Mercurial > public > ostc4
view Discovery/Src/tCCR.c @ 837:18946846b95b Evo_2_23
Bugfixes and code cleanup for BF views:
BF views gauge and apnoe were using "dive computer" T3 view functions which caused some problem because these legacy views were not intended to work with customer view selection. A switch condition has been added to skip these kind of functions in case a design other T3 is in use.
Another potential problem was that there were two definitions for T3 and T7 views which were basically the same. If they wold not be the same the switching functionality wold not work properly. To avoid this problem in futur the arrays have been merged => the view are handled sing the (newer) cv_view arrays instead of the standard_views which were in used before the user could the views which should be shown.
author | ideenmodellierer |
---|---|
date | Wed, 27 Dec 2023 19:37:17 +0100 |
parents | acf6614dc396 |
children | 4d98fb2a178e |
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/////////////////////////////////////////////////////////////////////////////// /// -*- coding: UTF-8 -*- /// /// \file Discovery/Src/tCCR.c /// \brief HUD data via optical port /// \author Heinrichs Weikamp gmbh /// \date 18-Dec-2014 /// /// \details /// /// $Id$ /////////////////////////////////////////////////////////////////////////////// /// \par Copyright (c) 2014-2018 Heinrichs Weikamp gmbh /// /// This program is free software: you can redistribute it and/or modify /// it under the terms of the GNU General Public License as published by /// the Free Software Foundation, either version 3 of the License, or /// (at your option) any later version. /// /// This program is distributed in the hope that it will be useful, /// but WITHOUT ANY WARRANTY; without even the implied warranty of /// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the /// GNU General Public License for more details. /// /// You should have received a copy of the GNU General Public License /// along with this program. If not, see <http://www.gnu.org/licenses/>. ////////////////////////////////////////////////////////////////////////////// /* Includes ------------------------------------------------------------------*/ #include <string.h> #include "tCCR.h" #include "ostc.h" #include "data_central.h" #include "data_exchange.h" #include "check_warning.h" #include "configuration.h" #include <math.h> /* Private types -------------------------------------------------------------*/ typedef struct { uint8_t hud_firmwareVersion; bit8_Type status_byte; uint16_t sensor_voltage_100uV[3]; uint8_t sensor_ppo2_cbar[3]; uint8_t temp1; uint16_t battery_voltage_mV; uint16_t checksum; } SIrLink; typedef enum { sensorOK = 0, sensorSuspect, SensorOutOfBounds } sensorTrustState_t; #define HUD_BABBLING_IDIOT (30u) /* 30 Bytes received without break */ #define HUD_RX_FRAME_LENGTH (15u) /* Length of a HUD data frame */ #define HUD_RX_FRAME_BREAK_MS (100u) /* Time used to detect a gap between two byte receptions => frame start */ #define HUD_RX_START_DELAY_MS (500u) /* Delay for start of RX function to avoid start of reception while a transmission is ongoing. */ /* Based on an assumed cycle time by the sensor of 1 second. Started at time of last RX */ #define BOTTLE_SENSOR_TIMEOUT (6000u) /* signal pressure budget as not received after 10 minutes (6000 * 100ms) */ #define MAX_SENSOR_COMPARE_DEVIATION (0.15f) /* max deviation between two sensors allowed before their results are rated as suspect */ #define MAX_SENSOR_VOLTAGE_MV (250u) /* max allowed voltage value for a sensor measurement */ #ifdef ENABLE_ALTERNATIVE_SENSORTYP #define MIN_SENSOR_VOLTAGE_MV (3u) /* min allowed voltage value for a sensor measurement (Inspiration, Submatix, Sentinel Typ) */ #else #define MIN_SENSOR_VOLTAGE_MV (8u) /* min allowed voltage value for a sensor measurement (legacy OSTC TYP) */ #endif /* Private variables ---------------------------------------------------------*/ static SIrLink receiveHUD[2]; static uint8_t boolHUDdata = 0; static uint8_t data_old__lost_connection_to_HUD = 1; static uint8_t receiveHUDraw[16]; static uint8_t StartListeningToUART_HUD = 0; static uint16_t HUDTimeoutCount = 0; static uint16_t ScrubberTimeoutCount = 0; static __IO ITStatus UartReadyHUD = RESET; static uint32_t LastReceivedTick_HUD = 0; /* Private variables with external access via get_xxx() function -------------*/ /* Private function prototypes -----------------------------------------------*/ static uint8_t tCCR_fallbackToFixedSetpoint(void); #ifndef USART_IR_HUD void tCCR_init(void) { } void tCCR_control(void) { } void tCCR_test(void) { } void tCCR_restart(void) { } float get_ppO2Sensor_bar(uint8_t sensor_id) { } float get_sensorVoltage_mV(uint8_t sensor_id) { } float get_HUD_battery_voltage_V(void) { } void tCCR_tick(void) { } #else /* Exported functions --------------------------------------------------------*/ float get_ppO2Sensor_bar(uint8_t sensor_id) { if((sensor_id > 2) || data_old__lost_connection_to_HUD) return 0; return (float)(receiveHUD[boolHUDdata].sensor_ppo2_cbar[sensor_id]) / 100.0f; } float get_sensorVoltage_mV(uint8_t sensor_id) { if((sensor_id > 2) || data_old__lost_connection_to_HUD) return 0; return (float)(receiveHUD[boolHUDdata].sensor_voltage_100uV[sensor_id]) / 10.0f; } float get_HUD_battery_voltage_V(void) { if(data_old__lost_connection_to_HUD) return 0; return (float)(receiveHUD[boolHUDdata].battery_voltage_mV) / 1000.0f; } void test_O2_sensor_values_outOfBounds(int8_t * outOfBouds1, int8_t * outOfBouds2, int8_t * outOfBouds3) { uint8_t sensorNotActiveBinary; uint8_t sensorActive[3]; sensorTrustState_t sensorState[3]; uint8_t index; // test1: user deactivation sensorNotActiveBinary = stateUsed->diveSettings.ppo2sensors_deactivated; for(int i=0;i<3;i++) sensorActive[i] = 1; if(sensorNotActiveBinary) { if(sensorNotActiveBinary & 1) sensorActive[0] = 0; if(sensorNotActiveBinary & 2) sensorActive[1] = 0; if(sensorNotActiveBinary & 4) sensorActive[2] = 0; } // test2: mV of remaining sensors for(index=0; index<3; index++) { sensorState[index] = sensorOK; if(sensorActive[index]) { if(((stateUsed->lifeData.extIf_sensor_map[index] == SENSOR_DIGO2M) && (((SSensorDataDiveO2*)(stateUsed->lifeData.extIf_sensor_data[index]))->status & DVO2_FATAL_ERROR)) || ((stateUsed->lifeData.extIf_sensor_map[index] != SENSOR_DIGO2M) && (((stateUsed->lifeData.sensorVoltage_mV[index] < MIN_SENSOR_VOLTAGE_MV) || (stateUsed->lifeData.sensorVoltage_mV[index] > MAX_SENSOR_VOLTAGE_MV))))) { sensorActive[index] = 0; switch(index) { case 0: sensorNotActiveBinary |= 1; break; case 1: sensorNotActiveBinary |= 2; break; case 2: sensorNotActiveBinary |= 4; break; } } } } *outOfBouds1 = 0; *outOfBouds2 = 0; *outOfBouds3 = 0; /* with two, one or no sensor, there is nothing to compare anymore */ if(sensorNotActiveBinary) { // set outOfBounds for both tests if(!sensorActive[0]) *outOfBouds1 = 1; if(!sensorActive[1]) *outOfBouds2 = 1; if(!sensorActive[2]) *outOfBouds3 = 1; } else { /* Check two or more of Three */ /* compare every sensor with each other. If there is only one mismatch the value might be OK. In case both comparisons fail the sensor is out of bounds */ if(fabsf(stateUsed->lifeData.ppO2Sensor_bar[0] - stateUsed->lifeData.ppO2Sensor_bar[1]) > MAX_SENSOR_COMPARE_DEVIATION) { sensorState[0]++; sensorState[1]++; } if(fabsf(stateUsed->lifeData.ppO2Sensor_bar[0] - stateUsed->lifeData.ppO2Sensor_bar[2]) > MAX_SENSOR_COMPARE_DEVIATION) { sensorState[0]++; sensorState[2]++; } if(fabsf(stateUsed->lifeData.ppO2Sensor_bar[1] - stateUsed->lifeData.ppO2Sensor_bar[2]) > MAX_SENSOR_COMPARE_DEVIATION) { sensorState[1]++; sensorState[2]++; } for(index = 0; index < 3; index++) { if(sensorState[index] == SensorOutOfBounds) { switch(index) { case 0: *outOfBouds1 = 1; break; case 1: *outOfBouds2 = 1; break; case 2: *outOfBouds3 = 1; break; default: break; } } } } } /* this function is called out of the 100ms callback => to be considered for debouncing */ uint8_t get_ppO2SensorWeightedResult_cbar(void) { static uint8_t lastValidValue = 0; int8_t sensorOutOfBound[3]; uint16_t result = 0; uint8_t count = 0; uint8_t retVal = 0; test_O2_sensor_values_outOfBounds(&sensorOutOfBound[0], &sensorOutOfBound[1], &sensorOutOfBound[2]); for(int i=0;i<3;i++) { if(!sensorOutOfBound[i]) { result += stateUsed->lifeData.ppO2Sensor_bar[i] * 100.0; /* convert centibar used by HUB */ count++; } } if(count == 0) /* all sensors out of bounds! => return last valid value as workaround till diver takes action */ { if(debounce_warning_fallback(100)) { set_warning_fallback(); retVal = tCCR_fallbackToFixedSetpoint(); /* this function only changes setpoint if option is enabled */ } if(retVal == 0) { retVal = lastValidValue; } } else { reset_debounce_warning_fallback(); retVal = (uint8_t)(result / count); lastValidValue = retVal; } return retVal; } void tCCR_init(void) { uint8_t loop; StartListeningToUART_HUD = 1; SDiveState* pDiveData = stateRealGetPointerWrite(); for(loop=0;loop<(2*NUM_GASES+1);loop++) { pDiveData->lifeData.bottle_bar_age_MilliSeconds[loop] = BOTTLE_SENSOR_TIMEOUT; } } /* after 3 seconds without update from HUD * data is considered old */ void tCCR_tick(void) { SSettings* pSettings = settingsGetPointer(); if(pSettings->ppo2sensors_source == O2_SENSOR_SOURCE_OPTIC) { if(HUDTimeoutCount < 3 * 10) HUDTimeoutCount++; else { data_old__lost_connection_to_HUD = 1; if(HUDTimeoutCount < 20 * 10) HUDTimeoutCount++; else tCCR_fallbackToFixedSetpoint(); } } /* decrease scrubber timer only in real dive mode, and if we are not bailed out */ if((pSettings->scrubTimerMode != SCRUB_TIMER_OFF) && (isLoopMode(pSettings->dive_mode)) && (stateUsed->mode == MODE_DIVE) && isLoopMode(stateUsed->diveSettings.diveMode)) // && (stateUsed == stateRealGetPointer())) { ScrubberTimeoutCount++; if(ScrubberTimeoutCount >= 600) /* resolution is minutes */ { ScrubberTimeoutCount = 0; if(pSettings->scrubberData[pSettings->scubberActiveId].TimerCur > MIN_SCRUBBER_TIME) { pSettings->scrubberData[pSettings->scubberActiveId].TimerCur--; } translateDate(stateUsed->lifeData.dateBinaryFormat, &pSettings->scrubberData[pSettings->scubberActiveId].lastDive); } } } void tCCR_SetRXIndication(void) { static uint8_t floatingRXCount = 0; if((UartIR_HUD_Handle.RxXferSize == HUD_RX_FRAME_LENGTH) || (UartIR_HUD_Handle.RxXferSize == HUD_RX_FRAME_LENGTH - 1)) /* we expected a complete frame */ { UartReadyHUD = SET; LastReceivedTick_HUD = HAL_GetTick(); floatingRXCount = 0; } else /* follow up of error handling */ { if(time_elapsed_ms(LastReceivedTick_HUD, HAL_GetTick()) > HUD_RX_FRAME_BREAK_MS) /* Reception took a while => frame start detected */ { HAL_UART_Receive_IT(&UartIR_HUD_Handle, &receiveHUDraw[1], 14); /* We have already the first byte => get the missing 14 */ } else { if(floatingRXCount++ < HUD_BABBLING_IDIOT) { HAL_UART_Receive_IT(&UartIR_HUD_Handle, receiveHUDraw, 1); /* Start polling of incoming bytes */ } else /* Significant amount of data comming in without break => disable input */ { /* by not reactivation HUD RX, no recovery fromthis state */ stateUsedWrite->diveSettings.ppo2sensors_deactivated = 0x07; /* Display deactivation */ } } } } void tCCR_restart(void) { HAL_UART_AbortReceive_IT(&UartIR_HUD_Handle); /* Called by the error handler. RX will be restarted by control function */ StartListeningToUART_HUD = 1; } void tCCR_control(void) { uint16_t checksum = 0; #ifdef ENABLE_BOTTLE_SENSOR SDiveState *pLivedata = stateRealGetPointerWrite(); #endif if((UartReadyHUD == RESET) && StartListeningToUART_HUD && (time_elapsed_ms(LastReceivedTick_HUD, HAL_GetTick()) > HUD_RX_START_DELAY_MS)) { StartListeningToUART_HUD = 0; HAL_UART_Receive_IT(&UartIR_HUD_Handle, receiveHUDraw, HUD_RX_FRAME_LENGTH); } if(UartReadyHUD == SET) { UartReadyHUD = RESET; StartListeningToUART_HUD = 1; /* check if received package is valid */ for(int i=0;i<13;i++) { checksum += receiveHUDraw[i]; } receiveHUD[!boolHUDdata].checksum = receiveHUDraw[13] + (256 * receiveHUDraw[14]); if(checksum == receiveHUD[!boolHUDdata].checksum) { #ifdef ENABLE_BOTTLE_SENSOR if(receiveHUDraw[0] == 0xA5) /* code for pressure sensor */ { pLivedata->lifeData.bottle_bar[pLivedata->lifeData.actualGas.GasIdInSettings] = receiveHUDraw[10]; pLivedata->lifeData.bottle_bar_age_MilliSeconds[pLivedata->lifeData.actualGas.GasIdInSettings] = 0; } else #endif /* handle O2 sensor data */ { memcpy(&receiveHUD[!boolHUDdata], receiveHUDraw, 11); receiveHUD[!boolHUDdata].battery_voltage_mV = receiveHUDraw[11] + (256 * receiveHUDraw[12]); } boolHUDdata = !boolHUDdata; HUDTimeoutCount = 0; data_old__lost_connection_to_HUD = 0; } else { if(data_old__lost_connection_to_HUD) /* we lost connection, maybe due to RX shift => start single byte read to resynchronize */ { HAL_UART_Receive_IT(&UartIR_HUD_Handle, receiveHUDraw, 1); StartListeningToUART_HUD = 0; } } memset(receiveHUDraw,0,sizeof(receiveHUDraw)); } } #endif /* Private functions ---------------------------------------------------------*/ static uint8_t tCCR_fallbackToFixedSetpoint(void) { uint8_t retVal = 0; uint8_t setpointCbar, actualGasID; if((stateUsed->mode == MODE_DIVE) && (stateUsed->diveSettings.CCR_Mode == CCRMODE_Sensors) && (stateUsed->diveSettings.fallbackOption)) { if(stateUsed->diveSettings.diveMode == DIVEMODE_CCR) { setpointCbar = stateUsed->diveSettings.setpoint[1].setpoint_cbar; stateUsedWrite->diveSettings.CCR_Mode = CCRMODE_FixedSetpoint; } else { setpointCbar = stateUsed->lifeData.ppo2Simulated_bar * 100; stateUsedWrite->diveSettings.CCR_Mode = CCRMODE_Simulation; } actualGasID = stateUsed->lifeData.actualGas.GasIdInSettings; setActualGas_DM(&stateUsedWrite->lifeData,actualGasID,setpointCbar); set_warning_fallback(); retVal = setpointCbar; } return retVal; }