Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/runfw/@/contrib/ngatm/netnatm/api/ |
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/runfw/@/contrib/ngatm/netnatm/api/unisap.c |
/* * Copyright (c) 2001-2003 * Fraunhofer Institute for Open Communication Systems (FhG Fokus). * All rights reserved. * Copyright (c) 2004 * Hartmut Brandt * * Author: Hartmut Brandt <harti@freebsd.org> * * 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. * * $Begemot: libunimsg/netnatm/api/unisap.c,v 1.4 2004/07/08 08:22:01 brandt Exp $ */ #include <sys/types.h> #ifdef _KERNEL #include <sys/ctype.h> #include <sys/libkern.h> #else #include <ctype.h> #include <string.h> #endif #include <netnatm/msg/unistruct.h> #include <netnatm/api/unisap.h> int unisve_check_addr(const struct unisve_addr *sve) { if (sve->tag == UNISVE_ABSENT) return (UNISVE_OK); if (sve->tag == UNISVE_ANY) return (UNISVE_OK); if (sve->tag != UNISVE_PRESENT) return (UNISVE_ERROR_BAD_TAG); if (sve->type == UNI_ADDR_INTERNATIONAL) { if (sve->plan != UNI_ADDR_E164) return (UNISVE_ERROR_TYPE_PLAN_CONFLICT); if (sve->len == 0 || sve->len > 15) return (UNISVE_ERROR_ADDR_LEN); } else if (sve->type == UNI_ADDR_UNKNOWN) { if (sve->plan != UNI_ADDR_ATME) return (UNISVE_ERROR_TYPE_PLAN_CONFLICT); if (sve->len != 19) return (UNISVE_ERROR_ADDR_LEN); } else return (UNISVE_ERROR_BAD_ADDR_TYPE); return (UNISVE_OK); } int unisve_check_selector(const struct unisve_selector *sve) { if (sve->tag != UNISVE_PRESENT && sve->tag != UNISVE_ABSENT && sve->tag != UNISVE_ANY) return (UNISVE_ERROR_BAD_TAG); return (UNISVE_OK); } /* * We don't want to check the protocol values here. */ int unisve_check_blli_id2(const struct unisve_blli_id2 *sve) { if (sve->tag != UNISVE_PRESENT && sve->tag != UNISVE_ABSENT && sve->tag != UNISVE_ANY) return (UNISVE_ERROR_BAD_TAG); return (UNISVE_OK); } /* * We don't want to check the protocol values here. */ int unisve_check_blli_id3(const struct unisve_blli_id3 *sve) { if (sve->tag != UNISVE_PRESENT && sve->tag != UNISVE_ABSENT && sve->tag != UNISVE_ANY) return (UNISVE_ERROR_BAD_TAG); return (UNISVE_OK); } int unisve_check_bhli(const struct unisve_bhli *sve) { if (sve->tag == UNISVE_ABSENT) return (UNISVE_OK); if (sve->tag == UNISVE_ANY) return (UNISVE_OK); if (sve->tag != UNISVE_PRESENT) return (UNISVE_ERROR_BAD_TAG); if (sve->type != UNI_BHLI_ISO && sve->type != UNI_BHLI_USER && sve->type != UNI_BHLI_VENDOR) return (UNISVE_ERROR_BAD_BHLI_TYPE); if (sve->len > sizeof(sve->info)) return (UNISVE_ERROR_BAD_BHLI_LEN); return (UNISVE_OK); } int unisve_check_sap(const struct uni_sap *sap) { int err; if ((err = unisve_check_addr(&sap->addr)) != 0 || (err = unisve_check_selector(&sap->selector)) != 0 || (err = unisve_check_blli_id2(&sap->blli_id2)) != 0 || (err = unisve_check_blli_id3(&sap->blli_id3)) != 0 || (err = unisve_check_bhli(&sap->bhli)) != 0) return (err); if (sap->addr.plan == UNI_ADDR_E164) { if (sap->selector.tag == UNISVE_PRESENT) return (UNISVE_ERROR_ADDR_SEL_CONFLICT); } else if (sap->addr.plan == UNI_ADDR_ATME) { if (sap->selector.tag == UNISVE_ABSENT) return (UNISVE_ERROR_ADDR_SEL_CONFLICT); } return (0); } #define COMMON_OVERLAP(A1,A2) \ if ((A1->tag == UNISVE_ABSENT && A2->tag == UNISVE_ABSENT) || \ A1->tag == UNISVE_ANY || A2->tag == UNISVE_ANY) \ return (1); \ if ((A1->tag == UNISVE_ABSENT && A2->tag == UNISVE_PRESENT) || \ (A2->tag == UNISVE_ABSENT && A1->tag == UNISVE_PRESENT)) \ return (0); int unisve_overlap_addr(const struct unisve_addr *s1, const struct unisve_addr *s2) { COMMON_OVERLAP(s1, s2); return (s1->type == s2->type && s1->plan == s2->plan && s1->len == s2->len && memcmp(s1->addr, s2->addr, s1->len) == 0); } int unisve_overlap_selector(const struct unisve_selector *s1, const struct unisve_selector *s2) { COMMON_OVERLAP(s1, s2); return (s1->selector == s2->selector); } int unisve_overlap_blli_id2(const struct unisve_blli_id2 *s1, const struct unisve_blli_id2 *s2) { COMMON_OVERLAP(s1, s2); return (s1->proto == s2->proto && (s1->proto != UNI_BLLI_L2_USER || s1->user == s2->user)); } int unisve_overlap_blli_id3(const struct unisve_blli_id3 *s1, const struct unisve_blli_id3 *s2) { COMMON_OVERLAP(s1, s2); if (s1->proto != s2->proto) return (0); if (s1->proto == UNI_BLLI_L3_USER) return (s1->user == s2->user); if (s1->proto == UNI_BLLI_L3_TR9577) { if (s1->noipi && s2->noipi) return (1); if (!s1->noipi && !s2->noipi) { if (s1->ipi == s2->ipi) { if (s1->ipi != UNI_BLLI_L3_SNAP) return (1); if (s1->oui == s2->oui && s1->pid == s2->pid) return (1); } } return (0); } return (1); } int unisve_overlap_bhli(const struct unisve_bhli *s1, const struct unisve_bhli *s2) { COMMON_OVERLAP(s1, s2); return (s1->type == s2->type && s1->len == s2->len && memcmp(s1->info, s2->info, s1->len) == 0); } int unisve_overlap_sap(const struct uni_sap *s1, const struct uni_sap *s2) { int any1, any2; /* * Two catch-all's SAP's are not allowed. A catch-all does never * overlap with a non-catch all SAP. */ any1 = unisve_is_catchall(s1); any2 = unisve_is_catchall(s2); if (any1 && any2) return (1); if(any1 || any2) return (0); return (unisve_overlap_addr(&s1->addr, &s2->addr) && unisve_overlap_selector(&s1->selector, &s2->selector) && unisve_overlap_blli_id2(&s1->blli_id2, &s2->blli_id2) && unisve_overlap_blli_id3(&s1->blli_id3, &s2->blli_id3) && unisve_overlap_bhli(&s1->bhli, &s2->bhli)); } int unisve_is_catchall(const struct uni_sap *sap) { return (sap->addr.tag == UNISVE_ANY && sap->selector.tag == UNISVE_ANY && sap->blli_id2.tag == UNISVE_ANY && sap->blli_id3.tag == UNISVE_ANY && sap->bhli.tag == UNISVE_ANY); } int unisve_match(const struct uni_sap *sap, const struct uni_ie_called *called, const struct uni_ie_blli *blli, const struct uni_ie_bhli *bhli) { switch (sap->addr.tag) { case UNISVE_ABSENT: if (IE_ISGOOD(*called)) return (0); break; case UNISVE_ANY: break; case UNISVE_PRESENT: if (!IE_ISGOOD(*called)) return (0); if (called->addr.type != sap->addr.type || called->addr.plan != sap->addr.plan) return (0); if (called->addr.plan == UNI_ADDR_E164) { if (called->addr.len != sap->addr.len || memcmp(called->addr.addr, sap->addr.addr, called->addr.len) != 0) return (0); } else if (called->addr.plan == UNI_ADDR_ATME) { if (called->addr.len != 20 || memcmp(called->addr.addr, sap->addr.addr, 19) != 0) return (0); } break; default: return (0); } switch (sap->selector.tag) { case UNISVE_ABSENT: if (IE_ISGOOD(*called) && called->addr.plan == UNI_ADDR_ATME) return (0); break; case UNISVE_ANY: break; case UNISVE_PRESENT: if (!IE_ISGOOD(*called)) return (0); if (called->addr.plan != UNI_ADDR_ATME) return (0); if (called->addr.addr[19] != sap->selector.selector) return (0); break; default: return (0); } switch (sap->blli_id2.tag) { case UNISVE_ABSENT: if (IE_ISGOOD(*blli) && (blli->h.present & UNI_BLLI_L2_P)) return (0); break; case UNISVE_ANY: break; case UNISVE_PRESENT: if (!IE_ISGOOD(*blli) || (blli->h.present & UNI_BLLI_L2_P) == 0) return (0); if (blli->l2 != sap->blli_id2.proto) return (0); if (blli->l2 == UNI_BLLI_L2_USER) { if ((blli->h.present & UNI_BLLI_L2_USER_P) == 0) return (0); if (blli->l2_user != sap->blli_id2.user) return (0); } break; default: return (0); } switch (sap->blli_id3.tag) { case UNISVE_ABSENT: if (IE_ISGOOD(*blli) && (blli->h.present & UNI_BLLI_L3_P)) return (0); break; case UNISVE_ANY: break; case UNISVE_PRESENT: if (!IE_ISGOOD(*blli) || (blli->h.present & UNI_BLLI_L3_P) == 0) return (0); if (blli->l3 != sap->blli_id3.proto) return (0); if (blli->l3 == UNI_BLLI_L3_USER) { if ((blli->h.present & UNI_BLLI_L3_USER_P) == 0) return (0); if (blli->l3_user != sap->blli_id3.user) return (0); break; } if (blli->l3 == UNI_BLLI_L3_TR9577) { if (sap->blli_id3.noipi) { if (blli->h.present & UNI_BLLI_L3_IPI_P) return (0); } else { if (!(blli->h.present & UNI_BLLI_L3_IPI_P)) return (0); if (blli->l3_ipi != sap->blli_id3.ipi) return (0); if (blli->l3_ipi == UNI_BLLI_L3_SNAP) { if (!(blli->h.present & UNI_BLLI_L3_SNAP_P)) return (0); if (blli->oui != sap->blli_id3.oui || blli->pid != sap->blli_id3.pid) return (0); } } } break; default: return (0); } switch (sap->bhli.tag) { case UNISVE_ABSENT: if (IE_ISGOOD(*bhli)) return (0); break; case UNISVE_ANY: break; case UNISVE_PRESENT: if (!IE_ISGOOD(*bhli)) return (0); if (sap->bhli.type != bhli->type) return (0); if (sap->bhli.len != bhli->len) return (0); if (memcmp(sap->bhli.info, bhli->info, bhli->len) != 0) return (0); break; default: return (0); } /* Uff */ return (1); }