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- /*
- * hal_adapter.c
- *中间层函数调用库
- * Created on: 2022年1月18日
- * Author: QiXiang_CHENJIE
- */
- #include "hal_adapter.h"
- #include "AppGlobalVar.h"
- #include "stdio.h"
- #include "stdarg.h"
- /********************************/
- #include "Icu.h"
- #include "Gpt.h"
- uint8_t __attribute__((section(".non_cacheable_data"))) RX_Buffer[3][BUFFER_SIZE];
- uint32_t bufferIdx[3] = {0};
- volatile uint32 VarNotification_0 = 0;
- volatile uint32 VarNotification_1 = 0;
- TP_Value_Type ConvertedBuffer[NUM_RESULTS];
- Adc_ValueGroupType ResultBuffer[NUM_RESULTS];
- volatile Uart_StatusType Uart_TransmitStatus[3] = {UART_STATUS_TIMEOUT,UART_STATUS_TIMEOUT,UART_STATUS_TIMEOUT};
- QueueHandle_t UartRecvQueue[3];
- QueueHandle_t TcpRecvQueue;
- QueueHandle_t UartSendQueue[3];
- QueueHandle_t UartHalQueueHandle;
- Std_ReturnType UartStartRecvFunc(uint8 channel);
- Std_ReturnType ADC_Converter(Adc_ValueGroupType *Buffer, TP_Value_Type *ConvertedValueR);
- void create_ringBuffer(ringbuffer_t *ringBuf, uint8_t *buf, uint32_t buf_len);
- void clear_ringBuffer(ringbuffer_t *ringBuf);
- uint32_t write_ringBuffer(uint8_t *buffer, uint16_t size, ringbuffer_t *ringBuf,uint32 *uartDataAddr);
- uint32_t read_ringBuffer(uint8_t *buffer, uint32_t size, ringbuffer_t *ringBuf);
- uint8 ringBufferforUart[3][BUFFER_SIZE];
- ringbuffer_t uartRingBuffer[3];
- sint8 AtcmdDelayRecvFunc(uint8 recvChannel,char *ResultStrPtr,uint16 delayTime)
- {
- sint8 outValue = -1;
- uint8 delayCnt = 0;
- uint8 UartData[256];
- uint16 ReadLen = 0;
- char *retptr = NULL;
- while (delayCnt<(delayTime/1000)&&outValue!=0)
- {
- UART_Receive_Data(recvChannel,UartData, &ReadLen,1000);
- if(ReadLen>0)
- {
- retptr = (char *)strstr((char *)UartData, ResultStrPtr);
- if (retptr)
- {
- outValue = 0;
- break;
- }
- }
- else
- {
- delayCnt++;
- }
- }
- return outValue;
- }
- #if 0
- uint16 myPrintf(const char *fmt, ...)
- {
- int n;
- uint8 databuffer[512]={0};
- va_list args;
- va_start(args, fmt);
- n = vsprintf((char *)databuffer, fmt, args);
- va_end(args);
- if( (printfRingBuffer.bw + n) <= printfRingBuffer.length )
- {
- memcpy(printfRingBuffer.source + printfRingBuffer.bw, databuffer, n);
- UART_Send_Data(UART_LPUART0, printfRingBuffer.source + printfRingBuffer.bw, n, 10);
- printfRingBuffer.bw = printfRingBuffer.bw + n;
- }
- else
- {
- printfRingBuffer.bw = 0;
- memcpy(printfRingBuffer.source + printfRingBuffer.bw, databuffer, n);
- UART_Send_Data(UART_LPUART0, printfRingBuffer.source + printfRingBuffer.bw, n, 10);
- }
- return n;
- }
- #endif
- void create_ringBuffer(ringbuffer_t *ringBuf, uint8_t *buf, uint32_t buf_len)
- {
- ringBuf->br = 0;
- ringBuf->bw = 0;
- ringBuf->btoRead = 0;
- ringBuf->source = buf;
- ringBuf->length = buf_len;
- }
- void clear_ringBuffer(ringbuffer_t *ringBuf)
- {
- ringBuf->br = 0;
- ringBuf->bw = 0;
- ringBuf->btoRead = 0;
- }
- uint32_t write_ringBuffer(uint8_t *buffer, uint16_t size, ringbuffer_t *ringBuf,uint32 *uartDataAddr)
- {
- volatile uint32_t ringBuf_bw = ringBuf->bw;
- uint32_t ringBuf_len = ringBuf->length;
- uint8_t *ringBuf_source = ringBuf->source;
- if( (ringBuf_bw + size + 1) > ringBuf_len )
- {
- ringBuf_bw = 0;
- }
- memcpy(ringBuf_source + ringBuf_bw, buffer, size);
- memset(ringBuf_source + ringBuf_bw + size + 1,0x00,1);//环形buffer 插入分隔符截断字符串
- ringBuf->bw = (ringBuf_bw + size + 1) % ringBuf_len;//数据长度不变,起始地址移位1
- ringBuf->btoRead += size;
- *uartDataAddr = (uint32)(ringBuf->source + ringBuf->bw - size - 1);
- /*
- if(ringBuf->br!=0)
- {
- memcpy(ringBuf_source, buffer, size);
- ringBuf->br = 0;
- }
- */
- /*
- if( (ringBuf_bw + size) <= ringBuf_len )
- {
- memcpy(ringBuf_source + ringBuf_bw, buffer, size);
- }
- else
- {
- len = ringBuf_len - ringBuf_bw;
- memcpy(ringBuf_source + ringBuf_bw, buffer, len);
- memcpy(ringBuf_source, buffer + ringBuf_bw, size - len);
- }
- ringBuf->bw = (ringBuf->bw + size) % ringBuf_len;
- ringBuf->btoRead += size;
- */
- return size;
- }
- uint32_t read_ringBuffer(uint8_t *buffer, uint32_t size, ringbuffer_t *ringBuf)
- {
- uint32_t len = 0;
- volatile uint32_t ringBuf_br = ringBuf->br;
- uint32_t ringBuf_len = ringBuf->length;
- uint8_t *ringBuf_source = ringBuf->source;
- memcpy(buffer, ringBuf_source, size);
- ringBuf->br = size;
- // if( (ringBuf_br + size ) <= ringBuf_len )
- // {
- // memcpy(buffer, ringBuf_source + ringBuf_br, size);
- // }
- // else
- // {
- // len = ringBuf_len - ringBuf_br;
- // memcpy(buffer, ringBuf_source + ringBuf_br, len);
- // memcpy(buffer + len, ringBuf_source, size - len);
- // }
- // ringBuf->br = (ringBuf->br + size) % ringBuf_len;
- // ringBuf->btoRead -= size;
- return size;
- }
- Std_ReturnType UART_Query_Data(uint8 transChannel, uint8 recvChannel, uint8 *txBuffer, uint16 sendLength, uint8 *rxBuffer, uint16 *rxlen, uint32 T_timeout)
- {
- UartMsg_t UartRecvMsg;
- UartMsg_t UartSendMsg;
- BaseType_t Sendret = pdFALSE;
- BaseType_t Recvret = pdFALSE;
- uint32 retVal = E_NOT_OK;
- UartSendMsg.DataLen = sendLength;
- UartSendMsg.dataPtr = txBuffer;
- *rxlen = 0;
- Sendret = xQueueSend(UartSendQueue[transChannel],&UartSendMsg,50);
- if(Sendret == pdTRUE)
- {
- Recvret = xQueueReceive(UartRecvQueue[recvChannel],&UartRecvMsg,T_timeout);
- if(Recvret == pdTRUE)
- {
- *rxlen = UartRecvMsg.DataLen;
- memcpy(rxBuffer,(uint8 *)(UartRecvMsg.dataAddr),UartRecvMsg.DataLen);
- retVal = E_OK;
- }
- else
- {
- retVal = 3;
- }
- }
- else
- {
- retVal = 2;
- }
- return retVal;
- }
- Std_ReturnType UART_Receive_Data(uint8 recvChannel, uint8 *rxBuffer, uint16 *rxlen, uint32 T_timeout)
- {
- UartMsg_t UartRecvMsg;
- BaseType_t ret = pdFALSE;
- uint32 retVal = E_NOT_OK;
- *rxlen = 0;
- ret = xQueueReceive(UartRecvQueue[recvChannel],&UartRecvMsg,T_timeout);
- if(ret == pdTRUE)
- {
- *rxlen = UartRecvMsg.DataLen;
- memcpy(rxBuffer,(uint8 *)UartRecvMsg.dataAddr,UartRecvMsg.DataLen);
- retVal = E_OK;
- }
- return retVal;
- }
- Std_ReturnType Tcp_Receive_Data(uint8 *rxBuffer, uint16 *rxlen, uint32 T_timeout)
- {
- UartMsg_t UartRecvMsg;
- BaseType_t ret = pdFALSE;
- uint32 retVal = E_NOT_OK;
- *rxlen = 0;
- ret = xQueueReceive(TcpRecvQueue,&UartRecvMsg,T_timeout);
- if(ret == pdTRUE)
- {
- *rxlen = UartRecvMsg.DataLen;
- memcpy(rxBuffer,(uint8 *)UartRecvMsg.dataAddr,UartRecvMsg.DataLen);
- retVal = E_OK;
- }
- return retVal;
- }
- Std_ReturnType UART_Reset(uint8 recvChannel)
- {
- uint32 retVal = E_NOT_OK;
- retVal = xQueueReset(UartRecvQueue[recvChannel]);
- return retVal;
- }
- Std_ReturnType UART_Send_Data(uint8 transChannel, const uint8 *txBuffer, uint32 sendLength, uint32 T_timeout)
- {
- UartMsg_t UartSendMsg;
- BaseType_t ret = pdFALSE;
- uint32 retVal = E_NOT_OK;
- UartSendMsg.DataLen = sendLength;
- UartSendMsg.dataPtr = txBuffer;
- ret = xQueueSend(UartSendQueue[transChannel],&UartSendMsg,T_timeout);
- if(ret == pdTRUE)
- {
- retVal = E_OK;
- }
- return retVal;
- }
- void UartInit(void)
- {
- create_ringBuffer(&uartRingBuffer[0],ringBufferforUart[0],sizeof(ringBufferforUart[0]));
- create_ringBuffer(&uartRingBuffer[1],ringBufferforUart[1],sizeof(ringBufferforUart[1]));
- create_ringBuffer(&uartRingBuffer[2],ringBufferforUart[2],sizeof(ringBufferforUart[2]));
- UartRecvQueue[0] = xQueueCreate(6, sizeof(UartMsg_t));
- UartRecvQueue[1] = xQueueCreate(6, sizeof(UartMsg_t));
- UartRecvQueue[2] = xQueueCreate(6, sizeof(UartMsg_t));
- TcpRecvQueue = xQueueCreate(2, sizeof(UartMsg_t));
- UartSendQueue[0] = xQueueCreate(3, sizeof(UartMsg_t));
- UartSendQueue[1] = xQueueCreate(1, sizeof(UartMsg_t));
- UartSendQueue[2] = xQueueCreate(1, sizeof(UartMsg_t));
- UartHalQueueHandle = xQueueCreate(9, sizeof(UartHalMsg_t));
- xTaskCreate(Uart_Hal_RecvTask, (const char *const)"UartRecv", 256, (void *)0, main_TASK_PRIORITY + 5, &Uart_Hal_RecvTask_Handle);
- xTaskCreate(Uart_Hal_SendTask, (const char *const)"UartSend", 256, (void *)0, main_TASK_PRIORITY + 4, &Uart_Hal_SendTask_Handle);
- }
- Std_ReturnType UartStartRecvFunc(uint8 channel)
- {
- sint8 out = 0;
- volatile Std_ReturnType R_Uart_Status=E_NOT_OK;
- bufferIdx[channel]=0;
- memset(RX_Buffer[channel],0x00,BUFFER_SIZE);
- switch(channel)
- {
- case 0:
- IP_LPUART0->CTRL |= LPUART_CTRL_ILIE(1);
- break;
- case 1:
- IP_LPUART1->CTRL |= LPUART_CTRL_ILIE(1);
- break;
- case 2:
- IP_LPUART2->CTRL |= LPUART_CTRL_ILIE(1);
- break;
- default:
- break;
- }
- Uart_SetBuffer(channel, RX_Buffer[channel], DMA_SIZE, UART_RECEIVE);
- R_Uart_Status = Uart_AsyncReceive(channel, RX_Buffer[channel], DMA_SIZE);
- if (E_OK != R_Uart_Status)
- {
- Uart_Abort(channel, UART_RECEIVE);
- out = E_NOT_OK;
- }
- return out;
- }
- void Uart_Hal_RecvTask(void *pvParameters)
- {
- UartHalMsg_t UartHalMsgRecv;
- UartMsg_t UartRecvMsg;
- uint16 recvSize = 0;
- BaseType_t ret = pdFALSE;
- BaseType_t ret_send = pdFALSE;
- uint32 T_bytesRemaining[3] = {0};
- uint16 T_timeout[3] = {0};
- volatile Uart_StatusType Uart_ReceiveStatus[3] = {UART_STATUS_TIMEOUT,UART_STATUS_TIMEOUT,UART_STATUS_TIMEOUT};
- uint8 UartIdx = UART_LPUART0;
- uint8 UartState[3] = {UartAbortRecv,UartAbortRecv,UartAbortRecv};
- while(1)
- {
- if((T_timeout[UartIdx]>1000) && (Uart_ReceiveStatus[UartIdx] != UART_STATUS_NO_ERROR) )
- {
- Uart_Abort(UartIdx, UART_RECEIVE);
- UartState[UartIdx] = UartAbortRecv;
- T_timeout[UartIdx] = 0;
- }
- else if(Uart_ReceiveStatus[UartIdx] == UART_STATUS_NO_ERROR)
- {
- UartState[UartIdx] = UartRecvComplete;
- }
- if((UartState[UartIdx] == UartAbortRecv) || (UartState[UartIdx] == UartRecvComplete))
- {
- if(E_OK == UartStartRecvFunc(UartIdx))
- {
- UartState[UartIdx] = UartStartRecv;
- }
- }
- Uart_ReceiveStatus[UartIdx] = Uart_GetStatus(UartIdx, &T_bytesRemaining[UartIdx], UART_RECEIVE);
- T_timeout[UartIdx]++;
- UartIdx = (UartIdx + 1) > 2 ? 1 : (UartIdx + 1);
- ret = xQueueReceive(UartHalQueueHandle,&UartHalMsgRecv,1);
- if(ret==pdTRUE)
- {
- if(UartHalMsgRecv.event==LPUART_UART_IP_EVENT_RECV_IDLE)
- {
- if(UartHalMsgRecv.value>0)
- {
- recvSize = write_ringBuffer(RX_Buffer[UartHalMsgRecv.Channel],UartHalMsgRecv.value,&uartRingBuffer[UartHalMsgRecv.Channel],&(UartRecvMsg.dataAddr));
- UartRecvMsg.DataLen = UartHalMsgRecv.value;
- if(UartHalMsgRecv.Channel==1 && strstr((char *)UartRecvMsg.dataAddr, (char *)("RECV FROM")))//网络接收数据放入其他队列
- {
- ret_send = xQueueSend(TcpRecvQueue,&UartRecvMsg,10);
- }
- else
- {
- ret_send = xQueueSend(UartRecvQueue[UartHalMsgRecv.Channel],&UartRecvMsg,10);
- }
- T_timeout[UartHalMsgRecv.Channel] = 0;
- UartState[UartHalMsgRecv.Channel] = UartRecvComplete;
- }
- }
- }
- }
- }
- void Uart_Hal_SendTask(void *pvParameters)
- {
- UartMsg_t UartSendMsg;
- BaseType_t ret = pdFALSE;
- uint32 T_bytesRemaining[3] = {0};
- uint16 T_timeout[3] = {0};
- volatile Std_ReturnType T_Uart_Status[3];
- uint8 UartIdx = UART_LPUART0;
- uint8 UartSendState[3] = {UartNoDataSend,UartNoDataSend,UartNoDataSend};
- while(1)
- {
- ret = xQueueReceive(UartSendQueue[UartIdx],&UartSendMsg,1);
- if(ret==pdTRUE)
- {
- T_Uart_Status[UartIdx] = Uart_AsyncSend(UartIdx, UartSendMsg.dataPtr, UartSendMsg.DataLen);
- if (E_OK != T_Uart_Status[UartIdx])
- {
- Uart_Abort(UartIdx, UART_SEND);
- UartSendState[UartIdx] = UartAbortSend;
- }
- else
- {
- UartSendState[UartIdx] = UartStartSend;
- }
- }
- /*开始发送后的判定*/
- if(UartSendState[UartIdx] == UartStartSend)
- {
- Uart_TransmitStatus[UartIdx] = Uart_GetStatus(UartIdx, &T_bytesRemaining[UartIdx], UART_SEND);
- T_timeout[UartIdx]++;
- }
- if(T_timeout[UartIdx]>=1000 || ((Uart_TransmitStatus[UartIdx] != UART_STATUS_OPERATION_ONGOING) && (UartSendState[UartIdx] == UartStartSend)))
- {
- if(T_timeout[UartIdx]>=1000)
- {
- Uart_Abort(UartIdx, UART_SEND);
- UartSendState[UartIdx] = UartAbortSend;
- }
- else if(Uart_TransmitStatus[UartIdx] == UART_STATUS_NO_ERROR)
- {
- UartSendState[UartIdx] = UartSendComplete;
- }
- T_timeout[UartIdx] = 0;
- }
- UartIdx = (UartIdx + 1) > 2 ? 0 : (UartIdx + 1);
- }
- }
- //
- //Std_ReturnType UART_Query_Data(uint8 transChannel, uint8 recvChannel, const uint8 *txBuffer, uint32 sendLength, uint8 *rxBuffer, uint16 *rxlen, uint32 T_timeout)
- //{
- // volatile Std_ReturnType R_Uart_Status;
- // volatile Std_ReturnType T_Uart_Status;
- // volatile Uart_StatusType Uart_ReceiveStatus = UART_STATUS_TIMEOUT;
- // volatile Uart_StatusType Uart_TransmitStatus = UART_STATUS_TIMEOUT;
- // uint32 T_bytesRemaining;
- // uint32 R_bytesRemaining;
- // uint32 timeout = T_timeout;
- // uint32 retVal = E_NOT_OK;
- // bufferIdx[recvChannel] = 0;
- // switch (recvChannel)
- // {
- // case 0:
- // IP_LPUART0->CTRL |= LPUART_CTRL_ILIE(1);
- // break;
- // case 1:
- // IP_LPUART1->CTRL |= LPUART_CTRL_ILIE(1);
- // break;
- // case 2:
- // IP_LPUART2->CTRL |= LPUART_CTRL_ILIE(1);
- // break;
- // default:
- // break;
- // }
- // if (txBuffer == NULL || rxBuffer == NULL)
- // {
- // return retVal;
- // }
- //
- // /* Uart_AsyncSend transmit data */
- // Uart_SetBuffer(transChannel, txBuffer, sendLength, UART_SEND);
- // T_Uart_Status = Uart_AsyncSend(transChannel, txBuffer, sendLength);
- // if (E_OK != T_Uart_Status)
- // {
- // Uart_Abort(transChannel, UART_SEND);
- // return E_NOT_OK;
- // }
- // Uart_SetBuffer(recvChannel, &RX_Buffer[recvChannel][0], DMA_SIZE, UART_RECEIVE);
- // R_Uart_Status = Uart_AsyncReceive(recvChannel, rxBuffer, DMA_SIZE);
- // if (E_OK != R_Uart_Status)
- // {
- // Uart_Abort(recvChannel, UART_RECEIVE);
- // return E_NOT_OK;
- // }
- // /* Check for no on-going transmission */
- // do
- // {
- // if (Uart_TransmitStatus != UART_STATUS_NO_ERROR)
- // {
- // Uart_TransmitStatus = Uart_GetStatus(transChannel, &T_bytesRemaining, UART_SEND);
- // }
- // if (Uart_ReceiveStatus != UART_STATUS_NO_ERROR)
- // {
- // Uart_ReceiveStatus = Uart_GetStatus(recvChannel, &R_bytesRemaining, UART_RECEIVE);
- // }
- // vTaskDelay(pdMS_TO_TICKS(1));
- // } while (((UART_STATUS_NO_ERROR != Uart_TransmitStatus || UART_STATUS_NO_ERROR != Uart_ReceiveStatus) && 0 < --timeout));
- // if ((UART_STATUS_NO_ERROR != Uart_TransmitStatus))
- // {
- // Uart_Abort(transChannel, UART_SEND);
- // retVal = E_NOT_OK;
- // }
- // else
- // {
- // retVal = E_OK;
- // }
- // if ((UART_STATUS_NO_ERROR != Uart_ReceiveStatus))
- // {
- // Uart_Abort(recvChannel, UART_RECEIVE);
- // *rxlen = bufferIdx[recvChannel];
- // retVal = E_NOT_OK;
- // }
- // else
- // {
- // *rxlen = bufferIdx[recvChannel];
- // retVal = E_OK;
- // }
- // return retVal;
- //}
- //
- //Std_ReturnType UART_Send_Data(uint8 transChannel, const uint8 *txBuffer, uint32 sendLength, uint32 T_timeout)
- //{
- //
- // volatile Std_ReturnType T_Uart_Status;
- // volatile Uart_StatusType Uart_TransmitStatus = UART_STATUS_TIMEOUT;
- // uint32 T_bytesRemaining;
- // uint32 timeout = T_timeout;
- // uint32 retVal = E_NOT_OK;
- // if (txBuffer == NULL)
- // {
- // return retVal;
- // }
- //
- // /* Uart_AsyncSend transmit data */
- // T_Uart_Status = Uart_AsyncSend(transChannel, txBuffer, sendLength);
- // if (E_OK != T_Uart_Status)
- // {
- // Uart_Abort(transChannel, UART_SEND);
- // return E_NOT_OK;
- // }
- // /* Check for no on-going transmission */
- // do
- // {
- // Uart_TransmitStatus = Uart_GetStatus(transChannel, &T_bytesRemaining, UART_SEND);
- // vTaskDelay(pdMS_TO_TICKS(1));
- // } while ((UART_STATUS_NO_ERROR != Uart_TransmitStatus && 0 < --timeout));
- //
- // if ((UART_STATUS_NO_ERROR != Uart_TransmitStatus))
- // {
- // retVal = E_NOT_OK;
- // }
- // else
- // {
- // retVal = E_OK;
- // }
- // return retVal;
- //}
- //
- //Std_ReturnType UART_Receive_Data(uint8 recvChannel, uint8 *rxBuffer, uint16 *rxlen, sint32 T_timeout)
- //{
- // volatile Std_ReturnType R_Uart_Status = E_NOT_OK;
- // volatile Uart_StatusType Uart_ReceiveStatus = UART_STATUS_TIMEOUT;
- // uint32 T_bytesRemaining = 0;
- // uint32 retVal = E_NOT_OK;
- // // uint8 Rx_Buffer[MSG_LEN];
- // bufferIdx[recvChannel] = 0;
- // *rxlen = 0;
- // if (rxBuffer == NULL)
- // {
- // return retVal;
- // }
- // /* Uart_AsyncReceive transmit data */
- // switch (recvChannel)
- // {
- // case 0:
- // IP_LPUART0->CTRL |= LPUART_CTRL_ILIE(1);
- // break;
- // case 1:
- // IP_LPUART1->CTRL |= LPUART_CTRL_ILIE(1);
- // break;
- // case 2:
- // IP_LPUART2->CTRL |= LPUART_CTRL_ILIE(1);
- // break;
- // default:
- // break;
- // }
- // Uart_SetBuffer(recvChannel, rxBuffer, DMA_SIZE, UART_RECEIVE);
- // R_Uart_Status = Uart_AsyncReceive(recvChannel, rxBuffer, DMA_SIZE);
- // if (E_OK != R_Uart_Status)
- // {
- // Uart_Abort(recvChannel, UART_RECEIVE);
- // return E_NOT_OK;
- // }
- // /* Check for no on-going transmission */
- // do
- // {
- // Uart_ReceiveStatus = Uart_GetStatus(recvChannel, &T_bytesRemaining, UART_RECEIVE);
- // vTaskDelay(pdMS_TO_TICKS(1));
- //
- // } while ((UART_STATUS_NO_ERROR != Uart_ReceiveStatus) && 0 < T_timeout--);
- // if ((UART_STATUS_NO_ERROR != Uart_ReceiveStatus))
- // {
- // Uart_Abort(recvChannel, UART_RECEIVE);
- // *rxlen = bufferIdx[recvChannel];
- // retVal = E_NOT_OK;
- // }
- // else
- // {
- // *rxlen = bufferIdx[recvChannel];
- // retVal = E_OK;
- // }
- // return retVal;
- //}
- extern Lpuart_Uart_Ip_StateStructureType *Lpuart_Uart_Ip_apStateStructuresArray[LPUART_UART_IP_NUMBER_OF_INSTANCES];
- void UART_Callback(uint32 hwInstance, Lpuart_Uart_Ip_EventType event)
- {
- // (void)userData;
- Lpuart_Uart_Ip_StateStructureType * UartState;
- UartState = (Lpuart_Uart_Ip_StateStructureType *)Lpuart_Uart_Ip_apStateStructuresArray[hwInstance];
- /* Check the event type */
- if (event == LPUART_UART_IP_EVENT_RX_FULL)
- {
- /* The reception stops when receiving idle is detected or the buffer is full */
- if (bufferIdx[hwInstance] <= (BUFFER_SIZE - DMA_SIZE))
- {
- /* Update the buffer index and the rx buffer */
- bufferIdx[hwInstance] += DMA_SIZE;
- Uart_SetBuffer(hwInstance, &RX_Buffer[hwInstance][bufferIdx[hwInstance]], DMA_SIZE, UART_RECEIVE);
- // Lpuart_Uart_Ip_SetRxBuffer(hwInstance, &RX_Buffer[bufferIdx], DMA_SIZE);
- }
- }
- if (event == LPUART_UART_IP_EVENT_ERROR)
- {
- // /*Get the transfered data size. DMA Channel 1 is used for LPUART DMA receiving, please modify accordingly.*/
- // temp = DMA_SIZE - (uint32_t)IP_DMA->TCD->CITER.ELINKNO;
- // /*Add the remaining data size to the sum of the received size*/
- // bufferIdx[hwInstance] += temp;
- /*Abort the receiving after detecting IDLE receiving*/
- Lpuart_Uart_Ip_AbortReceivingData(hwInstance);
- Lpuart_Uart_Ip_AbortSendingData(hwInstance);
- // bufferIdx = 0;
- }
- if (event == LPUART_UART_IP_EVENT_RECV_IDLE)
- {
- uint32_t temp;
- UartHalMsg_t UartHalMsg;
- UartHalMsg.Channel = hwInstance;
- UartHalMsg.event = event;
- /*Get the transfered data size. DMA Channel 1 is used for LPUART DMA receiving, please modify accordingly.*/
- temp = DMA_SIZE - (uint32_t)IP_DMA->TCD[hwInstance].CITER.ELINKNO;
- /*Add the remaining data size to the sum of the received size*/
- bufferIdx[hwInstance] += temp;
- /*Abort the receiving after detecting IDLE receiving*/
- UartHalMsg.value = bufferIdx[hwInstance];
- xQueueSendFromISR(UartHalQueueHandle,&UartHalMsg,pdFALSE);
- }
- }
- /*CAN*/
- Can_PduType Can_CreatePduInfo(Can_IdType id, CAN_IdFrameType idFrame, PduIdType swPduHandle, uint8 length, uint8 *sdu)
- {
- Can_PduType PduInfo;
- switch (idFrame)
- {
- case CAN_STANDARD_ID_TYPE:
- id = id & 0x7FF;
- break;
- case CANFD_STANDARD_ID_TYPE:
- id = (id & 0x7FF) | 0x40000000;
- break;
- case CAN_EXTENDED_ID_TYPE:
- id = id | 0x80000000;
- break;
- case CANFD_EXTENDED_ID_TYPE:
- id = id | 0xC0000000;
- break;
- default:
- id = id & 0x7FF;
- break;
- }
- PduInfo.id = id;
- PduInfo.swPduHandle = swPduHandle;
- PduInfo.length = length;
- PduInfo.sdu = sdu;
- return PduInfo;
- }
- Std_ReturnType CanIf_SendMessage(uint8 ControllerId, Can_Msg_Type CanMsg)
- {
- volatile Can_PduType Can_PduInfo;
- volatile Std_ReturnType CAN_Write_Status;
- Std_ReturnType retVal = E_NOT_OK;
- uint32 u8TimeOut = 100 * 100;
- Can_HwHandleType Hth = Can0HardwareObject_TX + (Can_HwHandleType)ControllerId; // controller 0 --> Can0HardwareObject_TX
- Can_PduInfo = Can_CreatePduInfo(CanMsg.id, CanMsg.idFrame, 0, CanMsg.length, CanMsg.sdu);
- CAN_Write_Status = Can_Write(Hth, &Can_PduInfo);
- CanIf_bTxFlag = FALSE;
- if (CAN_Write_Status == E_OK)
- {
- while ((!CanIf_bTxFlag) && (u8TimeOut != 0U))
- {
- Can_MainFunction_Write();
- u8TimeOut--;
- }
- }
- else
- {
- Can_MainFunction_BusOff();
- }
- if (CanIf_bTxFlag == TRUE)
- {
- retVal = E_OK;
- }
- else
- {
- retVal = E_NOT_OK;
- }
- return retVal;
- }
- Can_Msg_Type Can_GetMsgInfo(Can_IdType id, uint8 length, uint8 *sdu)
- {
- Can_Msg_Type CanMsgInfo;
- CanMsgInfo.idFrame = (CAN_IdFrameType)((id >> 30) & 0x03);
- if (CanMsgInfo.idFrame & 0x01)
- {
- CanMsgInfo.id = id & 0x7FF;
- }
- else
- {
- CanMsgInfo.id = id & 0x1FFFFFFF;
- }
- CanMsgInfo.length = length;
- CanMsgInfo.sdu = sdu;
- return CanMsgInfo;
- }
- void CanIf_ControllerBusOff(uint8 ControllerId)
- {
- (void)ControllerId;
- Can_SetControllerMode(ControllerId, CAN_CS_STARTED);
- }
- void CanIf_ControllerModeIndication(uint8 ControllerId, Can_ControllerStateType ControllerMode)
- {
- (void)ControllerId;
- (void)ControllerMode;
- }
- void CanIf_TxConfirmation(PduIdType CanTxPduId)
- {
- CanIf_u8TxConfirmCnt++;
- CanIf_bTxFlag = TRUE;
- (void)CanTxPduId;
- }
- void CanIf_RxIndication(const Can_HwType *Mailbox, const PduInfoType *PduInfoPtr)
- {
- Can_Msg_Type canRxMsg_Buff;
- Can_Msg_Type_Data canRxMsgQueueData;
- CanIf_bRxFlag = TRUE; // should not be delete
- // should put the msg into message queue
- canRxMsg_Buff = Can_GetMsgInfo(Mailbox->CanId, PduInfoPtr->SduLength, PduInfoPtr->SduDataPtr);
- canRxMsgQueueData.id = canRxMsg_Buff.id;
- canRxMsgQueueData.length = canRxMsg_Buff.length;
- memcpy(canRxMsgQueueData.data, canRxMsg_Buff.sdu, canRxMsgQueueData.length);
- switch(Mailbox->Hoh)
- {
- case 0:
- xQueueSend(CanRecvQueueHandle0, &canRxMsgQueueData, 0);
- break;
- case 1:
- xQueueSend(CanRecvQueueHandle1, &canRxMsgQueueData, 0);
- break;
- case 2:
- xQueueSend(CanRecvQueueHandle2, &canRxMsgQueueData, 0);
- break;
- }
- }
- void CanIf_CurrentIcomConfiguration(uint8 ControllerId, IcomConfigIdType ConfigurationId, IcomSwitch_ErrorType Error)
- {
- (void)ControllerId;
- (void)ConfigurationId;
- (void)Error;
- }
- void Notification_0(void)
- {
- ADC_Converter(ResultBuffer, ConvertedBuffer);
- memcpy(BattTempR, &ConvertedBuffer[3], 4 * sizeof(uint32));
- }
- void Notification_1(void)
- {
- VarNotification_1++;
- }
- Std_ReturnType ADC_Converter(Adc_ValueGroupType *Buffer, TP_Value_Type *ConvertedValueR)
- {
- Adc_ValueGroupType REFH, REFL;
- REFH = Buffer[0];
- REFL = Buffer[2];
- for (int i = 3; i < NUM_RESULTS; i++)
- {
- if (Buffer[i] >= REFH)
- {
- ConvertedValueR[i] = 40930000;
- }
- else if (Buffer[i] <= REFL)
- {
- ConvertedValueR[i] = 0x00;
- }
- else
- {
- ConvertedValueR[i] = (TP_Value_Type)((float)(10000 * (Buffer[i] - REFL) / (float)(REFH - REFL)) / (1 - (float)((Buffer[i] - REFL) / (float)(REFH - REFL))));
- }
- }
- return 0;
- }
- Std_ReturnType ADC_ReadValue()
- {
- Std_ReturnType ret = E_NOT_OK;
- for (uint8 i = 0; i < NUM_RESULTS; i++)
- {
- ResultBuffer[i] = 0xFFFF;
- ConvertedBuffer[i] = 0x00;
- }
- Adc_SetupResultBuffer(AdcGroupSoftwareOneShot, ResultBuffer);
- Adc_EnableGroupNotification(AdcGroupSoftwareOneShot);
- VarNotification_0 = 0;
- Adc_StartGroupConversion(AdcGroupSoftwareOneShot);
- return ret;
- }
- /*EEP*/
- static Std_ReturnType TestEep_FlexNvmProgramPartCmd(
- VAR(TestEep_CsecKeySize, AUTOMATIC) eepKeysize,
- VAR(TestEep_SfeType, AUTOMATIC) eepSecurityFlagExtension,
- VAR(TestEep_LoadFlexRamType, AUTOMATIC) eepLoadFlexRamAtReset,
- VAR(TestEep_Eeprom_FlexRamPartitionType, AUTOMATIC) eepFlexRamPartition,
- VAR(TestEep_Eeprom_FlexNvmPartitionType, AUTOMATIC) eepFlexNvmPartition)
- {
- Std_ReturnType u8RetVal = (Std_ReturnType)E_OK;
- uint32 u32FlexNvmPartSize = 0;
- uint32 u32RegSimFcfg1 = 0UL;
- u32RegSimFcfg1 = IP_SIM->FCFG1;
- /*get DEPART value */
- u32FlexNvmPartSize = (uint32)((u32RegSimFcfg1 & SIM_FCFG1_DEPART_MASK) >> SIM_FCFG1_DEPART_SHIFT);
- /* check that it was not partitioned before */
- if (u32FlexNvmPartSize == 0xF)
- {
- // /* if error flags are set the cmd is not executed */
- // REG_WRITE8(TEST_EEP_EEPROM_FSTAT_ADDR32, TEST_EEP_EEPROM_FSTAT_ACCERR_U8 | TEST_EEP_EEPROM_FSTAT_FPVIOL_U8);
- //
- // /*erase DF 0 sector*/
- // u32Addr=(TEST_EEP_DEEPROM_SECTOR_0_ADDR32 - D_EEPROM_BASE_ADDR) + 0x800000UL;
- //
- // REG_WRITE8(TEST_EEP_EEPROM_FCCOB0_ADDR32, TEST_EEP_EEPROM_CMD_ERASE_SECTOR);
- // REG_WRITE8(TEST_EEP_EEPROM_FCCOB1_ADDR32, (uint8)(u32Addr >> 16UL));
- // REG_WRITE8(TEST_EEP_EEPROM_FCCOB2_ADDR32, (uint8)(u32Addr >> 8UL));
- // REG_WRITE8(TEST_EEP_EEPROM_FCCOB3_ADDR32, (uint8)(u32Addr >> 0UL));
- // REG_WRITE8(TEST_EEP_EEPROM_FSTAT_ADDR32 , TEST_EEP_EEPROM_FSTAT_CCIF_U8);
- // while((0U == REG_BIT_GET8(TEST_EEP_EEPROM_FSTAT_ADDR32, TEST_EEP_EEPROM_FSTAT_CCIF_U8)))
- // {
- // }
- //
- if (0U == REG_BIT_GET8(TEST_EEP_EEPROM_FSTAT_ADDR32, TEST_EEP_EEPROM_FSTAT_ACCERR_U8 | TEST_EEP_EEPROM_FSTAT_FPVIOL_U8))
- {
- /* run program partition command */
- REG_WRITE8(TEST_EEP_EEPROM_FCCOB0_ADDR32, EEPROM_CMD_PROGRAM_PARTITION);
- REG_WRITE8(TEST_EEP_EEPROM_FCCOB1_ADDR32, (uint8)eepKeysize);
- REG_WRITE8(TEST_EEP_EEPROM_FCCOB2_ADDR32, (uint8)eepSecurityFlagExtension);
- REG_WRITE8(TEST_EEP_EEPROM_FCCOB3_ADDR32, (uint8)eepLoadFlexRamAtReset);
- REG_WRITE8(TEST_EEP_EEPROM_FCCOB4_ADDR32, (uint8)eepFlexRamPartition);
- REG_WRITE8(TEST_EEP_EEPROM_FCCOB5_ADDR32, (uint8)eepFlexNvmPartition);
- REG_WRITE8(TEST_EEP_EEPROM_FSTAT_ADDR32, TEST_EEP_EEPROM_FSTAT_CCIF_U8);
- while ((0U == REG_BIT_GET8(TEST_EEP_EEPROM_FSTAT_ADDR32, TEST_EEP_EEPROM_FSTAT_CCIF_U8)))
- {
- /* wait for operation to finish */
- }
- /* check if errors occured */
- if (REG_BIT_GET8(TEST_EEP_EEPROM_FSTAT_ADDR32, TEST_EEP_EEPROM_FSTAT_ACCERR_U8 | TEST_EEP_EEPROM_FSTAT_FPVIOL_U8))
- {
- /* NOK, error flags are set */
- u8RetVal = (Std_ReturnType)E_NOT_OK;
- }
- }
- else
- {
- /* NOK, error flags are set */
- u8RetVal = (Std_ReturnType)E_NOT_OK;
- }
- }
- else
- {
- /* NOK, partitioned already */
- u8RetVal = (Std_ReturnType)E_NOT_OK;
- }
- return u8RetVal;
- }
- void Eep_DepartParitition(TestEep_Eeprom_FlexNvmPartitionType T_EEP_SIZE)
- {
- uint32 u32FlexNvmPartSize = 0;
- uint32 u32RegSimFcfg1 = 0UL;
- u32RegSimFcfg1 = IP_SIM->FCFG1;
- /*get DEPART value */
- u32FlexNvmPartSize = (uint32)((u32RegSimFcfg1 & SIM_FCFG1_DEPART_MASK) >> SIM_FCFG1_DEPART_SHIFT);
- if (u32FlexNvmPartSize == 0xF) /* We just partition again if curent size different with expected */
- {
- /* partition for EERAM 64K with NOT loading EERAM at reset in hardware */
- TestEep_FlexNvmProgramPartCmd(EEP_FTFC_KEY_SIZE_0_BYTES, EEP_FTFC_VERIFY_ONLY_DISABLED,
- EEP_FTFC_LOAD_AT_RESET_ENABLED, EEP_FTFC_EERAM_SIZE_4K, T_EEP_SIZE);
- }
- }
- /* Erase memory by writing erase value */
- Std_ReturnType HAL_EEP_Erase(uint32 eepEraseStartAddr, uint32 eepEraseSize)
- {
- Std_ReturnType retReturnType = E_OK;
- MemIf_JobResultType retJobResultType;
- retReturnType = Eep_Erase(eepEraseStartAddr, eepEraseSize);
- if (E_OK != retReturnType)
- {
- return E_NOT_OK;
- }
- while (MEMIF_IDLE != Eep_GetStatus())
- {
- Eep_MainFunction();
- }
- retJobResultType = Eep_GetJobResult();
- if (MEMIF_JOB_OK != retJobResultType)
- {
- return E_NOT_OK;
- }
- return E_OK;
- }
- /* Write one or more complete eeprom pages to the eeprom device */
- Std_ReturnType HAL_EEP_Write(uint32 eepWriteStartAddr, uint8 *pDataNeedtoWrite, uint32 dataSize)
- {
- Std_ReturnType retReturnType = E_OK;
- MemIf_JobResultType retJobResultType;
- /*Erase the EEP before write*/
- retReturnType = HAL_EEP_Erase(eepWriteStartAddr, dataSize);
- if (E_OK != retReturnType)
- {
- return E_NOT_OK;
- }
- retReturnType = Eep_Write(eepWriteStartAddr, pDataNeedtoWrite, dataSize);
- if (E_OK != retReturnType)
- {
- return E_NOT_OK;
- }
- while (MEMIF_IDLE != Eep_GetStatus())
- {
- Eep_MainFunction();
- }
- retJobResultType = Eep_GetJobResult();
- if (MEMIF_JOB_OK != retJobResultType)
- {
- return E_NOT_OK;
- }
- return E_OK;
- }
- /* Reads from eeprom memory */
- Std_ReturnType HAL_EEP_Read(uint32 eepReadStartAddr, uint8 *pDataBuffer, uint32 dataSize)
- {
- Std_ReturnType retReturnType = E_OK;
- MemIf_JobResultType retJobResultType;
- retReturnType = Eep_Read(eepReadStartAddr, pDataBuffer, dataSize);
- if (E_OK != retReturnType)
- {
- return E_NOT_OK;
- }
- while (MEMIF_IDLE != Eep_GetStatus())
- {
- Eep_MainFunction();
- }
- retJobResultType = Eep_GetJobResult();
- if (MEMIF_JOB_OK != retJobResultType)
- {
- return E_NOT_OK;
- }
- return E_OK;
- }
- /* Compares a eeprom memory area with an application data buffer */
- Std_ReturnType HAL_EEP_Compare(uint32 eepCompareStartAddr, uint8 *pDataNeedtoCompare, uint32 dataSize)
- {
- Std_ReturnType retReturnType = E_OK;
- MemIf_JobResultType retJobResultType;
- retReturnType = Eep_Compare(eepCompareStartAddr, pDataNeedtoCompare, dataSize);
- if (E_OK != retReturnType)
- {
- return E_NOT_OK;
- }
- while (MEMIF_IDLE != Eep_GetStatus())
- {
- Eep_MainFunction();
- }
- retJobResultType = Eep_GetJobResult();
- if (MEMIF_JOB_OK != retJobResultType)
- {
- return E_NOT_OK;
- }
- return E_OK;
- }
- /* @brief VECTKEY value so that AIRCR register write is not ignored. */
- #define FEATURE_SCB_VECTKEY (0x05FAU)
- void SystemSoftwareReset(void)
- {
- uint32_t regValue;
- /* Read Application Interrupt and Reset Control Register */
- regValue = S32_SCB->AIRCR;
- /* Clear register key */
- regValue &= ~( S32_SCB_AIRCR_VECTKEY_MASK);
- /* Configure System reset request bit and Register Key */
- regValue |= S32_SCB_AIRCR_VECTKEY(FEATURE_SCB_VECTKEY);
- regValue |= S32_SCB_AIRCR_SYSRESETREQ(0x1u);
- /* Write computed register value */
- S32_SCB->AIRCR = regValue;
- }
- void MCUSleep(void)
- {
- #if (ICU_PRECOMPILE_SUPPORT == STD_ON)
- Icu_Init(NULL_PTR);
- #elif (ICU_PRECOMPILE_SUPPORT == STD_OFF)
- Icu_Init(&Icu_Config_VS_0);
- #endif
- Mcu_SetMode(McuModeSettingConf_VLPS);
- // typedef void (*AppAddr)(void);
- // AppAddr resetHandle = (AppAddr)(0x14601);
- // OsIf_SuspendAllInterrupts();
- // (resetHandle)();
- SystemSoftwareReset();
- // coreInit();
- }
- void SystemDeinit(void)
- {
- Dio_WriteChannel(DioConf_DioChannel_PTA7_GPIO_OUT_MCU_4G_PWRKEY, STD_OFF);
- vTaskDelay(pdMS_TO_TICKS(3000));
- Dio_WriteChannel(DioConf_DioChannel_PTA6_GPIO_OUT_MCU_4G_POW_EN, STD_OFF);
- Dio_WriteChannel(DioConf_DioChannel_PTD1_GPIO_OUT_MCU_GPS_POW_EN, STD_OFF);//GPS ShutDown
- Dio_WriteChannel(DioConf_DioChannel_PTE7_GPIO_OUT_MCU_LED3, STD_ON);
- Dio_WriteChannel(DioConf_DioChannel_PTE1_GPIO_OUT_MCU_LED2, STD_ON);
- Dio_WriteChannel(DioConf_DioChannel_PTE0_GPIO_OUT_MCU_LED1, STD_ON);
- Uart_Deinit();
- Can_SetControllerMode(CanController_0, CAN_CS_STOPPED);
- Can_SetControllerMode(CanController_1, CAN_CS_STOPPED);
- // Can_SetControllerMode(CanController_2, CAN_CS_STOPPED);
- Dio_WriteChannel(DioConf_DioChannel_PTC17_GPIO_OUT_MCU_CAN0_STB, STD_ON);
- Dio_WriteChannel(DioConf_DioChannel_PTC16_GPIO_OUT_MCU_CAN1_STB, STD_ON);
- Can_DeInit();
- Adc_DeInit();
- Gpt_DisableNotification(GptConf_GptChannelConfiguration_GptChannelConfiguration_0);
- Gpt_DeInit();
- Spi_DeInit();
- Mcl_DeInit();
- //port DeInit
- for(int pinIndex = 0; pinIndex <PortConfigSet_PortContainer_GPIO_PTB4_GPIO_OUT_MCU_RS485_EN; pinIndex++)
- {
- if(pinIndex == PortConfigSet_PortContainer_CAN_PTA12_CAN1_RX_MCU_CAN1_RX
- || pinIndex == PortConfigSet_PortContainer_INT_PTE11_GPIO_IN_MCU_3D_INT1
- || pinIndex == PortConfigSet_PortContainer_INT_PTD5_GPIO_IN_MCU_3D_INT2
- || pinIndex == PortConfigSet_PortContainer_INT_PTB0_GPIO_IN_MCU_WAKEUP1
- || pinIndex == PortConfigSet_PortContainer_INT_PTE2_GPIO_IN_MCU_WAKEUP2)
- {
- continue;
- }
- else
- {
- Port_SetAsUnusedPin(pinIndex);
- }
- }
- Port_SetPinMode(PortConfigSet_PortContainer_CAN_PTA12_CAN1_RX_MCU_CAN1_RX,PORT_GPIO_MODE);
- // systemInitFlag = false;
- }
- void MCUEnterSleep(void)
- {
- if(pdTRUE == xSemaphoreTake(sleep_mutex,1) && Fota_Process_Going == false)
- {
- extern boolean Uart_4G_Task_Sleep_FLag;
- WdgDeInit();
- Std_ReturnType Ret = E_NOT_OK;
- uint8 appConfigWriteTimes = 0;
- do
- {
- waitForSleepFlag = true;
- //save the app configure before power off
- if(Ret == E_NOT_OK)
- {
- AppConfigInfo.appSaveFlg = false;
- Ret = HAL_EEP_Write(0,(uint8 *)&AppConfigInfo,sizeof(AppConfigInfo));
- appConfigWriteTimes++;
- }
- vTaskDelay(pdMS_TO_TICKS(10));
- }while(Uart_4G_Task_Sleep_FLag == false || (Ret == E_NOT_OK && appConfigWriteTimes<5) );
- vTaskDelete(Uart_Hal_RecvTask_Handle);
- vTaskDelete(Uart_Hal_SendTask_Handle);
- vTaskDelete(CanTask_Handle);
- vTaskDelete(GpsTask_Handle);
- vTaskDelete(Uart_4G_Task_Handle);
- // vTaskDelete(MainTask_Handle);
- SystemDeinit();
- MCUSleep();
- // WdgInit();
- // DoResetECUWithWdg();
- }
- }
- void coreInit(void)
- {
- /* Initialize the Mcu driver */
- #if (MCU_PRECOMPILE_SUPPORT == STD_ON)
- Mcu_Init(NULL_PTR);
- #elif (MCU_PRECOMPILE_SUPPORT == STD_OFF)
- Mcu_Init(&Mcu_Config_VS_0);
- #endif /* (MCU_PRECOMPILE_SUPPORT == STD_ON) */
- Mcu_InitClock(McuClockSettingConfig_0);
- /* Wait until PLL is locked */
- while (MCU_PLL_LOCKED != Mcu_GetPllStatus())
- {
- /* Busy wait until the System PLL is locked */
- }
- Mcu_DistributePllClock();
- OsIf_Init(NULL_PTR);
- Platform_Init(NULL_PTR);
- /* Initialize all pins*/
- #if (PORT_PRECOMPILE_SUPPORT == STD_ON)
- Port_Init(NULL_PTR);
- #elif (PORT_PRECOMPILE_SUPPORT == STD_OFF)
- Port_Init(&Port_Config_VS_0);
- #endif
- }
- void SystemModulesInit(void)
- {
- // Dio_WriteChannel(DioConf_DioChannel_PTE0_GPIO_OUT_MCU_LED1, STD_OFF);
- /* Initialize Mcl module */
- Mcl_Init(NULL_PTR);
- SEGGER_RTT_Init();
- /* Initializes an UART driver*/
- #if (UART_PRECOMPILE_SUPPORT == STD_ON)
- Uart_Init(NULL_PTR);
- #elif (UART_PRECOMPILE_SUPPORT == STD_OFF)
- Uart_Init(&Uart_xConfig_VS_0);
- #endif
- IP_LPUART0->CTRL |= LPUART_CTRL_ILT(1);
- IP_LPUART1->CTRL |= LPUART_CTRL_ILT(1);
- IP_LPUART2->CTRL |= LPUART_CTRL_ILT(1);
- IP_LPUART0->CTRL |= LPUART_CTRL_IDLECFG(3);
- IP_LPUART1->CTRL |= LPUART_CTRL_IDLECFG(3);
- IP_LPUART2->CTRL |= LPUART_CTRL_IDLECFG(3);
- #if 1 /* Initialize Platform driver */
- #if (CAN_PRECOMPILE_SUPPORT == STD_ON)
- Can_Init(NULL_PTR);
- #elif (CAN_PRECOMPILE_SUPPORT == STD_OFF)
- Can_Init(&Can_Config_VS_0);
- #endif
- Can_SetControllerMode(CanController_0, CAN_CS_STARTED);
- Can_SetControllerMode(CanController_1, CAN_CS_STARTED);
- Dio_WriteChannel(DioConf_DioChannel_PTC17_GPIO_OUT_MCU_CAN0_STB, STD_OFF);
- Dio_WriteChannel(DioConf_DioChannel_PTC16_GPIO_OUT_MCU_CAN1_STB, STD_OFF);
- // Can_SetControllerMode(CanController_2, CAN_CS_STARTED);
- #endif
- #if (ADC_PRECOMPILE_SUPPORT == STD_ON)
- Adc_Init(NULL_PTR);
- #else
- Adc_Init(&Adc_Config_VS_0);
- #endif /* ADC_PRECOMPILE_SUPPORT == STD_ON */
- /* Partition only if it was not partitioned before for EERAM with code 0x4 */
- // Eep_DepartParitition(T_EEEPROM_SIZE);
- /* Initialize Eep driver */
- #if defined (EEP_PRECOMPILE_SUPPORT)
- Eep_Init(NULL_PTR);
- #else
- Eep_Init(&Eep_Config_VS_0);
- #endif
- //Init Flash Driver
- #if defined (FLS_PRECOMPILE_SUPPORT)
- Fls_Init(NULL_PTR);
- #else
- Fls_Init(&Fls_Config_VS_0);
- while(MEMIF_IDLE == Fls_GetStatus())
- {
- ;
- }
- #endif
- Spi_Init(NULL_PTR);
- /* Initialize the Gpt driver */
- Gpt_Init(&Gpt_Config_VS_0);
- /* Enable the Gpt notification to periodically service the Wdg */
- Gpt_EnableNotification(GptConf_GptChannelConfiguration_GptChannelConfiguration_0);
- Icu_DeInit();
- WdgInit();
- IsFeedWdg = true;
- }
- void displayResetReasonWithLED(void)
- {
- Mcu_ResetType bootreason;
- bootreason = Mcu_GetResetReason();
- }
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