WIP: Rework config of GYRs #613

Closed
meggert wants to merge 40 commits from gyr-config-rework into v2.1.0-dev
21 changed files with 416 additions and 132 deletions

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@ -16,12 +16,44 @@ will consitute of a breaking change warranting a new major release:
# [unreleased] # [unreleased]
# [v2.2.0] to be released
# [v2.1.0] to be released
## Changed
- Adapt EM configuration to include all GomSpace PCDU devices except the ACU. For the ACU
(which broke), a dummy will still be used.
- Event Manager queue depth is configurable now.
- Do not construct and schedule broken TMP1075 device anymore.
- Do not track payload modes in system mode tables.
- ACS modes derived from system modes.
## Added
- Add the remaining system modes.
## Fixed
- Host build is working again. Added reduced live TM helper which schedules the PUS and CFDP
funnel.
- The variance for the ADIS GYRs now represents the used `-3` version and not the `-1` version
# [v2.0.5] to be released
- The dual lane assembly transition failed handler started new transitions towards the current mode
instead of the target mode. This means that if the dual lane assembly never reached the initial
submode (e.g. mode normal and submode dual side), it will transition back to the current mode,
which miht be `MODE_OFF`. Furthermore, this can lead to invalid internal states, so the subsequent
recovery handling becomes stuck in the custom recovery sequence when swichting power back on.
- The dual lane custom recovery handling was adapted to always perform proper power switch handling
irrespective of current or target modes.
# [v2.0.4] 2023-04-19 # [v2.0.4] 2023-04-19
## Fixed ## Fixed
- The dual lane assembly device handlers did not properly set their datasets - The dual lane assembly datasets were not marked invalid properly on OFF transitions.
to invalid on off transitions
# [v2.0.3] 2023-04-17 # [v2.0.3] 2023-04-17

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@ -146,8 +146,11 @@ set(OBSW_ADD_TMP_DEVICES
${INIT_VAL} ${INIT_VAL}
CACHE STRING "Add TMP devices") CACHE STRING "Add TMP devices")
set(OBSW_ADD_GOMSPACE_PCDU set(OBSW_ADD_GOMSPACE_PCDU
${INIT_VAL} 1
CACHE STRING "Add GomSpace PCDU modules") CACHE STRING "Add GomSpace PCDU modules")
set(OBSW_ADD_GOMSPACE_ACU
${INIT_VAL}
CACHE STRING "Add GomSpace ACU submodule")
set(OBSW_ADD_RW set(OBSW_ADD_RW
${INIT_VAL} ${INIT_VAL}
CACHE STRING "Add RW modules") CACHE STRING "Add RW modules")

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@ -64,8 +64,9 @@ void ObjectFactory::produce(void* args) {
PersistentTmStores persistentStores; PersistentTmStores persistentStores;
auto sdcMan = new DummySdCardManager("/tmp"); auto sdcMan = new DummySdCardManager("/tmp");
ObjectFactory::produceGenericObjects(nullptr, &pusFunnel, &cfdpFunnel, *sdcMan, &ipcStore, ObjectFactory::produceGenericObjects(nullptr, &pusFunnel, &cfdpFunnel, *sdcMan, &ipcStore,
&tmStore, persistentStores); &tmStore, persistentStores, 120);
new TmFunnelHandler(objects::LIVE_TM_TASK, *pusFunnel, *cfdpFunnel);
auto* dummyGpioIF = new DummyGpioIF(); auto* dummyGpioIF = new DummyGpioIF();
auto* dummySwitcher = new DummyPowerSwitcher(objects::PCDU_HANDLER, 18, 0); auto* dummySwitcher = new DummyPowerSwitcher(objects::PCDU_HANDLER, 18, 0);
std::vector<ReturnValue_t> switcherList; std::vector<ReturnValue_t> switcherList;

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@ -59,19 +59,15 @@ void scheduling::initTasks() {
"DIST", 60, PeriodicTaskIF::MINIMUM_STACK_SIZE, 0.2, missedDeadlineFunc); "DIST", 60, PeriodicTaskIF::MINIMUM_STACK_SIZE, 0.2, missedDeadlineFunc);
ReturnValue_t result = tmtcDistributor->addComponent(objects::CCSDS_PACKET_DISTRIBUTOR); ReturnValue_t result = tmtcDistributor->addComponent(objects::CCSDS_PACKET_DISTRIBUTOR);
if (result != returnvalue::OK) { if (result != returnvalue::OK) {
sif::error << "adding CCSDS distributor failed" << std::endl; sif::error << "Adding CCSDS distributor failed" << std::endl;
} }
result = tmtcDistributor->addComponent(objects::PUS_PACKET_DISTRIBUTOR); result = tmtcDistributor->addComponent(objects::PUS_PACKET_DISTRIBUTOR);
if (result != returnvalue::OK) { if (result != returnvalue::OK) {
sif::error << "adding PUS distributor failed" << std::endl; sif::error << "Adding PUS distributor failed" << std::endl;
}
result = tmtcDistributor->addComponent(objects::TM_FUNNEL);
if (result != returnvalue::OK) {
sif::error << "adding TM funnel failed" << std::endl;
} }
result = tmtcDistributor->addComponent(objects::CFDP_DISTRIBUTOR); result = tmtcDistributor->addComponent(objects::CFDP_DISTRIBUTOR);
if (result != returnvalue::OK) { if (result != returnvalue::OK) {
sif::error << "adding CFDP distributor failed" << std::endl; sif::error << "Adding CFDP distributor failed" << std::endl;
} }
result = tmtcDistributor->addComponent(objects::UDP_TMTC_SERVER); result = tmtcDistributor->addComponent(objects::UDP_TMTC_SERVER);
if (result != returnvalue::OK) { if (result != returnvalue::OK) {
@ -95,6 +91,13 @@ void scheduling::initTasks() {
sif::error << "Add component UDP Polling failed" << std::endl; sif::error << "Add component UDP Polling failed" << std::endl;
} }
PeriodicTaskIF* liveTmTask = factory->createPeriodicTask(
"LIVE_TM", 55, PeriodicTaskIF::MINIMUM_STACK_SIZE, 0.4, nullptr, &RR_SCHEDULING);
result = liveTmTask->addComponent(objects::LIVE_TM_TASK);
if (result != returnvalue::OK) {
scheduling::printAddObjectError("LIVE_TM", objects::LIVE_TM_TASK);
}
PeriodicTaskIF* pusHighPrio = factory->createPeriodicTask( PeriodicTaskIF* pusHighPrio = factory->createPeriodicTask(
"PUS_HIGH_PRIO", 60, PeriodicTaskIF::MINIMUM_STACK_SIZE, 0.200, missedDeadlineFunc); "PUS_HIGH_PRIO", 60, PeriodicTaskIF::MINIMUM_STACK_SIZE, 0.200, missedDeadlineFunc);
result = pusHighPrio->addComponent(objects::PUS_SERVICE_1_VERIFICATION); result = pusHighPrio->addComponent(objects::PUS_SERVICE_1_VERIFICATION);
@ -149,7 +152,7 @@ void scheduling::initTasks() {
"THERMAL_CTL_TASK", 40, PeriodicTaskIF::MINIMUM_STACK_SIZE, 1.0, missedDeadlineFunc); "THERMAL_CTL_TASK", 40, PeriodicTaskIF::MINIMUM_STACK_SIZE, 1.0, missedDeadlineFunc);
result = thermalTask->addComponent(objects::CORE_CONTROLLER); result = thermalTask->addComponent(objects::CORE_CONTROLLER);
if (result != returnvalue::OK) { if (result != returnvalue::OK) {
scheduling::printAddObjectError("Core controller dummy", objects::CORE_CONTROLLER); scheduling::printAddObjectError("CORE_CTRL", objects::CORE_CONTROLLER);
} }
result = thermalTask->addComponent(objects::THERMAL_CONTROLLER); result = thermalTask->addComponent(objects::THERMAL_CONTROLLER);
if (result != returnvalue::OK) { if (result != returnvalue::OK) {
@ -217,6 +220,7 @@ void scheduling::initTasks() {
tmtcDistributor->startTask(); tmtcDistributor->startTask();
udpPollingTask->startTask(); udpPollingTask->startTask();
tcpPollingTask->startTask(); tcpPollingTask->startTask();
liveTmTask->startTask();
pusHighPrio->startTask(); pusHighPrio->startTask();
pusMedPrio->startTask(); pusMedPrio->startTask();

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@ -22,6 +22,9 @@
#define OBSW_COMMAND_SAFE_MODE_AT_STARTUP 1 #define OBSW_COMMAND_SAFE_MODE_AT_STARTUP 1
#define OBSW_ADD_GOMSPACE_PCDU @OBSW_ADD_GOMSPACE_PCDU@ #define OBSW_ADD_GOMSPACE_PCDU @OBSW_ADD_GOMSPACE_PCDU@
// This define is necessary because the EM setup has the P60 dock module, but no ACU on the P60
// module because it broke.
#define OBSW_ADD_GOMSPACE_ACU @OBSW_ADD_GOMSPACE_ACU@
#define OBSW_ADD_MGT @OBSW_ADD_MGT@ #define OBSW_ADD_MGT @OBSW_ADD_MGT@
#define OBSW_ADD_BPX_BATTERY_HANDLER @OBSW_ADD_BPX_BATTERY_HANDLER@ #define OBSW_ADD_BPX_BATTERY_HANDLER @OBSW_ADD_BPX_BATTERY_HANDLER@
#define OBSW_ADD_STAR_TRACKER @OBSW_ADD_STAR_TRACKER@ #define OBSW_ADD_STAR_TRACKER @OBSW_ADD_STAR_TRACKER@

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@ -189,7 +189,6 @@ void ObjectFactory::createCommunicationInterfaces(LinuxLibgpioIF** gpioComIF,
*i2cComIF = new I2cComIF(objects::I2C_COM_IF); *i2cComIF = new I2cComIF(objects::I2C_COM_IF);
*uartComIF = new SerialComIF(objects::UART_COM_IF); *uartComIF = new SerialComIF(objects::UART_COM_IF);
*spiMainComIF = new SpiComIF(objects::SPI_MAIN_COM_IF, q7s::SPI_DEFAULT_DEV, **gpioComIF); *spiMainComIF = new SpiComIF(objects::SPI_MAIN_COM_IF, q7s::SPI_DEFAULT_DEV, **gpioComIF);
//*spiRWComIF = new SpiComIF(objects::SPI_RW_COM_IF, q7s::SPI_RW_DEV, **gpioComIF);
} }
void ObjectFactory::createPcduComponents(LinuxLibgpioIF* gpioComIF, PowerSwitchIF** pwrSwitcher, void ObjectFactory::createPcduComponents(LinuxLibgpioIF* gpioComIF, PowerSwitchIF** pwrSwitcher,
@ -197,7 +196,6 @@ void ObjectFactory::createPcduComponents(LinuxLibgpioIF* gpioComIF, PowerSwitchI
CspCookie* p60DockCspCookie = new CspCookie(P60Dock::MAX_REPLY_SIZE, addresses::P60DOCK, 500); CspCookie* p60DockCspCookie = new CspCookie(P60Dock::MAX_REPLY_SIZE, addresses::P60DOCK, 500);
CspCookie* pdu1CspCookie = new CspCookie(PDU::MAX_REPLY_SIZE, addresses::PDU1, 500); CspCookie* pdu1CspCookie = new CspCookie(PDU::MAX_REPLY_SIZE, addresses::PDU1, 500);
CspCookie* pdu2CspCookie = new CspCookie(PDU::MAX_REPLY_SIZE, addresses::PDU2, 500); CspCookie* pdu2CspCookie = new CspCookie(PDU::MAX_REPLY_SIZE, addresses::PDU2, 500);
CspCookie* acuCspCookie = new CspCookie(ACU::MAX_REPLY_SIZE, addresses::ACU, 500);
auto p60Fdir = new GomspacePowerFdir(objects::P60DOCK_HANDLER); auto p60Fdir = new GomspacePowerFdir(objects::P60DOCK_HANDLER);
P60DockHandler* p60dockhandler = new P60DockHandler(objects::P60DOCK_HANDLER, objects::CSP_COM_IF, P60DockHandler* p60dockhandler = new P60DockHandler(objects::P60DOCK_HANDLER, objects::CSP_COM_IF,
@ -211,9 +209,12 @@ void ObjectFactory::createPcduComponents(LinuxLibgpioIF* gpioComIF, PowerSwitchI
Pdu2Handler* pdu2handler = new Pdu2Handler(objects::PDU2_HANDLER, objects::CSP_COM_IF, Pdu2Handler* pdu2handler = new Pdu2Handler(objects::PDU2_HANDLER, objects::CSP_COM_IF,
pdu2CspCookie, pdu2Fdir, enableHkSets); pdu2CspCookie, pdu2Fdir, enableHkSets);
#if OBSW_ADD_GOMSPACE_ACU == 1
CspCookie* acuCspCookie = new CspCookie(ACU::MAX_REPLY_SIZE, addresses::ACU, 500);
auto acuFdir = new GomspacePowerFdir(objects::ACU_HANDLER); auto acuFdir = new GomspacePowerFdir(objects::ACU_HANDLER);
ACUHandler* acuhandler = new ACUHandler(objects::ACU_HANDLER, objects::CSP_COM_IF, acuCspCookie, ACUHandler* acuhandler = new ACUHandler(objects::ACU_HANDLER, objects::CSP_COM_IF, acuCspCookie,
acuFdir, enableHkSets); acuFdir, enableHkSets);
#endif
auto pcduHandler = new PcduHandler(objects::PCDU_HANDLER, 50); auto pcduHandler = new PcduHandler(objects::PCDU_HANDLER, 50);
/** /**
@ -223,7 +224,9 @@ void ObjectFactory::createPcduComponents(LinuxLibgpioIF* gpioComIF, PowerSwitchI
p60dockhandler->setModeNormal(); p60dockhandler->setModeNormal();
pdu1handler->setModeNormal(); pdu1handler->setModeNormal();
pdu2handler->setModeNormal(); pdu2handler->setModeNormal();
#if OBSW_ADD_GOMSPACE_ACU == 1
acuhandler->setModeNormal(); acuhandler->setModeNormal();
#endif
if (pwrSwitcher != nullptr) { if (pwrSwitcher != nullptr) {
*pwrSwitcher = pcduHandler; *pwrSwitcher = pcduHandler;
} }

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@ -36,7 +36,8 @@ void ObjectFactory::produce(void* args) {
PersistentTmStores stores; PersistentTmStores stores;
ObjectFactory::produceGenericObjects(&healthTable, &pusFunnel, &cfdpFunnel, ObjectFactory::produceGenericObjects(&healthTable, &pusFunnel, &cfdpFunnel,
*SdCardManager::instance(), &ipcStore, &tmStore, stores); *SdCardManager::instance(), &ipcStore, &tmStore, stores,
200);
LinuxLibgpioIF* gpioComIF = nullptr; LinuxLibgpioIF* gpioComIF = nullptr;
SerialComIF* uartComIF = nullptr; SerialComIF* uartComIF = nullptr;
@ -56,6 +57,11 @@ void ObjectFactory::produce(void* args) {
#endif #endif
#if OBSW_ADD_GOMSPACE_PCDU == 1 #if OBSW_ADD_GOMSPACE_PCDU == 1
dummyCfg.addPowerDummies = false; dummyCfg.addPowerDummies = false;
// The ACU broke.
dummyCfg.addOnlyAcuDummy = true;
#endif
#if OBSW_ADD_BPX_BATTERY_HANDLER == 1
dummyCfg.addBpxBattDummy = false;
#endif #endif
#if OBSW_ADD_ACS_BOARD == 1 #if OBSW_ADD_ACS_BOARD == 1
dummyCfg.addAcsBoardDummies = false; dummyCfg.addAcsBoardDummies = false;
@ -89,7 +95,7 @@ void ObjectFactory::produce(void* args) {
// createRadSensorComponent(gpioComIF); // createRadSensorComponent(gpioComIF);
#if OBSW_ADD_ACS_BOARD == 1 #if OBSW_ADD_ACS_BOARD == 1
createAcsBoardComponents(*spiMainComIF, gpioComIF, uartComIF, *pwrSwitcher); createAcsBoardComponents(*spiMainComIF, gpioComIF, uartComIF, *pwrSwitcher, true);
#else #else
// Still add all GPIOs for EM. // Still add all GPIOs for EM.
GpioCookie* acsBoardGpios = new GpioCookie(); GpioCookie* acsBoardGpios = new GpioCookie();

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@ -32,7 +32,8 @@ void ObjectFactory::produce(void* args) {
PersistentTmStores stores; PersistentTmStores stores;
ObjectFactory::produceGenericObjects(&healthTable, &pusFunnel, &cfdpFunnel, ObjectFactory::produceGenericObjects(&healthTable, &pusFunnel, &cfdpFunnel,
*SdCardManager::instance(), &ipcStore, &tmStore, stores); *SdCardManager::instance(), &ipcStore, &tmStore, stores,
200);
LinuxLibgpioIF* gpioComIF = nullptr; LinuxLibgpioIF* gpioComIF = nullptr;
SerialComIF* uartComIF = nullptr; SerialComIF* uartComIF = nullptr;

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@ -45,7 +45,9 @@
void dummy::createDummies(DummyCfg cfg, PowerSwitchIF& pwrSwitcher, GpioIF* gpioIF) { void dummy::createDummies(DummyCfg cfg, PowerSwitchIF& pwrSwitcher, GpioIF* gpioIF) {
new ComIFDummy(objects::DUMMY_COM_IF); new ComIFDummy(objects::DUMMY_COM_IF);
auto* comCookieDummy = new ComCookieDummy(); auto* comCookieDummy = new ComCookieDummy();
new BpxDummy(objects::BPX_BATT_HANDLER, objects::DUMMY_COM_IF, comCookieDummy); if (cfg.addBpxBattDummy) {
new BpxDummy(objects::BPX_BATT_HANDLER, objects::DUMMY_COM_IF, comCookieDummy);
}
if (cfg.addCoreCtrlCfg) { if (cfg.addCoreCtrlCfg) {
new CoreControllerDummy(objects::CORE_CONTROLLER); new CoreControllerDummy(objects::CORE_CONTROLLER);
} }
@ -75,8 +77,9 @@ void dummy::createDummies(DummyCfg cfg, PowerSwitchIF& pwrSwitcher, GpioIF* gpio
auto* imtqDummy = new ImtqDummy(objects::IMTQ_HANDLER, objects::DUMMY_COM_IF, comCookieDummy); auto* imtqDummy = new ImtqDummy(objects::IMTQ_HANDLER, objects::DUMMY_COM_IF, comCookieDummy);
imtqDummy->enableThermalModule(ThermalStateCfg()); imtqDummy->enableThermalModule(ThermalStateCfg());
imtqDummy->connectModeTreeParent(*imtqAssy); imtqDummy->connectModeTreeParent(*imtqAssy);
if (cfg.addPowerDummies) { if (cfg.addOnlyAcuDummy) {
new AcuDummy(objects::ACU_HANDLER, objects::DUMMY_COM_IF, comCookieDummy); new AcuDummy(objects::ACU_HANDLER, objects::DUMMY_COM_IF, comCookieDummy);
} else if (cfg.addPowerDummies) {
new PduDummy(objects::PDU1_HANDLER, objects::DUMMY_COM_IF, comCookieDummy); new PduDummy(objects::PDU1_HANDLER, objects::DUMMY_COM_IF, comCookieDummy);
new PduDummy(objects::PDU2_HANDLER, objects::DUMMY_COM_IF, comCookieDummy); new PduDummy(objects::PDU2_HANDLER, objects::DUMMY_COM_IF, comCookieDummy);
new P60DockDummy(objects::P60DOCK_HANDLER, objects::DUMMY_COM_IF, comCookieDummy); new P60DockDummy(objects::P60DOCK_HANDLER, objects::DUMMY_COM_IF, comCookieDummy);
@ -195,10 +198,10 @@ void dummy::createDummies(DummyCfg cfg, PowerSwitchIF& pwrSwitcher, GpioIF* gpio
objects::TMP1075_HANDLER_PLPCDU_0, objects::TMP1075_HANDLER_PLPCDU_0,
new Tmp1075Dummy(objects::TMP1075_HANDLER_PLPCDU_0, objects::DUMMY_COM_IF, comCookieDummy)); new Tmp1075Dummy(objects::TMP1075_HANDLER_PLPCDU_0, objects::DUMMY_COM_IF, comCookieDummy));
// damaged. // damaged.
// tmpSensorDummies.emplace( // tmpSensorDummies.emplace(
// objects::TMP1075_HANDLER_PLPCDU_1, // objects::TMP1075_HANDLER_PLPCDU_1,
// new Tmp1075Dummy(objects::TMP1075_HANDLER_PLPCDU_1, objects::DUMMY_COM_IF, // new Tmp1075Dummy(objects::TMP1075_HANDLER_PLPCDU_1, objects::DUMMY_COM_IF,
// comCookieDummy)); // comCookieDummy));
tmpSensorDummies.emplace( tmpSensorDummies.emplace(
objects::TMP1075_HANDLER_IF_BOARD, objects::TMP1075_HANDLER_IF_BOARD,
new Tmp1075Dummy(objects::TMP1075_HANDLER_IF_BOARD, objects::DUMMY_COM_IF, comCookieDummy)); new Tmp1075Dummy(objects::TMP1075_HANDLER_IF_BOARD, objects::DUMMY_COM_IF, comCookieDummy));

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@ -6,9 +6,13 @@ class GpioIF;
namespace dummy { namespace dummy {
// Default values targeted towards EM.
struct DummyCfg { struct DummyCfg {
bool addCoreCtrlCfg = true; bool addCoreCtrlCfg = true;
// Special variant because the ACU broke. Overrides addPowerDummies, only ACU dummy will be added.
bool addOnlyAcuDummy = false;
bool addPowerDummies = true; bool addPowerDummies = true;
bool addBpxBattDummy = true;
bool addSyrlinksDummies = true; bool addSyrlinksDummies = true;
bool addAcsBoardDummies = true; bool addAcsBoardDummies = true;
bool addSusDummies = true; bool addSusDummies = true;

2
fsfw

@ -1 +1 @@
Subproject commit 5eb9ee8bc1e6f8640cbea46febd11e4b92241881 Subproject commit 258f0d331329d67e13eec9d7f4053fd269e3f9b6

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@ -3,6 +3,7 @@
#include <eive/eventSubsystemIds.h> #include <eive/eventSubsystemIds.h>
#include <fsfw/modes/HasModesIF.h> #include <fsfw/modes/HasModesIF.h>
#include <mission/sysDefs.h>
namespace acs { namespace acs {
@ -11,12 +12,12 @@ enum class SimpleSensorMode { NORMAL = 0, OFF = 1 };
// These modes are the modes of the ACS controller and of the ACS subsystem. // These modes are the modes of the ACS controller and of the ACS subsystem.
enum AcsMode : Mode_t { enum AcsMode : Mode_t {
OFF = HasModesIF::MODE_OFF, OFF = HasModesIF::MODE_OFF,
SAFE = 10, SAFE = satsystem::Mode::SAFE,
PTG_IDLE = 11, PTG_IDLE = satsystem::Mode::PTG_IDLE,
PTG_NADIR = 12, PTG_NADIR = satsystem::Mode::PTG_NADIR,
PTG_TARGET = 13, PTG_TARGET = satsystem::Mode::PTG_TARGET,
PTG_TARGET_GS = 14, PTG_TARGET_GS = satsystem::Mode::PTG_TARGET_GS,
PTG_INERTIAL = 15, PTG_INERTIAL = satsystem::Mode::PTG_INERTIAL,
}; };
enum SafeSubmode : Submode_t { DEFAULT = 0, DETUMBLE = 1 }; enum SafeSubmode : Submode_t { DEFAULT = 0, DETUMBLE = 1 };

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@ -92,6 +92,9 @@ static constexpr size_t SENSOR_READOUT_SIZE = 20 + 2;
static constexpr uint32_t ADIS_DATASET_ID = READ_SENSOR_DATA; static constexpr uint32_t ADIS_DATASET_ID = READ_SENSOR_DATA;
static constexpr uint32_t ADIS_CFG_DATASET_ID = READ_OUT_CONFIG; static constexpr uint32_t ADIS_CFG_DATASET_ID = READ_OUT_CONFIG;
static constexpr uint16_t FILT_CTRL = 0x0000;
static constexpr uint16_t DEC_RATE = 0x0013;
enum GlobCmds : uint8_t { enum GlobCmds : uint8_t {
FACTORY_CALIBRATION = 0b0000'0010, FACTORY_CALIBRATION = 0b0000'0010,
SENSOR_SELF_TEST = 0b0000'0100, SENSOR_SELF_TEST = 0b0000'0100,

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@ -781,9 +781,9 @@ class AcsParameters : public HasParametersIF {
/* var = sigma^2, sigma = RND*sqrt(freq), following values are RND^2 and not var as freq is /* var = sigma^2, sigma = RND*sqrt(freq), following values are RND^2 and not var as freq is
* assumed to be equal for the same class of sensors */ * assumed to be equal for the same class of sensors */
float gyr02variance[3] = {pow(3.0e-3, 2), // RND_x = 3.0e-3 deg/s/sqrt(Hz) rms float gyr02variance[3] = {pow(4.6e-3, 2), // RND_x = 3.0e-3 deg/s/sqrt(Hz) rms
pow(3.0e-3, 2), // RND_y = 3.0e-3 deg/s/sqrt(Hz) rms pow(4.6e-3, 2), // RND_y = 3.0e-3 deg/s/sqrt(Hz) rms
pow(4.3e-3, 2)}; // RND_z = 4.3e-3 deg/s/sqrt(Hz) rms pow(6.1e-3, 2)}; // RND_z = 4.3e-3 deg/s/sqrt(Hz) rms
float gyr13variance[3] = {pow(11e-3, 2), pow(11e-3, 2), pow(11e-3, 2)}; float gyr13variance[3] = {pow(11e-3, 2), pow(11e-3, 2), pow(11e-3, 2)};
uint8_t preferAdis = false; uint8_t preferAdis = false;
float gyrFilterWeight = 0.6; float gyrFilterWeight = 0.6;

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@ -96,9 +96,10 @@ std::atomic_bool tcs::TCS_BOARD_SHORTLY_UNAVAILABLE = false;
void ObjectFactory::produceGenericObjects(HealthTableIF** healthTable_, PusTmFunnel** pusFunnel, void ObjectFactory::produceGenericObjects(HealthTableIF** healthTable_, PusTmFunnel** pusFunnel,
CfdpTmFunnel** cfdpFunnel, SdCardMountedIF& sdcMan, CfdpTmFunnel** cfdpFunnel, SdCardMountedIF& sdcMan,
StorageManagerIF** ipcStore, StorageManagerIF** tmStore, StorageManagerIF** ipcStore, StorageManagerIF** tmStore,
PersistentTmStores& stores) { PersistentTmStores& stores,
uint32_t eventManagerQueueDepth) {
// Framework objects // Framework objects
new EventManager(objects::EVENT_MANAGER, 160); new EventManager(objects::EVENT_MANAGER, eventManagerQueueDepth);
auto healthTable = new HealthTable(objects::HEALTH_TABLE); auto healthTable = new HealthTable(objects::HEALTH_TABLE);
if (healthTable_ != nullptr) { if (healthTable_ != nullptr) {
*healthTable_ = healthTable; *healthTable_ = healthTable;

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@ -45,7 +45,7 @@ namespace ObjectFactory {
void produceGenericObjects(HealthTableIF** healthTable, PusTmFunnel** pusFunnel, void produceGenericObjects(HealthTableIF** healthTable, PusTmFunnel** pusFunnel,
CfdpTmFunnel** cfdpFunnel, SdCardMountedIF& sdcMan, CfdpTmFunnel** cfdpFunnel, SdCardMountedIF& sdcMan,
StorageManagerIF** ipcStore, StorageManagerIF** tmStore, StorageManagerIF** ipcStore, StorageManagerIF** tmStore,
PersistentTmStores& stores); PersistentTmStores& stores, uint32_t eventManagerQueueDepth);
void createGenericHeaterComponents(GpioIF& gpioIF, PowerSwitchIF& pwrSwitcher, void createGenericHeaterComponents(GpioIF& gpioIF, PowerSwitchIF& pwrSwitcher,
HeaterHandler*& heaterHandler); HeaterHandler*& heaterHandler);

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@ -5,10 +5,12 @@
#include "fsfw/tasks/PeriodicTaskIF.h" #include "fsfw/tasks/PeriodicTaskIF.h"
void scheduling::scheduleTmpTempSensors(PeriodicTaskIF* tmpTask) { void scheduling::scheduleTmpTempSensors(PeriodicTaskIF* tmpTask) {
const std::array<object_id_t, 5> tmpIds = { const std::array<object_id_t, 4> tmpIds = {objects::TMP1075_HANDLER_TCS_0,
objects::TMP1075_HANDLER_TCS_0, objects::TMP1075_HANDLER_TCS_1, objects::TMP1075_HANDLER_TCS_1,
objects::TMP1075_HANDLER_PLPCDU_0, objects::TMP1075_HANDLER_PLPCDU_1, objects::TMP1075_HANDLER_PLPCDU_0,
objects::TMP1075_HANDLER_IF_BOARD}; // damaged.
// objects::TMP1075_HANDLER_PLPCDU_1,
objects::TMP1075_HANDLER_IF_BOARD};
for (const auto& tmpId : tmpIds) { for (const auto& tmpId : tmpIds) {
tmpTask->addComponent(tmpId, DeviceHandlerIF::PERFORM_OPERATION); tmpTask->addComponent(tmpId, DeviceHandlerIF::PERFORM_OPERATION);
tmpTask->addComponent(tmpId, DeviceHandlerIF::SEND_WRITE); tmpTask->addComponent(tmpId, DeviceHandlerIF::SEND_WRITE);

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@ -1,16 +1,28 @@
#ifndef MISSION_SYSDEFS_H_ #ifndef MISSION_SYSDEFS_H_
#define MISSION_SYSDEFS_H_ #define MISSION_SYSDEFS_H_
#include <atomic> #include <fsfw/action/ActionMessage.h>
#include <fsfw/action/HasActionsIF.h>
#include <fsfw/modes/ModeMessage.h>
#include <fsfw/serialize/SerializeIF.h>
#include "acs/defs.h" #include <atomic>
#include <cstring>
extern std::atomic_uint16_t I2C_FATAL_ERRORS; extern std::atomic_uint16_t I2C_FATAL_ERRORS;
namespace satsystem { namespace satsystem {
enum Mode : Mode_t { BOOT = 5, SAFE = acs::AcsMode::SAFE, PTG_IDLE = acs::AcsMode::PTG_IDLE }; enum Mode : Mode_t {
BOOT = 5,
// DO NOT CHANGE THE ORDER starting from here, breaks ACS mode checks.
SAFE = 10,
PTG_IDLE = 11,
PTG_NADIR = 12,
PTG_TARGET = 13,
PTG_TARGET_GS = 14,
PTG_INERTIAL = 15,
};
} }
namespace xsc { namespace xsc {

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@ -39,18 +39,22 @@ void EiveSystem::announceMode(bool recursive) {
modeStr = "POINTING IDLE"; modeStr = "POINTING IDLE";
break; break;
} }
case (acs::AcsMode::PTG_INERTIAL): { case (satsystem::Mode::PTG_NADIR): {
modeStr = "POINTING INERTIAL"; modeStr = "POINTING NADIR";
break; break;
} }
case (acs::AcsMode::PTG_TARGET): { case (satsystem::Mode::PTG_TARGET): {
modeStr = "POINTING TARGET"; modeStr = "POINTING TARGET";
break; break;
} }
case (acs::AcsMode::PTG_TARGET_GS): { case (satsystem::Mode::PTG_TARGET_GS): {
modeStr = "POINTING TARGET GS"; modeStr = "POINTING TARGET GS";
break; break;
} }
case (satsystem::Mode::PTG_INERTIAL): {
modeStr = "POINTING INERTIAL";
break;
}
} }
sif::info << "EIVE system is now in " << modeStr << " mode" << std::endl; sif::info << "EIVE system is now in " << modeStr << " mode" << std::endl;
return Subsystem::announceMode(recursive); return Subsystem::announceMode(recursive);

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@ -183,11 +183,11 @@ void DualLaneAssemblyBase::handleModeTransitionFailed(ReturnValue_t result) {
// transition to dual mode. // transition to dual mode.
if (not tryingOtherSide) { if (not tryingOtherSide) {
triggerEvent(CANT_KEEP_MODE, mode, submode); triggerEvent(CANT_KEEP_MODE, mode, submode);
startTransition(mode, nextSubmode); startTransition(targetMode, nextSubmode);
tryingOtherSide = true; tryingOtherSide = true;
} else { } else {
triggerEvent(transitionOtherSideFailedEvent, mode, targetSubmode); triggerEvent(transitionOtherSideFailedEvent, targetMode, targetSubmode);
startTransition(mode, Submodes::DUAL_MODE); startTransition(targetMode, Submodes::DUAL_MODE);
} }
} }
@ -205,7 +205,8 @@ bool DualLaneAssemblyBase::checkAndHandleRecovery() {
opCode = pwrStateMachine.fsm(); opCode = pwrStateMachine.fsm();
if (opCode == OpCodes::TO_OFF_DONE or opCode == OpCodes::TIMEOUT_OCCURED) { if (opCode == OpCodes::TO_OFF_DONE or opCode == OpCodes::TIMEOUT_OCCURED) {
customRecoveryStates = RecoveryCustomStates::POWER_SWITCHING_ON; customRecoveryStates = RecoveryCustomStates::POWER_SWITCHING_ON;
pwrStateMachine.start(targetMode, targetSubmode); // Command power back on in any case.
pwrStateMachine.start(HasModesIF::MODE_ON, targetSubmode);
} }
} }
if (customRecoveryStates == POWER_SWITCHING_ON) { if (customRecoveryStates == POWER_SWITCHING_ON) {

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@ -22,6 +22,10 @@ const auto check = subsystem::checkInsert;
void buildBootSequence(Subsystem& ss, ModeListEntry& eh); void buildBootSequence(Subsystem& ss, ModeListEntry& eh);
void buildSafeSequence(Subsystem& ss, ModeListEntry& eh); void buildSafeSequence(Subsystem& ss, ModeListEntry& eh);
void buildIdleSequence(Subsystem& ss, ModeListEntry& eh); void buildIdleSequence(Subsystem& ss, ModeListEntry& eh);
void buildPtgNadirSequence(Subsystem& ss, ModeListEntry& eh);
void buildPtgTargetSequence(Subsystem& ss, ModeListEntry& eh);
void buildPtgTargetGsSequence(Subsystem& ss, ModeListEntry& eh);
void buildPtgInertialSequence(Subsystem& ss, ModeListEntry& eh);
} // namespace } // namespace
static const auto OFF = HasModesIF::MODE_OFF; static const auto OFF = HasModesIF::MODE_OFF;
@ -40,6 +44,10 @@ void satsystem::init() {
buildBootSequence(EIVE_SYSTEM, entry); buildBootSequence(EIVE_SYSTEM, entry);
buildSafeSequence(EIVE_SYSTEM, entry); buildSafeSequence(EIVE_SYSTEM, entry);
buildIdleSequence(EIVE_SYSTEM, entry); buildIdleSequence(EIVE_SYSTEM, entry);
buildPtgNadirSequence(EIVE_SYSTEM, entry);
buildPtgTargetSequence(EIVE_SYSTEM, entry);
buildPtgTargetGsSequence(EIVE_SYSTEM, entry);
buildPtgInertialSequence(EIVE_SYSTEM, entry);
EIVE_SYSTEM.setInitialMode(satsystem::Mode::BOOT, 0); EIVE_SYSTEM.setInitialMode(satsystem::Mode::BOOT, 0);
} }
@ -68,88 +76,44 @@ auto EIVE_TABLE_IDLE_TRANS_0 =
auto EIVE_TABLE_IDLE_TRANS_1 = auto EIVE_TABLE_IDLE_TRANS_1 =
std::make_pair((satsystem::Mode::PTG_IDLE << 24) | 3, FixedArrayList<ModeListEntry, 5>()); std::make_pair((satsystem::Mode::PTG_IDLE << 24) | 3, FixedArrayList<ModeListEntry, 5>());
auto EIVE_SEQUENCE_PTG_NADIR =
std::make_pair(satsystem::Mode::PTG_NADIR, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_NADIR_TGT =
std::make_pair((satsystem::Mode::PTG_NADIR << 24) | 1, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_NADIR_TRANS_0 =
std::make_pair((satsystem::Mode::PTG_NADIR << 24) | 2, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_NADIR_TRANS_1 =
std::make_pair((satsystem::Mode::PTG_NADIR << 24) | 3, FixedArrayList<ModeListEntry, 5>());
auto EIVE_SEQUENCE_PTG_TARGET =
std::make_pair(satsystem::Mode::PTG_TARGET, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_TARGET_TGT =
std::make_pair((satsystem::Mode::PTG_TARGET << 24) | 1, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_TARGET_TRANS_0 =
std::make_pair((satsystem::Mode::PTG_TARGET << 24) | 2, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_TARGET_TRANS_1 =
std::make_pair((satsystem::Mode::PTG_TARGET << 24) | 3, FixedArrayList<ModeListEntry, 5>());
auto EIVE_SEQUENCE_PTG_TARGET_GS =
std::make_pair(satsystem::Mode::PTG_TARGET_GS, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_TARGET_GS_TGT =
std::make_pair((satsystem::Mode::PTG_TARGET_GS << 24) | 1, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_TARGET_GS_TRANS_0 =
std::make_pair((satsystem::Mode::PTG_TARGET_GS << 24) | 2, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_TARGET_GS_TRANS_1 =
std::make_pair((satsystem::Mode::PTG_TARGET_GS << 24) | 3, FixedArrayList<ModeListEntry, 5>());
auto EIVE_SEQUENCE_PTG_INERTIAL =
std::make_pair(satsystem::Mode::PTG_INERTIAL, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_INERTIAL_TGT =
std::make_pair((satsystem::Mode::PTG_INERTIAL << 24) | 1, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_INERTIAL_TRANS_0 =
std::make_pair((satsystem::Mode::PTG_INERTIAL << 24) | 2, FixedArrayList<ModeListEntry, 5>());
auto EIVE_TABLE_PTG_INERTIAL_TRANS_1 =
std::make_pair((satsystem::Mode::PTG_INERTIAL << 24) | 3, FixedArrayList<ModeListEntry, 5>());
namespace { namespace {
void buildSafeSequence(Subsystem& ss, ModeListEntry& eh) {
std::string context = "satsystem::buildSafeSequence";
auto ctxc = context.c_str();
// Insert Helper Table
auto iht = [&](object_id_t obj, Mode_t mode, Submode_t submode, ArrayList<ModeListEntry>& table,
bool allowAllSubmodes = false) {
eh.setObject(obj);
eh.setMode(mode);
eh.setSubmode(submode);
if (allowAllSubmodes) {
eh.allowAllSubmodes();
}
check(table.insert(eh), ctxc);
};
// Insert Helper Sequence
auto ihs = [&](ArrayList<ModeListEntry>& sequence, Mode_t tableId, uint32_t waitSeconds,
bool checkSuccess) {
eh.setTableId(tableId);
eh.setWaitSeconds(waitSeconds);
eh.setCheckSuccess(checkSuccess);
check(sequence.insert(eh), ctxc);
};
// Do no track submode to allow transitions to DETUMBLE submode.
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::SAFE, 0, EIVE_TABLE_SAFE_TGT.second, true);
iht(objects::PL_SUBSYSTEM, OFF, 0, EIVE_TABLE_SAFE_TGT.second);
check(ss.addTable(TableEntry(EIVE_TABLE_SAFE_TGT.first, &EIVE_TABLE_SAFE_TGT.second)), ctxc);
// Build SAFE transition 0.
iht(objects::TCS_SUBSYSTEM, NML, 0, EIVE_TABLE_SAFE_TRANS_0.second);
iht(objects::PL_SUBSYSTEM, OFF, 0, EIVE_TABLE_SAFE_TRANS_0.second);
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::SAFE, 0, EIVE_TABLE_SAFE_TRANS_0.second, true);
check(ss.addTable(TableEntry(EIVE_TABLE_SAFE_TRANS_0.first, &EIVE_TABLE_SAFE_TRANS_0.second)),
ctxc);
// Build Safe sequence
ihs(EIVE_SEQUENCE_SAFE.second, EIVE_TABLE_SAFE_TGT.first, 0, false);
ihs(EIVE_SEQUENCE_SAFE.second, EIVE_TABLE_SAFE_TRANS_0.first, 0, false);
check(ss.addSequence(SequenceEntry(EIVE_SEQUENCE_SAFE.first, &EIVE_SEQUENCE_SAFE.second,
EIVE_SEQUENCE_SAFE.first)),
ctxc);
}
void buildIdleSequence(Subsystem& ss, ModeListEntry& eh) {
std::string context = "satsystem::buildIdleSequence";
auto ctxc = context.c_str();
// Insert Helper Table
auto iht = [&](object_id_t obj, Mode_t mode, Submode_t submode, ArrayList<ModeListEntry>& table) {
eh.setObject(obj);
eh.setMode(mode);
eh.setSubmode(submode);
check(table.insert(eh), ctxc);
};
// Insert Helper Sequence
auto ihs = [&](ArrayList<ModeListEntry>& sequence, Mode_t tableId, uint32_t waitSeconds,
bool checkSuccess) {
eh.setTableId(tableId);
eh.setWaitSeconds(waitSeconds);
eh.setCheckSuccess(checkSuccess);
check(sequence.insert(eh), ctxc);
};
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_IDLE, 0, EIVE_TABLE_IDLE_TGT.second);
check(ss.addTable(TableEntry(EIVE_TABLE_IDLE_TGT.first, &EIVE_TABLE_IDLE_TGT.second)), ctxc);
// Build IDLE transition 0
iht(objects::TCS_SUBSYSTEM, NML, 0, EIVE_TABLE_IDLE_TRANS_0.second);
iht(objects::PL_SUBSYSTEM, OFF, 0, EIVE_TABLE_IDLE_TRANS_0.second);
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_IDLE, 0, EIVE_TABLE_IDLE_TRANS_0.second);
check(ss.addTable(TableEntry(EIVE_TABLE_IDLE_TRANS_0.first, &EIVE_TABLE_IDLE_TRANS_0.second)),
ctxc);
// Build IDLE sequence
ihs(EIVE_SEQUENCE_IDLE.second, EIVE_TABLE_IDLE_TGT.first, 0, false);
ihs(EIVE_SEQUENCE_IDLE.second, EIVE_TABLE_IDLE_TRANS_0.first, 0, false);
check(ss.addSequence(SequenceEntry(EIVE_SEQUENCE_IDLE.first, &EIVE_SEQUENCE_IDLE.second,
EIVE_SEQUENCE_SAFE.first)),
ctxc);
}
void buildBootSequence(Subsystem& ss, ModeListEntry& eh) { void buildBootSequence(Subsystem& ss, ModeListEntry& eh) {
std::string context = "satsystem::buildBootSequence"; std::string context = "satsystem::buildBootSequence";
auto ctxc = context.c_str(); auto ctxc = context.c_str();
@ -194,4 +158,240 @@ void buildBootSequence(Subsystem& ss, ModeListEntry& eh) {
EIVE_SEQUENCE_SAFE.first)), EIVE_SEQUENCE_SAFE.first)),
ctxc); ctxc);
} }
void buildSafeSequence(Subsystem& ss, ModeListEntry& eh) {
std::string context = "satsystem::buildSafeSequence";
auto ctxc = context.c_str();
// Insert Helper Table
auto iht = [&](object_id_t obj, Mode_t mode, Submode_t submode, ArrayList<ModeListEntry>& table,
bool allowAllSubmodes = false) {
eh.setObject(obj);
eh.setMode(mode);
eh.setSubmode(submode);
if (allowAllSubmodes) {
eh.allowAllSubmodes();
}
check(table.insert(eh), ctxc);
};
// Insert Helper Sequence
auto ihs = [&](ArrayList<ModeListEntry>& sequence, Mode_t tableId, uint32_t waitSeconds,
bool checkSuccess) {
eh.setTableId(tableId);
eh.setWaitSeconds(waitSeconds);
eh.setCheckSuccess(checkSuccess);
check(sequence.insert(eh), ctxc);
};
// Do no track submode to allow transitions to DETUMBLE submode.
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::SAFE, 0, EIVE_TABLE_SAFE_TGT.second, true);
check(ss.addTable(TableEntry(EIVE_TABLE_SAFE_TGT.first, &EIVE_TABLE_SAFE_TGT.second)), ctxc);
// Build SAFE transition 0.
iht(objects::TCS_SUBSYSTEM, NML, 0, EIVE_TABLE_SAFE_TRANS_0.second);
iht(objects::PL_SUBSYSTEM, OFF, 0, EIVE_TABLE_SAFE_TRANS_0.second);
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::SAFE, 0, EIVE_TABLE_SAFE_TRANS_0.second, true);
check(ss.addTable(TableEntry(EIVE_TABLE_SAFE_TRANS_0.first, &EIVE_TABLE_SAFE_TRANS_0.second)),
ctxc);
// Build Safe sequence
ihs(EIVE_SEQUENCE_SAFE.second, EIVE_TABLE_SAFE_TGT.first, 0, false);
ihs(EIVE_SEQUENCE_SAFE.second, EIVE_TABLE_SAFE_TRANS_0.first, 0, false);
check(ss.addSequence(SequenceEntry(EIVE_SEQUENCE_SAFE.first, &EIVE_SEQUENCE_SAFE.second,
EIVE_SEQUENCE_SAFE.first)),
ctxc);
}
void buildIdleSequence(Subsystem& ss, ModeListEntry& eh) {
std::string context = "satsystem::buildIdleSequence";
auto ctxc = context.c_str();
// Insert Helper Table
auto iht = [&](object_id_t obj, Mode_t mode, Submode_t submode, ArrayList<ModeListEntry>& table) {
eh.setObject(obj);
eh.setMode(mode);
eh.setSubmode(submode);
check(table.insert(eh), ctxc);
};
// Insert Helper Sequence
auto ihs = [&](ArrayList<ModeListEntry>& sequence, Mode_t tableId, uint32_t waitSeconds,
bool checkSuccess) {
eh.setTableId(tableId);
eh.setWaitSeconds(waitSeconds);
eh.setCheckSuccess(checkSuccess);
check(sequence.insert(eh), ctxc);
};
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_IDLE, 0, EIVE_TABLE_IDLE_TGT.second);
check(ss.addTable(TableEntry(EIVE_TABLE_IDLE_TGT.first, &EIVE_TABLE_IDLE_TGT.second)), ctxc);
// Build IDLE transition 0
iht(objects::TCS_SUBSYSTEM, NML, 0, EIVE_TABLE_IDLE_TRANS_0.second);
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_IDLE, 0, EIVE_TABLE_IDLE_TRANS_0.second);
check(ss.addTable(TableEntry(EIVE_TABLE_IDLE_TRANS_0.first, &EIVE_TABLE_IDLE_TRANS_0.second)),
ctxc);
// Build IDLE sequence
ihs(EIVE_SEQUENCE_IDLE.second, EIVE_TABLE_IDLE_TGT.first, 0, false);
ihs(EIVE_SEQUENCE_IDLE.second, EIVE_TABLE_IDLE_TRANS_0.first, 0, false);
check(ss.addSequence(SequenceEntry(EIVE_SEQUENCE_IDLE.first, &EIVE_SEQUENCE_IDLE.second,
EIVE_SEQUENCE_SAFE.first)),
ctxc);
}
void buildPtgNadirSequence(Subsystem& ss, ModeListEntry& eh) {
std::string context = "satsystem::buildPtgNadirSequence";
auto ctxc = context.c_str();
// Insert Helper Table
auto iht = [&](object_id_t obj, Mode_t mode, Submode_t submode, ArrayList<ModeListEntry>& table) {
eh.setObject(obj);
eh.setMode(mode);
eh.setSubmode(submode);
check(table.insert(eh), ctxc);
};
// Insert Helper Sequence
auto ihs = [&](ArrayList<ModeListEntry>& sequence, Mode_t tableId, uint32_t waitSeconds,
bool checkSuccess) {
eh.setTableId(tableId);
eh.setWaitSeconds(waitSeconds);
eh.setCheckSuccess(checkSuccess);
check(sequence.insert(eh), ctxc);
};
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_NADIR, 0, EIVE_TABLE_PTG_NADIR_TGT.second);
check(ss.addTable(TableEntry(EIVE_TABLE_PTG_NADIR_TGT.first, &EIVE_TABLE_PTG_NADIR_TGT.second)),
ctxc);
// Build PTG_NADIR transition 0
iht(objects::TCS_SUBSYSTEM, NML, 0, EIVE_TABLE_PTG_NADIR_TRANS_0.second);
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_NADIR, 0, EIVE_TABLE_PTG_NADIR_TRANS_0.second);
check(ss.addTable(
TableEntry(EIVE_TABLE_PTG_NADIR_TRANS_0.first, &EIVE_TABLE_PTG_NADIR_TRANS_0.second)),
ctxc);
// Build PTG_NADIR sequence
ihs(EIVE_SEQUENCE_PTG_NADIR.second, EIVE_TABLE_PTG_NADIR_TGT.first, 0, false);
ihs(EIVE_SEQUENCE_PTG_NADIR.second, EIVE_TABLE_PTG_NADIR_TRANS_0.first, 0, false);
check(ss.addSequence(SequenceEntry(EIVE_SEQUENCE_PTG_NADIR.first, &EIVE_SEQUENCE_PTG_NADIR.second,
EIVE_SEQUENCE_IDLE.first)),
ctxc);
}
void buildPtgTargetSequence(Subsystem& ss, ModeListEntry& eh) {
std::string context = "satsystem::buildPtgTargetSequence";
auto ctxc = context.c_str();
// Insert Helper Table
auto iht = [&](object_id_t obj, Mode_t mode, Submode_t submode, ArrayList<ModeListEntry>& table) {
eh.setObject(obj);
eh.setMode(mode);
eh.setSubmode(submode);
check(table.insert(eh), ctxc);
};
// Insert Helper Sequence
auto ihs = [&](ArrayList<ModeListEntry>& sequence, Mode_t tableId, uint32_t waitSeconds,
bool checkSuccess) {
eh.setTableId(tableId);
eh.setWaitSeconds(waitSeconds);
eh.setCheckSuccess(checkSuccess);
check(sequence.insert(eh), ctxc);
};
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_TARGET, 0, EIVE_TABLE_PTG_TARGET_TGT.second);
check(ss.addTable(TableEntry(EIVE_TABLE_PTG_TARGET_TGT.first, &EIVE_TABLE_PTG_TARGET_TGT.second)),
ctxc);
// Build PTG_TARGET transition 0
iht(objects::TCS_SUBSYSTEM, NML, 0, EIVE_TABLE_PTG_TARGET_TRANS_0.second);
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_TARGET, 0, EIVE_TABLE_PTG_TARGET_TRANS_0.second);
check(ss.addTable(
TableEntry(EIVE_TABLE_PTG_TARGET_TRANS_0.first, &EIVE_TABLE_PTG_TARGET_TRANS_0.second)),
ctxc);
// Build PTG_TARGET sequence
ihs(EIVE_SEQUENCE_PTG_TARGET.second, EIVE_TABLE_PTG_TARGET_TGT.first, 0, false);
ihs(EIVE_SEQUENCE_PTG_TARGET.second, EIVE_TABLE_PTG_TARGET_TRANS_0.first, 0, false);
check(ss.addSequence(SequenceEntry(EIVE_SEQUENCE_PTG_TARGET.first,
&EIVE_SEQUENCE_PTG_TARGET.second, EIVE_SEQUENCE_IDLE.first)),
ctxc);
}
void buildPtgTargetGsSequence(Subsystem& ss, ModeListEntry& eh) {
std::string context = "satsystem::buildPtgTargetGsSequence";
auto ctxc = context.c_str();
// Insert Helper Table
auto iht = [&](object_id_t obj, Mode_t mode, Submode_t submode, ArrayList<ModeListEntry>& table) {
eh.setObject(obj);
eh.setMode(mode);
eh.setSubmode(submode);
check(table.insert(eh), ctxc);
};
// Insert Helper Sequence
auto ihs = [&](ArrayList<ModeListEntry>& sequence, Mode_t tableId, uint32_t waitSeconds,
bool checkSuccess) {
eh.setTableId(tableId);
eh.setWaitSeconds(waitSeconds);
eh.setCheckSuccess(checkSuccess);
check(sequence.insert(eh), ctxc);
};
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_TARGET_GS, 0, EIVE_TABLE_PTG_TARGET_GS_TGT.second);
check(ss.addTable(
TableEntry(EIVE_TABLE_PTG_TARGET_GS_TGT.first, &EIVE_TABLE_PTG_TARGET_GS_TGT.second)),
ctxc);
// Build PTG_TARGET_GS transition 0
iht(objects::TCS_SUBSYSTEM, NML, 0, EIVE_TABLE_PTG_TARGET_GS_TRANS_0.second);
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_TARGET_GS, 0,
EIVE_TABLE_PTG_TARGET_GS_TRANS_0.second);
check(ss.addTable(TableEntry(EIVE_TABLE_PTG_TARGET_GS_TRANS_0.first,
&EIVE_TABLE_PTG_TARGET_GS_TRANS_0.second)),
ctxc);
// Build PTG_TARGET_GS sequence
ihs(EIVE_SEQUENCE_PTG_TARGET_GS.second, EIVE_TABLE_PTG_TARGET_GS_TGT.first, 0, false);
ihs(EIVE_SEQUENCE_PTG_TARGET_GS.second, EIVE_TABLE_PTG_TARGET_GS_TRANS_0.first, 0, false);
check(
ss.addSequence(SequenceEntry(EIVE_SEQUENCE_PTG_TARGET_GS.first,
&EIVE_SEQUENCE_PTG_TARGET_GS.second, EIVE_SEQUENCE_IDLE.first)),
ctxc);
}
void buildPtgInertialSequence(Subsystem& ss, ModeListEntry& eh) {
std::string context = "satsystem::buildPtgInertialSequence";
auto ctxc = context.c_str();
// Insert Helper Table
auto iht = [&](object_id_t obj, Mode_t mode, Submode_t submode, ArrayList<ModeListEntry>& table) {
eh.setObject(obj);
eh.setMode(mode);
eh.setSubmode(submode);
check(table.insert(eh), ctxc);
};
// Insert Helper Sequence
auto ihs = [&](ArrayList<ModeListEntry>& sequence, Mode_t tableId, uint32_t waitSeconds,
bool checkSuccess) {
eh.setTableId(tableId);
eh.setWaitSeconds(waitSeconds);
eh.setCheckSuccess(checkSuccess);
check(sequence.insert(eh), ctxc);
};
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_INERTIAL, 0, EIVE_TABLE_PTG_INERTIAL_TGT.second);
check(ss.addTable(
TableEntry(EIVE_TABLE_PTG_INERTIAL_TGT.first, &EIVE_TABLE_PTG_INERTIAL_TGT.second)),
ctxc);
// Build PTG_INERTIAL transition 0
iht(objects::TCS_SUBSYSTEM, NML, 0, EIVE_TABLE_PTG_INERTIAL_TRANS_0.second);
iht(objects::ACS_SUBSYSTEM, acs::AcsMode::PTG_INERTIAL, 0,
EIVE_TABLE_PTG_INERTIAL_TRANS_0.second);
check(ss.addTable(TableEntry(EIVE_TABLE_PTG_INERTIAL_TRANS_0.first,
&EIVE_TABLE_PTG_INERTIAL_TRANS_0.second)),
ctxc);
// Build PTG_INERTIAL sequence
ihs(EIVE_SEQUENCE_PTG_INERTIAL.second, EIVE_TABLE_PTG_INERTIAL_TGT.first, 0, false);
ihs(EIVE_SEQUENCE_PTG_INERTIAL.second, EIVE_TABLE_PTG_INERTIAL_TRANS_0.first, 0, false);
check(ss.addSequence(SequenceEntry(EIVE_SEQUENCE_PTG_INERTIAL.first,
&EIVE_SEQUENCE_PTG_INERTIAL.second, EIVE_SEQUENCE_IDLE.first)),
ctxc);
}
} // namespace } // namespace