Mercurial > public > ostc4
view Small_CPU/Src/uartProtocol_GNSS.c @ 928:9b7859554beb Evo_2_23 tip
Cleanup Internal Uart:
The compile switches have been updated to allow GNSS data flow if new GPIO config is available or if GNSS is enabled for the external UART.
author | Ideenmodellierer |
---|---|
date | Tue, 26 Nov 2024 21:30:06 +0100 |
parents | 7c996354b8ac |
children |
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/** ****************************************************************************** * @file uartProtocol_GNSS.c * @author heinrichs weikamp gmbh * @version V0.0.1 * @date 30-Sep-2024 * @brief Interface functionality operation of GNSS devices * @verbatim @endverbatim ****************************************************************************** * @attention * * <h2><center>© COPYRIGHT(c) 2024 heinrichs weikamp</center></h2> * ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include <string.h> #include "scheduler.h" #include <uartProtocol_GNSS.h> #include "uart.h" #include "GNSS.h" #include "configuration.h" #include "externalInterface.h" #if defined ENABLE_GNSS || defined ENABLE_GNSS_SUPPORT static receiveStateGnss_t rxState = GNSSRX_READY; static uint8_t GnssConnected = 0; /* Binary indicator if a sensor is connected or not */ static uint8_t writeIndex = 0; static uint8_t dataToRead = 0; 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 uartGnss_SendCmd(uint8_t GnssCmd) { const uint8_t* pData; uint8_t txLength = 0; switch (GnssCmd) { case GNSSCMD_LOADCONF_0: pData = configUBX; txLength = sizeof(configUBX) / sizeof(uint8_t); break; case GNSSCMD_LOADCONF_1: pData = setNMEA410; txLength = sizeof(setNMEA410) / sizeof(uint8_t); break; case GNSSCMD_LOADCONF_2: pData = setGNSS; txLength = sizeof(setGNSS) / sizeof(uint8_t); break; case GNSSCMD_GET_PVT_DATA: pData = getPVTData; txLength = sizeof(getPVTData) / sizeof(uint8_t); break; case GNSSCMD_GET_NAV_DATA: pData = getNavigatorData; txLength = sizeof(getNavigatorData) / sizeof(uint8_t); break; default: break; } if(txLength != 0) { UART_SendCmdUbx(pData, txLength); } } void uartGnss_Control(void) { static uint32_t warmupTick = 0; uint8_t activeSensor = externalInterface_GetActiveUartSensor(); uartGnssStatus_t localComState = externalInterface_GetSensorState(activeSensor + EXT_INTERFACE_MUX_OFFSET); switch (localComState) { case UART_GNSS_INIT: localComState = UART_GNSS_WARMUP; warmupTick = HAL_GetTick(); UART_clearRxBuffer(); break; case UART_GNSS_WARMUP: if(time_elapsed_ms(warmupTick,HAL_GetTick()) > 1000) { localComState = UART_GNSS_LOADCONF_0; } break; case UART_GNSS_LOADCONF_0: uartGnss_SendCmd(GNSSCMD_LOADCONF_0); localComState = UART_GNSS_LOADCONF_1; rxState = GNSSRX_DETECT_ACK_0; break; case UART_GNSS_LOADCONF_1: uartGnss_SendCmd(GNSSCMD_LOADCONF_1); localComState = UART_GNSS_LOADCONF_2; rxState = GNSSRX_DETECT_ACK_0; break; case UART_GNSS_LOADCONF_2: uartGnss_SendCmd(GNSSCMD_LOADCONF_2); localComState = UART_GNSS_IDLE; rxState = GNSSRX_DETECT_ACK_0; break; case UART_GNSS_IDLE: uartGnss_SendCmd(GNSSCMD_GET_PVT_DATA); localComState = UART_GNSS_GET_PVT; rxState = GNSSRX_DETECT_HEADER_0; break; default: break; } externalInterface_SetSensorState(activeSensor + EXT_INTERFACE_MUX_OFFSET,localComState); } void uartGnss_ProcessData(uint8_t data) { uint8_t activeSensor = externalInterface_GetActiveUartSensor(); GNSS_Handle.uartWorkingBuffer[writeIndex++] = data; switch(rxState) { case GNSSRX_DETECT_ACK_0: case GNSSRX_DETECT_HEADER_0: if(data == 0xB5) { writeIndex = 0; memset(GNSS_Handle.uartWorkingBuffer,0, sizeof(GNSS_Handle.uartWorkingBuffer)); GNSS_Handle.uartWorkingBuffer[writeIndex++] = data; rxState++; } break; case GNSSRX_DETECT_ACK_1: case GNSSRX_DETECT_HEADER_1: if(data == 0x62) { rxState++; } else { rxState = GNSSRX_DETECT_HEADER_0; } break; case GNSSRX_DETECT_ACK_2: if(data == 0x05) { rxState++; } else { rxState = GNSSRX_DETECT_HEADER_0; } break; case GNSSRX_DETECT_ACK_3: if((data == 0x01) || (data == 0x00)) { GnssConnected = 1; rxState = GNSSRX_READY; } else { rxState = GNSSRX_DETECT_HEADER_0; } break; case GNSSRX_DETECT_HEADER_2: if(data == 0x01) { rxState++; } else { rxState = GNSSRX_DETECT_HEADER_0; } break; case GNSSRX_DETECT_HEADER_3: switch(data) { case 0x21: rxState = GNSSRX_READ_NAV_DATA; dataToRead = 20; break; case 0x07: rxState = GNSSRX_READ_PVT_DATA; dataToRead = 92; break; case 0x02: rxState = GNSSRX_READ_POSLLH_DATA; break; default: rxState = GNSSRX_DETECT_HEADER_0; break; } break; case GNSSRX_READ_NAV_DATA: case GNSSRX_READ_PVT_DATA: case GNSSRX_READ_POSLLH_DATA: if(dataToRead > 0) { dataToRead--; } else { switch(rxState) { case GNSSRX_READ_NAV_DATA: GNSS_ParseNavigatorData(&GNSS_Handle); break; case GNSSRX_READ_PVT_DATA: GNSS_ParsePVTData(&GNSS_Handle); break; case GNSSRX_READ_POSLLH_DATA: GNSS_ParsePOSLLHData(&GNSS_Handle); break; default: rxState = GNSSRX_DETECT_HEADER_0; break; } rxState = GNSSRX_DETECT_HEADER_0; externalInterface_SetSensorState(activeSensor + EXT_INTERFACE_MUX_OFFSET,UART_GNSS_IDLE); } break; default: rxState = GNSSRX_READY; break; } } uint8_t uartGnss_isSensorConnected() { return GnssConnected; } #endif