/* * BIRD Internet Routing Daemon -- Protocols * * (c) 1998--2000 Martin Mares * * Can be freely distributed and used under the terms of the GNU GPL. */ #ifndef _BIRD_PROTOCOL_H_ #define _BIRD_PROTOCOL_H_ #include "lib/tlists.h" #include "lib/resource.h" #include "lib/event.h" #include "nest/iface.h" #include "lib/settle.h" #include "nest/rt.h" #include "nest/limit.h" #include "conf/conf.h" #include "filter/data.h" struct iface; struct ifa; struct rte; struct neighbor; struct rta; struct network; struct proto_config; struct channel_limit; struct channel_config; struct config; struct proto; struct channel; struct ea_list; struct eattr; struct symbol; /* * Routing Protocol */ enum protocol_startup { PROTOCOL_STARTUP_REGULAR = 0, /* Regular network routing protocol, start last */ PROTOCOL_STARTUP_GENERATOR = 1, /* Static route generator, start ahead of regulars */ PROTOCOL_STARTUP_CONNECTOR = 2, /* Data connector, start first */ PROTOCOL_STARTUP_NECESSARY = 3, /* Vital auxiliary data, start zeroth */ }; struct protocol { node n; char *name; char *template; /* Template for automatic generation of names */ int name_counter; /* Counter for automatic name generation */ uint preference; /* Default protocol preference */ enum protocol_startup startup; /* When to start / stop this protocol */ uint channel_mask; /* Mask of accepted channel types (NB_*) */ uint proto_size; /* Size of protocol data structure */ uint config_size; /* Size of protocol config data structure */ uint eattr_begin; /* First ID of registered eattrs */ uint eattr_end; /* End of eattr id zone */ void (*preconfig)(struct protocol *, struct config *); /* Just before configuring */ void (*postconfig)(struct proto_config *); /* After configuring each instance */ struct proto * (*init)(struct proto_config *); /* Create new instance */ int (*reconfigure)(struct proto *, struct proto_config *); /* Try to reconfigure instance, returns success */ void (*dump)(struct proto *); /* Debugging dump */ int (*start)(struct proto *); /* Start the instance */ int (*shutdown)(struct proto *); /* Stop the instance */ void (*cleanup)(struct proto *); /* Cleanup the instance right before tearing it all down */ void (*get_status)(struct proto *, byte *buf); /* Get instance status (for `show protocols' command) */ // int (*get_attr)(const struct eattr *, byte *buf, int buflen); /* ASCIIfy dynamic attribute (returns GA_*) */ void (*show_proto_info)(struct proto *); /* Show protocol info (for `show protocols all' command) */ void (*copy_config)(struct proto_config *, struct proto_config *); /* Copy config from given protocol instance */ }; void protos_build(void); /* Called from sysdep to initialize protocols */ void proto_build(struct protocol *); /* Called from protocol to register itself */ void protos_preconfig(struct config *); void protos_commit(struct config *new, struct config *old, int force_restart, int type); struct proto * proto_spawn(struct proto_config *cf, uint disabled); void protos_dump_all(void); #define GA_UNKNOWN 0 /* Attribute not recognized */ #define GA_NAME 1 /* Result = name */ #define GA_FULL 2 /* Result = both name and value */ /* * Known protocols */ extern struct protocol proto_device, proto_radv, proto_rip, proto_static, proto_mrt, proto_ospf, proto_perf, proto_pipe, proto_bgp, proto_bfd, proto_babel, proto_rpki; /* * Routing Protocol Instance */ struct proto_config { node n; struct config *global; /* Global configuration data */ struct protocol *protocol; /* Protocol */ struct proto *proto; /* Instance we've created */ struct proto_config *parent; /* Parent proto_config for dynamic protocols */ const char *name; const char *dsc; int class; /* SYM_PROTO or SYM_TEMPLATE */ u8 net_type; /* Protocol network type (NET_*), 0 for undefined */ u8 disabled; /* Protocol enabled/disabled by default */ u8 late_if_feed; /* Delay interface feed after channels are up */ u32 debug, mrtdump; /* Debugging bitfields, both use D_* constants */ u32 router_id; /* Protocol specific router ID */ uint loop_order; /* Launch a birdloop on this locking level; use DOMAIN_ORDER(the_bird) for mainloop */ btime loop_max_latency; /* Request this specific maximum latency of loop; zero to default */ list channels; /* List of channel configs (struct channel_config) */ struct iface *vrf; /* Related VRF instance, NULL if global */ /* Check proto_reconfigure() and proto_copy_config() after changing struct proto_config */ /* Protocol-specific data follow... */ }; #define TLIST_PREFIX proto #define TLIST_TYPE struct proto #define TLIST_ITEM n #define TLIST_WANT_WALK #define TLIST_WANT_ADD_TAIL #define TLIST_WANT_ADD_AFTER /* Protocol statistics */ struct proto { TLIST_DEFAULT_NODE; /* Node in global proto_list */ struct protocol *proto; /* Protocol */ struct proto_config *cf; /* Configuration data */ struct proto_config *cf_new; /* Configuration we want to switch to after shutdown (NULL=delete) */ pool *pool; /* Pool containing local objects */ pool *pool_fragile; /* Pool containing fragile local objects which need to be freed before the protocol's birdloop actually stops, like olocks */ event *event; /* Protocol event */ timer *restart_timer; /* Timer to restart the protocol from limits */ event *restart_event; /* Event to restart/shutdown the protocol from limits */ struct birdloop *loop; /* BIRDloop running this protocol */ list channels; /* List of channels to rtables (struct channel) */ struct channel *main_channel; /* Primary channel */ struct rte_src *main_source; /* Primary route source */ struct rte_owner sources; /* Route source owner structure */ struct iface *vrf; /* Related VRF instance, NULL if global */ TLIST_LIST(proto_neigh) neighbors; /* List of neighbor structures */ struct iface_subscription iface_sub; /* Interface notification subscription */ const char *name; /* Name of this instance (== cf->name) */ u32 debug; /* Debugging flags */ u32 mrtdump; /* MRTDump flags */ uint active_channels; /* Number of active channels */ uint active_loops; /* Number of active IO loops */ byte net_type; /* Protocol network type (NET_*), 0 for undefined */ byte disabled; /* Manually disabled */ byte proto_state; /* Protocol state machine (PS_*, see below) */ byte active; /* From PS_START to cleanup after PS_STOP */ byte do_stop; /* Stop actions are scheduled */ byte reconfiguring; /* We're shutting down due to reconfiguration */ byte gr_recovery; /* Protocol should participate in graceful restart recovery */ byte down_sched; /* Shutdown is scheduled for later (PDS_*) */ byte down_code; /* Reason for shutdown (PDC_* codes) */ u32 hash_key; /* Random key used for hashing of neighbors */ btime last_state_change; /* Time of last state transition */ char *last_state_name_announced; /* Last state name we've announced to the user */ char *message; /* State-change message, allocated from proto_pool */ /* * General protocol hooks: * * if_notify Notify protocol about interface state changes. * ifa_notify Notify protocol about interface address changes. * rt_notify Notify protocol about routing table updates. * neigh_notify Notify protocol about neighbor cache events. * preexport Called as the first step of the route exporting process. * It can decide whether the route shall be exported: * -1 = reject, * 0 = continue to export filter * 1 = accept immediately * reload_routes Request channel to reload all its routes to the core * (using rte_update()). Returns: 0=reload cannot be done, * 1= reload is scheduled and will happen (asynchronously). * feed_begin Notify channel about beginning of route feeding. * feed_end Notify channel about finish of route feeding. */ void (*rt_notify)(struct proto *, struct channel *, const net_addr *net, struct rte *new, const struct rte *old); int (*preexport)(struct channel *, struct rte *rt); void (*reload_routes)(struct channel *); void (*feed_begin)(struct channel *); void (*feed_end)(struct channel *); /* * Routing entry hooks (called only for routes belonging to this protocol): * * rte_recalculate Called at the beginning of the best route selection * rte_mergable Compare two rte's and decide whether they could be merged (1=yes, 0=no). * rte_insert Called whenever a rte is inserted to a routing table. * rte_remove Called whenever a rte is removed from the routing table. */ int (*rte_recalculate)(struct rtable_private *, struct network *, struct rte *, struct rte *, struct rte *); int (*rte_mergable)(struct rte *, struct rte *); void (*rte_insert)(struct network *, struct rte *); void (*rte_remove)(struct network *, struct rte *); u32 (*rte_igp_metric)(const struct rte *); /* Hic sunt protocol-specific data */ }; #include "lib/tlists.h" struct proto_spec { const void *ptr; int patt; }; #define PDS_DISABLE 1 /* Proto disable scheduled */ #define PDS_RESTART 2 /* Proto restart scheduled */ #define PDC_CF_REMOVE 0x01 /* Removed in new config */ #define PDC_CF_DISABLE 0x02 /* Disabled in new config */ #define PDC_CF_RESTART 0x03 /* Restart due to reconfiguration */ #define PDC_CMD_DISABLE 0x11 /* Result of disable command */ #define PDC_CMD_RESTART 0x12 /* Result of restart command */ #define PDC_CMD_SHUTDOWN 0x13 /* Result of global shutdown */ #define PDC_CMD_GR_DOWN 0x14 /* Result of global graceful restart */ #define PDC_RX_LIMIT_HIT 0x21 /* Route receive limit reached */ #define PDC_IN_LIMIT_HIT 0x22 /* Route import limit reached */ #define PDC_OUT_LIMIT_HIT 0x23 /* Route export limit reached */ void *proto_new(struct proto_config *); void *proto_config_new(struct protocol *, int class); void proto_copy_config(struct proto_config *dest, struct proto_config *src); void proto_clone_config(struct symbol *sym, struct proto_config *parent); void proto_set_message(struct proto *p, char *msg, int len); void graceful_restart_recovery(void); void graceful_restart_init(void); void graceful_restart_show_status(void); void channel_graceful_restart_lock(struct channel *c); void channel_graceful_restart_unlock(struct channel *c); #define DEFAULT_GR_WAIT 240 static inline event_list *proto_event_list(struct proto *p) { return p->loop == &main_birdloop ? &global_event_list : birdloop_event_list(p->loop); } static inline event_list *proto_work_list(struct proto *p) { return p->loop == &main_birdloop ? &global_work_list : birdloop_event_list(p->loop); } static inline void proto_send_event(struct proto *p, event *e) { ev_send(proto_event_list(p), e); } void channel_show_limit(struct limit *l, const char *dsc, int active, int action); void channel_show_info(struct channel *c); void channel_cmd_debug(struct channel *c, uint mask); void proto_cmd_show(struct proto *, uintptr_t, int); void proto_cmd_disable(struct proto *, uintptr_t, int); void proto_cmd_enable(struct proto *, uintptr_t, int); void proto_cmd_restart(struct proto *, uintptr_t, int); void proto_cmd_reload(struct proto *, uintptr_t, int); void proto_cmd_debug(struct proto *, uintptr_t, int); void proto_cmd_mrtdump(struct proto *, uintptr_t, int); void proto_apply_cmd(struct proto_spec ps, void (* cmd)(struct proto *, uintptr_t, int), int restricted, uintptr_t arg); struct proto *proto_get_named(struct symbol *, struct protocol *); struct proto *proto_iterate_named(struct symbol *sym, struct protocol *proto, struct proto *old); #define PROTO_WALK_CMD(sym,pr,p) for(struct proto *p = NULL; p = proto_iterate_named(sym, pr, p); ) #define PROTO_ENTER_FROM_MAIN(p) ({ \ ASSERT_DIE(birdloop_inside(&main_birdloop)); \ struct birdloop *_loop = (p)->loop; \ if (_loop != &main_birdloop) birdloop_enter(_loop); \ _loop; \ }) #define PROTO_LEAVE_FROM_MAIN(loop) ({ if (loop != &main_birdloop) birdloop_leave(loop); }) #define PROTO_LOCKED_FROM_MAIN(p) for (struct birdloop *_proto_loop = PROTO_ENTER_FROM_MAIN(p); _proto_loop; PROTO_LEAVE_FROM_MAIN(_proto_loop), (_proto_loop = NULL)) static inline struct domain_generic *proto_domain(struct proto *p) { return birdloop_domain(p->loop); } #define CMD_RELOAD 0 #define CMD_RELOAD_IN 1 #define CMD_RELOAD_OUT 2 static inline u32 proto_get_router_id(struct proto_config *pc) { return pc->router_id ? pc->router_id : pc->global->router_id; } extern pool *proto_pool; /* * Each protocol instance runs two different state machines: * * [P] The protocol machine: (implemented inside protocol) * * DOWN ----> START * ^ | * | V * STOP <---- UP * * States: DOWN Protocol is down and it's waiting for the core * requesting protocol start. * START Protocol is waiting for connection with the rest * of the network and it's not willing to accept * packets. When it connects, it goes to UP state. * UP Protocol is up and running. When the network * connection breaks down or the core requests * protocol to be terminated, it goes to STOP state. * STOP Protocol is disconnecting from the network. * After it disconnects, it returns to DOWN state. * * In: start() Called in DOWN state to request protocol startup. * Returns new state: either UP or START (in this * case, the protocol will notify the core when it * finally comes UP). * stop() Called in START, UP or STOP state to request * protocol shutdown. Returns new state: either * DOWN or STOP (in this case, the protocol will * notify the core when it finally comes DOWN). * * Out: proto_notify_state() -- called by protocol instance when * it does any state transition not covered by * return values of start() and stop(). This includes * START->UP (delayed protocol startup), UP->STOP * (spontaneous shutdown) and STOP->DOWN (delayed * shutdown). */ #define PS_DOWN 0 #define PS_START 1 #define PS_UP 2 #define PS_STOP 3 void proto_notify_state(struct proto *p, unsigned state); /* * [F] The feeder machine: (implemented in core routines) * * HUNGRY ----> FEEDING * ^ | * | V * FLUSHING <---- HAPPY * * States: HUNGRY Protocol either administratively down (i.e., * disabled by the user) or temporarily down * (i.e., [P] is not UP) * FEEDING The protocol came up and we're feeding it * initial routes. [P] is UP. * HAPPY The protocol is up and it's receiving normal * routing updates. [P] is UP. * FLUSHING The protocol is down and we're removing its * routes from the table. [P] is STOP or DOWN. * * Normal lifecycle of a protocol looks like: * * HUNGRY/DOWN --> HUNGRY/START --> HUNGRY/UP --> * FEEDING/UP --> HAPPY/UP --> FLUSHING/STOP|DOWN --> * HUNGRY/STOP|DOWN --> HUNGRY/DOWN * * Sometimes, protocol might switch from HAPPY/UP to FEEDING/UP * if it wants to refeed the routes (for example BGP does so * as a result of received ROUTE-REFRESH request). */ static inline int proto_is_inactive(struct proto *p) { return (p->active_channels == 0) && (p->active_loops == 0) && (p->sources.uc == 0) && EMPTY_TLIST(proto_neigh, &p->neighbors) ; } /* * Debugging flags */ #define D_STATES 1 /* [core] State transitions */ #define D_ROUTES 2 /* [core] Routes passed by the filters */ #define D_FILTERS 4 /* [core] Routes rejected by the filters */ #define D_IFACES 8 /* [core] Interface events */ #define D_EVENTS 16 /* Protocol events */ #define D_PACKETS 32 /* Packets sent/received */ #ifndef PARSER #define TRACE(flags, msg, args...) \ do { if (p->p.debug & flags) log(L_TRACE "%s: " msg, p->p.name , ## args ); } while(0) #endif /* * MRTDump flags */ #define MD_STATES 1 /* Protocol state changes (BGP4MP_MESSAGE_AS4) */ #define MD_MESSAGES 2 /* Protocol packets (BGP4MP_MESSAGE_AS4) */ /* * Known unique protocol instances as referenced by config routines */ extern struct proto_config *cf_dev_proto; /* * Protocol limits */ #define PLD_RX 0 /* Receive limit */ #define PLD_IN 1 /* Import limit */ #define PLD_OUT 2 /* Export limit */ #define PLD_MAX 3 #define PLA_NONE 0 /* No limit */ #define PLA_WARN 1 /* Issue log warning */ #define PLA_BLOCK 2 /* Block new routes */ #define PLA_RESTART 4 /* Force protocol restart */ #define PLA_DISABLE 5 /* Shutdown and disable protocol */ struct channel_limit { u32 limit; /* Maximum number of prefixes */ u8 action; /* Action to take (PLA_*) */ }; struct channel_limit_data { struct channel *c; int dir; }; #define CLP__RX(_c) (&(_c)->rx_limit) #define CLP__IN(_c) (&(_c)->in_limit) #define CLP__OUT(_c) (&(_c)->out_limit) #if 0 #define CHANNEL_LIMIT_LOG(_c, _dir, _op) log(L_TRACE "%s.%s: %s limit %s %u", (_c)->proto->name, (_c)->name, #_dir, _op, (CLP__##_dir(_c))->count) #else #define CHANNEL_LIMIT_LOG(_c, _dir, _op) #endif #define CHANNEL_LIMIT_PUSH(_c, _dir) ({ CHANNEL_LIMIT_LOG(_c, _dir, "push from"); struct channel_limit_data cld = { .c = (_c), .dir = PLD_##_dir }; limit_push(CLP__##_dir(_c), &cld); }) #define CHANNEL_LIMIT_POP(_c, _dir) ({ limit_pop(CLP__##_dir(_c)); CHANNEL_LIMIT_LOG(_c, _dir, "pop to"); }) /* * Channels */ struct channel_class { uint channel_size; /* Size of channel data structure */ uint config_size; /* Size of channel config data structure */ void (*init)(struct channel *, struct channel_config *); /* Create new instance */ int (*reconfigure)(struct channel *, struct channel_config *, int *import_changed, int *export_changed); /* Try to reconfigure instance, returns success */ int (*start)(struct channel *); /* Start the instance */ void (*shutdown)(struct channel *); /* Stop the instance */ void (*cleanup)(struct channel *); /* Channel finished flush */ void (*copy_config)(struct channel_config *, struct channel_config *); /* Copy config from given channel instance */ #if 0 XXXX; void (*preconfig)(struct protocol *, struct config *); /* Just before configuring */ void (*postconfig)(struct proto_config *); /* After configuring each instance */ void (*dump)(struct proto *); /* Debugging dump */ void (*get_status)(struct proto *, byte *buf); /* Get instance status (for `show protocols' command) */ void (*get_route_info)(struct rte *, byte *buf); /* Get route information (for `show route' command) */ int (*get_attr)(struct eattr *, byte *buf, int buflen); /* ASCIIfy dynamic attribute (returns GA_*) */ void (*show_proto_info)(struct proto *); /* Show protocol info (for `show protocols all' command) */ #endif }; extern struct channel_class channel_bgp; struct channel_config { node n; const char *name; const struct channel_class *class; struct proto_config *parent; /* Where channel is defined (proto or template) */ struct rtable_config *table; /* Table we're attached to */ const struct filter *in_filter, *out_filter; /* Attached filters */ const net_addr *out_subprefix; /* Export only subprefixes of this net */ struct channel_limit rx_limit; /* Limit for receiving routes from protocol (relevant when in_keep & RIK_REJECTED) */ struct channel_limit in_limit; /* Limit for importing routes from protocol */ struct channel_limit out_limit; /* Limit for exporting routes to protocol */ struct settle_config roa_settle; /* Settle times for ROA-induced reload */ uint feed_block_size; /* How many routes to feed at once */ u8 net_type; /* Routing table network type (NET_*), 0 for undefined */ u8 ra_mode; /* Mode of received route advertisements (RA_*) */ u16 preference; /* Default route preference */ u32 debug; /* Debugging flags (D_*) */ u8 copy; /* Value from channel_config_get() is new (0) or from template (1) */ u8 merge_limit; /* Maximal number of nexthops for RA_MERGED */ u8 in_keep; /* Which states of routes to keep (RIK_*) */ u8 rpki_reload; /* RPKI changes trigger channel reload */ }; struct channel { node n; /* Node in proto->channels */ const char *name; /* Channel name (may be NULL) */ const struct channel_class *class; struct proto *proto; rtable *table; const struct filter *in_filter; /* Input filter */ const struct filter *out_filter; /* Output filter */ const net_addr *out_subprefix; /* Export only subprefixes of this net */ struct bmap export_map; /* Keeps track which routes were really exported */ struct bmap export_reject_map; /* Keeps track which routes were rejected by export filter */ struct limit rx_limit; /* Receive limit (for in_keep & RIK_REJECTED) */ struct limit in_limit; /* Input limit */ struct limit out_limit; /* Output limit */ struct settle_config roa_settle; /* Settle times for ROA-induced reload */ u8 limit_actions[PLD_MAX]; /* Limit actions enum */ u8 limit_active; /* Flags for active limits */ struct channel_import_stats { /* Import - from protocol to core */ u32 updates_received; /* Number of route updates received */ u32 updates_invalid; /* Number of route updates rejected as invalid */ u32 updates_filtered; /* Number of route updates rejected by filters */ u32 updates_limited_rx; /* Number of route updates exceeding the rx_limit */ u32 updates_limited_in; /* Number of route updates exceeding the in_limit */ u32 withdraws_received; /* Number of route withdraws received */ u32 withdraws_invalid; /* Number of route withdraws rejected as invalid */ } import_stats; struct channel_export_stats { /* Export - from core to protocol */ u32 updates_rejected; /* Number of route updates rejected by protocol */ u32 updates_filtered; /* Number of route updates rejected by filters */ u32 updates_accepted; /* Number of route updates accepted and exported */ u32 updates_limited; /* Number of route updates exceeding the out_limit */ u32 withdraws_accepted; /* Number of route withdraws accepted and processed */ } export_stats; struct rt_import_request in_req; /* Table import connection */ struct rt_export_request out_req; /* Table export connection */ struct rt_export_request refeed_req; /* Auxiliary refeed request */ struct f_trie *refeed_trie; /* Auxiliary refeed trie */ struct channel_feeding_request *refeeding; /* Refeeding the channel */ struct channel_feeding_request *refeed_pending; /* Scheduled refeeds */ uint feed_block_size; /* How many routes to feed at once */ u8 net_type; /* Routing table network type (NET_*), 0 for undefined */ u8 ra_mode; /* Mode of received route advertisements (RA_*) */ u16 preference; /* Default route preference */ u32 debug; /* Debugging flags (D_*) */ u8 merge_limit; /* Maximal number of nexthops for RA_MERGED */ u8 in_keep; /* Which states of routes to keep (RIK_*) */ u8 disabled; u8 stale; /* Used in reconfiguration */ u8 channel_state; u8 reloadable; /* Hook reload_routes() is allowed on the channel */ u8 gr_lock; /* Graceful restart mechanism should wait for this channel */ u8 gr_wait; /* Route export to channel is postponed until graceful restart */ btime last_state_change; /* Time of last state transition */ struct rt_export_request reload_req; /* Feeder for import reload */ u8 reload_pending; /* Reloading and another reload is scheduled */ u8 rpki_reload; /* RPKI changes trigger channel reload */ struct rt_exporter *out_table; /* Internal table for exported routes */ list roa_subscriptions; /* List of active ROA table subscriptions based on filters' roa_check() calls */ }; #define RIK_REJECTED 1 /* Routes rejected in import filter are kept */ #define RIK_PREFILTER (2 | RIK_REJECTED) /* All routes' attribute state before import filter is kept */ /* * Channel states * * CS_DOWN - The initial and the final state of a channel. There is no route * exchange between the protocol and the table. Channel is not counted as * active. Channel keeps a ptr to the table, but do not lock the table and is * not linked in the table. Generally, new closed channels are created in * protocols' init() hooks. The protocol is expected to explicitly activate its * channels (by calling channel_init() or channel_open()). * * CS_START - The channel as a connection between the protocol and the table is * initialized (counted as active by the protocol, linked in the table and keeps * the table locked), but there is no current route exchange. There still may be * routes associated with the channel in the routing table if the channel falls * to CS_START from CS_UP. Generally, channels are initialized in protocols' * start() hooks when going to PS_START. * * CS_UP - The channel is initialized and the route exchange is allowed. Note * that even in CS_UP state, route export may still be down (ES_DOWN) by the * core decision (e.g. waiting for table convergence after graceful restart). * I.e., the protocol decides to open the channel but the core decides to start * route export. Route import (caused by rte_update() from the protocol) is not * restricted by that and is on volition of the protocol. Generally, channels * are opened in protocols' start() hooks when going to PS_UP. * * CS_STOP - The transitional state between initialized channel and closed * channel. The channel is still initialized, but no route exchange is allowed. * Instead, the associated table is running flush loop to remove routes imported * through the channel. After that, the channel changes state to CS_DOWN and * is detached from the table (the table is unlocked and the channel is unlinked * from it). Unlike other states, the CS_STOP state is not explicitly * entered or left by the protocol. A protocol may request to close a channel * (by calling channel_close()), which causes the channel to change state to * CS_STOP and later to CS_DOWN. Also note that channels are closed * automatically by the core when the protocol is going down. * * CS_PAUSE - Almost the same as CS_STOP, just the table import is kept and * the table export is stopped before transitioning to CS_START. * * Allowed transitions: * * CS_DOWN -> CS_START / CS_UP * CS_START -> CS_UP / CS_STOP * CS_UP -> CS_PAUSE / CS_STOP * CS_PAUSE -> CS_START (automatic) * CS_STOP -> CS_DOWN (automatic) */ #define CS_DOWN 0 #define CS_START 1 #define CS_UP 2 #define CS_STOP 3 #define CS_PAUSE 4 struct channel_config *proto_cf_find_channel(struct proto_config *p, uint net_type); static inline struct channel_config *proto_cf_main_channel(struct proto_config *pc) { return proto_cf_find_channel(pc, pc->net_type); } struct channel *proto_find_channel_by_table(struct proto *p, rtable *t); struct channel *proto_find_channel_by_name(struct proto *p, const char *n); struct channel *proto_add_channel(struct proto *p, struct channel_config *cf); int proto_configure_channel(struct proto *p, struct channel **c, struct channel_config *cf); void channel_set_state(struct channel *c, uint state); void channel_schedule_reload(struct channel *c); static inline void channel_init(struct channel *c) { channel_set_state(c, CS_START); } static inline void channel_open(struct channel *c) { channel_set_state(c, CS_UP); } static inline void channel_close(struct channel *c) { channel_set_state(c, CS_STOP); } struct channel_feeding_request { struct channel_feeding_request *next; /* Next in request chain */ void (*done)(struct channel_feeding_request *); /* Called when refeed finishes */ PACKED enum channel_feeding_request_type { CFRT_DIRECT = 1, /* Refeed by export restart */ CFRT_AUXILIARY, /* Refeed by auxiliary request */ } type; PACKED enum { CFRS_INACTIVE = 0, /* Inactive request */ CFRS_PENDING, /* Request enqueued, do not touch */ CFRS_RUNNING, /* Request active, do not touch */ } state; }; struct channel *channel_from_export_request(struct rt_export_request *req); void channel_request_feeding(struct channel *c, struct channel_feeding_request *); void channel_request_feeding_dynamic(struct channel *c, enum channel_feeding_request_type); static inline int channel_net_is_refeeding(struct channel *c, const net_addr *n) { return (c->refeeding && c->refeed_trie && !trie_match_net(c->refeed_trie, n)); } static inline void channel_net_mark_refed(struct channel *c, const net_addr *n) { ASSERT_DIE(c->refeeding && c->refeed_trie); trie_add_prefix(c->refeed_trie, n, n->pxlen, n->pxlen); } void *channel_config_new(const struct channel_class *cc, const char *name, uint net_type, struct proto_config *proto); void *channel_config_get(const struct channel_class *cc, const char *name, uint net_type, struct proto_config *proto); int channel_reconfigure(struct channel *c, struct channel_config *cf); #endif