Compilation fix for newer mbed-os
Fork of X_NUCLEO_IDB0XA1 by
source/bluenrg-hci/hci/ble_hci.c
- Committer:
- Vincent Coubard
- Date:
- 2016-09-15
- Branch:
- 34e2f6254ad7de7fc7f377a0614c3a672cf7cd5c
- Revision:
- 280:fbee0e3444be
- Parent:
- source/bluenrg-hci/hci/hci.c@ 264:1e754a01869e
- Child:
- 294:fd19310b086d
File content as of revision 280:fbee0e3444be:
/** ****************************************************************************** * @file hci.c * @author AMS/HESA Application Team * @brief Function for managing HCI interface. ****************************************************************************** * * * THE PRESENT FIRMWARE WHICH IS FOR GUIDANCE ONLY AIMS AT PROVIDING CUSTOMERS * WITH CODING INFORMATION REGARDING THEIR PRODUCTS IN ORDER FOR THEM TO SAVE * TIME. AS A RESULT, STMICROELECTRONICS SHALL NOT BE HELD LIABLE FOR ANY * DIRECT, INDIRECT OR CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING * FROM THE CONTENT OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE * CODING INFORMATION CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS. * * <h2><center>© COPYRIGHT 2013 STMicroelectronics</center></h2> */ #include "hal_types.h" #include "osal.h" #include "ble_status.h" #include "hal.h" #include "hci_const.h" #include "gp_timer.h" #include "debug.h" #include "stm32_bluenrg_ble.h" #if BLE_CONFIG_DBG_ENABLE #undef PRINTF #endif #define HCI_LOG_ON 0 #define HCI_READ_PACKET_NUM_MAX (0x40) #define MIN(a,b) ((a) < (b) )? (a) : (b) #define MAX(a,b) ((a) > (b) )? (a) : (b) tListNode hciReadPktPool; tListNode hciReadPktRxQueue; // betzw - DEBUG: //#define POOL_CNT #ifdef POOL_CNT #include <stdio.h> static unsigned int nr_hciReadPktPool; static unsigned int lowest_nr_hciReadPktPool; #endif // POOL_CNT /* pool of hci read packets */ static tHciDataPacket hciReadPacketBuffer[HCI_READ_PACKET_NUM_MAX]; static volatile uint8_t readPacketListFull=FALSE; static volatile uint8_t hci_timer_id; static volatile uint8_t hci_timeout; void hci_timeout_callback(void) { hci_timeout = 1; return; } void HCI_Init(void) { uint8_t index; Disable_SPI_IRQ(); #ifdef POOL_CNT nr_hciReadPktPool = 0; #endif // POOL_CNT /* Initialize list heads of ready and free hci data packet queues */ list_init_head (&hciReadPktPool); list_init_head (&hciReadPktRxQueue); /* Initialize the queue of free hci data packets */ for (index = 0; index < HCI_READ_PACKET_NUM_MAX; index++) { list_insert_tail(&hciReadPktPool, (tListNode *)&hciReadPacketBuffer[index]); #ifdef POOL_CNT nr_hciReadPktPool++; #endif // POOL_CNT } #ifdef POOL_CNT lowest_nr_hciReadPktPool = nr_hciReadPktPool; #endif // POOL_CNT Enable_SPI_IRQ(); } #define HCI_PCK_TYPE_OFFSET 0 #define EVENT_PARAMETER_TOT_LEN_OFFSET 2 /** * Verify if HCI packet is correctly formatted.. * * @param[in] hciReadPacket The packet that is received from HCI interface. * @return 0 if HCI packet is as expected */ int HCI_verify(const tHciDataPacket * hciReadPacket) { const uint8_t *hci_pckt = hciReadPacket->dataBuff; if(hci_pckt[HCI_PCK_TYPE_OFFSET] != HCI_EVENT_PKT) return 1; /* Incorrect type. */ if(hci_pckt[EVENT_PARAMETER_TOT_LEN_OFFSET] != hciReadPacket->data_len - (1+HCI_EVENT_HDR_SIZE)) return 2; /* Wrong length (packet truncated or too long). */ return 0; } void HCI_Process(void) { uint8_t data_len; uint8_t buffer[HCI_READ_PACKET_SIZE]; tHciDataPacket * hciReadPacket = NULL; #ifdef POOL_CNT printf("betzw(%s, %d): nr_hciReadPktPool = %u (lowest = %u)\r\n", __func__, __LINE__, nr_hciReadPktPool, lowest_nr_hciReadPktPool); #endif // POOL_CNT Disable_SPI_IRQ(); uint8_t list_empty = list_is_empty(&hciReadPktRxQueue); /* process any pending events read */ while(list_empty == FALSE) { list_remove_head (&hciReadPktRxQueue, (tListNode **)&hciReadPacket); Enable_SPI_IRQ(); HCI_Event_CB(hciReadPacket->dataBuff); Disable_SPI_IRQ(); list_insert_tail(&hciReadPktPool, (tListNode *)hciReadPacket); #ifdef POOL_CNT nr_hciReadPktPool++; #endif list_empty = list_is_empty(&hciReadPktRxQueue); } if (readPacketListFull) { while(BlueNRG_DataPresent()) { data_len = BlueNRG_SPI_Read_All(buffer, HCI_READ_PACKET_SIZE); if(data_len > 0) HCI_Event_CB(buffer); } readPacketListFull = FALSE; } Enable_SPI_IRQ(); } BOOL HCI_Queue_Empty(void) { return list_is_empty(&hciReadPktRxQueue); } void HCI_Isr(void) { tHciDataPacket * hciReadPacket = NULL; uint8_t data_len; Clear_SPI_EXTI_Flag(); while(BlueNRG_DataPresent()){ if (list_is_empty (&hciReadPktPool) == FALSE){ /* enqueueing a packet for read */ list_remove_head (&hciReadPktPool, (tListNode **)&hciReadPacket); #ifdef POOL_CNT nr_hciReadPktPool--; if(nr_hciReadPktPool < lowest_nr_hciReadPktPool) lowest_nr_hciReadPktPool = nr_hciReadPktPool; #endif data_len = BlueNRG_SPI_Read_All(hciReadPacket->dataBuff, HCI_READ_PACKET_SIZE); if(data_len > 0){ hciReadPacket->data_len = data_len; if(HCI_verify(hciReadPacket) == 0) { list_insert_tail(&hciReadPktRxQueue, (tListNode *)hciReadPacket); signalEventsToProcess(); } else { list_insert_head(&hciReadPktPool, (tListNode *)hciReadPacket); #ifdef POOL_CNT nr_hciReadPktPool++; #endif } } else { // Insert the packet back into the pool. list_insert_head(&hciReadPktPool, (tListNode *)hciReadPacket); #ifdef POOL_CNT nr_hciReadPktPool++; #endif } } else{ // HCI Read Packet Pool is empty, wait for a free packet. signalEventsToProcess(); readPacketListFull = TRUE; Clear_SPI_EXTI_Flag(); return; } Clear_SPI_EXTI_Flag(); } } void hci_write(const void* data1, const void* data2, uint8_t n_bytes1, uint8_t n_bytes2){ #if HCI_LOG_ON PRINTF("HCI <- "); for(int i=0; i < n_bytes1; i++) PRINTF("%02X ", *((uint8_t*)data1 + i)); for(int i=0; i < n_bytes2; i++) PRINTF("%02X ", *((uint8_t*)data2 + i)); PRINTF("\n"); #endif Hal_Write_Serial(data1, data2, n_bytes1, n_bytes2); } void hci_send_cmd(uint16_t ogf, uint16_t ocf, uint8_t plen, void *param) { hci_command_hdr hc; hc.opcode = htobs(cmd_opcode_pack(ogf, ocf)); hc.plen= plen; uint8_t header[HCI_HDR_SIZE + HCI_COMMAND_HDR_SIZE]; header[0] = HCI_COMMAND_PKT; Osal_MemCpy(header+1, &hc, sizeof(hc)); hci_write(header, param, sizeof(header), plen); } static void move_list(tListNode * dest_list, tListNode * src_list) { pListNode tmp_node; while(!list_is_empty(src_list)){ list_remove_head(src_list, &tmp_node); list_insert_tail(dest_list, tmp_node); } } int hci_send_req(struct hci_request *r, BOOL async) { uint8_t *ptr; uint16_t opcode = htobs(cmd_opcode_pack(r->ogf, r->ocf)); hci_event_pckt *event_pckt; hci_uart_pckt *hci_hdr; int to = DEFAULT_TIMEOUT; struct timer t; tHciDataPacket * hciReadPacket = NULL; tListNode hciTempQueue; list_init_head(&hciTempQueue); hci_send_cmd(r->ogf, r->ocf, r->clen, r->cparam); if(async){ goto done; } /* Minimum timeout is 1. */ if(to == 0) to = 1; Timer_Set(&t, to); while(1) { evt_cmd_complete *cc; evt_cmd_status *cs; evt_le_meta_event *me; int len; #if ENABLE_MICRO_SLEEP while(1){ ATOMIC_SECTION_BEGIN(); if(Timer_Expired(&t)){ ATOMIC_SECTION_END(); goto failed; } if(!HCI_Queue_Empty()){ ATOMIC_SECTION_END(); break; } Enter_Sleep_Mode(); ATOMIC_SECTION_END(); } #else while(1){ if(Timer_Expired(&t)){ goto failed; } if(!HCI_Queue_Empty()){ break; } } #endif /* Extract packet from HCI event queue. */ Disable_SPI_IRQ(); list_remove_head(&hciReadPktRxQueue, (tListNode **)&hciReadPacket); hci_hdr = (void *)hciReadPacket->dataBuff; if(hci_hdr->type != HCI_EVENT_PKT){ list_insert_tail(&hciTempQueue, (tListNode *)hciReadPacket); // See comment below Enable_SPI_IRQ(); continue; } event_pckt = (void *) (hci_hdr->data); ptr = hciReadPacket->dataBuff + (1 + HCI_EVENT_HDR_SIZE); len = hciReadPacket->data_len - (1 + HCI_EVENT_HDR_SIZE); switch (event_pckt->evt) { case EVT_CMD_STATUS: cs = (void *) ptr; if (cs->opcode != opcode) goto failed; if (r->event != EVT_CMD_STATUS) { if (cs->status) { goto failed; } break; } r->rlen = MIN(len, r->rlen); Osal_MemCpy(r->rparam, ptr, r->rlen); goto done; case EVT_CMD_COMPLETE: cc = (void *) ptr; if (cc->opcode != opcode) goto failed; ptr += EVT_CMD_COMPLETE_SIZE; len -= EVT_CMD_COMPLETE_SIZE; r->rlen = MIN(len, r->rlen); Osal_MemCpy(r->rparam, ptr, r->rlen); goto done; case EVT_LE_META_EVENT: me = (void *) ptr; if (me->subevent != r->event) break; len -= 1; r->rlen = MIN(len, r->rlen); Osal_MemCpy(r->rparam, me->data, r->rlen); goto done; case EVT_HARDWARE_ERROR: goto failed; default: break; } /* In the meantime there could be other events from the controller. In this case, insert the packet in a different queue. These packets will be inserted back in the main queue just before exiting from send_req(). */ if(hciReadPacket != NULL) { list_insert_tail(&hciTempQueue, (tListNode *)hciReadPacket); hciReadPacket = NULL; } /* Be sure there is at list one packet in the pool to process the expected event. */ if(list_is_empty(&hciReadPktPool)){ // betzw: this is a kind of steeling (should never happen?!?) pListNode tmp_node; list_remove_head(&hciReadPktRxQueue, &tmp_node); list_insert_tail(&hciReadPktPool, tmp_node); #ifdef POOL_CNT nr_hciReadPktPool++; #endif } Enable_SPI_IRQ(); } failed: // Insert the packet back into the pool. if(hciReadPacket != NULL) { list_insert_head(&hciReadPktPool, (tListNode *)hciReadPacket); #ifdef POOL_CNT nr_hciReadPktPool++; #endif hciReadPacket = NULL; } move_list(&hciReadPktRxQueue, &hciTempQueue); Enable_SPI_IRQ(); return -1; done: // Insert the packet back into the pool. if(hciReadPacket != NULL) { list_insert_head(&hciReadPktPool, (tListNode *)hciReadPacket); #ifdef POOL_CNT nr_hciReadPktPool++; #endif hciReadPacket = NULL; } move_list(&hciReadPktRxQueue, &hciTempQueue); Enable_SPI_IRQ(); return 0; } int hci_reset() { struct hci_request rq; uint8_t status; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_HOST_CTL; rq.ocf = OCF_RESET; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_disconnect(uint16_t handle, uint8_t reason) { struct hci_request rq; disconnect_cp cp; uint8_t status; cp.handle = handle; cp.reason = reason; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LINK_CTL; rq.ocf = OCF_DISCONNECT; rq.cparam = &cp; rq.clen = DISCONNECT_CP_SIZE; rq.event = EVT_CMD_STATUS; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_le_read_local_version(uint8_t *hci_version, uint16_t *hci_revision, uint8_t *lmp_pal_version, uint16_t *manufacturer_name, uint16_t *lmp_pal_subversion) { struct hci_request rq; read_local_version_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_INFO_PARAM; rq.ocf = OCF_READ_LOCAL_VERSION; rq.cparam = NULL; rq.clen = 0; rq.rparam = &resp; rq.rlen = READ_LOCAL_VERSION_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; if (resp.status) { return resp.status; } *hci_version = resp.hci_version; *hci_revision = btohs(resp.hci_revision); *lmp_pal_version = resp.lmp_pal_version; *manufacturer_name = btohs(resp.manufacturer_name); *lmp_pal_subversion = btohs(resp.lmp_pal_subversion); return 0; } int hci_le_read_buffer_size(uint16_t *pkt_len, uint8_t *max_pkt) { struct hci_request rq; le_read_buffer_size_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_READ_BUFFER_SIZE; rq.cparam = NULL; rq.clen = 0; rq.rparam = &resp; rq.rlen = LE_READ_BUFFER_SIZE_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; if (resp.status) { return resp.status; } *pkt_len = resp.pkt_len; *max_pkt = resp.max_pkt; return 0; } int hci_le_set_advertising_parameters(uint16_t min_interval, uint16_t max_interval, uint8_t advtype, uint8_t own_bdaddr_type, uint8_t direct_bdaddr_type, const tBDAddr direct_bdaddr, uint8_t chan_map, uint8_t filter) { struct hci_request rq; le_set_adv_parameters_cp adv_cp; uint8_t status; Osal_MemSet(&adv_cp, 0, sizeof(adv_cp)); adv_cp.min_interval = min_interval; adv_cp.max_interval = max_interval; adv_cp.advtype = advtype; adv_cp.own_bdaddr_type = own_bdaddr_type; adv_cp.direct_bdaddr_type = direct_bdaddr_type; if(direct_bdaddr != NULL) Osal_MemCpy(adv_cp.direct_bdaddr,direct_bdaddr,sizeof(adv_cp.direct_bdaddr)); adv_cp.chan_map = chan_map; adv_cp.filter = filter; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_SET_ADV_PARAMETERS; rq.cparam = &adv_cp; rq.clen = LE_SET_ADV_PARAMETERS_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_le_set_advertising_data(uint8_t length, const uint8_t data[]) { struct hci_request rq; le_set_adv_data_cp adv_cp; uint8_t status; Osal_MemSet(&adv_cp, 0, sizeof(adv_cp)); adv_cp.length = length; Osal_MemCpy(adv_cp.data, data, MIN(31,length)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_SET_ADV_DATA; rq.cparam = &adv_cp; rq.clen = LE_SET_ADV_DATA_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_le_set_advertise_enable(uint8_t enable) { struct hci_request rq; le_set_advertise_enable_cp adv_cp; uint8_t status; Osal_MemSet(&adv_cp, 0, sizeof(adv_cp)); adv_cp.enable = enable?1:0; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_SET_ADVERTISE_ENABLE; rq.cparam = &adv_cp; rq.clen = LE_SET_ADVERTISE_ENABLE_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_le_set_scan_parameters(uint8_t type, uint16_t interval, uint16_t window, uint8_t own_bdaddr_type, uint8_t filter) { struct hci_request rq; le_set_scan_parameters_cp scan_cp; uint8_t status; Osal_MemSet(&scan_cp, 0, sizeof(scan_cp)); scan_cp.type = type; scan_cp.interval = interval; scan_cp.window = window; scan_cp.own_bdaddr_type = own_bdaddr_type; scan_cp.filter = filter; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_SET_SCAN_PARAMETERS; rq.cparam = &scan_cp; rq.clen = LE_SET_SCAN_PARAMETERS_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_le_set_scan_enable(uint8_t enable, uint8_t filter_dup) { struct hci_request rq; le_set_scan_enable_cp scan_cp; uint8_t status; Osal_MemSet(&scan_cp, 0, sizeof(scan_cp)); scan_cp.enable = enable?1:0; scan_cp.filter_dup = filter_dup; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_SET_SCAN_ENABLE; rq.cparam = &scan_cp; rq.clen = LE_SET_SCAN_ENABLE_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_le_rand(uint8_t random_number[8]) { struct hci_request rq; le_rand_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_RAND; rq.cparam = NULL; rq.clen = 0; rq.rparam = &resp; rq.rlen = LE_RAND_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; if (resp.status) { return resp.status; } Osal_MemCpy(random_number, resp.random, 8); return 0; } int hci_le_set_scan_resp_data(uint8_t length, const uint8_t data[]) { struct hci_request rq; le_set_scan_response_data_cp scan_resp_cp; uint8_t status; Osal_MemSet(&scan_resp_cp, 0, sizeof(scan_resp_cp)); scan_resp_cp.length = length; Osal_MemCpy(scan_resp_cp.data, data, MIN(31,length)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_SET_SCAN_RESPONSE_DATA; rq.cparam = &scan_resp_cp; rq.clen = LE_SET_SCAN_RESPONSE_DATA_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_le_read_advertising_channel_tx_power(int8_t *tx_power_level) { struct hci_request rq; le_read_adv_channel_tx_power_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_READ_ADV_CHANNEL_TX_POWER; rq.cparam = NULL; rq.clen = 0; rq.rparam = &resp; rq.rlen = LE_RAND_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; if (resp.status) { return resp.status; } *tx_power_level = resp.level; return 0; } int hci_le_set_random_address(tBDAddr bdaddr) { struct hci_request rq; le_set_random_address_cp set_rand_addr_cp; uint8_t status; Osal_MemSet(&set_rand_addr_cp, 0, sizeof(set_rand_addr_cp)); Osal_MemCpy(set_rand_addr_cp.bdaddr, bdaddr, sizeof(tBDAddr)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_SET_RANDOM_ADDRESS; rq.cparam = &set_rand_addr_cp; rq.clen = LE_SET_RANDOM_ADDRESS_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_read_bd_addr(tBDAddr bdaddr) { struct hci_request rq; read_bd_addr_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_INFO_PARAM; rq.ocf = OCF_READ_BD_ADDR; rq.cparam = NULL; rq.clen = 0; rq.rparam = &resp; rq.rlen = READ_BD_ADDR_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; if (resp.status) { return resp.status; } Osal_MemCpy(bdaddr, resp.bdaddr, sizeof(tBDAddr)); return 0; } int hci_le_create_connection(uint16_t interval, uint16_t window, uint8_t initiator_filter, uint8_t peer_bdaddr_type, const tBDAddr peer_bdaddr, uint8_t own_bdaddr_type, uint16_t min_interval, uint16_t max_interval, uint16_t latency, uint16_t supervision_timeout, uint16_t min_ce_length, uint16_t max_ce_length) { struct hci_request rq; le_create_connection_cp create_cp; uint8_t status; Osal_MemSet(&create_cp, 0, sizeof(create_cp)); create_cp.interval = interval; create_cp.window = window; create_cp.initiator_filter = initiator_filter; create_cp.peer_bdaddr_type = peer_bdaddr_type; Osal_MemCpy(create_cp.peer_bdaddr, peer_bdaddr, sizeof(tBDAddr)); create_cp.own_bdaddr_type = own_bdaddr_type; create_cp.min_interval=min_interval; create_cp.max_interval=max_interval; create_cp.latency = latency; create_cp.supervision_timeout=supervision_timeout; create_cp.min_ce_length=min_ce_length; create_cp.max_ce_length=max_ce_length; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_CREATE_CONN; rq.cparam = &create_cp; rq.clen = LE_CREATE_CONN_CP_SIZE; rq.event = EVT_CMD_STATUS; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_le_create_connection_cancel(void) { struct hci_request rq; uint8_t status; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_CREATE_CONN_CANCEL; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return status; } int hci_le_encrypt(uint8_t key[16], uint8_t plaintextData[16], uint8_t encryptedData[16]) { struct hci_request rq; le_encrypt_cp params; le_encrypt_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); Osal_MemCpy(params.key, key, 16); Osal_MemCpy(params.plaintext, plaintextData, 16); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_ENCRYPT; rq.cparam = ¶ms; rq.clen = LE_ENCRYPT_CP_SIZE; rq.rparam = &resp; rq.rlen = LE_ENCRYPT_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } if (resp.status) { return resp.status; } Osal_MemCpy(encryptedData, resp.encdata, 16); return 0; } int hci_le_ltk_request_reply(uint8_t key[16]) { struct hci_request rq; le_ltk_reply_cp params; le_ltk_reply_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); params.handle = 1; Osal_MemCpy(params.key, key, 16); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_LTK_REPLY; rq.cparam = ¶ms; rq.clen = LE_LTK_REPLY_CP_SIZE; rq.rparam = &resp; rq.rlen = LE_LTK_REPLY_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return resp.status; } int hci_le_ltk_request_neg_reply() { struct hci_request rq; le_ltk_neg_reply_cp params; le_ltk_neg_reply_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); params.handle = 1; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_LTK_NEG_REPLY; rq.cparam = ¶ms; rq.clen = LE_LTK_NEG_REPLY_CP_SIZE; rq.rparam = &resp; rq.rlen = LE_LTK_NEG_REPLY_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0) return BLE_STATUS_TIMEOUT; return resp.status; } int hci_le_read_white_list_size(uint8_t *size) { struct hci_request rq; le_read_white_list_size_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_READ_WHITE_LIST_SIZE; rq.rparam = &resp; rq.rlen = LE_READ_WHITE_LIST_SIZE_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } if (resp.status) { return resp.status; } *size = resp.size; return 0; } int hci_le_clear_white_list() { struct hci_request rq; uint8_t status; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_CLEAR_WHITE_LIST; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } return status; } int hci_le_add_device_to_white_list(uint8_t bdaddr_type, tBDAddr bdaddr) { struct hci_request rq; le_add_device_to_white_list_cp params; uint8_t status; params.bdaddr_type = bdaddr_type; Osal_MemCpy(params.bdaddr, bdaddr, 6); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_ADD_DEVICE_TO_WHITE_LIST; rq.cparam = ¶ms; rq.clen = LE_ADD_DEVICE_TO_WHITE_LIST_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } return status; } int hci_le_remove_device_from_white_list(uint8_t bdaddr_type, tBDAddr bdaddr) { struct hci_request rq; le_remove_device_from_white_list_cp params; uint8_t status; params.bdaddr_type = bdaddr_type; Osal_MemCpy(params.bdaddr, bdaddr, 6); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_REMOVE_DEVICE_FROM_WHITE_LIST; rq.cparam = ¶ms; rq.clen = LE_REMOVE_DEVICE_FROM_WHITE_LIST_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } return status; } int hci_read_transmit_power_level(uint16_t *conn_handle, uint8_t type, int8_t * tx_level) { struct hci_request rq; read_transmit_power_level_cp params; read_transmit_power_level_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); params.handle = *conn_handle; params.type = type; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_HOST_CTL; rq.ocf = OCF_READ_TRANSMIT_POWER_LEVEL; rq.cparam = ¶ms; rq.clen = READ_TRANSMIT_POWER_LEVEL_CP_SIZE; rq.rparam = &resp; rq.rlen = READ_TRANSMIT_POWER_LEVEL_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } if (resp.status) { return resp.status; } *conn_handle = resp.handle; *tx_level = resp.level; return 0; } int hci_read_rssi(uint16_t *conn_handle, int8_t * rssi) { struct hci_request rq; read_rssi_cp params; read_rssi_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); params.handle = *conn_handle; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_STATUS_PARAM; rq.ocf = OCF_READ_RSSI; rq.cparam = ¶ms; rq.clen = READ_RSSI_CP_SIZE; rq.rparam = &resp; rq.rlen = READ_RSSI_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } if (resp.status) { return resp.status; } *conn_handle = resp.handle; *rssi = resp.rssi; return 0; } int hci_le_read_local_supported_features(uint8_t *features) { struct hci_request rq; le_read_local_supported_features_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_READ_LOCAL_SUPPORTED_FEATURES; rq.rparam = &resp; rq.rlen = LE_READ_LOCAL_SUPPORTED_FEATURES_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } if (resp.status) { return resp.status; } Osal_MemCpy(features, resp.features, sizeof(resp.features)); return 0; } int hci_le_read_channel_map(uint16_t conn_handle, uint8_t ch_map[5]) { struct hci_request rq; le_read_channel_map_cp params; le_read_channel_map_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); params.handle = conn_handle; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_READ_CHANNEL_MAP; rq.cparam = ¶ms; rq.clen = LE_READ_CHANNEL_MAP_CP_SIZE; rq.rparam = &resp; rq.rlen = LE_READ_CHANNEL_MAP_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } if (resp.status) { return resp.status; } Osal_MemCpy(ch_map, resp.map, 5); return 0; } int hci_le_read_supported_states(uint8_t states[8]) { struct hci_request rq; le_read_supported_states_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_READ_SUPPORTED_STATES; rq.rparam = &resp; rq.rlen = LE_READ_SUPPORTED_STATES_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } if (resp.status) { return resp.status; } Osal_MemCpy(states, resp.states, 8); return 0; } int hci_le_receiver_test(uint8_t frequency) { struct hci_request rq; le_receiver_test_cp params; uint8_t status; params.frequency = frequency; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_RECEIVER_TEST; rq.cparam = ¶ms; rq.clen = LE_RECEIVER_TEST_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } return status; } int hci_le_transmitter_test(uint8_t frequency, uint8_t length, uint8_t payload) { struct hci_request rq; le_transmitter_test_cp params; uint8_t status; params.frequency = frequency; params.length = length; params.payload = payload; Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_TRANSMITTER_TEST; rq.cparam = ¶ms; rq.clen = LE_TRANSMITTER_TEST_CP_SIZE; rq.rparam = &status; rq.rlen = 1; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } return status; } int hci_le_test_end(uint16_t *num_pkts) { struct hci_request rq; le_test_end_rp resp; Osal_MemSet(&resp, 0, sizeof(resp)); Osal_MemSet(&rq, 0, sizeof(rq)); rq.ogf = OGF_LE_CTL; rq.ocf = OCF_LE_TEST_END; rq.rparam = &resp; rq.rlen = LE_TEST_END_RP_SIZE; if (hci_send_req(&rq, FALSE) < 0){ return BLE_STATUS_TIMEOUT; } if (resp.status) { return resp.status; } *num_pkts = resp.num_pkts; return 0; }