1 /* 2 * Copyright (C) 2014 BlueKitchen GmbH 3 * 4 * Redistribution and use in source and binary forms, with or without 5 * modification, are permitted provided that the following conditions 6 * are met: 7 * 8 * 1. Redistributions of source code must retain the above copyright 9 * notice, this list of conditions and the following disclaimer. 10 * 2. Redistributions in binary form must reproduce the above copyright 11 * notice, this list of conditions and the following disclaimer in the 12 * documentation and/or other materials provided with the distribution. 13 * 3. Neither the name of the copyright holders nor the names of 14 * contributors may be used to endorse or promote products derived 15 * from this software without specific prior written permission. 16 * 4. Any redistribution, use, or modification is done solely for 17 * personal benefit and not for any commercial purpose or for 18 * monetary gain. 19 * 20 * THIS SOFTWARE IS PROVIDED BY BLUEKITCHEN GMBH AND CONTRIBUTORS 21 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 22 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS 23 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL BLUEKITCHEN 24 * GMBH OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, 25 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, 26 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS 27 * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED 28 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, 29 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF 30 * THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 31 * SUCH DAMAGE. 32 * 33 * Please inquire about commercial licensing options at 34 * [email protected] 35 * 36 */ 37 38 #define BTSTACK_FILE__ "sm.c" 39 40 #include <string.h> 41 #include <inttypes.h> 42 43 #include "ble/le_device_db.h" 44 #include "ble/core.h" 45 #include "ble/sm.h" 46 #include "bluetooth_company_id.h" 47 #include "btstack_bool.h" 48 #include "btstack_crypto.h" 49 #include "btstack_debug.h" 50 #include "btstack_event.h" 51 #include "btstack_linked_list.h" 52 #include "btstack_memory.h" 53 #include "btstack_tlv.h" 54 #include "gap.h" 55 #include "hci.h" 56 #include "hci_dump.h" 57 #include "l2cap.h" 58 59 #if !defined(ENABLE_LE_PERIPHERAL) && !defined(ENABLE_LE_CENTRAL) 60 #error "LE Security Manager used, but neither ENABLE_LE_PERIPHERAL nor ENABLE_LE_CENTRAL defined. Please add at least one to btstack_config.h." 61 #endif 62 63 #if defined(ENABLE_CROSS_TRANSPORT_KEY_DERIVATION) && (!defined(ENABLE_CLASSIC) || !defined(ENABLE_LE_SECURE_CONNECTIONS)) 64 #error "Cross Transport Key Derivation requires support for LE Secure Connections and BR/EDR (Classic)" 65 #endif 66 67 // assert SM Public Key can be sent/received 68 #ifdef ENABLE_LE_SECURE_CONNECTIONS 69 #if HCI_ACL_PAYLOAD_SIZE < 69 70 #error "HCI_ACL_PAYLOAD_SIZE must be at least 69 bytes when using LE Secure Conection. Please increase HCI_ACL_PAYLOAD_SIZE or disable ENABLE_LE_SECURE_CONNECTIONS" 71 #endif 72 #endif 73 74 #if defined(ENABLE_LE_PERIPHERAL) && defined(ENABLE_LE_CENTRAL) 75 #define IS_RESPONDER(role) (role) 76 #else 77 #ifdef ENABLE_LE_CENTRAL 78 // only central - never responder (avoid 'unused variable' warnings) 79 #define IS_RESPONDER(role) (0 && role) 80 #else 81 // only peripheral - always responder (avoid 'unused variable' warnings) 82 #define IS_RESPONDER(role) (1 || role) 83 #endif 84 #endif 85 86 #if defined(ENABLE_LE_SIGNED_WRITE) || defined(ENABLE_LE_SECURE_CONNECTIONS) 87 #define USE_CMAC_ENGINE 88 #endif 89 90 91 #define BTSTACK_TAG32(A,B,C,D) (((A) << 24) | ((B) << 16) | ((C) << 8) | (D)) 92 93 // 94 // SM internal types and globals 95 // 96 97 typedef enum { 98 DKG_W4_WORKING, 99 DKG_CALC_IRK, 100 DKG_CALC_DHK, 101 DKG_READY 102 } derived_key_generation_t; 103 104 typedef enum { 105 RAU_IDLE, 106 RAU_GET_RANDOM, 107 RAU_W4_RANDOM, 108 RAU_GET_ENC, 109 RAU_W4_ENC, 110 } random_address_update_t; 111 112 typedef enum { 113 CMAC_IDLE, 114 CMAC_CALC_SUBKEYS, 115 CMAC_W4_SUBKEYS, 116 CMAC_CALC_MI, 117 CMAC_W4_MI, 118 CMAC_CALC_MLAST, 119 CMAC_W4_MLAST 120 } cmac_state_t; 121 122 typedef enum { 123 JUST_WORKS, 124 PK_RESP_INPUT, // Initiator displays PK, responder inputs PK 125 PK_INIT_INPUT, // Responder displays PK, initiator inputs PK 126 PK_BOTH_INPUT, // Only input on both, both input PK 127 NUMERIC_COMPARISON, // Only numerical compparison (yes/no) on on both sides 128 OOB // OOB available on one (SC) or both sides (legacy) 129 } stk_generation_method_t; 130 131 typedef enum { 132 SM_USER_RESPONSE_IDLE, 133 SM_USER_RESPONSE_PENDING, 134 SM_USER_RESPONSE_CONFIRM, 135 SM_USER_RESPONSE_PASSKEY, 136 SM_USER_RESPONSE_DECLINE 137 } sm_user_response_t; 138 139 typedef enum { 140 SM_AES128_IDLE, 141 SM_AES128_ACTIVE 142 } sm_aes128_state_t; 143 144 typedef enum { 145 ADDRESS_RESOLUTION_IDLE, 146 ADDRESS_RESOLUTION_GENERAL, 147 ADDRESS_RESOLUTION_FOR_CONNECTION, 148 } address_resolution_mode_t; 149 150 typedef enum { 151 ADDRESS_RESOLUTION_SUCCEEDED, 152 ADDRESS_RESOLUTION_FAILED, 153 } address_resolution_event_t; 154 155 typedef enum { 156 EC_KEY_GENERATION_IDLE, 157 EC_KEY_GENERATION_ACTIVE, 158 EC_KEY_GENERATION_DONE, 159 } ec_key_generation_state_t; 160 161 typedef enum { 162 SM_STATE_VAR_DHKEY_NEEDED = 1 << 0, 163 SM_STATE_VAR_DHKEY_CALCULATED = 1 << 1, 164 SM_STATE_VAR_DHKEY_COMMAND_RECEIVED = 1 << 2, 165 } sm_state_var_t; 166 167 typedef enum { 168 SM_SC_OOB_IDLE, 169 SM_SC_OOB_W4_RANDOM, 170 SM_SC_OOB_W2_CALC_CONFIRM, 171 SM_SC_OOB_W4_CONFIRM, 172 } sm_sc_oob_state_t; 173 174 typedef uint8_t sm_key24_t[3]; 175 typedef uint8_t sm_key56_t[7]; 176 typedef uint8_t sm_key256_t[32]; 177 178 // 179 // GLOBAL DATA 180 // 181 182 static bool sm_initialized; 183 184 static bool test_use_fixed_local_csrk; 185 static bool test_use_fixed_local_irk; 186 187 #ifdef ENABLE_TESTING_SUPPORT 188 static uint8_t test_pairing_failure; 189 #endif 190 191 // configuration 192 static uint8_t sm_accepted_stk_generation_methods; 193 static uint8_t sm_max_encryption_key_size; 194 static uint8_t sm_min_encryption_key_size; 195 static uint8_t sm_auth_req = 0; 196 static uint8_t sm_io_capabilities = IO_CAPABILITY_NO_INPUT_NO_OUTPUT; 197 static uint32_t sm_fixed_passkey_in_display_role; 198 static bool sm_reconstruct_ltk_without_le_device_db_entry; 199 200 #ifdef ENABLE_LE_PERIPHERAL 201 static uint8_t sm_slave_request_security; 202 #endif 203 204 #ifdef ENABLE_LE_SECURE_CONNECTIONS 205 static bool sm_sc_only_mode; 206 static uint8_t sm_sc_oob_random[16]; 207 static void (*sm_sc_oob_callback)(const uint8_t * confirm_value, const uint8_t * random_value); 208 static sm_sc_oob_state_t sm_sc_oob_state; 209 #ifdef ENABLE_LE_SECURE_CONNECTIONS_DEBUG_KEY 210 static bool sm_sc_debug_keys_enabled; 211 #endif 212 #endif 213 214 215 static bool sm_persistent_keys_random_active; 216 static const btstack_tlv_t * sm_tlv_impl; 217 static void * sm_tlv_context; 218 219 // Security Manager Master Keys, please use sm_set_er(er) and sm_set_ir(ir) with your own 128 bit random values 220 static sm_key_t sm_persistent_er; 221 static sm_key_t sm_persistent_ir; 222 223 // derived from sm_persistent_ir 224 static sm_key_t sm_persistent_dhk; 225 static sm_key_t sm_persistent_irk; 226 static derived_key_generation_t dkg_state; 227 228 // derived from sm_persistent_er 229 // .. 230 231 // random address update 232 static random_address_update_t rau_state; 233 static bd_addr_t sm_random_address; 234 235 #ifdef USE_CMAC_ENGINE 236 // CMAC Calculation: General 237 static btstack_crypto_aes128_cmac_t sm_cmac_request; 238 static void (*sm_cmac_done_callback)(uint8_t hash[8]); 239 static uint8_t sm_cmac_active; 240 static uint8_t sm_cmac_hash[16]; 241 #endif 242 243 // CMAC for ATT Signed Writes 244 #ifdef ENABLE_LE_SIGNED_WRITE 245 static uint16_t sm_cmac_signed_write_message_len; 246 static uint8_t sm_cmac_signed_write_header[3]; 247 static const uint8_t * sm_cmac_signed_write_message; 248 static uint8_t sm_cmac_signed_write_sign_counter[4]; 249 #endif 250 251 // CMAC for Secure Connection functions 252 #ifdef ENABLE_LE_SECURE_CONNECTIONS 253 static sm_connection_t * sm_cmac_connection; 254 static uint8_t sm_cmac_sc_buffer[80]; 255 #endif 256 257 // resolvable private address lookup / CSRK calculation 258 static int sm_address_resolution_test; 259 static uint8_t sm_address_resolution_addr_type; 260 static bd_addr_t sm_address_resolution_address; 261 static void * sm_address_resolution_context; 262 static address_resolution_mode_t sm_address_resolution_mode; 263 static btstack_linked_list_t sm_address_resolution_general_queue; 264 265 // aes128 crypto engine. 266 static sm_aes128_state_t sm_aes128_state; 267 268 // crypto 269 static btstack_crypto_random_t sm_crypto_random_request; 270 static btstack_crypto_aes128_t sm_crypto_aes128_request; 271 #ifdef ENABLE_LE_SECURE_CONNECTIONS 272 static btstack_crypto_ecc_p256_t sm_crypto_ecc_p256_request; 273 #endif 274 275 // temp storage for random data 276 static uint8_t sm_random_data[8]; 277 static uint8_t sm_aes128_key[16]; 278 static uint8_t sm_aes128_plaintext[16]; 279 static uint8_t sm_aes128_ciphertext[16]; 280 281 // to receive events 282 static btstack_packet_callback_registration_t hci_event_callback_registration; 283 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 284 static btstack_packet_callback_registration_t l2cap_event_callback_registration; 285 #endif 286 287 /* to dispatch sm event */ 288 static btstack_linked_list_t sm_event_handlers; 289 290 /* to schedule calls to sm_run */ 291 static btstack_timer_source_t sm_run_timer; 292 293 // LE Secure Connections 294 #ifdef ENABLE_LE_SECURE_CONNECTIONS 295 static ec_key_generation_state_t ec_key_generation_state; 296 static uint8_t ec_q[64]; 297 #endif 298 299 // 300 // Volume 3, Part H, Chapter 24 301 // "Security shall be initiated by the Security Manager in the device in the master role. 302 // The device in the slave role shall be the responding device." 303 // -> master := initiator, slave := responder 304 // 305 306 // data needed for security setup 307 typedef struct sm_setup_context { 308 309 btstack_timer_source_t sm_timeout; 310 311 // user response, (Phase 1 and/or 2) 312 uint8_t sm_user_response; 313 uint8_t sm_keypress_notification; // bitmap: passkey started, digit entered, digit erased, passkey cleared, passkey complete, 3 bit count 314 315 // defines which keys will be send after connection is encrypted - calculated during Phase 1, used Phase 3 316 uint8_t sm_key_distribution_send_set; 317 uint8_t sm_key_distribution_sent_set; 318 uint8_t sm_key_distribution_expected_set; 319 uint8_t sm_key_distribution_received_set; 320 321 // Phase 2 (Pairing over SMP) 322 stk_generation_method_t sm_stk_generation_method; 323 sm_key_t sm_tk; 324 uint8_t sm_have_oob_data; 325 uint8_t sm_use_secure_connections; 326 327 sm_key_t sm_c1_t3_value; // c1 calculation 328 sm_pairing_packet_t sm_m_preq; // pairing request - needed only for c1 329 sm_pairing_packet_t sm_s_pres; // pairing response - needed only for c1 330 sm_key_t sm_local_random; 331 sm_key_t sm_local_confirm; 332 sm_key_t sm_peer_random; 333 sm_key_t sm_peer_confirm; 334 uint8_t sm_m_addr_type; // address and type can be removed 335 uint8_t sm_s_addr_type; // '' 336 bd_addr_t sm_m_address; // '' 337 bd_addr_t sm_s_address; // '' 338 sm_key_t sm_ltk; 339 340 uint8_t sm_state_vars; 341 #ifdef ENABLE_LE_SECURE_CONNECTIONS 342 uint8_t sm_peer_q[64]; // also stores random for EC key generation during init 343 sm_key_t sm_peer_nonce; // might be combined with sm_peer_random 344 sm_key_t sm_local_nonce; // might be combined with sm_local_random 345 uint8_t sm_dhkey[32]; 346 sm_key_t sm_peer_dhkey_check; 347 sm_key_t sm_local_dhkey_check; 348 sm_key_t sm_ra; 349 sm_key_t sm_rb; 350 sm_key_t sm_t; // used for f5 and h6 351 sm_key_t sm_mackey; 352 uint8_t sm_passkey_bit; // also stores number of generated random bytes for EC key generation 353 #endif 354 355 // Phase 3 356 357 // key distribution, we generate 358 uint16_t sm_local_y; 359 uint16_t sm_local_div; 360 uint16_t sm_local_ediv; 361 uint8_t sm_local_rand[8]; 362 sm_key_t sm_local_ltk; 363 sm_key_t sm_local_csrk; 364 sm_key_t sm_local_irk; 365 // sm_local_address/addr_type not needed 366 367 // key distribution, received from peer 368 uint16_t sm_peer_y; 369 uint16_t sm_peer_div; 370 uint16_t sm_peer_ediv; 371 uint8_t sm_peer_rand[8]; 372 sm_key_t sm_peer_ltk; 373 sm_key_t sm_peer_irk; 374 sm_key_t sm_peer_csrk; 375 uint8_t sm_peer_addr_type; 376 bd_addr_t sm_peer_address; 377 #ifdef ENABLE_LE_SIGNED_WRITE 378 int sm_le_device_index; 379 #endif 380 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 381 link_key_t sm_link_key; 382 link_key_type_t sm_link_key_type; 383 #endif 384 } sm_setup_context_t; 385 386 // 387 static sm_setup_context_t the_setup; 388 static sm_setup_context_t * setup = &the_setup; 389 390 // active connection - the one for which the_setup is used for 391 static uint16_t sm_active_connection_handle = HCI_CON_HANDLE_INVALID; 392 393 // @return 1 if oob data is available 394 // stores oob data in provided 16 byte buffer if not null 395 static int (*sm_get_oob_data)(uint8_t addres_type, bd_addr_t addr, uint8_t * oob_data) = NULL; 396 static int (*sm_get_sc_oob_data)(uint8_t addres_type, bd_addr_t addr, uint8_t * oob_sc_peer_confirm, uint8_t * oob_sc_peer_random); 397 static bool (*sm_get_ltk_callback)(hci_con_handle_t con_handle, uint8_t addres_type, bd_addr_t addr, uint8_t * ltk); 398 399 static void sm_run(void); 400 static void sm_state_reset(void); 401 static void sm_done_for_handle(hci_con_handle_t con_handle); 402 static sm_connection_t * sm_get_connection_for_handle(hci_con_handle_t con_handle); 403 static void sm_cache_ltk(sm_connection_t * connection, const sm_key_t ltk); 404 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 405 static sm_connection_t * sm_get_connection_for_bd_addr_and_type(bd_addr_t address, bd_addr_type_t addr_type); 406 #endif 407 static inline int sm_calc_actual_encryption_key_size(int other); 408 static int sm_validate_stk_generation_method(void); 409 static void sm_handle_encryption_result_address_resolution(void *arg); 410 static void sm_handle_encryption_result_dkg_dhk(void *arg); 411 static void sm_handle_encryption_result_dkg_irk(void *arg); 412 static void sm_handle_encryption_result_enc_a(void *arg); 413 static void sm_handle_encryption_result_enc_b(void *arg); 414 static void sm_handle_encryption_result_enc_c(void *arg); 415 static void sm_handle_encryption_result_enc_csrk(void *arg); 416 static void sm_handle_encryption_result_enc_d(void * arg); 417 static void sm_handle_encryption_result_enc_ph3_ltk(void *arg); 418 static void sm_handle_encryption_result_enc_ph3_y(void *arg); 419 #ifdef ENABLE_LE_PERIPHERAL 420 static void sm_handle_encryption_result_enc_ph4_ltk(void *arg); 421 static void sm_handle_encryption_result_enc_ph4_y(void *arg); 422 #endif 423 static void sm_handle_encryption_result_enc_stk(void *arg); 424 static void sm_handle_encryption_result_rau(void *arg); 425 static void sm_handle_random_result_ph2_tk(void * arg); 426 static void sm_handle_random_result_rau(void * arg); 427 #ifdef ENABLE_LE_SECURE_CONNECTIONS 428 static void sm_cmac_message_start(const sm_key_t key, uint16_t message_len, const uint8_t * message, void (*done_callback)(uint8_t * hash)); 429 static void sm_ec_generate_new_key(void); 430 static void sm_handle_random_result_sc_next_w2_cmac_for_confirmation(void * arg); 431 static void sm_handle_random_result_sc_next_send_pairing_random(void * arg); 432 static int sm_passkey_entry(stk_generation_method_t method); 433 #endif 434 static void sm_pairing_complete(sm_connection_t * sm_conn, uint8_t status, uint8_t reason); 435 436 static void log_info_hex16(const char * name, uint16_t value){ 437 log_info("%-6s 0x%04x", name, value); 438 } 439 440 // static inline uint8_t sm_pairing_packet_get_code(sm_pairing_packet_t packet){ 441 // return packet[0]; 442 // } 443 static inline uint8_t sm_pairing_packet_get_io_capability(sm_pairing_packet_t packet){ 444 return packet[1]; 445 } 446 static inline uint8_t sm_pairing_packet_get_oob_data_flag(sm_pairing_packet_t packet){ 447 return packet[2]; 448 } 449 static inline uint8_t sm_pairing_packet_get_auth_req(sm_pairing_packet_t packet){ 450 return packet[3]; 451 } 452 static inline uint8_t sm_pairing_packet_get_max_encryption_key_size(sm_pairing_packet_t packet){ 453 return packet[4]; 454 } 455 static inline uint8_t sm_pairing_packet_get_initiator_key_distribution(sm_pairing_packet_t packet){ 456 return packet[5]; 457 } 458 static inline uint8_t sm_pairing_packet_get_responder_key_distribution(sm_pairing_packet_t packet){ 459 return packet[6]; 460 } 461 462 static inline void sm_pairing_packet_set_code(sm_pairing_packet_t packet, uint8_t code){ 463 packet[0] = code; 464 } 465 static inline void sm_pairing_packet_set_io_capability(sm_pairing_packet_t packet, uint8_t io_capability){ 466 packet[1] = io_capability; 467 } 468 static inline void sm_pairing_packet_set_oob_data_flag(sm_pairing_packet_t packet, uint8_t oob_data_flag){ 469 packet[2] = oob_data_flag; 470 } 471 static inline void sm_pairing_packet_set_auth_req(sm_pairing_packet_t packet, uint8_t auth_req){ 472 packet[3] = auth_req; 473 } 474 static inline void sm_pairing_packet_set_max_encryption_key_size(sm_pairing_packet_t packet, uint8_t max_encryption_key_size){ 475 packet[4] = max_encryption_key_size; 476 } 477 static inline void sm_pairing_packet_set_initiator_key_distribution(sm_pairing_packet_t packet, uint8_t initiator_key_distribution){ 478 packet[5] = initiator_key_distribution; 479 } 480 static inline void sm_pairing_packet_set_responder_key_distribution(sm_pairing_packet_t packet, uint8_t responder_key_distribution){ 481 packet[6] = responder_key_distribution; 482 } 483 484 static bool sm_is_null_random(uint8_t random[8]){ 485 return btstack_is_null(random, 8); 486 } 487 488 static bool sm_is_null_key(uint8_t * key){ 489 return btstack_is_null(key, 16); 490 } 491 492 #ifdef ENABLE_LE_SECURE_CONNECTIONS 493 static bool sm_is_ff(const uint8_t * buffer, uint16_t size){ 494 uint16_t i; 495 for (i=0; i < size ; i++){ 496 if (buffer[i] != 0xff) { 497 return false; 498 } 499 } 500 return true; 501 } 502 #endif 503 504 // sm_trigger_run allows to schedule callback from main run loop // reduces stack depth 505 static void sm_run_timer_handler(btstack_timer_source_t * ts){ 506 UNUSED(ts); 507 sm_run(); 508 } 509 static void sm_trigger_run(void){ 510 if (!sm_initialized) return; 511 (void)btstack_run_loop_remove_timer(&sm_run_timer); 512 btstack_run_loop_set_timer(&sm_run_timer, 0); 513 btstack_run_loop_add_timer(&sm_run_timer); 514 } 515 516 // Key utils 517 static void sm_reset_tk(void){ 518 int i; 519 for (i=0;i<16;i++){ 520 setup->sm_tk[i] = 0; 521 } 522 } 523 524 // "For example, if a 128-bit encryption key is 0x123456789ABCDEF0123456789ABCDEF0 525 // and it is reduced to 7 octets (56 bits), then the resulting key is 0x0000000000000000003456789ABCDEF0."" 526 static void sm_truncate_key(sm_key_t key, int max_encryption_size){ 527 int i; 528 for (i = max_encryption_size ; i < 16 ; i++){ 529 key[15-i] = 0; 530 } 531 } 532 533 // ER / IR checks 534 static void sm_er_ir_set_default(void){ 535 int i; 536 for (i=0;i<16;i++){ 537 sm_persistent_er[i] = 0x30 + i; 538 sm_persistent_ir[i] = 0x90 + i; 539 } 540 } 541 542 static int sm_er_is_default(void){ 543 int i; 544 for (i=0;i<16;i++){ 545 if (sm_persistent_er[i] != (0x30+i)) return 0; 546 } 547 return 1; 548 } 549 550 static int sm_ir_is_default(void){ 551 int i; 552 for (i=0;i<16;i++){ 553 if (sm_persistent_ir[i] != (0x90+i)) return 0; 554 } 555 return 1; 556 } 557 558 static void sm_dispatch_event(uint8_t packet_type, uint16_t channel, uint8_t * packet, uint16_t size){ 559 UNUSED(channel); 560 561 // log event 562 hci_dump_packet(packet_type, 1, packet, size); 563 // dispatch to all event handlers 564 btstack_linked_list_iterator_t it; 565 btstack_linked_list_iterator_init(&it, &sm_event_handlers); 566 while (btstack_linked_list_iterator_has_next(&it)){ 567 btstack_packet_callback_registration_t * entry = (btstack_packet_callback_registration_t*) btstack_linked_list_iterator_next(&it); 568 entry->callback(packet_type, 0, packet, size); 569 } 570 } 571 572 static void sm_setup_event_base(uint8_t * event, int event_size, uint8_t type, hci_con_handle_t con_handle, uint8_t addr_type, bd_addr_t address){ 573 event[0] = type; 574 event[1] = event_size - 2; 575 little_endian_store_16(event, 2, con_handle); 576 event[4] = addr_type; 577 reverse_bd_addr(address, &event[5]); 578 } 579 580 static void sm_notify_client_base(uint8_t type, hci_con_handle_t con_handle, uint8_t addr_type, bd_addr_t address){ 581 uint8_t event[11]; 582 sm_setup_event_base(event, sizeof(event), type, con_handle, addr_type, address); 583 sm_dispatch_event(HCI_EVENT_PACKET, 0, event, sizeof(event)); 584 } 585 586 static void sm_notify_client_index(uint8_t type, hci_con_handle_t con_handle, uint8_t addr_type, bd_addr_t address, uint16_t index){ 587 // fetch addr and addr type from db, only called for valid entries 588 bd_addr_t identity_address; 589 int identity_address_type; 590 le_device_db_info(index, &identity_address_type, identity_address, NULL); 591 592 uint8_t event[20]; 593 sm_setup_event_base(event, sizeof(event), type, con_handle, addr_type, address); 594 event[11] = identity_address_type; 595 reverse_bd_addr(identity_address, &event[12]); 596 little_endian_store_16(event, 18, index); 597 sm_dispatch_event(HCI_EVENT_PACKET, 0, event, sizeof(event)); 598 } 599 600 static void sm_notify_client_status(uint8_t type, hci_con_handle_t con_handle, uint8_t addr_type, bd_addr_t address, uint8_t status){ 601 uint8_t event[12]; 602 sm_setup_event_base(event, sizeof(event), type, con_handle, addr_type, address); 603 event[11] = status; 604 sm_dispatch_event(HCI_EVENT_PACKET, 0, (uint8_t*) &event, sizeof(event)); 605 } 606 607 608 static void sm_reencryption_started(sm_connection_t * sm_conn){ 609 610 if (sm_conn->sm_reencryption_active) return; 611 612 sm_conn->sm_reencryption_active = true; 613 614 int identity_addr_type; 615 bd_addr_t identity_addr; 616 if (sm_conn->sm_le_db_index >= 0){ 617 // fetch addr and addr type from db, only called for valid entries 618 le_device_db_info(sm_conn->sm_le_db_index, &identity_addr_type, identity_addr, NULL); 619 } else { 620 // for legacy pairing with LTK re-construction, use current peer addr 621 identity_addr_type = sm_conn->sm_peer_addr_type; 622 // cppcheck-suppress uninitvar ; identity_addr is reported as uninitialized although it's the destination of the memcpy 623 memcpy(identity_addr, sm_conn->sm_peer_address, 6); 624 } 625 626 sm_notify_client_base(SM_EVENT_REENCRYPTION_STARTED, sm_conn->sm_handle, identity_addr_type, identity_addr); 627 } 628 629 static void sm_reencryption_complete(sm_connection_t * sm_conn, uint8_t status){ 630 631 if (!sm_conn->sm_reencryption_active) return; 632 633 sm_conn->sm_reencryption_active = false; 634 635 int identity_addr_type; 636 bd_addr_t identity_addr; 637 if (sm_conn->sm_le_db_index >= 0){ 638 // fetch addr and addr type from db, only called for valid entries 639 le_device_db_info(sm_conn->sm_le_db_index, &identity_addr_type, identity_addr, NULL); 640 } else { 641 // for legacy pairing with LTK re-construction, use current peer addr 642 identity_addr_type = sm_conn->sm_peer_addr_type; 643 // cppcheck-suppress uninitvar ; identity_addr is reported as uninitialized although it's the destination of the memcpy 644 memcpy(identity_addr, sm_conn->sm_peer_address, 6); 645 } 646 647 sm_notify_client_status(SM_EVENT_REENCRYPTION_COMPLETE, sm_conn->sm_handle, identity_addr_type, identity_addr, status); 648 } 649 650 static void sm_pairing_started(sm_connection_t * sm_conn){ 651 652 if (sm_conn->sm_pairing_active) return; 653 654 sm_conn->sm_pairing_active = true; 655 656 uint8_t event[11]; 657 sm_setup_event_base(event, sizeof(event), SM_EVENT_PAIRING_STARTED, sm_conn->sm_handle, setup->sm_peer_addr_type, setup->sm_peer_address); 658 sm_dispatch_event(HCI_EVENT_PACKET, 0, (uint8_t*) &event, sizeof(event)); 659 } 660 661 static void sm_pairing_complete(sm_connection_t * sm_conn, uint8_t status, uint8_t reason){ 662 663 if (!sm_conn->sm_pairing_active) return; 664 665 sm_conn->sm_pairing_active = false; 666 667 uint8_t event[13]; 668 sm_setup_event_base(event, sizeof(event), SM_EVENT_PAIRING_COMPLETE, sm_conn->sm_handle, setup->sm_peer_addr_type, setup->sm_peer_address); 669 event[11] = status; 670 event[12] = reason; 671 sm_dispatch_event(HCI_EVENT_PACKET, 0, (uint8_t*) &event, sizeof(event)); 672 } 673 674 // SMP Timeout implementation 675 676 // Upon transmission of the Pairing Request command or reception of the Pairing Request command, 677 // the Security Manager Timer shall be reset and started. 678 // 679 // The Security Manager Timer shall be reset when an L2CAP SMP command is queued for transmission. 680 // 681 // If the Security Manager Timer reaches 30 seconds, the procedure shall be considered to have failed, 682 // and the local higher layer shall be notified. No further SMP commands shall be sent over the L2CAP 683 // Security Manager Channel. A new SM procedure shall only be performed when a new physical link has been 684 // established. 685 686 static void sm_timeout_handler(btstack_timer_source_t * timer){ 687 log_info("SM timeout"); 688 sm_connection_t * sm_conn = (sm_connection_t*) btstack_run_loop_get_timer_context(timer); 689 sm_conn->sm_engine_state = SM_GENERAL_TIMEOUT; 690 sm_reencryption_complete(sm_conn, ERROR_CODE_CONNECTION_TIMEOUT); 691 sm_pairing_complete(sm_conn, ERROR_CODE_CONNECTION_TIMEOUT, 0); 692 sm_done_for_handle(sm_conn->sm_handle); 693 694 // trigger handling of next ready connection 695 sm_run(); 696 } 697 static void sm_timeout_start(sm_connection_t * sm_conn){ 698 btstack_run_loop_remove_timer(&setup->sm_timeout); 699 btstack_run_loop_set_timer_context(&setup->sm_timeout, sm_conn); 700 btstack_run_loop_set_timer_handler(&setup->sm_timeout, sm_timeout_handler); 701 btstack_run_loop_set_timer(&setup->sm_timeout, 30000); // 30 seconds sm timeout 702 btstack_run_loop_add_timer(&setup->sm_timeout); 703 } 704 static void sm_timeout_stop(void){ 705 btstack_run_loop_remove_timer(&setup->sm_timeout); 706 } 707 static void sm_timeout_reset(sm_connection_t * sm_conn){ 708 sm_timeout_stop(); 709 sm_timeout_start(sm_conn); 710 } 711 712 // end of sm timeout 713 714 // GAP Random Address updates 715 static gap_random_address_type_t gap_random_adress_type; 716 static btstack_timer_source_t gap_random_address_update_timer; 717 static uint32_t gap_random_adress_update_period; 718 719 static void gap_random_address_trigger(void){ 720 log_info("gap_random_address_trigger, state %u", rau_state); 721 if (rau_state != RAU_IDLE) return; 722 rau_state = RAU_GET_RANDOM; 723 sm_trigger_run(); 724 } 725 726 static void gap_random_address_update_handler(btstack_timer_source_t * timer){ 727 UNUSED(timer); 728 729 log_info("GAP Random Address Update due"); 730 btstack_run_loop_set_timer(&gap_random_address_update_timer, gap_random_adress_update_period); 731 btstack_run_loop_add_timer(&gap_random_address_update_timer); 732 gap_random_address_trigger(); 733 } 734 735 static void gap_random_address_update_start(void){ 736 btstack_run_loop_set_timer_handler(&gap_random_address_update_timer, gap_random_address_update_handler); 737 btstack_run_loop_set_timer(&gap_random_address_update_timer, gap_random_adress_update_period); 738 btstack_run_loop_add_timer(&gap_random_address_update_timer); 739 } 740 741 static void gap_random_address_update_stop(void){ 742 btstack_run_loop_remove_timer(&gap_random_address_update_timer); 743 } 744 745 // ah(k,r) helper 746 // r = padding || r 747 // r - 24 bit value 748 static void sm_ah_r_prime(uint8_t r[3], uint8_t * r_prime){ 749 // r'= padding || r 750 memset(r_prime, 0, 16); 751 (void)memcpy(&r_prime[13], r, 3); 752 } 753 754 // d1 helper 755 // d' = padding || r || d 756 // d,r - 16 bit values 757 static void sm_d1_d_prime(uint16_t d, uint16_t r, uint8_t * d1_prime){ 758 // d'= padding || r || d 759 memset(d1_prime, 0, 16); 760 big_endian_store_16(d1_prime, 12, r); 761 big_endian_store_16(d1_prime, 14, d); 762 } 763 764 // calculate arguments for first AES128 operation in C1 function 765 static void sm_c1_t1(sm_key_t r, uint8_t preq[7], uint8_t pres[7], uint8_t iat, uint8_t rat, uint8_t * t1){ 766 767 // p1 = pres || preq || rat’ || iat’ 768 // "The octet of iat’ becomes the least significant octet of p1 and the most signifi- 769 // cant octet of pres becomes the most significant octet of p1. 770 // For example, if the 8-bit iat’ is 0x01, the 8-bit rat’ is 0x00, the 56-bit preq 771 // is 0x07071000000101 and the 56 bit pres is 0x05000800000302 then 772 // p1 is 0x05000800000302070710000001010001." 773 774 sm_key_t p1; 775 reverse_56(pres, &p1[0]); 776 reverse_56(preq, &p1[7]); 777 p1[14] = rat; 778 p1[15] = iat; 779 log_info_key("p1", p1); 780 log_info_key("r", r); 781 782 // t1 = r xor p1 783 int i; 784 for (i=0;i<16;i++){ 785 t1[i] = r[i] ^ p1[i]; 786 } 787 log_info_key("t1", t1); 788 } 789 790 // calculate arguments for second AES128 operation in C1 function 791 static void sm_c1_t3(sm_key_t t2, bd_addr_t ia, bd_addr_t ra, uint8_t * t3){ 792 // p2 = padding || ia || ra 793 // "The least significant octet of ra becomes the least significant octet of p2 and 794 // the most significant octet of padding becomes the most significant octet of p2. 795 // For example, if 48-bit ia is 0xA1A2A3A4A5A6 and the 48-bit ra is 796 // 0xB1B2B3B4B5B6 then p2 is 0x00000000A1A2A3A4A5A6B1B2B3B4B5B6. 797 798 sm_key_t p2; 799 // cppcheck-suppress uninitvar ; p2 is reported as uninitialized 800 memset(p2, 0, 16); 801 (void)memcpy(&p2[4], ia, 6); 802 (void)memcpy(&p2[10], ra, 6); 803 log_info_key("p2", p2); 804 805 // c1 = e(k, t2_xor_p2) 806 int i; 807 for (i=0;i<16;i++){ 808 t3[i] = t2[i] ^ p2[i]; 809 } 810 log_info_key("t3", t3); 811 } 812 813 static void sm_s1_r_prime(sm_key_t r1, sm_key_t r2, uint8_t * r_prime){ 814 log_info_key("r1", r1); 815 log_info_key("r2", r2); 816 (void)memcpy(&r_prime[8], &r2[8], 8); 817 (void)memcpy(&r_prime[0], &r1[8], 8); 818 } 819 820 821 // decide on stk generation based on 822 // - pairing request 823 // - io capabilities 824 // - OOB data availability 825 static void sm_setup_tk(void){ 826 827 // horizontal: initiator capabilities 828 // vertial: responder capabilities 829 static const stk_generation_method_t stk_generation_method [5] [5] = { 830 { JUST_WORKS, JUST_WORKS, PK_INIT_INPUT, JUST_WORKS, PK_INIT_INPUT }, 831 { JUST_WORKS, JUST_WORKS, PK_INIT_INPUT, JUST_WORKS, PK_INIT_INPUT }, 832 { PK_RESP_INPUT, PK_RESP_INPUT, PK_BOTH_INPUT, JUST_WORKS, PK_RESP_INPUT }, 833 { JUST_WORKS, JUST_WORKS, JUST_WORKS, JUST_WORKS, JUST_WORKS }, 834 { PK_RESP_INPUT, PK_RESP_INPUT, PK_INIT_INPUT, JUST_WORKS, PK_RESP_INPUT }, 835 }; 836 837 // uses numeric comparison if one side has DisplayYesNo and KeyboardDisplay combinations 838 #ifdef ENABLE_LE_SECURE_CONNECTIONS 839 static const stk_generation_method_t stk_generation_method_with_secure_connection[5][5] = { 840 { JUST_WORKS, JUST_WORKS, PK_INIT_INPUT, JUST_WORKS, PK_INIT_INPUT }, 841 { JUST_WORKS, NUMERIC_COMPARISON, PK_INIT_INPUT, JUST_WORKS, NUMERIC_COMPARISON }, 842 { PK_RESP_INPUT, PK_RESP_INPUT, PK_BOTH_INPUT, JUST_WORKS, PK_RESP_INPUT }, 843 { JUST_WORKS, JUST_WORKS, JUST_WORKS, JUST_WORKS, JUST_WORKS }, 844 { PK_RESP_INPUT, NUMERIC_COMPARISON, PK_INIT_INPUT, JUST_WORKS, NUMERIC_COMPARISON }, 845 }; 846 #endif 847 848 // default: just works 849 setup->sm_stk_generation_method = JUST_WORKS; 850 851 #ifdef ENABLE_LE_SECURE_CONNECTIONS 852 setup->sm_use_secure_connections = ( sm_pairing_packet_get_auth_req(setup->sm_m_preq) 853 & sm_pairing_packet_get_auth_req(setup->sm_s_pres) 854 & SM_AUTHREQ_SECURE_CONNECTION ) != 0u; 855 #else 856 setup->sm_use_secure_connections = 0; 857 #endif 858 log_info("Secure pairing: %u", setup->sm_use_secure_connections); 859 860 861 // decide if OOB will be used based on SC vs. Legacy and oob flags 862 bool use_oob; 863 if (setup->sm_use_secure_connections){ 864 // In LE Secure Connections pairing, the out of band method is used if at least 865 // one device has the peer device's out of band authentication data available. 866 use_oob = (sm_pairing_packet_get_oob_data_flag(setup->sm_m_preq) | sm_pairing_packet_get_oob_data_flag(setup->sm_s_pres)) != 0; 867 } else { 868 // In LE legacy pairing, the out of band method is used if both the devices have 869 // the other device's out of band authentication data available. 870 use_oob = (sm_pairing_packet_get_oob_data_flag(setup->sm_m_preq) & sm_pairing_packet_get_oob_data_flag(setup->sm_s_pres)) != 0; 871 } 872 if (use_oob){ 873 log_info("SM: have OOB data"); 874 log_info_key("OOB", setup->sm_tk); 875 setup->sm_stk_generation_method = OOB; 876 return; 877 } 878 879 // If both devices have not set the MITM option in the Authentication Requirements 880 // Flags, then the IO capabilities shall be ignored and the Just Works association 881 // model shall be used. 882 if (((sm_pairing_packet_get_auth_req(setup->sm_m_preq) & SM_AUTHREQ_MITM_PROTECTION) == 0u) 883 && ((sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_MITM_PROTECTION) == 0u)){ 884 log_info("SM: MITM not required by both -> JUST WORKS"); 885 return; 886 } 887 888 // Reset TK as it has been setup in sm_init_setup 889 sm_reset_tk(); 890 891 // Also use just works if unknown io capabilites 892 if ((sm_pairing_packet_get_io_capability(setup->sm_m_preq) > IO_CAPABILITY_KEYBOARD_DISPLAY) || (sm_pairing_packet_get_io_capability(setup->sm_s_pres) > IO_CAPABILITY_KEYBOARD_DISPLAY)){ 893 return; 894 } 895 896 // Otherwise the IO capabilities of the devices shall be used to determine the 897 // pairing method as defined in Table 2.4. 898 // see http://stackoverflow.com/a/1052837/393697 for how to specify pointer to 2-dimensional array 899 const stk_generation_method_t (*generation_method)[5] = stk_generation_method; 900 901 #ifdef ENABLE_LE_SECURE_CONNECTIONS 902 // table not define by default 903 if (setup->sm_use_secure_connections){ 904 generation_method = stk_generation_method_with_secure_connection; 905 } 906 #endif 907 setup->sm_stk_generation_method = generation_method[sm_pairing_packet_get_io_capability(setup->sm_s_pres)][sm_pairing_packet_get_io_capability(setup->sm_m_preq)]; 908 909 log_info("sm_setup_tk: master io cap: %u, slave io cap: %u -> method %u", 910 sm_pairing_packet_get_io_capability(setup->sm_m_preq), sm_pairing_packet_get_io_capability(setup->sm_s_pres), setup->sm_stk_generation_method); 911 } 912 913 static int sm_key_distribution_flags_for_set(uint8_t key_set){ 914 int flags = 0; 915 if (key_set & SM_KEYDIST_ENC_KEY){ 916 flags |= SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION; 917 flags |= SM_KEYDIST_FLAG_MASTER_IDENTIFICATION; 918 } 919 if (key_set & SM_KEYDIST_ID_KEY){ 920 flags |= SM_KEYDIST_FLAG_IDENTITY_INFORMATION; 921 flags |= SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION; 922 } 923 if (key_set & SM_KEYDIST_SIGN){ 924 flags |= SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION; 925 } 926 return flags; 927 } 928 929 static void sm_setup_key_distribution(uint8_t keys_to_send, uint8_t keys_to_receive){ 930 setup->sm_key_distribution_received_set = 0; 931 setup->sm_key_distribution_expected_set = sm_key_distribution_flags_for_set(keys_to_receive); 932 setup->sm_key_distribution_send_set = sm_key_distribution_flags_for_set(keys_to_send); 933 setup->sm_key_distribution_sent_set = 0; 934 #ifdef ENABLE_LE_SIGNED_WRITE 935 setup->sm_le_device_index = -1; 936 #endif 937 } 938 939 // CSRK Key Lookup 940 941 942 static int sm_address_resolution_idle(void){ 943 return sm_address_resolution_mode == ADDRESS_RESOLUTION_IDLE; 944 } 945 946 static void sm_address_resolution_start_lookup(uint8_t addr_type, hci_con_handle_t con_handle, bd_addr_t addr, address_resolution_mode_t mode, void * context){ 947 (void)memcpy(sm_address_resolution_address, addr, 6); 948 sm_address_resolution_addr_type = addr_type; 949 sm_address_resolution_test = 0; 950 sm_address_resolution_mode = mode; 951 sm_address_resolution_context = context; 952 sm_notify_client_base(SM_EVENT_IDENTITY_RESOLVING_STARTED, con_handle, addr_type, addr); 953 } 954 955 int sm_address_resolution_lookup(uint8_t address_type, bd_addr_t address){ 956 // check if already in list 957 btstack_linked_list_iterator_t it; 958 sm_lookup_entry_t * entry; 959 btstack_linked_list_iterator_init(&it, &sm_address_resolution_general_queue); 960 while(btstack_linked_list_iterator_has_next(&it)){ 961 entry = (sm_lookup_entry_t *) btstack_linked_list_iterator_next(&it); 962 if (entry->address_type != address_type) continue; 963 if (memcmp(entry->address, address, 6)) continue; 964 // already in list 965 return BTSTACK_BUSY; 966 } 967 entry = btstack_memory_sm_lookup_entry_get(); 968 if (!entry) return BTSTACK_MEMORY_ALLOC_FAILED; 969 entry->address_type = (bd_addr_type_t) address_type; 970 (void)memcpy(entry->address, address, 6); 971 btstack_linked_list_add(&sm_address_resolution_general_queue, (btstack_linked_item_t *) entry); 972 sm_trigger_run(); 973 return 0; 974 } 975 976 // CMAC calculation using AES Engineq 977 #ifdef USE_CMAC_ENGINE 978 979 static void sm_cmac_done_trampoline(void * arg){ 980 UNUSED(arg); 981 sm_cmac_active = 0; 982 (*sm_cmac_done_callback)(sm_cmac_hash); 983 sm_trigger_run(); 984 } 985 986 int sm_cmac_ready(void){ 987 return sm_cmac_active == 0u; 988 } 989 #endif 990 991 #ifdef ENABLE_LE_SECURE_CONNECTIONS 992 // generic cmac calculation 993 static void sm_cmac_message_start(const sm_key_t key, uint16_t message_len, const uint8_t * message, void (*done_callback)(uint8_t * hash)){ 994 sm_cmac_active = 1; 995 sm_cmac_done_callback = done_callback; 996 btstack_crypto_aes128_cmac_message(&sm_cmac_request, key, message_len, message, sm_cmac_hash, sm_cmac_done_trampoline, NULL); 997 } 998 #endif 999 1000 // cmac for ATT Message signing 1001 #ifdef ENABLE_LE_SIGNED_WRITE 1002 1003 static void sm_cmac_generator_start(const sm_key_t key, uint16_t message_len, uint8_t (*get_byte_callback)(uint16_t offset), void (*done_callback)(uint8_t * hash)){ 1004 sm_cmac_active = 1; 1005 sm_cmac_done_callback = done_callback; 1006 btstack_crypto_aes128_cmac_generator(&sm_cmac_request, key, message_len, get_byte_callback, sm_cmac_hash, sm_cmac_done_trampoline, NULL); 1007 } 1008 1009 static uint8_t sm_cmac_signed_write_message_get_byte(uint16_t offset){ 1010 if (offset >= sm_cmac_signed_write_message_len) { 1011 log_error("sm_cmac_signed_write_message_get_byte. out of bounds, access %u, len %u", offset, sm_cmac_signed_write_message_len); 1012 return 0; 1013 } 1014 1015 offset = sm_cmac_signed_write_message_len - 1 - offset; 1016 1017 // sm_cmac_signed_write_header[3] | message[] | sm_cmac_signed_write_sign_counter[4] 1018 if (offset < 3){ 1019 return sm_cmac_signed_write_header[offset]; 1020 } 1021 int actual_message_len_incl_header = sm_cmac_signed_write_message_len - 4; 1022 if (offset < actual_message_len_incl_header){ 1023 return sm_cmac_signed_write_message[offset - 3]; 1024 } 1025 return sm_cmac_signed_write_sign_counter[offset - actual_message_len_incl_header]; 1026 } 1027 1028 void sm_cmac_signed_write_start(const sm_key_t k, uint8_t opcode, hci_con_handle_t con_handle, uint16_t message_len, const uint8_t * message, uint32_t sign_counter, void (*done_handler)(uint8_t * hash)){ 1029 // ATT Message Signing 1030 sm_cmac_signed_write_header[0] = opcode; 1031 little_endian_store_16(sm_cmac_signed_write_header, 1, con_handle); 1032 little_endian_store_32(sm_cmac_signed_write_sign_counter, 0, sign_counter); 1033 uint16_t total_message_len = 3 + message_len + 4; // incl. virtually prepended att opcode, handle and appended sign_counter in LE 1034 sm_cmac_signed_write_message = message; 1035 sm_cmac_signed_write_message_len = total_message_len; 1036 sm_cmac_generator_start(k, total_message_len, &sm_cmac_signed_write_message_get_byte, done_handler); 1037 } 1038 #endif 1039 1040 static void sm_trigger_user_response_basic(sm_connection_t * sm_conn, uint8_t event_type){ 1041 setup->sm_user_response = SM_USER_RESPONSE_PENDING; 1042 uint8_t event[12]; 1043 sm_setup_event_base(event, sizeof(event), event_type, sm_conn->sm_handle, sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address); 1044 event[11] = setup->sm_use_secure_connections ? 1 : 0; 1045 sm_dispatch_event(HCI_EVENT_PACKET, 0, event, sizeof(event)); 1046 } 1047 1048 static void sm_trigger_user_response_passkey(sm_connection_t * sm_conn, uint8_t event_type){ 1049 uint8_t event[16]; 1050 uint32_t passkey = big_endian_read_32(setup->sm_tk, 12); 1051 sm_setup_event_base(event, sizeof(event), event_type, sm_conn->sm_handle, 1052 sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address); 1053 event[11] = setup->sm_use_secure_connections ? 1 : 0; 1054 little_endian_store_32(event, 12, passkey); 1055 sm_dispatch_event(HCI_EVENT_PACKET, 0, event, sizeof(event)); 1056 } 1057 1058 static void sm_trigger_user_response(sm_connection_t * sm_conn){ 1059 // notify client for: JUST WORKS confirm, Numeric comparison confirm, PASSKEY display or input 1060 setup->sm_user_response = SM_USER_RESPONSE_IDLE; 1061 sm_conn->sm_pairing_active = true; 1062 switch (setup->sm_stk_generation_method){ 1063 case PK_RESP_INPUT: 1064 if (IS_RESPONDER(sm_conn->sm_role)){ 1065 sm_trigger_user_response_basic(sm_conn, SM_EVENT_PASSKEY_INPUT_NUMBER); 1066 } else { 1067 sm_trigger_user_response_passkey(sm_conn, SM_EVENT_PASSKEY_DISPLAY_NUMBER); 1068 } 1069 break; 1070 case PK_INIT_INPUT: 1071 if (IS_RESPONDER(sm_conn->sm_role)){ 1072 sm_trigger_user_response_passkey(sm_conn, SM_EVENT_PASSKEY_DISPLAY_NUMBER); 1073 } else { 1074 sm_trigger_user_response_basic(sm_conn, SM_EVENT_PASSKEY_INPUT_NUMBER); 1075 } 1076 break; 1077 case PK_BOTH_INPUT: 1078 sm_trigger_user_response_basic(sm_conn, SM_EVENT_PASSKEY_INPUT_NUMBER); 1079 break; 1080 case NUMERIC_COMPARISON: 1081 sm_trigger_user_response_passkey(sm_conn, SM_EVENT_NUMERIC_COMPARISON_REQUEST); 1082 break; 1083 case JUST_WORKS: 1084 sm_trigger_user_response_basic(sm_conn, SM_EVENT_JUST_WORKS_REQUEST); 1085 break; 1086 case OOB: 1087 // client already provided OOB data, let's skip notification. 1088 break; 1089 default: 1090 btstack_assert(false); 1091 break; 1092 } 1093 } 1094 1095 static bool sm_key_distribution_all_received(void) { 1096 log_debug("sm_key_distribution_all_received: received 0x%02x, expecting 0x%02x", setup->sm_key_distribution_received_set, setup->sm_key_distribution_expected_set); 1097 return (setup->sm_key_distribution_expected_set & setup->sm_key_distribution_received_set) == setup->sm_key_distribution_expected_set; 1098 } 1099 1100 static void sm_done_for_handle(hci_con_handle_t con_handle){ 1101 if (sm_active_connection_handle == con_handle){ 1102 sm_timeout_stop(); 1103 sm_active_connection_handle = HCI_CON_HANDLE_INVALID; 1104 log_info("sm: connection 0x%x released setup context", con_handle); 1105 1106 #ifdef ENABLE_LE_SECURE_CONNECTIONS 1107 // generate new ec key after each pairing (that used it) 1108 if (setup->sm_use_secure_connections){ 1109 sm_ec_generate_new_key(); 1110 } 1111 #endif 1112 } 1113 } 1114 1115 static void sm_master_pairing_success(sm_connection_t *connection) {// master -> all done 1116 connection->sm_engine_state = SM_INITIATOR_CONNECTED; 1117 sm_pairing_complete(connection, ERROR_CODE_SUCCESS, 0); 1118 sm_done_for_handle(connection->sm_handle); 1119 } 1120 1121 static int sm_key_distribution_flags_for_auth_req(void){ 1122 1123 int flags = SM_KEYDIST_ID_KEY; 1124 if (sm_auth_req & SM_AUTHREQ_BONDING){ 1125 // encryption and signing information only if bonding requested 1126 flags |= SM_KEYDIST_ENC_KEY; 1127 #ifdef ENABLE_LE_SIGNED_WRITE 1128 flags |= SM_KEYDIST_SIGN; 1129 #endif 1130 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 1131 // LinkKey for CTKD requires SC 1132 if (sm_auth_req & SM_AUTHREQ_SECURE_CONNECTION){ 1133 flags |= SM_KEYDIST_LINK_KEY; 1134 } 1135 #endif 1136 } 1137 return flags; 1138 } 1139 1140 static void sm_reset_setup(void){ 1141 // fill in sm setup 1142 setup->sm_state_vars = 0; 1143 setup->sm_keypress_notification = 0; 1144 setup->sm_have_oob_data = 0; 1145 sm_reset_tk(); 1146 } 1147 1148 static void sm_init_setup(sm_connection_t * sm_conn){ 1149 // fill in sm setup 1150 setup->sm_peer_addr_type = sm_conn->sm_peer_addr_type; 1151 (void)memcpy(setup->sm_peer_address, sm_conn->sm_peer_address, 6); 1152 1153 // query client for Legacy Pairing OOB data 1154 if (sm_get_oob_data != NULL) { 1155 setup->sm_have_oob_data = (*sm_get_oob_data)(sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address, setup->sm_tk); 1156 } 1157 1158 // if available and SC supported, also ask for SC OOB Data 1159 #ifdef ENABLE_LE_SECURE_CONNECTIONS 1160 memset(setup->sm_ra, 0, 16); 1161 memset(setup->sm_rb, 0, 16); 1162 if (setup->sm_have_oob_data && (sm_auth_req & SM_AUTHREQ_SECURE_CONNECTION)){ 1163 if (sm_get_sc_oob_data != NULL){ 1164 if (IS_RESPONDER(sm_conn->sm_role)){ 1165 setup->sm_have_oob_data = (*sm_get_sc_oob_data)( 1166 sm_conn->sm_peer_addr_type, 1167 sm_conn->sm_peer_address, 1168 setup->sm_peer_confirm, 1169 setup->sm_ra); 1170 } else { 1171 setup->sm_have_oob_data = (*sm_get_sc_oob_data)( 1172 sm_conn->sm_peer_addr_type, 1173 sm_conn->sm_peer_address, 1174 setup->sm_peer_confirm, 1175 setup->sm_rb); 1176 } 1177 } else { 1178 setup->sm_have_oob_data = 0; 1179 } 1180 } 1181 #endif 1182 1183 sm_pairing_packet_t * local_packet; 1184 if (IS_RESPONDER(sm_conn->sm_role)){ 1185 // slave 1186 local_packet = &setup->sm_s_pres; 1187 setup->sm_m_addr_type = sm_conn->sm_peer_addr_type; 1188 setup->sm_s_addr_type = sm_conn->sm_own_addr_type; 1189 (void)memcpy(setup->sm_m_address, sm_conn->sm_peer_address, 6); 1190 (void)memcpy(setup->sm_s_address, sm_conn->sm_own_address, 6); 1191 } else { 1192 // master 1193 local_packet = &setup->sm_m_preq; 1194 setup->sm_s_addr_type = sm_conn->sm_peer_addr_type; 1195 setup->sm_m_addr_type = sm_conn->sm_own_addr_type; 1196 (void)memcpy(setup->sm_s_address, sm_conn->sm_peer_address, 6); 1197 (void)memcpy(setup->sm_m_address, sm_conn->sm_own_address, 6); 1198 1199 uint8_t key_distribution_flags = sm_key_distribution_flags_for_auth_req(); 1200 sm_pairing_packet_set_initiator_key_distribution(setup->sm_m_preq, key_distribution_flags); 1201 sm_pairing_packet_set_responder_key_distribution(setup->sm_m_preq, key_distribution_flags); 1202 } 1203 1204 uint8_t auth_req = sm_auth_req & ~SM_AUTHREQ_CT2; 1205 uint8_t max_encryption_key_size = sm_max_encryption_key_size; 1206 #ifdef ENABLE_LE_SECURE_CONNECTIONS 1207 // enable SC for SC only mode 1208 if (sm_sc_only_mode){ 1209 auth_req |= SM_AUTHREQ_SECURE_CONNECTION; 1210 max_encryption_key_size = 16; 1211 } 1212 #endif 1213 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 1214 // set CT2 if SC + Bonding + CTKD 1215 const uint8_t auth_req_for_ct2 = SM_AUTHREQ_SECURE_CONNECTION | SM_AUTHREQ_BONDING; 1216 if ((auth_req & auth_req_for_ct2) == auth_req_for_ct2){ 1217 auth_req |= SM_AUTHREQ_CT2; 1218 } 1219 #endif 1220 sm_pairing_packet_set_io_capability(*local_packet, sm_io_capabilities); 1221 sm_pairing_packet_set_oob_data_flag(*local_packet, setup->sm_have_oob_data); 1222 sm_pairing_packet_set_auth_req(*local_packet, auth_req); 1223 sm_pairing_packet_set_max_encryption_key_size(*local_packet, max_encryption_key_size); 1224 } 1225 1226 static int sm_stk_generation_init(sm_connection_t * sm_conn){ 1227 1228 sm_pairing_packet_t * remote_packet; 1229 uint8_t keys_to_send; 1230 uint8_t keys_to_receive; 1231 if (IS_RESPONDER(sm_conn->sm_role)){ 1232 // slave / responder 1233 remote_packet = &setup->sm_m_preq; 1234 keys_to_send = sm_pairing_packet_get_responder_key_distribution(setup->sm_m_preq); 1235 keys_to_receive = sm_pairing_packet_get_initiator_key_distribution(setup->sm_m_preq); 1236 } else { 1237 // master / initiator 1238 remote_packet = &setup->sm_s_pres; 1239 keys_to_send = sm_pairing_packet_get_initiator_key_distribution(setup->sm_s_pres); 1240 keys_to_receive = sm_pairing_packet_get_responder_key_distribution(setup->sm_s_pres); 1241 } 1242 1243 // check key size 1244 #ifdef ENABLE_LE_SECURE_CONNECTIONS 1245 // SC Only mandates 128 bit key size 1246 if (sm_sc_only_mode && (sm_pairing_packet_get_max_encryption_key_size(*remote_packet) < 16)) { 1247 return SM_REASON_ENCRYPTION_KEY_SIZE; 1248 } 1249 #endif 1250 sm_conn->sm_actual_encryption_key_size = sm_calc_actual_encryption_key_size(sm_pairing_packet_get_max_encryption_key_size(*remote_packet)); 1251 if (sm_conn->sm_actual_encryption_key_size == 0u) return SM_REASON_ENCRYPTION_KEY_SIZE; 1252 1253 // decide on STK generation method / SC 1254 sm_setup_tk(); 1255 log_info("SMP: generation method %u", setup->sm_stk_generation_method); 1256 1257 // check if STK generation method is acceptable by client 1258 if (!sm_validate_stk_generation_method()) return SM_REASON_AUTHENTHICATION_REQUIREMENTS; 1259 1260 #ifdef ENABLE_LE_SECURE_CONNECTIONS 1261 // Check LE SC Only mode 1262 if (sm_sc_only_mode && (setup->sm_use_secure_connections == false)){ 1263 log_info("SC Only mode active but SC not possible"); 1264 return SM_REASON_AUTHENTHICATION_REQUIREMENTS; 1265 } 1266 1267 // LTK (= encryption information & master identification) only used exchanged for LE Legacy Connection 1268 if (setup->sm_use_secure_connections){ 1269 keys_to_send &= ~SM_KEYDIST_ENC_KEY; 1270 keys_to_receive &= ~SM_KEYDIST_ENC_KEY; 1271 } 1272 #endif 1273 1274 // identical to responder 1275 sm_setup_key_distribution(keys_to_send, keys_to_receive); 1276 1277 // JUST WORKS doens't provide authentication 1278 sm_conn->sm_connection_authenticated = (setup->sm_stk_generation_method == JUST_WORKS) ? 0 : 1; 1279 1280 return 0; 1281 } 1282 1283 static void sm_address_resolution_handle_event(address_resolution_event_t event){ 1284 1285 // cache and reset context 1286 int matched_device_id = sm_address_resolution_test; 1287 address_resolution_mode_t mode = sm_address_resolution_mode; 1288 void * context = sm_address_resolution_context; 1289 1290 // reset context 1291 sm_address_resolution_mode = ADDRESS_RESOLUTION_IDLE; 1292 sm_address_resolution_context = NULL; 1293 sm_address_resolution_test = -1; 1294 hci_con_handle_t con_handle = 0; 1295 1296 sm_connection_t * sm_connection; 1297 sm_key_t ltk; 1298 bool have_ltk; 1299 #ifdef ENABLE_LE_CENTRAL 1300 bool trigger_pairing; 1301 int authenticated; 1302 #endif 1303 switch (mode){ 1304 case ADDRESS_RESOLUTION_GENERAL: 1305 break; 1306 case ADDRESS_RESOLUTION_FOR_CONNECTION: 1307 sm_connection = (sm_connection_t *) context; 1308 con_handle = sm_connection->sm_handle; 1309 1310 // have ltk -> start encryption / send security request 1311 // Core 5, Vol 3, Part C, 10.3.2 Initiating a Service Request 1312 // "When a bond has been created between two devices, any reconnection should result in the local device 1313 // enabling or requesting encryption with the remote device before initiating any service request." 1314 1315 switch (event){ 1316 case ADDRESS_RESOLUTION_SUCCEEDED: 1317 sm_connection->sm_irk_lookup_state = IRK_LOOKUP_SUCCEEDED; 1318 sm_connection->sm_le_db_index = matched_device_id; 1319 log_info("ADDRESS_RESOLUTION_SUCCEEDED, index %d", sm_connection->sm_le_db_index); 1320 1321 le_device_db_encryption_get(sm_connection->sm_le_db_index, NULL, NULL, ltk, NULL, &authenticated, NULL, NULL); 1322 have_ltk = !sm_is_null_key(ltk); 1323 1324 if (sm_connection->sm_role) { 1325 #ifdef ENABLE_LE_PERIPHERAL 1326 // IRK required before, continue 1327 if (sm_connection->sm_engine_state == SM_RESPONDER_PH0_RECEIVED_LTK_W4_IRK){ 1328 sm_connection->sm_engine_state = SM_RESPONDER_PH0_RECEIVED_LTK_REQUEST; 1329 break; 1330 } 1331 if (sm_connection->sm_engine_state == SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED_W4_IRK){ 1332 sm_connection->sm_engine_state = SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED; 1333 break; 1334 } 1335 bool trigger_security_request = (sm_connection->sm_pairing_requested != 0) || (sm_slave_request_security != 0); 1336 sm_connection->sm_pairing_requested = 0; 1337 #ifdef ENABLE_LE_PROACTIVE_AUTHENTICATION 1338 // trigger security request for Proactive Authentication if LTK available 1339 trigger_security_request = trigger_security_request || have_ltk; 1340 #endif 1341 1342 log_info("peripheral: pairing request local %u, have_ltk %u => trigger_security_request %u", 1343 sm_connection->sm_pairing_requested, (int) have_ltk, trigger_security_request); 1344 1345 if (trigger_security_request){ 1346 sm_connection->sm_engine_state = SM_RESPONDER_SEND_SECURITY_REQUEST; 1347 if (have_ltk){ 1348 sm_reencryption_started(sm_connection); 1349 } else { 1350 sm_pairing_started(sm_connection); 1351 } 1352 sm_trigger_run(); 1353 } 1354 #endif 1355 } else { 1356 1357 #ifdef ENABLE_LE_CENTRAL 1358 // check if pairing already requested and reset requests 1359 trigger_pairing = sm_connection->sm_pairing_requested || sm_connection->sm_security_request_received; 1360 bool auth_required = sm_auth_req & SM_AUTHREQ_MITM_PROTECTION; 1361 1362 log_info("central: pairing request local %u, remote %u => trigger_pairing %u. have_ltk %u", 1363 sm_connection->sm_pairing_requested, sm_connection->sm_security_request_received, (int) trigger_pairing, (int) have_ltk); 1364 sm_connection->sm_security_request_received = 0; 1365 sm_connection->sm_pairing_requested = 0; 1366 bool trigger_reencryption = false; 1367 1368 if (have_ltk){ 1369 if (trigger_pairing){ 1370 // if pairing is requested, re-encryption is sufficient, if ltk is already authenticated or we don't require authentication 1371 trigger_reencryption = (authenticated != 0) || (auth_required == false); 1372 } else { 1373 #ifdef ENABLE_LE_PROACTIVE_AUTHENTICATION 1374 trigger_reencryption = true; 1375 #else 1376 log_info("central: defer enabling encryption for bonded device"); 1377 #endif 1378 } 1379 } 1380 1381 if (trigger_reencryption){ 1382 log_info("central: enable encryption for bonded device"); 1383 sm_connection->sm_engine_state = SM_INITIATOR_PH4_HAS_LTK; 1384 break; 1385 } 1386 1387 // pairing_request -> send pairing request 1388 if (trigger_pairing){ 1389 sm_connection->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST; 1390 break; 1391 } 1392 #endif 1393 } 1394 break; 1395 case ADDRESS_RESOLUTION_FAILED: 1396 sm_connection->sm_irk_lookup_state = IRK_LOOKUP_FAILED; 1397 if (sm_connection->sm_role) { 1398 #ifdef ENABLE_LE_PERIPHERAL 1399 // LTK request received before, IRK required -> negative LTK reply 1400 if (sm_connection->sm_engine_state == SM_RESPONDER_PH0_RECEIVED_LTK_W4_IRK){ 1401 sm_connection->sm_engine_state = SM_RESPONDER_PH0_SEND_LTK_REQUESTED_NEGATIVE_REPLY; 1402 } 1403 // send security request if requested 1404 bool trigger_security_request = (sm_connection->sm_pairing_requested != 0) || (sm_slave_request_security != 0); 1405 sm_connection->sm_pairing_requested = 0; 1406 if (trigger_security_request){ 1407 sm_connection->sm_engine_state = SM_RESPONDER_SEND_SECURITY_REQUEST; 1408 sm_pairing_started(sm_connection); 1409 } 1410 break; 1411 #endif 1412 } 1413 #ifdef ENABLE_LE_CENTRAL 1414 if (!sm_connection->sm_pairing_requested && !sm_connection->sm_security_request_received) break; 1415 sm_connection->sm_security_request_received = 0; 1416 sm_connection->sm_pairing_requested = 0; 1417 sm_connection->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST; 1418 #endif 1419 break; 1420 1421 default: 1422 btstack_assert(false); 1423 break; 1424 } 1425 break; 1426 default: 1427 break; 1428 } 1429 1430 switch (event){ 1431 case ADDRESS_RESOLUTION_SUCCEEDED: 1432 sm_notify_client_index(SM_EVENT_IDENTITY_RESOLVING_SUCCEEDED, con_handle, sm_address_resolution_addr_type, sm_address_resolution_address, matched_device_id); 1433 break; 1434 case ADDRESS_RESOLUTION_FAILED: 1435 sm_notify_client_base(SM_EVENT_IDENTITY_RESOLVING_FAILED, con_handle, sm_address_resolution_addr_type, sm_address_resolution_address); 1436 break; 1437 default: 1438 btstack_assert(false); 1439 break; 1440 } 1441 } 1442 1443 static void sm_store_bonding_information(sm_connection_t * sm_conn){ 1444 int le_db_index = -1; 1445 1446 // lookup device based on IRK 1447 if (setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_IDENTITY_INFORMATION){ 1448 int i; 1449 for (i=0; i < le_device_db_max_count(); i++){ 1450 sm_key_t irk; 1451 bd_addr_t address; 1452 int address_type = BD_ADDR_TYPE_UNKNOWN; 1453 le_device_db_info(i, &address_type, address, irk); 1454 // skip unused entries 1455 if (address_type == BD_ADDR_TYPE_UNKNOWN) continue; 1456 // compare Identity Address 1457 if (memcmp(address, setup->sm_peer_address, 6) != 0) continue; 1458 // compare Identity Resolving Key 1459 if (memcmp(irk, setup->sm_peer_irk, 16) != 0) continue; 1460 1461 log_info("sm: device found for IRK, updating"); 1462 le_db_index = i; 1463 break; 1464 } 1465 } else { 1466 // assert IRK is set to zero 1467 memset(setup->sm_peer_irk, 0, 16); 1468 } 1469 1470 // if not found, lookup via public address if possible 1471 log_info("sm peer addr type %u, peer addres %s", setup->sm_peer_addr_type, bd_addr_to_str(setup->sm_peer_address)); 1472 if ((le_db_index < 0) && (setup->sm_peer_addr_type == BD_ADDR_TYPE_LE_PUBLIC)){ 1473 int i; 1474 for (i=0; i < le_device_db_max_count(); i++){ 1475 bd_addr_t address; 1476 int address_type = BD_ADDR_TYPE_UNKNOWN; 1477 le_device_db_info(i, &address_type, address, NULL); 1478 // skip unused entries 1479 if (address_type == BD_ADDR_TYPE_UNKNOWN) continue; 1480 log_info("device %u, sm peer addr type %u, peer addres %s", i, address_type, bd_addr_to_str(address)); 1481 if ((address_type == BD_ADDR_TYPE_LE_PUBLIC) && (memcmp(address, setup->sm_peer_address, 6) == 0)){ 1482 log_info("sm: device found for public address, updating"); 1483 le_db_index = i; 1484 break; 1485 } 1486 } 1487 } 1488 1489 // if not found, add to db 1490 bool new_to_le_device_db = false; 1491 if (le_db_index < 0) { 1492 le_db_index = le_device_db_add(setup->sm_peer_addr_type, setup->sm_peer_address, setup->sm_peer_irk); 1493 new_to_le_device_db = true; 1494 } 1495 1496 if (le_db_index >= 0){ 1497 1498 #ifdef ENABLE_LE_PRIVACY_ADDRESS_RESOLUTION 1499 if (!new_to_le_device_db){ 1500 hci_remove_le_device_db_entry_from_resolving_list(le_db_index); 1501 } 1502 hci_load_le_device_db_entry_into_resolving_list(le_db_index); 1503 #else 1504 UNUSED(new_to_le_device_db); 1505 #endif 1506 1507 sm_notify_client_index(SM_EVENT_IDENTITY_CREATED, sm_conn->sm_handle, setup->sm_peer_addr_type, setup->sm_peer_address, le_db_index); 1508 sm_conn->sm_irk_lookup_state = IRK_LOOKUP_SUCCEEDED; 1509 sm_conn->sm_le_db_index = le_db_index; 1510 1511 #ifdef ENABLE_LE_SIGNED_WRITE 1512 // store local CSRK 1513 setup->sm_le_device_index = le_db_index; 1514 if ((setup->sm_key_distribution_sent_set) & SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION){ 1515 log_info("sm: store local CSRK"); 1516 le_device_db_local_csrk_set(le_db_index, setup->sm_local_csrk); 1517 le_device_db_local_counter_set(le_db_index, 0); 1518 } 1519 1520 // store remote CSRK 1521 if (setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION){ 1522 log_info("sm: store remote CSRK"); 1523 le_device_db_remote_csrk_set(le_db_index, setup->sm_peer_csrk); 1524 le_device_db_remote_counter_set(le_db_index, 0); 1525 } 1526 #endif 1527 // store encryption information for secure connections: LTK generated by ECDH 1528 if (setup->sm_use_secure_connections){ 1529 log_info("sm: store SC LTK (key size %u, authenticated %u)", sm_conn->sm_actual_encryption_key_size, sm_conn->sm_connection_authenticated); 1530 uint8_t zero_rand[8]; 1531 memset(zero_rand, 0, 8); 1532 le_device_db_encryption_set(le_db_index, 0, zero_rand, setup->sm_ltk, sm_conn->sm_actual_encryption_key_size, 1533 sm_conn->sm_connection_authenticated, sm_conn->sm_connection_authorization_state == AUTHORIZATION_GRANTED, 1); 1534 } 1535 1536 // store encryption information for legacy pairing: peer LTK, EDIV, RAND 1537 else if ( (setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION) 1538 && (setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_MASTER_IDENTIFICATION )){ 1539 log_info("sm: set encryption information (key size %u, authenticated %u)", sm_conn->sm_actual_encryption_key_size, sm_conn->sm_connection_authenticated); 1540 le_device_db_encryption_set(le_db_index, setup->sm_peer_ediv, setup->sm_peer_rand, setup->sm_peer_ltk, 1541 sm_conn->sm_actual_encryption_key_size, sm_conn->sm_connection_authenticated, sm_conn->sm_connection_authorization_state == AUTHORIZATION_GRANTED, 0); 1542 1543 } 1544 } 1545 } 1546 1547 static void sm_pairing_error(sm_connection_t * sm_conn, uint8_t reason){ 1548 sm_conn->sm_pairing_failed_reason = reason; 1549 sm_conn->sm_engine_state = SM_GENERAL_SEND_PAIRING_FAILED; 1550 } 1551 1552 static int sm_le_device_db_index_lookup(bd_addr_type_t address_type, bd_addr_t address){ 1553 int i; 1554 for (i=0; i < le_device_db_max_count(); i++){ 1555 bd_addr_t db_address; 1556 int db_address_type = BD_ADDR_TYPE_UNKNOWN; 1557 le_device_db_info(i, &db_address_type, db_address, NULL); 1558 // skip unused entries 1559 if (address_type == BD_ADDR_TYPE_UNKNOWN) continue; 1560 if ((address_type == db_address_type) && (memcmp(address, db_address, 6) == 0)){ 1561 return i; 1562 } 1563 } 1564 return -1; 1565 } 1566 1567 static void sm_remove_le_device_db_entry(uint16_t i) { 1568 le_device_db_remove(i); 1569 #ifdef ENABLE_LE_PRIVACY_ADDRESS_RESOLUTION 1570 // to remove an entry from the resolving list requires its identity address, which was already deleted 1571 // fully reload resolving list instead 1572 gap_load_resolving_list_from_le_device_db(); 1573 #endif 1574 } 1575 1576 static uint8_t sm_key_distribution_validate_received(sm_connection_t * sm_conn){ 1577 // if identity is provided, abort if we have bonding with same address but different irk 1578 if (setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_IDENTITY_INFORMATION){ 1579 int index = sm_le_device_db_index_lookup(BD_ADDR_TYPE_LE_PUBLIC, setup->sm_peer_address); 1580 if (index >= 0){ 1581 sm_key_t irk; 1582 le_device_db_info(index, NULL, NULL, irk); 1583 if (memcmp(irk, setup->sm_peer_irk, 16) != 0){ 1584 // IRK doesn't match, delete bonding information 1585 log_info("New IRK for %s (type %u) does not match stored IRK -> delete bonding information", bd_addr_to_str(sm_conn->sm_peer_address), sm_conn->sm_peer_addr_type); 1586 sm_remove_le_device_db_entry(index); 1587 } 1588 } 1589 } 1590 return 0; 1591 } 1592 1593 static void sm_key_distribution_handle_all_received(sm_connection_t * sm_conn){ 1594 1595 // abort pairing if received keys are not valid 1596 uint8_t reason = sm_key_distribution_validate_received(sm_conn); 1597 if (reason != 0){ 1598 sm_pairing_error(sm_conn, reason); 1599 return; 1600 } 1601 1602 // only store pairing information if both sides are bondable, i.e., the bonadble flag is set 1603 bool bonding_enabled = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) 1604 & sm_pairing_packet_get_auth_req(setup->sm_s_pres) 1605 & SM_AUTHREQ_BONDING ) != 0u; 1606 1607 if (bonding_enabled){ 1608 sm_store_bonding_information(sm_conn); 1609 } else { 1610 log_info("Ignoring received keys, bonding not enabled"); 1611 } 1612 } 1613 1614 static inline void sm_pdu_received_in_wrong_state(sm_connection_t * sm_conn){ 1615 sm_pairing_error(sm_conn, SM_REASON_UNSPECIFIED_REASON); 1616 } 1617 1618 #ifdef ENABLE_LE_SECURE_CONNECTIONS 1619 1620 static void sm_sc_prepare_dhkey_check(sm_connection_t * sm_conn); 1621 static int sm_passkey_used(stk_generation_method_t method); 1622 static int sm_just_works_or_numeric_comparison(stk_generation_method_t method); 1623 1624 static void sm_sc_start_calculating_local_confirm(sm_connection_t * sm_conn){ 1625 if (setup->sm_stk_generation_method == OOB){ 1626 sm_conn->sm_engine_state = SM_SC_W2_CMAC_FOR_CONFIRMATION; 1627 } else { 1628 btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_nonce, 16, &sm_handle_random_result_sc_next_w2_cmac_for_confirmation, (void *)(uintptr_t) sm_conn->sm_handle); 1629 } 1630 } 1631 1632 static void sm_sc_state_after_receiving_random(sm_connection_t * sm_conn){ 1633 if (IS_RESPONDER(sm_conn->sm_role)){ 1634 // Responder 1635 if (setup->sm_stk_generation_method == OOB){ 1636 // generate Nb 1637 log_info("Generate Nb"); 1638 btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_nonce, 16, &sm_handle_random_result_sc_next_send_pairing_random, (void *)(uintptr_t) sm_conn->sm_handle); 1639 } else { 1640 sm_conn->sm_engine_state = SM_SC_SEND_PAIRING_RANDOM; 1641 } 1642 } else { 1643 // Initiator role 1644 switch (setup->sm_stk_generation_method){ 1645 case JUST_WORKS: 1646 sm_sc_prepare_dhkey_check(sm_conn); 1647 break; 1648 1649 case NUMERIC_COMPARISON: 1650 sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_G2; 1651 break; 1652 case PK_INIT_INPUT: 1653 case PK_RESP_INPUT: 1654 case PK_BOTH_INPUT: 1655 if (setup->sm_passkey_bit < 20u) { 1656 sm_sc_start_calculating_local_confirm(sm_conn); 1657 } else { 1658 sm_sc_prepare_dhkey_check(sm_conn); 1659 } 1660 break; 1661 case OOB: 1662 sm_sc_prepare_dhkey_check(sm_conn); 1663 break; 1664 default: 1665 btstack_assert(false); 1666 break; 1667 } 1668 } 1669 } 1670 1671 static void sm_sc_cmac_done(uint8_t * hash){ 1672 log_info("sm_sc_cmac_done: "); 1673 log_info_hexdump(hash, 16); 1674 1675 if (sm_sc_oob_state == SM_SC_OOB_W4_CONFIRM){ 1676 sm_sc_oob_state = SM_SC_OOB_IDLE; 1677 (*sm_sc_oob_callback)(hash, sm_sc_oob_random); 1678 return; 1679 } 1680 1681 sm_connection_t * sm_conn = sm_cmac_connection; 1682 sm_cmac_connection = NULL; 1683 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 1684 link_key_type_t link_key_type; 1685 #endif 1686 1687 switch (sm_conn->sm_engine_state){ 1688 case SM_SC_W4_CMAC_FOR_CONFIRMATION: 1689 (void)memcpy(setup->sm_local_confirm, hash, 16); 1690 sm_conn->sm_engine_state = SM_SC_SEND_CONFIRMATION; 1691 break; 1692 case SM_SC_W4_CMAC_FOR_CHECK_CONFIRMATION: 1693 // check 1694 if (0 != memcmp(hash, setup->sm_peer_confirm, 16)){ 1695 sm_pairing_error(sm_conn, SM_REASON_CONFIRM_VALUE_FAILED); 1696 break; 1697 } 1698 sm_sc_state_after_receiving_random(sm_conn); 1699 break; 1700 case SM_SC_W4_CALCULATE_G2: { 1701 uint32_t vab = big_endian_read_32(hash, 12) % 1000000; 1702 big_endian_store_32(setup->sm_tk, 12, vab); 1703 sm_conn->sm_engine_state = SM_SC_W4_USER_RESPONSE; 1704 sm_trigger_user_response(sm_conn); 1705 break; 1706 } 1707 case SM_SC_W4_CALCULATE_F5_SALT: 1708 (void)memcpy(setup->sm_t, hash, 16); 1709 sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F5_MACKEY; 1710 break; 1711 case SM_SC_W4_CALCULATE_F5_MACKEY: 1712 (void)memcpy(setup->sm_mackey, hash, 16); 1713 sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F5_LTK; 1714 break; 1715 case SM_SC_W4_CALCULATE_F5_LTK: 1716 // truncate sm_ltk, but keep full LTK for cross-transport key derivation in sm_local_ltk 1717 // Errata Service Release to the Bluetooth Specification: ESR09 1718 // E6405 – Cross transport key derivation from a key of size less than 128 bits 1719 // Note: When the BR/EDR link key is being derived from the LTK, the derivation is done before the LTK gets masked." 1720 (void)memcpy(setup->sm_ltk, hash, 16); 1721 (void)memcpy(setup->sm_local_ltk, hash, 16); 1722 sm_truncate_key(setup->sm_ltk, sm_conn->sm_actual_encryption_key_size); 1723 sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F6_FOR_DHKEY_CHECK; 1724 break; 1725 case SM_SC_W4_CALCULATE_F6_FOR_DHKEY_CHECK: 1726 (void)memcpy(setup->sm_local_dhkey_check, hash, 16); 1727 if (IS_RESPONDER(sm_conn->sm_role)){ 1728 // responder 1729 if (setup->sm_state_vars & SM_STATE_VAR_DHKEY_COMMAND_RECEIVED){ 1730 sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F6_TO_VERIFY_DHKEY_CHECK; 1731 } else { 1732 sm_conn->sm_engine_state = SM_SC_W4_DHKEY_CHECK_COMMAND; 1733 } 1734 } else { 1735 sm_conn->sm_engine_state = SM_SC_SEND_DHKEY_CHECK_COMMAND; 1736 } 1737 break; 1738 case SM_SC_W4_CALCULATE_F6_TO_VERIFY_DHKEY_CHECK: 1739 if (0 != memcmp(hash, setup->sm_peer_dhkey_check, 16) ){ 1740 sm_pairing_error(sm_conn, SM_REASON_DHKEY_CHECK_FAILED); 1741 break; 1742 } 1743 if (IS_RESPONDER(sm_conn->sm_role)){ 1744 // responder 1745 sm_conn->sm_engine_state = SM_SC_SEND_DHKEY_CHECK_COMMAND; 1746 } else { 1747 // initiator 1748 sm_conn->sm_engine_state = SM_INITIATOR_PH3_SEND_START_ENCRYPTION; 1749 } 1750 break; 1751 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 1752 case SM_SC_W4_CALCULATE_ILK: 1753 (void)memcpy(setup->sm_t, hash, 16); 1754 sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_BR_EDR_LINK_KEY; 1755 break; 1756 case SM_SC_W4_CALCULATE_BR_EDR_LINK_KEY: 1757 reverse_128(hash, setup->sm_t); 1758 link_key_type = sm_conn->sm_connection_authenticated ? 1759 AUTHENTICATED_COMBINATION_KEY_GENERATED_FROM_P256 : UNAUTHENTICATED_COMBINATION_KEY_GENERATED_FROM_P256; 1760 log_info("Derived classic link key from LE using h6, type %u", (int) link_key_type); 1761 gap_store_link_key_for_bd_addr(setup->sm_peer_address, setup->sm_t, link_key_type); 1762 if (IS_RESPONDER(sm_conn->sm_role)){ 1763 sm_conn->sm_engine_state = SM_RESPONDER_IDLE; 1764 } else { 1765 sm_conn->sm_engine_state = SM_INITIATOR_CONNECTED; 1766 } 1767 sm_pairing_complete(sm_conn, ERROR_CODE_SUCCESS, 0); 1768 sm_done_for_handle(sm_conn->sm_handle); 1769 break; 1770 case SM_BR_EDR_W4_CALCULATE_ILK: 1771 (void)memcpy(setup->sm_t, hash, 16); 1772 sm_conn->sm_engine_state = SM_BR_EDR_W2_CALCULATE_LE_LTK; 1773 break; 1774 case SM_BR_EDR_W4_CALCULATE_LE_LTK: 1775 log_info("Derived LE LTK from BR/EDR Link Key"); 1776 log_info_key("Link Key", hash); 1777 (void)memcpy(setup->sm_ltk, hash, 16); 1778 sm_truncate_key(setup->sm_ltk, sm_conn->sm_actual_encryption_key_size); 1779 sm_conn->sm_connection_authenticated = setup->sm_link_key_type == AUTHENTICATED_COMBINATION_KEY_GENERATED_FROM_P256; 1780 sm_store_bonding_information(sm_conn); 1781 sm_done_for_handle(sm_conn->sm_handle); 1782 break; 1783 #endif 1784 default: 1785 log_error("sm_sc_cmac_done in state %u", sm_conn->sm_engine_state); 1786 break; 1787 } 1788 sm_trigger_run(); 1789 } 1790 1791 static void f4_engine(sm_connection_t * sm_conn, const sm_key256_t u, const sm_key256_t v, const sm_key_t x, uint8_t z){ 1792 const uint16_t message_len = 65; 1793 sm_cmac_connection = sm_conn; 1794 (void)memcpy(sm_cmac_sc_buffer, u, 32); 1795 (void)memcpy(sm_cmac_sc_buffer + 32, v, 32); 1796 sm_cmac_sc_buffer[64] = z; 1797 log_info("f4 key"); 1798 log_info_hexdump(x, 16); 1799 log_info("f4 message"); 1800 log_info_hexdump(sm_cmac_sc_buffer, message_len); 1801 sm_cmac_message_start(x, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done); 1802 } 1803 1804 static const uint8_t f5_key_id[] = { 0x62, 0x74, 0x6c, 0x65 }; 1805 static const uint8_t f5_length[] = { 0x01, 0x00}; 1806 1807 static void f5_calculate_salt(sm_connection_t * sm_conn){ 1808 1809 static const sm_key_t f5_salt = { 0x6C ,0x88, 0x83, 0x91, 0xAA, 0xF5, 0xA5, 0x38, 0x60, 0x37, 0x0B, 0xDB, 0x5A, 0x60, 0x83, 0xBE}; 1810 1811 log_info("f5_calculate_salt"); 1812 // calculate salt for f5 1813 const uint16_t message_len = 32; 1814 sm_cmac_connection = sm_conn; 1815 (void)memcpy(sm_cmac_sc_buffer, setup->sm_dhkey, message_len); 1816 sm_cmac_message_start(f5_salt, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done); 1817 } 1818 1819 static inline void f5_mackkey(sm_connection_t * sm_conn, sm_key_t t, const sm_key_t n1, const sm_key_t n2, const sm_key56_t a1, const sm_key56_t a2){ 1820 const uint16_t message_len = 53; 1821 sm_cmac_connection = sm_conn; 1822 1823 // f5(W, N1, N2, A1, A2) = AES-CMACT (Counter = 0 || keyID || N1 || N2|| A1|| A2 || Length = 256) -- this is the MacKey 1824 sm_cmac_sc_buffer[0] = 0; 1825 (void)memcpy(sm_cmac_sc_buffer + 01, f5_key_id, 4); 1826 (void)memcpy(sm_cmac_sc_buffer + 05, n1, 16); 1827 (void)memcpy(sm_cmac_sc_buffer + 21, n2, 16); 1828 (void)memcpy(sm_cmac_sc_buffer + 37, a1, 7); 1829 (void)memcpy(sm_cmac_sc_buffer + 44, a2, 7); 1830 (void)memcpy(sm_cmac_sc_buffer + 51, f5_length, 2); 1831 log_info("f5 key"); 1832 log_info_hexdump(t, 16); 1833 log_info("f5 message for MacKey"); 1834 log_info_hexdump(sm_cmac_sc_buffer, message_len); 1835 sm_cmac_message_start(t, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done); 1836 } 1837 1838 static void f5_calculate_mackey(sm_connection_t * sm_conn){ 1839 sm_key56_t bd_addr_master, bd_addr_slave; 1840 bd_addr_master[0] = setup->sm_m_addr_type; 1841 bd_addr_slave[0] = setup->sm_s_addr_type; 1842 (void)memcpy(&bd_addr_master[1], setup->sm_m_address, 6); 1843 (void)memcpy(&bd_addr_slave[1], setup->sm_s_address, 6); 1844 if (IS_RESPONDER(sm_conn->sm_role)){ 1845 // responder 1846 f5_mackkey(sm_conn, setup->sm_t, setup->sm_peer_nonce, setup->sm_local_nonce, bd_addr_master, bd_addr_slave); 1847 } else { 1848 // initiator 1849 f5_mackkey(sm_conn, setup->sm_t, setup->sm_local_nonce, setup->sm_peer_nonce, bd_addr_master, bd_addr_slave); 1850 } 1851 } 1852 1853 // note: must be called right after f5_mackey, as sm_cmac_buffer[1..52] will be reused 1854 static inline void f5_ltk(sm_connection_t * sm_conn, sm_key_t t){ 1855 const uint16_t message_len = 53; 1856 sm_cmac_connection = sm_conn; 1857 sm_cmac_sc_buffer[0] = 1; 1858 // 1..52 setup before 1859 log_info("f5 key"); 1860 log_info_hexdump(t, 16); 1861 log_info("f5 message for LTK"); 1862 log_info_hexdump(sm_cmac_sc_buffer, message_len); 1863 sm_cmac_message_start(t, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done); 1864 } 1865 1866 static void f5_calculate_ltk(sm_connection_t * sm_conn){ 1867 f5_ltk(sm_conn, setup->sm_t); 1868 } 1869 1870 static void f6_setup(const sm_key_t n1, const sm_key_t n2, const sm_key_t r, const sm_key24_t io_cap, const sm_key56_t a1, const sm_key56_t a2){ 1871 (void)memcpy(sm_cmac_sc_buffer, n1, 16); 1872 (void)memcpy(sm_cmac_sc_buffer + 16, n2, 16); 1873 (void)memcpy(sm_cmac_sc_buffer + 32, r, 16); 1874 (void)memcpy(sm_cmac_sc_buffer + 48, io_cap, 3); 1875 (void)memcpy(sm_cmac_sc_buffer + 51, a1, 7); 1876 (void)memcpy(sm_cmac_sc_buffer + 58, a2, 7); 1877 } 1878 1879 static void f6_engine(sm_connection_t * sm_conn, const sm_key_t w){ 1880 const uint16_t message_len = 65; 1881 sm_cmac_connection = sm_conn; 1882 log_info("f6 key"); 1883 log_info_hexdump(w, 16); 1884 log_info("f6 message"); 1885 log_info_hexdump(sm_cmac_sc_buffer, message_len); 1886 sm_cmac_message_start(w, 65, sm_cmac_sc_buffer, &sm_sc_cmac_done); 1887 } 1888 1889 // g2(U, V, X, Y) = AES-CMACX(U || V || Y) mod 2^32 1890 // - U is 256 bits 1891 // - V is 256 bits 1892 // - X is 128 bits 1893 // - Y is 128 bits 1894 static void g2_engine(sm_connection_t * sm_conn, const sm_key256_t u, const sm_key256_t v, const sm_key_t x, const sm_key_t y){ 1895 const uint16_t message_len = 80; 1896 sm_cmac_connection = sm_conn; 1897 (void)memcpy(sm_cmac_sc_buffer, u, 32); 1898 (void)memcpy(sm_cmac_sc_buffer + 32, v, 32); 1899 (void)memcpy(sm_cmac_sc_buffer + 64, y, 16); 1900 log_info("g2 key"); 1901 log_info_hexdump(x, 16); 1902 log_info("g2 message"); 1903 log_info_hexdump(sm_cmac_sc_buffer, message_len); 1904 sm_cmac_message_start(x, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done); 1905 } 1906 1907 static void g2_calculate(sm_connection_t * sm_conn) { 1908 // calc Va if numeric comparison 1909 if (IS_RESPONDER(sm_conn->sm_role)){ 1910 // responder 1911 g2_engine(sm_conn, setup->sm_peer_q, ec_q, setup->sm_peer_nonce, setup->sm_local_nonce);; 1912 } else { 1913 // initiator 1914 g2_engine(sm_conn, ec_q, setup->sm_peer_q, setup->sm_local_nonce, setup->sm_peer_nonce); 1915 } 1916 } 1917 1918 static void sm_sc_calculate_local_confirm(sm_connection_t * sm_conn){ 1919 uint8_t z = 0; 1920 if (sm_passkey_entry(setup->sm_stk_generation_method)){ 1921 // some form of passkey 1922 uint32_t pk = big_endian_read_32(setup->sm_tk, 12); 1923 z = 0x80u | ((pk >> setup->sm_passkey_bit) & 1u); 1924 setup->sm_passkey_bit++; 1925 } 1926 f4_engine(sm_conn, ec_q, setup->sm_peer_q, setup->sm_local_nonce, z); 1927 } 1928 1929 static void sm_sc_calculate_remote_confirm(sm_connection_t * sm_conn){ 1930 // OOB 1931 if (setup->sm_stk_generation_method == OOB){ 1932 if (IS_RESPONDER(sm_conn->sm_role)){ 1933 f4_engine(sm_conn, setup->sm_peer_q, setup->sm_peer_q, setup->sm_ra, 0); 1934 } else { 1935 f4_engine(sm_conn, setup->sm_peer_q, setup->sm_peer_q, setup->sm_rb, 0); 1936 } 1937 return; 1938 } 1939 1940 uint8_t z = 0; 1941 if (sm_passkey_entry(setup->sm_stk_generation_method)){ 1942 // some form of passkey 1943 uint32_t pk = big_endian_read_32(setup->sm_tk, 12); 1944 // sm_passkey_bit was increased before sending confirm value 1945 z = 0x80u | ((pk >> (setup->sm_passkey_bit-1u)) & 1u); 1946 } 1947 f4_engine(sm_conn, setup->sm_peer_q, ec_q, setup->sm_peer_nonce, z); 1948 } 1949 1950 static void sm_sc_prepare_dhkey_check(sm_connection_t * sm_conn){ 1951 log_info("sm_sc_prepare_dhkey_check, DHKEY calculated %u", (setup->sm_state_vars & SM_STATE_VAR_DHKEY_CALCULATED) ? 1 : 0); 1952 1953 if (setup->sm_state_vars & SM_STATE_VAR_DHKEY_CALCULATED){ 1954 sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F5_SALT; 1955 return; 1956 } else { 1957 sm_conn->sm_engine_state = SM_SC_W4_CALCULATE_DHKEY; 1958 } 1959 } 1960 1961 static void sm_sc_dhkey_calculated(void * arg){ 1962 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 1963 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 1964 if (sm_conn == NULL) return; 1965 1966 // check for invalid public key detected by Controller 1967 if (sm_is_ff(setup->sm_dhkey, 32)){ 1968 log_info("sm: peer public key invalid"); 1969 sm_pairing_error(sm_conn, SM_REASON_DHKEY_CHECK_FAILED); 1970 return; 1971 } 1972 1973 log_info("dhkey"); 1974 log_info_hexdump(&setup->sm_dhkey[0], 32); 1975 setup->sm_state_vars |= SM_STATE_VAR_DHKEY_CALCULATED; 1976 // trigger next step 1977 if (sm_conn->sm_engine_state == SM_SC_W4_CALCULATE_DHKEY){ 1978 sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F5_SALT; 1979 } 1980 sm_trigger_run(); 1981 } 1982 1983 static void sm_sc_calculate_f6_for_dhkey_check(sm_connection_t * sm_conn){ 1984 // calculate DHKCheck 1985 sm_key56_t bd_addr_master, bd_addr_slave; 1986 bd_addr_master[0] = setup->sm_m_addr_type; 1987 bd_addr_slave[0] = setup->sm_s_addr_type; 1988 (void)memcpy(&bd_addr_master[1], setup->sm_m_address, 6); 1989 (void)memcpy(&bd_addr_slave[1], setup->sm_s_address, 6); 1990 uint8_t iocap_a[3]; 1991 iocap_a[0] = sm_pairing_packet_get_auth_req(setup->sm_m_preq); 1992 iocap_a[1] = sm_pairing_packet_get_oob_data_flag(setup->sm_m_preq); 1993 iocap_a[2] = sm_pairing_packet_get_io_capability(setup->sm_m_preq); 1994 uint8_t iocap_b[3]; 1995 iocap_b[0] = sm_pairing_packet_get_auth_req(setup->sm_s_pres); 1996 iocap_b[1] = sm_pairing_packet_get_oob_data_flag(setup->sm_s_pres); 1997 iocap_b[2] = sm_pairing_packet_get_io_capability(setup->sm_s_pres); 1998 if (IS_RESPONDER(sm_conn->sm_role)){ 1999 // responder 2000 f6_setup(setup->sm_local_nonce, setup->sm_peer_nonce, setup->sm_ra, iocap_b, bd_addr_slave, bd_addr_master); 2001 f6_engine(sm_conn, setup->sm_mackey); 2002 } else { 2003 // initiator 2004 f6_setup( setup->sm_local_nonce, setup->sm_peer_nonce, setup->sm_rb, iocap_a, bd_addr_master, bd_addr_slave); 2005 f6_engine(sm_conn, setup->sm_mackey); 2006 } 2007 } 2008 2009 static void sm_sc_calculate_f6_to_verify_dhkey_check(sm_connection_t * sm_conn){ 2010 // validate E = f6() 2011 sm_key56_t bd_addr_master, bd_addr_slave; 2012 bd_addr_master[0] = setup->sm_m_addr_type; 2013 bd_addr_slave[0] = setup->sm_s_addr_type; 2014 (void)memcpy(&bd_addr_master[1], setup->sm_m_address, 6); 2015 (void)memcpy(&bd_addr_slave[1], setup->sm_s_address, 6); 2016 2017 uint8_t iocap_a[3]; 2018 iocap_a[0] = sm_pairing_packet_get_auth_req(setup->sm_m_preq); 2019 iocap_a[1] = sm_pairing_packet_get_oob_data_flag(setup->sm_m_preq); 2020 iocap_a[2] = sm_pairing_packet_get_io_capability(setup->sm_m_preq); 2021 uint8_t iocap_b[3]; 2022 iocap_b[0] = sm_pairing_packet_get_auth_req(setup->sm_s_pres); 2023 iocap_b[1] = sm_pairing_packet_get_oob_data_flag(setup->sm_s_pres); 2024 iocap_b[2] = sm_pairing_packet_get_io_capability(setup->sm_s_pres); 2025 if (IS_RESPONDER(sm_conn->sm_role)){ 2026 // responder 2027 f6_setup(setup->sm_peer_nonce, setup->sm_local_nonce, setup->sm_rb, iocap_a, bd_addr_master, bd_addr_slave); 2028 f6_engine(sm_conn, setup->sm_mackey); 2029 } else { 2030 // initiator 2031 f6_setup(setup->sm_peer_nonce, setup->sm_local_nonce, setup->sm_ra, iocap_b, bd_addr_slave, bd_addr_master); 2032 f6_engine(sm_conn, setup->sm_mackey); 2033 } 2034 } 2035 2036 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 2037 2038 // 2039 // Link Key Conversion Function h6 2040 // 2041 // h6(W, keyID) = AES-CMAC_W(keyID) 2042 // - W is 128 bits 2043 // - keyID is 32 bits 2044 static void h6_engine(sm_connection_t * sm_conn, const sm_key_t w, const uint32_t key_id){ 2045 const uint16_t message_len = 4; 2046 sm_cmac_connection = sm_conn; 2047 big_endian_store_32(sm_cmac_sc_buffer, 0, key_id); 2048 log_info("h6 key"); 2049 log_info_hexdump(w, 16); 2050 log_info("h6 message"); 2051 log_info_hexdump(sm_cmac_sc_buffer, message_len); 2052 sm_cmac_message_start(w, message_len, sm_cmac_sc_buffer, &sm_sc_cmac_done); 2053 } 2054 // 2055 // Link Key Conversion Function h7 2056 // 2057 // h7(SALT, W) = AES-CMAC_SALT(W) 2058 // - SALT is 128 bits 2059 // - W is 128 bits 2060 static void h7_engine(sm_connection_t * sm_conn, const sm_key_t salt, const sm_key_t w) { 2061 const uint16_t message_len = 16; 2062 sm_cmac_connection = sm_conn; 2063 log_info("h7 key"); 2064 log_info_hexdump(salt, 16); 2065 log_info("h7 message"); 2066 log_info_hexdump(w, 16); 2067 sm_cmac_message_start(salt, message_len, w, &sm_sc_cmac_done); 2068 } 2069 2070 // For SC, setup->sm_local_ltk holds full LTK (sm_ltk is already truncated) 2071 // Errata Service Release to the Bluetooth Specification: ESR09 2072 // E6405 – Cross transport key derivation from a key of size less than 128 bits 2073 // "Note: When the BR/EDR link key is being derived from the LTK, the derivation is done before the LTK gets masked." 2074 2075 static void h6_calculate_ilk_from_le_ltk(sm_connection_t * sm_conn){ 2076 h6_engine(sm_conn, setup->sm_local_ltk, 0x746D7031); // "tmp1" 2077 } 2078 2079 static void h6_calculate_ilk_from_br_edr(sm_connection_t * sm_conn){ 2080 h6_engine(sm_conn, setup->sm_link_key, 0x746D7032); // "tmp2" 2081 } 2082 2083 static void h6_calculate_br_edr_link_key(sm_connection_t * sm_conn){ 2084 h6_engine(sm_conn, setup->sm_t, 0x6c656272); // "lebr" 2085 } 2086 2087 static void h6_calculate_le_ltk(sm_connection_t * sm_conn){ 2088 h6_engine(sm_conn, setup->sm_t, 0x62726C65); // "brle" 2089 } 2090 2091 static void h7_calculate_ilk_from_le_ltk(sm_connection_t * sm_conn){ 2092 const uint8_t salt[16] = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x74, 0x6D, 0x70, 0x31}; // "tmp1" 2093 h7_engine(sm_conn, salt, setup->sm_local_ltk); 2094 } 2095 2096 static void h7_calculate_ilk_from_br_edr(sm_connection_t * sm_conn){ 2097 const uint8_t salt[16] = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x74, 0x6D, 0x70, 0x32}; // "tmp2" 2098 h7_engine(sm_conn, salt, setup->sm_link_key); 2099 } 2100 2101 static void sm_ctkd_fetch_br_edr_link_key(sm_connection_t * sm_conn){ 2102 hci_connection_t * hci_connection = hci_connection_for_handle(sm_conn->sm_handle); 2103 btstack_assert(hci_connection != NULL); 2104 reverse_128(hci_connection->link_key, setup->sm_link_key); 2105 setup->sm_link_key_type = hci_connection->link_key_type; 2106 } 2107 2108 static void sm_ctkd_start_from_br_edr(sm_connection_t * sm_conn){ 2109 // only derive LTK if EncKey is set by both 2110 bool derive_ltk = (sm_pairing_packet_get_initiator_key_distribution(setup->sm_s_pres) & 2111 sm_pairing_packet_get_responder_key_distribution(setup->sm_s_pres) & SM_KEYDIST_ENC_KEY) != 0; 2112 if (derive_ltk){ 2113 bool use_h7 = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) & sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_CT2) != 0; 2114 sm_conn->sm_engine_state = use_h7 ? SM_BR_EDR_W2_CALCULATE_ILK_USING_H7 : SM_BR_EDR_W2_CALCULATE_ILK_USING_H6; 2115 } else { 2116 sm_done_for_handle(sm_conn->sm_handle); 2117 } 2118 } 2119 2120 #endif 2121 2122 #endif 2123 2124 // key management legacy connections: 2125 // - potentially two different LTKs based on direction. each device stores LTK provided by peer 2126 // - master stores LTK, EDIV, RAND. responder optionally stored master LTK (only if it needs to reconnect) 2127 // - initiators reconnects: initiator uses stored LTK, EDIV, RAND generated by responder 2128 // - responder reconnects: responder uses LTK receveived from master 2129 2130 // key management secure connections: 2131 // - both devices store same LTK from ECDH key exchange. 2132 2133 #if defined(ENABLE_LE_SECURE_CONNECTIONS) || defined(ENABLE_LE_CENTRAL) 2134 static void sm_load_security_info(sm_connection_t * sm_connection){ 2135 int encryption_key_size; 2136 int authenticated; 2137 int authorized; 2138 int secure_connection; 2139 2140 // fetch data from device db - incl. authenticated/authorized/key size. Note all sm_connection_X require encryption enabled 2141 le_device_db_encryption_get(sm_connection->sm_le_db_index, &setup->sm_peer_ediv, setup->sm_peer_rand, setup->sm_peer_ltk, 2142 &encryption_key_size, &authenticated, &authorized, &secure_connection); 2143 log_info("db index %u, key size %u, authenticated %u, authorized %u, secure connetion %u", sm_connection->sm_le_db_index, encryption_key_size, authenticated, authorized, secure_connection); 2144 sm_connection->sm_actual_encryption_key_size = encryption_key_size; 2145 sm_connection->sm_connection_authenticated = authenticated; 2146 sm_connection->sm_connection_authorization_state = authorized ? AUTHORIZATION_GRANTED : AUTHORIZATION_UNKNOWN; 2147 sm_connection->sm_connection_sc = secure_connection; 2148 } 2149 #endif 2150 2151 #ifdef ENABLE_LE_PERIPHERAL 2152 static void sm_start_calculating_ltk_from_ediv_and_rand(sm_connection_t * sm_connection){ 2153 (void)memcpy(setup->sm_local_rand, sm_connection->sm_local_rand, 8); 2154 setup->sm_local_ediv = sm_connection->sm_local_ediv; 2155 // re-establish used key encryption size 2156 // no db for encryption size hack: encryption size is stored in lowest nibble of setup->sm_local_rand 2157 sm_connection->sm_actual_encryption_key_size = (setup->sm_local_rand[7u] & 0x0fu) + 1u; 2158 // no db for authenticated flag hack: flag is stored in bit 4 of LSB 2159 sm_connection->sm_connection_authenticated = (setup->sm_local_rand[7u] & 0x10u) >> 4u; 2160 // Legacy paring -> not SC 2161 sm_connection->sm_connection_sc = 0; 2162 log_info("sm: received ltk request with key size %u, authenticated %u", 2163 sm_connection->sm_actual_encryption_key_size, sm_connection->sm_connection_authenticated); 2164 } 2165 #endif 2166 2167 // distributed key generation 2168 static bool sm_run_dpkg(void){ 2169 switch (dkg_state){ 2170 case DKG_CALC_IRK: 2171 // already busy? 2172 if (sm_aes128_state == SM_AES128_IDLE) { 2173 log_info("DKG_CALC_IRK started"); 2174 // IRK = d1(IR, 1, 0) 2175 sm_d1_d_prime(1, 0, sm_aes128_plaintext); // plaintext = d1 prime 2176 sm_aes128_state = SM_AES128_ACTIVE; 2177 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_ir, sm_aes128_plaintext, sm_persistent_irk, sm_handle_encryption_result_dkg_irk, NULL); 2178 return true; 2179 } 2180 break; 2181 case DKG_CALC_DHK: 2182 // already busy? 2183 if (sm_aes128_state == SM_AES128_IDLE) { 2184 log_info("DKG_CALC_DHK started"); 2185 // DHK = d1(IR, 3, 0) 2186 sm_d1_d_prime(3, 0, sm_aes128_plaintext); // plaintext = d1 prime 2187 sm_aes128_state = SM_AES128_ACTIVE; 2188 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_ir, sm_aes128_plaintext, sm_persistent_dhk, sm_handle_encryption_result_dkg_dhk, NULL); 2189 return true; 2190 } 2191 break; 2192 default: 2193 break; 2194 } 2195 return false; 2196 } 2197 2198 // random address updates 2199 static bool sm_run_rau(void){ 2200 switch (rau_state){ 2201 case RAU_GET_RANDOM: 2202 rau_state = RAU_W4_RANDOM; 2203 btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_address, 6, &sm_handle_random_result_rau, NULL); 2204 return true; 2205 case RAU_GET_ENC: 2206 // already busy? 2207 if (sm_aes128_state == SM_AES128_IDLE) { 2208 sm_ah_r_prime(sm_random_address, sm_aes128_plaintext); 2209 sm_aes128_state = SM_AES128_ACTIVE; 2210 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_irk, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_rau, NULL); 2211 return true; 2212 } 2213 break; 2214 default: 2215 break; 2216 } 2217 return false; 2218 } 2219 2220 // CSRK Lookup 2221 static bool sm_run_csrk(void){ 2222 btstack_linked_list_iterator_t it; 2223 2224 // -- if csrk lookup ready, find connection that require csrk lookup 2225 if (sm_address_resolution_idle()){ 2226 hci_connections_get_iterator(&it); 2227 while(btstack_linked_list_iterator_has_next(&it)){ 2228 hci_connection_t * hci_connection = (hci_connection_t *) btstack_linked_list_iterator_next(&it); 2229 sm_connection_t * sm_connection = &hci_connection->sm_connection; 2230 if (sm_connection->sm_irk_lookup_state == IRK_LOOKUP_W4_READY){ 2231 // and start lookup 2232 sm_address_resolution_start_lookup(sm_connection->sm_peer_addr_type, sm_connection->sm_handle, sm_connection->sm_peer_address, ADDRESS_RESOLUTION_FOR_CONNECTION, sm_connection); 2233 sm_connection->sm_irk_lookup_state = IRK_LOOKUP_STARTED; 2234 break; 2235 } 2236 } 2237 } 2238 2239 // -- if csrk lookup ready, resolved addresses for received addresses 2240 if (sm_address_resolution_idle()) { 2241 if (!btstack_linked_list_empty(&sm_address_resolution_general_queue)){ 2242 sm_lookup_entry_t * entry = (sm_lookup_entry_t *) sm_address_resolution_general_queue; 2243 btstack_linked_list_remove(&sm_address_resolution_general_queue, (btstack_linked_item_t *) entry); 2244 sm_address_resolution_start_lookup(entry->address_type, 0, entry->address, ADDRESS_RESOLUTION_GENERAL, NULL); 2245 btstack_memory_sm_lookup_entry_free(entry); 2246 } 2247 } 2248 2249 // -- Continue with device lookup by public or resolvable private address 2250 if (!sm_address_resolution_idle()){ 2251 while (sm_address_resolution_test < le_device_db_max_count()){ 2252 int addr_type = BD_ADDR_TYPE_UNKNOWN; 2253 bd_addr_t addr; 2254 sm_key_t irk; 2255 le_device_db_info(sm_address_resolution_test, &addr_type, addr, irk); 2256 2257 // skip unused entries 2258 if (addr_type == BD_ADDR_TYPE_UNKNOWN){ 2259 sm_address_resolution_test++; 2260 continue; 2261 } 2262 2263 log_info("LE Device Lookup: device %u of %u", sm_address_resolution_test, le_device_db_max_count()); 2264 2265 // map resolved identiry addresses to regular addresses 2266 int regular_addr_type = sm_address_resolution_addr_type & 1; 2267 if ((regular_addr_type == addr_type) && (memcmp(addr, sm_address_resolution_address, 6) == 0)){ 2268 log_info("LE Device Lookup: found by { addr_type, address} "); 2269 sm_address_resolution_handle_event(ADDRESS_RESOLUTION_SUCCEEDED); 2270 break; 2271 } 2272 2273 // if connection type is public, it must be a different one 2274 if (sm_address_resolution_addr_type == BD_ADDR_TYPE_LE_PUBLIC){ 2275 sm_address_resolution_test++; 2276 continue; 2277 } 2278 2279 // skip AH if no IRK 2280 if (sm_is_null_key(irk)){ 2281 sm_address_resolution_test++; 2282 continue; 2283 } 2284 2285 if (sm_aes128_state == SM_AES128_ACTIVE) break; 2286 2287 log_info("LE Device Lookup: calculate AH"); 2288 log_info_key("IRK", irk); 2289 2290 (void)memcpy(sm_aes128_key, irk, 16); 2291 sm_ah_r_prime(sm_address_resolution_address, sm_aes128_plaintext); 2292 sm_aes128_state = SM_AES128_ACTIVE; 2293 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_aes128_key, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_address_resolution, NULL); 2294 return true; 2295 } 2296 2297 if (sm_address_resolution_test >= le_device_db_max_count()){ 2298 log_info("LE Device Lookup: not found"); 2299 sm_address_resolution_handle_event(ADDRESS_RESOLUTION_FAILED); 2300 } 2301 } 2302 return false; 2303 } 2304 2305 // SC OOB 2306 static bool sm_run_oob(void){ 2307 #ifdef ENABLE_LE_SECURE_CONNECTIONS 2308 switch (sm_sc_oob_state){ 2309 case SM_SC_OOB_W2_CALC_CONFIRM: 2310 if (!sm_cmac_ready()) break; 2311 sm_sc_oob_state = SM_SC_OOB_W4_CONFIRM; 2312 f4_engine(NULL, ec_q, ec_q, sm_sc_oob_random, 0); 2313 return true; 2314 default: 2315 break; 2316 } 2317 #endif 2318 return false; 2319 } 2320 2321 static void sm_send_connectionless(sm_connection_t * sm_connection, const uint8_t * buffer, uint16_t size){ 2322 l2cap_send_connectionless(sm_connection->sm_handle, sm_connection->sm_cid, (uint8_t*) buffer, size); 2323 } 2324 2325 // handle basic actions that don't requires the full context 2326 static bool sm_run_basic(void){ 2327 btstack_linked_list_iterator_t it; 2328 hci_connections_get_iterator(&it); 2329 while(btstack_linked_list_iterator_has_next(&it)){ 2330 hci_connection_t * hci_connection = (hci_connection_t *) btstack_linked_list_iterator_next(&it); 2331 sm_connection_t * sm_connection = &hci_connection->sm_connection; 2332 switch(sm_connection->sm_engine_state){ 2333 2334 // general 2335 case SM_GENERAL_SEND_PAIRING_FAILED: { 2336 uint8_t buffer[2]; 2337 buffer[0] = SM_CODE_PAIRING_FAILED; 2338 buffer[1] = sm_connection->sm_pairing_failed_reason; 2339 sm_connection->sm_engine_state = sm_connection->sm_role ? SM_RESPONDER_IDLE : SM_INITIATOR_CONNECTED; 2340 sm_send_connectionless(sm_connection, (uint8_t*) buffer, sizeof(buffer)); 2341 sm_pairing_complete(sm_connection, ERROR_CODE_AUTHENTICATION_FAILURE, sm_connection->sm_pairing_failed_reason); 2342 sm_done_for_handle(sm_connection->sm_handle); 2343 break; 2344 } 2345 2346 // responder side 2347 case SM_RESPONDER_PH0_SEND_LTK_REQUESTED_NEGATIVE_REPLY: 2348 sm_connection->sm_engine_state = SM_RESPONDER_IDLE; 2349 hci_send_cmd(&hci_le_long_term_key_negative_reply, sm_connection->sm_handle); 2350 return true; 2351 2352 #ifdef ENABLE_LE_SECURE_CONNECTIONS 2353 case SM_SC_RECEIVED_LTK_REQUEST: 2354 switch (sm_connection->sm_irk_lookup_state){ 2355 case IRK_LOOKUP_FAILED: 2356 log_info("LTK Request: IRK Lookup Failed)"); 2357 sm_connection->sm_engine_state = SM_RESPONDER_IDLE; 2358 hci_send_cmd(&hci_le_long_term_key_negative_reply, sm_connection->sm_handle); 2359 return true; 2360 default: 2361 break; 2362 } 2363 break; 2364 #endif 2365 default: 2366 break; 2367 } 2368 } 2369 return false; 2370 } 2371 2372 static void sm_run_activate_connection(void){ 2373 // Find connections that requires setup context and make active if no other is locked 2374 btstack_linked_list_iterator_t it; 2375 hci_connections_get_iterator(&it); 2376 while((sm_active_connection_handle == HCI_CON_HANDLE_INVALID) && btstack_linked_list_iterator_has_next(&it)){ 2377 hci_connection_t * hci_connection = (hci_connection_t *) btstack_linked_list_iterator_next(&it); 2378 sm_connection_t * sm_connection = &hci_connection->sm_connection; 2379 // - if no connection locked and we're ready/waiting for setup context, fetch it and start 2380 bool done = true; 2381 int err; 2382 UNUSED(err); 2383 2384 #ifdef ENABLE_LE_SECURE_CONNECTIONS 2385 // assert ec key is ready 2386 if ( (sm_connection->sm_engine_state == SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED) 2387 || (sm_connection->sm_engine_state == SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST) 2388 || (sm_connection->sm_engine_state == SM_RESPONDER_SEND_SECURITY_REQUEST)){ 2389 if (ec_key_generation_state == EC_KEY_GENERATION_IDLE){ 2390 sm_ec_generate_new_key(); 2391 } 2392 if (ec_key_generation_state != EC_KEY_GENERATION_DONE){ 2393 continue; 2394 } 2395 } 2396 #endif 2397 2398 switch (sm_connection->sm_engine_state) { 2399 #ifdef ENABLE_LE_PERIPHERAL 2400 case SM_RESPONDER_SEND_SECURITY_REQUEST: 2401 case SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED: 2402 case SM_RESPONDER_PH0_RECEIVED_LTK_REQUEST: 2403 #ifdef ENABLE_LE_SECURE_CONNECTIONS 2404 case SM_SC_RECEIVED_LTK_REQUEST: 2405 #endif 2406 #endif 2407 #ifdef ENABLE_LE_CENTRAL 2408 case SM_INITIATOR_PH4_HAS_LTK: 2409 case SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST: 2410 #endif 2411 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 2412 case SM_BR_EDR_RESPONDER_PAIRING_REQUEST_RECEIVED: 2413 case SM_BR_EDR_INITIATOR_SEND_PAIRING_REQUEST: 2414 #endif 2415 // just lock context 2416 break; 2417 default: 2418 done = false; 2419 break; 2420 } 2421 if (done){ 2422 sm_active_connection_handle = sm_connection->sm_handle; 2423 log_info("sm: connection 0x%04x locked setup context as %s, state %u", sm_active_connection_handle, sm_connection->sm_role ? "responder" : "initiator", sm_connection->sm_engine_state); 2424 } 2425 } 2426 } 2427 2428 static void sm_run_send_keypress_notification(sm_connection_t * connection){ 2429 int i; 2430 uint8_t flags = setup->sm_keypress_notification & 0x1fu; 2431 uint8_t num_actions = setup->sm_keypress_notification >> 5; 2432 uint8_t action = 0; 2433 for (i=SM_KEYPRESS_PASSKEY_ENTRY_STARTED;i<=SM_KEYPRESS_PASSKEY_ENTRY_COMPLETED;i++){ 2434 if (flags & (1u<<i)){ 2435 bool clear_flag = true; 2436 switch (i){ 2437 case SM_KEYPRESS_PASSKEY_ENTRY_STARTED: 2438 case SM_KEYPRESS_PASSKEY_CLEARED: 2439 case SM_KEYPRESS_PASSKEY_ENTRY_COMPLETED: 2440 default: 2441 break; 2442 case SM_KEYPRESS_PASSKEY_DIGIT_ENTERED: 2443 case SM_KEYPRESS_PASSKEY_DIGIT_ERASED: 2444 num_actions--; 2445 clear_flag = num_actions == 0u; 2446 break; 2447 } 2448 if (clear_flag){ 2449 flags &= ~(1<<i); 2450 } 2451 action = i; 2452 break; 2453 } 2454 } 2455 setup->sm_keypress_notification = (num_actions << 5) | flags; 2456 2457 // send keypress notification 2458 uint8_t buffer[2]; 2459 buffer[0] = SM_CODE_KEYPRESS_NOTIFICATION; 2460 buffer[1] = action; 2461 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 2462 2463 // try 2464 l2cap_request_can_send_fix_channel_now_event(sm_active_connection_handle, connection->sm_cid); 2465 } 2466 2467 static void sm_run_distribute_keys(sm_connection_t * connection){ 2468 if (setup->sm_key_distribution_send_set & SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION){ 2469 setup->sm_key_distribution_send_set &= ~SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION; 2470 setup->sm_key_distribution_sent_set |= SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION; 2471 uint8_t buffer[17]; 2472 buffer[0] = SM_CODE_ENCRYPTION_INFORMATION; 2473 reverse_128(setup->sm_ltk, &buffer[1]); 2474 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 2475 sm_timeout_reset(connection); 2476 return; 2477 } 2478 if (setup->sm_key_distribution_send_set & SM_KEYDIST_FLAG_MASTER_IDENTIFICATION){ 2479 setup->sm_key_distribution_send_set &= ~SM_KEYDIST_FLAG_MASTER_IDENTIFICATION; 2480 setup->sm_key_distribution_sent_set |= SM_KEYDIST_FLAG_MASTER_IDENTIFICATION; 2481 uint8_t buffer[11]; 2482 buffer[0] = SM_CODE_MASTER_IDENTIFICATION; 2483 little_endian_store_16(buffer, 1, setup->sm_local_ediv); 2484 reverse_64(setup->sm_local_rand, &buffer[3]); 2485 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 2486 sm_timeout_reset(connection); 2487 return; 2488 } 2489 if (setup->sm_key_distribution_send_set & SM_KEYDIST_FLAG_IDENTITY_INFORMATION){ 2490 setup->sm_key_distribution_send_set &= ~SM_KEYDIST_FLAG_IDENTITY_INFORMATION; 2491 setup->sm_key_distribution_sent_set |= SM_KEYDIST_FLAG_IDENTITY_INFORMATION; 2492 uint8_t buffer[17]; 2493 buffer[0] = SM_CODE_IDENTITY_INFORMATION; 2494 reverse_128(sm_persistent_irk, &buffer[1]); 2495 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 2496 sm_timeout_reset(connection); 2497 return; 2498 } 2499 if (setup->sm_key_distribution_send_set & SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION){ 2500 setup->sm_key_distribution_send_set &= ~SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION; 2501 setup->sm_key_distribution_sent_set |= SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION; 2502 bd_addr_t local_address; 2503 uint8_t buffer[8]; 2504 buffer[0] = SM_CODE_IDENTITY_ADDRESS_INFORMATION; 2505 switch (gap_random_address_get_mode()){ 2506 case GAP_RANDOM_ADDRESS_TYPE_OFF: 2507 case GAP_RANDOM_ADDRESS_TYPE_STATIC: 2508 // public or static random 2509 gap_le_get_own_address(&buffer[1], local_address); 2510 break; 2511 case GAP_RANDOM_ADDRESS_NON_RESOLVABLE: 2512 case GAP_RANDOM_ADDRESS_RESOLVABLE: 2513 // fallback to public 2514 gap_local_bd_addr(local_address); 2515 buffer[1] = 0; 2516 break; 2517 default: 2518 btstack_assert(false); 2519 break; 2520 } 2521 reverse_bd_addr(local_address, &buffer[2]); 2522 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 2523 sm_timeout_reset(connection); 2524 return; 2525 } 2526 if (setup->sm_key_distribution_send_set & SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION){ 2527 setup->sm_key_distribution_send_set &= ~SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION; 2528 setup->sm_key_distribution_sent_set |= SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION; 2529 2530 #ifdef ENABLE_LE_SIGNED_WRITE 2531 // hack to reproduce test runs 2532 if (test_use_fixed_local_csrk){ 2533 memset(setup->sm_local_csrk, 0xcc, 16); 2534 } 2535 2536 // store local CSRK 2537 if (setup->sm_le_device_index >= 0){ 2538 log_info("sm: store local CSRK"); 2539 le_device_db_local_csrk_set(setup->sm_le_device_index, setup->sm_local_csrk); 2540 le_device_db_local_counter_set(setup->sm_le_device_index, 0); 2541 } 2542 #endif 2543 2544 uint8_t buffer[17]; 2545 buffer[0] = SM_CODE_SIGNING_INFORMATION; 2546 reverse_128(setup->sm_local_csrk, &buffer[1]); 2547 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 2548 sm_timeout_reset(connection); 2549 return; 2550 } 2551 btstack_assert(false); 2552 } 2553 2554 static bool sm_ctkd_from_le(sm_connection_t *sm_connection) { 2555 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 2556 // requirements to derive link key from LE: 2557 // - use secure connections 2558 if (setup->sm_use_secure_connections == 0) return false; 2559 // - bonding needs to be enabled: 2560 bool bonding_enabled = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) & sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_BONDING ) != 0u; 2561 if (!bonding_enabled) return false; 2562 // - need identity address / public addr 2563 bool have_identity_address_info = ((setup->sm_key_distribution_received_set & SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION) != 0) || (setup->sm_peer_addr_type == 0); 2564 if (!have_identity_address_info) return false; 2565 // - there is no stored BR/EDR link key or the derived key has at least the same level of authentication (bail if stored key has higher authentication) 2566 // this requirement is motivated by BLURtooth paper. The paper recommends to not overwrite keys at all. 2567 // If SC is authenticated, we consider it safe to overwrite a stored key. 2568 // If stored link key is not authenticated, it could already be compromised by a MITM attack. Allowing overwrite by unauthenticated derived key does not make it worse. 2569 uint8_t link_key[16]; 2570 link_key_type_t link_key_type; 2571 bool have_link_key = gap_get_link_key_for_bd_addr(setup->sm_peer_address, link_key, &link_key_type); 2572 bool link_key_authenticated = gap_authenticated_for_link_key_type(link_key_type); 2573 bool derived_key_authenticated = sm_connection->sm_connection_authenticated != 0; 2574 if (have_link_key && link_key_authenticated && !derived_key_authenticated) { 2575 return false; 2576 } 2577 // get started (all of the above are true) 2578 return true; 2579 #else 2580 UNUSED(sm_connection); 2581 return false; 2582 #endif 2583 } 2584 2585 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 2586 static bool sm_ctkd_from_classic(sm_connection_t * sm_connection){ 2587 hci_connection_t * hci_connection = hci_connection_for_handle(sm_connection->sm_handle); 2588 btstack_assert(hci_connection != NULL); 2589 // requirements to derive ltk from BR/EDR: 2590 // - BR/EDR uses secure connections 2591 if (gap_secure_connection_for_link_key_type(hci_connection->link_key_type) == false) return false; 2592 // - bonding needs to be enabled: 2593 bool bonding_enabled = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) & sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_BONDING ) != 0u; 2594 if (!bonding_enabled) return false; 2595 // - there is no stored LTK or the derived key has at least the same level of authentication (bail if LTK is authenticated but Link Key isn't) 2596 bool link_key_authenticated = gap_authenticated_for_link_key_type(hci_connection->link_key_type); 2597 if (link_key_authenticated) return true; 2598 int index = sm_le_device_db_index_lookup(BD_ADDR_TYPE_LE_PUBLIC, hci_connection->address); 2599 if (index >= 0){ 2600 int ltk_authenticated; 2601 sm_key_t ltk; 2602 le_device_db_encryption_get(sm_connection->sm_le_db_index, NULL, NULL, ltk, NULL, <k_authenticated, NULL, NULL); 2603 bool have_ltk = !sm_is_null_key(ltk); 2604 if (have_ltk && ltk_authenticated) return false; 2605 } 2606 return true; 2607 } 2608 #endif 2609 2610 static void sm_key_distribution_complete_responder(sm_connection_t * connection){ 2611 if (sm_ctkd_from_le(connection)){ 2612 bool use_h7 = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) & sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_CT2) != 0; 2613 connection->sm_engine_state = use_h7 ? SM_SC_W2_CALCULATE_ILK_USING_H7 : SM_SC_W2_CALCULATE_ILK_USING_H6; 2614 } else { 2615 connection->sm_engine_state = SM_RESPONDER_IDLE; 2616 sm_pairing_complete(connection, ERROR_CODE_SUCCESS, 0); 2617 sm_done_for_handle(connection->sm_handle); 2618 } 2619 } 2620 2621 static void sm_key_distribution_complete_initiator(sm_connection_t * connection){ 2622 if (sm_ctkd_from_le(connection)){ 2623 bool use_h7 = (sm_pairing_packet_get_auth_req(setup->sm_m_preq) & sm_pairing_packet_get_auth_req(setup->sm_s_pres) & SM_AUTHREQ_CT2) != 0; 2624 connection->sm_engine_state = use_h7 ? SM_SC_W2_CALCULATE_ILK_USING_H7 : SM_SC_W2_CALCULATE_ILK_USING_H6; 2625 } else { 2626 sm_master_pairing_success(connection); 2627 } 2628 } 2629 2630 #ifdef ENABLE_LE_SECURE_CONNECTIONS 2631 static void sm_run_state_sc_send_confirmation(sm_connection_t *connection) { 2632 uint8_t buffer[17]; 2633 buffer[0] = SM_CODE_PAIRING_CONFIRM; 2634 reverse_128(setup->sm_local_confirm, &buffer[1]); 2635 if (IS_RESPONDER(connection->sm_role)){ 2636 connection->sm_engine_state = SM_SC_W4_PAIRING_RANDOM; 2637 } else { 2638 connection->sm_engine_state = SM_SC_W4_CONFIRMATION; 2639 } 2640 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 2641 sm_timeout_reset(connection); 2642 } 2643 2644 static void sm_run_state_sc_send_pairing_random(sm_connection_t *connection) { 2645 uint8_t buffer[17]; 2646 buffer[0] = SM_CODE_PAIRING_RANDOM; 2647 reverse_128(setup->sm_local_nonce, &buffer[1]); 2648 log_info("stk method %u, bit num: %u", setup->sm_stk_generation_method, setup->sm_passkey_bit); 2649 if (sm_passkey_entry(setup->sm_stk_generation_method) && (setup->sm_passkey_bit < 20u)){ 2650 log_info("SM_SC_SEND_PAIRING_RANDOM A"); 2651 if (IS_RESPONDER(connection->sm_role)){ 2652 // responder 2653 connection->sm_engine_state = SM_SC_W4_CONFIRMATION; 2654 } else { 2655 // initiator 2656 connection->sm_engine_state = SM_SC_W4_PAIRING_RANDOM; 2657 } 2658 } else { 2659 log_info("SM_SC_SEND_PAIRING_RANDOM B"); 2660 if (IS_RESPONDER(connection->sm_role)){ 2661 // responder 2662 if (setup->sm_stk_generation_method == NUMERIC_COMPARISON){ 2663 log_info("SM_SC_SEND_PAIRING_RANDOM B1"); 2664 connection->sm_engine_state = SM_SC_W2_CALCULATE_G2; 2665 } else { 2666 log_info("SM_SC_SEND_PAIRING_RANDOM B2"); 2667 sm_sc_prepare_dhkey_check(connection); 2668 } 2669 } else { 2670 // initiator 2671 connection->sm_engine_state = SM_SC_W4_PAIRING_RANDOM; 2672 } 2673 } 2674 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 2675 sm_timeout_reset(connection); 2676 } 2677 2678 static void sm_run_state_sc_send_dhkey_check_command(sm_connection_t *connection) { 2679 uint8_t buffer[17]; 2680 buffer[0] = SM_CODE_PAIRING_DHKEY_CHECK; 2681 reverse_128(setup->sm_local_dhkey_check, &buffer[1]); 2682 2683 if (IS_RESPONDER(connection->sm_role)){ 2684 connection->sm_engine_state = SM_SC_W4_LTK_REQUEST_SC; 2685 } else { 2686 connection->sm_engine_state = SM_SC_W4_DHKEY_CHECK_COMMAND; 2687 } 2688 2689 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 2690 sm_timeout_reset(connection); 2691 } 2692 2693 static void sm_run_state_sc_send_public_key_command(sm_connection_t *connection) { 2694 bool trigger_user_response = false; 2695 bool trigger_start_calculating_local_confirm = false; 2696 uint8_t buffer[65]; 2697 buffer[0] = SM_CODE_PAIRING_PUBLIC_KEY; 2698 // 2699 reverse_256(&ec_q[0], &buffer[1]); 2700 reverse_256(&ec_q[32], &buffer[33]); 2701 2702 #ifdef ENABLE_TESTING_SUPPORT 2703 if (test_pairing_failure == SM_REASON_DHKEY_CHECK_FAILED){ 2704 log_info("testing_support: invalidating public key"); 2705 // flip single bit of public key coordinate 2706 buffer[1] ^= 1; 2707 } 2708 #endif 2709 2710 // stk generation method 2711 // passkey entry: notify app to show passkey or to request passkey 2712 switch (setup->sm_stk_generation_method){ 2713 case JUST_WORKS: 2714 case NUMERIC_COMPARISON: 2715 if (IS_RESPONDER(connection->sm_role)){ 2716 // responder 2717 trigger_start_calculating_local_confirm = true; 2718 connection->sm_engine_state = SM_SC_W4_LOCAL_NONCE; 2719 } else { 2720 // initiator 2721 connection->sm_engine_state = SM_SC_W4_PUBLIC_KEY_COMMAND; 2722 } 2723 break; 2724 case PK_INIT_INPUT: 2725 case PK_RESP_INPUT: 2726 case PK_BOTH_INPUT: 2727 // use random TK for display 2728 (void)memcpy(setup->sm_ra, setup->sm_tk, 16); 2729 (void)memcpy(setup->sm_rb, setup->sm_tk, 16); 2730 setup->sm_passkey_bit = 0; 2731 2732 if (IS_RESPONDER(connection->sm_role)){ 2733 // responder 2734 connection->sm_engine_state = SM_SC_W4_CONFIRMATION; 2735 } else { 2736 // initiator 2737 connection->sm_engine_state = SM_SC_W4_PUBLIC_KEY_COMMAND; 2738 } 2739 trigger_user_response = true; 2740 break; 2741 case OOB: 2742 if (IS_RESPONDER(connection->sm_role)){ 2743 // responder 2744 connection->sm_engine_state = SM_SC_W4_PAIRING_RANDOM; 2745 } else { 2746 // initiator 2747 connection->sm_engine_state = SM_SC_W4_PUBLIC_KEY_COMMAND; 2748 } 2749 break; 2750 default: 2751 btstack_assert(false); 2752 break; 2753 } 2754 2755 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 2756 sm_timeout_reset(connection); 2757 2758 // trigger user response and calc confirm after sending pdu 2759 if (trigger_user_response){ 2760 sm_trigger_user_response(connection); 2761 } 2762 if (trigger_start_calculating_local_confirm){ 2763 sm_sc_start_calculating_local_confirm(connection); 2764 } 2765 } 2766 #endif 2767 2768 static bool sm_run_non_connection_logic(void){ 2769 bool done;; 2770 2771 done = sm_run_dpkg(); 2772 if (done) return true; 2773 2774 done = sm_run_rau(); 2775 if (done) return true; 2776 2777 done = sm_run_csrk(); 2778 if (done) return true; 2779 2780 done = sm_run_oob(); 2781 return done; 2782 } 2783 2784 static void sm_run(void){ 2785 2786 // assert that stack has already bootet 2787 if (hci_get_state() != HCI_STATE_WORKING) return; 2788 2789 // assert that we can send at least commands 2790 if (!hci_can_send_command_packet_now()) return; 2791 2792 // pause until IR/ER are ready 2793 if (sm_persistent_keys_random_active) return; 2794 2795 // non-connection related behaviour 2796 bool done = sm_run_non_connection_logic(); 2797 if (done) return; 2798 2799 // assert that we can send at least commands - cmd might have been sent by crypto engine 2800 if (!hci_can_send_command_packet_now()) return; 2801 2802 // handle basic actions that don't requires the full context 2803 done = sm_run_basic(); 2804 if (done) return; 2805 2806 // 2807 // active connection handling 2808 // -- use loop to handle next connection if lock on setup context is released 2809 2810 while (true) { 2811 2812 sm_run_activate_connection(); 2813 2814 if (sm_active_connection_handle == HCI_CON_HANDLE_INVALID) return; 2815 2816 // 2817 // active connection handling 2818 // 2819 2820 sm_connection_t * connection = sm_get_connection_for_handle(sm_active_connection_handle); 2821 if (!connection) { 2822 log_info("no connection for handle 0x%04x", sm_active_connection_handle); 2823 return; 2824 } 2825 2826 // assert that we could send a SM PDU - not needed for all of the following 2827 if (!l2cap_can_send_fixed_channel_packet_now(sm_active_connection_handle, connection->sm_cid)) { 2828 log_info("cannot send now, requesting can send now event"); 2829 l2cap_request_can_send_fix_channel_now_event(sm_active_connection_handle, connection->sm_cid); 2830 return; 2831 } 2832 2833 // send keypress notifications 2834 if (setup->sm_keypress_notification){ 2835 sm_run_send_keypress_notification(connection); 2836 return; 2837 } 2838 2839 #ifdef ENABLE_LE_SECURE_CONNECTIONS 2840 // assert that sm cmac engine is ready 2841 if (sm_cmac_ready() == false){ 2842 break; 2843 } 2844 #endif 2845 2846 int key_distribution_flags; 2847 UNUSED(key_distribution_flags); 2848 #ifdef ENABLE_LE_PERIPHERAL 2849 int err; 2850 bool have_ltk; 2851 uint8_t ltk[16]; 2852 #endif 2853 2854 log_info("sm_run: state %u", connection->sm_engine_state); 2855 switch (connection->sm_engine_state){ 2856 2857 // secure connections, initiator + responding states 2858 #ifdef ENABLE_LE_SECURE_CONNECTIONS 2859 case SM_SC_W2_CMAC_FOR_CONFIRMATION: 2860 connection->sm_engine_state = SM_SC_W4_CMAC_FOR_CONFIRMATION; 2861 sm_sc_calculate_local_confirm(connection); 2862 break; 2863 case SM_SC_W2_CMAC_FOR_CHECK_CONFIRMATION: 2864 connection->sm_engine_state = SM_SC_W4_CMAC_FOR_CHECK_CONFIRMATION; 2865 sm_sc_calculate_remote_confirm(connection); 2866 break; 2867 case SM_SC_W2_CALCULATE_F6_FOR_DHKEY_CHECK: 2868 connection->sm_engine_state = SM_SC_W4_CALCULATE_F6_FOR_DHKEY_CHECK; 2869 sm_sc_calculate_f6_for_dhkey_check(connection); 2870 break; 2871 case SM_SC_W2_CALCULATE_F6_TO_VERIFY_DHKEY_CHECK: 2872 connection->sm_engine_state = SM_SC_W4_CALCULATE_F6_TO_VERIFY_DHKEY_CHECK; 2873 sm_sc_calculate_f6_to_verify_dhkey_check(connection); 2874 break; 2875 case SM_SC_W2_CALCULATE_F5_SALT: 2876 connection->sm_engine_state = SM_SC_W4_CALCULATE_F5_SALT; 2877 f5_calculate_salt(connection); 2878 break; 2879 case SM_SC_W2_CALCULATE_F5_MACKEY: 2880 connection->sm_engine_state = SM_SC_W4_CALCULATE_F5_MACKEY; 2881 f5_calculate_mackey(connection); 2882 break; 2883 case SM_SC_W2_CALCULATE_F5_LTK: 2884 connection->sm_engine_state = SM_SC_W4_CALCULATE_F5_LTK; 2885 f5_calculate_ltk(connection); 2886 break; 2887 case SM_SC_W2_CALCULATE_G2: 2888 connection->sm_engine_state = SM_SC_W4_CALCULATE_G2; 2889 g2_calculate(connection); 2890 break; 2891 #endif 2892 2893 #ifdef ENABLE_LE_CENTRAL 2894 // initiator side 2895 2896 case SM_INITIATOR_PH4_HAS_LTK: { 2897 sm_reset_setup(); 2898 sm_load_security_info(connection); 2899 2900 sm_key_t peer_ltk_flipped; 2901 reverse_128(setup->sm_peer_ltk, peer_ltk_flipped); 2902 connection->sm_engine_state = SM_PH4_W4_CONNECTION_ENCRYPTED; 2903 log_info("sm: hci_le_start_encryption ediv 0x%04x", setup->sm_peer_ediv); 2904 uint32_t rand_high = big_endian_read_32(setup->sm_peer_rand, 0); 2905 uint32_t rand_low = big_endian_read_32(setup->sm_peer_rand, 4); 2906 hci_send_cmd(&hci_le_start_encryption, connection->sm_handle,rand_low, rand_high, setup->sm_peer_ediv, peer_ltk_flipped); 2907 2908 // notify after sending 2909 sm_reencryption_started(connection); 2910 return; 2911 } 2912 2913 case SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST: 2914 sm_reset_setup(); 2915 sm_init_setup(connection); 2916 2917 sm_pairing_packet_set_code(setup->sm_m_preq, SM_CODE_PAIRING_REQUEST); 2918 connection->sm_engine_state = SM_INITIATOR_PH1_W4_PAIRING_RESPONSE; 2919 sm_send_connectionless(connection, (uint8_t*) &setup->sm_m_preq, sizeof(sm_pairing_packet_t)); 2920 sm_timeout_reset(connection); 2921 2922 // notify after sending 2923 sm_pairing_started(connection); 2924 break; 2925 #endif 2926 2927 #ifdef ENABLE_LE_SECURE_CONNECTIONS 2928 case SM_SC_SEND_PUBLIC_KEY_COMMAND: 2929 sm_run_state_sc_send_public_key_command(connection); 2930 break; 2931 case SM_SC_SEND_CONFIRMATION: 2932 sm_run_state_sc_send_confirmation(connection); 2933 break; 2934 case SM_SC_SEND_PAIRING_RANDOM: 2935 sm_run_state_sc_send_pairing_random(connection); 2936 break; 2937 case SM_SC_SEND_DHKEY_CHECK_COMMAND: 2938 sm_run_state_sc_send_dhkey_check_command(connection); 2939 break; 2940 #endif 2941 2942 #ifdef ENABLE_LE_PERIPHERAL 2943 2944 case SM_RESPONDER_SEND_SECURITY_REQUEST: { 2945 const uint8_t buffer[2] = {SM_CODE_SECURITY_REQUEST, sm_auth_req}; 2946 connection->sm_engine_state = SM_RESPONDER_PH1_W4_PAIRING_REQUEST; 2947 sm_send_connectionless(connection, (uint8_t *) buffer, sizeof(buffer)); 2948 sm_timeout_start(connection); 2949 break; 2950 } 2951 2952 #ifdef ENABLE_LE_SECURE_CONNECTIONS 2953 case SM_SC_RECEIVED_LTK_REQUEST: 2954 switch (connection->sm_irk_lookup_state){ 2955 case IRK_LOOKUP_SUCCEEDED: 2956 // assuming Secure Connection, we have a stored LTK and the EDIV/RAND are null 2957 // start using context by loading security info 2958 sm_reset_setup(); 2959 sm_load_security_info(connection); 2960 if ((setup->sm_peer_ediv == 0u) && sm_is_null_random(setup->sm_peer_rand) && !sm_is_null_key(setup->sm_peer_ltk)){ 2961 (void)memcpy(setup->sm_ltk, setup->sm_peer_ltk, 16); 2962 connection->sm_engine_state = SM_RESPONDER_PH4_SEND_LTK_REPLY; 2963 sm_reencryption_started(connection); 2964 sm_trigger_run(); 2965 break; 2966 } 2967 log_info("LTK Request: ediv & random are empty, but no stored LTK (IRK Lookup Succeeded)"); 2968 connection->sm_engine_state = SM_RESPONDER_IDLE; 2969 hci_send_cmd(&hci_le_long_term_key_negative_reply, connection->sm_handle); 2970 return; 2971 default: 2972 // just wait until IRK lookup is completed 2973 break; 2974 } 2975 break; 2976 #endif /* ENABLE_LE_SECURE_CONNECTIONS */ 2977 2978 case SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED: 2979 sm_reset_setup(); 2980 2981 // handle Pairing Request with LTK available 2982 switch (connection->sm_irk_lookup_state) { 2983 case IRK_LOOKUP_SUCCEEDED: 2984 le_device_db_encryption_get(connection->sm_le_db_index, NULL, NULL, ltk, NULL, NULL, NULL, NULL); 2985 have_ltk = !sm_is_null_key(ltk); 2986 if (have_ltk){ 2987 log_info("pairing request but LTK available"); 2988 // emit re-encryption start/fail sequence 2989 sm_reencryption_started(connection); 2990 sm_reencryption_complete(connection, ERROR_CODE_PIN_OR_KEY_MISSING); 2991 } 2992 break; 2993 default: 2994 break; 2995 } 2996 2997 sm_init_setup(connection); 2998 2999 // recover pairing request 3000 (void)memcpy(&setup->sm_m_preq, &connection->sm_m_preq, sizeof(sm_pairing_packet_t)); 3001 err = sm_stk_generation_init(connection); 3002 3003 #ifdef ENABLE_TESTING_SUPPORT 3004 if ((0 < test_pairing_failure) && (test_pairing_failure < SM_REASON_DHKEY_CHECK_FAILED)){ 3005 log_info("testing_support: respond with pairing failure %u", test_pairing_failure); 3006 err = test_pairing_failure; 3007 } 3008 #endif 3009 if (err != 0){ 3010 // emit pairing started/failed sequence 3011 sm_pairing_started(connection); 3012 sm_pairing_error(connection, err); 3013 sm_trigger_run(); 3014 break; 3015 } 3016 3017 sm_timeout_start(connection); 3018 3019 // generate random number first, if we need to show passkey, otherwise send response 3020 if (setup->sm_stk_generation_method == PK_INIT_INPUT){ 3021 btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph2_tk, (void *)(uintptr_t) connection->sm_handle); 3022 break; 3023 } 3024 3025 /* fall through */ 3026 3027 case SM_RESPONDER_PH1_SEND_PAIRING_RESPONSE: 3028 sm_pairing_packet_set_code(setup->sm_s_pres,SM_CODE_PAIRING_RESPONSE); 3029 3030 // start with initiator key dist flags 3031 key_distribution_flags = sm_key_distribution_flags_for_auth_req(); 3032 3033 #ifdef ENABLE_LE_SECURE_CONNECTIONS 3034 // LTK (= encyrption information & master identification) only exchanged for LE Legacy Connection 3035 if (setup->sm_use_secure_connections){ 3036 key_distribution_flags &= ~SM_KEYDIST_ENC_KEY; 3037 } 3038 #endif 3039 // setup in response 3040 sm_pairing_packet_set_initiator_key_distribution(setup->sm_s_pres, sm_pairing_packet_get_initiator_key_distribution(setup->sm_m_preq) & key_distribution_flags); 3041 sm_pairing_packet_set_responder_key_distribution(setup->sm_s_pres, sm_pairing_packet_get_responder_key_distribution(setup->sm_m_preq) & key_distribution_flags); 3042 3043 // update key distribution after ENC was dropped 3044 sm_setup_key_distribution(sm_pairing_packet_get_responder_key_distribution(setup->sm_s_pres), sm_pairing_packet_get_initiator_key_distribution(setup->sm_s_pres)); 3045 3046 if (setup->sm_use_secure_connections){ 3047 connection->sm_engine_state = SM_SC_W4_PUBLIC_KEY_COMMAND; 3048 } else { 3049 connection->sm_engine_state = SM_RESPONDER_PH1_W4_PAIRING_CONFIRM; 3050 } 3051 3052 sm_send_connectionless(connection, (uint8_t*) &setup->sm_s_pres, sizeof(sm_pairing_packet_t)); 3053 sm_timeout_reset(connection); 3054 3055 // notify after sending 3056 sm_pairing_started(connection); 3057 3058 // SC Numeric Comparison will trigger user response after public keys & nonces have been exchanged 3059 if (!setup->sm_use_secure_connections || (setup->sm_stk_generation_method == JUST_WORKS)){ 3060 sm_trigger_user_response(connection); 3061 } 3062 return; 3063 #endif 3064 3065 case SM_PH2_SEND_PAIRING_RANDOM: { 3066 uint8_t buffer[17]; 3067 buffer[0] = SM_CODE_PAIRING_RANDOM; 3068 reverse_128(setup->sm_local_random, &buffer[1]); 3069 if (IS_RESPONDER(connection->sm_role)){ 3070 connection->sm_engine_state = SM_RESPONDER_PH2_W4_LTK_REQUEST; 3071 } else { 3072 connection->sm_engine_state = SM_INITIATOR_PH2_W4_PAIRING_RANDOM; 3073 } 3074 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 3075 sm_timeout_reset(connection); 3076 break; 3077 } 3078 3079 case SM_PH2_C1_GET_ENC_A: 3080 // already busy? 3081 if (sm_aes128_state == SM_AES128_ACTIVE) break; 3082 // calculate confirm using aes128 engine - step 1 3083 sm_c1_t1(setup->sm_local_random, (uint8_t*) &setup->sm_m_preq, (uint8_t*) &setup->sm_s_pres, setup->sm_m_addr_type, setup->sm_s_addr_type, sm_aes128_plaintext); 3084 connection->sm_engine_state = SM_PH2_C1_W4_ENC_A; 3085 sm_aes128_state = SM_AES128_ACTIVE; 3086 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_enc_a, (void *)(uintptr_t) connection->sm_handle); 3087 break; 3088 3089 case SM_PH2_C1_GET_ENC_C: 3090 // already busy? 3091 if (sm_aes128_state == SM_AES128_ACTIVE) break; 3092 // calculate m_confirm using aes128 engine - step 1 3093 sm_c1_t1(setup->sm_peer_random, (uint8_t*) &setup->sm_m_preq, (uint8_t*) &setup->sm_s_pres, setup->sm_m_addr_type, setup->sm_s_addr_type, sm_aes128_plaintext); 3094 connection->sm_engine_state = SM_PH2_C1_W4_ENC_C; 3095 sm_aes128_state = SM_AES128_ACTIVE; 3096 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_enc_c, (void *)(uintptr_t) connection->sm_handle); 3097 break; 3098 3099 case SM_PH2_CALC_STK: 3100 // already busy? 3101 if (sm_aes128_state == SM_AES128_ACTIVE) break; 3102 // calculate STK 3103 if (IS_RESPONDER(connection->sm_role)){ 3104 sm_s1_r_prime(setup->sm_local_random, setup->sm_peer_random, sm_aes128_plaintext); 3105 } else { 3106 sm_s1_r_prime(setup->sm_peer_random, setup->sm_local_random, sm_aes128_plaintext); 3107 } 3108 connection->sm_engine_state = SM_PH2_W4_STK; 3109 sm_aes128_state = SM_AES128_ACTIVE; 3110 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, sm_aes128_plaintext, setup->sm_ltk, sm_handle_encryption_result_enc_stk, (void *)(uintptr_t) connection->sm_handle); 3111 break; 3112 3113 case SM_PH3_Y_GET_ENC: 3114 // already busy? 3115 if (sm_aes128_state == SM_AES128_ACTIVE) break; 3116 // PH3B2 - calculate Y from - enc 3117 3118 // dm helper (was sm_dm_r_prime) 3119 // r' = padding || r 3120 // r - 64 bit value 3121 memset(&sm_aes128_plaintext[0], 0, 8); 3122 (void)memcpy(&sm_aes128_plaintext[8], setup->sm_local_rand, 8); 3123 3124 // Y = dm(DHK, Rand) 3125 connection->sm_engine_state = SM_PH3_Y_W4_ENC; 3126 sm_aes128_state = SM_AES128_ACTIVE; 3127 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_dhk, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_enc_ph3_y, (void *)(uintptr_t) connection->sm_handle); 3128 break; 3129 3130 case SM_PH2_C1_SEND_PAIRING_CONFIRM: { 3131 uint8_t buffer[17]; 3132 buffer[0] = SM_CODE_PAIRING_CONFIRM; 3133 reverse_128(setup->sm_local_confirm, &buffer[1]); 3134 if (IS_RESPONDER(connection->sm_role)){ 3135 connection->sm_engine_state = SM_RESPONDER_PH2_W4_PAIRING_RANDOM; 3136 } else { 3137 connection->sm_engine_state = SM_INITIATOR_PH2_W4_PAIRING_CONFIRM; 3138 } 3139 sm_send_connectionless(connection, (uint8_t*) buffer, sizeof(buffer)); 3140 sm_timeout_reset(connection); 3141 return; 3142 } 3143 #ifdef ENABLE_LE_PERIPHERAL 3144 case SM_RESPONDER_PH2_SEND_LTK_REPLY: { 3145 // cache key before using 3146 sm_cache_ltk(connection, setup->sm_ltk); 3147 sm_key_t stk_flipped; 3148 reverse_128(setup->sm_ltk, stk_flipped); 3149 connection->sm_engine_state = SM_PH2_W4_CONNECTION_ENCRYPTED; 3150 hci_send_cmd(&hci_le_long_term_key_request_reply, connection->sm_handle, stk_flipped); 3151 return; 3152 } 3153 case SM_RESPONDER_PH4_SEND_LTK_REPLY: { 3154 // allow to override LTK 3155 if (sm_get_ltk_callback != NULL){ 3156 (void)(*sm_get_ltk_callback)(connection->sm_handle, connection->sm_peer_addr_type, connection->sm_peer_address, setup->sm_ltk); 3157 } 3158 // cache key before using 3159 sm_cache_ltk(connection, setup->sm_ltk); 3160 sm_key_t ltk_flipped; 3161 reverse_128(setup->sm_ltk, ltk_flipped); 3162 connection->sm_engine_state = SM_PH4_W4_CONNECTION_ENCRYPTED; 3163 hci_send_cmd(&hci_le_long_term_key_request_reply, connection->sm_handle, ltk_flipped); 3164 return; 3165 } 3166 3167 case SM_RESPONDER_PH0_RECEIVED_LTK_REQUEST: 3168 // already busy? 3169 if (sm_aes128_state == SM_AES128_ACTIVE) break; 3170 log_info("LTK Request: recalculating with ediv 0x%04x", setup->sm_local_ediv); 3171 3172 sm_reset_setup(); 3173 sm_start_calculating_ltk_from_ediv_and_rand(connection); 3174 3175 sm_reencryption_started(connection); 3176 3177 // dm helper (was sm_dm_r_prime) 3178 // r' = padding || r 3179 // r - 64 bit value 3180 memset(&sm_aes128_plaintext[0], 0, 8); 3181 (void)memcpy(&sm_aes128_plaintext[8], setup->sm_local_rand, 8); 3182 3183 // Y = dm(DHK, Rand) 3184 connection->sm_engine_state = SM_RESPONDER_PH4_Y_W4_ENC; 3185 sm_aes128_state = SM_AES128_ACTIVE; 3186 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_dhk, sm_aes128_plaintext, sm_aes128_ciphertext, sm_handle_encryption_result_enc_ph4_y, (void *)(uintptr_t) connection->sm_handle); 3187 return; 3188 #endif 3189 #ifdef ENABLE_LE_CENTRAL 3190 case SM_INITIATOR_PH3_SEND_START_ENCRYPTION: { 3191 sm_key_t stk_flipped; 3192 reverse_128(setup->sm_ltk, stk_flipped); 3193 connection->sm_engine_state = SM_PH2_W4_CONNECTION_ENCRYPTED; 3194 hci_send_cmd(&hci_le_start_encryption, connection->sm_handle, 0, 0, 0, stk_flipped); 3195 return; 3196 } 3197 #endif 3198 3199 case SM_PH3_DISTRIBUTE_KEYS: 3200 // send next key 3201 if (setup->sm_key_distribution_send_set != 0){ 3202 sm_run_distribute_keys(connection); 3203 } 3204 3205 // more to send? 3206 if (setup->sm_key_distribution_send_set != 0){ 3207 return; 3208 } 3209 3210 // keys are sent 3211 if (IS_RESPONDER(connection->sm_role)){ 3212 // slave -> receive master keys if any 3213 if (sm_key_distribution_all_received()){ 3214 sm_key_distribution_handle_all_received(connection); 3215 sm_key_distribution_complete_responder(connection); 3216 // start CTKD right away 3217 continue; 3218 } else { 3219 connection->sm_engine_state = SM_PH3_RECEIVE_KEYS; 3220 } 3221 } else { 3222 sm_master_pairing_success(connection); 3223 } 3224 break; 3225 3226 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 3227 case SM_BR_EDR_INITIATOR_SEND_PAIRING_REQUEST: 3228 // fill in sm setup (lite version of sm_init_setup) 3229 sm_reset_setup(); 3230 setup->sm_peer_addr_type = connection->sm_peer_addr_type; 3231 setup->sm_m_addr_type = connection->sm_peer_addr_type; 3232 setup->sm_s_addr_type = connection->sm_own_addr_type; 3233 (void) memcpy(setup->sm_peer_address, connection->sm_peer_address, 6); 3234 (void) memcpy(setup->sm_m_address, connection->sm_peer_address, 6); 3235 (void) memcpy(setup->sm_s_address, connection->sm_own_address, 6); 3236 setup->sm_use_secure_connections = true; 3237 sm_ctkd_fetch_br_edr_link_key(connection); 3238 3239 // Enc Key and IRK if requested 3240 key_distribution_flags = SM_KEYDIST_ID_KEY | SM_KEYDIST_ENC_KEY; 3241 #ifdef ENABLE_LE_SIGNED_WRITE 3242 // Plus signing key if supported 3243 key_distribution_flags |= SM_KEYDIST_ID_KEY; 3244 #endif 3245 sm_pairing_packet_set_code(setup->sm_m_preq, SM_CODE_PAIRING_REQUEST); 3246 sm_pairing_packet_set_io_capability(setup->sm_m_preq, 0); 3247 sm_pairing_packet_set_oob_data_flag(setup->sm_m_preq, 0); 3248 sm_pairing_packet_set_auth_req(setup->sm_m_preq, SM_AUTHREQ_CT2); 3249 sm_pairing_packet_set_max_encryption_key_size(setup->sm_m_preq, sm_max_encryption_key_size); 3250 sm_pairing_packet_set_initiator_key_distribution(setup->sm_m_preq, key_distribution_flags); 3251 sm_pairing_packet_set_responder_key_distribution(setup->sm_m_preq, key_distribution_flags); 3252 3253 // set state and send pairing response 3254 sm_timeout_start(connection); 3255 connection->sm_engine_state = SM_BR_EDR_INITIATOR_W4_PAIRING_RESPONSE; 3256 sm_send_connectionless(connection, (uint8_t *) &setup->sm_m_preq, sizeof(sm_pairing_packet_t)); 3257 break; 3258 3259 case SM_BR_EDR_RESPONDER_PAIRING_REQUEST_RECEIVED: 3260 // fill in sm setup (lite version of sm_init_setup) 3261 sm_reset_setup(); 3262 setup->sm_peer_addr_type = connection->sm_peer_addr_type; 3263 setup->sm_m_addr_type = connection->sm_peer_addr_type; 3264 setup->sm_s_addr_type = connection->sm_own_addr_type; 3265 (void) memcpy(setup->sm_peer_address, connection->sm_peer_address, 6); 3266 (void) memcpy(setup->sm_m_address, connection->sm_peer_address, 6); 3267 (void) memcpy(setup->sm_s_address, connection->sm_own_address, 6); 3268 setup->sm_use_secure_connections = true; 3269 sm_ctkd_fetch_br_edr_link_key(connection); 3270 (void) memcpy(&setup->sm_m_preq, &connection->sm_m_preq, sizeof(sm_pairing_packet_t)); 3271 3272 // Enc Key and IRK if requested 3273 key_distribution_flags = SM_KEYDIST_ID_KEY | SM_KEYDIST_ENC_KEY; 3274 #ifdef ENABLE_LE_SIGNED_WRITE 3275 // Plus signing key if supported 3276 key_distribution_flags |= SM_KEYDIST_ID_KEY; 3277 #endif 3278 // drop flags not requested by initiator 3279 key_distribution_flags &= sm_pairing_packet_get_initiator_key_distribution(connection->sm_m_preq); 3280 3281 // If Secure Connections pairing has been initiated over BR/EDR, the following fields of the SM Pairing Request PDU are reserved for future use: 3282 // - the IO Capability field, 3283 // - the OOB data flag field, and 3284 // - all bits in the Auth Req field except the CT2 bit. 3285 sm_pairing_packet_set_code(setup->sm_s_pres, SM_CODE_PAIRING_RESPONSE); 3286 sm_pairing_packet_set_io_capability(setup->sm_s_pres, 0); 3287 sm_pairing_packet_set_oob_data_flag(setup->sm_s_pres, 0); 3288 sm_pairing_packet_set_auth_req(setup->sm_s_pres, SM_AUTHREQ_CT2); 3289 sm_pairing_packet_set_max_encryption_key_size(setup->sm_s_pres, connection->sm_actual_encryption_key_size); 3290 sm_pairing_packet_set_initiator_key_distribution(setup->sm_s_pres, key_distribution_flags); 3291 sm_pairing_packet_set_responder_key_distribution(setup->sm_s_pres, key_distribution_flags); 3292 3293 // configure key distribution, LTK is derived locally 3294 key_distribution_flags &= ~SM_KEYDIST_ENC_KEY; 3295 sm_setup_key_distribution(key_distribution_flags, key_distribution_flags); 3296 3297 // set state and send pairing response 3298 sm_timeout_start(connection); 3299 connection->sm_engine_state = SM_BR_EDR_DISTRIBUTE_KEYS; 3300 sm_send_connectionless(connection, (uint8_t *) &setup->sm_s_pres, sizeof(sm_pairing_packet_t)); 3301 break; 3302 case SM_BR_EDR_DISTRIBUTE_KEYS: 3303 if (setup->sm_key_distribution_send_set != 0) { 3304 sm_run_distribute_keys(connection); 3305 return; 3306 } 3307 // keys are sent 3308 if (IS_RESPONDER(connection->sm_role)) { 3309 // responder -> receive master keys if there are any 3310 if (!sm_key_distribution_all_received()){ 3311 connection->sm_engine_state = SM_BR_EDR_RECEIVE_KEYS; 3312 break; 3313 } 3314 } 3315 // otherwise start CTKD right away (responder and no keys to receive / initiator) 3316 sm_ctkd_start_from_br_edr(connection); 3317 continue; 3318 case SM_SC_W2_CALCULATE_ILK_USING_H6: 3319 connection->sm_engine_state = SM_SC_W4_CALCULATE_ILK; 3320 h6_calculate_ilk_from_le_ltk(connection); 3321 break; 3322 case SM_SC_W2_CALCULATE_BR_EDR_LINK_KEY: 3323 connection->sm_engine_state = SM_SC_W4_CALCULATE_BR_EDR_LINK_KEY; 3324 h6_calculate_br_edr_link_key(connection); 3325 break; 3326 case SM_SC_W2_CALCULATE_ILK_USING_H7: 3327 connection->sm_engine_state = SM_SC_W4_CALCULATE_ILK; 3328 h7_calculate_ilk_from_le_ltk(connection); 3329 break; 3330 case SM_BR_EDR_W2_CALCULATE_ILK_USING_H6: 3331 connection->sm_engine_state = SM_BR_EDR_W4_CALCULATE_ILK; 3332 h6_calculate_ilk_from_br_edr(connection); 3333 break; 3334 case SM_BR_EDR_W2_CALCULATE_LE_LTK: 3335 connection->sm_engine_state = SM_BR_EDR_W4_CALCULATE_LE_LTK; 3336 h6_calculate_le_ltk(connection); 3337 break; 3338 case SM_BR_EDR_W2_CALCULATE_ILK_USING_H7: 3339 connection->sm_engine_state = SM_BR_EDR_W4_CALCULATE_ILK; 3340 h7_calculate_ilk_from_br_edr(connection); 3341 break; 3342 #endif 3343 3344 default: 3345 break; 3346 } 3347 3348 // check again if active connection was released 3349 if (sm_active_connection_handle != HCI_CON_HANDLE_INVALID) break; 3350 } 3351 } 3352 3353 // sm_aes128_state stays active 3354 static void sm_handle_encryption_result_enc_a(void *arg){ 3355 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3356 sm_aes128_state = SM_AES128_IDLE; 3357 3358 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3359 if (connection == NULL) return; 3360 3361 sm_c1_t3(sm_aes128_ciphertext, setup->sm_m_address, setup->sm_s_address, setup->sm_c1_t3_value); 3362 sm_aes128_state = SM_AES128_ACTIVE; 3363 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, setup->sm_c1_t3_value, setup->sm_local_confirm, sm_handle_encryption_result_enc_b, (void *)(uintptr_t) connection->sm_handle); 3364 } 3365 3366 static void sm_handle_encryption_result_enc_b(void *arg){ 3367 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3368 sm_aes128_state = SM_AES128_IDLE; 3369 3370 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3371 if (connection == NULL) return; 3372 3373 log_info_key("c1!", setup->sm_local_confirm); 3374 connection->sm_engine_state = SM_PH2_C1_SEND_PAIRING_CONFIRM; 3375 sm_trigger_run(); 3376 } 3377 3378 // sm_aes128_state stays active 3379 static void sm_handle_encryption_result_enc_c(void *arg){ 3380 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3381 sm_aes128_state = SM_AES128_IDLE; 3382 3383 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3384 if (connection == NULL) return; 3385 3386 sm_c1_t3(sm_aes128_ciphertext, setup->sm_m_address, setup->sm_s_address, setup->sm_c1_t3_value); 3387 sm_aes128_state = SM_AES128_ACTIVE; 3388 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, setup->sm_c1_t3_value, sm_aes128_ciphertext, sm_handle_encryption_result_enc_d, (void *)(uintptr_t) connection->sm_handle); 3389 } 3390 3391 static void sm_handle_encryption_result_enc_d(void * arg){ 3392 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3393 sm_aes128_state = SM_AES128_IDLE; 3394 3395 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3396 if (connection == NULL) return; 3397 3398 log_info_key("c1!", sm_aes128_ciphertext); 3399 if (memcmp(setup->sm_peer_confirm, sm_aes128_ciphertext, 16) != 0){ 3400 sm_pairing_error(connection, SM_REASON_CONFIRM_VALUE_FAILED); 3401 sm_trigger_run(); 3402 return; 3403 } 3404 if (IS_RESPONDER(connection->sm_role)){ 3405 connection->sm_engine_state = SM_PH2_SEND_PAIRING_RANDOM; 3406 sm_trigger_run(); 3407 } else { 3408 sm_s1_r_prime(setup->sm_peer_random, setup->sm_local_random, sm_aes128_plaintext); 3409 sm_aes128_state = SM_AES128_ACTIVE; 3410 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, setup->sm_tk, sm_aes128_plaintext, setup->sm_ltk, sm_handle_encryption_result_enc_stk, (void *)(uintptr_t) connection->sm_handle); 3411 } 3412 } 3413 3414 static void sm_handle_encryption_result_enc_stk(void *arg){ 3415 sm_aes128_state = SM_AES128_IDLE; 3416 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3417 3418 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3419 if (connection == NULL) return; 3420 3421 sm_truncate_key(setup->sm_ltk, connection->sm_actual_encryption_key_size); 3422 log_info_key("stk", setup->sm_ltk); 3423 if (IS_RESPONDER(connection->sm_role)){ 3424 connection->sm_engine_state = SM_RESPONDER_PH2_SEND_LTK_REPLY; 3425 } else { 3426 connection->sm_engine_state = SM_INITIATOR_PH3_SEND_START_ENCRYPTION; 3427 } 3428 sm_trigger_run(); 3429 } 3430 3431 // sm_aes128_state stays active 3432 static void sm_handle_encryption_result_enc_ph3_y(void *arg){ 3433 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3434 sm_aes128_state = SM_AES128_IDLE; 3435 3436 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3437 if (connection == NULL) return; 3438 3439 setup->sm_local_y = big_endian_read_16(sm_aes128_ciphertext, 14); 3440 log_info_hex16("y", setup->sm_local_y); 3441 // PH3B3 - calculate EDIV 3442 setup->sm_local_ediv = setup->sm_local_y ^ setup->sm_local_div; 3443 log_info_hex16("ediv", setup->sm_local_ediv); 3444 // PH3B4 - calculate LTK - enc 3445 // LTK = d1(ER, DIV, 0)) 3446 sm_d1_d_prime(setup->sm_local_div, 0, sm_aes128_plaintext); 3447 sm_aes128_state = SM_AES128_ACTIVE; 3448 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_er, sm_aes128_plaintext, setup->sm_ltk, sm_handle_encryption_result_enc_ph3_ltk, (void *)(uintptr_t) connection->sm_handle); 3449 } 3450 3451 #ifdef ENABLE_LE_PERIPHERAL 3452 // sm_aes128_state stays active 3453 static void sm_handle_encryption_result_enc_ph4_y(void *arg){ 3454 sm_aes128_state = SM_AES128_IDLE; 3455 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3456 3457 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3458 if (connection == NULL) return; 3459 3460 setup->sm_local_y = big_endian_read_16(sm_aes128_ciphertext, 14); 3461 log_info_hex16("y", setup->sm_local_y); 3462 3463 // PH3B3 - calculate DIV 3464 setup->sm_local_div = setup->sm_local_y ^ setup->sm_local_ediv; 3465 log_info_hex16("ediv", setup->sm_local_ediv); 3466 // PH3B4 - calculate LTK - enc 3467 // LTK = d1(ER, DIV, 0)) 3468 sm_d1_d_prime(setup->sm_local_div, 0, sm_aes128_plaintext); 3469 sm_aes128_state = SM_AES128_ACTIVE; 3470 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_er, sm_aes128_plaintext, setup->sm_ltk, sm_handle_encryption_result_enc_ph4_ltk, (void *)(uintptr_t) connection->sm_handle); 3471 } 3472 #endif 3473 3474 // sm_aes128_state stays active 3475 static void sm_handle_encryption_result_enc_ph3_ltk(void *arg){ 3476 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3477 sm_aes128_state = SM_AES128_IDLE; 3478 3479 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3480 if (connection == NULL) return; 3481 3482 log_info_key("ltk", setup->sm_ltk); 3483 // calc CSRK next 3484 sm_d1_d_prime(setup->sm_local_div, 1, sm_aes128_plaintext); 3485 sm_aes128_state = SM_AES128_ACTIVE; 3486 btstack_crypto_aes128_encrypt(&sm_crypto_aes128_request, sm_persistent_er, sm_aes128_plaintext, setup->sm_local_csrk, sm_handle_encryption_result_enc_csrk, (void *)(uintptr_t) connection->sm_handle); 3487 } 3488 3489 static void sm_handle_encryption_result_enc_csrk(void *arg){ 3490 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3491 sm_aes128_state = SM_AES128_IDLE; 3492 3493 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3494 if (connection == NULL) return; 3495 3496 sm_aes128_state = SM_AES128_IDLE; 3497 log_info_key("csrk", setup->sm_local_csrk); 3498 if (setup->sm_key_distribution_send_set){ 3499 connection->sm_engine_state = SM_PH3_DISTRIBUTE_KEYS; 3500 } else { 3501 // no keys to send, just continue 3502 if (IS_RESPONDER(connection->sm_role)){ 3503 if (sm_key_distribution_all_received()){ 3504 sm_key_distribution_handle_all_received(connection); 3505 sm_key_distribution_complete_responder(connection); 3506 } else { 3507 // slave -> receive master keys 3508 connection->sm_engine_state = SM_PH3_RECEIVE_KEYS; 3509 } 3510 } else { 3511 sm_key_distribution_complete_initiator(connection); 3512 } 3513 } 3514 sm_trigger_run(); 3515 } 3516 3517 #ifdef ENABLE_LE_PERIPHERAL 3518 static void sm_handle_encryption_result_enc_ph4_ltk(void *arg){ 3519 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3520 sm_aes128_state = SM_AES128_IDLE; 3521 3522 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3523 if (connection == NULL) return; 3524 3525 sm_truncate_key(setup->sm_ltk, connection->sm_actual_encryption_key_size); 3526 log_info_key("ltk", setup->sm_ltk); 3527 connection->sm_engine_state = SM_RESPONDER_PH4_SEND_LTK_REPLY; 3528 sm_trigger_run(); 3529 } 3530 #endif 3531 3532 static void sm_handle_encryption_result_address_resolution(void *arg){ 3533 UNUSED(arg); 3534 sm_aes128_state = SM_AES128_IDLE; 3535 3536 // compare calulated address against connecting device 3537 uint8_t * hash = &sm_aes128_ciphertext[13]; 3538 if (memcmp(&sm_address_resolution_address[3], hash, 3) == 0){ 3539 log_info("LE Device Lookup: matched resolvable private address"); 3540 sm_address_resolution_handle_event(ADDRESS_RESOLUTION_SUCCEEDED); 3541 sm_trigger_run(); 3542 return; 3543 } 3544 // no match, try next 3545 sm_address_resolution_test++; 3546 sm_trigger_run(); 3547 } 3548 3549 static void sm_handle_encryption_result_dkg_irk(void *arg){ 3550 UNUSED(arg); 3551 sm_aes128_state = SM_AES128_IDLE; 3552 3553 log_info_key("irk", sm_persistent_irk); 3554 dkg_state = DKG_CALC_DHK; 3555 sm_trigger_run(); 3556 } 3557 3558 static void sm_handle_encryption_result_dkg_dhk(void *arg){ 3559 UNUSED(arg); 3560 sm_aes128_state = SM_AES128_IDLE; 3561 3562 log_info_key("dhk", sm_persistent_dhk); 3563 dkg_state = DKG_READY; 3564 sm_trigger_run(); 3565 } 3566 3567 static void sm_handle_encryption_result_rau(void *arg){ 3568 UNUSED(arg); 3569 sm_aes128_state = SM_AES128_IDLE; 3570 3571 (void)memcpy(&sm_random_address[3], &sm_aes128_ciphertext[13], 3); 3572 rau_state = RAU_IDLE; 3573 hci_le_random_address_set(sm_random_address); 3574 3575 sm_trigger_run(); 3576 } 3577 3578 static void sm_handle_random_result_rau(void * arg){ 3579 UNUSED(arg); 3580 // non-resolvable vs. resolvable 3581 switch (gap_random_adress_type){ 3582 case GAP_RANDOM_ADDRESS_RESOLVABLE: 3583 // resolvable: use random as prand and calc address hash 3584 // "The two most significant bits of prand shall be equal to ‘0’ and ‘1" 3585 sm_random_address[0u] &= 0x3fu; 3586 sm_random_address[0u] |= 0x40u; 3587 rau_state = RAU_GET_ENC; 3588 break; 3589 case GAP_RANDOM_ADDRESS_NON_RESOLVABLE: 3590 default: 3591 // "The two most significant bits of the address shall be equal to ‘0’"" 3592 sm_random_address[0u] &= 0x3fu; 3593 rau_state = RAU_IDLE; 3594 hci_le_random_address_set(sm_random_address); 3595 break; 3596 } 3597 sm_trigger_run(); 3598 } 3599 3600 #ifdef ENABLE_LE_SECURE_CONNECTIONS 3601 static void sm_handle_random_result_sc_next_send_pairing_random(void * arg){ 3602 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3603 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3604 if (connection == NULL) return; 3605 3606 connection->sm_engine_state = SM_SC_SEND_PAIRING_RANDOM; 3607 sm_trigger_run(); 3608 } 3609 3610 static void sm_handle_random_result_sc_next_w2_cmac_for_confirmation(void * arg){ 3611 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3612 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3613 if (connection == NULL) return; 3614 3615 connection->sm_engine_state = SM_SC_W2_CMAC_FOR_CONFIRMATION; 3616 sm_trigger_run(); 3617 } 3618 #endif 3619 3620 static void sm_handle_random_result_ph2_random(void * arg){ 3621 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3622 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3623 if (connection == NULL) return; 3624 3625 connection->sm_engine_state = SM_PH2_C1_GET_ENC_A; 3626 sm_trigger_run(); 3627 } 3628 3629 static void sm_handle_random_result_ph2_tk(void * arg){ 3630 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3631 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3632 if (connection == NULL) return; 3633 3634 sm_reset_tk(); 3635 uint32_t tk; 3636 if (sm_fixed_passkey_in_display_role == 0xffffffffU){ 3637 // map random to 0-999999 without speding much cycles on a modulus operation 3638 tk = little_endian_read_32(sm_random_data,0); 3639 tk = tk & 0xfffff; // 1048575 3640 if (tk >= 999999u){ 3641 tk = tk - 999999u; 3642 } 3643 } else { 3644 // override with pre-defined passkey 3645 tk = sm_fixed_passkey_in_display_role; 3646 } 3647 big_endian_store_32(setup->sm_tk, 12, tk); 3648 if (IS_RESPONDER(connection->sm_role)){ 3649 connection->sm_engine_state = SM_RESPONDER_PH1_SEND_PAIRING_RESPONSE; 3650 } else { 3651 if (setup->sm_use_secure_connections){ 3652 connection->sm_engine_state = SM_SC_SEND_PUBLIC_KEY_COMMAND; 3653 } else { 3654 connection->sm_engine_state = SM_PH1_W4_USER_RESPONSE; 3655 sm_trigger_user_response(connection); 3656 // response_idle == nothing <--> sm_trigger_user_response() did not require response 3657 if (setup->sm_user_response == SM_USER_RESPONSE_IDLE){ 3658 btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_random, 16, &sm_handle_random_result_ph2_random, (void *)(uintptr_t) connection->sm_handle); 3659 } 3660 } 3661 } 3662 sm_trigger_run(); 3663 } 3664 3665 static void sm_handle_random_result_ph3_div(void * arg){ 3666 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3667 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3668 if (connection == NULL) return; 3669 3670 // use 16 bit from random value as div 3671 setup->sm_local_div = big_endian_read_16(sm_random_data, 0); 3672 log_info_hex16("div", setup->sm_local_div); 3673 connection->sm_engine_state = SM_PH3_Y_GET_ENC; 3674 sm_trigger_run(); 3675 } 3676 3677 static void sm_handle_random_result_ph3_random(void * arg){ 3678 hci_con_handle_t con_handle = (hci_con_handle_t) (uintptr_t) arg; 3679 sm_connection_t * connection = sm_get_connection_for_handle(con_handle); 3680 if (connection == NULL) return; 3681 3682 reverse_64(sm_random_data, setup->sm_local_rand); 3683 // no db for encryption size hack: encryption size is stored in lowest nibble of setup->sm_local_rand 3684 setup->sm_local_rand[7u] = (setup->sm_local_rand[7u] & 0xf0u) + (connection->sm_actual_encryption_key_size - 1u); 3685 // no db for authenticated flag hack: store flag in bit 4 of LSB 3686 setup->sm_local_rand[7u] = (setup->sm_local_rand[7u] & 0xefu) + (connection->sm_connection_authenticated << 4u); 3687 btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 2, &sm_handle_random_result_ph3_div, (void *)(uintptr_t) connection->sm_handle); 3688 } 3689 static void sm_validate_er_ir(void){ 3690 // warn about default ER/IR 3691 bool warning = false; 3692 if (sm_ir_is_default()){ 3693 warning = true; 3694 log_error("Persistent IR not set with sm_set_ir. Use of private addresses will cause pairing issues"); 3695 } 3696 if (sm_er_is_default()){ 3697 warning = true; 3698 log_error("Persistent ER not set with sm_set_er. Legacy Pairing LTK is not secure"); 3699 } 3700 if (warning) { 3701 log_error("Please configure btstack_tlv to let BTstack setup ER and IR keys"); 3702 } 3703 } 3704 3705 static void sm_handle_random_result_ir(void *arg){ 3706 sm_persistent_keys_random_active = false; 3707 if (arg != NULL){ 3708 // key generated, store in tlv 3709 int status = sm_tlv_impl->store_tag(sm_tlv_context, BTSTACK_TAG32('S','M','I','R'), sm_persistent_ir, 16u); 3710 log_info("Generated IR key. Store in TLV status: %d", status); 3711 UNUSED(status); 3712 } 3713 log_info_key("IR", sm_persistent_ir); 3714 dkg_state = DKG_CALC_IRK; 3715 3716 if (test_use_fixed_local_irk){ 3717 log_info_key("IRK", sm_persistent_irk); 3718 dkg_state = DKG_CALC_DHK; 3719 } 3720 3721 sm_trigger_run(); 3722 } 3723 3724 static void sm_handle_random_result_er(void *arg){ 3725 sm_persistent_keys_random_active = false; 3726 if (arg != 0){ 3727 // key generated, store in tlv 3728 int status = sm_tlv_impl->store_tag(sm_tlv_context, BTSTACK_TAG32('S','M','E','R'), sm_persistent_er, 16u); 3729 log_info("Generated ER key. Store in TLV status: %d", status); 3730 UNUSED(status); 3731 } 3732 log_info_key("ER", sm_persistent_er); 3733 3734 // try load ir 3735 int key_size = sm_tlv_impl->get_tag(sm_tlv_context, BTSTACK_TAG32('S','M','I','R'), sm_persistent_ir, 16u); 3736 if (key_size == 16){ 3737 // ok, let's continue 3738 log_info("IR from TLV"); 3739 sm_handle_random_result_ir( NULL ); 3740 } else { 3741 // invalid, generate new random one 3742 sm_persistent_keys_random_active = true; 3743 btstack_crypto_random_generate(&sm_crypto_random_request, sm_persistent_ir, 16, &sm_handle_random_result_ir, &sm_persistent_ir); 3744 } 3745 } 3746 3747 static void sm_connection_init(sm_connection_t * sm_conn, hci_con_handle_t con_handle, uint8_t role, uint8_t addr_type, bd_addr_t address){ 3748 3749 // connection info 3750 sm_conn->sm_handle = con_handle; 3751 sm_conn->sm_role = role; 3752 sm_conn->sm_peer_addr_type = addr_type; 3753 memcpy(sm_conn->sm_peer_address, address, 6); 3754 3755 // security properties 3756 sm_conn->sm_connection_encrypted = 0; 3757 sm_conn->sm_connection_authenticated = 0; 3758 sm_conn->sm_connection_authorization_state = AUTHORIZATION_UNKNOWN; 3759 sm_conn->sm_le_db_index = -1; 3760 sm_conn->sm_reencryption_active = false; 3761 3762 // prepare CSRK lookup (does not involve setup) 3763 sm_conn->sm_irk_lookup_state = IRK_LOOKUP_W4_READY; 3764 3765 sm_conn->sm_engine_state = SM_GENERAL_IDLE; 3766 } 3767 3768 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 3769 static void sm_event_handle_classic_encryption_event(sm_connection_t * sm_conn, hci_con_handle_t con_handle){ 3770 // CTKD requires BR/EDR Secure Connection 3771 if (sm_conn->sm_connection_encrypted != 2) return; 3772 // prepare for pairing request 3773 if (IS_RESPONDER(sm_conn->sm_role)){ 3774 sm_conn->sm_engine_state = SM_BR_EDR_RESPONDER_W4_PAIRING_REQUEST; 3775 } else if (sm_conn->sm_pairing_requested){ 3776 // check if remote supports fixed channels 3777 bool defer = true; 3778 const hci_connection_t * hci_connection = hci_connection_for_handle(con_handle); 3779 if (hci_connection->l2cap_state.information_state == L2CAP_INFORMATION_STATE_DONE){ 3780 // check if remote supports SMP over BR/EDR 3781 if ((hci_connection->l2cap_state.fixed_channels_supported & (1 << L2CAP_CID_BR_EDR_SECURITY_MANAGER)) != 0){ 3782 log_info("CTKD: SM_BR_EDR_INITIATOR_SEND_PAIRING_REQUEST"); 3783 sm_conn->sm_engine_state = SM_BR_EDR_INITIATOR_SEND_PAIRING_REQUEST; 3784 } else { 3785 defer = false; 3786 } 3787 } else { 3788 // wait for fixed channel info 3789 log_info("CTKD: SM_BR_EDR_INITIATOR_W4_FIXED_CHANNEL_MASK"); 3790 sm_conn->sm_engine_state = SM_BR_EDR_INITIATOR_W4_FIXED_CHANNEL_MASK; 3791 } 3792 if (defer){ 3793 hci_dedicated_bonding_defer_disconnect(con_handle, true); 3794 } 3795 } 3796 } 3797 #endif 3798 3799 static void sm_event_packet_handler (uint8_t packet_type, uint16_t channel, uint8_t *packet, uint16_t size){ 3800 3801 UNUSED(channel); // ok: there is no channel 3802 UNUSED(size); // ok: fixed format HCI events 3803 3804 sm_connection_t * sm_conn; 3805 hci_con_handle_t con_handle; 3806 uint8_t status; 3807 bd_addr_t addr; 3808 3809 switch (packet_type) { 3810 3811 case HCI_EVENT_PACKET: 3812 switch (hci_event_packet_get_type(packet)) { 3813 3814 case BTSTACK_EVENT_STATE: 3815 switch (btstack_event_state_get_state(packet)){ 3816 case HCI_STATE_WORKING: 3817 log_info("HCI Working!"); 3818 // setup IR/ER with TLV 3819 btstack_tlv_get_instance(&sm_tlv_impl, &sm_tlv_context); 3820 if (sm_tlv_impl != NULL){ 3821 int key_size = sm_tlv_impl->get_tag(sm_tlv_context, BTSTACK_TAG32('S','M','E','R'), sm_persistent_er, 16u); 3822 if (key_size == 16){ 3823 // ok, let's continue 3824 log_info("ER from TLV"); 3825 sm_handle_random_result_er( NULL ); 3826 } else { 3827 // invalid, generate random one 3828 sm_persistent_keys_random_active = true; 3829 btstack_crypto_random_generate(&sm_crypto_random_request, sm_persistent_er, 16, &sm_handle_random_result_er, &sm_persistent_er); 3830 } 3831 } else { 3832 sm_validate_er_ir(); 3833 dkg_state = DKG_CALC_IRK; 3834 3835 if (test_use_fixed_local_irk){ 3836 log_info_key("IRK", sm_persistent_irk); 3837 dkg_state = DKG_CALC_DHK; 3838 } 3839 } 3840 3841 #ifdef ENABLE_LE_SECURE_CONNECTIONS 3842 // trigger ECC key generation 3843 if (ec_key_generation_state == EC_KEY_GENERATION_IDLE){ 3844 sm_ec_generate_new_key(); 3845 } 3846 #endif 3847 3848 // restart random address updates after power cycle 3849 if (gap_random_adress_type == GAP_RANDOM_ADDRESS_TYPE_STATIC){ 3850 gap_random_address_set(sm_random_address); 3851 } else { 3852 gap_random_address_set_mode(gap_random_adress_type); 3853 } 3854 break; 3855 3856 case HCI_STATE_OFF: 3857 case HCI_STATE_HALTING: 3858 log_info("SM: reset state"); 3859 // stop random address update 3860 gap_random_address_update_stop(); 3861 // reset state 3862 sm_state_reset(); 3863 break; 3864 3865 default: 3866 break; 3867 } 3868 break; 3869 3870 #ifdef ENABLE_CLASSIC 3871 case HCI_EVENT_CONNECTION_COMPLETE: 3872 // ignore if connection failed 3873 if (hci_event_connection_complete_get_status(packet)) return; 3874 3875 con_handle = hci_event_connection_complete_get_connection_handle(packet); 3876 sm_conn = sm_get_connection_for_handle(con_handle); 3877 if (!sm_conn) break; 3878 3879 hci_event_connection_complete_get_bd_addr(packet, addr); 3880 sm_connection_init(sm_conn, 3881 con_handle, 3882 (uint8_t) gap_get_role(con_handle), 3883 BD_ADDR_TYPE_LE_PUBLIC, 3884 addr); 3885 // classic connection corresponds to public le address 3886 sm_conn->sm_own_addr_type = BD_ADDR_TYPE_LE_PUBLIC; 3887 gap_local_bd_addr(sm_conn->sm_own_address); 3888 sm_conn->sm_cid = L2CAP_CID_BR_EDR_SECURITY_MANAGER; 3889 sm_conn->sm_engine_state = SM_BR_EDR_W4_ENCRYPTION_COMPLETE; 3890 break; 3891 #endif 3892 3893 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 3894 case HCI_EVENT_SIMPLE_PAIRING_COMPLETE: 3895 if (hci_event_simple_pairing_complete_get_status(packet) != ERROR_CODE_SUCCESS) break; 3896 hci_event_simple_pairing_complete_get_bd_addr(packet, addr); 3897 sm_conn = sm_get_connection_for_bd_addr_and_type(addr, BD_ADDR_TYPE_ACL); 3898 if (sm_conn == NULL) break; 3899 sm_conn->sm_pairing_requested = 1; 3900 break; 3901 #endif 3902 3903 case HCI_EVENT_META_GAP: 3904 switch (hci_event_gap_meta_get_subevent_code(packet)) { 3905 case GAP_SUBEVENT_LE_CONNECTION_COMPLETE: 3906 // ignore if connection failed 3907 if (gap_subevent_le_connection_complete_get_status(packet) != ERROR_CODE_SUCCESS) break; 3908 3909 con_handle = gap_subevent_le_connection_complete_get_connection_handle(packet); 3910 sm_conn = sm_get_connection_for_handle(con_handle); 3911 if (!sm_conn) break; 3912 3913 gap_subevent_le_connection_complete_get_peer_address(packet, addr); 3914 sm_connection_init(sm_conn, 3915 con_handle, 3916 gap_subevent_le_connection_complete_get_role(packet), 3917 gap_subevent_le_connection_complete_get_peer_address_type(packet), 3918 addr); 3919 sm_conn->sm_cid = L2CAP_CID_SECURITY_MANAGER_PROTOCOL; 3920 3921 // track our addr used for this connection and set state 3922 #ifdef ENABLE_LE_PERIPHERAL 3923 if (gap_subevent_le_connection_complete_get_role(packet) != 0){ 3924 // responder - use own address from advertisements 3925 gap_le_get_own_advertisements_address(&sm_conn->sm_own_addr_type, sm_conn->sm_own_address); 3926 sm_conn->sm_engine_state = SM_RESPONDER_IDLE; 3927 } 3928 #endif 3929 #ifdef ENABLE_LE_CENTRAL 3930 if (gap_subevent_le_connection_complete_get_role(packet) == 0){ 3931 // initiator - use own address from create connection 3932 gap_le_get_own_connection_address(&sm_conn->sm_own_addr_type, sm_conn->sm_own_address); 3933 sm_conn->sm_engine_state = SM_INITIATOR_CONNECTED; 3934 } 3935 #endif 3936 break; 3937 default: 3938 break; 3939 } 3940 break; 3941 case HCI_EVENT_LE_META: 3942 switch (hci_event_le_meta_get_subevent_code(packet)) { 3943 case HCI_SUBEVENT_LE_LONG_TERM_KEY_REQUEST: 3944 con_handle = hci_subevent_le_long_term_key_request_get_connection_handle(packet); 3945 sm_conn = sm_get_connection_for_handle(con_handle); 3946 if (!sm_conn) break; 3947 3948 log_info("LTK Request: state %u", sm_conn->sm_engine_state); 3949 if (sm_conn->sm_engine_state == SM_RESPONDER_PH2_W4_LTK_REQUEST){ 3950 sm_conn->sm_engine_state = SM_PH2_CALC_STK; 3951 break; 3952 } 3953 if (sm_conn->sm_engine_state == SM_SC_W4_LTK_REQUEST_SC){ 3954 // PH2 SEND LTK as we need to exchange keys in PH3 3955 sm_conn->sm_engine_state = SM_RESPONDER_PH2_SEND_LTK_REPLY; 3956 break; 3957 } 3958 3959 // store rand and ediv 3960 reverse_64(&packet[5], sm_conn->sm_local_rand); 3961 sm_conn->sm_local_ediv = hci_subevent_le_long_term_key_request_get_encryption_diversifier(packet); 3962 3963 // For Legacy Pairing (<=> EDIV != 0 || RAND != NULL), we need to recalculated our LTK as a 3964 // potentially stored LTK is from the master 3965 if ((sm_conn->sm_local_ediv != 0u) || !sm_is_null_random(sm_conn->sm_local_rand)){ 3966 if (sm_reconstruct_ltk_without_le_device_db_entry){ 3967 sm_conn->sm_engine_state = SM_RESPONDER_PH0_RECEIVED_LTK_REQUEST; 3968 break; 3969 } 3970 // additionally check if remote is in LE Device DB if requested 3971 switch(sm_conn->sm_irk_lookup_state){ 3972 case IRK_LOOKUP_FAILED: 3973 log_info("LTK Request: device not in device db"); 3974 sm_conn->sm_engine_state = SM_RESPONDER_PH0_SEND_LTK_REQUESTED_NEGATIVE_REPLY; 3975 break; 3976 case IRK_LOOKUP_SUCCEEDED: 3977 sm_conn->sm_engine_state = SM_RESPONDER_PH0_RECEIVED_LTK_REQUEST; 3978 break; 3979 default: 3980 // wait for irk look doen 3981 sm_conn->sm_engine_state = SM_RESPONDER_PH0_RECEIVED_LTK_W4_IRK; 3982 break; 3983 } 3984 break; 3985 } 3986 3987 #ifdef ENABLE_LE_SECURE_CONNECTIONS 3988 sm_conn->sm_engine_state = SM_SC_RECEIVED_LTK_REQUEST; 3989 #else 3990 log_info("LTK Request: ediv & random are empty, but LE Secure Connections not supported"); 3991 sm_conn->sm_engine_state = SM_RESPONDER_PH0_SEND_LTK_REQUESTED_NEGATIVE_REPLY; 3992 #endif 3993 break; 3994 3995 default: 3996 break; 3997 } 3998 break; 3999 4000 case HCI_EVENT_ENCRYPTION_CHANGE: 4001 case HCI_EVENT_ENCRYPTION_CHANGE_V2: 4002 con_handle = hci_event_encryption_change_get_connection_handle(packet); 4003 sm_conn = sm_get_connection_for_handle(con_handle); 4004 if (!sm_conn) break; 4005 4006 sm_conn->sm_connection_encrypted = hci_event_encryption_change_get_encryption_enabled(packet); 4007 log_info("Encryption state change: %u, key size %u", sm_conn->sm_connection_encrypted, 4008 sm_conn->sm_actual_encryption_key_size); 4009 log_info("event handler, state %u", sm_conn->sm_engine_state); 4010 4011 switch (sm_conn->sm_engine_state){ 4012 4013 case SM_PH4_W4_CONNECTION_ENCRYPTED: 4014 // encryption change event concludes re-encryption for bonded devices (even if it fails) 4015 if (sm_conn->sm_connection_encrypted) { 4016 status = ERROR_CODE_SUCCESS; 4017 if (sm_conn->sm_role){ 4018 sm_conn->sm_engine_state = SM_RESPONDER_IDLE; 4019 } else { 4020 sm_conn->sm_engine_state = SM_INITIATOR_CONNECTED; 4021 } 4022 } else { 4023 status = hci_event_encryption_change_get_status(packet); 4024 // set state to 'RE-ENCRYPTION FAILED' to allow pairing but prevent other interactions 4025 // also, gap_reconnect_security_setup_active will return true 4026 sm_conn->sm_engine_state = SM_GENERAL_REENCRYPTION_FAILED; 4027 } 4028 4029 // emit re-encryption complete 4030 sm_reencryption_complete(sm_conn, status); 4031 4032 // notify client, if pairing was requested before 4033 if (sm_conn->sm_pairing_requested){ 4034 sm_conn->sm_pairing_requested = 0; 4035 sm_pairing_complete(sm_conn, status, 0); 4036 } 4037 4038 sm_done_for_handle(sm_conn->sm_handle); 4039 break; 4040 4041 case SM_PH2_W4_CONNECTION_ENCRYPTED: 4042 if (!sm_conn->sm_connection_encrypted) break; 4043 // handler for HCI_EVENT_ENCRYPTION_KEY_REFRESH_COMPLETE 4044 // contains the same code for this state 4045 sm_conn->sm_connection_sc = setup->sm_use_secure_connections; 4046 if (IS_RESPONDER(sm_conn->sm_role)){ 4047 // slave 4048 if (sm_conn->sm_connection_sc){ 4049 sm_conn->sm_engine_state = SM_PH3_DISTRIBUTE_KEYS; 4050 } else { 4051 btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph3_random, (void *)(uintptr_t) sm_conn->sm_handle); 4052 } 4053 } else { 4054 // master 4055 if (sm_key_distribution_all_received()){ 4056 // skip receiving keys as there are none 4057 sm_key_distribution_handle_all_received(sm_conn); 4058 btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph3_random, (void *)(uintptr_t) sm_conn->sm_handle); 4059 } else { 4060 sm_conn->sm_engine_state = SM_PH3_RECEIVE_KEYS; 4061 } 4062 } 4063 break; 4064 4065 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 4066 case SM_BR_EDR_W4_ENCRYPTION_COMPLETE: 4067 sm_event_handle_classic_encryption_event(sm_conn, con_handle); 4068 break; 4069 #endif 4070 default: 4071 break; 4072 } 4073 break; 4074 4075 case HCI_EVENT_ENCRYPTION_KEY_REFRESH_COMPLETE: 4076 con_handle = little_endian_read_16(packet, 3); 4077 sm_conn = sm_get_connection_for_handle(con_handle); 4078 if (!sm_conn) break; 4079 4080 log_info("Encryption key refresh complete, key size %u", sm_conn->sm_actual_encryption_key_size); 4081 log_info("event handler, state %u", sm_conn->sm_engine_state); 4082 // continue if part of initial pairing 4083 switch (sm_conn->sm_engine_state){ 4084 case SM_PH4_W4_CONNECTION_ENCRYPTED: 4085 if (sm_conn->sm_role){ 4086 sm_conn->sm_engine_state = SM_RESPONDER_IDLE; 4087 } else { 4088 sm_conn->sm_engine_state = SM_INITIATOR_CONNECTED; 4089 } 4090 sm_done_for_handle(sm_conn->sm_handle); 4091 break; 4092 case SM_PH2_W4_CONNECTION_ENCRYPTED: 4093 // handler for HCI_EVENT_ENCRYPTION_CHANGE 4094 // contains the same code for this state 4095 sm_conn->sm_connection_sc = setup->sm_use_secure_connections; 4096 if (IS_RESPONDER(sm_conn->sm_role)){ 4097 // slave 4098 if (sm_conn->sm_connection_sc){ 4099 sm_conn->sm_engine_state = SM_PH3_DISTRIBUTE_KEYS; 4100 } else { 4101 btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph3_random, (void *)(uintptr_t) sm_conn->sm_handle); 4102 } 4103 } else { 4104 // master 4105 if (sm_key_distribution_all_received()){ 4106 // skip receiving keys as there are none 4107 sm_key_distribution_handle_all_received(sm_conn); 4108 btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph3_random, (void *)(uintptr_t) sm_conn->sm_handle); 4109 } else { 4110 sm_conn->sm_engine_state = SM_PH3_RECEIVE_KEYS; 4111 } 4112 } 4113 break; 4114 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 4115 case SM_BR_EDR_W4_ENCRYPTION_COMPLETE: 4116 sm_event_handle_classic_encryption_event(sm_conn, con_handle); 4117 break; 4118 #endif 4119 default: 4120 break; 4121 } 4122 break; 4123 4124 4125 case HCI_EVENT_DISCONNECTION_COMPLETE: 4126 con_handle = little_endian_read_16(packet, 3); 4127 sm_done_for_handle(con_handle); 4128 sm_conn = sm_get_connection_for_handle(con_handle); 4129 if (!sm_conn) break; 4130 4131 // pairing failed, if it was ongoing 4132 switch (sm_conn->sm_engine_state){ 4133 case SM_GENERAL_IDLE: 4134 case SM_INITIATOR_CONNECTED: 4135 case SM_RESPONDER_IDLE: 4136 break; 4137 default: 4138 sm_reencryption_complete(sm_conn, ERROR_CODE_REMOTE_USER_TERMINATED_CONNECTION); 4139 sm_pairing_complete(sm_conn, ERROR_CODE_REMOTE_USER_TERMINATED_CONNECTION, 0); 4140 break; 4141 } 4142 4143 sm_conn->sm_engine_state = SM_GENERAL_IDLE; 4144 sm_conn->sm_handle = 0; 4145 break; 4146 4147 case HCI_EVENT_COMMAND_COMPLETE: 4148 if (hci_event_command_complete_get_command_opcode(packet) == HCI_OPCODE_HCI_READ_BD_ADDR) { 4149 // set local addr for le device db 4150 reverse_bd_addr(&packet[OFFSET_OF_DATA_IN_COMMAND_COMPLETE + 1], addr); 4151 le_device_db_set_local_bd_addr(addr); 4152 } 4153 break; 4154 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 4155 case L2CAP_EVENT_INFORMATION_RESPONSE: 4156 con_handle = l2cap_event_information_response_get_con_handle(packet); 4157 sm_conn = sm_get_connection_for_handle(con_handle); 4158 if (!sm_conn) break; 4159 if (sm_conn->sm_engine_state == SM_BR_EDR_INITIATOR_W4_FIXED_CHANNEL_MASK){ 4160 // check if remote supports SMP over BR/EDR 4161 const hci_connection_t * hci_connection = hci_connection_for_handle(con_handle); 4162 if ((hci_connection->l2cap_state.fixed_channels_supported & (1 << L2CAP_CID_BR_EDR_SECURITY_MANAGER)) != 0){ 4163 sm_conn->sm_engine_state = SM_BR_EDR_INITIATOR_SEND_PAIRING_REQUEST; 4164 } else { 4165 sm_conn->sm_engine_state = SM_INITIATOR_CONNECTED; 4166 hci_dedicated_bonding_defer_disconnect(con_handle, false); 4167 } 4168 } 4169 break; 4170 #endif 4171 default: 4172 break; 4173 } 4174 break; 4175 default: 4176 break; 4177 } 4178 4179 sm_run(); 4180 } 4181 4182 static inline int sm_calc_actual_encryption_key_size(int other){ 4183 if (other < sm_min_encryption_key_size) return 0; 4184 if (other < sm_max_encryption_key_size) return other; 4185 return sm_max_encryption_key_size; 4186 } 4187 4188 4189 #ifdef ENABLE_LE_SECURE_CONNECTIONS 4190 static int sm_just_works_or_numeric_comparison(stk_generation_method_t method){ 4191 switch (method){ 4192 case JUST_WORKS: 4193 case NUMERIC_COMPARISON: 4194 return 1; 4195 default: 4196 return 0; 4197 } 4198 } 4199 // responder 4200 4201 static int sm_passkey_used(stk_generation_method_t method){ 4202 switch (method){ 4203 case PK_RESP_INPUT: 4204 return 1; 4205 default: 4206 return 0; 4207 } 4208 } 4209 4210 static int sm_passkey_entry(stk_generation_method_t method){ 4211 switch (method){ 4212 case PK_RESP_INPUT: 4213 case PK_INIT_INPUT: 4214 case PK_BOTH_INPUT: 4215 return 1; 4216 default: 4217 return 0; 4218 } 4219 } 4220 4221 #endif 4222 4223 /** 4224 * @return ok 4225 */ 4226 static int sm_validate_stk_generation_method(void){ 4227 // check if STK generation method is acceptable by client 4228 switch (setup->sm_stk_generation_method){ 4229 case JUST_WORKS: 4230 return (sm_accepted_stk_generation_methods & SM_STK_GENERATION_METHOD_JUST_WORKS) != 0u; 4231 case PK_RESP_INPUT: 4232 case PK_INIT_INPUT: 4233 case PK_BOTH_INPUT: 4234 return (sm_accepted_stk_generation_methods & SM_STK_GENERATION_METHOD_PASSKEY) != 0u; 4235 case OOB: 4236 return (sm_accepted_stk_generation_methods & SM_STK_GENERATION_METHOD_OOB) != 0u; 4237 case NUMERIC_COMPARISON: 4238 return (sm_accepted_stk_generation_methods & SM_STK_GENERATION_METHOD_NUMERIC_COMPARISON) != 0u; 4239 default: 4240 return 0; 4241 } 4242 } 4243 4244 #ifdef ENABLE_LE_CENTRAL 4245 static void sm_initiator_connected_handle_security_request(sm_connection_t * sm_conn, const uint8_t *packet){ 4246 #ifdef ENABLE_LE_SECURE_CONNECTIONS 4247 if (sm_sc_only_mode){ 4248 uint8_t auth_req = packet[1]; 4249 if ((auth_req & SM_AUTHREQ_SECURE_CONNECTION) == 0){ 4250 sm_pairing_error(sm_conn, SM_REASON_AUTHENTHICATION_REQUIREMENTS); 4251 return; 4252 } 4253 } 4254 #else 4255 UNUSED(packet); 4256 #endif 4257 4258 int have_ltk; 4259 uint8_t ltk[16]; 4260 4261 // IRK complete? 4262 switch (sm_conn->sm_irk_lookup_state){ 4263 case IRK_LOOKUP_FAILED: 4264 // start pairing 4265 sm_conn->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST; 4266 break; 4267 case IRK_LOOKUP_SUCCEEDED: 4268 le_device_db_encryption_get(sm_conn->sm_le_db_index, NULL, NULL, ltk, NULL, NULL, NULL, NULL); 4269 have_ltk = !sm_is_null_key(ltk); 4270 log_info("central: security request - have_ltk %u, encryption %u", have_ltk, sm_conn->sm_connection_encrypted); 4271 if (have_ltk && (sm_conn->sm_connection_encrypted == 0)){ 4272 // start re-encrypt if we have LTK and the connection is not already encrypted 4273 sm_conn->sm_engine_state = SM_INITIATOR_PH4_HAS_LTK; 4274 } else { 4275 // start pairing 4276 sm_conn->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST; 4277 } 4278 break; 4279 default: 4280 // otherwise, store security request 4281 sm_conn->sm_security_request_received = 1; 4282 break; 4283 } 4284 } 4285 #endif 4286 4287 static uint8_t sm_pdu_validate_and_get_opcode(uint8_t packet_type, const uint8_t *packet, uint16_t size){ 4288 4289 // size of complete sm_pdu used to validate input 4290 static const uint8_t sm_pdu_size[] = { 4291 0, // 0x00 invalid opcode 4292 7, // 0x01 pairing request 4293 7, // 0x02 pairing response 4294 17, // 0x03 pairing confirm 4295 17, // 0x04 pairing random 4296 2, // 0x05 pairing failed 4297 17, // 0x06 encryption information 4298 11, // 0x07 master identification 4299 17, // 0x08 identification information 4300 8, // 0x09 identify address information 4301 17, // 0x0a signing information 4302 2, // 0x0b security request 4303 65, // 0x0c pairing public key 4304 17, // 0x0d pairing dhk check 4305 2, // 0x0e keypress notification 4306 }; 4307 4308 if (packet_type != SM_DATA_PACKET) return 0; 4309 if (size == 0u) return 0; 4310 4311 uint8_t sm_pdu_code = packet[0]; 4312 4313 // validate pdu size 4314 if (sm_pdu_code >= sizeof(sm_pdu_size)) return 0; 4315 if (sm_pdu_size[sm_pdu_code] != size) return 0; 4316 4317 return sm_pdu_code; 4318 } 4319 4320 static void sm_pdu_handler(uint8_t packet_type, hci_con_handle_t con_handle, uint8_t *packet, uint16_t size){ 4321 4322 if ((packet_type == HCI_EVENT_PACKET) && (packet[0] == L2CAP_EVENT_CAN_SEND_NOW)){ 4323 sm_run(); 4324 } 4325 4326 uint8_t sm_pdu_code = sm_pdu_validate_and_get_opcode(packet_type, packet, size); 4327 if (sm_pdu_code == 0) return; 4328 4329 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 4330 if (!sm_conn) return; 4331 4332 if (sm_pdu_code == SM_CODE_PAIRING_FAILED){ 4333 sm_reencryption_complete(sm_conn, ERROR_CODE_AUTHENTICATION_FAILURE); 4334 sm_pairing_complete(sm_conn, ERROR_CODE_AUTHENTICATION_FAILURE, packet[1]); 4335 sm_done_for_handle(con_handle); 4336 sm_conn->sm_engine_state = sm_conn->sm_role ? SM_RESPONDER_IDLE : SM_INITIATOR_CONNECTED; 4337 return; 4338 } 4339 4340 log_debug("sm_pdu_handler: state %u, pdu 0x%02x", sm_conn->sm_engine_state, sm_pdu_code); 4341 4342 int err; 4343 UNUSED(err); 4344 4345 if (sm_pdu_code == SM_CODE_KEYPRESS_NOTIFICATION){ 4346 uint8_t buffer[5]; 4347 buffer[0] = SM_EVENT_KEYPRESS_NOTIFICATION; 4348 buffer[1] = 3; 4349 little_endian_store_16(buffer, 2, con_handle); 4350 buffer[4] = packet[1]; 4351 sm_dispatch_event(HCI_EVENT_PACKET, 0, buffer, sizeof(buffer)); 4352 return; 4353 } 4354 4355 switch (sm_conn->sm_engine_state){ 4356 4357 // a sm timeout requires a new physical connection 4358 case SM_GENERAL_TIMEOUT: 4359 return; 4360 4361 #ifdef ENABLE_LE_CENTRAL 4362 4363 // Initiator 4364 case SM_INITIATOR_CONNECTED: 4365 if ((sm_pdu_code != SM_CODE_SECURITY_REQUEST) || (sm_conn->sm_role)){ 4366 sm_pdu_received_in_wrong_state(sm_conn); 4367 break; 4368 } 4369 sm_initiator_connected_handle_security_request(sm_conn, packet); 4370 break; 4371 4372 case SM_INITIATOR_PH1_W4_PAIRING_RESPONSE: 4373 // Core 5, Vol 3, Part H, 2.4.6: 4374 // "The master shall ignore the slave’s Security Request if the master has sent a Pairing Request 4375 // without receiving a Pairing Response from the slave or if the master has initiated encryption mode setup." 4376 if (sm_pdu_code == SM_CODE_SECURITY_REQUEST){ 4377 log_info("Ignoring Security Request"); 4378 break; 4379 } 4380 4381 // all other pdus are incorrect 4382 if (sm_pdu_code != SM_CODE_PAIRING_RESPONSE){ 4383 sm_pdu_received_in_wrong_state(sm_conn); 4384 break; 4385 } 4386 4387 // store pairing request 4388 (void)memcpy(&setup->sm_s_pres, packet, 4389 sizeof(sm_pairing_packet_t)); 4390 err = sm_stk_generation_init(sm_conn); 4391 4392 #ifdef ENABLE_TESTING_SUPPORT 4393 if (0 < test_pairing_failure && test_pairing_failure < SM_REASON_DHKEY_CHECK_FAILED){ 4394 log_info("testing_support: abort with pairing failure %u", test_pairing_failure); 4395 err = test_pairing_failure; 4396 } 4397 #endif 4398 4399 if (err != 0){ 4400 sm_pairing_error(sm_conn, err); 4401 break; 4402 } 4403 4404 // generate random number first, if we need to show passkey 4405 if (setup->sm_stk_generation_method == PK_RESP_INPUT){ 4406 btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph2_tk, (void *)(uintptr_t) sm_conn->sm_handle); 4407 break; 4408 } 4409 4410 #ifdef ENABLE_LE_SECURE_CONNECTIONS 4411 if (setup->sm_use_secure_connections){ 4412 // SC Numeric Comparison will trigger user response after public keys & nonces have been exchanged 4413 if (setup->sm_stk_generation_method == JUST_WORKS){ 4414 sm_conn->sm_engine_state = SM_PH1_W4_USER_RESPONSE; 4415 sm_trigger_user_response(sm_conn); 4416 if (setup->sm_user_response == SM_USER_RESPONSE_IDLE){ 4417 sm_conn->sm_engine_state = SM_SC_SEND_PUBLIC_KEY_COMMAND; 4418 } 4419 } else { 4420 sm_conn->sm_engine_state = SM_SC_SEND_PUBLIC_KEY_COMMAND; 4421 } 4422 break; 4423 } 4424 #endif 4425 sm_conn->sm_engine_state = SM_PH1_W4_USER_RESPONSE; 4426 sm_trigger_user_response(sm_conn); 4427 // response_idle == nothing <--> sm_trigger_user_response() did not require response 4428 if (setup->sm_user_response == SM_USER_RESPONSE_IDLE){ 4429 btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_random, 16, &sm_handle_random_result_ph2_random, (void *)(uintptr_t) sm_conn->sm_handle); 4430 } 4431 break; 4432 4433 case SM_INITIATOR_PH2_W4_PAIRING_CONFIRM: 4434 if (sm_pdu_code != SM_CODE_PAIRING_CONFIRM){ 4435 sm_pdu_received_in_wrong_state(sm_conn); 4436 break; 4437 } 4438 4439 // store s_confirm 4440 reverse_128(&packet[1], setup->sm_peer_confirm); 4441 4442 // abort if s_confirm matches m_confirm 4443 if (memcmp(setup->sm_local_confirm, setup->sm_peer_confirm, 16) == 0){ 4444 sm_pdu_received_in_wrong_state(sm_conn); 4445 break; 4446 } 4447 4448 #ifdef ENABLE_TESTING_SUPPORT 4449 if (test_pairing_failure == SM_REASON_CONFIRM_VALUE_FAILED){ 4450 log_info("testing_support: reset confirm value"); 4451 memset(setup->sm_peer_confirm, 0, 16); 4452 } 4453 #endif 4454 sm_conn->sm_engine_state = SM_PH2_SEND_PAIRING_RANDOM; 4455 break; 4456 4457 case SM_INITIATOR_PH2_W4_PAIRING_RANDOM: 4458 if (sm_pdu_code != SM_CODE_PAIRING_RANDOM){ 4459 sm_pdu_received_in_wrong_state(sm_conn); 4460 break;; 4461 } 4462 4463 // received random value 4464 reverse_128(&packet[1], setup->sm_peer_random); 4465 sm_conn->sm_engine_state = SM_PH2_C1_GET_ENC_C; 4466 break; 4467 4468 case SM_PH4_W4_CONNECTION_ENCRYPTED: 4469 // ignore Security Request, see SM_INITIATOR_PH1_W4_PAIRING_RESPONSE above 4470 if (sm_pdu_code != SM_CODE_SECURITY_REQUEST){ 4471 sm_pdu_received_in_wrong_state(sm_conn); 4472 } 4473 break; 4474 #endif 4475 4476 #ifdef ENABLE_LE_PERIPHERAL 4477 // Responder 4478 case SM_RESPONDER_IDLE: 4479 case SM_RESPONDER_SEND_SECURITY_REQUEST: 4480 case SM_RESPONDER_PH1_W4_PAIRING_REQUEST: 4481 if (sm_pdu_code != SM_CODE_PAIRING_REQUEST){ 4482 sm_pdu_received_in_wrong_state(sm_conn); 4483 break;; 4484 } 4485 4486 // store pairing request 4487 (void)memcpy(&sm_conn->sm_m_preq, packet, sizeof(sm_pairing_packet_t)); 4488 4489 // check if IRK completed 4490 switch (sm_conn->sm_irk_lookup_state){ 4491 case IRK_LOOKUP_SUCCEEDED: 4492 case IRK_LOOKUP_FAILED: 4493 sm_conn->sm_engine_state = SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED; 4494 break; 4495 default: 4496 sm_conn->sm_engine_state = SM_RESPONDER_PH1_PAIRING_REQUEST_RECEIVED_W4_IRK; 4497 break; 4498 } 4499 break; 4500 #endif 4501 4502 #ifdef ENABLE_LE_SECURE_CONNECTIONS 4503 case SM_SC_W4_PUBLIC_KEY_COMMAND: 4504 if (sm_pdu_code != SM_CODE_PAIRING_PUBLIC_KEY){ 4505 sm_pdu_received_in_wrong_state(sm_conn); 4506 break; 4507 } 4508 4509 // store public key for DH Key calculation 4510 reverse_256(&packet[01], &setup->sm_peer_q[0]); 4511 reverse_256(&packet[33], &setup->sm_peer_q[32]); 4512 4513 // CVE-2020-26558: abort pairing if remote uses the same public key 4514 if (memcmp(&setup->sm_peer_q, ec_q, 64) == 0){ 4515 log_info("Remote PK matches ours"); 4516 sm_pairing_error(sm_conn, SM_REASON_DHKEY_CHECK_FAILED); 4517 break; 4518 } 4519 4520 // validate public key 4521 err = btstack_crypto_ecc_p256_validate_public_key(setup->sm_peer_q); 4522 if (err != 0){ 4523 log_info("sm: peer public key invalid %x", err); 4524 sm_pairing_error(sm_conn, SM_REASON_DHKEY_CHECK_FAILED); 4525 break; 4526 } 4527 4528 // start calculating dhkey 4529 btstack_crypto_ecc_p256_calculate_dhkey(&sm_crypto_ecc_p256_request, setup->sm_peer_q, setup->sm_dhkey, sm_sc_dhkey_calculated, (void*)(uintptr_t) sm_conn->sm_handle); 4530 4531 4532 log_info("public key received, generation method %u", setup->sm_stk_generation_method); 4533 if (IS_RESPONDER(sm_conn->sm_role)){ 4534 // responder 4535 sm_conn->sm_engine_state = SM_SC_SEND_PUBLIC_KEY_COMMAND; 4536 } else { 4537 // initiator 4538 // stk generation method 4539 // passkey entry: notify app to show passkey or to request passkey 4540 switch (setup->sm_stk_generation_method){ 4541 case JUST_WORKS: 4542 case NUMERIC_COMPARISON: 4543 sm_conn->sm_engine_state = SM_SC_W4_CONFIRMATION; 4544 break; 4545 case PK_RESP_INPUT: 4546 sm_sc_start_calculating_local_confirm(sm_conn); 4547 break; 4548 case PK_INIT_INPUT: 4549 case PK_BOTH_INPUT: 4550 if (setup->sm_user_response != SM_USER_RESPONSE_PASSKEY){ 4551 sm_conn->sm_engine_state = SM_SC_W4_USER_RESPONSE; 4552 break; 4553 } 4554 sm_sc_start_calculating_local_confirm(sm_conn); 4555 break; 4556 case OOB: 4557 // generate Nx 4558 log_info("Generate Na"); 4559 btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_nonce, 16, &sm_handle_random_result_sc_next_send_pairing_random, (void*)(uintptr_t) sm_conn->sm_handle); 4560 break; 4561 default: 4562 btstack_assert(false); 4563 break; 4564 } 4565 } 4566 break; 4567 4568 case SM_SC_W4_CONFIRMATION: 4569 if (sm_pdu_code != SM_CODE_PAIRING_CONFIRM){ 4570 sm_pdu_received_in_wrong_state(sm_conn); 4571 break; 4572 } 4573 // received confirm value 4574 reverse_128(&packet[1], setup->sm_peer_confirm); 4575 4576 #ifdef ENABLE_TESTING_SUPPORT 4577 if (test_pairing_failure == SM_REASON_CONFIRM_VALUE_FAILED){ 4578 log_info("testing_support: reset confirm value"); 4579 memset(setup->sm_peer_confirm, 0, 16); 4580 } 4581 #endif 4582 if (IS_RESPONDER(sm_conn->sm_role)){ 4583 // responder 4584 if (sm_passkey_used(setup->sm_stk_generation_method)){ 4585 if (setup->sm_user_response != SM_USER_RESPONSE_PASSKEY){ 4586 // still waiting for passkey 4587 sm_conn->sm_engine_state = SM_SC_W4_USER_RESPONSE; 4588 break; 4589 } 4590 } 4591 sm_sc_start_calculating_local_confirm(sm_conn); 4592 } else { 4593 // initiator 4594 if (sm_just_works_or_numeric_comparison(setup->sm_stk_generation_method)){ 4595 btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_nonce, 16, &sm_handle_random_result_sc_next_send_pairing_random, (void*)(uintptr_t) sm_conn->sm_handle); 4596 } else { 4597 sm_conn->sm_engine_state = SM_SC_SEND_PAIRING_RANDOM; 4598 } 4599 } 4600 break; 4601 4602 case SM_SC_W4_PAIRING_RANDOM: 4603 if (sm_pdu_code != SM_CODE_PAIRING_RANDOM){ 4604 sm_pdu_received_in_wrong_state(sm_conn); 4605 break; 4606 } 4607 4608 // received random value 4609 reverse_128(&packet[1], setup->sm_peer_nonce); 4610 4611 // validate confirm value if Cb = f4(Pkb, Pka, Nb, z) 4612 // only check for JUST WORK/NC in initiator role OR passkey entry 4613 log_info("SM_SC_W4_PAIRING_RANDOM, responder: %u, just works: %u, passkey used %u, passkey entry %u", 4614 IS_RESPONDER(sm_conn->sm_role), sm_just_works_or_numeric_comparison(setup->sm_stk_generation_method), 4615 sm_passkey_used(setup->sm_stk_generation_method), sm_passkey_entry(setup->sm_stk_generation_method)); 4616 if ( (!IS_RESPONDER(sm_conn->sm_role) && sm_just_works_or_numeric_comparison(setup->sm_stk_generation_method)) 4617 || (sm_passkey_entry(setup->sm_stk_generation_method)) ) { 4618 sm_conn->sm_engine_state = SM_SC_W2_CMAC_FOR_CHECK_CONFIRMATION; 4619 break; 4620 } 4621 4622 // OOB 4623 if (setup->sm_stk_generation_method == OOB){ 4624 4625 // setup local random, set to zero if remote did not receive our data 4626 log_info("Received nonce, setup local random ra/rb for dhkey check"); 4627 if (IS_RESPONDER(sm_conn->sm_role)){ 4628 if (sm_pairing_packet_get_oob_data_flag(setup->sm_m_preq) == 0u){ 4629 log_info("Reset rb as A does not have OOB data"); 4630 memset(setup->sm_rb, 0, 16); 4631 } else { 4632 (void)memcpy(setup->sm_rb, sm_sc_oob_random, 16); 4633 log_info("Use stored rb"); 4634 log_info_hexdump(setup->sm_rb, 16); 4635 } 4636 } else { 4637 if (sm_pairing_packet_get_oob_data_flag(setup->sm_s_pres) == 0u){ 4638 log_info("Reset ra as B does not have OOB data"); 4639 memset(setup->sm_ra, 0, 16); 4640 } else { 4641 (void)memcpy(setup->sm_ra, sm_sc_oob_random, 16); 4642 log_info("Use stored ra"); 4643 log_info_hexdump(setup->sm_ra, 16); 4644 } 4645 } 4646 4647 // validate confirm value if Cb = f4(PKb, Pkb, rb, 0) for OOB if data received 4648 if (setup->sm_have_oob_data){ 4649 sm_conn->sm_engine_state = SM_SC_W2_CMAC_FOR_CHECK_CONFIRMATION; 4650 break; 4651 } 4652 } 4653 4654 // TODO: we only get here for Responder role with JW/NC 4655 sm_sc_state_after_receiving_random(sm_conn); 4656 break; 4657 4658 case SM_SC_W2_CALCULATE_G2: 4659 case SM_SC_W4_CALCULATE_G2: 4660 case SM_SC_W4_CALCULATE_DHKEY: 4661 case SM_SC_W2_CALCULATE_F5_SALT: 4662 case SM_SC_W4_CALCULATE_F5_SALT: 4663 case SM_SC_W2_CALCULATE_F5_MACKEY: 4664 case SM_SC_W4_CALCULATE_F5_MACKEY: 4665 case SM_SC_W2_CALCULATE_F5_LTK: 4666 case SM_SC_W4_CALCULATE_F5_LTK: 4667 case SM_SC_W2_CALCULATE_F6_FOR_DHKEY_CHECK: 4668 case SM_SC_W4_DHKEY_CHECK_COMMAND: 4669 case SM_SC_W4_CALCULATE_F6_FOR_DHKEY_CHECK: 4670 case SM_SC_W4_USER_RESPONSE: 4671 if (sm_pdu_code != SM_CODE_PAIRING_DHKEY_CHECK){ 4672 sm_pdu_received_in_wrong_state(sm_conn); 4673 break; 4674 } 4675 // store DHKey Check 4676 setup->sm_state_vars |= SM_STATE_VAR_DHKEY_COMMAND_RECEIVED; 4677 reverse_128(&packet[01], setup->sm_peer_dhkey_check); 4678 4679 // have we been only waiting for dhkey check command? 4680 if (sm_conn->sm_engine_state == SM_SC_W4_DHKEY_CHECK_COMMAND){ 4681 sm_conn->sm_engine_state = SM_SC_W2_CALCULATE_F6_TO_VERIFY_DHKEY_CHECK; 4682 } 4683 break; 4684 #endif 4685 4686 #ifdef ENABLE_LE_PERIPHERAL 4687 case SM_RESPONDER_PH1_W4_PAIRING_CONFIRM: 4688 if (sm_pdu_code != SM_CODE_PAIRING_CONFIRM){ 4689 sm_pdu_received_in_wrong_state(sm_conn); 4690 break; 4691 } 4692 4693 // received confirm value 4694 reverse_128(&packet[1], setup->sm_peer_confirm); 4695 4696 #ifdef ENABLE_TESTING_SUPPORT 4697 if (test_pairing_failure == SM_REASON_CONFIRM_VALUE_FAILED){ 4698 log_info("testing_support: reset confirm value"); 4699 memset(setup->sm_peer_confirm, 0, 16); 4700 } 4701 #endif 4702 // notify client to hide shown passkey 4703 if (setup->sm_stk_generation_method == PK_INIT_INPUT){ 4704 sm_notify_client_base(SM_EVENT_PASSKEY_DISPLAY_CANCEL, sm_conn->sm_handle, sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address); 4705 } 4706 4707 // handle user cancel pairing? 4708 if (setup->sm_user_response == SM_USER_RESPONSE_DECLINE){ 4709 sm_pairing_error(sm_conn, SM_REASON_PASSKEY_ENTRY_FAILED); 4710 break; 4711 } 4712 4713 // wait for user action? 4714 if (setup->sm_user_response == SM_USER_RESPONSE_PENDING){ 4715 sm_conn->sm_engine_state = SM_PH1_W4_USER_RESPONSE; 4716 break; 4717 } 4718 4719 // calculate and send local_confirm 4720 btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_random, 16, &sm_handle_random_result_ph2_random, (void *)(uintptr_t) sm_conn->sm_handle); 4721 break; 4722 4723 case SM_RESPONDER_PH2_W4_PAIRING_RANDOM: 4724 if (sm_pdu_code != SM_CODE_PAIRING_RANDOM){ 4725 sm_pdu_received_in_wrong_state(sm_conn); 4726 break;; 4727 } 4728 4729 // received random value 4730 reverse_128(&packet[1], setup->sm_peer_random); 4731 sm_conn->sm_engine_state = SM_PH2_C1_GET_ENC_C; 4732 break; 4733 #endif 4734 4735 case SM_PH2_W4_CONNECTION_ENCRYPTED: 4736 case SM_PH3_RECEIVE_KEYS: 4737 switch(sm_pdu_code){ 4738 case SM_CODE_ENCRYPTION_INFORMATION: 4739 setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_ENCRYPTION_INFORMATION; 4740 reverse_128(&packet[1], setup->sm_peer_ltk); 4741 break; 4742 4743 case SM_CODE_MASTER_IDENTIFICATION: 4744 setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_MASTER_IDENTIFICATION; 4745 setup->sm_peer_ediv = little_endian_read_16(packet, 1); 4746 reverse_64(&packet[3], setup->sm_peer_rand); 4747 break; 4748 4749 case SM_CODE_IDENTITY_INFORMATION: 4750 setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_IDENTITY_INFORMATION; 4751 reverse_128(&packet[1], setup->sm_peer_irk); 4752 break; 4753 4754 case SM_CODE_IDENTITY_ADDRESS_INFORMATION: 4755 setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION; 4756 setup->sm_peer_addr_type = packet[1]; 4757 reverse_bd_addr(&packet[2], setup->sm_peer_address); 4758 break; 4759 4760 case SM_CODE_SIGNING_INFORMATION: 4761 setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION; 4762 reverse_128(&packet[1], setup->sm_peer_csrk); 4763 break; 4764 default: 4765 // Unexpected PDU 4766 log_info("Unexpected PDU %u in SM_PH3_RECEIVE_KEYS", packet[0]); 4767 break; 4768 } 4769 // done with key distribution? 4770 if (sm_key_distribution_all_received()){ 4771 4772 sm_key_distribution_handle_all_received(sm_conn); 4773 4774 if (IS_RESPONDER(sm_conn->sm_role)){ 4775 sm_key_distribution_complete_responder(sm_conn); 4776 } else { 4777 if (setup->sm_use_secure_connections){ 4778 sm_conn->sm_engine_state = SM_PH3_DISTRIBUTE_KEYS; 4779 } else { 4780 btstack_crypto_random_generate(&sm_crypto_random_request, sm_random_data, 8, &sm_handle_random_result_ph3_random, (void *)(uintptr_t) sm_conn->sm_handle); 4781 } 4782 } 4783 } 4784 break; 4785 4786 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 4787 4788 case SM_BR_EDR_W4_ENCRYPTION_COMPLETE: 4789 // GAP/DM/LEP/BI-02-C - reject CTKD if P-192 encryption is used 4790 if (sm_pdu_code == SM_CODE_PAIRING_REQUEST){ 4791 sm_pairing_error(sm_conn, SM_REASON_CROSS_TRANSPORT_KEY_DERIVATION_NOT_ALLOWED); 4792 } 4793 break; 4794 4795 case SM_BR_EDR_INITIATOR_W4_PAIRING_RESPONSE: 4796 4797 // dedicated bonding complete 4798 hci_dedicated_bonding_defer_disconnect(sm_conn->sm_handle, false); 4799 4800 if (sm_pdu_code != SM_CODE_PAIRING_RESPONSE){ 4801 sm_pdu_received_in_wrong_state(sm_conn); 4802 break; 4803 } 4804 // store pairing response 4805 (void)memcpy(&setup->sm_s_pres, packet, sizeof(sm_pairing_packet_t)); 4806 4807 // validate encryption key size 4808 sm_conn->sm_actual_encryption_key_size = sm_calc_actual_encryption_key_size(sm_pairing_packet_get_max_encryption_key_size(setup->sm_s_pres)); 4809 // SC Only mandates 128 bit key size 4810 if (sm_sc_only_mode && (sm_conn->sm_actual_encryption_key_size < 16)) { 4811 sm_conn->sm_actual_encryption_key_size = 0; 4812 } 4813 if (sm_conn->sm_actual_encryption_key_size == 0){ 4814 sm_pairing_error(sm_conn, SM_REASON_ENCRYPTION_KEY_SIZE); 4815 break; 4816 } 4817 4818 // prepare key exchange, LTK is derived locally 4819 sm_setup_key_distribution(sm_pairing_packet_get_initiator_key_distribution(setup->sm_s_pres) & ~SM_KEYDIST_ENC_KEY, 4820 sm_pairing_packet_get_responder_key_distribution(setup->sm_s_pres) & ~SM_KEYDIST_ENC_KEY); 4821 4822 // skip receive if there are none 4823 if (sm_key_distribution_all_received()){ 4824 // distribute keys in run handles 'no keys to send' 4825 sm_conn->sm_engine_state = SM_BR_EDR_DISTRIBUTE_KEYS; 4826 } else { 4827 sm_conn->sm_engine_state = SM_BR_EDR_RECEIVE_KEYS; 4828 } 4829 break; 4830 4831 case SM_BR_EDR_RESPONDER_W4_PAIRING_REQUEST: 4832 if (sm_pdu_code != SM_CODE_PAIRING_REQUEST){ 4833 sm_pdu_received_in_wrong_state(sm_conn); 4834 break; 4835 } 4836 // store pairing request 4837 (void)memcpy(&sm_conn->sm_m_preq, packet, sizeof(sm_pairing_packet_t)); 4838 // validate encryption key size 4839 sm_conn->sm_actual_encryption_key_size = sm_calc_actual_encryption_key_size(sm_pairing_packet_get_max_encryption_key_size(sm_conn->sm_m_preq)); 4840 // SC Only mandates 128 bit key size 4841 if (sm_sc_only_mode && (sm_conn->sm_actual_encryption_key_size < 16)) { 4842 sm_conn->sm_actual_encryption_key_size = 0; 4843 } 4844 if (sm_conn->sm_actual_encryption_key_size == 0){ 4845 sm_pairing_error(sm_conn, SM_REASON_ENCRYPTION_KEY_SIZE); 4846 break; 4847 } 4848 // trigger response 4849 if (sm_ctkd_from_classic(sm_conn)){ 4850 sm_conn->sm_engine_state = SM_BR_EDR_RESPONDER_PAIRING_REQUEST_RECEIVED; 4851 } else { 4852 sm_pairing_error(sm_conn, SM_REASON_CROSS_TRANSPORT_KEY_DERIVATION_NOT_ALLOWED); 4853 } 4854 break; 4855 4856 case SM_BR_EDR_RECEIVE_KEYS: 4857 switch(sm_pdu_code){ 4858 case SM_CODE_IDENTITY_INFORMATION: 4859 setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_IDENTITY_INFORMATION; 4860 reverse_128(&packet[1], setup->sm_peer_irk); 4861 break; 4862 case SM_CODE_IDENTITY_ADDRESS_INFORMATION: 4863 setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_IDENTITY_ADDRESS_INFORMATION; 4864 setup->sm_peer_addr_type = packet[1]; 4865 reverse_bd_addr(&packet[2], setup->sm_peer_address); 4866 break; 4867 case SM_CODE_SIGNING_INFORMATION: 4868 setup->sm_key_distribution_received_set |= SM_KEYDIST_FLAG_SIGNING_IDENTIFICATION; 4869 reverse_128(&packet[1], setup->sm_peer_csrk); 4870 break; 4871 default: 4872 // Unexpected PDU 4873 log_info("Unexpected PDU %u in SM_PH3_RECEIVE_KEYS", packet[0]); 4874 break; 4875 } 4876 4877 // all keys received 4878 if (sm_key_distribution_all_received()){ 4879 if (IS_RESPONDER(sm_conn->sm_role)){ 4880 // responder -> keys exchanged, derive LE LTK 4881 sm_ctkd_start_from_br_edr(sm_conn); 4882 } else { 4883 // initiator -> send our keys if any 4884 sm_conn->sm_engine_state = SM_BR_EDR_DISTRIBUTE_KEYS; 4885 } 4886 } 4887 break; 4888 #endif 4889 4890 default: 4891 // Unexpected PDU 4892 log_info("Unexpected PDU %u in state %u", packet[0], sm_conn->sm_engine_state); 4893 sm_pdu_received_in_wrong_state(sm_conn); 4894 break; 4895 } 4896 4897 // try to send next pdu 4898 sm_trigger_run(); 4899 } 4900 4901 // Security Manager Client API 4902 void sm_register_oob_data_callback( int (*get_oob_data_callback)(uint8_t address_type, bd_addr_t addr, uint8_t * oob_data)){ 4903 sm_get_oob_data = get_oob_data_callback; 4904 } 4905 4906 void sm_register_sc_oob_data_callback( int (*get_sc_oob_data_callback)(uint8_t address_type, bd_addr_t addr, uint8_t * oob_sc_peer_confirm, uint8_t * oob_sc_peer_random)){ 4907 sm_get_sc_oob_data = get_sc_oob_data_callback; 4908 } 4909 4910 void sm_register_ltk_callback( bool (*get_ltk_callback)(hci_con_handle_t con_handle, uint8_t address_type, bd_addr_t addr, uint8_t * ltk)){ 4911 sm_get_ltk_callback = get_ltk_callback; 4912 } 4913 4914 void sm_add_event_handler(btstack_packet_callback_registration_t * callback_handler){ 4915 btstack_linked_list_add_tail(&sm_event_handlers, (btstack_linked_item_t*) callback_handler); 4916 } 4917 4918 void sm_remove_event_handler(btstack_packet_callback_registration_t * callback_handler){ 4919 btstack_linked_list_remove(&sm_event_handlers, (btstack_linked_item_t*) callback_handler); 4920 } 4921 4922 void sm_set_accepted_stk_generation_methods(uint8_t accepted_stk_generation_methods){ 4923 sm_accepted_stk_generation_methods = accepted_stk_generation_methods; 4924 } 4925 4926 void sm_set_encryption_key_size_range(uint8_t min_size, uint8_t max_size){ 4927 sm_min_encryption_key_size = min_size; 4928 sm_max_encryption_key_size = max_size; 4929 } 4930 4931 void sm_set_authentication_requirements(uint8_t auth_req){ 4932 #ifndef ENABLE_LE_SECURE_CONNECTIONS 4933 if (auth_req & SM_AUTHREQ_SECURE_CONNECTION){ 4934 log_error("ENABLE_LE_SECURE_CONNECTIONS not defined, but requested by app. Dropping SC flag"); 4935 auth_req &= ~SM_AUTHREQ_SECURE_CONNECTION; 4936 } 4937 #endif 4938 sm_auth_req = auth_req; 4939 } 4940 4941 void sm_set_io_capabilities(io_capability_t io_capability){ 4942 sm_io_capabilities = io_capability; 4943 } 4944 4945 #ifdef ENABLE_LE_PERIPHERAL 4946 void sm_set_request_security(int enable){ 4947 sm_slave_request_security = enable; 4948 } 4949 #endif 4950 4951 void sm_set_er(sm_key_t er){ 4952 (void)memcpy(sm_persistent_er, er, 16); 4953 } 4954 4955 void sm_set_ir(sm_key_t ir){ 4956 (void)memcpy(sm_persistent_ir, ir, 16); 4957 } 4958 4959 // Testing support only 4960 void sm_test_set_irk(sm_key_t irk){ 4961 (void)memcpy(sm_persistent_irk, irk, 16); 4962 dkg_state = DKG_CALC_DHK; 4963 test_use_fixed_local_irk = true; 4964 } 4965 4966 void sm_test_use_fixed_local_csrk(void){ 4967 test_use_fixed_local_csrk = true; 4968 } 4969 4970 #ifdef ENABLE_LE_SECURE_CONNECTIONS 4971 static void sm_ec_generated(void * arg){ 4972 UNUSED(arg); 4973 ec_key_generation_state = EC_KEY_GENERATION_DONE; 4974 // trigger pairing if pending for ec key 4975 sm_trigger_run(); 4976 } 4977 static void sm_ec_generate_new_key(void) { 4978 log_info("sm: generate new ec key"); 4979 #ifdef ENABLE_LE_SECURE_CONNECTIONS_DEBUG_KEY 4980 // LE Secure Connections Debug Key 4981 const uint8_t debug_key_public[64] = { 4982 0x20, 0xb0, 0x03, 0xd2, 0xf2, 0x97, 0xbe, 0x2c, 0x5e, 0x2c, 0x83, 0xa7, 0xe9, 0xf9, 0xa5, 0xb9, 4983 0xef, 0xf4, 0x91, 0x11, 0xac, 0xf4, 0xfd, 0xdb, 0xcc, 0x03, 0x01, 0x48, 0x0e, 0x35, 0x9d, 0xe6, 4984 0xdc, 0x80, 0x9c, 0x49, 0x65, 0x2a, 0xeb, 0x6d, 0x63, 0x32, 0x9a, 0xbf, 0x5a, 0x52, 0x15, 0x5c, 4985 0x76, 0x63, 0x45, 0xc2, 0x8f, 0xed, 0x30, 0x24, 0x74, 0x1c, 0x8e, 0xd0, 0x15, 0x89, 0xd2, 0x8b 4986 }; 4987 const uint8_t debug_key_private[32] = { 4988 0x3f, 0x49, 0xf6, 0xd4, 0xa3, 0xc5, 0x5f, 0x38, 0x74, 0xc9, 0xb3, 0xe3, 0xd2, 0x10, 0x3f, 0x50, 4989 0x4a, 0xff, 0x60, 0x7b, 0xeb, 0x40, 0xb7, 0x99, 0x58, 0x99, 0xb8, 0xa6, 0xcd, 0x3c, 0x1a, 0xbd 4990 }; 4991 if (sm_sc_debug_keys_enabled) { 4992 memcpy(ec_q, debug_key_public, 64); 4993 btstack_crypto_ecc_p256_set_key(debug_key_public, debug_key_private); 4994 ec_key_generation_state = EC_KEY_GENERATION_DONE; 4995 } else 4996 #endif 4997 { 4998 ec_key_generation_state = EC_KEY_GENERATION_ACTIVE; 4999 btstack_crypto_ecc_p256_generate_key(&sm_crypto_ecc_p256_request, ec_q, &sm_ec_generated, NULL); 5000 } 5001 } 5002 #endif 5003 5004 #ifdef ENABLE_TESTING_SUPPORT 5005 void sm_test_set_pairing_failure(int reason){ 5006 test_pairing_failure = reason; 5007 } 5008 #endif 5009 5010 static void sm_state_reset(void) { 5011 #ifdef USE_CMAC_ENGINE 5012 sm_cmac_active = 0; 5013 #endif 5014 dkg_state = DKG_W4_WORKING; 5015 rau_state = RAU_IDLE; 5016 sm_aes128_state = SM_AES128_IDLE; 5017 sm_address_resolution_test = -1; // no private address to resolve yet 5018 sm_address_resolution_mode = ADDRESS_RESOLUTION_IDLE; 5019 sm_address_resolution_general_queue = NULL; 5020 sm_active_connection_handle = HCI_CON_HANDLE_INVALID; 5021 sm_persistent_keys_random_active = false; 5022 #ifdef ENABLE_LE_SECURE_CONNECTIONS 5023 ec_key_generation_state = EC_KEY_GENERATION_IDLE; 5024 #endif 5025 } 5026 5027 void sm_init(void){ 5028 5029 if (sm_initialized) return; 5030 5031 // set default ER and IR values (should be unique - set by app or sm later using TLV) 5032 sm_er_ir_set_default(); 5033 5034 // defaults 5035 sm_accepted_stk_generation_methods = SM_STK_GENERATION_METHOD_JUST_WORKS 5036 | SM_STK_GENERATION_METHOD_OOB 5037 | SM_STK_GENERATION_METHOD_PASSKEY 5038 | SM_STK_GENERATION_METHOD_NUMERIC_COMPARISON; 5039 5040 sm_max_encryption_key_size = 16; 5041 sm_min_encryption_key_size = 7; 5042 5043 sm_fixed_passkey_in_display_role = 0xffffffffU; 5044 sm_reconstruct_ltk_without_le_device_db_entry = true; 5045 5046 gap_random_adress_update_period = 15 * 60 * 1000L; 5047 5048 test_use_fixed_local_csrk = false; 5049 5050 // other 5051 btstack_run_loop_set_timer_handler(&sm_run_timer, &sm_run_timer_handler); 5052 5053 // register for HCI Events 5054 hci_event_callback_registration.callback = &sm_event_packet_handler; 5055 hci_add_event_handler(&hci_event_callback_registration); 5056 5057 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 5058 // register for L2CAP events 5059 l2cap_event_callback_registration.callback = &sm_event_packet_handler; 5060 l2cap_add_event_handler(&l2cap_event_callback_registration); 5061 #endif 5062 5063 // 5064 btstack_crypto_init(); 5065 5066 // init le_device_db 5067 le_device_db_init(); 5068 5069 // and L2CAP PDUs + L2CAP_EVENT_CAN_SEND_NOW 5070 l2cap_register_fixed_channel(sm_pdu_handler, L2CAP_CID_SECURITY_MANAGER_PROTOCOL); 5071 #ifdef ENABLE_CLASSIC 5072 l2cap_register_fixed_channel(sm_pdu_handler, L2CAP_CID_BR_EDR_SECURITY_MANAGER); 5073 #endif 5074 5075 // state 5076 sm_state_reset(); 5077 5078 sm_initialized = true; 5079 } 5080 5081 void sm_deinit(void){ 5082 sm_initialized = false; 5083 btstack_run_loop_remove_timer(&sm_run_timer); 5084 #if defined(ENABLE_LE_SECURE_CONNECTIONS) && defined (ENABLE_LE_SECURE_CONNECTION_DEBUG_KEY) 5085 sm_sc_debug_keys_enabled = false; 5086 #endif 5087 } 5088 5089 void sm_use_fixed_passkey_in_display_role(uint32_t passkey){ 5090 sm_fixed_passkey_in_display_role = passkey; 5091 } 5092 5093 void sm_allow_ltk_reconstruction_without_le_device_db_entry(int allow){ 5094 sm_reconstruct_ltk_without_le_device_db_entry = allow != 0; 5095 } 5096 5097 static sm_connection_t * sm_get_connection_for_handle(hci_con_handle_t con_handle){ 5098 hci_connection_t * hci_con = hci_connection_for_handle(con_handle); 5099 if (!hci_con) return NULL; 5100 return &hci_con->sm_connection; 5101 } 5102 5103 static void sm_cache_ltk(sm_connection_t * connection, const sm_key_t ltk){ 5104 hci_connection_t * hci_con = hci_connection_for_handle(connection->sm_handle); 5105 btstack_assert(hci_con != NULL); 5106 memcpy(hci_con->link_key, ltk, 16); 5107 hci_con->link_key_type = 1; 5108 } 5109 5110 #ifdef ENABLE_CROSS_TRANSPORT_KEY_DERIVATION 5111 static sm_connection_t * sm_get_connection_for_bd_addr_and_type(bd_addr_t address, bd_addr_type_t addr_type){ 5112 hci_connection_t * hci_con = hci_connection_for_bd_addr_and_type(address, addr_type); 5113 if (!hci_con) return NULL; 5114 return &hci_con->sm_connection; 5115 } 5116 #endif 5117 5118 // @deprecated: map onto sm_request_pairing 5119 void sm_send_security_request(hci_con_handle_t con_handle){ 5120 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5121 if (!sm_conn) return; 5122 if (!IS_RESPONDER(sm_conn->sm_role)) return; 5123 sm_request_pairing(con_handle); 5124 } 5125 5126 // request pairing 5127 void sm_request_pairing(hci_con_handle_t con_handle){ 5128 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5129 if (!sm_conn) return; // wrong connection 5130 5131 bool have_ltk; 5132 uint8_t ltk[16]; 5133 bool auth_required; 5134 int authenticated; 5135 bool trigger_reencryption; 5136 log_info("sm_request_pairing in role %u, state %u", sm_conn->sm_role, sm_conn->sm_engine_state); 5137 if (IS_RESPONDER(sm_conn->sm_role)){ 5138 switch (sm_conn->sm_engine_state){ 5139 case SM_GENERAL_IDLE: 5140 case SM_RESPONDER_IDLE: 5141 switch (sm_conn->sm_irk_lookup_state){ 5142 case IRK_LOOKUP_SUCCEEDED: 5143 le_device_db_encryption_get(sm_conn->sm_le_db_index, NULL, NULL, ltk, NULL, NULL, NULL, NULL); 5144 have_ltk = !sm_is_null_key(ltk); 5145 log_info("have ltk %u", have_ltk); 5146 if (have_ltk){ 5147 sm_conn->sm_pairing_requested = 1; 5148 sm_conn->sm_engine_state = SM_RESPONDER_SEND_SECURITY_REQUEST; 5149 sm_reencryption_started(sm_conn); 5150 break; 5151 } 5152 /* fall through */ 5153 5154 case IRK_LOOKUP_FAILED: 5155 sm_conn->sm_pairing_requested = 1; 5156 sm_conn->sm_engine_state = SM_RESPONDER_SEND_SECURITY_REQUEST; 5157 sm_pairing_started(sm_conn); 5158 break; 5159 default: 5160 log_info("irk lookup pending"); 5161 sm_conn->sm_pairing_requested = 1; 5162 break; 5163 } 5164 break; 5165 default: 5166 break; 5167 } 5168 } else { 5169 // used as a trigger to start central/master/initiator security procedures 5170 switch (sm_conn->sm_engine_state){ 5171 case SM_INITIATOR_CONNECTED: 5172 switch (sm_conn->sm_irk_lookup_state){ 5173 case IRK_LOOKUP_SUCCEEDED: 5174 le_device_db_encryption_get(sm_conn->sm_le_db_index, NULL, NULL, ltk, NULL, &authenticated, NULL, NULL); 5175 have_ltk = !sm_is_null_key(ltk); 5176 auth_required = sm_auth_req & SM_AUTHREQ_MITM_PROTECTION; 5177 // re-encrypt is sufficient if we have ltk and that is either already authenticated or we don't require authentication 5178 trigger_reencryption = have_ltk && ((authenticated != 0) || (auth_required == false)); 5179 log_info("have ltk %u, authenticated %u, auth required %u => reencrypt %u", have_ltk, authenticated, auth_required, trigger_reencryption); 5180 if (trigger_reencryption){ 5181 sm_conn->sm_pairing_requested = 1; 5182 sm_conn->sm_engine_state = SM_INITIATOR_PH4_HAS_LTK; 5183 break; 5184 } 5185 /* fall through */ 5186 5187 case IRK_LOOKUP_FAILED: 5188 sm_conn->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST; 5189 break; 5190 default: 5191 log_info("irk lookup pending"); 5192 sm_conn->sm_pairing_requested = 1; 5193 break; 5194 } 5195 break; 5196 case SM_GENERAL_REENCRYPTION_FAILED: 5197 sm_conn->sm_engine_state = SM_INITIATOR_PH1_W2_SEND_PAIRING_REQUEST; 5198 break; 5199 case SM_GENERAL_IDLE: 5200 sm_conn->sm_pairing_requested = 1; 5201 break; 5202 default: 5203 break; 5204 } 5205 } 5206 sm_trigger_run(); 5207 } 5208 5209 // called by client app on authorization request 5210 void sm_authorization_decline(hci_con_handle_t con_handle){ 5211 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5212 if (!sm_conn) return; // wrong connection 5213 sm_conn->sm_connection_authorization_state = AUTHORIZATION_DECLINED; 5214 sm_notify_client_status(SM_EVENT_AUTHORIZATION_RESULT, sm_conn->sm_handle, sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address, 0); 5215 } 5216 5217 void sm_authorization_grant(hci_con_handle_t con_handle){ 5218 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5219 if (!sm_conn) return; // wrong connection 5220 sm_conn->sm_connection_authorization_state = AUTHORIZATION_GRANTED; 5221 sm_notify_client_status(SM_EVENT_AUTHORIZATION_RESULT, sm_conn->sm_handle, sm_conn->sm_peer_addr_type, sm_conn->sm_peer_address, 1); 5222 } 5223 5224 // GAP Bonding API 5225 5226 void sm_bonding_decline(hci_con_handle_t con_handle){ 5227 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5228 if (!sm_conn) return; // wrong connection 5229 setup->sm_user_response = SM_USER_RESPONSE_DECLINE; 5230 log_info("decline, state %u", sm_conn->sm_engine_state); 5231 switch(sm_conn->sm_engine_state){ 5232 #ifdef ENABLE_LE_SECURE_CONNECTIONS 5233 case SM_SC_W4_USER_RESPONSE: 5234 case SM_SC_W4_CONFIRMATION: 5235 case SM_SC_W4_PUBLIC_KEY_COMMAND: 5236 #endif 5237 case SM_PH1_W4_USER_RESPONSE: 5238 switch (setup->sm_stk_generation_method){ 5239 case PK_RESP_INPUT: 5240 case PK_INIT_INPUT: 5241 case PK_BOTH_INPUT: 5242 sm_pairing_error(sm_conn, SM_REASON_PASSKEY_ENTRY_FAILED); 5243 break; 5244 case NUMERIC_COMPARISON: 5245 sm_pairing_error(sm_conn, SM_REASON_NUMERIC_COMPARISON_FAILED); 5246 break; 5247 case JUST_WORKS: 5248 case OOB: 5249 sm_pairing_error(sm_conn, SM_REASON_UNSPECIFIED_REASON); 5250 break; 5251 default: 5252 btstack_assert(false); 5253 break; 5254 } 5255 break; 5256 default: 5257 break; 5258 } 5259 sm_trigger_run(); 5260 } 5261 5262 void sm_just_works_confirm(hci_con_handle_t con_handle){ 5263 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5264 if (!sm_conn) return; // wrong connection 5265 setup->sm_user_response = SM_USER_RESPONSE_CONFIRM; 5266 if (sm_conn->sm_engine_state == SM_PH1_W4_USER_RESPONSE){ 5267 if (setup->sm_use_secure_connections){ 5268 sm_conn->sm_engine_state = SM_SC_SEND_PUBLIC_KEY_COMMAND; 5269 } else { 5270 btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_random, 16, &sm_handle_random_result_ph2_random, (void *)(uintptr_t) sm_conn->sm_handle); 5271 } 5272 } 5273 5274 #ifdef ENABLE_LE_SECURE_CONNECTIONS 5275 if (sm_conn->sm_engine_state == SM_SC_W4_USER_RESPONSE){ 5276 sm_sc_prepare_dhkey_check(sm_conn); 5277 } 5278 #endif 5279 5280 sm_trigger_run(); 5281 } 5282 5283 void sm_numeric_comparison_confirm(hci_con_handle_t con_handle){ 5284 // for now, it's the same 5285 sm_just_works_confirm(con_handle); 5286 } 5287 5288 void sm_passkey_input(hci_con_handle_t con_handle, uint32_t passkey){ 5289 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5290 if (!sm_conn) return; // wrong connection 5291 sm_reset_tk(); 5292 big_endian_store_32(setup->sm_tk, 12, passkey); 5293 setup->sm_user_response = SM_USER_RESPONSE_PASSKEY; 5294 if (sm_conn->sm_engine_state == SM_PH1_W4_USER_RESPONSE){ 5295 btstack_crypto_random_generate(&sm_crypto_random_request, setup->sm_local_random, 16, &sm_handle_random_result_ph2_random, (void *)(uintptr_t) sm_conn->sm_handle); 5296 } 5297 #ifdef ENABLE_LE_SECURE_CONNECTIONS 5298 (void)memcpy(setup->sm_ra, setup->sm_tk, 16); 5299 (void)memcpy(setup->sm_rb, setup->sm_tk, 16); 5300 if (sm_conn->sm_engine_state == SM_SC_W4_USER_RESPONSE){ 5301 sm_sc_start_calculating_local_confirm(sm_conn); 5302 } 5303 #endif 5304 sm_trigger_run(); 5305 } 5306 5307 void sm_keypress_notification(hci_con_handle_t con_handle, uint8_t action){ 5308 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5309 if (!sm_conn) return; // wrong connection 5310 if (action > SM_KEYPRESS_PASSKEY_ENTRY_COMPLETED) return; 5311 uint8_t num_actions = setup->sm_keypress_notification >> 5; 5312 uint8_t flags = setup->sm_keypress_notification & 0x1fu; 5313 switch (action){ 5314 case SM_KEYPRESS_PASSKEY_ENTRY_STARTED: 5315 case SM_KEYPRESS_PASSKEY_ENTRY_COMPLETED: 5316 flags |= (1u << action); 5317 break; 5318 case SM_KEYPRESS_PASSKEY_CLEARED: 5319 // clear counter, keypress & erased flags + set passkey cleared 5320 flags = (flags & 0x19u) | (1u << SM_KEYPRESS_PASSKEY_CLEARED); 5321 break; 5322 case SM_KEYPRESS_PASSKEY_DIGIT_ENTERED: 5323 if (flags & (1u << SM_KEYPRESS_PASSKEY_DIGIT_ERASED)){ 5324 // erase actions queued 5325 num_actions--; 5326 if (num_actions == 0u){ 5327 // clear counter, keypress & erased flags 5328 flags &= 0x19u; 5329 } 5330 break; 5331 } 5332 num_actions++; 5333 flags |= (1u << SM_KEYPRESS_PASSKEY_DIGIT_ENTERED); 5334 break; 5335 case SM_KEYPRESS_PASSKEY_DIGIT_ERASED: 5336 if (flags & (1u << SM_KEYPRESS_PASSKEY_DIGIT_ENTERED)){ 5337 // enter actions queued 5338 num_actions--; 5339 if (num_actions == 0u){ 5340 // clear counter, keypress & erased flags 5341 flags &= 0x19u; 5342 } 5343 break; 5344 } 5345 num_actions++; 5346 flags |= (1u << SM_KEYPRESS_PASSKEY_DIGIT_ERASED); 5347 break; 5348 default: 5349 break; 5350 } 5351 setup->sm_keypress_notification = (num_actions << 5) | flags; 5352 sm_trigger_run(); 5353 } 5354 5355 #ifdef ENABLE_LE_SECURE_CONNECTIONS 5356 static void sm_handle_random_result_oob(void * arg){ 5357 UNUSED(arg); 5358 sm_sc_oob_state = SM_SC_OOB_W2_CALC_CONFIRM; 5359 sm_trigger_run(); 5360 } 5361 uint8_t sm_generate_sc_oob_data(void (*callback)(const uint8_t * confirm_value, const uint8_t * random_value)){ 5362 5363 static btstack_crypto_random_t sm_crypto_random_oob_request; 5364 5365 if (sm_sc_oob_state != SM_SC_OOB_IDLE) return ERROR_CODE_COMMAND_DISALLOWED; 5366 sm_sc_oob_callback = callback; 5367 sm_sc_oob_state = SM_SC_OOB_W4_RANDOM; 5368 btstack_crypto_random_generate(&sm_crypto_random_oob_request, sm_sc_oob_random, 16, &sm_handle_random_result_oob, NULL); 5369 return 0; 5370 } 5371 #endif 5372 5373 /** 5374 * @brief Get Identity Resolving state 5375 * @param con_handle 5376 * @return irk_lookup_state_t 5377 */ 5378 irk_lookup_state_t sm_identity_resolving_state(hci_con_handle_t con_handle){ 5379 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5380 if (!sm_conn) return IRK_LOOKUP_IDLE; 5381 return sm_conn->sm_irk_lookup_state; 5382 } 5383 5384 /** 5385 * @brief Identify device in LE Device DB 5386 * @param handle 5387 * @return index from le_device_db or -1 if not found/identified 5388 */ 5389 int sm_le_device_index(hci_con_handle_t con_handle ){ 5390 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5391 if (!sm_conn) return -1; 5392 return sm_conn->sm_le_db_index; 5393 } 5394 5395 uint8_t sm_get_ltk(hci_con_handle_t con_handle, sm_key_t ltk){ 5396 hci_connection_t * hci_connection = hci_connection_for_handle(con_handle); 5397 if (hci_connection == NULL){ 5398 return ERROR_CODE_UNKNOWN_CONNECTION_IDENTIFIER; 5399 } 5400 if (hci_connection->link_key_type == 0){ 5401 return ERROR_CODE_PIN_OR_KEY_MISSING; 5402 } 5403 memcpy(ltk, hci_connection->link_key, 16); 5404 return ERROR_CODE_SUCCESS; 5405 } 5406 5407 static int gap_random_address_type_requires_updates(void){ 5408 switch (gap_random_adress_type){ 5409 case GAP_RANDOM_ADDRESS_TYPE_OFF: 5410 case GAP_RANDOM_ADDRESS_TYPE_STATIC: 5411 return 0; 5412 default: 5413 return 1; 5414 } 5415 } 5416 5417 static uint8_t own_address_type(void){ 5418 switch (gap_random_adress_type){ 5419 case GAP_RANDOM_ADDRESS_TYPE_OFF: 5420 return BD_ADDR_TYPE_LE_PUBLIC; 5421 default: 5422 return BD_ADDR_TYPE_LE_RANDOM; 5423 } 5424 } 5425 5426 // GAP LE API 5427 void gap_random_address_set_mode(gap_random_address_type_t random_address_type){ 5428 gap_random_address_update_stop(); 5429 gap_random_adress_type = random_address_type; 5430 hci_le_set_own_address_type(own_address_type()); 5431 if (!gap_random_address_type_requires_updates()) return; 5432 gap_random_address_update_start(); 5433 gap_random_address_trigger(); 5434 } 5435 5436 gap_random_address_type_t gap_random_address_get_mode(void){ 5437 return gap_random_adress_type; 5438 } 5439 5440 void gap_random_address_set_update_period(int period_ms){ 5441 gap_random_adress_update_period = period_ms; 5442 if (!gap_random_address_type_requires_updates()) return; 5443 gap_random_address_update_stop(); 5444 gap_random_address_update_start(); 5445 } 5446 5447 void gap_random_address_set(const bd_addr_t addr){ 5448 gap_random_address_set_mode(GAP_RANDOM_ADDRESS_TYPE_STATIC); 5449 (void)memcpy(sm_random_address, addr, 6); 5450 // assert msb bits are set to '11' 5451 sm_random_address[0] |= 0xc0; 5452 hci_le_random_address_set(sm_random_address); 5453 } 5454 5455 #ifdef ENABLE_LE_PERIPHERAL 5456 /* 5457 * @brief Set Advertisement Paramters 5458 * @param adv_int_min 5459 * @param adv_int_max 5460 * @param adv_type 5461 * @param direct_address_type 5462 * @param direct_address 5463 * @param channel_map 5464 * @param filter_policy 5465 * 5466 * @note own_address_type is used from gap_random_address_set_mode 5467 */ 5468 void gap_advertisements_set_params(uint16_t adv_int_min, uint16_t adv_int_max, uint8_t adv_type, 5469 uint8_t direct_address_typ, bd_addr_t direct_address, uint8_t channel_map, uint8_t filter_policy){ 5470 hci_le_advertisements_set_params(adv_int_min, adv_int_max, adv_type, 5471 direct_address_typ, direct_address, channel_map, filter_policy); 5472 } 5473 #endif 5474 5475 int gap_reconnect_security_setup_active(hci_con_handle_t con_handle){ 5476 sm_connection_t * sm_conn = sm_get_connection_for_handle(con_handle); 5477 // wrong connection 5478 if (!sm_conn) return 0; 5479 // already encrypted 5480 if (sm_conn->sm_connection_encrypted) return 0; 5481 // irk status? 5482 switch(sm_conn->sm_irk_lookup_state){ 5483 case IRK_LOOKUP_FAILED: 5484 // done, cannot setup encryption 5485 return 0; 5486 case IRK_LOOKUP_SUCCEEDED: 5487 break; 5488 default: 5489 // IR Lookup pending 5490 return 1; 5491 } 5492 // IRK Lookup Succeeded, re-encryption should be initiated. When done, state gets reset or indicates failure 5493 if (sm_conn->sm_engine_state == SM_GENERAL_REENCRYPTION_FAILED) return 0; 5494 if (sm_conn->sm_role){ 5495 return sm_conn->sm_engine_state != SM_RESPONDER_IDLE; 5496 } else { 5497 return sm_conn->sm_engine_state != SM_INITIATOR_CONNECTED; 5498 } 5499 } 5500 5501 void sm_set_secure_connections_only_mode(bool enable){ 5502 #ifdef ENABLE_LE_SECURE_CONNECTIONS 5503 sm_sc_only_mode = enable; 5504 #else 5505 // SC Only mode not possible without support for SC 5506 btstack_assert(enable == false); 5507 #endif 5508 } 5509 5510 #if defined(ENABLE_LE_SECURE_CONNECTIONS) && defined (ENABLE_LE_SECURE_CONNECTION_DEBUG_KEY) 5511 void sm_test_enable_secure_connections_debug_keys(void) { 5512 log_info("Enable LE Secure Connection Debug Keys for testing"); 5513 sm_sc_debug_keys_enabled = true; 5514 // set debug key 5515 sm_ec_generate_new_key(); 5516 } 5517 #endif 5518 5519 const uint8_t * gap_get_persistent_irk(void){ 5520 return sm_persistent_irk; 5521 } 5522 5523 void gap_delete_bonding(bd_addr_type_t address_type, bd_addr_t address){ 5524 int index = sm_le_device_db_index_lookup(address_type, address); 5525 if (index >= 0){ 5526 sm_remove_le_device_db_entry(index); 5527 } 5528 } 5529