/*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2010 The FreeBSD Foundation * * This software was developed by Shteryana Sotirova Shopova under * sponsorship from the FreeBSD Foundation. * * 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. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define SNMPTREE_TYPES #include "wlan_tree.h" #include "wlan_snmp.h" #include "wlan_oid.h" static struct lmodule *wlan_module; /* For the registration. */ static const struct asn_oid oid_wlan = OIDX_begemotWlan; /* The registration. */ static uint reg_wlan; /* Periodic timer for polling the module's data. */ static void *wlan_data_timer; /* * Poll data from kernel every 15 minutes unless explicitly requested by an * SNMP client. * XXX: make that configurable. */ static int wlan_poll_ticks = (15 * 60) * 100; /* The age of each table. */ #define WLAN_LIST_MAXAGE 5 static time_t wlan_iflist_age; static time_t wlan_peerlist_age; static time_t wlan_chanlist_age; static time_t wlan_roamlist_age; static time_t wlan_tx_paramlist_age; static time_t wlan_scanlist_age; static time_t wlan_maclist_age; static time_t wlan_mrlist_age; /* * The list of all virtual wireless interfaces - sorted by name. */ SLIST_HEAD(wlan_ifaces, wlan_iface); static struct wlan_ifaces wlan_ifaces = SLIST_HEAD_INITIALIZER(wlan_ifaces); static struct wlan_config wlan_config; /* Forward declarations */ static int bits_get(struct snmp_value *, const u_char *, ssize_t); static int wlan_add_wif(struct wlan_iface *); static void wlan_delete_wif(struct wlan_iface *); static int wlan_attach_newif(struct mibif *); static int wlan_iface_create(struct wlan_iface *); static int wlan_iface_destroy(struct wlan_iface *); static struct wlan_iface * wlan_new_wif(char *); static void wlan_free_interface(struct wlan_iface *); static void wlan_free_iflist(void); static void wlan_free_peerlist(struct wlan_iface *); static void wlan_scan_free_results(struct wlan_iface *); static void wlan_mac_free_maclist(struct wlan_iface *); static void wlan_mesh_free_routes(struct wlan_iface *); static int wlan_update_interface(struct wlan_iface *); static void wlan_update_interface_list(void); static void wlan_update_peers(void); static void wlan_update_channels(void); static void wlan_update_roam_params(void); static void wlan_update_tx_params(void); static void wlan_scan_update_results(void); static void wlan_mac_update_aclmacs(void); static void wlan_mesh_update_routes(void); static struct wlan_iface * wlan_find_interface(const char *); static struct wlan_peer * wlan_find_peer(struct wlan_iface *, uint8_t *); static struct ieee80211_channel* wlan_find_channel(struct wlan_iface *, uint32_t); static struct wlan_scan_result * wlan_scan_find_result(struct wlan_iface *, uint8_t *, uint8_t *); static struct wlan_mac_mac * wlan_mac_find_mac(struct wlan_iface *, uint8_t *); static struct wlan_mesh_route * wlan_mesh_find_route(struct wlan_iface *, uint8_t *); static struct wlan_iface * wlan_first_interface(void); static struct wlan_iface * wlan_next_interface(struct wlan_iface *); static struct wlan_iface * wlan_mesh_first_interface(void); static struct wlan_iface * wlan_mesh_next_interface(struct wlan_iface *); static struct wlan_iface * wlan_get_interface(const struct asn_oid *, uint); static struct wlan_iface * wlan_get_snmp_interface(const struct asn_oid *, uint); static struct wlan_peer * wlan_get_peer(const struct asn_oid *, uint, struct wlan_iface **); static struct ieee80211_channel *wlan_get_channel(const struct asn_oid *, uint, struct wlan_iface **); static struct ieee80211_roamparam *wlan_get_roam_param(const struct asn_oid *, uint, struct wlan_iface **); static struct ieee80211_txparam *wlan_get_tx_param(const struct asn_oid *, uint, struct wlan_iface **, uint32_t *); static struct wlan_scan_result *wlan_get_scanr(const struct asn_oid *, uint, struct wlan_iface **); static struct wlan_mac_mac * wlan_get_acl_mac(const struct asn_oid *, uint, struct wlan_iface **); static struct wlan_iface * wlan_mesh_get_iface(const struct asn_oid *, uint); static struct wlan_peer * wlan_mesh_get_peer(const struct asn_oid *, uint, struct wlan_iface **); static struct wlan_mesh_route * wlan_mesh_get_route(const struct asn_oid *, uint, struct wlan_iface **); static struct wlan_iface * wlan_get_next_interface(const struct asn_oid *, uint); static struct wlan_iface * wlan_get_next_snmp_interface(const struct asn_oid *, uint); static struct wlan_peer * wlan_get_next_peer(const struct asn_oid *, uint, struct wlan_iface **); static struct ieee80211_channel *wlan_get_next_channel(const struct asn_oid *, uint, struct wlan_iface **); static struct ieee80211_roamparam *wlan_get_next_roam_param(const struct asn_oid *, uint sub, struct wlan_iface **, uint32_t *); static struct ieee80211_txparam *wlan_get_next_tx_param(const struct asn_oid *, uint, struct wlan_iface **, uint32_t *); static struct wlan_scan_result *wlan_get_next_scanr(const struct asn_oid *, uint , struct wlan_iface **); static struct wlan_mac_mac * wlan_get_next_acl_mac(const struct asn_oid *, uint, struct wlan_iface **); static struct wlan_iface * wlan_mesh_get_next_iface(const struct asn_oid *, uint); static struct wlan_peer * wlan_mesh_get_next_peer(const struct asn_oid *, uint, struct wlan_iface **); static struct wlan_mesh_route * wlan_mesh_get_next_route(const struct asn_oid *, uint sub, struct wlan_iface **); static uint8_t *wlan_get_ifname(const struct asn_oid *, uint, uint8_t *); static int wlan_mac_index_decode(const struct asn_oid *, uint, char *, uint8_t *); static int wlan_channel_index_decode(const struct asn_oid *, uint, char *, uint32_t *); static int wlan_phy_index_decode(const struct asn_oid *, uint, char *, uint32_t *); static int wlan_scanr_index_decode(const struct asn_oid *oid, uint sub, char *wname, uint8_t *ssid, uint8_t *bssid); static void wlan_append_ifindex(struct asn_oid *, uint, const struct wlan_iface *); static void wlan_append_mac_index(struct asn_oid *, uint, char *, uint8_t *); static void wlan_append_channel_index(struct asn_oid *, uint, const struct wlan_iface *, const struct ieee80211_channel *); static void wlan_append_phy_index(struct asn_oid *, uint, char *, uint32_t); static void wlan_append_scanr_index(struct asn_oid *, uint, char *, uint8_t *, uint8_t *); static int wlan_acl_mac_set_status(struct snmp_context *, struct snmp_value *, uint); static int wlan_mesh_route_set_status(struct snmp_context *, struct snmp_value *, uint); static int32_t wlan_get_channel_type(struct ieee80211_channel *); static int wlan_scan_compare_result(struct wlan_scan_result *, struct wlan_scan_result *); static int wlan_mac_delete_mac(struct wlan_iface *, struct wlan_mac_mac *); static int wlan_mesh_delete_route(struct wlan_iface *, struct wlan_mesh_route *); /* * The module's GET/SET data hooks per each table or group of objects as * required by bsnmpd(1). */ int op_wlan_iface(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { int rc; char wname[IFNAMSIZ]; struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_get_snmp_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((wif = wlan_get_next_snmp_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); break; case SNMP_OP_SET: if ((wif = wlan_get_snmp_interface(&val->var, sub)) == NULL) { if (val->var.subs[sub - 1] != LEAF_wlanIfaceName) return (SNMP_ERR_NOSUCHNAME); if (wlan_get_ifname(&val->var, sub, wname) == NULL) return (SNMP_ERR_INCONS_VALUE); if ((wif = wlan_new_wif(wname)) == NULL) return (SNMP_ERR_GENERR); wif->internal = 1; } if (wif->status == RowStatus_active && val->var.subs[sub - 1] != LEAF_wlanIfaceStatus && val->var.subs[sub - 1] != LEAF_wlanIfaceState) return (SNMP_ERR_INCONS_VALUE); switch (val->var.subs[sub - 1]) { case LEAF_wlanIfaceIndex: return (SNMP_ERR_NOT_WRITEABLE); case LEAF_wlanIfaceName: if (val->v.octetstring.len >= IFNAMSIZ) return (SNMP_ERR_INCONS_VALUE); if ((ctx->scratch->ptr1 = malloc(IFNAMSIZ)) == NULL) return (SNMP_ERR_GENERR); strlcpy(ctx->scratch->ptr1, wif->wname, IFNAMSIZ); memcpy(wif->wname, val->v.octetstring.octets, val->v.octetstring.len); wif->wname[val->v.octetstring.len] = '\0'; return (SNMP_ERR_NOERROR); case LEAF_wlanParentIfName: if (val->v.octetstring.len >= IFNAMSIZ) return (SNMP_ERR_INCONS_VALUE); if ((ctx->scratch->ptr1 = malloc(IFNAMSIZ)) == NULL) return (SNMP_ERR_GENERR); strlcpy(ctx->scratch->ptr1, wif->pname, IFNAMSIZ); memcpy(wif->pname, val->v.octetstring.octets, val->v.octetstring.len); wif->pname[val->v.octetstring.len] = '\0'; return (SNMP_ERR_NOERROR); case LEAF_wlanIfaceOperatingMode: ctx->scratch->int1 = wif->mode; wif->mode = val->v.integer; return (SNMP_ERR_NOERROR); case LEAF_wlanIfaceFlags: if (val->v.octetstring.len > sizeof(wif->flags)) return (SNMP_ERR_INCONS_VALUE); ctx->scratch->ptr1 = malloc(sizeof(wif->flags)); if (ctx->scratch->ptr1 == NULL) return (SNMP_ERR_GENERR); memcpy(ctx->scratch->ptr1, (uint8_t *)&wif->flags, sizeof(wif->flags)); memcpy((uint8_t *)&wif->flags, val->v.octetstring.octets, sizeof(wif->flags)); return (SNMP_ERR_NOERROR); case LEAF_wlanIfaceBssid: if (val->v.octetstring.len != IEEE80211_ADDR_LEN) return (SNMP_ERR_INCONS_VALUE); ctx->scratch->ptr1 = malloc(IEEE80211_ADDR_LEN); if (ctx->scratch->ptr1 == NULL) return (SNMP_ERR_GENERR); memcpy(ctx->scratch->ptr1, wif->dbssid, IEEE80211_ADDR_LEN); memcpy(wif->dbssid, val->v.octetstring.octets, IEEE80211_ADDR_LEN); return (SNMP_ERR_NOERROR); case LEAF_wlanIfaceLocalAddress: if (val->v.octetstring.len != IEEE80211_ADDR_LEN) return (SNMP_ERR_INCONS_VALUE); ctx->scratch->ptr1 = malloc(IEEE80211_ADDR_LEN); if (ctx->scratch->ptr1 == NULL) return (SNMP_ERR_GENERR); memcpy(ctx->scratch->ptr1, wif->dlmac, IEEE80211_ADDR_LEN); memcpy(wif->dlmac, val->v.octetstring.octets, IEEE80211_ADDR_LEN); return (SNMP_ERR_NOERROR); case LEAF_wlanIfaceStatus: ctx->scratch->int1 = wif->status; wif->status = val->v.integer; if (wif->status == RowStatus_active) { rc = wlan_iface_create(wif); /* XXX */ if (rc != SNMP_ERR_NOERROR) { wif->status = ctx->scratch->int1; return (rc); } } else if (wif->status == RowStatus_destroy) return (wlan_iface_destroy(wif)); else wif->status = RowStatus_notReady; return (SNMP_ERR_NOERROR); case LEAF_wlanIfaceState: ctx->scratch->int1 = wif->state; wif->state = val->v.integer; if (wif->status == RowStatus_active) if (wlan_config_state(wif, 1) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); } abort(); case SNMP_OP_ROLLBACK: if ((wif = wlan_get_snmp_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanIfaceName: strlcpy(wif->wname, ctx->scratch->ptr1, IFNAMSIZ); free(ctx->scratch->ptr1); break; case LEAF_wlanParentIfName: strlcpy(wif->pname, ctx->scratch->ptr1, IFNAMSIZ); free(ctx->scratch->ptr1); break; case LEAF_wlanIfaceOperatingMode: wif->mode = ctx->scratch->int1; break; case LEAF_wlanIfaceFlags: memcpy((uint8_t *)&wif->flags, ctx->scratch->ptr1, sizeof(wif->flags)); free(ctx->scratch->ptr1); break; case LEAF_wlanIfaceBssid: memcpy(wif->dbssid, ctx->scratch->ptr1, IEEE80211_ADDR_LEN); free(ctx->scratch->ptr1); break; case LEAF_wlanIfaceLocalAddress: memcpy(wif->dlmac, ctx->scratch->ptr1, IEEE80211_ADDR_LEN); free(ctx->scratch->ptr1); break; case LEAF_wlanIfaceStatus: wif->status = ctx->scratch->int1; if (ctx->scratch->int1 == RowStatus_active) return (SNMP_ERR_GENERR); /* XXX: FIXME */ else if (wif->internal != 0) return (wlan_iface_destroy(wif)); break; case LEAF_wlanIfaceState: wif->state = ctx->scratch->int1; if (wif->status == RowStatus_active) if (wlan_config_state(wif, 1) < 0) return (SNMP_ERR_GENERR); break; } return (SNMP_ERR_NOERROR); case SNMP_OP_COMMIT: switch (val->var.subs[sub - 1]) { case LEAF_wlanIfaceName: case LEAF_wlanParentIfName: case LEAF_wlanIfaceFlags: case LEAF_wlanIfaceBssid: case LEAF_wlanIfaceLocalAddress: free(ctx->scratch->ptr1); /* FALLTHROUGH */ default: return (SNMP_ERR_NOERROR); } default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanIfaceIndex: val->v.integer = wif->index; return (SNMP_ERR_NOERROR); case LEAF_wlanIfaceName: return (string_get(val, wif->wname, -1)); case LEAF_wlanParentIfName: return (string_get(val, wif->pname, -1)); case LEAF_wlanIfaceOperatingMode: val->v.integer = wif->mode; return (SNMP_ERR_NOERROR); case LEAF_wlanIfaceFlags: return (bits_get(val, (uint8_t *)&wif->flags, sizeof(wif->flags))); case LEAF_wlanIfaceBssid: return (string_get(val, wif->dbssid, IEEE80211_ADDR_LEN)); case LEAF_wlanIfaceLocalAddress: return (string_get(val, wif->dlmac, IEEE80211_ADDR_LEN)); case LEAF_wlanIfaceStatus: val->v.integer = wif->status; return (SNMP_ERR_NOERROR); case LEAF_wlanIfaceState: val->v.integer = wif->state; return (SNMP_ERR_NOERROR); } abort(); } int op_wlan_if_parent(struct snmp_context *ctx __unused, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((wif = wlan_get_next_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); break; case SNMP_OP_SET: return (SNMP_ERR_NOT_WRITEABLE); case SNMP_OP_COMMIT: /* FALLTHROUGH */ case SNMP_OP_ROLLBACK: /* FALLTHROUGH */ default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanIfParentDriverCapabilities: return (bits_get(val, (uint8_t *)&wif->drivercaps, sizeof(wif->drivercaps))); case LEAF_wlanIfParentCryptoCapabilities: return (bits_get(val, (uint8_t *)&wif->cryptocaps, sizeof(wif->cryptocaps))); case LEAF_wlanIfParentHTCapabilities: return (bits_get(val, (uint8_t *)&wif->htcaps, sizeof(wif->htcaps))); } abort(); } int op_wlan_iface_config(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { int intval, vlen, rc; char *strval; struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); goto get_config; case SNMP_OP_GETNEXT: if ((wif = wlan_get_next_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); goto get_config; case SNMP_OP_SET: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); intval = val->v.integer; strval = NULL; vlen = 0; /* Simple sanity checks & save old data. */ switch (val->var.subs[sub - 1]) { case LEAF_wlanIfaceCountryCode: if (val->v.octetstring.len != WLAN_COUNTRY_CODE_SIZE) return (SNMP_ERR_INCONS_VALUE); break; case LEAF_wlanIfaceDesiredSsid: if (val->v.octetstring.len > IEEE80211_NWID_LEN) return (SNMP_ERR_INCONS_VALUE); break; case LEAF_wlanIfaceDesiredBssid: if (val->v.octetstring.len != IEEE80211_ADDR_LEN) return (SNMP_ERR_INCONS_VALUE); break; case LEAF_wlanIfacePacketBurst: ctx->scratch->int1 = wif->packet_burst; break; case LEAF_wlanIfaceRegDomain: ctx->scratch->int1 = wif->reg_domain; break; case LEAF_wlanIfaceDesiredChannel: ctx->scratch->int1 = wif->desired_channel; break; case LEAF_wlanIfaceDynamicFreqSelection: ctx->scratch->int1 = wif->dyn_frequency; break; case LEAF_wlanIfaceFastFrames: ctx->scratch->int1 = wif->fast_frames; break; case LEAF_wlanIfaceDturbo: ctx->scratch->int1 = wif->dturbo; break; case LEAF_wlanIfaceTxPower: ctx->scratch->int1 = wif->tx_power; break; case LEAF_wlanIfaceFragmentThreshold: ctx->scratch->int1 = wif->frag_threshold; break; case LEAF_wlanIfaceRTSThreshold: ctx->scratch->int1 = wif->rts_threshold; break; case LEAF_wlanIfaceWlanPrivacySubscribe: ctx->scratch->int1 = wif->priv_subscribe; break; case LEAF_wlanIfaceBgScan: ctx->scratch->int1 = wif->bg_scan; break; case LEAF_wlanIfaceBgScanIdle: ctx->scratch->int1 = wif->bg_scan_idle; break; case LEAF_wlanIfaceBgScanInterval: ctx->scratch->int1 = wif->bg_scan_interval; break; case LEAF_wlanIfaceBeaconMissedThreshold: ctx->scratch->int1 = wif->beacons_missed; break; case LEAF_wlanIfaceRoamingMode: ctx->scratch->int1 = wif->roam_mode; break; case LEAF_wlanIfaceDot11d: ctx->scratch->int1 = wif->dot11d; break; case LEAF_wlanIfaceDot11h: ctx->scratch->int1 = wif->dot11h; break; case LEAF_wlanIfaceDynamicWds: ctx->scratch->int1 = wif->dynamic_wds; break; case LEAF_wlanIfacePowerSave: ctx->scratch->int1 = wif->power_save; break; case LEAF_wlanIfaceApBridge: ctx->scratch->int1 = wif->ap_bridge; break; case LEAF_wlanIfaceBeaconInterval: ctx->scratch->int1 = wif->beacon_interval; break; case LEAF_wlanIfaceDtimPeriod: ctx->scratch->int1 = wif->dtim_period; break; case LEAF_wlanIfaceHideSsid: ctx->scratch->int1 = wif->hide_ssid; break; case LEAF_wlanIfaceInactivityProccess: ctx->scratch->int1 = wif->inact_process; break; case LEAF_wlanIfaceDot11gProtMode: ctx->scratch->int1 = wif->do11g_protect; break; case LEAF_wlanIfaceDot11gPureMode: ctx->scratch->int1 = wif->dot11g_pure; break; case LEAF_wlanIfaceDot11nPureMode: ctx->scratch->int1 = wif->dot11n_pure; break; case LEAF_wlanIfaceDot11nAmpdu: ctx->scratch->int1 = wif->ampdu; break; case LEAF_wlanIfaceDot11nAmpduDensity: ctx->scratch->int1 = wif->ampdu_density; break; case LEAF_wlanIfaceDot11nAmpduLimit: ctx->scratch->int1 = wif->ampdu_limit; break; case LEAF_wlanIfaceDot11nAmsdu: ctx->scratch->int1 = wif->amsdu; break; case LEAF_wlanIfaceDot11nAmsduLimit: ctx->scratch->int1 = wif->amsdu_limit; break; case LEAF_wlanIfaceDot11nHighThroughput: ctx->scratch->int1 = wif->ht_enabled; break; case LEAF_wlanIfaceDot11nHTCompatible: ctx->scratch->int1 = wif->ht_compatible; break; case LEAF_wlanIfaceDot11nHTProtMode: ctx->scratch->int1 = wif->ht_prot_mode; break; case LEAF_wlanIfaceDot11nRIFS: ctx->scratch->int1 = wif->rifs; break; case LEAF_wlanIfaceDot11nShortGI: ctx->scratch->int1 = wif->short_gi; break; case LEAF_wlanIfaceDot11nSMPSMode: ctx->scratch->int1 = wif->smps_mode; break; case LEAF_wlanIfaceTdmaSlot: ctx->scratch->int1 = wif->tdma_slot; break; case LEAF_wlanIfaceTdmaSlotCount: ctx->scratch->int1 = wif->tdma_slot_count; break; case LEAF_wlanIfaceTdmaSlotLength: ctx->scratch->int1 = wif->tdma_slot_length; break; case LEAF_wlanIfaceTdmaBeaconInterval: ctx->scratch->int1 = wif->tdma_binterval; break; default: abort(); } if (val->syntax != SNMP_SYNTAX_OCTETSTRING) goto set_config; ctx->scratch->int1 = val->v.octetstring.len; ctx->scratch->ptr1 = malloc(val->v.octetstring.len + 1); if (ctx->scratch->ptr1 == NULL) return (SNMP_ERR_GENERR); /* XXX */ if (val->var.subs[sub - 1] == LEAF_wlanIfaceDesiredSsid) strlcpy(ctx->scratch->ptr1, val->v.octetstring.octets, val->v.octetstring.len + 1); else memcpy(ctx->scratch->ptr1, val->v.octetstring.octets, val->v.octetstring.len); strval = val->v.octetstring.octets; vlen = val->v.octetstring.len; goto set_config; case SNMP_OP_ROLLBACK: intval = ctx->scratch->int1; strval = NULL; vlen = 0; if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanIfaceCountryCode: case LEAF_wlanIfaceDesiredSsid: case LEAF_wlanIfaceDesiredBssid: strval = ctx->scratch->ptr1; vlen = ctx->scratch->int1; break; default: break; } goto set_config; case SNMP_OP_COMMIT: switch (val->var.subs[sub - 1]) { case LEAF_wlanIfaceCountryCode: case LEAF_wlanIfaceDesiredSsid: case LEAF_wlanIfaceDesiredBssid: free(ctx->scratch->ptr1); /* FALLTHROUGH */ default: return (SNMP_ERR_NOERROR); } } abort(); get_config: if (wlan_config_get_ioctl(wif, val->var.subs[sub - 1]) < 0) return (SNMP_ERR_GENERR); switch (val->var.subs[sub - 1]) { case LEAF_wlanIfacePacketBurst: val->v.integer = wif->packet_burst; break; case LEAF_wlanIfaceCountryCode: return (string_get(val, wif->country_code, WLAN_COUNTRY_CODE_SIZE)); case LEAF_wlanIfaceRegDomain: val->v.integer = wif->reg_domain; break; case LEAF_wlanIfaceDesiredSsid: return (string_get(val, wif->desired_ssid, -1)); case LEAF_wlanIfaceDesiredChannel: val->v.integer = wif->desired_channel; break; case LEAF_wlanIfaceDynamicFreqSelection: val->v.integer = wif->dyn_frequency; break; case LEAF_wlanIfaceFastFrames: val->v.integer = wif->fast_frames; break; case LEAF_wlanIfaceDturbo: val->v.integer = wif->dturbo; break; case LEAF_wlanIfaceTxPower: val->v.integer = wif->tx_power; break; case LEAF_wlanIfaceFragmentThreshold: val->v.integer = wif->frag_threshold; break; case LEAF_wlanIfaceRTSThreshold: val->v.integer = wif->rts_threshold; break; case LEAF_wlanIfaceWlanPrivacySubscribe: val->v.integer = wif->priv_subscribe; break; case LEAF_wlanIfaceBgScan: val->v.integer = wif->bg_scan; break; case LEAF_wlanIfaceBgScanIdle: val->v.integer = wif->bg_scan_idle; break; case LEAF_wlanIfaceBgScanInterval: val->v.integer = wif->bg_scan_interval; break; case LEAF_wlanIfaceBeaconMissedThreshold: val->v.integer = wif->beacons_missed; break; case LEAF_wlanIfaceDesiredBssid: return (string_get(val, wif->desired_bssid, IEEE80211_ADDR_LEN)); case LEAF_wlanIfaceRoamingMode: val->v.integer = wif->roam_mode; break; case LEAF_wlanIfaceDot11d: val->v.integer = wif->dot11d; break; case LEAF_wlanIfaceDot11h: val->v.integer = wif->dot11h; break; case LEAF_wlanIfaceDynamicWds: val->v.integer = wif->dynamic_wds; break; case LEAF_wlanIfacePowerSave: val->v.integer = wif->power_save; break; case LEAF_wlanIfaceApBridge: val->v.integer = wif->ap_bridge; break; case LEAF_wlanIfaceBeaconInterval: val->v.integer = wif->beacon_interval; break; case LEAF_wlanIfaceDtimPeriod: val->v.integer = wif->dtim_period; break; case LEAF_wlanIfaceHideSsid: val->v.integer = wif->hide_ssid; break; case LEAF_wlanIfaceInactivityProccess: val->v.integer = wif->inact_process; break; case LEAF_wlanIfaceDot11gProtMode: val->v.integer = wif->do11g_protect; break; case LEAF_wlanIfaceDot11gPureMode: val->v.integer = wif->dot11g_pure; break; case LEAF_wlanIfaceDot11nPureMode: val->v.integer = wif->dot11n_pure; break; case LEAF_wlanIfaceDot11nAmpdu: val->v.integer = wif->ampdu; break; case LEAF_wlanIfaceDot11nAmpduDensity: val->v.integer = wif->ampdu_density; break; case LEAF_wlanIfaceDot11nAmpduLimit: val->v.integer = wif->ampdu_limit; break; case LEAF_wlanIfaceDot11nAmsdu: val->v.integer = wif->amsdu; break; case LEAF_wlanIfaceDot11nAmsduLimit: val->v.integer = wif->amsdu_limit; break; case LEAF_wlanIfaceDot11nHighThroughput: val->v.integer = wif->ht_enabled; break; case LEAF_wlanIfaceDot11nHTCompatible: val->v.integer = wif->ht_compatible; break; case LEAF_wlanIfaceDot11nHTProtMode: val->v.integer = wif->ht_prot_mode; break; case LEAF_wlanIfaceDot11nRIFS: val->v.integer = wif->rifs; break; case LEAF_wlanIfaceDot11nShortGI: val->v.integer = wif->short_gi; break; case LEAF_wlanIfaceDot11nSMPSMode: val->v.integer = wif->smps_mode; break; case LEAF_wlanIfaceTdmaSlot: val->v.integer = wif->tdma_slot; break; case LEAF_wlanIfaceTdmaSlotCount: val->v.integer = wif->tdma_slot_count; break; case LEAF_wlanIfaceTdmaSlotLength: val->v.integer = wif->tdma_slot_length; break; case LEAF_wlanIfaceTdmaBeaconInterval: val->v.integer = wif->tdma_binterval; break; } return (SNMP_ERR_NOERROR); set_config: rc = wlan_config_set_ioctl(wif, val->var.subs[sub - 1], intval, strval, vlen); if (op == SNMP_OP_ROLLBACK) { switch (val->var.subs[sub - 1]) { case LEAF_wlanIfaceCountryCode: case LEAF_wlanIfaceDesiredSsid: case LEAF_wlanIfaceDesiredBssid: free(ctx->scratch->ptr1); /* FALLTHROUGH */ default: break; } } if (rc < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); } int op_wlan_if_peer(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_peer *wip; struct wlan_iface *wif; wlan_update_interface_list(); wlan_update_peers(); switch (op) { case SNMP_OP_GET: if ((wip = wlan_get_peer(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((wip = wlan_get_next_peer(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_mac_index(&val->var, sub, wif->wname, wip->pmac); break; case SNMP_OP_SET: if ((wip = wlan_get_peer(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); if (val->var.subs[sub - 1] != LEAF_wlanIfacePeerVlanTag) return (SNMP_ERR_GENERR); ctx->scratch->int1 = wip->vlan; if (wlan_peer_set_vlan(wif, wip, val->v.integer) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); case SNMP_OP_COMMIT: return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: if ((wip = wlan_get_peer(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); if (val->var.subs[sub - 1] != LEAF_wlanIfacePeerVlanTag) return (SNMP_ERR_GENERR); if (wlan_peer_set_vlan(wif, wip, ctx->scratch->int1) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanIfacePeerAddress: return (string_get(val, wip->pmac, IEEE80211_ADDR_LEN)); case LEAF_wlanIfacePeerAssociationId: val->v.integer = wip->associd; break; case LEAF_wlanIfacePeerVlanTag: val->v.integer = wip->vlan; break; case LEAF_wlanIfacePeerFrequency: val->v.integer = wip->frequency; break; case LEAF_wlanIfacePeerCurrentTXRate: val->v.integer = wip->txrate; break; case LEAF_wlanIfacePeerRxSignalStrength: val->v.integer = wip->rssi; break; case LEAF_wlanIfacePeerIdleTimer: val->v.integer = wip->idle; break; case LEAF_wlanIfacePeerTxSequenceNo: val->v.integer = wip->txseqs; break; case LEAF_wlanIfacePeerRxSequenceNo: val->v.integer = wip->rxseqs; break; case LEAF_wlanIfacePeerTxPower: val->v.integer = wip->txpower; break; case LEAF_wlanIfacePeerCapabilities: return (bits_get(val, (uint8_t *)&wip->capinfo, sizeof(wip->capinfo))); case LEAF_wlanIfacePeerFlags: return (bits_get(val, (uint8_t *)&wip->state, sizeof(wip->state))); default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_channels(struct snmp_context *ctx __unused, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { int32_t bits; struct ieee80211_channel *channel; struct wlan_iface *wif; wlan_update_interface_list(); wlan_update_channels(); switch (op) { case SNMP_OP_GET: if ((channel = wlan_get_channel(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: channel = wlan_get_next_channel(&val->var, sub, &wif); if (channel == NULL || wif == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_channel_index(&val->var, sub, wif, channel); break; case SNMP_OP_SET: return (SNMP_ERR_NOT_WRITEABLE); case SNMP_OP_COMMIT: /* FALLTHROUGH */ case SNMP_OP_ROLLBACK: /* FALLTHROUGH */ default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanIfaceChannelIeeeId: val->v.integer = channel->ic_ieee; break; case LEAF_wlanIfaceChannelType: val->v.integer = wlan_get_channel_type(channel); break; case LEAF_wlanIfaceChannelFlags: bits = wlan_channel_flags_to_snmp(channel->ic_flags); return (bits_get(val, (uint8_t *)&bits, sizeof(bits))); case LEAF_wlanIfaceChannelFrequency: val->v.integer = channel->ic_freq; break; case LEAF_wlanIfaceChannelMaxRegPower: val->v.integer = channel->ic_maxregpower; break; case LEAF_wlanIfaceChannelMaxTxPower: val->v.integer = channel->ic_maxpower; break; case LEAF_wlanIfaceChannelMinTxPower: val->v.integer = channel->ic_minpower; break; case LEAF_wlanIfaceChannelState: bits = wlan_channel_state_to_snmp(channel->ic_state); return (bits_get(val, (uint8_t *)&bits, sizeof(bits))); case LEAF_wlanIfaceChannelHTExtension: val->v.integer = channel->ic_extieee; break; case LEAF_wlanIfaceChannelMaxAntennaGain: val->v.integer = channel->ic_maxantgain; break; } return (SNMP_ERR_NOERROR); } int op_wlan_roam_params(struct snmp_context *ctx __unused, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { uint32_t phy; struct ieee80211_roamparam *rparam; struct wlan_iface *wif; wlan_update_interface_list(); wlan_update_roam_params(); switch (op) { case SNMP_OP_GET: rparam = wlan_get_roam_param(&val->var, sub, &wif); if (rparam == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: rparam = wlan_get_next_roam_param(&val->var, sub, &wif, &phy); if (rparam == NULL || wif == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_phy_index(&val->var, sub, wif->wname, phy); break; case SNMP_OP_SET: return (SNMP_ERR_NOT_WRITEABLE); case SNMP_OP_COMMIT: /* FALLTHROUGH */ case SNMP_OP_ROLLBACK: /* FALLTHROUGH */ default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanIfRoamRxSignalStrength: val->v.integer = rparam->rssi/2; break; case LEAF_wlanIfRoamTxRateThreshold: val->v.integer = rparam->rate/2; break; default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_tx_params(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { uint32_t phy; struct ieee80211_txparam *txparam; struct wlan_iface *wif; wlan_update_interface_list(); wlan_update_tx_params(); switch (op) { case SNMP_OP_GET: txparam = wlan_get_tx_param(&val->var, sub, &wif, &phy); if (txparam == NULL) return (SNMP_ERR_NOSUCHNAME); goto get_txparams; case SNMP_OP_GETNEXT: txparam = wlan_get_next_tx_param(&val->var, sub, &wif, &phy); if (txparam == NULL || wif == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_phy_index(&val->var, sub, wif->wname, phy); goto get_txparams; case SNMP_OP_SET: txparam = wlan_get_tx_param(&val->var, sub, &wif, &phy); if (txparam == NULL || wif == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanIfTxUnicastRate: ctx->scratch->int1 = txparam->ucastrate; txparam->ucastrate = val->v.integer * 2; break; case LEAF_wlanIfTxMcastRate: ctx->scratch->int1 = txparam->mcastrate; txparam->mcastrate = val->v.integer * 2; break; case LEAF_wlanIfTxMgmtRate: ctx->scratch->int1 = txparam->mgmtrate; txparam->mgmtrate = val->v.integer * 2; break; case LEAF_wlanIfTxMaxRetryCount: ctx->scratch->int1 = txparam->maxretry; txparam->maxretry = val->v.integer; break; default: abort(); } if (wlan_set_tx_params(wif, phy) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); case SNMP_OP_COMMIT: return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: txparam = wlan_get_tx_param(&val->var, sub, &wif, &phy); if (txparam == NULL || wif == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanIfTxUnicastRate: txparam->ucastrate = ctx->scratch->int1; break; case LEAF_wlanIfTxMcastRate: txparam->mcastrate = ctx->scratch->int1; break; case LEAF_wlanIfTxMgmtRate: txparam->mgmtrate = ctx->scratch->int1; break; case LEAF_wlanIfTxMaxRetryCount: txparam->maxretry = ctx->scratch->int1; break; default: abort(); } if (wlan_set_tx_params(wif, phy) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); default: abort(); } get_txparams: switch (val->var.subs[sub - 1]) { case LEAF_wlanIfTxUnicastRate: val->v.integer = txparam->ucastrate / 2; break; case LEAF_wlanIfTxMcastRate: val->v.integer = txparam->mcastrate / 2; break; case LEAF_wlanIfTxMgmtRate: val->v.integer = txparam->mgmtrate / 2; break; case LEAF_wlanIfTxMaxRetryCount: val->v.integer = txparam->maxretry; break; default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_scan_config(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((wif = wlan_get_next_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); break; case SNMP_OP_SET: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); if (wif->scan_status == wlanScanConfigStatus_running && val->var.subs[sub - 1] != LEAF_wlanScanConfigStatus) return (SNMP_ERR_INCONS_VALUE); switch (val->var.subs[sub - 1]) { case LEAF_wlanScanFlags: ctx->scratch->int1 = wif->scan_flags; wif->scan_flags = val->v.integer; break; case LEAF_wlanScanDuration: ctx->scratch->int1 = wif->scan_duration; wif->scan_duration = val->v.integer; break; case LEAF_wlanScanMinChannelDwellTime: ctx->scratch->int1 = wif->scan_mindwell; wif->scan_mindwell = val->v.integer; break; case LEAF_wlanScanMaxChannelDwellTime: ctx->scratch->int1 = wif->scan_maxdwell; wif->scan_maxdwell = val->v.integer; break; case LEAF_wlanScanConfigStatus: if (val->v.integer == wlanScanConfigStatus_running || val->v.integer == wlanScanConfigStatus_cancel) { ctx->scratch->int1 = wif->scan_status; wif->scan_status = val->v.integer; break; } return (SNMP_ERR_INCONS_VALUE); } return (SNMP_ERR_NOERROR); case SNMP_OP_COMMIT: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); if (val->var.subs[sub - 1] == LEAF_wlanScanConfigStatus) if (wif->scan_status == wlanScanConfigStatus_running) (void)wlan_set_scan_config(wif); /* XXX */ return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanScanFlags: wif->scan_flags = ctx->scratch->int1; break; case LEAF_wlanScanDuration: wif->scan_duration = ctx->scratch->int1; break; case LEAF_wlanScanMinChannelDwellTime: wif->scan_mindwell = ctx->scratch->int1; break; case LEAF_wlanScanMaxChannelDwellTime: wif->scan_maxdwell = ctx->scratch->int1; break; case LEAF_wlanScanConfigStatus: wif->scan_status = ctx->scratch->int1; break; } return (SNMP_ERR_NOERROR); default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanScanFlags: val->v.integer = wif->scan_flags; break; case LEAF_wlanScanDuration: val->v.integer = wif->scan_duration; break; case LEAF_wlanScanMinChannelDwellTime: val->v.integer = wif->scan_mindwell; break; case LEAF_wlanScanMaxChannelDwellTime: val->v.integer = wif->scan_maxdwell; break; case LEAF_wlanScanConfigStatus: val->v.integer = wif->scan_status; break; } return (SNMP_ERR_NOERROR); } int op_wlan_scan_results(struct snmp_context *ctx __unused, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_scan_result *sr; struct wlan_iface *wif; wlan_update_interface_list(); wlan_scan_update_results(); switch (op) { case SNMP_OP_GET: if ((sr = wlan_get_scanr(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((sr = wlan_get_next_scanr(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_scanr_index(&val->var, sub, wif->wname, sr->ssid, sr->bssid); break; case SNMP_OP_SET: return (SNMP_ERR_NOT_WRITEABLE); case SNMP_OP_COMMIT: /* FALLTHROUGH */ case SNMP_OP_ROLLBACK: /* FALLTHROUGH */ default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanScanResultID: return (string_get(val, sr->ssid, -1)); case LEAF_wlanScanResultBssid: return (string_get(val, sr->bssid, IEEE80211_ADDR_LEN)); case LEAF_wlanScanResultChannel: val->v.integer = sr->opchannel; /* XXX */ break; case LEAF_wlanScanResultRate: val->v.integer = sr->rssi; break; case LEAF_wlanScanResultNoise: val->v.integer = sr->noise; break; case LEAF_wlanScanResultBeaconInterval: val->v.integer = sr->bintval; break; case LEAF_wlanScanResultCapabilities: return (bits_get(val, &sr->capinfo, sizeof(sr->capinfo))); default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_iface_stats(struct snmp_context *ctx __unused, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((wif = wlan_get_next_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); break; case SNMP_OP_SET: /* XXX: LEAF_wlanStatsReset */ return (SNMP_ERR_NOT_WRITEABLE); case SNMP_OP_COMMIT: /* FALLTHROUGH */ case SNMP_OP_ROLLBACK: /* FALLTHROUGH */ default: abort(); } if (wlan_get_stats(wif) < 0) return (SNMP_ERR_GENERR); switch (val->var.subs[sub - 1]) { case LEAF_wlanStatsRxBadVersion: val->v.uint32 = wif->stats.is_rx_badversion; break; case LEAF_wlanStatsRxTooShort: val->v.uint32 = wif->stats.is_rx_tooshort; break; case LEAF_wlanStatsRxWrongBssid: val->v.uint32 = wif->stats.is_rx_wrongbss; break; case LEAF_wlanStatsRxDiscardedDups: val->v.uint32 = wif->stats.is_rx_dup; break; case LEAF_wlanStatsRxWrongDir: val->v.uint32 = wif->stats.is_rx_wrongdir; break; case LEAF_wlanStatsRxDiscardMcastEcho: val->v.uint32 = wif->stats.is_rx_mcastecho; break; case LEAF_wlanStatsRxDiscardNoAssoc: val->v.uint32 = wif->stats.is_rx_notassoc; break; case LEAF_wlanStatsRxWepNoPrivacy: val->v.uint32 = wif->stats.is_rx_noprivacy; break; case LEAF_wlanStatsRxWepUnencrypted: val->v.uint32 = wif->stats.is_rx_unencrypted; break; case LEAF_wlanStatsRxWepFailed: val->v.uint32 = wif->stats.is_rx_wepfail; break; case LEAF_wlanStatsRxDecapsulationFailed: val->v.uint32 = wif->stats.is_rx_decap; break; case LEAF_wlanStatsRxDiscardMgmt: val->v.uint32 = wif->stats.is_rx_mgtdiscard; break; case LEAF_wlanStatsRxControl: val->v.uint32 = wif->stats.is_rx_ctl; break; case LEAF_wlanStatsRxBeacon: val->v.uint32 = wif->stats.is_rx_beacon; break; case LEAF_wlanStatsRxRateSetTooBig: val->v.uint32 = wif->stats.is_rx_rstoobig; break; case LEAF_wlanStatsRxElemMissing: val->v.uint32 = wif->stats.is_rx_elem_missing; break; case LEAF_wlanStatsRxElemTooBig: val->v.uint32 = wif->stats.is_rx_elem_toobig; break; case LEAF_wlanStatsRxElemTooSmall: val->v.uint32 = wif->stats.is_rx_elem_toosmall; break; case LEAF_wlanStatsRxElemUnknown: val->v.uint32 = wif->stats.is_rx_elem_unknown; break; case LEAF_wlanStatsRxChannelMismatch: val->v.uint32 = wif->stats.is_rx_chanmismatch; break; case LEAF_wlanStatsRxDropped: val->v.uint32 = wif->stats.is_rx_nodealloc; break; case LEAF_wlanStatsRxSsidMismatch: val->v.uint32 = wif->stats.is_rx_ssidmismatch; break; case LEAF_wlanStatsRxAuthNotSupported: val->v.uint32 = wif->stats.is_rx_auth_unsupported; break; case LEAF_wlanStatsRxAuthFailed: val->v.uint32 = wif->stats.is_rx_auth_fail; break; case LEAF_wlanStatsRxAuthCM: val->v.uint32 = wif->stats.is_rx_auth_countermeasures; break; case LEAF_wlanStatsRxAssocWrongBssid: val->v.uint32 = wif->stats.is_rx_assoc_bss; break; case LEAF_wlanStatsRxAssocNoAuth: val->v.uint32 = wif->stats.is_rx_assoc_notauth; break; case LEAF_wlanStatsRxAssocCapMismatch: val->v.uint32 = wif->stats.is_rx_assoc_capmismatch; break; case LEAF_wlanStatsRxAssocNoRateMatch: val->v.uint32 = wif->stats.is_rx_assoc_norate; break; case LEAF_wlanStatsRxBadWpaIE: val->v.uint32 = wif->stats.is_rx_assoc_badwpaie; break; case LEAF_wlanStatsRxDeauthenticate: val->v.uint32 = wif->stats.is_rx_deauth; break; case LEAF_wlanStatsRxDisassociate: val->v.uint32 = wif->stats.is_rx_disassoc; break; case LEAF_wlanStatsRxUnknownSubtype: val->v.uint32 = wif->stats.is_rx_badsubtype; break; case LEAF_wlanStatsRxFailedNoBuf: val->v.uint32 = wif->stats.is_rx_nobuf; break; case LEAF_wlanStatsRxBadAuthRequest: val->v.uint32 = wif->stats.is_rx_bad_auth; break; case LEAF_wlanStatsRxUnAuthorized: val->v.uint32 = wif->stats.is_rx_unauth; break; case LEAF_wlanStatsRxBadKeyId: val->v.uint32 = wif->stats.is_rx_badkeyid; break; case LEAF_wlanStatsRxCCMPSeqViolation: val->v.uint32 = wif->stats.is_rx_ccmpreplay; break; case LEAF_wlanStatsRxCCMPBadFormat: val->v.uint32 = wif->stats.is_rx_ccmpformat; break; case LEAF_wlanStatsRxCCMPFailedMIC: val->v.uint32 = wif->stats.is_rx_ccmpmic; break; case LEAF_wlanStatsRxTKIPSeqViolation: val->v.uint32 = wif->stats.is_rx_tkipreplay; break; case LEAF_wlanStatsRxTKIPBadFormat: val->v.uint32 = wif->stats.is_rx_tkipformat; break; case LEAF_wlanStatsRxTKIPFailedMIC: val->v.uint32 = wif->stats.is_rx_tkipmic; break; case LEAF_wlanStatsRxTKIPFailedICV: val->v.uint32 = wif->stats.is_rx_tkipicv; break; case LEAF_wlanStatsRxDiscardACL: val->v.uint32 = wif->stats.is_rx_acl; break; case LEAF_wlanStatsTxFailedNoBuf: val->v.uint32 = wif->stats.is_tx_nobuf; break; case LEAF_wlanStatsTxFailedNoNode: val->v.uint32 = wif->stats.is_tx_nonode; break; case LEAF_wlanStatsTxUnknownMgmt: val->v.uint32 = wif->stats.is_tx_unknownmgt; break; case LEAF_wlanStatsTxBadCipher: val->v.uint32 = wif->stats.is_tx_badcipher; break; case LEAF_wlanStatsTxNoDefKey: val->v.uint32 = wif->stats.is_tx_nodefkey; break; case LEAF_wlanStatsTxFragmented: val->v.uint32 = wif->stats.is_tx_fragframes; break; case LEAF_wlanStatsTxFragmentsCreated: val->v.uint32 = wif->stats.is_tx_frags; break; case LEAF_wlanStatsActiveScans: val->v.uint32 = wif->stats.is_scan_active; break; case LEAF_wlanStatsPassiveScans: val->v.uint32 = wif->stats.is_scan_passive; break; case LEAF_wlanStatsTimeoutInactivity: val->v.uint32 = wif->stats.is_node_timeout; break; case LEAF_wlanStatsCryptoNoMem: val->v.uint32 = wif->stats.is_crypto_nomem; break; case LEAF_wlanStatsSwCryptoTKIP: val->v.uint32 = wif->stats.is_crypto_tkip; break; case LEAF_wlanStatsSwCryptoTKIPEnMIC: val->v.uint32 = wif->stats.is_crypto_tkipenmic; break; case LEAF_wlanStatsSwCryptoTKIPDeMIC: val->v.uint32 = wif->stats.is_crypto_tkipdemic; break; case LEAF_wlanStatsCryptoTKIPCM: val->v.uint32 = wif->stats.is_crypto_tkipcm; break; case LEAF_wlanStatsSwCryptoCCMP: val->v.uint32 = wif->stats.is_crypto_ccmp; break; case LEAF_wlanStatsSwCryptoWEP: val->v.uint32 = wif->stats.is_crypto_wep; break; case LEAF_wlanStatsCryptoCipherKeyRejected: val->v.uint32 = wif->stats.is_crypto_setkey_cipher; break; case LEAF_wlanStatsCryptoNoKey: val->v.uint32 = wif->stats.is_crypto_setkey_nokey; break; case LEAF_wlanStatsCryptoDeleteKeyFailed: val->v.uint32 = wif->stats.is_crypto_delkey; break; case LEAF_wlanStatsCryptoUnknownCipher: val->v.uint32 = wif->stats.is_crypto_badcipher; break; case LEAF_wlanStatsCryptoAttachFailed: val->v.uint32 = wif->stats.is_crypto_attachfail; break; case LEAF_wlanStatsCryptoKeyFailed: val->v.uint32 = wif->stats.is_crypto_keyfail; break; case LEAF_wlanStatsCryptoEnMICFailed: val->v.uint32 = wif->stats.is_crypto_enmicfail; break; case LEAF_wlanStatsIBSSCapMismatch: val->v.uint32 = wif->stats.is_ibss_capmismatch; break; case LEAF_wlanStatsUnassocStaPSPoll: val->v.uint32 = wif->stats.is_ps_unassoc; break; case LEAF_wlanStatsBadAidPSPoll: val->v.uint32 = wif->stats.is_ps_badaid; break; case LEAF_wlanStatsEmptyPSPoll: val->v.uint32 = wif->stats.is_ps_qempty; break; case LEAF_wlanStatsRxFFBadHdr: val->v.uint32 = wif->stats.is_ff_badhdr; break; case LEAF_wlanStatsRxFFTooShort: val->v.uint32 = wif->stats.is_ff_tooshort; break; case LEAF_wlanStatsRxFFSplitError: val->v.uint32 = wif->stats.is_ff_split; break; case LEAF_wlanStatsRxFFDecap: val->v.uint32 = wif->stats.is_ff_decap; break; case LEAF_wlanStatsTxFFEncap: val->v.uint32 = wif->stats.is_ff_encap; break; case LEAF_wlanStatsRxBadBintval: val->v.uint32 = wif->stats.is_rx_badbintval; break; case LEAF_wlanStatsRxDemicFailed: val->v.uint32 = wif->stats.is_rx_demicfail; break; case LEAF_wlanStatsRxDefragFailed: val->v.uint32 = wif->stats.is_rx_defrag; break; case LEAF_wlanStatsRxMgmt: val->v.uint32 = wif->stats.is_rx_mgmt; break; case LEAF_wlanStatsRxActionMgmt: val->v.uint32 = wif->stats.is_rx_action; break; case LEAF_wlanStatsRxAMSDUTooShort: val->v.uint32 = wif->stats.is_amsdu_tooshort; break; case LEAF_wlanStatsRxAMSDUSplitError: val->v.uint32 = wif->stats.is_amsdu_split; break; case LEAF_wlanStatsRxAMSDUDecap: val->v.uint32 = wif->stats.is_amsdu_decap; break; case LEAF_wlanStatsTxAMSDUEncap: val->v.uint32 = wif->stats.is_amsdu_encap; break; case LEAF_wlanStatsAMPDUBadBAR: val->v.uint32 = wif->stats.is_ampdu_bar_bad; break; case LEAF_wlanStatsAMPDUOowBar: val->v.uint32 = wif->stats.is_ampdu_bar_oow; break; case LEAF_wlanStatsAMPDUMovedBAR: val->v.uint32 = wif->stats.is_ampdu_bar_move; break; case LEAF_wlanStatsAMPDURxBAR: val->v.uint32 = wif->stats.is_ampdu_bar_rx; break; case LEAF_wlanStatsAMPDURxOor: val->v.uint32 = wif->stats.is_ampdu_rx_oor; break; case LEAF_wlanStatsAMPDURxCopied: val->v.uint32 = wif->stats.is_ampdu_rx_copy; break; case LEAF_wlanStatsAMPDURxDropped: val->v.uint32 = wif->stats.is_ampdu_rx_drop; break; case LEAF_wlanStatsTxDiscardBadState: val->v.uint32 = wif->stats.is_tx_badstate; break; case LEAF_wlanStatsTxFailedNoAssoc: val->v.uint32 = wif->stats.is_tx_notassoc; break; case LEAF_wlanStatsTxClassifyFailed: val->v.uint32 = wif->stats.is_tx_classify; break; case LEAF_wlanStatsDwdsMcastDiscard: val->v.uint32 = wif->stats.is_dwds_mcast; break; case LEAF_wlanStatsHTAssocRejectNoHT: val->v.uint32 = wif->stats.is_ht_assoc_nohtcap; break; case LEAF_wlanStatsHTAssocDowngrade: val->v.uint32 = wif->stats.is_ht_assoc_downgrade; break; case LEAF_wlanStatsHTAssocRateMismatch: val->v.uint32 = wif->stats.is_ht_assoc_norate; break; case LEAF_wlanStatsAMPDURxAge: val->v.uint32 = wif->stats.is_ampdu_rx_age; break; case LEAF_wlanStatsAMPDUMoved: val->v.uint32 = wif->stats.is_ampdu_rx_move; break; case LEAF_wlanStatsADDBADisabledReject: val->v.uint32 = wif->stats.is_addba_reject; break; case LEAF_wlanStatsADDBANoRequest: val->v.uint32 = wif->stats.is_addba_norequest; break; case LEAF_wlanStatsADDBABadToken: val->v.uint32 = wif->stats.is_addba_badtoken; break; case LEAF_wlanStatsADDBABadPolicy: val->v.uint32 = wif->stats.is_addba_badpolicy; break; case LEAF_wlanStatsAMPDUStopped: val->v.uint32 = wif->stats.is_ampdu_stop; break; case LEAF_wlanStatsAMPDUStopFailed: val->v.uint32 = wif->stats.is_ampdu_stop_failed; break; case LEAF_wlanStatsAMPDURxReorder: val->v.uint32 = wif->stats.is_ampdu_rx_reorder; break; case LEAF_wlanStatsScansBackground: val->v.uint32 = wif->stats.is_scan_bg; break; case LEAF_wlanLastDeauthReason: val->v.uint32 = wif->stats.is_rx_deauth_code; break; case LEAF_wlanLastDissasocReason: val->v.uint32 = wif->stats.is_rx_disassoc_code; break; case LEAF_wlanLastAuthFailReason: val->v.uint32 = wif->stats.is_rx_authfail_code; break; case LEAF_wlanStatsBeaconMissedEvents: val->v.uint32 = wif->stats.is_beacon_miss; break; case LEAF_wlanStatsRxDiscardBadStates: val->v.uint32 = wif->stats.is_rx_badstate; break; case LEAF_wlanStatsFFFlushed: val->v.uint32 = wif->stats.is_ff_flush; break; case LEAF_wlanStatsTxControlFrames: val->v.uint32 = wif->stats.is_tx_ctl; break; case LEAF_wlanStatsAMPDURexmt: val->v.uint32 = wif->stats.is_ampdu_rexmt; break; case LEAF_wlanStatsAMPDURexmtFailed: val->v.uint32 = wif->stats.is_ampdu_rexmt_fail; break; case LEAF_wlanStatsReset: val->v.uint32 = wlanStatsReset_no_op; break; default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_wep_iface(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_get_interface(&val->var, sub)) == NULL || !wif->wepsupported) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: /* XXX: filter wif->wepsupported */ if ((wif = wlan_get_next_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); break; case SNMP_OP_SET: if ((wif = wlan_get_interface(&val->var, sub)) == NULL || !wif->wepsupported) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanWepMode: if (val->v.integer < wlanWepMode_off || val->v.integer > wlanWepMode_mixed) return (SNMP_ERR_INCONS_VALUE); ctx->scratch->int1 = wif->wepmode; wif->wepmode = val->v.integer; if (wlan_set_wepmode(wif) < 0) { wif->wepmode = ctx->scratch->int1; return (SNMP_ERR_GENERR); } break; case LEAF_wlanWepDefTxKey: if (val->v.integer < 0 || val->v.integer > IEEE80211_WEP_NKID) return (SNMP_ERR_INCONS_VALUE); ctx->scratch->int1 = wif->weptxkey; wif->weptxkey = val->v.integer; if (wlan_set_weptxkey(wif) < 0) { wif->weptxkey = ctx->scratch->int1; return (SNMP_ERR_GENERR); } break; default: abort(); } return (SNMP_ERR_NOERROR); case SNMP_OP_COMMIT: return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanWepMode: wif->wepmode = ctx->scratch->int1; if (wlan_set_wepmode(wif) < 0) return (SNMP_ERR_GENERR); break; case LEAF_wlanWepDefTxKey: wif->weptxkey = ctx->scratch->int1; if (wlan_set_weptxkey(wif) < 0) return (SNMP_ERR_GENERR); break; default: abort(); } return (SNMP_ERR_NOERROR); default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanWepMode: if (wlan_get_wepmode(wif) < 0) return (SNMP_ERR_GENERR); val->v.integer = wif->wepmode; break; case LEAF_wlanWepDefTxKey: if (wlan_get_weptxkey(wif) < 0) return (SNMP_ERR_GENERR); val->v.integer = wif->weptxkey; break; default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_wep_key(struct snmp_context *ctx __unused, struct snmp_value *val __unused, uint32_t sub __unused, uint32_t iidx __unused, enum snmp_op op __unused) { return (SNMP_ERR_NOSUCHNAME); } int op_wlan_mac_access_control(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_get_interface(&val->var, sub)) == NULL || !wif->macsupported) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: /* XXX: filter wif->macsupported */ if ((wif = wlan_get_next_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); break; case SNMP_OP_SET: if ((wif = wlan_get_interface(&val->var, sub)) == NULL || !wif->macsupported) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanMACAccessControlPolicy: ctx->scratch->int1 = wif->mac_policy; wif->mac_policy = val->v.integer; break; case LEAF_wlanMACAccessControlNacl: return (SNMP_ERR_NOT_WRITEABLE); case LEAF_wlanMACAccessControlFlush: break; default: abort(); } return (SNMP_ERR_NOERROR); case SNMP_OP_COMMIT: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanMACAccessControlPolicy: if (wlan_set_mac_policy(wif) < 0) { wif->mac_policy = ctx->scratch->int1; return (SNMP_ERR_GENERR); } break; case LEAF_wlanMACAccessControlFlush: if (wlan_flush_mac_mac(wif) < 0) return (SNMP_ERR_GENERR); break; default: abort(); } return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: if ((wif = wlan_get_interface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); if (val->var.subs[sub - 1] == LEAF_wlanMACAccessControlPolicy) wif->mac_policy = ctx->scratch->int1; return (SNMP_ERR_NOERROR); default: abort(); } if (wlan_get_mac_policy(wif) < 0) return (SNMP_ERR_GENERR); switch (val->var.subs[sub - 1]) { case LEAF_wlanMACAccessControlPolicy: val->v.integer = wif->mac_policy; break; case LEAF_wlanMACAccessControlNacl: val->v.integer = wif->mac_nacls; break; case LEAF_wlanMACAccessControlFlush: val->v.integer = wlanMACAccessControlFlush_no_op; break; default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_mac_acl_mac(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_iface *wif; struct wlan_mac_mac *macl; wlan_update_interface_list(); wlan_mac_update_aclmacs(); switch (op) { case SNMP_OP_GET: if ((macl = wlan_get_acl_mac(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((macl = wlan_get_next_acl_mac(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_mac_index(&val->var, sub, wif->wname, macl->mac); break; case SNMP_OP_SET: switch (val->var.subs[sub - 1]) { case LEAF_wlanMACAccessControlMAC: return (SNMP_ERR_INCONS_NAME); case LEAF_wlanMACAccessControlMACStatus: return(wlan_acl_mac_set_status(ctx, val, sub)); default: abort(); } case SNMP_OP_COMMIT: if ((macl = wlan_get_acl_mac(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); if (val->v.integer == RowStatus_destroy && wlan_mac_delete_mac(wif, macl) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: if ((macl = wlan_get_acl_mac(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); if (ctx->scratch->int1 == RowStatus_destroy && wlan_mac_delete_mac(wif, macl) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanMACAccessControlMAC: return (string_get(val, macl->mac, IEEE80211_ADDR_LEN)); case LEAF_wlanMACAccessControlMACStatus: val->v.integer = macl->mac_status; break; default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_mesh_config(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { int which; switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshMaxRetries: which = WLAN_MESH_MAX_RETRIES; break; case LEAF_wlanMeshHoldingTimeout: which = WLAN_MESH_HOLDING_TO; break; case LEAF_wlanMeshConfirmTimeout: which = WLAN_MESH_CONFIRM_TO; break; case LEAF_wlanMeshRetryTimeout: which = WLAN_MESH_RETRY_TO; break; default: abort(); } switch (op) { case SNMP_OP_GET: if (wlan_do_sysctl(&wlan_config, which, 0) < 0) return (SNMP_ERR_GENERR); break; case SNMP_OP_GETNEXT: abort(); case SNMP_OP_SET: switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshRetryTimeout : ctx->scratch->int1 = wlan_config.mesh_retryto; wlan_config.mesh_retryto = val->v.integer; break; case LEAF_wlanMeshHoldingTimeout: ctx->scratch->int1 = wlan_config.mesh_holdingto; wlan_config.mesh_holdingto = val->v.integer; break; case LEAF_wlanMeshConfirmTimeout: ctx->scratch->int1 = wlan_config.mesh_confirmto; wlan_config.mesh_confirmto = val->v.integer; break; case LEAF_wlanMeshMaxRetries: ctx->scratch->int1 = wlan_config.mesh_maxretries; wlan_config.mesh_maxretries = val->v.integer; break; } if (wlan_do_sysctl(&wlan_config, which, 1) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); case SNMP_OP_COMMIT: return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshRetryTimeout: wlan_config.mesh_retryto = ctx->scratch->int1; break; case LEAF_wlanMeshConfirmTimeout: wlan_config.mesh_confirmto = ctx->scratch->int1; break; case LEAF_wlanMeshHoldingTimeout: wlan_config.mesh_holdingto= ctx->scratch->int1; break; case LEAF_wlanMeshMaxRetries: wlan_config.mesh_maxretries = ctx->scratch->int1; break; } if (wlan_do_sysctl(&wlan_config, which, 1) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshRetryTimeout: val->v.integer = wlan_config.mesh_retryto; break; case LEAF_wlanMeshHoldingTimeout: val->v.integer = wlan_config.mesh_holdingto; break; case LEAF_wlanMeshConfirmTimeout: val->v.integer = wlan_config.mesh_confirmto; break; case LEAF_wlanMeshMaxRetries: val->v.integer = wlan_config.mesh_maxretries; break; } return (SNMP_ERR_NOERROR); } int op_wlan_mesh_iface(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { int rc; struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_mesh_get_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((wif = wlan_mesh_get_next_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); break; case SNMP_OP_SET: if ((wif = wlan_mesh_get_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshId: if (val->v.octetstring.len > IEEE80211_NWID_LEN) return (SNMP_ERR_INCONS_VALUE); ctx->scratch->ptr1 = malloc(val->v.octetstring.len + 1); if (ctx->scratch->ptr1 == NULL) return (SNMP_ERR_GENERR); strlcpy(ctx->scratch->ptr1, wif->desired_ssid, val->v.octetstring.len + 1); ctx->scratch->int1 = strlen(wif->desired_ssid); memcpy(wif->desired_ssid, val->v.octetstring.octets, val->v.octetstring.len); wif->desired_ssid[val->v.octetstring.len] = '\0'; break; case LEAF_wlanMeshTTL: ctx->scratch->int1 = wif->mesh_ttl; wif->mesh_ttl = val->v.integer; break; case LEAF_wlanMeshPeeringEnabled: ctx->scratch->int1 = wif->mesh_peering; wif->mesh_peering = val->v.integer; break; case LEAF_wlanMeshForwardingEnabled: ctx->scratch->int1 = wif->mesh_forwarding; wif->mesh_forwarding = val->v.integer; break; case LEAF_wlanMeshMetric: ctx->scratch->int1 = wif->mesh_metric; wif->mesh_metric = val->v.integer; break; case LEAF_wlanMeshPath: ctx->scratch->int1 = wif->mesh_path; wif->mesh_path = val->v.integer; break; case LEAF_wlanMeshRoutesFlush: if (val->v.integer != wlanMeshRoutesFlush_flush) return (SNMP_ERR_INCONS_VALUE); return (SNMP_ERR_NOERROR); default: abort(); } if (val->var.subs[sub - 1] == LEAF_wlanMeshId) rc = wlan_config_set_dssid(wif, val->v.octetstring.octets, val->v.octetstring.len); else rc = wlan_mesh_config_set(wif, val->var.subs[sub - 1]); if (rc < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); case SNMP_OP_COMMIT: if ((wif = wlan_mesh_get_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); if (val->var.subs[sub - 1] == LEAF_wlanMeshRoutesFlush && wlan_mesh_flush_routes(wif) < 0) return (SNMP_ERR_GENERR); if (val->var.subs[sub - 1] == LEAF_wlanMeshId) free(ctx->scratch->ptr1); return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: if ((wif = wlan_mesh_get_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshId: strlcpy(wif->desired_ssid, ctx->scratch->ptr1, IEEE80211_NWID_LEN); free(ctx->scratch->ptr1); break; case LEAF_wlanMeshTTL: wif->mesh_ttl = ctx->scratch->int1; break; case LEAF_wlanMeshPeeringEnabled: wif->mesh_peering = ctx->scratch->int1; break; case LEAF_wlanMeshForwardingEnabled: wif->mesh_forwarding = ctx->scratch->int1; break; case LEAF_wlanMeshMetric: wif->mesh_metric = ctx->scratch->int1; break; case LEAF_wlanMeshPath: wif->mesh_path = ctx->scratch->int1; break; case LEAF_wlanMeshRoutesFlush: return (SNMP_ERR_NOERROR); default: abort(); } if (val->var.subs[sub - 1] == LEAF_wlanMeshId) rc = wlan_config_set_dssid(wif, wif->desired_ssid, strlen(wif->desired_ssid)); else rc = wlan_mesh_config_set(wif, val->var.subs[sub - 1]); if (rc < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); default: abort(); } if (val->var.subs[sub - 1] == LEAF_wlanMeshId) rc = wlan_config_get_dssid(wif); else rc = wlan_mesh_config_get(wif, val->var.subs[sub - 1]); if (rc < 0) return (SNMP_ERR_GENERR); switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshId: return (string_get(val, wif->desired_ssid, -1)); case LEAF_wlanMeshTTL: val->v.integer = wif->mesh_ttl; break; case LEAF_wlanMeshPeeringEnabled: val->v.integer = wif->mesh_peering; break; case LEAF_wlanMeshForwardingEnabled: val->v.integer = wif->mesh_forwarding; break; case LEAF_wlanMeshMetric: val->v.integer = wif->mesh_metric; break; case LEAF_wlanMeshPath: val->v.integer = wif->mesh_path; break; case LEAF_wlanMeshRoutesFlush: val->v.integer = wlanMeshRoutesFlush_no_op; break; default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_mesh_neighbor(struct snmp_context *ctx __unused, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_peer *wip; struct wlan_iface *wif; wlan_update_interface_list(); wlan_update_peers(); switch (op) { case SNMP_OP_GET: if ((wip = wlan_mesh_get_peer(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: wip = wlan_mesh_get_next_peer(&val->var, sub, &wif); if (wip == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_mac_index(&val->var, sub, wif->wname, wip->pmac); break; case SNMP_OP_SET: return (SNMP_ERR_NOT_WRITEABLE); case SNMP_OP_COMMIT: /* FALLTHROUGH */ case SNMP_OP_ROLLBACK: /* FALLTHROUGH */ default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshNeighborAddress: return (string_get(val, wip->pmac, IEEE80211_ADDR_LEN)); case LEAF_wlanMeshNeighborFrequency: val->v.integer = wip->frequency; break; case LEAF_wlanMeshNeighborLocalId: val->v.integer = wip->local_id; break; case LEAF_wlanMeshNeighborPeerId: val->v.integer = wip->peer_id; break; case LEAF_wlanMeshNeighborPeerState: return (bits_get(val, (uint8_t *)&wip->state, sizeof(wip->state))); case LEAF_wlanMeshNeighborCurrentTXRate: val->v.integer = wip->txrate; break; case LEAF_wlanMeshNeighborRxSignalStrength: val->v.integer = wip->rssi; break; case LEAF_wlanMeshNeighborIdleTimer: val->v.integer = wip->idle; break; case LEAF_wlanMeshNeighborTxSequenceNo: val->v.integer = wip->txseqs; break; case LEAF_wlanMeshNeighborRxSequenceNo: val->v.integer = wip->rxseqs; break; default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_mesh_route(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_mesh_route *wmr; struct wlan_iface *wif; wlan_update_interface_list(); wlan_mesh_update_routes(); switch (op) { case SNMP_OP_GET: if ((wmr = wlan_mesh_get_route(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: wmr = wlan_mesh_get_next_route(&val->var, sub, &wif); if (wmr == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_mac_index(&val->var, sub, wif->wname, wmr->imroute.imr_dest); break; case SNMP_OP_SET: switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshRouteDestination: return (SNMP_ERR_INCONS_NAME); case LEAF_wlanMeshRouteStatus: return(wlan_mesh_route_set_status(ctx, val, sub)); default: return (SNMP_ERR_NOT_WRITEABLE); } abort(); case SNMP_OP_COMMIT: if ((wmr = wlan_mesh_get_route(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); if (val->v.integer == RowStatus_destroy && wlan_mesh_delete_route(wif, wmr) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: if ((wmr = wlan_mesh_get_route(&val->var, sub, &wif)) == NULL) return (SNMP_ERR_NOSUCHNAME); if (ctx->scratch->int1 == RowStatus_destroy && wlan_mesh_delete_route(wif, wmr) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshRouteDestination: return (string_get(val, wmr->imroute.imr_dest, IEEE80211_ADDR_LEN)); case LEAF_wlanMeshRouteNextHop: return (string_get(val, wmr->imroute.imr_nexthop, IEEE80211_ADDR_LEN)); case LEAF_wlanMeshRouteHops: val->v.integer = wmr->imroute.imr_nhops; break; case LEAF_wlanMeshRouteMetric: val->v.integer = wmr->imroute.imr_metric; break; case LEAF_wlanMeshRouteLifeTime: val->v.integer = wmr->imroute.imr_lifetime; break; case LEAF_wlanMeshRouteLastMseq: val->v.integer = wmr->imroute.imr_lastmseq; break; case LEAF_wlanMeshRouteFlags: val->v.integer = 0; if ((wmr->imroute.imr_flags & IEEE80211_MESHRT_FLAGS_VALID) != 0) val->v.integer |= (0x1 << wlanMeshRouteFlags_valid); if ((wmr->imroute.imr_flags & IEEE80211_MESHRT_FLAGS_PROXY) != 0) val->v.integer |= (0x1 << wlanMeshRouteFlags_proxy); return (bits_get(val, (uint8_t *)&val->v.integer, sizeof(val->v.integer))); case LEAF_wlanMeshRouteStatus: val->v.integer = wmr->mroute_status; break; } return (SNMP_ERR_NOERROR); } int op_wlan_mesh_stats(struct snmp_context *ctx __unused, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_mesh_get_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((wif = wlan_mesh_get_next_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); break; case SNMP_OP_SET: return (SNMP_ERR_NOT_WRITEABLE); case SNMP_OP_COMMIT: /* FALLTHROUGH */ case SNMP_OP_ROLLBACK: /* FALLTHROUGH */ default: abort(); } if (wlan_get_stats(wif) < 0) return (SNMP_ERR_GENERR); switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshDroppedBadSta: val->v.uint32 = wif->stats.is_mesh_wrongmesh; break; case LEAF_wlanMeshDroppedNoLink: val->v.uint32 = wif->stats.is_mesh_nolink; break; case LEAF_wlanMeshNoFwdTtl: val->v.uint32 = wif->stats.is_mesh_fwd_ttl; break; case LEAF_wlanMeshNoFwdBuf: val->v.uint32 = wif->stats.is_mesh_fwd_nobuf; break; case LEAF_wlanMeshNoFwdTooShort: val->v.uint32 = wif->stats.is_mesh_fwd_tooshort; break; case LEAF_wlanMeshNoFwdDisabled: val->v.uint32 = wif->stats.is_mesh_fwd_disabled; break; case LEAF_wlanMeshNoFwdPathUnknown: val->v.uint32 = wif->stats.is_mesh_fwd_nopath; break; case LEAF_wlanMeshDroppedBadAE: val->v.uint32 = wif->stats.is_mesh_badae; break; case LEAF_wlanMeshRouteAddFailed: val->v.uint32 = wif->stats.is_mesh_rtaddfailed; break; case LEAF_wlanMeshDroppedNoProxy: val->v.uint32 = wif->stats.is_mesh_notproxy; break; case LEAF_wlanMeshDroppedMisaligned: val->v.uint32 = wif->stats.is_rx_badalign; break; default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_hwmp_config(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { int which; switch (val->var.subs[sub - 1]) { case LEAF_wlanHWMPRouteInactiveTimeout: which = WLAN_HWMP_INACTIVITY_TO; break; case LEAF_wlanHWMPRootAnnounceInterval: which = WLAN_HWMP_RANN_INT; break; case LEAF_wlanHWMPRootInterval: which = WLAN_HWMP_ROOT_INT; break; case LEAF_wlanHWMPRootTimeout: which = WLAN_HWMP_ROOT_TO; break; case LEAF_wlanHWMPPathLifetime: which = WLAN_HWMP_PATH_LIFETIME; break; case LEAF_wlanHWMPReplyForwardBit: which = WLAN_HWMP_REPLY_FORWARD; break; case LEAF_wlanHWMPTargetOnlyBit: which = WLAN_HWMP_TARGET_ONLY; break; default: abort(); } switch (op) { case SNMP_OP_GET: if (wlan_do_sysctl(&wlan_config, which, 0) < 0) return (SNMP_ERR_GENERR); break; case SNMP_OP_GETNEXT: abort(); case SNMP_OP_SET: switch (val->var.subs[sub - 1]) { case LEAF_wlanHWMPRouteInactiveTimeout: ctx->scratch->int1 = wlan_config.hwmp_inact; wlan_config.hwmp_inact = val->v.integer; break; case LEAF_wlanHWMPRootAnnounceInterval: ctx->scratch->int1 = wlan_config.hwmp_rannint; wlan_config.hwmp_rannint = val->v.integer; break; case LEAF_wlanHWMPRootInterval: ctx->scratch->int1 = wlan_config.hwmp_rootint; wlan_config.hwmp_rootint = val->v.integer; break; case LEAF_wlanHWMPRootTimeout: ctx->scratch->int1 = wlan_config.hwmp_roottimeout; wlan_config.hwmp_roottimeout = val->v.integer; break; case LEAF_wlanHWMPPathLifetime: ctx->scratch->int1 = wlan_config.hwmp_pathlifetime; wlan_config.hwmp_pathlifetime = val->v.integer; break; case LEAF_wlanHWMPReplyForwardBit: ctx->scratch->int1 = wlan_config.hwmp_replyforward; wlan_config.hwmp_replyforward = val->v.integer; break; case LEAF_wlanHWMPTargetOnlyBit: ctx->scratch->int1 = wlan_config.hwmp_targetonly; wlan_config.hwmp_targetonly = val->v.integer; break; } if (wlan_do_sysctl(&wlan_config, which, 1) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); case SNMP_OP_COMMIT: return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: switch (val->var.subs[sub - 1]) { case LEAF_wlanHWMPRouteInactiveTimeout: wlan_config.hwmp_inact = ctx->scratch->int1; break; case LEAF_wlanHWMPRootAnnounceInterval: wlan_config.hwmp_rannint = ctx->scratch->int1; break; case LEAF_wlanHWMPRootInterval: wlan_config.hwmp_rootint = ctx->scratch->int1; break; case LEAF_wlanHWMPRootTimeout: wlan_config.hwmp_roottimeout = ctx->scratch->int1; break; case LEAF_wlanHWMPPathLifetime: wlan_config.hwmp_pathlifetime = ctx->scratch->int1; break; case LEAF_wlanHWMPReplyForwardBit: wlan_config.hwmp_replyforward = ctx->scratch->int1; break; case LEAF_wlanHWMPTargetOnlyBit: wlan_config.hwmp_targetonly = ctx->scratch->int1; break; } if (wlan_do_sysctl(&wlan_config, which, 1) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); default: abort(); } switch (val->var.subs[sub - 1]) { case LEAF_wlanHWMPRouteInactiveTimeout: val->v.integer = wlan_config.hwmp_inact; break; case LEAF_wlanHWMPRootAnnounceInterval: val->v.integer = wlan_config.hwmp_rannint; break; case LEAF_wlanHWMPRootInterval: val->v.integer = wlan_config.hwmp_rootint; break; case LEAF_wlanHWMPRootTimeout: val->v.integer = wlan_config.hwmp_roottimeout; break; case LEAF_wlanHWMPPathLifetime: val->v.integer = wlan_config.hwmp_pathlifetime; break; case LEAF_wlanHWMPReplyForwardBit: val->v.integer = wlan_config.hwmp_replyforward; break; case LEAF_wlanHWMPTargetOnlyBit: val->v.integer = wlan_config.hwmp_targetonly; break; } return (SNMP_ERR_NOERROR); } int op_wlan_hwmp_iface(struct snmp_context *ctx, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_mesh_get_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((wif = wlan_mesh_get_next_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); break; case SNMP_OP_SET: if ((wif = wlan_mesh_get_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanHWMPRootMode: ctx->scratch->int1 = wif->hwmp_root_mode; wif->hwmp_root_mode = val->v.integer; break; case LEAF_wlanHWMPMaxHops: ctx->scratch->int1 = wif->hwmp_max_hops; wif->hwmp_max_hops = val->v.integer; break; default: abort(); } if (wlan_hwmp_config_set(wif, val->var.subs[sub - 1]) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); case SNMP_OP_COMMIT: return (SNMP_ERR_NOERROR); case SNMP_OP_ROLLBACK: if ((wif = wlan_mesh_get_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); switch (val->var.subs[sub - 1]) { case LEAF_wlanHWMPRootMode: wif->hwmp_root_mode = ctx->scratch->int1; break; case LEAF_wlanHWMPMaxHops: wif->hwmp_max_hops = ctx->scratch->int1; break; default: abort(); } if (wlan_hwmp_config_set(wif, val->var.subs[sub - 1]) < 0) return (SNMP_ERR_GENERR); return (SNMP_ERR_NOERROR); default: abort(); } if (wlan_hwmp_config_get(wif, val->var.subs[sub - 1]) < 0) return (SNMP_ERR_GENERR); switch (val->var.subs[sub - 1]) { case LEAF_wlanHWMPRootMode: val->v.integer = wif->hwmp_root_mode; break; case LEAF_wlanHWMPMaxHops: val->v.integer = wif->hwmp_max_hops; break; default: abort(); } return (SNMP_ERR_NOERROR); } int op_wlan_hwmp_stats(struct snmp_context *ctx __unused, struct snmp_value *val, uint32_t sub, uint32_t iidx __unused, enum snmp_op op) { struct wlan_iface *wif; wlan_update_interface_list(); switch (op) { case SNMP_OP_GET: if ((wif = wlan_mesh_get_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); break; case SNMP_OP_GETNEXT: if ((wif = wlan_mesh_get_next_iface(&val->var, sub)) == NULL) return (SNMP_ERR_NOSUCHNAME); wlan_append_ifindex(&val->var, sub, wif); break; case SNMP_OP_SET: return (SNMP_ERR_NOT_WRITEABLE); case SNMP_OP_COMMIT: /* FALLTHROUGH */ case SNMP_OP_ROLLBACK: /* FALLTHROUGH */ default: abort(); } if (wlan_get_stats(wif) < 0) return (SNMP_ERR_GENERR); switch (val->var.subs[sub - 1]) { case LEAF_wlanMeshHWMPWrongSeqNo: val->v.uint32 = wif->stats.is_hwmp_wrongseq; break; case LEAF_wlanMeshHWMPTxRootPREQ: val->v.uint32 = wif->stats.is_hwmp_rootreqs; break; case LEAF_wlanMeshHWMPTxRootRANN: val->v.uint32 = wif->stats.is_hwmp_rootrann; break; case LEAF_wlanMeshHWMPProxy: val->v.uint32 = wif->stats.is_hwmp_proxy; break; default: abort(); } return (SNMP_ERR_NOERROR); } /* * Encode BITS type for a response packet - XXX: this belongs to the snmp lib. */ static int bits_get(struct snmp_value *value, const u_char *ptr, ssize_t len) { int size; if (ptr == NULL) { value->v.octetstring.len = 0; value->v.octetstring.octets = NULL; return (SNMP_ERR_NOERROR); } /* Determine length - up to 8 octets supported so far. */ for (size = len; size > 0; size--) if (ptr[size - 1] != 0) break; if (size == 0) size = 1; value->v.octetstring.len = (u_long)size; if ((value->v.octetstring.octets = malloc((size_t)size)) == NULL) return (SNMP_ERR_RES_UNAVAIL); memcpy(value->v.octetstring.octets, ptr, (size_t)size); return (SNMP_ERR_NOERROR); } /* * Calls for adding/updating/freeing/etc of wireless interfaces. */ static void wlan_free_interface(struct wlan_iface *wif) { wlan_free_peerlist(wif); free(wif->chanlist); wlan_scan_free_results(wif); wlan_mac_free_maclist(wif); wlan_mesh_free_routes(wif); free(wif); } static void wlan_free_iflist(void) { struct wlan_iface *w; while ((w = SLIST_FIRST(&wlan_ifaces)) != NULL) { SLIST_REMOVE_HEAD(&wlan_ifaces, w_if); wlan_free_interface(w); } } static struct wlan_iface * wlan_find_interface(const char *wname) { struct wlan_iface *wif; SLIST_FOREACH(wif, &wlan_ifaces, w_if) if (strcmp(wif->wname, wname) == 0) { if (wif->status != RowStatus_active) return (NULL); break; } return (wif); } static struct wlan_iface * wlan_first_interface(void) { return (SLIST_FIRST(&wlan_ifaces)); } static struct wlan_iface * wlan_next_interface(struct wlan_iface *wif) { if (wif == NULL) return (NULL); return (SLIST_NEXT(wif, w_if)); } /* * Add a new interface to the list - sorted by name. */ static int wlan_add_wif(struct wlan_iface *wif) { int cmp; struct wlan_iface *temp, *prev; if ((prev = SLIST_FIRST(&wlan_ifaces)) == NULL || strcmp(wif->wname, prev->wname) < 0) { SLIST_INSERT_HEAD(&wlan_ifaces, wif, w_if); return (0); } SLIST_FOREACH(temp, &wlan_ifaces, w_if) { if ((cmp = strcmp(wif->wname, temp->wname)) <= 0) break; prev = temp; } if (temp == NULL) SLIST_INSERT_AFTER(prev, wif, w_if); else if (cmp > 0) SLIST_INSERT_AFTER(temp, wif, w_if); else { syslog(LOG_ERR, "Wlan iface %s already in list", wif->wname); return (-1); } return (0); } static struct wlan_iface * wlan_new_wif(char *wname) { struct wlan_iface *wif; /* Make sure it's not in the list. */ for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) if (strcmp(wname, wif->wname) == 0) { wif->internal = 0; return (wif); } if ((wif = (struct wlan_iface *)malloc(sizeof(*wif))) == NULL) return (NULL); memset(wif, 0, sizeof(struct wlan_iface)); strlcpy(wif->wname, wname, IFNAMSIZ); wif->status = RowStatus_notReady; wif->state = wlanIfaceState_down; wif->mode = WlanIfaceOperatingModeType_station; if (wlan_add_wif(wif) < 0) { free(wif); return (NULL); } return (wif); } static void wlan_delete_wif(struct wlan_iface *wif) { SLIST_REMOVE(&wlan_ifaces, wif, wlan_iface, w_if); wlan_free_interface(wif); } static int wlan_attach_newif(struct mibif *mif) { struct wlan_iface *wif; if (mif->mib.ifmd_data.ifi_type != IFT_ETHER || wlan_check_media(mif->name) != IFM_IEEE80211) return (0); if ((wif = wlan_new_wif(mif->name)) == NULL) return (-1); (void)wlan_get_opmode(wif); wif->index = mif->index; wif->status = RowStatus_active; (void)wlan_update_interface(wif); return (0); } static int wlan_iface_create(struct wlan_iface *wif) { int rc; if ((rc = wlan_clone_create(wif)) == SNMP_ERR_NOERROR) { /* * The rest of the info will be updated once the * snmp_mibII module notifies us of the interface. */ wif->status = RowStatus_active; if (wif->state == wlanIfaceState_up) (void)wlan_config_state(wif, 1); } return (rc); } static int wlan_iface_destroy(struct wlan_iface *wif) { int rc = SNMP_ERR_NOERROR; if (wif->internal == 0) rc = wlan_clone_destroy(wif); if (rc == SNMP_ERR_NOERROR) wlan_delete_wif(wif); return (rc); } static int wlan_update_interface(struct wlan_iface *wif) { int i; (void)wlan_config_state(wif, 0); (void)wlan_get_driver_caps(wif); for (i = LEAF_wlanIfacePacketBurst; i <= LEAF_wlanIfaceTdmaBeaconInterval; i++) (void)wlan_config_get_ioctl(wif, i); (void)wlan_get_stats(wif); /* * XXX: wlan_get_channel_list() not needed - * fetched with wlan_get_driver_caps() */ (void)wlan_get_channel_list(wif); (void)wlan_get_roam_params(wif); (void)wlan_get_tx_params(wif); (void)wlan_get_scan_results(wif); (void)wlan_get_wepmode(wif); (void)wlan_get_weptxkey(wif); (void)wlan_get_mac_policy(wif); (void)wlan_get_mac_acl_macs(wif); (void)wlan_get_peerinfo(wif); if (wif->mode == WlanIfaceOperatingModeType_meshPoint) { for (i = LEAF_wlanMeshTTL; i <= LEAF_wlanMeshPath; i++) (void)wlan_mesh_config_get(wif, i); (void)wlan_mesh_get_routelist(wif); for (i = LEAF_wlanHWMPRootMode; i <= LEAF_wlanHWMPMaxHops; i++) (void)wlan_hwmp_config_get(wif, i); } return (0); } static void wlan_update_interface_list(void) { struct wlan_iface *wif, *twif; if ((time(NULL) - wlan_iflist_age) <= WLAN_LIST_MAXAGE) return; /* * The snmp_mibII module would have notified us for new interfaces, * so only check if any have been deleted. */ SLIST_FOREACH_SAFE(wif, &wlan_ifaces, w_if, twif) if (wif->status == RowStatus_active && wlan_get_opmode(wif) < 0) wlan_delete_wif(wif); wlan_iflist_age = time(NULL); } static void wlan_append_ifindex(struct asn_oid *oid, uint sub, const struct wlan_iface *w) { uint32_t i; oid->len = sub + strlen(w->wname) + 1; oid->subs[sub] = strlen(w->wname); for (i = 1; i <= strlen(w->wname); i++) oid->subs[sub + i] = w->wname[i - 1]; } static uint8_t * wlan_get_ifname(const struct asn_oid *oid, uint sub, uint8_t *wname) { uint32_t i; memset(wname, 0, IFNAMSIZ); if (oid->len - sub != oid->subs[sub] + 1 || oid->subs[sub] >= IFNAMSIZ) return (NULL); for (i = 0; i < oid->subs[sub]; i++) wname[i] = oid->subs[sub + i + 1]; wname[i] = '\0'; return (wname); } static struct wlan_iface * wlan_get_interface(const struct asn_oid *oid, uint sub) { uint8_t wname[IFNAMSIZ]; if (wlan_get_ifname(oid, sub, wname) == NULL) return (NULL); return (wlan_find_interface(wname)); } static struct wlan_iface * wlan_get_next_interface(const struct asn_oid *oid, uint sub) { uint32_t i; uint8_t wname[IFNAMSIZ]; struct wlan_iface *wif; if (oid->len - sub == 0) { for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) if (wif->status == RowStatus_active) break; return (wif); } if (oid->len - sub != oid->subs[sub] + 1 || oid->subs[sub] >= IFNAMSIZ) return (NULL); memset(wname, 0, IFNAMSIZ); for (i = 0; i < oid->subs[sub]; i++) wname[i] = oid->subs[sub + i + 1]; wname[i] = '\0'; if ((wif = wlan_find_interface(wname)) == NULL) return (NULL); while ((wif = wlan_next_interface(wif)) != NULL) if (wif->status == RowStatus_active) break; return (wif); } static struct wlan_iface * wlan_get_snmp_interface(const struct asn_oid *oid, uint sub) { uint8_t wname[IFNAMSIZ]; struct wlan_iface *wif; if (wlan_get_ifname(oid, sub, wname) == NULL) return (NULL); for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) if (strcmp(wif->wname, wname) == 0) break; return (wif); } static struct wlan_iface * wlan_get_next_snmp_interface(const struct asn_oid *oid, uint sub) { uint32_t i; uint8_t wname[IFNAMSIZ]; struct wlan_iface *wif; if (oid->len - sub == 0) return (wlan_first_interface()); if (oid->len - sub != oid->subs[sub] + 1 || oid->subs[sub] >= IFNAMSIZ) return (NULL); memset(wname, 0, IFNAMSIZ); for (i = 0; i < oid->subs[sub]; i++) wname[i] = oid->subs[sub + i + 1]; wname[i] = '\0'; for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) if (strcmp(wif->wname, wname) == 0) break; return (wlan_next_interface(wif)); } /* * Decode/Append an index for tables indexed by the wireless interface * name and a MAC address - ACL MACs and Mesh Routes. */ static int wlan_mac_index_decode(const struct asn_oid *oid, uint sub, char *wname, uint8_t *mac) { uint32_t i; int mac_off; if (oid->len - sub != oid->subs[sub] + 2 + IEEE80211_ADDR_LEN || oid->subs[sub] >= IFNAMSIZ) return (-1); for (i = 0; i < oid->subs[sub]; i++) wname[i] = oid->subs[sub + i + 1]; wname[i] = '\0'; mac_off = sub + oid->subs[sub] + 1; if (oid->subs[mac_off] != IEEE80211_ADDR_LEN) return (-1); for (i = 0; i < IEEE80211_ADDR_LEN; i++) mac[i] = oid->subs[mac_off + i + 1]; return (0); } static void wlan_append_mac_index(struct asn_oid *oid, uint sub, char *wname, uint8_t *mac) { uint32_t i; oid->len = sub + strlen(wname) + IEEE80211_ADDR_LEN + 2; oid->subs[sub] = strlen(wname); for (i = 1; i <= strlen(wname); i++) oid->subs[sub + i] = wname[i - 1]; sub += strlen(wname) + 1; oid->subs[sub] = IEEE80211_ADDR_LEN; for (i = 1; i <= IEEE80211_ADDR_LEN; i++) oid->subs[sub + i] = mac[i - 1]; } /* * Decode/Append an index for tables indexed by the wireless interface * name and the PHY mode - Roam and TX params. */ static int wlan_phy_index_decode(const struct asn_oid *oid, uint sub, char *wname, uint32_t *phy) { uint32_t i; if (oid->len - sub != oid->subs[sub] + 2 || oid->subs[sub] >= IFNAMSIZ) return (-1); for (i = 0; i < oid->subs[sub]; i++) wname[i] = oid->subs[sub + i + 1]; wname[i] = '\0'; *phy = oid->subs[sub + oid->subs[sub] + 1]; return (0); } static void wlan_append_phy_index(struct asn_oid *oid, uint sub, char *wname, uint32_t phy) { uint32_t i; oid->len = sub + strlen(wname) + 2; oid->subs[sub] = strlen(wname); for (i = 1; i <= strlen(wname); i++) oid->subs[sub + i] = wname[i - 1]; oid->subs[sub + strlen(wname) + 1] = phy; } /* * Calls for manipulating the peerlist of a wireless interface. */ static void wlan_free_peerlist(struct wlan_iface *wif) { struct wlan_peer *wip; while ((wip = SLIST_FIRST(&wif->peerlist)) != NULL) { SLIST_REMOVE_HEAD(&wif->peerlist, wp); free(wip); } SLIST_INIT(&wif->peerlist); } static struct wlan_peer * wlan_find_peer(struct wlan_iface *wif, uint8_t *peermac) { struct wlan_peer *wip; SLIST_FOREACH(wip, &wif->peerlist, wp) if (memcmp(wip->pmac, peermac, IEEE80211_ADDR_LEN) == 0) break; return (wip); } struct wlan_peer * wlan_new_peer(const uint8_t *pmac) { struct wlan_peer *wip; if ((wip = (struct wlan_peer *)malloc(sizeof(*wip))) == NULL) return (NULL); memset(wip, 0, sizeof(struct wlan_peer)); memcpy(wip->pmac, pmac, IEEE80211_ADDR_LEN); return (wip); } void wlan_free_peer(struct wlan_peer *wip) { free(wip); } int wlan_add_peer(struct wlan_iface *wif, struct wlan_peer *wip) { struct wlan_peer *temp, *prev; SLIST_FOREACH(temp, &wif->peerlist, wp) if (memcmp(temp->pmac, wip->pmac, IEEE80211_ADDR_LEN) == 0) return (-1); if ((prev = SLIST_FIRST(&wif->peerlist)) == NULL || memcmp(wip->pmac, prev->pmac, IEEE80211_ADDR_LEN) < 0) { SLIST_INSERT_HEAD(&wif->peerlist, wip, wp); return (0); } SLIST_FOREACH(temp, &wif->peerlist, wp) { if (memcmp(wip->pmac, temp->pmac, IEEE80211_ADDR_LEN) < 0) break; prev = temp; } SLIST_INSERT_AFTER(prev, wip, wp); return (0); } static void wlan_update_peers(void) { struct wlan_iface *wif; if ((time(NULL) - wlan_peerlist_age) <= WLAN_LIST_MAXAGE) return; for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) { if (wif->status != RowStatus_active) continue; wlan_free_peerlist(wif); (void)wlan_get_peerinfo(wif); } wlan_peerlist_age = time(NULL); } static struct wlan_peer * wlan_get_peer(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { char wname[IFNAMSIZ]; uint8_t pmac[IEEE80211_ADDR_LEN]; if (wlan_mac_index_decode(oid, sub, wname, pmac) < 0) return (NULL); if ((*wif = wlan_find_interface(wname)) == NULL) return (NULL); return (wlan_find_peer(*wif, pmac)); } static struct wlan_peer * wlan_get_next_peer(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { char wname[IFNAMSIZ]; char pmac[IEEE80211_ADDR_LEN]; struct wlan_peer *wip; if (oid->len - sub == 0) { for (*wif = wlan_first_interface(); *wif != NULL; *wif = wlan_next_interface(*wif)) { if ((*wif)->mode == WlanIfaceOperatingModeType_meshPoint) continue; wip = SLIST_FIRST(&(*wif)->peerlist); if (wip != NULL) return (wip); } return (NULL); } if (wlan_mac_index_decode(oid, sub, wname, pmac) < 0 || (*wif = wlan_find_interface(wname)) == NULL || (wip = wlan_find_peer(*wif, pmac)) == NULL) return (NULL); if ((wip = SLIST_NEXT(wip, wp)) != NULL) return (wip); while ((*wif = wlan_next_interface(*wif)) != NULL) { if ((*wif)->mode == WlanIfaceOperatingModeType_meshPoint) continue; if ((wip = SLIST_FIRST(&(*wif)->peerlist)) != NULL) break; } return (wip); } /* * Calls for manipulating the active channel list of a wireless interface. */ static void wlan_update_channels(void) { struct wlan_iface *wif; if ((time(NULL) - wlan_chanlist_age) <= WLAN_LIST_MAXAGE) return; for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) { if (wif->status != RowStatus_active) continue; (void)wlan_get_channel_list(wif); } wlan_chanlist_age = time(NULL); } static int wlan_channel_index_decode(const struct asn_oid *oid, uint sub, char *wname, uint32_t *cindex) { uint32_t i; if (oid->len - sub != oid->subs[sub] + 2 || oid->subs[sub] >= IFNAMSIZ) return (-1); for (i = 0; i < oid->subs[sub]; i++) wname[i] = oid->subs[sub + i + 1]; wname[i] = '\0'; *cindex = oid->subs[sub + oid->subs[sub] + 1]; return (0); } static void wlan_append_channel_index(struct asn_oid *oid, uint sub, const struct wlan_iface *wif, const struct ieee80211_channel *channel) { uint32_t i; oid->len = sub + strlen(wif->wname) + 2; oid->subs[sub] = strlen(wif->wname); for (i = 1; i <= strlen(wif->wname); i++) oid->subs[sub + i] = wif->wname[i - 1]; oid->subs[sub + strlen(wif->wname) + 1] = (channel - wif->chanlist) + 1; } static int32_t wlan_get_channel_type(struct ieee80211_channel *c) { if (IEEE80211_IS_CHAN_FHSS(c)) return (WlanChannelType_fhss); if (IEEE80211_IS_CHAN_A(c)) return (WlanChannelType_dot11a); if (IEEE80211_IS_CHAN_B(c)) return (WlanChannelType_dot11b); if (IEEE80211_IS_CHAN_ANYG(c)) return (WlanChannelType_dot11g); if (IEEE80211_IS_CHAN_HALF(c)) return (WlanChannelType_tenMHz); if (IEEE80211_IS_CHAN_QUARTER(c)) return (WlanChannelType_fiveMHz); if (IEEE80211_IS_CHAN_TURBO(c)) return (WlanChannelType_turbo); if (IEEE80211_IS_CHAN_HT(c)) return (WlanChannelType_ht); return (-1); } static struct ieee80211_channel * wlan_find_channel(struct wlan_iface *wif, uint32_t cindex) { if (wif->chanlist == NULL || cindex > wif->nchannels) return (NULL); return (wif->chanlist + cindex - 1); } static struct ieee80211_channel * wlan_get_channel(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { uint32_t cindex; char wname[IFNAMSIZ]; if (wlan_channel_index_decode(oid, sub, wname, &cindex) < 0) return (NULL); if ((*wif = wlan_find_interface(wname)) == NULL) return (NULL); return (wlan_find_channel(*wif, cindex)); } static struct ieee80211_channel * wlan_get_next_channel(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { uint32_t cindex; char wname[IFNAMSIZ]; if (oid->len - sub == 0) { for (*wif = wlan_first_interface(); *wif != NULL; *wif = wlan_next_interface(*wif)) { if ((*wif)->status != RowStatus_active) continue; if ((*wif)->nchannels != 0 && (*wif)->chanlist != NULL) return ((*wif)->chanlist); } return (NULL); } if (wlan_channel_index_decode(oid, sub, wname, &cindex) < 0) return (NULL); if ((*wif = wlan_find_interface(wname)) == NULL) return (NULL); if (cindex < (*wif)->nchannels) return ((*wif)->chanlist + cindex); while ((*wif = wlan_next_interface(*wif)) != NULL) if ((*wif)->status == RowStatus_active) if ((*wif)->nchannels != 0 && (*wif)->chanlist != NULL) return ((*wif)->chanlist); return (NULL); } /* * Calls for manipulating the roam params of a wireless interface. */ static void wlan_update_roam_params(void) { struct wlan_iface *wif; if ((time(NULL) - wlan_roamlist_age) <= WLAN_LIST_MAXAGE) return; for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) { if (wif->status != RowStatus_active) continue; (void)wlan_get_roam_params(wif); } wlan_roamlist_age = time(NULL); } static struct ieee80211_roamparam * wlan_get_roam_param(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { uint32_t phy; char wname[IFNAMSIZ]; if (wlan_phy_index_decode(oid, sub, wname, &phy) < 0) return (NULL); if ((*wif = wlan_find_interface(wname)) == NULL) return (NULL); if (phy == 0 || phy > IEEE80211_MODE_MAX) return (NULL); return ((*wif)->roamparams.params + phy - 1); } static struct ieee80211_roamparam * wlan_get_next_roam_param(const struct asn_oid *oid, uint sub, struct wlan_iface **wif, uint32_t *phy) { char wname[IFNAMSIZ]; if (oid->len - sub == 0) { for (*wif = wlan_first_interface(); *wif != NULL; *wif = wlan_next_interface(*wif)) { if ((*wif)->status != RowStatus_active) continue; *phy = 1; return ((*wif)->roamparams.params); } return (NULL); } if (wlan_phy_index_decode(oid, sub, wname, phy) < 0) return (NULL); if (*phy == 0 || (*wif = wlan_find_interface(wname)) == NULL) return (NULL); if (++(*phy) <= IEEE80211_MODE_MAX) return ((*wif)->roamparams.params + *phy - 1); *phy = 1; while ((*wif = wlan_next_interface(*wif)) != NULL) if ((*wif)->status == RowStatus_active) return ((*wif)->roamparams.params); return (NULL); } /* * Calls for manipulating the tx params of a wireless interface. */ static void wlan_update_tx_params(void) { struct wlan_iface *wif; if ((time(NULL) - wlan_tx_paramlist_age) <= WLAN_LIST_MAXAGE) return; for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) { if (wif->status != RowStatus_active) continue; (void)wlan_get_tx_params(wif); } wlan_tx_paramlist_age = time(NULL); } static struct ieee80211_txparam * wlan_get_tx_param(const struct asn_oid *oid, uint sub, struct wlan_iface **wif, uint32_t *phy) { char wname[IFNAMSIZ]; if (wlan_phy_index_decode(oid, sub, wname, phy) < 0) return (NULL); if ((*wif = wlan_find_interface(wname)) == NULL) return (NULL); if (*phy == 0 || *phy > IEEE80211_MODE_MAX) return (NULL); return ((*wif)->txparams.params + *phy - 1); } static struct ieee80211_txparam * wlan_get_next_tx_param(const struct asn_oid *oid, uint sub, struct wlan_iface **wif, uint32_t *phy) { char wname[IFNAMSIZ]; if (oid->len - sub == 0) { for (*wif = wlan_first_interface(); *wif != NULL; *wif = wlan_next_interface(*wif)) { if ((*wif)->status != RowStatus_active) continue; *phy = 1; return ((*wif)->txparams.params); } return (NULL); } if (wlan_phy_index_decode(oid, sub, wname, phy) < 0) return (NULL); if (*phy == 0 || (*wif = wlan_find_interface(wname)) == NULL) return (NULL); if (++(*phy) <= IEEE80211_MODE_MAX) return ((*wif)->txparams.params + *phy - 1); *phy = 1; while ((*wif = wlan_next_interface(*wif)) != NULL) if ((*wif)->status == RowStatus_active) return ((*wif)->txparams.params); return (NULL); } /* * Calls for manipulating the scan results for a wireless interface. */ static void wlan_scan_free_results(struct wlan_iface *wif) { struct wlan_scan_result *sr; while ((sr = SLIST_FIRST(&wif->scanlist)) != NULL) { SLIST_REMOVE_HEAD(&wif->scanlist, wsr); free(sr); } SLIST_INIT(&wif->scanlist); } static struct wlan_scan_result * wlan_scan_find_result(struct wlan_iface *wif, uint8_t *ssid, uint8_t *bssid) { struct wlan_scan_result *sr; SLIST_FOREACH(sr, &wif->scanlist, wsr) if (strlen(ssid) == strlen(sr->ssid) && strcmp(sr->ssid, ssid) == 0 && memcmp(sr->bssid, bssid, IEEE80211_ADDR_LEN) == 0) break; return (sr); } struct wlan_scan_result * wlan_scan_new_result(const uint8_t *ssid, const uint8_t *bssid) { struct wlan_scan_result *sr; sr = (struct wlan_scan_result *)malloc(sizeof(*sr)); if (sr == NULL) return (NULL); memset(sr, 0, sizeof(*sr)); if (ssid[0] != '\0') strlcpy(sr->ssid, ssid, IEEE80211_NWID_LEN + 1); memcpy(sr->bssid, bssid, IEEE80211_ADDR_LEN); return (sr); } void wlan_scan_free_result(struct wlan_scan_result *sr) { free(sr); } static int wlan_scan_compare_result(struct wlan_scan_result *sr1, struct wlan_scan_result *sr2) { uint32_t i; if (strlen(sr1->ssid) < strlen(sr2->ssid)) return (-1); if (strlen(sr1->ssid) > strlen(sr2->ssid)) return (1); for (i = 0; i < strlen(sr1->ssid) && i < strlen(sr2->ssid); i++) { if (sr1->ssid[i] < sr2->ssid[i]) return (-1); if (sr1->ssid[i] > sr2->ssid[i]) return (1); } for (i = 0; i < IEEE80211_ADDR_LEN; i++) { if (sr1->bssid[i] < sr2->bssid[i]) return (-1); if (sr1->bssid[i] > sr2->bssid[i]) return (1); } return (0); } int wlan_scan_add_result(struct wlan_iface *wif, struct wlan_scan_result *sr) { struct wlan_scan_result *prev, *temp; SLIST_FOREACH(temp, &wif->scanlist, wsr) if (strlen(temp->ssid) == strlen(sr->ssid) && strcmp(sr->ssid, temp->ssid) == 0 && memcmp(sr->bssid, temp->bssid, IEEE80211_ADDR_LEN) == 0) return (-1); if ((prev = SLIST_FIRST(&wif->scanlist)) == NULL || wlan_scan_compare_result(sr, prev) < 0) { SLIST_INSERT_HEAD(&wif->scanlist, sr, wsr); return (0); } SLIST_FOREACH(temp, &wif->scanlist, wsr) { if (wlan_scan_compare_result(sr, temp) < 0) break; prev = temp; } SLIST_INSERT_AFTER(prev, sr, wsr); return (0); } static void wlan_scan_update_results(void) { struct wlan_iface *wif; if ((time(NULL) - wlan_scanlist_age) <= WLAN_LIST_MAXAGE) return; for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) { if (wif->status != RowStatus_active) continue; wlan_scan_free_results(wif); (void)wlan_get_scan_results(wif); } wlan_scanlist_age = time(NULL); } static int wlan_scanr_index_decode(const struct asn_oid *oid, uint sub, char *wname, uint8_t *ssid, uint8_t *bssid) { uint32_t i; int offset; if (oid->subs[sub] >= IFNAMSIZ) return (-1); for (i = 0; i < oid->subs[sub]; i++) wname[i] = oid->subs[sub + i + 1]; wname[oid->subs[sub]] = '\0'; offset = sub + oid->subs[sub] + 1; if (oid->subs[offset] > IEEE80211_NWID_LEN) return (-1); for (i = 0; i < oid->subs[offset]; i++) ssid[i] = oid->subs[offset + i + 1]; ssid[i] = '\0'; offset = sub + oid->subs[sub] + oid->subs[offset] + 2; if (oid->subs[offset] != IEEE80211_ADDR_LEN) return (-1); for (i = 0; i < IEEE80211_ADDR_LEN; i++) bssid[i] = oid->subs[offset + i + 1]; return (0); } static void wlan_append_scanr_index(struct asn_oid *oid, uint sub, char *wname, uint8_t *ssid, uint8_t *bssid) { uint32_t i; oid->len = sub + strlen(wname) + strlen(ssid) + IEEE80211_ADDR_LEN + 3; oid->subs[sub] = strlen(wname); for (i = 1; i <= strlen(wname); i++) oid->subs[sub + i] = wname[i - 1]; sub += strlen(wname) + 1; oid->subs[sub] = strlen(ssid); for (i = 1; i <= strlen(ssid); i++) oid->subs[sub + i] = ssid[i - 1]; sub += strlen(ssid) + 1; oid->subs[sub] = IEEE80211_ADDR_LEN; for (i = 1; i <= IEEE80211_ADDR_LEN; i++) oid->subs[sub + i] = bssid[i - 1]; } static struct wlan_scan_result * wlan_get_scanr(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { char wname[IFNAMSIZ]; uint8_t ssid[IEEE80211_NWID_LEN + 1]; uint8_t bssid[IEEE80211_ADDR_LEN]; if (wlan_scanr_index_decode(oid, sub, wname, ssid, bssid) < 0) return (NULL); if ((*wif = wlan_find_interface(wname)) == NULL) return (NULL); return (wlan_scan_find_result(*wif, ssid, bssid)); } static struct wlan_scan_result * wlan_get_next_scanr(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { char wname[IFNAMSIZ]; uint8_t ssid[IEEE80211_NWID_LEN + 1]; uint8_t bssid[IEEE80211_ADDR_LEN]; struct wlan_scan_result *sr; if (oid->len - sub == 0) { for (*wif = wlan_first_interface(); *wif != NULL; *wif = wlan_next_interface(*wif)) { sr = SLIST_FIRST(&(*wif)->scanlist); if (sr != NULL) return (sr); } return (NULL); } if (wlan_scanr_index_decode(oid, sub, wname, ssid, bssid) < 0 || (*wif = wlan_find_interface(wname)) == NULL || (sr = wlan_scan_find_result(*wif, ssid, bssid)) == NULL) return (NULL); if ((sr = SLIST_NEXT(sr, wsr)) != NULL) return (sr); while ((*wif = wlan_next_interface(*wif)) != NULL) if ((sr = SLIST_FIRST(&(*wif)->scanlist)) != NULL) break; return (sr); } /* * MAC Access Control. */ static void wlan_mac_free_maclist(struct wlan_iface *wif) { struct wlan_mac_mac *wmm; while ((wmm = SLIST_FIRST(&wif->mac_maclist)) != NULL) { SLIST_REMOVE_HEAD(&wif->mac_maclist, wm); free(wmm); } SLIST_INIT(&wif->mac_maclist); } static struct wlan_mac_mac * wlan_mac_find_mac(struct wlan_iface *wif, uint8_t *mac) { struct wlan_mac_mac *wmm; SLIST_FOREACH(wmm, &wif->mac_maclist, wm) if (memcmp(wmm->mac, mac, IEEE80211_ADDR_LEN) == 0) break; return (wmm); } struct wlan_mac_mac * wlan_mac_new_mac(const uint8_t *mac) { struct wlan_mac_mac *wmm; if ((wmm = (struct wlan_mac_mac *)malloc(sizeof(*wmm))) == NULL) return (NULL); memset(wmm, 0, sizeof(*wmm)); memcpy(wmm->mac, mac, IEEE80211_ADDR_LEN); wmm->mac_status = RowStatus_notReady; return (wmm); } void wlan_mac_free_mac(struct wlan_mac_mac *wmm) { free(wmm); } int wlan_mac_add_mac(struct wlan_iface *wif, struct wlan_mac_mac *wmm) { struct wlan_mac_mac *temp, *prev; SLIST_FOREACH(temp, &wif->mac_maclist, wm) if (memcmp(temp->mac, wmm->mac, IEEE80211_ADDR_LEN) == 0) return (-1); if ((prev = SLIST_FIRST(&wif->mac_maclist)) == NULL || memcmp(wmm->mac, prev->mac,IEEE80211_ADDR_LEN) < 0) { SLIST_INSERT_HEAD(&wif->mac_maclist, wmm, wm); return (0); } SLIST_FOREACH(temp, &wif->mac_maclist, wm) { if (memcmp(wmm->mac, temp->mac, IEEE80211_ADDR_LEN) < 0) break; prev = temp; } SLIST_INSERT_AFTER(prev, wmm, wm); return (0); } static int wlan_mac_delete_mac(struct wlan_iface *wif, struct wlan_mac_mac *wmm) { if (wmm->mac_status == RowStatus_active && wlan_del_mac_acl_mac(wif, wmm) < 0) return (-1); SLIST_REMOVE(&wif->mac_maclist, wmm, wlan_mac_mac, wm); free(wmm); return (0); } static void wlan_mac_update_aclmacs(void) { struct wlan_iface *wif; struct wlan_mac_mac *wmm, *twmm; if ((time(NULL) - wlan_maclist_age) <= WLAN_LIST_MAXAGE) return; for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) { if (wif->status != RowStatus_active) continue; /* * Nuke old entries - XXX - they are likely not to * change often - reconsider. */ SLIST_FOREACH_SAFE(wmm, &wif->mac_maclist, wm, twmm) if (wmm->mac_status == RowStatus_active) { SLIST_REMOVE(&wif->mac_maclist, wmm, wlan_mac_mac, wm); wlan_mac_free_mac(wmm); } (void)wlan_get_mac_acl_macs(wif); } wlan_maclist_age = time(NULL); } static struct wlan_mac_mac * wlan_get_acl_mac(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { char wname[IFNAMSIZ]; char mac[IEEE80211_ADDR_LEN]; if (wlan_mac_index_decode(oid, sub, wname, mac) < 0) return (NULL); if ((*wif = wlan_find_interface(wname)) == NULL) return (NULL); return (wlan_mac_find_mac(*wif, mac)); } static struct wlan_mac_mac * wlan_get_next_acl_mac(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { char wname[IFNAMSIZ]; char mac[IEEE80211_ADDR_LEN]; struct wlan_mac_mac *wmm; if (oid->len - sub == 0) { for (*wif = wlan_first_interface(); *wif != NULL; *wif = wlan_next_interface(*wif)) { wmm = SLIST_FIRST(&(*wif)->mac_maclist); if (wmm != NULL) return (wmm); } return (NULL); } if (wlan_mac_index_decode(oid, sub, wname, mac) < 0 || (*wif = wlan_find_interface(wname)) == NULL || (wmm = wlan_mac_find_mac(*wif, mac)) == NULL) return (NULL); if ((wmm = SLIST_NEXT(wmm, wm)) != NULL) return (wmm); while ((*wif = wlan_next_interface(*wif)) != NULL) if ((wmm = SLIST_FIRST(&(*wif)->mac_maclist)) != NULL) break; return (wmm); } static int wlan_acl_mac_set_status(struct snmp_context *ctx, struct snmp_value *val, uint sub) { char wname[IFNAMSIZ]; uint8_t mac[IEEE80211_ADDR_LEN]; struct wlan_iface *wif; struct wlan_mac_mac *macl; if (wlan_mac_index_decode(&val->var, sub, wname, mac) < 0) return (SNMP_ERR_GENERR); macl = wlan_get_acl_mac(&val->var, sub, &wif); switch (val->v.integer) { case RowStatus_createAndGo: if (macl != NULL) return (SNMP_ERR_INCONS_NAME); break; case RowStatus_destroy: if (macl == NULL) return (SNMP_ERR_NOSUCHNAME); ctx->scratch->int1 = RowStatus_active; return (SNMP_ERR_NOERROR); default: return (SNMP_ERR_INCONS_VALUE); } if (wif == NULL || !wif->macsupported) return (SNMP_ERR_INCONS_VALUE); if ((macl = wlan_mac_new_mac((const uint8_t *)mac)) == NULL) return (SNMP_ERR_GENERR); ctx->scratch->int1 = RowStatus_destroy; if (wlan_mac_add_mac(wif, macl) < 0) { wlan_mac_free_mac(macl); return (SNMP_ERR_GENERR); } ctx->scratch->int1 = RowStatus_destroy; if (wlan_add_mac_acl_mac(wif, macl) < 0) { (void)wlan_mac_delete_mac(wif, macl); return (SNMP_ERR_GENERR); } return (SNMP_ERR_NOERROR); } /* * Wireless interfaces operating as mesh points. */ static struct wlan_iface * wlan_mesh_first_interface(void) { struct wlan_iface *wif; SLIST_FOREACH(wif, &wlan_ifaces, w_if) if (wif->mode == WlanIfaceOperatingModeType_meshPoint && wif->status == RowStatus_active) break; return (wif); } static struct wlan_iface * wlan_mesh_next_interface(struct wlan_iface *wif) { struct wlan_iface *nwif; while ((nwif = wlan_next_interface(wif)) != NULL) { if (nwif->mode == WlanIfaceOperatingModeType_meshPoint && nwif->status == RowStatus_active) break; wif = nwif; } return (nwif); } static struct wlan_iface * wlan_mesh_get_iface(const struct asn_oid *oid, uint sub) { struct wlan_iface *wif; if ((wif = wlan_get_interface(oid, sub)) == NULL) return (NULL); if (wif->mode != WlanIfaceOperatingModeType_meshPoint) return (NULL); return (wif); } static struct wlan_iface * wlan_mesh_get_next_iface(const struct asn_oid *oid, uint sub) { uint32_t i; uint8_t wname[IFNAMSIZ]; struct wlan_iface *wif; if (oid->len - sub == 0) return (wlan_mesh_first_interface()); if (oid->len - sub != oid->subs[sub] + 1 || oid->subs[sub] >= IFNAMSIZ) return (NULL); memset(wname, 0, IFNAMSIZ); for (i = 0; i < oid->subs[sub]; i++) wname[i] = oid->subs[sub + i + 1]; wname[i] = '\0'; if ((wif = wlan_find_interface(wname)) == NULL) return (NULL); return (wlan_mesh_next_interface(wif)); } /* * The neighbors of wireless interfaces operating as mesh points. */ static struct wlan_peer * wlan_mesh_get_peer(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { char wname[IFNAMSIZ]; uint8_t pmac[IEEE80211_ADDR_LEN]; if (wlan_mac_index_decode(oid, sub, wname, pmac) < 0) return (NULL); if ((*wif = wlan_find_interface(wname)) == NULL || (*wif)->mode != WlanIfaceOperatingModeType_meshPoint) return (NULL); return (wlan_find_peer(*wif, pmac)); } static struct wlan_peer * wlan_mesh_get_next_peer(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { char wname[IFNAMSIZ]; char pmac[IEEE80211_ADDR_LEN]; struct wlan_peer *wip; if (oid->len - sub == 0) { for (*wif = wlan_mesh_first_interface(); *wif != NULL; *wif = wlan_mesh_next_interface(*wif)) { wip = SLIST_FIRST(&(*wif)->peerlist); if (wip != NULL) return (wip); } return (NULL); } if (wlan_mac_index_decode(oid, sub, wname, pmac) < 0 || (*wif = wlan_find_interface(wname)) == NULL || (*wif)->mode != WlanIfaceOperatingModeType_meshPoint || (wip = wlan_find_peer(*wif, pmac)) == NULL) return (NULL); if ((wip = SLIST_NEXT(wip, wp)) != NULL) return (wip); while ((*wif = wlan_mesh_next_interface(*wif)) != NULL) if ((wip = SLIST_FIRST(&(*wif)->peerlist)) != NULL) break; return (wip); } /* * Mesh routing table. */ static void wlan_mesh_free_routes(struct wlan_iface *wif) { struct wlan_mesh_route *wmr; while ((wmr = SLIST_FIRST(&wif->mesh_routelist)) != NULL) { SLIST_REMOVE_HEAD(&wif->mesh_routelist, wr); free(wmr); } SLIST_INIT(&wif->mesh_routelist); } static struct wlan_mesh_route * wlan_mesh_find_route(struct wlan_iface *wif, uint8_t *dstmac) { struct wlan_mesh_route *wmr; if (wif->mode != WlanIfaceOperatingModeType_meshPoint) return (NULL); SLIST_FOREACH(wmr, &wif->mesh_routelist, wr) if (memcmp(wmr->imroute.imr_dest, dstmac, IEEE80211_ADDR_LEN) == 0) break; return (wmr); } struct wlan_mesh_route * wlan_mesh_new_route(const uint8_t *dstmac) { struct wlan_mesh_route *wmr; if ((wmr = (struct wlan_mesh_route *)malloc(sizeof(*wmr))) == NULL) return (NULL); memset(wmr, 0, sizeof(*wmr)); memcpy(wmr->imroute.imr_dest, dstmac, IEEE80211_ADDR_LEN); wmr->mroute_status = RowStatus_notReady; return (wmr); } void wlan_mesh_free_route(struct wlan_mesh_route *wmr) { free(wmr); } int wlan_mesh_add_rtentry(struct wlan_iface *wif, struct wlan_mesh_route *wmr) { struct wlan_mesh_route *temp, *prev; SLIST_FOREACH(temp, &wif->mesh_routelist, wr) if (memcmp(temp->imroute.imr_dest, wmr->imroute.imr_dest, IEEE80211_ADDR_LEN) == 0) return (-1); if ((prev = SLIST_FIRST(&wif->mesh_routelist)) == NULL || memcmp(wmr->imroute.imr_dest, prev->imroute.imr_dest, IEEE80211_ADDR_LEN) < 0) { SLIST_INSERT_HEAD(&wif->mesh_routelist, wmr, wr); return (0); } SLIST_FOREACH(temp, &wif->mesh_routelist, wr) { if (memcmp(wmr->imroute.imr_dest, temp->imroute.imr_dest, IEEE80211_ADDR_LEN) < 0) break; prev = temp; } SLIST_INSERT_AFTER(prev, wmr, wr); return (0); } static int wlan_mesh_delete_route(struct wlan_iface *wif, struct wlan_mesh_route *wmr) { if (wmr->mroute_status == RowStatus_active && wlan_mesh_del_route(wif, wmr) < 0) return (-1); SLIST_REMOVE(&wif->mesh_routelist, wmr, wlan_mesh_route, wr); free(wmr); return (0); } static void wlan_mesh_update_routes(void) { struct wlan_iface *wif; struct wlan_mesh_route *wmr, *twmr; if ((time(NULL) - wlan_mrlist_age) <= WLAN_LIST_MAXAGE) return; for (wif = wlan_mesh_first_interface(); wif != NULL; wif = wlan_mesh_next_interface(wif)) { /* * Nuke old entries - XXX - they are likely not to * change often - reconsider. */ SLIST_FOREACH_SAFE(wmr, &wif->mesh_routelist, wr, twmr) if (wmr->mroute_status == RowStatus_active) { SLIST_REMOVE(&wif->mesh_routelist, wmr, wlan_mesh_route, wr); wlan_mesh_free_route(wmr); } (void)wlan_mesh_get_routelist(wif); } wlan_mrlist_age = time(NULL); } static struct wlan_mesh_route * wlan_mesh_get_route(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { char wname[IFNAMSIZ]; char dstmac[IEEE80211_ADDR_LEN]; if (wlan_mac_index_decode(oid, sub, wname, dstmac) < 0) return (NULL); if ((*wif = wlan_find_interface(wname)) == NULL) return (NULL); return (wlan_mesh_find_route(*wif, dstmac)); } static struct wlan_mesh_route * wlan_mesh_get_next_route(const struct asn_oid *oid, uint sub, struct wlan_iface **wif) { char wname[IFNAMSIZ]; char dstmac[IEEE80211_ADDR_LEN]; struct wlan_mesh_route *wmr; if (oid->len - sub == 0) { for (*wif = wlan_mesh_first_interface(); *wif != NULL; *wif = wlan_mesh_next_interface(*wif)) { wmr = SLIST_FIRST(&(*wif)->mesh_routelist); if (wmr != NULL) return (wmr); } return (NULL); } if (wlan_mac_index_decode(oid, sub, wname, dstmac) < 0 || (*wif = wlan_find_interface(wname)) == NULL || (wmr = wlan_mesh_find_route(*wif, dstmac)) == NULL) return (NULL); if ((wmr = SLIST_NEXT(wmr, wr)) != NULL) return (wmr); while ((*wif = wlan_mesh_next_interface(*wif)) != NULL) if ((wmr = SLIST_FIRST(&(*wif)->mesh_routelist)) != NULL) break; return (wmr); } static int wlan_mesh_route_set_status(struct snmp_context *ctx, struct snmp_value *val, uint sub) { char wname[IFNAMSIZ]; char mac[IEEE80211_ADDR_LEN]; struct wlan_mesh_route *wmr; struct wlan_iface *wif; if (wlan_mac_index_decode(&val->var, sub, wname, mac) < 0) return (SNMP_ERR_GENERR); wmr = wlan_mesh_get_route(&val->var, sub, &wif); switch (val->v.integer) { case RowStatus_createAndGo: if (wmr != NULL) return (SNMP_ERR_INCONS_NAME); break; case RowStatus_destroy: if (wmr == NULL) return (SNMP_ERR_NOSUCHNAME); ctx->scratch->int1 = RowStatus_active; return (SNMP_ERR_NOERROR); default: return (SNMP_ERR_INCONS_VALUE); } if ((wif = wlan_find_interface(wname)) == NULL) return (SNMP_ERR_INCONS_NAME); if ((wmr = wlan_mesh_new_route(mac)) == NULL) return (SNMP_ERR_GENERR); if (wlan_mesh_add_rtentry(wif, wmr) < 0) { wlan_mesh_free_route(wmr); return (SNMP_ERR_GENERR); } ctx->scratch->int1 = RowStatus_destroy; if (wlan_mesh_add_route(wif, wmr) < 0) { (void)wlan_mesh_delete_route(wif, wmr); return (SNMP_ERR_GENERR); } return (SNMP_ERR_NOERROR); } /* * Wlan snmp module initialization hook. * Returns 0 on success, < 0 on error. */ static int wlan_init(struct lmodule * mod __unused, int argc __unused, char *argv[] __unused) { if (wlan_kmodules_load() < 0) return (-1); if (wlan_ioctl_init() < 0) return (-1); /* Register for new interface creation notifications. */ if (mib_register_newif(wlan_attach_newif, wlan_module)) { syslog(LOG_ERR, "Cannot register newif function: %s", strerror(errno)); return (-1); } return (0); } /* * Wlan snmp module finalization hook. */ static int wlan_fini(void) { mib_unregister_newif(wlan_module); or_unregister(reg_wlan); /* XXX: Cleanup! */ wlan_free_iflist(); return (0); } /* * Refetch all available data from the kernel. */ static void wlan_update_data(void *arg __unused) { } /* * Wlan snmp module start operation. */ static void wlan_start(void) { struct mibif *ifp; reg_wlan = or_register(&oid_wlan, "The MIB module for managing wireless networking.", wlan_module); /* Add the existing wlan interfaces. */ for (ifp = mib_first_if(); ifp != NULL; ifp = mib_next_if(ifp)) wlan_attach_newif(ifp); wlan_data_timer = timer_start_repeat(wlan_poll_ticks, wlan_poll_ticks, wlan_update_data, NULL, wlan_module); } /* * Dump the Wlan snmp module data on SIGUSR1. */ static void wlan_dump(void) { /* XXX: Print some debug info to syslog. */ struct wlan_iface *wif; for (wif = wlan_first_interface(); wif != NULL; wif = wlan_next_interface(wif)) syslog(LOG_ERR, "wlan iface %s", wif->wname); } const char wlan_comment[] = \ "This module implements the BEGEMOT MIB for wireless networking."; const struct snmp_module config = { .comment = wlan_comment, .init = wlan_init, .fini = wlan_fini, .start = wlan_start, .tree = wlan_ctree, .dump = wlan_dump, .tree_size = wlan_CTREE_SIZE, };