/* * * 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 "sha1.h" #include "crypto.h" #include "eapol.h" #define VERIFY_IS_ZERO(field) \ do { \ unsigned int i; \ for (i = 0; i < sizeof(field); i++) \ if ((field)[i] != 0) \ 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_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 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 < 8 || key_data_len % 8) goto error; if (!aes_unwrap(kek, key_data, key_data_len, buf)) goto error; break; } return buf; error: l_free(buf); return NULL; } 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; if (ek->protocol_version != EAPOL_PROTOCOL_VERSION_2001 && ek->protocol_version != EAPOL_PROTOCOL_VERSION_2004) return NULL; if (ek->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; VERIFY_IS_ZERO(ek->eapol_key_iv); VERIFY_IS_ZERO(ek->key_rsc); VERIFY_IS_ZERO(ek->reserved); VERIFY_IS_ZERO(ek->key_mic_data); return ek; } 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; 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) { uint16_t key_len; /* Verify according to 802.11, Section 11.6.6.4 */ VERIFY_PTK_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 != 16) return false; VERIFY_IS_ZERO(ek->reserved); /* 0 (Version 2) or random (Version 1) */ if (ek->key_descriptor_version == EAPOL_KEY_DESCRIPTOR_VERSION_HMAC_MD5_ARC4) VERIFY_IS_ZERO(ek->eapol_key_iv); return true; } bool eapol_verify_ptk_4_of_4(const struct eapol_key *ek) { uint16_t key_len; /* Verify according to 802.11, Section 11.6.6.5 */ VERIFY_PTK_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) { 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->protocol_version = protocol; out_frame->packet_type = 0x3; out_frame->packet_len = L_CPU_TO_BE16(to_alloc + extra_len - 4); out_frame->descriptor_type = EAPOL_DESCRIPTOR_TYPE_80211; out_frame->key_descriptor_version = version; out_frame->key_type = true; 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) { return eapol_create_common(protocol, version, false, key_replay_counter, snonce, extra_len, extra_data); } 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) { uint8_t snonce[32]; memset(snonce, 0, sizeof(snonce)); return eapol_create_common(protocol, version, true, key_replay_counter, snonce, 0, NULL); } struct eapol_sm { uint8_t pmk[32]; uint64_t replay_counter; uint8_t sta_addr[6]; uint8_t snonce[32]; uint8_t aa_addr[6]; uint8_t anonce[32]; uint8_t ptk[64]; uint8_t *ap_rsn; size_t ap_rsn_size; uint8_t *own_rsn; size_t own_rsn_size; bool have_snonce:1; bool have_replay:1; }; static void eapol_sm_destroy(void *value) { struct eapol_sm *sm = value; l_free(sm->ap_rsn); l_free(sm->own_rsn); l_free(sm); } struct eapol_sm *eapol_sm_new() { struct eapol_sm *sm; sm = l_new(struct eapol_sm, 1); return sm; } void eapol_sm_free(struct eapol_sm *sm) { eapol_sm_destroy(sm); }