/* * Ouroboros - Copyright (C) 2016 - 2017 * * Shim IPC process over Ethernet with LLC * * Dimitri Staessens <dimitri.staessens@ugent.be> * Sander Vrijders <sander.vrijders@ugent.be> * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #define _DEFAULT_SOURCE #define OUROBOROS_PREFIX "ipcpd/shim-eth-llc" #include <ouroboros/config.h> #include <ouroboros/errno.h> #include <ouroboros/list.h> #include <ouroboros/utils.h> #include <ouroboros/bitmap.h> #include <ouroboros/dev.h> #include <ouroboros/ipcp-dev.h> #include <ouroboros/fqueue.h> #include <ouroboros/logs.h> #include <ouroboros/time_utils.h> #include "ipcp.h" #include "shim_eth_llc_messages.pb-c.h" #include <net/if.h> #include <signal.h> #include <stdlib.h> #include <pthread.h> #include <fcntl.h> #include <unistd.h> #include <string.h> #include <sys/socket.h> #include <sys/types.h> #include <sys/ioctl.h> #include <netinet/in.h> #ifdef __linux__ #include <linux/if_packet.h> #include <linux/if_ether.h> #endif #ifdef __FreeBSD__ #include <net/if_dl.h> #include <netinet/if_ether.h> #include <ifaddrs.h> #endif #include <poll.h> #include <sys/mman.h> #ifdef HAVE_NETMAP #define NETMAP_WITH_LIBS #include <net/netmap_user.h> #endif typedef ShimEthLlcMsg shim_eth_llc_msg_t; #define THIS_TYPE IPCP_SHIM_ETH_LLC #define MGMT_SAP 0x01 #define MAC_SIZE 6 #define LLC_HEADER_SIZE 3 #define MAX_SAPS 64 #define ETH_HEADER_SIZE (2 * MAC_SIZE + 2) #define ETH_FRAME_SIZE (ETH_HEADER_SIZE + LLC_HEADER_SIZE \ + SHIM_ETH_LLC_MAX_SDU_SIZE) #define SHIM_ETH_LLC_MAX_SDU_SIZE (1500 - LLC_HEADER_SIZE) #define EVENT_WAIT_TIMEOUT 100 /* us */ #define NAME_QUERY_TIMEOUT 2000 /* ms */ #define MGMT_TIMEOUT 100 /* ms */ struct eth_llc_frame { uint8_t dst_hwaddr[MAC_SIZE]; uint8_t src_hwaddr[MAC_SIZE]; uint8_t length[2]; uint8_t dsap; uint8_t ssap; uint8_t cf; uint8_t payload; }; struct ef { int8_t sap; int8_t r_sap; uint8_t r_addr[MAC_SIZE]; }; struct mgmt_frame { struct list_head next; uint8_t r_addr[MAC_SIZE]; uint8_t buf[ETH_FRAME_SIZE]; size_t len; }; struct { #ifdef HAVE_NETMAP struct nm_desc * nmd; uint8_t hw_addr[MAC_SIZE]; struct pollfd poll_in; struct pollfd poll_out; #else int s_fd; #ifdef __FreeBSD__ struct sockaddr_dl device; #else struct sockaddr_ll device; #endif #endif /* HAVE_NETMAP */ struct bmp * saps; flow_set_t * np1_flows; fqueue_t * fq; int * ef_to_fd; struct ef * fd_to_ef; pthread_rwlock_t flows_lock; pthread_t sdu_writer; pthread_t sdu_reader; /* Handle mgmt frames in a different thread */ pthread_t mgmt_handler; pthread_mutex_t mgmt_lock; pthread_cond_t mgmt_cond; struct list_head mgmt_frames; } eth_llc_data; static int eth_llc_data_init(void) { int i; int ret = -1; pthread_condattr_t cattr; eth_llc_data.fd_to_ef = malloc(sizeof(struct ef) * IRMD_MAX_FLOWS); if (eth_llc_data.fd_to_ef == NULL) return -ENOMEM; eth_llc_data.ef_to_fd = malloc(sizeof(struct ef) * MAX_SAPS); if (eth_llc_data.ef_to_fd == NULL) { ret = -ENOMEM; goto free_fd_to_ef; } eth_llc_data.saps = bmp_create(MAX_SAPS, 2); if (eth_llc_data.saps == NULL) { ret = -ENOMEM; goto free_ef_to_fd; } eth_llc_data.np1_flows = flow_set_create(); if (eth_llc_data.np1_flows == NULL) { ret = -ENOMEM; goto bmp_destroy; } eth_llc_data.fq = fqueue_create(); if (eth_llc_data.fq == NULL) { ret = -ENOMEM; goto flow_set_destroy; } for (i = 0; i < MAX_SAPS; ++i) eth_llc_data.ef_to_fd[i] = -1; for (i = 0; i < IRMD_MAX_FLOWS; ++i) { eth_llc_data.fd_to_ef[i].sap = -1; eth_llc_data.fd_to_ef[i].r_sap = -1; memset(ð_llc_data.fd_to_ef[i].r_addr, 0, MAC_SIZE); } if (pthread_rwlock_init(ð_llc_data.flows_lock, NULL)) goto fqueue_destroy; if (pthread_mutex_init(ð_llc_data.mgmt_lock, NULL)) goto flow_lock_destroy; if (pthread_condattr_init(&cattr)) goto mgmt_lock_destroy;; #ifndef __APPLE__ pthread_condattr_setclock(&cattr, PTHREAD_COND_CLOCK); #endif if (pthread_cond_init(ð_llc_data.mgmt_cond, &cattr)) goto mgmt_lock_destroy; list_head_init(ð_llc_data.mgmt_frames); return 0; mgmt_lock_destroy: pthread_mutex_destroy(ð_llc_data.mgmt_lock); flow_lock_destroy: pthread_rwlock_destroy(ð_llc_data.flows_lock); fqueue_destroy: fqueue_destroy(eth_llc_data.fq); flow_set_destroy: flow_set_destroy(eth_llc_data.np1_flows); bmp_destroy: bmp_destroy(eth_llc_data.saps); free_ef_to_fd: free(eth_llc_data.ef_to_fd); free_fd_to_ef: free(eth_llc_data.fd_to_ef); return ret; } void eth_llc_data_fini(void) { #ifdef HAVE_NETMAP nm_close(eth_llc_data.nmd); #else close(eth_llc_data.s_fd); #endif pthread_cond_destroy(ð_llc_data.mgmt_cond); pthread_mutex_destroy(ð_llc_data.mgmt_lock); pthread_rwlock_destroy(ð_llc_data.flows_lock); fqueue_destroy(eth_llc_data.fq); flow_set_destroy(eth_llc_data.np1_flows); bmp_destroy(eth_llc_data.saps); free(eth_llc_data.fd_to_ef); free(eth_llc_data.ef_to_fd); } static uint8_t reverse_bits(uint8_t b) { b = (b & 0xF0) >> 4 | (b & 0x0F) << 4; b = (b & 0xCC) >> 2 | (b & 0x33) << 2; b = (b & 0xAA) >> 1 | (b & 0x55) << 1; return b; } static int eth_llc_ipcp_send_frame(uint8_t * dst_addr, uint8_t dsap, uint8_t ssap, uint8_t * payload, size_t len) { uint32_t frame_len = 0; uint8_t cf = 0x03; uint16_t length; uint8_t frame[SHIM_ETH_LLC_MAX_SDU_SIZE]; struct eth_llc_frame * llc_frame; if (payload == NULL) { log_err("Payload was NULL."); return -1; } if (len > SHIM_ETH_LLC_MAX_SDU_SIZE) return -1; llc_frame = (struct eth_llc_frame *) frame; memcpy(llc_frame->dst_hwaddr, dst_addr, MAC_SIZE); memcpy(llc_frame->src_hwaddr, #ifdef HAVE_NETMAP eth_llc_data.hw_addr, #elif defined ( __FreeBSD__ ) LLADDR(ð_llc_data.device), #else eth_llc_data.device.sll_addr, #endif /* HAVE_NETMAP */ MAC_SIZE); length = htons(LLC_HEADER_SIZE + len); memcpy(&llc_frame->length, &length, sizeof(length)); llc_frame->dsap = dsap; llc_frame->ssap = ssap; llc_frame->cf = cf; memcpy(&llc_frame->payload, payload, len); frame_len = ETH_HEADER_SIZE + LLC_HEADER_SIZE + len; #ifdef HAVE_NETMAP if (poll(ð_llc_data.poll_out, 1, -1) < 0) return -1; if (nm_inject(eth_llc_data.nmd, frame, frame_len) != (int) frame_len) { log_err("Failed to send message."); return -1; } #else if (sendto(eth_llc_data.s_fd, frame, frame_len, 0, (struct sockaddr *) ð_llc_data.device, sizeof(eth_llc_data.device)) <= 0) { log_err("Failed to send message."); return -1; } #endif /* HAVE_NETMAP */ return 0; } static int eth_llc_ipcp_send_mgmt_frame(shim_eth_llc_msg_t * msg, uint8_t * dst_addr) { size_t len; uint8_t * buf; len = shim_eth_llc_msg__get_packed_size(msg); if (len == 0) return -1; buf = malloc(len); if (buf == NULL) return -1; shim_eth_llc_msg__pack(msg, buf); if (eth_llc_ipcp_send_frame(dst_addr, reverse_bits(MGMT_SAP), reverse_bits(MGMT_SAP), buf, len)) { log_err("Failed to send management frame."); free(buf); return -1; } free(buf); return 0; } static int eth_llc_ipcp_sap_alloc(uint8_t * dst_addr, uint8_t ssap, char * dst_name, qoscube_t cube) { shim_eth_llc_msg_t msg = SHIM_ETH_LLC_MSG__INIT; msg.code = SHIM_ETH_LLC_MSG_CODE__FLOW_REQ; msg.has_ssap = true; msg.ssap = ssap; msg.dst_name = dst_name; msg.has_qoscube = true; msg.qoscube = cube; return eth_llc_ipcp_send_mgmt_frame(&msg, dst_addr); } static int eth_llc_ipcp_sap_alloc_resp(uint8_t * dst_addr, uint8_t ssap, uint8_t dsap, int response) { shim_eth_llc_msg_t msg = SHIM_ETH_LLC_MSG__INIT; msg.code = SHIM_ETH_LLC_MSG_CODE__FLOW_REPLY; msg.has_ssap = true; msg.ssap = ssap; msg.has_dsap = true; msg.dsap = dsap; msg.has_response = true; msg.response = response; return eth_llc_ipcp_send_mgmt_frame(&msg, dst_addr); } static int eth_llc_ipcp_sap_req(uint8_t r_sap, uint8_t * r_addr, char * dst_name, qoscube_t cube) { struct timespec ts = {0, EVENT_WAIT_TIMEOUT * 1000}; int fd; pthread_mutex_lock(&ipcpi.alloc_lock); while (ipcpi.alloc_id != -1 && ipcp_get_state() == IPCP_OPERATIONAL) pthread_cond_timedwait(&ipcpi.alloc_cond, &ipcpi.alloc_lock, &ts); if (ipcp_get_state() != IPCP_OPERATIONAL) { log_dbg("Won't allocate over non-operational IPCP."); pthread_mutex_unlock(&ipcpi.alloc_lock); return -1; } /* reply to IRM, called under lock to prevent race */ fd = ipcp_flow_req_arr(getpid(), dst_name, cube); if (fd < 0) { pthread_mutex_unlock(&ipcpi.alloc_lock); log_err("Could not get new flow from IRMd."); return -1; } pthread_rwlock_wrlock(ð_llc_data.flows_lock); eth_llc_data.fd_to_ef[fd].r_sap = r_sap; memcpy(eth_llc_data.fd_to_ef[fd].r_addr, r_addr, MAC_SIZE); ipcpi.alloc_id = fd; pthread_cond_broadcast(&ipcpi.alloc_cond); pthread_rwlock_unlock(ð_llc_data.flows_lock); pthread_mutex_unlock(&ipcpi.alloc_lock); log_dbg("New flow request, fd %d, remote SAP %d.", fd, r_sap); return 0; } static int eth_llc_ipcp_sap_alloc_reply(uint8_t ssap, uint8_t * r_addr, int dsap, int response) { int ret = 0; int fd = -1; pthread_rwlock_wrlock(ð_llc_data.flows_lock); fd = eth_llc_data.ef_to_fd[dsap]; if (fd < 0) { pthread_rwlock_unlock(& eth_llc_data.flows_lock); log_err("No flow found with that SAP."); return -1; /* -EFLOWNOTFOUND */ } if (response) { bmp_release(eth_llc_data.saps, eth_llc_data.fd_to_ef[fd].sap); } else { eth_llc_data.fd_to_ef[fd].r_sap = ssap; memcpy(eth_llc_data.fd_to_ef[fd].r_addr, r_addr, MAC_SIZE); } pthread_rwlock_unlock(ð_llc_data.flows_lock); log_dbg("Flow reply, fd %d, SSAP %d, DSAP %d.", fd, ssap, dsap); if ((ret = ipcp_flow_alloc_reply(fd, response)) < 0) return -1; return ret; } static int eth_llc_ipcp_name_query_req(char * name, uint8_t * r_addr) { shim_eth_llc_msg_t msg = SHIM_ETH_LLC_MSG__INIT; if (shim_data_reg_has(ipcpi.shim_data, name)) { msg.code = SHIM_ETH_LLC_MSG_CODE__NAME_QUERY_REPLY; msg.dst_name = name; eth_llc_ipcp_send_mgmt_frame(&msg, r_addr); } return 0; } static int eth_llc_ipcp_name_query_reply(char * name, uint8_t * r_addr) { uint64_t address = 0; struct list_head * pos; memcpy(&address, r_addr, MAC_SIZE); shim_data_dir_add_entry(ipcpi.shim_data, name, address); pthread_mutex_lock(&ipcpi.shim_data->dir_queries_lock); list_for_each(pos, &ipcpi.shim_data->dir_queries) { struct dir_query * e = list_entry(pos, struct dir_query, next); if (strcmp(e->name, name) == 0) { shim_data_dir_query_respond(e); } } pthread_mutex_unlock(&ipcpi.shim_data->dir_queries_lock); return 0; } static int eth_llc_ipcp_mgmt_frame(uint8_t * buf, size_t len, uint8_t * r_addr) { shim_eth_llc_msg_t * msg; msg = shim_eth_llc_msg__unpack(NULL, len, buf); if (msg == NULL) { log_err("Failed to unpack."); return -1; } switch (msg->code) { case SHIM_ETH_LLC_MSG_CODE__FLOW_REQ: if (shim_data_reg_has(ipcpi.shim_data, msg->dst_name)) { eth_llc_ipcp_sap_req(msg->ssap, r_addr, msg->dst_name, msg->qoscube); } break; case SHIM_ETH_LLC_MSG_CODE__FLOW_REPLY: eth_llc_ipcp_sap_alloc_reply(msg->ssap, r_addr, msg->dsap, msg->response); break; case SHIM_ETH_LLC_MSG_CODE__NAME_QUERY_REQ: eth_llc_ipcp_name_query_req(msg->dst_name, r_addr); break; case SHIM_ETH_LLC_MSG_CODE__NAME_QUERY_REPLY: eth_llc_ipcp_name_query_reply(msg->dst_name, r_addr); break; default: log_err("Unknown message received %d.", msg->code); shim_eth_llc_msg__free_unpacked(msg, NULL); return -1; } shim_eth_llc_msg__free_unpacked(msg, NULL); return 0; } static void * eth_llc_ipcp_mgmt_handler(void * o) { int ret; struct timespec timeout = {(MGMT_TIMEOUT / 1000), (MGMT_TIMEOUT % 1000) * MILLION}; struct timespec abstime; struct mgmt_frame * frame; (void) o; while (true) { ret = 0; if (ipcp_get_state() != IPCP_OPERATIONAL) return (void *) 0; clock_gettime(PTHREAD_COND_CLOCK, &abstime); ts_add(&abstime, &timeout, &abstime); pthread_mutex_lock(ð_llc_data.mgmt_lock); while (list_is_empty(ð_llc_data.mgmt_frames) && ret != -ETIMEDOUT) ret = -pthread_cond_timedwait(ð_llc_data.mgmt_cond, ð_llc_data.mgmt_lock, &abstime); if (ret == -ETIMEDOUT) { pthread_mutex_unlock(ð_llc_data.mgmt_lock); continue; } frame = list_first_entry((ð_llc_data.mgmt_frames), struct mgmt_frame, next); if (frame == NULL) { pthread_mutex_unlock(ð_llc_data.mgmt_lock); continue; } list_del(&frame->next); pthread_mutex_unlock(ð_llc_data.mgmt_lock); eth_llc_ipcp_mgmt_frame(frame->buf, frame->len, frame->r_addr); free(frame); } } static void * eth_llc_ipcp_sdu_reader(void * o) { uint8_t br_addr[MAC_SIZE]; uint16_t length; uint8_t dsap; uint8_t ssap; int fd; #ifdef HAVE_NETMAP uint8_t * buf; #else uint8_t buf[ETH_FRAME_SIZE]; #endif int frame_len = 0; struct eth_llc_frame * llc_frame; struct mgmt_frame * frame; #ifdef HAVE_NETMAP struct nm_pkthdr hdr; #endif (void) o; memset(br_addr, 0xff, MAC_SIZE * sizeof(uint8_t)); while (true) { if (ipcp_get_state() != IPCP_OPERATIONAL) return (void *) 0; #ifdef HAVE_NETMAP if (poll(ð_llc_data.poll_in, 1, EVENT_WAIT_TIMEOUT) < 0) continue; if (eth_llc_data.poll_in.revents == 0) /* TIMED OUT */ continue; buf = nm_nextpkt(eth_llc_data.nmd, &hdr); if (buf == NULL) { log_err("Bad read from netmap device."); continue; } #else frame_len = recv(eth_llc_data.s_fd, buf, SHIM_ETH_LLC_MAX_SDU_SIZE, 0); #endif if (frame_len < 0) continue; llc_frame = (struct eth_llc_frame *) buf; assert(llc_frame->dst_hwaddr); #ifdef HAVE_NETMAP if (memcmp(eth_llc_data.hw_addr, #elif defined ( __FreeBSD__ ) if (memcmp(LLADDR(ð_llc_data.device), #else if (memcmp(eth_llc_data.device.sll_addr, #endif /* HAVE_NETMAP */ llc_frame->dst_hwaddr, MAC_SIZE) && memcmp(br_addr, llc_frame->dst_hwaddr, MAC_SIZE)) continue; memcpy(&length, &llc_frame->length, sizeof(length)); length = ntohs(length); if (length > 0x05FF) /* DIX */ continue; length -= LLC_HEADER_SIZE; dsap = reverse_bits(llc_frame->dsap); ssap = reverse_bits(llc_frame->ssap); if (ssap == MGMT_SAP && dsap == MGMT_SAP) { pthread_mutex_lock(ð_llc_data.mgmt_lock); frame = malloc(sizeof(*frame)); if (frame == NULL) { pthread_mutex_unlock(ð_llc_data.mgmt_lock); continue; } memcpy(frame->buf, &llc_frame->payload, length); memcpy(frame->r_addr, llc_frame->src_hwaddr, MAC_SIZE); frame->len = length; list_add(&frame->next, ð_llc_data.mgmt_frames); pthread_cond_signal(ð_llc_data.mgmt_cond); pthread_mutex_unlock(ð_llc_data.mgmt_lock); } else { pthread_rwlock_rdlock(ð_llc_data.flows_lock); fd = eth_llc_data.ef_to_fd[dsap]; if (fd < 0) { pthread_rwlock_unlock(ð_llc_data.flows_lock); continue; } if (eth_llc_data.fd_to_ef[fd].r_sap != ssap || memcmp(eth_llc_data.fd_to_ef[fd].r_addr, llc_frame->src_hwaddr, MAC_SIZE)) { pthread_rwlock_unlock(ð_llc_data.flows_lock); continue; } pthread_rwlock_unlock(ð_llc_data.flows_lock); flow_write(fd, &llc_frame->payload, length); } } return (void *) 0; } static void * eth_llc_ipcp_sdu_writer(void * o) { struct timespec timeout = {0, EVENT_WAIT_TIMEOUT * 1000}; int fd; struct shm_du_buff * sdb; uint8_t ssap; uint8_t dsap; uint8_t r_addr[MAC_SIZE]; (void) o; while (flow_event_wait(eth_llc_data.np1_flows, eth_llc_data.fq, &timeout)) { if (ipcp_get_state() != IPCP_OPERATIONAL) return (void *) 0; pthread_rwlock_rdlock(ð_llc_data.flows_lock); while ((fd = fqueue_next(eth_llc_data.fq)) >= 0) { if (ipcp_flow_read(fd, &sdb)) { log_err("Bad read from fd %d.", fd); continue; } ssap = reverse_bits(eth_llc_data.fd_to_ef[fd].sap); dsap = reverse_bits(eth_llc_data.fd_to_ef[fd].r_sap); memcpy(r_addr, eth_llc_data.fd_to_ef[fd].r_addr, MAC_SIZE); eth_llc_ipcp_send_frame(r_addr, dsap, ssap, shm_du_buff_head(sdb), shm_du_buff_tail(sdb) - shm_du_buff_head(sdb)); ipcp_flow_del(sdb); } pthread_rwlock_unlock(ð_llc_data.flows_lock); } return (void *) 1; } void ipcp_sig_handler(int sig, siginfo_t * info, void * c) { (void) c; switch(sig) { case SIGINT: case SIGTERM: case SIGHUP: if (info->si_pid == ipcpi.irmd_api) { if (ipcp_get_state() == IPCP_INIT) ipcp_set_state(IPCP_NULL); if (ipcp_get_state() == IPCP_OPERATIONAL) ipcp_set_state(IPCP_SHUTDOWN); } default: return; } } static int eth_llc_ipcp_bootstrap(struct dif_config * conf) { int idx; struct ifreq ifr; #ifdef HAVE_NETMAP char ifn[IFNAMSIZ]; #ifndef __FreeBSD__ int skfd; #endif #else struct timeval tv = {0, EVENT_WAIT_TIMEOUT * MILLION}; #ifdef __FreeBSD__ struct ifaddrs * ifaddr; struct ifaddrs * ifa; #endif int skfd; #endif /* HAVE_NETMAP */ assert(conf); assert(conf->type == THIS_TYPE); if (ipcp_get_state() != IPCP_INIT) { log_err("IPCP in wrong state."); return -1; } if (conf->if_name == NULL) { log_err("Interface name is NULL."); return -1; } memset(&ifr, 0, sizeof(ifr)); memcpy(ifr.ifr_name, conf->if_name, strlen(conf->if_name)); #ifdef __FreeBSD__ if (getifaddrs(&ifaddr) < 0) { log_err("Could not get interfaces."); return -1; } for (ifa = ifaddr, idx = 0; ifa != NULL; ifa = ifa->ifa_next, ++idx) { if (strcmp(ifa->ifa_name, conf->if_name)) continue; log_dbg("Interface %s found.", conf->if_name); memcpy(&ifr.ifr_addr, ifa->ifa_addr, sizeof(*ifa->ifa_addr)); break; } if (ifa == NULL) { log_err("Interface not found."); freeifaddrs(ifaddr); return -1; } freeifaddrs(ifaddr); #else skfd = socket(AF_UNIX, SOCK_STREAM, 0); if (skfd < 0) { log_err("Failed to open socket."); return -1; } if (ioctl(skfd, SIOCGIFHWADDR, &ifr)) { log_err("Failed to ioctl."); close(skfd); return -1; } close(skfd); idx = if_nametoindex(conf->if_name); if (idx == 0) { log_err("Failed to retrieve interface index."); close(skfd); return -1; } #endif /* __FreeBSD__ */ #ifdef HAVE_NETMAP strcpy(ifn, "netmap:"); strcat(ifn, conf->if_name); #ifdef __FreeBSD__ memcpy(eth_llc_data.hw_addr, ifr.ifr_addr.sa_data, MAC_SIZE); #else memcpy(eth_llc_data.hw_addr, ifr.ifr_hwaddr.sa_data, MAC_SIZE); #endif /* __FreeBSD__ */ eth_llc_data.nmd = nm_open(ifn, NULL, 0, NULL); if (eth_llc_data.nmd == NULL) { log_err("Failed to open netmap device."); return -1; } memset(ð_llc_data.poll_in, 0, sizeof(eth_llc_data.poll_in)); memset(ð_llc_data.poll_out, 0, sizeof(eth_llc_data.poll_out)); eth_llc_data.poll_in.fd = NETMAP_FD(eth_llc_data.nmd); eth_llc_data.poll_in.events = POLLIN; eth_llc_data.poll_out.fd = NETMAP_FD(eth_llc_data.nmd); eth_llc_data.poll_out.events = POLLOUT; log_info("Using netmap device."); #else /* !HAVE_NETMAP */ memset(&(eth_llc_data.device), 0, sizeof(eth_llc_data.device)); #ifdef __FreeBSD__ eth_llc_data.device.sdl_index = idx; eth_llc_data.device.sdl_family = AF_LINK; memcpy(LLADDR(ð_llc_data.device), ifr.ifr_addr.sa_data, MAC_SIZE); eth_llc_data.device.sdl_alen = MAC_SIZE; eth_llc_data.s_fd = socket(AF_LINK, SOCK_RAW, 0); log_info("Using berkeley packet filter."); /* TODO */ #else eth_llc_data.device.sll_ifindex = idx; eth_llc_data.device.sll_family = AF_PACKET; memcpy(eth_llc_data.device.sll_addr, ifr.ifr_hwaddr.sa_data, MAC_SIZE); eth_llc_data.device.sll_halen = MAC_SIZE; eth_llc_data.device.sll_protocol = htons(ETH_P_ALL); eth_llc_data.s_fd = socket(AF_PACKET, SOCK_RAW, htons(ETH_P_802_2)); log_info("Using raw socket device."); #endif /* __FreeBSD__ */ if (eth_llc_data.s_fd < 0) { log_err("Failed to create socket."); return -1; } if (bind(eth_llc_data.s_fd, (struct sockaddr *) ð_llc_data.device, sizeof(eth_llc_data.device))) { log_err("Failed to bind socket to interface"); close(eth_llc_data.s_fd); return -1; } if (setsockopt(eth_llc_data.s_fd, SOL_SOCKET, SO_RCVTIMEO, (void *) &tv, sizeof(tv))) { log_err("Failed to set socket timeout"); close(eth_llc_data.s_fd); return -1; } #endif /* HAVE_NETMAP */ ipcp_set_state(IPCP_OPERATIONAL); pthread_create(ð_llc_data.mgmt_handler, NULL, eth_llc_ipcp_mgmt_handler, NULL); pthread_create(ð_llc_data.sdu_reader, NULL, eth_llc_ipcp_sdu_reader, NULL); pthread_create(ð_llc_data.sdu_writer, NULL, eth_llc_ipcp_sdu_writer, NULL); log_dbg("Bootstrapped shim IPCP over Ethernet with LLC with api %d.", getpid()); return 0; } static int eth_llc_ipcp_name_reg(char * name) { char * name_dup; name_dup = strdup(name); if (name_dup == NULL) { log_err("Failed to duplicate name."); return -ENOMEM; } if (shim_data_reg_add_entry(ipcpi.shim_data, name_dup)) { log_err("Failed to add %s to local registry.", name); free(name_dup); return -1; } log_dbg("Registered %s.", name); return 0; } static int eth_llc_ipcp_name_unreg(char * name) { shim_data_reg_del_entry(ipcpi.shim_data, name); return 0; } static int eth_llc_ipcp_name_query(char * name) { uint8_t r_addr[MAC_SIZE]; struct timespec timeout = {(NAME_QUERY_TIMEOUT / 1000), (NAME_QUERY_TIMEOUT % 1000) * MILLION}; shim_eth_llc_msg_t msg = SHIM_ETH_LLC_MSG__INIT; struct dir_query * query; int ret; if (shim_data_dir_has(ipcpi.shim_data, name)) return 0; msg.code = SHIM_ETH_LLC_MSG_CODE__NAME_QUERY_REQ; msg.dst_name = name; memset(r_addr, 0xff, MAC_SIZE); query = shim_data_dir_query_create(name); if (query == NULL) return -1; pthread_mutex_lock(&ipcpi.shim_data->dir_queries_lock); list_add(&query->next, &ipcpi.shim_data->dir_queries); pthread_mutex_unlock(&ipcpi.shim_data->dir_queries_lock); eth_llc_ipcp_send_mgmt_frame(&msg, r_addr); ret = shim_data_dir_query_wait(query, &timeout); pthread_mutex_lock(&ipcpi.shim_data->dir_queries_lock); list_del(&query->next); shim_data_dir_query_destroy(query); pthread_mutex_unlock(&ipcpi.shim_data->dir_queries_lock); return ret; } static int eth_llc_ipcp_flow_alloc(int fd, char * dst_name, qoscube_t cube) { uint8_t ssap = 0; uint8_t r_addr[MAC_SIZE]; uint64_t addr = 0; log_dbg("Allocating flow to %s.", dst_name); if (dst_name == NULL) return -1; if (cube != QOS_CUBE_BE && cube != QOS_CUBE_FRC) { log_dbg("Unsupported QoS requested."); return -1; } if (ipcp_get_state() != IPCP_OPERATIONAL) { log_dbg("Won't allocate flow with non-enrolled IPCP."); return -1; /* -ENOTENROLLED */ } if (!shim_data_dir_has(ipcpi.shim_data, dst_name)) { log_err("Destination unreachable."); return -1; } addr = shim_data_dir_get_addr(ipcpi.shim_data, dst_name); pthread_rwlock_wrlock(ð_llc_data.flows_lock); ssap = bmp_allocate(eth_llc_data.saps); if (!bmp_is_id_valid(eth_llc_data.saps, ssap)) { pthread_rwlock_unlock(ð_llc_data.flows_lock); return -1; } eth_llc_data.fd_to_ef[fd].sap = ssap; eth_llc_data.ef_to_fd[ssap] = fd; pthread_rwlock_unlock(ð_llc_data.flows_lock); memcpy(r_addr, &addr, MAC_SIZE); if (eth_llc_ipcp_sap_alloc(r_addr, ssap, dst_name, cube) < 0) { pthread_rwlock_wrlock(ð_llc_data.flows_lock); bmp_release(eth_llc_data.saps, eth_llc_data.fd_to_ef[fd].sap); eth_llc_data.fd_to_ef[fd].sap = -1; eth_llc_data.ef_to_fd[ssap] = -1; pthread_rwlock_unlock(ð_llc_data.flows_lock); return -1; } flow_set_add(eth_llc_data.np1_flows, fd); log_dbg("Pending flow with fd %d on SAP %d.", fd, ssap); return 0; } static int eth_llc_ipcp_flow_alloc_resp(int fd, int response) { struct timespec ts = {0, EVENT_WAIT_TIMEOUT * 1000}; uint8_t ssap = 0; uint8_t r_sap = 0; uint8_t r_addr[MAC_SIZE]; pthread_mutex_lock(&ipcpi.alloc_lock); while (ipcpi.alloc_id != fd && ipcp_get_state() == IPCP_OPERATIONAL) pthread_cond_timedwait(&ipcpi.alloc_cond, &ipcpi.alloc_lock, &ts); if (ipcp_get_state() != IPCP_OPERATIONAL) { pthread_mutex_unlock(&ipcpi.alloc_lock); return -1; } ipcpi.alloc_id = -1; pthread_cond_broadcast(&ipcpi.alloc_cond); pthread_mutex_unlock(&ipcpi.alloc_lock); pthread_rwlock_wrlock(ð_llc_data.flows_lock); ssap = bmp_allocate(eth_llc_data.saps); if (!bmp_is_id_valid(eth_llc_data.saps, ssap)) { pthread_rwlock_unlock(ð_llc_data.flows_lock); return -1; } eth_llc_data.fd_to_ef[fd].sap = ssap; memcpy(r_addr, eth_llc_data.fd_to_ef[fd].r_addr, MAC_SIZE); r_sap = eth_llc_data.fd_to_ef[fd].r_sap; eth_llc_data.ef_to_fd[ssap] = fd; pthread_rwlock_unlock(ð_llc_data.flows_lock); if (eth_llc_ipcp_sap_alloc_resp(r_addr, ssap, r_sap, response) < 0) { pthread_rwlock_wrlock(ð_llc_data.flows_lock); bmp_release(eth_llc_data.saps, eth_llc_data.fd_to_ef[fd].sap); pthread_rwlock_unlock(ð_llc_data.flows_lock); return -1; } flow_set_add(eth_llc_data.np1_flows, fd); log_dbg("Accepted flow, fd %d, SAP %d.", fd, (uint8_t)ssap); return 0; } static int eth_llc_ipcp_flow_dealloc(int fd) { uint8_t sap; uint8_t addr[MAC_SIZE]; ipcp_flow_fini(fd); if (ipcp_get_state() != IPCP_OPERATIONAL) { log_dbg("Won't register with non-enrolled IPCP."); return -1; /* -ENOTENROLLED */ } pthread_rwlock_wrlock(ð_llc_data.flows_lock); flow_set_del(eth_llc_data.np1_flows, fd); sap = eth_llc_data.fd_to_ef[fd].sap; memcpy(addr, eth_llc_data.fd_to_ef[fd].r_addr, MAC_SIZE); bmp_release(eth_llc_data.saps, sap); eth_llc_data.fd_to_ef[fd].sap = -1; eth_llc_data.fd_to_ef[fd].r_sap = -1; memset(ð_llc_data.fd_to_ef[fd].r_addr, 0, MAC_SIZE); eth_llc_data.ef_to_fd[sap] = -1; pthread_rwlock_unlock(ð_llc_data.flows_lock); flow_dealloc(fd); log_dbg("Flow with fd %d deallocated.", fd); return 0; } static struct ipcp_ops eth_llc_ops = { .ipcp_bootstrap = eth_llc_ipcp_bootstrap, .ipcp_enroll = NULL, .ipcp_name_reg = eth_llc_ipcp_name_reg, .ipcp_name_unreg = eth_llc_ipcp_name_unreg, .ipcp_name_query = eth_llc_ipcp_name_query, .ipcp_flow_alloc = eth_llc_ipcp_flow_alloc, .ipcp_flow_alloc_resp = eth_llc_ipcp_flow_alloc_resp, .ipcp_flow_dealloc = eth_llc_ipcp_flow_dealloc }; int main(int argc, char * argv[]) { struct sigaction sig_act; sigset_t sigset; sigemptyset(&sigset); sigaddset(&sigset, SIGINT); sigaddset(&sigset, SIGQUIT); sigaddset(&sigset, SIGHUP); sigaddset(&sigset, SIGPIPE); /* init sig_act */ memset(&sig_act, 0, sizeof(sig_act)); /* install signal traps */ sig_act.sa_sigaction = &ipcp_sig_handler; sig_act.sa_flags = SA_SIGINFO; sigaction(SIGINT, &sig_act, NULL); sigaction(SIGTERM, &sig_act, NULL); sigaction(SIGHUP, &sig_act, NULL); sigaction(SIGPIPE, &sig_act, NULL); if (ipcp_init(argc, argv, THIS_TYPE, ð_llc_ops) < 0) { ipcp_create_r(getpid(), -1); exit(EXIT_FAILURE); } if (eth_llc_data_init() < 0) { log_err("Failed to init shim-eth-llc data."); ipcp_create_r(getpid(), -1); ipcp_fini(); exit(EXIT_FAILURE); } pthread_sigmask(SIG_BLOCK, &sigset, NULL); if (ipcp_boot() < 0) { log_err("Failed to boot IPCP."); ipcp_create_r(getpid(), -1); eth_llc_data_fini(); ipcp_fini(); exit(EXIT_FAILURE); } pthread_sigmask(SIG_UNBLOCK, &sigset, NULL); if (ipcp_create_r(getpid(), 0)) { log_err("Failed to notify IRMd we are initialized."); ipcp_set_state(IPCP_NULL); ipcp_shutdown(); eth_llc_data_fini(); ipcp_fini(); exit(EXIT_FAILURE); } ipcp_shutdown(); if (ipcp_get_state() == IPCP_SHUTDOWN) { pthread_join(eth_llc_data.sdu_writer, NULL); pthread_join(eth_llc_data.sdu_reader, NULL); pthread_join(eth_llc_data.mgmt_handler, NULL); } eth_llc_data_fini(); ipcp_fini(); exit(EXIT_SUCCESS); }