freebsd-dev/sys/netinet/sctp_structs.h
Michael Tuexen b5c164935e * Fix some race condition in SACK/NR-SACK processing.
* Fix handling of mapping arrays when draining mbufs or processing
  FORWARD-TSN chunks.
* Cleanup code (no duplicate code anymore for SACKs and NR-SACKs).
Part of this code was developed together with rrs.
MFC after: 2 weeks.
2010-04-03 15:40:14 +00:00

1076 lines
33 KiB
C

/*-
* Copyright (c) 2001-2008, by Cisco Systems, Inc. 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 <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#ifndef __sctp_structs_h__
#define __sctp_structs_h__
#include <netinet/sctp_os.h>
#include <netinet/sctp_header.h>
#include <netinet/sctp_auth.h>
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);
struct sctp_iterator {
TAILQ_ENTRY(sctp_iterator) sctp_nxt_itr;
struct sctp_timer tmr;
struct sctp_inpcb *inp; /* current endpoint */
struct sctp_tcb *stcb; /* current* assoc */
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 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 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 */
/* smoothed average things for RTT and RTO itself */
int lastsa;
int lastsv;
int rtt; /* last measured rtt value in ms */
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;
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 partial_bytes_acked; /* in CA tracks when to incr a MTU */
uint32_t prev_rtt;
/* 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 */
/* JRS - struct used in HTCP algorithm */
struct htcp htcp_ca;
};
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 */
/* ECN Nonce: Nonce Value for this chunk */
uint8_t ect_nonce;
uint8_t fwd_tsn_cnt;
/*
* 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;
};
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;
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;
};
/* This struct is used to track the traffic on outbound streams */
TAILQ_HEAD(sctpwheel_listhead, sctp_stream_out);
struct sctp_stream_out {
struct sctp_streamhead outqueue;
TAILQ_ENTRY(sctp_stream_out) next_spoke; /* next link in wheel */
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);
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);
};
/* 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;
/*
* this queue is used when we reach a condition that we can NOT put
* data into the socket buffer. We track the size of this queue and
* set our rwnd to the space in the socket minus also the
* size_on_delivery_queue.
*/
struct sctpwheel_listhead out_wheel;
/*
* 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;
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 last_echo_tsn;
uint32_t last_cwr_tsn;
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 */
/* 32 bit nonce stuff */
uint32_t nonce_resync_tsn;
uint32_t nonce_wait_tsn;
uint32_t default_flowlabel;
uint32_t pr_sctp_cnt;
int ctrl_queue_cnt; /* could be removed REM */
/*
* 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;
/* 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 after fast retransmit completes */
uint8_t 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 */
/* ECN Nonce stuff */
uint8_t receiver_nonce_sum; /* nonce I sum and put in my sack */
uint8_t ecn_nonce_allowed; /* Tells us if ECN nonce is on */
uint8_t nonce_sum_check;/* On off switch used during re-sync */
uint8_t nonce_wait_for_ecne; /* flag when we expect a ECN */
uint8_t peer_supports_ecn_nonce;
/*
* 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.
*/
uint8_t nonce_sum_expect_base;
/* 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 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;
/*
* 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