/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static dladm_status_t wpa_instance_create(datalink_id_t, void *); static dladm_status_t wpa_instance_delete(datalink_id_t); static dladm_status_t do_get_bsstype(datalink_id_t, wldp_t *); static dladm_status_t do_get_essid(datalink_id_t, wldp_t *); static dladm_status_t do_get_bssid(datalink_id_t, wldp_t *); static dladm_status_t do_get_signal(datalink_id_t, wldp_t *); static dladm_status_t do_get_encryption(datalink_id_t, wldp_t *); static dladm_status_t do_get_authmode(datalink_id_t, wldp_t *); static dladm_status_t do_get_linkstatus(datalink_id_t, wldp_t *); static dladm_status_t do_get_esslist(datalink_id_t, wldp_t *); static dladm_status_t do_get_rate(datalink_id_t, wldp_t *); static dladm_status_t do_get_mode(datalink_id_t, wldp_t *); static dladm_status_t do_get_capability(datalink_id_t, wldp_t *); static dladm_status_t do_get_wpamode(datalink_id_t, wldp_t *); static dladm_status_t do_set_bsstype(datalink_id_t, dladm_wlan_bsstype_t *); static dladm_status_t do_set_authmode(datalink_id_t, dladm_wlan_auth_t *); static dladm_status_t do_set_encryption(datalink_id_t, dladm_wlan_secmode_t *); static dladm_status_t do_set_essid(datalink_id_t, dladm_wlan_essid_t *); static dladm_status_t do_set_createibss(datalink_id_t, boolean_t *); static dladm_status_t do_set_key(datalink_id_t, dladm_wlan_key_t *, uint_t); static dladm_status_t do_set_channel(datalink_id_t, dladm_wlan_channel_t *); static dladm_status_t do_scan(datalink_id_t, wldp_t *); static dladm_status_t do_connect(datalink_id_t, wldp_t *, dladm_wlan_attr_t *, boolean_t, void *, uint_t, int); static dladm_status_t do_disconnect(datalink_id_t, wldp_t *); static boolean_t find_val_by_name(const char *, val_desc_t *, uint_t, uint_t *); static boolean_t find_name_by_val(uint_t, val_desc_t *, uint_t, char **); static void generate_essid(dladm_wlan_essid_t *); static dladm_status_t dladm_wlan_wlresult2status(wldp_t *); static dladm_status_t dladm_wlan_validate(datalink_id_t); static val_desc_t linkstatus_vals[] = { { "disconnected", DLADM_WLAN_LINK_DISCONNECTED }, { "connected", DLADM_WLAN_LINK_CONNECTED } }; static val_desc_t secmode_vals[] = { { "none", DLADM_WLAN_SECMODE_NONE }, { "wep", DLADM_WLAN_SECMODE_WEP }, { "wpa", DLADM_WLAN_SECMODE_WPA } }; static val_desc_t strength_vals[] = { { "very weak", DLADM_WLAN_STRENGTH_VERY_WEAK }, { "weak", DLADM_WLAN_STRENGTH_WEAK }, { "good", DLADM_WLAN_STRENGTH_GOOD }, { "very good", DLADM_WLAN_STRENGTH_VERY_GOOD }, { "excellent", DLADM_WLAN_STRENGTH_EXCELLENT } }; static val_desc_t mode_vals[] = { { "a", DLADM_WLAN_MODE_80211A }, { "b", DLADM_WLAN_MODE_80211B }, { "g", DLADM_WLAN_MODE_80211G }, }; static val_desc_t auth_vals[] = { { "open", DLADM_WLAN_AUTH_OPEN }, { "shared", DLADM_WLAN_AUTH_SHARED } }; static val_desc_t bsstype_vals[] = { { "bss", DLADM_WLAN_BSSTYPE_BSS }, { "ibss", DLADM_WLAN_BSSTYPE_IBSS }, { "any", DLADM_WLAN_BSSTYPE_ANY } }; #define IS_CONNECTED(gbuf) \ ((*(wl_linkstatus_t *)((gbuf)->wldp_buf) == WL_CONNECTED)) static dladm_status_t dladm_wlan_wlresult2status(wldp_t *gbuf) { switch (gbuf->wldp_result) { case WL_SUCCESS: return (DLADM_STATUS_OK); case WL_NOTSUPPORTED: case WL_LACK_FEATURE: return (DLADM_STATUS_NOTSUP); case WL_READONLY: return (DLADM_STATUS_PROPRDONLY); default: break; } return (DLADM_STATUS_FAILED); } static dladm_wlan_mode_t do_convert_mode(wl_phy_conf_t *phyp) { switch (phyp->wl_phy_fhss_conf.wl_fhss_subtype) { case WL_ERP: return (DLADM_WLAN_MODE_80211G); case WL_OFDM: return (DLADM_WLAN_MODE_80211A); case WL_DSSS: case WL_FHSS: return (DLADM_WLAN_MODE_80211B); default: break; } return (DLADM_WLAN_MODE_NONE); } boolean_t i_dladm_wlan_convert_chan(wl_phy_conf_t *phyp, uint32_t *channelp) { wl_fhss_t *wlfp = &phyp->wl_phy_fhss_conf; wl_ofdm_t *wlop = &phyp->wl_phy_ofdm_conf; switch (wlfp->wl_fhss_subtype) { case WL_FHSS: case WL_DSSS: case WL_IRBASE: case WL_HRDS: case WL_ERP: *channelp = wlfp->wl_fhss_channel; break; case WL_OFDM: *channelp = DLADM_WLAN_OFDM2CHAN(wlop->wl_ofdm_frequency); break; default: return (B_FALSE); } return (B_TRUE); } #define IEEE80211_RATE 0x7f static void fill_wlan_attr(wl_ess_conf_t *wlp, dladm_wlan_attr_t *attrp) { int i; (void) memset(attrp, 0, sizeof (*attrp)); (void) snprintf(attrp->wa_essid.we_bytes, DLADM_WLAN_MAX_ESSID_LEN, "%s", wlp->wl_ess_conf_essid.wl_essid_essid); attrp->wa_valid |= DLADM_WLAN_ATTR_ESSID; (void) memcpy(attrp->wa_bssid.wb_bytes, wlp->wl_ess_conf_bssid, DLADM_WLAN_BSSID_LEN); attrp->wa_valid |= DLADM_WLAN_ATTR_BSSID; attrp->wa_secmode = (wlp->wl_ess_conf_wepenabled == WL_ENC_WEP ? DLADM_WLAN_SECMODE_WEP : DLADM_WLAN_SECMODE_NONE); if (wlp->wl_ess_conf_reserved[0] > 0) attrp->wa_secmode = DLADM_WLAN_SECMODE_WPA; attrp->wa_valid |= DLADM_WLAN_ATTR_SECMODE; attrp->wa_bsstype = (wlp->wl_ess_conf_bsstype == WL_BSS_BSS ? DLADM_WLAN_BSSTYPE_BSS : DLADM_WLAN_BSSTYPE_IBSS); attrp->wa_valid |= DLADM_WLAN_ATTR_BSSTYPE; attrp->wa_auth = (wlp->wl_ess_conf_authmode == 0 ? DLADM_WLAN_AUTH_OPEN : DLADM_WLAN_AUTH_SHARED); attrp->wa_valid |= DLADM_WLAN_ATTR_AUTH; attrp->wa_strength = DLADM_WLAN_SIGNAL2STRENGTH(wlp->wl_ess_conf_sl); attrp->wa_valid |= DLADM_WLAN_ATTR_STRENGTH; attrp->wa_mode = do_convert_mode((wl_phy_conf_t *)&wlp->wl_phy_conf); attrp->wa_valid |= DLADM_WLAN_ATTR_MODE; for (i = 0; i < MAX_SCAN_SUPPORT_RATES; i++) { wlp->wl_supported_rates[i] &= IEEE80211_RATE; if (wlp->wl_supported_rates[i] > attrp->wa_speed) attrp->wa_speed = wlp->wl_supported_rates[i]; } if (attrp->wa_speed > 0) attrp->wa_valid |= DLADM_WLAN_ATTR_SPEED; if (i_dladm_wlan_convert_chan((wl_phy_conf_t *)&wlp->wl_phy_conf, &attrp->wa_channel)) attrp->wa_valid |= DLADM_WLAN_ATTR_CHANNEL; } dladm_status_t dladm_wlan_scan(datalink_id_t linkid, void *arg, boolean_t (*func)(void *, dladm_wlan_attr_t *)) { int i; uint32_t count; wl_ess_conf_t *wlp; wldp_t *gbuf = NULL; dladm_wlan_attr_t wlattr; dladm_status_t status; boolean_t connected; if ((status = dladm_wlan_validate(linkid)) != DLADM_STATUS_OK) goto done; if ((gbuf = malloc(MAX_BUF_LEN)) == NULL) { status = DLADM_STATUS_NOMEM; goto done; } if ((status = do_get_linkstatus(linkid, gbuf)) != DLADM_STATUS_OK) goto done; connected = IS_CONNECTED(gbuf); if ((status = do_scan(linkid, gbuf)) != DLADM_STATUS_OK) goto done; if (func == NULL) { status = DLADM_STATUS_OK; goto done; } if ((status = do_get_esslist(linkid, gbuf)) != DLADM_STATUS_OK) goto done; wlp = ((wl_ess_list_t *)gbuf->wldp_buf)->wl_ess_list_ess; count = ((wl_ess_list_t *)(gbuf->wldp_buf))->wl_ess_list_num; for (i = 0; i < count; i++, wlp++) { fill_wlan_attr(wlp, &wlattr); if (!func(arg, &wlattr)) break; } if (!connected) { status = do_get_linkstatus(linkid, gbuf); if (status != DLADM_STATUS_OK) goto done; if (IS_CONNECTED(gbuf)) (void) do_disconnect(linkid, gbuf); } status = DLADM_STATUS_OK; done: free(gbuf); return (status); } /* * Structures used in building the list of eligible WLANs to connect to. * Specifically, `connect_state' has the WLAN attributes that must be matched * (in `cs_attr') and a growing list of WLANs that matched those attributes * chained through `cs_list'. Each element in the list is of type `attr_node' * and has the matching WLAN's attributes and a pointer to the next element. * For convenience, `cs_count' tracks the number of elements in the list. */ typedef struct attr_node { dladm_wlan_attr_t an_attr; struct attr_node *an_next; } attr_node_t; typedef struct connect_state { dladm_wlan_attr_t *cs_attr; uint_t cs_count; attr_node_t *cs_list; } connect_state_t; /* * Compare two sets of WLAN attributes. For now, we only consider strength * and speed (in that order), which matches the documented default policy for * dladm_wlan_connect(). */ static int attr_compare(const void *p1, const void *p2) { dladm_wlan_attr_t *attrp1, *attrp2; attrp1 = (*(dladm_wlan_attr_t **)p1); attrp2 = (*(dladm_wlan_attr_t **)p2); if (attrp1->wa_strength < attrp2->wa_strength) return (1); if (attrp1->wa_strength > attrp2->wa_strength) return (-1); return (attrp2->wa_speed - attrp1->wa_speed); } /* * Callback function used by dladm_wlan_connect() to filter out unwanted * WLANs when scanning for available WLANs. Always returns B_TRUE to * continue the scan. */ static boolean_t connect_cb(void *arg, dladm_wlan_attr_t *attrp) { attr_node_t *nodep; dladm_wlan_attr_t *fattrp; connect_state_t *statep = (connect_state_t *)arg; fattrp = statep->cs_attr; if (fattrp == NULL) goto append; if ((fattrp->wa_valid & attrp->wa_valid) != fattrp->wa_valid) return (B_TRUE); if ((fattrp->wa_valid & DLADM_WLAN_ATTR_ESSID) != 0 && strncmp(fattrp->wa_essid.we_bytes, attrp->wa_essid.we_bytes, DLADM_WLAN_MAX_ESSID_LEN) != 0) return (B_TRUE); if ((fattrp->wa_valid & DLADM_WLAN_ATTR_SECMODE) != 0 && fattrp->wa_secmode != attrp->wa_secmode) return (B_TRUE); if ((fattrp->wa_valid & DLADM_WLAN_ATTR_MODE) != 0 && fattrp->wa_mode != attrp->wa_mode) return (B_TRUE); if ((fattrp->wa_valid & DLADM_WLAN_ATTR_STRENGTH) != 0 && fattrp->wa_strength != attrp->wa_strength) return (B_TRUE); if ((fattrp->wa_valid & DLADM_WLAN_ATTR_SPEED) != 0 && fattrp->wa_speed != attrp->wa_speed) return (B_TRUE); if ((fattrp->wa_valid & DLADM_WLAN_ATTR_AUTH) != 0) { attrp->wa_auth = fattrp->wa_auth; attrp->wa_valid |= DLADM_WLAN_ATTR_AUTH; } if ((fattrp->wa_valid & DLADM_WLAN_ATTR_BSSTYPE) != 0 && fattrp->wa_bsstype != attrp->wa_bsstype) return (B_TRUE); if ((fattrp->wa_valid & DLADM_WLAN_ATTR_BSSID) != 0 && memcmp(fattrp->wa_bssid.wb_bytes, attrp->wa_bssid.wb_bytes, DLADM_WLAN_BSSID_LEN) != 0) return (B_TRUE); append: nodep = malloc(sizeof (attr_node_t)); if (nodep == NULL) return (B_TRUE); (void) memcpy(&nodep->an_attr, attrp, sizeof (dladm_wlan_attr_t)); nodep->an_next = statep->cs_list; statep->cs_list = nodep; statep->cs_count++; return (B_TRUE); } #define IEEE80211_C_WPA 0x01800000 static dladm_status_t do_connect(datalink_id_t linkid, wldp_t *gbuf, dladm_wlan_attr_t *attrp, boolean_t create_ibss, void *keys, uint_t key_count, int timeout) { dladm_wlan_secmode_t secmode; dladm_wlan_auth_t authmode; dladm_wlan_bsstype_t bsstype; dladm_wlan_essid_t essid; boolean_t essid_valid = B_FALSE; dladm_status_t status; dladm_wlan_channel_t channel; hrtime_t start; wl_capability_t *caps; if ((attrp->wa_valid & DLADM_WLAN_ATTR_CHANNEL) != 0) { channel = attrp->wa_channel; status = do_set_channel(linkid, &channel); if (status != DLADM_STATUS_OK) goto fail; } secmode = ((attrp->wa_valid & DLADM_WLAN_ATTR_SECMODE) != 0) ? attrp->wa_secmode : DLADM_WLAN_SECMODE_NONE; if ((status = do_set_encryption(linkid, &secmode)) != DLADM_STATUS_OK) goto fail; authmode = ((attrp->wa_valid & DLADM_WLAN_ATTR_AUTH) != 0) ? attrp->wa_auth : DLADM_WLAN_AUTH_OPEN; if ((status = do_set_authmode(linkid, &authmode)) != DLADM_STATUS_OK) goto fail; bsstype = ((attrp->wa_valid & DLADM_WLAN_ATTR_BSSTYPE) != 0) ? attrp->wa_bsstype : DLADM_WLAN_BSSTYPE_BSS; if ((status = do_set_bsstype(linkid, &bsstype)) != DLADM_STATUS_OK) goto fail; if (secmode == DLADM_WLAN_SECMODE_WEP) { if (keys == NULL || key_count == 0 || key_count > MAX_NWEPKEYS) { status = DLADM_STATUS_BADARG; goto fail; } status = do_set_key(linkid, keys, key_count); if (status != DLADM_STATUS_OK) goto fail; } else if (secmode == DLADM_WLAN_SECMODE_WPA) { if (keys == NULL || key_count == 0 || key_count > MAX_NWEPKEYS) { status = DLADM_STATUS_BADARG; goto fail; } status = do_get_capability(linkid, gbuf); if (status != DLADM_STATUS_OK) goto fail; caps = (wl_capability_t *)(gbuf->wldp_buf); if ((caps->caps & IEEE80211_C_WPA) == 0) return (DLADM_STATUS_NOTSUP); } if (create_ibss) { status = do_set_channel(linkid, &channel); if (status != DLADM_STATUS_OK) goto fail; status = do_set_createibss(linkid, &create_ibss); if (status != DLADM_STATUS_OK) goto fail; if ((attrp->wa_valid & DLADM_WLAN_ATTR_ESSID) == 0) { generate_essid(&essid); essid_valid = B_TRUE; } } if ((attrp->wa_valid & DLADM_WLAN_ATTR_ESSID) != 0) { essid = attrp->wa_essid; essid_valid = B_TRUE; } if (!essid_valid) { status = DLADM_STATUS_FAILED; goto fail; } if ((status = do_set_essid(linkid, &essid)) != DLADM_STATUS_OK) goto fail; /* * Because wpa daemon needs getting essid from driver, * we need call do_set_essid() first, then call wpa_instance_create(). */ if (secmode == DLADM_WLAN_SECMODE_WPA && keys != NULL) (void) wpa_instance_create(linkid, keys); start = gethrtime(); for (;;) { status = do_get_linkstatus(linkid, gbuf); if (status != DLADM_STATUS_OK) goto fail; if (IS_CONNECTED(gbuf)) break; (void) poll(NULL, 0, DLADM_WLAN_CONNECT_POLLRATE); if ((timeout >= 0) && (gethrtime() - start) / NANOSEC >= timeout) { status = DLADM_STATUS_TIMEDOUT; goto fail; } } status = DLADM_STATUS_OK; fail: return (status); } dladm_status_t dladm_wlan_connect(datalink_id_t linkid, dladm_wlan_attr_t *attrp, int timeout, void *keys, uint_t key_count, uint_t flags) { int i; wldp_t *gbuf = NULL; connect_state_t state = {0, NULL, NULL}; attr_node_t *nodep = NULL; boolean_t create_ibss, set_authmode; dladm_wlan_attr_t **wl_list = NULL; dladm_status_t status; if ((status = dladm_wlan_validate(linkid)) != DLADM_STATUS_OK) return (status); if ((gbuf = malloc(MAX_BUF_LEN)) == NULL) return (DLADM_STATUS_NOMEM); if ((status = do_get_linkstatus(linkid, gbuf)) != DLADM_STATUS_OK) goto done; if (IS_CONNECTED(gbuf)) { status = DLADM_STATUS_ISCONN; goto done; } set_authmode = ((attrp != NULL) && (attrp->wa_valid & DLADM_WLAN_ATTR_MODE) != 0); create_ibss = ((flags & DLADM_WLAN_CONNECT_CREATEIBSS) != 0 && attrp != NULL && (attrp->wa_valid & DLADM_WLAN_ATTR_BSSTYPE) != 0 && attrp->wa_bsstype == DLADM_WLAN_BSSTYPE_IBSS); if ((flags & DLADM_WLAN_CONNECT_NOSCAN) != 0 || (create_ibss && attrp != NULL && (attrp->wa_valid & DLADM_WLAN_ATTR_ESSID) == 0)) { status = do_connect(linkid, gbuf, attrp, create_ibss, keys, key_count, timeout); goto done; } state.cs_attr = attrp; state.cs_list = NULL; state.cs_count = 0; status = dladm_wlan_scan(linkid, &state, connect_cb); if (status != DLADM_STATUS_OK) goto done; if (state.cs_count == 0) { if (!create_ibss) { status = DLADM_STATUS_NOTFOUND; goto done; } status = do_connect(linkid, gbuf, attrp, create_ibss, keys, key_count, timeout); goto done; } wl_list = malloc(state.cs_count * sizeof (dladm_wlan_attr_t *)); if (wl_list == NULL) { status = DLADM_STATUS_NOMEM; goto done; } nodep = state.cs_list; for (i = 0; i < state.cs_count; i++) { wl_list[i] = &nodep->an_attr; nodep = nodep->an_next; } qsort(wl_list, state.cs_count, sizeof (dladm_wlan_attr_t *), attr_compare); for (i = 0; i < state.cs_count; i++) { dladm_wlan_attr_t *ap = wl_list[i]; status = do_connect(linkid, gbuf, ap, create_ibss, keys, key_count, timeout); if (status == DLADM_STATUS_OK) break; if (!set_authmode) { ap->wa_auth = DLADM_WLAN_AUTH_SHARED; ap->wa_valid |= DLADM_WLAN_ATTR_AUTH; status = do_connect(linkid, gbuf, ap, create_ibss, keys, key_count, timeout); if (status == DLADM_STATUS_OK) break; } } done: if ((status != DLADM_STATUS_OK) && (status != DLADM_STATUS_ISCONN)) (void) do_disconnect(linkid, gbuf); while (state.cs_list != NULL) { nodep = state.cs_list; state.cs_list = nodep->an_next; free(nodep); } free(gbuf); free(wl_list); return (status); } dladm_status_t dladm_wlan_disconnect(datalink_id_t linkid) { wldp_t *gbuf; dladm_status_t status; if ((status = dladm_wlan_validate(linkid)) != DLADM_STATUS_OK) return (status); if ((gbuf = malloc(MAX_BUF_LEN)) == NULL) { status = DLADM_STATUS_NOMEM; goto done; } if ((status = do_get_linkstatus(linkid, gbuf)) != DLADM_STATUS_OK) goto done; if (!IS_CONNECTED(gbuf)) { status = DLADM_STATUS_NOTCONN; goto done; } if ((status = do_disconnect(linkid, gbuf)) != DLADM_STATUS_OK) goto done; if ((status = do_get_linkstatus(linkid, gbuf)) != DLADM_STATUS_OK) goto done; if (IS_CONNECTED(gbuf)) { status = DLADM_STATUS_FAILED; goto done; } status = DLADM_STATUS_OK; done: free(gbuf); return (status); } dladm_status_t dladm_wlan_get_linkattr(datalink_id_t linkid, dladm_wlan_linkattr_t *attrp) { wldp_t *gbuf = NULL; wl_rssi_t signal; wl_bss_type_t bsstype; wl_authmode_t authmode; wl_encryption_t encryption; wl_rates_t *ratesp; dladm_wlan_attr_t *wl_attrp; dladm_status_t status; if (attrp == NULL) return (DLADM_STATUS_BADARG); if ((status = dladm_wlan_validate(linkid)) != DLADM_STATUS_OK) goto done; if ((gbuf = malloc(MAX_BUF_LEN)) == NULL) { status = DLADM_STATUS_NOMEM; goto done; } (void) memset(attrp, 0, sizeof (*attrp)); wl_attrp = &attrp->la_wlan_attr; if ((status = do_get_linkstatus(linkid, gbuf)) != DLADM_STATUS_OK) goto done; attrp->la_valid |= DLADM_WLAN_LINKATTR_STATUS; if (!IS_CONNECTED(gbuf)) attrp->la_status = DLADM_WLAN_LINK_DISCONNECTED; else attrp->la_status = DLADM_WLAN_LINK_CONNECTED; if ((status = do_get_essid(linkid, gbuf)) != DLADM_STATUS_OK) goto done; (void) strlcpy(wl_attrp->wa_essid.we_bytes, ((wl_essid_t *)(gbuf->wldp_buf))->wl_essid_essid, DLADM_WLAN_MAX_ESSID_LEN); wl_attrp->wa_valid |= DLADM_WLAN_ATTR_ESSID; if ((status = do_get_bssid(linkid, gbuf)) != DLADM_STATUS_OK) goto done; (void) memcpy(wl_attrp->wa_bssid.wb_bytes, gbuf->wldp_buf, DLADM_WLAN_BSSID_LEN); wl_attrp->wa_valid |= DLADM_WLAN_ATTR_BSSID; if (attrp->la_status == DLADM_WLAN_LINK_DISCONNECTED) { attrp->la_valid |= DLADM_WLAN_LINKATTR_WLAN; status = DLADM_STATUS_OK; goto done; } if ((status = do_get_encryption(linkid, gbuf)) != DLADM_STATUS_OK) goto done; encryption = *(wl_encryption_t *)(gbuf->wldp_buf); wl_attrp->wa_valid |= DLADM_WLAN_ATTR_SECMODE; switch (encryption) { case WL_NOENCRYPTION: wl_attrp->wa_secmode = DLADM_WLAN_SECMODE_NONE; break; case WL_ENC_WEP: wl_attrp->wa_secmode = DLADM_WLAN_SECMODE_WEP; break; case WL_ENC_WPA: wl_attrp->wa_secmode = DLADM_WLAN_SECMODE_WPA; break; default: wl_attrp->wa_valid &= ~DLADM_WLAN_ATTR_SECMODE; break; } if ((status = do_get_signal(linkid, gbuf)) != DLADM_STATUS_OK) goto done; signal = *(wl_rssi_t *)(gbuf->wldp_buf); wl_attrp->wa_valid |= DLADM_WLAN_ATTR_STRENGTH; wl_attrp->wa_strength = DLADM_WLAN_SIGNAL2STRENGTH(signal); if ((status = do_get_rate(linkid, gbuf)) != DLADM_STATUS_OK) goto done; ratesp = (wl_rates_t *)(gbuf->wldp_buf); if (ratesp->wl_rates_num > 0) { uint_t i, r = 0; for (i = 0; i < ratesp->wl_rates_num; i++) { if (ratesp->wl_rates_rates[i] > r) r = ratesp->wl_rates_rates[i]; } wl_attrp->wa_speed = r; wl_attrp->wa_valid |= DLADM_WLAN_ATTR_SPEED; } if ((status = do_get_authmode(linkid, gbuf)) != DLADM_STATUS_OK) goto done; authmode = *(wl_authmode_t *)(gbuf->wldp_buf); wl_attrp->wa_valid |= DLADM_WLAN_ATTR_AUTH; switch (authmode) { case WL_OPENSYSTEM: wl_attrp->wa_auth = DLADM_WLAN_AUTH_OPEN; break; case WL_SHAREDKEY: wl_attrp->wa_auth = DLADM_WLAN_AUTH_SHARED; break; default: wl_attrp->wa_valid &= ~DLADM_WLAN_ATTR_AUTH; break; } if ((status = do_get_bsstype(linkid, gbuf)) != DLADM_STATUS_OK) goto done; bsstype = *(wl_bss_type_t *)(gbuf->wldp_buf); wl_attrp->wa_valid |= DLADM_WLAN_ATTR_BSSTYPE; switch (bsstype) { case WL_BSS_BSS: wl_attrp->wa_bsstype = DLADM_WLAN_BSSTYPE_BSS; break; case WL_BSS_IBSS: wl_attrp->wa_bsstype = DLADM_WLAN_BSSTYPE_IBSS; break; case WL_BSS_ANY: wl_attrp->wa_bsstype = DLADM_WLAN_BSSTYPE_ANY; break; default: wl_attrp->wa_valid &= ~DLADM_WLAN_ATTR_BSSTYPE; break; } if ((status = do_get_mode(linkid, gbuf)) != DLADM_STATUS_OK) goto done; wl_attrp->wa_mode = do_convert_mode((wl_phy_conf_t *)(gbuf->wldp_buf)); wl_attrp->wa_valid |= DLADM_WLAN_ATTR_MODE; if (wl_attrp->wa_mode != DLADM_WLAN_MODE_NONE) wl_attrp->wa_valid |= DLADM_WLAN_ATTR_MODE; attrp->la_valid |= DLADM_WLAN_LINKATTR_WLAN; status = DLADM_STATUS_OK; done: free(gbuf); return (status); } static dladm_status_t dladm_wlan_validate(datalink_id_t linkid) { wldp_t *gbuf; dladm_status_t status; if ((gbuf = malloc(MAX_BUF_LEN)) == NULL) { status = DLADM_STATUS_NOMEM; goto done; } /* * Check to see if the link is wireless. */ if ((status = do_get_bsstype(linkid, gbuf)) != DLADM_STATUS_OK) { status = DLADM_STATUS_LINKINVAL; goto done; } done: free(gbuf); return (status); } static boolean_t find_val_by_name(const char *str, val_desc_t *vdp, uint_t cnt, uint_t *valp) { int i; for (i = 0; i < cnt; i++) { if (strcasecmp(str, vdp[i].vd_name) == 0) { *valp = vdp[i].vd_val; return (B_TRUE); } } return (B_FALSE); } static boolean_t find_name_by_val(uint_t val, val_desc_t *vdp, uint_t cnt, char **strp) { int i; for (i = 0; i < cnt; i++) { if (val == vdp[i].vd_val) { *strp = vdp[i].vd_name; return (B_TRUE); } } return (B_FALSE); } const char * dladm_wlan_essid2str(dladm_wlan_essid_t *essid, char *buf) { (void) snprintf(buf, DLADM_STRSIZE, "%s", essid->we_bytes); return (buf); } const char * dladm_wlan_bssid2str(dladm_wlan_bssid_t *bssid, char *buf) { return (_link_ntoa(bssid->wb_bytes, buf, DLADM_WLAN_BSSID_LEN, IFT_OTHER)); } static const char * dladm_wlan_val2str(uint_t val, val_desc_t *vdp, uint_t cnt, char *buf) { char *s; if (!find_name_by_val(val, vdp, cnt, &s)) s = ""; (void) snprintf(buf, DLADM_STRSIZE, "%s", s); return (buf); } const char * dladm_wlan_secmode2str(dladm_wlan_secmode_t *secmode, char *buf) { return (dladm_wlan_val2str((uint_t)*secmode, secmode_vals, VALCNT(secmode_vals), buf)); } const char * dladm_wlan_strength2str(dladm_wlan_strength_t *strength, char *buf) { return (dladm_wlan_val2str((uint_t)*strength, strength_vals, VALCNT(strength_vals), buf)); } const char * dladm_wlan_mode2str(dladm_wlan_mode_t *mode, char *buf) { return (dladm_wlan_val2str((uint_t)*mode, mode_vals, VALCNT(mode_vals), buf)); } const char * dladm_wlan_speed2str(dladm_wlan_speed_t *speed, char *buf) { (void) snprintf(buf, DLADM_STRSIZE, "%.*f", *speed % 2, (float)(*speed) / 2); return (buf); } const char * dladm_wlan_auth2str(dladm_wlan_auth_t *auth, char *buf) { return (dladm_wlan_val2str((uint_t)*auth, auth_vals, VALCNT(auth_vals), buf)); } const char * dladm_wlan_bsstype2str(dladm_wlan_bsstype_t *bsstype, char *buf) { return (dladm_wlan_val2str((uint_t)*bsstype, bsstype_vals, VALCNT(bsstype_vals), buf)); } const char * dladm_wlan_linkstatus2str(dladm_wlan_linkstatus_t *linkstatus, char *buf) { return (dladm_wlan_val2str((uint_t)*linkstatus, linkstatus_vals, VALCNT(linkstatus_vals), buf)); } dladm_status_t dladm_wlan_str2essid(const char *str, dladm_wlan_essid_t *essid) { if (str[0] == '\0') return (DLADM_STATUS_BADARG); (void) strlcpy(essid->we_bytes, str, DLADM_WLAN_MAX_ESSID_LEN); return (DLADM_STATUS_OK); } dladm_status_t dladm_wlan_str2bssid(const char *str, dladm_wlan_bssid_t *bssid) { int len; uchar_t *buf; buf = _link_aton(str, &len); if (buf == NULL) return (DLADM_STATUS_BADARG); if (len != DLADM_WLAN_BSSID_LEN) { free(buf); return (DLADM_STATUS_BADARG); } (void) memcpy(bssid->wb_bytes, buf, len); free(buf); return (DLADM_STATUS_OK); } dladm_status_t dladm_wlan_str2secmode(const char *str, dladm_wlan_secmode_t *secmode) { uint_t val; if (!find_val_by_name(str, secmode_vals, VALCNT(secmode_vals), &val)) return (DLADM_STATUS_BADARG); *secmode = (dladm_wlan_secmode_t)val; return (DLADM_STATUS_OK); } dladm_status_t dladm_wlan_str2strength(const char *str, dladm_wlan_strength_t *strength) { uint_t val; if (!find_val_by_name(str, strength_vals, VALCNT(strength_vals), &val)) return (DLADM_STATUS_BADARG); *strength = (dladm_wlan_strength_t)val; return (DLADM_STATUS_OK); } dladm_status_t dladm_wlan_str2mode(const char *str, dladm_wlan_mode_t *mode) { uint_t val; if (!find_val_by_name(str, mode_vals, VALCNT(mode_vals), &val)) return (DLADM_STATUS_BADARG); *mode = (dladm_wlan_mode_t)val; return (DLADM_STATUS_OK); } dladm_status_t dladm_wlan_str2speed(const char *str, dladm_wlan_speed_t *speed) { *speed = (dladm_wlan_speed_t)(atof(str) * 2); return (DLADM_STATUS_OK); } dladm_status_t dladm_wlan_str2auth(const char *str, dladm_wlan_auth_t *auth) { uint_t val; if (!find_val_by_name(str, auth_vals, VALCNT(auth_vals), &val)) return (DLADM_STATUS_BADARG); *auth = (dladm_wlan_auth_t)val; return (DLADM_STATUS_OK); } dladm_status_t dladm_wlan_str2bsstype(const char *str, dladm_wlan_bsstype_t *bsstype) { uint_t val; if (!find_val_by_name(str, bsstype_vals, VALCNT(bsstype_vals), &val)) return (DLADM_STATUS_BADARG); *bsstype = (dladm_wlan_bsstype_t)val; return (DLADM_STATUS_OK); } dladm_status_t dladm_wlan_str2linkstatus(const char *str, dladm_wlan_linkstatus_t *linkstatus) { uint_t val; if (!find_val_by_name(str, linkstatus_vals, VALCNT(linkstatus_vals), &val)) { return (DLADM_STATUS_BADARG); } *linkstatus = (dladm_wlan_linkstatus_t)val; return (DLADM_STATUS_OK); } dladm_status_t i_dladm_wlan_ioctl(datalink_id_t linkid, wldp_t *gbuf, uint_t id, size_t len, uint_t cmd, size_t cmdlen) { char linkname[MAXPATHLEN]; int fd, rc; struct strioctl stri; uint32_t flags; dladm_status_t status; uint32_t media; char link[MAXLINKNAMELEN]; if ((status = dladm_datalink_id2info(linkid, &flags, NULL, &media, link, MAXLINKNAMELEN)) != DLADM_STATUS_OK) { return (status); } if (media != DL_WIFI) return (DLADM_STATUS_BADARG); if (!(flags & DLADM_OPT_ACTIVE)) return (DLADM_STATUS_TEMPONLY); /* * dlpi_open() is not used here because libdlpi depends on libdladm, * and we do not want to introduce recursive dependencies. */ (void) snprintf(linkname, MAXPATHLEN, "/dev/net/%s", link); if ((fd = open(linkname, O_RDWR)) < 0) return (DLADM_STATUS_LINKINVAL); gbuf->wldp_type = NET_802_11; gbuf->wldp_id = id; gbuf->wldp_length = len; stri.ic_timout = 0; stri.ic_dp = (char *)gbuf; stri.ic_cmd = cmd; stri.ic_len = cmdlen; if ((rc = ioctl(fd, I_STR, &stri)) != 0) { if (rc > 0) { /* * Non-negative return value indicates the specific * operation failed and the reason for the failure * was stored in gbuf->wldp_result. */ status = dladm_wlan_wlresult2status(gbuf); } else { /* * Negative return value indicates the ioctl failed. */ status = dladm_errno2status(errno); } } (void) close(fd); return (status); } dladm_status_t i_dladm_wlan_get_ioctl(datalink_id_t linkid, wldp_t *gbuf, uint_t id) { (void) memset(gbuf, 0, MAX_BUF_LEN); return (i_dladm_wlan_ioctl(linkid, gbuf, id, MAX_BUF_LEN, WLAN_GET_PARAM, MAX_BUF_LEN)); } dladm_status_t i_dladm_wlan_set_ioctl(datalink_id_t linkid, uint_t id, void *buf, uint_t buflen) { wldp_t *gbuf; dladm_status_t status = DLADM_STATUS_OK; if ((gbuf = malloc(MAX_BUF_LEN)) == NULL) return (DLADM_STATUS_NOMEM); (void) memset(gbuf, 0, MAX_BUF_LEN); (void) memcpy(gbuf->wldp_buf, buf, buflen); buflen += WIFI_BUF_OFFSET; status = i_dladm_wlan_ioctl(linkid, gbuf, id, buflen, WLAN_SET_PARAM, buflen); free(gbuf); return (status); } static dladm_status_t do_cmd_ioctl(datalink_id_t linkid, wldp_t *gbuf, uint_t cmd) { (void) memset(gbuf, 0, MAX_BUF_LEN); return (i_dladm_wlan_ioctl(linkid, gbuf, cmd, sizeof (wldp_t), WLAN_COMMAND, sizeof (wldp_t))); } static dladm_status_t do_scan(datalink_id_t linkid, wldp_t *gbuf) { return (do_cmd_ioctl(linkid, gbuf, WL_SCAN)); } static dladm_status_t do_disconnect(datalink_id_t linkid, wldp_t *gbuf) { if (do_get_wpamode(linkid, gbuf) == 0 && ((wl_wpa_t *)(gbuf->wldp_buf))->wpa_flag > 0) (void) wpa_instance_delete(linkid); return (do_cmd_ioctl(linkid, gbuf, WL_DISASSOCIATE)); } static dladm_status_t do_get_esslist(datalink_id_t linkid, wldp_t *gbuf) { (void) memset(gbuf, 0, MAX_BUF_LEN); return (i_dladm_wlan_ioctl(linkid, gbuf, WL_ESS_LIST, MAX_BUF_LEN, WLAN_GET_PARAM, sizeof (wldp_t))); } static dladm_status_t do_get_bssid(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_BSSID)); } static dladm_status_t do_get_essid(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_ESSID)); } static dladm_status_t do_get_bsstype(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_BSS_TYPE)); } static dladm_status_t do_get_linkstatus(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_LINKSTATUS)); } static dladm_status_t do_get_rate(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_DESIRED_RATES)); } static dladm_status_t do_get_authmode(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_AUTH_MODE)); } static dladm_status_t do_get_encryption(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_ENCRYPTION)); } static dladm_status_t do_get_signal(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_RSSI)); } static dladm_status_t do_get_mode(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_PHY_CONFIG)); } static dladm_status_t do_set_bsstype(datalink_id_t linkid, dladm_wlan_bsstype_t *bsstype) { wl_bss_type_t ibsstype; switch (*bsstype) { case DLADM_WLAN_BSSTYPE_BSS: ibsstype = WL_BSS_BSS; break; case DLADM_WLAN_BSSTYPE_IBSS: ibsstype = WL_BSS_IBSS; break; default: ibsstype = WL_BSS_ANY; break; } return (i_dladm_wlan_set_ioctl(linkid, WL_BSS_TYPE, &ibsstype, sizeof (ibsstype))); } static dladm_status_t do_set_authmode(datalink_id_t linkid, dladm_wlan_auth_t *auth) { wl_authmode_t auth_mode; switch (*auth) { case DLADM_WLAN_AUTH_OPEN: auth_mode = WL_OPENSYSTEM; break; case DLADM_WLAN_AUTH_SHARED: auth_mode = WL_SHAREDKEY; break; default: return (DLADM_STATUS_NOTSUP); } return (i_dladm_wlan_set_ioctl(linkid, WL_AUTH_MODE, &auth_mode, sizeof (auth_mode))); } static dladm_status_t do_set_encryption(datalink_id_t linkid, dladm_wlan_secmode_t *secmode) { wl_encryption_t encryption; switch (*secmode) { case DLADM_WLAN_SECMODE_NONE: encryption = WL_NOENCRYPTION; break; case DLADM_WLAN_SECMODE_WEP: encryption = WL_ENC_WEP; break; case DLADM_WLAN_SECMODE_WPA: return (0); default: return (DLADM_STATUS_NOTSUP); } return (i_dladm_wlan_set_ioctl(linkid, WL_ENCRYPTION, &encryption, sizeof (encryption))); } static dladm_status_t do_set_key(datalink_id_t linkid, dladm_wlan_key_t *keys, uint_t key_count) { int i; wl_wep_key_t *wkp; wl_wep_key_tab_t wepkey_tab; dladm_wlan_key_t *kp; if (key_count == 0 || key_count > MAX_NWEPKEYS || keys == NULL) return (DLADM_STATUS_BADARG); (void) memset(wepkey_tab, 0, sizeof (wepkey_tab)); for (i = 0; i < MAX_NWEPKEYS; i++) wepkey_tab[i].wl_wep_operation = WL_NUL; for (i = 0; i < key_count; i++) { kp = &keys[i]; if (kp->wk_idx == 0 || kp->wk_idx > MAX_NWEPKEYS) return (DLADM_STATUS_BADARG); if (kp->wk_len != DLADM_WLAN_WEPKEY64_LEN && kp->wk_len != DLADM_WLAN_WEPKEY128_LEN) return (DLADM_STATUS_BADARG); wkp = &wepkey_tab[kp->wk_idx - 1]; wkp->wl_wep_operation = WL_ADD; wkp->wl_wep_length = kp->wk_len; (void) memcpy(wkp->wl_wep_key, kp->wk_val, kp->wk_len); } return (i_dladm_wlan_set_ioctl(linkid, WL_WEP_KEY_TAB, &wepkey_tab, sizeof (wepkey_tab))); } static dladm_status_t do_set_essid(datalink_id_t linkid, dladm_wlan_essid_t *essid) { wl_essid_t iessid; (void) memset(&iessid, 0, sizeof (essid)); if (essid != NULL && essid->we_bytes[0] != '\0') { iessid.wl_essid_length = strlen(essid->we_bytes); (void) strlcpy(iessid.wl_essid_essid, essid->we_bytes, sizeof (iessid.wl_essid_essid)); } else { return (DLADM_STATUS_BADARG); } return (i_dladm_wlan_set_ioctl(linkid, WL_ESSID, &iessid, sizeof (iessid))); } static dladm_status_t do_set_channel(datalink_id_t linkid, dladm_wlan_channel_t *channel) { wl_phy_conf_t phy_conf; if (*channel > MAX_CHANNEL_NUM) return (DLADM_STATUS_BADVAL); (void) memset(&phy_conf, 0xff, sizeof (phy_conf)); phy_conf.wl_phy_dsss_conf.wl_dsss_channel = *channel; return (i_dladm_wlan_set_ioctl(linkid, WL_PHY_CONFIG, &phy_conf, sizeof (phy_conf))); } static dladm_status_t do_set_createibss(datalink_id_t linkid, boolean_t *create_ibss) { wl_create_ibss_t cr = (wl_create_ibss_t)(*create_ibss); return (i_dladm_wlan_set_ioctl(linkid, WL_CREATE_IBSS, &cr, sizeof (cr))); } static void generate_essid(dladm_wlan_essid_t *essid) { srandom(gethrtime()); (void) snprintf(essid->we_bytes, DLADM_WLAN_MAX_ESSID_LEN, "%d", random()); } static dladm_status_t do_get_capability(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_CAPABILITY)); } static dladm_status_t do_get_wpamode(datalink_id_t linkid, wldp_t *gbuf) { return (i_dladm_wlan_get_ioctl(linkid, gbuf, WL_WPA)); } dladm_status_t dladm_wlan_wpa_get_sr(datalink_id_t linkid, dladm_wlan_ess_t *sr, uint_t escnt, uint_t *estot) { int i, n; wldp_t *gbuf; wl_wpa_ess_t *es; dladm_status_t status; if ((gbuf = malloc(MAX_BUF_LEN)) == NULL) return (DLADM_STATUS_NOMEM); status = i_dladm_wlan_get_ioctl(linkid, gbuf, WL_SCANRESULTS); if (status == DLADM_STATUS_OK) { es = (wl_wpa_ess_t *)(gbuf->wldp_buf); n = (es->count > escnt) ? escnt : es->count; for (i = 0; i < n; i ++) { (void) memcpy(sr[i].we_bssid.wb_bytes, es->ess[i].bssid, DLADM_WLAN_BSSID_LEN); sr[i].we_ssid_len = es->ess[i].ssid_len; (void) memcpy(sr[i].we_ssid.we_bytes, es->ess[i].ssid, es->ess[i].ssid_len); sr[i].we_wpa_ie_len = es->ess[i].wpa_ie_len; (void) memcpy(sr[i].we_wpa_ie, es->ess[i].wpa_ie, es->ess[i].wpa_ie_len); sr[i].we_freq = es->ess[i].freq; } *estot = n; } free(gbuf); return (status); } dladm_status_t dladm_wlan_wpa_set_ie(datalink_id_t linkid, uint8_t *wpa_ie, uint_t wpa_ie_len) { wl_wpa_ie_t *ie; uint_t len; dladm_status_t status; if (wpa_ie_len > DLADM_WLAN_MAX_WPA_IE_LEN) return (DLADM_STATUS_BADARG); len = sizeof (wl_wpa_ie_t) + wpa_ie_len; ie = malloc(len); if (ie == NULL) return (DLADM_STATUS_NOMEM); (void) memset(ie, 0, len); ie->wpa_ie_len = wpa_ie_len; (void) memcpy(ie->wpa_ie, wpa_ie, wpa_ie_len); status = i_dladm_wlan_set_ioctl(linkid, WL_SETOPTIE, ie, len); free(ie); return (status); } dladm_status_t dladm_wlan_wpa_set_wpa(datalink_id_t linkid, boolean_t flag) { wl_wpa_t wpa; wpa.wpa_flag = flag; return (i_dladm_wlan_set_ioctl(linkid, WL_WPA, &wpa, sizeof (wl_wpa_t))); } dladm_status_t dladm_wlan_wpa_del_key(datalink_id_t linkid, uint_t key_idx, const dladm_wlan_bssid_t *addr) { wl_del_key_t wk; wk.idk_keyix = key_idx; if (addr != NULL) (void) memcpy((char *)wk.idk_macaddr, addr->wb_bytes, DLADM_WLAN_BSSID_LEN); return (i_dladm_wlan_set_ioctl(linkid, WL_DELKEY, &wk, sizeof (wl_del_key_t))); } dladm_status_t dladm_wlan_wpa_set_key(datalink_id_t linkid, dladm_wlan_cipher_t cipher, const dladm_wlan_bssid_t *addr, boolean_t set_tx, uint64_t seq, uint_t key_idx, uint8_t *key, uint_t key_len) { wl_key_t wk; (void) memset(&wk, 0, sizeof (wl_key_t)); switch (cipher) { case DLADM_WLAN_CIPHER_WEP: wk.ik_type = IEEE80211_CIPHER_WEP; break; case DLADM_WLAN_CIPHER_TKIP: wk.ik_type = IEEE80211_CIPHER_TKIP; break; case DLADM_WLAN_CIPHER_AES_OCB: wk.ik_type = IEEE80211_CIPHER_AES_OCB; break; case DLADM_WLAN_CIPHER_AES_CCM: wk.ik_type = IEEE80211_CIPHER_AES_CCM; break; case DLADM_WLAN_CIPHER_CKIP: wk.ik_type = IEEE80211_CIPHER_CKIP; break; case DLADM_WLAN_CIPHER_NONE: wk.ik_type = IEEE80211_CIPHER_NONE; break; default: return (DLADM_STATUS_BADARG); } wk.ik_flags = IEEE80211_KEY_RECV; if (set_tx) { wk.ik_flags |= IEEE80211_KEY_XMIT | IEEE80211_KEY_DEFAULT; (void) memcpy(wk.ik_macaddr, addr->wb_bytes, DLADM_WLAN_BSSID_LEN); } else (void) memset(wk.ik_macaddr, 0, DLADM_WLAN_BSSID_LEN); wk.ik_keyix = key_idx; wk.ik_keylen = key_len; (void) memcpy(&wk.ik_keyrsc, &seq, 6); /* only use 48-bit of seq */ (void) memcpy(wk.ik_keydata, key, key_len); return (i_dladm_wlan_set_ioctl(linkid, WL_KEY, &wk, sizeof (wl_key_t))); } dladm_status_t dladm_wlan_wpa_set_mlme(datalink_id_t linkid, dladm_wlan_mlme_op_t op, dladm_wlan_reason_t reason, dladm_wlan_bssid_t *bssid) { wl_mlme_t mlme; (void) memset(&mlme, 0, sizeof (wl_mlme_t)); switch (op) { case DLADM_WLAN_MLME_ASSOC: mlme.im_op = IEEE80211_MLME_ASSOC; break; case DLADM_WLAN_MLME_DISASSOC: mlme.im_op = IEEE80211_MLME_DISASSOC; break; default: return (DLADM_STATUS_BADARG); } mlme.im_reason = reason; if (bssid != NULL) (void) memcpy(mlme.im_macaddr, bssid->wb_bytes, DLADM_WLAN_BSSID_LEN); return (i_dladm_wlan_set_ioctl(linkid, WL_MLME, &mlme, sizeof (wl_mlme_t))); } /* * routines of create instance */ static scf_propertygroup_t * add_property_group_to_instance(scf_handle_t *handle, scf_instance_t *instance, const char *pg_name, const char *pg_type) { scf_propertygroup_t *pg; pg = scf_pg_create(handle); if (pg == NULL) return (NULL); if (scf_instance_add_pg(instance, pg_name, pg_type, 0, pg) != 0) { scf_pg_destroy(pg); return (NULL); } return (pg); } static dladm_status_t add_new_property(scf_handle_t *handle, const char *prop_name, scf_type_t type, const char *val, scf_transaction_t *tx) { scf_value_t *value = NULL; scf_transaction_entry_t *entry = NULL; entry = scf_entry_create(handle); if (entry == NULL) goto out; value = scf_value_create(handle); if (value == NULL) goto out; if (scf_transaction_property_new(tx, entry, prop_name, type) != 0) goto out; if (scf_value_set_from_string(value, type, val) != 0) goto out; if (scf_entry_add_value(entry, value) != 0) goto out; return (DLADM_STATUS_OK); out: if (value != NULL) scf_value_destroy(value); if (entry != NULL) scf_entry_destroy(entry); return (DLADM_STATUS_FAILED); } static dladm_status_t add_pg_method(scf_handle_t *handle, scf_instance_t *instance, const char *pg_name, const char *flags) { int rv, size; dladm_status_t status = DLADM_STATUS_FAILED; char *command = NULL; scf_transaction_t *tran = NULL; scf_propertygroup_t *pg; pg = add_property_group_to_instance(handle, instance, pg_name, SCF_GROUP_METHOD); if (pg == NULL) goto out; tran = scf_transaction_create(handle); if (tran == NULL) goto out; size = strlen(SVC_METHOD) + strlen(" ") + strlen(flags) + 1; command = malloc(size); if (command == NULL) { status = DLADM_STATUS_NOMEM; goto out; } (void) snprintf(command, size, "%s %s", SVC_METHOD, flags); do { if (scf_transaction_start(tran, pg) != 0) goto out; if (add_new_property(handle, SCF_PROPERTY_EXEC, SCF_TYPE_ASTRING, command, tran) != DLADM_STATUS_OK) { goto out; } rv = scf_transaction_commit(tran); switch (rv) { case 1: status = DLADM_STATUS_OK; goto out; case 0: scf_transaction_destroy_children(tran); if (scf_pg_update(pg) == -1) { goto out; } break; case -1: default: goto out; } } while (rv == 0); out: if (tran != NULL) { scf_transaction_destroy_children(tran); scf_transaction_destroy(tran); } if (pg != NULL) scf_pg_destroy(pg); if (command != NULL) free(command); return (status); } static dladm_status_t do_create_instance(scf_handle_t *handle, scf_service_t *svc, const char *instance_name, const char *command) { dladm_status_t status = DLADM_STATUS_FAILED; char *buf; ssize_t max_fmri_len; scf_instance_t *instance; instance = scf_instance_create(handle); if (instance == NULL) goto out; if (scf_service_add_instance(svc, instance_name, instance) != 0) { if (scf_error() == SCF_ERROR_EXISTS) /* Let the caller deal with the duplicate instance */ status = DLADM_STATUS_EXIST; goto out; } if (add_pg_method(handle, instance, "start", command) != DLADM_STATUS_OK) { goto out; } /* enabling the instance */ max_fmri_len = scf_limit(SCF_LIMIT_MAX_FMRI_LENGTH); if ((buf = malloc(max_fmri_len + 1)) == NULL) goto out; if (scf_instance_to_fmri(instance, buf, max_fmri_len + 1) > 0) { if ((smf_disable_instance(buf, 0) != 0) || (smf_enable_instance(buf, SMF_TEMPORARY) != 0)) { goto out; } status = DLADM_STATUS_OK; } out: if (instance != NULL) scf_instance_destroy(instance); return (status); } static dladm_status_t create_instance(const char *instance_name, const char *command) { dladm_status_t status = DLADM_STATUS_FAILED; scf_service_t *svc = NULL; scf_handle_t *handle = NULL; handle = scf_handle_create(SCF_VERSION); if (handle == NULL) goto out; if (scf_handle_bind(handle) == -1) goto out; if ((svc = scf_service_create(handle)) == NULL) goto out; if (scf_handle_decode_fmri(handle, SERVICE_NAME, NULL, svc, NULL, NULL, NULL, SCF_DECODE_FMRI_EXACT) != 0) goto out; status = do_create_instance(handle, svc, instance_name, command); out: if (svc != NULL) scf_service_destroy(svc); if (handle != NULL) { (void) scf_handle_unbind(handle); scf_handle_destroy(handle); } return (status); } /* * routines of delete instance */ #define DEFAULT_TIMEOUT 60000000 #define INIT_WAIT_USECS 50000 static void wait_until_disabled(scf_handle_t *handle, char *fmri) { char *state; useconds_t max; useconds_t usecs; uint64_t *cp = NULL; scf_simple_prop_t *sp = NULL; max = DEFAULT_TIMEOUT; if (((sp = scf_simple_prop_get(handle, fmri, "stop", SCF_PROPERTY_TIMEOUT)) != NULL) && ((cp = scf_simple_prop_next_count(sp)) != NULL) && (*cp != 0)) max = (*cp) * 1000000; /* convert to usecs */ if (sp != NULL) scf_simple_prop_free(sp); for (usecs = INIT_WAIT_USECS; max > 0; max -= usecs) { /* incremental wait */ usecs *= 2; usecs = (usecs > max) ? max : usecs; (void) usleep(usecs); /* Check state after the wait */ if ((state = smf_get_state(fmri)) != NULL) { if (strcmp(state, "disabled") == 0) return; } } } static dladm_status_t delete_instance(const char *instance_name) { dladm_status_t status = DLADM_STATUS_FAILED; char *buf; ssize_t max_fmri_len; scf_scope_t *scope = NULL; scf_service_t *svc = NULL; scf_handle_t *handle = NULL; scf_instance_t *instance; handle = scf_handle_create(SCF_VERSION); if (handle == NULL) goto out; if (scf_handle_bind(handle) == -1) goto out; if ((scope = scf_scope_create(handle)) == NULL) goto out; if ((svc = scf_service_create(handle)) == NULL) goto out; if (scf_handle_get_scope(handle, SCF_SCOPE_LOCAL, scope) == -1) goto out; if (scf_scope_get_service(scope, SERVICE_NAME, svc) < 0) goto out; instance = scf_instance_create(handle); if (instance == NULL) goto out; if (scf_service_get_instance(svc, instance_name, instance) != 0) { scf_error_t scf_errnum = scf_error(); if (scf_errnum == SCF_ERROR_NOT_FOUND) status = DLADM_STATUS_OK; scf_instance_destroy(instance); goto out; } max_fmri_len = scf_limit(SCF_LIMIT_MAX_FMRI_LENGTH); if ((buf = malloc(max_fmri_len + 1)) == NULL) { scf_instance_destroy(instance); goto out; } if (scf_instance_to_fmri(instance, buf, max_fmri_len + 1) > 0) { char *state; state = smf_get_state(buf); if (state && (strcmp(state, SCF_STATE_STRING_ONLINE) == 0 || strcmp(state, SCF_STATE_STRING_DEGRADED) == 0)) { if (smf_disable_instance(buf, 0) == 0) { /* * Wait for some time till timeout to avoid * a race with scf_instance_delete() below. */ wait_until_disabled(handle, buf); } } } if (scf_instance_delete(instance) != 0) { scf_instance_destroy(instance); goto out; } scf_instance_destroy(instance); status = DLADM_STATUS_OK; out: if (svc != NULL) scf_service_destroy(svc); if (scope != NULL) scf_scope_destroy(scope); if (handle != NULL) { (void) scf_handle_unbind(handle); scf_handle_destroy(handle); } return (status); } static dladm_status_t wpa_instance_create(datalink_id_t linkid, void *key) { dladm_status_t status = DLADM_STATUS_FAILED; char *command = NULL; char *wk_name = ((dladm_wlan_key_t *)key)->wk_name; int size; char instance_name[MAXLINKNAMELEN]; /* * Use the link name as the instance name of the network/wpad service. */ status = dladm_datalink_id2info(linkid, NULL, NULL, NULL, instance_name, sizeof (instance_name)); if (status != DLADM_STATUS_OK) goto out; size = strlen(instance_name) + strlen(" -i -k ") + strlen(wk_name) + 1; command = malloc(size); if (command == NULL) { status = DLADM_STATUS_NOMEM; goto out; } (void) snprintf(command, size, "-i %s -k %s", instance_name, wk_name); status = create_instance(instance_name, command); if (status == DLADM_STATUS_EXIST) { /* * Delete the existing instance and create a new instance * with the supplied arguments. */ if ((status = delete_instance(instance_name)) == DLADM_STATUS_OK) { status = create_instance(instance_name, command); } } out: if (command != NULL) free(command); return (status); } static dladm_status_t wpa_instance_delete(datalink_id_t linkid) { char instance_name[MAXLINKNAMELEN]; /* * Get the instance name of the network/wpad service (the same as * the link name). */ if (dladm_datalink_id2info(linkid, NULL, NULL, NULL, instance_name, sizeof (instance_name)) != DLADM_STATUS_OK) return (DLADM_STATUS_FAILED); return (delete_instance(instance_name)); }