Bug #5877

[asterisk/asterisk.git] / channels / chan_zap.c

/*
 * Asterisk -- An open source telephony toolkit.
 *
 * Copyright (C) 1999 - 2005, Digium, Inc.
 *
 * Mark Spencer <markster@digium.com>
 *
 * 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. See the LICENSE file
 * at the top of the source tree.
 */

/*! \file
 *
 * \brief Zaptel Pseudo TDM interface 
 * 
 * Connects to the zaptel telephony library as well as 
 * libpri. Libpri is optional and needed only if you are
 * going to use ISDN connections.
 *
 * You need to install libraries before you attempt to compile
 * and install the zaptel channel.
 *
 * \par See also
 * \arg \ref Config_zap
 *
 * \ingroup channel_drivers
 */

#include <stdio.h>
#include <string.h>
#ifdef __NetBSD__
#include <pthread.h>
#include <signal.h>
#else
#include <sys/signal.h>
#endif
#include <errno.h>
#include <stdlib.h>
#if !defined(SOLARIS) && !defined(__FreeBSD__)
#include <stdint.h>
#endif
#include <unistd.h>
#include <sys/ioctl.h>
#ifdef __linux__
#include <linux/zaptel.h>
#else
#include <zaptel.h>
#endif /* __linux__ */
#include <math.h>
#include <tonezone.h>
#include <ctype.h>
#ifdef ZAPATA_PRI
#include <libpri.h>
#ifndef PRI_KEYPAD_FACILITY_TX
#error "You need newer libpri"
#endif
#endif
#ifdef ZAPATA_R2
#include <libmfcr2.h>
#endif

#include "asterisk.h"

ASTERISK_FILE_VERSION(__FILE__, "$Revision$")

#include "asterisk/lock.h"
#include "asterisk/channel.h"
#include "asterisk/config.h"
#include "asterisk/logger.h"
#include "asterisk/module.h"
#include "asterisk/pbx.h"
#include "asterisk/options.h"
#include "asterisk/file.h"
#include "asterisk/ulaw.h"
#include "asterisk/alaw.h"
#include "asterisk/callerid.h"
#include "asterisk/adsi.h"
#include "asterisk/cli.h"
#include "asterisk/cdr.h"
#include "asterisk/features.h"
#include "asterisk/musiconhold.h"
#include "asterisk/say.h"
#include "asterisk/tdd.h"
#include "asterisk/app.h"
#include "asterisk/dsp.h"
#include "asterisk/astdb.h"
#include "asterisk/manager.h"
#include "asterisk/causes.h"
#include "asterisk/term.h"
#include "asterisk/utils.h"
#include "asterisk/transcap.h"

#ifndef ZT_SIG_EM_E1
#error "Your zaptel is too old.  please cvs update"
#endif

#ifndef ZT_TONEDETECT
/* Work around older code with no tone detect */
#define ZT_EVENT_DTMFDOWN 0
#define ZT_EVENT_DTMFUP 0
#endif

/*! 
 * \note Define ZHONE_HACK to cause us to go off hook and then back on hook when
 * the user hangs up to reset the state machine so ring works properly.
 * This is used to be able to support kewlstart by putting the zhone in
 * groundstart mode since their forward disconnect supervision is entirely
 * broken even though their documentation says it isn't and their support
 * is entirely unwilling to provide any assistance with their channel banks
 * even though their web site says they support their products for life.
 */
/* #define ZHONE_HACK */

/*! \note
 * Define if you want to check the hook state for an FXO (FXS signalled) interface
 * before dialing on it.  Certain FXO interfaces always think they're out of
 * service with this method however.
 */
/* #define ZAP_CHECK_HOOKSTATE */

/*! \brief Typically, how many rings before we should send Caller*ID */
#define DEFAULT_CIDRINGS 1

#define CHANNEL_PSEUDO -12

#define AST_LAW(p) (((p)->law == ZT_LAW_ALAW) ? AST_FORMAT_ALAW : AST_FORMAT_ULAW)

/*! \brief Signaling types that need to use MF detection should be placed in this macro */
#define NEED_MFDETECT(p) (((p)->sig == SIG_FEATDMF) || ((p)->sig == SIG_FEATDMF_TA) || ((p)->sig == SIG_E911) || ((p)->sig == SIG_FEATB)) 

static const char desc[] = "Zapata Telephony"
#ifdef ZAPATA_PRI
               " w/PRI"
#endif
#ifdef ZAPATA_R2
               " w/R2"
#endif
;

static const char tdesc[] = "Zapata Telephony Driver"
#ifdef ZAPATA_PRI
               " w/PRI"
#endif
#ifdef ZAPATA_R2
               " w/R2"
#endif
;

static const char type[] = "Zap";
static const char config[] = "zapata.conf";

#define SIG_EM          ZT_SIG_EM
#define SIG_EMWINK      (0x0100000 | ZT_SIG_EM)
#define SIG_FEATD       (0x0200000 | ZT_SIG_EM)
#define SIG_FEATDMF     (0x0400000 | ZT_SIG_EM)
#define SIG_FEATB       (0x0800000 | ZT_SIG_EM)
#define SIG_E911        (0x1000000 | ZT_SIG_EM)
#define SIG_FEATDMF_TA  (0x2000000 | ZT_SIG_EM)
#define SIG_FXSLS       ZT_SIG_FXSLS
#define SIG_FXSGS       ZT_SIG_FXSGS
#define SIG_FXSKS       ZT_SIG_FXSKS
#define SIG_FXOLS       ZT_SIG_FXOLS
#define SIG_FXOGS       ZT_SIG_FXOGS
#define SIG_FXOKS       ZT_SIG_FXOKS
#define SIG_PRI         ZT_SIG_CLEAR
#define SIG_R2          ZT_SIG_CAS
#define SIG_SF          ZT_SIG_SF
#define SIG_SFWINK      (0x0100000 | ZT_SIG_SF)
#define SIG_SF_FEATD    (0x0200000 | ZT_SIG_SF)
#define SIG_SF_FEATDMF  (0x0400000 | ZT_SIG_SF)
#define SIG_SF_FEATB    (0x0800000 | ZT_SIG_SF)
#define SIG_EM_E1       ZT_SIG_EM_E1
#define SIG_GR303FXOKS  (0x0100000 | ZT_SIG_FXOKS)
#define SIG_GR303FXSKS  (0x0100000 | ZT_SIG_FXSKS)

#define NUM_SPANS               32
#define NUM_DCHANS              4       /*!< No more than 4 d-channels */
#define MAX_CHANNELS    672             /*!< No more than a DS3 per trunk group */

#define CHAN_PSEUDO     -2

#define DCHAN_PROVISIONED (1 << 0)
#define DCHAN_NOTINALARM  (1 << 1)
#define DCHAN_UP          (1 << 2)

#define DCHAN_AVAILABLE (DCHAN_PROVISIONED | DCHAN_NOTINALARM | DCHAN_UP)

static char context[AST_MAX_CONTEXT] = "default";
static char cid_num[256] = "";
static char cid_name[256] = "";
static char defaultcic[64] = "";
static char defaultozz[64] = "";

static char language[MAX_LANGUAGE] = "";
static char musicclass[MAX_MUSICCLASS] = "";
static char progzone[10]= "";

static int usedistinctiveringdetection = 0;

static int transfertobusy = 1;

static int use_callerid = 1;
static int cid_signalling = CID_SIG_BELL;
static int cid_start = CID_START_RING;
static int zaptrcallerid = 0;
static int cur_signalling = -1;

static ast_group_t cur_group = 0;
static ast_group_t cur_callergroup = 0;
static ast_group_t cur_pickupgroup = 0;
static int relaxdtmf = 0;

static int immediate = 0;

static int stripmsd = 0;

static int callwaiting = 0;

static int callwaitingcallerid = 0;

static int hidecallerid = 0;

static int restrictcid = 0;

static int use_callingpres = 0;

static int callreturn = 0;

static int threewaycalling = 0;

static int transfer = 0;

static int canpark = 0;

static int cancallforward = 0;

static float rxgain = 0.0;

static float txgain = 0.0;

static int tonezone = -1;

static int echocancel;

static int echotraining;

static int pulse;

static int echocanbridged = 0;

static int busydetect = 0;

static int busycount = 3;
static int busy_tonelength = 0;
static int busy_quietlength = 0;

static int callprogress = 0;

static char accountcode[AST_MAX_ACCOUNT_CODE] = "";

static char mailbox[AST_MAX_EXTENSION];

static int amaflags = 0;

static int adsi = 0;

static int numbufs = 4;

static int cur_prewink = -1;
static int cur_preflash = -1;
static int cur_wink = -1;
static int cur_flash = -1;
static int cur_start = -1;
static int cur_rxwink = -1;
static int cur_rxflash = -1;
static int cur_debounce = -1;
static int cur_priexclusive = 0;

static int priindication_oob = 0;

#ifdef ZAPATA_PRI
static int minunused = 2;
static int minidle = 0;
static char idleext[AST_MAX_EXTENSION];
static char idledial[AST_MAX_EXTENSION];
static int overlapdial = 0;
static int facilityenable = 0;
static char internationalprefix[10] = "";
static char nationalprefix[10] = "";
static char localprefix[20] = "";
static char privateprefix[20] = "";
static char unknownprefix[20] = "";
static long resetinterval = 3600;       /*!< How often (in seconds) to reset unused channels. Default 1 hour. */
static struct ast_channel inuse = { "GR-303InUse" };
#ifdef PRI_GETSET_TIMERS
static int pritimers[PRI_MAX_TIMERS];
#endif
static int pridebugfd = -1;
static char pridebugfilename[1024]="";
#endif

/*! \brief Wait up to 16 seconds for first digit (FXO logic) */
static int firstdigittimeout = 16000;

/*! \brief How long to wait for following digits (FXO logic) */
static int gendigittimeout = 8000;

/*! \brief How long to wait for an extra digit, if there is an ambiguous match */
static int matchdigittimeout = 3000;

static int usecnt =0;
AST_MUTEX_DEFINE_STATIC(usecnt_lock);

/*! \brief Protect the interface list (of zt_pvt's) */
AST_MUTEX_DEFINE_STATIC(iflock);


static int ifcount = 0;

#ifdef ZAPATA_PRI
AST_MUTEX_DEFINE_STATIC(pridebugfdlock);
#endif

/*! \brief Whether we answer on a Polarity Switch event */
static int answeronpolarityswitch = 0;

/*! \brief Whether we hang up on a Polarity Switch event */
static int hanguponpolarityswitch = 0;

/*! \brief How long (ms) to ignore Polarity Switch events after we answer a call */
static int polarityonanswerdelay = 600;

/*! \brief When to send the CallerID signals (rings) */
static int sendcalleridafter = DEFAULT_CIDRINGS;

/*! \brief Protect the monitoring thread, so only one process can kill or start it, and not
   when it's doing something critical. */
AST_MUTEX_DEFINE_STATIC(monlock);

/*! \brief This is the thread for the monitor which checks for input on the channels
   which are not currently in use.  */
static pthread_t monitor_thread = AST_PTHREADT_NULL;

static int restart_monitor(void);

static enum ast_bridge_result zt_bridge(struct ast_channel *c0, struct ast_channel *c1, int flags, struct ast_frame **fo, struct ast_channel **rc, int timeoutms);

static int zt_sendtext(struct ast_channel *c, const char *text);

/*! \brief Avoid the silly zt_getevent which ignores a bunch of events */
static inline int zt_get_event(int fd)
{
        int j;
        if (ioctl(fd, ZT_GETEVENT, &j) == -1) return -1;
        return j;
}

/*! \brief Avoid the silly zt_waitevent which ignores a bunch of events */
static inline int zt_wait_event(int fd)
{
        int i,j=0;
        i = ZT_IOMUX_SIGEVENT;
        if (ioctl(fd, ZT_IOMUX, &i) == -1) return -1;
        if (ioctl(fd, ZT_GETEVENT, &j) == -1) return -1;
        return j;
}

/*! Chunk size to read -- we use 20ms chunks to make things happy.  */   
#define READ_SIZE 160

#define MASK_AVAIL              (1 << 0)        /*!< Channel available for PRI use */
#define MASK_INUSE              (1 << 1)        /*!< Channel currently in use */

#define CALLWAITING_SILENT_SAMPLES      ( (300 * 8) / READ_SIZE) /*!< 300 ms */
#define CALLWAITING_REPEAT_SAMPLES      ( (10000 * 8) / READ_SIZE) /*!< 300 ms */
#define CIDCW_EXPIRE_SAMPLES            ( (500 * 8) / READ_SIZE) /*!< 500 ms */
#define MIN_MS_SINCE_FLASH                      ( (2000) )      /*!< 2000 ms */
#define DEFAULT_RINGT                           ( (8000 * 8) / READ_SIZE)

struct zt_pvt;


#ifdef ZAPATA_R2
static int r2prot = -1;
#endif

static int ringt_base = DEFAULT_RINGT;

#ifdef ZAPATA_PRI

#define PVT_TO_CHANNEL(p) (((p)->prioffset) | ((p)->logicalspan << 8) | (p->pri->mastertrunkgroup ? 0x10000 : 0))
#define PRI_CHANNEL(p) ((p) & 0xff)
#define PRI_SPAN(p) (((p) >> 8) & 0xff)
#define PRI_EXPLICIT(p) (((p) >> 16) & 0x01)

struct zt_pri {
        pthread_t master;                                               /*!< Thread of master */
        ast_mutex_t lock;                                               /*!< Mutex */
        char idleext[AST_MAX_EXTENSION];                                /*!< Where to idle extra calls */
        char idlecontext[AST_MAX_CONTEXT];                              /*!< What context to use for idle */
        char idledial[AST_MAX_EXTENSION];                               /*!< What to dial before dumping */
        int minunused;                                                  /*!< Min # of channels to keep empty */
        int minidle;                                                    /*!< Min # of "idling" calls to keep active */
        int nodetype;                                                   /*!< Node type */
        int switchtype;                                                 /*!< Type of switch to emulate */
        int nsf;                                                        /*!< Network-Specific Facilities */
        int dialplan;                                                   /*!< Dialing plan */
        int localdialplan;                                              /*!< Local dialing plan */
        char internationalprefix[10];                                   /*!< country access code ('00' for european dialplans) */
        char nationalprefix[10];                                        /*!< area access code ('0' for european dialplans) */
        char localprefix[20];                                           /*!< area access code + area code ('0'+area code for european dialplans) */
        char privateprefix[20];                                         /*!< for private dialplans */
        char unknownprefix[20];                                         /*!< for unknown dialplans */
        int dchannels[NUM_DCHANS];                                      /*!< What channel are the dchannels on */
        int trunkgroup;                                                 /*!< What our trunkgroup is */
        int mastertrunkgroup;                                           /*!< What trunk group is our master */
        int prilogicalspan;                                             /*!< Logical span number within trunk group */
        int numchans;                                                   /*!< Num of channels we represent */
        int overlapdial;                                                /*!< In overlap dialing mode */
        int facilityenable;                                             /*!< Enable facility IEs */
        struct pri *dchans[NUM_DCHANS];                                 /*!< Actual d-channels */
        int dchanavail[NUM_DCHANS];                                     /*!< Whether each channel is available */
        struct pri *pri;                                                /*!< Currently active D-channel */
        int debug;
        int fds[NUM_DCHANS];                                            /*!< FD's for d-channels */
        int offset;
        int span;
        int resetting;
        int resetpos;
        time_t lastreset;                                               /*!< time when unused channels were last reset */
        long resetinterval;                                             /*!< Interval (in seconds) for resetting unused channels */
        struct zt_pvt *pvts[MAX_CHANNELS];                              /*!< Member channel pvt structs */
        struct zt_pvt *crvs;                                            /*!< Member CRV structs */
        struct zt_pvt *crvend;                                          /*!< Pointer to end of CRV structs */
};


static struct zt_pri pris[NUM_SPANS];

static int pritype = PRI_CPE;

#if 0
#define DEFAULT_PRI_DEBUG (PRI_DEBUG_Q931_DUMP | PRI_DEBUG_Q921_DUMP | PRI_DEBUG_Q921_RAW | PRI_DEBUG_Q921_STATE)
#else
#define DEFAULT_PRI_DEBUG 0
#endif

static inline void pri_rel(struct zt_pri *pri)
{
        ast_mutex_unlock(&pri->lock);
}

static int switchtype = PRI_SWITCH_NI2;
static int nsf = PRI_NSF_NONE;
static int dialplan = PRI_NATIONAL_ISDN + 1;
static int localdialplan = PRI_NATIONAL_ISDN + 1;

#else
/*! Shut up the compiler */
struct zt_pri;
#endif

#define SUB_REAL        0                       /*!< Active call */
#define SUB_CALLWAIT    1                       /*!< Call-Waiting call on hold */
#define SUB_THREEWAY    2                       /*!< Three-way call */

/* Polarity states */
#define POLARITY_IDLE   0
#define POLARITY_REV    1


static struct zt_distRings drings;

struct distRingData {
        int ring[3];
};
struct ringContextData {
        char contextData[AST_MAX_CONTEXT];
};
struct zt_distRings {
        struct distRingData ringnum[3];
        struct ringContextData ringContext[3];
};

static char *subnames[] = {
        "Real",
        "Callwait",
        "Threeway"
};

struct zt_subchannel {
        int zfd;
        struct ast_channel *owner;
        int chan;
        short buffer[AST_FRIENDLY_OFFSET/2 + READ_SIZE];
        struct ast_frame f;             /*!< One frame for each channel.  How did this ever work before? */
        unsigned int needringing:1;
        unsigned int needbusy:1;
        unsigned int needcongestion:1;
        unsigned int needcallerid:1;
        unsigned int needanswer:1;
        unsigned int needflash:1;
        unsigned int linear:1;
        unsigned int inthreeway:1;
        ZT_CONFINFO curconf;
};

#define CONF_USER_REAL          (1 << 0)
#define CONF_USER_THIRDCALL     (1 << 1)

#define MAX_SLAVES      4

static struct zt_pvt {
        ast_mutex_t lock;
        struct ast_channel *owner;                      /*!< Our current active owner (if applicable) */
                                                        /*!< Up to three channels can be associated with this call */
                
        struct zt_subchannel sub_unused;                /*!< Just a safety precaution */
        struct zt_subchannel subs[3];                   /*!< Sub-channels */
        struct zt_confinfo saveconf;                    /*!< Saved conference info */

        struct zt_pvt *slaves[MAX_SLAVES];              /*!< Slave to us (follows our conferencing) */
        struct zt_pvt *master;                          /*!< Master to us (we follow their conferencing) */
        int inconference;                               /*!< If our real should be in the conference */
        
        int sig;                                        /*!< Signalling style */
        int radio;                                      /*!< radio type */
        float rxgain;
        float txgain;
        int tonezone;                                   /*!< tone zone for this chan, or -1 for default */
        struct zt_pvt *next;                            /*!< Next channel in list */
        struct zt_pvt *prev;                            /*!< Prev channel in list */

        /* flags */
        unsigned int adsi:1;
        unsigned int answeronpolarityswitch:1;
        unsigned int busydetect:1;
        unsigned int callreturn:1;
        unsigned int callwaiting:1;
        unsigned int callwaitingcallerid:1;
        unsigned int cancallforward:1;
        unsigned int canpark:1;
        unsigned int confirmanswer:1;                   /*!< Wait for '#' to confirm answer */
        unsigned int destroy:1;
        unsigned int didtdd:1;                          /*!< flag to say its done it once */
        unsigned int dialednone:1;
        unsigned int dialing:1;
        unsigned int digital:1;
        unsigned int dnd:1;
        unsigned int echobreak:1;
        unsigned int echocanbridged:1;
        unsigned int echocanon:1;
        unsigned int faxhandled:1;                      /*!< Has a fax tone already been handled? */
        unsigned int firstradio:1;
        unsigned int hanguponpolarityswitch:1;
        unsigned int hardwaredtmf:1;
        unsigned int hidecallerid;
        unsigned int ignoredtmf:1;
        unsigned int immediate:1;                       /*!< Answer before getting digits? */
        unsigned int inalarm:1;
        unsigned int mate:1;                            /*!< flag to say its in MATE mode */
        unsigned int outgoing:1;
        unsigned int overlapdial:1;
        unsigned int permcallwaiting:1;
        unsigned int permhidecallerid:1;                /*!< Whether to hide our outgoing caller ID or not */
        unsigned int priindication_oob:1;
        unsigned int priexclusive:1;
        unsigned int pulse:1;
        unsigned int pulsedial:1;                       /*!< whether a pulse dial phone is detected */
        unsigned int restrictcid:1;                     /*!< Whether restrict the callerid -> only send ANI */
        unsigned int threewaycalling:1;
        unsigned int transfer:1;
        unsigned int use_callerid:1;                    /*!< Whether or not to use caller id on this channel */
        unsigned int use_callingpres:1;                 /*!< Whether to use the callingpres the calling switch sends */
        unsigned int usedistinctiveringdetection:1;
        unsigned int zaptrcallerid:1;                   /*!< should we use the callerid from incoming call on zap transfer or not */
        unsigned int transfertobusy:1;                  /*!< allow flash-transfers to busy channels */
#if defined(ZAPATA_PRI)
        unsigned int alerting:1;
        unsigned int alreadyhungup:1;
        unsigned int isidlecall:1;
        unsigned int proceeding:1;
        unsigned int progress:1;
        unsigned int resetting:1;
        unsigned int setup_ack:1;
#endif
#if defined(ZAPATA_R2)
        unsigned int hasr2call:1;
        unsigned int r2blocked:1;
        unsigned int sigchecked:1;
#endif

        struct zt_distRings drings;

        char context[AST_MAX_CONTEXT];
        char defcontext[AST_MAX_CONTEXT];
        char exten[AST_MAX_EXTENSION];
        char language[MAX_LANGUAGE];
        char musicclass[MAX_MUSICCLASS];
#ifdef PRI_ANI
        char cid_ani[AST_MAX_EXTENSION];
#endif
        char cid_num[AST_MAX_EXTENSION];
        int cid_ton;                                    /*!< Type Of Number (TON) */
        char cid_name[AST_MAX_EXTENSION];
        char lastcid_num[AST_MAX_EXTENSION];
        char lastcid_name[AST_MAX_EXTENSION];
        char *origcid_num;                              /*!< malloced original callerid */
        char *origcid_name;                             /*!< malloced original callerid */
        char callwait_num[AST_MAX_EXTENSION];
        char callwait_name[AST_MAX_EXTENSION];
        char rdnis[AST_MAX_EXTENSION];
        char dnid[AST_MAX_EXTENSION];
        unsigned int group;
        int law;
        int confno;                                     /*!< Our conference */
        int confusers;                                  /*!< Who is using our conference */
        int propconfno;                                 /*!< Propagated conference number */
        ast_group_t callgroup;
        ast_group_t pickupgroup;
        int channel;                                    /*!< Channel Number or CRV */
        int span;                                       /*!< Span number */
        time_t guardtime;                               /*!< Must wait this much time before using for new call */
        int cid_signalling;                             /*!< CID signalling type bell202 or v23 */
        int cid_start;                                  /*!< CID start indicator, polarity or ring */
        int callingpres;                                /*!< The value of callling presentation that we're going to use when placing a PRI call */
        int callwaitingrepeat;                          /*!< How many samples to wait before repeating call waiting */
        int cidcwexpire;                                /*!< When to expire our muting for CID/CW */
        unsigned char *cidspill;
        int cidpos;
        int cidlen;
        int ringt;
        int ringt_base;
        int stripmsd;
        int callwaitcas;
        int callwaitrings;
        int echocancel;
        int echotraining;
        char echorest[20];
        int busycount;
        int busy_tonelength;
        int busy_quietlength;
        int callprogress;
        struct timeval flashtime;                       /*!< Last flash-hook time */
        struct ast_dsp *dsp;
        int cref;                                       /*!< Call reference number */
        ZT_DIAL_OPERATION dop;
        int whichwink;                                  /*!< SIG_FEATDMF_TA Which wink are we on? */
        char finaldial[64];
        char accountcode[AST_MAX_ACCOUNT_CODE];         /*!< Account code */
        int amaflags;                                   /*!< AMA Flags */
        struct tdd_state *tdd;                          /*!< TDD flag */
        char call_forward[AST_MAX_EXTENSION];
        char mailbox[AST_MAX_EXTENSION];
        char dialdest[256];
        int onhooktime;
        int msgstate;
        int distinctivering;                            /*!< Which distinctivering to use */
        int cidrings;                                   /*!< Which ring to deliver CID on */
        int dtmfrelax;                                  /*!< whether to run in relaxed DTMF mode */
        int fake_event;
        int polarityonanswerdelay;
        struct timeval polaritydelaytv;
        int sendcalleridafter;
#ifdef ZAPATA_PRI
        struct zt_pri *pri;
        struct zt_pvt *bearer;
        struct zt_pvt *realcall;
        q931_call *call;
        int prioffset;
        int logicalspan;
#endif  
#ifdef ZAPATA_R2
        int r2prot;
        mfcr2_t *r2;
#endif  
        int polarity;
        int dsp_features;

} *iflist = NULL, *ifend = NULL;

static struct ast_channel *zt_request(const char *type, int format, void *data, int *cause);
static int zt_digit(struct ast_channel *ast, char digit);
static int zt_sendtext(struct ast_channel *c, const char *text);
static int zt_call(struct ast_channel *ast, char *rdest, int timeout);
static int zt_hangup(struct ast_channel *ast);
static int zt_answer(struct ast_channel *ast);
struct ast_frame *zt_read(struct ast_channel *ast);
static int zt_write(struct ast_channel *ast, struct ast_frame *frame);
struct ast_frame *zt_exception(struct ast_channel *ast);
static int zt_indicate(struct ast_channel *chan, int condition);
static int zt_fixup(struct ast_channel *oldchan, struct ast_channel *newchan);
static int zt_setoption(struct ast_channel *chan, int option, void *data, int datalen);

static const struct ast_channel_tech zap_tech = {
        .type = type,
        .description = tdesc,
        .capabilities = AST_FORMAT_SLINEAR | AST_FORMAT_ULAW,
        .requester = zt_request,
        .send_digit = zt_digit,
        .send_text = zt_sendtext,
        .call = zt_call,
        .hangup = zt_hangup,
        .answer = zt_answer,
        .read = zt_read,
        .write = zt_write,
        .bridge = zt_bridge,
        .exception = zt_exception,
        .indicate = zt_indicate,
        .fixup = zt_fixup,
        .setoption = zt_setoption,
};

#ifdef ZAPATA_PRI
#define GET_CHANNEL(p) ((p)->bearer ? (p)->bearer->channel : p->channel)
#else
#define GET_CHANNEL(p) ((p)->channel)
#endif

struct zt_pvt *round_robin[32];

#ifdef ZAPATA_PRI
static inline int pri_grab(struct zt_pvt *pvt, struct zt_pri *pri)
{
        int res;
        /* Grab the lock first */
        do {
            res = ast_mutex_trylock(&pri->lock);
                if (res) {
                        ast_mutex_unlock(&pvt->lock);
                        /* Release the lock and try again */
                        usleep(1);
                        ast_mutex_lock(&pvt->lock);
                }
        } while(res);
        /* Then break the poll */
        pthread_kill(pri->master, SIGURG);
        return 0;
}
#endif

#define NUM_CADENCE_MAX 25
static int num_cadence = 4;
static int user_has_defined_cadences = 0;

static struct zt_ring_cadence cadences[NUM_CADENCE_MAX] = {
        { { 125, 125, 2000, 4000 } },                   /*!< Quick chirp followed by normal ring */
        { { 250, 250, 500, 1000, 250, 250, 500, 4000 } }, /*!< British style ring */
        { { 125, 125, 125, 125, 125, 4000 } },  /*!< Three short bursts */
        { { 1000, 500, 2500, 5000 } },  /*!< Long ring */
};

int receivedRingT; /*!< Used to find out what ringtone we are on */

/*! \brief cidrings says in which pause to transmit the cid information, where the first pause
 * is 1, the second pause is 2 and so on.
 */

static int cidrings[NUM_CADENCE_MAX] = {
        2,                                                                              /*!< Right after first long ring */
        4,                                                                              /*!< Right after long part */
        3,                                                                              /*!< After third chirp */
        2,                                                                              /*!< Second spell */
};

#define ISTRUNK(p) ((p->sig == SIG_FXSLS) || (p->sig == SIG_FXSKS) || \
                        (p->sig == SIG_FXSGS) || (p->sig == SIG_PRI))

#define CANBUSYDETECT(p) (ISTRUNK(p) || (p->sig & (SIG_EM | SIG_EM_E1 | SIG_SF)) /* || (p->sig & __ZT_SIG_FXO) */)
#define CANPROGRESSDETECT(p) (ISTRUNK(p) || (p->sig & (SIG_EM | SIG_EM_E1 | SIG_SF)) /* || (p->sig & __ZT_SIG_FXO) */)

static int zt_get_index(struct ast_channel *ast, struct zt_pvt *p, int nullok)
{
        int res;
        if (p->subs[0].owner == ast)
                res = 0;
        else if (p->subs[1].owner == ast)
                res = 1;
        else if (p->subs[2].owner == ast)
                res = 2;
        else {
                res = -1;
                if (!nullok)
                        ast_log(LOG_WARNING, "Unable to get index, and nullok is not asserted\n");
        }
        return res;
}

#ifdef ZAPATA_PRI
static void wakeup_sub(struct zt_pvt *p, int a, struct zt_pri *pri)
#else
static void wakeup_sub(struct zt_pvt *p, int a, void *pri)
#endif
{
        struct ast_frame null = { AST_FRAME_NULL, };
#ifdef ZAPATA_PRI
        if (pri)
                ast_mutex_unlock(&pri->lock);
#endif                  
        for (;;) {
                if (p->subs[a].owner) {
                        if (ast_mutex_trylock(&p->subs[a].owner->lock)) {
                                ast_mutex_unlock(&p->lock);
                                usleep(1);
                                ast_mutex_lock(&p->lock);
                        } else {
                                ast_queue_frame(p->subs[a].owner, &null);
                                ast_mutex_unlock(&p->subs[a].owner->lock);
                                break;
                        }
                } else
                        break;
        }
#ifdef ZAPATA_PRI
        if (pri)
                ast_mutex_lock(&pri->lock);
#endif                  
}

#ifdef ZAPATA_PRI
static void zap_queue_frame(struct zt_pvt *p, struct ast_frame *f, struct zt_pri *pri)
#else
static void zap_queue_frame(struct zt_pvt *p, struct ast_frame *f, void *pri)
#endif
{
        /* We must unlock the PRI to avoid the possibility of a deadlock */
#ifdef ZAPATA_PRI
        if (pri)
                ast_mutex_unlock(&pri->lock);
#endif          
        for (;;) {
                if (p->owner) {
                        if (ast_mutex_trylock(&p->owner->lock)) {
                                ast_mutex_unlock(&p->lock);
                                usleep(1);
                                ast_mutex_lock(&p->lock);
                        } else {
                                ast_queue_frame(p->owner, f);
                                ast_mutex_unlock(&p->owner->lock);
                                break;
                        }
                } else
                        break;
        }
#ifdef ZAPATA_PRI
        if (pri)
                ast_mutex_lock(&pri->lock);
#endif          
}

static int restore_gains(struct zt_pvt *p);

static void swap_subs(struct zt_pvt *p, int a, int b)
{
        int tchan;
        int tinthreeway;
        struct ast_channel *towner;

        ast_log(LOG_DEBUG, "Swapping %d and %d\n", a, b);

        tchan = p->subs[a].chan;
        towner = p->subs[a].owner;
        tinthreeway = p->subs[a].inthreeway;

        p->subs[a].chan = p->subs[b].chan;
        p->subs[a].owner = p->subs[b].owner;
        p->subs[a].inthreeway = p->subs[b].inthreeway;

        p->subs[b].chan = tchan;
        p->subs[b].owner = towner;
        p->subs[b].inthreeway = tinthreeway;

        if (p->subs[a].owner) 
                p->subs[a].owner->fds[0] = p->subs[a].zfd;
        if (p->subs[b].owner) 
                p->subs[b].owner->fds[0] = p->subs[b].zfd;
        wakeup_sub(p, a, NULL);
        wakeup_sub(p, b, NULL);
}

static int zt_open(char *fn)
{
        int fd;
        int isnum;
        int chan = 0;
        int bs;
        int x;
        isnum = 1;
        for (x=0;x<strlen(fn);x++) {
                if (!isdigit(fn[x])) {
                        isnum = 0;
                        break;
                }
        }
        if (isnum) {
                chan = atoi(fn);
                if (chan < 1) {
                        ast_log(LOG_WARNING, "Invalid channel number '%s'\n", fn);
                        return -1;
                }
                fn = "/dev/zap/channel";
        }
        fd = open(fn, O_RDWR | O_NONBLOCK);
        if (fd < 0) {
                ast_log(LOG_WARNING, "Unable to open '%s': %s\n", fn, strerror(errno));
                return -1;
        }
        if (chan) {
                if (ioctl(fd, ZT_SPECIFY, &chan)) {
                        x = errno;
                        close(fd);
                        errno = x;
                        ast_log(LOG_WARNING, "Unable to specify channel %d: %s\n", chan, strerror(errno));
                        return -1;
                }
        }
        bs = READ_SIZE;
        if (ioctl(fd, ZT_SET_BLOCKSIZE, &bs) == -1) return -1;
        return fd;
}

static void zt_close(int fd)
{
        if(fd > 0)
                close(fd);
}

int zt_setlinear(int zfd, int linear)
{
        int res;
        res = ioctl(zfd, ZT_SETLINEAR, &linear);
        if (res)
                return res;
        return 0;
}


int zt_setlaw(int zfd, int law)
{
        int res;
        res = ioctl(zfd, ZT_SETLAW, &law);
        if (res)
                return res;
        return 0;
}

static int alloc_sub(struct zt_pvt *p, int x)
{
        ZT_BUFFERINFO bi;
        int res;
        if (p->subs[x].zfd < 0) {
                p->subs[x].zfd = zt_open("/dev/zap/pseudo");
                if (p->subs[x].zfd > -1) {
                        res = ioctl(p->subs[x].zfd, ZT_GET_BUFINFO, &bi);
                        if (!res) {
                                bi.txbufpolicy = ZT_POLICY_IMMEDIATE;
                                bi.rxbufpolicy = ZT_POLICY_IMMEDIATE;
                                bi.numbufs = numbufs;
                                res = ioctl(p->subs[x].zfd, ZT_SET_BUFINFO, &bi);
                                if (res < 0) {
                                        ast_log(LOG_WARNING, "Unable to set buffer policy on channel %d\n", x);
                                }
                        } else 
                                ast_log(LOG_WARNING, "Unable to check buffer policy on channel %d\n", x);
                        if (ioctl(p->subs[x].zfd, ZT_CHANNO, &p->subs[x].chan) == 1) {
                                ast_log(LOG_WARNING,"Unable to get channel number for pseudo channel on FD %d\n",p->subs[x].zfd);
                                zt_close(p->subs[x].zfd);
                                p->subs[x].zfd = -1;
                                return -1;
                        }
                        if (option_debug)
                                ast_log(LOG_DEBUG, "Allocated %s subchannel on FD %d channel %d\n", subnames[x], p->subs[x].zfd, p->subs[x].chan);
                        return 0;
                } else
                        ast_log(LOG_WARNING, "Unable to open pseudo channel: %s\n", strerror(errno));
                return -1;
        }
        ast_log(LOG_WARNING, "%s subchannel of %d already in use\n", subnames[x], p->channel);
        return -1;
}

static int unalloc_sub(struct zt_pvt *p, int x)
{
        if (!x) {
                ast_log(LOG_WARNING, "Trying to unalloc the real channel %d?!?\n", p->channel);
                return -1;
        }
        ast_log(LOG_DEBUG, "Released sub %d of channel %d\n", x, p->channel);
        if (p->subs[x].zfd > -1) {
                zt_close(p->subs[x].zfd);
        }
        p->subs[x].zfd = -1;
        p->subs[x].linear = 0;
        p->subs[x].chan = 0;
        p->subs[x].owner = NULL;
        p->subs[x].inthreeway = 0;
        p->polarity = POLARITY_IDLE;
        memset(&p->subs[x].curconf, 0, sizeof(p->subs[x].curconf));
        return 0;
}

static int zt_digit(struct ast_channel *ast, char digit)
{
        ZT_DIAL_OPERATION zo;
        struct zt_pvt *p;
        int res = 0;
        int index;
        p = ast->tech_pvt;
        ast_mutex_lock(&p->lock);
        index = zt_get_index(ast, p, 0);
        if ((index == SUB_REAL) && p->owner) {
#ifdef ZAPATA_PRI
                if ((p->sig == SIG_PRI) && (ast->_state == AST_STATE_DIALING) && !p->proceeding) {
                        if (p->setup_ack) {
                                if (!pri_grab(p, p->pri)) {
                                        pri_information(p->pri->pri,p->call,digit);
                                        pri_rel(p->pri);
                                } else
                                        ast_log(LOG_WARNING, "Unable to grab PRI on span %d\n", p->span);
                        } else if (strlen(p->dialdest) < sizeof(p->dialdest) - 1) {
                                ast_log(LOG_DEBUG, "Queueing digit '%c' since setup_ack not yet received\n", digit);
                                res = strlen(p->dialdest);
                                p->dialdest[res++] = digit;
                                p->dialdest[res] = '\0';
                        }
                } else {
#else
                {
#endif
                        zo.op = ZT_DIAL_OP_APPEND;
                        zo.dialstr[0] = 'T';
                        zo.dialstr[1] = digit;
                        zo.dialstr[2] = 0;
                        if ((res = ioctl(p->subs[SUB_REAL].zfd, ZT_DIAL, &zo)))
                                ast_log(LOG_WARNING, "Couldn't dial digit %c\n", digit);
                        else
                                p->dialing = 1;
                }
        }
        ast_mutex_unlock(&p->lock);
        return res;
}

static char *events[] = {
                "No event",
                "On hook",
                "Ring/Answered",
                "Wink/Flash",
                "Alarm",
                "No more alarm",
                "HDLC Abort",
                "HDLC Overrun",
                "HDLC Bad FCS",
                "Dial Complete",
                "Ringer On",
                "Ringer Off",
                "Hook Transition Complete",
                "Bits Changed",
                "Pulse Start",
                "Timer Expired",
                "Timer Ping",
                "Polarity Reversal",
                "Ring Begin",
};

static struct {
        int alarm;
        char *name;
} alarms[] = {
        { ZT_ALARM_RED, "Red Alarm" },
        { ZT_ALARM_YELLOW, "Yellow Alarm" },
        { ZT_ALARM_BLUE, "Blue Alarm" },
        { ZT_ALARM_RECOVER, "Recovering" },
        { ZT_ALARM_LOOPBACK, "Loopback" },
        { ZT_ALARM_NOTOPEN, "Not Open" },
        { ZT_ALARM_NONE, "None" },
};

static char *alarm2str(int alarm)
{
        int x;
        for (x=0;x<sizeof(alarms) / sizeof(alarms[0]); x++) {
                if (alarms[x].alarm & alarm)
                        return alarms[x].name;
        }
        return alarm ? "Unknown Alarm" : "No Alarm";
}

static char *event2str(int event)
{
        static char buf[256];
        if ((event < (sizeof(events) / sizeof(events[0]))) && (event > -1))
                return events[event];
        sprintf(buf, "Event %d", event); /* safe */
        return buf;
}

#ifdef ZAPATA_PRI
static char *dialplan2str(int dialplan)
{
        if (dialplan == -1) {
                return("Dynamically set dialplan in ISDN");
        }
        return(pri_plan2str(dialplan));
}
#endif

#ifdef ZAPATA_R2
static int str2r2prot(char *swtype)
{
    if (!strcasecmp(swtype, "ar"))
        return MFCR2_PROT_ARGENTINA;
    /*endif*/
    if (!strcasecmp(swtype, "cn"))
        return MFCR2_PROT_CHINA;
    /*endif*/
    if (!strcasecmp(swtype, "kr"))
        return MFCR2_PROT_KOREA;
    /*endif*/
    return -1;
}
#endif

static char *zap_sig2str(int sig)
{
        static char buf[256];
        switch(sig) {
        case SIG_EM:
                return "E & M Immediate";
        case SIG_EMWINK:
                return "E & M Wink";
        case SIG_EM_E1:
                return "E & M E1";
        case SIG_FEATD:
                return "Feature Group D (DTMF)";
        case SIG_FEATDMF:
                return "Feature Group D (MF)";
        case SIG_FEATDMF_TA:
                return "Feature Groud D (MF) Tandem Access";
        case SIG_FEATB:
                return "Feature Group B (MF)";
        case SIG_E911:
                return "E911 (MF)";
        case SIG_FXSLS:
                return "FXS Loopstart";
        case SIG_FXSGS:
                return "FXS Groundstart";
        case SIG_FXSKS:
                return "FXS Kewlstart";
        case SIG_FXOLS:
                return "FXO Loopstart";
        case SIG_FXOGS:
                return "FXO Groundstart";
        case SIG_FXOKS:
                return "FXO Kewlstart";
        case SIG_PRI:
                return "PRI Signalling";
        case SIG_R2:
                return "R2 Signalling";
        case SIG_SF:
                return "SF (Tone) Signalling Immediate";
        case SIG_SFWINK:
                return "SF (Tone) Signalling Wink";
        case SIG_SF_FEATD:
                return "SF (Tone) Signalling with Feature Group D (DTMF)";
        case SIG_SF_FEATDMF:
                return "SF (Tone) Signalling with Feature Group D (MF)";
        case SIG_SF_FEATB:
                return "SF (Tone) Signalling with Feature Group B (MF)";
        case SIG_GR303FXOKS:
                return "GR-303 Signalling with FXOKS";
        case SIG_GR303FXSKS:
                return "GR-303 Signalling with FXSKS";
        case 0:
                return "Pseudo Signalling";
        default:
                snprintf(buf, sizeof(buf), "Unknown signalling %d", sig);
                return buf;
        }
}

#define sig2str zap_sig2str

static int conf_add(struct zt_pvt *p, struct zt_subchannel *c, int index, int slavechannel)
{
        /* If the conference already exists, and we're already in it
           don't bother doing anything */
        ZT_CONFINFO zi;
        
        memset(&zi, 0, sizeof(zi));
        zi.chan = 0;

        if (slavechannel > 0) {
                /* If we have only one slave, do a digital mon */
                zi.confmode = ZT_CONF_DIGITALMON;
                zi.confno = slavechannel;
        } else {
                if (!index) {
                        /* Real-side and pseudo-side both participate in conference */
                        zi.confmode = ZT_CONF_REALANDPSEUDO | ZT_CONF_TALKER | ZT_CONF_LISTENER |
                                                                ZT_CONF_PSEUDO_TALKER | ZT_CONF_PSEUDO_LISTENER;
                } else
                        zi.confmode = ZT_CONF_CONF | ZT_CONF_TALKER | ZT_CONF_LISTENER;
                zi.confno = p->confno;
        }
        if ((zi.confno == c->curconf.confno) && (zi.confmode == c->curconf.confmode))
                return 0;
        if (c->zfd < 0)
                return 0;
        if (ioctl(c->zfd, ZT_SETCONF, &zi)) {
                ast_log(LOG_WARNING, "Failed to add %d to conference %d/%d\n", c->zfd, zi.confmode, zi.confno);
                return -1;
        }
        if (slavechannel < 1) {
                p->confno = zi.confno;
        }
        memcpy(&c->curconf, &zi, sizeof(c->curconf));
        ast_log(LOG_DEBUG, "Added %d to conference %d/%d\n", c->zfd, c->curconf.confmode, c->curconf.confno);
        return 0;
}

static int isourconf(struct zt_pvt *p, struct zt_subchannel *c)
{
        /* If they're listening to our channel, they're ours */ 
        if ((p->channel == c->curconf.confno) && (c->curconf.confmode == ZT_CONF_DIGITALMON))
                return 1;
        /* If they're a talker on our (allocated) conference, they're ours */
        if ((p->confno > 0) && (p->confno == c->curconf.confno) && (c->curconf.confmode & ZT_CONF_TALKER))
                return 1;
        return 0;
}

static int conf_del(struct zt_pvt *p, struct zt_subchannel *c, int index)
{
        ZT_CONFINFO zi;
        if (/* Can't delete if there's no zfd */
                (c->zfd < 0) ||
                /* Don't delete from the conference if it's not our conference */
                !isourconf(p, c)
                /* Don't delete if we don't think it's conferenced at all (implied) */
                ) return 0;
        memset(&zi, 0, sizeof(zi));
        zi.chan = 0;
        zi.confno = 0;
        zi.confmode = 0;
        if (ioctl(c->zfd, ZT_SETCONF, &zi)) {
                ast_log(LOG_WARNING, "Failed to drop %d from conference %d/%d\n", c->zfd, c->curconf.confmode, c->curconf.confno);
                return -1;
        }
        ast_log(LOG_DEBUG, "Removed %d from conference %d/%d\n", c->zfd, c->curconf.confmode, c->curconf.confno);
        memcpy(&c->curconf, &zi, sizeof(c->curconf));
        return 0;
}

static int isslavenative(struct zt_pvt *p, struct zt_pvt **out)
{
        int x;
        int useslavenative;
        struct zt_pvt *slave = NULL;
        /* Start out optimistic */
        useslavenative = 1;
        /* Update conference state in a stateless fashion */
        for (x=0;x<3;x++) {
                /* Any three-way calling makes slave native mode *definitely* out
                   of the question */
                if ((p->subs[x].zfd > -1) && p->subs[x].inthreeway)
                        useslavenative = 0;
        }
        /* If we don't have any 3-way calls, check to see if we have
           precisely one slave */
        if (useslavenative) {
                for (x=0;x<MAX_SLAVES;x++) {
                        if (p->slaves[x]) {
                                if (slave) {
                                        /* Whoops already have a slave!  No 
                                           slave native and stop right away */
                                        slave = NULL;
                                        useslavenative = 0;
                                        break;
                                } else {
                                        /* We have one slave so far */
                                        slave = p->slaves[x];
                                }
                        }
                }
        }
        /* If no slave, slave native definitely out */
        if (!slave)
                useslavenative = 0;
        else if (slave->law != p->law) {
                useslavenative = 0;
                slave = NULL;
        }
        if (out)
                *out = slave;
        return useslavenative;
}

static int reset_conf(struct zt_pvt *p)
{
        ZT_CONFINFO zi;
        memset(&zi, 0, sizeof(zi));
        p->confno = -1;
        memset(&p->subs[SUB_REAL].curconf, 0, sizeof(p->subs[SUB_REAL].curconf));
        if (p->subs[SUB_REAL].zfd > -1) {
                if (ioctl(p->subs[SUB_REAL].zfd, ZT_SETCONF, &zi))
                        ast_log(LOG_WARNING, "Failed to reset conferencing on channel %d!\n", p->channel);
        }
        return 0;
}

static int update_conf(struct zt_pvt *p)
{
        int needconf = 0;
        int x;
        int useslavenative;
        struct zt_pvt *slave = NULL;

        useslavenative = isslavenative(p, &slave);
        /* Start with the obvious, general stuff */
        for (x=0;x<3;x++) {
                /* Look for three way calls */
                if ((p->subs[x].zfd > -1) && p->subs[x].inthreeway) {
                        conf_add(p, &p->subs[x], x, 0);
                        needconf++;
                } else {
                        conf_del(p, &p->subs[x], x);
                }
        }
        /* If we have a slave, add him to our conference now. or DAX
           if this is slave native */
        for (x=0;x<MAX_SLAVES;x++) {
                if (p->slaves[x]) {
                        if (useslavenative)
                                conf_add(p, &p->slaves[x]->subs[SUB_REAL], SUB_REAL, GET_CHANNEL(p));
                        else {
                                conf_add(p, &p->slaves[x]->subs[SUB_REAL], SUB_REAL, 0);
                                needconf++;
                        }
                }
        }
        /* If we're supposed to be in there, do so now */
        if (p->inconference && !p->subs[SUB_REAL].inthreeway) {
                if (useslavenative)
                        conf_add(p, &p->subs[SUB_REAL], SUB_REAL, GET_CHANNEL(slave));
                else {
                        conf_add(p, &p->subs[SUB_REAL], SUB_REAL, 0);
                        needconf++;
                }
        }
        /* If we have a master, add ourselves to his conference */
        if (p->master) {
                if (isslavenative(p->master, NULL)) {
                        conf_add(p->master, &p->subs[SUB_REAL], SUB_REAL, GET_CHANNEL(p->master));
                } else {
                        conf_add(p->master, &p->subs[SUB_REAL], SUB_REAL, 0);
                }
        }
        if (!needconf) {
                /* Nobody is left (or should be left) in our conference.  
                   Kill it.  */
                p->confno = -1;
        }
        ast_log(LOG_DEBUG, "Updated conferencing on %d, with %d conference users\n", p->channel, needconf);
        return 0;
}

static void zt_enable_ec(struct zt_pvt *p)
{
        int x;
        int res;
        if (!p)
                return;
        if (p->echocanon) {
                ast_log(LOG_DEBUG, "Echo cancellation already on\n");
                return;
        }
        if (p->digital) {
                ast_log(LOG_DEBUG, "Echo cancellation isn't required on digital connection\n");
                return;
        }
        if (p->echocancel) {
                if (p->sig == SIG_PRI) {
                        x = 1;
                        res = ioctl(p->subs[SUB_REAL].zfd, ZT_AUDIOMODE, &x);
                        if (res)
                                ast_log(LOG_WARNING, "Unable to enable echo cancellation on channel %d\n", p->channel);
                }
                x = p->echocancel;
                res = ioctl(p->subs[SUB_REAL].zfd, ZT_ECHOCANCEL, &x);
                if (res) 
                        ast_log(LOG_WARNING, "Unable to enable echo cancellation on channel %d\n", p->channel);
                else {
                        p->echocanon = 1;
                        ast_log(LOG_DEBUG, "Enabled echo cancellation on channel %d\n", p->channel);
                }
        } else
                ast_log(LOG_DEBUG, "No echo cancellation requested\n");
}

static void zt_train_ec(struct zt_pvt *p)
{
        int x;
        int res;
        if (p && p->echocancel && p->echotraining) {
                x = p->echotraining;
                res = ioctl(p->subs[SUB_REAL].zfd, ZT_ECHOTRAIN, &x);
                if (res) 
                        ast_log(LOG_WARNING, "Unable to request echo training on channel %d\n", p->channel);
                else {
                        ast_log(LOG_DEBUG, "Engaged echo training on channel %d\n", p->channel);
                }
        } else
                ast_log(LOG_DEBUG, "No echo training requested\n");
}

static void zt_disable_ec(struct zt_pvt *p)
{
        int x;
        int res;
        if (p->echocancel) {
                x = 0;
                res = ioctl(p->subs[SUB_REAL].zfd, ZT_ECHOCANCEL, &x);
                if (res) 
                        ast_log(LOG_WARNING, "Unable to disable echo cancellation on channel %d\n", p->channel);
                else
                        ast_log(LOG_DEBUG, "disabled echo cancellation on channel %d\n", p->channel);
        }
        p->echocanon = 0;
}

static void fill_txgain(struct zt_gains *g, float gain, int law)
{
        int j;
        int k;
        float linear_gain = pow(10.0, gain / 20.0);

        switch (law) {
        case ZT_LAW_ALAW:
                for (j = 0; j < (sizeof(g->txgain) / sizeof(g->txgain[0])); j++) {
                        if (gain) {
                                k = (int) (((float) AST_ALAW(j)) * linear_gain);
                                if (k > 32767) k = 32767;
                                if (k < -32767) k = -32767;
                                g->txgain[j] = AST_LIN2A(k);
                        } else {
                                g->txgain[j] = j;
                        }
                }
                break;
        case ZT_LAW_MULAW:
                for (j = 0; j < (sizeof(g->txgain) / sizeof(g->txgain[0])); j++) {
                        if (gain) {
                                k = (int) (((float) AST_MULAW(j)) * linear_gain);
                                if (k > 32767) k = 32767;
                                if (k < -32767) k = -32767;
                                g->txgain[j] = AST_LIN2MU(k);
                        } else {
                                g->txgain[j] = j;
                        }
                }
                break;
        }
}

static void fill_rxgain(struct zt_gains *g, float gain, int law)
{
        int j;
        int k;
        float linear_gain = pow(10.0, gain / 20.0);

        switch (law) {
        case ZT_LAW_ALAW:
                for (j = 0; j < (sizeof(g->rxgain) / sizeof(g->rxgain[0])); j++) {
                        if (gain) {
                                k = (int) (((float) AST_ALAW(j)) * linear_gain);
                                if (k > 32767) k = 32767;
                                if (k < -32767) k = -32767;
                                g->rxgain[j] = AST_LIN2A(k);
                        } else {
                                g->rxgain[j] = j;
                        }
                }
                break;
        case ZT_LAW_MULAW:
                for (j = 0; j < (sizeof(g->rxgain) / sizeof(g->rxgain[0])); j++) {
                        if (gain) {
                                k = (int) (((float) AST_MULAW(j)) * linear_gain);
                                if (k > 32767) k = 32767;
                                if (k < -32767) k = -32767;
                                g->rxgain[j] = AST_LIN2MU(k);
                        } else {
                                g->rxgain[j] = j;
                        }
                }
                break;
        }
}

int set_actual_txgain(int fd, int chan, float gain, int law)
{
        struct zt_gains g;
        int res;

        memset(&g, 0, sizeof(g));
        g.chan = chan;
        res = ioctl(fd, ZT_GETGAINS, &g);
        if (res) {
                ast_log(LOG_DEBUG, "Failed to read gains: %s\n", strerror(errno));
                return res;
        }

        fill_txgain(&g, gain, law);

        return ioctl(fd, ZT_SETGAINS, &g);
}

int set_actual_rxgain(int fd, int chan, float gain, int law)
{
        struct zt_gains g;
        int res;

        memset(&g, 0, sizeof(g));
        g.chan = chan;
        res = ioctl(fd, ZT_GETGAINS, &g);
        if (res) {
                ast_log(LOG_DEBUG, "Failed to read gains: %s\n", strerror(errno));
                return res;
        }

        fill_rxgain(&g, gain, law);

        return ioctl(fd, ZT_SETGAINS, &g);
}

int set_actual_gain(int fd, int chan, float rxgain, float txgain, int law)
{
        return set_actual_txgain(fd, chan, txgain, law) | set_actual_rxgain(fd, chan, rxgain, law);
}

static int bump_gains(struct zt_pvt *p)
{
        int res;

        /* Bump receive gain by 5.0db */
        res = set_actual_gain(p->subs[SUB_REAL].zfd, 0, p->rxgain + 5.0, p->txgain, p->law);
        if (res) {
                ast_log(LOG_WARNING, "Unable to bump gain: %s\n", strerror(errno));
                return -1;
        }

        return 0;
}

static int restore_gains(struct zt_pvt *p)
{
        int res;

        res = set_actual_gain(p->subs[SUB_REAL].zfd, 0, p->rxgain, p->txgain, p->law);
        if (res) {
                ast_log(LOG_WARNING, "Unable to restore gains: %s\n", strerror(errno));
                return -1;
        }

        return 0;
}

static inline int zt_set_hook(int fd, int hs)
{
        int x, res;
        x = hs;
        res = ioctl(fd, ZT_HOOK, &x);
        if (res < 0) 
        {
                if (errno == EINPROGRESS) return 0;
                ast_log(LOG_WARNING, "zt hook failed: %s\n", strerror(errno));
        }
        return res;
}

static inline int zt_confmute(struct zt_pvt *p, int muted)
{
        int x, y, res;
        x = muted;
        if (p->sig == SIG_PRI) {
                y = 1;
                res = ioctl(p->subs[SUB_REAL].zfd, ZT_AUDIOMODE, &y);
                if (res)
                        ast_log(LOG_WARNING, "Unable to set audio mode on '%d'\n", p->channel);
        }
        res = ioctl(p->subs[SUB_REAL].zfd, ZT_CONFMUTE, &x);
        if (res < 0) 
                ast_log(LOG_WARNING, "zt confmute(%d) failed on channel %d: %s\n", muted, p->channel, strerror(errno));
        return res;
}

static int save_conference(struct zt_pvt *p)
{
        struct zt_confinfo c;
        int res;
        if (p->saveconf.confmode) {
                ast_log(LOG_WARNING, "Can't save conference -- already in use\n");
                return -1;
        }
        p->saveconf.chan = 0;
        res = ioctl(p->subs[SUB_REAL].zfd, ZT_GETCONF, &p->saveconf);
        if (res) {
                ast_log(LOG_WARNING, "Unable to get conference info: %s\n", strerror(errno));
                p->saveconf.confmode = 0;
                return -1;
        }
        c.chan = 0;
        c.confno = 0;
        c.confmode = ZT_CONF_NORMAL;
        res = ioctl(p->subs[SUB_REAL].zfd, ZT_SETCONF, &c);
        if (res) {
                ast_log(LOG_WARNING, "Unable to set conference info: %s\n", strerror(errno));
                return -1;
        }
        if (option_debug)
                ast_log(LOG_DEBUG, "Disabled conferencing\n");
        return 0;
}

static int restore_conference(struct zt_pvt *p)
{
        int res;
        if (p->saveconf.confmode) {
                res = ioctl(p->subs[SUB_REAL].zfd, ZT_SETCONF, &p->saveconf);
                p->saveconf.confmode = 0;
                if (res) {
                        ast_log(LOG_WARNING, "Unable to restore conference info: %s\n", strerror(errno));
                        return -1;
                }
        }
        if (option_debug)
                ast_log(LOG_DEBUG, "Restored conferencing\n");
        return 0;
}

static int send_callerid(struct zt_pvt *p);

int send_cwcidspill(struct zt_pvt *p)
{
        p->callwaitcas = 0;
        p->cidcwexpire = 0;
        p->cidspill = malloc(MAX_CALLERID_SIZE);
        if (p->cidspill) {
                memset(p->cidspill, 0x7f, MAX_CALLERID_SIZE);
                p->cidlen = ast_callerid_callwaiting_generate(p->cidspill, p->callwait_name, p->callwait_num, AST_LAW(p));
                /* Make sure we account for the end */
                p->cidlen += READ_SIZE * 4;
                p->cidpos = 0;
                send_callerid(p);
                if (option_verbose > 2)
                        ast_verbose(VERBOSE_PREFIX_3 "CPE supports Call Waiting Caller*ID.  Sending '%s/%s'\n", p->callwait_name, p->callwait_num);
        } else return -1;
        return 0;
}

static int has_voicemail(struct zt_pvt *p)
{

        return ast_app_has_voicemail(p->mailbox, NULL);
}

static int send_callerid(struct zt_pvt *p)
{
        /* Assumes spill in p->cidspill, p->cidlen in length and we're p->cidpos into it */
        int res;
        /* Take out of linear mode if necessary */
        if (p->subs[SUB_REAL].linear) {
                p->subs[SUB_REAL].linear = 0;
                zt_setlinear(p->subs[SUB_REAL].zfd, 0);
        }
        while(p->cidpos < p->cidlen) {
                res = write(p->subs[SUB_REAL].zfd, p->cidspill + p->cidpos, p->cidlen - p->cidpos);
                if (res < 0) {
                        if (errno == EAGAIN)
                                return 0;
                        else {
                                ast_log(LOG_WARNING, "write failed: %s\n", strerror(errno));
                                return -1;
                        }
                }
                if (!res)
                        return 0;
                p->cidpos += res;
        }
        free(p->cidspill);
        p->cidspill = NULL;
        if (p->callwaitcas) {
                /* Wait for CID/CW to expire */
                p->cidcwexpire = CIDCW_EXPIRE_SAMPLES;
        } else
                restore_conference(p);
        return 0;
}

static int zt_callwait(struct ast_channel *ast)
{
        struct zt_pvt *p = ast->tech_pvt;
        p->callwaitingrepeat = CALLWAITING_REPEAT_SAMPLES;
        if (p->cidspill) {
                ast_log(LOG_WARNING, "Spill already exists?!?\n");
                free(p->cidspill);
        }
        p->cidspill = malloc(2400 /* SAS */ + 680 /* CAS */ + READ_SIZE * 4);
        if (p->cidspill) {
                save_conference(p);
                /* Silence */
                memset(p->cidspill, 0x7f, 2400 + 600 + READ_SIZE * 4);
                if (!p->callwaitrings && p->callwaitingcallerid) {
                        ast_gen_cas(p->cidspill, 1, 2400 + 680, AST_LAW(p));
                        p->callwaitcas = 1;
                        p->cidlen = 2400 + 680 + READ_SIZE * 4;
                } else {
                        ast_gen_cas(p->cidspill, 1, 2400, AST_LAW(p));
                        p->callwaitcas = 0;
                        p->cidlen = 2400 + READ_SIZE * 4;
                }
                p->cidpos = 0;
                send_callerid(p);
        } else {
                ast_log(LOG_WARNING, "Unable to create SAS/CAS spill\n");
                return -1;
        }
        return 0;
}

static int zt_call(struct ast_channel *ast, char *rdest, int timeout)
{
        struct zt_pvt *p = ast->tech_pvt;
        int x, res, index;
        char *c, *n, *l;
#ifdef ZAPATA_PRI
        char *s=NULL;
#endif
        char dest[256]; /* must be same length as p->dialdest */
        ast_mutex_lock(&p->lock);
        ast_copy_string(dest, rdest, sizeof(dest));
        ast_copy_string(p->dialdest, rdest, sizeof(p->dialdest));
        if ((ast->_state == AST_STATE_BUSY)) {
                p->subs[SUB_REAL].needbusy = 1;
                ast_mutex_unlock(&p->lock);
                return 0;
        }
        if ((ast->_state != AST_STATE_DOWN) && (ast->_state != AST_STATE_RESERVED)) {
                ast_log(LOG_WARNING, "zt_call called on %s, neither down nor reserved\n", ast->name);
                ast_mutex_unlock(&p->lock);
                return -1;
        }
        p->dialednone = 0;
        if (p->radio)  /* if a radio channel, up immediately */
        {
                /* Special pseudo -- automatically up */
                ast_setstate(ast, AST_STATE_UP); 
                ast_mutex_unlock(&p->lock);
                return 0;
        }
        x = ZT_FLUSH_READ | ZT_FLUSH_WRITE;
        res = ioctl(p->subs[SUB_REAL].zfd, ZT_FLUSH, &x);
        if (res)
                ast_log(LOG_WARNING, "Unable to flush input on channel %d\n", p->channel);
        p->outgoing = 1;

        set_actual_gain(p->subs[SUB_REAL].zfd, 0, p->rxgain, p->txgain, p->law);

        switch(p->sig) {
        case SIG_FXOLS:
        case SIG_FXOGS:
        case SIG_FXOKS:
                if (p->owner == ast) {
                        /* Normal ring, on hook */
                        
                        /* Don't send audio while on hook, until the call is answered */
                        p->dialing = 1;
                        if (p->use_callerid) {
                                /* Generate the Caller-ID spill if desired */
                                if (p->cidspill) {
                                        ast_log(LOG_WARNING, "cidspill already exists??\n");
                                        free(p->cidspill);
                                }
                                p->cidspill = malloc(MAX_CALLERID_SIZE);
                                p->callwaitcas = 0;
                                if (p->cidspill) {
                                        p->cidlen = ast_callerid_generate(p->cidspill, ast->cid.cid_name, ast->cid.cid_num, AST_LAW(p));
                                        p->cidpos = 0;
                                        send_callerid(p);
                                } else
                                        ast_log(LOG_WARNING, "Unable to generate CallerID spill\n");
                        }
                        /* Choose proper cadence */
                        if ((p->distinctivering > 0) && (p->distinctivering <= num_cadence)) {
                                if (ioctl(p->subs[SUB_REAL].zfd, ZT_SETCADENCE, &cadences[p->distinctivering-1]))
                                        ast_log(LOG_WARNING, "Unable to set distinctive ring cadence %d on '%s'\n", p->distinctivering, ast->name);
                                p->cidrings = cidrings[p->distinctivering - 1];
                        } else {
                                if (ioctl(p->subs[SUB_REAL].zfd, ZT_SETCADENCE, NULL))
                                        ast_log(LOG_WARNING, "Unable to reset default ring on '%s'\n", ast->name);
                                p->cidrings = p->sendcalleridafter;
                        }


                        /* nick@dccinc.com 4/3/03 mods to allow for deferred dialing */
                        c = strchr(dest, '/');
                        if (c)
                                c++;
                        if (c && (strlen(c) < p->stripmsd)) {
                                ast_log(LOG_WARNING, "Number '%s' is shorter than stripmsd (%d)\n", c, p->stripmsd);
                                c = NULL;
                        }
                        if (c) {
                                p->dop.op = ZT_DIAL_OP_REPLACE;
                                snprintf(p->dop.dialstr, sizeof(p->dop.dialstr), "Tw%s", c);
                                ast_log(LOG_DEBUG, "FXO: setup deferred dialstring: %s\n", c);
                        } else {
                                p->dop.dialstr[0] = '\0';
                        }
                        x = ZT_RING;
                        if (ioctl(p->subs[SUB_REAL].zfd, ZT_HOOK, &x) && (errno != EINPROGRESS)) {
                                ast_log(LOG_WARNING, "Unable to ring phone: %s\n", strerror(errno));
                                ast_mutex_unlock(&p->lock);
                                return -1;
                        }
                        p->dialing = 1;
                } else {
                        /* Call waiting call */
                        p->callwaitrings = 0;
                        if (ast->cid.cid_num)
                                ast_copy_string(p->callwait_num, ast->cid.cid_num, sizeof(p->callwait_num));
                        else
                                p->callwait_num[0] = '\0';
                        if (ast->cid.cid_name)
                                ast_copy_string(p->callwait_name, ast->cid.cid_name, sizeof(p->callwait_name));
                        else
                                p->callwait_name[0] = '\0';
                        /* Call waiting tone instead */
                        if (zt_callwait(ast)) {
                                ast_mutex_unlock(&p->lock);
                                return -1;
                        }
                        /* Make ring-back */
                        if (tone_zone_play_tone(p->subs[SUB_CALLWAIT].zfd, ZT_TONE_RINGTONE))
                                ast_log(LOG_WARNING, "Unable to generate call-wait ring-back on channel %s\n", ast->name);
                                
                }
                n = ast->cid.cid_name;
                l = ast->cid.cid_num;
                if (l)
                        ast_copy_string(p->lastcid_num, l, sizeof(p->lastcid_num));
                else
                        p->lastcid_num[0] = '\0';
                if (n)
                        ast_copy_string(p->lastcid_name, n, sizeof(p->lastcid_name));
                else
                        p->lastcid_name[0] = '\0';
                ast_setstate(ast, AST_STATE_RINGING);
                index = zt_get_index(ast, p, 0);
                if (index > -1) {
                        p->subs[index].needringing = 1;
                }
                break;
        case SIG_FXSLS:
        case SIG_FXSGS:
        case SIG_FXSKS:
        case SIG_EMWINK:
        case SIG_EM:
        case SIG_EM_E1:
        case SIG_FEATD:
        case SIG_FEATDMF:
        case SIG_E911:
        case SIG_FEATB:
        case SIG_SFWINK:
        case SIG_SF:
        case SIG_SF_FEATD:
        case SIG_SF_FEATDMF:
        case SIG_FEATDMF_TA:
        case SIG_SF_FEATB:
                c = strchr(dest, '/');
                if (c)
                        c++;
                else
                        c = "";
                if (strlen(c) < p->stripmsd) {
                        ast_log(LOG_WARNING, "Number '%s' is shorter than stripmsd (%d)\n", c, p->stripmsd);
                        ast_mutex_unlock(&p->lock);
                        return -1;
                }
#ifdef ZAPATA_PRI
                /* Start the trunk, if not GR-303 */
                if (!p->pri) {
#endif
                        x = ZT_START;
                        res = ioctl(p->subs[SUB_REAL].zfd, ZT_HOOK, &x);
                        if (res < 0) {
                                if (errno != EINPROGRESS) {
                                        ast_log(LOG_WARNING, "Unable to start channel: %s\n", strerror(errno));
                                        ast_mutex_unlock(&p->lock);
                                        return -1;
                                }
                        }
#ifdef ZAPATA_PRI
                }
#endif
                ast_log(LOG_DEBUG, "Dialing '%s'\n", c);
                p->dop.op = ZT_DIAL_OP_REPLACE;

                c += p->stripmsd;

                switch (p->sig) {
                case SIG_FEATD:
                        l = ast->cid.cid_num;
                        if (l) 
                                snprintf(p->dop.dialstr, sizeof(p->dop.dialstr), "T*%s*%s*", l, c);
                        else
                                snprintf(p->dop.dialstr, sizeof(p->dop.dialstr), "T**%s*", c);
                        break;
                case SIG_FEATDMF:
                        l = ast->cid.cid_num;
                        if (l) 
                                snprintf(p->dop.dialstr, sizeof(p->dop.dialstr), "M*00%s#*%s#", l, c);
                        else
                                snprintf(p->dop.dialstr, sizeof(p->dop.dialstr), "M*02#*%s#", c);
                        break;
                case SIG_FEATDMF_TA:
                {
                        const char *cic, *ozz;

                        /* If you have to go through a Tandem Access point you need to use this */
                        ozz = pbx_builtin_getvar_helper(p->owner, "FEATDMF_OZZ");
                        if (!ozz)
                                ozz = defaultozz;
                        cic = pbx_builtin_getvar_helper(p->owner, "FEATDMF_CIC");
                        if (!cic)
                                cic = defaultcic;
                        if (!ozz || !cic) {
                                ast_log(LOG_WARNING, "Unable to dial channel of type feature group D MF tandem access without CIC or OZZ set\n");
                                ast_mutex_unlock(&p->lock);
                                return -1;
                        }
                        snprintf(p->dop.dialstr, sizeof(p->dop.dialstr), "M*%s%s#", ozz, cic);
                        snprintf(p->finaldial, sizeof(p->finaldial), "M*%s#", c);
                        p->whichwink = 0;
                }
                        break;
                case SIG_E911:
                        ast_copy_string(p->dop.dialstr, "M*911#", sizeof(p->dop.dialstr));
                        break;
                case SIG_FEATB:
                        snprintf(p->dop.dialstr, sizeof(p->dop.dialstr), "M*%s#", c);
                        break;
                default:
                        if (p->pulse)
                                snprintf(p->dop.dialstr, sizeof(p->dop.dialstr), "P%sw", c);
                        else
                                snprintf(p->dop.dialstr, sizeof(p->dop.dialstr), "T%sw", c);
                        break;
                }

                if (p->echotraining && (strlen(p->dop.dialstr) > 4)) {
                        memset(p->echorest, 'w', sizeof(p->echorest) - 1);
                        strcpy(p->echorest + (p->echotraining / 400) + 1, p->dop.dialstr + strlen(p->dop.dialstr) - 2);
                        p->echorest[sizeof(p->echorest) - 1] = '\0';
                        p->echobreak = 1;
                        p->dop.dialstr[strlen(p->dop.dialstr)-2] = '\0';
                } else
                        p->echobreak = 0;
                if (!res) {
                        if (ioctl(p->subs[SUB_REAL].zfd, ZT_DIAL, &p->dop)) {
                                x = ZT_ONHOOK;
                                ioctl(p->subs[SUB_REAL].zfd, ZT_HOOK, &x);
                                ast_log(LOG_WARNING, "Dialing failed on channel %d: %s\n", p->channel, strerror(errno));
                                ast_mutex_unlock(&p->lock);
                                return -1;
                        }
                } else
                        ast_log(LOG_DEBUG, "Deferring dialing...\n");
                p->dialing = 1;
                if (ast_strlen_zero(c))
                        p->dialednone = 1;
                ast_setstate(ast, AST_STATE_DIALING);
                break;
        case 0:
                /* Special pseudo -- automatically up*/
                ast_setstate(ast, AST_STATE_UP);
                break;          
        case SIG_PRI:
                /* We'll get it in a moment -- but use dialdest to store pre-setup_ack digits */
                p->dialdest[0] = '\0';
                break;
        default:
                ast_log(LOG_DEBUG, "not yet implemented\n");
                ast_mutex_unlock(&p->lock);
                return -1;
        }
#ifdef ZAPATA_PRI
        if (p->pri) {
                struct pri_sr *sr;
                const char *useruser;
                int pridialplan;
                int dp_strip;
                int prilocaldialplan;
                int ldp_strip;
                int exclusive;

                c = strchr(dest, '/');
                if (c)
                        c++;
                else
                        c = dest;
                if (!p->hidecallerid) {
                        l = ast->cid.cid_num;
                        n = ast->cid.cid_name;
                } else {
                        l = NULL;
                        n = NULL;
                }
                if (strlen(c) < p->stripmsd) {
                        ast_log(LOG_WARNING, "Number '%s' is shorter than stripmsd (%d)\n", c, p->stripmsd);
                        ast_mutex_unlock(&p->lock);
                        return -1;
                }
                if (p->sig != SIG_FXSKS) {
                        p->dop.op = ZT_DIAL_OP_REPLACE;
                        s = strchr(c + p->stripmsd, 'w');
                        if (s) {
                                if (strlen(s) > 1)
                                        snprintf(p->dop.dialstr, sizeof(p->dop.dialstr), "T%s", s);
                                else
                                        p->dop.dialstr[0] = '\0';
                                *s = '\0';
                        } else {
                                p->dop.dialstr[0] = '\0';
                        }
                }
                if (pri_grab(p, p->pri)) {
                        ast_log(LOG_WARNING, "Failed to grab PRI!\n");
                        ast_mutex_unlock(&p->lock);
                        return -1;
                }
                if (!(p->call = pri_new_call(p->pri->pri))) {
                        ast_log(LOG_WARNING, "Unable to create call on channel %d\n", p->channel);
                        pri_rel(p->pri);
                        ast_mutex_unlock(&p->lock);
                        return -1;
                }
                if (!(sr = pri_sr_new())) {
                        ast_log(LOG_WARNING, "Failed to allocate setup request channel %d\n", p->channel);
                        pri_rel(p->pri);
                        ast_mutex_unlock(&p->lock);
                }
                if (p->bearer || (p->sig == SIG_FXSKS)) {
                        if (p->bearer) {
                                ast_log(LOG_DEBUG, "Oooh, I have a bearer on %d (%d:%d)\n", PVT_TO_CHANNEL(p->bearer), p->bearer->logicalspan, p->bearer->channel);
                                p->bearer->call = p->call;
                        } else
                                ast_log(LOG_DEBUG, "I'm being setup with no bearer right now...\n");
                        pri_set_crv(p->pri->pri, p->call, p->channel, 0);
                }
                p->digital = IS_DIGITAL(ast->transfercapability);
                /* Add support for exclusive override */
                if (p->priexclusive)
                        exclusive = 1;
                else {
                /* otherwise, traditional behavior */
                        if (p->pri->nodetype == PRI_NETWORK)
                                exclusive = 0;
                        else
                                exclusive = 1;
                }
                
                pri_sr_set_channel(sr, p->bearer ? PVT_TO_CHANNEL(p->bearer) : PVT_TO_CHANNEL(p), exclusive, 1);
                pri_sr_set_bearer(sr, p->digital ? PRI_TRANS_CAP_DIGITAL : ast->transfercapability, 
                                        (p->digital ? -1 : 
                                                ((p->law == ZT_LAW_ALAW) ? PRI_LAYER_1_ALAW : PRI_LAYER_1_ULAW)));
                if (p->pri->facilityenable)
                        pri_facility_enable(p->pri->pri);

                if (option_verbose > 2)
                        ast_verbose(VERBOSE_PREFIX_3 "Requested transfer capability: 0x%.2x - %s\n", ast->transfercapability, ast_transfercapability2str(ast->transfercapability));
                dp_strip = 0;
                pridialplan = p->pri->dialplan - 1;
                if (pridialplan == -2) { /* compute dynamically */
                        if (strncmp(c + p->stripmsd, p->pri->internationalprefix, strlen(p->pri->internationalprefix)) == 0) {
                                dp_strip = strlen(p->pri->internationalprefix);
                                pridialplan = PRI_INTERNATIONAL_ISDN;
                        } else if (strncmp(c + p->stripmsd, p->pri->nationalprefix, strlen(p->pri->nationalprefix)) == 0) {
                                dp_strip = strlen(p->pri->nationalprefix);
                                pridialplan = PRI_NATIONAL_ISDN;
                        } else {
                                pridialplan = PRI_LOCAL_ISDN;
                        }
                }
                pri_sr_set_called(sr, c + p->stripmsd + dp_strip, pridialplan,  s ? 1 : 0);

                ldp_strip = 0;
                prilocaldialplan = p->pri->localdialplan - 1;
                if ((l != NULL) && (prilocaldialplan == -2)) { /* compute dynamically */
                        if (strncmp(l, p->pri->internationalprefix, strlen(p->pri->internationalprefix)) == 0) {
                                ldp_strip = strlen(p->pri->internationalprefix);
                                prilocaldialplan = PRI_INTERNATIONAL_ISDN;
                        } else if (strncmp(l, p->pri->nationalprefix, strlen(p->pri->nationalprefix)) == 0) {
                                ldp_strip = strlen(p->pri->nationalprefix);
                                prilocaldialplan = PRI_NATIONAL_ISDN;
                        } else {
                                prilocaldialplan = PRI_LOCAL_ISDN;
                        }
                }
                pri_sr_set_caller(sr, l ? (l + ldp_strip) : NULL, n, prilocaldialplan, 
                                        l ? (p->use_callingpres ? ast->cid.cid_pres : PRES_ALLOWED_USER_NUMBER_PASSED_SCREEN) : 
                                                 PRES_NUMBER_NOT_AVAILABLE);
                pri_sr_set_redirecting(sr, ast->cid.cid_rdnis, p->pri->localdialplan - 1, PRES_ALLOWED_USER_NUMBER_PASSED_SCREEN, PRI_REDIR_UNCONDITIONAL);
                /* User-user info */
                useruser = pbx_builtin_getvar_helper(p->owner, "USERUSERINFO");

                if (useruser)
                        pri_sr_set_useruser(sr, useruser);

                if (pri_setup(p->pri->pri, p->call,  sr)) {
                        ast_log(LOG_WARNING, "Unable to setup call to %s (using %s)\n", 
                                                c + p->stripmsd + dp_strip, dialplan2str(p->pri->dialplan));
                        pri_rel(p->pri);
                        ast_mutex_unlock(&p->lock);
                        pri_sr_free(sr);
                        return -1;
                }
                pri_sr_free(sr);
                ast_setstate(ast, AST_STATE_DIALING);
                pri_rel(p->pri);
        }
#endif          
        ast_mutex_unlock(&p->lock);
        return 0;
}

static void destroy_zt_pvt(struct zt_pvt **pvt)
{
        struct zt_pvt *p = *pvt;
        /* Remove channel from the list */
        if(p->prev)
                p->prev->next = p->next;
        if(p->next)
                p->next->prev = p->prev;
        ast_mutex_destroy(&p->lock);
        free(p);
        *pvt = NULL;
}

static int destroy_channel(struct zt_pvt *prev, struct zt_pvt *cur, int now)
{
        int owned = 0;
        int i = 0;

        if (!now) {
                if (cur->owner) {
                        owned = 1;
                }

                for (i = 0; i < 3; i++) {
                        if (cur->subs[i].owner) {
                                owned = 1;
                        }
                }
                if (!owned) {
                        if (prev) {
                                prev->next = cur->next;
                                if (prev->next)
                                        prev->next->prev = prev;
                                else
                                        ifend = prev;
                        } else {
                                iflist = cur->next;
                                if (iflist)
                                        iflist->prev = NULL;
                                else
                                        ifend = NULL;
                        }
                        if (cur->subs[SUB_REAL].zfd > -1) {
                                zt_close(cur->subs[SUB_REAL].zfd);
                        }
                        destroy_zt_pvt(&cur);
                }
        } else {
                if (prev) {
                        prev->next = cur->next;
                        if (prev->next)
                                prev->next->prev = prev;
                        else
                                ifend = prev;
                } else {
                        iflist = cur->next;
                        if (iflist)
                                iflist->prev = NULL;
                        else
                                ifend = NULL;
                }
                if (cur->subs[SUB_REAL].zfd > -1) {
                        zt_close(cur->subs[SUB_REAL].zfd);
                }
                destroy_zt_pvt(&cur);
        }
        return 0;
}

#ifdef ZAPATA_PRI
static char *zap_send_keypad_facility_app = "ZapSendKeypadFacility";

static char *zap_send_keypad_facility_synopsis = "Send digits out of band over a PRI";

static char *zap_send_keypad_facility_descrip = 
"  ZapSendKeypadFacility(): This application will send the given string of digits in a Keypad Facility\n"
"  IE over the current channel.\n";

static int zap_send_keypad_facility_exec(struct ast_channel *chan, void *data)
{
        /* Data will be our digit string */
        struct zt_pvt *p;
        char *digits = (char *) data;

        if (ast_strlen_zero(digits)) {
                ast_log(LOG_DEBUG, "No digit string sent to application!\n");
                return -1;
        }

        p = (struct zt_pvt *)chan->tech_pvt;

        if (!p) {
                ast_log(LOG_DEBUG, "Unable to find technology private\n");
                return -1;
        }

        ast_mutex_lock(&p->lock);

        if (!p->pri || !p->call) {
                ast_log(LOG_DEBUG, "Unable to find pri or call on channel!\n");
                ast_mutex_unlock(&p->lock);
                return -1;
        }

        if (!pri_grab(p, p->pri)) {
                pri_keypad_facility(p->pri->pri, p->call, digits);
                pri_rel(p->pri);
        } else {
                ast_log(LOG_DEBUG, "Unable to grab pri to send keypad facility!\n");
                ast_mutex_unlock(&p->lock);
                return -1;
        }

        ast_mutex_unlock(&p->lock);

        return 0;
}

int pri_is_up(struct zt_pri *pri)
{
        int x;
        for (x=0;x<NUM_DCHANS;x++) {
                if (pri->dchanavail[x] == DCHAN_AVAILABLE)
                        return 1;
        }
        return 0;
}

int pri_assign_bearer(struct zt_pvt *crv, struct zt_pri *pri, struct zt_pvt *bearer)
{
        bearer->owner = &inuse;
        bearer->realcall = crv;
        crv->subs[SUB_REAL].zfd = bearer->subs[SUB_REAL].zfd;
        if (crv->subs[SUB_REAL].owner)
                crv->subs[SUB_REAL].owner->fds[0] = crv->subs[SUB_REAL].zfd;
        crv->bearer = bearer;
        crv->call = bearer->call;
        crv->pri = pri;
        return 0;
}

static char *pri_order(int level)
{
        switch(level) {
        case 0:
                return "Primary";
        case 1:
                return "Secondary";
        case 2:
                return "Tertiary";
        case 3:
                return "Quaternary";
        default:
                return "<Unknown>";
        }               
}

/* Returns fd of the active dchan */
int pri_active_dchan_fd(struct zt_pri *pri)
{
        int x = -1;

        for (x = 0; x < NUM_DCHANS; x++) {
                if ((pri->dchans[x] == pri->pri))
                        break;
        }

        return pri->fds[x];
}

int pri_find_dchan(struct zt_pri *pri)
{
        int oldslot = -1;
        struct pri *old;
        int newslot = -1;
        int x;
        old = pri->pri;
        for(x=0;x<NUM_DCHANS;x++) {
                if ((pri->dchanavail[x] == DCHAN_AVAILABLE) && (newslot < 0))
                        newslot = x;
                if (pri->dchans[x] == old) {
                        oldslot = x;
                }
        }
        if (newslot < 0) {
                newslot = 0;
                ast_log(LOG_WARNING, "No D-channels available!  Using Primary channel %d as D-channel anyway!\n",
                        pri->dchannels[newslot]);
        }
        if (old && (oldslot != newslot))
                ast_log(LOG_NOTICE, "Switching from from d-channel %d to channel %d!\n",
                        pri->dchannels[oldslot], pri->dchannels[newslot]);
        pri->pri = pri->dchans[newslot];
        return 0;
}
#endif

static int zt_hangup(struct ast_channel *ast)
{
        int res;
        int index,x, law;
        /*static int restore_gains(struct zt_pvt *p);*/
        struct zt_pvt *p = ast->tech_pvt;
        struct zt_pvt *tmp = NULL;
        struct zt_pvt *prev = NULL;
        ZT_PARAMS par;

        if (option_debug)
                ast_log(LOG_DEBUG, "zt_hangup(%s)\n", ast->name);
        if (!ast->tech_pvt) {
                ast_log(LOG_WARNING, "Asked to hangup channel not connected\n");
                return 0;
        }
        
        ast_mutex_lock(&p->lock);
        
        index = zt_get_index(ast, p, 1);

        if (p->sig == SIG_PRI) {
                x = 1;
                ast_channel_setoption(ast,AST_OPTION_AUDIO_MODE,&x,sizeof(char),0);
        }

        x = 0;
        zt_confmute(p, 0);
        restore_gains(p);
        if (p->origcid_num) {
                ast_copy_string(p->cid_num, p->origcid_num, sizeof(p->cid_num));
                free(p->origcid_num);
                p->origcid_num = NULL;
        }       
        if (p->origcid_name) {
                ast_copy_string(p->cid_name, p->origcid_name, sizeof(p->cid_name));
                free(p->origcid_name);
                p->origcid_name = NULL;
        }       
        if (p->dsp)
                ast_dsp_digitmode(p->dsp,DSP_DIGITMODE_DTMF | p->dtmfrelax);
        if (p->exten)
                p->exten[0] = '\0';

        ast_log(LOG_DEBUG, "Hangup: channel: %d index = %d, normal = %d, callwait = %d, thirdcall = %d\n",
                p->channel, index, p->subs[SUB_REAL].zfd, p->subs[SUB_CALLWAIT].zfd, p->subs[SUB_THREEWAY].zfd);
        p->ignoredtmf = 0;
        
        if (index > -1) {
                /* Real channel, do some fixup */
                p->subs[index].owner = NULL;
                p->subs[index].needanswer = 0;
                p->subs[index].needflash = 0;
                p->subs[index].needringing = 0;
                p->subs[index].needbusy = 0;
                p->subs[index].needcongestion = 0;
                p->subs[index].linear = 0;
                p->subs[index].needcallerid = 0;
                p->polarity = POLARITY_IDLE;
                zt_setlinear(p->subs[index].zfd, 0);
                if (index == SUB_REAL) {
                        if ((p->subs[SUB_CALLWAIT].zfd > -1) && (p->subs[SUB_THREEWAY].zfd > -1)) {
                                ast_log(LOG_DEBUG, "Normal call hung up with both three way call and a call waiting call in place?\n");
                                if (p->subs[SUB_CALLWAIT].inthreeway) {
                                        /* We had flipped over to answer a callwait and now it's gone */
                                        ast_log(LOG_DEBUG, "We were flipped over to the callwait, moving back and unowning.\n");
                                        /* Move to the call-wait, but un-own us until they flip back. */
                                        swap_subs(p, SUB_CALLWAIT, SUB_REAL);
                                        unalloc_sub(p, SUB_CALLWAIT);
                                        p->owner = NULL;
                                } else {
                                        /* The three way hung up, but we still have a call wait */
                                        ast_log(LOG_DEBUG, "We were in the threeway and have a callwait still.  Ditching the threeway.\n");
                                        swap_subs(p, SUB_THREEWAY, SUB_REAL);
                                        unalloc_sub(p, SUB_THREEWAY);
                                        if (p->subs[SUB_REAL].inthreeway) {
                                                /* This was part of a three way call.  Immediately make way for
                                                   another call */
                                                ast_log(LOG_DEBUG, "Call was complete, setting owner to former third call\n");
                                                p->owner = p->subs[SUB_REAL].owner;
                                        } else {
                                                /* This call hasn't been completed yet...  Set owner to NULL */
                                                ast_log(LOG_DEBUG, "Call was incomplete, setting owner to NULL\n");
                                                p->owner = NULL;
                                        }
                                        p->subs[SUB_REAL].inthreeway = 0;
                                }
                        } else if (p->subs[SUB_CALLWAIT].zfd > -1) {
                                /* Move to the call-wait and switch back to them. */
                                swap_subs(p, SUB_CALLWAIT, SUB_REAL);
                                unalloc_sub(p, SUB_CALLWAIT);
                                p->owner = p->subs[SUB_REAL].owner;
                                if (p->owner->_state != AST_STATE_UP)
                                        p->subs[SUB_REAL].needanswer = 1;
                                if (ast_bridged_channel(p->subs[SUB_REAL].owner))
                                        ast_moh_stop(ast_bridged_channel(p->subs[SUB_REAL].owner));
                        } else if (p->subs[SUB_THREEWAY].zfd > -1) {
                                swap_subs(p, SUB_THREEWAY, SUB_REAL);
                                unalloc_sub(p, SUB_THREEWAY);
                                if (p->subs[SUB_REAL].inthreeway) {
                                        /* This was part of a three way call.  Immediately make way for
                                           another call */
                                        ast_log(LOG_DEBUG, "Call was complete, setting owner to former third call\n");
                                        p->owner = p->subs[SUB_REAL].owner;
                                } else {
                                        /* This call hasn't been completed yet...  Set owner to NULL */
                                        ast_log(LOG_DEBUG, "Call was incomplete, setting owner to NULL\n");
                                        p->owner = NULL;
                                }
                                p->subs[SUB_REAL].inthreeway = 0;
                        }
                } else if (index == SUB_CALLWAIT) {
                        /* Ditch the holding callwait call, and immediately make it availabe */
                        if (p->subs[SUB_CALLWAIT].inthreeway) {
                                /* This is actually part of a three way, placed on hold.  Place the third part
                                   on music on hold now */
                                if (p->subs[SUB_THREEWAY].owner && ast_bridged_channel(p->subs[SUB_THREEWAY].owner))
                                        ast_moh_start(ast_bridged_channel(p->subs[SUB_THREEWAY].owner), NULL);
                                p->subs[SUB_THREEWAY].inthreeway = 0;
                                /* Make it the call wait now */
                                swap_subs(p, SUB_CALLWAIT, SUB_THREEWAY);
                                unalloc_sub(p, SUB_THREEWAY);
                        } else
                                unalloc_sub(p, SUB_CALLWAIT);
                } else if (index == SUB_THREEWAY) {
                        if (p->subs[SUB_CALLWAIT].inthreeway) {
                                /* The other party of the three way call is currently in a call-wait state.
                                   Start music on hold for them, and take the main guy out of the third call */
                                if (p->subs[SUB_CALLWAIT].owner && ast_bridged_channel(p->subs[SUB_CALLWAIT].owner))
                                        ast_moh_start(ast_bridged_channel(p->subs[SUB_CALLWAIT].owner), NULL);
                                p->subs[SUB_CALLWAIT].inthreeway = 0;
                        }
                        p->subs[SUB_REAL].inthreeway = 0;
                        /* If this was part of a three way call index, let us make
                           another three way call */
                        unalloc_sub(p, SUB_THREEWAY);
                } else {
                        /* This wasn't any sort of call, but how are we an index? */
                        ast_log(LOG_WARNING, "Index found but not any type of call?\n");
                }
        }


        if (!p->subs[SUB_REAL].owner && !p->subs[SUB_CALLWAIT].owner && !p->subs[SUB_THREEWAY].owner) {
                p->owner = NULL;
                p->ringt = 0;
                p->distinctivering = 0;
                p->confirmanswer = 0;
                p->cidrings = 1;
                p->outgoing = 0;
                p->digital = 0;
                p->faxhandled = 0;
                p->pulsedial = 0;
                p->onhooktime = time(NULL);
#ifdef ZAPATA_PRI
                p->proceeding = 0;
                p->progress = 0;
                p->alerting = 0;
                p->setup_ack = 0;
#endif          
                if (p->dsp) {
                        ast_dsp_free(p->dsp);
                        p->dsp = NULL;
                }

                law = ZT_LAW_DEFAULT;
                res = ioctl(p->subs[SUB_REAL].zfd, ZT_SETLAW, &law);
                if (res < 0) 
                        ast_log(LOG_WARNING, "Unable to set law on channel %d to default\n", p->channel);
                /* Perform low level hangup if no owner left */
#ifdef ZAPATA_PRI
                if (p->pri) {
                        const char *useruser = pbx_builtin_getvar_helper(ast,"USERUSERINFO");
                        /* Make sure we have a call (or REALLY have a call in the case of a PRI) */
                        if (p->call && (!p->bearer || (p->bearer->call == p->call))) {
                                if (!pri_grab(p, p->pri)) {
                                        if (p->alreadyhungup) {
                                                ast_log(LOG_DEBUG, "Already hungup...  Calling hangup once, and clearing call\n");
                                                pri_call_set_useruser(p->call, useruser);
                                                pri_hangup(p->pri->pri, p->call, -1);
                                                p->call = NULL;
                                                if (p->bearer) 
                                                        p->bearer->call = NULL;
                                        } else {
                                                const char *cause = pbx_builtin_getvar_helper(ast,"PRI_CAUSE");
                                                int icause = ast->hangupcause ? ast->hangupcause : -1;
                                                ast_log(LOG_DEBUG, "Not yet hungup...  Calling hangup once with icause, and clearing call\n");
                                                pri_call_set_useruser(p->call, useruser);
                                                p->alreadyhungup = 1;
                                                if (p->bearer)
                                                        p->bearer->alreadyhungup = 1;
                                                if (cause) {
                                                        if (atoi(cause))
                                                                icause = atoi(cause);
                                                }
                                                pri_hangup(p->pri->pri, p->call, icause);
                                        }
                                        if (res < 0) 
                                                ast_log(LOG_WARNING, "pri_disconnect failed\n");
                                        pri_rel(p->pri);                        
                                } else {
                                        ast_log(LOG_WARNING, "Unable to grab PRI on span %d\n", p->span);
                                        res = -1;
                                }
                        } else {
                                if (p->bearer)
                                        ast_log(LOG_DEBUG, "Bearer call is %p, while ours is still %p\n", p->bearer->call, p->call);
                                p->call = NULL;
                                res = 0;
                        }
                }
#endif
#ifdef ZAPATA_R2
                if (p->sig == SIG_R2) {
                        if (p->hasr2call) {
                                mfcr2_DropCall(p->r2, NULL, UC_NORMAL_CLEARING);
                                p->hasr2call = 0;
                                res = 0;
                        } else
                                res = 0;

                }
#endif
                if (p->sig && (p->sig != SIG_PRI) && (p->sig != SIG_R2))
                        res = zt_set_hook(p->subs[SUB_REAL].zfd, ZT_ONHOOK);
                if (res < 0) {
                        ast_log(LOG_WARNING, "Unable to hangup line %s\n", ast->name);
                }
                switch(p->sig) {
                case SIG_FXOGS:
                case SIG_FXOLS:
                case SIG_FXOKS:
                        res = ioctl(p->subs[SUB_REAL].zfd, ZT_GET_PARAMS, &par);
                        if (!res) {
#if 0
                                ast_log(LOG_DEBUG, "Hanging up channel %d, offhook = %d\n", p->channel, par.rxisoffhook);
#endif
                                /* If they're off hook, try playing congestion */
                                if ((par.rxisoffhook) && (!p->radio))
                                        tone_zone_play_tone(p->subs[SUB_REAL].zfd, ZT_TONE_CONGESTION);
                                else
                                        tone_zone_play_tone(p->subs[SUB_REAL].zfd, -1);
                        }
                        break;
                case SIG_FXSGS:
                case SIG_FXSLS:
                case SIG_FXSKS:
                        /* Make sure we're not made available for at least two seconds assuming
                           we were actually used for an inbound or outbound call. */
                        if (ast->_state != AST_STATE_RESERVED) {
                                time(&p->guardtime);
                                p->guardtime += 2;
                        }
                        break;
                default:
                        tone_zone_play_tone(p->subs[SUB_REAL].zfd, -1);
                }
                if (p->cidspill)
                        free(p->cidspill);
                if (p->sig)
                        zt_disable_ec(p);
                x = 0;
                ast_channel_setoption(ast,AST_OPTION_TONE_VERIFY,&x,sizeof(char),0);
                ast_channel_setoption(ast,AST_OPTION_TDD,&x,sizeof(char),0);
                p->didtdd = 0;
                p->cidspill = NULL;
                p->callwaitcas = 0;
                p->callwaiting = p->permcallwaiting;
                p->hidecallerid = p->permhidecallerid;
                p->dialing = 0;
                p->rdnis[0] = '\0';
                update_conf(p);
                reset_conf(p);
                /* Restore data mode */
                if (p->sig == SIG_PRI) {
                        x = 0;
                        ast_channel_setoption(ast,AST_OPTION_AUDIO_MODE,&x,sizeof(char),0);
                }
#ifdef ZAPATA_PRI
                if (p->bearer) {
                        ast_log(LOG_DEBUG, "Freeing up bearer channel %d\n", p->bearer->channel);
                        /* Free up the bearer channel as well, and
                           don't use its file descriptor anymore */
                        update_conf(p->bearer);
                        reset_conf(p->bearer);
                        p->bearer->owner = NULL;
                        p->bearer->realcall = NULL;
                        p->bearer = NULL;
                        p->subs[SUB_REAL].zfd = -1;
                        p->pri = NULL;
                }
#endif
                restart_monitor();
        }


        p->callwaitingrepeat = 0;
        p->cidcwexpire = 0;
        ast->tech_pvt = NULL;
        ast_mutex_unlock(&p->lock);
        ast_mutex_lock(&usecnt_lock);
        usecnt--;
        if (usecnt < 0) 
                ast_log(LOG_WARNING, "Usecnt < 0???\n");
        ast_mutex_unlock(&usecnt_lock);
        ast_update_use_count();
        if (option_verbose > 2) 
                ast_verbose( VERBOSE_PREFIX_3 "Hungup '%s'\n", ast->name);

        ast_mutex_lock(&iflock);
        tmp = iflist;
        prev = NULL;
        if (p->destroy) {
                while (tmp) {
                        if (tmp == p) {
                                destroy_channel(prev, tmp, 0);
                                break;
                        } else {
                                prev = tmp;
                                tmp = tmp->next;
                        }
                }
        }
        ast_mutex_unlock(&iflock);
        return 0;
}

static int zt_answer(struct ast_channel *ast)
{
        struct zt_pvt *p = ast->tech_pvt;
        int res=0;
        int index;
        int oldstate = ast->_state;
        ast_setstate(ast, AST_STATE_UP);
        ast_mutex_lock(&p->lock);
        index = zt_get_index(ast, p, 0);
        if (index < 0)
                index = SUB_REAL;
        /* nothing to do if a radio channel */
        if (p->radio) {
                ast_mutex_unlock(&p->lock);
                return 0;
        }
        switch(p->sig) {
        case SIG_FXSLS:
        case SIG_FXSGS:
        case SIG_FXSKS:
                p->ringt = 0;
                /* Fall through */
        case SIG_EM:
        case SIG_EM_E1:
        case SIG_EMWINK:
        case SIG_FEATD:
        case SIG_FEATDMF:
        case SIG_E911:
        case SIG_FEATB:
        case SIG_SF:
        case SIG_SFWINK:
        case SIG_SF_FEATD:
        case SIG_SF_FEATDMF:
        case SIG_SF_FEATB:
        case SIG_FXOLS:
        case SIG_FXOGS:
        case SIG_FXOKS:
                /* Pick up the line */
                ast_log(LOG_DEBUG, "Took %s off hook\n", ast->name);
                if(p->hanguponpolarityswitch) {
                        gettimeofday(&p->polaritydelaytv, NULL);
                }
                res =  zt_set_hook(p->subs[SUB_REAL].zfd, ZT_OFFHOOK);
                tone_zone_play_tone(p->subs[index].zfd, -1);
                p->dialing = 0;
                if ((index == SUB_REAL) && p->subs[SUB_THREEWAY].inthreeway) {
                        if (oldstate == AST_STATE_RINGING) {
                                ast_log(LOG_DEBUG, "Finally swapping real and threeway\n");
                                tone_zone_play_tone(p->subs[SUB_THREEWAY].zfd, -1);
                                swap_subs(p, SUB_THREEWAY, SUB_REAL);
                                p->owner = p->subs[SUB_REAL].owner;
                        }
                }
                if (p->sig & __ZT_SIG_FXS) {
                        zt_enable_ec(p);
                        zt_train_ec(p);
                }
                break;
#ifdef ZAPATA_PRI
        case SIG_PRI:
                /* Send a pri acknowledge */
                if (!pri_grab(p, p->pri)) {
                        p->proceeding = 1;
                        res = pri_answer(p->pri->pri, p->call, 0, !p->digital);
                        pri_rel(p->pri);
                } else {
                        ast_log(LOG_WARNING, "Unable to grab PRI on span %d\n", p->span);
                        res= -1;
                }
                break;
#endif
#ifdef ZAPATA_R2
        case SIG_R2:
                res = mfcr2_AnswerCall(p->r2, NULL);
                if (res)
                        ast_log(LOG_WARNING, "R2 Answer call failed :( on %s\n", ast->name);
                break;
#endif                  
        case 0:
                ast_mutex_unlock(&p->lock);
                return 0;
        default:
                ast_log(LOG_WARNING, "Don't know how to answer signalling %d (channel %d)\n", p->sig, p->channel);
                res = -1;
        }
        ast_mutex_unlock(&p->lock);
        return res;
}

static int zt_setoption(struct ast_channel *chan, int option, void *data, int datalen)
{
        char *cp;
        signed char *scp;
        int x;
        int index;
        struct zt_pvt *p = chan->tech_pvt;

        /* all supported options require data */
        if (!data || (datalen < 1)) {
                errno = EINVAL;
                return -1;
        }

        switch(option) {
        case AST_OPTION_TXGAIN:
                scp = (signed char *) data;
                index = zt_get_index(chan, p, 0);
                if (index < 0) {
                        ast_log(LOG_WARNING, "No index in TXGAIN?\n");
                        return -1;
                }
                ast_log(LOG_DEBUG, "Setting actual tx gain on %s to %f\n", chan->name, p->txgain + (float) *scp);
                return set_actual_txgain(p->subs[index].zfd, 0, p->txgain + (float) *scp, p->law);
        case AST_OPTION_RXGAIN:
                scp = (signed char *) data;
                index = zt_get_index(chan, p, 0);
                if (index < 0) {
                        ast_log(LOG_WARNING, "No index in RXGAIN?\n");
                        return -1;
                }
                ast_log(LOG_DEBUG, "Setting actual rx gain on %s to %f\n", chan->name, p->rxgain + (float) *scp);
                return set_actual_rxgain(p->subs[index].zfd, 0, p->rxgain + (float) *scp, p->law);
        case AST_OPTION_TONE_VERIFY:
                if (!p->dsp)
                        break;
                cp = (char *) data;
                switch (*cp) {
                case 1:
                        ast_log(LOG_DEBUG, "Set option TONE VERIFY, mode: MUTECONF(1) on %s\n",chan->name);
                        ast_dsp_digitmode(p->dsp,DSP_DIGITMODE_MUTECONF | p->dtmfrelax);  /* set mute mode if desired */
                        break;
                case 2:
                        ast_log(LOG_DEBUG, "Set option TONE VERIFY, mode: MUTECONF/MAX(2) on %s\n",chan->name);
                        ast_dsp_digitmode(p->dsp,DSP_DIGITMODE_MUTECONF | DSP_DIGITMODE_MUTEMAX | p->dtmfrelax);  /* set mute mode if desired */
                        break;
                default:
                        ast_log(LOG_DEBUG, "Set option TONE VERIFY, mode: OFF(0) on %s\n",chan->name);
                        ast_dsp_digitmode(p->dsp,DSP_DIGITMODE_DTMF | p->dtmfrelax);  /* set mute mode if desired */
                        break;
                }
                break;
        case AST_OPTION_TDD:
                /* turn on or off TDD */
                cp = (char *) data;
                p->mate = 0;
                if (!*cp) { /* turn it off */
                        ast_log(LOG_DEBUG, "Set option TDD MODE, value: OFF(0) on %s\n",chan->name);
                        if (p->tdd) tdd_free(p->tdd);
                        p->tdd = 0;
                        break;
                }
                ast_log(LOG_DEBUG, "Set option TDD MODE, value: %s(%d) on %s\n",
                        (*cp == 2) ? "MATE" : "ON", (int) *cp, chan->name);
                zt_disable_ec(p);
                /* otherwise, turn it on */
                if (!p->didtdd) { /* if havent done it yet */
                        unsigned char mybuf[41000],*buf;
                        int size,res,fd,len;
                        struct pollfd fds[1];

                        buf = mybuf;
                        memset(buf, 0x7f, sizeof(mybuf)); /* set to silence */
                        ast_tdd_gen_ecdisa(buf + 16000, 16000);  /* put in tone */
                        len = 40000;
                        index = zt_get_index(chan, p, 0);
                        if (index < 0) {
                                ast_log(LOG_WARNING, "No index in TDD?\n");
                                return -1;
                        }
                        fd = p->subs[index].zfd;
                        while(len) {
                                if (ast_check_hangup(chan)) return -1;
                                size = len;
                                if (size > READ_SIZE)
                                        size = READ_SIZE;
                                fds[0].fd = fd;
                                fds[0].events = POLLPRI | POLLOUT;
                                fds[0].revents = 0;
                                res = poll(fds, 1, -1);
                                if (!res) {
                                        ast_log(LOG_DEBUG, "poll (for write) ret. 0 on channel %d\n", p->channel);
                                        continue;
                                }
                                /* if got exception */
                                if (fds[0].revents & POLLPRI) return -1;
                                if (!(fds[0].revents & POLLOUT)) {
                                        ast_log(LOG_DEBUG, "write fd not ready on channel %d\n", p->channel);
                                        continue;
                                }
                                res = write(fd, buf, size);
                                if (res != size) {
                                        if (res == -1) return -1;
                                        ast_log(LOG_DEBUG, "Write returned %d (%s) on channel %d\n", res, strerror(errno), p->channel);
                                        break;
                                }
                                len -= size;
                                buf += size;
                        }
                        p->didtdd = 1; /* set to have done it now */            
                }
                if (*cp == 2) { /* Mate mode */
                        if (p->tdd) tdd_free(p->tdd);
                        p->tdd = 0;
                        p->mate = 1;
                        break;
                }               
                if (!p->tdd) { /* if we dont have one yet */
                        p->tdd = tdd_new(); /* allocate one */
                }               
                break;
        case AST_OPTION_RELAXDTMF:  /* Relax DTMF decoding (or not) */
                if (!p->dsp)
                        break;
                cp = (char *) data;
                ast_log(LOG_DEBUG, "Set option RELAX DTMF, value: %s(%d) on %s\n",
                        *cp ? "ON" : "OFF", (int) *cp, chan->name);
                ast_dsp_digitmode(p->dsp, ((*cp) ? DSP_DIGITMODE_RELAXDTMF : DSP_DIGITMODE_DTMF) | p->dtmfrelax);
                break;
        case AST_OPTION_AUDIO_MODE:  /* Set AUDIO mode (or not) */
                cp = (char *) data;
                if (!*cp) {             
                        ast_log(LOG_DEBUG, "Set option AUDIO MODE, value: OFF(0) on %s\n", chan->name);
                        x = 0;
                        zt_disable_ec(p);
                } else {                
                        ast_log(LOG_DEBUG, "Set option AUDIO MODE, value: ON(1) on %s\n", chan->name);
                        x = 1;
                }
                if (ioctl(p->subs[SUB_REAL].zfd, ZT_AUDIOMODE, &x) == -1)
                        ast_log(LOG_WARNING, "Unable to set audio mode on channel %d to %d\n", p->channel, x);
                break;
        }
        errno = 0;

        return 0;
}

static void zt_unlink(struct zt_pvt *slave, struct zt_pvt *master, int needlock)
{
        /* Unlink a specific slave or all slaves/masters from a given master */
        int x;
        int hasslaves;
        if (!master)
                return;
        if (needlock) {
                ast_mutex_lock(&master->lock);
                if (slave) {
                        while(ast_mutex_trylock(&slave->lock)) {
                                ast_mutex_unlock(&master->lock);
                                usleep(1);
                                ast_mutex_lock(&master->lock);
                        }
                }
        }
        hasslaves = 0;
        for (x=0;x<MAX_SLAVES;x++) {
                if (master->slaves[x]) {
                        if (!slave || (master->slaves[x] == slave)) {
                                /* Take slave out of the conference */
                                ast_log(LOG_DEBUG, "Unlinking slave %d from %d\n", master->slaves[x]->channel, master->channel);
                                conf_del(master, &master->slaves[x]->subs[SUB_REAL], SUB_REAL);
                                conf_del(master->slaves[x], &master->subs[SUB_REAL], SUB_REAL);
                                master->slaves[x]->master = NULL;
                                master->slaves[x] = NULL;
                        } else
                                hasslaves = 1;
                }
                if (!hasslaves)
                        master->inconference = 0;
        }
        if (!slave) {
                if (master->master) {
                        /* Take master out of the conference */
                        conf_del(master->master, &master->subs[SUB_REAL], SUB_REAL);
                        conf_del(master, &master->master->subs[SUB_REAL], SUB_REAL);
                        hasslaves = 0;
                        for (x=0;x<MAX_SLAVES;x++) {
                                if (master->master->slaves[x] == master)
                                        master->master->slaves[x] = NULL;
                                else if (master->master->slaves[x])
                                        hasslaves = 1;
                        }
                        if (!hasslaves)
                                master->master->inconference = 0;
                }
                master->master = NULL;
        }
        update_conf(master);
        if (needlock) {
                if (slave)
                        ast_mutex_unlock(&slave->lock);
                ast_mutex_unlock(&master->lock);
        }
}

static void zt_link(struct zt_pvt *slave, struct zt_pvt *master) {
        int x;
        if (!slave || !master) {
                ast_log(LOG_WARNING, "Tried to link to/from NULL??\n");
                return;
        }
        for (x=0;x<MAX_SLAVES;x++) {
                if (!master->slaves[x]) {
                        master->slaves[x] = slave;
                        break;
                }
        }
        if (x >= MAX_SLAVES) {
                ast_log(LOG_WARNING, "Replacing slave %d with new slave, %d\n", master->slaves[MAX_SLAVES - 1]->channel, slave->channel);
                master->slaves[MAX_SLAVES - 1] = slave;
        }
        if (slave->master) 
                ast_log(LOG_WARNING, "Replacing master %d with new master, %d\n", slave->master->channel, master->channel);
        slave->master = master;
        
        ast_log(LOG_DEBUG, "Making %d slave to master %d at %d\n", slave->channel, master->channel, x);
}

static void disable_dtmf_detect(struct zt_pvt *p)
{
#ifdef ZT_TONEDETECT
        int val;
#endif

        p->ignoredtmf = 1;

#ifdef ZT_TONEDETECT
        val = 0;
        ioctl(p->subs[SUB_REAL].zfd, ZT_TONEDETECT, &val);
#endif          
        if (!p->hardwaredtmf && p->dsp) {
                p->dsp_features &= ~DSP_FEATURE_DTMF_DETECT;
                ast_dsp_set_features(p->dsp, p->dsp_features);
        }
}

static void enable_dtmf_detect(struct zt_pvt *p)
{
#ifdef ZT_TONEDETECT
        int val;
#endif

        p->ignoredtmf = 0;

#ifdef ZT_TONEDETECT
        val = ZT_TONEDETECT_ON | ZT_TONEDETECT_MUTE;
        ioctl(p->subs[SUB_REAL].zfd, ZT_TONEDETECT, &val);
#endif          
        if (!p->hardwaredtmf && p->dsp) {
                p->dsp_features |= DSP_FEATURE_DTMF_DETECT;
                ast_dsp_set_features(p->dsp, p->dsp_features);
        }
}

static enum ast_bridge_result zt_bridge(struct ast_channel *c0, struct ast_channel *c1, int flags, struct ast_frame **fo, struct ast_channel **rc, int timeoutms)
{
        struct ast_channel *who;
        struct zt_pvt *p0, *p1, *op0, *op1;
        struct zt_pvt *master = NULL, *slave = NULL;
        struct ast_frame *f;
        int inconf = 0;
        int nothingok = 1;
        int ofd0, ofd1;
        int oi0, oi1, i0 = -1, i1 = -1, t0, t1;
        int os0 = -1, os1 = -1;
        int priority = 0;
        struct ast_channel *oc0, *oc1;