Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/usb/urio/@/amd64/compile/hs32/modules/usr/src/sys/modules/usb/ucycom/@/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/usb/urio/@/amd64/compile/hs32/modules/usr/src/sys/modules/usb/ucycom/@/contrib/ngatm/netnatm/sig/sig_verify.c |
/* * Copyright (c) 2001-2003 * 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_verify.c,v 1.19 2004/07/08 08:22:23 brandt Exp $ * * Message verification with explicit action indicators. */ #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> void uni_mandate_ie(struct uni *uni, enum uni_ietype ie) { struct uni_ierr *e; FOREACH_ERR(e, uni) if (e->ie == ie) { e->man = 1; return; } if (UNI_SAVE_IERR(&uni->cx, ie, UNI_IEACT_DEFAULT, UNI_IERR_MIS)) uni->cx.err[uni->cx.errcnt - 1].man = 1; } /* * This special handling is required for ADD PARTY, PARTY ALERTING and * ADD PARTY ACKNOWLEDGE by Q.2971 9.5.3.2.1. * It means, that the EPREF should be handled as mandatory only if * no other IEs have explicit action indicators. */ void uni_mandate_epref(struct uni *uni, struct uni_ie_epref *epref) { struct uni_ierr *e; int maxact; if (!IE_ISPRESENT(*epref)) { /* * 9.5.3.2.1 -- missing endpoint reference */ /* * a) if any unrecognized or IE with error has a CLEAR * action indicator, this takes precedence. * b) if any unrecognized or IE with error has a * discard message and report action indicator, this takes * precedence. * c) if any unrecognized or IE with error has a * discard message action indicator, this takes * precedence. * * In any of these cases we must remove the EPREF IE * if it has CLEAR, otherwise the CLEAR would take over. */ maxact = -1; FOREACH_ERR(e, uni) { if (e->ie == UNI_IE_EPREF) continue; if (e->act == UNI_IEACT_CLEAR) maxact = UNI_IEACT_CLEAR; else if (e->act == UNI_IEACT_MSG_REPORT) { if (maxact == -1 && maxact != UNI_IEACT_CLEAR) maxact = UNI_IEACT_MSG_REPORT; } else if (e->act == UNI_IEACT_MSG_IGNORE) { if (maxact == -1) maxact = UNI_IEACT_MSG_IGNORE; } } if (maxact != -1) { /* ok, second pass to remove UNI_IE_EPREF */ FOREACH_ERR(e, uni) if (e->ie == UNI_IE_EPREF) { memmove(e, e + 1, (uni->cx.errcnt - (e - uni->cx.err) - 1) * sizeof(uni->cx.err[0])); uni->cx.errcnt--; break; } return; } /* * d) if nothing of the above, the IE is mandatory */ uni_mandate_ie(uni, UNI_IE_EPREF); return; } if (IE_ISGOOD(*epref)) return; /* * It has an error obviously * 9.5.3.2.2 * * It turns out, that Q.2931 handling just does the right thing * if we don't mandate the IE. */ return; } /* * Look, what to do with this message. We assume, that the message itself is * recognized. * * This is rather complicated. We must use the information provided in the * fields of the context, because IEs with length errors may not be set * altogether. */ enum verify uni_verify(struct uni *uni, enum uni_msgact msgact) { struct uni_ierr *e1; if (uni->debug[UNI_FAC_VERIFY] >= 2) { FOREACH_ERR(e1, uni) { VERBOSE(uni, UNI_FAC_VERIFY, 2, "ie=%02x err=%u man=%d" " act=%u", e1->ie, e1->err, e1->man, e1->act); } } /* * Look for missing mandatory IEs. The action indicator is ignored * according to 5.6.7.1. If IEs are missing the action is to * ignore the message and report status for all messages except * RELEASE, RELEASE_COMPLETE and SETUP. Because we must differentiate * this RAI from other RAIs in this case, use another return code. * Note, that mandatory IEs with errors are not handled here. */ FOREACH_ERR(e1, uni) { if (e1->err == UNI_IERR_MIS) { MK_IE_CAUSE(uni->cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_MANDAT); VERBOSE(uni, UNI_FAC_VERIFY, 1, "RAIM"); return (VFY_RAIM); } } /* * When any IE with error specifies a CLR action indicator, this * takes precedence obviously. There are two cases here: * unrecognized IEs and IEs with error. So we look through the * error array twice and send only one STATUS. Unrecognized will * take precedence. * * 5.7.2a) */ FOREACH_ERR(e1, uni) { if (e1->act == UNI_IEACT_CLEAR && e1->err == UNI_IERR_UNK) { MK_IE_CAUSE(uni->cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_IE_NIMPL); VERBOSE(uni, UNI_FAC_VERIFY, 1, "CLR1"); return (VFY_CLR); } } FOREACH_ERR(e1, uni) { if (e1->act == UNI_IEACT_CLEAR && (e1->err == UNI_IERR_LEN || e1->err == UNI_IERR_BAD || e1->err == UNI_IERR_ACC)) { MK_IE_CAUSE(uni->cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_IE_INV); VERBOSE(uni, UNI_FAC_VERIFY, 1, "CLR2"); return (VFY_CLR); } } /* * Now check, whether anybody wants to explicitly ignore the message * and report status. * * 5.7.2a) */ FOREACH_ERR(e1, uni) { if (e1->act == UNI_IEACT_MSG_REPORT && e1->err == UNI_IERR_UNK) { MK_IE_CAUSE(uni->cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_IE_NIMPL); VERBOSE(uni, UNI_FAC_VERIFY, 1, "RAI"); return (VFY_RAI); } } FOREACH_ERR(e1, uni) { if (e1->act == UNI_IEACT_MSG_REPORT && (e1->err == UNI_IERR_LEN || e1->err == UNI_IERR_BAD || e1->err == UNI_IERR_ACC)) { MK_IE_CAUSE(uni->cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_IE_INV); VERBOSE(uni, UNI_FAC_VERIFY, 1, "RAI"); return (VFY_RAI); } } /* * Now look whether some IE wants to explicitely ignore the message * without any report. */ FOREACH_ERR(e1, uni) { if (e1->act == UNI_IEACT_MSG_IGNORE) { VERBOSE(uni, UNI_FAC_VERIFY, 1, "I1"); return (VFY_I); } } /* * At this point we have left only * mandatory and non-mandatory IEs with error that want the IE to be * ignored or ignored with report or defaulted. * Because a mandatory IE with errors lead to * the message beeing ignored, we make this of higher * precedence, than the rest. */ FOREACH_ERR(e1, uni) { if (e1->man) { MK_IE_CAUSE(uni->cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_MANDAT); VERBOSE(uni, UNI_FAC_VERIFY, 1, "RAI"); return (VFY_RAI); } } /* * Now look for ignoring the IE and reporting. This takes precedence * over simply ignoring it. We also collect defaulted (non-mandatory) * IEs. * * 5.7.2d) and 5.6.8.1 */ FOREACH_ERR(e1, uni) { if ((e1->act == UNI_IEACT_DEFAULT || e1->act == UNI_IEACT_REPORT) && e1->err != UNI_IERR_UNK) { MK_IE_CAUSE(uni->cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_IE_INV); VERBOSE(uni, UNI_FAC_VERIFY, 1, "RAP"); return (VFY_RAP); } } FOREACH_ERR(e1, uni) { if ((e1->act == UNI_IEACT_DEFAULT || e1->act == UNI_IEACT_REPORT) && e1->err == UNI_IERR_UNK) { MK_IE_CAUSE(uni->cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_IE_NIMPL); VERBOSE(uni, UNI_FAC_VERIFY, 1, "RAPU"); return (VFY_RAPU); } } /* * This leaves us with IEs, that want to be ignored. Among these may * be mandatory IEs. If we have an mandatory IEs here in the error * array, then the message wil not contain enough information and * must be handled according to 5.8 as either in 5.6.7.1 (this * means, that mandatory IEs cannot really be ignored) or 5.7.1. */ FOREACH_ERR(e1, uni) { if (e1->man) { MK_IE_CAUSE(uni->cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_MANDAT); if (msgact == UNI_MSGACT_CLEAR) { VERBOSE(uni, UNI_FAC_VERIFY, 1, "CLR3"); return (VFY_CLR); } if (msgact == UNI_MSGACT_IGNORE) { VERBOSE(uni, UNI_FAC_VERIFY, 1, "I2"); return (VFY_I); } VERBOSE(uni, UNI_FAC_VERIFY, 1, "RAI"); return (VFY_RAI); } } /* * Now only non-mandatory IEs are left, that want to be explicitely * ignored. */ if (uni->cx.errcnt != 0) MK_IE_CAUSE(uni->cause, UNI_CAUSE_LOC_USER, UNI_CAUSE_IE_INV); VERBOSE(uni, UNI_FAC_VERIFY, 1, "OK"); return (VFY_OK); } /* * Collect the IE identifiers for some of the known cause codes. */ void uni_vfy_collect_ies(struct uni *uni) { struct uni_ierr *e; #define STUFF_IE(IE) \ uni->cause.u.ie.ie[uni->cause.u.ie.len++] = (IE); \ if (uni->cause.u.ie.len == UNI_CAUSE_IE_N) \ break; uni->cause.u.ie.len = 0; if (uni->cause.cause == UNI_CAUSE_MANDAT) { FOREACH_ERR(e, uni) { if (e->err == UNI_IERR_MIS || e->man != 0) { STUFF_IE(e->ie); } } } else if (uni->cause.cause == UNI_CAUSE_IE_NIMPL) { FOREACH_ERR(e, uni) { if (e->err == UNI_IERR_UNK) { STUFF_IE(e->ie); } } } else if (uni->cause.cause == UNI_CAUSE_IE_INV) { FOREACH_ERR(e, uni) { if (e->err == UNI_IERR_LEN || e->err == UNI_IERR_BAD || e->err == UNI_IERR_ACC) { STUFF_IE(e->ie); } } } else return; if (uni->cause.u.ie.len != 0) uni->cause.h.present |= UNI_CAUSE_IE_P; } void uni_respond_status_verify(struct uni *uni, struct uni_cref *cref, enum uni_callstate cs, struct uni_ie_epref *epref, enum uni_epstate ps) { struct uni_all *resp; if ((resp = UNI_ALLOC()) == NULL) return; uni_vfy_collect_ies(uni); MK_MSG_RESP(resp, UNI_STATUS, cref); MK_IE_CALLSTATE(resp->u.status.callstate, cs); resp->u.status.cause = uni->cause; if (epref && IE_ISGOOD(*epref)) { MK_IE_EPREF(resp->u.status.epref, epref->epref, !epref->flag); MK_IE_EPSTATE(resp->u.status.epstate, ps); } uni_send_output(resp, uni); UNI_FREE(resp); } /* * Handling of Q.2971 9.5.8.1: */ void uni_vfy_remove_unknown(struct uni *uni) { struct uni_ierr *e1, *e0; int flag = 0; FOREACH_ERR(e1, uni) { if (e1->err == UNI_IERR_UNK) { if (e1->act == UNI_IEACT_CLEAR || e1->act == UNI_IEACT_MSG_IGNORE || e1->act == UNI_IEACT_MSG_REPORT) return; if (e1->act == UNI_IEACT_REPORT || e1->act == UNI_IEACT_DEFAULT) flag = 1; } } if (flag) return; e0 = e1 = uni->cx.err; while (e1 < uni->cx.err + uni->cx.errcnt) { if (e1->err != UNI_IERR_UNK) { if (e0 != e1) *e0 = *e1; e0++; } e1++; } uni->cx.errcnt = e0 - uni->cx.err; } /* * Handling for ADD_PARTY_REJ and DROP_PARTY_ACK with bad cause */ void uni_vfy_remove_cause(struct uni *uni) { struct uni_ierr *e1, *e0; e0 = e1 = uni->cx.err; while (e1 < uni->cx.err + uni->cx.errcnt) { if (e1->ie != UNI_IE_CAUSE) { if (e0 != e1) *e0 = *e1; e0++; } e1++; } uni->cx.errcnt = e0 - uni->cx.err; }