Mercurial > public > ostc4
view Small_CPU/Src/uart.c @ 788:4abfb8a2a435
Define explicit setpoints for low / high / deco. Add an option to delay the switch to SPlow until all decompression has been cleared. (mikeller)
author | heinrichsweikamp |
---|---|
date | Tue, 04 Jul 2023 14:39:06 +0200 |
parents | aeb72882f30a |
children | bb37d4f3e50e |
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/** ****************************************************************************** * @file uart.c * @author heinrichs weikamp gmbh * @version V0.0.1 * @date 27-March-2014 * @brief button control * @verbatim ============================================================================== ##### How to use ##### ============================================================================== @endverbatim ****************************************************************************** * @attention * * <h2><center>© COPYRIGHT(c) 2015 heinrichs weikamp</center></h2> * ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include "uart.h" #include "externalInterface.h" #include "data_exchange.h" #include <string.h> /* memset */ /* Private variables ---------------------------------------------------------*/ #define BUFFER_NODATA (7u) /* The read function needs a byte which indecated that no data for processing is available.*/ /* This byte shall never appear in a normal data steam */ #define CHUNK_SIZE (25u) /* the DMA will handle chunk size transfers */ #define CHUNKS_PER_BUFFER (5u) #define COMMAND_TX_DELAY (30u) /* The time the sensor needs to recover from a invalid command request */ #define REQUEST_INT_SENSOR_MS (1500) /* Minimum time interval for cyclic sensor data requests per sensor */ UART_HandleTypeDef huart1; DMA_HandleTypeDef hdma_usart1_rx; uint8_t rxBuffer[CHUNK_SIZE * CHUNKS_PER_BUFFER]; /* The complete buffer has a X * chunk size to allow fariations in buffer read time */ static uint8_t rxWriteIndex; /* Index of the data item which is analysed */ static uint8_t rxReadIndex; /* Index at which new data is stared */ static uint8_t lastCmdIndex; /* Index of last command which has not been completly received */ static uint8_t dmaActive; /* Indicator if DMA reception needs to be started */ static uint8_t digO2Connected = 0; /* Binary indicator if a sensor is connected or not */ static uint8_t CO2Connected = 0; /* Binary indicator if a sensor is connected or not */ static uint8_t SentinelConnected = 0; /* Binary indicator if a sensor is connected or not */ static SSensorDataDiveO2 tmpSensorDataDiveO2; /* intermediate storage for additional sensor data */ char tmpRxBuf[30]; uint8_t tmpRxIdx = 0; static uartO2Status_t Comstatus_O2 = UART_O2_INIT; static uint8_t activeSensor = 0; static uint8_t sensorMapping[MAX_MUX_CHANNEL]; /* The mapping is used to assign the visible sensor channel to the mux address (DiveO2) */ float LED_Level = 0.0; /* Normalized LED value which may be used as indication for the health status of the sensor */ float LED_ZeroOffset = 0.0; float pCO2 = 0.0; /* Exported functions --------------------------------------------------------*/ void MX_USART1_UART_Init(void) { /* regular init */ huart1.Instance = USART1; if(externalInterface_GetUARTProtocol() == 0x04) { huart1.Init.BaudRate = 19200; Comstatus_O2 = UART_O2_INIT; } else { huart1.Init.BaudRate = 9600; } huart1.Init.WordLength = UART_WORDLENGTH_8B; huart1.Init.StopBits = UART_STOPBITS_1; huart1.Init.Parity = UART_PARITY_NONE; huart1.Init.Mode = UART_MODE_TX_RX; huart1.Init.HwFlowCtl = UART_HWCONTROL_NONE; huart1.Init.OverSampling = UART_OVERSAMPLING_16; HAL_UART_Init(&huart1); MX_USART1_DMA_Init(); memset(rxBuffer,BUFFER_NODATA,sizeof(rxBuffer)); rxReadIndex = 0; lastCmdIndex = 0; rxWriteIndex = 0; dmaActive = 0; digO2Connected = 0; CO2Connected = 0; SentinelConnected = 0; Comstatus_O2 = UART_O2_INIT; } void MX_USART1_UART_DeInit(void) { HAL_DMA_Abort(&hdma_usart1_rx); HAL_DMA_DeInit(&hdma_usart1_rx); HAL_UART_DeInit(&huart1); } void MX_USART1_DMA_Init() { /* DMA controller clock enable */ __DMA2_CLK_ENABLE(); /* Peripheral DMA init*/ hdma_usart1_rx.Instance = DMA2_Stream5; hdma_usart1_rx.Init.Channel = DMA_CHANNEL_4; hdma_usart1_rx.Init.Direction = DMA_PERIPH_TO_MEMORY; //DMA_MEMORY_TO_PERIPH; hdma_usart1_rx.Init.PeriphInc = DMA_PINC_DISABLE; hdma_usart1_rx.Init.MemInc = DMA_MINC_ENABLE; hdma_usart1_rx.Init.PeriphDataAlignment = DMA_MDATAALIGN_BYTE; hdma_usart1_rx.Init.MemDataAlignment = DMA_MDATAALIGN_BYTE; hdma_usart1_rx.Init.Mode = DMA_NORMAL; hdma_usart1_rx.Init.Priority = DMA_PRIORITY_LOW; hdma_usart1_rx.Init.FIFOMode = DMA_FIFOMODE_DISABLE; HAL_DMA_Init(&hdma_usart1_rx); __HAL_LINKDMA(&huart1,hdmarx,hdma_usart1_rx); /* DMA interrupt init */ HAL_NVIC_SetPriority(DMA2_Stream5_IRQn, 0, 0); HAL_NVIC_EnableIRQ(DMA2_Stream5_IRQn); } void DigitalO2_SelectSensor(uint8_t channel) { uint8_t indexstr[4]; uint8_t muxAddress = 0; indexstr[0] = '~'; indexstr[1] = '1'; indexstr[2] = 0x0D; indexstr[3] = 0x0A; /* Lookup mux address mapped to the provided channel. If no mapping is found the the MUX itself will be selected */ for(muxAddress = 0; muxAddress < MAX_MUX_CHANNEL; muxAddress++) { if(sensorMapping[muxAddress] == channel) { break; } } indexstr[1] = muxAddress; HAL_UART_Transmit(&huart1,indexstr,4,10); } void DigitalO2_SetupCmd(uint8_t O2State, uint8_t *cmdString, uint8_t *cmdLength) { switch (O2State) { case UART_O2_CHECK: *cmdLength = snprintf((char*)cmdString, 10, "#LOGO"); break; case UART_O2_REQ_INFO: *cmdLength = snprintf((char*)cmdString, 10, "#VERS"); break; case UART_O2_REQ_ID: *cmdLength = snprintf((char*)cmdString, 10, "#IDNR"); break; case UART_O2_REQ_O2: *cmdLength = snprintf((char*)cmdString, 10, "#DOXY"); break; case UART_O2_REQ_RAW: *cmdLength = snprintf((char*)cmdString, 10, "#DRAW"); break; default: *cmdLength = 0; break; } if(*cmdLength != 0) { cmdString[*cmdLength] = 0x0D; *cmdLength = *cmdLength + 1; } } void StringToInt(char *pstr, uint32_t *puInt32) { uint8_t index = 0; uint32_t result = 0; while((pstr[index] >= '0') && (pstr[index] <= '9')) { result *=10; result += pstr[index] - '0'; index++; } *puInt32 = result; } void StringToUInt64(char *pstr, uint64_t *puint64) { uint8_t index = 0; uint64_t result = 0; while((pstr[index] >= '0') && (pstr[index] <= '9')) { result *=10; result += pstr[index] - '0'; index++; } *puint64 = result; } void ConvertByteToHexString(uint8_t byte, char* str) { uint8_t worker = 0; uint8_t digit = 0; uint8_t digitCnt = 1; worker = byte; while((worker!=0) && (digitCnt != 255)) { digit = worker % 16; if( digit < 10) { digit += '0'; } else { digit += 'A' - 10; } str[digitCnt--]= digit; worker = worker / 16; } } void UART_StartDMA_Receiption() { if(HAL_OK == HAL_UART_Receive_DMA (&huart1, &rxBuffer[rxWriteIndex], CHUNK_SIZE)) { dmaActive = 1; } } #ifdef ENABLE_CO2_SUPPORT void UART_HandleCO2Data(void) { uint8_t localRX = rxReadIndex; static uint8_t dataType = 0; static uint32_t dataValue = 0; static receiveState_t rxState = RX_Ready; static uint32_t lastReceiveTick = 0; while((rxBuffer[localRX]!=0)) { lastReceiveTick = HAL_GetTick(); if(rxState == RX_Ready) /* identify data content */ { switch(rxBuffer[localRX]) { case 'l': case 'D': case 'Z': dataType = rxBuffer[localRX]; rxState = RX_Data0; dataValue = 0; break; default: /* unknown or corrupted => ignore */ break; } } else if((rxBuffer[localRX] >= '0') && (rxBuffer[localRX] <= '9')) { if((rxState >= RX_Data0) && (rxState <= RX_Data4)) { dataValue = dataValue * 10 + (rxBuffer[localRX] - '0'); rxState++; if(rxState == RX_Data5) { rxState = RX_DataComplete; CO2Connected = 1; } } else /* protocol error data has max 5 digits */ { rxState = RX_Ready; } } if((rxBuffer[localRX] == ' ') || (rxBuffer[localRX] == '\n')) /* Abort data detection */ { if(rxState == RX_DataComplete) { if(externalInterface_GetCO2State() == 0) { externalInterface_SetCO2State(EXT_INTERFACE_33V_ON); } switch(dataType) { case 'D': externalInterface_SetCO2SignalStrength(dataValue); break; case 'l': LED_ZeroOffset = dataValue; break; case 'Z': externalInterface_SetCO2Value(dataValue); break; default: rxState = RX_Ready; break; } } if(rxState != RX_Data0) /* reset state machine because message in wrong format */ { rxState = RX_Ready; } } rxBuffer[localRX] = 0; localRX++; rxReadIndex++; if(rxReadIndex >= CHUNK_SIZE * CHUNKS_PER_BUFFER) { localRX = 0; rxReadIndex = 0; } } if(time_elapsed_ms(lastReceiveTick,HAL_GetTick()) > 2000) /* check for communication timeout */ { externalInterface_SetCO2State(0); CO2Connected = 0; } if((dmaActive == 0) && (externalInterface_isEnabledPower33())) /* Should never happen in normal operation => restart in case of communication error */ { UART_StartDMA_Receiption(); } } #endif #ifdef ENABLE_SENTINEL_MODE void UART_HandleSentinelData(void) { uint8_t localRX = rxReadIndex; static uint8_t dataType = 0; static uint32_t dataValue[3]; static uint8_t dataValueIdx = 0; static receiveState_t rxState = RX_Ready; static uint32_t lastReceiveTick = 0; static uint8_t lastAlive = 0; static uint8_t curAlive = 0; static uint8_t checksum = 0; static char checksum_str[]="00"; while((rxBuffer[localRX]!=0)) { lastReceiveTick = HAL_GetTick(); switch(rxState) { case RX_Ready: if((rxBuffer[localRX] >= 'a') && (rxBuffer[localRX] <= 'z')) { rxState = RX_DetectStart; curAlive = rxBuffer[localRX]; checksum = 0; } break; case RX_DetectStart: checksum += rxBuffer[localRX]; if(rxBuffer[localRX] == '1') { rxState = RX_SelectData; dataType = 0xFF; } else { rxState = RX_Ready; } break; case RX_SelectData: checksum += rxBuffer[localRX]; switch(rxBuffer[localRX]) { case 'T': dataType = rxBuffer[localRX]; break; case '0': if(dataType != 0xff) { rxState = RX_Data0; dataValueIdx = 0; dataValue[0] = 0; } else { rxState = RX_Ready; } break; default: rxState = RX_Ready; } break; case RX_Data0: case RX_Data1: case RX_Data2: case RX_Data4: case RX_Data5: case RX_Data6: case RX_Data8: case RX_Data9: case RX_Data10: checksum += rxBuffer[localRX]; if((rxBuffer[localRX] >= '0') && (rxBuffer[localRX] <= '9')) { dataValue[dataValueIdx] = dataValue[dataValueIdx] * 10 + (rxBuffer[localRX] - '0'); rxState++; } else { rxState = RX_Ready; } break; case RX_Data3: case RX_Data7: checksum += rxBuffer[localRX]; if(rxBuffer[localRX] == '0') { rxState++; dataValueIdx++; dataValue[dataValueIdx] = 0; } else { rxState = RX_Ready; } break; case RX_Data11: rxState = RX_DataComplete; ConvertByteToHexString(checksum,checksum_str); if(rxBuffer[localRX] == checksum_str[0]) { rxState = RX_DataComplete; } else { rxState = RX_Ready; } break; case RX_DataComplete: if(rxBuffer[localRX] == checksum_str[1]) { setExternalInterfaceChannel(0,(float)(dataValue[0] / 10.0)); setExternalInterfaceChannel(1,(float)(dataValue[1] / 10.0)); setExternalInterfaceChannel(2,(float)(dataValue[2] / 10.0)); SentinelConnected = 1; } rxState = RX_Ready; break; default: rxState = RX_Ready; break; } localRX++; rxReadIndex++; if(rxReadIndex >= CHUNK_SIZE * CHUNKS_PER_BUFFER) { localRX = 0; rxReadIndex = 0; } } if(time_elapsed_ms(lastReceiveTick,HAL_GetTick()) > 4000) /* check for communication timeout */ { if(curAlive == lastAlive) { setExternalInterfaceChannel(0,0.0); setExternalInterfaceChannel(1,0.0); setExternalInterfaceChannel(2,0.0); SentinelConnected = 0; } lastAlive = curAlive; } if((dmaActive == 0) && (externalInterface_isEnabledPower33())) /* Should never happen in normal operation => restart in case of communication error */ { UART_StartDMA_Receiption(); } } #endif void UART_HandleDigitalO2(void) { static uint32_t lastO2ReqTick = 0; static uint8_t errorStr[] = "#ERRO"; static uartO2RxState_t rxState = O2RX_IDLE; static uint32_t lastReceiveTick = 0; static uint8_t lastAlive = 0; static uint8_t curAlive = 0; static uint8_t cmdLength = 0; static uint8_t cmdString[10]; static uint8_t cmdReadIndex = 0; static uint8_t errorReadIndex = 0; static uint32_t tickToTX = 0; static uint32_t delayStartTick = 0; static uint16_t requestIntervall = 0; static uint8_t retryRequest = 1; static uint8_t lastComState = 0; static uint8_t respondErrorDetected = 0; static uint8_t switchChannel = 0; uint8_t index = 0; uint32_t tmpO2 = 0; uint32_t tmpData = 0; uint8_t localRX = rxReadIndex; uint32_t tick = HAL_GetTick(); uint8_t *pmap = externalInterface_GetSensorMapPointer(0); /* The channel switch will cause the sensor to respond with an error message. */ /* The sensor needs ~30ms to recover before he is ready to receive the next command => transmission delay needed */ if((tickToTX) && (time_elapsed_ms(delayStartTick,tick) >= tickToTX )) { HAL_UART_Transmit(&huart1,cmdString,cmdLength,10); tickToTX = 0; } else { if(Comstatus_O2 == UART_O2_INIT) { memset((char*)&rxBuffer[rxWriteIndex],(int)BUFFER_NODATA, sizeof(rxBuffer)); memset((char*) &tmpSensorDataDiveO2, 0, sizeof(tmpSensorDataDiveO2)); externalInterface_SetSensorData(0xFF,(uint8_t*)&tmpSensorDataDiveO2); lastAlive = 0; curAlive = 0; Comstatus_O2 = UART_O2_CHECK; lastComState = UART_O2_IDLE; DigitalO2_SetupCmd(Comstatus_O2,cmdString,&cmdLength); if(activeSensor < MAX_MUX_CHANNEL) { externalInterface_GetSensorData(activeSensor, (uint8_t*)&tmpSensorDataDiveO2); } tickToTX = COMMAND_TX_DELAY; rxState = O2RX_CONFIRM; cmdReadIndex = 0; errorReadIndex = 0; respondErrorDetected = 0; digO2Connected = 0; switchChannel = 1; requestIntervall = 0; for(index = 0; index < MAX_MUX_CHANNEL; index++) { if(pmap[index] == SENSOR_DIGO2) { requestIntervall++; } } if(requestIntervall != 0) { requestIntervall = REQUEST_INT_SENSOR_MS / requestIntervall; } else { requestIntervall = REQUEST_INT_SENSOR_MS; } UART_StartDMA_Receiption(); lastO2ReqTick = tick + requestIntervall + 1; } if(time_elapsed_ms(lastO2ReqTick,tick) > requestIntervall) /* repeat request or iterate to next sensor */ { respondErrorDetected = 0; lastO2ReqTick = tick; index = activeSensor; if((lastComState == Comstatus_O2) && (Comstatus_O2 != UART_O2_IDLE)) { if(retryRequest) { retryRequest = 0; } else /* no answer even repeating the request => abort request */ { if(Comstatus_O2 == UART_O2_REQ_RAW) { setExternalInterfaceChannel(activeSensor,0.0); } Comstatus_O2 = UART_O2_IDLE; } } lastComState = Comstatus_O2; if(Comstatus_O2 == UART_O2_IDLE) /* cyclic request of o2 value */ { retryRequest = 1; if(pmap[EXT_INTERFACE_SENSOR_CNT-1] == SENSOR_MUX) /* select next sensor if mux is connected */ { if(activeSensor < MAX_MUX_CHANNEL) { do { index++; if(index == MAX_MUX_CHANNEL) { index = 0; } if((pmap[index] == SENSOR_DIGO2) && (index != activeSensor)) { activeSensor = index; switchChannel = 1; break; } } while(index != activeSensor); externalInterface_GetSensorData(activeSensor, (uint8_t*)&tmpSensorDataDiveO2); } } if((activeSensor != MAX_MUX_CHANNEL) && (tmpSensorDataDiveO2.sensorId == 0)) { Comstatus_O2 = UART_O2_REQ_ID; } else { Comstatus_O2 = UART_O2_REQ_RAW; } } rxState = O2RX_CONFIRM; if(switchChannel) { switchChannel = 0; delayStartTick = tick; DigitalO2_SelectSensor(activeSensor); tickToTX = COMMAND_TX_DELAY; } else { tickToTX = 0; HAL_UART_Transmit(&huart1,cmdString,cmdLength,10); } DigitalO2_SetupCmd(Comstatus_O2,cmdString,&cmdLength); } } while((rxBuffer[localRX] != BUFFER_NODATA)) { lastReceiveTick = tick; switch(rxState) { case O2RX_CONFIRM: if(rxBuffer[localRX] == '#') { cmdReadIndex = 0; errorReadIndex = 0; } if(errorReadIndex < sizeof(errorStr)-1) { if(rxBuffer[localRX] == errorStr[errorReadIndex]) { errorReadIndex++; } else { errorReadIndex = 0; } } else { respondErrorDetected = 1; errorReadIndex = 0; } if(rxBuffer[localRX] == cmdString[cmdReadIndex]) { cmdReadIndex++; if(cmdReadIndex == cmdLength - 1) { if((activeSensor == MAX_MUX_CHANNEL)) { if(respondErrorDetected) { digO2Connected = 0; /* the multiplexer mirrors the incoming message and does not generate an error information => no mux connected */ } else { digO2Connected = 1; } } else /* handle sensors which should respond with an error message after channel switch */ { if(respondErrorDetected) { digO2Connected = 1; } } tmpRxIdx = 0; memset((char*) tmpRxBuf, 0, sizeof(tmpRxBuf)); cmdReadIndex = 0; switch (Comstatus_O2) { case UART_O2_CHECK: Comstatus_O2 = UART_O2_IDLE; rxState = O2RX_IDLE; break; case UART_O2_REQ_ID: rxState = O2RX_GETNR; break; case UART_O2_REQ_INFO: rxState = O2RX_GETTYPE; break; case UART_O2_REQ_RAW: case UART_O2_REQ_O2: rxState = O2RX_GETO2; break; default: Comstatus_O2 = UART_O2_IDLE; rxState = O2RX_IDLE; break; } } } else { cmdReadIndex = 0; } break; case O2RX_GETSTATUS: case O2RX_GETTEMP: case O2RX_GETTYPE: case O2RX_GETVERSION: case O2RX_GETCHANNEL: case O2RX_GETSUBSENSORS: case O2RX_GETO2: case O2RX_GETNR: case O2RX_GETDPHI: case O2RX_INTENSITY: case O2RX_AMBIENTLIGHT: case O2RX_PRESSURE: case O2RX_HUMIDITY: if(rxBuffer[localRX] != 0x0D) { if(rxBuffer[localRX] != ' ') /* the following data entities are placed within the data stream => no need to store data at the end */ { tmpRxBuf[tmpRxIdx++] = rxBuffer[localRX]; } else { if(tmpRxIdx != 0) { switch(rxState) { case O2RX_GETCHANNEL: StringToInt(tmpRxBuf,&tmpData); rxState = O2RX_GETVERSION; break; case O2RX_GETVERSION: StringToInt(tmpRxBuf,&tmpData); rxState = O2RX_GETSUBSENSORS; break; case O2RX_GETTYPE: StringToInt(tmpRxBuf,&tmpData); rxState = O2RX_GETCHANNEL; break; case O2RX_GETO2: StringToInt(tmpRxBuf,&tmpO2); setExternalInterfaceChannel(activeSensor,(float)(tmpO2 / 10000.0)); rxState = O2RX_GETTEMP; break; case O2RX_GETTEMP: StringToInt(tmpRxBuf,(uint32_t*)&tmpSensorDataDiveO2.temperature); rxState = O2RX_GETSTATUS; break; case O2RX_GETSTATUS: StringToInt(tmpRxBuf,&tmpSensorDataDiveO2.status); /* raw data cycle */ rxState = O2RX_GETDPHI; break; case O2RX_GETDPHI: /* ignored to save memory and most likly irrelevant for diver */ rxState = O2RX_INTENSITY; break; case O2RX_INTENSITY: StringToInt(tmpRxBuf,(uint32_t*)&tmpSensorDataDiveO2.intensity); /* raw data cycle */ rxState = O2RX_AMBIENTLIGHT; break; case O2RX_AMBIENTLIGHT: StringToInt(tmpRxBuf,(uint32_t*)&tmpSensorDataDiveO2.ambient); /* raw data cycle */ rxState = O2RX_PRESSURE; break; case O2RX_PRESSURE: StringToInt(tmpRxBuf,(uint32_t*)&tmpSensorDataDiveO2.pressure); /* raw data cycle */ rxState = O2RX_HUMIDITY; break; default: break; } memset((char*) tmpRxBuf, 0, tmpRxIdx); tmpRxIdx = 0; } } } else { /* the following data items are the last of a sensor respond => store temporal data */ switch (rxState) { case O2RX_GETSTATUS: StringToInt(tmpRxBuf,&tmpSensorDataDiveO2.status); externalInterface_SetSensorData(activeSensor,(uint8_t*)&tmpSensorDataDiveO2); Comstatus_O2 = UART_O2_IDLE; rxState = O2RX_IDLE; break; case O2RX_GETSUBSENSORS: StringToInt(tmpRxBuf,&tmpData); Comstatus_O2 = UART_O2_IDLE; rxState = O2RX_IDLE; break; case O2RX_HUMIDITY: StringToInt(tmpRxBuf,(uint32_t*)&tmpSensorDataDiveO2.humidity); /* raw data cycle */ externalInterface_SetSensorData(activeSensor,(uint8_t*)&tmpSensorDataDiveO2); Comstatus_O2 = UART_O2_IDLE; rxState = O2RX_IDLE; break; case O2RX_GETNR: StringToUInt64((char*)tmpRxBuf,&tmpSensorDataDiveO2.sensorId); externalInterface_SetSensorData(activeSensor,(uint8_t*)&tmpSensorDataDiveO2); index = activeSensor; Comstatus_O2 = UART_O2_IDLE; rxState = O2RX_IDLE; break; default: Comstatus_O2 = UART_O2_IDLE; rxState = O2RX_IDLE; break; } } break; default: rxState = O2RX_IDLE; break; } rxBuffer[localRX] = BUFFER_NODATA; localRX++; rxReadIndex++; if(rxReadIndex >= CHUNK_SIZE * CHUNKS_PER_BUFFER) { localRX = 0; rxReadIndex = 0; } } if((digO2Connected) && time_elapsed_ms(lastReceiveTick,HAL_GetTick()) > 4000) /* check for communication timeout */ { digO2Connected = 0; if(curAlive == lastAlive) { for(index = 0; index < MAX_ADC_CHANNEL; index++) { if(pmap[index] == SENSOR_DIGO2) { setExternalInterfaceChannel(index,0.0); } } } lastAlive = curAlive; } if((dmaActive == 0) && (externalInterface_isEnabledPower33())) /* Should never happen in normal operation => restart in case of communication error */ { UART_StartDMA_Receiption(); } } void UART_SetDigO2_Channel(uint8_t channel) { if(channel <= MAX_MUX_CHANNEL) { activeSensor = channel; } } void UART_MapDigO2_Channel(uint8_t channel, uint8_t muxAddress) { if(((channel < MAX_ADC_CHANNEL) || (channel == 0xff)) && (muxAddress < MAX_MUX_CHANNEL)) { sensorMapping[muxAddress] = channel; } } uint8_t UART_isDigO2Connected() { return digO2Connected; } uint8_t UART_isCO2Connected() { return CO2Connected; } uint8_t UART_isSentinelConnected() { return SentinelConnected; } void HAL_UART_RxCpltCallback(UART_HandleTypeDef *huart) { if(huart == &huart1) { dmaActive = 0; rxWriteIndex+=CHUNK_SIZE; if(rxWriteIndex >= CHUNK_SIZE * CHUNKS_PER_BUFFER) { rxWriteIndex = 0; } if((rxWriteIndex / CHUNK_SIZE) != (rxReadIndex / CHUNK_SIZE) || (rxWriteIndex == rxReadIndex)) /* start next transfer if we did not catch up with read index */ { if(externalInterface_GetUARTProtocol() != 0) { UART_StartDMA_Receiption(); } } } } /************************ (C) COPYRIGHT heinrichs weikamp *****END OF FILE****/