Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/lindev/@/contrib/ngatm/netnatm/sig/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/lindev/@/contrib/ngatm/netnatm/sig/sig_coord.c |
/* * Copyright (c) 1996-2003 * Fraunhofer Institute for Open Communication Systems (FhG Fokus). * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * Author: Hartmut Brandt <harti@freebsd.org> * * $Begemot: libunimsg/netnatm/sig/sig_coord.c,v 1.12 2004/08/05 07:11:01 brandt Exp $ * * Coordinator */ #include <netnatm/unimsg.h> #include <netnatm/saal/sscfudef.h> #include <netnatm/msg/unistruct.h> #include <netnatm/msg/unimsglib.h> #include <netnatm/sig/uni.h> #include <netnatm/sig/unipriv.h> #include <netnatm/sig/unimkmsg.h> #define STR(S) [S] = #S static const char *const cunames[] = { STR(CU_STAT0), STR(CU_STAT1), STR(CU_STAT2), STR(CU_STAT3), }; #define DEF_PRIV_SIG(NAME, FROM) [SIG##NAME] = "SIG"#NAME, static const char *const coord_sigs[] = { DEF_COORD_SIGS }; #undef DEF_PRIV_SIG static void sig_all_calls(struct uni *, u_int sig); static void set_custat(struct uni *, enum cu_stat); static void input_dummy(struct uni *uni, struct uni_msg *m, struct uni_all *u); static void input_global(struct uni *uni, struct uni_msg *m, struct uni_all *u); static void input_unknown(struct uni *uni, struct uni_msg *m, struct uni_all *u); static void input_cobi(struct call *c, struct uni_msg *m, struct uni_all *u); static void input_call(struct call *c, struct uni_msg *m, struct uni_all *u); TIMER_FUNC_UNI(t309, t309_func) /* * All those 'bogus signal' printouts are not specified in the SDLs. */ /* * SAAL-ESTABLISH.indication * * This means either a resynchronisation or error-recovery or * an incoming SSCOP connection. */ static void coord_saal_establish_indication(struct uni *uni) { switch (uni->custat) { case CU_STAT0: /* Q.2931:Coord-U 4/10 */ case CU_STAT3: /* Q.2931:Coord-U 5/10 */ sig_all_calls(uni, SIGC_LINK_ESTABLISH_indication); set_custat(uni, CU_STAT3); break; case CU_STAT1: case CU_STAT2: VERBOSE0(uni, UNI_FAC_COORD, "signal saal_establish.indication in CU%u", uni->custat); break; default: ASSERT(0, ("CU_STAT*")); } } /* * SAAL-ESTABLISH.confirm */ static void coord_saal_establish_confirm(struct uni *uni) { switch (uni->custat) { case CU_STAT0: case CU_STAT2: VERBOSE0(uni, UNI_FAC_COORD, "signal saal_establish.confirm in CU%u", uni->custat); break; case CU_STAT1: /* * Q.2931:Co-ord-U 4/10 */ TIMER_STOP_UNI(uni, t309); sig_all_calls(uni, SIGC_LINK_ESTABLISH_confirm); uni->funcs->uni_output(uni, uni->arg, UNIAPI_LINK_ESTABLISH_confirm, 0, NULL); set_custat(uni, CU_STAT3); break; case CU_STAT3: /* * Q.2931:Coord-U 5/10 */ sig_all_calls(uni, SIGC_LINK_ESTABLISH_confirm); uni->funcs->uni_output(uni, uni->arg, UNIAPI_LINK_ESTABLISH_confirm, 0, NULL); break; default: ASSERT(0, ("CU_STAT*")); } } /* * SAAL-RELEASE.confirm */ static void coord_saal_release_confirm(struct uni *uni) { switch (uni->custat) { case CU_STAT0: case CU_STAT1: case CU_STAT3: VERBOSE0(uni, UNI_FAC_COORD, "signal saal_release.confirm in CU%u", uni->custat); break; case CU_STAT2: /* * Q.2931:Coord-U 5/10 */ uni->funcs->uni_output(uni, uni->arg, UNIAPI_LINK_RELEASE_confirm, 0, NULL); set_custat(uni, CU_STAT0); break; default: ASSERT(0, ("CU_STAT*")); } } /* * SAAL failure. */ static void coord_saal_release_indication(struct uni *uni) { switch (uni->custat) { case CU_STAT0: case CU_STAT2: VERBOSE0(uni, UNI_FAC_COORD, "signal saal_release.indication in CU%u", uni->custat); break; case CU_STAT1: case CU_STAT3: /* * Q.2931:Coord-U 4/10 * Q.2931:Coord-U 5/10 */ sig_all_calls(uni, SIGC_LINK_RELEASE_indication); set_custat(uni, CU_STAT0); break; default: ASSERT(0, ("CU_STAT*")); } } /* * Link-establish.request from USER. This can also come from * a call instance. In this case 'cookie' is zero. */ static void coord_link_establish_request(struct uni *uni, uint32_t cookie) { switch (uni->custat) { case CU_STAT0: /* * Q.2931:Coord-U 4/10 */ uni->funcs->saal_output(uni, uni->arg, SAAL_ESTABLISH_request, NULL); if (!TIMER_ISACT(uni, t309)) TIMER_START_UNI(uni, t309, uni->timer309); set_custat(uni, CU_STAT1); if (cookie) uniapi_uni_error(uni, UNIAPI_OK, cookie, 0); break; case CU_STAT1: /* * Q.2931:Coord-U 4/10 * This is probably missing from the delay field. */ uni_delenq_coord(uni, SIGO_LINK_ESTABLISH_request, cookie, NULL); break; case CU_STAT2: uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALLSTATE, cookie, 0); if (cookie == 0) VERBOSE0(uni, UNI_FAC_COORD, "signal link-establish.request in CU%u", uni->custat); break; case CU_STAT3: /* * Q.2931:Coord-U 5/10 */ uni->funcs->uni_output(uni, uni->arg, UNIAPI_LINK_ESTABLISH_confirm, 0, NULL); uniapi_uni_error(uni, UNIAPI_OK, cookie, 0); break; default: ASSERT(0, ("CU_STAT*")); } } /* * Link-release.request from user */ static void coord_link_release_request(struct uni *uni, u_int cookie) { switch (uni->custat) { case CU_STAT0: case CU_STAT1: case CU_STAT2: uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALLSTATE, cookie, 0); break; case CU_STAT3: /* * Q.2931:Coord-U 5/10 */ uni->funcs->saal_output(uni, uni->arg, SAAL_RELEASE_request, NULL); set_custat(uni, CU_STAT2); uniapi_uni_error(uni, UNIAPI_OK, cookie, 0); break; default: ASSERT(0, ("CU_STAT*")); } } /* * T309 timeout signal */ static void coord_t309(struct uni *uni) { switch (uni->custat) { case CU_STAT0: case CU_STAT1: /* * Q.2931:Coord-U 4/10 */ sig_all_calls(uni, SIGC_LINK_ESTABLISH_ERROR_indication); set_custat(uni, CU_STAT0); /* this is not in the SDLs, but how will the call control * know, that starting the LINK has failed otherwise? */ uni->funcs->uni_output(uni, uni->arg, UNIAPI_LINK_RELEASE_confirm, 0, NULL); break; case CU_STAT2: case CU_STAT3: VERBOSE0(uni, UNI_FAC_COORD, "signal T309 in CU%u", uni->custat); break; default: ASSERT(0, ("CU_STAT*")); } } /* * Message from SAAL */ static void coord_saal_data_indication(struct uni *uni, struct uni_msg *m) { struct uni_all *u; struct call *c; memset(&uni->cause, 0, sizeof(uni->cause)); if ((u = UNI_ALLOC()) == NULL) { uni_msg_destroy(m); return; } if (uni_decode_head(m, u, &uni->cx)) { VERBOSE(uni, UNI_FAC_COORD, 2, "bogus message - ignored"); uni_msg_destroy(m); UNI_FREE(u); return; } if (u->u.hdr.cref.cref == CREF_DUMMY) { if (uni->cx.q2932) { input_dummy(uni, m, u); } else { VERBOSE(uni, UNI_FAC_COORD, 2, "dummy cref - ignored"); UNI_FREE(u); uni_msg_destroy(m); } return; } if (u->u.hdr.cref.cref == CREF_GLOBAL) input_global(uni, m, u); else if ((c = uni_find_call(uni, &u->u.hdr.cref)) == NULL) input_unknown(uni, m, u); else if (c->type == CALL_COBI) input_cobi(c, m, u); else input_call(c, m, u); } /* * Message with global call reference * * Q.2931:Coord-U (X) 7/10 */ static void input_global(struct uni *uni, struct uni_msg *m, struct uni_all *u) { VERBOSE(uni, UNI_FAC_COORD, 2, "GLOB MTYPE = %x", u->mtype); switch (u->mtype) { default: /* * Q.2931:Coord-U 7/10 * Q.2931: 5.6.3.2e * Amd4: 29e */ uni_respond_status(uni, &u->u.hdr.cref, u->u.hdr.cref.flag ? uni->glob_start : uni->glob_respond, UNI_CAUSE_CREF_INV); break; case UNI_RESTART: if (u->u.hdr.cref.flag) { /* * Q.2931:Coord-U 7/10 (5.6.3.2h) */ uni_respond_status(uni, &u->u.hdr.cref, uni->glob_start, UNI_CAUSE_CREF_INV); break; } uni_enq_resp(uni, SIGR_RESTART, 0, m, u); return; case UNI_RESTART_ACK: if (!u->u.hdr.cref.flag) { /* * Q.2931:Coord-U 7/10 (5.6.3.2h) * Note, that the SDL diagram contains an error. * The error with the 'YES' label should go to the * box below 'OTHER'. */ uni_respond_status(uni, &u->u.hdr.cref, uni->glob_respond, UNI_CAUSE_CREF_INV); break; } uni_enq_start(uni, SIGS_RESTART_ACK, 0, m, u); return; case UNI_STATUS: if (u->u.hdr.cref.flag) uni_enq_start(uni, SIGS_STATUS, 0, m, u); else uni_enq_resp(uni, SIGR_STATUS, 0, m, u); return; } uni_msg_destroy(m); UNI_FREE(u); } /* * Q.2931:Coord-U 8/10 * * Message for an unknown call reference */ static void input_unknown(struct uni *uni, struct uni_msg *m, struct uni_all *u) { struct uni_all *resp; struct call *c; u_int cause = UNI_CAUSE_CREF_INV; VERBOSE(uni, UNI_FAC_COORD, 2, "UNKNOWN MTYPE = %x", u->mtype); switch (u->mtype) { default: /* * This message type is entirly unknown * * 5.6.4 and 5.7.1 are only when the call is not in the * NULL state. This means, 5.6.3.2a takes over. */ break; case UNI_SETUP: if (u->u.hdr.cref.flag) /* * 5.6.3.2c */ goto drop; if ((c = uni_create_call(uni, u->u.hdr.cref.cref, 0, 0)) != NULL) { uni_enq_call(c, SIGC_SETUP, 0, m, u); return; } goto drop; case UNI_RELEASE_COMPL: /* * 5.6.3.2c */ goto drop; case UNI_STATUS: /* * 5.6.12 * * The SDLs don't use the verify procedure and don't * handle the case of an invalid callstate - we * ignore the message, if the callstate is not good. */ (void)uni_decode_body(m, u, &uni->cx); if (!IE_ISGOOD(u->u.status.callstate)) goto drop; if (u->u.status.callstate.state == UNI_CALLSTATE_U0) goto drop; cause = UNI_CAUSE_MSG_INCOMP; break; case UNI_STATUS_ENQ: if ((resp = UNI_ALLOC()) == NULL) goto drop; (void)uni_decode_body(m, u, &uni->cx); MK_MSG_RESP(resp, UNI_STATUS, &u->u.hdr.cref); MK_IE_CALLSTATE(resp->u.status.callstate, UNI_CALLSTATE_U0); MK_IE_CAUSE(resp->u.status.cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_STATUS); if (IE_ISGOOD(u->u.status_enq.epref)) { /* reflect epref as required by L3MU_PO */ resp->u.status.epref = u->u.status_enq.epref; MK_IE_EPREF(resp->u.status.epref, u->u.status_enq.epref.epref, !u->u.status_enq.epref.flag); MK_IE_EPSTATE(resp->u.status.epstate, UNI_EPSTATE_NULL); } (void)uni_send_output(resp, uni); UNI_FREE(resp); goto drop; case UNI_COBISETUP: if (u->u.hdr.cref.flag) /* * 5.6.3.2c (probably) */ goto drop; if ((c = uni_create_call(uni, u->u.hdr.cref.cref, 0, 0)) != NULL) { uni_enq_call(c, SIGC_COBISETUP, 0, m, u); return; } goto drop; } /* * 5.6.3.2a) * * Respond with a RELEASE COMPLETE */ if ((resp = UNI_ALLOC()) == NULL) goto drop; MK_MSG_RESP(resp, UNI_RELEASE_COMPL, &u->u.hdr.cref); MK_IE_CAUSE(resp->u.release_compl.cause[0], UNI_CAUSE_LOC_USER, cause); if (uni_diag(cause, UNI_CODING_ITU) == UNI_DIAG_MTYPE) ADD_CAUSE_MTYPE(resp->u.release_compl.cause[0], u->mtype); (void)uni_send_output(resp, uni); UNI_FREE(resp); drop: UNI_FREE(u); uni_msg_destroy(m); } static void input_cobi(struct call *c __unused, struct uni_msg *m, struct uni_all *u) { /* XXX */ UNI_FREE(u); uni_msg_destroy(m); } static void input_dummy(struct uni *uni __unused, struct uni_msg *m, struct uni_all *u) { /* XXX */ UNI_FREE(u); uni_msg_destroy(m); } static void input_call(struct call *c, struct uni_msg *m, struct uni_all *u) { VERBOSE(c->uni, UNI_FAC_COORD, 2, "CALL MTYPE = %x %d/%s", u->mtype, c->cref, c->mine ? "mine":"his"); switch (u->mtype) { case UNI_SETUP: /* * Ignored */ break; case UNI_CALL_PROC: uni_enq_call(c, SIGC_CALL_PROC, 0, m, u); return; case UNI_ALERTING: uni_enq_call(c, SIGC_ALERTING, 0, m, u); return; case UNI_RELEASE: uni_enq_call(c, SIGC_RELEASE, 0, m, u); return; case UNI_RELEASE_COMPL: uni_enq_call(c, SIGC_RELEASE_COMPL, 0, m, u); return; case UNI_CONNECT: uni_enq_call(c, SIGC_CONNECT, 0, m, u); return; case UNI_CONNECT_ACK: uni_enq_call(c, SIGC_CONNECT_ACK, 0, m, u); return; case UNI_NOTIFY: uni_enq_call(c, SIGC_NOTIFY, 0, m, u); return; case UNI_STATUS: uni_enq_call(c, SIGC_STATUS, 0, m, u); return; case UNI_STATUS_ENQ: uni_enq_call(c, SIGC_STATUS_ENQ, 0, m, u); return; case UNI_ADD_PARTY: uni_enq_call(c, SIGC_ADD_PARTY, 0, m, u); return; case UNI_PARTY_ALERTING: uni_enq_call(c, SIGC_PARTY_ALERTING, 0, m, u); return; case UNI_ADD_PARTY_ACK: uni_enq_call(c, SIGC_ADD_PARTY_ACK, 0, m, u); return; case UNI_ADD_PARTY_REJ: uni_enq_call(c, SIGC_ADD_PARTY_REJ, 0, m, u); return; case UNI_DROP_PARTY: uni_enq_call(c, SIGC_DROP_PARTY, 0, m, u); return; case UNI_DROP_PARTY_ACK: uni_enq_call(c, SIGC_DROP_PARTY_ACK, 0, m, u); return; default: uni_enq_call(c, SIGC_UNKNOWN, 0, m, u); return; } UNI_FREE(u); uni_msg_destroy(m); } /* * This macro tries to implement the delaying behaviour for * message from the API when we are in the Awaiting-Establish state. * In this state, the message is delayed. If we drop back to CU 0, * everything gets unqueued and errors are returned for all that stuff. * If we progess to CUSTAT2 we process the requests. */ #define COMMON_DELAY(SIG, COOKIE) \ if (uni->custat == CU_STAT0 || uni->custat == CU_STAT2) {\ uniapi_uni_error(uni, UNIAPI_ERROR_BADCU, \ COOKIE, 0); \ break; \ } \ if (uni->custat == CU_STAT1) { \ uni_delenq_coord(uni, SIG, COOKIE, msg); \ break; \ } /* * Signal handler of the coordinator */ void uni_sig_coord(struct uni *uni, enum coord_sig sig, uint32_t cookie, struct uni_msg *msg) { struct call *c; if (sig >= SIGO_END) { VERBOSE(uni, UNI_FAC_ERR, 1, "Signal %d outside of range to " "Coord", sig); if (msg) uni_msg_destroy(msg); return; } VERBOSE(uni, UNI_FAC_COORD, 1, "Signal %s in state %s", coord_sigs[sig], cunames[uni->custat]); switch (sig) { case SIGO_END: break; case SIGO_DATA: /* delayed output */ if (uni->custat == CU_STAT0 || uni->custat == CU_STAT1) break; /* drop */ if (uni->custat == CU_STAT1) uni_delenq_coord(uni, SIGO_DATA, cookie, msg);/* ??? */ else uni->funcs->saal_output(uni, uni->arg, SAAL_DATA_request, msg); msg = NULL; break; /* * SAAL signals */ case SIGO_SAAL_ESTABLISH_indication: coord_saal_establish_indication(uni); break; case SIGO_SAAL_ESTABLISH_confirm: coord_saal_establish_confirm(uni); break; case SIGO_SAAL_RELEASE_confirm: coord_saal_release_confirm(uni); break; case SIGO_SAAL_RELEASE_indication: coord_saal_release_indication(uni); break; case SIGO_SAAL_DATA_indication: coord_saal_data_indication(uni, msg); msg = NULL; break; case SIGO_SAAL_UDATA_indication: VERBOSE0(uni, UNI_FAC_ERR, "SAAL_UDATA_indication"); break; /* * Signals from USER */ case SIGO_LINK_ESTABLISH_request: coord_link_establish_request(uni, cookie); break; case SIGO_LINK_RELEASE_request: coord_link_release_request(uni, cookie); break; case SIGO_RESET_request: uni_enq_start(uni, SIGS_RESET_request, cookie, msg, NULL); msg = NULL; if (uni->custat == CU_STAT0) { uni->funcs->saal_output(uni, uni->arg, SAAL_ESTABLISH_request, NULL); if (!TIMER_ISACT(uni, t309)) TIMER_START_UNI(uni, t309, uni->timer309); set_custat(uni, CU_STAT1); } break; case SIGO_RESET_ERROR_response: COMMON_DELAY(SIGO_RESET_ERROR_response, cookie); uni_enq_resp(uni, SIGR_RESET_ERROR_response, cookie, msg, NULL); msg = NULL; break; case SIGO_RESET_response: COMMON_DELAY(SIGO_RESET_response, cookie); uni_enq_resp(uni, SIGR_RESET_response, cookie, msg, NULL); msg = NULL; break; case SIGO_SETUP_request: if ((c = uni_create_new_call(uni, cookie)) != NULL) { uni_enq_call(c, SIGC_SETUP_request, cookie, msg, NULL); msg = NULL; if (uni->custat == CU_STAT0) { uni->funcs->saal_output(uni, uni->arg, SAAL_ESTABLISH_request, NULL); if (!TIMER_ISACT(uni, t309)) TIMER_START_UNI(uni, t309, uni->timer309); set_custat(uni, CU_STAT1); } } else { uniapi_uni_error(uni, UNIAPI_ERROR_NOMEM, cookie, UNI_CALLSTATE_U0); } break; case SIGO_PROCEEDING_request: { struct uniapi_proceeding_request *arg = uni_msg_rptr(msg, struct uniapi_proceeding_request *); COMMON_DELAY(SIGO_PROCEEDING_request, cookie); if ((c = uni_find_call(uni, &arg->call_proc.hdr.cref)) != NULL) { uni_enq_call(c, SIGC_PROCEEDING_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_ALERTING_request: { struct uniapi_alerting_request *arg = uni_msg_rptr(msg, struct uniapi_alerting_request *); COMMON_DELAY(SIGO_ALERTING_request, cookie); if ((c = uni_find_call(uni, &arg->alerting.hdr.cref)) != NULL) { uni_enq_call(c, SIGC_ALERTING_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_SETUP_response: { struct uniapi_setup_response *arg = uni_msg_rptr(msg, struct uniapi_setup_response *); COMMON_DELAY(SIGO_SETUP_response, cookie); if ((c = uni_find_call(uni, &arg->connect.hdr.cref)) != NULL) { uni_enq_call(c, SIGC_SETUP_response, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_SETUP_COMPLETE_request: { struct uniapi_setup_complete_request *arg = uni_msg_rptr(msg, struct uniapi_setup_complete_request *); COMMON_DELAY(SIGO_SETUP_COMPLETE_request, cookie); if ((c = uni_find_call(uni, &arg->connect_ack.hdr.cref)) != NULL) { uni_enq_call(c, SIGC_SETUP_COMPLETE_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_RELEASE_request: { struct uniapi_release_request *arg = uni_msg_rptr(msg, struct uniapi_release_request *); COMMON_DELAY(SIGO_RELEASE_request, cookie); if ((c = uni_find_call(uni, &arg->release.hdr.cref)) != NULL) { uni_enq_call(c, SIGC_RELEASE_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_RELEASE_response: { struct uniapi_release_response *arg = uni_msg_rptr(msg, struct uniapi_release_response *); COMMON_DELAY(SIGO_RELEASE_response, cookie); if ((c = uni_find_call(uni, &arg->release_compl.hdr.cref)) != NULL) { uni_enq_call(c, SIGC_RELEASE_response, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_NOTIFY_request: { struct uniapi_notify_request *arg = uni_msg_rptr(msg, struct uniapi_notify_request *); COMMON_DELAY(SIGO_NOTIFY_request, cookie); if ((c = uni_find_call(uni, &arg->notify.hdr.cref)) != NULL) { uni_enq_call(c, SIGC_NOTIFY_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_STATUS_ENQUIRY_request: { struct uniapi_status_enquiry_request *arg = uni_msg_rptr(msg, struct uniapi_status_enquiry_request *); COMMON_DELAY(SIGO_STATUS_ENQUIRY_request, cookie); if ((c = uni_find_call(uni, &arg->cref)) != NULL) { uni_enq_call(c, SIGC_STATUS_ENQUIRY_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_ADD_PARTY_request: { struct uniapi_add_party_request *arg = uni_msg_rptr(msg, struct uniapi_add_party_request *); COMMON_DELAY(SIGO_ADD_PARTY_request, cookie); if ((c = uni_find_call(uni, &arg->add.hdr.cref)) != NULL) { if (c->type != CALL_ROOT) { uniapi_call_error(c, UNIAPI_ERROR_BAD_CTYPE, cookie); break; } uni_enq_call(c, SIGC_ADD_PARTY_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_PARTY_ALERTING_request: { struct uniapi_party_alerting_request *arg = uni_msg_rptr(msg, struct uniapi_party_alerting_request *); COMMON_DELAY(SIGO_PARTY_ALERTING_request, cookie); if ((c = uni_find_call(uni, &arg->alert.hdr.cref)) != NULL) { if (c->type != CALL_LEAF) { uniapi_call_error(c, UNIAPI_ERROR_BAD_CTYPE, cookie); break; } uni_enq_call(c, SIGC_PARTY_ALERTING_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_ADD_PARTY_ACK_request: { struct uniapi_add_party_ack_request *arg = uni_msg_rptr(msg, struct uniapi_add_party_ack_request *); COMMON_DELAY(SIGO_ADD_PARTY_ACK_request, cookie); if ((c = uni_find_call(uni, &arg->ack.hdr.cref)) != NULL) { if (c->type != CALL_LEAF) { uniapi_call_error(c, UNIAPI_ERROR_BAD_CTYPE, cookie); break; } uni_enq_call(c, SIGC_ADD_PARTY_ACK_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_ADD_PARTY_REJ_request: { struct uniapi_add_party_rej_request *arg = uni_msg_rptr(msg, struct uniapi_add_party_rej_request *); COMMON_DELAY(SIGO_ADD_PARTY_REJ_request, cookie); if ((c = uni_find_call(uni, &arg->rej.hdr.cref)) != NULL) { if (c->type != CALL_LEAF) { uniapi_call_error(c, UNIAPI_ERROR_BAD_CTYPE, cookie); break; } uni_enq_call(c, SIGC_ADD_PARTY_REJ_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_DROP_PARTY_request: { struct uniapi_drop_party_request *arg = uni_msg_rptr(msg, struct uniapi_drop_party_request *); COMMON_DELAY(SIGO_DROP_PARTY_request, cookie); if ((c = uni_find_call(uni, &arg->drop.hdr.cref)) != NULL) { if (c->type != CALL_ROOT && c->type != CALL_LEAF) { uniapi_call_error(c, UNIAPI_ERROR_BAD_CTYPE, cookie); break; } uni_enq_call(c, SIGC_DROP_PARTY_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_DROP_PARTY_ACK_request: { struct uniapi_drop_party_ack_request *arg = uni_msg_rptr(msg, struct uniapi_drop_party_ack_request *); COMMON_DELAY(SIGO_DROP_PARTY_ACK_request, cookie); if ((c = uni_find_call(uni, &arg->ack.hdr.cref)) != NULL) { if (c->type != CALL_ROOT && c->type != CALL_LEAF) { uniapi_call_error(c, UNIAPI_ERROR_BAD_CTYPE, cookie); break; } uni_enq_call(c, SIGC_DROP_PARTY_ACK_request, cookie, msg, NULL); msg = NULL; } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } case SIGO_ABORT_CALL_request: { struct uniapi_abort_call_request *arg = uni_msg_rptr(msg, struct uniapi_abort_call_request *); if ((c = uni_find_call(uni, &arg->cref)) != NULL) { uni_enq_call(c, SIGC_ABORT_CALL_request, cookie, NULL, NULL); } else { uniapi_uni_error(uni, UNIAPI_ERROR_BAD_CALL, cookie, UNI_CALLSTATE_U0); } break; } /* * Call-Control */ case SIGO_CALL_DESTROYED: uni->funcs->uni_output(uni, uni->arg, UNIAPI_CALL_DESTROYED, 0, msg); msg = NULL; break; /* * ResetRespond */ case SIGO_RESET_indication: uni->funcs->uni_output(uni, uni->arg, UNIAPI_RESET_indication, 0, msg); msg = NULL; break; /* * Timeouts */ case SIGO_T309: coord_t309(uni); break; } if (msg != NULL) uni_msg_destroy(msg); } /* * Send a signal to all call instances */ static void sig_all_calls(struct uni *uni, u_int sig) { struct call *call; TAILQ_FOREACH(call, &uni->calls, link) uni_enq_call(call, sig, 0, NULL, NULL); } /* * Set a new coordinator state - this moves all delayed coordinator * signals from the delayed queue to the signal queue. */ static int cufilt(struct sig *s, void *arg __unused) { return (s->type == SIG_COORD); } static void set_custat(struct uni *uni, enum cu_stat nstate) { if (uni->custat != nstate) { uni->custat = nstate; uni_undel(uni, cufilt, NULL); } } /* * T309 timeout function */ static void t309_func(struct uni *uni) { uni_enq_coord(uni, SIGO_T309, 0, NULL); } /* * Respond with a status message */ void uni_respond_status(struct uni *uni, struct uni_cref *cref, enum uni_callstate cs, enum uni_cause c1) { struct uni_all *resp; if ((resp = UNI_ALLOC()) == NULL) return; MK_MSG_RESP(resp, UNI_STATUS, cref); MK_IE_CALLSTATE(resp->u.status.callstate, cs); MK_IE_CAUSE(resp->u.status.cause, UNI_CAUSE_LOC_USER, c1); (void)uni_send_output(resp, uni); UNI_FREE(resp); } /* * Respond with a status message */ void uni_respond_status_mtype(struct uni *uni, struct uni_cref *cref, enum uni_callstate cs, enum uni_cause c1, u_int mtype) { struct uni_all *resp; if((resp = UNI_ALLOC()) == NULL) return; MK_MSG_RESP(resp, UNI_STATUS, cref); MK_IE_CALLSTATE(resp->u.status.callstate, cs); MK_IE_CAUSE(resp->u.status.cause, UNI_CAUSE_LOC_USER, c1); ADD_CAUSE_MTYPE(resp->u.status.cause, mtype); (void)uni_send_output(resp, uni); UNI_FREE(resp); } /* * Send a message. If we are in CUSTAT1, delay the message if we * are in CUSTAT3 send it, else drop it. */ int uni_send_output(struct uni_all *u, struct uni *uni) { struct uni_msg *m; int err; if (uni->custat == CU_STAT0 || uni->custat == CU_STAT2) return (0); m = uni_msg_alloc(1024); if ((err = uni_encode(m, u, &uni->cx)) != 0) { VERBOSE0(uni, UNI_FAC_ERR, "uni_encode failed: %08x", err); uni_msg_destroy(m); return (-1); } if (uni->custat == CU_STAT1) uni_delenq_coord(uni, SIGO_DATA, 0, m); else uni->funcs->saal_output(uni, uni->arg, SAAL_DATA_request, m); return (0); }