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kernel / pub / scm / network / wireless / iwd / 1de8d188837e4cbce8894fa7cc1202d48afbcff3 / . / src / eap-wsc.c
blob: 4642fb366cbb3d8c414ddf2d5a67fa751188bbc5 [file] [log] [blame]
/*
*
* Wireless daemon for Linux
*
* Copyright (C) 2016 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 <config.h>
#endif
#include <string.h>
#include <stdio.h>
#include <errno.h>
#include <ell/ell.h>
#include "crypto.h"
#include "eap.h"
#include "eap-private.h"
#include "wscutil.h"
#include "util.h"
#include "eap-wsc.h"
#define EAP_WSC_HEADER_LEN 14
#define EAP_WSC_PDU_MAX_LEN 4096
/* WSC v2.0.5, Section 7.7.1 */
enum wsc_op {
WSC_OP_START = 0x01,
WSC_OP_ACK = 0x02,
WSC_OP_NACK = 0x03,
WSC_OP_MSG = 0x04,
WSC_OP_DONE = 0x05,
WSC_OP_FRAG_ACK = 0x06,
};
/* WSC v2.0.5, Section 7.7.1 */
enum wsc_flag {
WSC_FLAG_MF = 0x01,
WSC_FLAG_LF = 0x02,
};
enum state {
STATE_EXPECT_START = 0,
STATE_EXPECT_M2,
STATE_EXPECT_M4,
STATE_EXPECT_M6,
STATE_EXPECT_M8,
STATE_FINISHED,
};
static struct l_key *dh5_generator;
static struct l_key *dh5_prime;
struct eap_wsc_state {
struct wsc_m1 *m1;
struct wsc_m2 *m2;
uint8_t *sent_pdu;
size_t sent_len;
struct l_key *private;
char *device_password;
uint8_t e_snonce1[16];
uint8_t e_snonce2[16];
uint8_t iv1[16];
uint8_t iv2[16];
uint8_t psk1[16];
uint8_t psk2[16];
uint8_t r_hash2[32];
enum state state;
struct l_checksum *hmac_auth_key;
struct l_cipher *aes_cbc_128;
uint8_t *rx_pdu_buf;
size_t rx_pdu_buf_len;
size_t rx_pdu_buf_offset;
size_t tx_frag_offset;
size_t tx_last_frag_len;
};
static inline void eap_wsc_state_set_sent_pdu(struct eap_wsc_state *wsc,
uint8_t *pdu, size_t len)
{
l_free(wsc->sent_pdu);
wsc->sent_pdu = pdu;
wsc->sent_len = len;
}
static inline bool authenticator_check(struct eap_wsc_state *wsc,
const uint8_t *pdu, size_t len)
{
uint8_t authenticator[8];
struct iovec iov[2];
iov[0].iov_base = wsc->sent_pdu;
iov[0].iov_len = wsc->sent_len;
iov[1].iov_base = (void *) pdu;
iov[1].iov_len = len - 12;
l_checksum_updatev(wsc->hmac_auth_key, iov, 2);
l_checksum_get_digest(wsc->hmac_auth_key, authenticator, 8);
/* Authenticator is the last 8 bytes of the message */
if (memcmp(authenticator, pdu + len - 8, 8))
return false;
return true;
}
static inline void authenticator_put(struct eap_wsc_state *wsc,
const uint8_t *prev_msg,
size_t prev_msg_len,
uint8_t *cur_msg, size_t cur_msg_len)
{
struct iovec iov[2];
iov[0].iov_base = (void *) prev_msg;
iov[0].iov_len = prev_msg_len;
iov[1].iov_base = cur_msg;
iov[1].iov_len = cur_msg_len - 12;
l_checksum_updatev(wsc->hmac_auth_key, iov, 2);
l_checksum_get_digest(wsc->hmac_auth_key, cur_msg + cur_msg_len - 8, 8);
}
static inline bool keywrap_authenticator_check(struct eap_wsc_state *wsc,
const uint8_t *pdu, size_t len)
{
uint8_t authenticator[8];
/* We omit the included KeyWrapAuthenticator element from the hash */
l_checksum_update(wsc->hmac_auth_key, pdu, len - 12);
l_checksum_get_digest(wsc->hmac_auth_key, authenticator, 8);
/* KeyWrapAuthenticator is the last 8 bytes of the message */
if (memcmp(authenticator, pdu + len - 8, 8))
return false;
return true;
}
static inline void keywrap_authenticator_put(struct eap_wsc_state *wsc,
uint8_t *pdu, size_t len)
{
l_checksum_update(wsc->hmac_auth_key, pdu, len - 12);
l_checksum_get_digest(wsc->hmac_auth_key, pdu + len - 8, 8);
}
static inline bool r_hash_check(struct eap_wsc_state *wsc,
uint8_t *r_snonce,
uint8_t *psk,
uint8_t *r_hash_expected)
{
struct iovec iov[4];
uint8_t r_hash[32];
/*
* WSC 2.0.5, Section 7.4:
* The Registrar creates two 128-bit secret nonces, R-S1, R-S2 and
* then computes
* R-Hash1 = HMACAuthKey(R-S1 || PSK1 || PKE || PKR)
* R-Hash2 = HMACAuthKey(R-S2 || PSK2 || PKE || PKR)
*/
iov[0].iov_base = r_snonce;
iov[0].iov_len = 16;
iov[1].iov_base = psk;
iov[1].iov_len = 16;
iov[2].iov_base = wsc->m1->public_key;
iov[2].iov_len = sizeof(wsc->m1->public_key);
iov[3].iov_base = wsc->m2->public_key;
iov[3].iov_len = sizeof(wsc->m2->public_key);
l_checksum_updatev(wsc->hmac_auth_key, iov, 4);
l_checksum_get_digest(wsc->hmac_auth_key, r_hash, sizeof(r_hash));
return !memcmp(r_hash, r_hash_expected, sizeof(r_hash));
}
static uint8_t *encrypted_settings_decrypt(struct eap_wsc_state *wsc,
const uint8_t *pdu,
size_t len,
size_t *out_len)
{
size_t encrypted_len;
uint8_t *decrypted;
unsigned int i;
uint8_t pad;
/* WSC 2.0.5, Section 12, Encrypted Settings:
* "The Data field of the Encrypted Settings attribute includes an
* initialization vector (IV) followed by a set of encrypted Wi-Fi
* Simple Configuration TLV attributes."
*
* Account for the IV being in the beginning 16 bytes
*/
if (len < 16 )
return NULL;
encrypted_len = len - 16;
if (encrypted_len < 16 || encrypted_len % 16)
return NULL;
decrypted = l_malloc(encrypted_len);
l_cipher_set_iv(wsc->aes_cbc_128, pdu, 16);
if (!l_cipher_decrypt(wsc->aes_cbc_128, pdu + 16,
decrypted, encrypted_len))
goto fail;
/* Check that the pad value is sane */
pad = decrypted[encrypted_len - 1];
if (pad > encrypted_len)
goto fail;
for (i = 0; i < pad; i++) {
if (decrypted[encrypted_len - pad + i] == pad)
continue;
goto fail;
}
*out_len = encrypted_len - pad;
return decrypted;
fail:
l_free(decrypted);
return NULL;
}
static bool encrypted_settings_encrypt(struct eap_wsc_state *wsc,
const uint8_t *iv,
const uint8_t *in,
size_t in_len,
uint8_t *out,
size_t *out_len)
{
size_t len = 0;
unsigned int i;
uint8_t pad;
l_cipher_set_iv(wsc->aes_cbc_128, iv, 16);
memcpy(out, iv, 16);
len += 16;
memcpy(out + len, in, in_len);
len += in_len;
pad = 16 - in_len % 16;
for (i = 0; i < pad; i++)
out[len++] = pad;
if (!l_cipher_encrypt(wsc->aes_cbc_128, out + 16, out + 16, len - 16))
return false;
*out_len = len;
return true;
}
static void eap_wsc_free(struct eap_state *eap)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
eap_set_data(eap, NULL);
l_free(wsc->device_password);
l_key_free(wsc->private);
l_free(wsc->sent_pdu);
wsc->sent_pdu = NULL;
wsc->sent_len = 0;
if (wsc->rx_pdu_buf) {
l_free(wsc->rx_pdu_buf);
wsc->rx_pdu_buf = NULL;
wsc->rx_pdu_buf_len = 0;
wsc->rx_pdu_buf_offset = 0;
}
l_checksum_free(wsc->hmac_auth_key);
l_cipher_free(wsc->aes_cbc_128);
l_free(wsc->m1);
l_free(wsc->m2);
l_free(wsc);
}
static void eap_wsc_send_fragment(struct eap_state *eap)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
size_t mtu = eap_get_mtu(eap);
uint8_t buf[mtu];
size_t len = wsc->sent_len - wsc->tx_frag_offset;
size_t header_len = EAP_WSC_HEADER_LEN;
buf[12] = WSC_OP_MSG;
if (len > mtu - EAP_WSC_HEADER_LEN) {
len = mtu - EAP_WSC_HEADER_LEN;
buf[13] = WSC_FLAG_MF;
} else {
buf[13] = 0;
}
if (!wsc->tx_frag_offset) {
buf[13] |= WSC_FLAG_LF;
l_put_be16(wsc->sent_len, &buf[14]);
len -= 2;
header_len += 2;
}
memcpy(buf + header_len, wsc->sent_pdu + wsc->tx_frag_offset, len);
eap_send_response(eap, EAP_TYPE_EXPANDED, buf, header_len + len);
wsc->tx_last_frag_len = len;
}
static void eap_wsc_send_response(struct eap_state *eap,
uint8_t *pdu, size_t pdu_len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
size_t msg_len = pdu_len + EAP_WSC_HEADER_LEN;
eap_wsc_state_set_sent_pdu(wsc, pdu, pdu_len);
if (msg_len <= eap_get_mtu(eap)) {
uint8_t buf[msg_len];
buf[12] = WSC_OP_MSG;
buf[13] = 0;
memcpy(buf + EAP_WSC_HEADER_LEN, pdu, pdu_len);
eap_send_response(eap, EAP_TYPE_EXPANDED, buf, msg_len);
return;
}
wsc->tx_frag_offset = 0;
eap_wsc_send_fragment(eap);
}
static void eap_wsc_send_nack(struct eap_state *eap,
enum wsc_configuration_error error)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
struct wsc_nack nack;
uint8_t *pdu;
size_t pdu_len;
uint8_t buf[256];
/*
* WSC 2.0.5, Table 34, Configuration Error 0 states:
* "- not valid for WSC_NACK except when a station acts as an External
* Registrar (to learn the current AP settings after M7 with
* configuration error = 0)"
*
* However, section 7.7.3 states:
* "Once M5 is sent, for example, if anything but M6 is received,
* the Enrollee will respond with a NACK message."
*
* Section 7.1 states:
* "If a message is received with either an invalid nonce or an invalid
* Authenticator attribute, the recipient shall silently ignore this
* message."
*
* So it is entirely unclear what to do in the situation of an
* out-of-order message being sent. To centralize decision making,
* callers will call this function with error 0.
*/
if (error == WSC_CONFIGURATION_ERROR_NO_ERROR)
return;
nack.version2 = true;
memcpy(nack.enrollee_nonce, wsc->m1->enrollee_nonce,
sizeof(nack.enrollee_nonce));
if (wsc->m2)
memcpy(nack.registrar_nonce, wsc->m2->registrar_nonce,
sizeof(nack.registrar_nonce));
else
memset(nack.registrar_nonce, 0, sizeof(nack.registrar_nonce));
nack.configuration_error = error;
pdu = wsc_build_wsc_nack(&nack, &pdu_len);
if (!pdu)
return;
buf[12] = WSC_OP_NACK;
buf[13] = 0;
memcpy(buf + EAP_WSC_HEADER_LEN, pdu, pdu_len);
eap_send_response(eap, EAP_TYPE_EXPANDED, buf,
pdu_len + EAP_WSC_HEADER_LEN);
l_free(pdu);
}
static void eap_wsc_send_done(struct eap_state *eap)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
struct wsc_done done;
uint8_t *pdu;
size_t pdu_len;
uint8_t buf[256];
done.version2 = true;
memcpy(done.enrollee_nonce, wsc->m1->enrollee_nonce,
sizeof(done.enrollee_nonce));
memcpy(done.registrar_nonce, wsc->m2->registrar_nonce,
sizeof(done.registrar_nonce));
pdu = wsc_build_wsc_done(&done, &pdu_len);
if (!pdu)
return;
buf[12] = WSC_OP_DONE;
buf[13] = 0;
memcpy(buf + EAP_WSC_HEADER_LEN, pdu, pdu_len);
eap_send_response(eap, EAP_TYPE_EXPANDED, buf,
pdu_len + EAP_WSC_HEADER_LEN);
l_free(pdu);
}
static void eap_wsc_send_frag_ack(struct eap_state *eap)
{
uint8_t buf[EAP_WSC_HEADER_LEN];
buf[12] = WSC_OP_FRAG_ACK;
buf[13] = 0;
eap_send_response(eap, EAP_TYPE_EXPANDED, buf, EAP_WSC_HEADER_LEN);
}
static void eap_wsc_handle_m8(struct eap_state *eap,
const uint8_t *pdu, size_t len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
struct wsc_m8 m8;
struct iovec encrypted;
uint8_t *decrypted;
size_t decrypted_len;
struct wsc_m8_encrypted_settings m8es;
struct iovec creds[3];
size_t n_creds;
size_t i;
/* Spec unclear what to do here, see comments in eap_wsc_send_nack */
if (wsc_parse_m8(pdu, len, &m8, &encrypted) != 0) {
eap_wsc_send_nack(eap, WSC_CONFIGURATION_ERROR_NO_ERROR);
return;
}
if (!authenticator_check(wsc, pdu, len))
return;
decrypted = encrypted_settings_decrypt(wsc, encrypted.iov_base,
encrypted.iov_len,
&decrypted_len);
if (!decrypted)
goto send_nack;
n_creds = L_ARRAY_SIZE(creds);
if (wsc_parse_m8_encrypted_settings(decrypted, decrypted_len,
&m8es, creds, &n_creds))
goto invalid_settings;
if (!keywrap_authenticator_check(wsc, decrypted, decrypted_len))
goto invalid_settings;
for (i = 0; i < n_creds; i++) {
struct wsc_credential cred;
if (wsc_parse_credential(creds[i].iov_base, creds[i].iov_len,
&cred) != 0)
continue;
eap_method_event(eap, EAP_WSC_EVENT_CREDENTIAL_OBTAINED, &cred);
}
l_free(decrypted);
eap_wsc_send_done(eap);
wsc->state = STATE_FINISHED;
return;
invalid_settings:
l_free(decrypted);
send_nack:
eap_wsc_send_nack(eap, WSC_CONFIGURATION_ERROR_DECRYPTION_CRC_FAILURE);
}
static void eap_wsc_send_m7(struct eap_state *eap,
const uint8_t *m6_pdu, size_t m6_len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
struct wsc_m7_encrypted_settings m7es;
struct wsc_m7 m7;
uint8_t *pdu;
size_t pdu_len;
/* 20 for SNonce, 12 for Authenticator, 16 for IV + up to 16 pad */
uint8_t encrypted[64];
size_t encrypted_len;
bool r;
memcpy(m7es.e_snonce2, wsc->e_snonce2, sizeof(wsc->e_snonce2));
pdu = wsc_build_m7_encrypted_settings(&m7es, &pdu_len);
if (!pdu)
return;
keywrap_authenticator_put(wsc, pdu, pdu_len);
r = encrypted_settings_encrypt(wsc, wsc->iv2, pdu, pdu_len,
encrypted, &encrypted_len);
l_free(pdu);
if (!r)
return;
m7.version2 = true;
memcpy(m7.registrar_nonce, wsc->m2->registrar_nonce,
sizeof(m7.registrar_nonce));
pdu = wsc_build_m7(&m7, encrypted, encrypted_len, &pdu_len);
if (!pdu)
return;
authenticator_put(wsc, m6_pdu, m6_len, pdu, pdu_len);
eap_wsc_send_response(eap, pdu, pdu_len);
wsc->state = STATE_EXPECT_M8;
}
static void eap_wsc_handle_m6(struct eap_state *eap,
const uint8_t *pdu, size_t len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
struct wsc_m6 m6;
struct iovec encrypted;
uint8_t *decrypted;
size_t decrypted_len;
struct wsc_m6_encrypted_settings m6es;
/* Spec unclear what to do here, see comments in eap_wsc_send_nack */
if (wsc_parse_m6(pdu, len, &m6, &encrypted) != 0) {
eap_wsc_send_nack(eap, WSC_CONFIGURATION_ERROR_NO_ERROR);
return;
}
if (!authenticator_check(wsc, pdu, len))
return;
decrypted = encrypted_settings_decrypt(wsc, encrypted.iov_base,
encrypted.iov_len,
&decrypted_len);
if (!decrypted)
goto send_nack;
if (wsc_parse_m6_encrypted_settings(decrypted, decrypted_len, &m6es))
goto invalid_settings;
if (!keywrap_authenticator_check(wsc, decrypted, decrypted_len))
goto invalid_settings;
l_free(decrypted);
/* We now have R-SNonce2, verify R-Hash2 stored in eap_wsc_handle_m4 */
if (!r_hash_check(wsc, m6es.r_snonce2, wsc->psk2, wsc->r_hash2)) {
eap_wsc_send_nack(eap,
WSC_CONFIGURATION_ERROR_DEVICE_PASSWORD_AUTH_FAILURE);
return;
}
eap_wsc_send_m7(eap, pdu, len);
return;
invalid_settings:
l_free(decrypted);
send_nack:
eap_wsc_send_nack(eap, WSC_CONFIGURATION_ERROR_DECRYPTION_CRC_FAILURE);
}
static void eap_wsc_send_m5(struct eap_state *eap,
const uint8_t *m4_pdu, size_t m4_len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
struct wsc_m5_encrypted_settings m5es;
struct wsc_m5 m5;
uint8_t *pdu;
size_t pdu_len;
/* 20 for SNonce, 12 for Authenticator, 16 for IV + up to 16 pad */
uint8_t encrypted[64];
size_t encrypted_len;
bool r;
memcpy(m5es.e_snonce1, wsc->e_snonce1, sizeof(wsc->e_snonce1));
pdu = wsc_build_m5_encrypted_settings(&m5es, &pdu_len);
if (!pdu)
return;
keywrap_authenticator_put(wsc, pdu, pdu_len);
r = encrypted_settings_encrypt(wsc, wsc->iv1, pdu, pdu_len,
encrypted, &encrypted_len);
l_free(pdu);
if (!r)
return;
m5.version2 = true;
memcpy(m5.registrar_nonce, wsc->m2->registrar_nonce,
sizeof(m5.registrar_nonce));
pdu = wsc_build_m5(&m5, encrypted, encrypted_len, &pdu_len);
if (!pdu)
return;
authenticator_put(wsc, m4_pdu, m4_len, pdu, pdu_len);
eap_wsc_send_response(eap, pdu, pdu_len);
wsc->state = STATE_EXPECT_M6;
}
static void eap_wsc_handle_m4(struct eap_state *eap,
const uint8_t *pdu, size_t len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
struct wsc_m4 m4;
struct iovec encrypted;
uint8_t *decrypted;
size_t decrypted_len;
struct wsc_m4_encrypted_settings m4es;
/* Spec unclear what to do here, see comments in eap_wsc_send_nack */
if (wsc_parse_m4(pdu, len, &m4, &encrypted) != 0) {
eap_wsc_send_nack(eap, WSC_CONFIGURATION_ERROR_NO_ERROR);
return;
}
if (!authenticator_check(wsc, pdu, len))
return;
decrypted = encrypted_settings_decrypt(wsc, encrypted.iov_base,
encrypted.iov_len,
&decrypted_len);
if (!decrypted)
goto send_nack;
if (wsc_parse_m4_encrypted_settings(decrypted, decrypted_len, &m4es))
goto invalid_settings;
if (!keywrap_authenticator_check(wsc, decrypted, decrypted_len))
goto invalid_settings;
l_free(decrypted);
/* Since we have obtained R-SNonce1, we can now verify R-Hash1. */
if (!r_hash_check(wsc, m4es.r_snonce1, wsc->psk1, m4.r_hash1)) {
eap_wsc_send_nack(eap,
WSC_CONFIGURATION_ERROR_DEVICE_PASSWORD_AUTH_FAILURE);
return;
}
/* Now store R_Hash2 so we can verify it when we receive M6 */
memcpy(wsc->r_hash2, m4.r_hash2, sizeof(m4.r_hash2));
eap_wsc_send_m5(eap, pdu, len);
return;
invalid_settings:
l_free(decrypted);
send_nack:
eap_wsc_send_nack(eap, WSC_CONFIGURATION_ERROR_DECRYPTION_CRC_FAILURE);
}
static void eap_wsc_send_m3(struct eap_state *eap,
const uint8_t *m2_pdu, size_t m2_len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
struct wsc_m2 *m2 = wsc->m2;
size_t len;
size_t len_half1;
struct wsc_m3 m3;
struct iovec iov[4];
uint8_t *pdu;
size_t pdu_len;
len = strlen(wsc->device_password);
/* WSC 2.0.5, Section 7.4:
* In case the UTF8 representation of the DevicePassword length is an
* odd number (N), the first half of DevicePassword will have length
* of N/2+1 and the second half of the DevicePassword will have length
* of N/2.
*/
len_half1 = len / 2;
if ((len % 2) == 1)
len_half1 += 1;
l_checksum_update(wsc->hmac_auth_key, wsc->device_password, len_half1);
l_checksum_get_digest(wsc->hmac_auth_key, wsc->psk1, sizeof(wsc->psk1));
l_checksum_update(wsc->hmac_auth_key, wsc->device_password + len_half1,
len / 2);
l_checksum_get_digest(wsc->hmac_auth_key, wsc->psk2, sizeof(wsc->psk2));
m3.version2 = true;
memcpy(m3.registrar_nonce, m2->registrar_nonce,
sizeof(m3.registrar_nonce));
/* WSC 2.0.5, Section 7.4:
* The Enrollee creates two 128-bit secret nonces, E-S1, E-S2 and then
* computes:
* E-Hash1 = HMACAuthKey(E-S1 || PSK1 || PKE || PKR)
* E-Hash2 = HMACAuthKey(E-S2 || PSK2 || PKE || PKR)
*/
iov[0].iov_base = wsc->e_snonce1;
iov[0].iov_len = sizeof(wsc->e_snonce1);
iov[1].iov_base = wsc->psk1;
iov[1].iov_len = sizeof(wsc->psk1);
iov[2].iov_base = wsc->m1->public_key;
iov[2].iov_len = sizeof(wsc->m1->public_key);
iov[3].iov_base = m2->public_key;
iov[3].iov_len = sizeof(m2->public_key);
l_checksum_updatev(wsc->hmac_auth_key, iov, 4);
l_checksum_get_digest(wsc->hmac_auth_key,
m3.e_hash1, sizeof(m3.e_hash1));
iov[0].iov_base = wsc->e_snonce2;
iov[0].iov_len = sizeof(wsc->e_snonce2);
iov[1].iov_base = wsc->psk2;
iov[1].iov_len = sizeof(wsc->psk2);
l_checksum_updatev(wsc->hmac_auth_key, iov, 4);
l_checksum_get_digest(wsc->hmac_auth_key,
m3.e_hash2, sizeof(m3.e_hash2));
pdu = wsc_build_m3(&m3, &pdu_len);
if (!pdu)
return;
authenticator_put(wsc, m2_pdu, m2_len, pdu, pdu_len);
eap_wsc_send_response(eap, pdu, pdu_len);
wsc->state = STATE_EXPECT_M4;
}
static void eap_wsc_handle_m2(struct eap_state *eap,
const uint8_t *pdu, size_t len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
struct l_key *remote_public;
uint8_t shared_secret[192];
size_t shared_secret_len = sizeof(shared_secret);
struct l_checksum *sha256;
uint8_t dhkey[32];
struct l_checksum *hmac_sha256;
struct iovec iov[3];
uint8_t kdk[32];
struct wsc_session_key keys;
bool r;
/* TODO: Check to see if message is M2D first */
if (!wsc->m2)
wsc->m2 = l_new(struct wsc_m2, 1);
/* Spec unclear what to do here, see comments in eap_wsc_send_nack */
if (wsc_parse_m2(pdu, len, wsc->m2) != 0) {
eap_wsc_send_nack(eap, WSC_CONFIGURATION_ERROR_NO_ERROR);
return;
}
remote_public = l_key_new(L_KEY_RAW, wsc->m2->public_key,
sizeof(wsc->m2->public_key));
if (!remote_public)
return;
r = l_key_compute_dh_secret(remote_public, wsc->private, dh5_prime,
shared_secret, &shared_secret_len);
l_key_free(remote_public);
if (!r)
return;
sha256 = l_checksum_new(L_CHECKSUM_SHA256);
if (!sha256)
return;
l_checksum_update(sha256, shared_secret, shared_secret_len);
l_checksum_get_digest(sha256, dhkey, sizeof(dhkey));
l_checksum_free(sha256);
memset(shared_secret, 0, shared_secret_len);
hmac_sha256 = l_checksum_new_hmac(L_CHECKSUM_SHA256,
dhkey, sizeof(dhkey));
memset(dhkey, 0, sizeof(dhkey));
if (!hmac_sha256)
return;
iov[0].iov_base = wsc->m1->enrollee_nonce;
iov[0].iov_len = 16;
iov[1].iov_base = wsc->m1->addr;
iov[1].iov_len = 6;
iov[2].iov_base = wsc->m2->registrar_nonce;
iov[2].iov_len = 16;
l_checksum_updatev(hmac_sha256, iov, 3);
l_checksum_get_digest(hmac_sha256, kdk, sizeof(kdk));
l_checksum_free(hmac_sha256);
r = wsc_kdf(kdk, &keys, sizeof(keys));
memset(kdk, 0, sizeof(kdk));
if (!r)
return;
wsc->hmac_auth_key = l_checksum_new_hmac(L_CHECKSUM_SHA256,
keys.auth_key,
sizeof(keys.auth_key));
if (!authenticator_check(wsc, pdu, len)) {
l_checksum_free(wsc->hmac_auth_key);
wsc->hmac_auth_key = NULL;
goto clear_keys;
}
/* Everything checks out, lets build M3 */
eap_wsc_send_m3(eap, pdu, len);
/*
* AuthKey is uploaded into the kernel, once we upload KeyWrapKey,
* the keys variable is no longer useful. Make sure to wipe it
*/
wsc->aes_cbc_128 = l_cipher_new(L_CIPHER_AES_CBC, keys.keywrap_key,
sizeof(keys.keywrap_key));
clear_keys:
memset(&keys, 0, sizeof(keys));
}
static void eap_wsc_handle_nack(struct eap_state *eap,
const uint8_t *pdu, size_t len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
struct wsc_nack nack;
if (wsc_parse_wsc_nack(pdu, len, &nack) != 0)
return;
if (memcmp(nack.enrollee_nonce, wsc->m1->enrollee_nonce,
sizeof(nack.enrollee_nonce)))
return;
if (!wsc->m2)
return;
if (memcmp(nack.registrar_nonce, wsc->m2->registrar_nonce,
sizeof(nack.registrar_nonce)))
return;
/*
* The spec is completely unclear what the NACK error should be set
* to. Our choice is to reflect back what the request error code is
* in the response.
*/
eap_wsc_send_nack(eap, nack.configuration_error);
}
static void eap_wsc_handle_request(struct eap_state *eap,
const uint8_t *pkt, size_t len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
uint8_t op;
uint8_t flags;
uint8_t *pdu;
size_t pdu_len;
size_t rx_header_offset = 0;
if (len < 2)
return;
op = pkt[0];
flags = pkt[1];
pkt += 2;
len -= 2;
switch (op) {
case WSC_OP_START:
if (len)
return;
if (wsc->state != STATE_EXPECT_START)
return;
pdu = wsc_build_m1(wsc->m1, &pdu_len);
if (!pdu)
return;
eap_wsc_send_response(eap, pdu, pdu_len);
wsc->state = STATE_EXPECT_M2;
return;
case WSC_OP_NACK:
if (!len)
return;
eap_wsc_handle_nack(eap, pkt, len);
return;
case WSC_OP_ACK:
case WSC_OP_DONE:
/* Should never receive these as Enrollee */
return;
case WSC_OP_FRAG_ACK:
if (wsc->tx_last_frag_len &&
(wsc->tx_frag_offset + wsc->tx_last_frag_len) <
wsc->sent_len) {
wsc->tx_frag_offset += wsc->tx_last_frag_len;
wsc->tx_last_frag_len = 0;
eap_wsc_send_fragment(eap);
}
return;
case WSC_OP_MSG:
if (flags & WSC_FLAG_LF) {
if (wsc->rx_pdu_buf ||
!(flags & WSC_FLAG_MF) || len < 2)
goto invalid_frag;
wsc->rx_pdu_buf_len = l_get_be16(pkt);
if (!wsc->rx_pdu_buf_len ||
wsc->rx_pdu_buf_len >
EAP_WSC_PDU_MAX_LEN) {
l_warn("Fragmented pkt size is outside of "
"alowed boundaries [1, %u]",
EAP_WSC_PDU_MAX_LEN);
return;
}
if (wsc->rx_pdu_buf_len < len) {
l_warn("Fragmented pkt size is smaller than "
"the received packet");
return;
}
wsc->rx_pdu_buf = l_malloc(wsc->rx_pdu_buf_len);
wsc->rx_pdu_buf_offset = 0;
rx_header_offset = 2;
}
if (wsc->rx_pdu_buf) {
pdu_len = len - rx_header_offset;
if (wsc->rx_pdu_buf_len <
(wsc->rx_pdu_buf_offset + pdu_len)) {
l_error("Request fragment pkt size mismatch");
goto invalid_frag;
}
memcpy(wsc->rx_pdu_buf + wsc->rx_pdu_buf_offset,
pkt + rx_header_offset, pdu_len);
wsc->rx_pdu_buf_offset += pdu_len;
}
if (flags & WSC_FLAG_MF) {
if (!wsc->rx_pdu_buf) {
eap_method_error(eap);
return;
}
eap_wsc_send_frag_ack(eap);
return;
} else if (wsc->rx_pdu_buf) {
if (wsc->rx_pdu_buf_len != wsc->rx_pdu_buf_offset) {
l_error("Request fragment pkt size mismatch");
goto invalid_frag;
}
pkt = wsc->rx_pdu_buf;
len = wsc->rx_pdu_buf_len;
}
break;
}
if (!len)
return;
switch (wsc->state) {
case STATE_EXPECT_START:
return;
case STATE_EXPECT_M2:
eap_wsc_handle_m2(eap, pkt, len);
break;
case STATE_EXPECT_M4:
eap_wsc_handle_m4(eap, pkt, len);
break;
case STATE_EXPECT_M6:
eap_wsc_handle_m6(eap, pkt, len);
break;
case STATE_EXPECT_M8:
eap_wsc_handle_m8(eap, pkt, len);
break;
case STATE_FINISHED:
eap_wsc_send_nack(eap, WSC_CONFIGURATION_ERROR_NO_ERROR);
return;
}
if (wsc->rx_pdu_buf) {
l_free(wsc->rx_pdu_buf);
wsc->rx_pdu_buf = NULL;
wsc->rx_pdu_buf_len = 0;
wsc->rx_pdu_buf_offset = 0;
}
return;
invalid_frag:
eap_method_error(eap);
}
static void eap_wsc_handle_retransmit(struct eap_state *eap,
const uint8_t *pkt, size_t len)
{
struct eap_wsc_state *wsc = eap_get_data(eap);
uint8_t op;
uint8_t flags;
if (len < 2)
return;
op = pkt[0];
switch (op) {
case WSC_OP_NACK:
eap_wsc_handle_nack(eap, pkt + 2, len - 2);
return;
case WSC_OP_ACK:
case WSC_OP_DONE:
/* Should never receive these as Enrollee */
return;
case WSC_OP_MSG:
flags = pkt[1];
if (flags & WSC_FLAG_MF) {
if (!wsc->rx_pdu_buf) {
eap_method_error(eap);
return;
}
eap_wsc_send_frag_ack(eap);
return;
}
}
if (!wsc->sent_pdu || !wsc->sent_len) {
eap_method_error(eap);
return;
}
if (wsc->sent_len + EAP_WSC_HEADER_LEN > eap_get_mtu(eap)) {
eap_wsc_send_fragment(eap);
} else {
size_t msg_len = wsc->sent_len + EAP_WSC_HEADER_LEN;
uint8_t buf[msg_len];
buf[12] = WSC_OP_MSG;
buf[13] = 0;
memcpy(buf + EAP_WSC_HEADER_LEN, wsc->sent_pdu, wsc->sent_len);
eap_send_response(eap, EAP_TYPE_EXPANDED, buf, msg_len);
}
}
static bool load_hexencoded(struct l_settings *settings, const char *key,
uint8_t *to, size_t len)
{
const char *v;
size_t decoded_len;
unsigned char *decoded;
v = l_settings_get_value(settings, "WSC", key);
if (!v)
return false;
decoded = l_util_from_hexstring(v, &decoded_len);
if (!decoded)
return false;
if (decoded_len != len) {
l_free(decoded);
return false;
}
memcpy(to, decoded, len);
l_free(decoded);
return true;
}
static bool load_primary_device_type(struct l_settings *settings,
struct wsc_primary_device_type *pdt)
{
const char *v;
int r;
v = l_settings_get_value(settings, "WSC", "PrimaryDeviceType");
if (!v)
return false;
r = sscanf(v, "%hx-%2hhx%2hhx%2hhx%2hhx-%2hx", &pdt->category,
&pdt->oui[0], &pdt->oui[1], &pdt->oui[2],
&pdt->oui_type, &pdt->subcategory);
if (r != 6)
return false;
return true;
}
static bool load_constrained_string(struct l_settings *settings,
const char *key,
char *out, size_t max)
{
char *v;
size_t tocopy;
v = l_settings_get_string(settings, "WSC", key);
if (!v)
return false;
tocopy = strlen(v);
if (tocopy >= max)
tocopy = max - 1;
memcpy(out, v, tocopy);
out[max - 1] = '\0';
l_free(v);
return true;
}
static bool eap_wsc_load_settings(struct eap_state *eap,
struct l_settings *settings,
const char *prefix)
{
struct eap_wsc_state *wsc;
const char *v;
uint8_t private_key[192];
size_t len;
unsigned int u32;
const char *device_password;
wsc = l_new(struct eap_wsc_state, 1);
wsc->m1 = l_new(struct wsc_m1, 1);
wsc->m1->version2 = true;
v = l_settings_get_value(settings, "WSC", "EnrolleeMAC");
if (!v)
goto err;
if (!util_string_to_address(v, wsc->m1->addr))
goto err;
if (!wsc_uuid_from_addr(wsc->m1->addr, wsc->m1->uuid_e))
goto err;
if (!load_hexencoded(settings, "EnrolleeNonce",
wsc->m1->enrollee_nonce, 16))
l_getrandom(wsc->m1->enrollee_nonce, 16);
if (!load_hexencoded(settings, "PrivateKey", private_key, 192))
l_getrandom(private_key, 192);
wsc->private = l_key_new(L_KEY_RAW, private_key, 192);
memset(private_key, 0, 192);
if (!wsc->private)
goto err;
len = sizeof(wsc->m1->public_key);
if (!l_key_compute_dh_public(dh5_generator, wsc->private, dh5_prime,
wsc->m1->public_key, &len))
goto err;
if (len != sizeof(wsc->m1->public_key))
goto err;
wsc->m1->auth_type_flags = WSC_AUTHENTICATION_TYPE_WPA2_PERSONAL |
WSC_AUTHENTICATION_TYPE_WPA_PERSONAL |
WSC_AUTHENTICATION_TYPE_OPEN;
wsc->m1->encryption_type_flags = WSC_ENCRYPTION_TYPE_NONE |
WSC_ENCRYPTION_TYPE_AES_TKIP;
wsc->m1->connection_type_flags = WSC_CONNECTION_TYPE_ESS;
if (!l_settings_get_uint(settings, "WSC",
"ConfigurationMethods", &u32))
u32 = WSC_CONFIGURATION_METHOD_VIRTUAL_DISPLAY_PIN;
wsc->m1->config_methods = u32;
wsc->m1->state = WSC_STATE_NOT_CONFIGURED;
if (!load_constrained_string(settings, "Manufacturer",
wsc->m1->manufacturer, sizeof(wsc->m1->manufacturer)))
strcpy(wsc->m1->manufacturer, " ");
if (!load_constrained_string(settings, "ModelName",
wsc->m1->model_name, sizeof(wsc->m1->model_name)))
strcpy(wsc->m1->model_name, " ");
if (!load_constrained_string(settings, "ModelNumber",
wsc->m1->model_number, sizeof(wsc->m1->model_number)))
strcpy(wsc->m1->model_number, " ");
if (!load_constrained_string(settings, "SerialNumber",
wsc->m1->serial_number, sizeof(wsc->m1->serial_number)))
strcpy(wsc->m1->serial_number, " ");
if (!load_primary_device_type(settings,
&wsc->m1->primary_device_type)) {
/* Make ourselves a WFA standard PC by default */
wsc->m1->primary_device_type.category = 1;
memcpy(wsc->m1->primary_device_type.oui, wsc_wfa_oui, 3);
wsc->m1->primary_device_type.oui_type = 0x04;
wsc->m1->primary_device_type.subcategory = 1;
}
if (!load_constrained_string(settings, "DeviceName",
wsc->m1->device_name, sizeof(wsc->m1->device_name)))
strcpy(wsc->m1->device_name, " ");
if (!l_settings_get_uint(settings, "WSC", "RFBand", &u32))
goto err;
switch (u32) {
case WSC_RF_BAND_2_4_GHZ:
case WSC_RF_BAND_5_0_GHZ:
case WSC_RF_BAND_60_GHZ:
wsc->m1->rf_bands = u32;
break;
default:
goto err;
}
wsc->m1->association_state = WSC_ASSOCIATION_STATE_NOT_ASSOCIATED;
wsc->m1->configuration_error = WSC_CONFIGURATION_ERROR_NO_ERROR;
if (!l_settings_get_uint(settings, "WSC",
"OSVersion", &u32))
u32 = 0;
wsc->m1->os_version = u32 & 0x7fffffff;
if (!l_settings_get_uint(settings, "WSC", "DevicePasswordId", &u32))
u32 = WSC_DEVICE_PASSWORD_ID_PUSH_BUTTON;
wsc->m1->device_password_id = u32;
device_password = l_settings_get_string(settings, "WSC",
"DevicePassword");
if (device_password) {
int i;
for (i = 0; device_password[i]; i++) {
if (!l_ascii_isxdigit(device_password[i]))
goto err;
}
if (i < 8)
goto err;
wsc->device_password = strdup(device_password);
/*
* WSC 2.0.5: Section 7.4:
* If an out-of-band mechanism is used as the configuration
* method, the device password is expressed in hexadecimal
* using ASCII character (two characters per octet, uppercase
* letters only).
*/
for (i = 0; wsc->device_password[i]; i++) {
if (wsc->device_password[i] >= 'a' &&
wsc->device_password[i] <= 'f')
wsc->device_password[i] =
'A' + wsc->device_password[i] - 'a';
}
} else
wsc->device_password = strdup("00000000");
if (!load_hexencoded(settings, "E-SNonce1", wsc->e_snonce1, 16))
l_getrandom(wsc->e_snonce1, 16);
if (!load_hexencoded(settings, "E-SNonce2", wsc->e_snonce2, 16))
l_getrandom(wsc->e_snonce2, 16);
if (!load_hexencoded(settings, "IV1", wsc->iv1, 16))
l_getrandom(wsc->iv1, 16);
if (!load_hexencoded(settings, "IV2", wsc->iv2, 16))
l_getrandom(wsc->iv2, 16);
eap_set_data(eap, wsc);
return true;
err:
l_free(wsc->device_password);
if (wsc->private)
l_key_free(wsc->private);
l_free(wsc->m1);
l_free(wsc);
return false;
}
static struct eap_method eap_wsc = {
.vendor_id = { 0x00, 0x37, 0x2a },
.vendor_type = 0x00000001,
.request_type = EAP_TYPE_EXPANDED,
.exports_msk = true,
.name = "WSC",
.free = eap_wsc_free,
.handle_request = eap_wsc_handle_request,
.handle_retransmit = eap_wsc_handle_retransmit,
.load_settings = eap_wsc_load_settings,
};
static int eap_wsc_init(void)
{
int r = -ENOTSUP;
l_debug("");
dh5_generator = l_key_new(L_KEY_RAW, crypto_dh5_generator,
crypto_dh5_generator_size);
if (!dh5_generator)
goto fail_generator;
dh5_prime = l_key_new(L_KEY_RAW, crypto_dh5_prime,
crypto_dh5_prime_size);
if (!dh5_prime)
goto fail_prime;
r = eap_register_method(&eap_wsc);
if (!r)
return 0;
l_key_free(dh5_prime);
dh5_prime = NULL;
fail_prime:
l_key_free(dh5_generator);
dh5_generator = NULL;
fail_generator:
return r;
}
static void eap_wsc_exit(void)
{
l_debug("");
eap_unregister_method(&eap_wsc);
l_key_free(dh5_prime);
l_key_free(dh5_generator);
}
EAP_METHOD_BUILTIN(eap_wsc, eap_wsc_init, eap_wsc_exit)