/* * BIRD Internet Routing Daemon -- Configuration File Handling * * (c) 1998--2000 Martin Mares * * Can be freely distributed and used under the terms of the GNU GPL. */ /** * DOC: Configuration manager * * Configuration of BIRD is complex, yet straightforward. There are three * modules taking care of the configuration: config manager (which takes care * of storage of the config information and controls switching between configs), * lexical analyzer and parser. * * The configuration manager stores each config as a &config structure * accompanied by a linear pool from which all information associated * with the config and pointed to by the &config structure is allocated. * * There can exist up to four different configurations at one time: an active * one (pointed to by @config), configuration we are just switching from * (@old_config), one queued for the next reconfiguration (@future_config; if * there is one and the user wants to reconfigure once again, we just free the * previous queued config and replace it with the new one) and finally a config * being parsed (@new_config). The stored @old_config is also used for undo * reconfiguration, which works in a similar way. Reconfiguration could also * have timeout (using @config_timer) and undo is automatically called if the * new configuration is not confirmed later. The new config (@new_config) and * associated linear pool (@cfg_mem) is non-NULL only during parsing. * * Loading of new configuration is very simple: just call config_alloc() to get * a new &config structure, then use config_parse() to parse a configuration * file and fill all fields of the structure and finally ask the config manager * to switch to the new config by calling config_commit(). * * CLI commands are parsed in a very similar way -- there is also a stripped-down * &config structure associated with them and they are lex-ed and parsed by the * same functions, only a special fake token is prepended before the command * text to make the parser recognize only the rules corresponding to CLI commands. */ #include #include #undef LOCAL_DEBUG #include "nest/bird.h" #include "nest/route.h" #include "nest/protocol.h" #include "nest/iface.h" #include "lib/resource.h" #include "lib/string.h" #include "lib/event.h" #include "lib/timer.h" #include "conf/conf.h" #include "conf/parser.h" #include "filter/filter.h" struct config *config, *new_config; static struct config *old_config; /* Old configuration */ static struct config *future_config; /* New config held here if recon requested during recon */ static int old_cftype; /* Type of transition old_config -> config (RECONFIG_SOFT/HARD) */ static int future_cftype; /* Type of scheduled transition, may also be RECONFIG_UNDO */ /* Note that when future_cftype is RECONFIG_UNDO, then future_config is NULL, therefore proper check for future scheduled config checks future_cftype */ static event *config_event; /* Event for finalizing reconfiguration */ static timer *config_timer; /* Timer for scheduled configuration rollback */ /* These are public just for cmd_show_status(), should not be accessed elsewhere */ int shutting_down; /* Shutdown requested, do not accept new config changes */ int configuring; /* Reconfiguration is running */ int undo_available; /* Undo was not requested from last reconfiguration */ /* Note that both shutting_down and undo_available are related to requests, not processing */ /** * config_alloc - allocate a new configuration * @name: name of the config * * This function creates new &config structure, attaches a resource * pool and a linear memory pool to it and makes it available for * further use. Returns a pointer to the structure. */ static struct config * config_alloc(struct pool *pp, struct linpool *lp) { pool *p = rp_new(pp ?: &root_pool, "Config"); linpool *l = lp ?: lp_new_default(p); struct config *c = lp_allocz(l, sizeof(struct config)); init_list(&c->tests); c->mrtdump_file = -1; /* Hack, this should be sysdep-specific */ c->pool = p; c->mem = l; c->load_time = current_time(); c->tf_route = c->tf_proto = TM_ISO_SHORT_MS; c->tf_base = c->tf_log = TM_ISO_LONG_MS; c->gr_wait = DEFAULT_GR_WAIT; return c; } int config_parse(struct conf_order *order) { DBG("Parsing configuration named `%s'\n", order->state->name); if (!order->new_config) order->new_config = config_alloc(order->pool, order->lp); struct cf_context *ctx = cf_new_context(0, order); int ret; if (setjmp(ctx->jmpbuf)) { if (order->cf_outclude) while (! order->cf_outclude(order)) ; ret = 0; config_free(ctx->new_config); order->new_config = NULL; goto cleanup; } sysdep_preconfig(ctx); protos_preconfig(ctx->new_config); rt_preconfig(ctx); cfx_parse(ctx, ctx->yyscanner); if (EMPTY_LIST((ctx->new_config)->protos)) cf_error(ctx, "No protocol is specified in the config file"); ret = 1; cleanup: cf_free_context(ctx); order->ctx = NULL; return ret; } int cli_parse(struct conf_order *order) { DBG("Parsing command line\n"); struct config cc = {}; cc.pool = rp_new(order->pool ?: &root_pool, "CLI Dummy Config"); cc.mem = order->lp ?: lp_new_default(cc.pool); order->new_config = &cc; struct cf_context *ctx = cf_new_context(1, order); int ok = 0; if (setjmp(ctx->jmpbuf)) goto done; cfx_parse(ctx, ctx->yyscanner); ok = 1; done: cf_free_context(ctx); config_free(&cc); order->new_config = NULL; order->ctx = NULL; return ok; } /** * config_free - free a configuration * @c: configuration to be freed * * This function takes a &config structure and frees all resources * associated with it. */ void config_free(struct config *c) { if (c) rfree(c->pool); } void config_add_obstacle(struct config *c) { DBG("+++ adding obstacle %d\n", c->obstacle_count); c->obstacle_count++; } void config_del_obstacle(struct config *c) { DBG("+++ deleting obstacle %d\n", c->obstacle_count); c->obstacle_count--; if (!c->obstacle_count) ev_schedule(config_event); } static int global_commit(struct config *new, struct config *old) { if (!old) return 0; if (!new->router_id) { new->router_id = old->router_id; if (new->router_id_from) { u32 id = if_choose_router_id(new->router_id_from, old->router_id); if (!id) log(L_WARN "Cannot determine router ID, using old one"); else new->router_id = id; } } return 0; } static int config_do_commit(struct config *c, int type) { if (type == RECONFIG_UNDO) { c = old_config; type = old_cftype; } else config_free(old_config); old_config = config; old_cftype = type; config = c; configuring = 1; if (old_config && !config->shutdown) log(L_INFO "Reconfiguring"); if (old_config) old_config->obstacle_count++; DBG("sysdep_commit\n"); int force_restart = sysdep_commit(c, old_config); DBG("global_commit\n"); force_restart |= global_commit(c, old_config); DBG("rt_commit\n"); rt_commit(c, old_config); DBG("protos_commit\n"); protos_commit(c, old_config, force_restart, type); int obs = 0; if (old_config) obs = --old_config->obstacle_count; DBG("do_commit finished with %d obstacles remaining\n", obs); return !obs; } static void config_done(void *unused UNUSED) { if (config->shutdown) sysdep_shutdown_done(); configuring = 0; if (old_config) log(L_INFO "Reconfigured"); if (future_cftype) { int type = future_cftype; struct config *conf = future_config; future_cftype = RECONFIG_NONE; future_config = NULL; log(L_INFO "Reconfiguring to queued configuration"); if (config_do_commit(conf, type)) config_done(NULL); } } /** * config_commit - commit a configuration * @c: new configuration * @type: type of reconfiguration (RECONFIG_SOFT or RECONFIG_HARD) * @timeout: timeout for undo (in seconds; or 0 for no timeout) * * When a configuration is parsed and prepared for use, the * config_commit() function starts the process of reconfiguration. * It checks whether there is already a reconfiguration in progress * in which case it just queues the new config for later processing. * Else it notifies all modules about the new configuration by calling * their commit() functions which can either accept it immediately * or call config_add_obstacle() to report that they need some time * to complete the reconfiguration. After all such obstacles are removed * using config_del_obstacle(), the old configuration is freed and * everything runs according to the new one. * * When @timeout is nonzero, the undo timer is activated with given * timeout. The timer is deactivated when config_commit(), * config_confirm() or config_undo() is called. * * Result: %CONF_DONE if the configuration has been accepted immediately, * %CONF_PROGRESS if it will take some time to switch to it, %CONF_QUEUED * if it's been queued due to another reconfiguration being in progress now * or %CONF_SHUTDOWN if BIRD is in shutdown mode and no new configurations * are accepted. */ int config_commit(struct config *c, int type, uint timeout) { if (shutting_down) { config_free(c); return CONF_SHUTDOWN; } undo_available = 1; if (timeout) tm_start(config_timer, timeout S); else tm_stop(config_timer); if (configuring) { if (future_cftype) { log(L_INFO "Queueing new configuration, ignoring the one already queued"); config_free(future_config); } else log(L_INFO "Queueing new configuration"); future_cftype = type; future_config = c; return CONF_QUEUED; } if (config_do_commit(c, type)) { config_done(NULL); return CONF_DONE; } return CONF_PROGRESS; } /** * config_confirm - confirm a commited configuration * * When the undo timer is activated by config_commit() with nonzero timeout, * this function can be used to deactivate it and therefore confirm * the current configuration. * * Result: %CONF_CONFIRM when the current configuration is confirmed, * %CONF_NONE when there is nothing to confirm (i.e. undo timer is not active). */ int config_confirm(void) { if (config_timer->expires == 0) return CONF_NOTHING; tm_stop(config_timer); return CONF_CONFIRM; } /** * config_undo - undo a configuration * * Function config_undo() can be used to change the current * configuration back to stored %old_config. If no reconfiguration is * running, this stored configuration is commited in the same way as a * new configuration in config_commit(). If there is already a * reconfiguration in progress and no next reconfiguration is * scheduled, then the undo is scheduled for later processing as * usual, but if another reconfiguration is already scheduled, then * such reconfiguration is removed instead (i.e. undo is applied on * the last commit that scheduled it). * * Result: %CONF_DONE if the configuration has been accepted immediately, * %CONF_PROGRESS if it will take some time to switch to it, %CONF_QUEUED * if it's been queued due to another reconfiguration being in progress now, * %CONF_UNQUEUED if a scheduled reconfiguration is removed, %CONF_NOTHING * if there is no relevant configuration to undo (the previous config request * was config_undo() too) or %CONF_SHUTDOWN if BIRD is in shutdown mode and * no new configuration changes are accepted. */ int config_undo(void) { if (shutting_down) return CONF_SHUTDOWN; if (!undo_available || !old_config) return CONF_NOTHING; undo_available = 0; tm_stop(config_timer); if (configuring) { if (future_cftype) { config_free(future_config); future_config = NULL; log(L_INFO "Removing queued configuration"); future_cftype = RECONFIG_NONE; return CONF_UNQUEUED; } else { log(L_INFO "Queueing undo configuration"); future_cftype = RECONFIG_UNDO; return CONF_QUEUED; } } if (config_do_commit(NULL, RECONFIG_UNDO)) { config_done(NULL); return CONF_DONE; } return CONF_PROGRESS; } extern void cmd_reconfig_undo_notify(void); static void config_timeout(timer *t UNUSED) { log(L_INFO "Config timeout expired, starting undo"); cmd_reconfig_undo_notify(); int r = config_undo(); if (r < 0) log(L_ERR "Undo request failed"); } void config_init(void) { config_event = ev_new(&root_pool); config_event->hook = config_done; config_timer = tm_new(&root_pool); config_timer->hook = config_timeout; cf_init_kh(); } /** * order_shutdown - order BIRD shutdown * * This function initiates shutdown of BIRD. It's accomplished by asking * for switching to an empty configuration. */ void order_shutdown(void) { struct config *c; if (shutting_down) return; log(L_INFO "Shutting down"); c = lp_alloc(config->mem, sizeof(struct config)); memcpy(c, config, sizeof(struct config)); init_list(&c->protos); init_list(&c->tables); c->shutdown = 1; config_commit(c, RECONFIG_HARD, 0); shutting_down = 1; } /** * cf_error - report a configuration error * @msg: printf-like format string * * cf_error() can be called during execution of config_parse(), that is * from the parser, a preconfig hook or a postconfig hook, to report an * error in the configuration. */ void cf_error(struct cf_context *ctx, const char *msg, ...) { va_list args; va_start(args, msg); ctx->order->cf_error(ctx->order, msg, args); va_end(args); longjmp(ctx->jmpbuf, 1); } #if 0 if (bvsnprintf(ctx->order->err.msg, CONF_ERROR_MSG_LEN, msg, args) < 0) strcpy(ctx->order->err.msg, ""); ctx->order->err.lino = ctx->order->state->lino; uint fnlen = strlen(ctx->order->state->name); if (fnlen >= CONF_FILENAME_LEN) { uint l = (CONF_FILENAME_LEN - 6) / 2; uint r = CONF_FILENAME_LEN - 6 - l; memcpy(ctx->order->err.file_name, ctx->order->state->name, l); memcpy(ctx->order->err.file_name + l, " ... ", 5); strncpy(ctx->order->err.file_name + l + 5, ctx->order->state->name + fnlen - r, r); } else memcpy(ctx->order->err.file_name, ctx->order->state->name, fnlen + 1); } #endif void *cf_alloc(struct cf_context *ctx, unsigned size) { return cfg_alloc(size); } void *cf_allocu(struct cf_context *ctx, unsigned size) { return cfg_allocu(size); } void *cf_allocz(struct cf_context *ctx, unsigned size) { return cfg_allocz(size); } /** * cfg_strdup - copy a string to config memory * @c: string to copy * * cfg_strdup() creates a new copy of the string in the memory * pool associated with the configuration being currently parsed. * It's often used when a string literal occurs in the configuration * and we want to preserve it for further use. */ char * cf_strdup(struct cf_context *ctx, const char *c) { int l = strlen(c) + 1; char *z = cfg_allocu(l); memcpy(z, c, l); return z; } void cf_copy_list(struct cf_context *ctx, list *dest, list *src, unsigned node_size) { node *dn, *sn; init_list(dest); WALK_LIST(sn, *src) { dn = cfg_alloc(node_size); memcpy(dn, sn, node_size); add_tail(dest, dn); } }