1 /* 2 * Copyright (C) 2009-2012 by Matthias Ringwald 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 MATTHIAS RINGWALD 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 MATTHIAS 24 * RINGWALD 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 [email protected] 34 * 35 */ 36 37 /* 38 * hci.c 39 * 40 * Created by Matthias Ringwald on 4/29/09. 41 * 42 */ 43 44 #include "btstack-config.h" 45 46 #include "hci.h" 47 #include "gap.h" 48 49 #include <stdarg.h> 50 #include <string.h> 51 #include <stdio.h> 52 53 #ifndef EMBEDDED 54 #include <unistd.h> // gethostbyname 55 #include <btstack/version.h> 56 #endif 57 58 #include "btstack_memory.h" 59 #include "debug.h" 60 #include "hci_dump.h" 61 62 #include <btstack/hci_cmds.h> 63 64 #define HCI_CONNECTION_TIMEOUT_MS 10000 65 66 #define HCI_INTIALIZING_SUBSTATE_AFTER_SLEEP 11 67 68 #ifdef USE_BLUETOOL 69 #include "bt_control_iphone.h" 70 #endif 71 72 static void hci_update_scan_enable(void); 73 static gap_security_level_t gap_security_level_for_connection(hci_connection_t * connection); 74 static void hci_connection_timeout_handler(timer_source_t *timer); 75 static void hci_connection_timestamp(hci_connection_t *connection); 76 77 // the STACK is here 78 #ifndef HAVE_MALLOC 79 static hci_stack_t hci_stack_static; 80 #endif 81 static hci_stack_t * hci_stack = NULL; 82 83 // test helper 84 static uint8_t disable_l2cap_timeouts = 0; 85 86 /** 87 * create connection for given address 88 * 89 * @return connection OR NULL, if no memory left 90 */ 91 static hci_connection_t * create_connection_for_bd_addr_and_type(bd_addr_t addr, bd_addr_type_t addr_type){ 92 93 printf("create_connection_for_addr %s\n", bd_addr_to_str(addr)); 94 hci_connection_t * conn = (hci_connection_t *) btstack_memory_hci_connection_get(); 95 if (!conn) return NULL; 96 BD_ADDR_COPY(conn->address, addr); 97 conn->address_type = addr_type; 98 conn->con_handle = 0xffff; 99 conn->authentication_flags = AUTH_FLAGS_NONE; 100 conn->bonding_flags = 0; 101 conn->requested_security_level = LEVEL_0; 102 linked_item_set_user(&conn->timeout.item, conn); 103 conn->timeout.process = hci_connection_timeout_handler; 104 hci_connection_timestamp(conn); 105 conn->acl_recombination_length = 0; 106 conn->acl_recombination_pos = 0; 107 conn->num_acl_packets_sent = 0; 108 linked_list_add(&hci_stack->connections, (linked_item_t *) conn); 109 return conn; 110 } 111 112 /** 113 * get connection for a given handle 114 * 115 * @return connection OR NULL, if not found 116 */ 117 hci_connection_t * hci_connection_for_handle(hci_con_handle_t con_handle){ 118 linked_item_t *it; 119 for (it = (linked_item_t *) hci_stack->connections; it ; it = it->next){ 120 if ( ((hci_connection_t *) it)->con_handle == con_handle){ 121 return (hci_connection_t *) it; 122 } 123 } 124 return NULL; 125 } 126 127 /** 128 * get connection for given address 129 * 130 * @return connection OR NULL, if not found 131 */ 132 hci_connection_t * hci_connection_for_bd_addr_and_type(bd_addr_t * addr, bd_addr_type_t addr_type){ 133 linked_item_t *it; 134 for (it = (linked_item_t *) hci_stack->connections; it ; it = it->next){ 135 hci_connection_t * connection = (hci_connection_t *) it; 136 if (connection->address_type != addr_type) continue; 137 if (memcmp(addr, connection->address, 6) != 0) continue; 138 return connection; 139 } 140 return NULL; 141 } 142 143 static void hci_connection_timeout_handler(timer_source_t *timer){ 144 hci_connection_t * connection = (hci_connection_t *) linked_item_get_user(&timer->item); 145 #ifdef HAVE_TIME 146 struct timeval tv; 147 gettimeofday(&tv, NULL); 148 if (tv.tv_sec >= connection->timestamp.tv_sec + HCI_CONNECTION_TIMEOUT_MS/1000) { 149 // connections might be timed out 150 hci_emit_l2cap_check_timeout(connection); 151 } 152 #endif 153 #ifdef HAVE_TICK 154 if (embedded_get_ticks() > connection->timestamp + embedded_ticks_for_ms(HCI_CONNECTION_TIMEOUT_MS)){ 155 // connections might be timed out 156 hci_emit_l2cap_check_timeout(connection); 157 } 158 #endif 159 run_loop_set_timer(timer, HCI_CONNECTION_TIMEOUT_MS); 160 run_loop_add_timer(timer); 161 } 162 163 static void hci_connection_timestamp(hci_connection_t *connection){ 164 #ifdef HAVE_TIME 165 gettimeofday(&connection->timestamp, NULL); 166 #endif 167 #ifdef HAVE_TICK 168 connection->timestamp = embedded_get_ticks(); 169 #endif 170 } 171 172 173 inline static void connectionSetAuthenticationFlags(hci_connection_t * conn, hci_authentication_flags_t flags){ 174 conn->authentication_flags = (hci_authentication_flags_t)(conn->authentication_flags | flags); 175 } 176 177 inline static void connectionClearAuthenticationFlags(hci_connection_t * conn, hci_authentication_flags_t flags){ 178 conn->authentication_flags = (hci_authentication_flags_t)(conn->authentication_flags & ~flags); 179 } 180 181 182 /** 183 * add authentication flags and reset timer 184 * @note: assumes classic connection 185 */ 186 static void hci_add_connection_flags_for_flipped_bd_addr(uint8_t *bd_addr, hci_authentication_flags_t flags){ 187 bd_addr_t addr; 188 bt_flip_addr(addr, *(bd_addr_t *) bd_addr); 189 hci_connection_t * conn = hci_connection_for_bd_addr_and_type(&addr, BD_ADDR_TYPE_CLASSIC); 190 if (conn) { 191 connectionSetAuthenticationFlags(conn, flags); 192 hci_connection_timestamp(conn); 193 } 194 } 195 196 int hci_authentication_active_for_handle(hci_con_handle_t handle){ 197 hci_connection_t * conn = hci_connection_for_handle(handle); 198 if (!conn) return 0; 199 if (conn->authentication_flags & LEGACY_PAIRING_ACTIVE) return 1; 200 if (conn->authentication_flags & SSP_PAIRING_ACTIVE) return 1; 201 return 0; 202 } 203 204 void hci_drop_link_key_for_bd_addr(bd_addr_t *addr){ 205 if (hci_stack->remote_device_db) { 206 hci_stack->remote_device_db->delete_link_key(addr); 207 } 208 } 209 210 int hci_is_le_connection(hci_connection_t * connection){ 211 return connection->address_type == BD_ADDR_TYPE_LE_PUBLIC || 212 connection->address_type == BD_ADDR_TYPE_LE_RANDOM; 213 } 214 215 216 /** 217 * count connections 218 */ 219 static int nr_hci_connections(void){ 220 int count = 0; 221 linked_item_t *it; 222 for (it = (linked_item_t *) hci_stack->connections; it ; it = it->next, count++); 223 return count; 224 } 225 226 /** 227 * Dummy handler called by HCI 228 */ 229 static void dummy_handler(uint8_t packet_type, uint8_t *packet, uint16_t size){ 230 } 231 232 uint8_t hci_number_outgoing_packets(hci_con_handle_t handle){ 233 hci_connection_t * connection = hci_connection_for_handle(handle); 234 if (!connection) { 235 log_error("hci_number_outgoing_packets connectino for handle %u does not exist!\n", handle); 236 return 0; 237 } 238 return connection->num_acl_packets_sent; 239 } 240 241 uint8_t hci_number_free_acl_slots(){ 242 uint8_t free_slots = hci_stack->total_num_acl_packets; 243 linked_item_t *it; 244 for (it = (linked_item_t *) hci_stack->connections; it ; it = it->next){ 245 hci_connection_t * connection = (hci_connection_t *) it; 246 if (free_slots < connection->num_acl_packets_sent) { 247 log_error("hci_number_free_acl_slots: sum of outgoing packets > total acl packets!\n"); 248 return 0; 249 } 250 free_slots -= connection->num_acl_packets_sent; 251 } 252 return free_slots; 253 } 254 255 int hci_can_send_packet_now(uint8_t packet_type){ 256 257 // check for async hci transport implementations 258 if (hci_stack->hci_transport->can_send_packet_now){ 259 if (!hci_stack->hci_transport->can_send_packet_now(packet_type)){ 260 return 0; 261 } 262 } 263 264 // check regular Bluetooth flow control 265 switch (packet_type) { 266 case HCI_ACL_DATA_PACKET: 267 return hci_number_free_acl_slots(); 268 case HCI_COMMAND_DATA_PACKET: 269 return hci_stack->num_cmd_packets; 270 default: 271 return 0; 272 } 273 } 274 275 // same as hci_can_send_packet_now, but also checks if packet buffer is free for use 276 int hci_can_send_packet_now_using_packet_buffer(uint8_t packet_type){ 277 if (hci_stack->hci_packet_buffer_reserved) return 0; 278 return hci_can_send_packet_now(packet_type); 279 } 280 281 // used for internal checks in l2cap[-le].c 282 int hci_is_packet_buffer_reserved(void){ 283 return hci_stack->hci_packet_buffer_reserved; 284 } 285 286 // reserves outgoing packet buffer. @returns 1 if successful 287 int hci_reserve_packet_buffer(void){ 288 if (hci_stack->hci_packet_buffer_reserved) return 0; 289 hci_stack->hci_packet_buffer_reserved = 1; 290 return 1; 291 } 292 293 void hci_release_packet_buffer(void){ 294 hci_stack->hci_packet_buffer_reserved = 0; 295 } 296 297 // assumption: synchronous implementations don't provide can_send_packet_now as they don't keep the buffer after the call 298 int hci_transport_synchronous(void){ 299 return hci_stack->hci_transport->can_send_packet_now == NULL; 300 } 301 302 int hci_send_acl_packet(uint8_t *packet, int size){ 303 304 // check for free places on BT module 305 if (!hci_number_free_acl_slots()) return BTSTACK_ACL_BUFFERS_FULL; 306 307 hci_con_handle_t con_handle = READ_ACL_CONNECTION_HANDLE(packet); 308 hci_connection_t *connection = hci_connection_for_handle( con_handle); 309 if (!connection) return 0; 310 hci_connection_timestamp(connection); 311 312 // count packet 313 connection->num_acl_packets_sent++; 314 // log_info("hci_send_acl_packet - handle %u, sent %u\n", connection->con_handle, connection->num_acl_packets_sent); 315 316 // send packet 317 int err = hci_stack->hci_transport->send_packet(HCI_ACL_DATA_PACKET, packet, size); 318 319 // free packet buffer for synchronous transport implementations 320 if (hci_transport_synchronous() && (packet == hci_stack->hci_packet_buffer)){ 321 hci_stack->hci_packet_buffer_reserved = 0; 322 } 323 324 return err; 325 } 326 327 static void acl_handler(uint8_t *packet, int size){ 328 329 // log_info("acl_handler: size %u", size); 330 331 // get info 332 hci_con_handle_t con_handle = READ_ACL_CONNECTION_HANDLE(packet); 333 hci_connection_t *conn = hci_connection_for_handle(con_handle); 334 uint8_t acl_flags = READ_ACL_FLAGS(packet); 335 uint16_t acl_length = READ_ACL_LENGTH(packet); 336 337 // ignore non-registered handle 338 if (!conn){ 339 log_error( "hci.c: acl_handler called with non-registered handle %u!\n" , con_handle); 340 return; 341 } 342 343 // assert packet is complete 344 if (acl_length + 4 != size){ 345 log_error("hci.c: acl_handler called with ACL packet of wrong size %u, expected %u => dropping packet", size, acl_length + 4); 346 return; 347 } 348 349 // update idle timestamp 350 hci_connection_timestamp(conn); 351 352 // handle different packet types 353 switch (acl_flags & 0x03) { 354 355 case 0x01: // continuation fragment 356 357 // sanity check 358 if (conn->acl_recombination_pos == 0) { 359 log_error( "ACL Cont Fragment but no first fragment for handle 0x%02x\n", con_handle); 360 return; 361 } 362 363 // append fragment payload (header already stored) 364 memcpy(&conn->acl_recombination_buffer[conn->acl_recombination_pos], &packet[4], acl_length ); 365 conn->acl_recombination_pos += acl_length; 366 367 // log_error( "ACL Cont Fragment: acl_len %u, combined_len %u, l2cap_len %u\n", acl_length, 368 // conn->acl_recombination_pos, conn->acl_recombination_length); 369 370 // forward complete L2CAP packet if complete. 371 if (conn->acl_recombination_pos >= conn->acl_recombination_length + 4 + 4){ // pos already incl. ACL header 372 373 hci_stack->packet_handler(HCI_ACL_DATA_PACKET, conn->acl_recombination_buffer, conn->acl_recombination_pos); 374 // reset recombination buffer 375 conn->acl_recombination_length = 0; 376 conn->acl_recombination_pos = 0; 377 } 378 break; 379 380 case 0x02: { // first fragment 381 382 // sanity check 383 if (conn->acl_recombination_pos) { 384 log_error( "ACL First Fragment but data in buffer for handle 0x%02x\n", con_handle); 385 return; 386 } 387 388 // peek into L2CAP packet! 389 uint16_t l2cap_length = READ_L2CAP_LENGTH( packet ); 390 391 // log_info( "ACL First Fragment: acl_len %u, l2cap_len %u\n", acl_length, l2cap_length); 392 393 // compare fragment size to L2CAP packet size 394 if (acl_length >= l2cap_length + 4){ 395 396 // forward fragment as L2CAP packet 397 hci_stack->packet_handler(HCI_ACL_DATA_PACKET, packet, acl_length + 4); 398 399 } else { 400 // store first fragment and tweak acl length for complete package 401 memcpy(conn->acl_recombination_buffer, packet, acl_length + 4); 402 conn->acl_recombination_pos = acl_length + 4; 403 conn->acl_recombination_length = l2cap_length; 404 bt_store_16(conn->acl_recombination_buffer, 2, l2cap_length +4); 405 } 406 break; 407 408 } 409 default: 410 log_error( "hci.c: acl_handler called with invalid packet boundary flags %u\n", acl_flags & 0x03); 411 return; 412 } 413 414 // execute main loop 415 hci_run(); 416 } 417 418 static void hci_shutdown_connection(hci_connection_t *conn){ 419 log_info("Connection closed: handle %u, %s\n", conn->con_handle, bd_addr_to_str(conn->address)); 420 421 run_loop_remove_timer(&conn->timeout); 422 423 linked_list_remove(&hci_stack->connections, (linked_item_t *) conn); 424 btstack_memory_hci_connection_free( conn ); 425 426 // now it's gone 427 hci_emit_nr_connections_changed(); 428 } 429 430 static const uint16_t packet_type_sizes[] = { 431 0, HCI_ACL_2DH1_SIZE, HCI_ACL_3DH1_SIZE, HCI_ACL_DM1_SIZE, 432 HCI_ACL_DH1_SIZE, 0, 0, 0, 433 HCI_ACL_2DH3_SIZE, HCI_ACL_3DH3_SIZE, HCI_ACL_DM3_SIZE, HCI_ACL_DH3_SIZE, 434 HCI_ACL_2DH5_SIZE, HCI_ACL_3DH5_SIZE, HCI_ACL_DM5_SIZE, HCI_ACL_DH5_SIZE 435 }; 436 static const uint8_t packet_type_feature_requirement_bit[] = { 437 0, // 3 slot packets 438 1, // 5 slot packets 439 25, // EDR 2 mpbs 440 26, // EDR 3 mbps 441 39, // 3 slot EDR packts 442 40, // 5 slot EDR packet 443 }; 444 static const uint16_t packet_type_feature_packet_mask[] = { 445 0x0f00, // 3 slot packets 446 0xf000, // 5 slot packets 447 0x1102, // EDR 2 mpbs 448 0x2204, // EDR 3 mbps 449 0x0300, // 3 slot EDR packts 450 0x3000, // 5 slot EDR packet 451 }; 452 453 static uint16_t hci_acl_packet_types_for_buffer_size_and_local_features(uint16_t buffer_size, uint8_t * local_supported_features){ 454 // enable packet types based on size 455 uint16_t packet_types = 0; 456 int i; 457 for (i=0;i<16;i++){ 458 if (packet_type_sizes[i] == 0) continue; 459 if (packet_type_sizes[i] <= buffer_size){ 460 packet_types |= 1 << i; 461 } 462 } 463 // disable packet types due to missing local supported features 464 for (i=0;i<sizeof(packet_type_feature_requirement_bit);i++){ 465 int bit_idx = packet_type_feature_requirement_bit[i]; 466 int feature_set = (local_supported_features[bit_idx >> 3] & (1<<(bit_idx & 7))) != 0; 467 if (feature_set) continue; 468 log_info("Features bit %02u is not set, removing packet types 0x%04x", bit_idx, packet_type_feature_packet_mask[i]); 469 packet_types &= ~packet_type_feature_packet_mask[i]; 470 } 471 // flip bits for "may not be used" 472 packet_types ^= 0x3306; 473 return packet_types; 474 } 475 476 uint16_t hci_usable_acl_packet_types(void){ 477 return hci_stack->packet_types; 478 } 479 480 uint8_t* hci_get_outgoing_packet_buffer(void){ 481 // hci packet buffer is >= acl data packet length 482 return hci_stack->hci_packet_buffer; 483 } 484 485 uint16_t hci_max_acl_data_packet_length(void){ 486 return hci_stack->acl_data_packet_length; 487 } 488 489 int hci_non_flushable_packet_boundary_flag_supported(void){ 490 // No. 54, byte 6, bit 6 491 return (hci_stack->local_supported_features[6] & (1 << 6)) != 0; 492 } 493 494 int hci_ssp_supported(void){ 495 // No. 51, byte 6, bit 3 496 return (hci_stack->local_supported_features[6] & (1 << 3)) != 0; 497 } 498 499 int hci_classic_supported(void){ 500 // No. 37, byte 4, bit 5, = No BR/EDR Support 501 return (hci_stack->local_supported_features[4] & (1 << 5)) == 0; 502 } 503 504 int hci_le_supported(void){ 505 #ifdef HAVE_BLE 506 // No. 37, byte 4, bit 6 = LE Supported (Controller) 507 return (hci_stack->local_supported_features[4] & (1 << 6)) != 0; 508 #else 509 return 0; 510 #endif 511 } 512 513 // get addr type and address used in advertisement packets 514 void hci_le_advertisement_address(uint8_t * addr_type, bd_addr_t * addr){ 515 *addr_type = hci_stack->adv_addr_type; 516 if (hci_stack->adv_addr_type){ 517 memcpy(addr, hci_stack->adv_address, 6); 518 } else { 519 memcpy(addr, hci_stack->local_bd_addr, 6); 520 } 521 } 522 523 #ifdef HAVE_BLE 524 static void le_handle_advertisement_report(uint8_t *packet, int size){ 525 int num_reports = packet[3]; 526 int i; 527 int total_data_length = 0; 528 int data_offset = 0; 529 530 for (i=0; i<num_reports;i++){ 531 total_data_length += packet[4+num_reports*8+i]; 532 } 533 534 for (i=0; i<num_reports;i++){ 535 int pos = 0; 536 uint8_t data_length = packet[4+num_reports*8+i]; 537 uint8_t event_size = 10 + data_length; 538 uint8_t event[2 + event_size ]; 539 event[pos++] = GAP_LE_ADVERTISING_REPORT; 540 event[pos++] = event_size; 541 event[pos++] = packet[4+i]; // event_type; 542 event[pos++] = packet[4+num_reports+i]; // address_type; 543 memcpy(&event[pos], &packet[4+num_reports*2+i*6], 6); // bt address 544 pos += 6; 545 event[pos++] = packet[4+num_reports*9+total_data_length + i]; 546 event[pos++] = data_length; 547 memcpy(&event[pos], &packet[4+num_reports*9+data_offset], data_length); 548 data_offset += data_length; 549 pos += data_length; 550 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 551 } 552 } 553 #endif 554 555 // avoid huge local variables 556 #ifndef EMBEDDED 557 static device_name_t device_name; 558 #endif 559 static void event_handler(uint8_t *packet, int size){ 560 561 uint16_t event_length = packet[1]; 562 563 // assert packet is complete 564 if (size != event_length + 2){ 565 log_error("hci.c: event_handler called with event packet of wrong size %u, expected %u => dropping packet", size, event_length + 2); 566 return; 567 } 568 569 bd_addr_t addr; 570 bd_addr_type_t addr_type; 571 uint8_t link_type; 572 hci_con_handle_t handle; 573 hci_connection_t * conn; 574 int i; 575 576 // printf("HCI:EVENT:%02x\n", packet[0]); 577 578 switch (packet[0]) { 579 580 case HCI_EVENT_COMMAND_COMPLETE: 581 // get num cmd packets 582 // log_info("HCI_EVENT_COMMAND_COMPLETE cmds old %u - new %u\n", hci_stack->num_cmd_packets, packet[2]); 583 hci_stack->num_cmd_packets = packet[2]; 584 585 if (COMMAND_COMPLETE_EVENT(packet, hci_read_buffer_size)){ 586 // from offset 5 587 // status 588 // "The HC_ACL_Data_Packet_Length return parameter will be used to determine the size of the L2CAP segments contained in ACL Data Packets" 589 hci_stack->acl_data_packet_length = READ_BT_16(packet, 6); 590 // ignore: SCO data packet len (8) 591 hci_stack->total_num_acl_packets = packet[9]; 592 // ignore: total num SCO packets 593 if (hci_stack->state == HCI_STATE_INITIALIZING){ 594 // determine usable ACL payload size 595 if (HCI_ACL_PAYLOAD_SIZE < hci_stack->acl_data_packet_length){ 596 hci_stack->acl_data_packet_length = HCI_ACL_PAYLOAD_SIZE; 597 } 598 log_info("hci_read_buffer_size: used size %u, count %u\n", 599 hci_stack->acl_data_packet_length, hci_stack->total_num_acl_packets); 600 } 601 } 602 #ifdef HAVE_BLE 603 if (COMMAND_COMPLETE_EVENT(packet, hci_le_read_buffer_size)){ 604 hci_stack->le_data_packet_length = READ_BT_16(packet, 6); 605 hci_stack->total_num_le_packets = packet[8]; 606 log_info("hci_le_read_buffer_size: size %u, count %u\n", hci_stack->le_data_packet_length, hci_stack->total_num_le_packets); 607 608 // use LE buffers if no clasic buffers have been reported 609 if (hci_stack->total_num_acl_packets == 0){ 610 log_info("use le buffers instead of classic ones"); 611 hci_stack->total_num_acl_packets = hci_stack->total_num_le_packets; 612 hci_stack->acl_data_packet_length = hci_stack->le_data_packet_length; 613 // determine usable ACL payload size 614 if (HCI_ACL_PAYLOAD_SIZE < hci_stack->acl_data_packet_length){ 615 hci_stack->acl_data_packet_length = HCI_ACL_PAYLOAD_SIZE; 616 } 617 } 618 } 619 #endif 620 // Dump local address 621 if (COMMAND_COMPLETE_EVENT(packet, hci_read_bd_addr)) { 622 bt_flip_addr(hci_stack->local_bd_addr, &packet[OFFSET_OF_DATA_IN_COMMAND_COMPLETE + 1]); 623 log_info("Local Address, Status: 0x%02x: Addr: %s\n", 624 packet[OFFSET_OF_DATA_IN_COMMAND_COMPLETE], bd_addr_to_str(hci_stack->local_bd_addr)); 625 } 626 if (COMMAND_COMPLETE_EVENT(packet, hci_write_scan_enable)){ 627 hci_emit_discoverable_enabled(hci_stack->discoverable); 628 } 629 // Note: HCI init checks 630 if (COMMAND_COMPLETE_EVENT(packet, hci_read_local_supported_features)){ 631 memcpy(hci_stack->local_supported_features, &packet[OFFSET_OF_DATA_IN_COMMAND_COMPLETE+1], 8); 632 log_info("Local Supported Features: 0x%02x%02x%02x%02x%02x%02x%02x%02x", 633 hci_stack->local_supported_features[0], hci_stack->local_supported_features[1], 634 hci_stack->local_supported_features[2], hci_stack->local_supported_features[3], 635 hci_stack->local_supported_features[4], hci_stack->local_supported_features[5], 636 hci_stack->local_supported_features[6], hci_stack->local_supported_features[7]); 637 638 // determine usable ACL packet types based buffer size and supported features 639 hci_stack->packet_types = hci_acl_packet_types_for_buffer_size_and_local_features(hci_stack->acl_data_packet_length, &hci_stack->local_supported_features[0]); 640 log_info("packet types %04x", hci_stack->packet_types); 641 642 // Classic/LE 643 log_info("BR/EDR support %u, LE support %u", hci_classic_supported(), hci_le_supported()); 644 } 645 break; 646 647 case HCI_EVENT_COMMAND_STATUS: 648 // get num cmd packets 649 // log_info("HCI_EVENT_COMMAND_STATUS cmds - old %u - new %u\n", hci_stack->num_cmd_packets, packet[3]); 650 hci_stack->num_cmd_packets = packet[3]; 651 break; 652 653 case HCI_EVENT_NUMBER_OF_COMPLETED_PACKETS: 654 for (i=0; i<packet[2];i++){ 655 handle = READ_BT_16(packet, 3 + 2*i); 656 uint16_t num_packets = READ_BT_16(packet, 3 + packet[2]*2 + 2*i); 657 conn = hci_connection_for_handle(handle); 658 if (!conn){ 659 log_error("hci_number_completed_packet lists unused con handle %u\n", handle); 660 continue; 661 } 662 conn->num_acl_packets_sent -= num_packets; 663 // log_info("hci_number_completed_packet %u processed for handle %u, outstanding %u\n", num_packets, handle, conn->num_acl_packets_sent); 664 } 665 break; 666 667 case HCI_EVENT_CONNECTION_REQUEST: 668 bt_flip_addr(addr, &packet[2]); 669 // TODO: eval COD 8-10 670 link_type = packet[11]; 671 log_info("Connection_incoming: %s, type %u\n", bd_addr_to_str(addr), link_type); 672 if (link_type == 1) { // ACL 673 conn = hci_connection_for_bd_addr_and_type(&addr, BD_ADDR_TYPE_CLASSIC); 674 if (!conn) { 675 conn = create_connection_for_bd_addr_and_type(addr, BD_ADDR_TYPE_CLASSIC); 676 } 677 if (!conn) { 678 // CONNECTION REJECTED DUE TO LIMITED RESOURCES (0X0D) 679 hci_stack->decline_reason = 0x0d; 680 BD_ADDR_COPY(hci_stack->decline_addr, addr); 681 break; 682 } 683 conn->state = RECEIVED_CONNECTION_REQUEST; 684 hci_run(); 685 } else { 686 // SYNCHRONOUS CONNECTION LIMIT TO A DEVICE EXCEEDED (0X0A) 687 hci_stack->decline_reason = 0x0a; 688 BD_ADDR_COPY(hci_stack->decline_addr, addr); 689 } 690 break; 691 692 case HCI_EVENT_CONNECTION_COMPLETE: 693 // Connection management 694 bt_flip_addr(addr, &packet[5]); 695 log_info("Connection_complete (status=%u) %s\n", packet[2], bd_addr_to_str(addr)); 696 addr_type = BD_ADDR_TYPE_CLASSIC; 697 conn = hci_connection_for_bd_addr_and_type(&addr, addr_type); 698 if (conn) { 699 if (!packet[2]){ 700 conn->state = OPEN; 701 conn->con_handle = READ_BT_16(packet, 3); 702 conn->bonding_flags |= BONDING_REQUEST_REMOTE_FEATURES; 703 704 // restart timer 705 run_loop_set_timer(&conn->timeout, HCI_CONNECTION_TIMEOUT_MS); 706 run_loop_add_timer(&conn->timeout); 707 708 log_info("New connection: handle %u, %s\n", conn->con_handle, bd_addr_to_str(conn->address)); 709 710 hci_emit_nr_connections_changed(); 711 } else { 712 // notify client if dedicated bonding 713 if (conn->bonding_flags & BONDING_DEDICATED){ 714 hci_emit_dedicated_bonding_result(conn, packet[2]); 715 } 716 717 // connection failed, remove entry 718 linked_list_remove(&hci_stack->connections, (linked_item_t *) conn); 719 btstack_memory_hci_connection_free( conn ); 720 721 // if authentication error, also delete link key 722 if (packet[2] == 0x05) { 723 hci_drop_link_key_for_bd_addr(&addr); 724 } 725 } 726 } 727 break; 728 729 case HCI_EVENT_READ_REMOTE_SUPPORTED_FEATURES_COMPLETE: 730 handle = READ_BT_16(packet, 3); 731 conn = hci_connection_for_handle(handle); 732 if (!conn) break; 733 if (!packet[2]){ 734 uint8_t * features = &packet[5]; 735 if (features[6] & (1 << 3)){ 736 conn->bonding_flags |= BONDING_REMOTE_SUPPORTS_SSP; 737 } 738 } 739 conn->bonding_flags |= BONDING_RECEIVED_REMOTE_FEATURES; 740 log_info("HCI_EVENT_READ_REMOTE_SUPPORTED_FEATURES_COMPLETE, bonding flags %x", conn->bonding_flags); 741 if (conn->bonding_flags & BONDING_DEDICATED){ 742 conn->bonding_flags |= BONDING_SEND_AUTHENTICATE_REQUEST; 743 } 744 break; 745 746 case HCI_EVENT_LINK_KEY_REQUEST: 747 log_info("HCI_EVENT_LINK_KEY_REQUEST\n"); 748 hci_add_connection_flags_for_flipped_bd_addr(&packet[2], RECV_LINK_KEY_REQUEST); 749 // non-bondable mode: link key negative reply will be sent by HANDLE_LINK_KEY_REQUEST 750 if (hci_stack->bondable && !hci_stack->remote_device_db) break; 751 hci_add_connection_flags_for_flipped_bd_addr(&packet[2], HANDLE_LINK_KEY_REQUEST); 752 hci_run(); 753 // request handled by hci_run() as HANDLE_LINK_KEY_REQUEST gets set 754 return; 755 756 case HCI_EVENT_LINK_KEY_NOTIFICATION: { 757 bt_flip_addr(addr, &packet[2]); 758 conn = hci_connection_for_bd_addr_and_type(&addr, BD_ADDR_TYPE_CLASSIC); 759 if (!conn) break; 760 conn->authentication_flags |= RECV_LINK_KEY_NOTIFICATION; 761 link_key_type_t link_key_type = (link_key_type_t)packet[24]; 762 // Change Connection Encryption keeps link key type 763 if (link_key_type != CHANGED_COMBINATION_KEY){ 764 conn->link_key_type = link_key_type; 765 } 766 if (!hci_stack->remote_device_db) break; 767 hci_stack->remote_device_db->put_link_key(&addr, (link_key_t *) &packet[8], conn->link_key_type); 768 // still forward event to allow dismiss of pairing dialog 769 break; 770 } 771 772 case HCI_EVENT_PIN_CODE_REQUEST: 773 hci_add_connection_flags_for_flipped_bd_addr(&packet[2], LEGACY_PAIRING_ACTIVE); 774 // non-bondable mode: pin code negative reply will be sent 775 if (!hci_stack->bondable){ 776 hci_add_connection_flags_for_flipped_bd_addr(&packet[2], DENY_PIN_CODE_REQUEST); 777 hci_run(); 778 return; 779 } 780 // PIN CODE REQUEST means the link key request didn't succee -> delete stored link key 781 if (!hci_stack->remote_device_db) break; 782 bt_flip_addr(addr, &packet[2]); 783 hci_stack->remote_device_db->delete_link_key(&addr); 784 break; 785 786 case HCI_EVENT_IO_CAPABILITY_REQUEST: 787 hci_add_connection_flags_for_flipped_bd_addr(&packet[2], RECV_IO_CAPABILITIES_REQUEST); 788 hci_add_connection_flags_for_flipped_bd_addr(&packet[2], SEND_IO_CAPABILITIES_REPLY); 789 break; 790 791 case HCI_EVENT_USER_CONFIRMATION_REQUEST: 792 hci_add_connection_flags_for_flipped_bd_addr(&packet[2], SSP_PAIRING_ACTIVE); 793 if (!hci_stack->ssp_auto_accept) break; 794 hci_add_connection_flags_for_flipped_bd_addr(&packet[2], SEND_USER_CONFIRM_REPLY); 795 break; 796 797 case HCI_EVENT_USER_PASSKEY_REQUEST: 798 hci_add_connection_flags_for_flipped_bd_addr(&packet[2], SSP_PAIRING_ACTIVE); 799 if (!hci_stack->ssp_auto_accept) break; 800 hci_add_connection_flags_for_flipped_bd_addr(&packet[2], SEND_USER_PASSKEY_REPLY); 801 break; 802 803 case HCI_EVENT_ENCRYPTION_CHANGE: 804 handle = READ_BT_16(packet, 3); 805 conn = hci_connection_for_handle(handle); 806 if (!conn) break; 807 if (packet[2] == 0) { 808 if (packet[5]){ 809 conn->authentication_flags |= CONNECTION_ENCRYPTED; 810 } else { 811 conn->authentication_flags &= ~CONNECTION_ENCRYPTED; 812 } 813 } 814 hci_emit_security_level(handle, gap_security_level_for_connection(conn)); 815 break; 816 817 case HCI_EVENT_AUTHENTICATION_COMPLETE_EVENT: 818 handle = READ_BT_16(packet, 3); 819 conn = hci_connection_for_handle(handle); 820 if (!conn) break; 821 822 // dedicated bonding: send result and disconnect 823 if (conn->bonding_flags & BONDING_DEDICATED){ 824 conn->bonding_flags &= ~BONDING_DEDICATED; 825 hci_emit_dedicated_bonding_result( conn, packet[2]); 826 conn->bonding_flags |= BONDING_DISCONNECT_DEDICATED_DONE; 827 break; 828 } 829 830 if (packet[2] == 0 && gap_security_level_for_link_key_type(conn->link_key_type) >= conn->requested_security_level){ 831 // link key sufficient for requested security 832 conn->bonding_flags |= BONDING_SEND_ENCRYPTION_REQUEST; 833 break; 834 } 835 // not enough 836 hci_emit_security_level(handle, gap_security_level_for_connection(conn)); 837 break; 838 839 #ifndef EMBEDDED 840 case HCI_EVENT_REMOTE_NAME_REQUEST_COMPLETE: 841 if (!hci_stack->remote_device_db) break; 842 if (packet[2]) break; // status not ok 843 bt_flip_addr(addr, &packet[3]); 844 // fix for invalid remote names - terminate on 0xff 845 for (i=0; i<248;i++){ 846 if (packet[9+i] == 0xff){ 847 packet[9+i] = 0; 848 break; 849 } 850 } 851 memset(&device_name, 0, sizeof(device_name_t)); 852 strncpy((char*) device_name, (char*) &packet[9], 248); 853 hci_stack->remote_device_db->put_name(&addr, &device_name); 854 break; 855 856 case HCI_EVENT_INQUIRY_RESULT: 857 case HCI_EVENT_INQUIRY_RESULT_WITH_RSSI: 858 if (!hci_stack->remote_device_db) break; 859 // first send inq result packet 860 hci_stack->packet_handler(HCI_EVENT_PACKET, packet, size); 861 // then send cached remote names 862 for (i=0; i<packet[2];i++){ 863 bt_flip_addr(addr, &packet[3+i*6]); 864 if (hci_stack->remote_device_db->get_name(&addr, &device_name)){ 865 hci_emit_remote_name_cached(&addr, &device_name); 866 } 867 } 868 return; 869 #endif 870 871 case HCI_EVENT_DISCONNECTION_COMPLETE: 872 if (!packet[2]){ 873 handle = READ_BT_16(packet, 3); 874 hci_connection_t * conn = hci_connection_for_handle(handle); 875 if (conn) { 876 hci_shutdown_connection(conn); 877 } 878 } 879 break; 880 881 case HCI_EVENT_HARDWARE_ERROR: 882 if(hci_stack->control && hci_stack->control->hw_error){ 883 (*hci_stack->control->hw_error)(); 884 } 885 break; 886 887 case DAEMON_EVENT_HCI_PACKET_SENT: 888 // free packet buffer for asynchronous transport 889 if (hci_transport_synchronous()) break; 890 hci_stack->hci_packet_buffer_reserved = 0; 891 break; 892 893 #ifdef HAVE_BLE 894 case HCI_EVENT_LE_META: 895 switch (packet[2]){ 896 case HCI_SUBEVENT_LE_ADVERTISING_REPORT: 897 if (hci_stack->le_scanning_state != LE_SCANNING) break; 898 le_handle_advertisement_report(packet, size); 899 break; 900 case HCI_SUBEVENT_LE_CONNECTION_COMPLETE: 901 // Connection management 902 bt_flip_addr(addr, &packet[8]); 903 addr_type = (bd_addr_type_t)packet[7]; 904 log_info("LE Connection_complete (status=%u) type %u, %s\n", packet[3], addr_type, bd_addr_to_str(addr)); 905 // LE connections are auto-accepted, so just create a connection if there isn't one already 906 conn = hci_connection_for_bd_addr_and_type(&addr, addr_type); 907 if (packet[3]){ 908 if (conn){ 909 // outgoing connection failed, remove entry 910 linked_list_remove(&hci_stack->connections, (linked_item_t *) conn); 911 btstack_memory_hci_connection_free( conn ); 912 913 } 914 // if authentication error, also delete link key 915 if (packet[3] == 0x05) { 916 hci_drop_link_key_for_bd_addr(&addr); 917 } 918 break; 919 } 920 if (!conn){ 921 conn = create_connection_for_bd_addr_and_type(addr, addr_type); 922 } 923 if (!conn){ 924 // no memory 925 break; 926 } 927 928 conn->state = OPEN; 929 conn->con_handle = READ_BT_16(packet, 4); 930 931 // TODO: store - role, peer address type, conn_interval, conn_latency, supervision timeout, master clock 932 933 // restart timer 934 // run_loop_set_timer(&conn->timeout, HCI_CONNECTION_TIMEOUT_MS); 935 // run_loop_add_timer(&conn->timeout); 936 937 log_info("New connection: handle %u, %s\n", conn->con_handle, bd_addr_to_str(conn->address)); 938 939 hci_emit_nr_connections_changed(); 940 break; 941 942 // printf("LE buffer size: %u, count %u\n", READ_BT_16(packet,6), packet[8]); 943 944 default: 945 break; 946 } 947 break; 948 #endif 949 950 default: 951 break; 952 } 953 954 // handle BT initialization 955 if (hci_stack->state == HCI_STATE_INITIALIZING){ 956 if (hci_stack->substate % 2){ 957 // odd: waiting for event 958 if (packet[0] == HCI_EVENT_COMMAND_COMPLETE || packet[0] == HCI_EVENT_COMMAND_STATUS){ 959 // wait for explicit COMMAND COMPLETE on RESET 960 if (hci_stack->substate > 1 || COMMAND_COMPLETE_EVENT(packet, hci_reset)) { 961 hci_stack->substate++; 962 } 963 } 964 } 965 } 966 967 // help with BT sleep 968 if (hci_stack->state == HCI_STATE_FALLING_ASLEEP 969 && hci_stack->substate == 1 970 && COMMAND_COMPLETE_EVENT(packet, hci_write_scan_enable)){ 971 hci_stack->substate++; 972 } 973 974 hci_stack->packet_handler(HCI_EVENT_PACKET, packet, size); 975 976 // execute main loop 977 hci_run(); 978 } 979 980 static void packet_handler(uint8_t packet_type, uint8_t *packet, uint16_t size){ 981 switch (packet_type) { 982 case HCI_EVENT_PACKET: 983 event_handler(packet, size); 984 break; 985 case HCI_ACL_DATA_PACKET: 986 acl_handler(packet, size); 987 break; 988 default: 989 break; 990 } 991 } 992 993 /** Register HCI packet handlers */ 994 void hci_register_packet_handler(void (*handler)(uint8_t packet_type, uint8_t *packet, uint16_t size)){ 995 hci_stack->packet_handler = handler; 996 } 997 998 void hci_state_reset(){ 999 // no connections yet 1000 hci_stack->connections = NULL; 1001 hci_stack->discoverable = 0; 1002 hci_stack->connectable = 0; 1003 hci_stack->bondable = 1; 1004 1005 // no pending cmds 1006 hci_stack->decline_reason = 0; 1007 hci_stack->new_scan_enable_value = 0xff; 1008 1009 // LE 1010 hci_stack->adv_addr_type = 0; 1011 memset(hci_stack->adv_address, 0, 6); 1012 hci_stack->le_scanning_state = LE_SCAN_IDLE; 1013 } 1014 1015 void hci_init(hci_transport_t *transport, void *config, bt_control_t *control, remote_device_db_t const* remote_device_db){ 1016 1017 #ifdef HAVE_MALLOC 1018 if (!hci_stack) { 1019 hci_stack = (hci_stack_t*) malloc(sizeof(hci_stack_t)); 1020 } 1021 #else 1022 hci_stack = &hci_stack_static; 1023 #endif 1024 memset(hci_stack, 0, sizeof(hci_stack_t)); 1025 1026 // reference to use transport layer implementation 1027 hci_stack->hci_transport = transport; 1028 1029 // references to used control implementation 1030 hci_stack->control = control; 1031 1032 // reference to used config 1033 hci_stack->config = config; 1034 1035 // higher level handler 1036 hci_stack->packet_handler = dummy_handler; 1037 1038 // store and open remote device db 1039 hci_stack->remote_device_db = remote_device_db; 1040 if (hci_stack->remote_device_db) { 1041 hci_stack->remote_device_db->open(); 1042 } 1043 1044 // max acl payload size defined in config.h 1045 hci_stack->acl_data_packet_length = HCI_ACL_PAYLOAD_SIZE; 1046 1047 // register packet handlers with transport 1048 transport->register_packet_handler(&packet_handler); 1049 1050 hci_stack->state = HCI_STATE_OFF; 1051 1052 // class of device 1053 hci_stack->class_of_device = 0x007a020c; // Smartphone 1054 1055 // Secure Simple Pairing default: enable, no I/O capabilities, general bonding, mitm not required, auto accept 1056 hci_stack->ssp_enable = 1; 1057 hci_stack->ssp_io_capability = SSP_IO_CAPABILITY_NO_INPUT_NO_OUTPUT; 1058 hci_stack->ssp_authentication_requirement = SSP_IO_AUTHREQ_MITM_PROTECTION_NOT_REQUIRED_GENERAL_BONDING; 1059 hci_stack->ssp_auto_accept = 1; 1060 1061 hci_state_reset(); 1062 } 1063 1064 void hci_close(){ 1065 // close remote device db 1066 if (hci_stack->remote_device_db) { 1067 hci_stack->remote_device_db->close(); 1068 } 1069 while (hci_stack->connections) { 1070 // cancel all l2cap connections 1071 hci_emit_disconnection_complete(((hci_connection_t *) hci_stack->connections)->con_handle, 0x16); // terminated by local host 1072 hci_shutdown_connection((hci_connection_t *) hci_stack->connections); 1073 } 1074 hci_power_control(HCI_POWER_OFF); 1075 1076 #ifdef HAVE_MALLOC 1077 free(hci_stack); 1078 #endif 1079 hci_stack = NULL; 1080 } 1081 1082 void hci_set_class_of_device(uint32_t class_of_device){ 1083 hci_stack->class_of_device = class_of_device; 1084 } 1085 1086 void hci_disable_l2cap_timeout_check(){ 1087 disable_l2cap_timeouts = 1; 1088 } 1089 // State-Module-Driver overview 1090 // state module low-level 1091 // HCI_STATE_OFF off close 1092 // HCI_STATE_INITIALIZING, on open 1093 // HCI_STATE_WORKING, on open 1094 // HCI_STATE_HALTING, on open 1095 // HCI_STATE_SLEEPING, off/sleep close 1096 // HCI_STATE_FALLING_ASLEEP on open 1097 1098 static int hci_power_control_on(void){ 1099 1100 // power on 1101 int err = 0; 1102 if (hci_stack->control && hci_stack->control->on){ 1103 err = (*hci_stack->control->on)(hci_stack->config); 1104 } 1105 if (err){ 1106 log_error( "POWER_ON failed\n"); 1107 hci_emit_hci_open_failed(); 1108 return err; 1109 } 1110 1111 // open low-level device 1112 err = hci_stack->hci_transport->open(hci_stack->config); 1113 if (err){ 1114 log_error( "HCI_INIT failed, turning Bluetooth off again\n"); 1115 if (hci_stack->control && hci_stack->control->off){ 1116 (*hci_stack->control->off)(hci_stack->config); 1117 } 1118 hci_emit_hci_open_failed(); 1119 return err; 1120 } 1121 return 0; 1122 } 1123 1124 static void hci_power_control_off(void){ 1125 1126 log_info("hci_power_control_off\n"); 1127 1128 // close low-level device 1129 hci_stack->hci_transport->close(hci_stack->config); 1130 1131 log_info("hci_power_control_off - hci_transport closed\n"); 1132 1133 // power off 1134 if (hci_stack->control && hci_stack->control->off){ 1135 (*hci_stack->control->off)(hci_stack->config); 1136 } 1137 1138 log_info("hci_power_control_off - control closed\n"); 1139 1140 hci_stack->state = HCI_STATE_OFF; 1141 } 1142 1143 static void hci_power_control_sleep(void){ 1144 1145 log_info("hci_power_control_sleep\n"); 1146 1147 #if 0 1148 // don't close serial port during sleep 1149 1150 // close low-level device 1151 hci_stack->hci_transport->close(hci_stack->config); 1152 #endif 1153 1154 // sleep mode 1155 if (hci_stack->control && hci_stack->control->sleep){ 1156 (*hci_stack->control->sleep)(hci_stack->config); 1157 } 1158 1159 hci_stack->state = HCI_STATE_SLEEPING; 1160 } 1161 1162 static int hci_power_control_wake(void){ 1163 1164 log_info("hci_power_control_wake\n"); 1165 1166 // wake on 1167 if (hci_stack->control && hci_stack->control->wake){ 1168 (*hci_stack->control->wake)(hci_stack->config); 1169 } 1170 1171 #if 0 1172 // open low-level device 1173 int err = hci_stack->hci_transport->open(hci_stack->config); 1174 if (err){ 1175 log_error( "HCI_INIT failed, turning Bluetooth off again\n"); 1176 if (hci_stack->control && hci_stack->control->off){ 1177 (*hci_stack->control->off)(hci_stack->config); 1178 } 1179 hci_emit_hci_open_failed(); 1180 return err; 1181 } 1182 #endif 1183 1184 return 0; 1185 } 1186 1187 1188 int hci_power_control(HCI_POWER_MODE power_mode){ 1189 1190 log_info("hci_power_control: %u, current mode %u\n", power_mode, hci_stack->state); 1191 1192 int err = 0; 1193 switch (hci_stack->state){ 1194 1195 case HCI_STATE_OFF: 1196 switch (power_mode){ 1197 case HCI_POWER_ON: 1198 err = hci_power_control_on(); 1199 if (err) return err; 1200 // set up state machine 1201 hci_stack->num_cmd_packets = 1; // assume that one cmd can be sent 1202 hci_stack->state = HCI_STATE_INITIALIZING; 1203 hci_stack->substate = 0; 1204 break; 1205 case HCI_POWER_OFF: 1206 // do nothing 1207 break; 1208 case HCI_POWER_SLEEP: 1209 // do nothing (with SLEEP == OFF) 1210 break; 1211 } 1212 break; 1213 1214 case HCI_STATE_INITIALIZING: 1215 switch (power_mode){ 1216 case HCI_POWER_ON: 1217 // do nothing 1218 break; 1219 case HCI_POWER_OFF: 1220 // no connections yet, just turn it off 1221 hci_power_control_off(); 1222 break; 1223 case HCI_POWER_SLEEP: 1224 // no connections yet, just turn it off 1225 hci_power_control_sleep(); 1226 break; 1227 } 1228 break; 1229 1230 case HCI_STATE_WORKING: 1231 switch (power_mode){ 1232 case HCI_POWER_ON: 1233 // do nothing 1234 break; 1235 case HCI_POWER_OFF: 1236 // see hci_run 1237 hci_stack->state = HCI_STATE_HALTING; 1238 break; 1239 case HCI_POWER_SLEEP: 1240 // see hci_run 1241 hci_stack->state = HCI_STATE_FALLING_ASLEEP; 1242 hci_stack->substate = 0; 1243 break; 1244 } 1245 break; 1246 1247 case HCI_STATE_HALTING: 1248 switch (power_mode){ 1249 case HCI_POWER_ON: 1250 // set up state machine 1251 hci_stack->state = HCI_STATE_INITIALIZING; 1252 hci_stack->substate = 0; 1253 break; 1254 case HCI_POWER_OFF: 1255 // do nothing 1256 break; 1257 case HCI_POWER_SLEEP: 1258 // see hci_run 1259 hci_stack->state = HCI_STATE_FALLING_ASLEEP; 1260 hci_stack->substate = 0; 1261 break; 1262 } 1263 break; 1264 1265 case HCI_STATE_FALLING_ASLEEP: 1266 switch (power_mode){ 1267 case HCI_POWER_ON: 1268 1269 #if defined(USE_POWERMANAGEMENT) && defined(USE_BLUETOOL) 1270 // nothing to do, if H4 supports power management 1271 if (bt_control_iphone_power_management_enabled()){ 1272 hci_stack->state = HCI_STATE_INITIALIZING; 1273 hci_stack->substate = HCI_INTIALIZING_SUBSTATE_AFTER_SLEEP; 1274 break; 1275 } 1276 #endif 1277 // set up state machine 1278 hci_stack->num_cmd_packets = 1; // assume that one cmd can be sent 1279 hci_stack->state = HCI_STATE_INITIALIZING; 1280 hci_stack->substate = 0; 1281 break; 1282 case HCI_POWER_OFF: 1283 // see hci_run 1284 hci_stack->state = HCI_STATE_HALTING; 1285 break; 1286 case HCI_POWER_SLEEP: 1287 // do nothing 1288 break; 1289 } 1290 break; 1291 1292 case HCI_STATE_SLEEPING: 1293 switch (power_mode){ 1294 case HCI_POWER_ON: 1295 1296 #if defined(USE_POWERMANAGEMENT) && defined(USE_BLUETOOL) 1297 // nothing to do, if H4 supports power management 1298 if (bt_control_iphone_power_management_enabled()){ 1299 hci_stack->state = HCI_STATE_INITIALIZING; 1300 hci_stack->substate = HCI_INTIALIZING_SUBSTATE_AFTER_SLEEP; 1301 hci_update_scan_enable(); 1302 break; 1303 } 1304 #endif 1305 err = hci_power_control_wake(); 1306 if (err) return err; 1307 // set up state machine 1308 hci_stack->num_cmd_packets = 1; // assume that one cmd can be sent 1309 hci_stack->state = HCI_STATE_INITIALIZING; 1310 hci_stack->substate = 0; 1311 break; 1312 case HCI_POWER_OFF: 1313 hci_stack->state = HCI_STATE_HALTING; 1314 break; 1315 case HCI_POWER_SLEEP: 1316 // do nothing 1317 break; 1318 } 1319 break; 1320 } 1321 1322 // create internal event 1323 hci_emit_state(); 1324 1325 // trigger next/first action 1326 hci_run(); 1327 1328 return 0; 1329 } 1330 1331 static void hci_update_scan_enable(void){ 1332 // 2 = page scan, 1 = inq scan 1333 hci_stack->new_scan_enable_value = hci_stack->connectable << 1 | hci_stack->discoverable; 1334 hci_run(); 1335 } 1336 1337 void hci_discoverable_control(uint8_t enable){ 1338 if (enable) enable = 1; // normalize argument 1339 1340 if (hci_stack->discoverable == enable){ 1341 hci_emit_discoverable_enabled(hci_stack->discoverable); 1342 return; 1343 } 1344 1345 hci_stack->discoverable = enable; 1346 hci_update_scan_enable(); 1347 } 1348 1349 void hci_connectable_control(uint8_t enable){ 1350 if (enable) enable = 1; // normalize argument 1351 1352 // don't emit event 1353 if (hci_stack->connectable == enable) return; 1354 1355 hci_stack->connectable = enable; 1356 hci_update_scan_enable(); 1357 } 1358 1359 bd_addr_t * hci_local_bd_addr(void){ 1360 return &hci_stack->local_bd_addr; 1361 } 1362 1363 void hci_run(){ 1364 1365 hci_connection_t * connection; 1366 linked_item_t * it; 1367 1368 if (!hci_can_send_packet_now_using_packet_buffer(HCI_COMMAND_DATA_PACKET)) return; 1369 1370 // global/non-connection oriented commands 1371 1372 // decline incoming connections 1373 if (hci_stack->decline_reason){ 1374 uint8_t reason = hci_stack->decline_reason; 1375 hci_stack->decline_reason = 0; 1376 hci_send_cmd(&hci_reject_connection_request, hci_stack->decline_addr, reason); 1377 return; 1378 } 1379 1380 // send scan enable 1381 if (hci_stack->state == HCI_STATE_WORKING && hci_stack->new_scan_enable_value != 0xff && hci_classic_supported()){ 1382 hci_send_cmd(&hci_write_scan_enable, hci_stack->new_scan_enable_value); 1383 hci_stack->new_scan_enable_value = 0xff; 1384 return; 1385 } 1386 1387 #ifdef HAVE_BLE 1388 // handle le scan 1389 if (hci_stack->state == HCI_STATE_WORKING){ 1390 switch(hci_stack->le_scanning_state){ 1391 case LE_START_SCAN: 1392 hci_stack->le_scanning_state = LE_SCANNING; 1393 hci_send_cmd(&hci_le_set_scan_enable, 1, 0); 1394 return; 1395 1396 case LE_STOP_SCAN: 1397 hci_stack->le_scanning_state = LE_SCAN_IDLE; 1398 hci_send_cmd(&hci_le_set_scan_enable, 0, 0); 1399 return; 1400 default: 1401 break; 1402 } 1403 } 1404 #endif 1405 1406 // send pending HCI commands 1407 for (it = (linked_item_t *) hci_stack->connections; it ; it = it->next){ 1408 connection = (hci_connection_t *) it; 1409 1410 switch(connection->state){ 1411 case SEND_CREATE_CONNECTION: 1412 switch(connection->address_type){ 1413 case BD_ADDR_TYPE_CLASSIC: 1414 log_info("sending hci_create_connection\n"); 1415 hci_send_cmd(&hci_create_connection, connection->address, hci_usable_acl_packet_types(), 0, 0, 0, 1); 1416 break; 1417 default: 1418 #ifdef HAVE_BLE 1419 log_info("sending hci_le_create_connection\n"); 1420 hci_send_cmd(&hci_le_create_connection, 1421 1000, // scan interval: 625 ms 1422 1000, // scan interval: 625 ms 1423 0, // don't use whitelist 1424 connection->address_type, // peer address type 1425 connection->address, // peer bd addr 1426 0, // our addr type: public 1427 80, // conn interval min 1428 80, // conn interval max (3200 * 0.625) 1429 0, // conn latency 1430 2000, // supervision timeout 1431 0, // min ce length 1432 1000 // max ce length 1433 ); 1434 1435 connection->state = SENT_CREATE_CONNECTION; 1436 #endif 1437 break; 1438 } 1439 return; 1440 1441 case RECEIVED_CONNECTION_REQUEST: 1442 log_info("sending hci_accept_connection_request\n"); 1443 connection->state = ACCEPTED_CONNECTION_REQUEST; 1444 hci_send_cmd(&hci_accept_connection_request, connection->address, 1); 1445 return; 1446 1447 #ifdef HAVE_BLE 1448 case SEND_CANCEL_CONNECTION: 1449 connection->state = SENT_CANCEL_CONNECTION; 1450 hci_send_cmd(&hci_le_create_connection_cancel); 1451 return; 1452 #endif 1453 case SEND_DISCONNECT: 1454 hci_send_cmd(&hci_disconnect, connection->con_handle, 0x13); // remote closed connection 1455 connection->state = SENT_DISCONNECT; 1456 return; 1457 1458 default: 1459 break; 1460 } 1461 1462 1463 1464 if (connection->authentication_flags & HANDLE_LINK_KEY_REQUEST){ 1465 log_info("responding to link key request\n"); 1466 connectionClearAuthenticationFlags(connection, HANDLE_LINK_KEY_REQUEST); 1467 link_key_t link_key; 1468 link_key_type_t link_key_type; 1469 if ( hci_stack->remote_device_db 1470 && hci_stack->remote_device_db->get_link_key( &connection->address, &link_key, &link_key_type) 1471 && gap_security_level_for_link_key_type(link_key_type) >= connection->requested_security_level){ 1472 connection->link_key_type = link_key_type; 1473 hci_send_cmd(&hci_link_key_request_reply, connection->address, &link_key); 1474 } else { 1475 hci_send_cmd(&hci_link_key_request_negative_reply, connection->address); 1476 } 1477 return; 1478 } 1479 1480 if (connection->authentication_flags & DENY_PIN_CODE_REQUEST){ 1481 log_info("denying to pin request\n"); 1482 connectionClearAuthenticationFlags(connection, DENY_PIN_CODE_REQUEST); 1483 hci_send_cmd(&hci_pin_code_request_negative_reply, connection->address); 1484 return; 1485 } 1486 1487 if (connection->authentication_flags & SEND_IO_CAPABILITIES_REPLY){ 1488 connectionClearAuthenticationFlags(connection, SEND_IO_CAPABILITIES_REPLY); 1489 log_info("IO Capability Request received, stack bondable %u, io cap %u", hci_stack->bondable, hci_stack->ssp_io_capability); 1490 if (hci_stack->bondable && (hci_stack->ssp_io_capability != SSP_IO_CAPABILITY_UNKNOWN)){ 1491 // tweak authentication requirements 1492 uint8_t authreq = hci_stack->ssp_authentication_requirement; 1493 if (connection->bonding_flags & BONDING_DEDICATED){ 1494 authreq = SSP_IO_AUTHREQ_MITM_PROTECTION_NOT_REQUIRED_DEDICATED_BONDING; 1495 } 1496 if (gap_mitm_protection_required_for_security_level(connection->requested_security_level)){ 1497 authreq |= 1; 1498 } 1499 hci_send_cmd(&hci_io_capability_request_reply, &connection->address, hci_stack->ssp_io_capability, NULL, authreq); 1500 } else { 1501 hci_send_cmd(&hci_io_capability_request_negative_reply, &connection->address, ERROR_CODE_PAIRING_NOT_ALLOWED); 1502 } 1503 return; 1504 } 1505 1506 if (connection->authentication_flags & SEND_USER_CONFIRM_REPLY){ 1507 connectionClearAuthenticationFlags(connection, SEND_USER_CONFIRM_REPLY); 1508 hci_send_cmd(&hci_user_confirmation_request_reply, &connection->address); 1509 return; 1510 } 1511 1512 if (connection->authentication_flags & SEND_USER_PASSKEY_REPLY){ 1513 connectionClearAuthenticationFlags(connection, SEND_USER_PASSKEY_REPLY); 1514 hci_send_cmd(&hci_user_passkey_request_reply, &connection->address, 000000); 1515 return; 1516 } 1517 1518 if (connection->bonding_flags & BONDING_REQUEST_REMOTE_FEATURES){ 1519 connection->bonding_flags &= ~BONDING_REQUEST_REMOTE_FEATURES; 1520 hci_send_cmd(&hci_read_remote_supported_features_command, connection->con_handle); 1521 return; 1522 } 1523 1524 if (connection->bonding_flags & BONDING_DISCONNECT_SECURITY_BLOCK){ 1525 connection->bonding_flags &= ~BONDING_DISCONNECT_SECURITY_BLOCK; 1526 hci_send_cmd(&hci_disconnect, connection->con_handle, 0x0005); // authentication failure 1527 return; 1528 } 1529 if (connection->bonding_flags & BONDING_DISCONNECT_DEDICATED_DONE){ 1530 connection->bonding_flags &= ~BONDING_DISCONNECT_DEDICATED_DONE; 1531 hci_send_cmd(&hci_disconnect, connection->con_handle, 0x13); // authentication done 1532 return; 1533 } 1534 if (connection->bonding_flags & BONDING_SEND_AUTHENTICATE_REQUEST){ 1535 connection->bonding_flags &= ~BONDING_SEND_AUTHENTICATE_REQUEST; 1536 hci_send_cmd(&hci_authentication_requested, connection->con_handle); 1537 return; 1538 } 1539 if (connection->bonding_flags & BONDING_SEND_ENCRYPTION_REQUEST){ 1540 connection->bonding_flags &= ~BONDING_SEND_ENCRYPTION_REQUEST; 1541 hci_send_cmd(&hci_set_connection_encryption, connection->con_handle, 1); 1542 return; 1543 } 1544 } 1545 1546 switch (hci_stack->state){ 1547 case HCI_STATE_INITIALIZING: 1548 // log_info("hci_init: substate %u\n", hci_stack->substate); 1549 if (hci_stack->substate % 2) { 1550 // odd: waiting for command completion 1551 return; 1552 } 1553 switch (hci_stack->substate >> 1){ 1554 case 0: // RESET 1555 hci_state_reset(); 1556 1557 hci_send_cmd(&hci_reset); 1558 if (hci_stack->config == 0 || ((hci_uart_config_t *)hci_stack->config)->baudrate_main == 0){ 1559 // skip baud change 1560 hci_stack->substate = 4; // >> 1 = 2 1561 } 1562 break; 1563 case 1: // SEND BAUD CHANGE 1564 hci_stack->control->baudrate_cmd(hci_stack->config, ((hci_uart_config_t *)hci_stack->config)->baudrate_main, hci_stack->hci_packet_buffer); 1565 hci_send_cmd_packet(hci_stack->hci_packet_buffer, 3 + hci_stack->hci_packet_buffer[2]); 1566 break; 1567 case 2: // LOCAL BAUD CHANGE 1568 hci_stack->hci_transport->set_baudrate(((hci_uart_config_t *)hci_stack->config)->baudrate_main); 1569 hci_stack->substate += 2; 1570 // break missing here for fall through 1571 1572 case 3: 1573 // Custom initialization 1574 if (hci_stack->control && hci_stack->control->next_cmd){ 1575 int valid_cmd = (*hci_stack->control->next_cmd)(hci_stack->config, hci_stack->hci_packet_buffer); 1576 if (valid_cmd){ 1577 int size = 3 + hci_stack->hci_packet_buffer[2]; 1578 hci_stack->hci_transport->send_packet(HCI_COMMAND_DATA_PACKET, hci_stack->hci_packet_buffer, size); 1579 hci_stack->substate = 4; // more init commands 1580 break; 1581 } 1582 log_info("hci_run: init script done\n\r"); 1583 } 1584 // otherwise continue 1585 hci_send_cmd(&hci_read_bd_addr); 1586 break; 1587 case 4: 1588 hci_send_cmd(&hci_read_buffer_size); 1589 break; 1590 case 5: 1591 hci_send_cmd(&hci_read_local_supported_features); 1592 break; 1593 case 6: 1594 if (hci_le_supported()){ 1595 hci_send_cmd(&hci_set_event_mask,0xffffffff, 0x3FFFFFFF); 1596 } else { 1597 // Kensington Bluetoot 2.1 USB Dongle (CSR Chipset) returns an error for 0xffff... 1598 hci_send_cmd(&hci_set_event_mask,0xffffffff, 0x1FFFFFFF); 1599 } 1600 1601 // skip Classic init commands for LE only chipsets 1602 if (!hci_classic_supported()){ 1603 if (hci_le_supported()){ 1604 hci_stack->substate = 11 << 1; // skip all classic command 1605 } else { 1606 log_error("Neither BR/EDR nor LE supported"); 1607 hci_stack->substate = 13 << 1; // skip all 1608 } 1609 } 1610 break; 1611 case 7: 1612 if (hci_ssp_supported()){ 1613 hci_send_cmd(&hci_write_simple_pairing_mode, hci_stack->ssp_enable); 1614 break; 1615 } 1616 hci_stack->substate += 2; 1617 // break missing here for fall through 1618 1619 case 8: 1620 // ca. 15 sec 1621 hci_send_cmd(&hci_write_page_timeout, 0x6000); 1622 break; 1623 case 9: 1624 hci_send_cmd(&hci_write_class_of_device, hci_stack->class_of_device); 1625 break; 1626 case 10: 1627 if (hci_stack->local_name){ 1628 hci_send_cmd(&hci_write_local_name, hci_stack->local_name); 1629 } else { 1630 char hostname[30]; 1631 #ifdef EMBEDDED 1632 // BTstack-11:22:33:44:55:66 1633 strcpy(hostname, "BTstack "); 1634 strcat(hostname, bd_addr_to_str(hci_stack->local_bd_addr)); 1635 printf("---> Name %s\n", hostname); 1636 #else 1637 // hostname for POSIX systems 1638 gethostname(hostname, 30); 1639 hostname[29] = '\0'; 1640 #endif 1641 hci_send_cmd(&hci_write_local_name, hostname); 1642 } 1643 break; 1644 case 11: 1645 hci_send_cmd(&hci_write_scan_enable, (hci_stack->connectable << 1) | hci_stack->discoverable); // page scan 1646 if (!hci_le_supported()){ 1647 // SKIP LE init for Classic only configuration 1648 hci_stack->substate = 13 << 1; 1649 } 1650 break; 1651 1652 #ifdef HAVE_BLE 1653 // LE INIT 1654 case 12: 1655 hci_send_cmd(&hci_le_read_buffer_size); 1656 break; 1657 case 13: 1658 // LE Supported Host = 1, Simultaneous Host = 0 1659 hci_send_cmd(&hci_write_le_host_supported, 1, 0); 1660 break; 1661 #endif 1662 1663 // DONE 1664 case 14: 1665 // done. 1666 hci_stack->state = HCI_STATE_WORKING; 1667 hci_emit_state(); 1668 break; 1669 default: 1670 break; 1671 } 1672 hci_stack->substate++; 1673 break; 1674 1675 case HCI_STATE_HALTING: 1676 1677 log_info("HCI_STATE_HALTING\n"); 1678 // close all open connections 1679 connection = (hci_connection_t *) hci_stack->connections; 1680 if (connection){ 1681 1682 // send disconnect 1683 if (!hci_can_send_packet_now_using_packet_buffer(HCI_COMMAND_DATA_PACKET)) return; 1684 1685 log_info("HCI_STATE_HALTING, connection %p, handle %u\n", connection, (uint16_t)connection->con_handle); 1686 hci_send_cmd(&hci_disconnect, connection->con_handle, 0x13); // remote closed connection 1687 1688 // send disconnected event right away - causes higher layer connections to get closed, too. 1689 hci_shutdown_connection(connection); 1690 return; 1691 } 1692 log_info("HCI_STATE_HALTING, calling off\n"); 1693 1694 // switch mode 1695 hci_power_control_off(); 1696 1697 log_info("HCI_STATE_HALTING, emitting state\n"); 1698 hci_emit_state(); 1699 log_info("HCI_STATE_HALTING, done\n"); 1700 break; 1701 1702 case HCI_STATE_FALLING_ASLEEP: 1703 switch(hci_stack->substate) { 1704 case 0: 1705 log_info("HCI_STATE_FALLING_ASLEEP\n"); 1706 // close all open connections 1707 connection = (hci_connection_t *) hci_stack->connections; 1708 1709 #if defined(USE_POWERMANAGEMENT) && defined(USE_BLUETOOL) 1710 // don't close connections, if H4 supports power management 1711 if (bt_control_iphone_power_management_enabled()){ 1712 connection = NULL; 1713 } 1714 #endif 1715 if (connection){ 1716 1717 // send disconnect 1718 if (!hci_can_send_packet_now(HCI_COMMAND_DATA_PACKET)) return; 1719 1720 log_info("HCI_STATE_FALLING_ASLEEP, connection %p, handle %u\n", connection, (uint16_t)connection->con_handle); 1721 hci_send_cmd(&hci_disconnect, connection->con_handle, 0x13); // remote closed connection 1722 1723 // send disconnected event right away - causes higher layer connections to get closed, too. 1724 hci_shutdown_connection(connection); 1725 return; 1726 } 1727 1728 if (hci_classic_supported()){ 1729 // disable page and inquiry scan 1730 if (!hci_can_send_packet_now_using_packet_buffer(HCI_COMMAND_DATA_PACKET)) return; 1731 1732 log_info("HCI_STATE_HALTING, disabling inq scans\n"); 1733 hci_send_cmd(&hci_write_scan_enable, hci_stack->connectable << 1); // drop inquiry scan but keep page scan 1734 1735 // continue in next sub state 1736 hci_stack->substate++; 1737 break; 1738 } 1739 // fall through for ble-only chips 1740 1741 case 2: 1742 log_info("HCI_STATE_HALTING, calling sleep\n"); 1743 #if defined(USE_POWERMANAGEMENT) && defined(USE_BLUETOOL) 1744 // don't actually go to sleep, if H4 supports power management 1745 if (bt_control_iphone_power_management_enabled()){ 1746 // SLEEP MODE reached 1747 hci_stack->state = HCI_STATE_SLEEPING; 1748 hci_emit_state(); 1749 break; 1750 } 1751 #endif 1752 // switch mode 1753 hci_power_control_sleep(); // changes hci_stack->state to SLEEP 1754 hci_emit_state(); 1755 break; 1756 1757 default: 1758 break; 1759 } 1760 break; 1761 1762 default: 1763 break; 1764 } 1765 } 1766 1767 int hci_send_cmd_packet(uint8_t *packet, int size){ 1768 bd_addr_t addr; 1769 hci_connection_t * conn; 1770 // house-keeping 1771 1772 // create_connection? 1773 if (IS_COMMAND(packet, hci_create_connection)){ 1774 bt_flip_addr(addr, &packet[3]); 1775 log_info("Create_connection to %s\n", bd_addr_to_str(addr)); 1776 1777 conn = hci_connection_for_bd_addr_and_type(&addr, BD_ADDR_TYPE_CLASSIC); 1778 if (!conn){ 1779 conn = create_connection_for_bd_addr_and_type(addr, BD_ADDR_TYPE_CLASSIC); 1780 if (!conn){ 1781 // notify client that alloc failed 1782 hci_emit_connection_complete(conn, BTSTACK_MEMORY_ALLOC_FAILED); 1783 return 0; // don't sent packet to controller 1784 } 1785 conn->state = SEND_CREATE_CONNECTION; 1786 } 1787 log_info("conn state %u", conn->state); 1788 switch (conn->state){ 1789 // if connection active exists 1790 case OPEN: 1791 // and OPEN, emit connection complete command, don't send to controller 1792 hci_emit_connection_complete(conn, 0); 1793 return 0; 1794 case SEND_CREATE_CONNECTION: 1795 // connection created by hci, e.g. dedicated bonding 1796 break; 1797 default: 1798 // otherwise, just ignore as it is already in the open process 1799 return 0; 1800 } 1801 conn->state = SENT_CREATE_CONNECTION; 1802 } 1803 1804 if (IS_COMMAND(packet, hci_link_key_request_reply)){ 1805 hci_add_connection_flags_for_flipped_bd_addr(&packet[3], SENT_LINK_KEY_REPLY); 1806 } 1807 if (IS_COMMAND(packet, hci_link_key_request_negative_reply)){ 1808 hci_add_connection_flags_for_flipped_bd_addr(&packet[3], SENT_LINK_KEY_NEGATIVE_REQUEST); 1809 } 1810 1811 if (IS_COMMAND(packet, hci_delete_stored_link_key)){ 1812 if (hci_stack->remote_device_db){ 1813 bt_flip_addr(addr, &packet[3]); 1814 hci_stack->remote_device_db->delete_link_key(&addr); 1815 } 1816 } 1817 1818 if (IS_COMMAND(packet, hci_pin_code_request_negative_reply) 1819 || IS_COMMAND(packet, hci_pin_code_request_reply)){ 1820 bt_flip_addr(addr, &packet[3]); 1821 conn = hci_connection_for_bd_addr_and_type(&addr, BD_ADDR_TYPE_CLASSIC); 1822 if (conn){ 1823 connectionClearAuthenticationFlags(conn, LEGACY_PAIRING_ACTIVE); 1824 } 1825 } 1826 1827 if (IS_COMMAND(packet, hci_user_confirmation_request_negative_reply) 1828 || IS_COMMAND(packet, hci_user_confirmation_request_reply) 1829 || IS_COMMAND(packet, hci_user_passkey_request_negative_reply) 1830 || IS_COMMAND(packet, hci_user_passkey_request_reply)) { 1831 bt_flip_addr(addr, &packet[3]); 1832 conn = hci_connection_for_bd_addr_and_type(&addr, BD_ADDR_TYPE_CLASSIC); 1833 if (conn){ 1834 connectionClearAuthenticationFlags(conn, SSP_PAIRING_ACTIVE); 1835 } 1836 } 1837 1838 #ifdef HAVE_BLE 1839 if (IS_COMMAND(packet, hci_le_set_advertising_parameters)){ 1840 hci_stack->adv_addr_type = packet[8]; 1841 } 1842 if (IS_COMMAND(packet, hci_le_set_random_address)){ 1843 bt_flip_addr(hci_stack->adv_address, &packet[3]); 1844 } 1845 #endif 1846 1847 hci_stack->num_cmd_packets--; 1848 int err = hci_stack->hci_transport->send_packet(HCI_COMMAND_DATA_PACKET, packet, size); 1849 1850 // free packet buffer for synchronous transport implementations 1851 if (hci_transport_synchronous() && (packet == hci_stack->hci_packet_buffer)){ 1852 hci_stack->hci_packet_buffer_reserved = 0; 1853 } 1854 1855 return err; 1856 } 1857 1858 // disconnect because of security block 1859 void hci_disconnect_security_block(hci_con_handle_t con_handle){ 1860 hci_connection_t * connection = hci_connection_for_handle(con_handle); 1861 if (!connection) return; 1862 connection->bonding_flags |= BONDING_DISCONNECT_SECURITY_BLOCK; 1863 } 1864 1865 1866 // Configure Secure Simple Pairing 1867 1868 // enable will enable SSP during init 1869 void hci_ssp_set_enable(int enable){ 1870 hci_stack->ssp_enable = enable; 1871 } 1872 1873 int hci_local_ssp_activated(){ 1874 return hci_ssp_supported() && hci_stack->ssp_enable; 1875 } 1876 1877 // if set, BTstack will respond to io capability request using authentication requirement 1878 void hci_ssp_set_io_capability(int io_capability){ 1879 hci_stack->ssp_io_capability = io_capability; 1880 } 1881 void hci_ssp_set_authentication_requirement(int authentication_requirement){ 1882 hci_stack->ssp_authentication_requirement = authentication_requirement; 1883 } 1884 1885 // if set, BTstack will confirm a numberic comparion and enter '000000' if requested 1886 void hci_ssp_set_auto_accept(int auto_accept){ 1887 hci_stack->ssp_auto_accept = auto_accept; 1888 } 1889 1890 /** 1891 * pre: numcmds >= 0 - it's allowed to send a command to the controller 1892 */ 1893 int hci_send_cmd(const hci_cmd_t *cmd, ...){ 1894 va_list argptr; 1895 va_start(argptr, cmd); 1896 uint16_t size = hci_create_cmd_internal(hci_stack->hci_packet_buffer, cmd, argptr); 1897 va_end(argptr); 1898 return hci_send_cmd_packet(hci_stack->hci_packet_buffer, size); 1899 } 1900 1901 // Create various non-HCI events. 1902 // TODO: generalize, use table similar to hci_create_command 1903 1904 void hci_emit_state(){ 1905 log_info("BTSTACK_EVENT_STATE %u", hci_stack->state); 1906 uint8_t event[3]; 1907 event[0] = BTSTACK_EVENT_STATE; 1908 event[1] = sizeof(event) - 2; 1909 event[2] = hci_stack->state; 1910 hci_dump_packet( HCI_EVENT_PACKET, 0, event, sizeof(event)); 1911 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 1912 } 1913 1914 void hci_emit_connection_complete(hci_connection_t *conn, uint8_t status){ 1915 uint8_t event[13]; 1916 event[0] = HCI_EVENT_CONNECTION_COMPLETE; 1917 event[1] = sizeof(event) - 2; 1918 event[2] = status; 1919 bt_store_16(event, 3, conn->con_handle); 1920 bt_flip_addr(&event[5], conn->address); 1921 event[11] = 1; // ACL connection 1922 event[12] = 0; // encryption disabled 1923 hci_dump_packet(HCI_EVENT_PACKET, 0, event, sizeof(event)); 1924 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 1925 } 1926 1927 void hci_emit_le_connection_complete(hci_connection_t *conn, uint8_t status){ 1928 uint8_t event[21]; 1929 event[0] = HCI_EVENT_LE_META; 1930 event[1] = sizeof(event) - 2; 1931 event[2] = HCI_SUBEVENT_LE_CONNECTION_COMPLETE; 1932 event[3] = status; 1933 bt_store_16(event, 4, conn->con_handle); 1934 event[6] = 0; // TODO: role 1935 event[7] = conn->address_type; 1936 bt_flip_addr(&event[8], conn->address); 1937 bt_store_16(event, 14, 0); // interval 1938 bt_store_16(event, 16, 0); // latency 1939 bt_store_16(event, 18, 0); // supervision timeout 1940 event[20] = 0; // master clock accuracy 1941 hci_dump_packet(HCI_EVENT_PACKET, 0, event, sizeof(event)); 1942 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 1943 } 1944 1945 void hci_emit_disconnection_complete(uint16_t handle, uint8_t reason){ 1946 uint8_t event[6]; 1947 event[0] = HCI_EVENT_DISCONNECTION_COMPLETE; 1948 event[1] = sizeof(event) - 2; 1949 event[2] = 0; // status = OK 1950 bt_store_16(event, 3, handle); 1951 event[5] = reason; 1952 hci_dump_packet(HCI_EVENT_PACKET, 0, event, sizeof(event)); 1953 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 1954 } 1955 1956 void hci_emit_l2cap_check_timeout(hci_connection_t *conn){ 1957 if (disable_l2cap_timeouts) return; 1958 log_info("L2CAP_EVENT_TIMEOUT_CHECK"); 1959 uint8_t event[4]; 1960 event[0] = L2CAP_EVENT_TIMEOUT_CHECK; 1961 event[1] = sizeof(event) - 2; 1962 bt_store_16(event, 2, conn->con_handle); 1963 hci_dump_packet(HCI_EVENT_PACKET, 0, event, sizeof(event)); 1964 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 1965 } 1966 1967 void hci_emit_nr_connections_changed(){ 1968 log_info("BTSTACK_EVENT_NR_CONNECTIONS_CHANGED %u", nr_hci_connections()); 1969 uint8_t event[3]; 1970 event[0] = BTSTACK_EVENT_NR_CONNECTIONS_CHANGED; 1971 event[1] = sizeof(event) - 2; 1972 event[2] = nr_hci_connections(); 1973 hci_dump_packet( HCI_EVENT_PACKET, 0, event, sizeof(event)); 1974 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 1975 } 1976 1977 void hci_emit_hci_open_failed(){ 1978 log_info("BTSTACK_EVENT_POWERON_FAILED"); 1979 uint8_t event[2]; 1980 event[0] = BTSTACK_EVENT_POWERON_FAILED; 1981 event[1] = sizeof(event) - 2; 1982 hci_dump_packet( HCI_EVENT_PACKET, 0, event, sizeof(event)); 1983 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 1984 } 1985 1986 #ifndef EMBEDDED 1987 void hci_emit_btstack_version() { 1988 log_info("BTSTACK_EVENT_VERSION %u.%u", BTSTACK_MAJOR, BTSTACK_MINOR); 1989 uint8_t event[6]; 1990 event[0] = BTSTACK_EVENT_VERSION; 1991 event[1] = sizeof(event) - 2; 1992 event[2] = BTSTACK_MAJOR; 1993 event[3] = BTSTACK_MINOR; 1994 bt_store_16(event, 4, BTSTACK_REVISION); 1995 hci_dump_packet( HCI_EVENT_PACKET, 0, event, sizeof(event)); 1996 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 1997 } 1998 #endif 1999 2000 void hci_emit_system_bluetooth_enabled(uint8_t enabled){ 2001 log_info("BTSTACK_EVENT_SYSTEM_BLUETOOTH_ENABLED %u", enabled); 2002 uint8_t event[3]; 2003 event[0] = BTSTACK_EVENT_SYSTEM_BLUETOOTH_ENABLED; 2004 event[1] = sizeof(event) - 2; 2005 event[2] = enabled; 2006 hci_dump_packet( HCI_EVENT_PACKET, 0, event, sizeof(event)); 2007 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 2008 } 2009 2010 void hci_emit_remote_name_cached(bd_addr_t *addr, device_name_t *name){ 2011 uint8_t event[2+1+6+248+1]; // +1 for \0 in log_info 2012 event[0] = BTSTACK_EVENT_REMOTE_NAME_CACHED; 2013 event[1] = sizeof(event) - 2 - 1; 2014 event[2] = 0; // just to be compatible with HCI_EVENT_REMOTE_NAME_REQUEST_COMPLETE 2015 bt_flip_addr(&event[3], *addr); 2016 memcpy(&event[9], name, 248); 2017 2018 event[9+248] = 0; // assert \0 for log_info 2019 log_info("BTSTACK_EVENT_REMOTE_NAME_CACHED %s = '%s'", bd_addr_to_str(*addr), &event[9]); 2020 2021 hci_dump_packet(HCI_EVENT_PACKET, 0, event, sizeof(event)-1); 2022 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)-1); 2023 } 2024 2025 void hci_emit_discoverable_enabled(uint8_t enabled){ 2026 log_info("BTSTACK_EVENT_DISCOVERABLE_ENABLED %u", enabled); 2027 uint8_t event[3]; 2028 event[0] = BTSTACK_EVENT_DISCOVERABLE_ENABLED; 2029 event[1] = sizeof(event) - 2; 2030 event[2] = enabled; 2031 hci_dump_packet( HCI_EVENT_PACKET, 0, event, sizeof(event)); 2032 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 2033 } 2034 2035 void hci_emit_security_level(hci_con_handle_t con_handle, gap_security_level_t level){ 2036 log_info("hci_emit_security_level %u for handle %x", level, con_handle); 2037 uint8_t event[5]; 2038 int pos = 0; 2039 event[pos++] = GAP_SECURITY_LEVEL; 2040 event[pos++] = sizeof(event) - 2; 2041 bt_store_16(event, 2, con_handle); 2042 pos += 2; 2043 event[pos++] = level; 2044 hci_dump_packet( HCI_EVENT_PACKET, 0, event, sizeof(event)); 2045 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 2046 } 2047 2048 void hci_emit_dedicated_bonding_result(hci_connection_t * connection, uint8_t status){ 2049 log_info("hci_emit_dedicated_bonding_result %u ", status); 2050 uint8_t event[9]; 2051 int pos = 0; 2052 event[pos++] = GAP_DEDICATED_BONDING_COMPLETED; 2053 event[pos++] = sizeof(event) - 2; 2054 event[pos++] = status; 2055 bt_flip_addr( * (bd_addr_t *) &event[pos], connection->address); 2056 pos += 6; 2057 hci_dump_packet( HCI_EVENT_PACKET, 0, event, sizeof(event)); 2058 hci_stack->packet_handler(HCI_EVENT_PACKET, event, sizeof(event)); 2059 } 2060 2061 // query if remote side supports SSP 2062 int hci_remote_ssp_supported(hci_con_handle_t con_handle){ 2063 hci_connection_t * connection = hci_connection_for_handle(con_handle); 2064 if (!connection) return 0; 2065 return (connection->bonding_flags & BONDING_REMOTE_SUPPORTS_SSP) ? 1 : 0; 2066 } 2067 2068 int hci_ssp_supported_on_both_sides(hci_con_handle_t handle){ 2069 return hci_local_ssp_activated() && hci_remote_ssp_supported(handle); 2070 } 2071 2072 // GAP API 2073 /** 2074 * @bbrief enable/disable bonding. default is enabled 2075 * @praram enabled 2076 */ 2077 void gap_set_bondable_mode(int enable){ 2078 hci_stack->bondable = enable ? 1 : 0; 2079 } 2080 2081 /** 2082 * @brief map link keys to security levels 2083 */ 2084 gap_security_level_t gap_security_level_for_link_key_type(link_key_type_t link_key_type){ 2085 switch (link_key_type){ 2086 case AUTHENTICATED_COMBINATION_KEY_GENERATED_FROM_P256: 2087 return LEVEL_4; 2088 case COMBINATION_KEY: 2089 case AUTHENTICATED_COMBINATION_KEY_GENERATED_FROM_P192: 2090 return LEVEL_3; 2091 default: 2092 return LEVEL_2; 2093 } 2094 } 2095 2096 static gap_security_level_t gap_security_level_for_connection(hci_connection_t * connection){ 2097 if (!connection) return LEVEL_0; 2098 if ((connection->authentication_flags & CONNECTION_ENCRYPTED) == 0) return LEVEL_0; 2099 return gap_security_level_for_link_key_type(connection->link_key_type); 2100 } 2101 2102 2103 int gap_mitm_protection_required_for_security_level(gap_security_level_t level){ 2104 printf("gap_mitm_protection_required_for_security_level %u\n", level); 2105 return level > LEVEL_2; 2106 } 2107 2108 /** 2109 * @brief get current security level 2110 */ 2111 gap_security_level_t gap_security_level(hci_con_handle_t con_handle){ 2112 hci_connection_t * connection = hci_connection_for_handle(con_handle); 2113 if (!connection) return LEVEL_0; 2114 return gap_security_level_for_connection(connection); 2115 } 2116 2117 /** 2118 * @brief request connection to device to 2119 * @result GAP_AUTHENTICATION_RESULT 2120 */ 2121 void gap_request_security_level(hci_con_handle_t con_handle, gap_security_level_t requested_level){ 2122 hci_connection_t * connection = hci_connection_for_handle(con_handle); 2123 if (!connection){ 2124 hci_emit_security_level(con_handle, LEVEL_0); 2125 return; 2126 } 2127 gap_security_level_t current_level = gap_security_level(con_handle); 2128 log_info("gap_request_security_level %u, current level %u", requested_level, current_level); 2129 if (current_level >= requested_level){ 2130 hci_emit_security_level(con_handle, current_level); 2131 return; 2132 } 2133 2134 connection->requested_security_level = requested_level; 2135 2136 // would enabling ecnryption suffice (>= LEVEL_2)? 2137 if (hci_stack->remote_device_db){ 2138 link_key_type_t link_key_type; 2139 link_key_t link_key; 2140 if (hci_stack->remote_device_db->get_link_key( &connection->address, &link_key, &link_key_type)){ 2141 if (gap_security_level_for_link_key_type(link_key_type) >= requested_level){ 2142 connection->bonding_flags |= BONDING_SEND_ENCRYPTION_REQUEST; 2143 return; 2144 } 2145 } 2146 } 2147 2148 // try to authenticate connection 2149 connection->bonding_flags |= BONDING_SEND_AUTHENTICATE_REQUEST; 2150 hci_run(); 2151 } 2152 2153 /** 2154 * @brief start dedicated bonding with device. disconnect after bonding 2155 * @param device 2156 * @param request MITM protection 2157 * @result GAP_DEDICATED_BONDING_COMPLETE 2158 */ 2159 int gap_dedicated_bonding(bd_addr_t device, int mitm_protection_required){ 2160 2161 // create connection state machine 2162 hci_connection_t * connection = create_connection_for_bd_addr_and_type(device, BD_ADDR_TYPE_CLASSIC); 2163 2164 if (!connection){ 2165 return BTSTACK_MEMORY_ALLOC_FAILED; 2166 } 2167 2168 // delete linkn key 2169 hci_drop_link_key_for_bd_addr( (bd_addr_t *) &device); 2170 2171 // configure LEVEL_2/3, dedicated bonding 2172 connection->state = SEND_CREATE_CONNECTION; 2173 connection->requested_security_level = mitm_protection_required ? LEVEL_3 : LEVEL_2; 2174 printf("gap_dedicated_bonding, mitm %u -> level %u\n", mitm_protection_required, connection->requested_security_level); 2175 connection->bonding_flags = BONDING_DEDICATED; 2176 2177 // wait for GAP Security Result and send GAP Dedicated Bonding complete 2178 2179 // handle: connnection failure (connection complete != ok) 2180 // handle: authentication failure 2181 // handle: disconnect on done 2182 2183 hci_run(); 2184 2185 return 0; 2186 } 2187 2188 void gap_set_local_name(const char * local_name){ 2189 hci_stack->local_name = local_name; 2190 } 2191 2192 le_command_status_t le_central_start_scan(){ 2193 if (hci_stack->le_scanning_state == LE_SCANNING) return BLE_PERIPHERAL_OK; 2194 hci_stack->le_scanning_state = LE_START_SCAN; 2195 hci_run(); 2196 return BLE_PERIPHERAL_OK; 2197 } 2198 2199 le_command_status_t le_central_stop_scan(){ 2200 if ( hci_stack->le_scanning_state == LE_SCAN_IDLE) return BLE_PERIPHERAL_OK; 2201 hci_stack->le_scanning_state = LE_STOP_SCAN; 2202 hci_run(); 2203 return BLE_PERIPHERAL_OK; 2204 } 2205 2206 2207 le_command_status_t le_central_connect(bd_addr_t * addr, bd_addr_type_t addr_type){ 2208 hci_connection_t * conn = hci_connection_for_bd_addr_and_type(addr, addr_type); 2209 log_info("le_central_connect, conn struct %p", conn); 2210 if (!conn){ 2211 conn = create_connection_for_bd_addr_and_type(*addr, addr_type); 2212 if (!conn){ 2213 // notify client that alloc failed 2214 hci_emit_le_connection_complete(conn, BTSTACK_MEMORY_ALLOC_FAILED); 2215 return BLE_PERIPHERAL_NOT_CONNECTED; // don't sent packet to controller 2216 } 2217 conn->state = SEND_CREATE_CONNECTION; 2218 log_info("le_central_connect, state %u", conn->state); 2219 hci_run(); 2220 return BLE_PERIPHERAL_OK; 2221 } 2222 2223 if (!hci_is_le_connection(conn) || 2224 conn->state == SEND_CREATE_CONNECTION || 2225 conn->state == SENT_CREATE_CONNECTION) { 2226 hci_emit_le_connection_complete(conn, ERROR_CODE_COMMAND_DISALLOWED); 2227 return BLE_PERIPHERAL_IN_WRONG_STATE; 2228 } 2229 2230 log_info("le_central_connect, state %u", conn->state); 2231 hci_emit_le_connection_complete(conn, 0); 2232 hci_run(); 2233 return BLE_PERIPHERAL_OK; 2234 } 2235 2236 le_command_status_t le_central_connect_cancel(){ 2237 linked_item_t *it; 2238 for (it = (linked_item_t *) hci_stack->connections; it ; it = it->next){ 2239 hci_connection_t * conn = (hci_connection_t *) it; 2240 if (!hci_is_le_connection(conn)) continue; 2241 switch (conn->state){ 2242 case SEND_CREATE_CONNECTION: 2243 hci_emit_le_connection_complete(conn, ERROR_CODE_UNKNOWN_CONNECTION_IDENTIFIER); 2244 break; 2245 case SENT_CREATE_CONNECTION: 2246 conn->state = SEND_CANCEL_CONNECTION; 2247 hci_run(); 2248 break; 2249 default: 2250 break; 2251 }; 2252 } 2253 return BLE_PERIPHERAL_OK; 2254 } 2255 2256 le_command_status_t gap_disconnect(hci_con_handle_t handle){ 2257 hci_connection_t * conn = hci_connection_for_handle(handle); 2258 if (!conn){ 2259 hci_emit_disconnection_complete(conn, 0); 2260 return BLE_PERIPHERAL_OK; 2261 } 2262 conn->state = SEND_DISCONNECT; 2263 hci_run(); 2264 return BLE_PERIPHERAL_OK; 2265 } 2266