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dtls.c
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dtls.c
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/*******************************************************************************
*
* Copyright (c) 2011, 2012, 2013, 2014, 2015 Olaf Bergmann (TZI) and others.
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0
* and Eclipse Distribution License v. 1.0 which accompanies this distribution.
*
* The Eclipse Public License is available at http://www.eclipse.org/legal/epl-v10.html
* and the Eclipse Distribution License is available at
* http://www.eclipse.org/org/documents/edl-v10.php.
*
* Contributors:
* Olaf Bergmann - initial API and implementation
* Hauke Mehrtens - memory optimization, ECC integration
* Achim Kraus - session recovery
* Sachin Agrawal - rehandshake support
*
*******************************************************************************/
#include "tinydtls.h"
#include "dtls_time.h"
#include <stdio.h>
#include <stdlib.h>
#ifdef HAVE_ASSERT_H
#include <assert.h>
#endif
#ifndef WITH_CONTIKI
#include <stdlib.h>
#include "global.h"
#endif /* WITH_CONTIKI */
#ifdef HAVE_INTTYPES_H
#define __STDC_FORMAT_MACROS
#include <inttypes.h>
#else
# ifndef PRIu64
# define PRIu64 "llu"
# endif
# ifndef PRIx64
# define PRIx64 "llx"
# endif
#endif /* HAVE_INTTYPES_H */
#include "utlist.h"
#ifndef DTLS_PEERS_NOHASH
#include "uthash.h"
#endif /* DTLS_PEERS_NOHASH */
#include "dtls_debug.h"
#include "numeric.h"
#include "netq.h"
#include "dtls.h"
#include "alert.h"
#include "session.h"
#include "dtls_prng.h"
#ifdef WITH_SHA256
# include "hmac.h"
#endif /* WITH_SHA256 */
#define DTLS10_VERSION 0xfeff
#ifdef RIOT_VERSION
# include <memarray.h>
dtls_context_t dtlscontext_storage_data[DTLS_CONTEXT_MAX];
memarray_t dtlscontext_storage;
#endif /* RIOT_VERSION */
#define dtls_set_version(H,V) dtls_int_to_uint16((H)->version, (V))
#define dtls_set_content_type(H,V) ((H)->content_type = (V) & 0xff)
#define dtls_set_length(H,V) ((H)->length = (V))
#define dtls_get_content_type(H) ((H)->content_type & 0xff)
#define dtls_get_version(H) dtls_uint16_to_int((H)->version)
#define dtls_get_epoch(H) dtls_uint16_to_int((H)->epoch)
#define dtls_get_sequence_number(H) dtls_uint48_to_ulong((H)->sequence_number)
#define dtls_get_fragment_length(H) dtls_uint24_to_int((H)->fragment_length)
#ifdef DTLS_PEERS_NOHASH
#define FIND_PEER(head,sess,out) \
do { \
dtls_peer_t * tmp; \
(out) = NULL; \
LL_FOREACH((head), tmp) { \
if (dtls_session_equals(&tmp->session, (sess))) { \
(out) = tmp; \
break; \
} \
} \
} while (0)
#define DEL_PEER(head,delptr) \
if ((head) != NULL && (delptr) != NULL) { \
LL_DELETE(head,delptr); \
}
#define ADD_PEER(head,sess,add) \
LL_PREPEND(ctx->peers, peer);
#else /* DTLS_PEERS_NOHASH */
#define FIND_PEER(head,sess,out) \
HASH_FIND(hh,head,sess,sizeof(session_t),out)
#define ADD_PEER(head,sess,add) \
HASH_ADD(hh,head,sess,sizeof(session_t),add)
#define DEL_PEER(head,delptr) \
if ((head) != NULL && (delptr) != NULL) { \
HASH_DELETE(hh,head,delptr); \
}
#endif /* DTLS_PEERS_NOHASH */
#define DTLS_RH_LENGTH sizeof(dtls_record_header_t)
#define DTLS_HS_LENGTH sizeof(dtls_handshake_header_t)
#define DTLS_CH_LENGTH sizeof(dtls_client_hello_t) /* no variable length fields! */
#define DTLS_COOKIE_LENGTH_MAX 32
#define DTLS_CH_LENGTH_MAX sizeof(dtls_client_hello_t) + DTLS_COOKIE_LENGTH_MAX + 12 + 26
#define DTLS_HV_LENGTH sizeof(dtls_hello_verify_t)
#define DTLS_SH_LENGTH (2 + DTLS_RANDOM_LENGTH + 1 + 2 + 1)
#define DTLS_CE_LENGTH (3 + 3 + 27 + DTLS_EC_KEY_SIZE + DTLS_EC_KEY_SIZE)
#define DTLS_SKEXEC_LENGTH (1 + 2 + 1 + 1 + DTLS_EC_KEY_SIZE + DTLS_EC_KEY_SIZE + 1 + 1 + 2 + 70)
#define DTLS_SKEXECPSK_LENGTH_MIN 2
#define DTLS_SKEXECPSK_LENGTH_MAX 2 + DTLS_PSK_MAX_CLIENT_IDENTITY_LEN
#define DTLS_CKXPSK_LENGTH_MIN 2
#define DTLS_CKXEC_LENGTH (1 + 1 + DTLS_EC_KEY_SIZE + DTLS_EC_KEY_SIZE)
#define DTLS_CV_LENGTH (1 + 1 + 2 + 1 + 1 + 1 + 1 + DTLS_EC_KEY_SIZE + 1 + 1 + DTLS_EC_KEY_SIZE)
#define DTLS_FIN_LENGTH 12
#define HS_HDR_LENGTH DTLS_RH_LENGTH + DTLS_HS_LENGTH
#define HV_HDR_LENGTH HS_HDR_LENGTH + DTLS_HV_LENGTH
#define HIGH(V) (((V) >> 8) & 0xff)
#define LOW(V) ((V) & 0xff)
#define DTLS_RECORD_HEADER(M) ((dtls_record_header_t *)(M))
#define DTLS_HANDSHAKE_HEADER(M) ((dtls_handshake_header_t *)(M))
#define HANDSHAKE(M) ((dtls_handshake_header_t *)((M) + DTLS_RH_LENGTH))
#define CLIENTHELLO(M) ((dtls_client_hello_t *)((M) + HS_HDR_LENGTH))
/* The length check here should work because dtls_*_to_int() works on
* unsigned char. Otherwise, broken messages could cause severe
* trouble. Note that this macro jumps out of the current program flow
* when the message is too short. Beware!
*/
#define SKIP_VAR_FIELD(P,L,T) { \
if (L < dtls_ ## T ## _to_int(P) + sizeof(T)) \
goto error; \
L -= dtls_ ## T ## _to_int(P) + sizeof(T); \
P += dtls_ ## T ## _to_int(P) + sizeof(T); \
}
/* some constants for the PRF */
#define PRF_LABEL(Label) prf_label_##Label
#define PRF_LABEL_SIZE(Label) (sizeof(PRF_LABEL(Label)) - 1)
static const unsigned char prf_label_master[] = "master secret";
static const unsigned char prf_label_key[] = "key expansion";
static const unsigned char prf_label_client[] = "client";
static const unsigned char prf_label_server[] = "server";
static const unsigned char prf_label_finished[] = " finished";
#ifdef DTLS_ECC
/* first part of Raw public key, the is the start of the Subject Public Key */
static const unsigned char cert_asn1_header[] = {
0x30, 0x59, /* SEQUENCE, length 89 bytes */
0x30, 0x13, /* SEQUENCE, length 19 bytes */
0x06, 0x07, /* OBJECT IDENTIFIER ecPublicKey (1 2 840 10045 2 1) */
0x2A, 0x86, 0x48, 0xCE, 0x3D, 0x02, 0x01,
0x06, 0x08, /* OBJECT IDENTIFIER prime256v1 (1 2 840 10045 3 1 7) */
0x2A, 0x86, 0x48, 0xCE, 0x3D, 0x03, 0x01, 0x07,
0x03, 0x42, 0x00, /* BIT STRING, length 66 bytes, 0 bits unused */
0x04 /* uncompressed, followed by the r und s values of the public key */
};
#endif /* DTLS_ECC */
#ifdef WITH_CONTIKI
PROCESS(dtls_retransmit_process, "DTLS retransmit process");
static dtls_context_t the_dtls_context;
static inline dtls_context_t *
malloc_context(void) {
return &the_dtls_context;
}
static inline void
free_context(dtls_context_t *context) {
}
#endif /* WITH_CONTIKI */
#ifdef RIOT_VERSION
static inline dtls_context_t *
malloc_context(void) {
return (dtls_context_t *) memarray_alloc(&dtlscontext_storage);
}
static inline void free_context(dtls_context_t *context) {
memarray_free(&dtlscontext_storage, context);
}
#endif /* RIOT_VERSION */
#ifdef WITH_POSIX
static inline dtls_context_t *
malloc_context(void) {
return (dtls_context_t *)malloc(sizeof(dtls_context_t));
}
static inline void
free_context(dtls_context_t *context) {
free(context);
}
#endif /* WITH_POSIX */
void
dtls_init(void) {
dtls_clock_init();
crypto_init();
dtls_hmac_storage_init();
netq_init();
peer_init();
#ifdef RIOT_VERSION
memarray_init(&dtlscontext_storage, dtlscontext_storage_data,
sizeof(dtls_context_t), DTLS_CONTEXT_MAX);
#endif /* RIOT_VERSION */
}
/* Calls cb_alert() with given arguments if defined, otherwise an
* error message is logged and the result is -1. This is just an
* internal helper.
*/
#define CALL(Context, which, ...) \
((Context)->h && (Context)->h->which \
? (Context)->h->which((Context), ##__VA_ARGS__) \
: -1)
static int
dtls_send_multi(dtls_context_t *ctx, dtls_peer_t *peer,
dtls_security_parameters_t *security , session_t *session,
unsigned char type, uint8 *buf_array[],
size_t buf_len_array[], size_t buf_array_len);
/**
* Sends the fragment of length \p buflen given in \p buf to the
* specified \p peer. The data will be MAC-protected and encrypted
* according to the selected cipher and split into one or more DTLS
* records of the specified \p type. This function returns the number
* of bytes that were sent, or \c -1 if an error occurred.
*
* \param ctx The DTLS context to use.
* \param peer The remote peer.
* \param type The content type of the record.
* \param buf The data to send.
* \param buflen The actual length of \p buf.
* \return Less than zero on error, the number of bytes written otherwise.
*/
static int
dtls_send(dtls_context_t *ctx, dtls_peer_t *peer, unsigned char type,
uint8 *buf, size_t buflen) {
return dtls_send_multi(ctx, peer, dtls_security_params(peer), &peer->session,
type, &buf, &buflen, 1);
}
/**
* Stops ongoing retransmissions of handshake messages for @p peer.
*/
static void dtls_stop_retransmission(dtls_context_t *context, dtls_peer_t *peer);
dtls_peer_t *
dtls_get_peer(const dtls_context_t *ctx, const session_t *session) {
dtls_peer_t *p;
FIND_PEER(ctx->peers, session, p);
return p;
}
/**
* Adds @p peer to list of peers in @p ctx. This function returns @c 0
* on success, or a negative value on error (e.g. due to insufficient
* storage).
*/
static int
dtls_add_peer(dtls_context_t *ctx, dtls_peer_t *peer) {
ADD_PEER(ctx->peers, session, peer);
return 0;
}
int
dtls_write(struct dtls_context_t *ctx,
session_t *dst, uint8 *buf, size_t len) {
dtls_peer_t *peer = dtls_get_peer(ctx, dst);
/* Check if peer connection already exists */
if (!peer) { /* no ==> create one */
int res;
/* dtls_connect() returns a value greater than zero if a new
* connection attempt is made, 0 for session reuse. */
res = dtls_connect(ctx, dst);
return (res >= 0) ? 0 : res;
} else { /* a session exists, check if it is in state connected */
if (peer->state != DTLS_STATE_CONNECTED) {
return 0;
} else {
return dtls_send(ctx, peer, DTLS_CT_APPLICATION_DATA, buf, len);
}
}
}
static int
dtls_get_cookie(uint8 *msg, size_t msglen, uint8 **cookie) {
/* To access the cookie, we have to determine the session id's
* length and skip the whole thing. */
if (msglen < DTLS_HS_LENGTH + DTLS_CH_LENGTH + sizeof(uint8))
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
if (dtls_uint16_to_int(msg + DTLS_HS_LENGTH) != DTLS_VERSION)
return dtls_alert_fatal_create(DTLS_ALERT_PROTOCOL_VERSION);
msglen -= DTLS_HS_LENGTH + DTLS_CH_LENGTH;
msg += DTLS_HS_LENGTH + DTLS_CH_LENGTH;
SKIP_VAR_FIELD(msg, msglen, uint8); /* skip session id */
if (msglen < (*msg & 0xff) + sizeof(uint8))
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
*cookie = msg + sizeof(uint8);
return dtls_uint8_to_int(msg);
error:
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
}
static int
dtls_create_cookie(dtls_context_t *ctx,
session_t *session,
uint8 *msg, size_t msglen,
uint8 *cookie, int *clen) {
unsigned char buf[DTLS_HMAC_MAX];
size_t e;
int len;
/* create cookie with HMAC-SHA256 over:
* - SECRET
* - session parameters (only IP address?)
* - client version
* - random gmt and bytes
* - session id
* - cipher_suites
* - compression method
*/
/* We use our own buffer as hmac_context instead of a dynamic buffer
* created by dtls_hmac_new() to separate storage space for cookie
* creation from storage that is used in real sessions. Note that
* the buffer size must fit with the default hash algorithm (see
* implementation of dtls_hmac_context_new()). */
dtls_hmac_context_t hmac_context;
dtls_hmac_init(&hmac_context, ctx->cookie_secret, DTLS_COOKIE_SECRET_LENGTH);
dtls_hmac_update(&hmac_context,
(unsigned char *)&session->addr, session->size);
/* feed in the beginning of the Client Hello up to and including the
session id */
e = sizeof(dtls_client_hello_t);
e += (*(msg + DTLS_HS_LENGTH + e) & 0xff) + sizeof(uint8);
if (e + DTLS_HS_LENGTH > msglen)
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
dtls_hmac_update(&hmac_context, msg + DTLS_HS_LENGTH, e);
/* skip cookie bytes and length byte */
e += *(uint8 *)(msg + DTLS_HS_LENGTH + e) & 0xff;
e += sizeof(uint8);
if (e + DTLS_HS_LENGTH > msglen)
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
dtls_hmac_update(&hmac_context,
msg + DTLS_HS_LENGTH + e,
dtls_get_fragment_length(DTLS_HANDSHAKE_HEADER(msg)) - e);
len = dtls_hmac_finalize(&hmac_context, buf);
if (len < *clen) {
memset(cookie + len, 0, *clen - len);
*clen = len;
}
memcpy(cookie, buf, *clen);
return 0;
}
#ifdef DTLS_CHECK_CONTENTTYPE
/* used to check if a received datagram contains a DTLS message */
static char const content_types[] = {
DTLS_CT_CHANGE_CIPHER_SPEC,
DTLS_CT_ALERT,
DTLS_CT_HANDSHAKE,
DTLS_CT_APPLICATION_DATA,
0 /* end marker */
};
/**
* Checks if the content type of \p msg is known. This function returns
* the found content type, or 0 otherwise.
*/
static int
known_content_type(const uint8_t *msg) {
unsigned int n;
assert(msg);
for (n = 0; (content_types[n] != 0) && (content_types[n]) != msg[0]; n++)
;
return content_types[n];
}
#else /* DTLS_CHECK_CONTENTTYPE */
static int
known_content_type(const uint8_t *msg) {
return msg[0];
}
#endif /* DTLS_CHECK_CONTENTTYPE */
/**
* Checks if \p msg points to a valid DTLS record. If
*
*/
static unsigned int
is_record(uint8 *msg, size_t msglen) {
unsigned int rlen = 0;
if (msglen >= DTLS_RH_LENGTH) { /* FIXME allow empty records? */
uint16_t version = dtls_uint16_to_int(msg + 1);
if ((((version == DTLS_VERSION) || (version == DTLS10_VERSION))
&& known_content_type(msg))) {
rlen = DTLS_RH_LENGTH +
dtls_uint16_to_int(DTLS_RECORD_HEADER(msg)->length);
/* we do not accept wrong length field in record header */
if (rlen > msglen)
rlen = 0;
}
}
return rlen;
}
/**
* Initializes \p buf as record header. The caller must ensure that \p
* buf is capable of holding at least \c sizeof(dtls_record_header_t)
* bytes. Increments sequence number counter of \p security.
* \return pointer to the next byte after the written header.
* The length will be set to 0 and has to be changed before sending.
*/
static inline uint8 *
dtls_set_record_header(uint8 type, dtls_security_parameters_t *security,
uint8 *buf) {
dtls_int_to_uint8(buf, type);
buf += sizeof(uint8);
dtls_int_to_uint16(buf, DTLS_VERSION);
buf += sizeof(uint16);
if (security) {
dtls_int_to_uint16(buf, security->epoch);
buf += sizeof(uint16);
dtls_int_to_uint48(buf, security->rseq);
buf += sizeof(uint48);
/* increment record sequence counter by 1 */
security->rseq++;
} else {
memset(buf, 0, sizeof(uint16) + sizeof(uint48));
buf += sizeof(uint16) + sizeof(uint48);
}
memset(buf, 0, sizeof(uint16));
return buf + sizeof(uint16);
}
/**
* Initializes \p buf as handshake header. The caller must ensure that \p
* buf is capable of holding at least \c sizeof(dtls_handshake_header_t)
* bytes. Increments message sequence number counter of \p peer.
* \return pointer to the next byte after \p buf
*/
static inline uint8 *
dtls_set_handshake_header(uint8 type, dtls_peer_t *peer,
int length,
int frag_offset, int frag_length,
uint8 *buf) {
dtls_int_to_uint8(buf, type);
buf += sizeof(uint8);
dtls_int_to_uint24(buf, length);
buf += sizeof(uint24);
if (peer && peer->handshake_params) {
/* and copy the result to buf */
dtls_int_to_uint16(buf, peer->handshake_params->hs_state.mseq_s);
/* increment handshake message sequence counter by 1 */
peer->handshake_params->hs_state.mseq_s++;
} else {
memset(buf, 0, sizeof(uint16));
}
buf += sizeof(uint16);
dtls_int_to_uint24(buf, frag_offset);
buf += sizeof(uint24);
dtls_int_to_uint24(buf, frag_length);
buf += sizeof(uint24);
return buf;
}
/** only one compression method is currently defined */
static uint8 compression_methods[] = {
TLS_COMPRESSION_NULL
};
/** returns true if the cipher matches TLS_ECDHE_ECDSA_WITH_AES_128_CCM_8 */
static inline int is_tls_ecdhe_ecdsa_with_aes_128_ccm_8(dtls_cipher_t cipher)
{
#ifdef DTLS_ECC
return cipher == TLS_ECDHE_ECDSA_WITH_AES_128_CCM_8;
#else
(void) cipher;
return 0;
#endif /* DTLS_ECC */
}
/** returns true if the cipher matches TLS_PSK_WITH_AES_128_CCM_8 */
static inline int is_tls_psk_with_aes_128_ccm_8(dtls_cipher_t cipher)
{
(void) cipher;
#ifdef DTLS_PSK
return cipher == TLS_PSK_WITH_AES_128_CCM_8;
#else
return 0;
#endif /* DTLS_PSK */
}
/** returns true if the application is configured for psk */
static inline int is_psk_supported(dtls_context_t *ctx)
{
#ifdef DTLS_PSK
return ctx && ctx->h && ctx->h->get_psk_info;
#else
(void) ctx;
return 0;
#endif /* DTLS_PSK */
}
/** returns true if the application is configured for ecdhe_ecdsa */
static inline int is_ecdsa_supported(dtls_context_t *ctx, int is_client)
{
#ifdef DTLS_ECC
return ctx && ctx->h && ((!is_client && ctx->h->get_ecdsa_key) ||
(is_client && ctx->h->verify_ecdsa_key));
#else
(void) ctx;
(void) is_client;
return 0;
#endif /* DTLS_ECC */
}
/** Returns true if the application is configured for ecdhe_ecdsa with
* client authentication */
static inline int is_ecdsa_client_auth_supported(dtls_context_t *ctx)
{
#ifdef DTLS_ECC
return ctx && ctx->h && ctx->h->get_ecdsa_key && ctx->h->verify_ecdsa_key;
#else
(void) ctx;
return 0;
#endif /* DTLS_ECC */
}
/**
* Returns @c 1 if @p code is a cipher suite other than @c
* TLS_NULL_WITH_NULL_NULL that we recognize.
*
* @param ctx The current DTLS context
* @param code The cipher suite identifier to check
* @param is_client 1 for a dtls client, 0 for server
* @return @c 1 iff @p code is recognized,
*/
static int
known_cipher(dtls_context_t *ctx, dtls_cipher_t code, int is_client) {
int psk;
int ecdsa;
psk = is_psk_supported(ctx);
ecdsa = is_ecdsa_supported(ctx, is_client);
return (psk && is_tls_psk_with_aes_128_ccm_8(code)) ||
(ecdsa && is_tls_ecdhe_ecdsa_with_aes_128_ccm_8(code));
}
/**
* This method detects if we already have a established DTLS session with
* peer and the peer is attempting to perform a fresh handshake by sending
* messages with epoch = 0. This is to handle situations mentioned in
* RFC 6347 - section 4.2.8.
*
* @param msg The packet received from Client
* @param msglen Packet length
* @param peer peer who is the sender for this packet
* @return @c 1 if this is a rehandshake attempt by
* client
*/
static int
hs_attempt_with_existing_peer(uint8_t *msg, size_t msglen,
dtls_peer_t *peer)
{
(void) msglen;
if ((peer) && (peer->state == DTLS_STATE_CONNECTED)) {
if (msg[0] == DTLS_CT_HANDSHAKE) {
uint16_t msg_epoch = dtls_uint16_to_int(DTLS_RECORD_HEADER(msg)->epoch);
if (msg_epoch == 0) {
dtls_handshake_header_t * hs_header = DTLS_HANDSHAKE_HEADER(msg + DTLS_RH_LENGTH);
if (hs_header->msg_type == DTLS_HT_CLIENT_HELLO ||
hs_header->msg_type == DTLS_HT_HELLO_REQUEST) {
return 1;
}
}
}
}
return 0;
}
/** Dump out the cipher keys and IVs used for the symetric cipher. */
static void dtls_debug_keyblock(dtls_security_parameters_t *config)
{
dtls_debug("key_block (%d bytes):\n", dtls_kb_size(config, peer->role));
dtls_debug_dump(" client_MAC_secret",
dtls_kb_client_mac_secret(config, peer->role),
dtls_kb_mac_secret_size(config, peer->role));
dtls_debug_dump(" server_MAC_secret",
dtls_kb_server_mac_secret(config, peer->role),
dtls_kb_mac_secret_size(config, peer->role));
dtls_debug_dump(" client_write_key",
dtls_kb_client_write_key(config, peer->role),
dtls_kb_key_size(config, peer->role));
dtls_debug_dump(" server_write_key",
dtls_kb_server_write_key(config, peer->role),
dtls_kb_key_size(config, peer->role));
dtls_debug_dump(" client_IV",
dtls_kb_client_iv(config, peer->role),
dtls_kb_iv_size(config, peer->role));
dtls_debug_dump(" server_IV",
dtls_kb_server_iv(config, peer->role),
dtls_kb_iv_size(config, peer->role));
}
/** returns the name of the goven handshake type number.
* see IANA for a full list of types:
* https://www.iana.org/assignments/tls-parameters/tls-parameters.xml#tls-parameters-7
*/
static char *dtls_handshake_type_to_name(int type)
{
switch (type) {
case DTLS_HT_HELLO_REQUEST:
return "hello_request";
case DTLS_HT_CLIENT_HELLO:
return "client_hello";
case DTLS_HT_SERVER_HELLO:
return "server_hello";
case DTLS_HT_HELLO_VERIFY_REQUEST:
return "hello_verify_request";
case DTLS_HT_CERTIFICATE:
return "certificate";
case DTLS_HT_SERVER_KEY_EXCHANGE:
return "server_key_exchange";
case DTLS_HT_CERTIFICATE_REQUEST:
return "certificate_request";
case DTLS_HT_SERVER_HELLO_DONE:
return "server_hello_done";
case DTLS_HT_CERTIFICATE_VERIFY:
return "certificate_verify";
case DTLS_HT_CLIENT_KEY_EXCHANGE:
return "client_key_exchange";
case DTLS_HT_FINISHED:
return "finished";
default:
return "unknown";
}
}
/**
* Calculate the pre master secret and after that calculate the master-secret.
*/
static int
calculate_key_block(dtls_context_t *ctx,
dtls_handshake_parameters_t *handshake,
dtls_peer_t *peer,
session_t *session,
dtls_peer_type role) {
(void) ctx;
(void) session;
unsigned char *pre_master_secret;
int pre_master_len = 0;
dtls_security_parameters_t *security = dtls_security_params_next(peer);
uint8 master_secret[DTLS_MASTER_SECRET_LENGTH];
(void)role; /* The macro dtls_kb_size() does not use role. */
if (!security) {
return dtls_alert_fatal_create(DTLS_ALERT_INTERNAL_ERROR);
}
pre_master_secret = security->key_block;
switch (handshake->cipher) {
#ifdef DTLS_PSK
case TLS_PSK_WITH_AES_128_CCM_8: {
unsigned char psk[DTLS_PSK_MAX_KEY_LEN];
int len;
len = CALL(ctx, get_psk_info, session, DTLS_PSK_KEY,
handshake->keyx.psk.identity,
handshake->keyx.psk.id_length,
psk, DTLS_PSK_MAX_KEY_LEN);
if (len < 0) {
dtls_crit("no psk key for session available\n");
return len;
}
/* Temporarily use the key_block storage space for the pre master secret. */
pre_master_len = dtls_psk_pre_master_secret(psk, len,
pre_master_secret,
MAX_KEYBLOCK_LENGTH);
dtls_debug_hexdump("psk", psk, len);
memset(psk, 0, DTLS_PSK_MAX_KEY_LEN);
if (pre_master_len < 0) {
dtls_crit("the psk was too long, for the pre master secret\n");
return dtls_alert_fatal_create(DTLS_ALERT_INTERNAL_ERROR);
}
break;
}
#endif /* DTLS_PSK */
#ifdef DTLS_ECC
case TLS_ECDHE_ECDSA_WITH_AES_128_CCM_8: {
pre_master_len = dtls_ecdh_pre_master_secret(handshake->keyx.ecdsa.own_eph_priv,
handshake->keyx.ecdsa.other_eph_pub_x,
handshake->keyx.ecdsa.other_eph_pub_y,
sizeof(handshake->keyx.ecdsa.own_eph_priv),
pre_master_secret,
MAX_KEYBLOCK_LENGTH);
if (pre_master_len < 0) {
dtls_crit("the curve was too long, for the pre master secret\n");
return dtls_alert_fatal_create(DTLS_ALERT_INTERNAL_ERROR);
}
break;
}
#endif /* DTLS_ECC */
case TLS_NULL_WITH_NULL_NULL:
assert(!"calculate_key_block: tried to use NULL cipher\n");
return dtls_alert_fatal_create(DTLS_ALERT_INSUFFICIENT_SECURITY);
/* The following cases cover the enum symbols that are not
* included in this build. These must be kept just above the
* default case as they do nothing but fall through.
*/
#ifndef DTLS_PSK
case TLS_PSK_WITH_AES_128_CCM_8:
/* fall through to default */
#endif /* !DTLS_PSK */
#ifndef DTLS_ECC
case TLS_ECDHE_ECDSA_WITH_AES_128_CCM_8:
/* fall through to default */
#endif /* !DTLS_ECC */
default:
dtls_crit("calculate_key_block: unknown cipher %x04 \n", handshake->cipher);
return dtls_alert_fatal_create(DTLS_ALERT_INTERNAL_ERROR);
}
dtls_debug_dump("client_random", handshake->tmp.random.client, DTLS_RANDOM_LENGTH);
dtls_debug_dump("server_random", handshake->tmp.random.server, DTLS_RANDOM_LENGTH);
dtls_debug_dump("pre_master_secret", pre_master_secret, pre_master_len);
dtls_prf(pre_master_secret, pre_master_len,
PRF_LABEL(master), PRF_LABEL_SIZE(master),
handshake->tmp.random.client, DTLS_RANDOM_LENGTH,
handshake->tmp.random.server, DTLS_RANDOM_LENGTH,
master_secret,
DTLS_MASTER_SECRET_LENGTH);
dtls_debug_dump("master_secret", master_secret, DTLS_MASTER_SECRET_LENGTH);
/* create key_block from master_secret
* key_block = PRF(master_secret,
"key expansion" + tmp.random.server + tmp.random.client) */
dtls_prf(master_secret,
DTLS_MASTER_SECRET_LENGTH,
PRF_LABEL(key), PRF_LABEL_SIZE(key),
handshake->tmp.random.server, DTLS_RANDOM_LENGTH,
handshake->tmp.random.client, DTLS_RANDOM_LENGTH,
security->key_block,
dtls_kb_size(security, role));
memcpy(handshake->tmp.master_secret, master_secret, DTLS_MASTER_SECRET_LENGTH);
dtls_debug_keyblock(security);
security->cipher = handshake->cipher;
security->compression = handshake->compression;
security->rseq = 0;
return 0;
}
/* TODO: add a generic method which iterates over a list and searches for a specific key */
static int verify_ext_eliptic_curves(uint8 *data, size_t data_length) {
int i, curve_name;
/* length of curve list */
i = dtls_uint16_to_int(data);
data += sizeof(uint16);
if (i + sizeof(uint16) != data_length) {
dtls_warn("the list of the supported elliptic curves should be tls extension length - 2\n");
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
}
for (i = data_length - sizeof(uint16); i > 0; i -= sizeof(uint16)) {
/* check if this curve is supported */
curve_name = dtls_uint16_to_int(data);
data += sizeof(uint16);
if (curve_name == TLS_EXT_ELLIPTIC_CURVES_SECP256R1)
return 0;
}
dtls_warn("no supported elliptic curve found\n");
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
}
static int verify_ext_cert_type(uint8 *data, size_t data_length) {
int i, cert_type;
/* length of cert type list */
i = dtls_uint8_to_int(data);
data += sizeof(uint8);
if (i + sizeof(uint8) != data_length) {
dtls_warn("the list of the supported certificate types should be tls extension length - 1\n");
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
}
for (i = data_length - sizeof(uint8); i > 0; i -= sizeof(uint8)) {
/* check if this cert type is supported */
cert_type = dtls_uint8_to_int(data);
data += sizeof(uint8);
if (cert_type == TLS_CERT_TYPE_RAW_PUBLIC_KEY)
return 0;
}
dtls_warn("no supported certificate type found\n");
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
}
static int verify_ext_ec_point_formats(uint8 *data, size_t data_length) {
int i, cert_type;
/* length of ec_point_formats list */
i = dtls_uint8_to_int(data);
data += sizeof(uint8);
if (i + sizeof(uint8) != data_length) {
dtls_warn("the list of the supported ec_point_formats should be tls extension length - 1\n");
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
}
for (i = data_length - sizeof(uint8); i > 0; i -= sizeof(uint8)) {
/* check if this ec_point_format is supported */
cert_type = dtls_uint8_to_int(data);
data += sizeof(uint8);
if (cert_type == TLS_EXT_EC_POINT_FORMATS_UNCOMPRESSED)
return 0;
}
dtls_warn("no supported ec_point_format found\n");
return dtls_alert_fatal_create(DTLS_ALERT_HANDSHAKE_FAILURE);
}
/*
* Check for some TLS Extensions used by the ECDHE_ECDSA cipher.
*/
static int
dtls_check_tls_extension(dtls_peer_t *peer,
uint8 *data, size_t data_length, int client_hello)
{
uint16_t i, j;
int ext_elliptic_curve = 0;
int ext_client_cert_type = 0;
int ext_server_cert_type = 0;
int ext_ec_point_formats = 0;
dtls_handshake_parameters_t *handshake = peer->handshake_params;
if (data_length < sizeof(uint16)) {
/* no tls extensions specified */
if (is_tls_ecdhe_ecdsa_with_aes_128_ccm_8(handshake->cipher)) {
goto error;
}
return 0;
}
/* get the length of the tls extension list */
j = dtls_uint16_to_int(data);
data += sizeof(uint16);
data_length -= sizeof(uint16);
if (data_length < j)
goto error;
/* check for TLS extensions needed for this cipher */
while (data_length) {
if (data_length < sizeof(uint16) * 2)
goto error;
/* get the tls extension type */
i = dtls_uint16_to_int(data);
data += sizeof(uint16);
data_length -= sizeof(uint16);
/* get the length of the tls extension */
j = dtls_uint16_to_int(data);
data += sizeof(uint16);
data_length -= sizeof(uint16);
if (data_length < j)
goto error;
switch (i) {
case TLS_EXT_ELLIPTIC_CURVES:
ext_elliptic_curve = 1;
if (verify_ext_eliptic_curves(data, j))
goto error;
break;
case TLS_EXT_CLIENT_CERTIFICATE_TYPE:
ext_client_cert_type = 1;
if (client_hello) {
if (verify_ext_cert_type(data, j))
goto error;
} else {
if (dtls_uint8_to_int(data) != TLS_CERT_TYPE_RAW_PUBLIC_KEY)
goto error;
}
break;
case TLS_EXT_SERVER_CERTIFICATE_TYPE:
ext_server_cert_type = 1;
if (client_hello) {
if (verify_ext_cert_type(data, j))
goto error;
} else {
if (dtls_uint8_to_int(data) != TLS_CERT_TYPE_RAW_PUBLIC_KEY)
goto error;
}
break;
case TLS_EXT_EC_POINT_FORMATS:
ext_ec_point_formats = 1;
if (verify_ext_ec_point_formats(data, j))
goto error;
break;
case TLS_EXT_ENCRYPT_THEN_MAC:
/* As only AEAD cipher suites are currently available, this
* extension can be skipped.
*/
dtls_info("skipped encrypt-then-mac extension\n");
break;
default:
dtls_warn("unsupported tls extension: %i\n", i);
break;
}
data += j;
data_length -= j;
}
if (is_tls_ecdhe_ecdsa_with_aes_128_ccm_8(handshake->cipher) && client_hello) {
if (!ext_elliptic_curve || !ext_client_cert_type || !ext_server_cert_type
|| !ext_ec_point_formats) {
dtls_warn("not all required tls extensions found in client hello\n");
goto error;
}