/**
* send the bluetooth link state query to KW40
*/
void watch_SendGetLinkStateReq()
{
static hostInterface_packet_t dataPacket =
{
.start1 = gHostInterface_startByte1,
.start2 = gHostInterface_startByte2,
.length = 0,
.data[0] = gHostInterface_trailerByte
};
dataPacket.type = packetType_linkStateGet;
while(HostInterface_TxQueueMsgPut((hostInterface_packet_t *)&dataPacket, true) != kStatus_OSA_Success);
}
/**
* wait for the bluetooth link state query response from KW40
* @param timeout timeout value in [ms]
* @return status flag
*/
osa_status_t watch_WaitForLinkStateUpdate( uint32_t timeout )
{
osa_status_t status;
event_flags_t setFlags;
status = OSA_EventWait( &watch_event, linkStateUpdate_eventFlag, false, timeout, &setFlags );
if ( kStatus_OSA_Success != status )
{
return kStatus_OSA_Error;
}
return (osa_status_t)status;
}
uint32_t OS_Event_wait(os_event_handle handle, uint32_t bitmask, uint32_t flag, uint32_t timeout)
{
osa_status_t status = kStatus_OSA_Idle;
event_flags_t event_bit;
uint32_t re;
event_t* event = (event_t*) handle;
// flag will always be false, so wait any bits
#if (USE_RTOS)
if (0 == timeout)
{
timeout = OSA_WAIT_FOREVER;
}
#endif
// Block or timeout mode
do
{
status = OSA_EventWait(event, bitmask, flag, timeout, &event_bit);
} while (kStatus_OSA_Idle == status);
switch(status)
{
case kStatus_OSA_Success:
re = (uint32_t) OS_EVENT_OK;
break;
case kStatus_OSA_Timeout:
re = (uint32_t) OS_EVENT_TIMEOUT;
break;
default:
re = (uint32_t) OS_EVENT_ERROR;
break;
}
return re;
}
/*FUNCTION**********************************************************************
*
* Function Name : I2C_DRV_SlaveSendDataBlocking
* Description : Send the data using a blocking method.
* This function set buffer pointer and length to Tx buffer & Tx Size.
* Then wait until the transmission is end ( NAK is detected)
*
*END**************************************************************************/
i2c_status_t I2C_DRV_SlaveSendDataBlocking(uint32_t instance,
const uint8_t * txBuff,
uint32_t txSize,
uint32_t timeout_ms)
{
assert(txBuff);
assert(instance < HW_I2C_INSTANCE_COUNT);
i2c_slave_state_t * i2cSlaveState = (i2c_slave_state_t *)g_i2cStatePtr[instance];
if(!i2cSlaveState->slaveListening)
{
event_flags_t i2cIrqSetFlags;
osa_status_t syncStatus;
if (i2cSlaveState->isTxBusy)
{
return kStatus_I2C_Busy;
}
/* Initialize the module driver state structure. */
i2cSlaveState->txBuff = txBuff;
i2cSlaveState->txSize = txSize;
i2cSlaveState->isTxBusy = true;
i2cSlaveState->isTxBlocking = true;
#if FSL_FEATURE_I2C_HAS_START_STOP_DETECT
I2C_HAL_ClearStartFlag(g_i2cBaseAddr[instance]);
#endif
I2C_HAL_ClearInt(g_i2cBaseAddr[instance]);
I2C_HAL_SetIntCmd(g_i2cBaseAddr[instance], true);
/* Wait until the transmit is complete. */
do
{
syncStatus = OSA_EventWait(&i2cSlaveState->irqEvent,
kI2CSlaveTxNAK | kI2CSlaveAbort,
false,
timeout_ms,
&i2cIrqSetFlags);
} while(syncStatus == kStatus_OSA_Idle);
if (syncStatus != kStatus_OSA_Success)
{
I2C_HAL_SetIntCmd(g_i2cBaseAddr[instance], false);
i2cSlaveState->status = kStatus_I2C_Timeout;
}
i2cSlaveState->isTxBlocking = false;
return i2cSlaveState->status;
}
else /* i2cSlaveState->slaveListening */
{
return kStatus_I2C_Fail;
}
}
/*FUNCTION**********************************************************************
*
* Function Name : SPI_DRV_DmaSlaveTransferBlocking
* Description : Transfer data with the master, using blocking call and DMA
* driven.
*
*END**************************************************************************/
spi_status_t SPI_DRV_DmaSlaveTransferBlocking(uint32_t instance,
const uint8_t *sendBuffer,
uint8_t *receiveBuffer,
uint32_t transferByteCount,
uint32_t timeout)
{
spi_dma_slave_state_t * spiState = (spi_dma_slave_state_t *)g_spiStatePtr[instance];
spi_status_t errorStatus = kStatus_SPI_Success;
event_flags_t setFlags = 0;
/* fill in members of the run-time state struct */
spiState->isSync = true;
spiState->sendBuffer = (const uint8_t *)sendBuffer;
spiState->receiveBuffer = (uint8_t *)receiveBuffer;
spiState->remainingSendByteCount = transferByteCount;
spiState->remainingReceiveByteCount = transferByteCount;
/* Clear the event flags */
OSA_EventClear(&spiState->event, kSpiDmaTransferDone);
errorStatus = SPI_DRV_DmaSlaveStartTransfer(instance);
if (errorStatus != kStatus_SPI_Success)
{
return errorStatus;
}
/* As this is a synchronous transfer, wait until the transfer is complete. */
osa_status_t syncStatus;
do
{
syncStatus = OSA_EventWait(&spiState->event, kSpiDmaTransferDone, true, timeout, &setFlags);
}while(syncStatus == kStatus_OSA_Idle);
if (syncStatus != kStatus_OSA_Success)
{
/* Abort the transfer so it doesn't continue unexpectedly. */
SPI_DRV_DmaSlaveAbortTransfer(instance);
errorStatus = kStatus_SPI_Timeout;
}
return errorStatus;
}
/**
* update GUI upon analyzing data
* @param param optional parameter
*/
static void watch_GuiUpdateTask(task_param_t param)
{
osa_status_t status;
event_flags_t setFlags;
// Read active button group
//watch_SendGetLinkStateReq();
// check once in the beginning
watch_CheckBatteryStatus();
while(1)
{
status = OSA_EventWait(
&watch_event,
( linkStateUpdate_eventFlag | timeUpdate_eventFlag | dateUpdate_eventFlag |
tempUpdate_eventFlag | batteryUpdate_eventFlag | chargDetect_eventFlag | notifDetect_eventFlag ),
false,
OSA_WAIT_FOREVER,
&setFlags
);
if ( kStatus_OSA_Success != status )
{
continue;
}
if(setFlags & timeUpdate_eventFlag)
{
GuiDriver_LabelDraw(&watch_labelTime);
}
if(setFlags & dateUpdate_eventFlag)
{
GuiDriver_LabelDraw(&watch_labelDate);
}
if(setFlags & batteryUpdate_eventFlag)
{
watch_UpdateBatteryLevel(batteryLevel);
}
if(setFlags & chargDetect_eventFlag)
{
if ( true == watch_IsBatteryCharging() )
{
watch_imgBattery.img = (const uint8_t*)battery_charge_bmp;
GuiDriver_ImageDraw( &watch_imgBattery );
}
else
{
sensor_ResetPacketcounter( PACKET_BAT );
}
}
if(setFlags & tempUpdate_eventFlag)
{
GuiDriver_LabelDraw(&watch_labelTemp);
}
if(setFlags & linkStateUpdate_eventFlag)
{
if(watch_linkState == linkState_connected)
{
watch_imgBluetoothLogo.img = watch_bluetooth_logo_blue_bmp;
}
else
{
watch_imgBluetoothLogo.img = watch_bluetooth_logo_white_bmp;
}
GuiDriver_ImageDraw(&watch_imgBluetoothLogo);
}
if ( setFlags & notifDetect_eventFlag )
{
// Check for notifications
if( 0 != Notification_GetUnreadCounter( NOTIF_TYPE_CALL ) )
{
watch_imgCall.img = watch_phone_call_bmp;
}
else
{
watch_imgCall.img = watch_phone_call_gray_bmp;
}
if( 0 != Notification_GetUnreadCounter( NOTIF_TYPE_MAIL) )
{
watch_imgMail.img = watch_mail_bmp;
}
else
{
watch_imgMail.img = watch_mail_gray_bmp;
}
if( 0 != Notification_GetUnreadCounter( NOTIF_TYPE_SMS ) )
{
watch_imgSms.img = watch_sms_bmp;
}
else
{
watch_imgSms.img = watch_sms_gray_bmp;
}
GuiDriver_ImageDraw( &watch_imgCall );
GuiDriver_ImageDraw( &watch_imgMail);
GuiDriver_ImageDraw( &watch_imgSms );
}
}
}
/*FUNCTION**********************************************************************
*
* Function Name : I2C_DRV_SlaveReceiveDataBlocking
* Description : Receive the data using a blocking method.
* This function set buffer pointer and length to Rx buffer &Rx Size. Then wait
* until the transmission is end (all data are received or STOP signal is
* detected)
*
*END*/
i2c_status_t I2C_DRV_SlaveReceiveDataBlocking(uint32_t instance,
uint8_t * rxBuff,
uint32_t rxSize,
uint32_t timeout_ms)
{
assert(rxBuff);
assert(instance < I2C_INSTANCE_COUNT);
i2c_slave_state_t * i2cSlaveState = (i2c_slave_state_t *)g_i2cStatePtr[instance];
if(!i2cSlaveState->slaveListening)
{
event_flags_t i2cIrqSetFlags;
osa_status_t syncStatus;
if (i2cSlaveState->isRxBusy)
{
return kStatus_I2C_Busy;
}
i2cSlaveState->rxBuff = rxBuff;
i2cSlaveState->rxSize = rxSize;
i2cSlaveState->isRxBusy = true;
i2cSlaveState->isRxBlocking = true;
/** If IAAS event already comes, read dummy to release the bus.*/
if(I2C_HAL_GetStatusFlag(g_i2cBase[instance], kI2CAddressAsSlave))
{
/** Switch to RX mode.*/
I2C_HAL_SetDirMode(g_i2cBase[instance], kI2CReceive);
I2C_HAL_ReadByte(g_i2cBase[instance]);
}
I2C_HAL_SetIntCmd(g_i2cBase[instance], true);
/** Wait until the transmit is complete. */
do
{
syncStatus = OSA_EventWait(&i2cSlaveState->irqEvent,
#if (FSL_FEATURE_I2C_HAS_START_STOP_DETECT || FSL_FEATURE_I2C_HAS_STOP_DETECT)
kI2CSlaveStopDetect |
#endif
kI2CSlaveRxFull | kI2CSlaveAbort,
false,
timeout_ms,
&i2cIrqSetFlags);
} while(syncStatus == kStatus_OSA_Idle);
if (syncStatus != kStatus_OSA_Success)
{
I2C_HAL_SetIntCmd(g_i2cBase[instance], false);
i2cSlaveState->status = kStatus_I2C_Timeout;
}
i2cSlaveState->isRxBlocking = false;
return i2cSlaveState->status;
}
else /** i2cSlaveState->slaveListening */
{
return kStatus_I2C_Fail;
}
}
void bluetooth_SendGetAdvModeReq(void)
{
static hostInterface_packet_t dataPacket =
{
.start1 = gHostInterface_startByte1,
.start2 = gHostInterface_startByte2,
.length = 0,
.data[0] = gHostInterface_trailerByte
};
dataPacket.type = packetType_advModeGet;
while(HostInterface_TxQueueMsgPut((hostInterface_packet_t *)&dataPacket, true) != kStatus_OSA_Success);
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
void bluetooth_SendToggleAdvModeReq(void)
{
static hostInterface_packet_t dataPacket =
{
.start1 = gHostInterface_startByte1,
.start2 = gHostInterface_startByte2,
.length = 0,
.data[0] = gHostInterface_trailerByte
};
dataPacket.type = packetType_advModeToggle;
while(HostInterface_TxQueueMsgPut((hostInterface_packet_t *)&dataPacket, true) != kStatus_OSA_Success);
haptic_Vibrate();
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
/**
* [buttonsGroup_DestroyTasks description]
* @param param [description]
*/
osa_status_t bluetooth_WaitForAdvModeUpdate(uint32_t timeout)
{
osa_status_t status;
event_flags_t setFlags;
status = OSA_EventWait(&advModeUpdate_event, advModeUpdate_eventFlag, false, timeout, &setFlags);
if ( kStatus_OSA_Success != status )
{
return kStatus_OSA_Error;
}
return (osa_status_t)status;
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
/**
* [buttonsGroup_DestroyTasks description]
* @param param [description]
*/
osa_status_t bluetooth_AdvModeUpdate(bluetooth_advMode_t bluetooth_advMode)
{
OSA_EventSet( &advModeUpdate_event, (event_flags_t)advModeUpdate_eventFlag);
bluetoothCurrentAdvMode = bluetooth_advMode;
return kStatus_OSA_Success;
}
