/* * libpri: An implementation of Primary Rate ISDN * * Written by Mark Spencer * * This program is confidential * * Copyright (C) 2001, Linux Support Services, Inc. * All Rights Reserved. * */ #include #include #include #include #include #include #include #include #include #include "compat.h" #include "libpri.h" #include "pri_internal.h" #include "pri_facility.h" #include "pri_q921.h" #include "pri_q931.h" #include "pri_timers.h" char *pri_node2str(int node) { switch(node) { case PRI_UNKNOWN: return "Unknown node type"; case PRI_NETWORK: return "Network"; case PRI_CPE: return "CPE"; default: return "Invalid value"; } } char *pri_switch2str(int sw) { switch(sw) { case PRI_SWITCH_NI2: return "National ISDN"; case PRI_SWITCH_DMS100: return "Nortel DMS100"; case PRI_SWITCH_LUCENT5E: return "Lucent 5E"; case PRI_SWITCH_ATT4ESS: return "AT&T 4ESS"; case PRI_SWITCH_NI1: return "National ISDN 1"; case PRI_SWITCH_EUROISDN_E1: return "EuroISDN"; case PRI_SWITCH_GR303_EOC: return "GR303 EOC"; case PRI_SWITCH_GR303_TMC: return "GR303 TMC"; case PRI_SWITCH_QSIG: return "Q.SIG switch"; default: return "Unknown switchtype"; } } static void pri_default_timers(struct pri *pri, int switchtype) { int defaulttimers[20][PRI_MAX_TIMERS] = PRI_TIMERS_ALL; int x; for (x = 0; xtimers[x] = defaulttimers[switchtype][x]; } } int pri_set_timer(struct pri *pri, int timer, int value) { if (timer < 0 || timer > PRI_MAX_TIMERS || value < 0) return -1; pri->timers[timer] = value; return 0; } int pri_get_timer(struct pri *pri, int timer) { if (timer < 0 || timer > PRI_MAX_TIMERS) return -1; return pri->timers[timer]; } int pri_timer2idx(char *timer) { if (!strcasecmp(timer, "N200")) return PRI_TIMER_N200; else if (!strcasecmp(timer, "N201")) return PRI_TIMER_N201; else if (!strcasecmp(timer, "N202")) return PRI_TIMER_N202; else if (!strcasecmp(timer, "K")) return PRI_TIMER_K; else if (!strcasecmp(timer, "T200")) return PRI_TIMER_T200; else if (!strcasecmp(timer, "T202")) return PRI_TIMER_T202; else if (!strcasecmp(timer, "T203")) return PRI_TIMER_T203; else if (!strcasecmp(timer, "T300")) return PRI_TIMER_T300; else if (!strcasecmp(timer, "T301")) return PRI_TIMER_T301; else if (!strcasecmp(timer, "T302")) return PRI_TIMER_T302; else if (!strcasecmp(timer, "T303")) return PRI_TIMER_T303; else if (!strcasecmp(timer, "T304")) return PRI_TIMER_T304; else if (!strcasecmp(timer, "T305")) return PRI_TIMER_T305; else if (!strcasecmp(timer, "T306")) return PRI_TIMER_T306; else if (!strcasecmp(timer, "T307")) return PRI_TIMER_T307; else if (!strcasecmp(timer, "T308")) return PRI_TIMER_T308; else if (!strcasecmp(timer, "T309")) return PRI_TIMER_T309; else if (!strcasecmp(timer, "T310")) return PRI_TIMER_T310; else if (!strcasecmp(timer, "T313")) return PRI_TIMER_T313; else if (!strcasecmp(timer, "T314")) return PRI_TIMER_T314; else if (!strcasecmp(timer, "T316")) return PRI_TIMER_T316; else if (!strcasecmp(timer, "T317")) return PRI_TIMER_T317; else if (!strcasecmp(timer, "T318")) return PRI_TIMER_T318; else if (!strcasecmp(timer, "T319")) return PRI_TIMER_T319; else if (!strcasecmp(timer, "T320")) return PRI_TIMER_T320; else if (!strcasecmp(timer, "T321")) return PRI_TIMER_T321; else if (!strcasecmp(timer, "T322")) return PRI_TIMER_T322; else return -1; } static int __pri_read(struct pri *pri, void *buf, int buflen) { int res = read(pri->fd, buf, buflen); if (res < 0) { if (errno != EAGAIN) pri_error(pri, "Read on %d failed: %s\n", pri->fd, strerror(errno)); return 0; } return res; } static int __pri_write(struct pri *pri, void *buf, int buflen) { int res = write(pri->fd, buf, buflen); if (res < 0) { if (errno != EAGAIN) pri_error(pri, "Write to %d failed: %s\n", pri->fd, strerror(errno)); return 0; } return res; } static struct pri *__pri_new(int fd, int node, int switchtype, struct pri *master, pri_io_cb rd, pri_io_cb wr, void *userdata) { struct pri *p; p = malloc(sizeof(struct pri)); if (p) { memset(p, 0, sizeof(struct pri)); p->fd = fd; p->read_func = rd; p->write_func = wr; p->userdata = userdata; p->localtype = node; p->switchtype = switchtype; p->cref = 1; p->sapi = Q921_SAPI_CALL_CTRL; p->tei = 0; p->nsf = PRI_NSF_NONE; p->protodisc = Q931_PROTOCOL_DISCRIMINATOR; p->master = master; p->callpool = &p->localpool; pri_default_timers(p, switchtype); #ifdef LIBPRI_COUNTERS p->q921_rxcount = 0; p->q921_txcount = 0; p->q931_rxcount = 0; p->q931_txcount = 0; #endif if (switchtype == PRI_SWITCH_GR303_EOC) { p->protodisc = GR303_PROTOCOL_DISCRIMINATOR; p->sapi = Q921_SAPI_GR303_EOC; p->tei = Q921_TEI_GR303_EOC_OPS; p->subchannel = __pri_new(-1, node, PRI_SWITCH_GR303_EOC_PATH, p, NULL, NULL, NULL); if (!p->subchannel) { free(p); p = NULL; } } else if (switchtype == PRI_SWITCH_GR303_TMC) { p->protodisc = GR303_PROTOCOL_DISCRIMINATOR; p->sapi = Q921_SAPI_GR303_TMC_CALLPROC; p->tei = Q921_TEI_GR303_TMC_CALLPROC; p->subchannel = __pri_new(-1, node, PRI_SWITCH_GR303_TMC_SWITCHING, p, NULL, NULL, NULL); if (!p->subchannel) { free(p); p = NULL; } } else if (switchtype == PRI_SWITCH_GR303_TMC_SWITCHING) { p->protodisc = GR303_PROTOCOL_DISCRIMINATOR; p->sapi = Q921_SAPI_GR303_TMC_SWITCHING; p->tei = Q921_TEI_GR303_TMC_SWITCHING; } else if (switchtype == PRI_SWITCH_GR303_EOC_PATH) { p->protodisc = GR303_PROTOCOL_DISCRIMINATOR; p->sapi = Q921_SAPI_GR303_EOC; p->tei = Q921_TEI_GR303_EOC_PATH; } /* Start Q.921 layer, Wait if we're the network */ if (p) q921_start(p, p->localtype == PRI_CPE); } return p; } struct pri *pri_new(int fd, int nodetype, int switchtype) { return __pri_new(fd, nodetype, switchtype, NULL, __pri_read, __pri_write, NULL); } struct pri *pri_new_cb(int fd, int nodetype, int switchtype, pri_io_cb io_read, pri_io_cb io_write, void *userdata) { if (!io_read) io_read = __pri_read; if (!io_write) io_write = __pri_write; return __pri_new(fd, nodetype, switchtype, NULL, io_read, io_write, userdata); } void *pri_get_userdata(struct pri *pri) { return pri ? pri->userdata : NULL; } void pri_set_userdata(struct pri *pri, void *userdata) { if (pri) pri->userdata = userdata; } void pri_set_nsf(struct pri *pri, int nsf) { if (pri) pri->nsf = nsf; } char *pri_event2str(int id) { switch(id) { case PRI_EVENT_DCHAN_UP: return "D-Channel Up"; case PRI_EVENT_DCHAN_DOWN: return "D-channel Down"; case PRI_EVENT_RESTART: return "Restart channel"; case PRI_EVENT_RING: return "Ring"; case PRI_EVENT_HANGUP: return "Hangup"; case PRI_EVENT_RINGING: return "Ringing"; case PRI_EVENT_ANSWER: return "Answer"; case PRI_EVENT_HANGUP_ACK: return "Hangup ACK"; case PRI_EVENT_RESTART_ACK: return "Restart ACK"; case PRI_EVENT_FACNAME: return "FacName"; case PRI_EVENT_INFO_RECEIVED: return "Info Received"; case PRI_EVENT_PROCEEDING: return "Proceeding"; case PRI_EVENT_SETUP_ACK: return "Setup ACK"; case PRI_EVENT_HANGUP_REQ: return "Hangup Req"; case PRI_EVENT_NOTIFY: return "Notify"; case PRI_EVENT_PROGRESS: return "Progress"; case PRI_EVENT_CONFIG_ERR: return "Configuration Error"; default: return "Unknown Event"; } } pri_event *pri_check_event(struct pri *pri) { char buf[1024]; int res; pri_event *e; res = pri->read_func ? pri->read_func(pri, buf, sizeof(buf)) : 0; if (!res) return NULL; /* Receive the q921 packet */ e = q921_receive(pri, (q921_h *)buf, res); return e; } static int wait_pri(struct pri *pri) { struct timeval *tv, real; fd_set fds; int res; FD_ZERO(&fds); FD_SET(pri->fd, &fds); tv = pri_schedule_next(pri); if (tv) { gettimeofday(&real, NULL); real.tv_sec = tv->tv_sec - real.tv_sec; real.tv_usec = tv->tv_usec - real.tv_usec; if (real.tv_usec < 0) { real.tv_usec += 1000000; real.tv_sec -= 1; } if (real.tv_sec < 0) { real.tv_sec = 0; real.tv_usec = 0; } } res = select(pri->fd + 1, &fds, NULL, NULL, tv ? &real : tv); if (res < 0) return -1; return res; } pri_event *pri_mkerror(struct pri *pri, char *errstr) { /* Return a configuration error */ pri->ev.err.e = PRI_EVENT_CONFIG_ERR; strncpy(pri->ev.err.err, errstr, sizeof(pri->ev.err.err) - 1); return &pri->ev; } pri_event *pri_dchannel_run(struct pri *pri, int block) { pri_event *e; int res; if (!pri) return NULL; if (block) { do { e = NULL; res = wait_pri(pri); /* Check for error / interruption */ if (res < 0) return NULL; if (!res) e = pri_schedule_run(pri); else e = pri_check_event(pri); } while(!e); } else { e = pri_check_event(pri); return e; } return e; } void pri_set_debug(struct pri *pri, int debug) { if (!pri) return; pri->debug = debug; if (pri->subchannel) pri_set_debug(pri->subchannel, debug); } int pri_get_debug(struct pri *pri) { if (!pri) return -1; if (pri->subchannel) return pri_get_debug(pri->subchannel); return pri->debug; } void pri_facility_enable(struct pri *pri) { if (!pri) return; pri->sendfacility = 1; if (pri->subchannel) pri_facility_enable(pri->subchannel); return; } int pri_acknowledge(struct pri *pri, q931_call *call, int channel, int info) { if (!pri || !call) return -1; return q931_alerting(pri, call, channel, info); } int pri_proceeding(struct pri *pri, q931_call *call, int channel, int info) { if (!pri || !call) return -1; return q931_call_proceeding(pri, call, channel, info); } int pri_progress(struct pri *pri, q931_call *call, int channel, int info) { if (!pri || !call) return -1; return q931_call_progress(pri, call, channel, info); } int pri_information(struct pri *pri, q931_call *call, char digit) { if (!pri || !call) return -1; return q931_information(pri, call, digit); } int pri_notify(struct pri *pri, q931_call *call, int channel, int info) { if (!pri || !call) return -1; return q931_notify(pri, call, channel, info); } void pri_destroycall(struct pri *pri, q931_call *call) { if (pri && call) __q931_destroycall(pri, call); return; } int pri_need_more_info(struct pri *pri, q931_call *call, int channel, int nonisdn) { if (!pri || !call) return -1; return q931_setup_ack(pri, call, channel, nonisdn); } int pri_answer(struct pri *pri, q931_call *call, int channel, int nonisdn) { if (!pri || !call) return -1; return q931_connect(pri, call, channel, nonisdn); } #if 0 /* deprecated routines, use pri_hangup */ int pri_release(struct pri *pri, q931_call *call, int cause) { if (!pri || !call) return -1; return q931_release(pri, call, cause); } int pri_disconnect(struct pri *pri, q931_call *call, int cause) { if (!pri || !call) return -1; return q931_disconnect(pri, call, cause); } #endif int pri_channel_bridge(q931_call *call1, q931_call *call2) { if (!call1 || !call2) return -1; /* Check switchtype compatibility */ if (call1->pri->switchtype != PRI_SWITCH_LUCENT5E || call2->pri->switchtype != PRI_SWITCH_LUCENT5E) return -1; /* Check for bearer capability */ if (call1->transcapability != call2->transcapability) return -1; /* Check to see if calls are on the same PRI dchannel * Currently only support calls on the same dchannel */ if (call1->pri != call2->pri) return -1; if (eect_initiate_transfer(call1->pri, call1, call2)) return -1; return 0; } int pri_hangup(struct pri *pri, q931_call *call, int cause) { if (!pri || !call) return -1; if (cause == -1) /* normal clear cause */ cause = 16; return q931_hangup(pri, call, cause); } int pri_reset(struct pri *pri, int channel) { if (!pri) return -1; return q931_restart(pri, channel); } q931_call *pri_new_call(struct pri *pri) { if (!pri) return NULL; return q931_new_call(pri); } void pri_dump_event(struct pri *pri, pri_event *e) { if (!pri || !e) return; pri_message(pri, "Event type: %s (%d)\n", pri_event2str(e->gen.e), e->gen.e); switch(e->gen.e) { case PRI_EVENT_DCHAN_UP: case PRI_EVENT_DCHAN_DOWN: break; case PRI_EVENT_CONFIG_ERR: pri_message(pri, "Error: %s", e->err.err); break; case PRI_EVENT_RESTART: pri_message(pri, "Restart on channel %d\n", e->restart.channel); case PRI_EVENT_RING: pri_message(pri, "Calling number: %s (%s, %s)\n", e->ring.callingnum, pri_plan2str(e->ring.callingplan), pri_pres2str(e->ring.callingpres)); pri_message(pri, "Called number: %s (%s)\n", e->ring.callednum, pri_plan2str(e->ring.calledplan)); pri_message(pri, "Channel: %d (%s) Reference number: %d\n", e->ring.channel, e->ring.flexible ? "Flexible" : "Not Flexible", e->ring.cref); break; case PRI_EVENT_HANGUP: pri_message(pri, "Hangup, reference number: %d, reason: %s\n", e->hangup.cref, pri_cause2str(e->hangup.cause)); break; default: pri_message(pri, "Don't know how to dump events of type %d\n", e->gen.e); } } static void pri_sr_init(struct pri_sr *req) { memset(req, 0, sizeof(struct pri_sr)); } int pri_sr_set_connection_call_independent(struct pri_sr *req) { if (!req) return -1; req->justsignalling = 1; /* have to set justsignalling for all those pesky IEs we need to setup */ return 0; } /* Don't call any other pri functions on this */ int pri_mwi_activate(struct pri *pri, q931_call *c, char *caller, int callerplan, char *callername, int callerpres, char *called, int calledplan) { struct pri_sr req; if (!pri || !c) return -1; pri_sr_init(&req); pri_sr_set_connection_call_independent(&req); req.caller = caller; req.callerplan = callerplan; req.callername = callername; req.callerpres = callerpres; req.called = called; req.calledplan = calledplan; if (mwi_message_send(pri, c, &req, 1) < 0) { pri_message(pri, "Unable to send MWI activate message\n"); return -1; } /* Do more stuff when we figure out that the CISC stuff works */ return q931_setup(pri, c, &req); } int pri_mwi_deactivate(struct pri *pri, q931_call *c, char *caller, int callerplan, char *callername, int callerpres, char *called, int calledplan) { struct pri_sr req; if (!pri || !c) return -1; pri_sr_init(&req); pri_sr_set_connection_call_independent(&req); req.caller = caller; req.callerplan = callerplan; req.callername = callername; req.callerpres = callerpres; req.called = called; req.calledplan = calledplan; if(mwi_message_send(pri, c, &req, 0) < 0) { pri_message(pri, "Unable to send MWI deactivate message\n"); return -1; } return q931_setup(pri, c, &req); } int pri_setup(struct pri *pri, q931_call *c, struct pri_sr *req) { if (!pri || !c) return -1; return q931_setup(pri, c, req); } int pri_call(struct pri *pri, q931_call *c, int transmode, int channel, int exclusive, int nonisdn, char *caller, int callerplan, char *callername, int callerpres, char *called, int calledplan,int ulayer1) { struct pri_sr req; if (!pri || !c) return -1; pri_sr_init(&req); req.transmode = transmode; req.channel = channel; req.exclusive = exclusive; req.nonisdn = nonisdn; req.caller = caller; req.callerplan = callerplan; req.callername = callername; req.callerpres = callerpres; req.called = called; req.calledplan = calledplan; req.userl1 = ulayer1; return q931_setup(pri, c, &req); } static void (*__pri_error)(struct pri *pri, char *stuff); static void (*__pri_message)(struct pri *pri, char *stuff); void pri_set_message(void (*func)(struct pri *pri, char *stuff)) { __pri_message = func; } void pri_set_error(void (*func)(struct pri *pri, char *stuff)) { __pri_error = func; } void pri_message(struct pri *pri, char *fmt, ...) { char tmp[1024]; va_list ap; va_start(ap, fmt); vsnprintf(tmp, sizeof(tmp), fmt, ap); va_end(ap); if (__pri_message) __pri_message(pri, tmp); else fputs(tmp, stdout); } void pri_error(struct pri *pri, char *fmt, ...) { char tmp[1024]; va_list ap; va_start(ap, fmt); vsnprintf(tmp, sizeof(tmp), fmt, ap); va_end(ap); if (__pri_error) __pri_error(pri, tmp); else fputs(tmp, stderr); } /* Set overlap mode */ void pri_set_overlapdial(struct pri *pri,int state) { pri->overlapdial = state; } int pri_fd(struct pri *pri) { return pri->fd; } char *pri_dump_info_str(struct pri *pri) { char buf[4096]; int len = 0; #ifdef LIBPRI_COUNTERS struct q921_frame *f; int q921outstanding = 0; #endif if (!pri) return NULL; /* Might be nice to format these a little better */ len += sprintf(buf + len, "Switchtype: %s\n", pri_switch2str(pri->switchtype)); len += sprintf(buf + len, "Type: %s\n", pri_node2str(pri->localtype)); #ifdef LIBPRI_COUNTERS /* Remember that Q921 Counters include Q931 packets (and any retransmissions) */ len += sprintf(buf + len, "Q931 RX: %d\n", pri->q931_rxcount); len += sprintf(buf + len, "Q931 TX: %d\n", pri->q931_txcount); len += sprintf(buf + len, "Q921 RX: %d\n", pri->q921_rxcount); len += sprintf(buf + len, "Q921 TX: %d\n", pri->q921_txcount); f = pri->txqueue; while (f) { q921outstanding++; f = f->next; } len += sprintf(buf + len, "Q921 Outstanding: %d\n", q921outstanding); #endif len += sprintf(buf + len, "Window Length: %d/%d\n", pri->windowlen, pri->window); len += sprintf(buf + len, "Sentrej: %d\n", pri->sentrej); len += sprintf(buf + len, "SolicitFbit: %d\n", pri->solicitfbit); len += sprintf(buf + len, "Retrans: %d\n", pri->retrans); len += sprintf(buf + len, "Busy: %d\n", pri->busy); len += sprintf(buf + len, "Overlap Dial: %d\n", pri->overlapdial); len += sprintf(buf + len, "T200 Timer: %d\n", pri->timers[PRI_TIMER_T200]); len += sprintf(buf + len, "T203 Timer: %d\n", pri->timers[PRI_TIMER_T203]); len += sprintf(buf + len, "T305 Timer: %d\n", pri->timers[PRI_TIMER_T305]); len += sprintf(buf + len, "T308 Timer: %d\n", pri->timers[PRI_TIMER_T308]); len += sprintf(buf + len, "T313 Timer: %d\n", pri->timers[PRI_TIMER_T313]); len += sprintf(buf + len, "N200 Counter: %d\n", pri->timers[PRI_TIMER_N200]); return strdup(buf); } int pri_get_crv(struct pri *pri, q931_call *call, int *callmode) { return q931_call_getcrv(pri, call, callmode); } int pri_set_crv(struct pri *pri, q931_call *call, int crv, int callmode) { return q931_call_setcrv(pri, call, crv, callmode); } void pri_enslave(struct pri *master, struct pri *slave) { if (master && slave) slave->callpool = &master->localpool; } struct pri_sr *pri_sr_new(void) { struct pri_sr *req; req = malloc(sizeof(struct pri_sr)); if (req) pri_sr_init(req); return req; } void pri_sr_free(struct pri_sr *sr) { free(sr); } int pri_sr_set_channel(struct pri_sr *sr, int channel, int exclusive, int nonisdn) { sr->channel = channel; sr->exclusive = exclusive; sr->nonisdn = nonisdn; return 0; } int pri_sr_set_bearer(struct pri_sr *sr, int transmode, int userl1) { sr->transmode = transmode; sr->userl1 = userl1; return 0; } int pri_sr_set_called(struct pri_sr *sr, char *called, int calledplan, int numcomplete) { sr->called = called; sr->calledplan = calledplan; sr->numcomplete = numcomplete; return 0; } int pri_sr_set_caller(struct pri_sr *sr, char *caller, char *callername, int callerplan, int callerpres) { sr->caller = caller; sr->callername = callername; sr->callerplan = callerplan; sr->callerpres = callerpres; return 0; } int pri_sr_set_redirecting(struct pri_sr *sr, char *num, int plan, int pres, int reason) { sr->redirectingnum = num; sr->redirectingplan = plan; sr->redirectingpres = pres; sr->redirectingreason = reason; return 0; }