/* * hostapd / WPS integration * Copyright (c) 2008-2016, Jouni Malinen * * This software may be distributed under the terms of the BSD license. * See README for more details. */ #include "utils/includes.h" #include "utils/common.h" #include "utils/eloop.h" #include "utils/uuid.h" #include "common/wpa_ctrl.h" #include "common/ieee802_11_defs.h" #include "common/ieee802_11_common.h" #include "eapol_auth/eapol_auth_sm.h" #include "eapol_auth/eapol_auth_sm_i.h" #include "wps/wps.h" #include "wps/wps_defs.h" #include "wps/wps_dev_attr.h" #include "wps/wps_attr_parse.h" #include "hostapd.h" #include "ap_config.h" #include "ap_drv_ops.h" #include "beacon.h" #include "sta_info.h" #include "wps_hostapd.h" #ifdef CONFIG_WPS_UPNP #include "wps/wps_upnp.h" static int hostapd_wps_upnp_init(struct hostapd_data *hapd, struct wps_context *wps); static void hostapd_wps_upnp_deinit(struct hostapd_data *hapd); #endif /* CONFIG_WPS_UPNP */ static int hostapd_wps_probe_req_rx(void *ctx, const u8 *addr, const u8 *da, const u8 *bssid, const u8 *ie, size_t ie_len, int ssi_signal); static void hostapd_wps_ap_pin_timeout(void *eloop_data, void *user_ctx); static void hostapd_wps_nfc_clear(struct wps_context *wps); struct wps_for_each_data { int (*func)(struct hostapd_data *h, void *ctx); void *ctx; struct hostapd_data *calling_hapd; }; static int wps_for_each(struct hostapd_iface *iface, void *ctx) { struct wps_for_each_data *data = ctx; size_t j; if (iface == NULL) return 0; for (j = 0; j < iface->num_bss; j++) { struct hostapd_data *hapd = iface->bss[j]; int ret; if (hapd != data->calling_hapd && (hapd->conf->wps_independent || data->calling_hapd->conf->wps_independent)) continue; ret = data->func(hapd, data->ctx); if (ret) return ret; } return 0; } static int hostapd_wps_for_each(struct hostapd_data *hapd, int (*func)(struct hostapd_data *h, void *ctx), void *ctx) { struct hostapd_iface *iface = hapd->iface; struct wps_for_each_data data; data.func = func; data.ctx = ctx; data.calling_hapd = hapd; if (iface->interfaces == NULL || iface->interfaces->for_each_interface == NULL) return wps_for_each(iface, &data); return iface->interfaces->for_each_interface(iface->interfaces, wps_for_each, &data); } static int hostapd_wps_new_psk_cb(void *ctx, const u8 *mac_addr, const u8 *p2p_dev_addr, const u8 *psk, size_t psk_len) { struct hostapd_data *hapd = ctx; struct hostapd_wpa_psk *p; struct hostapd_ssid *ssid = &hapd->conf->ssid; if (is_zero_ether_addr(p2p_dev_addr)) { wpa_printf(MSG_DEBUG, "Received new WPA/WPA2-PSK from WPS for STA " MACSTR, MAC2STR(mac_addr)); } else { wpa_printf(MSG_DEBUG, "Received new WPA/WPA2-PSK from WPS for STA " MACSTR " P2P Device Addr " MACSTR, MAC2STR(mac_addr), MAC2STR(p2p_dev_addr)); } wpa_hexdump_key(MSG_DEBUG, "Per-device PSK", psk, psk_len); if (psk_len != PMK_LEN) { wpa_printf(MSG_DEBUG, "Unexpected PSK length %lu", (unsigned long) psk_len); return -1; } /* Add the new PSK to runtime PSK list */ p = os_zalloc(sizeof(*p)); if (p == NULL) return -1; os_memcpy(p->addr, mac_addr, ETH_ALEN); os_memcpy(p->p2p_dev_addr, p2p_dev_addr, ETH_ALEN); os_memcpy(p->psk, psk, PMK_LEN); if (hapd->new_psk_cb) { hapd->new_psk_cb(hapd->new_psk_cb_ctx, mac_addr, p2p_dev_addr, psk, psk_len); } p->next = ssid->wpa_psk; ssid->wpa_psk = p; if (ssid->wpa_psk_file) { FILE *f; char hex[PMK_LEN * 2 + 1]; /* Add the new PSK to PSK list file */ f = fopen(ssid->wpa_psk_file, "a"); if (f == NULL) { wpa_printf(MSG_DEBUG, "Failed to add the PSK to " "'%s'", ssid->wpa_psk_file); return -1; } wpa_snprintf_hex(hex, sizeof(hex), psk, psk_len); fprintf(f, MACSTR " %s\n", MAC2STR(mac_addr), hex); fclose(f); } return 0; } static int hostapd_wps_set_ie_cb(void *ctx, struct wpabuf *beacon_ie, struct wpabuf *probe_resp_ie) { struct hostapd_data *hapd = ctx; wpabuf_free(hapd->wps_beacon_ie); hapd->wps_beacon_ie = beacon_ie; wpabuf_free(hapd->wps_probe_resp_ie); hapd->wps_probe_resp_ie = probe_resp_ie; if (hapd->beacon_set_done) ieee802_11_set_beacon(hapd); return hostapd_set_ap_wps_ie(hapd); } static void hostapd_wps_pin_needed_cb(void *ctx, const u8 *uuid_e, const struct wps_device_data *dev) { struct hostapd_data *hapd = ctx; char uuid[40], txt[400]; int len; char devtype[WPS_DEV_TYPE_BUFSIZE]; if (uuid_bin2str(uuid_e, uuid, sizeof(uuid))) return; wpa_printf(MSG_DEBUG, "WPS: PIN needed for E-UUID %s", uuid); len = os_snprintf(txt, sizeof(txt), WPS_EVENT_PIN_NEEDED "%s " MACSTR " [%s|%s|%s|%s|%s|%s]", uuid, MAC2STR(dev->mac_addr), dev->device_name, dev->manufacturer, dev->model_name, dev->model_number, dev->serial_number, wps_dev_type_bin2str(dev->pri_dev_type, devtype, sizeof(devtype))); if (!os_snprintf_error(sizeof(txt), len)) wpa_msg(hapd->msg_ctx, MSG_INFO, "%s", txt); if (hapd->conf->wps_pin_requests) { FILE *f; struct os_time t; f = fopen(hapd->conf->wps_pin_requests, "a"); if (f == NULL) return; os_get_time(&t); fprintf(f, "%ld\t%s\t" MACSTR "\t%s\t%s\t%s\t%s\t%s" "\t%s\n", t.sec, uuid, MAC2STR(dev->mac_addr), dev->device_name, dev->manufacturer, dev->model_name, dev->model_number, dev->serial_number, wps_dev_type_bin2str(dev->pri_dev_type, devtype, sizeof(devtype))); fclose(f); } } struct wps_stop_reg_data { struct hostapd_data *current_hapd; const u8 *uuid_e; const u8 *dev_pw; size_t dev_pw_len; }; static int wps_stop_registrar(struct hostapd_data *hapd, void *ctx) { struct wps_stop_reg_data *data = ctx; if (hapd != data->current_hapd && hapd->wps != NULL) wps_registrar_complete(hapd->wps->registrar, data->uuid_e, data->dev_pw, data->dev_pw_len); return 0; } static void hostapd_wps_reg_success_cb(void *ctx, const u8 *mac_addr, const u8 *uuid_e, const u8 *dev_pw, size_t dev_pw_len) { struct hostapd_data *hapd = ctx; char uuid[40]; struct wps_stop_reg_data data; if (uuid_bin2str(uuid_e, uuid, sizeof(uuid))) return; wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_REG_SUCCESS MACSTR " %s", MAC2STR(mac_addr), uuid); if (hapd->wps_reg_success_cb) hapd->wps_reg_success_cb(hapd->wps_reg_success_cb_ctx, mac_addr, uuid_e); data.current_hapd = hapd; data.uuid_e = uuid_e; data.dev_pw = dev_pw; data.dev_pw_len = dev_pw_len; hostapd_wps_for_each(hapd, wps_stop_registrar, &data); } static void hostapd_wps_enrollee_seen_cb(void *ctx, const u8 *addr, const u8 *uuid_e, const u8 *pri_dev_type, u16 config_methods, u16 dev_password_id, u8 request_type, const char *dev_name) { struct hostapd_data *hapd = ctx; char uuid[40]; char devtype[WPS_DEV_TYPE_BUFSIZE]; if (uuid_bin2str(uuid_e, uuid, sizeof(uuid))) return; if (dev_name == NULL) dev_name = ""; wpa_msg_ctrl(hapd->msg_ctx, MSG_INFO, WPS_EVENT_ENROLLEE_SEEN MACSTR " %s %s 0x%x %u %u [%s]", MAC2STR(addr), uuid, wps_dev_type_bin2str(pri_dev_type, devtype, sizeof(devtype)), config_methods, dev_password_id, request_type, dev_name); } static void wps_reload_config(void *eloop_data, void *user_ctx) { struct hostapd_iface *iface = eloop_data; wpa_printf(MSG_DEBUG, "WPS: Reload configuration data"); if (iface->interfaces == NULL || iface->interfaces->reload_config(iface) < 0) { wpa_printf(MSG_WARNING, "WPS: Failed to reload the updated " "configuration"); } } void hostapd_wps_eap_completed(struct hostapd_data *hapd) { /* * Reduce race condition of the station trying to reconnect immediately * after AP reconfiguration through WPS by rescheduling the reload * timeout to happen after EAP completion rather than the originally * scheduled 100 ms after new configuration became known. */ if (eloop_deplete_timeout(0, 0, wps_reload_config, hapd->iface, NULL) == 1) wpa_printf(MSG_DEBUG, "WPS: Reschedule immediate configuration reload"); } static void hapd_new_ap_event(struct hostapd_data *hapd, const u8 *attr, size_t attr_len) { size_t blen = attr_len * 2 + 1; char *buf = os_malloc(blen); if (buf) { wpa_snprintf_hex(buf, blen, attr, attr_len); wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_NEW_AP_SETTINGS "%s", buf); os_free(buf); } } static int hapd_wps_reconfig_in_memory(struct hostapd_data *hapd, const struct wps_credential *cred) { struct hostapd_bss_config *bss = hapd->conf; wpa_printf(MSG_DEBUG, "WPS: Updating in-memory configuration"); bss->wps_state = 2; if (cred->ssid_len <= SSID_MAX_LEN) { os_memcpy(bss->ssid.ssid, cred->ssid, cred->ssid_len); bss->ssid.ssid_len = cred->ssid_len; bss->ssid.ssid_set = 1; } if ((cred->auth_type & (WPS_AUTH_WPA2 | WPS_AUTH_WPA2PSK)) && (cred->auth_type & (WPS_AUTH_WPA | WPS_AUTH_WPAPSK))) bss->wpa = 3; else if (cred->auth_type & (WPS_AUTH_WPA2 | WPS_AUTH_WPA2PSK)) bss->wpa = 2; else if (cred->auth_type & (WPS_AUTH_WPA | WPS_AUTH_WPAPSK)) bss->wpa = 1; else bss->wpa = 0; if (bss->wpa) { if (cred->auth_type & (WPS_AUTH_WPA2 | WPS_AUTH_WPA)) bss->wpa_key_mgmt = WPA_KEY_MGMT_IEEE8021X; if (cred->auth_type & (WPS_AUTH_WPA2PSK | WPS_AUTH_WPAPSK)) bss->wpa_key_mgmt = WPA_KEY_MGMT_PSK; bss->wpa_pairwise = 0; if (cred->encr_type & WPS_ENCR_AES) { if (hapd->iconf->hw_mode == HOSTAPD_MODE_IEEE80211AD) bss->wpa_pairwise |= WPA_CIPHER_GCMP; else bss->wpa_pairwise |= WPA_CIPHER_CCMP; } if (cred->encr_type & WPS_ENCR_TKIP) bss->wpa_pairwise |= WPA_CIPHER_TKIP; bss->rsn_pairwise = bss->wpa_pairwise; bss->wpa_group = wpa_select_ap_group_cipher(bss->wpa, bss->wpa_pairwise, bss->rsn_pairwise); if (cred->key_len >= 8 && cred->key_len < 64) { os_free(bss->ssid.wpa_passphrase); bss->ssid.wpa_passphrase = os_zalloc(cred->key_len + 1); if (bss->ssid.wpa_passphrase) os_memcpy(bss->ssid.wpa_passphrase, cred->key, cred->key_len); hostapd_config_clear_wpa_psk(&bss->ssid.wpa_psk); } else if (cred->key_len == 64) { hostapd_config_clear_wpa_psk(&bss->ssid.wpa_psk); bss->ssid.wpa_psk = os_zalloc(sizeof(struct hostapd_wpa_psk)); if (bss->ssid.wpa_psk && hexstr2bin((const char *) cred->key, bss->ssid.wpa_psk->psk, PMK_LEN) == 0) { bss->ssid.wpa_psk->group = 1; os_free(bss->ssid.wpa_passphrase); bss->ssid.wpa_passphrase = NULL; } } bss->auth_algs = 1; } else { /* * WPS 2.0 does not allow WEP to be configured, so no need to * process that option here either. */ bss->auth_algs = 1; } /* Schedule configuration reload after short period of time to allow * EAP-WSC to be finished. */ eloop_register_timeout(0, 100000, wps_reload_config, hapd->iface, NULL); return 0; } static int hapd_wps_cred_cb(struct hostapd_data *hapd, void *ctx) { const struct wps_credential *cred = ctx; FILE *oconf, *nconf; size_t len, i; char *tmp_fname; char buf[1024]; int multi_bss; int wpa; if (hapd->wps == NULL) return 0; wpa_hexdump_key(MSG_DEBUG, "WPS: Received Credential attribute", cred->cred_attr, cred->cred_attr_len); wpa_printf(MSG_DEBUG, "WPS: Received new AP Settings"); wpa_hexdump_ascii(MSG_DEBUG, "WPS: SSID", cred->ssid, cred->ssid_len); wpa_printf(MSG_DEBUG, "WPS: Authentication Type 0x%x", cred->auth_type); wpa_printf(MSG_DEBUG, "WPS: Encryption Type 0x%x", cred->encr_type); wpa_printf(MSG_DEBUG, "WPS: Network Key Index %d", cred->key_idx); wpa_hexdump_key(MSG_DEBUG, "WPS: Network Key", cred->key, cred->key_len); wpa_printf(MSG_DEBUG, "WPS: MAC Address " MACSTR, MAC2STR(cred->mac_addr)); if ((hapd->conf->wps_cred_processing == 1 || hapd->conf->wps_cred_processing == 2) && cred->cred_attr) { hapd_new_ap_event(hapd, cred->cred_attr, cred->cred_attr_len); } else if (hapd->conf->wps_cred_processing == 1 || hapd->conf->wps_cred_processing == 2) { struct wpabuf *attr; attr = wpabuf_alloc(200); if (attr && wps_build_credential_wrap(attr, cred) == 0) hapd_new_ap_event(hapd, wpabuf_head_u8(attr), wpabuf_len(attr)); wpabuf_free(attr); } else wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_NEW_AP_SETTINGS); if (hapd->conf->wps_cred_processing == 1) return 0; os_memcpy(hapd->wps->ssid, cred->ssid, cred->ssid_len); hapd->wps->ssid_len = cred->ssid_len; hapd->wps->encr_types = cred->encr_type; hapd->wps->encr_types_rsn = cred->encr_type; hapd->wps->encr_types_wpa = cred->encr_type; hapd->wps->auth_types = cred->auth_type; hapd->wps->ap_encr_type = cred->encr_type; hapd->wps->ap_auth_type = cred->auth_type; if (cred->key_len == 0) { os_free(hapd->wps->network_key); hapd->wps->network_key = NULL; hapd->wps->network_key_len = 0; } else if ((cred->auth_type & (WPS_AUTH_WPA2PSK | WPS_AUTH_WPAPSK)) && (cred->key_len < 8 || cred->key_len > 2 * PMK_LEN)) { wpa_printf(MSG_INFO, "WPS: Invalid key length %lu for WPA/WPA2", (unsigned long) cred->key_len); return -1; } else { if (hapd->wps->network_key == NULL || hapd->wps->network_key_len < cred->key_len) { hapd->wps->network_key_len = 0; os_free(hapd->wps->network_key); hapd->wps->network_key = os_malloc(cred->key_len); if (hapd->wps->network_key == NULL) return -1; } hapd->wps->network_key_len = cred->key_len; os_memcpy(hapd->wps->network_key, cred->key, cred->key_len); } hapd->wps->wps_state = WPS_STATE_CONFIGURED; if (hapd->iface->config_fname == NULL) return hapd_wps_reconfig_in_memory(hapd, cred); len = os_strlen(hapd->iface->config_fname) + 5; tmp_fname = os_malloc(len); if (tmp_fname == NULL) return -1; os_snprintf(tmp_fname, len, "%s-new", hapd->iface->config_fname); oconf = fopen(hapd->iface->config_fname, "r"); if (oconf == NULL) { wpa_printf(MSG_WARNING, "WPS: Could not open current " "configuration file"); os_free(tmp_fname); return -1; } nconf = fopen(tmp_fname, "w"); if (nconf == NULL) { wpa_printf(MSG_WARNING, "WPS: Could not write updated " "configuration file"); os_free(tmp_fname); fclose(oconf); return -1; } fprintf(nconf, "# WPS configuration - START\n"); fprintf(nconf, "wps_state=2\n"); if (is_hex(cred->ssid, cred->ssid_len)) { fprintf(nconf, "ssid2="); for (i = 0; i < cred->ssid_len; i++) fprintf(nconf, "%02x", cred->ssid[i]); fprintf(nconf, "\n"); } else { fprintf(nconf, "ssid="); for (i = 0; i < cred->ssid_len; i++) fputc(cred->ssid[i], nconf); fprintf(nconf, "\n"); } if ((cred->auth_type & (WPS_AUTH_WPA2 | WPS_AUTH_WPA2PSK)) && (cred->auth_type & (WPS_AUTH_WPA | WPS_AUTH_WPAPSK))) wpa = 3; else if (cred->auth_type & (WPS_AUTH_WPA2 | WPS_AUTH_WPA2PSK)) wpa = 2; else if (cred->auth_type & (WPS_AUTH_WPA | WPS_AUTH_WPAPSK)) wpa = 1; else wpa = 0; if (wpa) { char *prefix; fprintf(nconf, "wpa=%d\n", wpa); fprintf(nconf, "wpa_key_mgmt="); prefix = ""; if (cred->auth_type & (WPS_AUTH_WPA2 | WPS_AUTH_WPA)) { fprintf(nconf, "WPA-EAP"); prefix = " "; } if (cred->auth_type & (WPS_AUTH_WPA2PSK | WPS_AUTH_WPAPSK)) fprintf(nconf, "%sWPA-PSK", prefix); fprintf(nconf, "\n"); fprintf(nconf, "wpa_pairwise="); prefix = ""; if (cred->encr_type & WPS_ENCR_AES) { if (hapd->iconf->hw_mode == HOSTAPD_MODE_IEEE80211AD) fprintf(nconf, "GCMP"); else fprintf(nconf, "CCMP"); prefix = " "; } if (cred->encr_type & WPS_ENCR_TKIP) { fprintf(nconf, "%sTKIP", prefix); } fprintf(nconf, "\n"); if (cred->key_len >= 8 && cred->key_len < 64) { fprintf(nconf, "wpa_passphrase="); for (i = 0; i < cred->key_len; i++) fputc(cred->key[i], nconf); fprintf(nconf, "\n"); } else if (cred->key_len == 64) { fprintf(nconf, "wpa_psk="); for (i = 0; i < cred->key_len; i++) fputc(cred->key[i], nconf); fprintf(nconf, "\n"); } else { wpa_printf(MSG_WARNING, "WPS: Invalid key length %lu " "for WPA/WPA2", (unsigned long) cred->key_len); } fprintf(nconf, "auth_algs=1\n"); } else { /* * WPS 2.0 does not allow WEP to be configured, so no need to * process that option here either. */ fprintf(nconf, "auth_algs=1\n"); } fprintf(nconf, "# WPS configuration - END\n"); multi_bss = 0; while (fgets(buf, sizeof(buf), oconf)) { if (os_strncmp(buf, "bss=", 4) == 0) multi_bss = 1; if (!multi_bss && (str_starts(buf, "ssid=") || str_starts(buf, "ssid2=") || str_starts(buf, "auth_algs=") || str_starts(buf, "wep_default_key=") || str_starts(buf, "wep_key") || str_starts(buf, "wps_state=") || str_starts(buf, "wpa=") || str_starts(buf, "wpa_psk=") || str_starts(buf, "wpa_pairwise=") || str_starts(buf, "rsn_pairwise=") || str_starts(buf, "wpa_key_mgmt=") || str_starts(buf, "wpa_passphrase="))) { fprintf(nconf, "#WPS# %s", buf); } else fprintf(nconf, "%s", buf); } fclose(nconf); fclose(oconf); if (rename(tmp_fname, hapd->iface->config_fname) < 0) { wpa_printf(MSG_WARNING, "WPS: Failed to rename the updated " "configuration file: %s", strerror(errno)); os_free(tmp_fname); return -1; } os_free(tmp_fname); /* Schedule configuration reload after short period of time to allow * EAP-WSC to be finished. */ eloop_register_timeout(0, 100000, wps_reload_config, hapd->iface, NULL); wpa_printf(MSG_DEBUG, "WPS: AP configuration updated"); return 0; } static int hostapd_wps_cred_cb(void *ctx, const struct wps_credential *cred) { struct hostapd_data *hapd = ctx; return hostapd_wps_for_each(hapd, hapd_wps_cred_cb, (void *) cred); } static void hostapd_wps_reenable_ap_pin(void *eloop_data, void *user_ctx) { struct hostapd_data *hapd = eloop_data; if (hapd->conf->ap_setup_locked) return; if (hapd->ap_pin_failures_consecutive >= 10) return; wpa_printf(MSG_DEBUG, "WPS: Re-enable AP PIN"); wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_AP_SETUP_UNLOCKED); hapd->wps->ap_setup_locked = 0; wps_registrar_update_ie(hapd->wps->registrar); } static int wps_pwd_auth_fail(struct hostapd_data *hapd, void *ctx) { struct wps_event_pwd_auth_fail *data = ctx; if (!data->enrollee || hapd->conf->ap_pin == NULL || hapd->wps == NULL) return 0; /* * Registrar failed to prove its knowledge of the AP PIN. Lock AP setup * for some time if this happens multiple times to slow down brute * force attacks. */ hapd->ap_pin_failures++; hapd->ap_pin_failures_consecutive++; wpa_printf(MSG_DEBUG, "WPS: AP PIN authentication failure number %u " "(%u consecutive)", hapd->ap_pin_failures, hapd->ap_pin_failures_consecutive); if (hapd->ap_pin_failures < 3) return 0; wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_AP_SETUP_LOCKED); hapd->wps->ap_setup_locked = 1; wps_registrar_update_ie(hapd->wps->registrar); if (!hapd->conf->ap_setup_locked && hapd->ap_pin_failures_consecutive >= 10) { /* * In indefinite lockdown - disable automatic AP PIN * reenablement. */ eloop_cancel_timeout(hostapd_wps_reenable_ap_pin, hapd, NULL); wpa_printf(MSG_DEBUG, "WPS: AP PIN disabled indefinitely"); } else if (!hapd->conf->ap_setup_locked) { if (hapd->ap_pin_lockout_time == 0) hapd->ap_pin_lockout_time = 60; else if (hapd->ap_pin_lockout_time < 365 * 24 * 60 * 60 && (hapd->ap_pin_failures % 3) == 0) hapd->ap_pin_lockout_time *= 2; wpa_printf(MSG_DEBUG, "WPS: Disable AP PIN for %u seconds", hapd->ap_pin_lockout_time); eloop_cancel_timeout(hostapd_wps_reenable_ap_pin, hapd, NULL); eloop_register_timeout(hapd->ap_pin_lockout_time, 0, hostapd_wps_reenable_ap_pin, hapd, NULL); } return 0; } static void hostapd_pwd_auth_fail(struct hostapd_data *hapd, struct wps_event_pwd_auth_fail *data) { /* Update WPS Status - Authentication Failure */ wpa_printf(MSG_DEBUG, "WPS: Authentication failure update"); hapd->wps_stats.status = WPS_STATUS_FAILURE; hapd->wps_stats.failure_reason = WPS_EI_AUTH_FAILURE; os_memcpy(hapd->wps_stats.peer_addr, data->peer_macaddr, ETH_ALEN); hostapd_wps_for_each(hapd, wps_pwd_auth_fail, data); } static int wps_ap_pin_success(struct hostapd_data *hapd, void *ctx) { if (hapd->conf->ap_pin == NULL || hapd->wps == NULL) return 0; if (hapd->ap_pin_failures_consecutive == 0) return 0; wpa_printf(MSG_DEBUG, "WPS: Clear consecutive AP PIN failure counter " "- total validation failures %u (%u consecutive)", hapd->ap_pin_failures, hapd->ap_pin_failures_consecutive); hapd->ap_pin_failures_consecutive = 0; return 0; } static void hostapd_wps_ap_pin_success(struct hostapd_data *hapd) { hostapd_wps_for_each(hapd, wps_ap_pin_success, NULL); } static void hostapd_wps_event_pbc_overlap(struct hostapd_data *hapd) { /* Update WPS Status - PBC Overlap */ hapd->wps_stats.pbc_status = WPS_PBC_STATUS_OVERLAP; } static void hostapd_wps_event_pbc_timeout(struct hostapd_data *hapd) { /* Update WPS PBC Status:PBC Timeout */ hapd->wps_stats.pbc_status = WPS_PBC_STATUS_TIMEOUT; } static void hostapd_wps_event_pbc_active(struct hostapd_data *hapd) { /* Update WPS PBC status - Active */ hapd->wps_stats.pbc_status = WPS_PBC_STATUS_ACTIVE; } static void hostapd_wps_event_pbc_disable(struct hostapd_data *hapd) { /* Update WPS PBC status - Active */ hapd->wps_stats.pbc_status = WPS_PBC_STATUS_DISABLE; } static void hostapd_wps_event_success(struct hostapd_data *hapd, struct wps_event_success *success) { /* Update WPS status - Success */ hapd->wps_stats.pbc_status = WPS_PBC_STATUS_DISABLE; hapd->wps_stats.status = WPS_STATUS_SUCCESS; os_memcpy(hapd->wps_stats.peer_addr, success->peer_macaddr, ETH_ALEN); } static void hostapd_wps_event_fail(struct hostapd_data *hapd, struct wps_event_fail *fail) { /* Update WPS status - Failure */ hapd->wps_stats.status = WPS_STATUS_FAILURE; os_memcpy(hapd->wps_stats.peer_addr, fail->peer_macaddr, ETH_ALEN); hapd->wps_stats.failure_reason = fail->error_indication; if (fail->error_indication > 0 && fail->error_indication < NUM_WPS_EI_VALUES) { wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_FAIL "msg=%d config_error=%d reason=%d (%s)", fail->msg, fail->config_error, fail->error_indication, wps_ei_str(fail->error_indication)); } else { wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_FAIL "msg=%d config_error=%d", fail->msg, fail->config_error); } } static void hostapd_wps_event_cb(void *ctx, enum wps_event event, union wps_event_data *data) { struct hostapd_data *hapd = ctx; switch (event) { case WPS_EV_M2D: wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_M2D); break; case WPS_EV_FAIL: hostapd_wps_event_fail(hapd, &data->fail); break; case WPS_EV_SUCCESS: hostapd_wps_event_success(hapd, &data->success); wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_SUCCESS); break; case WPS_EV_PWD_AUTH_FAIL: hostapd_pwd_auth_fail(hapd, &data->pwd_auth_fail); break; case WPS_EV_PBC_OVERLAP: hostapd_wps_event_pbc_overlap(hapd); wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_OVERLAP); break; case WPS_EV_PBC_TIMEOUT: hostapd_wps_event_pbc_timeout(hapd); wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_TIMEOUT); break; case WPS_EV_PBC_ACTIVE: hostapd_wps_event_pbc_active(hapd); wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_ACTIVE); break; case WPS_EV_PBC_DISABLE: hostapd_wps_event_pbc_disable(hapd); wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_DISABLE); break; case WPS_EV_ER_AP_ADD: break; case WPS_EV_ER_AP_REMOVE: break; case WPS_EV_ER_ENROLLEE_ADD: break; case WPS_EV_ER_ENROLLEE_REMOVE: break; case WPS_EV_ER_AP_SETTINGS: break; case WPS_EV_ER_SET_SELECTED_REGISTRAR: break; case WPS_EV_AP_PIN_SUCCESS: hostapd_wps_ap_pin_success(hapd); break; } if (hapd->wps_event_cb) hapd->wps_event_cb(hapd->wps_event_cb_ctx, event, data); } static int hostapd_wps_rf_band_cb(void *ctx) { struct hostapd_data *hapd = ctx; return hapd->iconf->hw_mode == HOSTAPD_MODE_IEEE80211A ? WPS_RF_50GHZ : hapd->iconf->hw_mode == HOSTAPD_MODE_IEEE80211AD ? WPS_RF_60GHZ : WPS_RF_24GHZ; /* FIX: dualband AP */ } static void hostapd_wps_clear_ies(struct hostapd_data *hapd, int deinit_only) { wpabuf_free(hapd->wps_beacon_ie); hapd->wps_beacon_ie = NULL; wpabuf_free(hapd->wps_probe_resp_ie); hapd->wps_probe_resp_ie = NULL; if (deinit_only) { if (hapd->drv_priv) hostapd_reset_ap_wps_ie(hapd); return; } hostapd_set_ap_wps_ie(hapd); } static int get_uuid_cb(struct hostapd_iface *iface, void *ctx) { const u8 **uuid = ctx; size_t j; if (iface == NULL) return 0; for (j = 0; j < iface->num_bss; j++) { struct hostapd_data *hapd = iface->bss[j]; if (hapd->wps && !hapd->conf->wps_independent && !is_nil_uuid(hapd->wps->uuid)) { *uuid = hapd->wps->uuid; return 1; } } return 0; } static const u8 * get_own_uuid(struct hostapd_iface *iface) { const u8 *uuid; if (iface->interfaces == NULL || iface->interfaces->for_each_interface == NULL) return NULL; uuid = NULL; iface->interfaces->for_each_interface(iface->interfaces, get_uuid_cb, &uuid); return uuid; } static int count_interface_cb(struct hostapd_iface *iface, void *ctx) { int *count= ctx; (*count)++; return 0; } static int interface_count(struct hostapd_iface *iface) { int count = 0; if (iface->interfaces == NULL || iface->interfaces->for_each_interface == NULL) return 0; iface->interfaces->for_each_interface(iface->interfaces, count_interface_cb, &count); return count; } static int hostapd_wps_set_vendor_ext(struct hostapd_data *hapd, struct wps_context *wps) { int i; for (i = 0; i < MAX_WPS_VENDOR_EXTENSIONS; i++) { wpabuf_free(wps->dev.vendor_ext[i]); wps->dev.vendor_ext[i] = NULL; if (hapd->conf->wps_vendor_ext[i] == NULL) continue; wps->dev.vendor_ext[i] = wpabuf_dup(hapd->conf->wps_vendor_ext[i]); if (wps->dev.vendor_ext[i] == NULL) { while (--i >= 0) wpabuf_free(wps->dev.vendor_ext[i]); return -1; } } return 0; } static void hostapd_free_wps(struct wps_context *wps) { int i; for (i = 0; i < MAX_WPS_VENDOR_EXTENSIONS; i++) wpabuf_free(wps->dev.vendor_ext[i]); wps_device_data_free(&wps->dev); os_free(wps->network_key); hostapd_wps_nfc_clear(wps); wpabuf_free(wps->dh_pubkey); wpabuf_free(wps->dh_privkey); os_free(wps); } int hostapd_init_wps(struct hostapd_data *hapd, struct hostapd_bss_config *conf) { struct wps_context *wps; struct wps_registrar_config cfg; if (conf->wps_state == 0) { hostapd_wps_clear_ies(hapd, 0); return 0; } wps = os_zalloc(sizeof(*wps)); if (wps == NULL) return -1; wps->cred_cb = hostapd_wps_cred_cb; wps->event_cb = hostapd_wps_event_cb; wps->rf_band_cb = hostapd_wps_rf_band_cb; wps->cb_ctx = hapd; os_memset(&cfg, 0, sizeof(cfg)); wps->wps_state = hapd->conf->wps_state; wps->ap_setup_locked = hapd->conf->ap_setup_locked; if (is_nil_uuid(hapd->conf->uuid)) { const u8 *uuid; uuid = get_own_uuid(hapd->iface); if (uuid && !conf->wps_independent) { os_memcpy(wps->uuid, uuid, UUID_LEN); wpa_hexdump(MSG_DEBUG, "WPS: Clone UUID from another " "interface", wps->uuid, UUID_LEN); } else { uuid_gen_mac_addr(hapd->own_addr, wps->uuid); wpa_hexdump(MSG_DEBUG, "WPS: UUID based on MAC " "address", wps->uuid, UUID_LEN); } } else { os_memcpy(wps->uuid, hapd->conf->uuid, UUID_LEN); wpa_hexdump(MSG_DEBUG, "WPS: Use configured UUID", wps->uuid, UUID_LEN); } wps->ssid_len = hapd->conf->ssid.ssid_len; os_memcpy(wps->ssid, hapd->conf->ssid.ssid, wps->ssid_len); wps->ap = 1; os_memcpy(wps->dev.mac_addr, hapd->own_addr, ETH_ALEN); wps->dev.device_name = hapd->conf->device_name ? os_strdup(hapd->conf->device_name) : NULL; wps->dev.manufacturer = hapd->conf->manufacturer ? os_strdup(hapd->conf->manufacturer) : NULL; wps->dev.model_name = hapd->conf->model_name ? os_strdup(hapd->conf->model_name) : NULL; wps->dev.model_number = hapd->conf->model_number ? os_strdup(hapd->conf->model_number) : NULL; wps->dev.serial_number = hapd->conf->serial_number ? os_strdup(hapd->conf->serial_number) : NULL; wps->config_methods = wps_config_methods_str2bin(hapd->conf->config_methods); if ((wps->config_methods & (WPS_CONFIG_DISPLAY | WPS_CONFIG_VIRT_DISPLAY | WPS_CONFIG_PHY_DISPLAY)) == WPS_CONFIG_DISPLAY) { wpa_printf(MSG_INFO, "WPS: Converting display to " "virtual_display for WPS 2.0 compliance"); wps->config_methods |= WPS_CONFIG_VIRT_DISPLAY; } if ((wps->config_methods & (WPS_CONFIG_PUSHBUTTON | WPS_CONFIG_VIRT_PUSHBUTTON | WPS_CONFIG_PHY_PUSHBUTTON)) == WPS_CONFIG_PUSHBUTTON) { wpa_printf(MSG_INFO, "WPS: Converting push_button to " "virtual_push_button for WPS 2.0 compliance"); wps->config_methods |= WPS_CONFIG_VIRT_PUSHBUTTON; } os_memcpy(wps->dev.pri_dev_type, hapd->conf->device_type, WPS_DEV_TYPE_LEN); if (hostapd_wps_set_vendor_ext(hapd, wps) < 0) goto fail; wps->dev.os_version = WPA_GET_BE32(hapd->conf->os_version); if (conf->wps_rf_bands) { wps->dev.rf_bands = conf->wps_rf_bands; } else { wps->dev.rf_bands = hapd->iconf->hw_mode == HOSTAPD_MODE_IEEE80211A ? WPS_RF_50GHZ : hapd->iconf->hw_mode == HOSTAPD_MODE_IEEE80211AD ? WPS_RF_60GHZ : WPS_RF_24GHZ; /* FIX: dualband AP */ } if (conf->wpa & WPA_PROTO_RSN) { if (conf->wpa_key_mgmt & WPA_KEY_MGMT_PSK) wps->auth_types |= WPS_AUTH_WPA2PSK; if (conf->wpa_key_mgmt & WPA_KEY_MGMT_IEEE8021X) wps->auth_types |= WPS_AUTH_WPA2; if (conf->rsn_pairwise & (WPA_CIPHER_CCMP | WPA_CIPHER_GCMP | WPA_CIPHER_CCMP_256 | WPA_CIPHER_GCMP_256)) { wps->encr_types |= WPS_ENCR_AES; wps->encr_types_rsn |= WPS_ENCR_AES; } if (conf->rsn_pairwise & WPA_CIPHER_TKIP) { wps->encr_types |= WPS_ENCR_TKIP; wps->encr_types_rsn |= WPS_ENCR_TKIP; } } if (conf->wpa & WPA_PROTO_WPA) { if (conf->wpa_key_mgmt & WPA_KEY_MGMT_PSK) wps->auth_types |= WPS_AUTH_WPAPSK; if (conf->wpa_key_mgmt & WPA_KEY_MGMT_IEEE8021X) wps->auth_types |= WPS_AUTH_WPA; if (conf->wpa_pairwise & WPA_CIPHER_CCMP) { wps->encr_types |= WPS_ENCR_AES; wps->encr_types_wpa |= WPS_ENCR_AES; } if (conf->wpa_pairwise & WPA_CIPHER_TKIP) { wps->encr_types |= WPS_ENCR_TKIP; wps->encr_types_wpa |= WPS_ENCR_TKIP; } } if (conf->ssid.security_policy == SECURITY_PLAINTEXT) { wps->encr_types |= WPS_ENCR_NONE; wps->auth_types |= WPS_AUTH_OPEN; } if (conf->ssid.wpa_psk_file) { /* Use per-device PSKs */ } else if (conf->ssid.wpa_passphrase) { wps->network_key = (u8 *) os_strdup(conf->ssid.wpa_passphrase); wps->network_key_len = os_strlen(conf->ssid.wpa_passphrase); } else if (conf->ssid.wpa_psk) { wps->network_key = os_malloc(2 * PMK_LEN + 1); if (wps->network_key == NULL) goto fail; wpa_snprintf_hex((char *) wps->network_key, 2 * PMK_LEN + 1, conf->ssid.wpa_psk->psk, PMK_LEN); wps->network_key_len = 2 * PMK_LEN; } else if (conf->ssid.wep.keys_set && conf->ssid.wep.key[0]) { wps->network_key = os_malloc(conf->ssid.wep.len[0]); if (wps->network_key == NULL) goto fail; os_memcpy(wps->network_key, conf->ssid.wep.key[0], conf->ssid.wep.len[0]); wps->network_key_len = conf->ssid.wep.len[0]; } if (conf->ssid.wpa_psk) { os_memcpy(wps->psk, conf->ssid.wpa_psk->psk, PMK_LEN); wps->psk_set = 1; } wps->ap_auth_type = wps->auth_types; wps->ap_encr_type = wps->encr_types; if (conf->wps_state == WPS_STATE_NOT_CONFIGURED) { /* Override parameters to enable security by default */ wps->auth_types = WPS_AUTH_WPA2PSK | WPS_AUTH_WPAPSK; wps->encr_types = WPS_ENCR_AES | WPS_ENCR_TKIP; wps->encr_types_rsn = WPS_ENCR_AES | WPS_ENCR_TKIP; wps->encr_types_wpa = WPS_ENCR_AES | WPS_ENCR_TKIP; } wps->ap_settings = conf->ap_settings; wps->ap_settings_len = conf->ap_settings_len; cfg.new_psk_cb = hostapd_wps_new_psk_cb; cfg.set_ie_cb = hostapd_wps_set_ie_cb; cfg.pin_needed_cb = hostapd_wps_pin_needed_cb; cfg.reg_success_cb = hostapd_wps_reg_success_cb; cfg.enrollee_seen_cb = hostapd_wps_enrollee_seen_cb; cfg.cb_ctx = hapd; cfg.skip_cred_build = conf->skip_cred_build; cfg.extra_cred = conf->extra_cred; cfg.extra_cred_len = conf->extra_cred_len; cfg.disable_auto_conf = (hapd->conf->wps_cred_processing == 1) && conf->skip_cred_build; if (conf->ssid.security_policy == SECURITY_STATIC_WEP) cfg.static_wep_only = 1; cfg.dualband = interface_count(hapd->iface) > 1; if ((wps->dev.rf_bands & (WPS_RF_50GHZ | WPS_RF_24GHZ)) == (WPS_RF_50GHZ | WPS_RF_24GHZ)) cfg.dualband = 1; if (cfg.dualband) wpa_printf(MSG_DEBUG, "WPS: Dualband AP"); cfg.force_per_enrollee_psk = conf->force_per_enrollee_psk; wps->registrar = wps_registrar_init(wps, &cfg); if (wps->registrar == NULL) { wpa_printf(MSG_ERROR, "Failed to initialize WPS Registrar"); goto fail; } #ifdef CONFIG_WPS_UPNP wps->friendly_name = hapd->conf->friendly_name; wps->manufacturer_url = hapd->conf->manufacturer_url; wps->model_description = hapd->conf->model_description; wps->model_url = hapd->conf->model_url; wps->upc = hapd->conf->upc; #endif /* CONFIG_WPS_UPNP */ hostapd_register_probereq_cb(hapd, hostapd_wps_probe_req_rx, hapd); hapd->wps = wps; return 0; fail: hostapd_free_wps(wps); return -1; } int hostapd_init_wps_complete(struct hostapd_data *hapd) { struct wps_context *wps = hapd->wps; if (wps == NULL) return 0; #ifdef CONFIG_WPS_UPNP if (hostapd_wps_upnp_init(hapd, wps) < 0) { wpa_printf(MSG_ERROR, "Failed to initialize WPS UPnP"); wps_registrar_deinit(wps->registrar); hostapd_free_wps(wps); hapd->wps = NULL; return -1; } #endif /* CONFIG_WPS_UPNP */ return 0; } static void hostapd_wps_nfc_clear(struct wps_context *wps) { #ifdef CONFIG_WPS_NFC wpa_printf(MSG_DEBUG, "WPS: Clear NFC Tag context %p", wps); wps->ap_nfc_dev_pw_id = 0; wpabuf_free(wps->ap_nfc_dh_pubkey); wps->ap_nfc_dh_pubkey = NULL; wpabuf_free(wps->ap_nfc_dh_privkey); wps->ap_nfc_dh_privkey = NULL; wpabuf_free(wps->ap_nfc_dev_pw); wps->ap_nfc_dev_pw = NULL; #endif /* CONFIG_WPS_NFC */ } void hostapd_deinit_wps(struct hostapd_data *hapd) { eloop_cancel_timeout(hostapd_wps_reenable_ap_pin, hapd, NULL); eloop_cancel_timeout(hostapd_wps_ap_pin_timeout, hapd, NULL); eloop_cancel_timeout(wps_reload_config, hapd->iface, NULL); if (hapd->wps == NULL) { hostapd_wps_clear_ies(hapd, 1); return; } #ifdef CONFIG_WPS_UPNP hostapd_wps_upnp_deinit(hapd); #endif /* CONFIG_WPS_UPNP */ wps_registrar_deinit(hapd->wps->registrar); wps_free_pending_msgs(hapd->wps->upnp_msgs); hostapd_free_wps(hapd->wps); hapd->wps = NULL; hostapd_wps_clear_ies(hapd, 1); } void hostapd_update_wps(struct hostapd_data *hapd) { if (hapd->wps == NULL) return; #ifdef CONFIG_WPS_UPNP hapd->wps->friendly_name = hapd->conf->friendly_name; hapd->wps->manufacturer_url = hapd->conf->manufacturer_url; hapd->wps->model_description = hapd->conf->model_description; hapd->wps->model_url = hapd->conf->model_url; hapd->wps->upc = hapd->conf->upc; #endif /* CONFIG_WPS_UPNP */ hostapd_wps_set_vendor_ext(hapd, hapd->wps); if (hapd->conf->wps_state) wps_registrar_update_ie(hapd->wps->registrar); else hostapd_deinit_wps(hapd); } struct wps_add_pin_data { const u8 *addr; const u8 *uuid; const u8 *pin; size_t pin_len; int timeout; int added; }; static int wps_add_pin(struct hostapd_data *hapd, void *ctx) { struct wps_add_pin_data *data = ctx; int ret; if (hapd->wps == NULL) return 0; ret = wps_registrar_add_pin(hapd->wps->registrar, data->addr, data->uuid, data->pin, data->pin_len, data->timeout); if (ret == 0) data->added++; return ret; } int hostapd_wps_add_pin(struct hostapd_data *hapd, const u8 *addr, const char *uuid, const char *pin, int timeout) { u8 u[UUID_LEN]; struct wps_add_pin_data data; data.addr = addr; data.uuid = u; data.pin = (const u8 *) pin; data.pin_len = os_strlen(pin); data.timeout = timeout; data.added = 0; if (os_strcmp(uuid, "any") == 0) data.uuid = NULL; else { if (uuid_str2bin(uuid, u)) return -1; data.uuid = u; } if (hostapd_wps_for_each(hapd, wps_add_pin, &data) < 0) return -1; return data.added ? 0 : -1; } struct wps_button_pushed_ctx { const u8 *p2p_dev_addr; unsigned int count; }; static int wps_button_pushed(struct hostapd_data *hapd, void *ctx) { struct wps_button_pushed_ctx *data = ctx; if (hapd->wps) { data->count++; return wps_registrar_button_pushed(hapd->wps->registrar, data->p2p_dev_addr); } return 0; } int hostapd_wps_button_pushed(struct hostapd_data *hapd, const u8 *p2p_dev_addr) { struct wps_button_pushed_ctx ctx; int ret; os_memset(&ctx, 0, sizeof(ctx)); ctx.p2p_dev_addr = p2p_dev_addr; ret = hostapd_wps_for_each(hapd, wps_button_pushed, &ctx); if (ret == 0 && !ctx.count) ret = -1; return ret; } struct wps_cancel_ctx { unsigned int count; }; static int wps_cancel(struct hostapd_data *hapd, void *ctx) { struct wps_cancel_ctx *data = ctx; if (hapd->wps) { data->count++; wps_registrar_wps_cancel(hapd->wps->registrar); ap_for_each_sta(hapd, ap_sta_wps_cancel, NULL); } return 0; } int hostapd_wps_cancel(struct hostapd_data *hapd) { struct wps_cancel_ctx ctx; int ret; os_memset(&ctx, 0, sizeof(ctx)); ret = hostapd_wps_for_each(hapd, wps_cancel, &ctx); if (ret == 0 && !ctx.count) ret = -1; return ret; } static int hostapd_wps_probe_req_rx(void *ctx, const u8 *addr, const u8 *da, const u8 *bssid, const u8 *ie, size_t ie_len, int ssi_signal) { struct hostapd_data *hapd = ctx; struct wpabuf *wps_ie; struct ieee802_11_elems elems; if (hapd->wps == NULL) return 0; if (ieee802_11_parse_elems(ie, ie_len, &elems, 0) == ParseFailed) { wpa_printf(MSG_DEBUG, "WPS: Could not parse ProbeReq from " MACSTR, MAC2STR(addr)); return 0; } if (elems.ssid && elems.ssid_len > 0 && (elems.ssid_len != hapd->conf->ssid.ssid_len || os_memcmp(elems.ssid, hapd->conf->ssid.ssid, elems.ssid_len) != 0)) return 0; /* Not for us */ wps_ie = ieee802_11_vendor_ie_concat(ie, ie_len, WPS_DEV_OUI_WFA); if (wps_ie == NULL) return 0; if (wps_validate_probe_req(wps_ie, addr) < 0) { wpabuf_free(wps_ie); return 0; } if (wpabuf_len(wps_ie) > 0) { int p2p_wildcard = 0; #ifdef CONFIG_P2P if (elems.ssid && elems.ssid_len == P2P_WILDCARD_SSID_LEN && os_memcmp(elems.ssid, P2P_WILDCARD_SSID, P2P_WILDCARD_SSID_LEN) == 0) p2p_wildcard = 1; #endif /* CONFIG_P2P */ wps_registrar_probe_req_rx(hapd->wps->registrar, addr, wps_ie, p2p_wildcard); #ifdef CONFIG_WPS_UPNP /* FIX: what exactly should be included in the WLANEvent? * WPS attributes? Full ProbeReq frame? */ if (!p2p_wildcard) upnp_wps_device_send_wlan_event( hapd->wps_upnp, addr, UPNP_WPS_WLANEVENT_TYPE_PROBE, wps_ie); #endif /* CONFIG_WPS_UPNP */ } wpabuf_free(wps_ie); return 0; } #ifdef CONFIG_WPS_UPNP static int hostapd_rx_req_put_wlan_response( void *priv, enum upnp_wps_wlanevent_type ev_type, const u8 *mac_addr, const struct wpabuf *msg, enum wps_msg_type msg_type) { struct hostapd_data *hapd = priv; struct sta_info *sta; struct upnp_pending_message *p; wpa_printf(MSG_DEBUG, "WPS UPnP: PutWLANResponse ev_type=%d mac_addr=" MACSTR, ev_type, MAC2STR(mac_addr)); wpa_hexdump(MSG_MSGDUMP, "WPS UPnP: PutWLANResponse NewMessage", wpabuf_head(msg), wpabuf_len(msg)); if (ev_type != UPNP_WPS_WLANEVENT_TYPE_EAP) { wpa_printf(MSG_DEBUG, "WPS UPnP: Ignored unexpected " "PutWLANResponse WLANEventType %d", ev_type); return -1; } /* * EAP response to ongoing to WPS Registration. Send it to EAP-WSC * server implementation for delivery to the peer. */ sta = ap_get_sta(hapd, mac_addr); #ifndef CONFIG_WPS_STRICT if (!sta) { /* * Workaround - Intel wsccmd uses bogus NewWLANEventMAC: * Pick STA that is in an ongoing WPS registration without * checking the MAC address. */ wpa_printf(MSG_DEBUG, "WPS UPnP: No matching STA found based " "on NewWLANEventMAC; try wildcard match"); for (sta = hapd->sta_list; sta; sta = sta->next) { if (sta->eapol_sm && (sta->flags & WLAN_STA_WPS)) break; } } #endif /* CONFIG_WPS_STRICT */ if (!sta || !(sta->flags & WLAN_STA_WPS)) { wpa_printf(MSG_DEBUG, "WPS UPnP: No matching STA found"); return 0; } if (!sta->eapol_sm) { /* * This can happen, e.g., if an ER sends an extra message after * the station has disassociated (but not fully * deauthenticated). */ wpa_printf(MSG_DEBUG, "WPS UPnP: Matching STA did not have EAPOL state machine initialized"); return 0; } p = os_zalloc(sizeof(*p)); if (p == NULL) return -1; os_memcpy(p->addr, sta->addr, ETH_ALEN); p->msg = wpabuf_dup(msg); p->type = msg_type; p->next = hapd->wps->upnp_msgs; hapd->wps->upnp_msgs = p; return eapol_auth_eap_pending_cb(sta->eapol_sm, sta->eapol_sm->eap); } static int hostapd_wps_upnp_init(struct hostapd_data *hapd, struct wps_context *wps) { struct upnp_wps_device_ctx *ctx; if (!hapd->conf->upnp_iface) return 0; ctx = os_zalloc(sizeof(*ctx)); if (ctx == NULL) return -1; ctx->rx_req_put_wlan_response = hostapd_rx_req_put_wlan_response; if (hapd->conf->ap_pin) ctx->ap_pin = os_strdup(hapd->conf->ap_pin); hapd->wps_upnp = upnp_wps_device_init(ctx, wps, hapd, hapd->conf->upnp_iface); if (hapd->wps_upnp == NULL) return -1; wps->wps_upnp = hapd->wps_upnp; return 0; } static void hostapd_wps_upnp_deinit(struct hostapd_data *hapd) { upnp_wps_device_deinit(hapd->wps_upnp, hapd); } #endif /* CONFIG_WPS_UPNP */ int hostapd_wps_get_mib_sta(struct hostapd_data *hapd, const u8 *addr, char *buf, size_t buflen) { if (hapd->wps == NULL) return 0; return wps_registrar_get_info(hapd->wps->registrar, addr, buf, buflen); } static void hostapd_wps_ap_pin_timeout(void *eloop_data, void *user_ctx) { struct hostapd_data *hapd = eloop_data; wpa_printf(MSG_DEBUG, "WPS: AP PIN timed out"); hostapd_wps_ap_pin_disable(hapd); wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_AP_PIN_DISABLED); } static void hostapd_wps_ap_pin_enable(struct hostapd_data *hapd, int timeout) { wpa_printf(MSG_DEBUG, "WPS: Enabling AP PIN (timeout=%d)", timeout); hapd->ap_pin_failures = 0; hapd->ap_pin_failures_consecutive = 0; hapd->conf->ap_setup_locked = 0; if (hapd->wps->ap_setup_locked) { wpa_msg(hapd->msg_ctx, MSG_INFO, WPS_EVENT_AP_SETUP_UNLOCKED); hapd->wps->ap_setup_locked = 0; wps_registrar_update_ie(hapd->wps->registrar); } eloop_cancel_timeout(hostapd_wps_ap_pin_timeout, hapd, NULL); if (timeout > 0) eloop_register_timeout(timeout, 0, hostapd_wps_ap_pin_timeout, hapd, NULL); } static int wps_ap_pin_disable(struct hostapd_data *hapd, void *ctx) { os_free(hapd->conf->ap_pin); hapd->conf->ap_pin = NULL; #ifdef CONFIG_WPS_UPNP upnp_wps_set_ap_pin(hapd->wps_upnp, NULL); #endif /* CONFIG_WPS_UPNP */ eloop_cancel_timeout(hostapd_wps_ap_pin_timeout, hapd, NULL); return 0; } void hostapd_wps_ap_pin_disable(struct hostapd_data *hapd) { wpa_printf(MSG_DEBUG, "WPS: Disabling AP PIN"); hostapd_wps_for_each(hapd, wps_ap_pin_disable, NULL); } struct wps_ap_pin_data { char pin_txt[9]; int timeout; }; static int wps_ap_pin_set(struct hostapd_data *hapd, void *ctx) { struct wps_ap_pin_data *data = ctx; if (!hapd->wps) return 0; os_free(hapd->conf->ap_pin); hapd->conf->ap_pin = os_strdup(data->pin_txt); #ifdef CONFIG_WPS_UPNP upnp_wps_set_ap_pin(hapd->wps_upnp, data->pin_txt); #endif /* CONFIG_WPS_UPNP */ hostapd_wps_ap_pin_enable(hapd, data->timeout); return 0; } const char * hostapd_wps_ap_pin_random(struct hostapd_data *hapd, int timeout) { unsigned int pin; struct wps_ap_pin_data data; if (wps_generate_pin(&pin) < 0) return NULL; os_snprintf(data.pin_txt, sizeof(data.pin_txt), "%08u", pin); data.timeout = timeout; hostapd_wps_for_each(hapd, wps_ap_pin_set, &data); return hapd->conf->ap_pin; } const char * hostapd_wps_ap_pin_get(struct hostapd_data *hapd) { return hapd->conf->ap_pin; } int hostapd_wps_ap_pin_set(struct hostapd_data *hapd, const char *pin, int timeout) { struct wps_ap_pin_data data; int ret; ret = os_snprintf(data.pin_txt, sizeof(data.pin_txt), "%s", pin); if (os_snprintf_error(sizeof(data.pin_txt), ret)) return -1; data.timeout = timeout; return hostapd_wps_for_each(hapd, wps_ap_pin_set, &data); } static int wps_update_ie(struct hostapd_data *hapd, void *ctx) { if (hapd->wps) wps_registrar_update_ie(hapd->wps->registrar); return 0; } void hostapd_wps_update_ie(struct hostapd_data *hapd) { hostapd_wps_for_each(hapd, wps_update_ie, NULL); } int hostapd_wps_config_ap(struct hostapd_data *hapd, const char *ssid, const char *auth, const char *encr, const char *key) { struct wps_credential cred; size_t len; os_memset(&cred, 0, sizeof(cred)); len = os_strlen(ssid); if ((len & 1) || len > 2 * sizeof(cred.ssid) || hexstr2bin(ssid, cred.ssid, len / 2)) return -1; cred.ssid_len = len / 2; if (os_strncmp(auth, "OPEN", 4) == 0) cred.auth_type = WPS_AUTH_OPEN; else if (os_strncmp(auth, "WPAPSK", 6) == 0) cred.auth_type = WPS_AUTH_WPAPSK; else if (os_strncmp(auth, "WPA2PSK", 7) == 0) cred.auth_type = WPS_AUTH_WPA2PSK; else return -1; if (encr) { if (os_strncmp(encr, "NONE", 4) == 0) cred.encr_type = WPS_ENCR_NONE; else if (os_strncmp(encr, "TKIP", 4) == 0) cred.encr_type = WPS_ENCR_TKIP; else if (os_strncmp(encr, "CCMP", 4) == 0) cred.encr_type = WPS_ENCR_AES; else return -1; } else cred.encr_type = WPS_ENCR_NONE; if (key) { len = os_strlen(key); if ((len & 1) || len > 2 * sizeof(cred.key) || hexstr2bin(key, cred.key, len / 2)) return -1; cred.key_len = len / 2; } return wps_registrar_config_ap(hapd->wps->registrar, &cred); } #ifdef CONFIG_WPS_NFC struct wps_nfc_password_token_data { const u8 *oob_dev_pw; size_t oob_dev_pw_len; int added; }; static int wps_add_nfc_password_token(struct hostapd_data *hapd, void *ctx) { struct wps_nfc_password_token_data *data = ctx; int ret; if (hapd->wps == NULL) return 0; ret = wps_registrar_add_nfc_password_token(hapd->wps->registrar, data->oob_dev_pw, data->oob_dev_pw_len); if (ret == 0) data->added++; return ret; } static int hostapd_wps_add_nfc_password_token(struct hostapd_data *hapd, struct wps_parse_attr *attr) { struct wps_nfc_password_token_data data; data.oob_dev_pw = attr->oob_dev_password; data.oob_dev_pw_len = attr->oob_dev_password_len; data.added = 0; if (hostapd_wps_for_each(hapd, wps_add_nfc_password_token, &data) < 0) return -1; return data.added ? 0 : -1; } static int hostapd_wps_nfc_tag_process(struct hostapd_data *hapd, const struct wpabuf *wps) { struct wps_parse_attr attr; wpa_hexdump_buf(MSG_DEBUG, "WPS: Received NFC tag payload", wps); if (wps_parse_msg(wps, &attr)) { wpa_printf(MSG_DEBUG, "WPS: Ignore invalid data from NFC tag"); return -1; } if (attr.oob_dev_password) return hostapd_wps_add_nfc_password_token(hapd, &attr); wpa_printf(MSG_DEBUG, "WPS: Ignore unrecognized NFC tag"); return -1; } int hostapd_wps_nfc_tag_read(struct hostapd_data *hapd, const struct wpabuf *data) { const struct wpabuf *wps = data; struct wpabuf *tmp = NULL; int ret; if (wpabuf_len(data) < 4) return -1; if (*wpabuf_head_u8(data) != 0x10) { /* Assume this contains full NDEF record */ tmp = ndef_parse_wifi(data); if (tmp == NULL) { wpa_printf(MSG_DEBUG, "WPS: Could not parse NDEF"); return -1; } wps = tmp; } ret = hostapd_wps_nfc_tag_process(hapd, wps); wpabuf_free(tmp); return ret; } struct wpabuf * hostapd_wps_nfc_config_token(struct hostapd_data *hapd, int ndef) { struct wpabuf *ret; if (hapd->wps == NULL) return NULL; ret = wps_get_oob_cred(hapd->wps, hostapd_wps_rf_band_cb(hapd), hapd->iconf->channel); if (ndef && ret) { struct wpabuf *tmp; tmp = ndef_build_wifi(ret); wpabuf_free(ret); if (tmp == NULL) return NULL; ret = tmp; } return ret; } struct wpabuf * hostapd_wps_nfc_hs_cr(struct hostapd_data *hapd, int ndef) { struct wpabuf *ret; if (hapd->wps == NULL) return NULL; if (hapd->conf->wps_nfc_dh_pubkey == NULL) { struct wps_context *wps = hapd->wps; if (wps_nfc_gen_dh(&hapd->conf->wps_nfc_dh_pubkey, &hapd->conf->wps_nfc_dh_privkey) < 0) return NULL; hostapd_wps_nfc_clear(wps); wps->ap_nfc_dev_pw_id = DEV_PW_NFC_CONNECTION_HANDOVER; wps->ap_nfc_dh_pubkey = wpabuf_dup(hapd->conf->wps_nfc_dh_pubkey); wps->ap_nfc_dh_privkey = wpabuf_dup(hapd->conf->wps_nfc_dh_privkey); if (!wps->ap_nfc_dh_pubkey || !wps->ap_nfc_dh_privkey) { hostapd_wps_nfc_clear(wps); return NULL; } } ret = wps_build_nfc_handover_sel(hapd->wps, hapd->conf->wps_nfc_dh_pubkey, hapd->own_addr, hapd->iface->freq); if (ndef && ret) { struct wpabuf *tmp; tmp = ndef_build_wifi(ret); wpabuf_free(ret); if (tmp == NULL) return NULL; ret = tmp; } return ret; } int hostapd_wps_nfc_report_handover(struct hostapd_data *hapd, const struct wpabuf *req, const struct wpabuf *sel) { struct wpabuf *wps; int ret = -1; u16 wsc_len; const u8 *pos; struct wpabuf msg; struct wps_parse_attr attr; u16 dev_pw_id; /* * Enrollee/station is always initiator of the NFC connection handover, * so use the request message here to find Enrollee public key hash. */ wps = ndef_parse_wifi(req); if (wps == NULL) return -1; wpa_printf(MSG_DEBUG, "WPS: Received application/vnd.wfa.wsc " "payload from NFC connection handover"); wpa_hexdump_buf(MSG_DEBUG, "WPS: NFC payload", wps); if (wpabuf_len(wps) < 2) { wpa_printf(MSG_DEBUG, "WPS: Too short Wi-Fi Handover Request " "Message"); goto out; } pos = wpabuf_head(wps); wsc_len = WPA_GET_BE16(pos); if (wsc_len > wpabuf_len(wps) - 2) { wpa_printf(MSG_DEBUG, "WPS: Invalid WSC attribute length (%u) " "in rt Wi-Fi Handover Request Message", wsc_len); goto out; } pos += 2; wpa_hexdump(MSG_DEBUG, "WPS: WSC attributes in Wi-Fi Handover Request Message", pos, wsc_len); if (wsc_len < wpabuf_len(wps) - 2) { wpa_hexdump(MSG_DEBUG, "WPS: Ignore extra data after WSC attributes", pos + wsc_len, wpabuf_len(wps) - 2 - wsc_len); } wpabuf_set(&msg, pos, wsc_len); ret = wps_parse_msg(&msg, &attr); if (ret < 0) { wpa_printf(MSG_DEBUG, "WPS: Could not parse WSC attributes in " "Wi-Fi Handover Request Message"); goto out; } if (attr.oob_dev_password == NULL || attr.oob_dev_password_len < WPS_OOB_PUBKEY_HASH_LEN + 2) { wpa_printf(MSG_DEBUG, "WPS: No Out-of-Band Device Password " "included in Wi-Fi Handover Request Message"); ret = -1; goto out; } if (attr.uuid_e == NULL) { wpa_printf(MSG_DEBUG, "WPS: No UUID-E included in Wi-Fi " "Handover Request Message"); ret = -1; goto out; } wpa_hexdump(MSG_DEBUG, "WPS: UUID-E", attr.uuid_e, WPS_UUID_LEN); wpa_hexdump(MSG_DEBUG, "WPS: Out-of-Band Device Password", attr.oob_dev_password, attr.oob_dev_password_len); dev_pw_id = WPA_GET_BE16(attr.oob_dev_password + WPS_OOB_PUBKEY_HASH_LEN); if (dev_pw_id != DEV_PW_NFC_CONNECTION_HANDOVER) { wpa_printf(MSG_DEBUG, "WPS: Unexpected OOB Device Password ID " "%u in Wi-Fi Handover Request Message", dev_pw_id); ret = -1; goto out; } wpa_hexdump(MSG_DEBUG, "WPS: Enrollee Public Key hash", attr.oob_dev_password, WPS_OOB_PUBKEY_HASH_LEN); ret = wps_registrar_add_nfc_pw_token(hapd->wps->registrar, attr.oob_dev_password, DEV_PW_NFC_CONNECTION_HANDOVER, NULL, 0, 1); out: wpabuf_free(wps); return ret; } struct wpabuf * hostapd_wps_nfc_token_gen(struct hostapd_data *hapd, int ndef) { if (hapd->conf->wps_nfc_pw_from_config) { return wps_nfc_token_build(ndef, hapd->conf->wps_nfc_dev_pw_id, hapd->conf->wps_nfc_dh_pubkey, hapd->conf->wps_nfc_dev_pw); } return wps_nfc_token_gen(ndef, &hapd->conf->wps_nfc_dev_pw_id, &hapd->conf->wps_nfc_dh_pubkey, &hapd->conf->wps_nfc_dh_privkey, &hapd->conf->wps_nfc_dev_pw); } int hostapd_wps_nfc_token_enable(struct hostapd_data *hapd) { struct wps_context *wps = hapd->wps; struct wpabuf *pw; if (wps == NULL) return -1; if (!hapd->conf->wps_nfc_dh_pubkey || !hapd->conf->wps_nfc_dh_privkey || !hapd->conf->wps_nfc_dev_pw || !hapd->conf->wps_nfc_dev_pw_id) return -1; hostapd_wps_nfc_clear(wps); wpa_printf(MSG_DEBUG, "WPS: Enable NFC Tag (Dev Pw Id %u) for AP interface %s (context %p)", hapd->conf->wps_nfc_dev_pw_id, hapd->conf->iface, wps); wps->ap_nfc_dev_pw_id = hapd->conf->wps_nfc_dev_pw_id; wps->ap_nfc_dh_pubkey = wpabuf_dup(hapd->conf->wps_nfc_dh_pubkey); wps->ap_nfc_dh_privkey = wpabuf_dup(hapd->conf->wps_nfc_dh_privkey); pw = hapd->conf->wps_nfc_dev_pw; wps->ap_nfc_dev_pw = wpabuf_alloc( wpabuf_len(pw) * 2 + 1); if (wps->ap_nfc_dev_pw) { wpa_snprintf_hex_uppercase( (char *) wpabuf_put(wps->ap_nfc_dev_pw, wpabuf_len(pw) * 2), wpabuf_len(pw) * 2 + 1, wpabuf_head(pw), wpabuf_len(pw)); } if (!wps->ap_nfc_dh_pubkey || !wps->ap_nfc_dh_privkey || !wps->ap_nfc_dev_pw) { hostapd_wps_nfc_clear(wps); return -1; } return 0; } void hostapd_wps_nfc_token_disable(struct hostapd_data *hapd) { wpa_printf(MSG_DEBUG, "WPS: Disable NFC token for AP interface %s", hapd->conf->iface); hostapd_wps_nfc_clear(hapd->wps); } #endif /* CONFIG_WPS_NFC */