap-dag.h" #endif /* HAVE_DAG_API */ #ifdef HAVE_SEPTEL_API #include "pcap-septel.h" #endif /* HAVE_SEPTEL_API */ #ifdef PCAP_SUPPORT_USB #include "pcap-usb-linux.h" #endif #ifdef PCAP_SUPPORT_BT #include "pcap-bt-linux.h" #endif /* * If PF_PACKET is defined, we can use {SOCK_RAW,SOCK_DGRAM}/PF_PACKET * sockets rather than SOCK_PACKET sockets. * * To use them, we include rather than * ; we do so because * * some Linux distributions (e.g., Slackware 4.0) have 2.2 or * later kernels and libc5, and don't provide a * file; * * not all versions of glibc2 have a file * that defines stuff needed for some of the 2.4-or-later-kernel * features, so if the system has a 2.4 or later kernel, we * still can't use those features. * * We're already including a number of other headers, and * this code is Linux-specific (no other OS has PF_PACKET sockets as * a raw packet capture mechanism), so it's not as if you gain any * useful portability by using * * XXX - should we just include even if PF_PACKET * isn't defined? It only defines one data structure in 2.0.x, so * it shouldn't cause any problems. */ #ifdef PF_PACKET # include /* * On at least some Linux distributions (for example, Red Hat 5.2), * there's no file, but PF_PACKET is defined if * you include , but doesn't define * any of the PF_PACKET stuff such as "struct sockaddr_ll" or any of * the PACKET_xxx stuff. * * So we check whether PACKET_HOST is defined, and assume that we have * PF_PACKET sockets only if it is defined. */ # ifdef PACKET_HOST # define HAVE_PF_PACKET_SOCKETS # ifdef PACKET_AUXDATA # define HAVE_PACKET_AUXDATA # endif /* PACKET_AUXDATA */ # endif /* PACKET_HOST */ /* check for memory mapped access avaibility. We assume every needed * struct is defined if the macro TPACKET_HDRLEN is defined, because it * uses many ring related structs and macros */ # ifdef TPACKET_HDRLEN # define HAVE_PACKET_RING # ifdef TPACKET2_HDRLEN # define HAVE_TPACKET2 # else # define TPACKET_V1 0 # endif /* TPACKET2_HDRLEN */ # endif /* TPACKET_HDRLEN */ #endif /* PF_PACKET */ #ifdef SO_ATTACH_FILTER #include #include #endif #ifndef HAVE_SOCKLEN_T typedef int socklen_t; #endif #ifndef MSG_TRUNC /* * This is being compiled on a system that lacks MSG_TRUNC; define it * with the value it has in the 2.2 and later kernels, so that, on * those kernels, when we pass it in the flags argument to "recvfrom()" * we're passing the right value and thus get the MSG_TRUNC behavior * we want. (We don't get that behavior on 2.0[.x] kernels, because * they didn't support MSG_TRUNC.) */ #define MSG_TRUNC 0x20 #endif #ifndef SOL_PACKET /* * This is being compiled on a system that lacks SOL_PACKET; define it * with the value it has in the 2.2 and later kernels, so that we can * set promiscuous mode in the good modern way rather than the old * 2.0-kernel crappy way. */ #define SOL_PACKET 263 #endif #define MAX_LINKHEADER_SIZE 256 /* * When capturing on all interfaces we use this as the buffer size. * Should be bigger then all MTUs that occur in real life. * 64kB should be enough for now. */ #define BIGGER_THAN_ALL_MTUS (64*1024) /* * Prototypes for internal functions and methods. */ static void map_arphrd_to_dlt(pcap_t *, int, int); #ifdef HAVE_PF_PACKET_SOCKETS static short int map_packet_type_to_sll_type(short int); #endif static int pcap_activate_linux(pcap_t *); static int activate_old(pcap_t *); static int activate_new(pcap_t *); static int activate_mmap(pcap_t *); static int pcap_can_set_rfmon_linux(pcap_t *); static int pcap_read_linux(pcap_t *, int, pcap_handler, u_char *); static int pcap_read_packet(pcap_t *, pcap_handler, u_char *); static int pcap_inject_linux(pcap_t *, const void *, size_t); static int pcap_stats_linux(pcap_t *, struct pcap_stat *); static int pcap_setfilter_linux(pcap_t *, struct bpf_program *); static int pcap_setdirection_linux(pcap_t *, pcap_direction_t); static void pcap_cleanup_linux(pcap_t *); union thdr { struct tpacket_hdr *h1; struct tpacket2_hdr *h2; void *raw; }; #ifdef HAVE_PACKET_RING #define RING_GET_FRAME(h) (((union thdr **)h->buffer)[h->offset]) static void destroy_ring(pcap_t *handle); static int create_ring(pcap_t *handle); static int prepare_tpacket_socket(pcap_t *handle); static void pcap_cleanup_linux_mmap(pcap_t *); static int pcap_read_linux_mmap(pcap_t *, int, pcap_handler , u_char *); static int pcap_setfilter_linux_mmap(pcap_t *, struct bpf_program *); static int pcap_setnonblock_mmap(pcap_t *p, int nonblock, char *errbuf); static int pcap_getnonblock_mmap(pcap_t *p, char *errbuf); #endif /* * Wrap some ioctl calls */ #ifdef HAVE_PF_PACKET_SOCKETS static int iface_get_id(int fd, const char *device, char *ebuf); #endif static int iface_get_mtu(int fd, const char *device, char *ebuf); static int iface_get_arptype(int fd, const char *device, char *ebuf); #ifdef HAVE_PF_PACKET_SOCKETS static int iface_bind(int fd, int ifindex, char *ebuf); static int has_wext(int sock_fd, const char *device, char *ebuf); static int enter_rfmon_mode_wext(pcap_t *handle, int sock_fd, const char *device); #endif static int iface_bind_old(int fd, const char *device, char *ebuf); #ifdef SO_ATTACH_FILTER static int fix_program(pcap_t *handle, struct sock_fprog *fcode); static int fix_offset(struct bpf_insn *p); static int set_kernel_filter(pcap_t *handle, struct sock_fprog *fcode); static int reset_kernel_filter(pcap_t *handle); static struct sock_filter total_insn = BPF_STMT(BPF_RET | BPF_K, 0); static struct sock_fprog total_fcode = { 1, &total_insn }; #endif pcap_t * pcap_create(const char *device, char *ebuf) { pcap_t *handle; #ifdef HAVE_DAG_API if (strstr(device, "dag")) { return dag_create(device, ebuf); } #endif /* HAVE_DAG_API */ #ifdef HAVE_SEPTEL_API if (strstr(device, "septel")) { return septel_create(device, ebuf); } #endif /* HAVE_SEPTEL_API */ #ifdef PCAP_SUPPORT_BT if (strstr(device, "bluetooth")) { return bt_create(device, ebuf); } #endif #ifdef PCAP_SUPPORT_USB if (strstr(device, "usb")) { return usb_create(device, ebuf); } #endif handle = pcap_create_common(device, ebuf); if (handle == NULL) return NULL; handle->activate_op = pcap_activate_linux; handle->can_set_rfmon_op = pcap_can_set_rfmon_linux; return handle; } static int pcap_can_set_rfmon_linux(pcap_t *p) { #ifdef IW_MODE_MONITOR int sock_fd; struct iwreq ireq; #endif if (p->opt.source == NULL) { /* * This is equivalent to the "any" device, and we don't * support monitor mode on it. */ return 0; } #ifdef IW_MODE_MONITOR /* * Bleah. There doesn't appear to be an ioctl to use to ask * whether a device supports monitor mode; we'll just do * SIOCGIWMODE and, if it succeeds, assume the device supports * monitor mode. * * Open a socket on which to attempt to get the mode. * (We assume that if we have Wireless Extensions support * we also have PF_PACKET support.) */ sock_fd = socket(PF_PACKET, SOCK_RAW, htons(ETH_P_ALL)); if (sock_fd == -1) { (void)snprintf(p->errbuf, PCAP_ERRBUF_SIZE, "socket: %s", pcap_strerror(errno)); return PCAP_ERROR; } /* * Attempt to get the current mode. */ strncpy(ireq.ifr_ifrn.ifrn_name, p->opt.source, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; if (ioctl(sock_fd, SIOCGIWMODE, &ireq) != -1) { /* * Well, we got the mode; assume we can set it. */ close(sock_fd); return 1; } if (errno == ENODEV) { /* The device doesn't even exist. */ close(sock_fd); return PCAP_ERROR_NO_SUCH_DEVICE; } close(sock_fd); #endif return 0; } /* * With older kernels promiscuous mode is kind of interesting because we * have to reset the interface before exiting. The problem can't really * be solved without some daemon taking care of managing usage counts. * If we put the interface into promiscuous mode, we set a flag indicating * that we must take it out of that mode when the interface is closed, * and, when closing the interface, if that flag is set we take it out * of promiscuous mode. * * Even with newer kernels, we have the same issue with rfmon mode. */ static void pcap_cleanup_linux( pcap_t *handle ) { struct ifreq ifr; #ifdef IW_MODE_MONITOR struct iwreq ireq; #endif if (handle->md.must_clear != 0) { /* * There's something we have to do when closing this * pcap_t. */ if (handle->md.must_clear & MUST_CLEAR_PROMISC) { /* * We put the interface into promiscuous mode; * take it out of promiscuous mode. * * XXX - if somebody else wants it in promiscuous * mode, this code cannot know that, so it'll take * it out of promiscuous mode. That's not fixable * in 2.0[.x] kernels. */ memset(&ifr, 0, sizeof(ifr)); strncpy(ifr.ifr_name, handle->md.device, sizeof(ifr.ifr_name)); if (ioctl(handle->fd, SIOCGIFFLAGS, &ifr) == -1) { fprintf(stderr, "Can't restore interface flags (SIOCGIFFLAGS failed: %s).\n" "Please adjust manually.\n" "Hint: This can't happen with Linux >= 2.2.0.\n", strerror(errno)); } else { if (ifr.ifr_flags & IFF_PROMISC) { /* * Promiscuous mode is currently on; * turn it off. */ ifr.ifr_flags &= ~IFF_PROMISC; if (ioctl(handle->fd, SIOCSIFFLAGS, &ifr) == -1) { fprintf(stderr, "Can't restore interface flags (SIOCSIFFLAGS failed: %s).\n" "Please adjust manually.\n" "Hint: This can't happen with Linux >= 2.2.0.\n", strerror(errno)); } } } } #ifdef IW_MODE_MONITOR if (handle->md.must_clear & MUST_CLEAR_RFMON) { /* * We put the interface into rfmon mode; * take it out of rfmon mode. * * XXX - if somebody else wants it in rfmon * mode, this code cannot know that, so it'll take * it out of rfmon mode. */ strncpy(ireq.ifr_ifrn.ifrn_name, handle->md.device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; ireq.u.mode = handle->md.oldmode; if (ioctl(handle->fd, SIOCSIWMODE, &ireq) == -1) { /* * Scientist, you've failed. */ fprintf(stderr, "Can't restore interface wireless mode (SIOCSIWMODE failed: %s).\n" "Please adjust manually.\n", strerror(errno)); } } #endif /* * Take this pcap out of the list of pcaps for which we * have to take the interface out of some mode. */ pcap_remove_from_pcaps_to_close(handle); } if (handle->md.device != NULL) { free(handle->md.device); handle->md.device = NULL; } pcap_cleanup_live_common(handle); } /* * Get a handle for a live capture from the given device. You can * pass NULL as device to get all packages (without link level * information of course). If you pass 1 as promisc the interface * will be set to promiscous mode (XXX: I think this usage should * be deprecated and functions be added to select that later allow * modification of that values -- Torsten). */ static int pcap_activate_linux(pcap_t *handle) { const char *device; int status = 0; int activate_ok = 0; device = handle->opt.source; handle->inject_op = pcap_inject_linux; handle->setfilter_op = pcap_setfilter_linux; handle->setdirection_op = pcap_setdirection_linux; handle->set_datalink_op = NULL; /* can't change data link type */ handle->getnonblock_op = pcap_getnonblock_fd; handle->setnonblock_op = pcap_setnonblock_fd; handle->cleanup_op = pcap_cleanup_linux; handle->read_op = pcap_read_linux; handle->stats_op = pcap_stats_linux; /* * NULL and "any" are special devices which give us the hint to * monitor all devices. */ if (!device || strcmp(device, "any") == 0) { device = NULL; handle->md.device = strdup("any"); if (handle->opt.promisc) { handle->opt.promisc = 0; /* Just a warning. */ snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "Promiscuous mode not supported on the \"any\" device"); status = PCAP_WARNING_PROMISC_NOTSUP; } } else handle->md.device = strdup(device); if (handle->md.device == NULL) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "strdup: %s", pcap_strerror(errno) ); return PCAP_ERROR; } /* * Current Linux kernels use the protocol family PF_PACKET to * allow direct access to all packets on the network while * older kernels had a special socket type SOCK_PACKET to * implement this feature. * While this old implementation is kind of obsolete we need * to be compatible with older kernels for a while so we are * trying both methods with the newer method preferred. */ if ((status = activate_new(handle)) == 1) { activate_ok = 1; /* * Try to use memory-mapped access. */ if (activate_mmap(handle) == 1) return 0; /* we succeeded; nothing more to do */ } else if (status == 0) { /* Non-fatal error; try old way */ if ((status = activate_old(handle)) == 1) activate_ok = 1; } if (!activate_ok) { /* * Both methods to open the packet socket failed. Tidy * up and report our failure (ebuf is expected to be * set by the functions above). */ goto fail; } if (handle->opt.buffer_size != 0) { /* * Set the socket buffer size to the specified value. */ if (setsockopt(handle->fd, SOL_SOCKET, SO_RCVBUF, &handle->opt.buffer_size, sizeof(handle->opt.buffer_size)) == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "SO_RCVBUF: %s", pcap_strerror(errno)); status = PCAP_ERROR; goto fail; } } /* Allocate the buffer */ handle->buffer = malloc(handle->bufsize + handle->offset); if (!handle->buffer) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "malloc: %s", pcap_strerror(errno)); status = PCAP_ERROR; goto fail; } /* * "handle->fd" is a socket, so "select()" and "poll()" * should work on it. */ handle->selectable_fd = handle->fd; return status; fail: pcap_cleanup_linux(handle); return status; } /* * Read at most max_packets from the capture stream and call the callback * for each of them. Returns the number of packets handled or -1 if an * error occured. */ static int pcap_read_linux(pcap_t *handle, int max_packets, pcap_handler callback, u_char *user) { /* * Currently, on Linux only one packet is delivered per read, * so we don't loop. */ return pcap_read_packet(handle, callback, user); } /* * Read a packet from the socket calling the handler provided by * the user. Returns the number of packets received or -1 if an * error occured. */ static int pcap_read_packet(pcap_t *handle, pcap_handler callback, u_char *userdata) { u_char *bp; int offset; #ifdef HAVE_PF_PACKET_SOCKETS struct sockaddr_ll from; struct sll_header *hdrp; #else struct sockaddr from; #endif #if defined(HAVE_PACKET_AUXDATA) && defined(HAVE_LINUX_TPACKET_AUXDATA_TP_VLAN_TCI) struct iovec iov; struct msghdr msg; struct cmsghdr *cmsg; union { struct cmsghdr cmsg; char buf[CMSG_SPACE(sizeof(struct tpacket_auxdata))]; } cmsg_buf; #else /* defined(HAVE_PACKET_AUXDATA) && defined(HAVE_LINUX_TPACKET_AUXDATA_TP_VLAN_TCI) */ socklen_t fromlen; #endif /* defined(HAVE_PACKET_AUXDATA) && defined(HAVE_LINUX_TPACKET_AUXDATA_TP_VLAN_TCI) */ int packet_len, caplen; struct pcap_pkthdr pcap_header; #ifdef HAVE_PF_PACKET_SOCKETS /* * If this is a cooked device, leave extra room for a * fake packet header. */ if (handle->md.cooked) offset = SLL_HDR_LEN; else offset = 0; #else /* * This system doesn't have PF_PACKET sockets, so it doesn't * support cooked devices. */ offset = 0; #endif /* * Receive a single packet from the kernel. * We ignore EINTR, as that might just be due to a signal * being delivered - if the signal should interrupt the * loop, the signal handler should call pcap_breakloop() * to set handle->break_loop (we ignore it on other * platforms as well). * We also ignore ENETDOWN, so that we can continue to * capture traffic if the interface goes down and comes * back up again; comments in the kernel indicate that * we'll just block waiting for packets if we try to * receive from a socket that delivered ENETDOWN, and, * if we're using a memory-mapped buffer, we won't even * get notified of "network down" events. */ bp = handle->buffer + handle->offset; #if defined(HAVE_PACKET_AUXDATA) && defined(HAVE_LINUX_TPACKET_AUXDATA_TP_VLAN_TCI) msg.msg_name = &from; msg.msg_namelen = sizeof(from); msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_control = &cmsg_buf; msg.msg_controllen = sizeof(cmsg_buf); msg.msg_flags = 0; iov.iov_len = handle->bufsize - offset; iov.iov_base = bp + offset; #endif /* defined(HAVE_PACKET_AUXDATA) && defined(HAVE_LINUX_TPACKET_AUXDATA_TP_VLAN_TCI) */ do { /* * Has "pcap_breakloop()" been called? */ if (handle->break_loop) { /* * Yes - clear the flag that indicates that it * has, and return -2 as an indication that we * were told to break out of the loop. */ handle->break_loop = 0; return -2; } #if defined(HAVE_PACKET_AUXDATA) && defined(HAVE_LINUX_TPACKET_AUXDATA_TP_VLAN_TCI) packet_len = recvmsg(handle->fd, &msg, MSG_TRUNC); #else /* defined(HAVE_PACKET_AUXDATA) && defined(HAVE_LINUX_TPACKET_AUXDATA_TP_VLAN_TCI) */ fromlen = sizeof(from); packet_len = recvfrom( handle->fd, bp + offset, handle->bufsize - offset, MSG_TRUNC, (struct sockaddr *) &from, &fromlen); #endif /* defined(HAVE_PACKET_AUXDATA) && defined(HAVE_LINUX_TPACKET_AUXDATA_TP_VLAN_TCI) */ } while (packet_len == -1 && (errno == EINTR || errno == ENETDOWN)); /* Check if an error occured */ if (packet_len == -1) { if (errno == EAGAIN) return 0; /* no packet there */ else { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "recvfrom: %s", pcap_strerror(errno)); return -1; } } #ifdef HAVE_PF_PACKET_SOCKETS if (!handle->md.sock_packet) { /* * Unfortunately, there is a window between socket() and * bind() where the kernel may queue packets from any * interface. If we're bound to a particular interface, * discard packets not from that interface. * * (If socket filters are supported, we could do the * same thing we do when changing the filter; however, * that won't handle packet sockets without socket * filter support, and it's a bit more complicated. * It would save some instructions per packet, however.) */ if (handle->md.ifindex != -1 && from.sll_ifindex != handle->md.ifindex) return 0; /* * Do checks based on packet direction. * We can only do this if we're using PF_PACKET; the * address returned for SOCK_PACKET is a "sockaddr_pkt" * which lacks the relevant packet type information. */ if (from.sll_pkttype == PACKET_OUTGOING) { /* * Outgoing packet. * If this is from the loopback device, reject it; * we'll see the packet as an incoming packet as well, * and we don't want to see it twice. */ if (from.sll_ifindex == handle->md.lo_ifindex) return 0; /* * If the user only wants incoming packets, reject it. */ if (handle->direction == PCAP_D_IN) return 0; } else { /* * Incoming packet. * If the user only wants outgoing packets, reject it. */ if (handle->direction == PCAP_D_OUT) return 0; } } #endif #ifdef HAVE_PF_PACKET_SOCKETS /* * If this is a cooked device, fill in the fake packet header. */ if (handle->md.cooked) { /* * Add the length of the fake header to the length * of packet data we read. */ packet_len += SLL_HDR_LEN; hdrp = (struct sll_header *)bp; hdrp->sll_pkttype = map_packet_type_to_sll_type(from.sll_pkttype); hdrp->sll_hatype = htons(from.sll_hatype); hdrp->sll_halen = htons(from.sll_halen); memcpy(hdrp->sll_addr, from.sll_addr, (from.sll_halen > SLL_ADDRLEN) ? SLL_ADDRLEN : from.sll_halen); hdrp->sll_protocol = from.sll_protocol; } #if defined(HAVE_PACKET_AUXDATA) && defined(HAVE_LINUX_TPACKET_AUXDATA_TP_VLAN_TCI) for (cmsg = CMSG_FIRSTHDR(&msg); cmsg; cmsg = CMSG_NXTHDR(&msg, cmsg)) { struct tpacket_auxdata *aux; unsigned int len; struct vlan_tag *tag; if (cmsg->cmsg_len < CMSG_LEN(sizeof(struct tpacket_auxdata)) || cmsg->cmsg_level != SOL_PACKET || cmsg->cmsg_type != PACKET_AUXDATA) continue; aux = (struct tpacket_auxdata *)CMSG_DATA(cmsg); if (aux->tp_vlan_tci == 0) continue; len = packet_len > iov.iov_len ? iov.iov_len : packet_len; if (len < 2 * ETH_ALEN) break; bp -= VLAN_TAG_LEN; memmove(bp, bp + VLAN_TAG_LEN, 2 * ETH_ALEN); tag = (struct vlan_tag *)(bp + 2 * ETH_ALEN); tag->vlan_tpid = htons(ETH_P_8021Q); tag->vlan_tci = htons(aux->tp_vlan_tci); packet_len += VLAN_TAG_LEN; } #endif /* defined(HAVE_PACKET_AUXDATA) && defined(HAVE_LINUX_TPACKET_AUXDATA_TP_VLAN_TCI) */ #endif /* HAVE_PF_PACKET_SOCKETS */ /* * XXX: According to the kernel source we should get the real * packet len if calling recvfrom with MSG_TRUNC set. It does * not seem to work here :(, but it is supported by this code * anyway. * To be honest the code RELIES on that feature so this is really * broken with 2.2.x kernels. * I spend a day to figure out what's going on and I found out * that the following is happening: * * The packet comes from a random interface and the packet_rcv * hook is called with a clone of the packet. That code inserts * the packet into the receive queue of the packet socket. * If a filter is attached to that socket that filter is run * first - and there lies the problem. The default filter always * cuts the packet at the snaplen: * * # tcpdump -d * (000) ret #68 * * So the packet filter cuts down the packet. The recvfrom call * says "hey, it's only 68 bytes, it fits into the buffer" with * the result that we don't get the real packet length. This * is valid at least until kernel 2.2.17pre6. * * We currently handle this by making a copy of the filter * program, fixing all "ret" instructions with non-zero * operands to have an operand of 65535 so that the filter * doesn't truncate the packet, and supplying that modified * filter to the kernel. */ caplen = packet_len; if (caplen > handle->snapshot) caplen = handle->snapshot; /* Run the packet filter if not using kernel filter */ if (!handle->md.use_bpf && handle->fcode.bf_insns) { if (bpf_filter(handle->fcode.bf_insns, bp, packet_len, caplen) == 0) { /* rejected by filter */ return 0; } } /* Fill in our own header data */ if (ioctl(handle->fd, SIOCGSTAMP, &pcap_header.ts) == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "SIOCGSTAMP: %s", pcap_strerror(errno)); return -1; } pcap_header.caplen = caplen; pcap_header.len = packet_len; /* * Count the packet. * * Arguably, we should count them before we check the filter, * as on many other platforms "ps_recv" counts packets * handed to the filter rather than packets that passed * the filter, but if filtering is done in the kernel, we * can't get a count of packets that passed the filter, * and that would mean the meaning of "ps_recv" wouldn't * be the same on all Linux systems. * * XXX - it's not the same on all systems in any case; * ideally, we should have a "get the statistics" call * that supplies more counts and indicates which of them * it supplies, so that we supply a count of packets * handed to the filter only on platforms where that * information is available. * * We count them here even if we can get the packet count * from the kernel, as we can only determine at run time * whether we'll be able to get it from the kernel (if * HAVE_TPACKET_STATS isn't defined, we can't get it from * the kernel, but if it is defined, the library might * have been built with a 2.4 or later kernel, but we * might be running on a 2.2[.x] kernel without Alexey * Kuznetzov's turbopacket patches, and thus the kernel * might not be able to supply those statistics). We * could, I guess, try, when opening the socket, to get * the statistics, and if we can not increment the count * here, but it's not clear that always incrementing * the count is more expensive than always testing a flag * in memory. * * We keep the count in "md.packets_read", and use that for * "ps_recv" if we can't get the statistics from the kernel. * We do that because, if we *can* get the statistics from * the kernel, we use "md.stat.ps_recv" and "md.stat.ps_drop" * as running counts, as reading the statistics from the * kernel resets the kernel statistics, and if we directly * increment "md.stat.ps_recv" here, that means it will * count packets *twice* on systems where we can get kernel * statistics - once here, and once in pcap_stats_linux(). */ handle->md.packets_read++; /* Call the user supplied callback function */ callback(userdata, &pcap_header, bp); return 1; } static int pcap_inject_linux(pcap_t *handle, const void *buf, size_t size) { int ret; #ifdef HAVE_PF_PACKET_SOCKETS if (!handle->md.sock_packet) { /* PF_PACKET socket */ if (handle->md.ifindex == -1) { /* * We don't support sending on the "any" device. */ strlcpy(handle->errbuf, "Sending packets isn't supported on the \"any\" device", PCAP_ERRBUF_SIZE); return (-1); } if (handle->md.cooked) { /* * We don't support sending on the "any" device. * * XXX - how do you send on a bound cooked-mode * socket? * Is a "sendto()" required there? */ strlcpy(handle->errbuf, "Sending packets isn't supported in cooked mode", PCAP_ERRBUF_SIZE); return (-1); } } #endif ret = send(handle->fd, buf, size, 0); if (ret == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "send: %s", pcap_strerror(errno)); return (-1); } return (ret); } /* * Get the statistics for the given packet capture handle. * Reports the number of dropped packets iff the kernel supports * the PACKET_STATISTICS "getsockopt()" argument (2.4 and later * kernels, and 2.2[.x] kernels with Alexey Kuznetzov's turbopacket * patches); otherwise, that information isn't available, and we lie * and report 0 as the count of dropped packets. */ static int pcap_stats_linux(pcap_t *handle, struct pcap_stat *stats) { #ifdef HAVE_TPACKET_STATS struct tpacket_stats kstats; socklen_t len = sizeof (struct tpacket_stats); #endif #ifdef HAVE_TPACKET_STATS /* * Try to get the packet counts from the kernel. */ if (getsockopt(handle->fd, SOL_PACKET, PACKET_STATISTICS, &kstats, &len) > -1) { /* * On systems where the PACKET_STATISTICS "getsockopt()" * argument is supported on PF_PACKET sockets: * * "ps_recv" counts only packets that *passed* the * filter, not packets that didn't pass the filter. * This includes packets later dropped because we * ran out of buffer space. * * "ps_drop" counts packets dropped because we ran * out of buffer space. It doesn't count packets * dropped by the interface driver. It counts only * packets that passed the filter. * * Both statistics include packets not yet read from * the kernel by libpcap, and thus not yet seen by * the application. * * In "linux/net/packet/af_packet.c", at least in the * 2.4.9 kernel, "tp_packets" is incremented for every * packet that passes the packet filter *and* is * successfully queued on the socket; "tp_drops" is * incremented for every packet dropped because there's * not enough free space in the socket buffer. * * When the statistics are returned for a PACKET_STATISTICS * "getsockopt()" call, "tp_drops" is added to "tp_packets", * so that "tp_packets" counts all packets handed to * the PF_PACKET socket, including packets dropped because * there wasn't room on the socket buffer - but not * including packets that didn't pass the filter. * * In the BSD BPF, the count of received packets is * incremented for every packet handed to BPF, regardless * of whether it passed the filter. * * We can't make "pcap_stats()" work the same on both * platforms, but the best approximation is to return * "tp_packets" as the count of packets and "tp_drops" * as the count of drops. * * Keep a running total because each call to * getsockopt(handle->fd, SOL_PACKET, PACKET_STATISTICS, .... * resets the counters to zero. */ handle->md.stat.ps_recv += kstats.tp_packets; handle->md.stat.ps_drop += kstats.tp_drops; *stats = handle->md.stat; return 0; } else { /* * If the error was EOPNOTSUPP, fall through, so that * if you build the library on a system with * "struct tpacket_stats" and run it on a system * that doesn't, it works as it does if the library * is built on a system without "struct tpacket_stats". */ if (errno != EOPNOTSUPP) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "pcap_stats: %s", pcap_strerror(errno)); return -1; } } #endif /* * On systems where the PACKET_STATISTICS "getsockopt()" argument * is not supported on PF_PACKET sockets: * * "ps_recv" counts only packets that *passed* the filter, * not packets that didn't pass the filter. It does not * count packets dropped because we ran out of buffer * space. * * "ps_drop" is not supported. * * "ps_recv" doesn't include packets not yet read from * the kernel by libpcap. * * We maintain the count of packets processed by libpcap in * "md.packets_read", for reasons described in the comment * at the end of pcap_read_packet(). We have no idea how many * packets were dropped. */ stats->ps_recv = handle->md.packets_read; stats->ps_drop = 0; return 0; } /* * Description string for the "any" device. */ static const char any_descr[] = "Pseudo-device that captures on all interfaces"; int pcap_platform_finddevs(pcap_if_t **alldevsp, char *errbuf) { if (pcap_add_if(alldevsp, "any", 0, any_descr, errbuf) < 0) return (-1); #ifdef HAVE_DAG_API if (dag_platform_finddevs(alldevsp, errbuf) < 0) return (-1); #endif /* HAVE_DAG_API */ #ifdef HAVE_SEPTEL_API if (septel_platform_finddevs(alldevsp, errbuf) < 0) return (-1); #endif /* HAVE_SEPTEL_API */ #ifdef PCAP_SUPPORT_BT if (bt_platform_finddevs(alldevsp, errbuf) < 0) return (-1); #endif #ifdef PCAP_SUPPORT_USB if (usb_platform_finddevs(alldevsp, errbuf) < 0) return (-1); #endif return (0); } /* * Attach the given BPF code to the packet capture device. */ static int pcap_setfilter_linux(pcap_t *handle, struct bpf_program *filter) { #ifdef SO_ATTACH_FILTER struct sock_fprog fcode; int can_filter_in_kernel; int err = 0; #endif if (!handle) return -1; if (!filter) { strncpy(handle->errbuf, "setfilter: No filter specified", PCAP_ERRBUF_SIZE); return -1; } /* Make our private copy of the filter */ if (install_bpf_program(handle, filter) < 0) /* install_bpf_program() filled in errbuf */ return -1; /* * Run user level packet filter by default. Will be overriden if * installing a kernel filter succeeds. */ handle->md.use_bpf = 0; /* Install kernel level filter if possible */ #ifdef SO_ATTACH_FILTER #ifdef USHRT_MAX if (handle->fcode.bf_len > USHRT_MAX) { /* * fcode.len is an unsigned short for current kernel. * I have yet to see BPF-Code with that much * instructions but still it is possible. So for the * sake of correctness I added this check. */ fprintf(stderr, "Warning: Filter too complex for kernel\n"); fcode.len = 0; fcode.filter = NULL; can_filter_in_kernel = 0; } else #endif /* USHRT_MAX */ { /* * Oh joy, the Linux kernel uses struct sock_fprog instead * of struct bpf_program and of course the length field is * of different size. Pointed out by Sebastian * * Oh, and we also need to fix it up so that all "ret" * instructions with non-zero operands have 65535 as the * operand, and so that, if we're in cooked mode, all * memory-reference instructions use special magic offsets * in references to the link-layer header and assume that * the link-layer payload begins at 0; "fix_program()" * will do that. */ switch (fix_program(handle, &fcode)) { case -1: default: /* * Fatal error; just quit. * (The "default" case shouldn't happen; we * return -1 for that reason.) */ return -1; case 0: /* * The program performed checks that we can't make * work in the kernel. */ can_filter_in_kernel = 0; break; case 1: /* * We have a filter that'll work in the kernel. */ can_filter_in_kernel = 1; break; } } if (can_filter_in_kernel) { if ((err = set_kernel_filter(handle, &fcode)) == 0) { /* Installation succeded - using kernel filter. */ handle->md.use_bpf = 1; } else if (err == -1) /* Non-fatal error */ { /* * Print a warning if we weren't able to install * the filter for a reason other than "this kernel * isn't configured to support socket filters. */ if (errno != ENOPROTOOPT && errno != EOPNOTSUPP) { fprintf(stderr, "Warning: Kernel filter failed: %s\n", pcap_strerror(errno)); } } } /* * If we're not using the kernel filter, get rid of any kernel * filter that might've been there before, e.g. because the * previous filter could work in the kernel, or because some other * code attached a filter to the socket by some means other than * calling "pcap_setfilter()". Otherwise, the kernel filter may * filter out packets that would pass the new userland filter. */ if (!handle->md.use_bpf) reset_kernel_filter(handle); /* * Free up the copy of the filter that was made by "fix_program()". */ if (fcode.filter != NULL) free(fcode.filter); if (err == -2) /* Fatal error */ return -1; #endif /* SO_ATTACH_FILTER */ return 0; } /* * Set direction flag: Which packets do we accept on a forwarding * single device? IN, OUT or both? */ static int pcap_setdirection_linux(pcap_t *handle, pcap_direction_t d) { #ifdef HAVE_PF_PACKET_SOCKETS if (!handle->md.sock_packet) { handle->direction = d; return 0; } #endif /* * We're not using PF_PACKET sockets, so we can't determine * the direction of the packet. */ snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "Setting direction is not supported on SOCK_PACKET sockets"); return -1; } #ifdef HAVE_PF_PACKET_SOCKETS /* * Map the PACKET_ value to a LINUX_SLL_ value; we * want the same numerical value to be used in * the link-layer header even if the numerical values * for the PACKET_ #defines change, so that programs * that look at the packet type field will always be * able to handle DLT_LINUX_SLL captures. */ static short int map_packet_type_to_sll_type(short int sll_pkttype) { switch (sll_pkttype) { case PACKET_HOST: return htons(LINUX_SLL_HOST); case PACKET_BROADCAST: return htons(LINUX_SLL_BROADCAST); case PACKET_MULTICAST: return htons(LINUX_SLL_MULTICAST); case PACKET_OTHERHOST: return htons(LINUX_SLL_OTHERHOST); case PACKET_OUTGOING: return htons(LINUX_SLL_OUTGOING); default: return -1; } } #endif /* * Linux uses the ARP hardware type to identify the type of an * interface. pcap uses the DLT_xxx constants for this. This * function takes a pointer to a "pcap_t", and an ARPHRD_xxx * constant, as arguments, and sets "handle->linktype" to the * appropriate DLT_XXX constant and sets "handle->offset" to * the appropriate value (to make "handle->offset" plus link-layer * header length be a multiple of 4, so that the link-layer payload * will be aligned on a 4-byte boundary when capturing packets). * (If the offset isn't set here, it'll be 0; add code as appropriate * for cases where it shouldn't be 0.) * * If "cooked_ok" is non-zero, we can use DLT_LINUX_SLL and capture * in cooked mode; otherwise, we can't use cooked mode, so we have * to pick some type that works in raw mode, or fail. * * Sets the link type to -1 if unable to map the type. */ static void map_arphrd_to_dlt(pcap_t *handle, int arptype, int cooked_ok) { switch (arptype) { case ARPHRD_ETHER: /* * This is (presumably) a real Ethernet capture; give it a * link-layer-type list with DLT_EN10MB and DLT_DOCSIS, so * that an application can let you choose it, in case you're * capturing DOCSIS traffic that a Cisco Cable Modem * Termination System is putting out onto an Ethernet (it * doesn't put an Ethernet header onto the wire, it puts raw * DOCSIS frames out on the wire inside the low-level * Ethernet framing). * * XXX - are there any sorts of "fake Ethernet" that have * ARPHRD_ETHER but that *shouldn't offer DLT_DOCSIS as * a Cisco CMTS won't put traffic onto it or get traffic * bridged onto it? ISDN is handled in "activate_new()", * as we fall back on cooked mode there; are there any * others? */ handle->dlt_list = (u_int *) malloc(sizeof(u_int) * 2); /* * If that fails, just leave the list empty. */ if (handle->dlt_list != NULL) { handle->dlt_list[0] = DLT_EN10MB; handle->dlt_list[1] = DLT_DOCSIS; handle->dlt_count = 2; } /* FALLTHROUGH */ case ARPHRD_METRICOM: case ARPHRD_LOOPBACK: handle->linktype = DLT_EN10MB; handle->offset = 2; break; case ARPHRD_EETHER: handle->linktype = DLT_EN3MB; break; case ARPHRD_AX25: handle->linktype = DLT_AX25_KISS; break; case ARPHRD_PRONET: handle->linktype = DLT_PRONET; break; case ARPHRD_CHAOS: handle->linktype = DLT_CHAOS; break; #ifndef ARPHRD_IEEE802_TR #define ARPHRD_IEEE802_TR 800 /* From Linux 2.4 */ #endif case ARPHRD_IEEE802_TR: case ARPHRD_IEEE802: handle->linktype = DLT_IEEE802; handle->offset = 2; break; case ARPHRD_ARCNET: handle->linktype = DLT_ARCNET_LINUX; break; #ifndef ARPHRD_FDDI /* From Linux 2.2.13 */ #define ARPHRD_FDDI 774 #endif case ARPHRD_FDDI: handle->linktype = DLT_FDDI; handle->offset = 3; break; #ifndef ARPHRD_ATM /* FIXME: How to #include this? */ #define ARPHRD_ATM 19 #endif case ARPHRD_ATM: /* * The Classical IP implementation in ATM for Linux * supports both what RFC 1483 calls "LLC Encapsulation", * in which each packet has an LLC header, possibly * with a SNAP header as well, prepended to it, and * what RFC 1483 calls "VC Based Multiplexing", in which * different virtual circuits carry different network * layer protocols, and no header is prepended to packets. * * They both have an ARPHRD_ type of ARPHRD_ATM, so * you can't use the ARPHRD_ type to find out whether * captured packets will have an LLC header, and, * while there's a socket ioctl to *set* the encapsulation * type, there's no ioctl to *get* the encapsulation type. * * This means that * * programs that dissect Linux Classical IP frames * would have to check for an LLC header and, * depending on whether they see one or not, dissect * the frame as LLC-encapsulated or as raw IP (I * don't know whether there's any traffic other than * IP that would show up on the socket, or whether * there's any support for IPv6 in the Linux * Classical IP code); * * filter expressions would have to compile into * code that checks for an LLC header and does * the right thing. * * Both of those are a nuisance - and, at least on systems * that support PF_PACKET sockets, we don't have to put * up with those nuisances; instead, we can just capture * in cooked mode. That's what we'll do, if we can. * Otherwise, we'll just fail. */ if (cooked_ok) handle->linktype = DLT_LINUX_SLL; else handle->linktype = -1; break; #ifndef ARPHRD_IEEE80211 /* From Linux 2.4.6 */ #define ARPHRD_IEEE80211 801 #endif case ARPHRD_IEEE80211: handle->linktype = DLT_IEEE802_11; break; #ifndef ARPHRD_IEEE80211_PRISM /* From Linux 2.4.18 */ #define ARPHRD_IEEE80211_PRISM 802 #endif case ARPHRD_IEEE80211_PRISM: handle->linktype = DLT_PRISM_HEADER; break; #ifndef ARPHRD_IEEE80211_RADIOTAP /* new */ #define ARPHRD_IEEE80211_RADIOTAP 803 #endif case ARPHRD_IEEE80211_RADIOTAP: handle->linktype = DLT_IEEE802_11_RADIO; break; case ARPHRD_PPP: /* * Some PPP code in the kernel supplies no link-layer * header whatsoever to PF_PACKET sockets; other PPP * code supplies PPP link-layer headers ("syncppp.c"); * some PPP code might supply random link-layer * headers (PPP over ISDN - there's code in Ethereal, * for example, to cope with PPP-over-ISDN captures * with which the Ethereal developers have had to cope, * heuristically trying to determine which of the * oddball link-layer headers particular packets have). * * As such, we just punt, and run all PPP interfaces * in cooked mode, if we can; otherwise, we just treat * it as DLT_RAW, for now - if somebody needs to capture, * on a 2.0[.x] kernel, on PPP devices that supply a * link-layer header, they'll have to add code here to * map to the appropriate DLT_ type (possibly adding a * new DLT_ type, if necessary). */ if (cooked_ok) handle->linktype = DLT_LINUX_SLL; else { /* * XXX - handle ISDN types here? We can't fall * back on cooked sockets, so we'd have to * figure out from the device name what type of * link-layer encapsulation it's using, and map * that to an appropriate DLT_ value, meaning * we'd map "isdnN" devices to DLT_RAW (they * supply raw IP packets with no link-layer * header) and "isdY" devices to a new DLT_I4L_IP * type that has only an Ethernet packet type as * a link-layer header. * * But sometimes we seem to get random crap * in the link-layer header when capturing on * ISDN devices.... */ handle->linktype = DLT_RAW; } break; #ifndef ARPHRD_CISCO #define ARPHRD_CISCO 513 /* previously ARPHRD_HDLC */ #endif case ARPHRD_CISCO: handle->linktype = DLT_C_HDLC; break; /* Not sure if this is correct for all tunnels, but it * works for CIPE */ case ARPHRD_TUNNEL: #ifndef ARPHRD_SIT #define ARPHRD_SIT 776 /* From Linux 2.2.13 */ #endif case ARPHRD_SIT: case ARPHRD_CSLIP: case ARPHRD_SLIP6: case ARPHRD_CSLIP6: case ARPHRD_ADAPT: case ARPHRD_SLIP: #ifndef ARPHRD_RAWHDLC #define ARPHRD_RAWHDLC 518 #endif case ARPHRD_RAWHDLC: #ifndef ARPHRD_DLCI #define ARPHRD_DLCI 15 #endif case ARPHRD_DLCI: /* * XXX - should some of those be mapped to DLT_LINUX_SLL * instead? Should we just map all of them to DLT_LINUX_SLL? */ handle->linktype = DLT_RAW; break; #ifndef ARPHRD_FRAD #define ARPHRD_FRAD 770 #endif case ARPHRD_FRAD: handle->linktype = DLT_FRELAY; break; case ARPHRD_LOCALTLK: handle->linktype = DLT_LTALK; break; #ifndef ARPHRD_FCPP #define ARPHRD_FCPP 784 #endif case ARPHRD_FCPP: #ifndef ARPHRD_FCAL #define ARPHRD_FCAL 785 #endif case ARPHRD_FCAL: #ifndef ARPHRD_FCPL #define ARPHRD_FCPL 786 #endif case ARPHRD_FCPL: #ifndef ARPHRD_FCFABRIC #define ARPHRD_FCFABRIC 787 #endif case ARPHRD_FCFABRIC: /* * We assume that those all mean RFC 2625 IP-over- * Fibre Channel, with the RFC 2625 header at * the beginning of the packet. */ handle->linktype = DLT_IP_OVER_FC; break; #ifndef ARPHRD_IRDA #define ARPHRD_IRDA 783 #endif case ARPHRD_IRDA: /* Don't expect IP packet out of this interfaces... */ handle->linktype = DLT_LINUX_IRDA; /* We need to save packet direction for IrDA decoding, * so let's use "Linux-cooked" mode. Jean II */ //handle->md.cooked = 1; break; /* ARPHRD_LAPD is unofficial and randomly allocated, if reallocation * is needed, please report it to */ #ifndef ARPHRD_LAPD #define ARPHRD_LAPD 8445 #endif case ARPHRD_LAPD: /* Don't expect IP packet out of this interfaces... */ handle->linktype = DLT_LINUX_LAPD; break; #ifndef ARPHRD_NONE #define ARPHRD_NONE 0xFFFE #endif case ARPHRD_NONE: /* * No link-layer header; packets are just IP * packets, so use DLT_RAW. */ handle->linktype = DLT_RAW; break; default: handle->linktype = -1; break; } } /* ===== Functions to interface to the newer kernels ================== */ /* * Try to open a packet socket using the new kernel PF_PACKET interface. * Returns 1 on success, 0 on an error that means the new interface isn't * present (so the old SOCK_PACKET interface should be tried), and a * PCAP_ERROR_ value on an error that means that the old mechanism won't * work either (so it shouldn't be tried). */ static int activate_new(pcap_t *handle) { #ifdef HAVE_PF_PACKET_SOCKETS int sock_fd = -1, arptype, val; int err = 0; struct packet_mreq mr; const char* device = handle->opt.source; /* * Open a socket with protocol family packet. If a device is * given we try to open it in raw mode otherwise we use * the cooked interface. */ sock_fd = device ? socket(PF_PACKET, SOCK_RAW, htons(ETH_P_ALL)) : socket(PF_PACKET, SOCK_DGRAM, htons(ETH_P_ALL)); if (sock_fd == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "socket: %s", pcap_strerror(errno) ); return 0; /* try old mechanism */ } /* It seems the kernel supports the new interface. */ handle->md.sock_packet = 0; /* * Get the interface index of the loopback device. * If the attempt fails, don't fail, just set the * "md.lo_ifindex" to -1. * * XXX - can there be more than one device that loops * packets back, i.e. devices other than "lo"? If so, * we'd need to find them all, and have an array of * indices for them, and check all of them in * "pcap_read_packet()". */ handle->md.lo_ifindex = iface_get_id(sock_fd, "lo", handle->errbuf); /* * Default value for offset to align link-layer payload * on a 4-byte boundary. */ handle->offset = 0; /* * What kind of frames do we have to deal with? Fall back * to cooked mode if we have an unknown interface type * or a type we know doesn't work well in raw mode. */ if (device) { /* Assume for now we don't need cooked mode. */ handle->md.cooked = 0; if (handle->opt.rfmon) { /* * We were asked to turn on monitor mode. * Do so before we get the link-layer type, * because entering monitor mode could change * the link-layer type. */ err = enter_rfmon_mode_wext(handle, sock_fd, device); if (err < 0) { /* Hard failure */ close(sock_fd); return err; } if (err == 0) { /* * Nothing worked for turning monitor mode * on. */ close(sock_fd); return PCAP_ERROR_RFMON_NOTSUP; } } arptype = iface_get_arptype(sock_fd, device, handle->errbuf); if (arptype < 0) { close(sock_fd); return arptype; } map_arphrd_to_dlt(handle, arptype, 1); if (handle->linktype == -1 || handle->linktype == DLT_LINUX_SLL || handle->linktype == DLT_LINUX_IRDA || handle->linktype == DLT_LINUX_LAPD || (handle->linktype == DLT_EN10MB && (strncmp("isdn", device, 4) == 0 || strncmp("isdY", device, 4) == 0))) { /* * Unknown interface type (-1), or a * device we explicitly chose to run * in cooked mode (e.g., PPP devices), * or an ISDN device (whose link-layer * type we can only determine by using * APIs that may be different on different * kernels) - reopen in cooked mode. */ if (close(sock_fd) == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "close: %s", pcap_strerror(errno)); return PCAP_ERROR; } sock_fd = socket(PF_PACKET, SOCK_DGRAM, htons(ETH_P_ALL)); if (sock_fd == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "socket: %s", pcap_strerror(errno)); return PCAP_ERROR; } handle->md.cooked = 1; /* * Get rid of any link-layer type list * we allocated - this only supports cooked * capture. */ if (handle->dlt_list != NULL) { free(handle->dlt_list); handle->dlt_list = NULL; handle->dlt_count = 0; } if (handle->linktype == -1) { /* * Warn that we're falling back on * cooked mode; we may want to * update "map_arphrd_to_dlt()" * to handle the new type. */ snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "arptype %d not " "supported by libpcap - " "falling back to cooked " "socket", arptype); } /* * IrDA capture is not a real "cooked" capture, * it's IrLAP frames, not IP packets. The * same applies to LAPD capture. */ if (handle->linktype != DLT_LINUX_IRDA && handle->linktype != DLT_LINUX_LAPD) handle->linktype = DLT_LINUX_SLL; } handle->md.ifindex = iface_get_id(sock_fd, device, handle->errbuf); if (handle->md.ifindex == -1) { close(sock_fd); return PCAP_ERROR; } if ((err = iface_bind(sock_fd, handle->md.ifindex, handle->errbuf)) != 1) { close(sock_fd); if (err < 0) return err; else return 0; /* try old mechanism */ } } else { /* * This is cooked mode. */ handle->md.cooked = 1; handle->linktype = DLT_LINUX_SLL; /* * We're not bound to a device. * XXX - true? Or true only if we're using * the "any" device? * For now, we're using this as an indication * that we can't transmit; stop doing that only * if we figure out how to transmit in cooked * mode. */ handle->md.ifindex = -1; } /* * Select promiscuous mode on if "promisc" is set. * * Do not turn allmulti mode on if we don't select * promiscuous mode - on some devices (e.g., Orinoco * wireless interfaces), allmulti mode isn't supported * and the driver implements it by turning promiscuous * mode on, and that screws up the operation of the * card as a normal networking interface, and on no * other platform I know of does starting a non- * promiscuous capture affect which multicast packets * are received by the interface. */ /* * Hmm, how can we set promiscuous mode on all interfaces? * I am not sure if that is possible at all. */ if (device && handle->opt.promisc) { memset(&mr, 0, sizeof(mr)); mr.mr_ifindex = handle->md.ifindex; mr.mr_type = PACKET_MR_PROMISC; if (setsockopt(sock_fd, SOL_PACKET, PACKET_ADD_MEMBERSHIP, &mr, sizeof(mr)) == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "setsockopt: %s", pcap_strerror(errno)); close(sock_fd); return PCAP_ERROR; } } /* Enable auxillary data if supported and reserve room for * reconstructing VLAN headers. */ #ifdef HAVE_PACKET_AUXDATA val = 1; if (setsockopt(sock_fd, SOL_PACKET, PACKET_AUXDATA, &val, sizeof(val)) == -1 && errno != ENOPROTOOPT) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "setsockopt: %s", pcap_strerror(errno)); close(sock_fd); return PCAP_ERROR; } handle->offset += VLAN_TAG_LEN; #endif /* HAVE_PACKET_AUXDATA */ /* * This is a 2.2[.x] or later kernel (we know that * because we're not using a SOCK_PACKET socket - * PF_PACKET is supported only in 2.2 and later * kernels). * * We can safely pass "recvfrom()" a byte count * based on the snapshot length. * * If we're in cooked mode, make the snapshot length * large enough to hold a "cooked mode" header plus * 1 byte of packet data (so we don't pass a byte * count of 0 to "recvfrom()"). */ if (handle->md.cooked) { if (handle->snapshot < SLL_HDR_LEN + 1) handle->snapshot = SLL_HDR_LEN + 1; } handle->bufsize = handle->snapshot; /* Save the socket FD in the pcap structure */ handle->fd = sock_fd; return 1; #else strncpy(ebuf, "New packet capturing interface not supported by build " "environment", PCAP_ERRBUF_SIZE); return 0; #endif } static int activate_mmap(pcap_t *handle) { #ifdef HAVE_PACKET_RING int ret; if (handle->opt.buffer_size == 0) { /* by default request 2M for the ring buffer */ handle->opt.buffer_size = 2*1024*1024; } ret = prepare_tpacket_socket(handle); if (ret == 0) return ret; ret = create_ring(handle); if (ret == 0) return ret; /* override some defaults and inherit the other fields from * activate_new * handle->offset is used to get the current position into the rx ring * handle->cc is used to store the ring size */ handle->read_op = pcap_read_linux_mmap; handle->cleanup_op = pcap_cleanup_linux_mmap; handle->setfilter_op = pcap_setfilter_linux_mmap; handle->setnonblock_op = pcap_setnonblock_mmap; handle->getnonblock_op = pcap_getnonblock_mmap; handle->selectable_fd = handle->fd; return 1; #else /* HAVE_PACKET_RING */ return 0; #endif /* HAVE_PACKET_RING */ } #ifdef HAVE_PACKET_RING static int prepare_tpacket_socket(pcap_t *handle) { #ifdef HAVE_TPACKET2 socklen_t len; int val; #endif handle->md.tp_version = TPACKET_V1; handle->md.tp_hdrlen = sizeof(struct tpacket_hdr); #ifdef HAVE_TPACKET2 /* Probe whether kernel supports TPACKET_V2 */ val = TPACKET_V2; len = sizeof(val); if (getsockopt(handle->fd, SOL_PACKET, PACKET_HDRLEN, &val, &len) < 0) { if (errno == ENOPROTOOPT) return 1; snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "can't get TPACKET_V2 header len on socket %d: %d-%s", handle->fd, errno, pcap_strerror(errno)); return 0; } handle->md.tp_hdrlen = val; val = TPACKET_V2; if (setsockopt(handle->fd, SOL_PACKET, PACKET_VERSION, &val, sizeof(val)) < 0) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "can't activate TPACKET_V2 on socket %d: %d-%s", handle->fd, errno, pcap_strerror(errno)); return 0; } handle->md.tp_version = TPACKET_V2; /* Reserve space for VLAN tag reconstruction */ val = VLAN_TAG_LEN; if (setsockopt(handle->fd, SOL_PACKET, PACKET_RESERVE, &val, sizeof(val)) < 0) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "can't set up reserve on socket %d: %d-%s", handle->fd, errno, pcap_strerror(errno)); return 0; } #endif /* HAVE_TPACKET2 */ return 1; } static void compute_ring_block(int frame_size, unsigned *block_size, unsigned *frames_per_block) { /* compute the minumum block size that will handle this frame. * The block has to be page size aligned. * The max block size allowed by the kernel is arch-dependent and * it's not explicitly checked here. */ *block_size = getpagesize(); while (*block_size < frame_size) *block_size <<= 1; *frames_per_block = *block_size/frame_size; } static int create_ring(pcap_t *handle) { unsigned i, j, ringsize, frames_per_block; struct tpacket_req req; /* Note that with large snapshot (say 64K) only a few frames * will be available in the ring even with pretty large ring size * (and a lot of memory will be unused). * The snap len should be carefully chosen to achive best * performance */ req.tp_frame_size = TPACKET_ALIGN(handle->snapshot + TPACKET_ALIGN(handle->md.tp_hdrlen) + sizeof(struct sockaddr_ll)); req.tp_frame_nr = handle->opt.buffer_size/req.tp_frame_size; compute_ring_block(req.tp_frame_size, &req.tp_block_size, &frames_per_block); req.tp_block_nr = req.tp_frame_nr / frames_per_block; /* req.tp_frame_nr is requested to match frames_per_block*req.tp_block_nr */ req.tp_frame_nr = req.tp_block_nr * frames_per_block; /* ask the kernel to create the ring */ retry: if (setsockopt(handle->fd, SOL_PACKET, PACKET_RX_RING, (void *) &req, sizeof(req))) { /* try to reduce requested ring size to prevent memory failure */ if ((errno == ENOMEM) && (req.tp_block_nr > 1)) { req.tp_frame_nr >>= 1; req.tp_block_nr = req.tp_frame_nr/frames_per_block; goto retry; } snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "can't create rx ring on " "packet socket %d: %d-%s", handle->fd, errno, pcap_strerror(errno)); return 0; } /* memory map the rx ring */ ringsize = req.tp_block_nr * req.tp_block_size; handle->bp = mmap(0, ringsize, PROT_READ| PROT_WRITE, MAP_SHARED, handle->fd, 0); if (handle->bp == MAP_FAILED) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "can't mmap rx ring: %d-%s", errno, pcap_strerror(errno)); /* clear the allocated ring on error*/ destroy_ring(handle); return 0; } /* allocate a ring for each frame header pointer*/ handle->cc = req.tp_frame_nr; handle->buffer = malloc(handle->cc * sizeof(union thdr *)); if (!handle->buffer) { destroy_ring(handle); return 0; } /* fill the header ring with proper frame ptr*/ handle->offset = 0; for (i=0; ibp[i*req.tp_block_size]; for (j=0; joffset) { RING_GET_FRAME(handle) = base; base += req.tp_frame_size; } } handle->bufsize = req.tp_frame_size; handle->offset = 0; return 1; } /* free all ring related resources*/ static void destroy_ring(pcap_t *handle) { /* tell the kernel to destroy the ring*/ struct tpacket_req req; memset(&req, 0, sizeof(req)); setsockopt(handle->fd, SOL_PACKET, PACKET_RX_RING, (void *) &req, sizeof(req)); /* if ring is mapped, unmap it*/ if (handle->bp) { /* need to re-compute the ring size */ unsigned frames_per_block, block_size; compute_ring_block(handle->bufsize, &block_size, &frames_per_block); /* do not perform sanity check here: we can't recover any error */ munmap(handle->bp, block_size * handle->cc / frames_per_block); handle->bp = 0; } } static void pcap_cleanup_linux_mmap( pcap_t *handle ) { destroy_ring(handle); pcap_cleanup_linux(handle); } static int pcap_getnonblock_mmap(pcap_t *p, char *errbuf) { /* use negative value of timeout to indicate non blocking ops */ return (p->md.timeout<0); } static int pcap_setnonblock_mmap(pcap_t *p, int nonblock, char *errbuf) { /* map each value to the corresponding 2's complement, to * preserve the timeout value provided with pcap_set_timeout */ if (nonblock) { if (p->md.timeout > 0) p->md.timeout = p->md.timeout*-1 - 1; } else if (p->md.timeout < 0) p->md.timeout = (p->md.timeout+1)*-1; return 0; } static inline union thdr * pcap_get_ring_frame(pcap_t *handle, int status) { union thdr h; h.raw = RING_GET_FRAME(handle); switch (handle->md.tp_version) { case TPACKET_V1: if (status != (h.h1->tp_status ? TP_STATUS_USER : TP_STATUS_KERNEL)) return NULL; break; #ifdef HAVE_TPACKET2 case TPACKET_V2: if (status != (h.h2->tp_status ? TP_STATUS_USER : TP_STATUS_KERNEL)) return NULL; break; #endif } return h.raw; } static int pcap_read_linux_mmap(pcap_t *handle, int max_packets, pcap_handler callback, u_char *user) { int pkts = 0; /* wait for frames availability.*/ if ((handle->md.timeout >= 0) && !pcap_get_ring_frame(handle, TP_STATUS_USER)) { struct pollfd pollinfo; int ret; pollinfo.fd = handle->fd; pollinfo.events = POLLIN; do { /* poll() requires a negative timeout to wait forever */ ret = poll(&pollinfo, 1, (handle->md.timeout > 0)? handle->md.timeout: -1); if ((ret < 0) && (errno != EINTR)) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "can't poll on packet socket fd %d: %d-%s", handle->fd, errno, pcap_strerror(errno)); return -1; } /* check for break loop condition on interrupted syscall*/ if (handle->break_loop) { handle->break_loop = 0; return -2; } } while (ret < 0); } /* non-positive values of max_packets are used to require all * packets currently available in the ring */ while ((pkts < max_packets) || (max_packets <= 0)) { int run_bpf; struct sockaddr_ll *sll; struct pcap_pkthdr pcaphdr; unsigned char *bp; union thdr h; unsigned int tp_len; unsigned int tp_mac; unsigned int tp_snaplen; unsigned int tp_sec; unsigned int tp_usec; h.raw = pcap_get_ring_frame(handle, TP_STATUS_USER); if (!h.raw) break; switch (handle->md.tp_version) { case TPACKET_V1: tp_len = h.h1->tp_len; tp_mac = h.h1->tp_mac; tp_snaplen = h.h1->tp_snaplen; tp_sec = h.h1->tp_sec; tp_usec = h.h1->tp_usec; break; #ifdef HAVE_TPACKET2 case TPACKET_V2: tp_len = h.h2->tp_len; tp_mac = h.h2->tp_mac; tp_snaplen = h.h2->tp_snaplen; tp_sec = h.h2->tp_sec; tp_usec = h.h2->tp_nsec / 1000; break; #endif default: snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "unsupported tpacket version %d", handle->md.tp_version); return -1; } /* perform sanity check on internal offset. */ if (tp_mac + tp_snaplen > handle->bufsize) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "corrupted frame on kernel ring mac " "offset %d + caplen %d > frame len %d", tp_mac, tp_snaplen, handle->bufsize); return -1; } /* run filter on received packet * If the kernel filtering is enabled we need to run the * filter until all the frames present into the ring * at filter creation time are processed. * In such case md.use_bpf is used as a counter for the * packet we need to filter. * Note: alternatively it could be possible to stop applying * the filter when the ring became empty, but it can possibly * happen a lot later... */ bp = (unsigned char*)h.raw + tp_mac; run_bpf = (!handle->md.use_bpf) || ((handle->md.use_bpf>1) && handle->md.use_bpf--); if (run_bpf && handle->fcode.bf_insns && (bpf_filter(handle->fcode.bf_insns, bp, tp_len, tp_snaplen) == 0)) goto skip; /* check direction and interface index */ sll = (void *)h.raw + TPACKET_ALIGN(handle->md.tp_hdrlen); if ((sll->sll_ifindex == handle->md.lo_ifindex) && (sll->sll_pkttype == PACKET_OUTGOING)) goto skip; /* get required packet info from ring header */ pcaphdr.ts.tv_sec = tp_sec; pcaphdr.ts.tv_usec = tp_usec; pcaphdr.caplen = tp_snaplen; pcaphdr.len = tp_len; /* if required build in place the sll header*/ if (handle->md.cooked) { struct sll_header *hdrp; /* * The kernel should have left us with enough * space for an sll header; back up the packet * data pointer into that space, as that'll be * the beginning of the packet we pass to the * callback. */ bp -= SLL_HDR_LEN; /* * Let's make sure that's past the end of * the tpacket header, i.e. >= * ((u_char *)thdr + TPACKET_HDRLEN), so we * don't step on the header when we construct * the sll header. */ if (bp < (u_char *)h.raw + TPACKET_ALIGN(handle->md.tp_hdrlen) + sizeof(struct sockaddr_ll)) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "cooked-mode frame doesn't have room for sll header"); return -1; } /* * OK, that worked; construct the sll header. */ hdrp = (struct sll_header *)bp; hdrp->sll_pkttype = map_packet_type_to_sll_type( sll->sll_pkttype); hdrp->sll_hatype = htons(sll->sll_hatype); hdrp->sll_halen = htons(sll->sll_halen); memcpy(hdrp->sll_addr, sll->sll_addr, SLL_ADDRLEN); hdrp->sll_protocol = sll->sll_protocol; /* update packet len */ pcaphdr.caplen += SLL_HDR_LEN; pcaphdr.len += SLL_HDR_LEN; } #ifdef HAVE_TPACKET2 if (handle->md.tp_version == TPACKET_V2 && h.h2->tp_vlan_tci && tp_snaplen >= 2 * ETH_ALEN) { struct vlan_tag *tag; bp -= VLAN_TAG_LEN; memmove(bp, bp + VLAN_TAG_LEN, 2 * ETH_ALEN); tag = (struct vlan_tag *)(bp + 2 * ETH_ALEN); tag->vlan_tpid = htons(ETH_P_8021Q); tag->vlan_tci = htons(h.h2->tp_vlan_tci); pcaphdr.caplen += VLAN_TAG_LEN; pcaphdr.len += VLAN_TAG_LEN; } #endif /* pass the packet to the user */ pkts++; callback(user, &pcaphdr, bp); handle->md.packets_read++; skip: /* next packet */ switch (handle->md.tp_version) { case TPACKET_V1: h.h1->tp_status = TP_STATUS_KERNEL; break; #ifdef HAVE_TPACKET2 case TPACKET_V2: h.h2->tp_status = TP_STATUS_KERNEL; break; #endif } if (++handle->offset >= handle->cc) handle->offset = 0; /* check for break loop condition*/ if (handle->break_loop) { handle->break_loop = 0; return -2; } } return pkts; } static int pcap_setfilter_linux_mmap(pcap_t *handle, struct bpf_program *filter) { int n, offset; int ret = pcap_setfilter_linux(handle, filter); if (ret < 0) return ret; /* if the kernel filter is enabled, we need to apply the filter on * all packets present into the ring. Get an upper bound of their number */ if (!handle->md.use_bpf) return ret; /* walk the ring backward and count the free slot */ offset = handle->offset; if (--handle->offset < 0) handle->offset = handle->cc - 1; for (n=0; n < handle->cc; ++n) { if (--handle->offset < 0) handle->offset = handle->cc - 1; if (!pcap_get_ring_frame(handle, TP_STATUS_KERNEL)) break; } /* be careful to not change current ring position */ handle->offset = offset; /* store the number of packets currently present in the ring */ handle->md.use_bpf = 1 + (handle->cc - n); return ret; } #endif /* HAVE_PACKET_RING */ #ifdef HAVE_PF_PACKET_SOCKETS /* * Return the index of the given device name. Fill ebuf and return * -1 on failure. */ static int iface_get_id(int fd, const char *device, char *ebuf) { struct ifreq ifr; memset(&ifr, 0, sizeof(ifr)); strncpy(ifr.ifr_name, device, sizeof(ifr.ifr_name)); if (ioctl(fd, SIOCGIFINDEX, &ifr) == -1) { snprintf(ebuf, PCAP_ERRBUF_SIZE, "SIOCGIFINDEX: %s", pcap_strerror(errno)); return -1; } return ifr.ifr_ifindex; } /* * Bind the socket associated with FD to the given device. * Return 1 on success, 0 if we should try a SOCK_PACKET socket, * or a PCAP_ERROR_ value on a hard error. */ static int iface_bind(int fd, int ifindex, char *ebuf) { struct sockaddr_ll sll; int err; socklen_t errlen = sizeof(err); memset(&sll, 0, sizeof(sll)); sll.sll_family = AF_PACKET; sll.sll_ifindex = ifindex; sll.sll_protocol = htons(ETH_P_ALL); if (bind(fd, (struct sockaddr *) &sll, sizeof(sll)) == -1) { if (errno == ENETDOWN) { /* * Return a "network down" indication, so that * the application can report that rather than * saying we had a mysterious failure and * suggest that they report a problem to the * libpcap developers. */ return PCAP_ERROR_IFACE_NOT_UP; } else { snprintf(ebuf, PCAP_ERRBUF_SIZE, "bind: %s", pcap_strerror(errno)); return PCAP_ERROR; } } /* Any pending errors, e.g., network is down? */ if (getsockopt(fd, SOL_SOCKET, SO_ERROR, &err, &errlen) == -1) { snprintf(ebuf, PCAP_ERRBUF_SIZE, "getsockopt: %s", pcap_strerror(errno)); return 0; } if (err == ENETDOWN) { /* * Return a "network down" indication, so that * the application can report that rather than * saying we had a mysterious failure and * suggest that they report a problem to the * libpcap developers. */ return PCAP_ERROR_IFACE_NOT_UP; } else if (err > 0) { snprintf(ebuf, PCAP_ERRBUF_SIZE, "bind: %s", pcap_strerror(err)); return 0; } return 1; } /* * Check whether the device supports the Wireless Extensions. * Returns 1 if it does, 0 if it doesn't, PCAP_ERROR_NO_SUCH_DEVICE * if the device doesn't even exist. */ static int has_wext(int sock_fd, const char *device, char *ebuf) { #ifdef IW_MODE_MONITOR struct iwreq ireq; strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; if (ioctl(sock_fd, SIOCGIWNAME, &ireq) >= 0) return 1; /* yes */ snprintf(ebuf, PCAP_ERRBUF_SIZE, "%s: SIOCGIWPRIV: %s", device, pcap_strerror(errno)); if (errno == ENODEV) return PCAP_ERROR_NO_SUCH_DEVICE; #endif return 0; } /* * Per me si va ne la citta dolente, * Per me si va ne l'etterno dolore, * ... * Lasciate ogne speranza, voi ch'intrate. * * XXX - airmon-ng does special stuff with the Orinoco driver and the * wlan-ng driver. */ typedef enum { MONITOR_WEXT, MONITOR_HOSTAP, MONITOR_PRISM, MONITOR_PRISM54, MONITOR_ACX100, MONITOR_RT2500, MONITOR_RT2570, MONITOR_RT73, MONITOR_RTL8XXX } monitor_type; /* * Use the Wireless Extensions, if we have them, to try to turn monitor mode * on if it's not already on. * * Returns 1 on success, 0 if we don't support the Wireless Extensions * on this device, or a PCAP_ERROR_ value if we do support them but * we weren't able to turn monitor mode on. */ static int enter_rfmon_mode_wext(pcap_t *handle, int sock_fd, const char *device) { #ifdef IW_MODE_MONITOR /* * XXX - at least some adapters require non-Wireless Extensions * mechanisms to turn monitor mode on. * * Atheros cards might require that a separate "monitor virtual access * point" be created, with later versions of the madwifi driver. * airmon-ng does "wlanconfig ath create wlandev {if} wlanmode * monitor -bssid", which apparently spits out a line "athN" * where "athN" is the monitor mode device. To leave monitor * mode, it destroys the monitor mode device. * * Some Intel Centrino adapters might require private ioctls to get * radio headers; the ipw2200 and ipw3945 drivers allow you to * configure a separate "rtapN" interface to capture in monitor * mode without preventing the adapter from operating normally. * (airmon-ng doesn't appear to use that, though.) * * It would be Truly Wonderful if mac80211 and nl80211 cleaned this * up, and if all drivers were converted to mac80211 drivers. * * If interface {if} is a mac80211 driver, the file * /sys/class/net/{if}/phy80211 is a symlink to * /sys/class/ieee80211/{phydev}, for some {phydev}. * * On Fedora 9, with a 2.6.26.3-29 kernel, my Zydas stick, at * least, has a "wmaster0" device and a "wlan0" device; the * latter is the one with the IP address. Both show up in * "tcpdump -D" output. Capturing on the wmaster0 device * captures with 802.11 headers. * * airmon-ng searches through /sys/class/net for devices named * monN, starting with mon0; as soon as one *doesn't* exist, * it chooses that as the monitor device name. If the "iw" * command exists, it does "iw dev {if} interface add {monif} * type monitor", where {monif} is the monitor device. It * then (sigh) sleeps .1 second, and then configures the * device up. Otherwise, if /sys/class/ieee80211/{phydev}/add_iface * is a file, it writes {mondev}, without a newline, to that file, * and again (sigh) sleeps .1 second, and then iwconfig's that * device into monitor mode and configures it up. Otherwise, * you can't do monitor mode. * * All these devices are "glued" together by having the * /sys/class/net/{device}/phy80211 links pointing to the same * place, so, given a wmaster, wlan, or mon device, you can * find the other devices by looking for devices with * the same phy80211 link. * * To turn monitor mode off, delete the monitor interface, * either with "iw dev {monif} interface del" or by sending * {monif}, with no NL, down /sys/class/ieee80211/{phydev}/remove_iface * * Note: if you try to create a monitor device named "monN", and * there's already a "monN" device, it fails, as least with * the netlink interface (which is what iw uses), with a return * value of -ENFILE. (Return values are negative errnos.) We * could probably use that to find an unused device. */ int err; struct iwreq ireq; struct iw_priv_args *priv; monitor_type montype; int i; __u32 cmd; int args[2]; int channel; /* * Does this device *support* the Wireless Extensions? */ err = has_wext(sock_fd, device, handle->errbuf); if (err <= 0) return err; /* either it doesn't or the device doesn't even exist */ /* * Try to get all the Wireless Extensions private ioctls * supported by this device. * * First, get the size of the buffer we need, by supplying no * buffer and a length of 0. If the device supports private * ioctls, it should return E2BIG, with ireq.u.data.length set * to the length we need. If it doesn't support them, it should * return EOPNOTSUPP. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; ireq.u.data.pointer = args; ireq.u.data.length = 0; ireq.u.data.flags = 0; if (ioctl(sock_fd, SIOCGIWPRIV, &ireq) != -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "%s: SIOCGIWPRIV with a zero-length buffer didn't fail!", device); return PCAP_ERROR; } if (errno == EOPNOTSUPP) { /* * No private ioctls, so we assume that there's only one * DLT_ for monitor mode. */ return 0; } if (errno != E2BIG) { /* * Failed. */ snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "%s: SIOCGIWPRIV: %s", device, pcap_strerror(errno)); return PCAP_ERROR; } priv = malloc(ireq.u.data.length * sizeof (struct iw_priv_args)); if (priv == NULL) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "malloc: %s", pcap_strerror(errno)); return PCAP_ERROR; } ireq.u.data.pointer = priv; if (ioctl(sock_fd, SIOCGIWPRIV, &ireq) == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "%s: SIOCGIWPRIV: %s", device, pcap_strerror(errno)); free(priv); return PCAP_ERROR; } /* * Look for private ioctls to turn monitor mode on or, if * monitor mode is on, to set the header type. */ montype = MONITOR_WEXT; cmd = 0; for (i = 0; i < ireq.u.data.length; i++) { if (strcmp(priv[i].name, "monitor_type") == 0) { /* * Hostap driver, use this one. * Set monitor mode first. * You can set it to 0 to get DLT_IEEE80211, * 1 to get DLT_PRISM, or 2 to get * DLT_IEEE80211_RADIO_AVS. */ if ((priv[i].set_args & IW_PRIV_TYPE_MASK) != IW_PRIV_TYPE_INT) break; if (!(priv[i].set_args & IW_PRIV_SIZE_FIXED)) break; if ((priv[i].set_args & IW_PRIV_SIZE_MASK) != 1) break; montype = MONITOR_HOSTAP; cmd = priv[i].cmd; break; } if (strcmp(priv[i].name, "set_prismhdr") == 0) { /* * Prism54 driver, use this one. * Set monitor mode first. * You can set it to 2 to get DLT_IEEE80211 * or 3 or get DLT_PRISM. */ if ((priv[i].set_args & IW_PRIV_TYPE_MASK) != IW_PRIV_TYPE_INT) break; if (!(priv[i].set_args & IW_PRIV_SIZE_FIXED)) break; if ((priv[i].set_args & IW_PRIV_SIZE_MASK) != 1) break; montype = MONITOR_PRISM54; cmd = priv[i].cmd; break; } if (strcmp(priv[i].name, "forceprismheader") == 0) { /* * RT2570 driver, use this one. * Do this after turning monitor mode on. * You can set it to 1 to get DLT_PRISM or 2 * to get DLT_IEEE80211. */ if ((priv[i].set_args & IW_PRIV_TYPE_MASK) != IW_PRIV_TYPE_INT) break; if (!(priv[i].set_args & IW_PRIV_SIZE_FIXED)) break; if ((priv[i].set_args & IW_PRIV_SIZE_MASK) != 1) break; montype = MONITOR_RT2570; cmd = priv[i].cmd; break; } if (strcmp(priv[i].name, "forceprism") == 0) { /* * RT73 driver, use this one. * Do this after turning monitor mode on. * Its argument is a *string*; you can * set it to "1" to get DLT_PRISM or "2" * to get DLT_IEEE80211. */ if ((priv[i].set_args & IW_PRIV_TYPE_MASK) != IW_PRIV_TYPE_CHAR) break; if (priv[i].set_args & IW_PRIV_SIZE_FIXED) break; montype = MONITOR_RT73; cmd = priv[i].cmd; break; } if (strcmp(priv[i].name, "prismhdr") == 0) { /* * One of the RTL8xxx drivers, use this one. * It can only be done after monitor mode * has been turned on. You can set it to 1 * to get DLT_PRISM or 0 to get DLT_IEEE80211. */ if ((priv[i].set_args & IW_PRIV_TYPE_MASK) != IW_PRIV_TYPE_INT) break; if (!(priv[i].set_args & IW_PRIV_SIZE_FIXED)) break; if ((priv[i].set_args & IW_PRIV_SIZE_MASK) != 1) break; montype = MONITOR_RTL8XXX; cmd = priv[i].cmd; break; } if (strcmp(priv[i].name, "rfmontx") == 0) { /* * RT2500 or RT61 driver, use this one. * It has one one-byte parameter; set * u.data.length to 1 and u.data.pointer to * point to the parameter. * It doesn't itself turn monitor mode on. * You can set it to 1 to allow transmitting * in monitor mode(?) and get DLT_IEEE80211, * or set it to 0 to disallow transmitting in * monitor mode(?) and get DLT_PRISM. */ if ((priv[i].set_args & IW_PRIV_TYPE_MASK) != IW_PRIV_TYPE_INT) break; if ((priv[i].set_args & IW_PRIV_SIZE_MASK) != 2) break; montype = MONITOR_RT2500; cmd = priv[i].cmd; break; } if (strcmp(priv[i].name, "monitor") == 0) { /* * Either ACX100 or hostap, use this one. * It turns monitor mode on. * If it takes two arguments, it's ACX100; * the first argument is 1 for DLT_PRISM * or 2 for DLT_IEEE80211, and the second * argument is the channel on which to * run. If it takes one argument, it's * HostAP, and the argument is 2 for * DLT_IEEE80211 and 3 for DLT_PRISM. * * If we see this, we don't quit, as this * might be a version of the hostap driver * that also supports "monitor_type". */ if ((priv[i].set_args & IW_PRIV_TYPE_MASK) != IW_PRIV_TYPE_INT) break; if (!(priv[i].set_args & IW_PRIV_SIZE_FIXED)) break; switch (priv[i].set_args & IW_PRIV_SIZE_MASK) { case 1: montype = MONITOR_PRISM; cmd = priv[i].cmd; break; case 2: montype = MONITOR_ACX100; cmd = priv[i].cmd; break; default: break; } } } free(priv); /* * XXX - ipw3945? islism? */ /* * Get the old mode. */ strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; if (ioctl(sock_fd, SIOCGIWMODE, &ireq) == -1) { /* * We probably won't be able to set the mode, either. */ return PCAP_ERROR_RFMON_NOTSUP; } /* * Is it currently in monitor mode? */ if (ireq.u.mode == IW_MODE_MONITOR) { /* * Yes. Just leave things as they are. * We don't offer multiple link-layer types, as * changing the link-layer type out from under * somebody else capturing in monitor mode would * be considered rude. */ return 1; } /* * No. We have to put the adapter into rfmon mode. */ /* * If we haven't already done so, arrange to have * "pcap_close_all()" called when we exit. */ if (!pcap_do_addexit(handle)) { /* * "atexit()" failed; don't put the interface * in rfmon mode, just give up. */ return PCAP_ERROR_RFMON_NOTSUP; } /* * Save the old mode. */ handle->md.oldmode = ireq.u.mode; /* * Put the adapter in rfmon mode. How we do this depends * on whether we have a special private ioctl or not. */ if (montype == MONITOR_PRISM) { /* * We have the "monitor" private ioctl, but none of * the other private ioctls. Use this, and select * the Prism header. * * If it fails, just fall back on SIOCSIWMODE. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; ireq.u.data.length = 1; /* 1 argument */ args[0] = 3; /* request Prism header */ memcpy(ireq.u.name, args, IFNAMSIZ); if (ioctl(sock_fd, cmd, &ireq) != -1) { /* * Success. * Note that we have to put the old mode back * when we close the device. */ handle->md.must_clear |= MUST_CLEAR_RFMON; /* * Add this to the list of pcaps to close * when we exit. */ pcap_add_to_pcaps_to_close(handle); return 1; } /* * Failure. Fall back on SIOCSIWMODE. */ } /* * First, turn monitor mode on. */ strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; ireq.u.mode = IW_MODE_MONITOR; if (ioctl(sock_fd, SIOCSIWMODE, &ireq) == -1) { /* * Scientist, you've failed. */ return PCAP_ERROR_RFMON_NOTSUP; } /* * XXX - airmon-ng does "iwconfig {if} key off" after setting * monitor mode and setting the channel, and then does * "iwconfig up". */ /* * Now select the appropriate radio header. */ switch (montype) { case MONITOR_WEXT: /* * We don't have any private ioctl to set the header. */ break; case MONITOR_HOSTAP: /* * Select the AVS header if we can, otherwise * select the Prism header. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; args[0] = 2; /* request AVS header */ memcpy(ireq.u.name, args, sizeof (int)); if (ioctl(sock_fd, cmd, &ireq) == -1) { /* * Failure - try the Prism header. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; args[0] = 1; /* request Prism header */ memcpy(ireq.u.name, args, sizeof (int)); ioctl(sock_fd, cmd, &ireq); } break; case MONITOR_PRISM: /* * The private ioctl failed. */ break; case MONITOR_PRISM54: /* * Select the Prism header. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; args[0] = 3; /* request Prism header */ memcpy(ireq.u.name, args, sizeof (int)); ioctl(sock_fd, cmd, &ireq); break; case MONITOR_ACX100: /* * Get the current channel. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; if (ioctl(sock_fd, SIOCGIWFREQ, &ireq) == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "%s: SIOCGIWFREQ: %s", device, pcap_strerror(errno)); return PCAP_ERROR; } channel = ireq.u.freq.m; /* * Select the Prism header, and set the channel to the * current value. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; args[0] = 1; /* request Prism header */ args[1] = channel; /* set channel */ memcpy(ireq.u.name, args, 2*sizeof (int)); ioctl(sock_fd, cmd, &ireq); break; case MONITOR_RT2500: /* * Disallow transmission - that turns on the * Prism header. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; args[0] = 0; /* disallow transmitting */ memcpy(ireq.u.name, args, sizeof (int)); ioctl(sock_fd, cmd, &ireq); break; case MONITOR_RT2570: /* * Force the Prism header. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; args[0] = 1; /* request Prism header */ memcpy(ireq.u.name, args, sizeof (int)); ioctl(sock_fd, cmd, &ireq); break; case MONITOR_RT73: /* * Force the Prism header. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; ireq.u.data.length = 1; /* 1 argument */ ireq.u.data.pointer = "1"; ireq.u.data.flags = 0; ioctl(sock_fd, cmd, &ireq); break; case MONITOR_RTL8XXX: /* * Force the Prism header. */ memset(&ireq, 0, sizeof ireq); strncpy(ireq.ifr_ifrn.ifrn_name, device, sizeof ireq.ifr_ifrn.ifrn_name); ireq.ifr_ifrn.ifrn_name[sizeof ireq.ifr_ifrn.ifrn_name - 1] = 0; args[0] = 1; /* request Prism header */ memcpy(ireq.u.name, args, sizeof (int)); ioctl(sock_fd, cmd, &ireq); break; } /* * Note that we have to put the old mode back when we * close the device. */ handle->md.must_clear |= MUST_CLEAR_RFMON; /* * Add this to the list of pcaps to close when we exit. */ pcap_add_to_pcaps_to_close(handle); return 1; #else /* * We don't have the Wireless Extensions available, so we can't * do monitor mode. */ return 0; #endif } #endif /* HAVE_PF_PACKET_SOCKETS */ /* ===== Functions to interface to the older kernels ================== */ /* * Try to open a packet socket using the old kernel interface. * Returns 1 on success and a PCAP_ERROR_ value on an error. */ static int activate_old(pcap_t *handle) { int arptype; struct ifreq ifr; const char *device = handle->opt.source; struct utsname utsname; int mtu; /* Open the socket */ handle->fd = socket(PF_INET, SOCK_PACKET, htons(ETH_P_ALL)); if (handle->fd == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "socket: %s", pcap_strerror(errno)); return PCAP_ERROR_PERM_DENIED; } /* It worked - we are using the old interface */ handle->md.sock_packet = 1; /* ...which means we get the link-layer header. */ handle->md.cooked = 0; /* Bind to the given device */ if (!device) { strncpy(handle->errbuf, "pcap_activate: The \"any\" device isn't supported on 2.0[.x]-kernel systems", PCAP_ERRBUF_SIZE); return PCAP_ERROR; } if (iface_bind_old(handle->fd, device, handle->errbuf) == -1) return PCAP_ERROR; /* * Try to get the link-layer type. */ arptype = iface_get_arptype(handle->fd, device, handle->errbuf); if (arptype < 0) return PCAP_ERROR; /* * Try to find the DLT_ type corresponding to that * link-layer type. */ map_arphrd_to_dlt(handle, arptype, 0); if (handle->linktype == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "unknown arptype %d", arptype); return PCAP_ERROR; } /* Go to promisc mode if requested */ if (handle->opt.promisc) { memset(&ifr, 0, sizeof(ifr)); strncpy(ifr.ifr_name, device, sizeof(ifr.ifr_name)); if (ioctl(handle->fd, SIOCGIFFLAGS, &ifr) == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "SIOCGIFFLAGS: %s", pcap_strerror(errno)); return PCAP_ERROR; } if ((ifr.ifr_flags & IFF_PROMISC) == 0) { /* * Promiscuous mode isn't currently on, * so turn it on, and remember that * we should turn it off when the * pcap_t is closed. */ /* * If we haven't already done so, arrange * to have "pcap_close_all()" called when * we exit. */ if (!pcap_do_addexit(handle)) { /* * "atexit()" failed; don't put * the interface in promiscuous * mode, just give up. */ return PCAP_ERROR; } ifr.ifr_flags |= IFF_PROMISC; if (ioctl(handle->fd, SIOCSIFFLAGS, &ifr) == -1) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "SIOCSIFFLAGS: %s", pcap_strerror(errno)); return PCAP_ERROR; } handle->md.must_clear |= MUST_CLEAR_PROMISC; /* * Add this to the list of pcaps * to close when we exit. */ pcap_add_to_pcaps_to_close(handle); } } /* * Compute the buffer size. * * We're using SOCK_PACKET, so this might be a 2.0[.x] * kernel, and might require special handling - check. */ if (uname(&utsname) < 0 || strncmp(utsname.release, "2.0", 3) == 0) { /* * Either we couldn't find out what kernel release * this is, or it's a 2.0[.x] kernel. * * In the 2.0[.x] kernel, a "recvfrom()" on * a SOCK_PACKET socket, with MSG_TRUNC set, will * return the number of bytes read, so if we pass * a length based on the snapshot length, it'll * return the number of bytes from the packet * copied to userland, not the actual length * of the packet. * * This means that, for example, the IP dissector * in tcpdump will get handed a packet length less * than the length in the IP header, and will * complain about "truncated-ip". * * So we don't bother trying to copy from the * kernel only the bytes in which we're interested, * but instead copy them all, just as the older * versions of libpcap for Linux did. * * The buffer therefore needs to be big enough to * hold the largest packet we can get from this * device. Unfortunately, we can't get the MRU * of the network; we can only get the MTU. The * MTU may be too small, in which case a packet larger * than the buffer size will be truncated *and* we * won't get the actual packet size. * * However, if the snapshot length is larger than * the buffer size based on the MTU, we use the * snapshot length as the buffer size, instead; * this means that with a sufficiently large snapshot * length we won't artificially truncate packets * to the MTU-based size. * * This mess just one of many problems with packet * capture on 2.0[.x] kernels; you really want a * 2.2[.x] or later kernel if you want packet capture * to work well. */ mtu = iface_get_mtu(handle->fd, device, handle->errbuf); if (mtu == -1) return PCAP_ERROR; handle->bufsize = MAX_LINKHEADER_SIZE + mtu; if (handle->bufsize < handle->snapshot) handle->bufsize = handle->snapshot; } else { /* * This is a 2.2[.x] or later kernel. * * We can safely pass "recvfrom()" a byte count * based on the snapshot length. */ handle->bufsize = handle->snapshot; } /* * Default value for offset to align link-layer payload * on a 4-byte boundary. */ handle->offset = 0; return 1; } /* * Bind the socket associated with FD to the given device using the * interface of the old kernels. */ static int iface_bind_old(int fd, const char *device, char *ebuf) { struct sockaddr saddr; int err; socklen_t errlen = sizeof(err); memset(&saddr, 0, sizeof(saddr)); strncpy(saddr.sa_data, device, sizeof(saddr.sa_data)); if (bind(fd, &saddr, sizeof(saddr)) == -1) { snprintf(ebuf, PCAP_ERRBUF_SIZE, "bind: %s", pcap_strerror(errno)); return -1; } /* Any pending errors, e.g., network is down? */ if (getsockopt(fd, SOL_SOCKET, SO_ERROR, &err, &errlen) == -1) { snprintf(ebuf, PCAP_ERRBUF_SIZE, "getsockopt: %s", pcap_strerror(errno)); return -1; } if (err > 0) { snprintf(ebuf, PCAP_ERRBUF_SIZE, "bind: %s", pcap_strerror(err)); return -1; } return 0; } /* ===== System calls available on all supported kernels ============== */ /* * Query the kernel for the MTU of the given interface. */ static int iface_get_mtu(int fd, const char *device, char *ebuf) { struct ifreq ifr; if (!device) return BIGGER_THAN_ALL_MTUS; memset(&ifr, 0, sizeof(ifr)); strncpy(ifr.ifr_name, device, sizeof(ifr.ifr_name)); if (ioctl(fd, SIOCGIFMTU, &ifr) == -1) { snprintf(ebuf, PCAP_ERRBUF_SIZE, "SIOCGIFMTU: %s", pcap_strerror(errno)); return -1; } return ifr.ifr_mtu; } /* * Get the hardware type of the given interface as ARPHRD_xxx constant. */ static int iface_get_arptype(int fd, const char *device, char *ebuf) { struct ifreq ifr; memset(&ifr, 0, sizeof(ifr)); strncpy(ifr.ifr_name, device, sizeof(ifr.ifr_name)); if (ioctl(fd, SIOCGIFHWADDR, &ifr) == -1) { snprintf(ebuf, PCAP_ERRBUF_SIZE, "SIOCGIFHWADDR: %s", pcap_strerror(errno)); if (errno == ENODEV) { /* * No such device. */ return PCAP_ERROR_NO_SUCH_DEVICE; } return PCAP_ERROR; } return ifr.ifr_hwaddr.sa_family; } #ifdef SO_ATTACH_FILTER static int fix_program(pcap_t *handle, struct sock_fprog *fcode) { size_t prog_size; register int i; register struct bpf_insn *p; struct bpf_insn *f; int len; /* * Make a copy of the filter, and modify that copy if * necessary. */ prog_size = sizeof(*handle->fcode.bf_insns) * handle->fcode.bf_len; len = handle->fcode.bf_len; f = (struct bpf_insn *)malloc(prog_size); if (f == NULL) { snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "malloc: %s", pcap_strerror(errno)); return -1; } memcpy(f, handle->fcode.bf_insns, prog_size); fcode->len = len; fcode->filter = (struct sock_filter *) f; for (i = 0; i < len; ++i) { p = &f[i]; /* * What type of instruction is this? */ switch (BPF_CLASS(p->code)) { case BPF_RET: /* * It's a return instruction; is the snapshot * length a constant, rather than the contents * of the accumulator? */ if (BPF_MODE(p->code) == BPF_K) { /* * Yes - if the value to be returned, * i.e. the snapshot length, is anything * other than 0, make it 65535, so that * the packet is truncated by "recvfrom()", * not by the filter. * * XXX - there's nothing we can easily do * if it's getting the value from the * accumulator; we'd have to insert * code to force non-zero values to be * 65535. */ if (p->k != 0) p->k = 65535; } break; case BPF_LD: case BPF_LDX: /* * It's a load instruction; is it loading * from the packet? */ switch (BPF_MODE(p->code)) { case BPF_ABS: case BPF_IND: case BPF_MSH: /* * Yes; are we in cooked mode? */ if (handle->md.cooked) { /* * Yes, so we need to fix this * instruction. */ if (fix_offset(p) < 0) { /* * We failed to do so. * Return 0, so our caller * knows to punt to userland. */ return 0; } } break; } break; } } return 1; /* we succeeded */ } static int fix_offset(struct bpf_insn *p) { /* * What's the offset? */ if (p->k >= SLL_HDR_LEN) { /* * It's within the link-layer payload; that starts at an * offset of 0, as far as the kernel packet filter is * concerned, so subtract the length of the link-layer * header. */ p->k -= SLL_HDR_LEN; } else if (p->k == 14) { /* * It's the protocol field; map it to the special magic * kernel offset for that field. */ p->k = SKF_AD_OFF + SKF_AD_PROTOCOL; } else { /* * It's within the header, but it's not one of those * fields; we can't do that in the kernel, so punt * to userland. */ return -1; } return 0; } static int set_kernel_filter(pcap_t *handle, struct sock_fprog *fcode) { int total_filter_on = 0; int save_mode; int ret; int save_errno; /* * The socket filter code doesn't discard all packets queued * up on the socket when the filter is changed; this means * that packets that don't match the new filter may show up * after the new filter is put onto the socket, if those * packets haven't yet been read. * * This means, for example, that if you do a tcpdump capture * with a filter, the first few packets in the capture might * be packets that wouldn't have passed the filter. * * We therefore discard all packets queued up on the socket * when setting a kernel filter. (This isn't an issue for * userland filters, as the userland filtering is done after * packets are queued up.) * * To flush those packets, we put the socket in read-only mode, * and read packets from the socket until there are no more to * read. * * In order to keep that from being an infinite loop - i.e., * to keep more packets from arriving while we're draining * the queue - we put the "total filter", which is a filter * that rejects all packets, onto the socket before draining * the queue. * * This code deliberately ignores any errors, so that you may * get bogus packets if an error occurs, rather than having * the filtering done in userland even if it could have been * done in the kernel. */ if (setsockopt(handle->fd, SOL_SOCKET, SO_ATTACH_FILTER, &total_fcode, sizeof(total_fcode)) == 0) { char drain[1]; /* * Note that we've put the total filter onto the socket. */ total_filter_on = 1; /* * Save the socket's current mode, and put it in * non-blocking mode; we drain it by reading packets * until we get an error (which is normally a * "nothing more to be read" error). */ save_mode = fcntl(handle->fd, F_GETFL, 0); if (save_mode != -1 && fcntl(handle->fd, F_SETFL, save_mode | O_NONBLOCK) >= 0) { while (recv(handle->fd, &drain, sizeof drain, MSG_TRUNC) >= 0) ; save_errno = errno; fcntl(handle->fd, F_SETFL, save_mode); if (save_errno != EAGAIN) { /* Fatal error */ reset_kernel_filter(handle); snprintf(handle->errbuf, PCAP_ERRBUF_SIZE, "recv: %s", pcap_strerror(save_errno)); return -2; } } } /* * Now attach the new filter. */ ret = setsockopt(handle->fd, SOL_SOCKET, SO_ATTACH_FILTER, fcode, sizeof(*fcode)); if (ret == -1 && total_filter_on) { /* * Well, we couldn't set that filter on the socket, * but we could set the total filter on the socket. * * This could, for example, mean that the filter was * too big to put into the kernel, so we'll have to * filter in userland; in any case, we'll be doing * filtering in userland, so we need to remove the * total filter so we see packets. */ save_errno = errno; /* * XXX - if this fails, we're really screwed; * we have the total filter on the socket, * and it won't come off. What do we do then? */ reset_kernel_filter(handle); errno = save_errno; } return ret; } static int reset_kernel_filter(pcap_t *handle) { /* * setsockopt() barfs unless it get a dummy parameter. * valgrind whines unless the value is initialized, * as it has no idea that setsockopt() ignores its * parameter. */ int dummy = 0; return setsockopt(handle->fd, SOL_SOCKET, SO_DETACH_FILTER, &dummy, sizeof(dummy)); } #endif