/* * Ouroboros - Copyright (C) 2016 - 2017 * * Normal IPC Process * * Dimitri Staessens * Sander Vrijders * * 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 OUROBOROS_PREFIX "normal-ipcp" #include #include #include #include #include #include #include #include #include "addr_auth.h" #include "connmgr.h" #include "dir.h" #include "enroll.h" #include "fmgr.h" #include "ipcp.h" #include "ribconfig.h" #include "ribmgr.h" #include #include #include #include #include #include #define THIS_TYPE IPCP_NORMAL 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) { pthread_rwlock_wrlock(&ipcpi.state_lock); if (ipcp_get_state() == IPCP_INIT) ipcp_set_state(IPCP_NULL); if (ipcp_get_state() == IPCP_OPERATIONAL) ipcp_set_state(IPCP_SHUTDOWN); pthread_rwlock_unlock(&ipcpi.state_lock); } default: return; } } /* * Boots the IPCP off information in the rib. * Common function after bootstrap or enroll. * Call under ipcpi.state_lock */ static int boot_components(void) { char buf[256]; ssize_t len; enum pol_addr_auth pa; len = rib_read(DIF_PATH, &buf, 256); if (len < 0) { log_err("Failed to read DIF name: %zd.", len); return -1; } ipcpi.dif_name = strdup(buf); if (ipcpi.dif_name == NULL) { log_err("Failed to set DIF name."); return -1; } if (rib_add(MEMBERS_PATH, ipcpi.name)) { log_err("Failed to add name to " MEMBERS_PATH); return -1; } log_dbg("Starting components."); if (rib_read(BOOT_PATH "/addr_auth/type", &pa, sizeof(pa)) != sizeof(pa)) { log_err("Failed to read policy for address authority."); connmgr_fini(); return -1; } if (addr_auth_init(pa)) { log_err("Failed to init address authority."); return -1; } ipcpi.dt_addr = addr_auth_address(); if (ipcpi.dt_addr == 0) { log_err("Failed to get a valid address."); addr_auth_fini(); return -1; } log_dbg("IPCP got address %" PRIu64 ".", ipcpi.dt_addr); log_dbg("Starting ribmgr."); if (ribmgr_init()) { log_err("Failed to initialize RIB manager."); addr_auth_fini(); return -1; } if (dir_init()) { log_err("Failed to initialize directory."); ribmgr_fini(); addr_auth_fini(); return -1; } log_dbg("Ribmgr started."); if (fmgr_init()) { dir_fini(); ribmgr_fini(); addr_auth_fini(); log_err("Failed to start flow manager."); return -1; } if (frct_init()) { fmgr_fini(); dir_fini(); ribmgr_fini(); addr_auth_fini(); log_err("Failed to initialize FRCT."); return -1; } if (enroll_start()) { fmgr_fini(); dir_fini(); ribmgr_fini(); addr_auth_fini(); log_err("Failed to start enroll."); return -1; } ipcp_set_state(IPCP_OPERATIONAL); if (connmgr_start()) { ipcp_set_state(IPCP_INIT); enroll_stop(); frct_fini(); fmgr_fini(); dir_fini(); ribmgr_fini(); addr_auth_fini(); log_err("Failed to start AP connection manager."); return -1; } return 0; } void shutdown_components(void) { connmgr_stop(); enroll_stop(); frct_fini(); fmgr_fini(); dir_fini(); ribmgr_fini(); addr_auth_fini(); } static int normal_ipcp_enroll(char * dst_name) { pthread_rwlock_wrlock(&ipcpi.state_lock); if (ipcp_get_state() != IPCP_INIT) { pthread_rwlock_unlock(&ipcpi.state_lock); log_err("IPCP in wrong state."); return -1; /* -ENOTINIT */ } if (rib_add(RIB_ROOT, MEMBERS_NAME)) { pthread_rwlock_unlock(&ipcpi.state_lock); log_err("Failed to create members."); return -1; } /* Get boot state from peer */ if (enroll_boot(dst_name)) { pthread_rwlock_unlock(&ipcpi.state_lock); log_err("Failed to boot IPCP components."); return -1; } if (boot_components()) { pthread_rwlock_unlock(&ipcpi.state_lock); log_err("Failed to boot IPCP components."); return -1; } pthread_rwlock_unlock(&ipcpi.state_lock); log_dbg("Enrolled with %s.", dst_name); return 0; } const struct ros { char * parent; char * child; } ros[] = { /* GENERAL IPCP INFO */ {RIB_ROOT, DIF_NAME}, /* BOOT INFO */ {RIB_ROOT, BOOT_NAME}, /* OTHER RIB STRUCTURES */ {RIB_ROOT, MEMBERS_NAME}, /* DT COMPONENT */ {BOOT_PATH, "dt"}, {BOOT_PATH "/dt", "gam"}, {BOOT_PATH "/dt/gam", "type"}, {BOOT_PATH "/dt/gam", "cacep"}, {BOOT_PATH "/dt", "const"}, {BOOT_PATH "/dt/const", "addr_size"}, {BOOT_PATH "/dt/const", "cep_id_size"}, {BOOT_PATH "/dt/const", "pdu_length_size"}, {BOOT_PATH "/dt/const", "seqno_size"}, {BOOT_PATH "/dt/const", "has_ttl"}, {BOOT_PATH "/dt/const", "has_chk"}, {BOOT_PATH "/dt/const", "min_pdu_size"}, {BOOT_PATH "/dt/const", "max_pdu_size"}, /* RIB MGR COMPONENT */ {BOOT_PATH, "rm"}, {BOOT_PATH "/rm","gam"}, {BOOT_PATH "/rm/gam", "type"}, {BOOT_PATH "/rm/gam", "cacep"}, /* ADDR AUTH COMPONENT */ {BOOT_PATH, "addr_auth"}, {BOOT_PATH "/addr_auth", "type"}, {NULL, NULL} }; int normal_rib_init(void) { struct ros * r; for (r = (struct ros *) ros; r->parent; ++r) { if (rib_add(r->parent, r->child)) { log_err("Failed to create %s/%s", r->parent, r->child); return -1; } } return 0; } static int normal_ipcp_bootstrap(struct dif_config * conf) { assert(conf); assert(conf->type == THIS_TYPE); pthread_rwlock_wrlock(&ipcpi.state_lock); if (ipcp_get_state() != IPCP_INIT) { pthread_rwlock_unlock(&ipcpi.state_lock); log_err("IPCP in wrong state."); return -1; /* -ENOTINIT */ } if (normal_rib_init()) { pthread_rwlock_unlock(&ipcpi.state_lock); log_err("Failed to write initial structure to the RIB."); return -1; } if (rib_write(DIF_PATH, conf->dif_name, strlen(conf->dif_name) + 1) || rib_write(BOOT_PATH "/dt/const/addr_size", &conf->addr_size, sizeof(conf->addr_size)) || rib_write(BOOT_PATH "/dt/const/cep_id_size", &conf->cep_id_size, sizeof(conf->cep_id_size)) || rib_write(BOOT_PATH "/dt/const/seqno_size", &conf->seqno_size, sizeof(conf->seqno_size)) || rib_write(BOOT_PATH "/dt/const/has_ttl", &conf->has_ttl, sizeof(conf->has_ttl)) || rib_write(BOOT_PATH "/dt/const/has_chk", &conf->has_chk, sizeof(conf->has_chk)) || rib_write(BOOT_PATH "/dt/const/min_pdu_size", &conf->min_pdu_size, sizeof(conf->min_pdu_size)) || rib_write(BOOT_PATH "/dt/const/max_pdu_size", &conf->max_pdu_size, sizeof(conf->max_pdu_size)) || rib_write(BOOT_PATH "/dt/gam/type", &conf->dt_gam_type, sizeof(conf->dt_gam_type)) || rib_write(BOOT_PATH "/rm/gam/type", &conf->rm_gam_type, sizeof(conf->rm_gam_type)) || rib_write(BOOT_PATH "/addr_auth/type", &conf->addr_auth_type, sizeof(conf->addr_auth_type))) { log_err("Failed to write boot info to RIB."); pthread_rwlock_unlock(&ipcpi.state_lock); return -1; } if (boot_components()) { log_err("Failed to boot IPCP components."); pthread_rwlock_unlock(&ipcpi.state_lock); return -1; } pthread_rwlock_unlock(&ipcpi.state_lock); log_dbg("Bootstrapped in DIF %s.", conf->dif_name); return 0; } static struct ipcp_ops normal_ops = { .ipcp_bootstrap = normal_ipcp_bootstrap, .ipcp_enroll = normal_ipcp_enroll, .ipcp_name_reg = dir_name_reg, .ipcp_name_unreg = dir_name_unreg, .ipcp_name_query = dir_name_query, .ipcp_flow_alloc = fmgr_np1_alloc, .ipcp_flow_alloc_resp = fmgr_np1_alloc_resp, .ipcp_flow_dealloc = fmgr_np1_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, &normal_ops) < 0) { ipcp_create_r(getpid(), -1); exit(EXIT_FAILURE); } if (irm_bind_api(getpid(), ipcpi.name)) { log_err("Failed to bind AP name."); ipcp_create_r(getpid(), -1); ipcp_fini(); exit(EXIT_FAILURE); } if (rib_init()) { log_err("Failed to initialize RIB."); ipcp_create_r(getpid(), -1); irm_unbind_api(getpid(), ipcpi.name); ipcp_fini(); exit(EXIT_FAILURE); } if (connmgr_init()) { log_err("Failed to initialize connection manager."); ipcp_create_r(getpid(), -1); rib_fini(); irm_unbind_api(getpid(), ipcpi.name); ipcp_fini(); exit(EXIT_FAILURE); } if (enroll_init()) { log_err("Failed to initialize enroll component."); ipcp_create_r(getpid(), -1); connmgr_fini(); rib_fini(); irm_unbind_api(getpid(), ipcpi.name); 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); enroll_fini(); connmgr_fini(); rib_fini(); irm_unbind_api(getpid(), ipcpi.name); 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(); enroll_fini(); connmgr_fini(); rib_fini(); irm_unbind_api(getpid(), ipcpi.name); ipcp_fini(); exit(EXIT_FAILURE); } ipcp_shutdown(); if (ipcp_get_state() == IPCP_SHUTDOWN) shutdown_components(); rib_fini(); connmgr_fini(); enroll_fini(); irm_unbind_api(getpid(), ipcpi.name); ipcp_fini(); exit(EXIT_SUCCESS); }