libpri/pri_internal.h
Richard Mudgett 2867fc717e Crash if NFAS swaps D channels on a call with an active timer.
If a Q.931 call record related timer is started on one NFAS D channel
expires after NFAS swaps to another D channel, then libpri could crash.

For example:
1) Hangup a call.
1a) Send a DISCONNECT.
1b) Start the T305 retransmit timer on the current D channel.
2) The RELEASE comes in on another D channel.
2a) The found call record switches its assignment to the new D channel.
2b) Attempt to stop T305.  Unfortunately, the timer was started on another
    D channel so the attempt does not find the timer to stop.
3) The hangup sequence continues normally and the call record is freed
   since there is only one call record pool.
4) T305 expires on the original D channel and crashes the system when it
   uses the stale call record pointer it has saved.

Made each D channel timer pool have a unique range of valid timer
identifiers.  If a given timer identifier is not in the range for the
current NFAS D channel, then search the D channel group for the original D
channel.

JIRA LIBPRI-58
JIRA SWP-2721


git-svn-id: https://origsvn.digium.com/svn/libpri/branches/1.4@2202 2fbb986a-6c06-0410-b554-c9c1f0a7f128
2011-02-16 19:23:02 +00:00

1131 lines
37 KiB
C

/*
* libpri: An implementation of Primary Rate ISDN
*
* Written by Mark Spencer <markster@digium.com>
*
* Copyright (C) 2001, Digium, Inc.
* All Rights Reserved.
*/
/*
* See http://www.asterisk.org for more information about
* the Asterisk project. Please do not directly contact
* any of the maintainers of this project for assistance;
* the project provides a web site, mailing lists and IRC
* channels for your use.
*
* This program is free software, distributed under the terms of
* the GNU General Public License Version 2 as published by the
* Free Software Foundation. See the LICENSE file included with
* this program for more details.
*
* In addition, when this program is distributed with Asterisk in
* any form that would qualify as a 'combined work' or as a
* 'derivative work' (but not mere aggregation), you can redistribute
* and/or modify the combination under the terms of the license
* provided with that copy of Asterisk, instead of the license
* terms granted here.
*/
#ifndef _PRI_INTERNAL_H
#define _PRI_INTERNAL_H
#include <stddef.h>
#include <sys/time.h>
#include "pri_q921.h"
#include "pri_q931.h"
#define ARRAY_LEN(arr) (sizeof(arr) / sizeof((arr)[0]))
#define DBGHEAD __FILE__ ":%d %s: "
#define DBGINFO __LINE__,__PRETTY_FUNCTION__
/* Forward declare some structs */
struct apdu_event;
struct pri_cc_record;
struct pri_sched {
struct timeval when;
void (*callback)(void *data);
void *data;
};
/*
* libpri needs to be able to allocate B channels to support Q.SIG path reservation.
* Until that happens, path reservation is not possible. Fortunately,
* path reservation is optional with a fallback to what we can implement.
*/
//#define QSIG_PATH_RESERVATION_SUPPORT 1
/*! Maximum number of facility ie's to handle per incoming message. */
#define MAX_FACILITY_IES 8
/*! Maximum length of sent display text string. (No null terminator.) */
#define MAX_DISPLAY_TEXT 80
/*! Accumulated pri_message() line until a '\n' is seen on the end. */
struct pri_msg_line {
/*! Accumulated buffer used. */
unsigned length;
/*! Accumulated pri_message() contents. */
char str[2048];
};
/*! \brief D channel controller structure */
struct pri {
int fd; /* File descriptor for D-Channel */
pri_io_cb read_func; /* Read data callback */
pri_io_cb write_func; /* Write data callback */
void *userdata;
/*! Accumulated pri_message() line. (Valid in master record only) */
struct pri_msg_line *msg_line;
/*! NFAS master/primary channel if appropriate */
struct pri *master;
/*! Next NFAS slaved D channel if appropriate */
struct pri *slave;
struct {
/*! Dynamically allocated array of timers that can grow as needed. */
struct pri_sched *timer;
/*! Numer of timer slots in the allocated array of timers. */
unsigned num_slots;
/*! Maximum timer slots currently needed. */
unsigned max_used;
/*! First timer id in this timer pool. */
unsigned first_id;
} sched;
int debug; /* Debug stuff */
int state; /* State of D-channel */
int switchtype; /* Switch type */
int nsf; /* Network-Specific Facility (if any) */
int localtype; /* Local network type (unknown, network, cpe) */
int remotetype; /* Remote network type (unknown, network, cpe) */
int protodisc; /* Layer 3 protocol discriminator */
unsigned int nfas:1;/* TRUE if this D channel is involved with an NFAS group */
unsigned int bri:1;
unsigned int acceptinbanddisconnect:1; /* Should we allow inband progress after DISCONNECT? */
unsigned int sendfacility:1;
unsigned int overlapdial:1;/* TRUE if we do overlap dialing */
unsigned int chan_mapping_logical:1;/* TRUE if do not skip channel 16 (Q.SIG) */
unsigned int service_message_support:1;/* TRUE if upper layer supports SERVICE messages */
unsigned int hold_support:1;/* TRUE if upper layer supports call hold. */
unsigned int deflection_support:1;/* TRUE if upper layer supports call deflection/rerouting. */
unsigned int hangup_fix_enabled:1;/* TRUE if should follow Q.931 Section 5.3.2 instead of blindly sending RELEASE_COMPLETE for certain causes */
unsigned int cc_support:1;/* TRUE if upper layer supports call completion. */
unsigned int transfer_support:1;/* TRUE if the upper layer supports ECT */
unsigned int aoc_support:1;/* TRUE if can send AOC events to the upper layer. */
unsigned int manual_connect_ack:1;/* TRUE if the CONNECT_ACKNOWLEDGE is sent with API call */
unsigned int mcid_support:1;/* TRUE if the upper layer supports MCID */
/*! Layer 2 link control for D channel. */
struct q921_link link;
/*! T201 TEI Identity Check timer. */
int t201_timer;
/*! Number of times T201 has expired. */
int t201_expirycnt;
int cref; /* Next call reference value */
/* All ISDN Timer values */
int timers[PRI_MAX_TIMERS];
/* Used by scheduler */
int schedev;
pri_event ev; /* Static event thingy */
/*! Subcommands for static event thingy. */
struct pri_subcommands subcmds;
/* Q.931 calls */
struct q931_call **callpool;
struct q931_call *localpool;
/* q921/q931 packet counters */
unsigned int q921_txcount;
unsigned int q921_rxcount;
unsigned int q931_txcount;
unsigned int q931_rxcount;
short last_invoke; /* Last ROSE invoke ID (Valid in master record only) */
/*! Call completion (Valid in master record only) */
struct {
/*! Active CC records */
struct pri_cc_record *pool;
/*! Last CC record id allocated. */
unsigned short last_record_id;
/*! Last CC PTMP reference id allocated. (0-127) */
unsigned char last_reference_id;
/*! Last CC PTMP linkage id allocated. (0-127) */
unsigned char last_linkage_id;
/*! Configured CC options. */
struct {
/*! PTMP recall mode: globalRecall(0), specificRecall(1) */
unsigned char recall_mode;
/*! Q.SIG Request signaling link retention: release(0), retain(1), do-not-care(2) */
unsigned char signaling_retention_req;
/*! Q.SIG Response request signaling link retention: release(0), retain(1) */
unsigned char signaling_retention_rsp;
#if defined(QSIG_PATH_RESERVATION_SUPPORT)
/*! Q.SIG TRUE if response request can support path reservation. */
unsigned char allow_path_reservation;
#endif /* defined(QSIG_PATH_RESERVATION_SUPPORT) */
} option;
} cc;
/*! For delayed processing of facility ie's. */
struct {
/*! Array of facility ie locations in the current received message. */
q931_ie *ie[MAX_FACILITY_IES];
/*! Codeset facility ie found within. */
unsigned char codeset[MAX_FACILITY_IES];
/*! Number of facility ie's in the array from the current received message. */
unsigned char count;
} facility;
/*! Display text policy handling options. */
struct {
/*! Send display text policy option flags. */
unsigned long send;
/*! Receive display text policy option flags. */
unsigned long receive;
} display_flags;
};
/*! \brief Maximum name length plus null terminator (From ECMA-164) */
#define PRI_MAX_NAME_LEN (50 + 1)
/*! \brief Q.SIG name information. */
struct q931_party_name {
/*! \brief TRUE if name data is valid */
unsigned char valid;
/*!
* \brief Q.931 presentation-indicator encoded field
* \note Must tollerate the Q.931 screening-indicator field values being present.
*/
unsigned char presentation;
/*!
* \brief Character set the name is using.
* \details
* unknown(0),
* iso8859-1(1),
* enum-value-withdrawn-by-ITU-T(2)
* iso8859-2(3),
* iso8859-3(4),
* iso8859-4(5),
* iso8859-5(6),
* iso8859-7(7),
* iso10646-BmpString(8),
* iso10646-utf-8String(9)
*/
unsigned char char_set;
/*! \brief Name data with null terminator. */
char str[PRI_MAX_NAME_LEN];
};
/*! \brief Maximum phone number (address) length plus null terminator */
#define PRI_MAX_NUMBER_LEN (31 + 1)
struct q931_party_number {
/*! \brief TRUE if number data is valid */
unsigned char valid;
/*! \brief Q.931 presentation-indicator and screening-indicator encoded fields */
unsigned char presentation;
/*! \brief Q.931 Type-Of-Number and numbering-plan encoded fields */
unsigned char plan;
/*! \brief Number data with terminator. */
char str[PRI_MAX_NUMBER_LEN];
};
/*! \brief Maximum subaddress length plus null terminator */
#define PRI_MAX_SUBADDRESS_LEN (20 + 1)
struct q931_party_subaddress {
/*! \brief TRUE if the subaddress information is valid/present */
unsigned char valid;
/*!
* \brief Subaddress type.
* \details
* nsap(0),
* user_specified(2)
*/
unsigned char type;
/*!
* \brief TRUE if odd number of address signals
* \note The odd/even indicator is used when the type of subaddress is
* user_specified and the coding is BCD.
*/
unsigned char odd_even_indicator;
/*! \brief Length of the subaddress data */
unsigned char length;
/*!
* \brief Subaddress data with null terminator.
* \note The null terminator is a convenience only since the data could be
* BCD/binary and thus have a null byte as part of the contents.
*/
unsigned char data[PRI_MAX_SUBADDRESS_LEN];
};
struct q931_party_address {
/*! \brief Subscriber phone number */
struct q931_party_number number;
/*! \brief Subscriber subaddress */
struct q931_party_subaddress subaddress;
};
/*! \brief Information needed to identify an endpoint in a call. */
struct q931_party_id {
/*! \brief Subscriber name */
struct q931_party_name name;
/*! \brief Subscriber phone number */
struct q931_party_number number;
/*! \brief Subscriber subaddress */
struct q931_party_subaddress subaddress;
};
enum Q931_REDIRECTING_STATE {
/*!
* \details
* CDO-Idle/CDF-Inv-Idle
*/
Q931_REDIRECTING_STATE_IDLE,
/*!
* \details
* CDF-Inv-Wait - A DivLeg2 has been received and
* we are waiting for valid presentation restriction information to send.
*/
Q931_REDIRECTING_STATE_PENDING_TX_DIV_LEG_3,
/*!
* \details
* CDO-Divert - A DivLeg1 has been received and
* we are waiting for the presentation restriction information to come in.
*/
Q931_REDIRECTING_STATE_EXPECTING_RX_DIV_LEG_3,
};
/*!
* \brief Do not increment above this count.
* \details
* It is not our responsibility to enforce the maximum number of redirects.
* However, we cannot allow an increment past this number without breaking things.
* Besides, more than 255 redirects is probably not a good thing.
*/
#define PRI_MAX_REDIRECTS 0xFF
/*! \brief Redirecting information struct */
struct q931_party_redirecting {
enum Q931_REDIRECTING_STATE state;
/*! \brief Who is redirecting the call (Sent to the party the call is redirected toward) */
struct q931_party_id from;
/*! \brief Call is redirecting to a new party (Sent to the caller) */
struct q931_party_id to;
/*! Originally called party (in cases of multiple redirects) */
struct q931_party_id orig_called;
/*!
* \brief Number of times the call was redirected
* \note The call is being redirected if the count is non-zero.
*/
unsigned char count;
/*! Original reason for redirect (in cases of multiple redirects) */
unsigned char orig_reason;
/*! \brief Redirection reasons */
unsigned char reason;
};
/*! \brief New call setup parameter structure */
struct pri_sr {
int transmode;
int channel;
int exclusive;
int nonisdn;
struct q931_party_redirecting redirecting;
struct q931_party_id caller;
struct q931_party_address called;
int userl1;
int numcomplete;
int cis_call;
int cis_auto_disconnect;
const char *useruserinfo;
const char *keypad_digits;
int transferable;
int reversecharge;
int aoc_charging_request;
};
#define Q931_MAX_TEI 8
/*! \brief Incoming call transfer states. */
enum INCOMING_CT_STATE {
/*!
* \details
* Incoming call transfer is not active.
*/
INCOMING_CT_STATE_IDLE,
/*!
* \details
* We have seen an incoming CallTransferComplete(alerting)
* so we are waiting for the expected CallTransferActive
* before updating the connected line about the remote party id.
*/
INCOMING_CT_STATE_EXPECT_CT_ACTIVE,
/*!
* \details
* A call transfer message came in that updated the remote party id
* that we need to post a connected line update.
*/
INCOMING_CT_STATE_POST_CONNECTED_LINE
};
/*! Call hold supplementary states. */
enum Q931_HOLD_STATE {
/*! \brief No call hold activity. */
Q931_HOLD_STATE_IDLE,
/*! \brief Request made to hold call. */
Q931_HOLD_STATE_HOLD_REQ,
/*! \brief Request received to hold call. */
Q931_HOLD_STATE_HOLD_IND,
/*! \brief Call is held. */
Q931_HOLD_STATE_CALL_HELD,
/*! \brief Request made to retrieve call. */
Q931_HOLD_STATE_RETRIEVE_REQ,
/*! \brief Request received to retrieve call. */
Q931_HOLD_STATE_RETRIEVE_IND,
};
/* Only save the first of each BC, HLC, and LLC from the initial SETUP. */
#define CC_SAVED_IE_BC (1 << 0) /*!< BC has already been saved. */
#define CC_SAVED_IE_HLC (1 << 1) /*!< HLC has already been saved. */
#define CC_SAVED_IE_LLC (1 << 2) /*!< LLC has already been saved. */
/*! Saved ie contents for BC, HLC, and LLC. (Only the first of each is saved.) */
struct q931_saved_ie_contents {
/*! Length of saved ie contents. */
unsigned char length;
/*! Saved ie contents data. */
unsigned char data[
/* Bearer Capability has a max length of 12. */
12
/* High Layer Compatibility has a max length of 5. */
+ 5
/* Low Layer Compatibility has a max length of 18. */
+ 18
/* Room for null terminator just in case. */
+ 1];
};
/*! Digested BC parameters. */
struct decoded_bc {
int transcapability;
int transmoderate;
int transmultiple;
int userl1;
int userl2;
int userl3;
int rateadaption;
};
/* q931_call datastructure */
struct q931_call {
struct pri *pri; /* D channel controller (master) */
struct q921_link *link; /* Q.921 link associated with this call. */
struct q931_call *next;
int cr; /* Call Reference */
/* Slotmap specified (bitmap of channels 31/24-1) (Channel Identifier IE) (-1 means not specified) */
int slotmap;
/* An explicit channel (Channel Identifier IE) (-1 means not specified) */
int channelno;
/* An explicit DS1 (-1 means not specified) */
int ds1no;
/* Whether or not the ds1 is explicitly identified or implicit. If implicit
the bchan is on the same span as the current active dchan (NFAS) */
int ds1explicit;
/* Channel flags (0 means none retrieved) */
int chanflags;
int alive; /* Whether or not the call is alive */
int acked; /* Whether setup has been acked or not */
int sendhangupack; /* Whether or not to send a hangup ack */
int proc; /* Whether we've sent a call proceeding / alerting */
int ri; /* Restart Indicator (Restart Indicator IE) */
/*! Bearer Capability */
struct decoded_bc bc;
/*!
* \brief TRUE if the call is a Call Independent Signalling connection.
* \note The call has no B channel associated with it. (Just signalling)
*/
int cis_call;
/*!
* \brief TRUE if we have recognized a use for this CIS call.
* \note An incoming CIS call will be immediately disconnected if not set.
* This is a safeguard against unhandled incoming CIS calls to protect the
* call reference pool.
*/
int cis_recognized;
/*! \brief TRUE if we will auto disconnect the cis_call we originated. */
int cis_auto_disconnect;
int progcode; /* Progress coding */
int progloc; /* Progress Location */
int progress; /* Progress indicator */
int progressmask; /* Progress Indicator bitmask */
int notify; /* Notification indicator. */
int causecode; /* Cause Coding */
int causeloc; /* Cause Location */
int cause; /* Cause of clearing */
enum Q931_CALL_STATE peercallstate; /* Call state of peer as reported */
enum Q931_CALL_STATE ourcallstate; /* Our call state */
enum Q931_CALL_STATE sugcallstate; /* Status call state */
int ani2; /* ANI II */
/*! Buffer for digits that come in KEYPAD_FACILITY */
char keypad_digits[32 + 1];
/*! Current dialed digits to be sent or just received. */
char overlap_digits[PRI_MAX_NUMBER_LEN];
/*!
* \brief Local party ID
* \details
* The Caller-ID and connected-line ID are just roles the local and remote party
* play while a call is being established. Which roll depends upon the direction
* of the call.
* Outgoing party info is to identify the local party to the other end.
* (Caller-ID for originated or connected-line for answered calls.)
* Incoming party info is to identify the remote party to us.
* (Caller-ID for answered or connected-line for originated calls.)
*/
struct q931_party_id local_id;
/*!
* \brief Remote party ID
* \details
* The Caller-ID and connected-line ID are just roles the local and remote party
* play while a call is being established. Which roll depends upon the direction
* of the call.
* Outgoing party info is to identify the local party to the other end.
* (Caller-ID for originated or connected-line for answered calls.)
* Incoming party info is to identify the remote party to us.
* (Caller-ID for answered or connected-line for originated calls.)
*/
struct q931_party_id remote_id;
/*! \brief Automatic Number Identification (ANI) */
struct q931_party_number ani;
/*!
* \brief Staging place for the Q.931 redirection number ie.
* \note
* The number could be the remote_id.number or redirecting.to.number
* depending upon the notification indicator.
*/
struct q931_party_number redirection_number;
/*!
* \brief Called party address.
* \note The called.number.str is the accumulated overlap dial digits
* and enbloc digits.
* \note The called.number.presentation value is not used.
*/
struct q931_party_address called;
int nonisdn;
int complete; /* no more digits coming */
int newcall; /* if the received message has a new call reference value */
int retranstimer; /* Timer for retransmitting DISC */
int t308_timedout; /* Whether t308 timed out once */
struct q931_party_redirecting redirecting;
/*! \brief Incoming call transfer state. */
enum INCOMING_CT_STATE incoming_ct_state;
/*! Call hold supplementary state. Valid on master call record only. */
enum Q931_HOLD_STATE hold_state;
/*! Call hold event timer. Valid on master call record only. */
int hold_timer;
int deflection_in_progress; /*!< CallDeflection for NT PTMP in progress. */
/*! TRUE if the connected number ie was in the current received message. */
int connected_number_in_message;
/*! TRUE if the redirecting number ie was in the current received message. */
int redirecting_number_in_message;
int useruserprotocoldisc;
char useruserinfo[256];
long aoc_units; /* Advice of Charge Units */
struct apdu_event *apdus; /* APDU queue for call */
int transferable; /* RLT call is transferable */
unsigned int rlt_call_id; /* RLT call id */
/*! ETSI Explicit Call Transfer link id. */
int link_id;
/*! TRUE if link_id is valid. */
int is_link_id_valid;
/* Bridged call info */
struct q931_call *bridged_call; /* Pointer to other leg of bridged call (Used by Q.SIG when eliminating tromboned calls) */
int changestatus; /* SERVICE message changestatus */
int reversecharge; /* Reverse charging indication:
-1 - No reverse charging
1 - Reverse charging
0,2-7 - Reserved for future use */
int t303_timer;
int t303_expirycnt;
int hangupinitiated;
/*! \brief TRUE if we broadcast this call's SETUP message. */
int outboundbroadcast;
int performing_fake_clearing;
/*!
* \brief Master call controlling this call.
* \note Always valid. Master and normal calls point to self.
*/
struct q931_call *master_call;
/* These valid in master call only */
struct q931_call *subcalls[Q931_MAX_TEI];
int pri_winner;
/* Call completion */
struct {
/*!
* \brief CC record associated with this call.
* \note
* CC signaling link or original call when cc-available indicated.
*/
struct pri_cc_record *record;
/*! Original calling party. */
struct q931_party_id party_a;
/*! Saved BC, HLC, and LLC from initial SETUP */
struct q931_saved_ie_contents saved_ie_contents;
/*! Only save the first of each BC, HLC, and LLC from the initial SETUP. */
unsigned char saved_ie_flags;
/*! TRUE if call needs to be hung up. */
unsigned char hangup_call;
/*! TRUE if we originated this call. */
unsigned char originated;
/*! TRUE if outgoing call was already redirected. */
unsigned char initially_redirected;
} cc;
/*! Display text ie contents. */
struct {
/*! Display ie text. NULL if not present or consumed as remote name. */
const char *text;
/*! Length of display text. */
unsigned char length;
/*!
* \brief Character set the text is using.
* \details
* unknown(0),
* iso8859-1(1),
* enum-value-withdrawn-by-ITU-T(2)
* iso8859-2(3),
* iso8859-3(4),
* iso8859-4(5),
* iso8859-5(6),
* iso8859-7(7),
* iso10646-BmpString(8),
* iso10646-utf-8String(9)
*/
unsigned char char_set;
} display;
/* AOC charge requesting on Setup */
int aoc_charging_request;
};
enum CC_STATES {
/*! CC is not active. */
CC_STATE_IDLE,
// /*! CC has recorded call information in anticipation of CC availability. */
// CC_STATE_RECORD_RETENTION,
/*! CC is available and waiting on ALERTING or DISCONNECT to go out. */
CC_STATE_PENDING_AVAILABLE,
/*! CC is available and waiting on possible CC request. */
CC_STATE_AVAILABLE,
/*! CC is requested to be activated and waiting on party B to acknowledge. */
CC_STATE_REQUESTED,
/*! CC is activated and waiting for party B to become available. */
CC_STATE_ACTIVATED,
/*! CC party B is available and waiting for status of party A. */
CC_STATE_B_AVAILABLE,
/*! CC is suspended because party A is not available. (Monitor party A.) */
CC_STATE_SUSPENDED,
/*! CC is waiting for party A to initiate CC callback. */
CC_STATE_WAIT_CALLBACK,
/*! CC callback in progress. */
CC_STATE_CALLBACK,
/*! CC is waiting for signaling link to be cleared before destruction. */
CC_STATE_WAIT_DESTRUCTION,
/*! Number of CC states. Must be last in enum. */
CC_STATE_NUM
};
enum CC_EVENTS {
/*! CC is available for the current call. */
CC_EVENT_AVAILABLE,
/*! Requesting CC activation. */
CC_EVENT_CC_REQUEST,
/*! Requesting CC activation accepted. */
CC_EVENT_CC_REQUEST_ACCEPT,
/*! Requesting CC activation failed (error/reject received). */
CC_EVENT_CC_REQUEST_FAIL,
/*! CC party B is available, party A is considered free. */
CC_EVENT_REMOTE_USER_FREE,
/*! CC party B is available, party A is busy or CCBS busy. */
CC_EVENT_B_FREE,
/*! Someone else responded to the CC recall. */
CC_EVENT_STOP_ALERTING,
/*! CC poll/prompt for party A status. */
CC_EVENT_A_STATUS,
/*! CC party A is free/available for recall. */
CC_EVENT_A_FREE,
/*! CC party A is busy/not-available for recall. */
CC_EVENT_A_BUSY,
/*! Suspend monitoring party B because party A is busy. */
CC_EVENT_SUSPEND,
/*! Resume monitoring party B because party A is now available. */
CC_EVENT_RESUME,
/*! This is the CC recall call attempt. */
CC_EVENT_RECALL,
/*! Link request to cancel/deactivate CC received. */
CC_EVENT_LINK_CANCEL,
/*! Tear down CC request from upper layer. */
CC_EVENT_CANCEL,
/*! Abnormal clearing of original call. (T309 processing/T309 timeout/TEI removal) */
CC_EVENT_INTERNAL_CLEARING,
/*! Received message indicating tear down of CC signaling link completed. */
CC_EVENT_SIGNALING_GONE,
/*! Delayed hangup request for the signaling link to allow subcmd events to be passed up. */
CC_EVENT_HANGUP_SIGNALING,
/*! Sent ALERTING message. */
CC_EVENT_MSG_ALERTING,
/*! Sent DISCONNECT message. */
CC_EVENT_MSG_DISCONNECT,
/*! Sent RELEASE message. */
CC_EVENT_MSG_RELEASE,
/*! Sent RELEASE_COMPLETE message. */
CC_EVENT_MSG_RELEASE_COMPLETE,
/*! T_ACTIVATE timer timed out. */
CC_EVENT_TIMEOUT_T_ACTIVATE,
#if 0
/*! T_DEACTIVATE timer timed out. */
CC_EVENT_TIMEOUT_T_DEACTIVATE,
/*! T_INTERROGATE timer timed out. */
CC_EVENT_TIMEOUT_T_INTERROGATE,
#endif
/*! T_RETENTION timer timed out. */
CC_EVENT_TIMEOUT_T_RETENTION,
/*! T-STATUS timer equivalent for CC user A status timed out. */
CC_EVENT_TIMEOUT_T_CCBS1,
/*! Timeout for valid party A status. */
CC_EVENT_TIMEOUT_EXTENDED_T_CCBS1,
/*! Max time the CCBS/CCNR service will be active. */
CC_EVENT_TIMEOUT_T_SUPERVISION,
/*! Max time to wait for user A to respond to user B availability. */
CC_EVENT_TIMEOUT_T_RECALL,
};
enum CC_PARTY_A_AVAILABILITY {
CC_PARTY_A_AVAILABILITY_INVALID,
CC_PARTY_A_AVAILABILITY_BUSY,
CC_PARTY_A_AVAILABILITY_FREE,
};
/* Invalid PTMP call completion reference and linkage id value. */
#define CC_PTMP_INVALID_ID 0xFF
/*! \brief Call-completion record */
struct pri_cc_record {
/*! Next call-completion record in the list */
struct pri_cc_record *next;
/*! D channel control structure. */
struct pri *ctrl;
/*! Original call that is offered CC availability. (NULL if no longer exists.) */
struct q931_call *original_call;
/*!
* \brief Associated signaling link. (NULL if not established.)
* \note
* PTMP - Broadcast dummy call reference call.
* (If needed, the TE side could use this pointer to locate its specific
* dummy call reference call.)
* \note
* PTP - REGISTER signaling link.
* \note
* Q.SIG - SETUP signaling link.
*/
struct q931_call *signaling;
/*! Call-completion record id (0 - 65535) */
long record_id;
/*! Call-completion state */
enum CC_STATES state;
/*! Original calling party. */
struct q931_party_id party_a;
/*! Original called party. */
struct q931_party_address party_b;
/*! Saved BC, HLC, and LLC from initial SETUP */
struct q931_saved_ie_contents saved_ie_contents;
/*! Saved decoded BC */
struct decoded_bc bc;
/*! FSM parameters. */
union {
/*! PTMP FSM parameters. */
struct {
/*! Extended T_CCBS1 timer id for CCBSStatusRequest handling. */
int extended_t_ccbs1;
/*! Invoke id for the CCBSStatusRequest message to find if T_CCBS1 still running. */
int t_ccbs1_invoke_id;
/*! Number of times party A status request got no responses. */
int party_a_status_count;
/*! Accumulating party A availability status */
enum CC_PARTY_A_AVAILABILITY party_a_status_acc;
} ptmp;
/*! PTP FSM parameters. */
struct {
} ptp;
struct {
/*! Q.931 message type the current message event came in on. */
int msgtype;
} qsig;
} fsm;
/*! Received message parameters of interest. */
union {
/*! cc-request error/reject response */
struct {
/*! enum APDU_CALLBACK_REASON reason */
int reason;
/*! MSG_ERROR/MSG_REJECT fail code. */
int code;
} cc_req_rsp;
} msg;
/*! Party A availability status */
enum CC_PARTY_A_AVAILABILITY party_a_status;
/*! Indirect timer id to abort indirect action events. */
int t_indirect;
/*!
* \brief PTMP T_RETENTION timer id.
* \note
* This timer is used by all CC agents to implement
* the Asterisk CC core offer timer.
*/
int t_retention;
/*!
* \brief CC service supervision timer.
*
* \details
* This timer is one of the following timer id's depending upon
* switch type and CC mode:
* PTMP - T_CCBS2/T_CCNR2,
* PTP - T_CCBS5/T_CCNR5/T_CCBS6/T_CCNR6,
* Q.SIG - QSIG_CCBS_T2/QSIG_CCNR_T2
*/
int t_supervision;
/*!
* \brief Party A response to B availability for recall timer.
* \details
* This timer is one of the following timer id's:
* PTMP - T_CCBS3
* Q.SIG - QSIG_CC_T3
*/
int t_recall;
/*! Invoke id for the cc-request message to find if T_ACTIVATE/QSIG_CC_T1 still running. */
int t_activate_invoke_id;
/*! Pending response information. */
struct {
/*!
* \brief Send response on this signaling link.
* \note Used by PTMP for CCBSRequest/CCNRRequest/CCBSCall responses.
* \note Used by Q.SIG for ccRingout responses.
*/
struct q931_call *signaling;
/*! Invoke operation code */
int invoke_operation;
/*! Invoke id to use in the pending response. */
short invoke_id;
} response;
/*! TRUE if the call-completion FSM has completed and this record needs to be destroyed. */
unsigned char fsm_complete;
/*! TRUE if we are a call completion agent. */
unsigned char is_agent;
/*! TRUE if active cc mode is CCNR. */
unsigned char is_ccnr;
/*! PTMP pre-activation reference id. (0-127) */
unsigned char call_linkage_id;
/*! PTMP active CCBS reference id. (0-127) */
unsigned char ccbs_reference_id;
/*! Negotiated options */
struct {
/*! PTMP recall mode: globalRecall(0), specificRecall(1) */
unsigned char recall_mode;
/*! TRUE if negotiated for Q.SIG signaling link to be retained. */
unsigned char retain_signaling_link;
#if defined(QSIG_PATH_RESERVATION_SUPPORT)
/*! Q.SIG TRUE if can do path reservation. */
unsigned char do_path_reservation;
#endif /* defined(QSIG_PATH_RESERVATION_SUPPORT) */
} option;
};
/*! D channel control structure with associated dummy call reference record. */
struct d_ctrl_dummy {
/*! D channel control structure. Must be first in the structure. */
struct pri ctrl;
/*! Dummy call reference call record. */
struct q931_call dummy_call;
};
/*! Layer 2 link control structure with associated dummy call reference record. */
struct link_dummy {
/*! Layer 2 control structure. Must be first in the structure. */
struct q921_link link;
/*! Dummy call reference call record. */
struct q931_call dummy_call;
};
/*!
* \brief Check if the given call ptr is valid and gripe if not.
*
* \param ctrl D channel controller.
* \param call Q.931 call leg.
*
* \retval TRUE if call ptr is valid.
* \retval FALSE if call ptr is invalid.
*/
#define pri_is_call_valid(ctrl, call) \
q931_is_call_valid_gripe(ctrl, call, __PRETTY_FUNCTION__, __LINE__)
int q931_is_call_valid(struct pri *ctrl, struct q931_call *call);
int q931_is_call_valid_gripe(struct pri *ctrl, struct q931_call *call, const char *func_name, unsigned long func_line);
unsigned pri_schedule_event(struct pri *ctrl, int ms, void (*function)(void *data), void *data);
extern pri_event *pri_schedule_run(struct pri *pri);
void pri_schedule_del(struct pri *ctrl, unsigned id);
int pri_schedule_check(struct pri *ctrl, unsigned id, void (*function)(void *data), void *data);
extern pri_event *pri_mkerror(struct pri *pri, char *errstr);
void pri_message(struct pri *ctrl, const char *fmt, ...) __attribute__((format(printf, 2, 3)));
void pri_error(struct pri *ctrl, const char *fmt, ...) __attribute__((format(printf, 2, 3)));
void libpri_copy_string(char *dst, const char *src, size_t size);
void pri_link_destroy(struct q921_link *link);
struct q921_link *pri_link_new(struct pri *ctrl, int sapi, int tei);
void q931_init_call_record(struct q921_link *link, struct q931_call *call, int cr);
void pri_sr_init(struct pri_sr *req);
void q931_party_name_init(struct q931_party_name *name);
void q931_party_number_init(struct q931_party_number *number);
void q931_party_subaddress_init(struct q931_party_subaddress *subaddr);
void q931_party_address_init(struct q931_party_address *address);
void q931_party_id_init(struct q931_party_id *id);
void q931_party_redirecting_init(struct q931_party_redirecting *redirecting);
static inline void q931_party_address_to_id(struct q931_party_id *id, const struct q931_party_address *address)
{
id->number = address->number;
id->subaddress = address->subaddress;
}
static inline void q931_party_id_to_address(struct q931_party_address *address, const struct q931_party_id *id)
{
address->number = id->number;
address->subaddress = id->subaddress;
}
int q931_party_name_cmp(const struct q931_party_name *left, const struct q931_party_name *right);
int q931_party_number_cmp(const struct q931_party_number *left, const struct q931_party_number *right);
int q931_party_subaddress_cmp(const struct q931_party_subaddress *left, const struct q931_party_subaddress *right);
int q931_party_address_cmp(const struct q931_party_address *left, const struct q931_party_address *right);
int q931_party_id_cmp(const struct q931_party_id *left, const struct q931_party_id *right);
int q931_party_id_cmp_address(const struct q931_party_id *left, const struct q931_party_id *right);
int q931_cmp_party_id_to_address(const struct q931_party_id *id, const struct q931_party_address *address);
void q931_party_id_copy_to_address(struct q931_party_address *address, const struct q931_party_id *id);
void q931_party_name_copy_to_pri(struct pri_party_name *pri_name, const struct q931_party_name *q931_name);
void q931_party_number_copy_to_pri(struct pri_party_number *pri_number, const struct q931_party_number *q931_number);
void q931_party_subaddress_copy_to_pri(struct pri_party_subaddress *pri_subaddress, const struct q931_party_subaddress *q931_subaddress);
void q931_party_address_copy_to_pri(struct pri_party_address *pri_address, const struct q931_party_address *q931_address);
void q931_party_id_copy_to_pri(struct pri_party_id *pri_id, const struct q931_party_id *q931_id);
void q931_party_redirecting_copy_to_pri(struct pri_party_redirecting *pri_redirecting, const struct q931_party_redirecting *q931_redirecting);
void pri_copy_party_name_to_q931(struct q931_party_name *q931_name, const struct pri_party_name *pri_name);
void pri_copy_party_number_to_q931(struct q931_party_number *q931_number, const struct pri_party_number *pri_number);
void pri_copy_party_subaddress_to_q931(struct q931_party_subaddress *q931_subaddress, const struct pri_party_subaddress *pri_subaddress);
void pri_copy_party_id_to_q931(struct q931_party_id *q931_id, const struct pri_party_id *pri_id);
void q931_party_id_fixup(const struct pri *ctrl, struct q931_party_id *id);
int q931_party_id_presentation(const struct q931_party_id *id);
int q931_display_name_get(struct q931_call *call, struct q931_party_name *name);
int q931_display_text(struct pri *ctrl, struct q931_call *call, const struct pri_subcmd_display_txt *display);
int q931_facility_display_name(struct pri *ctrl, struct q931_call *call, const struct q931_party_name *name);
const char *q931_call_state_str(enum Q931_CALL_STATE callstate);
const char *msg2str(int msg);
struct q931_call *q931_find_winning_call(struct q931_call *call);
int q931_master_pass_event(struct pri *ctrl, struct q931_call *subcall, int msg_type);
struct pri_subcommand *q931_alloc_subcommand(struct pri *ctrl);
struct q931_call *q931_find_link_id_call(struct pri *ctrl, int link_id);
struct q931_call *q931_find_held_active_call(struct pri *ctrl, struct q931_call *held_call);
int q931_request_subaddress(struct pri *ctrl, struct q931_call *call, int notify, const struct q931_party_name *name, const struct q931_party_number *number);
int q931_subaddress_transfer(struct pri *ctrl, struct q931_call *call);
int q931_notify_redirection(struct pri *ctrl, struct q931_call *call, int notify, const struct q931_party_name *name, const struct q931_party_number *number);
struct pri_cc_record *pri_cc_find_by_reference(struct pri *ctrl, unsigned reference_id);
struct pri_cc_record *pri_cc_find_by_linkage(struct pri *ctrl, unsigned linkage_id);
struct pri_cc_record *pri_cc_find_by_addressing(struct pri *ctrl, const struct q931_party_address *party_a, const struct q931_party_address *party_b, unsigned length, const unsigned char *q931_ies);
struct pri_cc_record *pri_cc_new_record(struct pri *ctrl, q931_call *call);
void pri_cc_qsig_determine_available(struct pri *ctrl, q931_call *call);
int pri_cc_event(struct pri *ctrl, q931_call *call, struct pri_cc_record *cc_record, enum CC_EVENTS event);
int q931_cc_timeout(struct pri *ctrl, struct pri_cc_record *cc_record, enum CC_EVENTS event);
void q931_cc_indirect(struct pri *ctrl, struct pri_cc_record *cc_record, void (*func)(struct pri *ctrl, q931_call *call, struct pri_cc_record *cc_record));
/*!
* \brief Get the NFAS master PRI control structure.
*
* \param ctrl D channel controller.
*
* \return NFAS master PRI control structure.
*/
static inline struct pri *PRI_NFAS_MASTER(struct pri *ctrl)
{
if (ctrl->master) {
ctrl = ctrl->master;
}
return ctrl;
}
/*!
* \brief Determine if layer 2 is in BRI NT PTMP mode.
*
* \param ctrl D channel controller.
*
* \retval TRUE if in BRI NT PTMP mode.
* \retval FALSE otherwise.
*/
static inline int BRI_NT_PTMP(const struct pri *ctrl)
{
struct pri *my_ctrl = (struct pri *) ctrl;
return my_ctrl->bri && my_ctrl->localtype == PRI_NETWORK
&& my_ctrl->link.tei == Q921_TEI_GROUP;
}
/*!
* \brief Determine if layer 2 is in BRI TE PTMP mode.
*
* \param ctrl D channel controller.
*
* \retval TRUE if in BRI TE PTMP mode.
* \retval FALSE otherwise.
*/
static inline int BRI_TE_PTMP(const struct pri *ctrl)
{
struct pri *my_ctrl = (struct pri *) ctrl;
return my_ctrl->bri && my_ctrl->localtype == PRI_CPE
&& my_ctrl->link.tei == Q921_TEI_GROUP;
}
/*!
* \brief Determine if layer 2 is in NT mode.
*
* \param ctrl D channel controller.
*
* \retval TRUE if in NT mode.
* \retval FALSE otherwise.
*/
static inline int NT_MODE(const struct pri *ctrl)
{
struct pri *my_ctrl = (struct pri *) ctrl;
return my_ctrl->localtype == PRI_NETWORK;
}
/*!
* \brief Determine if layer 2 is in TE mode.
*
* \param ctrl D channel controller.
*
* \retval TRUE if in TE mode.
* \retval FALSE otherwise.
*/
static inline int TE_MODE(const struct pri *ctrl)
{
struct pri *my_ctrl = (struct pri *) ctrl;
return my_ctrl->localtype == PRI_CPE;
}
/*!
* \brief Determine if layer 2 is in PTP mode.
*
* \param ctrl D channel controller.
*
* \retval TRUE if in PTP mode.
* \retval FALSE otherwise.
*/
static inline int PTP_MODE(const struct pri *ctrl)
{
struct pri *my_ctrl = (struct pri *) ctrl;
return my_ctrl->link.tei == Q921_TEI_PRI;
}
/*!
* \brief Determine if layer 2 is in PTMP mode.
*
* \param ctrl D channel controller.
*
* \retval TRUE if in PTMP mode.
* \retval FALSE otherwise.
*/
static inline int PTMP_MODE(const struct pri *ctrl)
{
struct pri *my_ctrl = (struct pri *) ctrl;
return my_ctrl->link.tei == Q921_TEI_GROUP;
}
#define Q931_DUMMY_CALL_REFERENCE -1
#define Q931_CALL_REFERENCE_FLAG 0x8000 /* Identify which end allocted the CR. */
/*!
* \brief Deterimine if the given call control pointer is a dummy call.
*
* \retval TRUE if given call is a dummy call.
* \retval FALSE otherwise.
*/
static inline int q931_is_dummy_call(const struct q931_call *call)
{
return (call->cr == Q931_DUMMY_CALL_REFERENCE) ? 1 : 0;
}
static inline short get_invokeid(struct pri *ctrl)
{
return ++ctrl->last_invoke;
}
#endif