408 lines
17 KiB
C++
408 lines
17 KiB
C++
#include "AcsBoardAssembly.h"
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#include <devices/gpioIds.h>
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#include <fsfw/power/PowerSwitchIF.h>
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#include <fsfw/serviceinterface.h>
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#include "OBSWConfig.h"
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AcsBoardAssembly::AcsBoardAssembly(object_id_t objectId, PowerSwitchIF* switcher,
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AcsBoardHelper helper, GpioIF* gpioIF)
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: DualLaneAssemblyBase(objectId, switcher, SWITCH_A, SWITCH_B, POWER_STATE_MACHINE_TIMEOUT,
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SIDE_SWITCH_TRANSITION_NOT_ALLOWED, TRANSITION_OTHER_SIDE_FAILED),
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helper(helper),
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gpioIF(gpioIF) {
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if (switcher == nullptr) {
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sif::error << "AcsBoardAssembly::AcsBoardAssembly: Invalid Power Switcher "
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"IF passed"
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<< std::endl;
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}
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if (gpioIF == nullptr) {
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sif::error << "AcsBoardAssembly::AcsBoardAssembly: Invalid GPIO IF passed" << std::endl;
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}
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ModeListEntry entry;
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initModeTableEntry(helper.mgm0Lis3IdSideA, entry, modeTable);
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initModeTableEntry(helper.mgm1Rm3100IdSideA, entry, modeTable);
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initModeTableEntry(helper.mgm2Lis3IdSideB, entry, modeTable);
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initModeTableEntry(helper.mgm3Rm3100IdSideB, entry, modeTable);
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initModeTableEntry(helper.gyro0AdisIdSideA, entry, modeTable);
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initModeTableEntry(helper.gyro1L3gIdSideA, entry, modeTable);
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initModeTableEntry(helper.gyro2AdisIdSideB, entry, modeTable);
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initModeTableEntry(helper.gyro3L3gIdSideB, entry, modeTable);
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initModeTableEntry(helper.gpsId, entry, modeTable);
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}
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ReturnValue_t AcsBoardAssembly::commandChildren(Mode_t mode, Submode_t submode) {
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using namespace duallane;
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ReturnValue_t result = returnvalue::OK;
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refreshHelperModes();
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// Initialize the mode table to ensure all devices are in a defined state
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modeTable[ModeTableIdx::GYRO_0_A].setMode(MODE_OFF);
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modeTable[ModeTableIdx::GYRO_0_A].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::GYRO_1_A].setMode(MODE_OFF);
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modeTable[ModeTableIdx::GYRO_1_A].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::GYRO_2_B].setMode(MODE_OFF);
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modeTable[ModeTableIdx::GYRO_2_B].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::GYRO_3_B].setMode(MODE_OFF);
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modeTable[ModeTableIdx::GYRO_3_B].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::MGM_0_A].setMode(MODE_OFF);
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modeTable[ModeTableIdx::MGM_0_A].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::MGM_1_A].setMode(MODE_OFF);
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modeTable[ModeTableIdx::MGM_1_A].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::MGM_2_B].setMode(MODE_OFF);
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modeTable[ModeTableIdx::MGM_2_B].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::MGM_3_B].setMode(MODE_OFF);
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modeTable[ModeTableIdx::MGM_3_B].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::GPS].setMode(MODE_OFF);
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modeTable[ModeTableIdx::GPS].setSubmode(SUBMODE_NONE);
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if (recoveryState == RecoveryState::RECOVERY_IDLE) {
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result = checkAndHandleHealthStates(mode, submode);
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if (result != returnvalue::OK) {
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return result;
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}
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}
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if (recoveryState != RecoveryState::RECOVERY_STARTED) {
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if (mode == DeviceHandlerIF::MODE_NORMAL or mode == MODE_ON) {
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result = handleNormalOrOnModeCmd(mode, submode);
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}
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}
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HybridIterator<ModeListEntry> tableIter(modeTable.begin(), modeTable.end());
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executeTable(tableIter);
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return result;
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}
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ReturnValue_t AcsBoardAssembly::checkChildrenStateOn(Mode_t wantedMode, Submode_t wantedSubmode) {
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using namespace duallane;
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refreshHelperModes();
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if (wantedSubmode == A_SIDE) {
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if ((helper.gyro0SideAMode != wantedMode and helper.gyro1SideAMode != wantedMode) or
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(helper.mgm0SideAMode != wantedMode and helper.mgm1SideAMode != wantedMode) or
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(helper.gpsMode != MODE_ON) or gps0HealthDevFaulty()) {
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return NOT_ENOUGH_CHILDREN_IN_CORRECT_STATE;
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}
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return returnvalue::OK;
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} else if (wantedSubmode == B_SIDE) {
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if ((helper.gyro2SideBMode != wantedMode and helper.gyro3SideBMode != wantedMode) or
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(helper.mgm2SideBMode != wantedMode and helper.mgm3SideBMode != wantedMode) or
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(helper.gpsMode != MODE_ON) or gps1HealthDevFaulty()) {
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return NOT_ENOUGH_CHILDREN_IN_CORRECT_STATE;
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}
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return returnvalue::OK;
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} else if (wantedSubmode == DUAL_MODE) {
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if ((helper.gyro0SideAMode != wantedMode and helper.gyro1SideAMode != wantedMode and
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helper.gyro2AdisIdSideB != wantedMode and helper.gyro3SideBMode != wantedMode) or
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(helper.mgm0SideAMode != wantedMode and helper.mgm1SideAMode != wantedMode and
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helper.mgm2SideBMode != wantedMode and helper.mgm3SideBMode != wantedMode) or
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helper.gpsMode != MODE_ON) {
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// Trigger event, but don't start any other transitions. This is the last fallback mode.
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if (dualModeErrorSwitch) {
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triggerEvent(NOT_ENOUGH_DEVICES_DUAL_MODE, 0, 0);
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dualModeErrorSwitch = false;
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}
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return returnvalue::OK;
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}
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return returnvalue::OK;
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}
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return returnvalue::OK;
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}
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ReturnValue_t AcsBoardAssembly::handleNormalOrOnModeCmd(Mode_t mode, Submode_t submode) {
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using namespace duallane;
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ReturnValue_t result = returnvalue::OK;
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bool needsSecondStep = false;
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handleSideSwitchStates(submode, needsSecondStep);
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auto cmdSeq = [&](object_id_t objectId, Mode_t devMode, ModeTableIdx tableIdx) {
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if (mode == devMode) {
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modeTable[tableIdx].setMode(mode);
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} else if (isModeCommandable(objectId, devMode)) {
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modeTable[tableIdx].setMode(mode);
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modeTable[tableIdx].setSubmode(SUBMODE_NONE);
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}
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};
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bool gpsUsable = isGpsUsable(submode);
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auto gpsCmd = [&](bool gnss0NReset, bool gnss1NReset, uint8_t gnssSelect) {
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if (gpsUsable) {
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if (mode == MODE_ON or mode == DeviceHandlerIF::MODE_NORMAL) {
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modeTable[ModeTableIdx::GPS].setMode(MODE_ON);
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} else if (mode == MODE_OFF) {
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gnss0NReset = true;
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gnss1NReset = true;
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modeTable[ModeTableIdx::GPS].setMode(MODE_OFF);
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}
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modeTable[ModeTableIdx::GPS].setSubmode(SUBMODE_NONE);
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gpioHandler(gpioIds::GNSS_0_NRESET, gnss0NReset,
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"AcsBoardAssembly::handleNormalOrOnModeCmd: Could not pull nReset pin"
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"of GNSS 0");
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gpioHandler(gpioIds::GNSS_1_NRESET, gnss1NReset,
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"AcsBoardAssembly::handleNormalOrOnModeCmd: Could not pull nReset pin"
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"of GNSS 1");
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gpioHandler(gpioIds::GNSS_SELECT, gnssSelect,
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"AcsBoardAssembly::handleNormalOrOnModeCmd: Could not pull GNSS select");
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}
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};
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switch (submode) {
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case (A_SIDE): {
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modeTable[ModeTableIdx::GYRO_2_B].setMode(MODE_OFF);
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modeTable[ModeTableIdx::GYRO_2_B].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::GYRO_3_B].setMode(MODE_OFF);
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modeTable[ModeTableIdx::GYRO_3_B].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::MGM_2_B].setMode(MODE_OFF);
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modeTable[ModeTableIdx::MGM_2_B].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::MGM_3_B].setMode(MODE_OFF);
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modeTable[ModeTableIdx::MGM_3_B].setSubmode(SUBMODE_NONE);
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cmdSeq(helper.gyro0AdisIdSideA, helper.gyro0SideAMode, ModeTableIdx::GYRO_0_A);
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cmdSeq(helper.gyro1L3gIdSideA, helper.gyro1SideAMode, ModeTableIdx::GYRO_1_A);
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cmdSeq(helper.mgm0Lis3IdSideA, helper.mgm0SideAMode, ModeTableIdx::MGM_0_A);
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cmdSeq(helper.mgm1Rm3100IdSideA, helper.mgm1SideAMode, ModeTableIdx::MGM_1_A);
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gpsCmd(true, false, 0);
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break;
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}
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case (B_SIDE): {
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modeTable[ModeTableIdx::GYRO_0_A].setMode(MODE_OFF);
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modeTable[ModeTableIdx::GYRO_0_A].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::GYRO_1_A].setMode(MODE_OFF);
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modeTable[ModeTableIdx::GYRO_1_A].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::MGM_0_A].setMode(MODE_OFF);
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modeTable[ModeTableIdx::MGM_0_A].setSubmode(SUBMODE_NONE);
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modeTable[ModeTableIdx::MGM_1_A].setMode(MODE_OFF);
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modeTable[ModeTableIdx::MGM_1_A].setSubmode(SUBMODE_NONE);
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cmdSeq(helper.gyro2AdisIdSideB, helper.gyro2SideBMode, ModeTableIdx::GYRO_2_B);
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cmdSeq(helper.gyro3L3gIdSideB, helper.gyro3SideBMode, ModeTableIdx::GYRO_3_B);
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cmdSeq(helper.mgm2Lis3IdSideB, helper.mgm2SideBMode, ModeTableIdx::MGM_2_B);
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cmdSeq(helper.mgm3Rm3100IdSideB, helper.mgm3SideBMode, ModeTableIdx::MGM_3_B);
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gpsCmd(false, true, 1);
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break;
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}
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case (DUAL_MODE): {
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cmdSeq(helper.gyro0AdisIdSideA, helper.gyro0SideAMode, ModeTableIdx::GYRO_0_A);
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cmdSeq(helper.gyro1L3gIdSideA, helper.gyro1SideAMode, ModeTableIdx::GYRO_1_A);
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cmdSeq(helper.mgm0Lis3IdSideA, helper.mgm0SideAMode, ModeTableIdx::MGM_0_A);
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cmdSeq(helper.mgm1Rm3100IdSideA, helper.mgm1SideAMode, ModeTableIdx::MGM_1_A);
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cmdSeq(helper.gyro2AdisIdSideB, helper.gyro2SideBMode, ModeTableIdx::GYRO_2_B);
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cmdSeq(helper.gyro3L3gIdSideB, helper.gyro3SideBMode, ModeTableIdx::GYRO_3_B);
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cmdSeq(helper.mgm2Lis3IdSideB, helper.mgm2SideBMode, ModeTableIdx::MGM_2_B);
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cmdSeq(helper.mgm3Rm3100IdSideB, helper.mgm3SideBMode, ModeTableIdx::MGM_3_B);
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if (defaultSubmode == Submodes::A_SIDE) {
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gpsCmd(true, true, 0);
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} else {
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gpsCmd(true, true, 1);
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}
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break;
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}
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default: {
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sif::error << "AcsBoardAssembly::handleNormalModeCmd: Unknown submode" << std::endl;
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}
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}
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if (needsSecondStep) {
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result = NEED_SECOND_STEP;
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}
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return result;
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}
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void AcsBoardAssembly::selectGpsInDualMode(duallane::Submodes side) {
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using namespace duallane;
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if (submode != Submodes::DUAL_MODE) {
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return;
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}
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ReturnValue_t result = returnvalue::OK;
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if (side == Submodes::A_SIDE) {
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result = gpioIF->pullLow(gpioIds::GNSS_SELECT);
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} else {
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result = gpioIF->pullHigh(gpioIds::GNSS_SELECT);
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}
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if (result != returnvalue::OK) {
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#if OBSW_VERBOSE_LEVEL >= 1
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sif::error << "AcsBoardAssembly::switchGpsInDualMode: Switching GPS failed" << std::endl;
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#endif
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}
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}
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void AcsBoardAssembly::gpioHandler(gpioId_t gpio, bool high, std::string error) {
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ReturnValue_t result = returnvalue::OK;
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if (high) {
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result = gpioIF->pullHigh(gpio);
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} else {
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result = gpioIF->pullLow(gpio);
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}
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if (result != returnvalue::OK) {
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#if OBSW_VERBOSE_LEVEL >= 1
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sif::error << error << std::endl;
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#endif
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}
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}
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void AcsBoardAssembly::refreshHelperModes() {
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try {
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helper.gyro0SideAMode = childrenMap.at(helper.gyro0AdisIdSideA).mode;
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helper.gyro1SideAMode = childrenMap.at(helper.gyro1L3gIdSideA).mode;
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helper.gyro2SideBMode = childrenMap.at(helper.gyro2AdisIdSideB).mode;
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helper.gyro3SideBMode = childrenMap.at(helper.gyro3L3gIdSideB).mode;
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helper.mgm0SideAMode = childrenMap.at(helper.mgm0Lis3IdSideA).mode;
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helper.mgm1SideAMode = childrenMap.at(helper.mgm1Rm3100IdSideA).mode;
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helper.mgm2SideBMode = childrenMap.at(helper.mgm2Lis3IdSideB).mode;
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helper.mgm3SideBMode = childrenMap.at(helper.mgm3Rm3100IdSideB).mode;
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helper.gpsMode = childrenMap.at(helper.gpsId).mode;
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} catch (const std::out_of_range& e) {
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sif::error << "AcsBoardAssembly::refreshHelperModes: Invalid map: " << e.what() << std::endl;
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}
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}
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ReturnValue_t AcsBoardAssembly::initialize() {
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for (const auto& child : childrenMap) {
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updateChildModeByObjId(child.first, MODE_OFF, 0);
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}
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return AssemblyBase::initialize();
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}
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ReturnValue_t AcsBoardAssembly::checkAndHandleHealthStates(Mode_t commandedMode,
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Submode_t commandedSubmode) {
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using namespace returnvalue;
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ReturnValue_t status = returnvalue::OK;
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bool healthNeedsToBeOverwritten = false;
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auto checkAcsBoardSensorGroup = [&](object_id_t o0, object_id_t o1, object_id_t o2,
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object_id_t o3) {
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HealthState h0 = healthHelper.healthTable->getHealth(o0);
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HealthState h1 = healthHelper.healthTable->getHealth(o1);
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HealthState h2 = healthHelper.healthTable->getHealth(o2);
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HealthState h3 = healthHelper.healthTable->getHealth(o3);
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// All device are faulty or permanent faulty, but this is a safe mode assembly, so we need
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// to restore the devices.
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if ((h0 == FAULTY or h0 == PERMANENT_FAULTY) and (h1 == FAULTY or h1 == PERMANENT_FAULTY) and
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(h2 == FAULTY or h2 == PERMANENT_FAULTY) and (h3 == FAULTY or h3 == PERMANENT_FAULTY)) {
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uint8_t numPermFaulty = 0;
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if (h0 == PERMANENT_FAULTY) {
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numPermFaulty++;
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}
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if (h1 == PERMANENT_FAULTY) {
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numPermFaulty++;
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}
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if (h2 == PERMANENT_FAULTY) {
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numPermFaulty++;
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}
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if (h3 == PERMANENT_FAULTY) {
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numPermFaulty++;
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}
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if (numPermFaulty < 4) {
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// Some are faulty and some are permanent faulty, so only set faulty ones to
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// EXTERNAL_CONTROL.
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if (h0 == FAULTY) {
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overwriteDeviceHealth(o0, h0);
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}
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if (h1 == FAULTY) {
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overwriteDeviceHealth(o1, h1);
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}
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if (h2 == FAULTY) {
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overwriteDeviceHealth(o2, h2);
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}
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if (h3 == FAULTY) {
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overwriteDeviceHealth(o3, h3);
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}
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} else {
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// All permanent faulty, so set all to EXTERNAL_CONTROL
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overwriteDeviceHealth(o0, h0);
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overwriteDeviceHealth(o1, h1);
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overwriteDeviceHealth(o2, h2);
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overwriteDeviceHealth(o3, h3);
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}
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healthNeedsToBeOverwritten = true;
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}
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if (h0 == EXTERNAL_CONTROL or h1 == EXTERNAL_CONTROL or h2 == EXTERNAL_CONTROL or
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h3 == EXTERNAL_CONTROL) {
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modeHelper.setForced(true);
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}
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};
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if (healthHelper.healthTable->getHealth(helper.healthDevGps0) == EXTERNAL_CONTROL or
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healthHelper.healthTable->getHealth(helper.healthDevGps1) == EXTERNAL_CONTROL) {
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modeHelper.setForced(true);
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}
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if (healthHelper.healthTable->getHealth(helper.healthDevGps0) == PERMANENT_FAULTY and
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healthHelper.healthTable->getHealth(helper.healthDevGps1) == FAULTY) {
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overwriteDeviceHealth(helper.healthDevGps1, FAULTY);
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healthNeedsToBeOverwritten = true;
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} else if (healthHelper.healthTable->getHealth(helper.healthDevGps1) == PERMANENT_FAULTY and
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healthHelper.healthTable->getHealth(helper.healthDevGps0) == FAULTY) {
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overwriteDeviceHealth(helper.healthDevGps0, FAULTY);
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} else if (healthHelper.healthTable->isFaulty(helper.healthDevGps0) and
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healthHelper.healthTable->isFaulty(helper.healthDevGps1)) {
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overwriteDeviceHealth(helper.healthDevGps0,
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healthHelper.healthTable->getHealth(helper.healthDevGps0));
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overwriteDeviceHealth(helper.healthDevGps1,
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healthHelper.healthTable->getHealth(helper.healthDevGps1));
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healthNeedsToBeOverwritten = true;
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}
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if (commandedSubmode == duallane::DUAL_MODE) {
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checkAcsBoardSensorGroup(helper.mgm0Lis3IdSideA, helper.mgm1Rm3100IdSideA,
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helper.mgm2Lis3IdSideB, helper.mgm3Rm3100IdSideB);
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checkAcsBoardSensorGroup(helper.gyro0AdisIdSideA, helper.gyro1L3gIdSideA,
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helper.gyro2AdisIdSideB, helper.gyro3L3gIdSideB);
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}
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if (healthNeedsToBeOverwritten) {
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// If we are overwriting the health states, we are already in a transition to dual mode,
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// and we would like that transition to complete. The default behaviour is to go back to the
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// old mode. We force our behaviour by overwriting the internal modes.
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mode = commandedMode;
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submode = commandedSubmode;
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return NEED_TO_CHANGE_HEALTH;
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}
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return status;
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}
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void AcsBoardAssembly::handleChildrenLostMode(ReturnValue_t result) {
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using namespace duallane;
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// Special handling to account for GPS devices being faulty. If the GPS device on the other
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// side is marked faulty, directly to to dual side.
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if (submode == Submodes::A_SIDE) {
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if (gps0HealthDevFaulty()) {
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triggerEvent(DIRECT_TRANSITION_TO_DUAL_OTHER_GPS_FAULTY, submode, 0);
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startTransition(mode, Submodes::DUAL_MODE);
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return;
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}
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} else if (submode == Submodes::B_SIDE) {
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if (gps1HealthDevFaulty()) {
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triggerEvent(DIRECT_TRANSITION_TO_DUAL_OTHER_GPS_FAULTY, submode, 0);
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startTransition(mode, Submodes::DUAL_MODE);
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return;
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}
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}
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DualLaneAssemblyBase::handleChildrenLostMode(result);
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}
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bool AcsBoardAssembly::gps0HealthDevFaulty() const {
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auto health = healthHelper.healthTable->getHealth(helper.healthDevGps0);
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if (health == FAULTY or health == PERMANENT_FAULTY) {
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return true;
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}
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return false;
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}
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bool AcsBoardAssembly::gps1HealthDevFaulty() const {
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auto health = healthHelper.healthTable->getHealth(helper.healthDevGps1);
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if (health == FAULTY or health == PERMANENT_FAULTY) {
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return true;
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}
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|
return false;
|
|
}
|
|
|
|
bool AcsBoardAssembly::isGpsUsable(uint8_t targetSubmode) const {
|
|
if (targetSubmode == duallane::A_SIDE and
|
|
healthHelper.healthTable->isFaulty(helper.healthDevGps0)) {
|
|
// Causes a OFF command to be sent, which triggers a side switch or a switch to dual side.
|
|
return false;
|
|
}
|
|
if (targetSubmode == duallane::B_SIDE and
|
|
healthHelper.healthTable->isFaulty(helper.healthDevGps1)) {
|
|
// Causes a OFF command to be sent, which triggers a side switch or a switch to dual side.
|
|
return false;
|
|
}
|
|
auto gpsIter = childrenMap.find(helper.gpsId);
|
|
// Check if device is already in target mode
|
|
if (gpsIter != childrenMap.end() and gpsIter->second.mode == mode) {
|
|
return true;
|
|
}
|
|
return true;
|
|
}
|