/*- * Copyright (c) 2001-2008, by Cisco Systems, Inc. All rights reserved. * Copyright (c) 2008-2011, by Randall Stewart. All rights reserved. * Copyright (c) 2008-2011, by Michael Tuexen. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * a) Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * b) 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. * * c) Neither the name of Cisco Systems, Inc. nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ /* $KAME: sctp_structs.h,v 1.13 2005/03/06 16:04:18 itojun Exp $ */ #include __FBSDID("$FreeBSD$"); #ifndef __sctp_structs_h__ #define __sctp_structs_h__ #include #include #include struct sctp_timer { sctp_os_timer_t timer; int type; /* * Depending on the timer type these will be setup and cast with the * appropriate entity. */ void *ep; void *tcb; void *net; void *vnet; /* for sanity checking */ void *self; uint32_t ticks; uint32_t stopped_from; }; struct sctp_foo_stuff { struct sctp_inpcb *inp; uint32_t lineno; uint32_t ticks; int updown; }; /* * This is the information we track on each interface that we know about from * the distant end. */ TAILQ_HEAD(sctpnetlisthead, sctp_nets); struct sctp_stream_reset_list { TAILQ_ENTRY(sctp_stream_reset_list) next_resp; uint32_t tsn; int number_entries; struct sctp_stream_reset_out_request req; }; TAILQ_HEAD(sctp_resethead, sctp_stream_reset_list); /* * Users of the iterator need to malloc a iterator with a call to * sctp_initiate_iterator(inp_func, assoc_func, inp_func, pcb_flags, pcb_features, * asoc_state, void-ptr-arg, uint32-arg, end_func, inp); * * Use the following two defines if you don't care what pcb flags are on the EP * and/or you don't care what state the association is in. * * Note that if you specify an INP as the last argument then ONLY each * association of that single INP will be executed upon. Note that the pcb * flags STILL apply so if the inp you specify has different pcb_flags then * what you put in pcb_flags nothing will happen. use SCTP_PCB_ANY_FLAGS to * assure the inp you specify gets treated. */ #define SCTP_PCB_ANY_FLAGS 0x00000000 #define SCTP_PCB_ANY_FEATURES 0x00000000 #define SCTP_ASOC_ANY_STATE 0x00000000 typedef void (*asoc_func) (struct sctp_inpcb *, struct sctp_tcb *, void *ptr, uint32_t val); typedef int (*inp_func) (struct sctp_inpcb *, void *ptr, uint32_t val); typedef void (*end_func) (void *ptr, uint32_t val); #if defined(__FreeBSD__) && defined(SCTP_MCORE_INPUT) && defined(SMP) /* whats on the mcore control struct */ struct sctp_mcore_queue { TAILQ_ENTRY(sctp_mcore_queue) next; struct vnet *vn; struct mbuf *m; int off; int v6; }; TAILQ_HEAD(sctp_mcore_qhead, sctp_mcore_queue); struct sctp_mcore_ctrl { SCTP_PROCESS_STRUCT thread_proc; struct sctp_mcore_qhead que; struct mtx core_mtx; struct mtx que_mtx; int running; int cpuid; }; #endif struct sctp_iterator { TAILQ_ENTRY(sctp_iterator) sctp_nxt_itr; struct vnet *vn; struct sctp_timer tmr; struct sctp_inpcb *inp; /* current endpoint */ struct sctp_tcb *stcb; /* current* assoc */ struct sctp_inpcb *next_inp; /* special hook to skip to */ asoc_func function_assoc; /* per assoc function */ inp_func function_inp; /* per endpoint function */ inp_func function_inp_end; /* end INP function */ end_func function_atend;/* iterator completion function */ void *pointer; /* pointer for apply func to use */ uint32_t val; /* value for apply func to use */ uint32_t pcb_flags; /* endpoint flags being checked */ uint32_t pcb_features; /* endpoint features being checked */ uint32_t asoc_state; /* assoc state being checked */ uint32_t iterator_flags; uint8_t no_chunk_output; uint8_t done_current_ep; }; /* iterator_flags values */ #define SCTP_ITERATOR_DO_ALL_INP 0x00000001 #define SCTP_ITERATOR_DO_SINGLE_INP 0x00000002 TAILQ_HEAD(sctpiterators, sctp_iterator); struct sctp_copy_all { struct sctp_inpcb *inp; /* ep */ struct mbuf *m; struct sctp_sndrcvinfo sndrcv; int sndlen; int cnt_sent; int cnt_failed; }; struct sctp_asconf_iterator { struct sctpladdr list_of_work; int cnt; }; struct iterator_control { struct mtx ipi_iterator_wq_mtx; struct mtx it_mtx; SCTP_PROCESS_STRUCT thread_proc; struct sctpiterators iteratorhead; struct sctp_iterator *cur_it; uint32_t iterator_running; uint32_t iterator_flags; }; #define SCTP_ITERATOR_MUST_EXIT 0x00000001 #define SCTP_ITERATOR_STOP_CUR_IT 0x00000002 #define SCTP_ITERATOR_STOP_CUR_INP 0x00000004 struct sctp_net_route { sctp_rtentry_t *ro_rt; void *ro_lle; union sctp_sockstore _l_addr; /* remote peer addr */ struct sctp_ifa *_s_addr; /* our selected src addr */ }; struct htcp { uint16_t alpha; /* Fixed point arith, << 7 */ uint8_t beta; /* Fixed point arith, << 7 */ uint8_t modeswitch; /* Delay modeswitch until we had at least one * congestion event */ uint32_t last_cong; /* Time since last congestion event end */ uint32_t undo_last_cong; uint16_t bytes_acked; uint32_t bytecount; uint32_t minRTT; uint32_t maxRTT; uint32_t undo_maxRTT; uint32_t undo_old_maxB; /* Bandwidth estimation */ uint32_t minB; uint32_t maxB; uint32_t old_maxB; uint32_t Bi; uint32_t lasttime; }; struct rtcc_cc { struct timeval tls; /* The time we started the sending */ uint64_t lbw; /* Our last estimated bw */ uint64_t lbw_rtt; /* RTT at bw estimate */ uint64_t bw_bytes; /* The total bytes since this sending began */ uint64_t bw_tot_time; /* The total time since sending began */ uint64_t new_tot_time; /* temp holding the new value */ uint32_t cwnd_at_bw_set; uint8_t ret_from_eq; uint8_t use_dccc_ecn; uint8_t tls_needs_set; /* Flag to indicate we need to set tls 0 or 1 * means set at send 2 not */ }; struct sctp_nets { TAILQ_ENTRY(sctp_nets) sctp_next; /* next link */ /* * Things on the top half may be able to be split into a common * structure shared by all. */ struct sctp_timer pmtu_timer; /* * The following two in combination equate to a route entry for v6 * or v4. */ struct sctp_net_route ro; /* mtu discovered so far */ uint32_t mtu; uint32_t ssthresh; /* not sure about this one for split */ uint32_t last_cwr_tsn; uint32_t cwr_window_tsn; uint32_t ecn_ce_pkt_cnt; uint32_t lost_cnt; /* smoothed average things for RTT and RTO itself */ int lastsa; int lastsv; uint64_t rtt; /* last measured rtt value in us */ unsigned int RTO; /* This is used for SHUTDOWN/SHUTDOWN-ACK/SEND or INIT timers */ struct sctp_timer rxt_timer; struct sctp_timer fr_timer; /* for early fr */ /* last time in seconds I sent to it */ struct timeval last_sent_time; union cc_control_data { struct htcp htcp_ca; /* JRS - struct used in HTCP algorithm */ struct rtcc_cc rtcc; /* rtcc module cc stuff */ } cc_mod; int ref_count; /* Congestion stats per destination */ /* * flight size variables and such, sorry Vern, I could not avoid * this if I wanted performance :> */ uint32_t flight_size; uint32_t cwnd; /* actual cwnd */ uint32_t prev_cwnd; /* cwnd before any processing */ uint32_t ecn_prev_cwnd; /* ECN prev cwnd at first ecn_echo seen in new * window */ uint32_t partial_bytes_acked; /* in CA tracks when to incr a MTU */ /* tracking variables to avoid the aloc/free in sack processing */ unsigned int net_ack; unsigned int net_ack2; /* * JRS - 5/8/07 - Variable to track last time a destination was * active for CMT PF */ uint32_t last_active; /* * CMT variables (iyengar@cis.udel.edu) */ uint32_t this_sack_highest_newack; /* tracks highest TSN newly * acked for a given dest in * the current SACK. Used in * SFR and HTNA algos */ uint32_t pseudo_cumack; /* CMT CUC algorithm. Maintains next expected * pseudo-cumack for this destination */ uint32_t rtx_pseudo_cumack; /* CMT CUC algorithm. Maintains next * expected pseudo-cumack for this * destination */ /* CMT fast recovery variables */ uint32_t fast_recovery_tsn; uint32_t heartbeat_random1; uint32_t heartbeat_random2; uint32_t tos_flowlabel; struct timeval start_time; /* time when this net was created */ uint32_t marked_retrans;/* number or DATA chunks marked for timer * based retransmissions */ uint32_t marked_fastretrans; /* if this guy is ok or not ... status */ uint16_t dest_state; /* number of transmit failures to down this guy */ uint16_t failure_threshold; /* error stats on destination */ uint16_t error_count; /* UDP port number in case of UDP tunneling */ uint16_t port; uint8_t fast_retran_loss_recovery; uint8_t will_exit_fast_recovery; /* Flags that probably can be combined into dest_state */ uint8_t fast_retran_ip; /* fast retransmit in progress */ uint8_t hb_responded; uint8_t saw_newack; /* CMT's SFR algorithm flag */ uint8_t src_addr_selected; /* if we split we move */ uint8_t indx_of_eligible_next_to_use; uint8_t addr_is_local; /* its a local address (if known) could move * in split */ /* * CMT variables (iyengar@cis.udel.edu) */ uint8_t find_pseudo_cumack; /* CMT CUC algorithm. Flag used to * find a new pseudocumack. This flag * is set after a new pseudo-cumack * has been received and indicates * that the sender should find the * next pseudo-cumack expected for * this destination */ uint8_t find_rtx_pseudo_cumack; /* CMT CUCv2 algorithm. Flag used to * find a new rtx-pseudocumack. This * flag is set after a new * rtx-pseudo-cumack has been received * and indicates that the sender * should find the next * rtx-pseudo-cumack expected for this * destination */ uint8_t new_pseudo_cumack; /* CMT CUC algorithm. Flag used to * indicate if a new pseudo-cumack or * rtx-pseudo-cumack has been received */ uint8_t window_probe; /* Doing a window probe? */ uint8_t RTO_measured; /* Have we done the first measure */ uint8_t last_hs_used; /* index into the last HS table entry we used */ uint8_t lan_type; uint32_t flowid; #ifdef INVARIANTS uint8_t flowidset; #endif }; struct sctp_data_chunkrec { uint32_t TSN_seq; /* the TSN of this transmit */ uint16_t stream_seq; /* the stream sequence number of this transmit */ uint16_t stream_number; /* the stream number of this guy */ uint32_t payloadtype; uint32_t context; /* from send */ uint32_t cwnd_at_send; /* * part of the Highest sacked algorithm to be able to stroke counts * on ones that are FR'd. */ uint32_t fast_retran_tsn; /* sending_seq at the time of FR */ struct timeval timetodrop; /* time we drop it from queue */ uint8_t doing_fast_retransmit; uint8_t rcv_flags; /* flags pulled from data chunk on inbound for * outbound holds sending flags for PR-SCTP. */ uint8_t state_flags; uint8_t chunk_was_revoked; uint8_t fwd_tsn_cnt; }; TAILQ_HEAD(sctpchunk_listhead, sctp_tmit_chunk); /* The lower byte is used to enumerate PR_SCTP policies */ #define CHUNK_FLAGS_PR_SCTP_TTL SCTP_PR_SCTP_TTL #define CHUNK_FLAGS_PR_SCTP_BUF SCTP_PR_SCTP_BUF #define CHUNK_FLAGS_PR_SCTP_RTX SCTP_PR_SCTP_RTX /* The upper byte is used a a bit mask */ #define CHUNK_FLAGS_FRAGMENT_OK 0x0100 struct chk_id { uint16_t id; uint16_t can_take_data; }; struct sctp_tmit_chunk { union { struct sctp_data_chunkrec data; struct chk_id chunk_id; } rec; struct sctp_association *asoc; /* bp to asoc this belongs to */ struct timeval sent_rcv_time; /* filled in if RTT being calculated */ struct mbuf *data; /* pointer to mbuf chain of data */ struct mbuf *last_mbuf; /* pointer to last mbuf in chain */ struct sctp_nets *whoTo; TAILQ_ENTRY(sctp_tmit_chunk) sctp_next; /* next link */ int32_t sent; /* the send status */ uint16_t snd_count; /* number of times I sent */ uint16_t flags; /* flags, such as FRAGMENT_OK */ uint16_t send_size; uint16_t book_size; uint16_t mbcnt; uint16_t auth_keyid; uint8_t holds_key_ref; /* flag if auth keyid refcount is held */ uint8_t pad_inplace; uint8_t do_rtt; uint8_t book_size_scale; uint8_t no_fr_allowed; uint8_t pr_sctp_on; uint8_t copy_by_ref; uint8_t window_probe; }; /* * The first part of this structure MUST be the entire sinfo structure. Maybe * I should have made it a sub structure... we can circle back later and do * that if we want. */ struct sctp_queued_to_read { /* sinfo structure Pluse more */ uint16_t sinfo_stream; /* off the wire */ uint16_t sinfo_ssn; /* off the wire */ uint16_t sinfo_flags; /* SCTP_UNORDERED from wire use SCTP_EOF for * EOR */ uint32_t sinfo_ppid; /* off the wire */ uint32_t sinfo_context; /* pick this up from assoc def context? */ uint32_t sinfo_timetolive; /* not used by kernel */ uint32_t sinfo_tsn; /* Use this in reassembly as first TSN */ uint32_t sinfo_cumtsn; /* Use this in reassembly as last TSN */ sctp_assoc_t sinfo_assoc_id; /* our assoc id */ /* Non sinfo stuff */ uint32_t length; /* length of data */ uint32_t held_length; /* length held in sb */ struct sctp_nets *whoFrom; /* where it came from */ struct mbuf *data; /* front of the mbuf chain of data with * PKT_HDR */ struct mbuf *tail_mbuf; /* used for multi-part data */ struct mbuf *aux_data; /* used to hold/cache control if o/s does not * take it from us */ struct sctp_tcb *stcb; /* assoc, used for window update */ TAILQ_ENTRY(sctp_queued_to_read) next; uint16_t port_from; uint16_t spec_flags; /* Flags to hold the notification field */ uint8_t do_not_ref_stcb; uint8_t end_added; uint8_t pdapi_aborted; uint8_t some_taken; }; /* This data structure will be on the outbound * stream queues. Data will be pulled off from * the front of the mbuf data and chunk-ified * by the output routines. We will custom * fit every chunk we pull to the send/sent * queue to make up the next full packet * if we can. An entry cannot be removed * from the stream_out queue until * the msg_is_complete flag is set. This * means at times data/tail_mbuf MIGHT * be NULL.. If that occurs it happens * for one of two reasons. Either the user * is blocked on a send() call and has not * awoken to copy more data down... OR * the user is in the explict MSG_EOR mode * and wrote some data, but has not completed * sending. */ struct sctp_stream_queue_pending { struct mbuf *data; struct mbuf *tail_mbuf; struct timeval ts; struct sctp_nets *net; TAILQ_ENTRY(sctp_stream_queue_pending) next; TAILQ_ENTRY(sctp_stream_queue_pending) ss_next; uint32_t length; uint32_t timetolive; uint32_t ppid; uint32_t context; uint16_t sinfo_flags; uint16_t stream; uint16_t strseq; uint16_t act_flags; uint16_t auth_keyid; uint8_t holds_key_ref; uint8_t msg_is_complete; uint8_t some_taken; uint8_t pr_sctp_on; uint8_t sender_all_done; uint8_t put_last_out; uint8_t discard_rest; }; /* * this struct contains info that is used to track inbound stream data and * help with ordering. */ TAILQ_HEAD(sctpwheelunrel_listhead, sctp_stream_in); struct sctp_stream_in { struct sctp_readhead inqueue; uint16_t stream_no; uint16_t last_sequence_delivered; /* used for re-order */ uint8_t delivery_started; }; TAILQ_HEAD(sctpwheel_listhead, sctp_stream_out); TAILQ_HEAD(sctplist_listhead, sctp_stream_queue_pending); /* Round-robin schedulers */ struct ss_rr { /* next link in wheel */ TAILQ_ENTRY(sctp_stream_out) next_spoke; }; /* Priority scheduler */ struct ss_prio { /* next link in wheel */ TAILQ_ENTRY(sctp_stream_out) next_spoke; /* priority id */ uint16_t priority; }; /* Fair Bandwidth scheduler */ struct ss_fb { /* next link in wheel */ TAILQ_ENTRY(sctp_stream_out) next_spoke; /* stores message size */ int32_t rounds; }; /* * This union holds all data necessary for * different stream schedulers. */ union scheduling_data { struct sctpwheel_listhead out_wheel; struct sctplist_listhead out_list; }; /* * This union holds all parameters per stream * necessary for different stream schedulers. */ union scheduling_parameters { struct ss_rr rr; struct ss_prio prio; struct ss_fb fb; }; /* This struct is used to track the traffic on outbound streams */ struct sctp_stream_out { struct sctp_streamhead outqueue; union scheduling_parameters ss_params; uint16_t stream_no; uint16_t next_sequence_sent; /* next one I expect to send out */ uint8_t last_msg_incomplete; }; /* used to keep track of the addresses yet to try to add/delete */ TAILQ_HEAD(sctp_asconf_addrhead, sctp_asconf_addr); struct sctp_asconf_addr { TAILQ_ENTRY(sctp_asconf_addr) next; struct sctp_asconf_addr_param ap; struct sctp_ifa *ifa; /* save the ifa for add/del ip */ uint8_t sent; /* has this been sent yet? */ uint8_t special_del; /* not to be used in lookup */ }; struct sctp_scoping { uint8_t ipv4_addr_legal; uint8_t ipv6_addr_legal; uint8_t loopback_scope; uint8_t ipv4_local_scope; uint8_t local_scope; uint8_t site_scope; }; #define SCTP_TSN_LOG_SIZE 40 struct sctp_tsn_log { void *stcb; uint32_t tsn; uint16_t strm; uint16_t seq; uint16_t sz; uint16_t flgs; uint16_t in_pos; uint16_t in_out; }; #define SCTP_FS_SPEC_LOG_SIZE 200 struct sctp_fs_spec_log { uint32_t sent; uint32_t total_flight; uint32_t tsn; uint16_t book; uint8_t incr; uint8_t decr; }; /* This struct is here to cut out the compatiabilty * pad that bulks up both the inp and stcb. The non * pad portion MUST stay in complete sync with * sctp_sndrcvinfo... i.e. if sinfo_xxxx is added * this must be done here too. */ struct sctp_nonpad_sndrcvinfo { uint16_t sinfo_stream; uint16_t sinfo_ssn; uint16_t sinfo_flags; uint32_t sinfo_ppid; uint32_t sinfo_context; uint32_t sinfo_timetolive; uint32_t sinfo_tsn; uint32_t sinfo_cumtsn; sctp_assoc_t sinfo_assoc_id; }; /* * JRS - Structure to hold function pointers to the functions responsible * for congestion control. */ struct sctp_cc_functions { void (*sctp_set_initial_cc_param) (struct sctp_tcb *stcb, struct sctp_nets *net); void (*sctp_cwnd_update_after_sack) (struct sctp_tcb *stcb, struct sctp_association *asoc, int accum_moved, int reneged_all, int will_exit); void (*sctp_cwnd_update_after_fr) (struct sctp_tcb *stcb, struct sctp_association *asoc); void (*sctp_cwnd_update_after_timeout) (struct sctp_tcb *stcb, struct sctp_nets *net); void (*sctp_cwnd_update_after_ecn_echo) (struct sctp_tcb *stcb, struct sctp_nets *net, int in_window, int num_pkt_lost); void (*sctp_cwnd_update_after_packet_dropped) (struct sctp_tcb *stcb, struct sctp_nets *net, struct sctp_pktdrop_chunk *cp, uint32_t * bottle_bw, uint32_t * on_queue); void (*sctp_cwnd_update_after_output) (struct sctp_tcb *stcb, struct sctp_nets *net, int burst_limit); void (*sctp_cwnd_update_after_fr_timer) (struct sctp_inpcb *inp, struct sctp_tcb *stcb, struct sctp_nets *net); void (*sctp_cwnd_update_packet_transmitted) (struct sctp_tcb *stcb, struct sctp_nets *net); void (*sctp_cwnd_update_tsn_acknowledged) (struct sctp_nets *net, struct sctp_tmit_chunk *); void (*sctp_cwnd_new_transmission_begins) (struct sctp_tcb *stcb, struct sctp_nets *net); void (*sctp_cwnd_prepare_net_for_sack) (struct sctp_tcb *stcb, struct sctp_nets *net); int (*sctp_cwnd_socket_option) (struct sctp_tcb *stcb, int set, struct sctp_cc_option *); }; /* * RS - Structure to hold function pointers to the functions responsible * for stream scheduling. */ struct sctp_ss_functions { void (*sctp_ss_init) (struct sctp_tcb *stcb, struct sctp_association *asoc, int holds_lock); void (*sctp_ss_clear) (struct sctp_tcb *stcb, struct sctp_association *asoc, int clear_values, int holds_lock); void (*sctp_ss_init_stream) (struct sctp_stream_out *strq, struct sctp_stream_out *with_strq); void (*sctp_ss_add_to_stream) (struct sctp_tcb *stcb, struct sctp_association *asoc, struct sctp_stream_out *strq, struct sctp_stream_queue_pending *sp, int holds_lock); int (*sctp_ss_is_empty) (struct sctp_tcb *stcb, struct sctp_association *asoc); void (*sctp_ss_remove_from_stream) (struct sctp_tcb *stcb, struct sctp_association *asoc, struct sctp_stream_out *strq, struct sctp_stream_queue_pending *sp, int holds_lock); struct sctp_stream_out *(*sctp_ss_select_stream) (struct sctp_tcb *stcb, struct sctp_nets *net, struct sctp_association *asoc); void (*sctp_ss_scheduled) (struct sctp_tcb *stcb, struct sctp_nets *net, struct sctp_association *asoc, struct sctp_stream_out *strq, int moved_how_much); void (*sctp_ss_packet_done) (struct sctp_tcb *stcb, struct sctp_nets *net, struct sctp_association *asoc); int (*sctp_ss_get_value) (struct sctp_tcb *stcb, struct sctp_association *asoc, struct sctp_stream_out *strq, uint16_t * value); int (*sctp_ss_set_value) (struct sctp_tcb *stcb, struct sctp_association *asoc, struct sctp_stream_out *strq, uint16_t value); }; /* used to save ASCONF chunks for retransmission */ TAILQ_HEAD(sctp_asconf_head, sctp_asconf); struct sctp_asconf { TAILQ_ENTRY(sctp_asconf) next; uint32_t serial_number; uint16_t snd_count; struct mbuf *data; uint16_t len; }; /* used to save ASCONF-ACK chunks for retransmission */ TAILQ_HEAD(sctp_asconf_ackhead, sctp_asconf_ack); struct sctp_asconf_ack { TAILQ_ENTRY(sctp_asconf_ack) next; uint32_t serial_number; struct sctp_nets *last_sent_to; struct mbuf *data; uint16_t len; }; /* * Here we have information about each individual association that we track. * We probably in production would be more dynamic. But for ease of * implementation we will have a fixed array that we hunt for in a linear * fashion. */ struct sctp_association { /* association state */ int state; /* queue of pending addrs to add/delete */ struct sctp_asconf_addrhead asconf_queue; struct timeval time_entered; /* time we entered state */ struct timeval time_last_rcvd; struct timeval time_last_sent; struct timeval time_last_sat_advance; struct sctp_nonpad_sndrcvinfo def_send; /* timers and such */ struct sctp_timer hb_timer; /* hb timer */ struct sctp_timer dack_timer; /* Delayed ack timer */ struct sctp_timer asconf_timer; /* asconf */ struct sctp_timer strreset_timer; /* stream reset */ struct sctp_timer shut_guard_timer; /* shutdown guard */ struct sctp_timer autoclose_timer; /* automatic close timer */ struct sctp_timer delayed_event_timer; /* timer for delayed events */ struct sctp_timer delete_prim_timer; /* deleting primary dst */ /* list of restricted local addresses */ struct sctpladdr sctp_restricted_addrs; /* last local address pending deletion (waiting for an address add) */ struct sctp_ifa *asconf_addr_del_pending; /* Deleted primary destination (used to stop timer) */ struct sctp_nets *deleted_primary; struct sctpnetlisthead nets; /* remote address list */ /* Free chunk list */ struct sctpchunk_listhead free_chunks; /* Control chunk queue */ struct sctpchunk_listhead control_send_queue; /* ASCONF chunk queue */ struct sctpchunk_listhead asconf_send_queue; /* * Once a TSN hits the wire it is moved to the sent_queue. We * maintain two counts here (don't know if any but retran_cnt is * needed). The idea is that the sent_queue_retran_cnt reflects how * many chunks have been marked for retranmission by either T3-rxt * or FR. */ struct sctpchunk_listhead sent_queue; struct sctpchunk_listhead send_queue; /* re-assembly queue for fragmented chunks on the inbound path */ struct sctpchunk_listhead reasmqueue; /* Scheduling queues */ union scheduling_data ss_data; /* * This pointer will be set to NULL most of the time. But when we * have a fragmented message, where we could not get out all of the * message at the last send then this will point to the stream to go * get data from. */ struct sctp_stream_out *locked_on_sending; /* If an iterator is looking at me, this is it */ struct sctp_iterator *stcb_starting_point_for_iterator; /* ASCONF save the last ASCONF-ACK so we can resend it if necessary */ struct sctp_asconf_ackhead asconf_ack_sent; /* * pointer to last stream reset queued to control queue by us with * requests. */ struct sctp_tmit_chunk *str_reset; /* * if Source Address Selection happening, this will rotate through * the link list. */ struct sctp_laddr *last_used_address; /* stream arrays */ struct sctp_stream_in *strmin; struct sctp_stream_out *strmout; uint8_t *mapping_array; /* primary destination to use */ struct sctp_nets *primary_destination; /* For CMT */ struct sctp_nets *last_net_cmt_send_started; /* last place I got a data chunk from */ struct sctp_nets *last_data_chunk_from; /* last place I got a control from */ struct sctp_nets *last_control_chunk_from; /* circular looking for output selection */ struct sctp_stream_out *last_out_stream; /* * wait to the point the cum-ack passes req->send_reset_at_tsn for * any req on the list. */ struct sctp_resethead resetHead; /* queue of chunks waiting to be sent into the local stack */ struct sctp_readhead pending_reply_queue; /* JRS - the congestion control functions are in this struct */ struct sctp_cc_functions cc_functions; /* * JRS - value to store the currently loaded congestion control * module */ uint32_t congestion_control_module; /* RS - the stream scheduling functions are in this struct */ struct sctp_ss_functions ss_functions; /* RS - value to store the currently loaded stream scheduling module */ uint32_t stream_scheduling_module; uint32_t vrf_id; uint32_t cookie_preserve_req; /* ASCONF next seq I am sending out, inits at init-tsn */ uint32_t asconf_seq_out; uint32_t asconf_seq_out_acked; /* ASCONF last received ASCONF from peer, starts at peer's TSN-1 */ uint32_t asconf_seq_in; /* next seq I am sending in str reset messages */ uint32_t str_reset_seq_out; /* next seq I am expecting in str reset messages */ uint32_t str_reset_seq_in; /* various verification tag information */ uint32_t my_vtag; /* The tag to be used. if assoc is re-initited * by remote end, and I have unlocked this * will be regenerated to a new random value. */ uint32_t peer_vtag; /* The peers last tag */ uint32_t my_vtag_nonce; uint32_t peer_vtag_nonce; uint32_t assoc_id; /* This is the SCTP fragmentation threshold */ uint32_t smallest_mtu; /* * Special hook for Fast retransmit, allows us to track the highest * TSN that is NEW in this SACK if gap ack blocks are present. */ uint32_t this_sack_highest_gap; /* * The highest consecutive TSN that has been acked by peer on my * sends */ uint32_t last_acked_seq; /* The next TSN that I will use in sending. */ uint32_t sending_seq; /* Original seq number I used ??questionable to keep?? */ uint32_t init_seq_number; /* The Advanced Peer Ack Point, as required by the PR-SCTP */ /* (A1 in Section 4.2) */ uint32_t advanced_peer_ack_point; /* * The highest consequetive TSN at the bottom of the mapping array * (for his sends). */ uint32_t cumulative_tsn; /* * Used to track the mapping array and its offset bits. This MAY be * lower then cumulative_tsn. */ uint32_t mapping_array_base_tsn; /* * used to track highest TSN we have received and is listed in the * mapping array. */ uint32_t highest_tsn_inside_map; /* EY - new NR variables used for nr_sack based on mapping_array */ uint8_t *nr_mapping_array; uint32_t highest_tsn_inside_nr_map; uint32_t fast_recovery_tsn; uint32_t sat_t3_recovery_tsn; uint32_t tsn_last_delivered; /* * For the pd-api we should re-write this a bit more efficent. We * could have multiple sctp_queued_to_read's that we are building at * once. Now we only do this when we get ready to deliver to the * socket buffer. Note that we depend on the fact that the struct is * "stuck" on the read queue until we finish all the pd-api. */ struct sctp_queued_to_read *control_pdapi; uint32_t tsn_of_pdapi_last_delivered; uint32_t pdapi_ppid; uint32_t context; uint32_t last_reset_action[SCTP_MAX_RESET_PARAMS]; uint32_t last_sending_seq[SCTP_MAX_RESET_PARAMS]; uint32_t last_base_tsnsent[SCTP_MAX_RESET_PARAMS]; #ifdef SCTP_ASOCLOG_OF_TSNS /* * special log - This adds considerable size to the asoc, but * provides a log that you can use to detect problems via kgdb. */ struct sctp_tsn_log in_tsnlog[SCTP_TSN_LOG_SIZE]; struct sctp_tsn_log out_tsnlog[SCTP_TSN_LOG_SIZE]; uint32_t cumack_log[SCTP_TSN_LOG_SIZE]; uint32_t cumack_logsnt[SCTP_TSN_LOG_SIZE]; uint16_t tsn_in_at; uint16_t tsn_out_at; uint16_t tsn_in_wrapped; uint16_t tsn_out_wrapped; uint16_t cumack_log_at; uint16_t cumack_log_atsnt; #endif /* SCTP_ASOCLOG_OF_TSNS */ #ifdef SCTP_FS_SPEC_LOG struct sctp_fs_spec_log fslog[SCTP_FS_SPEC_LOG_SIZE]; uint16_t fs_index; #endif /* * window state information and smallest MTU that I use to bound * segmentation */ uint32_t peers_rwnd; uint32_t my_rwnd; uint32_t my_last_reported_rwnd; uint32_t sctp_frag_point; uint32_t total_output_queue_size; uint32_t sb_cc; /* shadow of sb_cc */ uint32_t sb_send_resv; /* amount reserved on a send */ uint32_t my_rwnd_control_len; /* shadow of sb_mbcnt used for rwnd * control */ uint32_t default_flowlabel; uint32_t pr_sctp_cnt; int ctrl_queue_cnt; /* could be removed REM - NO IT CAN'T!! RRS */ /* * All outbound datagrams queue into this list from the individual * stream queue. Here they get assigned a TSN and then await * sending. The stream seq comes when it is first put in the * individual str queue */ unsigned int stream_queue_cnt; unsigned int send_queue_cnt; unsigned int sent_queue_cnt; unsigned int sent_queue_cnt_removeable; /* * Number on sent queue that are marked for retran until this value * is 0 we only send one packet of retran'ed data. */ unsigned int sent_queue_retran_cnt; unsigned int size_on_reasm_queue; unsigned int cnt_on_reasm_queue; unsigned int fwd_tsn_cnt; /* amount of data (bytes) currently in flight (on all destinations) */ unsigned int total_flight; /* Total book size in flight */ unsigned int total_flight_count; /* count of chunks used with * book total */ /* count of destinaton nets and list of destination nets */ unsigned int numnets; /* Total error count on this association */ unsigned int overall_error_count; unsigned int cnt_msg_on_sb; /* All stream count of chunks for delivery */ unsigned int size_on_all_streams; unsigned int cnt_on_all_streams; /* Heart Beat delay in ticks */ unsigned int heart_beat_delay; /* autoclose */ unsigned int sctp_autoclose_ticks; /* how many preopen streams we have */ unsigned int pre_open_streams; /* How many streams I support coming into me */ unsigned int max_inbound_streams; /* the cookie life I award for any cookie, in seconds */ unsigned int cookie_life; /* time to delay acks for */ unsigned int delayed_ack; unsigned int old_delayed_ack; unsigned int sack_freq; unsigned int data_pkts_seen; unsigned int numduptsns; int dup_tsns[SCTP_MAX_DUP_TSNS]; unsigned int initial_init_rto_max; /* initial RTO for INIT's */ unsigned int initial_rto; /* initial send RTO */ unsigned int minrto; /* per assoc RTO-MIN */ unsigned int maxrto; /* per assoc RTO-MAX */ /* authentication fields */ sctp_auth_chklist_t *local_auth_chunks; sctp_auth_chklist_t *peer_auth_chunks; sctp_hmaclist_t *local_hmacs; /* local HMACs supported */ sctp_hmaclist_t *peer_hmacs; /* peer HMACs supported */ struct sctp_keyhead shared_keys; /* assoc's shared keys */ sctp_authinfo_t authinfo; /* randoms, cached keys */ /* * refcnt to block freeing when a sender or receiver is off coping * user data in. */ uint32_t refcnt; uint32_t chunks_on_out_queue; /* total chunks floating around, * locked by send socket buffer */ uint32_t peers_adaptation; uint16_t peer_hmac_id; /* peer HMAC id to send */ /* * Being that we have no bag to collect stale cookies, and that we * really would not want to anyway.. we will count them in this * counter. We of course feed them to the pigeons right away (I have * always thought of pigeons as flying rats). */ uint16_t stale_cookie_count; /* * For the partial delivery API, if up, invoked this is what last * TSN I delivered */ uint16_t str_of_pdapi; uint16_t ssn_of_pdapi; /* counts of actual built streams. Allocation may be more however */ /* could re-arrange to optimize space here. */ uint16_t streamincnt; uint16_t streamoutcnt; uint16_t strm_realoutsize; /* my maximum number of retrans of INIT and SEND */ /* copied from SCTP but should be individually setable */ uint16_t max_init_times; uint16_t max_send_times; uint16_t def_net_failure; /* * lock flag: 0 is ok to send, 1+ (duals as a retran count) is * awaiting ACK */ uint16_t mapping_array_size; uint16_t last_strm_seq_delivered; uint16_t last_strm_no_delivered; uint16_t last_revoke_count; int16_t num_send_timers_up; uint16_t stream_locked_on; uint16_t ecn_echo_cnt_onq; uint16_t free_chunk_cnt; uint8_t stream_locked; uint8_t authenticated; /* packet authenticated ok */ /* * This flag indicates that a SACK need to be sent. Initially this * is 1 to send the first sACK immediately. */ uint8_t send_sack; /* max burst of new packets into the network */ uint32_t max_burst; /* max burst of fast retransmit packets */ uint32_t fr_max_burst; uint8_t sat_network; /* RTT is in range of sat net or greater */ uint8_t sat_network_lockout; /* lockout code */ uint8_t burst_limit_applied; /* Burst limit in effect at last send? */ /* flag goes on when we are doing a partial delivery api */ uint8_t hb_random_values[4]; uint8_t fragmented_delivery_inprogress; uint8_t fragment_flags; uint8_t last_flags_delivered; uint8_t hb_ect_randombit; uint8_t hb_random_idx; uint8_t hb_is_disabled; /* is the hb disabled? */ uint8_t default_tos; uint8_t asconf_del_pending; /* asconf delete last addr pending */ /* * This value, plus all other ack'd but above cum-ack is added * together to cross check against the bit that we have yet to * define (probably in the SACK). When the cum-ack is updated, this * sum is updated as well. */ /* Flag to tell if ECN is allowed */ uint8_t ecn_allowed; /* flag to indicate if peer can do asconf */ uint8_t peer_supports_asconf; /* EY - flag to indicate if peer can do nr_sack */ uint8_t peer_supports_nr_sack; /* pr-sctp support flag */ uint8_t peer_supports_prsctp; /* peer authentication support flag */ uint8_t peer_supports_auth; /* stream resets are supported by the peer */ uint8_t peer_supports_strreset; uint8_t peer_supports_nat; /* * packet drop's are supported by the peer, we don't really care * about this but we bookkeep it anyway. */ uint8_t peer_supports_pktdrop; /* Do we allow V6/V4? */ uint8_t ipv4_addr_legal; uint8_t ipv6_addr_legal; /* Address scoping flags */ /* scope value for IPv4 */ uint8_t ipv4_local_scope; /* scope values for IPv6 */ uint8_t local_scope; uint8_t site_scope; /* loopback scope */ uint8_t loopback_scope; /* flags to handle send alternate net tracking */ uint8_t used_alt_onsack; uint8_t used_alt_asconfack; uint8_t fast_retran_loss_recovery; uint8_t sat_t3_loss_recovery; uint8_t dropped_special_cnt; uint8_t seen_a_sack_this_pkt; uint8_t stream_reset_outstanding; uint8_t stream_reset_out_is_outstanding; uint8_t delayed_connection; uint8_t ifp_had_enobuf; uint8_t saw_sack_with_frags; uint8_t saw_sack_with_nr_frags; uint8_t in_asocid_hash; uint8_t assoc_up_sent; uint8_t adaptation_needed; uint8_t adaptation_sent; /* CMT variables */ uint8_t cmt_dac_pkts_rcvd; uint8_t sctp_cmt_on_off; uint8_t iam_blocking; uint8_t cookie_how[8]; /* EY 05/05/08 - NR_SACK variable */ uint8_t sctp_nr_sack_on_off; /* JRS 5/21/07 - CMT PF variable */ uint8_t sctp_cmt_pf; uint8_t use_precise_time; /* * The mapping array is used to track out of order sequences above * last_acked_seq. 0 indicates packet missing 1 indicates packet * rec'd. We slide it up every time we raise last_acked_seq and 0 * trailing locactions out. If I get a TSN above the array * mappingArraySz, I discard the datagram and let retransmit happen. */ uint32_t marked_retrans; uint32_t timoinit; uint32_t timodata; uint32_t timosack; uint32_t timoshutdown; uint32_t timoheartbeat; uint32_t timocookie; uint32_t timoshutdownack; struct timeval start_time; struct timeval discontinuity_time; }; #endif