/* * * Wireless daemon for Linux * * Copyright (C) 2013-2014 Intel Corporation. All rights reserved. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA * */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include "crypto.h" #include "eapol.h" #include "ie.h" #include "util.h" #include "mpdu.h" #include "eap.h" #include "handshake.h" #include "watchlist.h" struct l_queue *state_machines; struct l_queue *preauths; struct watchlist frame_watches; static uint32_t eapol_4way_handshake_time = 2; eapol_rekey_offload_func_t rekey_offload = NULL; eapol_tx_packet_func_t tx_packet = NULL; void *tx_user_data; uint32_t next_frame_watch_id; #define VERIFY_IS_ZERO(field) \ do { \ if (!util_mem_is_zero((field), sizeof((field)))) \ return false; \ } while (false) \ /* * MIC calculation depends on the selected hash function. The has function * is given in the EAPoL Key Descriptor Version field. * * The MIC length is always 16 bytes for currently known Key Descriptor * Versions. * * The input struct eapol_key *frame should have a zero-d MIC field */ bool eapol_calculate_mic(const uint8_t *kck, const struct eapol_key *frame, uint8_t *mic) { size_t frame_len = sizeof(struct eapol_key); frame_len += L_BE16_TO_CPU(frame->key_data_len); switch (frame->key_descriptor_version) { case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_MD5_ARC4: return hmac_md5(kck, 16, frame, frame_len, mic, 16); case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_SHA1_AES: return hmac_sha1(kck, 16, frame, frame_len, mic, 16); case EAPOL_KEY_DESCRIPTOR_VERSION_AES_128_CMAC_AES: return cmac_aes(kck, 16, frame, frame_len, mic, 16); default: return false; } } bool eapol_verify_mic(const uint8_t *kck, const struct eapol_key *frame) { size_t frame_len = sizeof(struct eapol_key); uint8_t mic[16]; struct iovec iov[3]; struct l_checksum *checksum = NULL; iov[0].iov_base = (void *) frame; iov[0].iov_len = offsetof(struct eapol_key, key_mic_data); memset(mic, 0, sizeof(mic)); iov[1].iov_base = mic; iov[1].iov_len = sizeof(mic); iov[2].iov_base = ((void *) frame) + offsetof(struct eapol_key, key_data_len); iov[2].iov_len = frame_len - offsetof(struct eapol_key, key_data_len) + L_BE16_TO_CPU(frame->key_data_len); switch (frame->key_descriptor_version) { case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_MD5_ARC4: checksum = l_checksum_new_hmac(L_CHECKSUM_MD5, kck, 16); break; case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_SHA1_AES: checksum = l_checksum_new_hmac(L_CHECKSUM_SHA1, kck, 16); break; case EAPOL_KEY_DESCRIPTOR_VERSION_AES_128_CMAC_AES: checksum = l_checksum_new_cmac_aes(kck, 16); break; default: return false; } if (checksum == NULL) return false; l_checksum_updatev(checksum, iov, 3); l_checksum_get_digest(checksum, mic, 16); l_checksum_free(checksum); if (!memcmp(frame->key_mic_data, mic, 16)) return true; return false; } uint8_t *eapol_decrypt_key_data(const uint8_t *kek, const struct eapol_key *frame, size_t *decrypted_size) { size_t key_data_len = L_BE16_TO_CPU(frame->key_data_len); const uint8_t *key_data = frame->key_data; size_t expected_len; uint8_t *buf; switch (frame->key_descriptor_version) { case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_MD5_ARC4: expected_len = key_data_len; break; case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_SHA1_AES: case EAPOL_KEY_DESCRIPTOR_VERSION_AES_128_CMAC_AES: expected_len = key_data_len - 8; break; default: return NULL; }; buf = l_new(uint8_t, expected_len); switch (frame->key_descriptor_version) { case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_MD5_ARC4: { uint8_t key[32]; bool ret; memcpy(key, frame->eapol_key_iv, 16); memcpy(key + 16, kek, 16); ret = arc4_skip(key, 32, 256, key_data, key_data_len, buf); memset(key, 0, sizeof(key)); if (!ret) goto error; break; } case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_SHA1_AES: case EAPOL_KEY_DESCRIPTOR_VERSION_AES_128_CMAC_AES: if (key_data_len < 24 || key_data_len % 8) goto error; if (!aes_unwrap(kek, key_data, key_data_len, buf)) goto error; break; } if (decrypted_size) *decrypted_size = expected_len; return buf; error: l_free(buf); return NULL; } /* * Pad and encrypt the plaintext Key Data contents in @key_data using * the encryption scheme required by @out_frame->key_descriptor_version, * write results to @out_frame->key_data and @out_frame->key_data_len. * * Note that for efficiency @key_data is being modified, including in * case of failure, so it must be sufficiently larger than @key_data_len. */ bool eapol_encrypt_key_data(const uint8_t *kek, uint8_t *key_data, size_t key_data_len, struct eapol_key *out_frame) { switch (out_frame->key_descriptor_version) { case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_MD5_ARC4: /* Not supported */ return false; case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_SHA1_AES: case EAPOL_KEY_DESCRIPTOR_VERSION_AES_128_CMAC_AES: if (key_data_len < 16 || key_data_len % 8) key_data[key_data_len++] = 0xdd; while (key_data_len < 16 || key_data_len % 8) key_data[key_data_len++] = 0x00; if (!aes_wrap(kek, key_data, key_data_len, out_frame->key_data)) return false; key_data_len += 8; break; } out_frame->key_data_len = L_CPU_TO_BE16(key_data_len); return true; } void eapol_key_data_append(struct eapol_key *ek, enum handshake_kde selector, const uint8_t *data, size_t data_len) { uint16_t key_data_len = L_BE16_TO_CPU(ek->key_data_len); ek->key_data[key_data_len++] = IE_TYPE_VENDOR_SPECIFIC; ek->key_data[key_data_len++] = 4 + data_len; /* OUI + Data type + len */ l_put_be32(selector, ek->key_data + key_data_len); key_data_len += 4; memcpy(ek->key_data + key_data_len, data, data_len); key_data_len += data_len; ek->key_data_len = L_CPU_TO_BE16(key_data_len); } const struct eapol_key *eapol_key_validate(const uint8_t *frame, size_t len) { const struct eapol_key *ek; uint16_t key_data_len; if (len < sizeof(struct eapol_key)) return NULL; ek = (const struct eapol_key *) frame; switch (ek->header.protocol_version) { case EAPOL_PROTOCOL_VERSION_2001: case EAPOL_PROTOCOL_VERSION_2004: break; default: return NULL; } if (ek->header.packet_type != 3) return NULL; switch (ek->descriptor_type) { case EAPOL_DESCRIPTOR_TYPE_RC4: case EAPOL_DESCRIPTOR_TYPE_80211: case EAPOL_DESCRIPTOR_TYPE_WPA: break; default: return NULL; } switch (ek->key_descriptor_version) { case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_MD5_ARC4: case EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_SHA1_AES: case EAPOL_KEY_DESCRIPTOR_VERSION_AES_128_CMAC_AES: break; default: return NULL; } key_data_len = L_BE16_TO_CPU(ek->key_data_len); if (len < sizeof(struct eapol_key) + key_data_len) return NULL; return ek; } #define VERIFY_PTK_COMMON(ek) \ if (!ek->key_type) \ return false; \ if (ek->smk_message) \ return false; \ if (ek->request) \ return false; \ if (ek->error) \ return false \ bool eapol_verify_ptk_1_of_4(const struct eapol_key *ek) { /* Verify according to 802.11, Section 11.6.6.2 */ VERIFY_PTK_COMMON(ek); if (ek->install) return false; if (!ek->key_ack) return false; if (ek->key_mic) return false; if (ek->secure) return false; if (ek->encrypted_key_data) return false; if (ek->wpa_key_id) return false; VERIFY_IS_ZERO(ek->key_rsc); VERIFY_IS_ZERO(ek->reserved); VERIFY_IS_ZERO(ek->key_mic_data); return true; } bool eapol_verify_ptk_2_of_4(const struct eapol_key *ek) { uint16_t key_len; /* Verify according to 802.11, Section 11.6.6.3 */ VERIFY_PTK_COMMON(ek); if (ek->install) return false; if (ek->key_ack) return false; if (!ek->key_mic) return false; if (ek->secure) return false; if (ek->encrypted_key_data) return false; if (ek->wpa_key_id) return false; if (ek->request) return false; key_len = L_BE16_TO_CPU(ek->key_length); if (key_len != 0) return false; VERIFY_IS_ZERO(ek->eapol_key_iv); VERIFY_IS_ZERO(ek->key_rsc); VERIFY_IS_ZERO(ek->reserved); return true; } bool eapol_verify_ptk_3_of_4(const struct eapol_key *ek, bool is_wpa) { uint16_t key_len; /* Verify according to 802.11, Section 11.6.6.4 */ VERIFY_PTK_COMMON(ek); /* * TODO: Handle cases where install might be 0: * For PTK generation, 0 only if the AP does not support key mapping * keys, or if the STA has the No Pairwise bit (in the RSN Capabilities * field) equal to 1 and only the group key is used. */ if (!ek->install) return false; if (!ek->key_ack) return false; if (!ek->key_mic) return false; if (ek->secure != !is_wpa) return false; /* Must be encrypted when GTK is present but reserved in WPA */ if (!ek->encrypted_key_data && !is_wpa) return false; if (ek->wpa_key_id) return false; key_len = L_BE16_TO_CPU(ek->key_length); if (key_len != 16 && key_len != 32) return false; VERIFY_IS_ZERO(ek->reserved); return true; } bool eapol_verify_ptk_4_of_4(const struct eapol_key *ek, bool is_wpa) { uint16_t key_len; /* Verify according to 802.11, Section 11.6.6.5 */ VERIFY_PTK_COMMON(ek); if (ek->install) return false; if (ek->key_ack) return false; if (!ek->key_mic) return false; if (ek->secure != !is_wpa) return false; if (ek->encrypted_key_data) return false; if (ek->wpa_key_id) return false; if (ek->request) return false; key_len = L_BE16_TO_CPU(ek->key_length); if (key_len != 0) return false; VERIFY_IS_ZERO(ek->key_nonce); VERIFY_IS_ZERO(ek->eapol_key_iv); VERIFY_IS_ZERO(ek->key_rsc); VERIFY_IS_ZERO(ek->reserved); return true; } #define VERIFY_GTK_COMMON(ek) \ if (ek->key_type) \ return false; \ if (ek->smk_message) \ return false; \ if (ek->request) \ return false; \ if (ek->error) \ return false; \ if (ek->install) \ return false \ bool eapol_verify_gtk_1_of_2(const struct eapol_key *ek, bool is_wpa) { uint16_t key_len; VERIFY_GTK_COMMON(ek); if (!ek->key_ack) return false; if (!ek->key_mic) return false; if (!ek->secure) return false; /* Must be encrypted when GTK is present but reserved in WPA */ if (!ek->encrypted_key_data && !is_wpa) return false; /* * In P802.11i/D3.0 the Key Length should be 16 for WPA but hostapd * uses 16 for CCMP and 32 for TKIP. Since 802.11i-2004 there's * inconsistency in the required value, for example 0 is clearly * specified in 802.11-2012 11.6.7.2 but 11.6.2 doesn't list 0 and * makes the value depend on the pairwise key type. */ key_len = L_BE16_TO_CPU(ek->key_length); if (key_len != 0 && key_len != 16 && key_len != 32) return false; VERIFY_IS_ZERO(ek->reserved); /* * WPA_80211_v3_1, Section 2.2.4: * "Key Index (bits 4 and 5): specifies the key id of the temporal * key of the key derived from the message. The value of this shall be * zero (0) if the value of Key Type (bit 4) is Pairwise (1). The Key * Type and Key Index shall not both be 0 in the same message. * * Group keys shall not use key id 0. This means that key ids 1 to 3 * are available to be used to identify Group keys. This document * recommends that implementations reserve key ids 1 and 2 for Group * Keys, and that key id 3 is not used. */ if (is_wpa && !ek->wpa_key_id) return false; return true; } bool eapol_verify_gtk_2_of_2(const struct eapol_key *ek, bool is_wpa) { uint16_t key_len; /* Verify according to 802.11, Section 11.6.7.3 */ VERIFY_GTK_COMMON(ek); if (ek->key_ack) return false; if (!ek->key_mic) return false; if (!ek->secure) return false; if (ek->encrypted_key_data) return false; key_len = L_BE16_TO_CPU(ek->key_length); if (key_len != 0) return false; VERIFY_IS_ZERO(ek->key_nonce); VERIFY_IS_ZERO(ek->eapol_key_iv); VERIFY_IS_ZERO(ek->key_rsc); VERIFY_IS_ZERO(ek->reserved); return true; } static struct eapol_key *eapol_create_common( enum eapol_protocol_version protocol, enum eapol_key_descriptor_version version, bool secure, uint64_t key_replay_counter, const uint8_t snonce[], size_t extra_len, const uint8_t *extra_data, int key_type, bool is_wpa) { size_t to_alloc = sizeof(struct eapol_key); struct eapol_key *out_frame = l_malloc(to_alloc + extra_len); memset(out_frame, 0, to_alloc + extra_len); out_frame->header.protocol_version = protocol; out_frame->header.packet_type = 0x3; out_frame->header.packet_len = L_CPU_TO_BE16(to_alloc + extra_len - 4); out_frame->descriptor_type = is_wpa ? EAPOL_DESCRIPTOR_TYPE_WPA : EAPOL_DESCRIPTOR_TYPE_80211; out_frame->key_descriptor_version = version; out_frame->key_type = key_type; out_frame->install = false; out_frame->key_ack = false; out_frame->key_mic = true; out_frame->secure = secure; out_frame->error = false; out_frame->request = false; out_frame->encrypted_key_data = false; out_frame->smk_message = false; out_frame->key_length = 0; out_frame->key_replay_counter = L_CPU_TO_BE64(key_replay_counter); memcpy(out_frame->key_nonce, snonce, sizeof(out_frame->key_nonce)); out_frame->key_data_len = L_CPU_TO_BE16(extra_len); memcpy(out_frame->key_data, extra_data, extra_len); return out_frame; } struct eapol_key *eapol_create_ptk_2_of_4( enum eapol_protocol_version protocol, enum eapol_key_descriptor_version version, uint64_t key_replay_counter, const uint8_t snonce[], size_t extra_len, const uint8_t *extra_data, bool is_wpa) { return eapol_create_common(protocol, version, false, key_replay_counter, snonce, extra_len, extra_data, 1, is_wpa); } struct eapol_key *eapol_create_ptk_4_of_4( enum eapol_protocol_version protocol, enum eapol_key_descriptor_version version, uint64_t key_replay_counter, bool is_wpa) { uint8_t snonce[32]; memset(snonce, 0, sizeof(snonce)); return eapol_create_common(protocol, version, is_wpa ? false : true, key_replay_counter, snonce, 0, NULL, 1, is_wpa); } struct eapol_key *eapol_create_gtk_2_of_2( enum eapol_protocol_version protocol, enum eapol_key_descriptor_version version, uint64_t key_replay_counter, bool is_wpa, uint8_t wpa_key_id) { uint8_t snonce[32]; struct eapol_key *step2; memset(snonce, 0, sizeof(snonce)); step2 = eapol_create_common(protocol, version, true, key_replay_counter, snonce, 0, NULL, 0, is_wpa); if (!step2) return step2; /* * WPA_80211_v3_1, Section 2.2.4: * "The Key Type and Key Index shall not both be 0 in the same message" * * The above means that even though sending the key index back to the * AP has no practical value, we must still do so. */ if (is_wpa) step2->wpa_key_id = wpa_key_id; return step2; } struct eapol_sm { struct handshake_state *handshake; enum eapol_protocol_version protocol_version; uint64_t replay_counter; eapol_sm_event_func_t event_func; void *user_data; struct l_timeout *timeout; struct l_timeout *eapol_start_timeout; unsigned int frame_retry; uint16_t listen_interval; bool have_replay:1; bool started:1; bool use_eapol_start:1; bool require_handshake:1; bool eap_exchanged:1; bool authenticator:1; struct eap_state *eap; struct eapol_frame *early_frame; uint32_t watch_id; uint8_t installed_gtk_len; uint8_t installed_gtk[CRYPTO_MAX_GTK_LEN]; uint8_t installed_igtk_len; uint8_t installed_igtk[CRYPTO_MAX_IGTK_LEN]; }; static void eapol_sm_destroy(void *value) { struct eapol_sm *sm = value; l_timeout_remove(sm->timeout); l_timeout_remove(sm->eapol_start_timeout); if (sm->eap) eap_free(sm->eap); l_free(sm->early_frame); eapol_frame_watch_remove(sm->watch_id); sm->installed_gtk_len = 0; memset(sm->installed_gtk, 0, sizeof(sm->installed_gtk)); sm->installed_igtk_len = 0; memset(sm->installed_igtk, 0, sizeof(sm->installed_igtk)); l_free(sm); l_queue_remove(state_machines, sm); } struct eapol_sm *eapol_sm_new(struct handshake_state *hs) { struct eapol_sm *sm; sm = l_new(struct eapol_sm, 1); sm->handshake = hs; if (hs->settings_8021x) sm->use_eapol_start = true; sm->require_handshake = true; return sm; } void eapol_sm_free(struct eapol_sm *sm) { eapol_sm_destroy(sm); } void eapol_sm_set_protocol_version(struct eapol_sm *sm, enum eapol_protocol_version protocol_version) { sm->protocol_version = protocol_version; } void eapol_sm_set_listen_interval(struct eapol_sm *sm, uint16_t interval) { sm->listen_interval = interval; } void eapol_sm_set_user_data(struct eapol_sm *sm, void *user_data) { sm->user_data = user_data; } void eapol_sm_set_event_func(struct eapol_sm *sm, eapol_sm_event_func_t func) { sm->event_func = func; } static void eapol_sm_write(struct eapol_sm *sm, const struct eapol_frame *ef, bool noencrypt) { __eapol_tx_packet(sm->handshake->ifindex, sm->handshake->aa, ETH_P_PAE, ef, noencrypt); } static inline void handshake_failed(struct eapol_sm *sm, uint16_t reason_code) { handshake_event(sm->handshake, HANDSHAKE_EVENT_FAILED, &reason_code); eapol_sm_free(sm); } static void eapol_timeout(struct l_timeout *timeout, void *user_data) { struct eapol_sm *sm = user_data; l_timeout_remove(sm->timeout); sm->timeout = NULL; handshake_failed(sm, MMPDU_REASON_CODE_4WAY_HANDSHAKE_TIMEOUT); } static void eapol_install_gtk(struct eapol_sm *sm, uint8_t gtk_key_index, const uint8_t *gtk, size_t gtk_len, const uint8_t *rsc) { /* * Don't install the same GTK. On older kernels this resets the * replay counters, etc and can lead to various attacks */ if (sm->installed_gtk_len == gtk_len && !memcmp(sm->installed_gtk, gtk, gtk_len)) return; handshake_state_install_gtk(sm->handshake, gtk_key_index, gtk, gtk_len, rsc, 6); memcpy(sm->installed_gtk, gtk, gtk_len); sm->installed_gtk_len = gtk_len; } static void eapol_install_igtk(struct eapol_sm *sm, uint8_t igtk_key_index, const uint8_t *igtk, size_t igtk_len) { /* * Don't install the same IGTK. On older kernels this resets the * replay counters, etc and can lead to various attacks */ if (sm->installed_igtk_len == igtk_len - 6 && !memcmp(sm->installed_igtk, igtk + 6, igtk_len - 6)) return; handshake_state_install_igtk(sm->handshake, igtk_key_index, igtk + 6, igtk_len - 6, igtk); memcpy(sm->installed_igtk, igtk + 6, igtk_len - 6); sm->installed_igtk_len = igtk_len - 6; } static void send_eapol_start(struct l_timeout *timeout, void *user_data) { struct eapol_sm *sm = user_data; uint8_t buf[sizeof(struct eapol_frame)]; struct eapol_frame *frame = (struct eapol_frame *) buf; handshake_event(sm->handshake, HANDSHAKE_EVENT_STARTED, NULL); l_timeout_remove(sm->eapol_start_timeout); sm->eapol_start_timeout = NULL; if (!sm->protocol_version) sm->protocol_version = EAPOL_PROTOCOL_VERSION_2001; frame->header.protocol_version = sm->protocol_version; frame->header.packet_type = 1; l_put_be16(0, &frame->header.packet_len); eapol_sm_write(sm, frame, false); } static void eapol_set_key_timeout(struct eapol_sm *sm, l_timeout_notify_cb_t cb) { /* * 802.11-2016 12.7.6.6: "The retransmit timeout value shall be * 100 ms for the first timeout, half the listen interval for the * second timeout, and the listen interval for subsequent timeouts. * If there is no listen interval or the listen interval is zero, * then 100 ms shall be used for all timeout values." */ unsigned int timeout_ms = 100; unsigned int beacon_us = 100 * 1024; sm->frame_retry++; if (sm->frame_retry == 2 && sm->listen_interval != 0) timeout_ms = sm->listen_interval * beacon_us / 2000; else if (sm->frame_retry > 2 && sm->listen_interval != 0) timeout_ms = sm->listen_interval * beacon_us / 1000; if (sm->frame_retry > 1) l_timeout_modify_ms(sm->timeout, timeout_ms); else { if (sm->timeout) l_timeout_remove(sm->timeout); sm->timeout = l_timeout_create_ms(timeout_ms, cb, sm, NULL); } } /* 802.11-2016 Section 12.7.6.2 */ static void eapol_send_ptk_1_of_4(struct eapol_sm *sm) { uint32_t ifindex = sm->handshake->ifindex; const uint8_t *aa = sm->handshake->aa; uint8_t frame_buf[512]; struct eapol_key *ek = (struct eapol_key *) frame_buf; enum crypto_cipher cipher = ie_rsn_cipher_suite_to_cipher( sm->handshake->pairwise_cipher); uint8_t pmkid[16]; handshake_state_new_anonce(sm->handshake); sm->handshake->ptk_complete = false; sm->replay_counter++; memset(ek, 0, sizeof(struct eapol_key)); ek->header.protocol_version = sm->protocol_version; ek->header.packet_type = 0x3; ek->descriptor_type = EAPOL_DESCRIPTOR_TYPE_80211; /* Must be HMAC-SHA1-128 + AES when using CCMP with PSK or 8021X */ ek->key_descriptor_version = EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_SHA1_AES; ek->key_type = true; ek->key_ack = true; ek->key_length = L_CPU_TO_BE16(crypto_cipher_key_len(cipher)); ek->key_replay_counter = L_CPU_TO_BE64(sm->replay_counter); memcpy(ek->key_nonce, sm->handshake->anonce, sizeof(ek->key_nonce)); /* Write the PMKID KDE into Key Data field unencrypted */ crypto_derive_pmkid(sm->handshake->pmk, sm->handshake->spa, aa, pmkid, false); eapol_key_data_append(ek, HANDSHAKE_KDE_PMKID, pmkid, 16); ek->header.packet_len = L_CPU_TO_BE16(sizeof(struct eapol_key) + L_BE16_TO_CPU(ek->key_data_len) - 4); l_debug("STA: "MAC" retries=%u", MAC_STR(sm->handshake->spa), sm->frame_retry); __eapol_tx_packet(ifindex, sm->handshake->spa, ETH_P_PAE, (struct eapol_frame *) ek, false); } static void eapol_ptk_1_of_4_retry(struct l_timeout *timeout, void *user_data) { struct eapol_sm *sm = user_data; if (sm->frame_retry >= 3) { handshake_failed(sm, MMPDU_REASON_CODE_4WAY_HANDSHAKE_TIMEOUT); return; } eapol_send_ptk_1_of_4(sm); eapol_set_key_timeout(sm, eapol_ptk_1_of_4_retry); } static void eapol_handle_ptk_1_of_4(struct eapol_sm *sm, const struct eapol_key *ek) { const struct crypto_ptk *ptk; struct eapol_key *step2; uint8_t mic[16]; uint8_t *ies; size_t ies_len; const uint8_t *own_ie = sm->handshake->own_ie; const uint8_t *pmkid; struct ie_rsn_info rsn_info; l_debug("ifindex=%u", sm->handshake->ifindex); if (!eapol_verify_ptk_1_of_4(ek)) goto error_unspecified; pmkid = handshake_util_find_pmkid_kde(ek->key_data, L_BE16_TO_CPU(ek->key_data_len)); ie_parse_rsne_from_data(own_ie, own_ie[1] + 2, &rsn_info); /* * Require the PMKID KDE whenever we've sent a list of PMKIDs in * our RSNE and we've haven't seen any EAPOL-EAP frame since * (sm->eap_exchanged is false), otherwise treat it as optional and * only validate it against our PMK. Some 802.11-2012 sections * show message 1/4 without a PMKID KDE and there are APs that * send no PMKID KDE. */ if (!sm->eap_exchanged && !sm->handshake->wpa_ie && rsn_info.num_pmkids) { bool found = false; int i; if (!pmkid) goto error_unspecified; for (i = 0; i < rsn_info.num_pmkids; i++) if (!memcmp(rsn_info.pmkids + i * 16, pmkid, 16)) { found = true; break; } if (!found) goto error_unspecified; } else if (pmkid) { uint8_t own_pmkid[16]; if (handshake_state_get_pmkid(sm->handshake, own_pmkid) && memcmp(pmkid, own_pmkid, 16)) { l_debug("Authenticator sent a PMKID that didn't match"); /* * If the AP has a different PMKSA from ours and we * have means to create a new PMKSA through EAP then * try that, otherwise give up. */ if (sm->eap) { send_eapol_start(NULL, sm); return; } /* * Some APs are known to send a PMKID KDE with all * zeros for the PMKID. Likely we can still * successfully negotiate a handshake, so ignore this * for now and treat it as if the PMKID KDE was not * included */ if (util_mem_is_zero(pmkid, 16)) l_debug("PMKID is all zero, ignoring"); else goto error_unspecified; } } /* * If we're in a state where we have successfully processed Message 3, * then assume that the new message 1 is a PTK rekey and start a new * handshake */ if (!sm->handshake->have_snonce || memcmp(sm->handshake->anonce, ek->key_nonce, sizeof(ek->key_nonce)) || sm->handshake->ptk_complete) { handshake_state_new_snonce(sm->handshake); handshake_state_set_anonce(sm->handshake, ek->key_nonce); if (!handshake_state_derive_ptk(sm->handshake)) goto error_unspecified; } if (sm->handshake->akm_suite & (IE_RSN_AKM_SUITE_FT_OVER_8021X | IE_RSN_AKM_SUITE_FT_USING_PSK | IE_RSN_AKM_SUITE_FT_OVER_SAE_SHA256)) { const uint8_t *mde = sm->handshake->mde; const uint8_t *fte = sm->handshake->fte; /* * Rebuild the RSNE to include the PMKR1Name and append * MDE + FTE. */ ies = alloca(512); rsn_info.num_pmkids = 1; rsn_info.pmkids = sm->handshake->pmk_r1_name; ie_build_rsne(&rsn_info, ies); ies_len = ies[1] + 2; memcpy(ies + ies_len, mde, mde[1] + 2); ies_len += mde[1] + 2; memcpy(ies + ies_len, fte, fte[1] + 2); ies_len += fte[1] + 2; } else { ies_len = own_ie[1] + 2; ies = (uint8_t *) own_ie; } step2 = eapol_create_ptk_2_of_4(sm->protocol_version, ek->key_descriptor_version, L_BE64_TO_CPU(ek->key_replay_counter), sm->handshake->snonce, ies_len, ies, sm->handshake->wpa_ie); ptk = handshake_state_get_ptk(sm->handshake); if (!eapol_calculate_mic(ptk->kck, step2, mic)) { l_info("MIC calculation failed. " "Ensure Kernel Crypto is available."); l_free(step2); handshake_failed(sm, MMPDU_REASON_CODE_UNSPECIFIED); return; } memcpy(step2->key_mic_data, mic, sizeof(mic)); eapol_sm_write(sm, (struct eapol_frame *) step2, false); l_free(step2); l_timeout_remove(sm->eapol_start_timeout); sm->eapol_start_timeout = NULL; return; error_unspecified: handshake_failed(sm, MMPDU_REASON_CODE_UNSPECIFIED); } #define EAPOL_PAIRWISE_UPDATE_COUNT 3 /* 802.11-2016 Section 12.7.6.4 */ static void eapol_send_ptk_3_of_4(struct eapol_sm *sm) { uint32_t ifindex = sm->handshake->ifindex; uint8_t frame_buf[512]; uint8_t key_data_buf[128]; struct eapol_key *ek = (struct eapol_key *) frame_buf; size_t key_data_len; enum crypto_cipher cipher = ie_rsn_cipher_suite_to_cipher( sm->handshake->pairwise_cipher); const struct crypto_ptk *ptk = (struct crypto_ptk *) sm->handshake->ptk; struct ie_rsn_info rsn; sm->replay_counter++; memset(ek, 0, sizeof(struct eapol_key)); ek->header.protocol_version = sm->protocol_version; ek->header.packet_type = 0x3; ek->descriptor_type = EAPOL_DESCRIPTOR_TYPE_80211; /* Must be HMAC-SHA1-128 + AES when using CCMP with PSK or 8021X */ ek->key_descriptor_version = EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_SHA1_AES; ek->key_type = true; ek->install = true; ek->key_ack = true; ek->key_mic = true; ek->secure = true; ek->encrypted_key_data = true; ek->key_length = L_CPU_TO_BE16(crypto_cipher_key_len(cipher)); ek->key_replay_counter = L_CPU_TO_BE64(sm->replay_counter); memcpy(ek->key_nonce, sm->handshake->anonce, sizeof(ek->key_nonce)); /* * We don't currently handle group traffic, to support that we'd need * to provide the NL80211_ATTR_KEY_SEQ value from NL80211_CMD_GET_KEY * here. */ l_put_be64(1, ek->key_rsc); /* * Just one RSNE in Key Data as we only set one cipher in ap->ciphers * currently. */ memset(&rsn, 0, sizeof(rsn)); rsn.akm_suites = IE_RSN_AKM_SUITE_PSK; rsn.pairwise_ciphers = sm->handshake->pairwise_cipher; rsn.group_cipher = IE_RSN_CIPHER_SUITE_NO_GROUP_TRAFFIC; if (!ie_build_rsne(&rsn, key_data_buf)) return; if (!eapol_encrypt_key_data(ptk->kek, key_data_buf, 2 + key_data_buf[1], ek)) return; key_data_len = L_BE16_TO_CPU(ek->key_data_len); ek->header.packet_len = L_CPU_TO_BE16(sizeof(struct eapol_key) + key_data_len - 4); if (!eapol_calculate_mic(ptk->kck, ek, ek->key_mic_data)) return; l_debug("STA: "MAC" retries=%u", MAC_STR(sm->handshake->spa), sm->frame_retry); __eapol_tx_packet(ifindex, sm->handshake->spa, ETH_P_PAE, (struct eapol_frame *) ek, false); } static void eapol_ptk_3_of_4_retry(struct l_timeout *timeout, void *user_data) { struct eapol_sm *sm = user_data; if (sm->frame_retry >= EAPOL_PAIRWISE_UPDATE_COUNT) { handshake_failed(sm, MMPDU_REASON_CODE_4WAY_HANDSHAKE_TIMEOUT); return; } eapol_send_ptk_3_of_4(sm); eapol_set_key_timeout(sm, eapol_ptk_3_of_4_retry); l_debug("attempt %i", sm->frame_retry); } /* 802.11-2016 Section 12.7.6.3 */ static void eapol_handle_ptk_2_of_4(struct eapol_sm *sm, const struct eapol_key *ek) { const uint8_t *rsne; enum crypto_cipher cipher; size_t ptk_size; uint8_t ptk_buf[64]; struct crypto_ptk *ptk = (struct crypto_ptk *) ptk_buf; const uint8_t *aa = sm->handshake->aa; l_debug("ifindex=%u", sm->handshake->ifindex); if (!eapol_verify_ptk_2_of_4(ek)) return; if (L_BE64_TO_CPU(ek->key_replay_counter) != sm->replay_counter) return; cipher = ie_rsn_cipher_suite_to_cipher(sm->handshake->pairwise_cipher); ptk_size = sizeof(struct crypto_ptk) + crypto_cipher_key_len(cipher); if (!crypto_derive_pairwise_ptk(sm->handshake->pmk, sm->handshake->spa, aa, sm->handshake->anonce, ek->key_nonce, ptk, ptk_size, false)) return; if (!eapol_verify_mic(ptk->kck, ek)) return; /* Bitwise identical RSNE required */ rsne = eapol_find_rsne(ek->key_data, L_BE16_TO_CPU(ek->key_data_len), NULL); if (!rsne || rsne[1] != sm->handshake->own_ie[1] || memcmp(rsne + 2, sm->handshake->own_ie + 2, rsne[1])) { handshake_failed(sm, MMPDU_REASON_CODE_IE_DIFFERENT); return; } memcpy(sm->handshake->ptk, ptk_buf, ptk_size); memcpy(sm->handshake->snonce, ek->key_nonce, sizeof(sm->handshake->snonce)); sm->handshake->have_snonce = true; sm->handshake->ptk_complete = true; sm->frame_retry = 0; eapol_ptk_3_of_4_retry(NULL, sm); } const uint8_t *eapol_find_rsne(const uint8_t *data, size_t data_len, const uint8_t **optional) { struct ie_tlv_iter iter; const uint8_t *first = NULL; ie_tlv_iter_init(&iter, data, data_len); while (ie_tlv_iter_next(&iter)) { if (ie_tlv_iter_get_tag(&iter) != IE_TYPE_RSN) continue; if (!first) { first = ie_tlv_iter_get_data(&iter) - 2; continue; } if (optional) *optional = ie_tlv_iter_get_data(&iter) - 2; return first; } return first; } static const uint8_t *eapol_find_wpa_ie(const uint8_t *data, size_t data_len) { struct ie_tlv_iter iter; ie_tlv_iter_init(&iter, data, data_len); while (ie_tlv_iter_next(&iter)) { if (ie_tlv_iter_get_tag(&iter) != IE_TYPE_VENDOR_SPECIFIC) continue; if (is_ie_wpa_ie(ie_tlv_iter_get_data(&iter), ie_tlv_iter_get_length(&iter))) return ie_tlv_iter_get_data(&iter) - 2; } return NULL; } static void eapol_handle_ptk_3_of_4(struct eapol_sm *sm, const struct eapol_key *ek, const uint8_t *decrypted_key_data, size_t decrypted_key_data_size) { const struct crypto_ptk *ptk; struct eapol_key *step4; uint8_t mic[16]; const uint8_t *gtk = NULL; size_t gtk_len; const uint8_t *igtk = NULL; size_t igtk_len; const uint8_t *rsne; const uint8_t *optional_rsne = NULL; uint8_t gtk_key_index; uint8_t igtk_key_index; l_debug("ifindex=%u", sm->handshake->ifindex); if (!eapol_verify_ptk_3_of_4(ek, sm->handshake->wpa_ie)) { handshake_failed(sm, MMPDU_REASON_CODE_UNSPECIFIED); return; } /* * 802.11-2016, Section 12.7.6.4: * "On reception of message 3, the Supplicant silently discards the * message if the Key Replay Counter field value has already been used * or if the ANonce value in message 3 differs from the ANonce value * in message 1." */ if (memcmp(sm->handshake->anonce, ek->key_nonce, sizeof(ek->key_nonce))) return; /* * 11.6.6.4: "Verifies the RSNE. If it is part of a Fast BSS Transition * Initial Mobility Domain Association, see 12.4.2. Otherwise, if it is * not identical to that the STA received in the Beacon or Probe * Response frame, the STA shall disassociate. */ if (!sm->handshake->wpa_ie) rsne = eapol_find_rsne(decrypted_key_data, decrypted_key_data_size, &optional_rsne); else rsne = eapol_find_wpa_ie(decrypted_key_data, decrypted_key_data_size); if (!rsne) goto error_ie_different; if (!handshake_util_ap_ie_matches(rsne, sm->handshake->ap_ie, sm->handshake->wpa_ie)) goto error_ie_different; if (sm->handshake->akm_suite & (IE_RSN_AKM_SUITE_FT_OVER_8021X | IE_RSN_AKM_SUITE_FT_USING_PSK | IE_RSN_AKM_SUITE_FT_OVER_SAE_SHA256)) { struct ie_tlv_iter iter; struct ie_rsn_info ie_info; const uint8_t *mde = sm->handshake->mde; const uint8_t *fte = sm->handshake->fte; ie_parse_rsne_from_data(rsne, rsne[1] + 2, &ie_info); if (ie_info.num_pmkids != 1 || memcmp(ie_info.pmkids, sm->handshake->pmk_r1_name, 16)) goto error_ie_different; ie_tlv_iter_init(&iter, decrypted_key_data, decrypted_key_data_size); while (ie_tlv_iter_next(&iter)) switch (ie_tlv_iter_get_tag(&iter)) { case IE_TYPE_MOBILITY_DOMAIN: if (memcmp(ie_tlv_iter_get_data(&iter) - 2, mde, mde[1] + 2)) goto error_ie_different; break; case IE_TYPE_FAST_BSS_TRANSITION: if (memcmp(ie_tlv_iter_get_data(&iter) - 2, fte, fte[1] + 2)) goto error_ie_different; break; } } /* * If ptk_complete is set, then we are receiving Message 3 again. * It must be a retransmission, otherwise the anonce wouldn't match * and we wouldn't get here. Skip processing the rest of the message * and send our reply. Do not install the keys again. */ if (sm->handshake->ptk_complete) goto retransmit; /* * 11.6.6.4: "If a second RSNE is provided in the message, the * Supplicant uses the pairwise cipher suite specified in the second * RSNE or deauthenticates." */ if (optional_rsne) { struct ie_rsn_info info1; struct ie_rsn_info info2; uint16_t override; if (ie_parse_rsne_from_data(rsne, rsne[1] + 2, &info1) < 0) goto error_ie_different; if (ie_parse_rsne_from_data(optional_rsne, optional_rsne[1] + 2, &info2) < 0) goto error_ie_different; /* * 11.6.2: * It may happen, for example, that a Supplicant selects a * pairwise cipher suite which is advertised by an AP, but * which policy disallows for this particular STA. An * Authenticator may, therefore, insert a second RSNE to * overrule the STA’s selection. An Authenticator’s SME shall * insert the second RSNE, after the first RSNE, only for this * purpose. The pairwise cipher suite in the second RSNE * included shall be one of the ciphers advertised by the * Authenticator. All other fields in the second RSNE shall be * identical to the first RSNE. * * - Check that akm_suites and group_cipher are the same * between rsne1 and rsne2 * - Check that pairwise_ciphers is not the same between rsne1 * and rsne2 * - Check that rsne2 pairwise_ciphers is a subset of rsne */ if (info1.akm_suites != info2.akm_suites || info1.group_cipher != info2.group_cipher) goto error_ie_different; override = info2.pairwise_ciphers; if (override == info1.pairwise_ciphers || !(info1.pairwise_ciphers & override) || __builtin_popcount(override) != 1) { handshake_failed(sm, MMPDU_REASON_CODE_INVALID_PAIRWISE_CIPHER); return; } handshake_state_override_pairwise_cipher(sm->handshake, override); } if (!sm->handshake->wpa_ie && sm->handshake->group_cipher != IE_RSN_CIPHER_SUITE_NO_GROUP_TRAFFIC) { gtk = handshake_util_find_gtk_kde(decrypted_key_data, decrypted_key_data_size, >k_len); if (!gtk) { handshake_failed(sm, MMPDU_REASON_CODE_UNSPECIFIED); return; } /* TODO: Handle tx bit */ gtk_key_index = util_bit_field(gtk[0], 0, 2); gtk += 2; gtk_len -= 2; } else gtk = NULL; if (sm->handshake->mfp) { igtk = handshake_util_find_igtk_kde(decrypted_key_data, decrypted_key_data_size, &igtk_len); if (!igtk) { handshake_failed(sm, MMPDU_REASON_CODE_UNSPECIFIED); return; } igtk_key_index = l_get_le16(igtk);; igtk += 2; igtk_len -= 2; } else igtk = NULL; retransmit: /* * 802.11-2016, Section 12.7.6.4: * "b) Verifies the message 3 MIC. If the calculated MIC does not match * the MIC that the Authenticator included in the EAPOL-Key frame, the * Supplicant silently discards message 3." * "c) Updates the last-seen value of the Key Replay Counter field." * * Note that part b was done in eapol_key_handle */ sm->replay_counter = L_BE64_TO_CPU(ek->key_replay_counter); sm->have_replay = true; step4 = eapol_create_ptk_4_of_4(sm->protocol_version, ek->key_descriptor_version, sm->replay_counter, sm->handshake->wpa_ie); ptk = handshake_state_get_ptk(sm->handshake); if (!eapol_calculate_mic(ptk->kck, step4, mic)) { l_free(step4); handshake_failed(sm, MMPDU_REASON_CODE_UNSPECIFIED); return; } memcpy(step4->key_mic_data, mic, sizeof(mic)); eapol_sm_write(sm, (struct eapol_frame *) step4, false); l_free(step4); if (sm->handshake->ptk_complete) return; handshake_state_install_ptk(sm->handshake); if (gtk) eapol_install_gtk(sm, gtk_key_index, gtk, gtk_len, ek->key_rsc); if (igtk) eapol_install_igtk(sm, igtk_key_index, igtk, igtk_len); if (rekey_offload) rekey_offload(sm->handshake->ifindex, ptk->kek, ptk->kck, sm->replay_counter, sm->user_data); l_timeout_remove(sm->timeout); sm->timeout = NULL; return; error_ie_different: handshake_failed(sm, MMPDU_REASON_CODE_IE_DIFFERENT); } /* 802.11-2016 Section 12.7.6.5 */ static void eapol_handle_ptk_4_of_4(struct eapol_sm *sm, const struct eapol_key *ek) { const struct crypto_ptk *ptk = (struct crypto_ptk *) sm->handshake->ptk; l_debug("ifindex=%u", sm->handshake->ifindex); if (!eapol_verify_ptk_4_of_4(ek, false)) return; if (L_BE64_TO_CPU(ek->key_replay_counter) != sm->replay_counter) return; if (!eapol_verify_mic(ptk->kck, ek)) return; l_timeout_remove(sm->timeout); sm->timeout = NULL; handshake_state_install_ptk(sm->handshake); } static void eapol_handle_gtk_1_of_2(struct eapol_sm *sm, const struct eapol_key *ek, const uint8_t *decrypted_key_data, size_t decrypted_key_data_size) { const struct crypto_ptk *ptk; struct eapol_key *step2; uint8_t mic[16]; const uint8_t *gtk; size_t gtk_len; uint8_t gtk_key_index; const uint8_t *igtk; size_t igtk_len; uint8_t igtk_key_index; if (!eapol_verify_gtk_1_of_2(ek, sm->handshake->wpa_ie)) { handshake_failed(sm, MMPDU_REASON_CODE_UNSPECIFIED); return; } if (!sm->handshake->wpa_ie) { gtk = handshake_util_find_gtk_kde(decrypted_key_data, decrypted_key_data_size, >k_len); if (!gtk) return; gtk_key_index = util_bit_field(gtk[0], 0, 2); gtk += 2; gtk_len -= 2; } else { gtk = decrypted_key_data; gtk_len = decrypted_key_data_size; if (!gtk || gtk_len < CRYPTO_MIN_GTK_LEN || gtk_len > CRYPTO_MAX_GTK_LEN) return; gtk_key_index = ek->wpa_key_id; } if (sm->handshake->mfp) { igtk = handshake_util_find_igtk_kde(decrypted_key_data, decrypted_key_data_size, &igtk_len); if (!igtk) return; igtk_key_index = l_get_le16(igtk);; igtk += 2; igtk_len -= 2; } else igtk = NULL; /* * 802.11-2016, Section 12.7.7.2: * " * a) Verifies that the Key Replay Counter field value has not yet been * seen before, i.e., its value is strictly larger than that in any * other EAPOL-Key frame received thus far during this session. * b) Verifies that the MIC is valid, i.e., it uses the KCK that is * part of the PTK to verify that there is no data integrity error. * c) Uses the MLME-SETKEYS.request primitive to configure the temporal * GTK and, when present, IGTK into its IEEE 802.11 MAC. * d) Responds by creating and sending message 2 of the group key * handshake to the Authenticator and incrementing the replay counter. * " * Note: steps a & b are performed in eapol_key_handle */ sm->replay_counter = L_BE64_TO_CPU(ek->key_replay_counter); sm->have_replay = true; step2 = eapol_create_gtk_2_of_2(sm->protocol_version, ek->key_descriptor_version, sm->replay_counter, sm->handshake->wpa_ie, ek->wpa_key_id); ptk = handshake_state_get_ptk(sm->handshake); if (!eapol_calculate_mic(ptk->kck, step2, mic)) { l_free(step2); handshake_failed(sm, MMPDU_REASON_CODE_UNSPECIFIED); return; } memcpy(step2->key_mic_data, mic, sizeof(mic)); eapol_sm_write(sm, (struct eapol_frame *) step2, false); l_free(step2); eapol_install_gtk(sm, gtk_key_index, gtk, gtk_len, ek->key_rsc); if (igtk) eapol_install_igtk(sm, igtk_key_index, igtk, igtk_len); } static struct eapol_sm *eapol_find_sm(uint32_t ifindex, const uint8_t *aa) { const struct l_queue_entry *entry; struct eapol_sm *sm; for (entry = l_queue_get_entries(state_machines); entry; entry = entry->next) { sm = entry->data; if (sm->handshake->ifindex != ifindex) continue; if (memcmp(sm->handshake->aa, aa, ETH_ALEN)) continue; return sm; } return NULL; } static void eapol_key_handle(struct eapol_sm *sm, const struct eapol_frame *frame) { const struct eapol_key *ek; const struct crypto_ptk *ptk; uint8_t *decrypted_key_data = NULL; size_t key_data_len = 0; uint64_t replay_counter; ek = eapol_key_validate((const uint8_t *) frame, sizeof(struct eapol_header) + L_BE16_TO_CPU(frame->header.packet_len)); if (!ek) return; /* Wrong direction */ if (!ek->key_ack) return; /* Further Descriptor Type check */ if (!sm->handshake->wpa_ie && ek->descriptor_type != EAPOL_DESCRIPTOR_TYPE_80211) return; else if (sm->handshake->wpa_ie && ek->descriptor_type != EAPOL_DESCRIPTOR_TYPE_WPA) return; replay_counter = L_BE64_TO_CPU(ek->key_replay_counter); /* * 802.11-2016, Section 12.7.2: * "The Supplicant and Authenticator shall track the key replay counter * per security association. The key replay counter shall be * initialized to 0 on (re)association. The Authenticator shall * increment the key replay counter on each successive EAPOL-Key frame." * * and * * "The Supplicant should also use the key replay counter and ignore * EAPOL-Key frames with a Key Replay Counter field value smaller than * or equal to any received in a valid message. The local Key Replay * Counter field should not be updated until after the EAPOL-Key MIC is * checked and is found to be valid. In other words, the Supplicant * never updates the Key Replay Counter field for message 1 in the * 4-way handshake, as it includes no MIC. This implies the Supplicant * needs to allow for retransmission of message 1 when checking for * the key replay counter of message 3." * * Note: The latter condition implies that Message 1 and Message 3 * can have the same replay counter, though other parts of the spec * mandate that the Authenticator has to increment the replay counter * for each frame sent. Contradictory. */ if (sm->have_replay && sm->replay_counter >= replay_counter) return; ptk = handshake_state_get_ptk(sm->handshake); if (ek->key_mic) { /* Haven't received step 1 yet, so no ptk */ if (!sm->handshake->have_snonce) return; if (!eapol_verify_mic(ptk->kck, ek)) return; } if ((ek->encrypted_key_data && !sm->handshake->wpa_ie) || (ek->key_type == 0 && sm->handshake->wpa_ie)) { /* Haven't received step 1 yet, so no ptk */ if (!sm->handshake->have_snonce) return; decrypted_key_data = eapol_decrypt_key_data(ptk->kek, ek, &key_data_len); if (!decrypted_key_data) return; } else key_data_len = L_BE16_TO_CPU(ek->key_data_len); if (ek->key_type == 0) { /* GTK handshake allowed only after PTK handshake complete */ if (!sm->handshake->ptk_complete) goto done; if (sm->handshake->group_cipher == IE_RSN_CIPHER_SUITE_NO_GROUP_TRAFFIC) goto done; if (!decrypted_key_data) goto done; eapol_handle_gtk_1_of_2(sm, ek, decrypted_key_data, key_data_len); goto done; } /* If no MIC, then assume packet 1, otherwise packet 3 */ if (!ek->key_mic) eapol_handle_ptk_1_of_4(sm, ek); else { if (!key_data_len) goto done; eapol_handle_ptk_3_of_4(sm, ek, decrypted_key_data ?: ek->key_data, key_data_len); } done: l_free(decrypted_key_data); } /* This respresentes the eapMsg message in 802.1X Figure 8-1 */ static void eapol_eap_msg_cb(const uint8_t *eap_data, size_t len, void *user_data) { struct eapol_sm *sm = user_data; uint8_t buf[sizeof(struct eapol_frame) + len]; struct eapol_frame *frame = (struct eapol_frame *) buf; frame->header.protocol_version = sm->protocol_version; frame->header.packet_type = 0; l_put_be16(len, &frame->header.packet_len); memcpy(frame->data, eap_data, len); eapol_sm_write(sm, frame, false); } /* This respresentes the eapTimout, eapFail and eapSuccess messages */ static void eapol_eap_complete_cb(enum eap_result result, void *user_data) { struct eapol_sm *sm = user_data; l_info("EAP completed with %s", result == EAP_RESULT_SUCCESS ? "eapSuccess" : (result == EAP_RESULT_FAIL ? "eapFail" : "eapTimeout")); if (result != EAP_RESULT_SUCCESS) { eap_free(sm->eap); sm->eap = NULL; handshake_failed(sm, MMPDU_REASON_CODE_IEEE8021X_FAILED); return; } eap_reset(sm->eap); } /* This respresentes the eapResults message */ static void eapol_eap_results_cb(const uint8_t *msk_data, size_t msk_len, const uint8_t *emsk_data, size_t emsk_len, const uint8_t *iv, size_t iv_len, void *user_data) { struct eapol_sm *sm = user_data; l_debug("EAP key material received"); /* * 802.11i 8.5.1.2: * "When not using a PSK, the PMK is derived from the AAA key. * The PMK shall be computed as the first 256 bits (bits 0–255) * of the AAA key: PMK ← L(PTK, 0, 256)." * 802.11-2016 12.7.1.3: * "When not using a PSK, the PMK is derived from the MSK. * The PMK shall be computed as the first PMK_bits bits * (bits 0 to PMK_bits–1) of the MSK: PMK = L(MSK, 0, PMK_bits)." * RFC5247 explains AAA-Key refers to the MSK and confirms the * first 32 bytes of the MSK are used. MSK is at least 64 octets * long per RFC3748. Note WEP derives the PTK from MSK differently. * * In a Fast Transition initial mobility domain association the PMK * maps to the XXKey, except with EAP: * 802.11-2016 12.7.1.7.3: * "If the AKM negotiated is 00-0F-AC:3, then [...] XXKey shall be * the second 256 bits of the MSK (which is derived from the IEEE * 802.1X authentication), i.e., XXKey = L(MSK, 256, 256)." * So we need to save the first 64 bytes at minimum. */ if (sm->handshake->akm_suite == IE_RSN_AKM_SUITE_FT_OVER_8021X) { if (msk_len < 64) goto msk_short; } else { if (msk_len < 32) goto msk_short; } if (msk_len > sizeof(sm->handshake->pmk)) msk_len = sizeof(sm->handshake->pmk); handshake_state_set_pmk(sm->handshake, msk_data, msk_len); return; msk_short: l_error("EAP method's MSK too short for AKM suite %u", sm->handshake->akm_suite); handshake_failed(sm, MMPDU_REASON_CODE_IEEE8021X_FAILED); } static void eapol_eap_event_cb(unsigned int event, const void *event_data, void *user_data) { struct eapol_sm *sm = user_data; if (!sm->event_func) return; sm->event_func(event, event_data, sm->user_data); } void eapol_sm_set_use_eapol_start(struct eapol_sm *sm, bool enabled) { sm->use_eapol_start = enabled; } void eapol_sm_set_require_handshake(struct eapol_sm *sm, bool enabled) { sm->require_handshake = enabled; if (!sm->require_handshake) sm->use_eapol_start = false; } static void eapol_auth_key_handle(struct eapol_sm *sm, const struct eapol_frame *frame) { size_t frame_len = 4 + L_BE16_TO_CPU(frame->header.packet_len); const struct eapol_key *ek = eapol_key_validate((const void *) frame, frame_len); if (!ek) return; /* Wrong direction */ if (ek->key_ack) return; if (ek->request) return; /* Not supported */ if (!sm->handshake->have_anonce) return; /* Not expecting an EAPoL-Key yet */ if (!sm->handshake->ptk_complete) eapol_handle_ptk_2_of_4(sm, ek); else eapol_handle_ptk_4_of_4(sm, ek); } static void eapol_rx_auth_packet(uint16_t proto, const uint8_t *from, const struct eapol_frame *frame, void *user_data) { struct eapol_sm *sm = user_data; if (!sm->protocol_version) sm->protocol_version = frame->header.protocol_version; switch (frame->header.packet_type) { case 3: /* EAPOL-Key */ eapol_auth_key_handle(sm, frame); break; default: l_error("Authenticator received unknown packet type %i from %s", frame->header.packet_type, util_address_to_string(from)); return; } } static void eapol_rx_packet(uint16_t proto, const uint8_t *from, const struct eapol_frame *frame, void *user_data) { struct eapol_sm *sm = user_data; if (proto != ETH_P_PAE || memcmp(from, sm->handshake->aa, 6)) return; if (!sm->started) { size_t len = sizeof(struct eapol_header) + L_BE16_TO_CPU(frame->header.packet_len); /* * If the state machine hasn't started yet save the frame * for processing later. */ if (sm->early_frame) /* Is the 1-element queue full */ return; sm->early_frame = l_memdup(frame, len); return; } if (!sm->protocol_version) sm->protocol_version = frame->header.protocol_version; switch (frame->header.packet_type) { case 0: /* EAPOL-EAP */ l_timeout_remove(sm->eapol_start_timeout); sm->eapol_start_timeout = 0; if (!sm->eap) { /* If we're not configured for EAP, send a NAK */ sm->eap = eap_new(eapol_eap_msg_cb, eapol_eap_complete_cb, sm); if (!sm->eap) return; eap_set_key_material_func(sm->eap, eapol_eap_results_cb); } sm->eap_exchanged = true; eap_rx_packet(sm->eap, frame->data, L_BE16_TO_CPU(frame->header.packet_len)); break; case 3: /* EAPOL-Key */ if (!sm->handshake->have_pmk) { if (!sm->eap) return; /* * Either this is an error (EAP negotiation in * progress) or the server is giving us a chance to * use a cached PMK. We don't yet cache PMKs so * send an EAPOL-Start if we haven't sent one yet. */ if (sm->eapol_start_timeout) send_eapol_start(NULL, sm); return; } eapol_key_handle(sm, frame); break; default: return; } } void __eapol_update_replay_counter(uint32_t ifindex, const uint8_t *spa, const uint8_t *aa, uint64_t replay_counter) { struct eapol_sm *sm; sm = eapol_find_sm(ifindex, aa); if (!sm) return; if (sm->replay_counter >= replay_counter) return; sm->replay_counter = replay_counter; } void __eapol_set_tx_packet_func(eapol_tx_packet_func_t func) { tx_packet = func; } void __eapol_set_tx_user_data(void *user_data) { tx_user_data = user_data; } void __eapol_set_rekey_offload_func(eapol_rekey_offload_func_t func) { rekey_offload = func; } void eapol_register(struct eapol_sm *sm) { l_queue_push_head(state_machines, sm); sm->watch_id = eapol_frame_watch_add(sm->handshake->ifindex, eapol_rx_packet, sm); } void eapol_register_authenticator(struct eapol_sm *sm) { l_queue_push_head(state_machines, sm); sm->watch_id = eapol_frame_watch_add(sm->handshake->ifindex, eapol_rx_auth_packet, sm); sm->started = true; sm->authenticator = true; /* kick off handshake */ eapol_ptk_1_of_4_retry(NULL, sm); } bool eapol_start(struct eapol_sm *sm) { if (sm->handshake->settings_8021x) { sm->eap = eap_new(eapol_eap_msg_cb, eapol_eap_complete_cb, sm); if (!sm->eap) goto eap_error; if (!eap_load_settings(sm->eap, sm->handshake->settings_8021x, "EAP-")) { eap_free(sm->eap); sm->eap = NULL; goto eap_error; } eap_set_key_material_func(sm->eap, eapol_eap_results_cb); eap_set_event_func(sm->eap, eapol_eap_event_cb); } sm->started = true; if (sm->require_handshake) sm->timeout = l_timeout_create(eapol_4way_handshake_time, eapol_timeout, sm, NULL); if (sm->use_eapol_start) { /* * We start a short timeout, if EAP packets are not received * from AP, then we send the EAPoL-Start */ sm->eapol_start_timeout = l_timeout_create(1, send_eapol_start, sm, NULL); } /* Process any frames received early due to scheduling */ if (sm->early_frame) { eapol_rx_packet(ETH_P_PAE, sm->handshake->aa, sm->early_frame, sm); l_free(sm->early_frame); sm->early_frame = NULL; } return true; eap_error: l_error("Error initializing EAP for ifindex %i", (int) sm->handshake->ifindex); return false; } struct eapol_frame_watch { uint32_t ifindex; struct watchlist_item super; }; static void eapol_frame_watch_free(struct watchlist_item *item) { struct eapol_frame_watch *efw = container_of(item, struct eapol_frame_watch, super); l_free(efw); } static const struct watchlist_ops eapol_frame_watch_ops = { .item_free = eapol_frame_watch_free, }; uint32_t eapol_frame_watch_add(uint32_t ifindex, eapol_frame_watch_func_t handler, void *user_data) { struct eapol_frame_watch *efw; efw = l_new(struct eapol_frame_watch, 1); efw->ifindex = ifindex; return watchlist_link(&frame_watches, &efw->super, handler, user_data, NULL); } bool eapol_frame_watch_remove(uint32_t id) { return watchlist_remove(&frame_watches, id); } struct preauth_sm { uint32_t ifindex; uint8_t aa[6]; uint8_t spa[6]; struct eap_state *eap; uint8_t pmk[32]; eapol_preauth_cb_t cb; eapol_preauth_destroy_func_t destroy; void *user_data; struct l_timeout *timeout; uint32_t watch_id; bool initial_rx:1; }; #define EAPOL_TIMEOUT_SEC 1 static void preauth_sm_destroy(void *value) { struct preauth_sm *sm = value; if (sm->destroy) sm->destroy(sm->user_data); eap_free(sm->eap); l_timeout_remove(sm->timeout); eapol_frame_watch_remove(sm->watch_id); l_free(sm); } static void preauth_frame(struct preauth_sm *sm, uint8_t packet_type, const uint8_t *data, size_t data_len) { uint8_t buf[sizeof(struct eapol_frame) + data_len]; struct eapol_frame *frame = (struct eapol_frame *) buf; frame->header.protocol_version = EAPOL_PROTOCOL_VERSION_2001; frame->header.packet_type = packet_type; l_put_be16(data_len, &frame->header.packet_len); if (data_len) memcpy(frame->data, data, data_len); __eapol_tx_packet(sm->ifindex, sm->aa, 0x88c7, frame, false); } static void preauth_rx_packet(uint16_t proto, const uint8_t *from, const struct eapol_frame *frame, void *user_data) { struct preauth_sm *sm = user_data; if (proto != 0x88c7 || memcmp(from, sm->aa, 6)) return; if (frame->header.packet_type != 0) /* EAPOL-EAP */ return; if (!sm->initial_rx) { sm->initial_rx = true; /* * Initial frame from authenticator received, it's alive * so set a longer timeout. The timeout is for the whole * EAP exchange as we have no way to monitor the * negotiation progress and keep rearming the timer each * time progress is made. */ l_timeout_modify(sm->timeout, EAPOL_TIMEOUT_SEC * 3); } eap_rx_packet(sm->eap, frame->data, L_BE16_TO_CPU(frame->header.packet_len)); } static void preauth_eap_msg_cb(const uint8_t *eap_data, size_t len, void *user_data) { struct preauth_sm *sm = user_data; preauth_frame(sm, 0, eap_data, len); } static void preauth_eap_complete_cb(enum eap_result result, void *user_data) { struct preauth_sm *sm = user_data; l_info("Preauthentication completed with %s", result == EAP_RESULT_SUCCESS ? "eapSuccess" : (result == EAP_RESULT_FAIL ? "eapFail" : "eapTimeout")); l_queue_remove(preauths, sm); if (result == EAP_RESULT_SUCCESS) sm->cb(sm->pmk, sm->user_data); else sm->cb(NULL, sm->user_data); preauth_sm_destroy(sm); } /* See eapol_eap_results_cb for documentation */ static void preauth_eap_results_cb(const uint8_t *msk_data, size_t msk_len, const uint8_t *emsk_data, size_t emsk_len, const uint8_t *iv, size_t iv_len, void *user_data) { struct preauth_sm *sm = user_data; l_debug("Preauthentication EAP key material received"); if (msk_len < 32) goto msk_short; memcpy(sm->pmk, msk_data, 32); return; msk_short: l_error("Preauthentication MSK too short"); l_queue_remove(preauths, sm); sm->cb(NULL, sm->user_data); preauth_sm_destroy(sm); } static void preauth_timeout(struct l_timeout *timeout, void *user_data) { struct preauth_sm *sm = user_data; l_error("Preauthentication timeout"); l_queue_remove(preauths, sm); sm->cb(NULL, sm->user_data); preauth_sm_destroy(sm); } struct preauth_sm *eapol_preauth_start(const uint8_t *aa, const struct handshake_state *hs, eapol_preauth_cb_t cb, void *user_data, eapol_preauth_destroy_func_t destroy) { struct preauth_sm *sm; sm = l_new(struct preauth_sm, 1); sm->ifindex = hs->ifindex; memcpy(sm->aa, aa, 6); memcpy(sm->spa, hs->spa, 6); sm->cb = cb; sm->destroy = destroy; sm->user_data = user_data; sm->eap = eap_new(preauth_eap_msg_cb, preauth_eap_complete_cb, sm); if (!sm->eap) goto err_free_sm; if (!eap_load_settings(sm->eap, hs->settings_8021x, "EAP-")) goto err_free_eap; eap_set_key_material_func(sm->eap, preauth_eap_results_cb); sm->timeout = l_timeout_create(EAPOL_TIMEOUT_SEC, preauth_timeout, sm, NULL); sm->watch_id = eapol_frame_watch_add(sm->ifindex, preauth_rx_packet, sm); l_queue_push_head(preauths, sm); /* Send EAPOL-Start */ preauth_frame(sm, 1, NULL, 0); return sm; err_free_eap: eap_free(sm->eap); err_free_sm: l_free(sm); return NULL; } static bool preauth_remove_by_ifindex(void *data, void *user_data) { struct preauth_sm *sm = data; if (sm->ifindex != L_PTR_TO_UINT(user_data)) return false; preauth_sm_destroy(sm); return true; } void eapol_preauth_cancel(uint32_t ifindex) { l_queue_foreach_remove(preauths, preauth_remove_by_ifindex, L_UINT_TO_PTR(ifindex)); } static bool eapol_frame_watch_match_ifindex(const void *a, const void *b) { struct eapol_frame_watch *efw = container_of(a, struct eapol_frame_watch, super); return efw->ifindex == L_PTR_TO_UINT(b); } void __eapol_rx_packet(uint32_t ifindex, const uint8_t *src, uint16_t proto, const uint8_t *frame, size_t len, bool noencrypt) { const struct eapol_header *eh; /* Validate Header */ if (len < sizeof(struct eapol_header)) return; eh = (const struct eapol_header *) frame; switch (eh->protocol_version) { case EAPOL_PROTOCOL_VERSION_2001: case EAPOL_PROTOCOL_VERSION_2004: break; default: return; } if (len < sizeof(struct eapol_header) + L_BE16_TO_CPU(eh->packet_len)) return; WATCHLIST_NOTIFY_MATCHES(&frame_watches, eapol_frame_watch_match_ifindex, L_UINT_TO_PTR(ifindex), eapol_frame_watch_func_t, proto, src, (const struct eapol_frame *) eh); } void __eapol_tx_packet(uint32_t ifindex, const uint8_t *dst, uint16_t proto, const struct eapol_frame *frame, bool noencrypt) { if (!tx_packet) return; tx_packet(ifindex, dst, proto, frame, noencrypt, tx_user_data); } void __eapol_set_config(struct l_settings *config) { if (!l_settings_get_uint(config, "EAPoL", "max_4way_handshake_time", &eapol_4way_handshake_time)) eapol_4way_handshake_time = 2; } bool eapol_init() { state_machines = l_queue_new(); preauths = l_queue_new(); watchlist_init(&frame_watches, &eapol_frame_watch_ops); return true; } bool eapol_exit() { if (!l_queue_isempty(state_machines)) l_warn("stale eapol state machines found"); l_queue_destroy(state_machines, eapol_sm_destroy); if (!l_queue_isempty(preauths)) l_warn("stale preauth state machines found"); l_queue_destroy(preauths, preauth_sm_destroy); watchlist_destroy(&frame_watches); return true; }