flipperzero-firmware/firmware/targets/f7/ble-glue/ble_app.c

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#include "ble_app.h"
#include "hci_tl.h"
#include "ble.h"
#include "shci.h"
#include "gap.h"
#include <furi-hal.h>
#define TAG "Bt"
#define BLE_APP_FLAG_HCI_EVENT (1UL << 0)
#define BLE_APP_FLAG_KILL_THREAD (1UL << 1)
#define BLE_APP_FLAG_ALL (BLE_APP_FLAG_HCI_EVENT | BLE_APP_FLAG_KILL_THREAD)
PLACE_IN_SECTION("MB_MEM1") ALIGN(4) static TL_CmdPacket_t ble_app_cmd_buffer;
PLACE_IN_SECTION("MB_MEM2") ALIGN(4) static uint32_t ble_app_nvm[BLE_NVM_SRAM_SIZE];
typedef struct {
osMutexId_t hci_mtx;
osSemaphoreId_t hci_sem;
FuriThread* thread;
osEventFlagsId_t event_flags;
} BleApp;
static BleApp* ble_app = NULL;
static int32_t ble_app_hci_thread(void* context);
static void ble_app_hci_event_handler(void* pPayload);
static void ble_app_hci_status_not_handler(HCI_TL_CmdStatus_t status);
bool ble_app_init() {
SHCI_CmdStatus_t status;
ble_app = furi_alloc(sizeof(BleApp));
// Allocate semafore and mutex for ble command buffer access
ble_app->hci_mtx = osMutexNew(NULL);
ble_app->hci_sem = osSemaphoreNew(1, 0, NULL);
ble_app->event_flags = osEventFlagsNew(NULL);
// HCI transport layer thread to handle user asynch events
ble_app->thread = furi_thread_alloc();
furi_thread_set_name(ble_app->thread, "BleHciWorker");
furi_thread_set_stack_size(ble_app->thread, 1024);
furi_thread_set_context(ble_app->thread, ble_app);
furi_thread_set_callback(ble_app->thread, ble_app_hci_thread);
furi_thread_start(ble_app->thread);
// Initialize Ble Transport Layer
HCI_TL_HciInitConf_t hci_tl_config = {
.p_cmdbuffer = (uint8_t*)&ble_app_cmd_buffer,
.StatusNotCallBack = ble_app_hci_status_not_handler,
};
hci_init(ble_app_hci_event_handler, (void*)&hci_tl_config);
// Configure NVM store for pairing data
SHCI_C2_CONFIG_Cmd_Param_t config_param = {
.PayloadCmdSize = SHCI_C2_CONFIG_PAYLOAD_CMD_SIZE,
.Config1 =SHCI_C2_CONFIG_CONFIG1_BIT0_BLE_NVM_DATA_TO_SRAM,
.BleNvmRamAddress = (uint32_t)ble_app_nvm,
.EvtMask1 = SHCI_C2_CONFIG_EVTMASK1_BIT1_BLE_NVM_RAM_UPDATE_ENABLE,
};
status = SHCI_C2_Config(&config_param);
if(status) {
FURI_LOG_E(TAG, "Failed to configure 2nd core: %d", status);
}
// Start ble stack on 2nd core
SHCI_C2_Ble_Init_Cmd_Packet_t ble_init_cmd_packet = {
.Header = {{0,0,0}}, // Header unused
.Param = {
.pBleBufferAddress = 0, // pBleBufferAddress not used
.BleBufferSize = 0, // BleBufferSize not used
.NumAttrRecord = CFG_BLE_NUM_GATT_ATTRIBUTES,
.NumAttrServ = CFG_BLE_NUM_GATT_SERVICES,
.AttrValueArrSize = CFG_BLE_ATT_VALUE_ARRAY_SIZE,
.NumOfLinks = CFG_BLE_NUM_LINK,
.ExtendedPacketLengthEnable = CFG_BLE_DATA_LENGTH_EXTENSION,
.PrWriteListSize = CFG_BLE_PREPARE_WRITE_LIST_SIZE,
.MblockCount = CFG_BLE_MBLOCK_COUNT,
.AttMtu = CFG_BLE_MAX_ATT_MTU,
.SlaveSca = CFG_BLE_SLAVE_SCA,
.MasterSca = CFG_BLE_MASTER_SCA,
.LsSource = CFG_BLE_LSE_SOURCE,
.MaxConnEventLength = CFG_BLE_MAX_CONN_EVENT_LENGTH,
.HsStartupTime = CFG_BLE_HSE_STARTUP_TIME,
.ViterbiEnable = CFG_BLE_VITERBI_MODE,
.Options = CFG_BLE_OPTIONS,
.HwVersion = 0,
.max_coc_initiator_nbr = 32,
.min_tx_power = 0,
.max_tx_power = 0,
.rx_model_config = 1,
}
};
status = SHCI_C2_BLE_Init(&ble_init_cmd_packet);
if(status) {
FURI_LOG_E(TAG, "Failed to start ble stack: %d", status);
}
return status == SHCI_Success;
}
void ble_app_get_key_storage_buff(uint8_t** addr, uint16_t* size) {
*addr = (uint8_t*)ble_app_nvm;
*size = sizeof(ble_app_nvm);
}
void ble_app_thread_stop() {
if(ble_app) {
osEventFlagsSet(ble_app->event_flags, BLE_APP_FLAG_KILL_THREAD);
furi_thread_join(ble_app->thread);
furi_thread_free(ble_app->thread);
// Wait to make sure that EventFlags delivers pending events before memory free
osDelay(50);
// Free resources
osMutexDelete(ble_app->hci_mtx);
osSemaphoreDelete(ble_app->hci_sem);
osEventFlagsDelete(ble_app->event_flags);
free(ble_app);
ble_app = NULL;
memset(&ble_app_cmd_buffer, 0, sizeof(ble_app_cmd_buffer));
}
}
static int32_t ble_app_hci_thread(void *arg) {
uint32_t flags = 0;
while(1) {
flags = osEventFlagsWait(ble_app->event_flags, BLE_APP_FLAG_ALL, osFlagsWaitAny, osWaitForever);
if(flags & BLE_APP_FLAG_KILL_THREAD) {
break;
}
if(flags & BLE_APP_FLAG_HCI_EVENT) {
hci_user_evt_proc();
}
}
return 0;
}
// Called by WPAN lib
void hci_notify_asynch_evt(void* pdata) {
if(ble_app) {
osEventFlagsSet(ble_app->event_flags, BLE_APP_FLAG_HCI_EVENT);
}
}
void hci_cmd_resp_release(uint32_t flag) {
if(ble_app) {
osSemaphoreRelease(ble_app->hci_sem);
}
}
void hci_cmd_resp_wait(uint32_t timeout) {
if(ble_app) {
osSemaphoreAcquire(ble_app->hci_sem, osWaitForever);
}
}
static void ble_app_hci_event_handler( void * pPayload ) {
SVCCTL_UserEvtFlowStatus_t svctl_return_status;
tHCI_UserEvtRxParam *pParam = (tHCI_UserEvtRxParam *)pPayload;
if(ble_app) {
svctl_return_status = SVCCTL_UserEvtRx((void *)&(pParam->pckt->evtserial));
if (svctl_return_status != SVCCTL_UserEvtFlowDisable) {
pParam->status = HCI_TL_UserEventFlow_Enable;
} else {
pParam->status = HCI_TL_UserEventFlow_Disable;
}
}
}
static void ble_app_hci_status_not_handler( HCI_TL_CmdStatus_t status ) {
if(status == HCI_TL_CmdBusy) {
osMutexAcquire(ble_app->hci_mtx, osWaitForever );
} else if(status == HCI_TL_CmdAvailable) {
osMutexRelease(ble_app->hci_mtx);
}
}
void SVCCTL_ResumeUserEventFlow( void ) {
hci_resume_flow();
}